Verbesserter elektronischer Tauchsieder

Aquarium-Heizvorrichtung

Aquarium

Aquariumheizer

HEIZKÖRPER FÜR AQUARIEN

Transparentes Gehäuse mit Versorgungsleitungen für einen elektrischen Verbraucher

Gehäuse mit mindestens einem transparenten Plattenelement und mindestens einen elektrischen Leiter, wobei das mindestens eine transparente Plattenelement eine Aussparung aufweist, deren Längsrichtung sich im wesentlichen parallel zu einer Hauptfläche des Plattenelementes erstreckt, und wobei der elektrische Leiter zumindest abschnittsweise in der Aussparung verläuft.

Heating device for aquaria of two thousand litres of water is attachable to in-house heating system and has thermostatic regulating valve with remote control sensor

The heating device is attachable to a heating system provided in house and feeding the heating elements (11) with hot water. A thermostatic regulating valve with remote control sensor is attached to the filter system or direct to the aquarium. Independent claim describes safety aspect by mechanically regulating thermostatic control through flow volume ...

AQUARIUM HEATER

Containers of live marine animals

Automatic environment control system for animal or plant enclosures

A device for the automated control of an enclosure for animals or plant enclosures comprises the control of temperature and/or humidity and/or lighting based upon daily geographical sunrise/sunset times downloaded from a web service. This invention seeks to replicate the environment of a specific geographical location by downloading environmental data from the geographical location to control the lighting, humidity and temperature. A website may be created to control the device by downloading data onto a memory card.

Self-sustainable water temperature regulating floating vehicle

An electrical floating vehicle powered by renewable energy systems that regulates the temperature of the water it floats on, such as local areas of sea, oceans or lakes. The vehicle is powered by wind sails having wind turbines 1; hydro generators/turbines (77, Fig 6 ) and solar panels 34, 35, 37, 40. The wind turbines and hydro turbines have two axis of rotation, one to allow the turbines to track wind and water direction changes, and another to allow the turbines to be retracted. The energy systems power may power the vehicles propulsion units; be stored in energy storage devices e.g. battery; or used to regulate the water temperature via temperature regulating channels within the vehicle. Water enters the channels due to the movement of the vehicle, or via the use of circulation pumps. The water is either cooled or heated via its interaction with said channels, e.g. heat exchange. The vehicle may have water temperature and velocity measuring devices, sonar and means to control the workings ...

A heating device

Freezing method and apparatus.

HEATING AND PUMPING DEVICE FOR LIQUIDS, IN PARTICULAR FOR AQUARIUM WATER

HEATER PROVIDED WITH A COMPACT THERMOSTAT

Method for utilizing heat in a plant or animal growing device, corresponding system and greenhouse

A method for utilizing heat in a plant or animal growing device, 5 comprises the following steps: - circulating a heat transfer fluid through a circuit forming a closed fluid loop, and in the circuit: 1) heating of a heat transfer fluid by a heat source (2), 2) supplying heat from the heat transfer fluid to a first heat user consisting of a thermal desalination unit (4), and 3) .0 returning at least part of the heat transfer fluid that has been cooled down, wherein the heat transfer fluid supplies heat to at least one additional heat user (5; 6; 25), serially arranged before or after the thermal desalination unit. The heat transfer fluid .5 temperature ranges wherein the heat users may be within the optimal operating temperature ranges of the respective heat users in the fluid circuit. A corresponding system and greenhouse are claimed, in which the method is embodied. Fig. 1 Si :110 -- -41 ...

HEATERS

DEICING SYSTEMS

Certain embodiments of the present invention provide a deicer system for heating water within a fluid receptacle to prevent ice from forming including a main body configured to be positioned within the fluid receptacle, a heating element adapted to heat the water, a temperature sensor adapted to detect a temperature of the heating element, a switch adapted to activate and deactivate the heating element, and a control unit in communication with the heating element, the temperature sensor, and the switch. The heating element is supported by the main body. The heating element includes a heating coil and a plate. The plate includes one or more fins. The control unit is adapted to control the heating element using the switch based at least in part on a temperature detected by the temperature sensor.

SUBMERSIBLE THERMOSTATICALLY CONTROLLED HEATERS

Instead of the usual glass case the heating element and thermostat of a submersible thermostatically controlled heater are disposed in separate cases made of metal and plastics respectively which are secured together in liquid-tight manner with the heating element connected through the thermostat to an external source of operating current and the metal case for the heating element connected to earth.

RESISTANCE HEATING AND THERMOSTAT FOR AQUARIA

OFF-WATER SHUTDOWN PROTECTION MECHANICAL HEATER

An off-water shutdown protection mechanical heater includes a tube and a cap mounted to an end of the tube. The tube includes therein an off-water protection transducer, one of a relay and a TRIAC, a circuit board including a bimetal plate, and a heating element. When he off-water protection transducer detects a situation of being immersed in water, the one of the relay and the TRIAC turns on to conduct electricity and the bimetal plate detects a temperature of water and undergoes deformation by the temperature to control the heating element to generate heat or not; and when the off-water protection transducer detects a situation of being removed out of water, the one of the relay and the TRIAC turns off to cut off electricity, making the heating element not generating heat. The off-water protection transducer ensures that electricity is quickly cut off upon removal out of water.

IMMERSION HEATER AND METHOD OF USE

An immersion heater comprising temperature elevating components contained within a housing. The housing comprises a thermally conductive, electrically insulating epoxy on an upper portion thereof, and a highly thermally conductive epoxy o n a lower portion thereof. The temperature elevating components comprise a heating element in communication with a heat regulating system comprising a thermostat, an electrically conductive bracket, and a thermal cut off fuse. The heating element comprise s electrical resistant wire elements which are disposed in the lower portion of the housi ng and contained within a sheath. A temperature non-regulating portion of the thermostat, which is in communication with the electrically conductive bracket, is contained i n the lower portion of the housing, and the temperature regulating component of the thermostat is contained in the upper portion of the housing.

Vorrichtung zum Erwärmen und Warmhalten von Aquarien und Terrarien.

Vorrichtung zum elektrischen Heizen von Aquarien.

Elektrisch-vollautomatische Fischbrut-Anlage.

Mit einem Temperaturregler ausgerüstete Vorrichtung zum Erwärmen und Warmhalten von Flüssigkeiten, insbesondere für Aquarien und Laboratoriumszwecke.

Method and system for using the waste heat of a data processing system.

Die Erfindung betrifft ein Verfahren sowie ein System zur Nutzung der Abwärme einer Datenverarbeitungsanlage (1) mit einer Mehrzahl von Prozessoren mittels eines Kühlwasserkreislaufs. Für das erfindungsgemässe Verfahren beziehungsweise System ist kennzeichnend, dass die Abwärme zur Erwärmung wenigstens eines für wasserlebende Pflanzen oder Tiere bestimmten Aufzuchtbeckens (3) und vorzugsweise zur Erwärmung einer unterhalb einer Pflanzenanbaufläche (5) angeordneten Bodenheizung (4) verwendet wird.

Refrigerator with special radiator for stabilizing the temperature in seawater aquaria.

Gegenstand der Erfindung ist ein in den Kältekreislauf einer Kältemaschine eingebauter Verdampfer (2) für die Kühlung und Stabilisierung der Temperatur speziell in Meerwasser-Aquarien, in den das Kältemittel durch eine Kapillare eingespritzt wird. Der Verdampfer (2) ist meerwasserbeständig, gibt keine schädlichen Ionen ab und kann gut montiert und dank der glatten Oberfläche ohne Ausbau leicht gereinigt werden. Die Saugleitung (4) ist mit einer speziellen Bohrung für die Ölrückführung versehen. Die Einspritzkapillare kann in der Saugleitung (4) verlegt und zur einfachen Montage als flexibler Schlauch in den Kältekreislauf eingebaut werden.

Refrigeration apparatus with refrigerator and evaporator for maintaining temperature in aquariums.

Gegenstand der Erfindung ist ein Kühlgerät für Aquarien, umfassend eine Kältemaschine und einen Verdampfer (2) für die Kühlung und Stabilisierung der Temperatur, speziell in Meerwaser-Aquarien. Das Kältemittel wird durch eine Kapillare in den Verdampfer eingespritzt. Der Verdampfer (2) ist meerwasserbeständig, gibt keine schädlichen Ionen ab und kann gut montiert und dank der glatten Oberfläche ohne Ausbau leicht gereinigt werden. Die Saugleitung (4) ist mit einer speziellen Bohrung für die Ölrückführung versehen. Die Einspritzkapillare kann in der Saugleitung (4) verlegt und zur einfachen Montage als flexibler Schlauch in den Kältekreislauf eingebaut werden.

Macrobrachium rosenbergii fry shipment method

Water tank structure with wireless power transmission electric appliance

RESISTANCES CHAUFFANTES ET THERMOSTATS POUR AQUARIOPHILIE

LA PRESENTE INVENTION CONCERNE UNE RESISTANCE CHAUFFANTE UTILISABLE NOTAMMENT POUR AQUARIUM CARACTERISEE EN CE QU'ELLE EST CONSTITUEE PAR UNE RESISTANCE ELECTRIQUE PROPREMENT DITE, REVETUE D'UNE RESINE THERMOCONDUCTRICE ETANCHE POUVANT ETRE MISE EN FORME PAR DES PROCEDES CONNUS NOTAMMENT PAR MOULAGE.

Plant for adjusting water temperature in reservoir for shellfish culture comprises interchange system in reservoir linked to water to adjust

L'invention concerne une installation pour le refroidissement ou le réchauffement d'un liquide pouvant notamment être utilisé dans le domaine de la conchyliculture caractérisée en ce qu'elle comprend : au moins un bassin (1) accueillant un médium réfrigérant ou un médium réchauffant, au moins un premier dispositif échangeur (2) de calories ou de frigories dans lequel circule un fluide caloporteur ou un fluide frigorigène, ledit premier dispositif étant prévu au moins en partie dans ledit bassin et permettant de chauffer ou de refroidir ledit médium; au moins un second dispositif échangeur (3, 3a) de calories ou de frigories dans lequel circule ledit liquide à refroidir ou à réchauffer, ledit premier dispositif étant prévu au moins en partie dans ledit bassin et étant relié à au moins un réservoir (6, 6a) dudit liquide.

System useful in an aquarium for purifying water, comprises a tank separated from aquarium to receive limited quantity of water and closed by a lid, a unit to heat water present in the tank, a condensation coil, and a reintroduction unit

Ce système (1) comprend : - un réservoir (2) séparé de l'aquarium (20), propre à recevoir une quantité limitée de l'eau de l'aquarium (20), fermé par un couvercle (8) ; - un moyen de chauffage (10) jusqu'à ébullition de l'eau contenue dans ce réservoir (2) ; - un serpentin de condensation (4) de la vapeur d'eau s'échappant du réservoir (2), et - des moyens de réintroduction (6) dans l'aquarium (20) de l'eau distillée ainsi générée.

Device for the heating, ventilation and incidentally, the lighting of the aquarium, terrarium and others, and method for realization

구배 형성이 용이한 밀도 측정 장치

... 본 발명은 어류 란의 발달에 따른 양식수의 적정밀도를 측정하기 위한 밀도 측정 장치에 있어서, 기둥 형상으로 제작되어 내부에 상기 양식수가 수용되기 위한 중공을 마련한 몸체; 및 상기 몸체에 설치되어 상기 중공을 설정된 간격으로 구획하고, 상기 구획된 중공에 상이한 온도를 갖는 상기 양식수를 각각 공급 또는 배출시켜 상기 중공 내 양식수의 온도와 밀도가 조절되도록 하며, 상기 조절에 의해 구배를 형성하는 구배유닛을 포함하는 것을 특징으로 하여, 몸체에 마련된 중공을 설정된 간격으로 구획하고, 서로 다른 온도의 양식수를 각각 공급 및 배출시켜 온도 및 밀도가 조절되도록 하며, 조절에 의해 다양한 밀도구배를 형성하는 구배유닛을 통해 어류 란의 발달에 따른 양식수의 적정밀도를 효율적으로 측정할 수 있다.

FILTRATION APPARATUS FOR AQUAPONICS AND AQUAPONICS SYSTEM USING SAME

APPARATUS FOR PURIFYING WATER AND CONTROLLING WATER TEMPERATURE IN AQUARIUM

The present invention relates to an apparatus for controlling water temperature and purifying water in an aquarium, which maintains a water (seawater) temperature in the aquarium suitable for the survival of fish in accordance with the temperature of the surroundings, and purifies contaminated water in the aquarium, thereby preventing the fish from dying from unsuitable water temperature and contamination, and ensuring long term survival of the fish. The apparatus comprises: a water chamber for keeping fish in seawater contained therein; a water temperature control means; and a water purification means for detecting the contamination level of circulating seawater introduced by the water temperature control means and purifying the seawater, wherein the water temperature control means comprises: a water temperature sensor which is disposed on the outside of the water chamber and detects the water temperature; a control unit which controls the water temperature detected at the water temperature ...

METHOD FOR FARMING SABLEFISH

The present invention relates to a method for farming sablefish, in which water temperature is controlled depending on the size of the young of fishes during sablefish culture. COPYRIGHT KIPO 2018 ...

AQUARIUM WATER HEATER

An aquarium water heater (10) includes a hollow heat-conducting internal tube (12) with an electric resistance heater element (14) and electrical connection disposed adjacent an outer surface of the follow heat-conducting internal tube, a temperature thermal cut-out switch (18) electrically connected to the heater element for overheat protection, and a heat-conducting, electrically insulating polymeric filler (22) spaced between the internal tube and an external tube that circumscribes the internal tube and the heater element. The aquarium water heater also includes a water temperature sensor (76) that senses the temperature of water into which the heater is at least partially immersible, electrically coupled to a controller (70) to activate and deactivate the heater element and to an indicator (24) that indicates a condition that corresponds to the water temperature being in between a first predetermined minimum temperature and a first predetermined maximum temperature and a different ...

Water conditioning assembly

A drop-in, portable, water conditioning assembly for use in a tank containing water is disclosed. The water conditioning assembly includes a refrigeration unit having a compressor assembly, a condenser and at least one depending evaporator coil for insertion into the tank water. A heating element also ends downwardly from a base and a temperature controller is operatively connected to both the refrigeration unit and the heating element for controlling both the heating and cooling of the water. A motor drives a depending shaft which mounts a blade. The blade both aerates and circulates water within the tank.

Heater with distributed heating element

A heater for heating liquids such as water in an aquarium comprises a water-impermeable housing including a heating section for immersion in the water. Within the heating section of the housing is a flexible, distributed planar heating element. The housing is resistant to breakage from mechanical and operating abuse and has a high heat transfer coefficient and high heat distortion temperature. To prevent the housing from melting when a control element of the heater malfunctions, preferably the aquarium heater includes temperature limiting means such as a circuit protection element comprising a material having a positive temperature coefficient of resistance. Preferably, the heating section of the housing is fabricated with large surface area walls to accommodate the planar heating element, and is provided with coupling means for maintaining the heating element thermally coupled to the walls of the heating section. The coupling means can be a ribbed support for holding the heating element ...

Heater apparatus for use in a liquid environment

An improved heater and control apparatus (10) suitable for maintaining a proper temperature in a liquid environment such as an aquarium (12) is provided. The apparatus (10) includes a heater element (26) housed within a protective casing (28) to reduce the likelihood of heater element (26) breakage. A number of openings (30) are provided in casing (28) to permit direct contact between the heater element (26) and water in the aquarium (12). The control assembly (16) includes a novel active light display (99). Additional novel features and corresponding advantages of the apparatus (10) are disclosed.

Temperature control system

A portable, climate controlled, pet enclosure for hermit crabs and the like features an ice chest which receives a temperature controlled pet enclosure. Cigarette lighter DC power and/or a house-current to low-voltage adapter powers a control circuit and heating element on the top of the pet enclosure. By placing a cold substance, such as ice in the ice chest, the desired temperature is maintained in the pet enclosure when the ambient temperature is either too warm or too cold for the pet. Other features include a cool-to-the-touch heater grill, a simple humidifier, and a temperature sensor reflector.

System and method of deactivating a fluid receptacle deicer

A deicing system configured to heat fluid within a fluid receptacle to prevent ice from forming includes a sensing unit and a heating element. The sensing unit is configured to detect a change in at least one of capacitance and resistivity. The heating element is configured to heat the fluid. The sensing unit operates to deactivate the heating element when the sensing unit detects the change in at least one of capacitance and resistivity.

ARTIFICIAL ENVIRONMENT MONITORING

A monitoring system can implement a method including receiving data characterizing first measurements recorded by a sensor in a heating area, second measurements recorded by the sensor in an ambient area, and third measurements recorded by the sensor in a central area, located between the heating area and the ambient area. The method further includes determining a first average temperature, a second average temperature, and a third average temperature. The method further includes computing a first temperature difference between the first average temperature in the heating area and the third average temperature in the central area, and a second temperature difference between second average temperature in the ambient area and the third average temperature of the central area. The method further includes providing the first temperature difference and the second temperature difference.

SEGMENT OF AN AQUARIUM COVER WITH A HEATING AND LIGHTING DEVICE

УЗЕЛ ЩЕТКИ ДЛЯ ПЫЛЕСОСА

... 1. Узел щетки, содержащий корпус, в котором выполнено всасывающее отверстие для грязи, крышку, соединенную с верхней частью корпуса с образованием всасывающего канала и турбинной камеры, турбину, установленную в турбинной камере, и щеточный барабан, приводимый во вращение вращательным усилием, передаваемым от турбины, причем турбинная камера и всасывающий канал отделены друг от друга, а турбина приводится во вращение воздухом, втягиваемым через всасывающее отверстие для воздуха, отделенное от всасывающего отверстия для грязи. 2. Узел щетки по п.1, в котором всасывающее отверстие для воздуха выполнено на крышке с предотвращением втягивания через него грязи. 3. Узел щетки по п.2, в котором крышка содержит первую крышку и вторую крышку, при этом всасывающее отверстие для воздуха содержит первое всасывающее отверстие для воздуха, выполненное на первой крышке, и второе всасывающее отверстие для воздуха, выполненное на второй крышке. 4. Узел щетки по п.3, в котором вторая крышка выполнена из ...

Aquariumsicherheitsheizung mit einem justierbaren Schaltkreisunterbrecher

Verschiedene Formen von Kühlern für Wasser in Aquarien

"TAUCHHEIZVORRICHTUNG"

SICHERHEITSHEIZGERAET

Modular heating element - comprises and crosspieces of conductive fibre-reinforced plastics

A heating element of composite material has a gap (11) between at least two parallel webs (10) of electrically conductive fibre-reinforced plastics and has, at the web ends, a connecting cross-piece (10a) of the same material and with the same volume resistivity. Pref. the composite material contains woven carbon fibres or carbonised synthetic fibres. The heating element (10) consists of carbon fibres or carbonised synthetic fibres, impregnated with resin, such as epoxy, silicone of furan resin, or a water glass binder to form a prepreg which is dried and then hardened by hot pressing at about 500 N/sq.cm. The product is stamped or cut to form the webs and crosspieces. Alternatively, the crosspieces (10a) may consist of metal. The heating element may be covered with plates of glass fibre-reinforced plastics. USE/ADVANTAGE - The heating element is useful for various applications such as hot plates, heating drums for paper and textile processing, heating of electroplating baths and chemical ...

Elektrische Schaltung und Schaltungsschutzeinrichtung

Wärmeaustauschvorrichtung zur Kontrolle der Wassertemperatur

Wärmeaustauschvorrichtung zur Kontrolle der Wassertemperatur, die einen Hauptkörper (1), einen thermoelektrischen Kühler (2) und eine Kühleinheit (3) umfasst, wobei eine Seite des Hauptkörpers (1) offen ist, wobei der Hauptkörper (1) an der offenen Seite mindestens einen Raum (11) aufweist, durch den das Wasser (A) durchfließt, wobei an dem Raum (11) des Hauptkörpers (1) der thermoelektrische Kühler (2) angeordnet ist, wodurch der Raum (11) des Hauptkörpers (1) mit der Wärmeaufnahmefläche (21) des thermoelektrischen Kühlers (2) verbunden ist, wobei die Kühleinheit (3) mit der Wärmeabgabefläche (22) verbunden ist, wobei der Hauptkörper (1) an der gleichen Seite oder an den beiden Seiten zwei Röhrstücke (12) für Wassereinlauf und einen Wasserauslauf aufweist, wobei eine Pumpe (4) das Wasser (A) durch ein Rohrstück (12) des Hauptkörpers (1) in den Raum (11) des Hauptkörpers (1) fördert, wobei das Wasser (A) im Hauptkörper (1) direkt mit der Wärmeaufnahmefläche (21) des thermoelektrischen Kühlers ...

Aquarium heater

An aquarium heater that is disposed on an outside surface of the aquarium tank for maintaining the water in the tank at a selectable temperature. The heater is preferably supported by a hanger or holder from a top edge of the tank and has a heat transfer plate disposed in intimate contact with a side or back wall of the tank. The heater includes, in addition to the heat transfer plate, a plastic or phenolic housing, a heating element, insulation and a settable thermostat contained in a temperature-sensing section of the housing. When the tank water is below a threshold temperature the thermostat closes coupling power to the heating element, which is preferably a rope-type resistance heater covered by a metal foil blanket, and when the temperature of the water reaches the threshold the thermostat temporarily opens to uncouple power to the heating element.

AQUARIUM WATER WARMING UP DEVICE

DEVICE FOR WARMING UP AND TO CONSTANT STOPS OF THE TEMPERATURE OF A LIQUID, IN PARTICULAR AQUARIUM WATER

RESISTANCE HEATING AND THERMOSTAT FOR AQUARIA

La présente invention concerne une résistance chauffante utilisable notamment pour aquarium, caractérisée en ce qu'elle est constituée par une résistance électrique proprement dite contenant des particules conductrices mélangées avec un polymère hydrocarboné; la résistance est mise en forme et sujette à subir un traitement thermique contrôlé pour obtenir une conductivité électrique voulue du mélange de particules et du polymère. Un revêtement constitué d'un matériau, isolé électriquement, est prévu autour de la résistance électrique, le matériau étant un matériau thermoplastique qui conduit la chaleur et procure un revêtement étanche et moulable.

