ЗВУКОПОГЛОЩАЮЩАЯ ПЛИТКА

Звукопоглощающая плитка, содержащая внутреннюю часть и обработанную поверхность, в которой обработанная поверхность содержит свободное от формальдегида латексное связующее, свободный от формальдегида эфир целлюлозы выбранный из группы, состоящей из метилцеллюлозы, метилгидроксицеллюлозы, метилгидроксипропилцеллюлозы, гидроксипропилцеллюлозы, карбоксипропилцеллюлозы натрия, гидроксиэтилцеллюлозы или их комбинации, и полимерное производное протеина сои, по меньшей мере, один свободный от формальдегида биоцид. Охарактеризован также способ получения плитки. Технический результат: получение звукопоглощающей плитки с требуемыми эксплуатационными свойствами при высвобождении или эмиссии формальдегида, ниже поддающегося количественному определению предела, составляющего приблизительно 1 мкг/м3. 2 н. и 20 з.п. ф-лы, 1 ил.,1 табл., 1пр.

ЖАРОСТОЙКИЙ ИЗОЛЯЦИОННЫЙ КОМПОЗИТНЫЙ МАТЕРИАЛ И СПОСОБ ЕГО ПОЛУЧЕНИЯ

FIELD: production of composite materials. SUBSTANCE: heat-resistant composite material comprises basic insulating layer, hollow nonporous particles, binding matrix, and heat-reflecting layer that has binder and agent that reflects the infrared radiation. The heat conductivity of the heat reflecting insulating composite material is about 50 mW/m°K or less. The method of production of the heat-resistant insulating composite material is also presented. EFFECT: improved insulation. 15 cl, 3 tbl ÐÎÑÑÈÉÑÊÀß ÔÅÄÅÐÀÖÈß RU (19) (11) 2 303 744 (13) C2 (51) ÌÏÊ F16L 59/02 (2006.01) ÔÅÄÅÐÀËÜÍÀß ÑËÓÆÁÀ ÏÎ ÈÍÒÅËËÅÊÒÓÀËÜÍÎÉ ÑÎÁÑÒÂÅÍÍÎÑÒÈ, ÏÀÒÅÍÒÀÌ È ÒÎÂÀÐÍÛÌ ÇÍÀÊÀÌ (12) ÎÏÈÑÀÍÈÅ ÈÇÎÁÐÅÒÅÍÈß Ê ÏÀÒÅÍÒÓ (21), (22) Çà âêà: 2004136599/06, 15.05.2003 (72) Àâòîð(û): ÔÈËÄ Ðåêñ Äæåéìñ (DE), ØÀÉÄÅÌÀÍÒÅËÜ Áåàòå (DE) (24) Äàòà íà÷àëà îòñ÷åòà ñðîêà äåéñòâè ïàòåíòà: 15.05.2003 (73) Ïàòåíòîîáëàäàòåëü(è): ÊÀÁÎÒ ÊÎÐÏÎÐÅÉØÍ (US) R U (30) Êîíâåíöèîííûé ïðèîðèòåò: 15.05.2002 US 60/380,967 (43) Äàòà ïóáëèêàöèè çà âêè: 27.10.2005 (45) Îïóáëèêîâàíî: 27.07.2007 Áþë. ¹ 21 2 3 0 3 7 4 4 (56) Ñïèñîê äîêóìåíòîâ, öèòèðîâàííûõ â îò÷åòå î ïîèñêå: RU 99123441 A, 11.06.1998. RU 2169131 Ñ2, 20.06.2001. US 5665442 A, 09.09.1997. US 5641584 A, 24.06.1997. US 5631097 A, 20.05.1997. (85) Äàòà ïåðåâîäà çà âêè PCT íà íàöèîíàëüíóþ ôàçó: 15.12.2004 2 3 0 3 7 4 4 R U (87) Ïóáëèêàöè PCT: WO 2004/037533 (06.05.2004) C 2 C 2 (86) Çà âêà PCT: US 03/15530 (15.05.2003) Àäðåñ äë ïåðåïèñêè: 129010, Ìîñêâà, óë. Á.Ñïàññêà , 25, ñòð.3, ÎÎÎ "Þðèäè÷åñêà ôèðìà Ãîðîäèññêèé è Ïàðòíåðû", ïàò.ïîâ. Å.Å.Íàçèíîé, ðåã. ¹ 517 (54) ÆÀÐÎÑÒÎÉÊÈÉ ÈÇÎËßÖÈÎÍÍÛÉ ÊÎÌÏÎÇÈÒÍÛÉ ÌÀÒÅÐÈÀË È ÑÏÎÑÎÁ ÅÃÎ ÏÎËÓ×ÅÍÈß (57) Ðåôåðàò: Æàðîñòîéêèé èçîë öèîííûé êîìïîçèöèîííûé ìàòåðèàë, ñîäåðæàùèé èçîë öèîííûé îñíîâíîé ñëîé, ïîëûå íåïîðèñòûå ÷àñòèöû, ñâ çóþùóþ ìàòðèöó è òåïëîîòðàæàþùèé ñëîé, ñîäåðæàùèé çàùèòíîå ñâ çóþùåå è àãåíò, îòðàæàþùèé èíôðàêðàñíîå èçëó÷åíèå, ïðè÷åì òåïëîïðîâîäíîñòü òåïëîîòðàæàþùåãî èçîë öèîííîãî êîìïîçèòíîãî ìàòåðèàëà ñîñòàâë åò ïðèìåðíî 50 ìÂò/(ì ...

СПОСОБ ПОЛУЧЕНИЯ НАРУЖНОЙ КОНСТРУКЦИИ ЗДАНИЯ

FIELD: construction. SUBSTANCE: method of getting a heat reflecting outdoor construction (1) of the building includes the formation of the outer surface (4) of the building from an insulating layer (11) which is simultaneously a vapour barrier layer (12) and which absorption coefficient is ε>0,6 fixing remote elements (7) to the outer surface (4) of the building, preparation of a support layer (2) containing a layer (3) with a material reflecting heat radiation, fixing the support layer to the first place on the remote elements (7), tensioning manually fixing the support layer (2), fastening the tensioned backing layer (2) to other locations or surfaces of the remote elements (7) so that the backing layer is fully stretched over the remote elements (7) from the sides and parallel to the outer surface (4) of the building. The inner side (5) of the support layer (2) containing the layer with the radiation reflecting material is facing the outer surface (4) of the building, and between the support layer (2) and the outer surface (4) of the building, as well as between the remote elements (7) an air gap (6) is formed. EFFECT: invention allows to reduce heat losses, improve the thermal protection of buildings and improve the efficiency of air conditioning while reducing the use of insulating materials. 7 cl, 4 dwg РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (13) 2 630 836 C2 (51) МПК E04B 1/76 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ОПИСАНИЕ ИЗОБРЕТЕНИЯ К ПАТЕНТУ (21)(22) Заявка: 2014137452, 18.02.2013 (24) Дата начала отсчета срока действия патента: 18.02.2013 (72) Автор(ы): БРАНД Рудольф (DE) (73) Патентообладатель(и): БДПС ИНЖЕНЕРГЕЗЕЛЛЬШАФТ МБХ (DE) Дата регистрации: (56) Список документов, цитированных в отчете о поиске: RU 86630 U1, 10.09.2009. SU Приоритет(ы): (30) Конвенционный приоритет: 17.02.2012 DE 10 2012 101 318.7; 02.04.2012 DE 10 2012 102 862.1 (45) Опубликовано: 13.09.2017 Бюл. № 26 (85) Дата начала рассмотрения заявки PCT на ...

Замковая технология теплоизоляционного материала для бесшовной сварки соединительных замков

FIELD: construction. SUBSTANCE: invention relates to construction industry, in particular to the installation of external and/or internal insulation of various construction sites using Tepofol®, a heat-insulating material. Locking technology of seamless welding of connecting locks of heat-insulating material, the size of which varies from 10 to 250 mm, includes two layers of roll insulation, consisting of non-cross-linked polyethylene foam (non-cross-linked PE foam) and heat-reflecting coating, the surfaces of which are glued together with a heat gun by heating the surfaces to be glued to a temperature of 110–120 °C to achieve an integral, pressure-tight, seamless, heat-insulating web, fully formed from the roll insulation of non-cross-linked PE foam. Connecting locks are cut in two ways: directly during the production process of insulation, becoming in that case an integral element of the finished product, or at the time of installation work on the site when an additional locking connection is required to comply with the installation conditions. EFFECT: invention allows to increase the energy efficiency of the facilities in the subsequent long-term operation, to reduce the labor costs and the costs of carrying out repair and insulation works during the installation of the thermal insulation Tepofol® due to simple and easy technology of installation and welding of locking systems. 4 cl, 1 dwg РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (13) 2 645 190 C1 (51) МПК E04B 1/78 (2006.01) E04B 1/76 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ОПИСАНИЕ ИЗОБРЕТЕНИЯ К ПАТЕНТУ (52) СПК E04B 1/76 (2006.01); E04B 1/7604 (2006.01); E04B 1/762 (2006.01); E04B 2001/7691 (2006.01); E04B 1/78 (2006.01) (21)(22) Заявка: 2016138156, 26.09.2016 26.09.2016 (73) Патентообладатель(и): Тер-Закарян Карапет Арменович (RU) Дата регистрации: 16.02.2018 Приоритет(ы): (22) Дата подачи заявки: 26.09.2016 (45) Опубликовано: 16.02.2018 Бюл. № 5 2 6 4 5 1 9 0 R U (54) Замковая технология ...

АКУСТИЧЕСКАЯ ПАНЕЛЬ, СОДЕРЖАЩАЯ ПЕРЕПЛЕТЕННУЮ ФИКСИРОВАННУЮ МАТРИЦУ ИЗ ЗАТВЕРДЕВШЕГО ГИПСА И СПОСОБ ЕЕ ИЗГОТОВЛЕНИЯ

... 1. Способ непрерывного изготовления акустической панели, включающий этапы, на которых осуществляют получение смеси, включающей воду, вспениватель и обожженный гипс; разлив смеси с образованием непрерывной ленты; удержание ленты в условиях, достаточных для того, чтобы обожженный гипс образовал переплетенную фиксированную матрицу из затвердевшего гипса; нарезание ленты с образованием предшественника влажной акустической панели; и сушка предшественника влажной панели с получением акустической панели, в котором акустическая панель характеризуется значением нормального случайного звукопоглощения, равным по меньшей мере примерно 0,32, в соответствии с модифицированным ASTM E 1050-98. 2. Способ по п.1, в котором используют смесь, включающую целлюлозное волокно. 3. Способ по п.2, в котором целлюлозное волокно представляет собой бумажное волокно. 4. Способ по п.2, в котором количество целлюлозного волокна составляет от примерно 1 до примерно 12 вес.% от твердого содержимого смеси. 5. Способ по п ...

Folienlaminate als Hochbarrierefolien und deren Verwendung in Vakuumisolierpaneelen

VERBESSERTE KOMPAKTE VAKUUMISOLATION

Werkstoff und,insbesondere fuer waerme- und stossisolierende Bauteile,Verpackungen od.dgl. sowie Verfahren zu dessen Herstellung

THERMAL CONTROL MATERIALS

IMPROVEMENTS IN AND RELATING TO PACKAGING

A package for preserving perishable food products such as produce shipped in large quantities on a pallet wherein the invention includes panels formed of honeycomb material covered by aluminum foil panels to provide a stronger and better insulated package.