SYSTEM AND METHOD FOR SOLAR GREENHOUSE AQUAPONICS AND BLACK SOLDIER FLY COMPOSTER AND AUTO FISH FEEDER

An aquaponics and greenhouse system, includes an insulated solar greenhouse with a glazing on a sun facing side at an angle to maximize winter sunlight, and housing a fish tank housed within the solar greenhouse; a plant growing area housed within the solar greenhouse; a mushroom growing area housed within the solar greenhouse; a water wall thermal mass housed within the solar greenhouse and disposed between the plant growing area and mushroom growing area; and a natural air ventilation system housed within the solar greenhouse and configured to provide misted air into the mushroom growing area. 02 generated by the plant growing area is received by the natural air ventilation system and provided to the mushroom growing area, and C02 generated by the mushroom growing area is provided to the plant growing area.

FULLY SUBMERSIBLE IMMERSION HEATER

A fully submersible immersion heater having reduced dimensions. The immersion heater includes a waterproof housing, an electric heating element, a thermostat, an end cap, a temperature control, a power cable and a sheath. The waterproof housing has an opening at one end. The electric heating element, which generates a heat output, is placed inside of the housing. The thermostat is also placed inside of the housing. The thermostat is electrically connected to the heating element for regulating the heat output of the heating element. The end cap sealingly engages the opening in the housing to form a watertight seal between the end cap and the opening in the housing. The end cap has a first conduit and a second conduit that extend through the end cap from a first surface of the end cap outside of the housing to a second surface of the end cap inside of the housing. The temperature control, which controls the thermostat, is seated adjacent to the second conduit. The temperature control is operatively ...

AQUARIUM WATER HEATER

ORGANIC FISHERY SYSTEM HAVING HEATING AND CLEANING FEATURES

A system for organic farming of aquatic livestock has at least one substantially enclosed container structured and arranged to contain at least one input-controlled organic environment usable to organically farm such aquatic livestock. At least one pollutant-free water-supplier is structured and arranged to supply, to the at least one substantially enclosed container, water substantially free of environmental pollutants. At least one aquatic life-support unit is structured and arranged to maintain within the at least one substantially enclosed container habitable environment consistent with sustaining growth of such aquatic livestock. At least one heating system is coupled to the at least one substantially enclosed container for heating an air mixture. The air mixture is injected into the water substantially free of environmental pollutants to heat the water substantially free of environmental pollutants.

METHOD AND APPARATUS FOR REMOVAL OF SEA LICE FROM LIVE FISH

A fish delousing installation includes a warm water source, and a fish slide for fish to slide down. The fish slide has a fish inlet, a fish outlet, and a slide length defined therebetween. A plurality of shower nozzles are in communication with the warm water source and are positioned to shower the fish with warm water as the fish slide from the fish inlet to the fish outlet.

AQUARIUM HEATER AND COOLER

A combination aquarium heater and cooler apparatus is provided which utilizes a feedback circuit to automatically maintain the fluid in an ecosystem at an operator set desired temperature. The feedback system scheme takes advantage of a thermo-electric heat pump component in combination with a high gain amplifier in order to achieve the desired result of maintaining the ecosystem at a temperature which is nearly constant regardless of other undesirable spurious heat inputs or losses to the ecosystem.

HEATER FOR AQUARIUM FISH TANK

In a heater unit comprising a case which accommodates therewithin an electrical heating element and a temperature sensor for detecting the temperature of the case heated by the electrical heating element to stop the power supply to the electrical heating element when the temperature reaches a predetermined value, there is provided a heat conductive path 20 made of a material having a higher heat conductivity than that of the material making up the case and extending from a region corresponding to the space in which the electrical heating element or heater is placed to a region corresponding to the space in which the temperature sensor or temperature detecting and power supply control member is placed. Thus, the heater unit for an aquarium fish tank is prevented from being extraordinarily heated when the tank has been destroyed.

ELECTRIC HEATER AND METHOD OF MAKING A HEATER

... 2108887 9220200 PCTABS00017 An electric heater comprises a heating element (10) encapsulated in a rigid plastics moulding (11). The element may be in the form of a flexible sheet and may comprise a substrate of electrically insulating material such as a woven glass-fibre mat (12), coated with electrically resistive material, such as a plastics material containing carbon particles. A method of making the heater is also disclosed.

Marine organism incubator

Aquarium with heat dissipating device

Pull cover type fish tank device based on semiconductor thermoelectric cooling and heating

IMMERSION HEATER FOR AQUARIUMS

HEATING RESISTANCES AND THERMOSTATS FOR AQUARIOPHILIE

DEVICE OF HEATING IMMERSIBLE FOR AQUARIUM

SMART FISHBOWL SYSTEM USING TRANSPARENT DISPLAY

A smart fishbowl system using transparent display comprises: a fishbowl tank main body formed of a transparent material; a transparent touch display unit attached to at least one surface of the fishbowl main body; an illuminance adjusting unit adjusting the illuminance inside the fishbowl main body; a temperature regulator regulating the temperature of water contained in the fishbowl main body; a sensor unit sensing the illuminance inside the fishbowl main body and the temperature of the water; and a controller controlling operations of the illumination controller and the temperature controller based on data sensed by the sensor unit. Provided is the smart fishbowl system, which displays habitat environments of fish through the transparent display, and can display illuminance, water temperature and feeding time in real time. COPYRIGHT KIPO 2018 ...

AIR SUPPLY DEVICE FOR CONTROLLING TEMPERATURE OF LIVE FISH AQUARIUM

The present invention relates to an air supply device for controlling the temperature of a live fish aquarium, capable of strengthening use versatility, which comprises: a case; a distribution pipe; an air cooler; a distribution hose; an opening/closing valve; a shielding plate; and an air supplier. COPYRIGHT KIPO 2018 ...

HEATING DEVICE FOR A CONTAINER FOR KEEPING ANIMALS AND/OR PLANTS AND AQUARIUM EQUIPPED WITH SUCH A HEATING DEVICE

L'invention concerne un dispositif de chauffage pour récipient prévu pour recevoir des animaux et/ou des plantes. Ce dispositif de chauffage présente au moins une unité chauffante placée dans le récipient et à commande électrique. Cette unité chauffante est disposée à proximité d'une plaque qui la sépare de l'intérieur du récipient lorsqu'elle se trouve placée dans le récipient.

ADJUSTABLE HEATER FOR AQUARIA

An adjustable heater for aquaria, comprising a substantially tubular container (2) within which are housed an electrical heating element (3), a switch (6) comprising s fixed contacts (7, 8) and moving contacts (9, 10) and capable of electrically connecting the heating element (3) with an external source (R) of electrical power, a temperature sensor (12) with a bi-metal strip (13) capable of detecting the temperature of the liquid and interacting with the switch (6) to move it from a closed position to an open position when a predetermined temperature (T) is to reached. The moving contacts (9, 10) of the switch (6) are secured to a free end (13") of the bi-metal strip (13) while the other end (13") of the bi-metal strip (13) is electrically insulated. This yields the advantage that electrical current does not pass through the bi-metal strip (13) and therefore does not create a Joule effect within it which affects the sensitivity and proper behaviour of the temperature Is sensor (12).

AQUARIUM WATER HEATER

An aquarium water heater includes a hollow heat-conducting internal tube with an electric resistance heater element and electrical connections disposed adjacent an outer surface of the hollow heat-conducting internal tube, a temperature thermal cut-out switch electrically connected to the heater element for overheat protection, and a heat-conducting, electrically insulating polymeric filler spaced between the internal tube and an external tube that circumscribes the internal tube and the heater element. The aquarium water heater also includes a water temperature sensor that senses the temperature of water into which the heater is at least partially immersible, electrically coupled to a controller to activate and deactivate the heater element and to an indicator that indicates a condition that corresponds to the water temperature being in between a first predetermined minimum temperature and a first predetermined maximum temperature and a different indicating pattern corresponding to the ...

Aquarium heater

An aquarium heater including an elongated heater element including an insulating member and a wire heater extending from one end of the insulating member to the other end of the insulating member and with an outer sheath of insulating material having open and closed ends for enclosing the heater element at the closed end and having an inner dimension larger than the outer dimension of the heater element and with a pair of spacer members disposed individually at each end of the insulating member of the heater element for spacing the heater element from the inner surface of the outer sheath and with the spacer members including means for retaining the ends of the wire heater in fixed positions at each end of the insulating member and with a resilient sealing element disposed from the open end of the sheath to seal the heater element in the closed end of the sheath and with the sealing element including grooves for passing electrical wires for supplying electrical energy to the wire heater ...

Home aquarium

Closed top home aquarium for setting up and maintaining a sea water aquatic environment in particular. The aquarium includes a transparent open topped box-like enclosure, a compartment integrally formed with and behind the box-like enclosure, and a hinged dual position fan cooled hood. The compartment includes a water circulation system and a multistage filtration system. The hood includes a lighting system for daytime and nighttime illumination, and a built-in 24 programmable timer. The aquarium includes a thermostat controlled water temperature system and a below water level splash proof power center for safely and aesthetically connecting all electrical aquarium components to a mains electricity outlet. Home aquariums can be provided with an integrally formed below water level splash proof power center for use with off-the-shelf electrical aquarium appliances.

AQUARIUM WATER HEATER

Temperature control device for aquarium heater

A temperature control device for use with an aquarium heater, including a control housing, a first contact fastened to the control housing, a second contact responsive to the temperature responsive movement of a bimetallic strip maintained at the control housing and movable between a closed position wherein the second contact abuts the first contact and an open position wherein the second contact is separated from the first contact, a plate spring, the second contact fastened at the free end of the plate spring and with the plate spring mounted on the control housing and movable through an unstable intermediate position between a first stable position wherein the contacts lie abuting one another and a second stable position wherein the contacts are separated from one another, and the plate spring abuting a stop on the control housing and with the bimetallic strip abuting the plate spring and moving the plate spring in response to temperature changes between the first and second positions ...

A device for heating and maintaining a constant temperature in a liquid, in particular the water of aquariums

ELEKTRISCHE HEIZVORRICHTUNG

Ameisenfarm und Befeuchtungs-/Heizmodul dafür

Ameisenfarm (1) mit einem im Wesentlichen kastenförmiger Körper mit einer Bodenfläche (11), zwei gegenüberliegenden Seitenwänden, einer die Seitenwände verbindenden Oberseite sowie einer Rückwand und einer transparenten Vorderseite, wobei zwischen Bodenfläche (11) und Oberseite mehrere zueinander beabstandete, zwischen den Seitenwänden verlaufende Etagenböden (161) mit mindestens einem Auf- und Abgang (162) zwischen zwei Etagenböden angeordnet sind, dadurch gekennzeichnet, dass der kastenförmige Körper aus Kunststoff gebildet ist.

Heizungsvorrichtung für Aquarium-Gehäuse

Transparentes Gehäuse mit Versorgungsleitungen für einen elektrischen Verbraucher

Gehäuse, umfassend: ein erstes transparentes Plattenelement (1, 4b; 32, 34; 34a), welches durch zwei im wesentlichen parallel verlaufende Hauptflächen und durch mehrere Randflächen begrenzt ist, wobei die Randflächen die Hauptflächen begrenzen und diese miteinander verbinden, wobei der Abstand der Hauptflächen zueinander wesentlich geringer ist als die Erstreckung des ersten Plattenelements in der Ebene der Hauptflächen; mindestens ein zweites transparentes Plattenelement (2, 4, 4a; 31; 34b), welches durch zwei im wesentlichen parallel verlaufende Hauptflächen und durch mehrere Randflächen begrenzt ist, wobei die Randflächen die Hauptflächen begrenzen und diese miteinander verbinden, wobei der Abstand der Hauptflächen zueinander wesentlich geringer ist als die Erstreckung des zweiten Plattenelements in der Ebene der Hauptflächen, sowie einen elektrischen Leiter (5, 6, 7), wobei der elektrische Leiter zumindest abschnittsweise in einer Aussparung verläuft, deren Längsrichtung sich im wesentlichen ...

Cultivation of phytoplankton and zooplankton

A device and method for continuous culturing of live food for an aquarium. Phytoplankton and zooplankton are cultivated in separate adjacent chambers 1, 2 provided with light 4, heat 6 and aeration 5. Fluid from the phytoplanakton tank overflows 19 into the zooplankton tank to provide feed for the zooplankton. Fluid from the zooplankton tank, including zooplankton is removed and sent to the aquarium to provide food for the species therein. Fluid from the aquarium is subsequently removed, filtered and sent to the phytoplankton tank. The process repeats continuously with the aid of dosing pumps 8a, 8b. Alternatively waste nutrients from the zooplankton are fed to the phytoplankton system and the zooplankton removed manually from the zooplankton tank and fed to the aquarium.

GLASS CASED IMMERSION HEARTERS

SUBMERSIBLE THERMOSTATICALLY CONTROLLED HEATERS

Method and apparatus for cultivating zooplankton and phytoplankton

THERMALLY ACTUATED SWITCH

SYSTEMS AND METHODS FOR SMART DEICERS

Certain embodiments of the present invention provide a deicer system for heating water within a fluid receptacle to prevent ice from forming, the system including a main body configured to be positioned within the fluid receptacle, a heating element adapted to heat the water, a temperature sensor adapted to detect a temperature of the water, a switch adapted to activate and deactivate the heating element, and a control unit in communication with the heating element, the temperature sensor, and the switch. The heating element is supported by the main body. The control unit is adapted to control the heating element using the switch based at least in part on a temperature detected by the temperature sensor.

AN AQUACULTURE PROCESS FOR THE PRODUCTION OF SALMON EGGS

A process for harvesting fish eggs is provided, in particular fish eggs from Salmon. The process comprises rearing sexually immature salmon in an aquatic environment in stages during which at least the light exposure and time span is adjusted. The rearing includes at least a winter-summer period that comprises a winter life-cycle stage, within which the broodstock is exposed to light that simulates winter light exposure, and a subsequent summer life-cycle stage, within which the broodstock is exposed to light that simulates summer light exposure, wherein the total Accumulated Thermal Unit (ATU) during the winter-summer period is no more than 5000. The inventions also provides salmon eggs that are produced by the disclosed process.

GLASS-TUBE HEATER

A glass-tube heater includes a glass tube, a cap, and a temperature display unit. The glass tube is provided therein with an off-water protection sensor or a tipping switch, a control circuit board, one of a TRIAC and a relay, and a heating element. The control circuit board includes a control unit (which is an MCU or a comparator). All the components that are disposed in the glass tube are electrically connected to form a control circuit. Devices for temperature control, detection, and heating are all disposed inside the glass tube. The off-water protection sensor is operable to detect if being removed out of water for controlling the heating element to carry out heating or not, thereby ensuring quick termination of heating upon removal out of water. The tipping switch is operable to control the heating element from heating in case of excessive tipping of the heater.

Aquaponic System

An aquaponic system generally comprises an aquarium module, a garden module and a reservoir module. The aquarium module is generally configured to be installed on a supporting structure (e.g. a cabinet). The garden module is generally configured to be installed on the supporting structure near the aquarium module, in front, beside or even all around it. The garden module is generally configured to support terrestrial and/or semi-aquatic plants. The reservoir module is typically installed inside the supporting structure with the utilities (e.g. pumps). The system is generally designed such that the waste water from the aquarium module flows to the garden module where it irrigates the plants and where it is at least partially filtered by plants which consume at least some of the waste products contained in the water. 2. An aquaponic system as claimed in claim 1 , wherein the aquarium module is in fluid communication with the garden module via at least one first drain conduit.3. An aquaponic system as claimed in claim 2 , wherein the aquarium module comprises at least one skimmer connected to the at least one first drain conduit.4. An aquaponic system as claimed in claim 2 , wherein the at least one first drain conduit comprises at least one filter fluidly mounted thereto claim 2 , the at least one filter being configured to remove at least a portion of the waste products contained in the waste water.5. An aquaponic system as claimed in claim 2 , wherein the at least one first drain conduit comprises inwardly extending protrusions to break the flow of waste water such as to force waste water and air to mix.6. An aquaponic system as claimed in claim 1 , wherein the garden module is in fluid communication with the reservoir module via at least one second drain conduit.7. An aquaponic system as claimed in claim 6 , wherein the garden module comprises at least one draining system fluidly connected to the at least one second drain conduit and configured to regularly drain ...

Co-Location of a Heat Source Cooling Subsystem and Aquaculture

The present disclosure provides systems for heat source, e.g., data center, cooling and aquaculture. In certain aspects, the systems include a heat source, e.g., data center, having a water cooling subsystem configured to receive cool water and output warm water and an aquaculture center co-located with the heat source, e.g., data center, and configured to receive the warm water. Aspects of the invention also include methods for cooling a heat source, e.g., data center, using a water cooling subsystem and cultivating aquatic organisms with an aquaculture center that is co-located with the heat source, e.g., data center. 1. A system comprising:(a) a heat source comprising a water cooling subsystem configured to receive cool water and output warm water; and(b) an aquaculture center co-located with heat source and comprising a water temperature control subsystem configured to receive the output warm water.2. The system according to claim 1 , wherein the cool water is received from an ocean or sea.3. The system according to claim 1 , wherein the water cooling subsystem comprises a water intake.4. The system according to claim 3 , wherein the water intake is positioned at a depth of 15 m or more in a water source.5. The system according to claim 3 , wherein the water intake is positioned below the photic zone in a water source.6. The system according to any of the preceding claims claim 3 , further comprising a water discharge for discharging water from the aquaculture center.7. The system according to claim 6 , wherein the water discharge is positioned at a depth of 15 m or more in a body of water.8. The system according to claim 7 , wherein the body of water is the same body of water from which the water cooling subsystem receives the cool water.9. The system according to any of the preceding claims claim 7 , further comprising a power plant co-located with the data center and the aquaculture center.10. The system according to claim 9 , wherein the power plant is ...

Aquarium System

An aquarium filtering and purifying system includes an upper display tank and a lower filter tank. The water from the upper tank can be delivered to the lower tank to a filter, such as within a surrounding filter fabric or membrane, such as a filter sock. An air tube can also be inserted into the filter tank to an unfiltered side of the filter, such as within the filter sock, to deliver air bubbles into the filter tank. The air tube can have an air stone at the end thereof to diffuse the air bubbles. Further air stones can be provided on an outside of the sock in the first compartment. Filtered water is delivered to a second compartment in the filter tank. The next compartment can have sand, and/or rocks and/or algae and/or a clean-up crew to assist in purifying the water. Water from the second compartment then passes to a third compartment, through a bubble trap, and then is pumped back to the display tank. Alternatively, the first compartment can be provided with a macro algae bed instead of a filter sock. 1. An aquarium system comprising a display tank and a filter tank , the display tank elevated above the filter tank , a filter tube having an inlet end open to the display tank and an outlet end open into the filter tank , the outlet end delivering water from the display tank into a first compartment of the filter tank;the first compartments is defined by a first baffle which allows water from the first compartment to spill over the first baffle into a second compartment;a source of pressurized air communicating through an air tube wherein the air tube has an outlet end submerged within the first compartment, wherein air bubbles are provided into the first compartment;the second compartment defined by the first baffle and a second baffle, wherein the second baffle has a top elevation equal to or below a top elevation of the first baffle, wherein water is delivered from the second compartment to a third compartment spill over the second battle;wherein water moves ...

WIRELESS CONTROLLER FOR DEVICES IN A WATER FILLED HABITAT

A Bluetooth®, or other wireless communications protocol, control of a water filled habitat system. A Bluetooth® phone application will control the duty cycle on a timed basis or programmed to maintain a desired oxygen saturation of the water based on the readings sensed by the oxygen sensor. The Bluetooth® phone application will control the duty cycle on a timed basis or programmed to maintain a desired temperature of the water based on the readings sensed by the temperature sensor. On and off duty cycles will conserve on power supply life and reduce noise and extend the life of the environmental regulating device. 1. A control system for regulating an environmental condition of a controlled habitat , comprising:one or more environmental control regulating devices in communication with the controlled habitat, the one or more environmental control regulating devices configured to control one or more environmental parameters of the controlled habitat; anda control relay having a wireless communications module, the control relay configured to receive a status signal from one or more sensors sensing the one or more environmental parameters and communicate the status signal via the wireless communications module, the control relay further configured to receive a command signal to power on the one or more environmental control regulating devices.2. The control system of claim 1 , further comprising:a mobile computing device configurable for communication with the wireless communications module; anda program logic to selectively transmit the command signal to the control relay.3. The control system of claim 2 , the program logic further comprising:receiving the status signal; andgenerating the command signal based on the status signal.4. The control system of claim 3 , the program logic further comprising:receiving a set point for the one or more environmental parameters.5. The control system of claim 4 , the program logic further comprising:transmitting the command signal ...

HEAT DELIVERY SYSTEM AND METHOD

A heat delivery system for agricultural applications, the system including: piping including alternate heat insulated segments and heat transferring segments, the piping being configured with a fluid flow path extending through the alternating heat insulated segments and heat transferring segments; and a fluid propelling arrangement configured for motivating flow of heat accommodating fluid within the fluid flow path. 130.-. (canceled)31. A heat delivery system for agricultural applications , the system comprising:piping having alternate heat insulated segments and heat transferring segments, said piping being configured with a fluid flow path extending through the alternating heat insulated segments and heat transferring segments; anda fluid propelling arrangement configured for motivating flow of heat accommodating fluid within said fluid flow path.32. The heat delivery system according to claim 31 , wherein the heat transferring segments are disposed along the piping according to a predetermined arrangement claim 31 , so that the location of each heat transferring segment is corresponding to the location of a respective heat consumer in proximity to which the heat transferring segment is to be disposed.33. The heat delivery system according to claim 31 , wherein the heat insulating segments comprise a heat insulating sheath applied to an external or an internal sidewall of the piping.34. The heat delivery system according to claim 31 , wherein sidewalls of the heat insulated segments are configured with one or more lateral protrusions projecting from internal or external surfaces of the sidewalls.35. The heat delivery system according to claim 34 , further comprising a sleeve claim 34 , wherein the one or more lateral protrusions are configured for forming one or more heat insulating cavities between the lateral protrusions and the sleeve when the sleeve is applied over the lateral protrusions.36. The heat delivery system according to claim 31 , wherein the heat ...