Membrane and building construction

Insulating foil

An insulating foil comprises a sheet (2,12) with cushions protruding therefrom and provided on one side with an aluminium-containing layer (3,13) for the blocking of (infrared) radiation. This insulating foil is provided with openings (7,17) which are vapour-permeable but liquid-tight. Openings of this type have, for example, dimensions of from 0.05 to 0.1 mm. A foil of this type may be used in all cases where vapour-permeability and water-tightness are important. An example is the insulating of architectural constructions comprising walls or roofs. In such cases, the insulating foil may be attached to the outside of the architectural construction. If a construction of this type is subject to considerable solar irradiation, the reflective layer, which consists of aluminium material or aluminized material, is preferably attached to the outside in order thus to prevent heat irradiation.

Improvements in and relating to liquid impermeable and liquid vapour/gas permeable fabrics

A vapour permeable fabric comprises a first reflective layer laminated to a second filamentous layer for example by calendering. The first reflective layer may comprise a single metallic or reflective foil, a polymeric foil with metallic (eg. aluminium or an alloy thereof) or reflective material applied thereto, or a laminate of multiple reflective foils interspersed with non reflective foils. The reflective layer may be microporous or micro perforated. The filamentous layer may comprise a non woven (eg spun-bonded) or a woven polymeric fabric. Suitable polymers for either layer include polypropylene, polyamides or polyesters. In an alternative embodiment the reflective layer comprises a filamentous layer wherein the filaments are spun from a blend comprising a polymeric material and a reflective material. Said reflective material may be supplied as a masterbatch and may comprise finely ground aluminium (or an alloy thereof) particles in a polymer matrix. The invented fabrics may be used ...

Composite insulation

Thermally insulated wall construction

A thermally insulated wall structure has a framework of spaced studs 2 supporting, on a first side, an outer wall panel 6 and, on a second side, an inner wall surface 10. A layer of insulating sheathing 12 extends continually across the framework in the space between the outer wall panel 6 and the inner wall surface 10. The insulating sheathing may be provided between the stud framing 2 and one of the outer wall panel 6 and the inner wall surface 10, which may be secured to the studs 2 by fixings which pass through the insulating sheathing. The insulating sheathing may be a multi-foil insulant comprising two outer foil surfaces sandwiching a plurality of layers of non-woven textile materials and insulating foils. The outer foil surfaces may be reinforced with mesh. A method of insulating a building with such a wall structure and a surface panel with a layer of insulating material bonded thereto are also disclosed.

Water vapour permeable multi-layer thermal insulation

A water vapour permeable multi-layer thermal insulation 10 includes two water vapour permeable outer layers 16, 18 encapsulating inner air and water vapour permeable layers 14 of insulation material and at least one inner separating layer 12 of an air-open fibrous material. This layer is interleaved with the inner thermal insulation layers 14 and having a mean flow pore size that allows water vapour to move from one side of the at least one inner fibrous separating layer to the other and through the inner insulation layers yet restricts mass movement of air from one side to the other of the at least one inner fibrous separating layer 12 to form a barrier to convection. The multi layer having a moisture vapour transmission rate (MVTR) or at least 1200 g/m2.day and a thermal resistance R of at least 1.40 m2.K/W. The pore size may be in the range 1 to 20 micrometres. The fibres of the fibrous layer may be metallised.

Building industry membrane, and building

Insulation materials

Improvements in and relating to liquid impermeable and liquid vapour/gas permeable fabrics

THERMAL CONTROL MATERIALS

IMPROVEMENTS IN AND RELATING TO PACKAGING

HEATDAMMING SOFT MATERIAL WITH AT LEAST A PERFORATED MAT

ISOLATING ONE, MULTILEVEL COURSE OR MAT

MULTILEVEL INSULATING MATERIAL ELEMENT FOR THE WARMTH AND SOUND ABSORPTION

FOIL LAMINATES AS HIGH BARRIER FOILS AND THEIR USE IN VACUUM ISOLATION PANELS

DAM ELEMENT AND FROM AT LEAST SUCH AN DAM ELEMENT MANUFACTURED LINING

COMPRESS-CASH ISOLATION ELEMENT WITH REDUCED FRICTION

VAKUUMPUTZ, BAU- UND DÄMMSTOFFE AUS EVAKUIERTEN POREN

Die Erfindung stellt Verfahren zur Gewinnung baustellentauglicher hochvakuumhaltender innen verspiegelter geschlossenporiger Bau- und Dämmstoffe, die vor Ort zugeschnitten werden können, bereit. Dazu werden beim Schmelzen Entgasungsprozesse vor vollständiger Entgasung unter Vakuum abgebrochen und das Material zu Vakuumschäumen, Einzelporen (Hohlkugeln), Fasern, Agglomeraten, Putzen oder Platten geformt. Bevorzugt kommt ein zweistufiger Produktionsprozess zum Einsatz, wo zunächst das bekannte Herstellungs- oder Umformungsverfahren (z.B. Glasschmelze) so geführt wird, dass Mikroporen entstehen, diese werden dann im Vakuum expandiert und mit Wellenfeldern (HF/Mikrowelle, Lichtbogen u.a.) sukzessive weiter aufgeheizt bis hin zur theoretischen Minimalwandstärke.

Thermal insulation element

Bei einem Isolationselement zur thermischen Isolation von Räumen umfassend eine Mehrzahl von geschlossenen Zellen, wobei eine erste und eine zweite Gruppe von geschlossenen Zellen von ersten bzw. zweiten Vertiefungen (2,2') in einem ersten bzw. zweiten flächigen Element (1,1') gebildet ist und das erste und das zweite flächige Element (1,1') zwischen den Rändern der Öffnungen (3,3') benachbarter Vertiefungen (2,2') erste bzw. zweite Verbindungsbereiche (31,31') ausbilden, mit welchen jeweils ein die Öffnungen (3,3') einer Vielzahl von ersten Vertiefungen (2) verschließendes flächiges Deckelement (14) an einer Vorderseite des flächigen Elements (1) stoffschlüssig verbunden ist, sind die zweiten Vertiefungen (2') an einer Rückseite des ersten flächigen Elements (1) zwischen den ersten Vertiefungen (2) und die ersten Vertiefungen (2) an einer Rückseite des zweiten flächigen Elements (1') zwischen den zweiten Vertiefungen (2') angeordnet, sodass das zwischen dem ersten (1) und dem zweiten flächigen ...

LAMINAR WÄRMEUND/ODER LÄRMUND/ODER HUMIDITY INSULATING CLAMP

COMPLEX MATERIAL FOR APPLICATION AMONG OTHER THINGS AS THERMAL INSULATION

FEUERSICHERE PUR-VAKUUMDÄMMSTOFFE/PUTZE

The invention relates to methods for obtaining building and insulating materials which are suitable for use on building sites, are inwardly reflective, have a closed-pore structure and can be cut to size in situ. To this purpose, degassing processes are broken off during melting before degassing under vacuum is completed and the material is formed to vacuum foams, single pores (hollow spheres), fibres, agglomerates, coatings or plates. A two-stage production process is preferably used, where the known production or deformation process (e.g. glass melt) is first carried out in such a manner that micropores are produced which are subsequently expanded in the vacuum and are successively heated with wave fields (HF/microwave, arc, etc) until the theoretical minimum wall thickness is reached. Preferably, plasmas are produced in the interior of the pores by clocked waves (heating of pores from the inside). Due to the rapid alternation of temperature increase and pressure increase, induced by ...

MULTILEVEL OUTER WALL LINING PLATE

IMPROVED COMPACT ONE VACUUM ISOLATION

WÄRMEDÄMMPLATTE

TIFF 00000005.TIF 294 208 ...

Wärmedämmplatte

The insulation board has reflector plate (1) and cover plate (2) with additional protective function. The reflector plate is made of highly foamed material having insulation effect. The adhesive-free plates are joined together in full surface nominal dimension of plate thickness, such that the cover plate is provided with non-white polystyrene particles and pearls in form of graphite particles having athermanous effect.

WAERMEISOLIERENDE VERBUNDFOLIE

FLEXIBLE REFLEKTIERENDE ISOLIERSTRUKTUREN

Fire Resistant Sarking Membrane

Abstract A sarking membrane comprises a reinforcing base sheet knitted with fibreglass element and having a water-resistant coating on both sides. A layer of aluminium can be bonded to the fibreglass substrate as radiant barrier layer to achieve some thermal value. Tiny penetrations can be applied throughout the layers to make the membrane breathable. The membrane will not only block the water from penetrating into the buildings, but also block the flame spreading through the cavity in case of fire. U) "- -a cc 0) 0 m Ca) La 4" U): 0 i =.cm 00' = 4- cI)c ...

Decorative sheet and decorative material using same

Provided is a decorative sheet capable of expressing a design excellent in dark color degree while satisfying heat shielding property. The decorative sheet has, on an infrared-reflective substrate, a decoration layer including a solid printed layer and a pattern layer, wherein the solid printed later contains an infrared-reflective or infrared-transmissive pigment and a binder resin, and the infrared-reflective or infrared-transmissive pigment comprises: (A) three or more kinds of compounds selected from the group of pigments consisting of quinacridone, isoindolinone, nickel azo complex, and phthalocyanine; or (B) one or more compounds selected from the group of pigments consisting of a composite oxide containing manganese and at least one metal element other than manganese, an azo-azomethine compound, and a perylene compound, and wherein at least a part of the pattern layer contains carbon black and a binder resin.

Multi-layer thermal insulation system

Acoustical panel comprising interlocking matrix of set gypsum and method for making same

Multi-layer thermal insulation system

A material

Insulation Sheeting

Aircell reflective insulation sheeting

REFLECTIVE INSULATION BATTS

MULTI-COMPOSITE ACOUSTIC PANEL

L'invention vise un panneau acoustique multi-composite utilisable à titre d'appui pour plancher ou murs. Ce panneau est composé de 15 à 65% de particules de brin de scie avec une granulométrie de 4 à 60 mèches; de 25 à 75% de poudrettes ou autres dérivés du pétrole ou de caoutchouc recyclé avec une granulométrie de 4 à 30 mèches; et de 3 à 20% d'un liant à base de polyuréthane d'élastomère, les pourcentages étant exprimeés en poids par rapport au poids total du panneau. En pratique, le caoutchouc agit comme élément anti-vibration et le brin de scie agit comme élément absorbant l~énergie acoustique car ce type de fibre est évidé dans le centre, ce qui lui donne un rôle d'absorption que la particule de caoutchouc n'a pas. Elle possède donc la capacité de réduire un impact.

TWO-COMPONENT POLYISOCYANURATE ADHESIVE AND INSULATION PANELS PREPARED THEREFROM

A layered insulation panel including a rigid polyisocyanurate foam layer and, adhered to at least one surface thereof, a facing material. The two materials are adhered by a two-component polyisocyanurate adhesive, and both the polyisocyanurate adhesive and the polyisocyanurate foam layer undergo polymerization concurrently and in place. The result is that the tensile bond strength between the polyisocyanurate foam layer and the facing surface is improved, due to interaction between the polymerization occurring at the surface of the foam layer and the polymerization of the polyisocyanurate adhesive.