PORTABLE AGRARIAN BIOSYSTEM

A portable agrarian biosystem is a self-contained plant and fish growth facility encased in a shipping container so that it can be readily transported and set up. The system is designed for self-sufficient operation without connection to external sources of water or electricity. The modified aquaponic growth system is computer controlled for unattended operation with significantly lower consumption of water than other plant growth systems. 1. A portable , self-contained , self-sustaining , self-powered , self-watered growing system comprising:a modified intermodal shipping container;a computer control system;a microgrid electric power system;a photovoltaic racking system including photovoltaic solar cells disposed on the intermodal shipping container; and a recirculating water system;', 'a plant feed control system;', 'a multi-mode lighting system; and', 'an environmental control system., 'a hybrid aquaponic hydroponic system with aquaponic, hydroponic and combination aquaponic-hydroponic operating modes disposed within the intermodal shipping container comprising2. The growing system according to further comprising a security system.3. The growing system according to further comprising a communications system including an antenna.4. The growing system according to claim 1 , wherein said hybrid aquaponic hydroponic system further comprises an array of environmental sensors.5. The growing system according to claim 4 , wherein the array of environmental sensors comprises at least one of rainfall rate and accumulation sensors claim 4 , solar irradiation sensors claim 4 , wind speed sensors claim 4 , water level sensors claim 4 , temperature and humidity sensors claim 4 , pH sensors and electrical conductivity sensors claim 4 , dissolved oxygen sensors claim 4 , carbon dioxide sensors claim 4 , oxygen sensors claim 4 , nitrogen claim 4 , potassium and phosphorus sensors claim 4 , ammonia/ammonium sensors and photosynthetically active light sensors.6. The growing system ...

METHOD AND APPARATUS FOR REMOVAL OF SEA LICE FROM LIVE FISH

A fish delousing installation includes a warm water source, and a fish slide for fish to slide down. The fish slide has a fish inlet, a fish outlet, and a slide length defined therebetween. A plurality of shower nozzles are in communication with the warm water source and are positioned to shower the fish with warm water as the fish slide from the fish inlet to the fish outlet. 136-. (canceled)37. A fish delousing installation , the fish delousing installation comprising:a fish slide for fish to slide down, the fish slide having a fish inlet, a fish outlet, and a slide length defined therebetween, the fish slide having a negative slope along the entirety of the slide length;a plurality of shower nozzles positioned to shower the fish with warm water as the fish slide from the fish inlet to the fish outlet;a seawater separator upstream of the fish inlet for separating sea water from the fish prior to the fish entering the fish slide;a used warm water separator downstream of the fish outlet for separating used warm water from the fish exiting the fish slide; anda recycle line downstream of the used warm water separator for feeding used warm water back towards the shower nozzles.38. The fish delousing installation of claim 37 , further comprising a warm water source in communication with the plurality of shower nozzles.39. The fish delousing installation of claim 37 , further comprising a sea lice separator downstream of the used warm water separator for removing sea lice from the used warm water.40. The fish delousing installation of claim 37 , wherein the fish slide has a negative slope along the entirety of the slide length.41. The fish delousing installation of claim 37 , wherein the slide is tubular.42. The fish delousing installation of claim 37 , wherein: the shower nozzles are positioned at a plurality of spaced apart positions along the slide length claim 37 , and the shower nozzles span a majority of the slide length.43. The fish delousing installation of claim ...

SYSTEM AND METHOD FOR SOLAR GREENHOUSE AQUAPONICS AND BLACK SOLDIER FLY COMPOSTER AND AUTO FISH FEEDER

A system, method, and computer program product for an aquaponics, and greenhouse system, includes a solar greenhouse with north, east and west sides insulted and with glazing on a south side angled to maximize winter sunlight, and housing a fish tank with grow beds, and a hard filter filtering water from the fish tank coupled thereto, and including a stilling well inside of a solids collection chamber receiving water from a hard filter geyser pump, and with filter media sections of varying coarseness for providing mechanical filtration therearound, including coarser and finer media section from a bottom to a top of the solids collection chamber, a with air stones on top, and with aquatic plants including algae, and/or Duckweed, providing biological filtration growing on a water surface thereabove. A sponge filter receives overflow water from the aquatic plants and with an output thereof provided to the fish tank. 1. An aquaponics , and greenhouse system comprising:a solar greenhouse insulated on north, east and west sides and with glazing on a south side at an angle to maximize winter sunlight, and housing:a fish tank housed within the solar greenhouse; anda plurality of grow beds coupled to the fish tank and also housed within the solar greenhouse;a hard filter coupled to the fish tank through a hard filter geyser pump filters water from the fish tank, and including:a stilling well receiving water from the fish tank pumped by the hard filter geyser pump;a solids collection chamber with the stilling well disposed therewithin;a plurality of filter media sections of varying coarseness for providing mechanical filtration disposed around the stilling well, including a coarser media section near a bottom of the solids collection chamber, and finer media section near a top of the solids collection chamber;one or more air stones disposed on top portion of the finer media section;aquatic plants including one or more of algae, and Duckweed, providing biological filtration ...

VIVARIUM SYSTEM

The invention relates to a vivarium system which is composed of combinable individual containers (II) and plant climbing aids and is provided with magnetic adhesion to ferromagnetically equipped walls and ceilings (I) having a painted and/or plastered and/or lined surface. Vitalization of inner spaces, facades and free spaces by a module system that can be combined in a variable manner and is composed of small biotopes such as aquariums, terrariums, aviaries, paludariums and other vivariums for small animals, birds, insects and plants, for the fastening to walls and ceilings without causing damage to the visible surfaces by drillings for dowels, pins and screws and without rigid bonds with the fastening base. 1. A vivarium system consisting of containers for small-scale biotopes such as aquaria , terraria , paludaria , aviaries , plant and floriculture vessels , climbing rods , and climbing ropes , characterized in that heavy-duty magnets are installed in each of the individual containers on the side faces in the region of the bottom of the vessel and/or in the region of the lid of the vessel , the field strength of said magnets being adapted to the respective total weight of the container when filled to the maximum for a reference magnetic holding surface , wherein in the region of the outsides of the resulting magnetic contact surfaces a thin adhesive coating made of silicone or rough , tough and resilient plastic is applied , which increases the friction on the adherent surface on ferromagnetic wall areas by nano-interlocking and/or adhesion and protects the wall surface from scratching.2. The vivarium system according to claim 1 ,characterized in that one or more apertures are integrated in the water-tight bottom parts and/or in the water-tight lid parts of each of the individual biotope containers, said apertures being provided with a peripheral seal in the insertion area and plug-in interfaces into which tubes with plug-in sleeves and plug-in contacts for ...

GLASS-TUBE HEATER

A glass-tube heater includes a glass tube, a cap, and a temperature display unit. The glass tube is provided therein with an off-water protection sensor or a tipping switch, a control circuit board, one of a TRIAC and a relay, and a heating element. The control circuit board includes a control unit (which is an MCU or a comparator). All the components that are disposed in the glass tube are electrically connected to form a control circuit. Devices for temperature control, detection, and heating are all disposed inside the glass tube. The off-water protection sensor is operable to detect if being removed out of water for controlling the heating element to carry out heating or not, thereby ensuring quick termination of heating upon removal out of water. The tipping switch is operable to control the heating element from heating in case of excessive tipping of the heater. 1. A glass-tube heater , comprising a glass tube , a cap coupled to an end of the glass tube , and a temperature display unit ,wherein the glass tube is provided, in an interior thereof, with an off-water protection sensor, a control circuit board, a switch element, and a heating element, the control circuit board comprising a control unit, the control circuit board being electrically connected with the temperature display unit; andthe off-water protection sensor, the control unit, the switch element, and the heating element are electrically connected together to form a control circuit;wherein the off-water protection sensor, upon identifying being located in water, transmits a signal to the control unit, and the control unit is operable, according to a detected water temperature, to control the switch element to switch one for conducting electricity, so as to control operation of the heating element for heating or not; andthe off-water protection sensor, upon identifying being removed out of water, transmits a signal to the control unit, and the switch element cuts off the electricity to prevent the ...

AQUACULTURE SYSTEM

An aquaculture system () for farming aquatic organisms includes an apparatus () for supplying oxygenated water into an enclosure () in which aquatic organisms are to be fanned. The apparatus () includes a water inlet () and an oxygen inlet () to create a water and oxygen mixture. The apparatus () also includes a venturi () arranged to dissolve the oxygen into the water passing through the venturi and such that the oxygen and water mixture passing through the venturi () is exposed to a substantially null magnetic field. The apparatus is also arranged such that the water and oxygen mixture that is supplied to the venturi () contains substantially no colloidal minerals. The apparatus also includes an outlet () for the oxygenated water in fluid communication with, and downstream of, the venturi () and in fluid communication with the inlet of the enclosure (). 1. An aquaculture system for farming aquatic organisms comprising:an enclosure for oxygenated water in which aquatic organisms are to be farmed, wherein the enclosure comprises an inlet for feeding oxygenated water into the enclosure; a water inlet for supplying water into the apparatus;', 'an oxygen inlet for supplying oxygen into the water within the apparatus to create a water and oxygen mixture, the oxygen inlet being in fluid communication with, and downstream of, the water inlet;', 'a venturi in fluid communication with, and downstream of, the water inlet and the oxygen inlet, wherein the venturi is arranged to dissolve the oxygen into the water passing through the venturi and such that the oxygen and water mixture passing through the venturi is exposed to a substantially null magnetic field, and wherein the apparatus is arranged such that the water and oxygen mixture that is supplied to the venturi contains substantially no colloidal minerals; and', 'an outlet for the oxygenated water in fluid communication with, and downstream of, the venturi;, 'an apparatus for supplying oxygenated water into the enclosure ...

INLAND AQUAPONICS SYSTEM USING BIOFLOC TECHNOLOGY

A closed recirculating aquaponics system combined with a biofloc tank for symbiotic breeding of aquatic species and plant species, wherein the culture water for growing aquatic species is transferred to a plant growing apparatus, organic material in the culture water is used as nutrients for plant species and the water is purified in the plant growing apparatus, and purified water is reused as culture water for aquatic species to facilitate symbiotic breeding of aquatic species and plant species without any need of culture water exchange, reducing cost for production and enhancing production efficiency. 1. An inland biofloc aquaculture system comprising a biofloc tank for growing nutrient microorganisms and aquatic species , said biofloc tank formed on a single-layer or plural layer frame , in connection with a reservoir tank ,wherein culture water containing organic feces generated from aquatic species is filtrated in said reservoir tank to be firstly purified; andwherein culture water purified in the above first purification process is transferred to an aquaponics plant growing apparatus, to be secondly purified by plant breeding and is supplied back to said biofloc aquaculture system.2. The biofloc aquaculture system and the aquaponics plant growing apparatus of claim 1 , further comprising a monitoring system which monitors aquaculture of aquatic species and plant breeding claim 1 ,wherein said monitoring system comprises: a water quality measurement device of said biofloc aquaculture system; and a thermo-hygrostat and an illumination regulator of said aquaponics plant growing apparatus, andwherein said biofloc aquaculture system and said aquaponics plant growing apparatus are driven by the control of said monitoring system.3. The system of claim 1 , wherein said biofloc tank is connected to a cooling reservoir tank equipped with a cooler and a heating reservoir tank equipped with a heater claim 1 , in order for culture water discharged from said biofloc ...

Conditioning of Aquarium Water

A mobile treatment system having a mobile or wheelable container able to receive a secondary volume of water separate from the primary volume of water of the aquarium; a pump mountable to a portion of the mobile container, a first Inlet of the pump able to draw water from a portion of the mobile container, a first outlet of the pump connectable for selectively directing water drawn into the first Inlet back into the mobile container after conditioning of the water, a second inlet able to draw conditioned water from a portion of the mobile container having the conditioned water; a second outlet allowing transfer of the conditioned water from the mobile container to the aquarium, wherein the water is conditioned in the secondary volume of the mobile container at a position remote to the aquarium. 117.-. (canceled)18. A water replenishment apparatus that prepares a volume of water from a domestic water supply for delivery to an aquarium , the apparatus including:a first domestic water inlet that is configured to receive water from a domestic water supply and is configured to transfer the water to a container separate from the aquarium, the inlet including a water condition sensor that senses a condition of the domestic water flowing through the inlet;a water re-circulator including a re-circulating flow path that has a second inlet positioned to receive water from within the container, an outlet that delivers the water back to the container and a water pump that pumps water through the re-circulating flow path and a conditioner that changes a condition of water flowing through the re-circulating flow path; anda water delivery system that is configured to extract conditioned water from the container and is configured to pump the extracted water into a transfer line for delivering the extracted water into an aquarium.19. The water replenishment apparatus of claim 18 , wherein the water re-circulator includes an air inlet positioned to aerate a flow of water through the ...

Co-Location of a Heat Source Cooling Subsystem and Aquaculture

The present disclosure provides systems for heat source, e.g., data center, cooling and aquaculture. In certain aspects, the systems include a heat source, e.g., data center, having a water cooling subsystem configured to receive cool water and output warm water and an aquaculture center co-located with the heat source, e.g., data center, and configured to receive the warm water. Aspects of the invention also include methods for cooling a heat source, e.g., data center, using a water cooling subsystem and cultivating aquatic organisms with an aquaculture center that is co-located with the heat source, e.g., data center. 115-. (canceled)16. A system comprising:(a) a heat source comprising a water cooling subsystem; and(b) an aquaculture center co-located with heat source and configured to receive warm water from the water cooling subsystem.17. The system according to claim 16 , wherein the water cooling subsystem is configured to receive cool water from an ocean or sea.18. The system according to claim 17 , wherein the water cooling subsystem comprises a water intake.19. The system according to claim 18 , wherein the water intake is positioned at a depth of 15 m or more in a water source.20. The system according to claim 18 , wherein the water intake is positioned below the photic zone in a water source.21. The system according to claim 16 , further comprising a water discharge for discharging water from the aquaculture center.22. The system according to claim 21 , wherein the water discharge is positioned at a depth of 15 m or more in a body of water.23. The system according to claim 22 , wherein the body of water is the same body of water from which the water cooling subsystem receives the cool water.24. The system according to claim 16 , further comprising a power plant co-located with the data center and the aquaculture center.25. The system according to claim 24 , wherein the power plant is operably connected to both of the data center and the aquaculture center ...

OFF-WATER SHUTDOWN PROTECTION MECHANICAL HEATER

An off-water shutdown protection mechanical heater includes a tube and a cap mounted to an end of the tube. The tube includes therein an off-water protection transducer, one of a relay and a TRIAC, a circuit board including a bimetal plate, and a heating element. When he off-water protection transducer detects a situation of being immersed in water, the one of the relay and the TRIAC turns on to conduct electricity and the bimetal plate detects a temperature of water and undergoes deformation by the temperature to control the heating element to generate heat or not; and when the off-water protection transducer detects a situation of being removed out of water, the one of the relay and the TRIAC turns off to cut off electricity, making the heating element not generating heat. The off-water protection transducer ensures that electricity is quickly cut off upon removal out of water. 1. An off-water shutdown protection mechanical heater , comprising a tube and a cap mounted to an end of the tube ,wherein the tube comprises, as being arranged in an interior thereof, an off-water protection transducer, a bidirectional triode thyristor (TRIAC), a circuit board that includes a bimetal plate, and a heating element, wherein the off-water protection transducer, the TRIAC, the bimetal plate, and the heating element are electrically connected in sequence to form a control loop;wherein when the off-water protection transducer detects a situation of being immersed in water, the TRIAC turns on to conduct electricity and the bimetal plate detects a temperature of water and undergoes deformation by the temperature to control the heating element to generate heat or not; andwhen the off-water protection transducer detects a situation of being removed out of water, the TRIAC turns off to cut off electricity, making the heating element not generating heat.2. An off-water shutdown protection mechanical heater , comprising a tube and a cap mounted to an end of the tube ,wherein the tube ...

OFF-WATER PROTECTION HEATER WITH CONTROLLER

An off-water protection heater with controller includes a controller, a tube, and a cap mounted to an end of the tube. The controller includes a control circuit and one of a relay and a TRIAC. The control circuit includes a control unit (an MCU or a comparator). The tube is provided, in an interior thereof, with an off-water protection transducer and a heating element. The off-water protection transducer is electrically connected to the control unit or is electrically connected, together with the control unit, to the one of relay and TRIAC. By using the off-water protection transducer to detect a situation of being removed out of water or not, the heating element is controlled to generate heat or not in order to ensure electricity being quickly cut off upon removal out of water thereby saving energy and preventing excessively high temperature and unloaded heating as being removed out of water. 1. An off-water protection heater with controller , comprising a controller , a tube , and a cap mounted to an end of the tube ,wherein the controller comprises, as being arranged in an interior thereof, a control circuit and one of a relay and a bidirectional triode thyristor (TRIAC), and the control circuit includes a control unit; andthe tube comprises, as being arranged in an interior thereof, an off-water protection transducer and a heating element;wherein the off-water protection transducer, the control unit, the one of the relay and TRIAC, and the heating element are electrically connected in sequence to form a control loop;wherein the off-water protection transducer, upon detecting being immersed in water, transmits a signal to the control unit, and the control unit controls the one of the relay and TRIAC, according a detected temperature of water, to activate for conducting electricity to control the heating element to generate heat or not; andthe off-water protection transducer, upon detecting being removed out of water, transmits a signal to the control unit, and ...

LIGHTING SYSTEM INCLUDING NEAR FIELD COMMUNICATION CONTROLLER

An environmental control system such as an illumination system includes one or more LED lighting devices or other environmental factor control devices and a control device for controlling one or a combination of the LED lighting devices or other environmental factor control devices. A remote controller for remotely setting control content, control parameters and the like can be communicatively coupled (e.g., wirelessly) to the control device. The remote controller can be a smartphone or other device that includes an LED lighting control or other environmental control module or unit for setting one or more properties or parameters of a control target lighting/environmental device using near field communications. Properties and functions controlled by the remote controller can include timers, spectral content, intensity, etc. that are programmed by a user employing a simple application (e.g., featuring a GUI or other user-friendly interface). 1. A lighting unit comprising:a plurality of light emitting devices; anda near field communication unit communicatively coupled with the light emitting devices,wherein the near field communication unit is operable to receive lighting unit information from a remote control unit via near field communication, and to transmit lighting unit information to the remote control unit via near field communication.2. The lighting unit according to claim 1 , wherein the light emitting devices are light emitting diodes.3. The lighting unit according to claim 1 , wherein the lighting unit information includes control parameters for controlling the operation of at least one of the light emitting devices.4. The lighting unit according to claim 1 , wherein the lighting unit information includes at least one selected from the group consisting of:lighting unit production data including at least one of a serial number, a manufacturing date, inspection information, and a production batch number;lighting unit distribution data including at least one of ...

STRUCTURE OF AQUARIUM HEATER WITH OFF-WATER OVERHEAT PROTECTION

A structure of an aquarium heater with off-water overheat protection, wherein a control box with a control circuit is set inside. The control circuit includes: setting a temperature-control module; connecting with an electric heater; and connecting with either an overheat sensor or an off-water protection sensor; wherein the control circuit consists of a single chip, an electric relay box, and a plurality of resistors, capacitors, diodes, and transistors to constitute a complete electric circuit. Therefore, saving the electric energy and avoiding the conditions which the heating temperature is too high or the electric heater is emptily burned to damage because of the off-water can be achieved through the overheat sensor senses the temperature or the off-water protection sensor senses weather the electric heater is off water or not, and then the temperature-control module does the temperature comparison to control the electric heater to heat or not. 1. A structure of an aquarium heater with off-water overheat protection , wherein a control box with a control circuit is set inside , which is characterized in that the control circuit comprises: setting a temperature-control module; connecting with an electric heater; and connecting with either an overheat sensor or an off-water protection sensor; wherein the control circuit consists of a single chip , an electric relay box , and a plurality of resistors , capacitors , diodes , and transistors to constitute a complete electric circuit; therefore saving the electric energy and avoiding the conditions which the heating temperature is too high or the electric heater is emptily burned to damage because of the off-water can be achieved through the overheat sensor senses the temperature or the off-water protection sensor senses weather the electric heater is off water or not , and then the temperature-control module does the temperature comparison to control the electric heater to heat or not.2. The structure of an aquarium ...

Aquarium Theater Device

An aquarium device having a compartment for a video playing device that is viewable through an aquarium tank for conveniently enhancing the viewing experience. The device includes a filtration system that is concealed from the viewer and that filters the water around the video device without exposing the device to water or any other elements of the aquarium's habitat.

HABITAT FOR HOUSING COLD BLOODED ANIMALS, WARM BLOODED ANIMALS, AND PLANTS

The present invention is directed to a habitat for housing either cold blooded animals, warm blooded animals or plants, and in particular it is directed to a habitat for housing cold blooded animals such as lizards including geckos and the like. The present habitat apparatus comprises a transparent terrarium in combination with a stand, the stand including a partition that provides a space to receive and nest the transparent terrarium within so a portion of the transparent terrarium is masked by the partition to create a secure zone within the interior space of the terrarium that is distinct from adjoining interior space. 1) A habitat apparatus comprising:a) a transparent terrarium having a top, a base, sidewalls, and a backwall opposite a front wall, said front wall including a fixed panel attached to said sidewalls and base, and a hinged panel attached to said fixed panel, said hinged panel attached to open in an outward direction; i) a partition including a terrarium support panel, said partition configured to nest said transparent terrarium therein, said partition shaped to mask a portion of said transparent terrarium to create a secure zone within an interior space of said transparent terrarium distinct from an adjoining interior space, and', 'ii) a life support system comprising a thermostat fixed to said stand and connected to a heat source attached to a surface of said partition at a location to contact a surface of a transparent terrarium nested within the partition, said thermostat connected to control output temperature of said heat source., 'b) a stand comprising;'}2) The habitat apparatus recited in claim 1 , wherein said partition includes side panels shaped to mask a portion of said transparent terrarium sidewalls to create said secure zone within the interior space and to also expose a portion of said sidewalls to provide an optimum visibility through said sidewalls into said interior space.3) The habitat apparatus recited in claim 2 , wherein said ...