TWO-COMPONENT POLYISOCYANURATE ADHESIVE AND INSULATION PANELS PREPARED THEREFROM

A layered insulation panel including a rigid polyisocyanurate foam layer and, adhered to at least one surface thereof, a facing material. The two materials are adhered by a two-component polyisocyanurate adhesive, and both the polyisocyanurate adhesive and the polyisocyanurate foam layer undergo polymerization concurrently and in place. The result is that the tensile bond strength between the polyisocyanurate foam layer and the facing surface is improved, due to interaction between the polymerization occurring at the surface of the foam layer and the polymerization of the polyisocyanurate adhesive.

INSULATION MATERIALS

An insulation material (3) for use in, or when used in, building and/or construction, including a moisture vapour permeable, liquid water and air impermeable, monolithic, dimensionally stable, substrate layer (1) bearing an overlying moisture vapour permeable, liquid water impermeable, low emissivity layer (2) applied as a thin organic coating containing infrared reflective matter. The substrate layer (1) may be laminated to a support layer (5) having a strength which is greater than that of the substrate layer by an intermittent adhesive 4 (Figure 1).

INSULATION MATERIALS

An insulation material (3) for use in, or when used in, building and/or construction, including a moisture vapour permeable, liquid water and air impermeable, monolithic, dimensionally stable, substrate layer (1 ) bearing an overlying moisture vapour permeable, liquid water impermeable, low emissivity layer (2) applied as a thin organic coating containing infrared reflective matter. The substrate layer (1 ) may be laminated to a support layer (5) having a strength which is greater than that of the substrate layer by an intermittent adhesive 4 (Figure 1).

RADIANT THERMAL BARRIER

Fan-folded panels are provided with longitudinal cuts or fold lines along an extended length of the panels to enable folding of edge sections of the panels into channel walls on either side of an intermediate panel section together forming a channel having a heat reflective surface inside the channel, the channel for insertion between two facing joists or studs so that tops of the channel walls are pushed up against a facing surface supported by the joists to form an air cavity between the facing surface and the channel acting as the radiant thermal barrier. A hydronic under floor heating pipe may be pre-installed attached to the facing surface supported by the joists or studs with the result that a proper air cavity is maintained with the radiant thermal barrier.

PROCESS FOR FORMING A DURABLE LOW EMISSIVITY MOISTURE VAPOR PERMEABLE METALLIZED SHEET INCLUDING A PROTECTIVE METAL OXIDE LAYER

A process for forming a low emissivity, moisture vapor permeable metallized composite sheet by coating a moisture vapor permeable sheet with at least one metal and exposing the freshly deposited metal to an oxidizing plasma thereby forming a protective synthetic metal oxide over the metal. The composite sheet material is suitable for use as a building construction barrier layer such as roof lining and house wrap.

BUILDING FRAME CONSTRUCTION AND METHOD THEREOF

A method of building frame construction can include forming an opening in at least a first portion of the building frame. The opening can be at least partially surrounded by king studs, trimmer studs, and a header. The method can also include wrapping a full perimeter defined about a longitudinal axis of at least one of the king studs, the trimmer studs, and the header. The wrapping can be at least proximate to the opening prior to the forming such that the at least one of the king studs, the trimmer studs, and the header is joined to another of the king studs, the trimmer studs, and the header while wrapped. The wrapping can be performed with a flexible sheet.

LOW-E HOUSEWRAP

A flexible insulation comprising a base insulating material, a covering material positioned over the base insulating material, and a plurality of perforations, wherein each of the perforations comprises an opening through both the base insulating material and the covering material.

PACKAGING HAVING A SURROUNDING HEAT BARRIER

In an insulating element (1) for bounding spaces to be thermally insulated, e.g. for transport or packaging containers, comprising an in particular plate-shaped substrate element (2) made of a material having a low thermal conductivity, such as a polymer, the substrate element (2) is provided with a metallic coating (3) having a low emissivity in order to reduce the thermal radiation, yet is applied in a layer thickness of <80 nm, preferably <50 nm, such that the thermal conduction of the metallic coating will only insignificantly reduce the thus optimized insulating value. The metallic coating in the nanometer range does not only reduce the thermal radiation, but also enables optimal gas tightness with minimal thermal conduction.

REINFORCED INSULATING PANEL AND METHOD OF MANUFACTURING SAME

A reinforced insulating panel comprises an insulating foam slab, and at least one reinforcement sheet disposed on a respective face of the insulating foam slab. Each reinforcement sheet comprises a plurality of continuous fibers extending diagonally across the insulating foam slab.

FIRE AND HEAT RESISTANT FIBRES

A flexible fire and heat resistant material comprising an intimate mixture o f organic intumescent filler and organic fibres adapted to char intensely within the temperature range of 200 .degree.C to 5 00 .degree.C. The added presence of inorganic fibre components enhances the structural integrity of this structure both during char formati on up to 500 .degree. C and at higher temperatures up to 1200 .degree.C once char oxidation takes place.

SOUND AND THERMAL INSULATING NON-WOVEN SYNTHETIC SHEET MATERIAL

A non-woven synthetic sheet material for use in sound insulation and/or thermal insulation is described. The sheet material is a felt or mat of substantially uniform synthetic fiber thickness and defines opposed flat surfaces. The sheet material is needle-punched from at least one of the opposed flat surfaces thereof to cause the synthetic fibers to intertwine to form a pliable sound and/or thermal insulating sheet. The insulating sheet has a density in the range of from about 100 to 1500 g/m2 and a homogeneous integrity resistant to fragmentation. Preferably a polymeric film is interconnected to a surface of the synthetic fiber sheet by a further needle punch step the polymeric film is preferably a metalized polyethylene film. The material has a multitude of uses in the construction industry. The felt may also be provided in strip form for use in the framing of wooden structures to sound insulate interconnected parts.

Mehrschichtige Leichtbau-Wärmedämmplatte

Insbesondere für Bekleidung verwendbares Kälteschutz-Material

Isolierbahn

Paroi isotherme

Auf Zug belastbare Wärmereflexions-Matte.

Die Wärmereflexions-Matte (8) dient zur Ausrüstung von Traglufthallen, Holzbinder-Hallen, Stahlbau- und Aluminiumstahl-Bauten, Gerüstbauten, Festzelten und Gebäuden mit geringer Wärmedämmung. Sie kann aussen oder innen angewendet werden und besteht aus einem Sandwich-Aufbau aus wenigstens zwei Lagen von textilverstärkter Kunststoff-Folie (12). Im Zwischenraum zwischen den äusserten Lagen der Kunststoff-Folien (12) ist eine Wärmerefiexions-Schicht (13) eingelegt. Mindestens zwei einander gegenüberliegende Ränder sind mit Verbindungsmitteln für eine zugkraftschlüssige Befestigung ausgerüstet, vorzugsweise in Form von eingeschweissten Kederprofilen (5).

Thermal insulation board for heat insulation of exterior e.g. facade of building, has adhesive-free reflector and cover plates that are joined together in full surface nominal dimension of plate thickness

The insulation board has reflector plate (1) and cover plate (2) with additional protective function. The reflector plate is made of highly foamed material having insulation effect. The adhesive-free plates are joined together in full surface nominal dimension of plate thickness, such that the cover plate is provided with non-white polystyrene particles and pearls in form of graphite particles having athermanous effect.

Heat Insulation Plate.

Die Erfindung betrifft eine Wärmedämmplatte aus expandiertem Polystyrol (EPS), insbesondere eine Wärmedämmplatte zur Wärmeisolation von z.B. Gebäudeteilen wie Aussenfassaden, Sockelbereichen, Wänden, Decken, Dächern oder anderen Teilen von Gebäuden, umfassend eine Dämmplatte resp. Reflektorplatte und mindestens eine Deckplatte. Bereitgestellt werden soll eine Dämmplatte, die einen Schutz gegen Aufheizung infolge Sonneneinstrahlung aufweist, bei gleichzeitig verbessertem Dämmwert. Dies wird erreicht durch die Verbindung einer Dämmplatte (1) mit einer Deckplatte (2), die nichtweisspigmentierte Polystyrolpartikel resp. -perlen, die atherman wirken, aufweist.

Thermal insulation board for insulating outer facades, base areas, walls, ceilings and roofs of buildings, has insulating portion and cover plate that are attached through contact surface, which are free of adhesive over whole surface

The thermal insulation board comprises insulating portion (1) and cover plate (2) that are attached through contact surface (3). The insulating portion and cover plate are free of adhesive over the whole surface. The cover plate is made of yellow polystyrene particles and dark-pigment containing particles such as graphite particles.

Heat Insulation Plate.

Die Erfindung betrifft eine Wärmedämmplatte, insbesondere eine Wärmedämmplatte zur Wärmeisolation von Aussenfassaden, Sockelbereichen, Wänden, Decken, Dächern oder anderen Teilen von Gebäuden aus expandiertem Polystyrol (EPS), umfassend eine Dämmplatte und mindestens eine Deckplatte. Bereitgestellt werden soll eine Dämmplatte, die einen Schutz gegen Aufheizung infolge Sonneneinstrahlung aufweist, bei gleichzeitig verbessertem Dämmwert. Dies wird erreicht durch die Verbindung einer Dämmplatte (1) mit einer Deckplatte (2), die aus gelben Polystyrolpartikeln und schwarz oder grau pigmentierten, atherman wirkenden Stoffen besteht.

Heat Insulation Plate.

Die Erfindung betrifft eine Wärmedämmplatte aus expandiertem Polystyrol (EPS), insbesondere zur Wärmeisolation von Gebäudeteilen, insbesondere Aussenfassaden, Sockelbereichen, Wänden oder Dächern, umfassend eine Dämmplatte. Bereitgestellt werden soll eine Wärmedämmplatte, die kostengünstig herstellbar ist, bei gleichzeitig verbessertem Dämmwert. Dies wird erreicht durch eine Dämmplatte, die aus gelb pigmentierten Polystyrolpartikeln und weniger als 30 Vol.-% dunkel pigmentierten Polystyrolpartikeln resp. -perlen mit atherman wirkenden Bestandteilen besteht.

Thermal insulation board, particularly for thermal insulation of exterior facades, walls, ceilings or roofs building, has insulation plate that provides insulation effect, where insulation plate has yellow polystyrene particles

The thermal insulation board has an insulation plate that provides the insulation effect, where the insulation plate has yellow polystyrene particles and a fraction of less than 30 percent dark polystyrene particles with athermanous acting material. The athermanous acting material is made of graphite particles and has about 29 percent dark polystyrene particles. The thermal insulation board has a lambda value of 0.025-0.035.

Procedure for the production of Dämmplatten.

Die Erfindung betrifft ein Verfahren zur Herstellung von Dämmplatten, insbesondere zur Wärmeisolation von Aussenfassaden, Wänden oder anderen Teilen von Gebäuden aus expandiertem Polystyrol (EPS), bestehend aus einer Reflektorplatte (1) und einer Deckplatte (2), deren Herstellung deutlich vereinfacht werden soll. Hergestellt werden soll eine Dämmplatte, die eine minimale Wasseraufnahme aufweist, bei gleichzeitig verbessertem Dämmwert infolge athermaner Bestandteile. Dies ist dadurch gelöst, dass die sich gegenüberliegenden Flächen der Reflektorplatte (1) und der Deckplatte (2) durch Erwärmung und nachfolgendes Andrücken vollflächig unter Bildung einer Kontaktfläche (3) miteinander verbunden werden.