AUTOMATIC WATER QUALITY SURVEILLANCE APPARATUS

Provided is a small and simple automatic water quality surveillance apparatus that can automatically sense toxic substances, oil, mold, or the like contained in raw water. The apparatus includes an odor-sensing water tank through which the raw water circulates. The tank further includes an odor sensor sensing an odor, such as an oily odor, a mold odor, and so on. Upon having sensed the toxic substances, oil, mold, or the like, an alarm is automatically issued thereby. 1. An automatic water quality surveillance apparatus , comprising:a water tank for fish always and continuously receiving raw water so as to rear a plurality of cyprinodonts therein, the raw water including: river flowing water; lake water; and ground water; anda CCD video camera photographing abnormal behavior when the raw water contains toxic substances therein, the abnormal behavior including:a first case where the plurality of cyprinodonts form a fixed group that does not move;a second case where the plurality of cyprinodonts take at least one of repelling action and madly-rushing action; anda third case where the plurality of cyprinodonts die,wherein:the automatic water quality surveillance apparatus performs digital conversion on image signals from the CCD video camera, and judges an abnormality according to image processing to automatically output an alarm;the automatic water quality surveillance apparatus further comprising:an odor-sensing water tank through which the raw water circulates;an odor sensor sensing a mold odor of the odor-sensing water tank; anda heater warming the raw water circulating within the odor-sensing water tank;the odor sensor includes: an odor sensor sensing element; and an odor sensor control unit;the odor sensor sensing element and the odor sensor control unit are separately arranged and are connected to each other by means of a cable;the odor sensor sensing element is arranged within the odor-sensing water tank;the odor sensor control unit includes:a sensitivity- ...

FLAT HEATER

A flat heater includes a housing including an accommodating groove formed inside the housing; a circuit unit disposed within the housing to control the heater, wherein the circuit unit includes a circuit board and a first rectifier disposed on the circuit board; a heating module disposed in the accommodating groove and electrically connected to the circuit unit, wherein the heating module includes a plurality of heating pipes and a plurality of second rectifiers disposed in each of the heating pipes; an upper cover assembled to a top surface of the housing and comprising a long side and a short side, wherein a plurality of fluid-permeable holes are formed on the upper cover; and a suction member inserted into the through hole and attached to an object and thereby fixing the housing to the object. 1. A flat heater , comprising:a housing comprising an accommodating groove formed inside the housing;a circuit unit disposed within the housing and configured to control the heater, wherein the circuit unit comprises a circuit board and a first rectifier disposed on the circuit board;a heating module disposed in the accommodating groove and electrically connected to the circuit unit, wherein the heating module comprises a plurality of heating pipes and a plurality of second rectifiers, and each of the second rectifiers is disposed in each of the heating pipes;an upper cover assembled to a top surface of the housing and comprising a long side and a short side, wherein a plurality of fluid-permeable holes are formed on the upper cover, at least one through hole is formed on the upper cover and near the long side, and the upper cover is a plate; anda suction member inserted into the through hole and attached to an object and thereby fixing the housing to the object.2. The flat heater as claimed in claim 1 , further comprising a power cable claim 1 , wherein the housing comprises a short side claim 1 , the power cable is disposed on the short side claim 1 , the power cable is ...

Aquaculture system with improved feed transportation and method for transporting feed in an aquaculture system

An aquaculture system including a fish holding unit which is fluidly connected to a water recirculation conduit, a water treatment unit, a water inlet, and a feed storage unit. The system further includes a feed loading section. When feed is added into the system at the feed loading section it is transported to the fish holding unit. In another aspect the invention relates to a method of transporting a feed in a recirculated aquaculture system. 116-. (canceled)17. An aquaculture system , the system comprising:a fish holding unit fluidly connected to a water recirculation conduit, a water treatment unit, a water inlet, and a feed storage unit,the system further comprising a feed loading section located in the water recirculation conduit, so that when feed is added into the system at the feed loading section it is hydraulically transported as a solid-liquid flow to the fish holding unit, wherein the water recirculation conduit comprises the water treatment unit and wherein the feed loading section is located downstream of the water treatment unit.18. The aquaculture system according to claim 17 , wherein the water treatment unit comprises one or more of a bio-filtration unit claim 17 , a solids removal unit claim 17 , a pH control unit claim 17 , a temperature control unit claim 17 , an Ultra Violet (UV) treatment unit claim 17 , an oxygenation unit claim 17 , a COstripping unit claim 17 , and an ozone treatment unit.19. The aquaculture system according to claim 17 , wherein the fish holding unit is fluidly connected to one or more further fish holding units claim 17 , which fish holding units are optionally coupled in series or in parallel or a combination thereof.20. The aquaculture system according to claim 17 , wherein conduits in the aquaculture system which are located downstream of the feed loading section are made of a plastic material.21. A method of transporting a feed in a recirculated aquaculture system claim 17 , the method comprising the steps of: ...

MODULAR HABITAT SYSTEM AND METHOD

Modular habitat structure (MHS) which accommodates one or more live inhabitants is comprised of a rigid pillar which extends linearly away from a base end toward an upper end. A plurality of major system components disposed at different locations along a length of the rigid pillar are each comprised of modular segments. A control unit controls a plurality of electronic devices integrated in the MHS, including one or more video cameras which generate live video streams of a wildlife habitat within the MHS, and communicates the video streams from the MHS to a remote computing device.

SMART CLOUD-BASED INTERACTIVE AQUARIAL DEVICE

A smart cloud-based interactive aquarial device, mounted on an aquarium and connected to at least one cloud server to communicate with an electronic device through the cloud server, including an image capturing device for capturing images in the aquarium; at least one peripheral control device including a feeding member for feeding fish foods into the aquarium automatically or according to a feeding instruction of the electronic device; a processing module connected to the image capturing device and the peripheral control device to control operation thereof; and a wireless communication module for enabling the smart cloud-based interactive aquarial device to communicate with the cloud server or the electronic device, sending images captured by the image capturing device to the cloud server for storage and sending at least one instruction to the processing module through the cloud server. 1. A smart cloud-based interactive aquarial device , mounted on an aquarium and connected to at least one cloud server to communicate with an electronic device interactively through the cloud server , the smart cloud-based interactive aquarial device comprising:an image capturing device for capturing images in the aquarium;at least one peripheral control device including a feeding member for feeding fish foods into the aquarium automatically or according to at least one feeding instruction of the electronic device;a processing module connected to the image capturing device and the peripheral control device to control operation thereof; anda wireless communication module connected to the processing module to enable communication between the smart cloud-based interactive aquarial device and the cloud server or allow the smart cloud-based interactive aquarial device to communicate with the electronic device through the cloud server, sending images captured by the image capturing device to the cloud server for storage and sending at least one instruction to the processing module through ...

Kit for assembling an aquarium aquaponic assembly and aquarium aquaponic assemblies thereof

A kit for an aquarium aquaponic assembly is disclosed. The kit comprises generally an aquarium module, a garden module, a reservoir module, drain conduits fluidly connecting the modules and a pump. The reservoir module has a top opening adapted to receive and maintained both the aquarium module and at least one garden module. Each garden module supports terrestrial plants and is located directly adjacent to one side of the aquarium module and located below a predetermined operating water level of the aquarium module. The aquarium module comprises a transparent tank adapted to be partially supported by the reservoir module. The system is designed such that the waste water from the aquarium module flows to the garden module for irrigating and feeding the plants. The waste water flowing from the garden module is filtered and directed to the reservoir module then pumped back to the aquarium module.

SCALABLE, BIOREGENERATIVE CROP AND ENERGY PRODUCTION SYSTEM FOR TERRESTRIAL AND NON-TERRESTRIAL USE

A method and system for self-contained growth and harvesting of plant and animal foodstuffs and energy generation for terrestrial and non-terrestrial uses. The system can be self-contained and sealed from an ambient atmosphere wherein sufficient oxygen and carbon dioxide levels are maintained (bio-regenerative) to support human life. The system and method may utilize aquaculture and hydroponic plant growth with a digester for converting waste into nutrients. Water may circulate among the digester, aquaculture tanks and hydroponic growth tanks. The method may be scalable to support varying quantities of human life. The system and method may generate energy and consume greater quantities of carbon dioxide than generated. The system may be energy self-sufficient utilizing solar, wind or other energy sources such as generated methane gas. 120-. (canceled)21. A self-contained system having at least one enclosure for growing food and generating energy comprising:(a) one or more enclosures;(b) at least one first tank within the enclosure structured for hydroponic growth of plants;(c) at least one second tank within the enclosure structured for growth of aquatic animals and containing reproducing plant or algae;(d) an anerobic digester structured to transform organic waste by-products collected from the second tank into nutrients that can be conveyed to the first tank;(e) a piping and pump component structured to convey and circulate water among the second tank, the digester, and the first tank;(f) one or more aquatic animals within the second tank wherein the animals produce a sufficient quantity of animal waste that can be transformed into a sufficient quantity of water conveyable nutrients to allow plant growth within the first tank;(g) a quantity of plants in the first tank to cleanse the water of nitrogen and ammonia to be convey to the second tank; and(h) wherein the quantity of nutrients a produced by the animals of the second tank to grow the plants of the first ...

ORGANIC FISHERY SYSTEM HAVING CLEANING AND HEATING FEATURES

A system for organic farming of aquatic livestock has at least one substantially enclosed container structured and arranged to contain at least one input-controlled organic environment usable to organically farm such aquatic livestock. At least one pollutant-free water-supplier is structured and arranged to supply, to the at least one substantially enclosed container, water substantially free of environmental pollutants. At least one aquatic life-support unit is structured and arranged to maintain within the at least one substantially enclosed container habitable environment consistent with sustaining growth of such aquatic livestock. At least one heating system is coupled to the at least one substantially enclosed container for heating an air mixture. The air mixture is injected into the water substantially free of environmental pollutants to heat the water substantially free of environmental pollutants. 1. A system for organic farming of aquatic livestock , comprising:at least one substantially enclosed container structured and arranged to contain at least one input-controlled organic environment usable to organically farm such aquatic livestock;at least one pollutant-free water-supplier structured and arranged to supply, to said at least one substantially enclosed container, water substantially free of environmental pollutants;at least one aquatic life-support unit structured and arranged to maintain within said at least one substantially enclosed container habitable environment consistent with sustaining growth of such aquatic livestock; andat least one system coupled to said at least one substantially enclosed container for heating an air mixture, said air mixture that was heated being injected into said water substantially free of environmental pollutants to heat said water substantially free of environmental pollutants.2. The system for organic farming of aquatic livestock in accordance with claim 1 , further comprising an automated vacuum system coupled to a ...

Aquarium with wireless power supply function

An aquarium with a wireless power supply function is disclosed. In the aquarium, a base frame is disposed under a water tank, a top box is disposed on the water tank, and the base frame includes a coil box and a coil holder. The coil holder is disposed on the coil box, and an outer diameter of the coil holder is smaller than an inner diameter of the coil box, to form a gap between the coil box and the coil holder to dispose a first coil around the coil box. The first coil can generate electromagnetic induction when being energized. The first coil surrounds an outer side of a bottom of the water tank, and a second coil is disposed around an inner periphery of the top box, so that the first coil can generate electric energy through electromagnetic induction and transfer power to multiple devices.

BIOREACTOR USING MACROALGAE

The invention features a bioreactor for the growth of macroalgae and methods for using the bioreactor to maintain optimal nutrient levels for the organisms in an aquarium or aquaculture system. The devices and methods of the invention provide for the bioremediation of excess nutrients in order to maintain nutrient balance in an aquarium or aquaculture system that facilitates growth and/or health of one or more of the organisms that reside therein. 1. A bioreactor for the bio-absorption of targeted nutrients in an aquarium or aquaculture system comprising a light assembly that is mounted in an armature assembly comprising a light-transmissible tube and support structures for the growth of macroalgae , wherein the armature assembly is mounted within an outer chamber assembly , wherein the light transmissible tube and the outer chamber define a growth chamber for the macroalgae.2. The bioreactor of claim 1 , wherein the growth chamber is substantially sealed from the surrounding atmosphere when the bioreactor is in use.3. The bioreactor of claim 1 , wherein the light assembly is removably affixed to the armature assembly and the armature assembly is removably affixed to the outer chamber assembly.4. The bioreactor of claim 1 , wherein the light assembly comprises a light source and a cooling system.5. The bioreactor of claim 1 , wherein the light assembly comprises a light source selected from one or more of the group consisting of LED claim 1 , fluorescent light claim 1 , light emitting cathode (LEC) claim 1 , and side emitting fiber optics.6. The bioreactor of claim 5 , wherein the light source comprises a plurality of LED lights.7. The bioreactor of claim 4 , wherein the cooling system comprises one or more of the group consisting of a water-based cooling system claim 4 , a refrigerant-based cooling system claim 4 , a conductive metal rod claim 4 , and a heat pipe.8. The bioreactor of claim 7 , wherein the cooling system comprises a heat pipe.9. The bioreactor of ...

SYSTEM AND METHOD FOR PASSIVE SOLAR CONTAINERS WITH INTEGRATED AQUAPONICS, GREENHOUSE AND MUSHROOM CULTIVATION

A foldable aquaponics, and greenhouse container system and method, includes an insulated shipping container having foldable insulated roof panel disposed thereover; a foldable glazing on a sun facing side at an angle to maximize winter sunlight attached to the roof panel; a foldable floor panel attached to the container with a foldable vent panel attached thereto connecting to the glazing; foldable side panels attached to sides of the container, glazing and roof panel; a plant growing under the glazing; a mushroom growing area within the container having an integrated water wall thermal mass and disposed between the plant and mushroom growing areas; a fish tank within the container; and a natural air ventilation system within the container under the roof panel to provide CO2 and O2 gas exchange between the mushroom growing area and the plant growing area. 1. A foldable aquaponics , and greenhouse container system comprising:an insulated shipping container;a foldable insulated roof panel attached to and disposed over the shipping container;a foldable glazing on a sun facing side at an angle to maximize winter sunlight attached to the insulated roof panel;a foldable floor panel attached to the shipping container;a foldable vent panel attached to the foldable floor panel and connecting to the foldable glazing;foldable side panels attached to sides of the shipping container and the glazing and the foldable insulated roof panel;a plant growing area housed under the glazing;a mushroom growing area housed within the shipping container;a water wall thermal mass integrated with the shipping container and disposed between the plant growing area and the mushroom growing area;a fish tank housed within the shipping container; anda natural air ventilation system housed within the shipping container under the foldable insulated roof panel and configured to provide misted air into the mushroom growing area,wherein O2 generated by the plant growing area is received by the natural ...

AQUACULTURE SYSTEMS AND METHODS

An aquaculture system can include stacked growth trays. Animals, such as shrimp, can be transferred between the growth trays for different stages of growth. Waste water can be removed from the growth trays and can be processed by a water treatment system. Treated water can be returned to the growth trays. A valve in a first configuration can permit water to circulate through the growth tray, while impeding the animals from exiting the growth tray. In a second configuration, the valve can permit the animals to exit the growth tray, such as for transition to a subsequent growth tray. A sweeper system can be used for cleaning and/or mixing the water in the growth tray, and/or for pushing the animals out of the growth tray during a transition. 1. A shrimp aquaculture system comprising: a first growth tray;', 'a second growth tray;', 'a third growth tray;', 'a fourth growth tray;', 'a fifth growth tray;', 'a sixth growth tray; and', 'a seventh growth tray;, 'a plurality of growth trays in a stacked configuration, the plurality of growth trays comprisinga drainage tray positioned below the plurality of growth trays, wherein water drains out of the plurality of growth trays and into the drainage tray; anda water treatment system configured to treat water received from the drainage tray and to deliver treated water to the plurality of growth trays; a first configuration to drain water out of the first growth tray and into the drainage tray while impeding shrimp from exiting the first growth tray;', 'a second configuration to transfer water and shrimp from the first growth tray to the second growth tray; and', 'a third configuration to transfer water and shrimp from the first growth tray to the third growth tray;, 'wherein the first growth tray has a first configuration to drain water out of the second growth tray and into the drainage tray while impeding shrimp from exiting the second growth tray;', 'a second configuration to transfer water and shrimp from the second growth ...

SYSTEM AND METHOD FOR MAINTAINING THE HEALTH OF CAPTIVE FISH IN A MOBILE ENVIRONMENT

A system for maintaining the health of captive fish in a mobile environment, comprising a live well for containing fish in a fluid medium, a plurality of thermoelectric coolers affixed to the live well, and a live well controller for controlling a direct current applied to the thermoelectric coolers, and a method for maintaining a consistent temperature comprising the steps of setting an initial temperature, applying a current to thermoelectric coolers, reading a new temperature, and adjusting the current based at least in part on the new temperature reading. 1. A system for maintaining the health of captive fish in a mobile environment , comprising:a live well;a fluid medium;a plurality of thermoelectric coolers; anda live well controller;wherein the live well is a container that holds the fluid medium;wherein the thermoelectric coolers are affixed to the live well and receive a direct electric current; andwherein the live well controller controls the direct electric current and thereby controls water temperature in the live well.2. The system of claim 1 , wherein the thermoelectric coolers are integral to the design of the live well.3. The system of claim 1 , wherein the thermoelectric coolers are removably affixed to the live well.4. The system of claim 1 , wherein the live well is affixed to the hull of a boat.5. The system of claim 1 , further comprising an internal sensor claim 1 , wherein the internal sensor reads the fluid conditions of the fluid medium within the live well.6. The system of claim 5 , wherein the live well controller receives sensor data from the internal sensor claim 5 , and alters the direct electric current based at least in part on the sensor data.7. The system of claim 5 , wherein the internal sensor is a thermometer.8. The system of claim 5 , wherein the internal sensor is a pH sensor.9. The system of claim 5 , further comprising an external sensor claim 5 , wherein the external sensor reads the fluid conditions of an environment ...

Vivaria Assembly

A vivaria assembly for separating aquatic animals and plants from terrestrial animals and plants includes a container and a set of panels. The panels are engaged to the container and positioned in an interior space defined by the container. Each panel extends from a bottom to proximate to a top of the container so that the container and the panels define a plurality of compartments within the interior space. The panels and at least a portion of a wall of the container are substantially transparent. A plurality of cutouts is positioned in the container so that each compartment has at least one cutout permitting access to the compartment. A respective habitat element and at least one of an animal and a plant can be inserted into each compartment to create a respective vivarium within the compartment. 1. A vivaria assembly comprising:a container defining an interior space;a panel engaged to the container and positioned in the interior space, the panel extending from a bottom to proximate to a top of the container, such that the container and the panel define a plurality of compartments within the interior space, the panel and at least a portion of a wall of the container being substantially transparent, the panel extending between opposed sides of the container defining a first chamber and a second chamber; anda plurality of cutouts positioned in the container, such that each compartment has at least one cutout permitting access to the compartment, wherein each compartment is configured for insertion of a respective habitat element and at least one of an animal and a plant, for creating a respective vivarium within the compartment; anda pump engaged to the container, the pump being positioned on a pump stand extending laterally from the container coplanar with the top of the container, the pump being configured for pumping air into the first chamber, wherein the pump is configured for aerating water positioned in the first chamber, such that the first chamber is ...

DISSOLVED GAS SUPPLYING DEVICE

A problem with conventional rearing apparatuses for deep-sea organisms was difficulty in supplying dissolved gas into water in an appropriate amount. 1. A dissolved gas supplying device for supplying dissolved gas to water in a water tank , comprising:a circulation path to take out the water from the water tank and to return the water to the water tank;a pressure pump to allow the water to flow through the circulation path;a gas cylinder filled with gas to be dissolved;a dissolved gas supplying means that is disposed in the circulation path to allow the water to pass through the dissolved gas supplying means and to dissolve the gas of the gas cylinder into the water; anda gas regulating valve to open and close a gas channel that connects the gas cylinder to the dissolved gas supplying means.4. The aquatic organism rearing apparatus according to claim 3 , further comprising a water temperature controlling means to control a temperature of the water in the water tank claim 3 , wherein the water temperature controlling means comprises a temperature sensor to measure the water temperature claim 3 , and a water temperature controller to control the temperature of the water to be within a predetermined range according to a detected value of the temperature sensor.6. The aquatic organism rearing apparatus according to claim 5 , further comprising a water temperature controlling means to control a temperature of the water in the water tank claim 5 , wherein the water temperature controlling means comprises a temperature sensor to measure the water temperature claim 5 , and a water temperature controller to control the temperature of the water to be within a predetermined range according to a detected value of the temperature sensor. The present invention relates to a device for supplying predetermined gas to be dissolved into water, in particular to a dissolved gas supplying device used for rearing aquatic organisms of chemosynthetic ecosystems that live in the environment ...

MODULAR HABITAT SYSTEM AND METHOD

Modular habitat structure (MHS) which can accommodate one or more live inhabitants is comprised of a rigid pillar which extends linearly away from a base end toward an upper end. A plurality of major system components are disposed at different locations along a length of the rigid pillar. Each of the major system components is comprised of modular segments which individually extend circumferentially around at least a portion of the rigid pillar. The modular configuration of the segments allows user configuration of the MHS by selectively adding or removing one or more segments of each of the major system components. 1. A modular habitat structure (MHS) for accommodating one or more live inhabitants , comprising:a rigid pillar which extends away from a base end toward an upper end;a plurality of major system components, each disposed at a different one of a plurality of locations along a length of the rigid pillar;each of the major system components comprised of one or more segments which individually extend circumferentially around at least a portion of the rigid pillar;each of the segments having a predefined modular configuration, whereby the MHS is user adjustable to a plurality of different configurations by selectively adding or removing one or more segments of the major system components to circumferentially vary an extent of each of the major system components around a periphery of the rigid pillar.2. The MHS according to claim 1 , wherein the plurality of major system components include a retention cabinet system claim 1 , wherein each of the one or more of the segments of the retention cabinet system is individually comprised of a retention well in the form of a bowl.3. The MHS according to claim 2 , wherein the plurality of major system components further comprise a canopy structure claim 2 , each of the one or more segments of the canopy structure extending radially outward from the central pillar to define an upper surface and a lower surface opposed ...