Wärmedämmplatte.

Die Erfindung betrifft eine Wärmedämmplatte, insbesondere eine Wärmedämmplatte zur Wärmeisolation von Aussenfassaden, Sockelbereichen, Wänden, Decken, Dächern oder anderen Teilen von Gebäuden, umfassend eine beschichtete Dämmplatte resp. Reflektorplatte aus expandiertem Polystyrol (EPS). Bereitgestellt werden soll eine Wärmedämmplatte, die einen verbesserten Dämmwert und mindestens eine Zusatzfunktion aufweist. Hierzu umfasst sie eine geschäumte Dämmplatte resp. Reflektorplatte und eine Deckschicht, wobei die Reflektorplatte einen hohen Anteil an atherman wirkenden Stoffen aufweist und/oder hochgeschäumt ist und die wesentliche Dämmwirkung erbringt. Die Deckschicht ist in Form einer dünnen Schaumschicht oder einer Perlendeckschicht ausgebildet.

Heat reflection mat can be loaded in tension.

Die Wärmereflexions-Matte (8) dient zur Ausrüstung von Traglufthallen, Holzbinder-Hallen, Stahlbau- und Aluminiumstahl-Bauten, Gerüstbauten, Festzelten und ähnlichen Gebäuden. Sie kann aussen oder innen angewendet werden und besteht aus einem Sandwich-Aufbau aus wenigstens zwei Lagen von textilverstärkter Kunststoff-Folie (12). Zwischen den Lagen ist eine Wärmereflexions-Schicht (13) eingelegt. Mindestens zwei einander gegenüberliegende Ränder sind mit Verbindungsmitteln für eine zugkraftschlüssige Befestigung ausgerüstet, vorzugsweise in Form von eingeschweissten Kederprofilen (5).

Insulation board for heat insulation of e.g. external facades, has insulation layer and/or reflector plate and cover layer and/or cover plate connected with each other in glue-less and fully covered manner

The board has an insulation layer and/or a reflector plate (1) and a cover layer and/or a cover plate (2) connected with each other in a glue-less and fully covered manner, where thickness of the cover layer is smaller than 10 percent of the insulation layer. The insulation layer contains polymer particles with dark pigments such as graphite particles, where the board is formed from expanded polystyrene. Longitudinal sides of a plate are connected with longitudinal sides the insulation layer and/or reflector plate in a glue-less and fully covered manner. An independent claim is also included for a method for producing an insulation board.

ТЕПЛОИЗОЛИРУЮЩЕЕ ИЗДЕЛИЕ

Сжимаемый изолирующий элемент (1) из минерального волокна имеет первую основную поверхность (3), противоположную второй основной поверхности (4), и имеет боковые поверхности (5), соединяющие две основные поверхности (3, 4) и задающие толщину изолирующего элемента (1). Изолирующий элемент содержит облицовку (20), снабженную по меньшей мере одним выступающим фланцем (21), наружный конец (22) которого не закреплен на изолирующем элементе. Облицовка (20) прикреплена по меньшей мере к части первой основной поверхности (3), и выступающий фланец (21) подготовлен для прохождения над существенной частью боковой поверхности (5) изолирующего элемента (1) и покрытия ее. Раскрыт также способ установки сжимаемого изолирующего элемента.

АКУСТИЧЕСКАЯ ПАНЕЛЬ, СОДЕРЖАЩАЯ ПЕРЕПЛЕТЕННУЮ ФИКСИРОВАННУЮ МАТРИЦУ ИЗ ЗАТВЕРДЕВШЕГО ГИПСА, И СПОСОБ ЕЕ ИЗГОТОВЛЕНИЯ (ВАРИАНТЫ)

Предложена акустическая панель, содержащая беспрерывную фазу переплетенной фиксированной матрицы из затвердевшего гипса и способ изготовления акустической панели. Один из вариантов способа беспрерывного изготовления акустической панели включает получение смеси, включающей воду и обожженный гипс (приблизительно 50-95 вес. % от общего содержания твердых компонентов в смеси); добавление вспенивателя (приблизительно 0,003-0,4 вес. % от общего содержания твердых компонентов в смеси) до водной суспензии обожженного гипса; разливание смеси с образованием беспрерывной ленты, выдерживание ленты в условиях, достаточных для образования обожженным гипсом переплетенной фиксированной матрицы из затвердевшего гипса, нарезание ленты с образованием предшественника влажной акустической панели; сушку предшественника с получением акустической панели, которая имеет плотность приблизительно 160-400 кг/м3 и характеризуется значением нормального случайного звукопоглощения, равного, по меньшей мере, приблизительно ...

СЖИМАЕМЫЙ ИЗОЛИРУЮЩИЙ ЭЛЕМЕНТ С УМЕНЬШЕННЫМ ТРЕНИЕМ

Сжимаемый изолирующий элемент (1) из минерального волокна имеет первую основную поверхность (3), противоположную второй основной поверхности (4), и имеет боковые поверхности (5), соединяющие две основные поверхности (3, 4) и задающие толщину изолирующего элемента (1). Изолирующий элемент содержит облицовку (20), снабженную по меньшей мере одним выступающим фланцем (21), наружный конец (22) которого не закреплен на изолирующем элементе. Облицовка (20) прикреплена, по меньшей мере, к части первой основной поверхности (3), и выступающий фланец (21) подготовлен для прохождения над существенной частью боковой поверхности (5) изолирующего элемента (1) и покрытия ее. Раскрыт также способ установки сжимаемого изолирующего элемента.

FLEXIBLE SCREEN OF SOUS-TOITURE, AND ROOF COMPRISING SUCH A SCREEN

Ecran souple (E) de sous-toiture destiné à être installé, au-dessous d'une toiture en pente, en lés qui se recouvrent sur leurs bords parallèles à une direction de mise en place, cet écran comprenant un parement extérieur réfléchissant (Ea), une couche intermédiaire étanche (Eb) comportant un liant déformable, telle qu'une couche bitumineuse, et un parement intérieur (Ec). Le parement intérieur (Ec) est faiblement émissif et constitué par un matelas fibreux (7) hydrophobe apte à retenir des gouttelettes d'eau (15) sans qu'elles diffusent dans ce matelas.

HEAT INSULATOR AND PHONIC TOTAL INTENDS FOR the BUILDING AND CAPABLE OF REDUIRETOUS the TRANSFERS Of ENERGIES AND DISCOMFORTS MEETINGS IN the HABITATIONSHABITEES, the BUILDINGS OCCUPY, PARTICULARLY IN the ROOFS

FILM HAS AIR BUBBLES AND FIREPROOF HEAT INSULATING

ELEMENT OF WALL PREFABRICATES INSULATES THERMICALLY AND EASY TO ASSEMBLE

L'invention consiste en un élément de mur préfabriqué transportable (1) intégrant optionnellement des parements (21). Cet élément préfabriqué remplit les fonctions mécaniques et thermiques inhérentes à un mur et permet de créer sur site 10 mètres linéaires de mur en moins de 2 heures. Cet élément de mur (1) est constitué de panneaux standardisés (6) et (7), de préférence en bois, qui assemblés créent des cavités emprisonnant et stabilisant de l'air. L'isolation thermique est élevée. L'assemblage créé une structure mécanique plus résistante que les murs bois actuels. Les parements optionnels (21) génèrent des espaces pour l'électricité ou la plomberie. Ces options rendent l'usage de ce mur préfabriqué encore plus intéressant. Cette invention permet de créer des bâtiments à usage d'habitation ou de bureaux.

Single-sided draining reflective device, useful as screen under roof, rain barrier and vapor barrier in building, comprises non-woven geotextile layer, polypropylene foam layer and polished aluminum foil or another reflective metal

Dispositif réflectif drainant simple face, pouvant être utilisé comme pare pluie ou pare vapeur avec un haut pouvoir réflectif et, également, d'écran de sous toiture. La présente invention concerne un dispositif réflectif drainant simple face, pouvant être utilisé comme pare pluie ou pare vapeur avec un haut pouvoir réflectif et, également, d'écran de sous toiture. Ce complexe est composé d'une couche de géotextile non tissé (1), permettant d'évacuer l'hygrométrie résiduelle du support sur lequel il est appliqué, et assurant une très haute résistance mécanique au test du clou, d'une couche de mousse polypropylène (2) et d'une feuille d'aluminium poli (3) ou autre métal réfléchissant, l'ensemble sera assemblé par thermo soudure sans couture, ni perforation.

MULTILAYER STRUCTURE LINED WITH CONSTANT SPACING

PHONIC AND THERMAL INSULATOR

L'invention concerne un isolant phonique et thermique dont les faces extérieures sont constituées d'une couche (1, 1') continue, comportant de l'aluminium, soudée à chaud sur la face externe d'une nappe (2, 2') de film de matière synthétique à bulles. Cet isolant est caractérisé en ce qu'il comprend en outre, interposé entre les faces internes des nappes (2, 2') de film à bulles au moins une couche (3) de mousse en matière synthétique ignifugée reliée aux nappes (2, 2') de film à bulles uniquement par des lignes (4, 4', 4") de soudage longitudinales solidarisant les bords périphériques longitudinaux et une zone sensiblement médiane des différentes épaisseurs de l'isolant de manière à ménager entre les faces internes des films (2, 2') à bulles et la couche (3) de mousse des lames d'air (5, 5'). Application : isolation de bâtiments.

ACOUSTIC AND THERMAL INSULATING MATERIAL

ELASTIC STRUCTURE MULTI-LAYER HAS CELLS WITH HOLES

Coating material for use as e.g. building`s roof coating, has thermal insulating component extended on ribbed or wavy foil by using self-adhesive mass, where component is constituted of polyethylene foam between foil and polyester film

La présente invention concerne un matériau de revêtement pour bâtiment, au moins isolant thermique se présentant sous la forme d'un matériau composite. L'invention consiste en ce que la couche extérieure dudit matériau est constituée d'une tôle et une couche continue d'aluminium constitue la couche intérieure dudit matériau, au moins une nappe de film en matière synthétique à bulles d'air étant interposée entre la couche extérieure et la couche intérieure. Application au revêtement de bâtiment.

Flexible composite material for thermal and/or phonic insulation of roofer of building, has structure with sheet components, and foil layer forming surface of one sheet component oriented towards exterior with respect to space

La présente invention a pour objet un matériau composite souple pour l'isolation thermique et/ou phonique dans le domaine du bâtiment, présentant une structure stratifiée ou laminée, formée de deux composantes en feuilles définissant les faces extérieures opposées de la structure et d'au moins une composante intermédiaire sous forme de couche fibreuse, alvéolaire ou analogue apte à former une lame d'air entre lesdites faces extérieures, chaque composante en feuille consistant essentiellement en une feuille de matériau polymère recouverte, au moins sur son côté formant la face extérieure correspondante, d'une couche pelliculaire métallique. Ce matériau (1) est caractérisé en ce que la couche pelliculaire métallique (6) formant la face extérieure (3) de la composante en feuille (2) destinée à être orientée vers l'extérieur par rapport au volume à isoler, consiste en une pellicule dorée.

Multiple insulation material especially for roofing comprises heat absorbing reinforcing, reflective and impermeable layers

Isolant pluriel contre tous les transferts d'inconforts, tels que thermiques par conductions, convections entrantes et sortantes, rayonnements thermiques, mais aussi électriques, électromagnétiques, auditifs, psychologiques présentant une bonne résistance au feu. L'invention concerne un complexe permettant non seulement de réduire tous les transferts thermiques générateurs d'inconforts mais aussi de réduire les variations d'humidité relative et aussi de réduire les champs électriques et électromagnétiques. Pour cela le complexe est composé d'une succession de strates isoréflectives hétérogènes composées de séparateurs et de réflecteurs. Par exemple la composition sera un film noir armé étanche suivi d'une succession de strates isoréflectives. Certaines strates sont en laine de mouton associée avec des films réflectifs. Des espaceurs établiront devant les réflecteurs un espace transparent quasi sans contact obligeant l'énergie à s'y transmettre par rayonnement. On pourra ainsi constituer ...

Insulating materials

Multi-layer insulation material, especially for habitable loft rooms, has different layers to prevent transmission of heat, noise and damp

Isolant thermique et phonique global destiné au bâtiment et capable de réduire tous les transferts d'énergies et d'inconforts rencontrés dans les habitations habitées, dans les locaux occupés, particulièrement dans les combles. L'invention concerne un isolant thermique global capable de réduire tous les transferts d'énergies et d'inconforts dans les locaux habités ou occupés tout en étant capable de ne pas perdre ses aptitudes et qualités devant les contingences d'utilisation dans le bâtiment. Il est constitué d'une succession de strates actives et passives dans le domaine des échanges thermoradiatifs. Entre des films réflecteurs I non émetteurs sont disposés des matériaux hétérogènes destinés à perturber, désorganiser les échanges thermoradiatifs pour créer des interférences en augmentant les énergies radiatives différentielles. Le complexe comporte en supplément des composants destinés à supprimer les introductions d'humidités, à éliminer les charges électrostatiques et électromagnétiques ...

APPARATUS TO MANUFACTURE HEAT REFLECTION TYPE THERMAL INSULATION SHEET FOR BUILDING

The present invention relates to a heat reflection type thermal insulation sheet for a building, and a manufacture apparatus thereof. According to the present invention, the sheet has a multilayer structure comprising: an aluminum foil layer (11), a polyethylene terephthalate (PET) film layer (12) bonded on a lower surface of the aluminum foil layer by adhesives; and a non-woven fabric layer (13) attached on a lower surface of the PET film layer by adhesives. As a plurality of holes (15), which provide sound absorption and ventilation properties, and antibacterial property due to reduction of occurrence of fungi while passing air inside and outside while preventing penetration of moisture, are perforated on the thermal insulation sheet (10) to be attached and used on various types of building panels; flame retardant characteristics, sound absorption, ventilation, moisture-proof properties, wrinkle and breakage prevention performance, etc. are enhanced, and heat retention and insulation ...

ACOUSTICAL TILE

The present invention relates to an acoustical tile that includes a core and a surface treatment. The surface treatment comprises a formaldehyde-free latex binder, the binder including at least one formaldehyde-free biocide. The present invention also provides a process of manufacturing an acoustical tile. © KIPO & WIPO 2009 ...

투습방수성 및 난연성이 우수한 건축용판넬

... 본 발명은 투습방수성이 우수하면서도 난연성, 강성 및 단열기능이 우수한 건축용판넬에 관한 것으로서 본 발명에 의해 기존의 건축현장에서 단열재, 투습방수재, 복사열 차단재의 3가지 시공을 하나의 시공으로 대체할 수 있는 건축자재를 제공할 수 있다.

ACOUSTICAL TILE

The present invention relates to an acoustical tile that includes a core and a surface treatment. The surface treatment comprises a formaldehyde-free latex binder, the binder including at least one formaldehyde-free biocide. The present invention also provides a process of manufacturing an acoustical tile.

WEB FRAME

The web frame is a bonded assembly of panels and porous blanket layers, separated by an arrangement of isolated spacers. The panels and spacers are covered with a bonding means. A coating covers inner surfaces of the panels and spacers. The porous blanket is compressed and pinned between these panels, by spacers that are arranged as isolated nodes or columns The spacers have sharpened ends that penetrate the blanket and connect with the opposing panel. The web frame assembly provides thermal and sound insulation for buildings and other solid objects. These web frames are lightweight, durable, and permeable. Capillaries and passages throughout the panels and fibres of the blanket allow passage of moisture and air, thereby assisting in the management of condensation within the web frame.

COMPRESSIBLE INSULATION ELEMENT WITH REDUCED FRICTION

A compressible mineral fibre insulation element (1) having a first major surface (3) opposed to a second major surface (4), and having side surfaces (5) connecting the two major surfaces (3, 4) and defining a thickness of the insulation element (1). The thickness is at least 10 cm. The insulation element comprises a facing (20) provided with at least one extension flange (21) of which the outer end (22) is not secured to the insulation element. The facing (20) is attached to at least a part of the first major surface (3), and the extension flange (21) is prepared for extending over and covering a substantial part of the side surface (5) of the insulation element (1). A method of installing a compressible insulation element is also disclosed.

Heat barrier laminate

A lightweight and resilient heat barrier laminate which provides sound and vibration dampening. The laminate has a density less than about 5 lb/ft3 and a total thickness of no greater than about 1 inch. The laminate includes a first metal foil having high heat conductivity and a first batt of insulating nonwoven fiber material having a thickness of at least about 0.03 inch. The first batt is an outermost layer of the laminate which is adhesively bonded to a first side of the first metal foil. The laminate also includes a second metal foil and a second batt of insulating nonwoven fiber material different from the material of the first batt. The second batt has a thickness of at least twice as thick as the first batt and is adhesively bonded to a second side of the first metal foil. The second metal foil is an outermost layer of the laminate, has high heat conductivity, is in contact with the second batt of insulating material and in contact with a carpet.

Combined thermal and acoustic insulator

A combined thermal and acoustic insulator comprises a first metallic material layer formed, for example, from a metal foil, a fibrous low density material batt layer adjacent the first metallic layer, a high density plastic material layer, for example, a mass loaded elastomer, adjacent the batt material layer, and a second metallic foil layer. The first metallic material layer forms the heat exposed side and the second metallic layer forms the shielded side of the insulator. Alternatively, additional layers may be provided, for example, a third foil layer adjacent the fibrous material layer and a second fibrous layer between the third metal foil layer and the first metal foil layer.

Shear Panel Building Material

A shear panel building material that includes a first facing membrane, a core matrix disposed on a face of the first facing membrane, and a semi-rigid or rigid material attached to the core matrix. The core matrix can include microspheres having a size of about 200 microns to about 800 microns, sodium silicate, and ethylene vinyl acetate. In one aspect, the shear panel is substantially free from glue and cement.

Thermal energy venting system

The thermal energy venting system includes an insulation board disposed in the cavity between adjacent studs and other areas of a domicile or building to form venting channels directing excess heat through a roof/ridge vent. The insulation board is a non-porous laminate formed by a rigid foam core covered or sheathed with a reflective polymeric facer or plastic. The insulation board provides a thermal barrier for conduction, convection and radiation aspects of thermal energy transfer. The installation of the insulation board forms an envelope that reflects exterior thermal energy and interior thermal energy to maintain comfortable interior temperatures with minimal heating/cooling energy expenditure and costs.

Building insulation system

The building insulation system includes a reflective, non-porous bag filled with thermal insulation material. The covering of the bag is made from reflective polymeric facer or plastic, which facilitates reflection of thermal energy radiation. The reflective non-porous bag provides a thermal barrier for conduction, convection and radiation aspects of thermal energy transfer.

Thermal Insulation with Entangled Particulate Units having Non-Integer Dimensionality

A synthetic insulation material that rivals and surpasses down in performance without suffering degradation in insulating power over time. The material is an aggregate of particulate units that have a fractal-like geometric configuration. The geometric configuration includes non-integer dimensionality that promotes physical entanglements of the particulate units. The physical entanglements impart a high frictional resistance to slippage of the particulate units to maintain loft over time by inhibiting the settling of particulate units upon compression. The geometric configuration further includes aspects of self-similarity. The particulate units are formed from a material that efficiently scatters thermal radiation. The combination of high loft and efficient scattering of thermal radiation minimizes heat loss resulting from conduction and radiation, leads to a superior material for thermal insulation, has excellent health characteristics for human and the environment, and exhibits excellent long term life cycle performance.

Portable Shelter With Outer Vinyl and Low Emissivity Layers

A portable shelter with low emissivity is provided for sheltering materials or human occupants at a remote location. The shelter has a flexible, multi-layer cover, including a vinyl material, reflective material located inside and immediately adjacent to the vinyl material, and insulation material located inside the reflective material. The low-ε vinyl cover is lightweight and thermally efficient. The shelter may be adapted for use with interior-climate control equipment at the remote location.

Method and apparatus that use the spectral reflectance characteristics of a reflector matrix, or other spectral filters, to limit available broad spectrum electromagnetic energy, reflected toward a patient target, to specific infrared bandwidths, to increase the effectiveness, comfort and/or duration of thermotherapy

Reflected thermotherapy is a superior way to use ambient and available transmitted electromagnetic energy to treat a broad variety of illnesses. Warm blooded animals transmit a large amount of electromagnetic energy that can be reflected for thermotherapy. Using reflected electromagnetic energy from existing sources eliminates the need for a power supply, infrared lights, and cords. The problem is that in our modern energized world broad spectrum ambient and available transmitted electromagnetic energy from source may be contaminated with extra bandwidths of the full electromagnetic spectrum. This broad-spectrum energy when reflected onto a patient target can make the patient feel uncomfortably warm and produce undesirable effects. A variety of reflector coatings are available that can limit the spectra reflected back to a target from a broad spectra source. Gold finishes or tailored ceramic finishes are examples of spectral limiting coatings. When a gold reflector matrix is used, the spectral reflectance characteristics of gold limits the reflected energy to the infrared bandwidths. This reduces the hyperthermic discomfort of the patient target and allows the patient target to be treated with desired therapeutic infrared bandwidths for a much longer period of time. The gold reflector matrix can be attached to a fabric substrate. Once attached the substrate fabric, the resulting composite can be used to make a variety of apparatus. Blankets, beds, pads, athletic braces, and medicinal devices can all be lined with the gold composite fabric to achieve the desired therapeutic effect 1) A method for using the spectral reflectance characteristics of a gold reflector matrix , to limit broad spectrum electromagnetic energy , reflected toward a patient target , to infrared bandwidths , to increase the efficacy , duration and/or comfort of thermotherapy.2) An apparatus that uses the spectral reflectance characteristics of a gold reflector matrix , to limit broad spectrum ...