SELF-HARVESTING SUSTAINING FEED SYSTEM FOR AQUAPONICS

A self-harvesting sustaining feed system includes a tank for housing fish, a frame located above the fish tank, one or more plant floats which float atop water within shelves held by the frame, and an insect tray for housing larvae. Temporary temperature changes in the insect tray cause the larvae within the insect tray to migrate out and fall into the fish tank below. 1. A self-harvesting sustaining feed system for an aquaponics system comprising:a tank;a frame above the tank;one or more plant floats in communication with the frame;an insect tray held by the frame, the insect tray having slanted walls; andone or more shelves held by the frame.2. The self-harvesting sustaining feed system of claim 1 , wherein the insect tray further comprises a base claim 1 , wherein the slanted walls of the insect tray form a forty-five degree angle with the base.3. The self-harvesting sustaining feed system of claim 2 , wherein the slanted walls have one or more apertures.4. The self-harvesting sustaining feed system of claim 1 , wherein the system further comprises a water heating system to heat water in the tank.5. The self-harvesting sustaining feed system of claim 4 , wherein the water heating system has an inlet pipe and an outlet pipe.6. The self-harvesting sustaining feed system of claim 1 , wherein the tank houses fish.7. The self-harvesting sustaining feed system of claim 1 , wherein the insect tray houses insect larvae.8. The self-harvesting sustaining feed system of claim 1 , wherein the one or more shelves have side walls.9. The self-harvesting sustaining feed system of claim 5 , wherein the one or more shelves have apertures for accepting an outlet pipe from the water heating system.10. The self-harvesting sustaining feed system of claim 1 , wherein the frame is above a tank.11. The self-harvesting sustaining feed system of claim 1 , wherein the tank houses fish comprising at least one of tilapia claim 1 , blue gill claim 1 , brim claim 1 , sunfish claim 1 , crappie ...

SYSTEM AND METHOD FOR SOLAR GREENHOUSE AQUAPONICS AND BLACK SOLDIER FLY COMPOSTER AND AUTO FISH FEEDER

A system, method, and computer program product for an aquaponics, and greenhouse system, including a solar greenhouse insulated on north, east and west sides and with glazing on a south side at an angle to maximize winter sunlight, and housing: a fish tank; grow beds coupled to the fish tank; and hydroponic tanks respectively coupled to the grow beds. The grow beds are coupled to a fish tank geyser pump internal to the fish tank, and a hydroponic tank geyser pump internal to a respective one of the hydroponic tanks. The fish tank and hydroponic tank geyser pumps are powered by an external air pump via an air selector switch to pump and aerate water from the hydroponic tank to the grow bed and to pump water from the fish tank to the grow bed and aerate water of the fish tank. 1. An aquaponics , and greenhouse system comprising:a solar greenhouse insulated on north, east and west sides and with glazing on a south side at an angle to maximize winter sunlight, and housing:a fish tank housed within the solar greenhouse;a plurality of grow beds coupled to the fish tank and also housed within the solar greenhouse;a plurality of hydroponic tanks respectively coupled to the grow beds and also housed within the solar greenhouse; andeach one of the plurality of grow beds is coupled to a fish tank geyser pump internal to the fish tank, and a hydroponic tank geyser pump internal to a respective one of the hydroponic tanks,wherein the fish tank and hydroponic tank geyser pumps are powered by an external air pump via an air selector switch to pump and aerate water from the hydroponic tank to the grow bed and to pump water from the fish tank to the grow bed and aerate water of the fish tank.2. The system of claim 1 , further comprising:a rocket mass heater inside the greenhouse to heat the greenhouse and fish tank water, and comprising an L-shaped mass with an interior metal column with metal coils wrapped around the metal column to heat water from the fish tank circulating ...

SYSTEM AND METHOD FOR SOLAR GREENHOUSE AQUAPONICS AND BLACK SOLDIER FLY COMPOSTER AND AUTO FISH FEEDER

An aquaponics and greenhouse system, includes an insulated solar greenhouse with a glazing on a sun facing side at an angle to maximize winter sunlight, and housing a fish tank housed within the solar greenhouse; a plant growing area housed within the solar greenhouse; a mushroom growing area housed within the solar greenhouse; a water wall thermal mass housed within the solar greenhouse and disposed between the plant growing area and mushroom growing area; and a natural air ventilation system housed within the solar greenhouse and configured to provide misted air into the mushroom growing area. O2 generated by the plant growing area is received by the natural air ventilation system and provided to the mushroom growing area, and CO2 generated by the mushroom growing area is provided to the plant growing area. 1. An aquaponics , and greenhouse system comprising:an insulated solar greenhouse with a glazing on a sun facing side at an angle to maximize winter sunlight, and housing:a fish tank housed within the solar greenhouse;a plant growing area housed within the solar greenhouse;a mushroom growing area housed within the solar greenhouse;a water wall thermal mass housed within the solar greenhouse and disposed between the plant growing area and mushroom growing area; anda natural air ventilation system housed within the solar greenhouse and configured to provide misted air into the mushroom growing area,wherein O2 generated by the plant growing area is received by the natural air ventilation system and provided to the mushroom growing area, and CO2 generated by the mushroom growing area is provided to the plant growing area.2. The system of claim 1 , further comprising:a plurality of grow beds coupled to the fish tank and also housed within the solar greenhouse in the plant growing area, wherein each one of the plurality of grow beds is coupled to a respective fish tank geyser pump internal to the fish tank,wherein the fish tank geyser pumps are powered by an external ...

MARINE FARMING SYSTEM

Provided are systems and methods for farming bivalves, such as clams, oysters and scallops, using the principles of geothermal cooling. The system comprises a housing for containing the bivalves and a fluid distribution system configured to move water from a relatively warm body of water, such as an inlet to an ocean, to the housing. The fluid distribution system includes a conduit having an outer surface in thermal contact with a natural thermal reservoir with a temperature cooler than the body of water. The conduit is configured to transfer energy from the water to the thermal reservoir to cool the water and to pump nutrient-rich cooler water through the housing containing the bivalves. 1. A system for raising bivalves comprising:a housing having an interior configured for containing a plurality of bivalves; anda fluid distribution system configured to move water from a body of water to the housing, wherein the fluid distribution system includes a conduit in thermal contact with a thermal reservoir having a temperature cooler than the body of water, the fluid distribution system being configured to cool the water such that a temperature of the water is substantially reduced between the body of water and the housing.2. The system of wherein the body of water has a first temperature and the water in the housing has a second temperature claim 1 , the first temperature being at least 10 degrees Fahrenheit higher than the second temperature.3. The system of wherein the fluid distribution system comprises a pump coupled to the conduit and configured to move the water through the conduit past the thermal reservoir and through the housing.4. The system of wherein the fluid distribution system is configured to immerse the bivalves within the water.5. The system of wherein the thermal reservoir is the earth.62. The system of wherein at least a portion of the conduit is positioned at least feet under a surface of the earth.7. (canceled)8. The system of wherein the body of ...

INSULATED AND VENTILATED SHELLFISH STORAGE

Various embodiments relating to insulated and ventilated shellfish storage, for transport for example, are disclosed. An insulated container includes a bottom and walls defining an interior space to accommodate live shellfish. A COhandling feature to handle COthat is released into the interior space by the live shellfish is also provided. The COhandling feature could include, for example, a ventilated wall having a vent at a location toward the bottom of the insulated container, COscrubbing, a COaccumulation structure to accumulate CObelow the live shellfish, and/or a ventilated wall substantially parallel to the bottom to divide the interior space into an animal section to accommodate the live shellfish and a COaccumulation section to accumulate CO. Embodiments are based on a discovery by the inventor that COis a limiting factor for storage time of crustaceans out of water. 1. An insulated container comprising:a bottom and a plurality of walls defining an interior space to accommodate live shellfish, the plurality of walls comprising a ventilated wall having a vent at a location toward the bottom.25-. (canceled)6. The insulated container of claim 1 , further comprising:a gas permeable and water-resistant structure, adjacent to the vent, to form a water-resistant seal over the vent.7. The insulated container of claim 1 , wherein the location is at or below an expected height of gills of the live shellfish relative to the bottom.8. The insulated container of claim 7 , wherein the expected height is based on the live shellfish being oriented in a vertical orientation substantially perpendicular to the bottom.9. The insulated container of claim 7 , wherein the expected height is based on the live shellfish being oriented in a horizontal orientation substantially parallel to the bottom.10. The insulated container of claim 1 , wherein the location is at or above an expected height of a liquid level inside the insulated container relative to the bottom.1132-. (canceled)33 ...

AQUARIUM SYSTEM FOR ALL-AROUND VIEWING AND MICROCLIMATE SIMULATION

An aquarium system for all-around viewing has a tank enclosure formed by optically transparent sides and a bottom plane, a sunken chamber below the tank for circulating water from and into the tank by a water circulation pump, water circulation outlet and inlet risers for circulating water flow from the tank into the sunken chamber and back into the tank, and a base on which the tank and sunken chamber are seated for containing electrical components for the aquarium system. The sunken chamber may be immersed within an outer pool of water to give the appearance of the tank enclosure floating on water. The base may hold various electrical and mechanical components for microclimate simulation, including magnetic induction drive for the water circulation pump and other motorized components; water spray pump to simulate rain; cooling pad; heating pad; temperature sensors; audio speakers; lighting controller; fog dispenser; and microprocessor for programmed control of desired microclimate simulations. 1. An aquarium system comprising:a tank enclosure formed with contiguous sides of optically transparent material and a bottom plane for containing a volume of water therein;a sunken chamber provided below the bottom plane of the tank enclosure for channeling a flow of water circulated from and back into the tank enclosure by a water circulation pump positioned within or adjacent to the sunken chamber;a water circulation outlet riser for circulating water from the tank enclosure directly or indirectly into the sunken chamber below, and a water circulation inlet riser connected to the water circulation pump for circulation of water back into the tank enclosure above, wherein said water circulation outlet and inlet risers are made of optically transparent material; anda bottom base on which the sunken chamber and tank enclosure are seated containing therein equipment for powering the water circulation pump positioned within or adjacent to the sunken chamber and other equipment ...

A method of controlling culture water temperature in a water tank for aquarium fish and a culture water thermostat using a plurality of peltier elements

A peltier device comprises peltier elements specified in cooling or heating temperature, a heating heat sink connected in contact on one side surface of the peltier element, a chilling heat sink connected in contact on the other side surface of the peltier element, and a cooling fan. Using peltier elements each of which is specified in a cooling or a heating activity, a heat exchange efficiency is enhanced thank to a plurality of functions of a single peltier element; thermal radiation is separated by bringing the peltier element into contact with a heating heat sink and a cooling heat sink independently from each other; the surface area in contact with the fluid is maximized through the “X” shaped aperture formed with four wings protruding from the inner surface of the aperture towards the center part, directly transferring the endothermic and exothermic effects from the Peltier element to the fluid.

AUTOMATED ENCLOSED SYSTEM FOR EGG INCUBATION AND LARVAL GROWTH

An enclosed incubation system for production of trout fish is disclosed. The incubation system includes: an ultraviolet unit to disinfect water prior to entering the system, a disinfecting tank to disinfect water, a plurality of water tanks to supply water, a water heater, a plurality of fish tanks, a plurality of inlet and outlet valves, a plurality of canals, a first and a second aeration pump to aerate the plurality of the fish tanks. 1. An enclosed incubation system for production of trout fish comprising:a disinfecting tank, configured to receive and disinfect water;a plurality of water tanks that are disposed adjacent to one another, wherein each water tank is in fluid communication with at least one adjacent water tank and the disinfecting tank;a water heater connected to a first water tank of the plurality of the water tanks;a plurality of fish tanks arranged in a substantially stacked formation, the plurality of fish tanks being disposed adjacent to the water tanks;wherein each of the plurality of fish tanks has a first water outlet on an upper half of a first end of each of the plurality of the fish tanks and a second water outlet below the first water outlet;a first inlet valve being configured to permit water to travel between at least one water tank of the plurality of water tanks and a fish tank of the plurality of fish tanks;a plurality of canal portions formed along a second end of at least one fish tank of the plurality of the fish tanks;each of the plurality of fish tanks including a second inlet valve from among a plurality of second inlet valves connecting each of the plurality of fish tanks to the disinfecting tank;a first aeration pump configured to aerate the plurality of the water tanks; anda second aeration pump configured to aerate the plurality of the fish tanks.2. The system of claim 1 , further comprising an ultraviolet unit coupled to the incubation system and configured to disinfect water prior entering the incubation system.3. The ...

System and method for storing live seafood

A system for storing live seafood, includes: compartments into which the seafood is introduced, a hydraulic circuit to cause water to circulate, an installation for treating the water, characterized in that: the compartments form part of at least one module taking the form of a unit which unit is made of a lightweight material, the water flow generated by the hydraulic circuit enters the compartments via the upstream end and reemerges via the downstream end thereof, the water circulating through the compartments is kept at a temperature of below 25° C.

Sustainable Aquaponic System and Method for Growing Useful Plants and for Treating Gray Water

A system and method of sustainable aquaponics that vertically integrates unique aquaponic system designs with alternative aquaculture fish feed sources, fingerling production methods, alternative aquaculture/farmed fish grow out models, and green energy sources that yield organic produce in the form of fruits and vegetables. A raceway system serves as the hub for grow-out throughout the warm and cold months. During the summer months, fish can be spawned and fed for steady growth, while during the winter months, the fish continue to grow at slower quite acceptable growth rates. Plants like legal (licensed) cannabis for medical use can be grown in plant areas near the raceways with very high yields. The system may also be used to reclaim gray water using the biology of the system to purify it for agricultural use. 1. A sustainable gray water reclamation system comprising:a man-made pond connected by a pump to a plurality of man-made raceways including a last raceway, each raceway lined with tarp and containing a variety of plant species including blue algae placed in the raceway to remove waste materials from raceway water and provide food for fish, wherein each raceway spills water through a man-made spillway into an adjacent raceway at a lower vertical level;a first source of water from a natural ecosystem feeding into said manmade pond;at least one insulated and heated winter quarters for fish in colder temperatures;a second source of gray water also feeding into said manmade pond;a poly-culture fish population wherein chosen predator fish eat other chosen fish in the system in a food chain wherein lower members in the food chain spawn faster than they are consumed by predator fish higher in said food chain;a plurality of man-made plant growing areas adjacent to or on said raceways, at least some of said plant growing areas producing legal cannabis with a yield of four to five pounds of buds per plant or hemp;a plurality of micro-electric generators situated in ...

Method for NR Radio Link Monitoring (RLM) and Evaluation Period Determination

Methods are proposed to define UE behavior for performing synchronization signal block (SSB) based radio link monitoring (RLM) and channel state information reference signal (CSI-RS) based RLM. In a first novel aspect, if CSI-RS based RLM-RS is not QCLed to any CORESET, then UE determines that CSI-RS RLM configuration is error and does not perform RLM accordingly. In a second novel aspect, SSB for RLM and RLM CSI-RS resources are configured with different numerologies. UE perform SSB based RLM and CSI-RS based RLM based on whether the SSB and CSI-RS resources are TDMed configured by the network. In a third novel aspect, when multiple SMTC configurations are configured to UE, UE determines an SMTC period and whether SMTC and RLM-RS are overlapped for the purpose of RLM evaluation period determination. 1. A method , comprising:receiving synchronization signal block (SSB) configuration for radio link monitoring (RLM) by a user equipment (UE) in a new radio (NR) network, wherein the SSB occupies a first OFDM symbol having a first numerology;receiving channel state information reference signal (CSI-RS) configuration for RLM by the UE, wherein the configured CSI-RS resource is allocated over a second OFDM symbol having a second numerology;determining whether the SSB and the configured CSI-RS resource are Time Division Multiplexed (TDMed) responsive to the first numerology and the second numerology being different; andperforming SSB based RLM and CSI-RS based RLM using the SSB and CSI-RS configuration for RLM based on whether the SSB and the configured CSI-RS resource are TDMed.2. The method of claim 1 , wherein the first numerology and the second numerology being different includes the first numerology and the second numerology having different subcarrier spacing (SCS) values.3. The method of claim 1 , wherein the first numerology and the second numerology being different includes the first numerology and the second numerology having different cyclic-shift prefix (CP) ...

HEAT EXCHANGE SYSTEM FOR WATER TEMPERATURE CONTROL

A heat exchange system includes a water flow casing shaped like an open box and having a flow space defined therein and water inlet/outlet pipes for guiding a water into the flow space or for guiding the water out of the flow space, a thermoelectric cooling chip fastened to the open side of the water flow casing with the cold side facing toward the flow space for cooling the water, a heat dissipating unit fastened to the opposing hot side of the thermoelectric cooling chip for dissipating heat from the thermoelectric cooling chip, and a water pump adapted for pumping the water through the water inlet/outlet pipes and flow space of the water flow casing for cooling. 1. A heat exchange system , comprising:a water flow casing made in the form of an open box, comprising at least one flow space, a plurality of water inlet/outlet pipes selectively for guiding a water into said at least one flow space or for guiding said water (A) out of said at least one flow space;at least one thermoelectric cooling chip respectively fastened to said water flow casing, each said thermoelectric cooling chip comprising a cold side facing toward one said flow space for cooling said water and a hot side opposite to said cold side;at least one heat dissipating unit fastened to said at least one thermoelectric cooling chip for dissipating heat from the said hot side of each said thermoelectric cooling chip; anda water pump adapted for pumping said water through said water inlet/outlet pipes and said at least one flow space of said water flow casing.2. The heat exchange system as claimed in claim 1 , wherein said water flow casing comprises two said flow spaces and a water passage disposed in communication with the two said flow spaces; two said thermoelectric cooling chips are fastened to said water flow casing with the cold sides thereof respectively disposed to face toward the respective two said flow spaces for direct contact with said water; two said heat dissipating units are respectively ...

DEVICE FOR COOLING A LIVEWELL

A modular apparatus and system for managing the temperature of a livewell or other container housing water, and an associated method for installing the same. The system featuring a self-contained fluid line in communication with a first fluid line, which is in fluid communication with the livewell. The system further can comprise an output module capable of outputting a signal related to the system. The modular apparatus generally featuring the system and an enclosure. The enclosure may comprise a user interface and be capable of being located in areas with limited available space. The enclosure can be located adjacent the livewell and detachably coupled to a fishing vessel. The modular apparatus and system can further comprise a condenser, which can be a forced air coil unit, a liquid-cooled unit, or a cold plate heat sink unit. The method of installing generally comprises removing existing livewell hose and providing the system. 1. A modular apparatus for managing the temperature of a livewell comprising:a self-contained fluid line;a first fluid line in communication with the self-contained fluid line;a condenser in communication with the self-contained fluid line;an enclosure comprising the self-contained fluid line, the first fluid line, and the condenser; anda user interface located on the enclosure; the self-contained fluid line comprises an expansion valve in fluid communication with a compressor;', 'the first fluid line comprises a first pump in fluid communication with a first inlet port and a first outlet port; and', 'the user interface comprises an output module., 'wherein2. The apparatus of claim 1 , wherein the first fluid line further comprises:a filter in fluid communication with the first inlet port and the first outlet port; anda first fluid line control valve in fluid communication with the first pump.3. The apparatus of further comprising a pressure sensor in communication with a pressure gauge located on the enclosure.4. The apparatus of claim 1 ...

SYSTEM AND METHOD FOR SOLAR GREENHOUSE AQUAPONICS AND BLACK SOLDIER FLY COMPOSTER AND AUTO FISH FEEDER

An aquaponics and greenhouse system, includes a solar greenhouse insulated on north, east and west sides and with glazing on a south side at an angle to maximize winter sunlight, and housing a fish tank, grow beds, and a hard filter. The grow beds and hard filter include geyser pumps in the fish tank powered by air pumps that pump water from the fish tank to the grow bed or hard filter and aerate fish tank water. The hard filter includes algae layer with an air stone powered by an air pump underneath to aerate the algae. Grow beds on the north side have a barrier layer over media, and with a mushroom bulk substrate layer disposed thereover. The air intake of the air pump of the hard filter or the air stone extract CO2 from the mushroom bulk substrate and pump the extracted CO2 to the algae layer. 1. An aquaponics , and greenhouse system comprising:a solar greenhouse insulated on north, east and west sides and with glazing on a south side at an angle to maximize winter sunlight, and housing:a fish tank housed within the solar greenhouse;a plurality of grow beds coupled to the fish tank and also housed within the solar greenhouse, wherein each one of the plurality of grow beds is coupled to a respective fish tank geyser pump internal to the fish tank, andthe fish tank geyser pumps are powered by an external air pump to pump water from the fish tank to the grow bed and aerate water of the fish tank; anda hard filter coupled to the fish tank and having a hard filter geyser pump internal to the fish tank and powered by an external air pump to pump water from the fish tank to the hard filter to aerate and filter water of the fish tank, wherein the hard filter includes algae layer on an upper portion thereof with an air stone powered by an external air pump underneath the algae layer to aerate the algae,one or more of the grow beds are disposed on the north side of the greenhouse and are configured with a barrier layer over media, and with a mushroom bulk substrate layer ...

AQUACULTURE HEATING DEVICE

This invention is related to an aquaculture heating device. A heating unit is hung on a support rod, so that the support rod can be horizontally placed above an aquaculture and two ends of the support rod can be fixedly positioned on two sides of the aquaculture to let the heating unit hung on the support rod to be dropped and immersed in the water of the aquaculture when winter, especially cold stream, comes. When electricity is provided to conductive yarns of a heating layer of the heating unit, heating filaments of the conductive yarns will generate heat to be transferred to the water and gradually diffused throughout the aqua culture through the waterproof fabric layer. Thus, the water temperature is raised to effectively help the aquatic organisms to resist the cold winter and not to be frozen to death caused by the very low water temperature. 1. An aquaculture heating device , comprising:at least a heating unit having at least two waterproof fabric layers covering a heating layer, wherein the heating layer comprises at least a heating fabric comprising multiple conductive yarns in a first direction and multiple nonconductive yarns in a second direction, as well as multiple metal conductive filaments disposed on two sides of the heating fabric and in a direction parallel to the second direction to be interwoven with the conductive yarns in the first direction to form a conductive path, wherein the conductive yarns and the nonconductive yarns are interwoven as warps and wefts, and wherein the conductive yarns each has a nonconductive axial yarn spiral-wound by a heating filament; anda suspension unit comprising a support rod having at least a binding part, wherein one terminal of the binding part disposed on the support rod and the other terminal of the binding part assembled with the heating unit.2. The aquaculture heating device of claim 1 , wherein the heating layer comprises multiple heating fabrics and a fixing element for fixing the heating fabrics.3. The ...