HIGH-PERFORMANCE TORCHABLE THERMAL INSULATING PANEL FOR BUILDINGS ROOFS

Separating membrane of plastic material, made up of a bossed and waterproof sheet which is coupled with a permeable base layer. The bosses are of the cylindrical type with a double diameter and have such a shape and arrangement as to feature improved adhesion on both faces. The gripping of the adhesive is increased in order to obtain greater tear strength, on the upper face, and at the same time increases the area of contact with the base layer for a greater resistance to delamination on the lower face. In particular, inside each chamber there is an internal crown, which divides it like a necking into two superimposed compartments having the same diameter, wherein the first compartment has a depth amounting to at least ⅓ of the total. A production process for obtaining the membrane is also disclosed. 121. High-performance torchable thermal insulating panel for buildings roofs of the multi-layer type comprising a sandwich structure being provided with an intermediate layer of rigid polyurethane foam of the PUR or PIR type or of an equivalent material whose upper face and lower face are each provided with a multi-layer coating , characterised in that the multi-layer coating is gas-tight and torchable and is coupled to the intermediate insulating layer of the thermal insulating panel at least in correspondence of the upper face () and of the lower face.2. High-performance torchable thermal insulating panel for buildings roofs according to claim 1 , characterised in that the multi-layer coating is made up of the following layers coupled in sequence:a) at least one layer consisting of a metallized polyester film;b) at least one layer consisting of a polyethylene film;c) at least one layer consisting of a moisture-proof paper sheet;d) at least one layer consisting of a film of bituminous compound of polymer bitumen;e) at least one layer consisting of a non-woven polypropylene fabric,wherein the layer consisting of the metallized polyester film is coupled to the ...

SILICONE COATINGS FOR EXTERIOR ARCHITECTURAL SUBSTRATES FOR BUILDINGS

A method comprising applying a reflective silicone-containing composition to at least a portion of a surface of at least one architectural substrate, wherein the silicone-containing composition-applied surface faces an exterior wall of a building or an exterior roof of a building. 1. A method comprising:applying a reflective silicone-containing composition to at least a portion of a surface of at least one architectural substrate, wherein the silicone-containing composition-applied surface faces an exterior wall of a building or an exterior roof of a building.2. The method of claim 1 , wherein the silicone is a silicone water-based elastomer or a liquid silicone elastomer.3. The method of claim 1 , wherein the architectural substrate is a panel secured to the exterior wall of a building.4. The method of claim 1 , wherein the architectural substrate is a ceramic panel.5. The method of claim 1 , wherein the architectural substrate is a glass panel.6. The method of claim 1 , wherein the architectural substrate is a roof panel.7. The method of claim 1 , wherein the architectural substrate includes at least one photovoltaic cell.8. The method of claim 1 , further comprising curing the reflective silicone-containing composition to a form reflective silicone coating.9. The method of claim 1 , further comprising drying the reflective silicone-containing composition to a form reflective silicone coating.10. The method of claim 8 , wherein at least a portion of the reflective silicone coating contacts the exterior wall of the building or the exterior roof of the building.11. The method of claim 1 , wherein the reflective silicone-containing composition also includes at least one pigment that imparts reflectivity in the ultraviolet and/or visible and/or infrared wavelength range.12. The method of claim 11 , wherein the pigment is titanium dioxide.13. The method of claim 1 , wherein the reflective silicone-containing composition is a water-based silicone emulsion14. A method ...

Insulation Board

External wall insulation system comprising a high efficient insulation layer of rigid polyurethane or polyisocyanurate foam provided on at least one side with a facing, preferably a gastight (aluminium) layer, and a base layer provided on at least one of the surfaces of the facing wherein said base layer is a polyurethane layer or a polyisocyanurate layer.

UNDERLAYMENT WITH THERMAL INSULATION

An underlayment that meets underlayment requirements and provides thermal insulation is disclosed. The underlayment includes a core material and an upper emittance layer having an exterior surface. An upper reinforcement layer is positioned between the upper emittance layer and the core material. A first encapsulation layer is positioned between the upper emittance layer and the upper reinforcement layer. A second encapsulation layer is positioned between the upper reinforcement layer and the core material. The underlayment includes a lower emittance layer having an exterior surface. A lower reinforcement layer is positioned between the lower emittance layer and the core material. A third encapsulation layer is positioned between the lower emittance layer and the lower reinforcement layer. A fourth encapsulation layer is positioned between the lower reinforcement layer and the core material. 118-. (canceled)19. A method of manufacturing an underlayment with thermal insulation , the method comprising:assembling an upper foil laminate including an upper low-emittance reflective layer having an exterior surface, an upper scrim layer, a first encapsulation layer between the upper low-emittance reflective layer and the upper scrim layer, and a second encapsulation layer on a side of the upper scrim layer opposite the first encapsulation layer;assembling a lower foil laminate including a lower low-emittance reflective layer having an exterior surface, a lower scrim layer, a third encapsulation layer between the lower low-emittance reflective layer and the lower scrim layer, and a fourth encapsulation layer on a side of the lower scrim layer opposite the third encapsulation layer;placing the upper foil laminate over an insulating layer that includes a closed-cell foam core material;placing the lower foil laminate under the insulating layer; andlaminating the upper foil laminate, the insulating layer, and the lower foil laminate together to form the underlayment,wherein the ...

AEROGEL LAMINATE AND THERMAL INSULATION MATERIAL

The present invention relates to an aerogel laminate having a structure in which an aerogel layer and a support having a heat ray reflective function or a heat ray absorbing function are laminated. 1. An aerogel laminate having a structure in which an aerogel layer and a support having a heat ray reflective function or a heat ray absorbing function are laminated.2. The aerogel laminate according to claim 1 , wherein the aerogel layer is a layer containing an aerogel having a structure derived from polysiloxane.3. The aerogel laminate according to claim 1 , wherein the aerogel layer is a layer prepared by drying a wet gel formed from a sol containing at least one selected from the group consisting of polysiloxane compounds having a reactive group in the molecule and hydrolysis products of the polysiloxane compounds.4. The aerogel laminate according to claim 1 , wherein the aerogel layer is a layer prepared by drying a wet gel formed from a sol containing silica particles.5. The aerogel laminate according to claim 4 , wherein an average primary particle diameter of the silica particles is 1 nm or more and 500 nm or less.6. The aerogel laminate according to claim 1 , wherein the support has a layer composed of a material comprising at least one selected from the group consisting of carbon graphite claim 1 , aluminum claim 1 , magnesium claim 1 , silver claim 1 , titanium claim 1 , carbon black claim 1 , metal sulfates claim 1 , and antimony compounds.7. The aerogel laminate according to claim 1 , wherein the support is an aluminum foil claim 1 , an aluminum deposited film claim 1 , a silver deposited film claim 1 , or an antimony oxide containing film.8. A thermal insulation material including the aerogel laminate according to . The present invention relates to an aerogel laminate and a thermal insulation material.Recently, requirements for comfortability of living spaces and energy saving have been increasing; for this reason, the shapes of target objects required for ...

LAYERED INSULATION SYSTEM

A layered insulation system comprising one or more layers. A variety of types of layers can be used in conjunction with one another to deliver a range of desired Low-E and/or Low-U insulation properties and/or venting choices. Some types of layers can be foam layers with foam that inhibits heat conjunction interspersed with microparticles and/or nanoparticles that reflect, scatter, abate, and/or negate infrared radiation (IR) wavelengths, including dampening “Ideal Model Matrix” vibrations to inhibit heat flux through an IR opaque system. Other layers can be Low-E layers, Low-U layers, primarily empty layers, and/or other types of layers. 1a form layer comprising foam resistant to heat conduction; said foam layer having a plurality of protrusions extending from each surface of said foam layer, each protrusion having an apex region;at least two reflective layers couples with said foam layer, said at least two reflective layers being configured to reflect spectral and wide-band thermal radiation, and said at least two reflective layers being positioned to line at least a portion of substantially aligned substantially vertical channels on a first surface of said foam layer between said plurality of protrusions;said plurality of protrusions substantially aligned as a matrix grid having a plurality of section on a second side of said foam layer; andat least one or more infrared transparent membranes couples with said foam layer substantially at said apex regions and/or said at least one reflective layer to form one or more hermetically sealed gaps by sealing said spaces between said protrusions with said one or more infrared transparent membranes on said first side.. A layered insulation system, comprising: This Application claims priority under 35 U.S.C. § 119(e) from earlier filed U.S. Provisional Application Ser. No. 61/710,617, filed Oct. 5, 2013, by Michael Leonard, the entirety of which is incorporated herein by reference.The present disclosure relates generally to ...

BUILDING INSULATION SYSTEM

The building insulation system includes a reflective, non-porous bag filled with thermal insulation material. The covering of the bag is made from reflective polymeric facer or plastic, which facilitates reflection of thermal energy radiation. The reflective non-porous bag provides a thermal barrier for conduction, convection and radiation aspects of thermal energy transfer. 1. A building insulation system , comprising:a bag having a first and a second surface, a first and a second end, and a first and a second side that form a hollow compartment;an inlet port at the first end of the bag; andthe hollow compartment filled with an insulation material.2. The system of wherein a hose extending from a hopper machine is connected to the inlet port.3. The system of wherein an extension tube is connected between the inlet port and the hose and has a diameter smaller than a diameter of the inlet port to permit air to escape around the extension tube.4. The system of wherein the bag has a vent on one of the sides.5. The system of wherein the vent has a removable cover.6. The system of wherein the inlet port has a removable cover.7. The system of wherein the first surface has at least one removable member that forms an indentation.8. The system of wherein the bag has a cover made of a reflective material. This application is a Continuation-in-part of U.S. Ser. No. 16/291,853, filed Mar. 4, 2019 which is a Continuation of U.S. Ser. No. 13/652,442, filed Oct. 15, 2012 which claims the benefit of U.S. Provisional Patent Application Ser. No. 61/548,099, filed Oct. 17, 2011, the contents of these applications are hereby incorporated by reference in their entirety.The present invention relates to building construction systems, and particularly to a building insulation system that provides improved insulations for maintaining more moderate temperatures and reducing energy costs.Typical building insulation does not have the capacity to provide the full range of thermal barriers ...

Fiber reinforced polymer building systems and methods

A composite building system comprising a structural frame and walls which is made of pultrusion fiber reinforced polymer (PFRP) material. PFRP provides increased performance, strength, protection, and longevity for mobile and fixed building structures, enclosures or vehicles, commonly found in residential, commercial, industrial, healthcare, aerospace, government defense, energy, and agriculture sectors. The PFRP material comprises fibers embedded in a resin matrix. Exemplary fibers are glass, carbon, and synthetic fibers. PFRP products can be formed using a pultrusion method that eliminates outgassing. An intumescent fire barrier can be applied to the PFRP to meet National Fire Protection Association fire endurance codes and standards. The composite building system increases personal safety while reducing weight, labor costs, construction time, and total cost of ownership over the life of the structure while being resistant to ballistic, seismic, corrosion, rotting, impact, and insect damage. In addition, a wall and wall assembly consisting of the PFRP material is impervious to water and air and does not require an exterior finish coating. The PFRP wall and wall assembly can be designed to be versatile, allowing for use with both PFRP structural framing and traditional framing materials, such as concrete, steel, and wood.