BIOREACTOR USING MACROALGAE

The invention features a bioreactor for the growth of macroalgae and methods for using the bioreactor to maintain optimal nutrient levels for the organisms in an aquarium or aquaculture system. The devices and methods of the invention provide for the bioremediation of excess nutrients in order to maintain nutrient balance in an aquarium or aquaculture system that facilitates growth and/or health of one or more of the organisms that reside therein. 1. A bioreactor for the bio-absorption of nutrients in an aquarium or aquaculture system comprising a light assembly , comprising an LED light source , that is mounted in an armature assembly comprising a light-transmissible tube and support structures for the growth of macroalgae , wherein the armature assembly is mounted within an outer chamber assembly , and wherein the light transmissible tube and the outer chamber define a growth chamber for the macroalgae.2. The bioreactor of claim 1 , wherein the growth chamber is substantially sealed from the surrounding atmosphere when the bioreactor is in use.3. The bioreactor of claim 1 , wherein the light assembly is removably mounted to the armature assembly and the armature assembly is removably mounted to the outer chamber assembly.4. The bioreactor of claim 1 , wherein the LED light source comprises a plurality of LED lights.5. The bioreactor of claim 1 , wherein the light assembly further comprises a cooling system.6. The bioreactor of claim 5 , wherein the cooling system comprises one or more of the group consisting of a water-based cooling system claim 5 , a refrigerant-based cooling system claim 5 , a conductive metal rod claim 5 , and a heat pipe.7. The bioreactor of claim 6 , wherein the cooling system comprises a heat pipe.8. The bioreactor of claim 6 , wherein the cooling system comprises a water-based cooling system.9. The bioreactor of wherein the armature assembly comprises a lid removably affixed to the light tube claim 1 , wherein the lid creates a ...

Sustainable Aquaponic System and Method for Growing Plants Like Medical Cannabis

A system and method of sustainable aquaponics that vertically integrates unique aquaponic system designs with alternative aquaculture fish feed sources, fingerling production methods, alternative aquaculture/farmed fish grow out models, and green energy sources that yield organic produce in the form of fruits and vegetables. A raceway system serves as the hub for grow-out throughout the warm and cold months. During the summer months, fish can be spawned and fed for steady growth, while during the winter months, the fish continue to grow at slower quite acceptable growth rates. Plants like legal (licensed) cannabis for medical use can be grown in plant areas near the raceways with very high yields. 1. A sustainable aquaponics system comprising:a man-made pond connected by a pump to a plurality of man-made raceways, each raceway lined with tarp and containing a variety of plant species including blue algae placed in the raceway to remove waste materials from raceway water and provide food for fish, wherein each raceway spills water through a man-made spillway into an adjacent raceway at a lower vertical level;a source of water from a natural ecosystem feeding into said man-made pond;at least one insulated and heated winter quarters for fish in colder temperatures;a poly-culture fish population wherein chosen predator fish eat other chosen fish in the system in a food chain, wherein lower members in the food chain spawn faster than they are consumed by predator fish higher in said food chain;a plurality of man-made plant growing areas adjacent to or on said raceways, at least some of said plant growing areas producing legal cannabis with a yield of four to five pounds of buds per plant or hemp;a plurality of micro-electric generators situated in said raceways producing electricity from moving water, said electricity used to partially power said pump.2. The sustainable aquaponic system of further comprising at least one of wind energy generators claim 1 , solar energy ...

BIOREACTOR USING MACROALGAE

The invention features a bioreactor for the growth of macroalgae and methods for using the bioreactor to maintain optimal nutrient levels for the organisms in an aquarium or aquaculture system. The devices and methods of the invention provide for the bioremediation of excess nutrients in order to maintain nutrient balance in an aquarium or aquaculture system that facilitates growth and/or health of one or more of the organisms that reside therein. 1. A bioreactor for the bio-absorption of nutrients in an aquarium or aquaculture system comprising a light assembly comprising an LED light source enclosed in a light-transmissible tube; and an armature assembly comprising one or more support structures for the growth of macroalgae; wherein the light assembly and armature assembly are mounted within an outer chamber assembly; wherein the light transmissible tube and the outer chamber define a growth chamber for the macroalgae; and wherein the light assembly has a coaxial orientation with respect to the growth chamber.2. The bioreactor of claim 1 , wherein the growth chamber is substantially sealed from the surrounding atmosphere when the bioreactor is in use.3. The bioreactor of claim 1 , wherein the light assembly further comprises a cooling system.4. The bioreactor of claim 3 , wherein the cooling system comprises one or more of the group consisting of a water-based cooling system claim 3 , a refrigerant-based cooling system claim 3 , a conductive metal rod claim 3 , and a heat pipe.5. The bioreactor of claim 4 , wherein the cooling system comprises a heat pipe.6. The bioreactor of claim 4 , wherein the cooling system comprises a water-based cooling system.7. The bioreactor of claim 1 , wherein the LED light source comprises a plurality of LED lights.8. The bioreactor of claim 1 , wherein the one or more support structures of the armature assembly are selected from the group consisting of baffle plates claim 1 , axially radiating pins claim 1 , axially radiating blades ...

WATERLESS KEEP-ALIVE APPARATUS AND REFRIGERATION APPLIANCE PROVIDED WITH THE WATERLESS KEEP-ALIVE APPARATUS

The present invention provides a waterless keep-alive apparatus and a refrigeration appliance having the same. The waterless keep-alive apparatus is provided in an inner tank of a refrigeration appliance, and comprises: a keep-alive box allowing pulling inward and outward; a temperature controlling module and a humidity controlling module which are connected with the keep-alive box; and an air controlling module having an air hole provided on a side wall of the keep-alive box and an air duct fixed on the inner tank of the refrigeration appliance. The air duct is hermetically connected with the air hole when the keep-alive box is pushed into the inner tank of the refrigeration appliance. The air duct is disconnected from the air hole when the keep-alive box is pulled out. The waterless keep-alive apparatus realizes convenient article fetching while the oxygen concentration in the keep-alive box can meet the survival needs of aquatic products. 2: The waterless keep-alive apparatus of claim 1 , wherein the air hole includes an air inlet and an air outlet claim 1 , and the air duct includes an air intake duct and an air exhaust duct; wherein the air intake duct and the air exhaust duct are hermetically connected with the air inlet and the air outlet respectively when the keep-alive box is pushed into the inner tank of the refrigeration appliance claim 1 , and the air intake duct and the air exhaust duct are respectively disconnected from the air inlet and the air outlet when the keep-alive box is pulled out.3: The waterless keep-alive apparatus of claim 2 , wherein both the air inlet and the air outlet are provided on the same side wall of the keep-alive box and a setting position of the air inlet is higher than a setting position of the air outlet in a vertical direction.4: The waterless keep-alive apparatus of claim 3 , wherein the air inlet and the air outlet are disposed along a diagonal line on the same side wall of the keep-alive box.5: The waterless keep-alive ...

System and method for maintaining the health of captive fish in a mobile environment

A system for maintaining the health of captive fish in a mobile environment, comprising a live well for containing fish in a fluid medium, a plurality of thermoelectric coolers affixed to the live well, and a live well controller for controlling a direct current applied to the thermoelectric coolers, and a method for maintaining a consistent temperature comprising the steps of setting an initial temperature, applying a current to thermoelectric coolers, reading a new temperature, and adjusting the current based at least in part on the new temperature reading.

FLOATING DEVICE FOR GROWING FISH AND/OR ALGAE

A floating device for use on a water surface is disclosed. The floating device comprises: a generally spherical hollow body defined by an equator line, a top pole and a bottom pole. The floating device further comprises a non-flat floating member, being inside the hollow body and having an apex constituted to support the top pole when the floating device is placed on the water surface. The body of the floating device is formed with at least one opening at each of the top and the bottom poles, and with an arrangement of openings circumferentially distributed above and below the equator line. 159-: (canceled)60. A method of growing algae , comprising placing on a water surface a floating device , and allowing algae culture to grow therein , wherein said floating device comprises:a generally spherical hollow body defined by an equator line, a top pole and a bottom pole; anda floating member inside said hollow body; said body being formed with at least one opening at each of said top and said bottom poles, and with an arrangement of openings circumferentially distributed above and below said equator line.61. A method of growing fish , comprising placing on a water surface a floating device , and allowing fish to enter said floating device , wherein said floating device comprises:a generally spherical hollow body defined by an equator line, a top pole and a bottom pole, said body being formed with at least one opening at each of said top and said bottom poles, said at least one opening being sizewise compatible with a size of the fish; anda non-flat floating member, being inside said hollow body and having an apex constituted to support said top pole when the floating device is placed on said water surface, wherein sealing of said opening at said top pole by said floating member is prevented.62. The method according to claim 60 , wherein said floating member is generally shaped as a ring.63. The method of claim 62 , wherein an inner diameter of said ring is selected to ...

LIVE ORGANISM STORAGE SYSTEM

A live organism storage system includes a holding tank configured to hold water and a plurality of live organisms, a water purifier in fluid communication with the holding tank and configured to purify water flowing therethrough, a fractionator in fluid communication with the holding tank, the fractionator configured to gather and remove protein and waste from water flowing therethrough, an oxygenator in fluid communication with the holding tank to increase oxygen content of water flowing therethrough, and a filter in fluid communication with the holding tank and configured to filter water flowing therethrough. The live organism storage system is a closed loop system. 1. A live organism storage system , comprising:a holding tank configured to hold water and a plurality of live organisms;a water purifier in fluid communication with the holding tank and configured to purify water flowing therethrough;a fractionator in fluid communication with the holding tank, the fractionator configured to gather and remove protein and waste from water flowing therethrough;an oxygenator in fluid communication with the holding tank to increase oxygen content of water flowing therethrough; anda filter in fluid communication with the holding tank and configured to filter water flowing therethrough,wherein the live organism storage system is a closed loop system.2. The system of claim 1 , wherein the water purifier includes an ultraviolet (UV) water treatment system.3. The system of claim 2 , wherein the UV treatment system includes a horizontally mounted channel mounted over the holding tank to a wall of the holding tank.4. The system of claim 1 , wherein the fractionator includes a vertical chamber configured to fractionate water flowing therethrough.5. The system of claim 1 , wherein the filter includes a bio filter.6. The system of claim 5 , wherein the bio filter includes a chamber with biological material disposed therein.7. The system of claim 6 , wherein the biological material ...

AUTOMATED, MODULAR, SELF-CONTAINED, AQUAPONICS GROWING SYSTEM AND METHOD

A shipping container that includes a greenhouse mounted above an aqueous tank or tanks. Aquaponics fruits and vegetables grow in greenhouse in vertical and horizontal grow systems, while fish are grown in the tanks. Water flows between all plants and fish with no soil. The system is run by a computer automation system which operates on data obtained by various sensors and control components that include automated control valves, fish feeders, temperature and water flow measurements. The container can be operated from an established grid or can run off-grid with solar or other renewable energy sources. Part of the water needed for the system can be collected from rainfall. All necessary components except for the water, fish and plant seedlings are delivered in the shipping container. 1. An automated aquaculture system , comprising:at least one fish tank disposed in or as a modular base structure;at least one greenhouse disposed and removably attached atop the at least one base structure;a recirculating water treatment system attached to both the at least one fish tank and the at least one greenhouse including a plurality of valves and pumps;a sensor array disposed within the at least one fish tank, the at least one greenhouse, and the water treatment system; andan automatic monitoring and control system electrically connected to a power system and the sensor array;wherein the automatic monitoring and control system is configured to detect and maintain both a healthy greenhouse environment and a healthy fish tank environment to promote growth and life within each via the sensor array; andwherein the recirculating water treatment system includes a main pump, a sump tank, a sump pump, a rain catchment, a reserve tank and a reserve pump with the water treatment system being in fluid flow association with the fish tank(s) with the fluid flow directed by the pumps and controlled by the valves.2. The system according to claim 1 , wherein the sensor array comprises a ...

Co-Location of a Heat Source Cooling Subsystem and Aquaculture

The present disclosure provides systems for heat source, e.g., data center, cooling and aquaculture. In certain aspects, the systems include a heat source, e.g., data center, having a water cooling subsystem configured to receive cool water and output warm water and an aquaculture center co-located with the heat source, e.g., data center, and configured to receive the warm water. Aspects of the invention also include methods for cooling a heat source, e.g., data center, using a water cooling subsystem and cultivating aquatic organisms with an aquaculture center that is co-located with the heat source, e.g., data center. 1. A system comprising:(a) a heat source comprising a water cooling subsystem configured to receive cool water and output warm water; and(b) an aquaculture center co-located with heat source and comprising a water temperature control subsystem configured to receive the output warm water.2. The system according to claim 1 , wherein the cool water is received from an ocean or sea.3. The system according to claim 1 , wherein the water cooling subsystem comprises a water intake.4. The system according to claim 3 , wherein the water intake is positioned at a depth of 15 m or more in a water source.5. The system according to claim 3 , wherein the water intake is positioned below the photic zone in a water source.6. The system according to claim 1 , further comprising a water discharge for discharging water from the aquaculture center.7. The system according to claim 6 , wherein the water discharge is positioned at a depth of 15 m or more in a body of water.8. The system according to claim 7 , wherein the body of water is the same body of water from which the water cooling subsystem receives the cool water.9. The system according to claim 1 , further comprising a power plant co-located with the data center and the aquaculture center.10. The system according to claim 9 , wherein the power plant is operably connected to both of the data center and the ...

HABITAT LIGHTING ASSEMBLY

A lighting assembly includes a light guide having opposite first and second major surfaces and at least one edge surface extending between the first and second major surfaces, a solid-state light source arranged to emit light into the edge surface of the light guide, and a plurality of integrated optical elements associated with the first major surface to redirect the light emitted by the solid-state light source. The lighting assembly may further include an air circulation device and a heat transfer system configured to transfer heat generated by the solid-state lighting source to a flow of air generated by the air circulation device. The solid-state light source may include light-emitting diodes, laser diodes, and/or organic light emitting diodes configured to produce multiple colors. Also provided is a habitat including the lighting assembly, and related methods. 1. A habitat lighting assembly , comprising:an outer housing comprising an air intake opening, an air discharge opening, and a base with a light-transmissive opening;an air circulation device configured to generate a flow of air into the outer housing through the air intake opening and out of the outer housing through the air discharge opening;a light guide contained in the outer housing and positioned over the light-transmissive opening, the light guide comprising opposite first and second major surfaces and at least one edge surface extending between the first and second major;a solid-state light source contained in the outer housing and arranged to emit light into the edge surface of the light guide;a plurality of integrated optical elements associated with the first major surface and configured to redirect the light emitted by the solid-state light source; anda heat transfer system configured to transfer heat generated by the solid-state lighting source to the flow of air generated by the air circulation device.2. The habitat lighting assembly of claim 1 , wherein the heat transfer system comprises ...

WATER HEATER WITH MOUNTING ERROR PROTECTION

A water heater includes a water heater main unit and a control circuit unit connected in parallel. The control circuit unit includes a circuit board carrying a water permeation safety control device and a tilt angle sensor switch. The water permeation safety control device includes an auto power-off safety device for automatically interrupts electrical current if water is permeated in the control circuit unit. If the water heater is installed in a wrong direction or tilted over a predetermined angle, the angle sensor switch automatically switches off the circuit. 1. A water heater , comprising a water heater main unit adapted for heating the water passing therethrough and a control circuit unit mounted at one lateral side of said water heater main unit in a parallel manner , said control circuit unit comprising a circuit board mounted therein and a heater control circuit installed in said circuit board for controlling the operation of said water heater main unit , said heater control circuit comprising a water permeation safety control device , said water permeation safety control device being a water permeation protection circuit , said water permeation protection circuit comprising a water sensor switch , a comparator circuit electrically connected to said water sensor switch , a normally open AC electrically connected to said comparator circuit , and an auto power-off safety device electrically connected to said comparator circuit.2. The water heater as claimed in claim 1 , wherein said auto power-off safety device comprises a plurality of resistors and a thermal fuse electrically connected to said resistors.3. The water heater as claimed in claim 2 , wherein said resistors and said thermal fuse are integrally sealed on said circuit board.4. The water heater as claimed in claim 1 , wherein said circuit board heater control circuit further comprises a tilt angle sensor switch.5. The water heater as claimed in claim 4 , wherein said tilt angle sensor switch is a ...

AQUARIUM OR TERRARIUM

An aquarium or terrarium () with a gravel and/or sand layer () arranged in the aquarium or terrarium (), at least having a base element () which is arranged at a distance from the base of the aquarium or terrarium (). The at least one base element () is used as a support for the sand and/or gravel layer () in that the sand and/or gravel is rigidly connected to the respective base element (). 176747464.) An aquarium or terrarium () with a gravel or sand layer () arranged in the aquarium or terrarium () and having at least one bottom element () that is arranged spaced apart from a bottom of the aquarium or terrarium () , wherein the at least one bottom element () serves as a carrier for a sand and/or gravel layer () by the sand and/or gravel layer being fixedly connected to the at least one bottom element ().27. The aquarium or terrarium () according to claim 1 , wherein{'b': '4', 'the at least one bottom element () has a bottom side and has spacing or supporting nubs on the bottom side'}or,{'b': 4', '12', '11', '4', '4, 'beneath the bottom element (), a flat nub carrying mat () with nubs () pointing in the direction of the bottom element () is arranged on which the bottom element () rests, or'}{'b': '4', 'the bottom element () has a double-walled structure with selectively placed spacers between the double walls,'}{'b': '4', 'each for forming a collecting space for suctionable foulants, deposited matter and fecal matter which enter into the collecting space through openings in the bottom element ().'}3741234121. The aquarium or terrarium () according to claim 2 , wherein the at least one bottom element () or claim 2 , if present claim 2 , the nub carrying mat () rests on a layer () made of plant substrate arranged in the aquarium or terrarium on the bottom side and the at least one bottom element () and claim 2 , if present claim 2 , the nub carrying mat () are equipped with apertures through which natural plants () are insertable into the plant substrate.4748. The ...

Aquarium Theater Device

An aquarium having a compartment for a holding a video device that is viewable through an aquarium tank for conveniently enhancing the viewing experience of the aquarium. The device includes a filtration system that is concealed from the viewer and that filters the water around the video device without exposing the video device to water or any other elements of the aquarium's habitat.

LIGHTING SYSTEM FOR REPTILE AND REPTILE HABITAT INCLUDING THE SAME

A lighting system includes an ultraviolet (UV) light source including a UVA light source configured to emit UVA light having various wavelengths; and a UVB light source configured to emit UVB light and control a lighting direction of the UVB light towards a target, a sensor including a UVA sensor configured to sense the UVA light, and a control unit configured to control lighting characteristics of the UV light source, in which the lighting characteristics include an intensity of the UVA light. 1. A lighting system , comprising: a UVA light source configured to emit UVA light having various wavelengths; and', 'a UVB light source configured to emit UVB light and control a lighting direction of the UVB light towards a target;, 'an ultraviolet (UV) light source, comprisinga sensor comprising a UVA sensor configured to sense the UVA light; anda control unit configured to control lighting characteristics of the UV light source,wherein the lighting characteristics comprise an intensity of the UVA light.2. The lighting system of claim 1 , wherein the UVA sensor comprises UVA sensor elements configured to sense wavelengths of the UVA light having various wavelengths.3. The lighting system of claim 1 , wherein the lighting characteristics further comprise at least one of a wavelength of emitted light claim 1 , lighting intensity depending on the wavelength claim 1 , lighting spectrum of light claim 1 , and irradiation time.4. The lighting system of claim 1 , further comprising:an input unit configured to input a command to the control unit.5. The lighting system of claim 1 , further comprising:at least one of a visible light source and an infrared (IR) light source configured to be controlled by the control unit.6. The lighting system of claim 1 , wherein the control unit is configured to inform a user of a defect in the UVA light source based on the UVA light sensed by the UVA sensor.7. The lighting system of claim 1 , wherein the control unit is configured to control the ...

Modular Hydroponic System

Accordingly, the present disclosure relates to a modular hydroponic system that may integrate various farming mechanisms. More specifically, the modular hydroponic system may utilize interconnected modules and lines to cycle nutrient-rich water to a range of plant and animal life. The modular hydroponic system may comprise aquaponic modules that may continuously process recycled water and replenish it with nutrients to facilitate growth of the plant life. With a combination of hydroponics and aquaponics, the modular hydroponic system may provide for both a farm and fisheries, allowing for the harvest of produce and fish. The modular aspect of the modular hydroponic system may allow for customization based on resources, spaces, and needs, wherein modules may be combined and substituted. 1. A modular hydroponic system comprising:an interconnected series of hydroponic modules, the series are linked through a recycling irrigation system, the series of hydroponic modules comprising at least: a hydroponic intake pipe that accepts water from the recycling irrigation system,', 'a hydroponic water tank configured to hold water,', 'a tank liner attached to the water tank, wherein the tank liner contains the water within the hydroponic water tank,', 'one or more hydroponic grow beds configured to hold plants, wherein roots of inserted plants are in contact with the water in the hydroponic water tank, a hydroponic outflow pipe that provides water to the recycling irrigation system;, 'a hydroponic tank module comprising an aquaponic intake pipe that accepts water from the recycling irrigation system,', 'at least one aquaponic water tank configured to hold water,', 'a plurality of fish in the at least one aquaponic water tank providing nutrients to the water, wherein the plurality of fish are held for a predefined duration and stage of growth,', 'an aquaponic outflow pipe that provides water to the recycling irrigation system;, 'an aquaponic module comprising an aeroponic intake ...

LIGHT AND HEAT MANAGEMENT SYSTEM FOR INDOOR HORTICULTURE

A system for heat and light management for indoor horticulture is described. More particularly, a system including light sources, a light distribution chamber, and circulating water is described. 1. A light and heat management system for indoor horticulture , the system comprising:a light distribution chamber having a first end and a second end;one or more light sources disposed proximate at least one of the ends of the light distribution chamber;a fluid circulation system including a fluid;wherein at least one of the one or more light sources is thermally coupled to the fluid circulation system.2. The system of claim 1 , further comprising a heat exchanger claim 1 , wherein the heat exchanger is thermally coupled to the fluid circulation system.3. The system of claim 1 , wherein the fluid is water.4. The system of claim 1 , wherein the fluid is a fluorochemical.5. The system of claim 1 , wherein the fluid is a gas.6. The system of claim 1 , wherein thermally coupled means heat is primarily transferred through conduction.7. The system of claim 1 , wherein the light distribution chamber is hollow.8. The system of claim 1 , wherein the light distribution chamber consists essentially of a multilayer optical reflector.9. The system of claim 1 , wherein the light distribution chamber consists essentially of a specular or semi-specular reflector.10. The system of claim 1 , wherein the light distribution chamber consists essentially of a reflector and a light redirecting film. Indoor horticulture introduces challenges relating to heat management as compared to traditional, outdoor horticulture. Light sources are conventionally placed directly above the growing plants.In one aspect, the present disclosure relates to a light and heat management system for indoor horticulture. In particular, the present disclosure relates to a system including a light distribution chamber having a first end and a second end, one or more light sources disposed proximate at least one of the ...

LARVAE COUNTER

A larvae counter comprising a first container for receiving water, eggs of insects and/or larvae, a second container in fluid communication with the first container for receiving water and larvae from the first container, and a larvae counting module in fluid communication with the second container for receiving water and larvae from the second container and counting the larvae. 1. A larvae counter comprising:a first container for receiving water, eggs of insects and/or larvae, the first container having an outlet for dispensing larvae and water from the first container;a second container in fluid communication with the first container for receiving larvae and water from the first container; anda larvae counting module in fluid communication with the second container for receiving larvae from the second container and counting the larvae;wherein the second container comprises a channel in fluid communication with the larvae counting module, the channel comprises a plurality of openings disposed along the longitudinal surface of the channel that is away from the second container and configured for directing larvae from the second container into the larvae counting module; andwherein the larvae counting module comprises a passage for single larva to pass through and a detector positioned proximate the passage for detecting each larva passing through the passage.2. The larvae counter of claim 1 , wherein the channel is configured to direct larva one at a time from the second container into the passage of the larvae counting module.3. The larvae counter of claim 2 , wherein the channel is connected to a water outlet of the second container positioned at the base of the second container claim 2 , the channel includes an outlet valve for regulating flow rate of water through the water outlet of the second container.4. The larvae counter of claim 1 , wherein the channel has a diameter of 3 mm sufficient for a single larva to pass through the channel.5. The larvae counter of ...

AN AQUACULTURE PROCESS FOR THE PRODUCTION OF SALMON EGGS

A process for harvesting fish eggs is provided, in particular fish eggs from Salmon. The process comprises rearing sexually immature salmon in an aquatic environment in stages during which at least the light exposure and time span is adjusted. The rearing includes at least a winter-summer period that comprises a winter life-cycle stage, within which the broodstock is exposed to light that simulates winter light exposure, and a subsequent summer life-cycle stage, within which the broodstock is exposed to light that simulates summer light exposure, wherein the total Accumulated Thermal Unit (ATU) during the winter-summer period is no more than 5000. The inventions also provides salmon eggs that are produced by the disclosed process. 1. A process for the harvesting of fish eggs , comprising:{'i': 'Salmo salar', 'providing a broodstock comprising sexually immature fish from at least one strain;'}rearing the broodstock in an aquatic environment comprising an aqueous medium that is suitable for sustaining life of the broodstock such that it proceeds to maturation, wherein the rearing is performed in life-cycle stages during which at least the light exposure and time span of each life cycle stage is adjusted, wherein the rearing includes at least a winter-summer period that comprises a winter life-cycle stage, within which the broodstock is exposed to light that simulates winter light exposure, and a subsequent summer life-cycle stage, within which the broodstock is exposed to light that simulates summer light exposure, wherein the total Accumulated Thermal Unit (ATU) during the winter-summer period is no more than 5000; andharvesting eggs from the mature fish.2. The process of claim 1 , wherein during the winter-summer period claim 1 , the summer life-cycle stage immediately follows the winter life-cycle stage.3. The process of claim 1 , wherein the rearing comprises at least one further summer life-cycle stage that precedes the winter-summer period.4. The process of ...

AQUACULTURE SYSTEM AND PRODUCING METHOD FOR AQUATIC ORGANISMS

An aquaculture system including an aquaculture tank for holding aquaculture water for conducting biofloc aquaculture therein, and an immobilizing material in the aquaculture tank. The immobilizing material includes a carrier that carries nitrifying bacteria. 1. An aquaculture system , comprising:an aquaculture tank configured to hold aquaculture water for conducting biofloc aquaculture therein; andan immobilizing material in the aquaculture tank,wherein the immobilizing material includes a carrier configured to carry nitrifying bacteria.2. The aquaculture system according to claim 1 , wherein the carrier comprises a foamed carrier.3. The aquaculture system according to claim 1 , wherein the immobilizing material is packed in a container having water permeability.4. The aquaculture system according to claim 3 , wherein the aquaculture tank includes an air injector configured to circulate a water flow in the aquaculture tank claim 3 , and an aeration device configured to discharge aquaculture water and mix the aquaculture water with air claim 3 , andthe container is positioned downstream of the air injector and/or the aeration device.5. The aquaculture system according to claim 1 , wherein the aquaculture tank includes at least one of a paddlewheel claim 1 , a feeding machine claim 1 , and a heat insulation material.6. The aquaculture system according to claim 1 , wherein the aquaculture tank is configured such that the aquaculture tank is installed on land.7. A method for producing an aquatic organism claim 1 , comprising:{'claim-ref': {'@idref': 'CLM-00001', 'claim 1'}, 'performing aquaculture of the aquatic organism in the aquaculture system of .'}8. The method according to claim 7 , wherein the aquatic organism is a marine organism.9. The method according to claim 8 , wherein the marine product is a crustacean.10. The method according to claim 9 , wherein the crustacean is the order Decapoda.11. The method according to claim 10 , wherein the order Decapoda is the ...

AQUACULTURE SYSTEM

An aquaculture system including an aquaculture tank for holding aquaculture water for culturing an aquatic organism, a thermal insulation house that covers the aquaculture tank, an insulation positioned on at least part of a region surrounding the aquaculture tank, and a temperature adjuster that adjusts a temperature inside the thermal insulation house and/or a temperature of the aquaculture water in the aquaculture tank. 1. An aquaculture system , comprising:an aquaculture tank configured to hold aquaculture water for culturing an aquatic organism;a thermal insulation house configured to cover the aquaculture tank;an insulation positioned on at least part of a region surrounding the aquaculture tank; anda temperature adjuster configured to adjust a temperature inside the thermal insulation house and/or a temperature of the aquaculture water in the aquaculture tank.2. The aquaculture system according to claim 1 , wherein the aquaculture tank has an endless stream passage that allows at least part of the aquaculture water to circulate while flowing in a horizontal direction.3. The aquaculture system according to claim 1 , wherein the aquaculture tank has an inner wall surface claim 1 , and at least part of a submerged portion of the inner wall surface is inclined to form a descending slope toward a bottom surface of the aquaculture tank.4. The aquaculture system according to claim 2 , wherein the aquaculture tank has a partition wall vertically placed therein claim 2 , and the partition wall is positioned such that an end portion of the partition wall in the horizontal direction is distanced from the inner wall surface of the aquaculture tank toward an inner side of the aquaculture tank claim 2 , and that the endless stream passage is formed around the partition wall.5. The aquaculture system according to claim 3 , wherein the inner wall surface of the aquaculture tank has an inclination angle of 40 degrees to 70 degrees with respect to a horizontal plane.6. The ...

SYSTEM AND METHOD FOR PASSIVE SOLAR HOUSES, BUILDINGS AND SKYSCRAPERS WITH INTEGRATED AQUAPONICS, GREENHOUSE AND MUSHROOM CULTIVATION

An insulated passive house, building, or skyscrapers system and method with integrated aquaponics, greenhouse, and mushroom cultivation, includes a glazing on a sun facing side at an angle to maximize winter sunlight, and housing a fish tank; a plant growing area; a mushroom growing area; a shop, apartment or office area; a water wall thermal mass that divides the plant growing area from the mushroom growing and the shop, apartment or office areas, and the fish tank; and a natural air ventilation (NAV) system that provides misted air to the mushroom growing and the shop, apartment or office areas, and the fish tank from O2 generated by the plant growing area, and CO2 generated by the mushroom growing and the shop, apartment or office areas, and the fish tank to the plant growing area. 1. An insulated passive solar house , building or skyscraper system with integrated aquaponics , greenhouse , and mushroom cultivation , comprising:an insulated passive solar house, building or skyscraper with a glazing on a sun facing side at an angle to maximize winter sunlight, and housing:a fish tank housed within the passive solar house, building or skyscraper;a plant growing area housed within the passive solar house, building or skyscraper;a mushroom growing area housed within the passive solar house, building or skyscraper;a shop, apartment or office area housed within the passive solar house, building or skyscraper;a water wall thermal mass housed within the passive solar house, building or skyscraper; anda natural air ventilation system housed within the passive solar house, building or skyscraper,wherein the water wall is disposed between the plant growing area, and the mushroom growing area, the fish tank, and the shop, apartment or office area,wherein the natural air ventilation system is configured to provide misted air into the mushroom growing area, the fish tank, and the shop, apartment or office area, andwherein O2 generated by the plant growing area is received by ...

AQUACULTURE SYSTEMS AND METHODS

An aquaculture system can include stacked growth trays. Animals, such as shrimp, can be transferred between the growth trays for different stages of growth. Waste water can be removed from the growth trays and can be processed by a water treatment system. Treated water can be returned to the growth trays. A valve in a first configuration can permit water to circulate through the growth tray, while impeding the animals from exiting the growth tray. In a second configuration, the valve can permit the animals to exit the growth tray, such as for transition to a subsequent growth tray. A sweeper system can be used for cleaning and/or mixing the water in the growth tray, and/or for pushing the animals out of the growth tray during a transition. 1. A shrimp aquaculture system comprising: a first growth tray;', 'a second growth tray;', 'a third growth tray;', 'a fourth growth tray;', 'a fifth growth tray;', 'a sixth growth tray; and', 'a seventh growth tray;, 'a plurality of growth trays in a stacked configuration, the plurality of growth trays comprisinga drainage tray positioned below the plurality of growth trays, wherein water drains out of the plurality of growth trays and into the drainage tray; anda water treatment system configured to treat water received from the drainage tray and to deliver treated water to the plurality of growth trays; a first configuration to drain water out of the first growth tray and into the drainage tray while impeding shrimp from exiting the first growth tray;', 'a second configuration to transfer water and shrimp from the first growth tray to the second growth tray; and', 'a third configuration to transfer water and shrimp from the first growth tray to the third growth tray;, 'wherein the first growth tray has a first configuration to drain water out of the second growth tray and into the drainage tray while impeding shrimp from exiting the second growth tray;', 'a second configuration to transfer water and shrimp from the second growth ...

一种智能可视化集装箱养鱼装置

本发明公开了一种智能可视化集装箱养鱼装置，包括外集装箱，外集装箱内部的背面固定连接有调温层，外集装箱底端的表面均匀固定连接有陶瓷增氧棒，外集装箱内部右侧的底端固定连接有排污引槽，排污引槽内部靠近底端的两侧固定连接有下除污盖板，限制滑块位于内限制轨道外部的一端固定连接有除污盖板，空气压缩泵的输出端连通有曝气管，曝气管位于外集装箱内部的右端连通有纳米曝气喷孔，本发明涉及鱼类养殖技术领域。该智能可视化集装箱养鱼装置，达到了实现鱼类养殖环境的智能化操作，避免鱼类受环境影响出现大面积死亡现象，降低劳动力，提高鱼类养殖的可控性，为鱼类提供最适环境，增加鱼产量的目的。

해수조용 정수 시스템

본 발명은 해수조용 정수 시스템에 관한 것으로서, 활어가 수용되는 활어조(10); 활어조(10)에서 배출되는 해수를 여과 및 정수하는 여과정수조(20); 여과정수조(20)에서 정수된 해수를 공급받아 저장하고, 해수의 저장 과정에서 해수를 활어조(10)에 자연 낙하시켜 폭기시키는 침전저수조(30); 를 포함한다. 본 발명에 따르면, 해수조에서 바닷물고기를 보관하거나 양식할 때 물고기의 배설물 및 잔존먹이로 인해 오염된 해수를 여과수단(201a)에 의한 정화작용 및 미생물에 의한 자정작용을 통해 효과적으로 정수함과 동시에 미생물의 안정적인 번식 환경을 제공하여 미생물에 의한 자정작용을 장기간 안정적으로 유지할 수 있는 효과가 있다.

热递送系统和方法

一种用于农业应用的热递送系统，该系统包括：具有交替的绝热段和传热段的管道，所述管道被构造成具有延伸穿过交替的绝热段和传热段的流体流动路径；以及流体推进装置，其构造成推动热容纳流体在所述流体流动路径内的流动。

Fish culture and mushroom cultivation facilities using sunlight

본 발명은, 농지의 양식장 상에 버섯 재배사 및 태양광 집열판을 설치하여 어류 양식은 물론 버섯 재배를 효율적으로 행할 수 있도록 구성한 태양광을 이용한 어류 양식 및 버섯 재배설비에 관한 것이다. 본 발명은, 어류 양식이 가능한 수조를 포함하여 이 수조의 상단부에 가설되는 버섯 재배사 및 이 버섯 재배사의 내부 환경을 컨트롤러에 의해 제어하기 위한 태양광 수집부 및 가동부로 이루어진다. 상기 수조는 컨트롤러의 가동시에 지하수를 순환시킬 수 있도록 구성됨과 동시에 기초받침들을 개재하여 지주가 수직으로 배설되고, 상기 버섯 재배사는 기초받침을 포함한 외곽 측벽 상에 작업자의 출입이 가능하도록 수평으로 배열되는 이동통로를 구비하며, 지주를 중심으로 양측에 가설되는 난간을 개재하여 버섯 숙주가 함침된 생육목들이 경사져 배치되고, 상기 태양광 수집부는 지주의 선단에 설치된 경사 프레임 상에 배설되는 태양전지모듈 및 이들 태양전지모듈의 사이에 차광막이 탈,부착 가능하도록 설치되며, 상기 가동부는 수조 및 버섯 재배사 내의 실내 환경을 동시에 제어할 수 있도록 구성된다. The present invention relates to a fish farming and mushroom cultivation facility using sunlight configured to efficiently cultivate not only fish but also mushroom cultivation by installing a mushroom cultivation company and a solar heat collecting plate on a farmland farmland. The present invention comprises a mushroom cultivation cultivation house installed at the upper end of the fish cultivation tank, including a fish cultivation tank, and a solar light collection unit and a movable unit for controlling the internal environment of the mushroom cultivation house by a controller. The water tank is configured to circulate groundwater when the controller is operated, and at the same time, the posts are vertically disposed through the foundation supports, and the mushroom cultivation houses are arranged horizontally so that workers can enter and exit on the outer side wall including the foundation support. A solar cell module provided with a moving path that is installed on the inclined frame installed at the tip of the post, and the growth trees impregnated with mushroom hosts are arranged in an inclined manner through the handrails installed on both sides of the post. And a light-shielding film is installed between the solar cell modules so as to be detachable and attachable, and the movable unit is configured to simultaneously control the indoor environment in the water tank and the mushroom cultivation house.

The method of northern area kind hippocampus overwintering culture a kind of and kind hippocampus survive the winter RAS systems

本发明为线纹海马种海马在北方地区的越冬培育提供方法，通过对越冬种海马的挑选、种海马越冬RAS系统的构建、种海马越冬密度的控制、种海马越冬饵料的强化四个方面，来满足线纹海马对各种越冬条件的要求，减少线纹海马在越冬期间因发病或环境不适造成的死亡，使种海马在北方地区成功越冬，最终为翌年线纹海马的人工育苗和养殖提供健康优质的种海马。此方法能有效解决目前北方地区线纹海马种海马越冬难题，为线纹海马在北方地区形成规模化养殖提供优质种海马。

A hydroponic machine

본 발명은 수경재배용으로 선택한 특용작물을 재배하는 수경재배기에 관한 것으로, 분수함, 화분걸이, 저수함을 갖춘 수경재배기에 있어서, 전기히터(21)를 저수함(6')에 설치하여 영약액의 온도조절과 수족관(18)내의 온도조절이 가능하도록하고, 분수함(6)의 상부에는 물방우리 맺히는 물방울관(22)를 설치하여 이끼류 또한 식재가능하도록 함을 특징으로 하는 수경재배기. The present invention relates to a hydroponic cultivator for growing a special crop selected for hydroponic cultivation, in a hydroponic cultivator equipped with a fountain box, a planter hanger, and a water reservoir, the electric heater 21 is installed in the reservoir (6 ') and the medicinal solution. Hydroponic cultivation is possible to control the temperature and the temperature in the aquarium (18), and to install the water drop tube 22 forming the water droplets on the upper portion of the fountain (6).

At-home cultivation and breeding device and system

재택 재배 및 사육 장치 및 시스템이 개시된다. 본 발명의 일 실시예에 따른 재택 재배 및 사육 장치는, 케이스의 내부공간에 식물 재배를 위한 재배지가 마련되고, 상면 하부에 LED 및 수분 공급 파이프가 설치되며, 상기 내부공간의 온도를 조절하는 온도 조절부와 상기 내부공간의 상태를 센싱하는 재배실 센싱부를 포함하는 상부 재배부; 어류를 사육하기 위한 어항의 내부에 물을 공급하기 위한 물 펌프와, 상기 어항 내부의 물을 히팅하기 위한 수중 히터와, 상기 어항 내부의 상태를 센싱하는 어항 센싱부를 포함하는 하부 어항부를 포함하되, 상기 수분 공급 파이프는 상기 물 펌프에 연결되어 물을 공급받고, 상기 온도 조절부는 상기 수중 히터와 연결되어 열을 공급받을 수 있다. Home grown and breeding devices and systems are disclosed. Home cultivation and breeding apparatus according to an embodiment of the present invention, the planting site for plant cultivation is provided in the inner space of the case, the LED and the water supply pipe is installed on the lower surface, the temperature to control the temperature of the inner space An upper cultivation unit including a cultivation room sensing unit for sensing a state of the control unit and the internal space; A lower fishbowl including a water pump for supplying water to the inside of the fishbowl for raising fish, an underwater heater for heating the water in the fishbowl, and a fishbowl sensing unit sensing the state of the fishbowl, The water supply pipe may be connected to the water pump to receive water, and the temperature controller may be connected to the underwater heater to receive heat.

Water Supply System for Fish Facility with Water Temperature Control and Virus Sterilization

The present invention relates to a water supply system for fish farming facility supply, capable of controlling water temperature and sterilizing virus, which comprises: a raw water inlet pipe; a virus sterilizer; a filtering device; a water tank; a machinery chamber, and an underground container. According to the present invention, a growing environment of a fish can be optimized.

Maintenance device of aquarium temperature using radiation heat of cold and hot water of water purifier

본 발명은 수족관의 수온을 유지시키는 냉각장치 및 가열장치를 별도로 설치하지 않고, 정수기에 구비된 냉각장치 및 가열장치와 연계하여 수족관 내의 물을 냉각 또는 가열 처리될 수 있도록 구성하며, 수족관 내의 온도가 일정 온도를 유지하면 별도의 순환라인을 설치하지 않고, 하나의 공급밸브를 통해 정수기의 냉온수 복사열을 거치지 않고, 수족관의 물이 직접 공급되는 방식으로 순환되게 함으로써, 생산비를 절감하고, 공간 활용도를 향상시키도록 한 정수기의 냉온수 복사열을 이용한 수족관 온도 유지 장치에 관한 것이다. 본 발명은 수족관 내의 수온을 감지하여 제어수단으로 신호를 전송하는 감지수단; 수족관 내의 물이 유입되어 수족관 내의 물을 직접 순환 공급하거나 정수기의 냉수장치 또는 가열장치에 형성된 냉각수단 또는 가열수단으로 공급되게 제어수단의 제어신호를 인가받아 개폐 작동되는 공급밸브; 정수기의 냉각장치에 결합되어 공급밸브를 통해 배출된 수족관의 물이 열교환을 통해 냉각 처리되는 냉각수단; 정수기의 가열장치에 결합되어 공급밸브를 통해 배출된 수족관의 물이 열교환을 통해 가열 처리되는 가열수단; 수족관 내부의 물이 공급밸브를 통과되게 하고, 상기 공급밸브를 통해 수족관 내부로 다시 순환되게 하거나 냉각수단 또는 가열수단을 통해 냉각 또는 가열 처리된 물을 다시 수족관 내부로 공급되게 작동되는 순환펌프; 수족관 내에 형성된 감지수단을 통해 수족관 내의 수온이 기설정된 일정 온도를 유지하는지 또는 기설정된 온도 범위를 경과하는 지를 판단한 후, 공급밸브에 제어신호를 인가하여 공급밸브를 개폐 작동시켜 수족관의 물이 직접 순환 공급되게 제어하고, 정수기 내에 설치된 냉각수단 또는 가열수단으로 수족관의 물을 공급하여 냉각 또는 가열 처리된 물을 수족관 내부로 공급되게 제어하는 제어수단;으로 구성되는 정수기의 냉온수 복사열을 이용한 수족관 온도 유지 장치에 관한 것이다.