COMPOSITE MATERIALS WITH TAILORED ELECTROMAGNETIC SPECTRAL PROPERTIES, STRUCTURAL ELEMENTS FOR ENHANCED THERMAL MANAGEMENT, AND METHODS FOR MANUFACTURING THEREOF

Disclosed is a method to produce composite materials, which contain customized mixes of nano- and/or micro-particles with tailored electromagnetic spectral properties, structural elements based thereon, in particular layers, but also bulk materials including inhomogeneous bulk materials. In some embodiments the IR-reflectivity is enhanced predominantly independently of reflectivity for visible wavelength. The enhanced IR-reflectivity is achieved by combining spectral properties from a plurality of nano- and/or micro-particles of distinct size distribution, shape distribution, chemical composition, crystal structure, and crystallinity distribution. This enables to approximate desired target spectra better than know solutions, which comprise only a single type of particles and/or an uncontrolled natural size distribution. Furthermore disclosed are methods of manufacturing such materials, including ceramics, clay, and concrete, as well as applications related to design and construction of buildings or other confined spaces. 1. A method of creating a composite material ,the composite material comprising a plurality of populations of nano- or micro-particles and/or of nano- or micro-cavities of predominantly distinct size distributions, shape distributions, chemical compositions, crystal structures, and crystallinity distributions, wherein the plurality of populations are predominantly embedded in a carrier material,in such composition ratios, with such typical properties per population, and in such density relative to the carrier material, that a specific targeted broadband spectral reflectance at least within the VIS and NIR range is approximated,which is at least partially different from the spectral properties of each individual population within the plurality of populations and the carrier.2. The method according claim 1 , [{'sub': 'i', 'creating a plurality of reservoirs Rcorresponding to a plurality of said populations of nano- or micro-particles,'}, {'sub': i', ' ...

HIGH THERMAL RESISTANCE AND PERMEANCE INSULATION MATERIAL

A low-emittance material having improved energy efficiency protection against air infiltration and moisture build-up in buildings is disclosed. The aforementioned low-emittance material utilizes existing framing openings or without increasing the wall profile of a building. The present invention provides a low-emittance material which may be implemented on traditional 2×4 framing having R-15 mass insulation material within existing or newly constructed framing cavities. The material of the present invention also meets requirements for serving as a water resistive barrier as defined by ICC AC38. 1. A flexible insulation comprising:a base insulating material;a covering material positioned over the base insulating material: anda plurality of perforations, wherein each of the perforations comprises an opening through both the base insulating material and the covering material.225-. (canceled) The present application is a continuation of Application No. 13,107,568, filed on May 13, 2011, which claims priority to provisional patent application entitled, “LOW-E HOUSEWRAP,” filed on May 21, 2010, and assigned U.S. Application Ser. No. 61/346,916. The contents of these applications are incorporated by reference.The present invention relates generally to building structure materials, and more specifically to an infiltration barrier used in building construction to improve energy efficiency and to protect against air infiltration and moisture build-up in buildings.In order to improve the energy efficiency of new and existing buildings, it has been common practice in building new structures, and in residing old structures, to cover the exterior wall sheathing with an infiltration barrier, for example, prior to installation of a covering material such as siding. One such infiltration barrier is a high density polyethylene fiber sheeting. While infiltration barriers cut down on drafts and thereby convective heat loss, they provide little other contribution to the energy ...

Insulating materials

Insulating materials which reduce heat loss are provided. The insulating materials include an air layer forming portion which forms a plurality of air layers, a lower cover portion which covers a lower side of the air layer forming portion, and an upper cover portion which covers an upper side of the air layer forming portion. Here, the lower cover portion and the upper cover portion insulate the air layers from the outside.

Radiant and insulating barrier

A radiant and insulating barrier having two sheets bonded together along spaced flat channels to define a plurality of hermetically sealed and spaced pockets between the channels. The pockets are filled with insulation. The sheets have an outer surface formed of a radiant heat reflecting material.

Materials and methods for passive radiative cooling

A coating including a relatively thin visible-absorptive layer atop a relatively thick non-absorptive, solar-scattering underlayer. The thin top layer enables efficient absorption of appropriate visible wavelengths to show specific colors, and minimizes absorption in the infrared radiation in sunlight due to its relatively small thickness. Meanwhile, the bottom layer maximizes the backscattering of infrared light without absorption to reduce solar heating.

Radiant Barrier Ventilation System

This invention relates to a system of ventilating a residential or light commercial structure with lightweight, easy to install radiant barriers that reflect external sunlight heat away from the structure, reflect heat produced within the structure to maintain internal warmth, and contain internal air ventilation space to prevent condensation. 1. An improved insulation ventilation system for a roof structure comprising:a load bearing roof frame with a plurality of roof rafters;a plurality of radiant barriers, wherein each radiant barrier comprises a first surface, a second surface, a top edge, a bottom edge, a first side edge, a second side edge, and a plurality of fold lines, further wherein the fold lines produce a corrugated first and second surfaces for each radiant barrier with a plurality of adjacent oppositely pointing apexes on the first surface and the second surface;a plurality of air holes between each of the fold lines;a heat reflective material on the first surface and the second surface of each radiant barrier;wherein the plurality of radiant barriers is attached between each roof rafter with the first surface facing upwards and the second surface facing inwards to form at least one layer;wherein the first surfaces of the plurality of radiant barriers substantially reflects radiant heat, and the second surfaces of the plurality of radiant barriers substantially reflects radiant heat; andthe corrugated surfaces and the air holes for the barriers produce convective air flow the plurality of radiant barriers that removes hot air and moisture from the radiant barriers.2. The insulation ventilation system for a roof structure of claim 1 , wherein the roof bearing frame is made out of at least one of a group of materials consisting of solid wood claim 1 , timber materials claim 1 , engineered wood products claim 1 , wood composite materials claim 1 , steel and aluminum.3. The insulation ventilation system for the roof structure of claim 1 , wherein angle of ...

Heat-shielding panel and prefabricated building

The present disclosure provides a heat-shielding panel having a heat-shielding function and a heat-isolating function, and a prefabricated building constructed by arranging a plurality of heat-shielding panels adjacently. The heat-shielding panel ( 1 ) of the present disclosure includes a pair of sheets ( 10, 20 ) and an enclosed space ( 30 ). The pair of sheets ( 10, 20 ) are provided with an exposed surface respectively, and back faces of the pair of sheets ( 10, 20 ) are oppositely arranged at intervals. The pair of sheets ( 10, 20 ) are formed by heat-shielding sheets ( 12 ). The enclosed space is arranged between the pair of sheets ( 10, 20 ). The enclosed space is formed by sandwiching a spacer ( 31 ) between the pair of sheets ( 10, 20 ). A fluid such as air is enclosed in the enclosed space.

Ceiling system

A ceiling system includes a ceiling support structure supporting a plurality of ceiling panels, each ceiling panel including a core layer having a top surface facing a first interior space above the ceiling panels, a bottom surface facing a second interior space below the ceiling panels, and a plurality of peripheral edges extending between the top and bottom surfaces. A top frame layer extends from the top surface and a thermal layer is on the top frame layer opposite the top surface. The thermal layer has a first surface facing away from the top frame layer and a second surface facing toward the top frame layer. The top frame layer supports the second surface in a spaced-apart manner from the top surface to form one or more air gaps between the top surface and the second surface. The first and second surfaces have a thermal emissivity of 0.5 or less.

STRUCTURE WITH SURFACE FOR SEASONAL SELECTIVENESS OF SOLAR IRRADIATION ABSORPTION AND REFLECTION

Disclosed are various structure surface configurations and related methods. An exemplary structure includes a facade that has grooved cavities that are configured in a manner that reflects summer (cooling season) insolation and absorbs winter (heating season) insolation. The effective absorptivities of the exemplary structure for various cavity reflectance characteristics, i.e., a wide range of diffuse and specular reflectance characteristics, are evaluated using a Monte Carlo model. The calculations in an illustrated embodiment are performed for the latitude of 41° N where both heating and cooling loads are significant. Embodiments of various structures are similarly within the scope of the disclosure for locations of different latitudes and longitudes. 1. A seasonally selective structure formed at least in part by a radiation absorbing portion covered by a light transmitting plate having a surface with at least one radiation absorbing cavity defined therein , the at least one radiation absorbing cavity being defined by an upper longitudinal surface and a lower longitudinal surface that is generally parallel to the upper interior longitudinal surface , wherein:a) the lower longitudinal surface of the at least one radiation absorbing cavity is oriented to prevent direct solar contact with at least a portion of the at least one radiation absorbing cavity during summer months; andb) the at least one radiation absorbing cavity is oriented to absorb solar radiation in winter months by permitting direct solar contact with at least a portion of the at least one radiation absorbing cavity, the at least one radiation absorbing cavity being configured to permit incident direct solar radiation to undergo multiple reflections within the at least one radiation absorbing cavity between the upper and lower longitudinal surfaces during winter months.2. The seasonally selective structure of claim 1 , wherein the at least one radiation absorbing cavity includes an exterior portion ...

High thermal resistance and permeance insulation material

A low-emittance material having improved energy efficiency protection against air infiltration and moisture build-up in buildings is disclosed. The aforementioned low-emittance material utilizes existing framing openings or without increasing the wall profile of a building. The present invention provides a low-emittance material which may be implemented on traditional 2×4 framing having R-15 mass insulation material within existing or newly constructed framing cavities. The material of the present invention also meets requirements for serving as a water resistive barrier as defined by ICC AC38.

SYSTEMS AND METHODS OF INSULATING RAILCARS

Systems for and methods of insulating an uninsulated railroad car that include a plurality of insulation segments that are nonpermanently secured to interior surfaces of walls and a ceiling of the railroad car. 1. A system of insulating a railroad car , the system comprising:a plurality of insulation segments; andmeans for nonpermanently securing the insulation segments to interior surfaces of walls and a ceiling of the railroad car.2. The system of claim 1 , wherein the insulation segments are nonpermanently secured to the interior surfaces of walls and ceiling of the railroad car claim 1 , and the walls and the ceiling of the railroad car are each entirely covered with at least one of the insulation segments.3. The system of claim 1 , wherein the nonpermanent securing means comprise magnets secured to a surface of each of the insulation segments.4. The system of claim 3 , wherein the insulation segments are nonpermanently secured to the interior surfaces of walls and ceiling of the railroad car claim 3 , and the magnets define an air space between the insulation segments and the interior surfaces of the walls and the ceiling.5. The system of claim 1 , wherein at least some of the insulation segments are formed of a reflective bubble film material.6. The system of claim 1 , wherein at least some of the insulation segments are formed of a woven matting material having at least one layer of a reflective radiant barrier thereon.7. The system of claim 1 , wherein at least some of the insulation segments are formed of a non-woven matting material having at least one layer of a reflective radiant barrier thereon.8. The system of claim 1 , wherein at least some of the insulation segments are formed of a rigid foam board material.9. The system of claim 1 , wherein the insulation segments are nonpermanently secured to the interior surfaces of the walls and the ceiling of the railroad car claim 1 , the ceiling is covered with at least one insulation segment formed of a high ...