Water purifying fish tank heater

本发明涉及一种具有净水功能的鱼缸加热器。市场上销售的玻璃管加热棒，其结构是将电热丝缠绕在陶瓷骨架上，再放在玻璃管中，用石棉层托垫，用石英沙填实；存在产品故障率高，使用寿命短等问题。本发明的目的是研制一种专用于具有净水功能的鱼缸加热器。结构是机壳内装配加热组件和加热控制组件组成，加热控制组件是由安装座(6)上固定的电路板(PCB板)(11)、温度传感器(13)、温度调节杆(3)等组成，加热组件就是晶瓷厚膜发热器件(KMCH)电热基片加热片(14)。效果是实现了安全可靠、使用寿命长，体积小，重量轻，结构简单，热曲线平坦稳定，热交换效率高，且具有净化水质功能的鱼缸加热器件及鱼缸加热器。

Cultivation structure of plants using reflectors

본 발명은 반사경을 이용한 식물의 재배구조에 관한 것으로, 남향으로 경사지게 설치되는 태양광 모듈의 저면에 분리 가능한 방한, 방온의 벽체로 이루어진 식물 생산 공장을 계단식으로 설치하고 태양광 모듈의 남쪽 하단에 확산 렌즈를 설치하여 확산 투시되는 빛이 열은 차단하면서 빛만 투과하는 투광판을 통과하여 북쪽의 절반을 비추도록 하고, 열은 차단하면서 빛만 투과하는 투광판의 북쪽 상단에 확산 반사경을 설치하여 확산 반사되는 빛이 남쪽의 절반을 비추도록 하여 식물 생산 공장의 내부에 빛이 고루 비추도록 함으로써 계절에 관계없이 식물을 재배할 수 있도록 하고, 상기의 확산 렌즈와 확산 반사경에 경사각 조절장치를 설치하여 계절에 따라 변화하는 태양의 기울기에 따라 확산 렌즈와 확산 반사경의 기울기를 변화시키면서 보다 많은 빛이 식물 생산 공장에 비추도록 하고, 상기 확산 렌즈와 확산 반사경에 회전각 조절장치를 설치하여 하루 중의 태양의 이동에 따라 확산 렌즈와 확산 반사경의 회전각을 변화시키면서 보다 많은 빛이 식물 생산 공장에 비추도록 구성한 것이다.

Seawater fish circulating water culture system and culture method

本发明公开了海水鱼循环水养殖系统及养殖方法，包括鱼塘，鱼塘的一侧设置有过滤系统，过滤系统的底部设置有生化反应系统，生化反应系统的一侧设置有消毒杀菌系统，消毒杀菌系统的一侧设置有温控监测系统，鱼塘的一侧设置有储水保温箱，储水保温箱的内部固定连接有阻隔板，阻隔板的顶部开设有出水堰，储水保温箱远离鱼塘的一侧贯穿设置有进水管；该海水鱼循环水养殖系统及养殖方法通过设置弧形筛，可以达到直接将循环水内部的固态杂质去除的效果；通过设置的温度监测器、温控仪与加热器，能够使得循环水的温度与鱼塘内部的温度一致，通过设置的安装板与螺纹孔，能够更好地更换紫外线消毒灯。

A kind of temporary shellfish culture system and method

本发明提供一种贝类暂养系统，该系统包括暂养池、微滤机和地源热泵。暂养池养殖贝类一段时间后，将养殖水通过第一出水口排出至第一水泵。第一水泵将养殖水排入微滤机中，以便于微滤机处理养殖水。微滤机将养殖水中的微小杂质以及粪便等截留，并将处理后干净的养殖水送入地源热泵中。地源热泵经过与大地的热交换后重新将养殖水排入暂养池中。养殖水经过地源热泵的过程中，通过地源热泵控制养殖水温度，使得养殖水温度较低，且水温接近于低温保活运输时的温度。由于贝类所处的养殖温度与低温保活运输时的温度较近，因而贝类能够适应低温保活运输过程中的温度，进而贝类在到达目的地后仍然处于存活状态，且存活率较高。

Filtration apparatus for aquaponics and aquaponics system using same

본 발명은, 복수 개의 하부 서포터에 지지되고, 상단부에 원수(오수)가 도입되는 입수구 및 하단부에 여과 및 정화된 물이 배출되는 출수구를 포함하는 여과탱크; 상기 여과탱크 내측 상부에서 일정간격으로 하부 방향으로 이격되어 위치되고, 복수 개의 타공이 형성된 상부 타공판; 상기 입수구를 통하여 상기 상부 타공판과 연결되고, 원수를 입수시키는 절곡된 입수관; 상기 여과탱크 내측 하부에서 일정간격으로 상부 방향으로 이격되어 위치되고, 복수 개의 타공이 형성된 하부 타공판; 상기 하부 타공판의 중앙을 관통하여 상기 출수구와 연결되고, 여과 및 정화된 물이 배출되는 절곡된 출수관; 상기 하부 타공판의 외주면에서부터 나선형으로 감겨 일정 높이로 적층된 열교환 나선관, 상기 열교환 나선관은, 열교환 매체가 순환됨; 상기 하부 타공판 상에 배치된 에어공급관, 상기 에어공급관은, 상기 열교환 나선관의 내주연 영역 내에서 상기 하부 타공판의 중심부에서부터 회오리 형상으로 회전하는 방식으로 배치됨; 상기 에어 공급관 상에 일정 간격으로 배치되고, 에어를 분사하는 복수 개의 에어노즐; 및 상기 하부 타공판 상에서부터 상기 출수구 높이까지 충진된 복수 개의 바이오 헬릭스 여재; 를 포함하는, 수온조절이 가능한, 아쿠아포닉스용 바이오헬릭스 여과장치 및 이를 포함하는 아쿠아포닉스 시스템에 관한 것이다. The present invention is supported by a plurality of lower supporters, a filtration tank including an inlet through which raw water (sewage) is introduced at an upper end and an outlet through which filtered and purified water is discharged at a lower end; An upper perforated plate spaced from an upper portion of the filtration tank in a lower direction at regular intervals, and having a plurality of perforations formed therein; A bent inlet pipe connected to the upper perforated plate through the inlet port and for receiving raw water; A lower perforated plate located at a predetermined interval in the upper direction from a lower portion of the filtration tank and having a plurality of perforated holes formed thereon; A bent water outlet pipe passing through the center of the lower perforated plate and connected to the outlet, and through which filtered and purified water is discharged; A heat exchange spiral tube spirally wound from an outer circumferential surface of the lower perforated plate and stacked to a predetermined height, wherein the heat exchange spiral tube is circulated through a heat exchange medium; An air supply pipe disposed on the lower perforated plate, the air supply pipe being arranged in a manner of rotating in a tornado shape from the center of the lower perforated plate within an ...

Filtration apparatus for aquaponics and aquaponics system using same

본 발명은, 복수 개의 하부 서포터에 지지되고, 상단부에 원수(오수)가 도입되는 입수구 및 하단부에 여과 및 정화된 물이 배출되는 출수구를 포함하는 여과탱크; 상기 여과탱크 내측 상부에서 일정간격으로 하부 방향으로 이격되어 위치되고, 복수 개의 타공이 형성된 상부 타공판; 상기 입수구를 통하여 상기 상부 타공판과 연결되고, 원수를 입수시키는 절곡된 입수관; 상기 여과탱크 내측 하부에서 일정간격으로 상부 방향으로 이격되어 위치되고, 복수 개의 타공이 형성된 하부 타공판; 상기 하부 타공판의 중앙을 관통하여 상기 출수구와 연결되고, 여과 및 정화된 물이 배출되는 절곡된 출수관; 상기 하부 타공판의 외주면에서부터 나선형으로 감겨 일정 높이로 적층된 열교환 나선관, 상기 열교환 나선관은, 열교환 매체가 순환됨; 상기 하부 타공관 상에 배치된 에어공급관, 상기 에어공급관은, 상기 열교환 나선관의 내주연 영역 내에서 상기 하부 타공판의 중심부에서부터 회오리 형상으로 회전하는 방식으로 배치됨; 상기 에어 공급관 상에 일정 간격으로 배치되고, 에어를 분사하는 복수 개의 에어노즐; 및 상기 하부 타공판 상에서부터 상기 출수구 높이까지 충진된 복수 개의 바이오 헬릭스 여재; 를 포함하는, 수온조절이 가능한, 아쿠아포닉스용 바이오헬릭스 여과장치 및 이를 포함하는 아쿠아포닉스 시스템에 관한 것이다.

Circulating seawer cultivating system based on warmhouse booth

本发明涉及一种基于温室大棚的循环海水养殖系统，包括温室养殖大棚、养殖模块、水处理模块和环境在线监测系统，温室养殖大棚为间隔的双层结构，温室养殖大棚双层结构之间设雾化喷头，养殖模块和水处理模块设于大棚内，沉淀池与养殖模块排水管相连，沉淀池、生物填料池、泡沫分离器、过滤器和人工湿地依次相连且过滤器和人工湿地与海水养殖池相连形成海水循环处理系统，环境在线监测系统包括控制主机和温度、pH、溶氧量、盐度、水位五种传感器。本发明解决冬季大棚升温效率低和换水时热量损失大的问题，解决了夏季大棚内温度过高的问题，能够营造适宜养殖环境，扩展养殖周期，提高养殖对象生长速度，实现海水养殖温室大棚全年的稳定运行。

Water quality control method for artificially breeding Changjiang river finless porpoise

本发明公开了一种人工养殖长江江豚的水质调控方法。首先建立由循环水泵、过滤砂缸、臭氧发生器、消毒剂添加系统和淡水蛋白分离器设备组成的维生系统，之后通过维生系统建立人工饲养池的水循环，通过收集人工饲养池饲养长江江豚的水质标准，确定水质标准的目标参数值及各项参数运行波动范围；根据监测设备监测的实际水质参数，科学利用这些设备添加消毒剂、絮凝剂相互配合达到调节和控制人工养殖长江江豚生活水体水质的目的。本发明通过对水质的调整使得人工饲养池内水体完全达到养殖长江江豚的标准，水质可控并且相对稳定，可有效避免水质调整过程中消毒剂添加等各种人为操作对长江江豚的影响。

Brush unit for vacuum cleaner

FIELD: mechanical unit. SUBSTANCE: brush unit has casing, cover connected with casing upper part so as to form suction channel and turbine chamber, turbine wheel positioned within turbine chamber, and brush drum driven into rotation by rotational force transmitted from turbine wheel. Dividing member is detachably positioned within casing for defining of suction channel and turbine wheel chamber, which are separated from one another. Turbine wheel is driven for rotation by air drawn through air suction opening separated from filth suction opening. Turbine has base and wheel fins protruding from base and radially positioned on its upper surface with the exception of its center. EFFECT: provision for preventing of turbine wheel from contamination with filth regardless of size and amount of filth, and increased efficiency due to sufficient extent of transmitting of air kinetic energy to turbine. 8 cl, 6 dwg ÐÎÑÑÈÉÑÊÀß ÔÅÄÅÐÀÖÈß (19) RU (11) 2 308 213 (13) C2 (51) ÌÏÊ A47L 9/04 (2006.01) ÔÅÄÅÐÀËÜÍÀß ÑËÓÆÁÀ ÏÎ ÈÍÒÅËËÅÊÒÓÀËÜÍÎÉ ÑÎÁÑÒÂÅÍÍÎÑÒÈ, ÏÀÒÅÍÒÀÌ È ÒÎÂÀÐÍÛÌ ÇÍÀÊÀÌ (12) ÎÏÈÑÀÍÈÅ ÈÇÎÁÐÅÒÅÍÈß Ê ÏÀÒÅÍÒÓ (72) Àâòîð(û): ÊÈÌ Õóà-äæóíã (KR), ÞÐÀÒÀÍÈ Õèðîþêè (KR) (21), (22) Çà âêà: 2005130312/12, 30.09.2005 (24) Äàòà íà÷àëà îòñ÷åòà ñðîêà äåéñòâè ïàòåíòà: 30.09.2005 (73) Ïàòåíòîîáëàäàòåëü(è): Ñàìñóíã Ãóàíãäæó Ýëåêòðîíèêñ Êî., Ëòä. (KR) R U (30) Êîíâåíöèîííûé ïðèîðèòåò: 23.02.2005 (ïï.1-8) KR 10-2005-0015074 (43) Äàòà ïóáëèêàöèè çà âêè: 10.04.2007 (45) Îïóáëèêîâàíî: 20.10.2007 Áþë. ¹ 29 2 3 0 8 2 1 3 (56) Ñïèñîê äîêóìåíòîâ, öèòèðîâàííûõ â îò÷åòå î ïîèñêå: JP 11009523 À, 19.01.1999. JP 10127542 À, 19.05.1998. JP 11009524 À, 19.01.1999. ÑÀ 1077206 À, 13.05.1980. RU 2241367 Ñ2, 10.12.2004. 2 3 0 8 2 1 3 R U (54) ÓÇÅË ÙÅÒÊÈ ÄËß ÏÛËÅÑÎÑÀ (57) Ðåôåðàò: Äàííîå èçîáðåòåíèå îòíîñèòñ ê óçëó ùåòêè äë ïûëåñîñà. Òåõíè÷åñêèì ðåçóëüòàòîì çà âëåííîãî èçîáðåòåíè âë åòñ ñîçäàíèå óçëà ùåòêè, â êîòîðîì ïðåäîòâðàùåíî çàñîðåíèå òóðáèíû ãð çüþ, íåçàâèñèìî îò ðàçìåðà è êîëè÷åñòâà ãð çè, è â êîòîðîì ...

Multipurpose fish farm

The present invention relates to a multipurpose fish farm with an improved structure, which includes a breeding facility for breeding insects in the upper part of an indoor water tank-type fish farm for breeding fish and thus, naturally regulates the temperature and humidity of the inside of the fish farm by using the water tank without any additional temperature and humidity regulator required for insect breeding; utilizes excretion of fish therein as nutrients for water culture; provides a portion of water cultured plants as a feed required for the insect breeding; and provides a portion of the insects bred in the insect breeding facility as a feed for fish. In addition, the multipurpose fish farm comprises: a fish breeding room in which a water tank is placed for breeding fish in an indoor space; a fish breeding water supply unit which supplies breeding water to the inside of the water tank; a purification means which purifies water drained from the water tank; a water temperature heating unit which maintains the temperature of the breeding water filled inside the water tank within the range of 25-30°C in order to maintain the indoor temperature of the fish breeding room, the breeding water temperature necessary for breeding fish, and the indoor temperature of a plant culturing room for culturing the plant in water within the appropriate range; an insect breeding board which is placed in the upper part of the indoor fish breeding room and has an open upper part thereof in order to flow indoor air heated by the temperature of the water tank; and a plant culturing room which is placed in the external side of the fish breeding room in order to block the inflow of air of the fish breeding room.

A kind of cabinet recirculation system and the fish culture box using the system

本发明属于养殖设备技术领域，涉及一种箱体循环养殖系统及应用该系统的养鱼箱，包括养殖系统及应用养殖系统的养鱼箱，养鱼箱左侧设有安装该养殖系统的设备控制箱，所述的设备控制箱内至少安装有过滤系统、CB水发生器、恒温机、增氧系统、自动投料系统、微生物投放器及沙缸。养鱼箱还与上述的自动投料系统、微生物投放器及沙缸相连通，养鱼箱内的鱼粪和残饵的水体通过上吸水管和下吸水管进入至沙缸和过滤系统进行过滤处理，处理后的水质通过CB水发生器活化处理，活化后的水质和增氧系统生成的氧气再由恒温机恒温处理，恒温处理完毕后的水质和氧气输送至养鱼箱，以此形成循环养殖系统；该养鱼箱可移动运输，并实现多箱组合模式，适应市场需求。

greenhouse for mariculture and plant cultivation using inner heat

본 발명은 내부 폐열을 활용한 어류 양식 및 작물재배용 온실에 관한 것으로, 온실 내부에 구비되어 어류를 양육하도록 양식수가 채워지는 양식용 수조와, 상기 양식용 수조의 상측에 구비되며 작물을 재배하는 작물재배지와, 상기 온실 내부 상측의 공기를 강제 순환시켜 양식용 수조를 통과시켜 양식수와 열교환을 통해 냉각하는 공기 열교환수단과, 상기 양식용 수조의 양식수와 열매체를 통해 열교환을 일으키는 열교환코일과, 상기 열교환코일에서 온배수와의 열교환 된 열매체를 강제순환하는 순환펌프와, 상기 순환펌프에 의해 순환되는 열매체와 열교환을 통해 온수탱크의 온수를 고온으로 가열하거나 냉수탱크의 냉수를 냉각하는 히트펌프와, 상기 온수탱크의 온수 또는 냉수탱크의 냉수를 상기 양식용 수조의 양식수와 열교환하는 가온코일 또는 냉각코일로 구성되는 것을 특징으로 한다. 본 발명에 따르면, 어류와 작물을 하나의 온실 내부에서 양식 및 재배함으로서 어류 및 식용 작물의 생산성을 높일 수 있을 뿐만 아니라 온실 내부의 폐열을 이용해 어류와 작물의 양육 및 재배에 필요한 온도를 일정하게 유지할 수 있어 온실 내부의 냉난방으로 위한 에너지를 효율적 이용할 수 있다. The present invention relates to a greenhouse for cultivation of fish and crops utilizing internal waste heat, comprising: a water tank for aquaculture which is provided in a greenhouse and filled with aquaculture water so as to raise fish; A heat exchanger coil for forcedly circulating air above the inside of the greenhouse and passing through the aquaculture water tank for cooling through the heat exchange with the aquaculture water, a heat exchanger coil for exchanging heat with the aquarium water of the aqua- A heat pump for heating the hot water of the hot water tank to a high temperature or cooling the cold water of the cold water tank through heat exchange with the heat medium circulated by the circulation pump, A warming coil for heat-exchanging the cold water of the hot water tank or the cold water tank with the aqua- It is characterized by consisting of a cooling coil. According to the present invention, fish and crops can be cultivated and cultivated in a single greenhouse to increase the productivity of fish and edible crops, as well as to maintain a constant temperature for raising and growing fish and crops using waste heat inside the greenhouse It is possible to efficiently use the energy for cooling and heating the inside of the greenhouse.

Seafood temporarily supports water circulating purification system and its seafood and temporarily supports machine

本发明公开了一种海鲜暂养水循环净化系统及其海鲜暂养机，包括养殖水池，所述养殖水池并列布置若干个；所述各个养殖水池的进水口均单独地连通与之相应的制冷水箱，制冷水箱并列布置若干个且与养殖水池数量相应；所述各个养殖水池的出水口均单独地连通与之相应的过滤箱，过滤箱并列布置若干个且与养殖水池数量相应；制冷水箱通入冷媒使养殖水降温，形成多个不同温区冷养殖水，低温养殖水分别输入每个养殖水池中供暂养海鲜，暂养后含杂质和蛋白质养殖水进入过滤箱过滤、降解、排除蛋白质，还原成净水循环利用。养殖水池水温恒温稳定，暂养时间长，实现了多个不同温区养殖海鲜，暂养品种数量多，满足人们消费要求。

A kind of snakeheaded fish recirculating water purification cultivating system

本发明提供一种黑鱼循环水净化养殖系统，包括黑鱼养殖室、反冲洗过滤装置、集污沉淀箱、花白鲢养殖箱、微生物净化装置和紫外线消毒装置，所述黑鱼养殖室的底部设有排水管，所述排水管的末端与所述反冲洗过滤装置连通，所述集污沉淀箱通过反冲排污管与所述反冲洗过滤装置连通，所述花白鲢养殖箱通过输肥管与所述集污沉淀箱的底部连通，所述反冲洗过滤装置的出水口与所述微生物净化装置连通，所述微生物净化装置的出水管与所述紫外线消毒装置的进水口连接，所述紫外线消毒装置的出水口连接回水管。本发明的养殖系统能实现养殖水的循环使用，能节约大量的水资源，用于解决现有技术中黑鱼养殖水循环利用以及废料利用的问题。

System and method for solar greenhouse aquaponics and black soldier fly composter and auto fish feeder

An aquaponics and greenhouse system, includes an insulated solar greenhouse with a glazing on a sun facing side at an angle to maximize winter sunlight, and housing a fish tank housed within the solar greenhouse; a plant growing area housed within the solar greenhouse; a mushroom growing area housed within the solar greenhouse; a water wall thermal mass housed within the solar greenhouse and disposed between the plant growing area and mushroom growing area; and a natural air ventilation system housed within the solar greenhouse and configured to provide misted air into the mushroom growing area. 02 generated by the plant growing area is received by the natural air ventilation system and provided to the mushroom growing area, and C02 generated by the mushroom growing area is provided to the plant growing area.

System and method for passive solar containers with integrated aquaponics, greenhouse and mushroom cultivation

A foldable aquaponics, and greenhouse container system and method, includes an insulated shipping container having foldable insulated roof panel disposed thereover; a foldable glazing on a sun facing side at an angle to maximize winter sunlight attached to the roof panel; a foldable floor panel attached to the container with a foldable vent panel attached thereto connecting to the glazing; foldable side panels attached to sides of the container, glazing and roof panel; a plant growing under the glazing; a mushroom growing area within the container having an integrated water wall thermal mass and disposed between the plant and mushroom growing areas; a fish tank within the container; and a natural air ventilation system within the container under the roof panel to provide CO2 and O2 gas exchange between the mushroom growing area and the plant growing area.

System and method for solar greenhouse fish-vegetable symbiosis and black soldier fly composter and automatic fish feeder

披露了一种鱼菜共生和温室系统，该鱼菜共生和温室系统包括隔热的太阳能温室，该隔热的太阳能温室具有以一定角度位于面向太阳侧上以使冬日太阳光最大化的玻璃窗，并且容纳：鱼槽，该鱼槽位于该太阳能温室内；植物生长区域，该植物生长区域被容纳在该太阳能温室内；菇类生长区域，该菇类生长区域被容纳在该太阳能温室内；水壁热质量块，该水壁热质量块被容纳在该太阳能温室内并设置在该植物生长区域与该菇类生长区域之间；以及自然空气通风系统，该自然空气通风系统被容纳在该太阳能温室内，并被配置成向该菇类生长区域提供雾状空气。由该植物生长区域产生的O2被该自然空气通风系统接收并提供给该菇类生长区域，而由该菇类生长区域产生的CO2被提供给该植物生长区域。

System and method for solar greenhouse fish-vegetable symbiosis and black soldier fly composter and automatic fish feeder

披露了一种鱼菜共生和温室系统，该鱼菜共生和温室系统包括隔热的太阳能温室，该隔热的太阳能温室具有以一定角度位于面向太阳侧上以使冬日太阳光最大化的玻璃窗，并且容纳：鱼槽，该鱼槽位于该太阳能温室内；植物生长区域，该植物生长区域被容纳在该太阳能温室内；菇类生长区域，该菇类生长区域被容纳在该太阳能温室内；水壁热质量块，该水壁热质量块被容纳在该太阳能温室内并设置在该植物生长区域与该菇类生长区域之间；以及自然空气通风系统，该自然空气通风系统被容纳在该太阳能温室内，并被配置成向该菇类生长区域提供雾状空气。由该植物生长区域产生的O2被该自然空气通风系统接收并提供给该菇类生长区域，而由该菇类生长区域产生的CO2被提供给该植物生长区域。