ASPHALTIC MEMBRANE WITH MULLITE-CONTAINING GRANULES

A roofing article comprising (i) an asphaltic substrate; and (ii) a plurality of mullite-containing granules disposed on a surface of the substrate, where said mullite-containing granules include a mullite concentration of at least 35 wt % and at most 63 wt % as determined by quantitative x-ray diffraction. 1. A reflective roofing article , said roofing article comprising:(i) an asphaltic substrate; and(ii) a plurality of mullite-containing granules disposed on a surface of the substrate, where said mullite-containing granules include a mullite concentration of at least 35 wt % and at most 63 wt % as determined by quantitative x-ray diffraction.2. The article of claim 1 , where the mullite is in the form of crystallites having a size of at least 25 nm and at most 65 nm as determined by x-ray diffraction line broadening by the isolated (110) diffraction peak.3. The article of claim 2 , wherein the mullite concentration is at least 45 wt % and at most 55 wt % as determined by quantitative x-ray diffraction claim 2 , and the mullite crystallite size is at least 35 nm and at most 55 nm as determined by x-ray diffraction line broadening by the isolated (110) diffraction peak.4. The article of claim 3 , wherein the said mullite crystallites have an aspect ratio of at least 1.5 claim 3 , where the aspect ratio is a ratio of the mullite crystallite size by the isolated (001) x-ray diffraction peak to the mullite crystallite size by the isolated (110) x-ray diffraction peak.5. The article of claim 4 , wherein the said mullite crystallites have an aspect ratio of at least 1.7.6. The article of claim 2 , where the mullite-containing granules are calcined kaolin.7. The article of claim 6 , wherein the calcined kaolin is thermally prepared at a calcination temperature of at least 1000° C. and at most 1300° C.8. The article of claim 7 , wherein the calcined kaolin is thermally prepared at a calcination temperature of at least 1050° C. and at most 1200° C.9. The article of claim 6 ...

Synthetic fiber insulation with facing

An insulation product includes a fibrous layer and a facing layer. The fibrous layer includes synthetic fibers, has first and second opposing major surfaces, and has an average denier of less than about 3.0. The facing layer includes a paper-backed facing adhered to one of the first and second major surfaces of the fibrous layer. The insulation product has: a flame spread index of no greater than 25 and a smoke developed index of no greater than 50 as measured in accordance with ASTM E84; a thickness of between about 0.5 and 2 inches; and a thermal conductivity of less than about 0.3 Btu-in./ft 2 -hr-° F.

Multiple layered radiant active assembly

An active insulated assembly for controlling heat transfer through insulated assemblies. The active insulated assembly includes a thermal conductor configured to actively move thermal energy from the active insulated assembly. The active insulated assembly also includes a first radiant barrier on a first side of the thermal conductor configured to reflect radiant energy back to its source and allow the assembly to resist heat transfer in either direction. The active insulated assembly further includes a second radiant barrier on a second side of the thermal conductor wherein the second side is opposite the first side, the second radiant barrier configured to reflect radiant energy back to its source and allow the assembly to resist heat transfer in either direction.

Insulating Device for Building Foundation Slab

A device for insulating the slab foundation of a building, said device comprising: a generally horizontal insulating section disposed between the slab foundation and a footer of a building, said horizontally disposed insulating section comprising a generally elongated cuboid shape having at least one cutout through which a concrete column is disposed; said prefabricated device further comprising a generally vertical insulating section disposed adjacent to said horizontal insulating section and attached to said building. 1. A device for insulating the slab foundation of a building , said device comprising: a generally horizontal insulating section disposed between the slab foundation and a footer of a building , said horizontally disposed insulating section comprising a generally elongated cuboid shape having at least one cutout through which a concrete column is disposed; said prefabricated device further comprising a generally vertical insulating section disposed adjacent to said horizontal insulating section and attached to said building.2. The device of claim 1 , wherein the device is prefabricated and comprises a material selected from the group consisting of extruded foam claim 1 , polyisocyanurate foam claim 1 , expanded foam claim 1 , insulated foil bubble wrap claim 1 , and blown insulation.3. The device of claim 1 , wherein the material comprises an additive selected from the group consisting of an insecticide claim 1 , an herbicide claim 1 , a fungicide claim 1 , and a water repellant.4. The device of claim 1 , wherein the vertical insulating section further comprises a semi rigid external sheath.5. The device of claim 1 , further comprising a vertical metal bar disposed through at least one column claim 1 , where the bar comprises a material selected from the group consisting of steel claim 1 , iron claim 1 , and metal alloy.6. The device of claim 1 , further comprising a horizontal metal bar disposed across the device through and perpendicular to the at ...

THERMALLY INSULATED SHEET

A thermally insulating sheet for installation adjacent a surface of an object comprising a reflective metalized polymeric insulation material having moisture vapour transference properties. An apparatus and methods for producing a reflective metalized polymeric thermally insulating assembly having moisture vapour transference properties are also provided. The insulation material provides enhanced thermal retention. 1. An object having an outer surface comprising a thermally insulating sheet of a reflective metalized polymeric insulation material located adjacent to said outer surface;said reflective metalized polymeric insulation material comprising a first bubble pack assembly including a first thermoplastic film having a plurality of portions wherein each of said portions defines a cavity and a second thermoplastic film in sealed engagement with said first thermoplastic film to provide a plurality of closed-cell cavities;said reflective metalized polymeric insulation material further characterized in having a plurality of frusto-conically shaped apertures suitably sized and interposed between said closed-cell cavities such that said thermally insulating sheet has the narrower dimension of each of said frusto-conically shaped apertures oriented distal to said outer surface so as to effect transference of moisture vapour through said frusto-conically shaped apertures from outer surface without substantial ingress of external air through the apertures, each of said plurality of frusto-conically shaped apertures being defined by a proximal opening and a distal opening with a continuous perimeter aperture wall extending therebetween, said aperture wall being substantially linear and inclined between said proximal opening and said distal opening such that said proximal opening has a greater area than said distal opening; andwherein within any thermally insulating layer of a reflective metalized polymeric insulation material having frusto-conically shaped apertures, the ...

Exterior heat insultation cover panel

An exterior heat insulation cover panel includes a plate member installed on an outer wall surface of an exterior wall of a building to form a heat insulation air layer between the plate member and the outer wall surface and a supporter configured to support the plate member on the outer wall surface in a point contact manner.

NONFLAMMABLE THERMAL INSULATING SHEET, APPARATUS FOR MANUFACTURING SAME, AND METHOD FOR MANUFACTURING SAME

A nonflammable insulating sheet and an apparatus and method for manufacturing the same are disclosed. The disclosed nonflammable insulating sheet includes: a glass fiber fabric having a nonflammable coating layer formed on one side or both sides; an aluminum film arranged on one side of the glass fiber fabric; and another glass fiber fabric arranged on the side of the aluminum film opposite from the glass fiber fabric and having a nonflammable coating layer formed on one side or both sides, where the nonflammable insulating sheet is formed by forming a fire-retardant adhesive layer on both sides of the aluminum film and pressing with the aluminum film arranged between the glass fiber fabrics. 1. A nonflammable insulating sheet comprising:a glass fiber fabric having a nonflammable coating layer formed on one side or both sides thereof;an aluminum film arranged on one side of the glass fiber fabric; andanother glass fiber fabric arranged on a side of the aluminum film opposite from the glass fiber fabric and having a nonflammable coating layer formed on one side or both sides thereof,wherein the nonflammable insulating sheet is formed by forming a fire-retardant adhesive layer on both sides of the aluminum film and pressing with the aluminum film arranged between the glass fiber fabrics.2. The nonflammable insulating sheet according to claim 1 , wherein the aluminum film is an aluminum foil processed by rolling an aluminum material or an aluminum alloy to a predetermined thickness.3. The nonflammable insulating sheet according to claim 1 , wherein the nonflammable coating layer comprises water and melamine cyanurate claim 1 , water-based polyurethane claim 1 , and a surface treatment agent.4. The nonflammable insulating sheet according to claim 1 , wherein the nonflammable coating layer further comprises one or more of melamine and water-based acrylic to provide a smooth surface.5. The nonflammable insulating sheet according to claim 1 , wherein the nonflammable ...

Thermal Insulation System for Non-Vacuum Applications Including a Multilayer Composite

The thermal insulation system of the present invention is for non-vacuum applications and is specifically tailored to the ambient pressure environment with any level of humidity or moisture. The thermal insulation system includes a multilayered composite including i) at least one thermal insulation layer and at least one compressible barrier layer provided as alternating, successive layers, and ii) at least one reflective film provided on at least one surface of the thermal insulation layer and/or said compressible barrier layer. The different layers and materials and their combinations are designed to provide low effective thermal conductivity for the system by managing all modes of heat transfer. The thermal insulation system includes an optional outer casing surrounding the multilayered composite. The thermal insulation system is particularly suited for use in any sub-ambient temperature environment where moisture or its adverse effects are a concern. The thermal insulation system provides physical resilience against damaging mechanical effects including compression, flexure, impact, vibration, and thermal expansion/contraction.

ALVEOLAR MULTILAYER STRUCTURE HAVING A METAL COATING

A multilayer structure is disclosed, comprising: at least one first layer comprising a first polymer film that carries, on a first face, a metal deposit, the first face being a free face of the first layer; and at least one second layer comprising a second polymer film. The second layer is joined, in a plurality of junction zones, to the first layer on the first face carrying the metal deposit, the junction zones defining a region of contact between the first layer and the second layer, the first layer and the second layer forming at least one cell outside the contact region. 1. (canceled)2. A thermally insulating structure comprising:a multi-layer film including a first polymer layer and a metallized layer; anda second polymer layer joined to the multi-layer film by a plurality of disjoint zones, wherein the plurality of disjoint zones cause the second polymer layer to form a set of cells, wherein the multi-layer film forms a bottom of each cell of the set of cells and the second polymer layer forms a top of each cell of the set of cells, wherein an aperture is present in the top of each cell of the set of cells.3. The thermally insulating structure of wherein the second polymer layer includes a plurality of apertures in the top of each cell of the set of cells.4. The thermally insulating structure of wherein the aperture in each cell of the set of cells allows air to flow freely between each cell of the set of cells and an ambient environment.5. The thermally insulating structure of wherein the first polymer layer includes a plurality of apertures in each cell of the set of cells.6. The thermally insulating structure of wherein each cell of the set of cells has a rectangular geometry.7. The thermally insulating structure of wherein the second polymer layer is joined directly to the metallized layer at the plurality of disjoint zones.8. The thermally insulating structure of wherein a surface area of the second polymer layer is greater than a surface area of the ...

HEAT COMPOSITE SYSTEM BASED ON POLYURETHANE RIGID FOAM FOR BUILDING FACADES

The present invention relates to a process for the production of a composite element. The process includes (i) provision of an outer layer with an uncoated surface and a coated surface coated at least partially with a composition (B) including at least one inorganic material, (ii) treatment of the uncoated surface of the outer layer and (iii) application, to the treated surface of the outer layer, of a composition (Z2) suitable for the production of a polyurethane foam and/or polyisocyanurate foam. The present invention further relates to a composite element obtainable or obtained by a process of the invention, and also to the use of a composite element obtainable or obtained by a process of the invention or of a composite element of the invention as insulation material or in the construction of façades. 1. A process for the production of a composite element , the process comprising:i) provision of an outer layer with an uncoated surface and a coated surface coated at least partially with a composition (B) comprising at least one inorganic material;ii) treatment of the uncoated surface of the outer layer; andiii) application, to the outer-layer surface treated in step ii), of a composition (Z2) suitable for the production of a polyurethane foam and/or polyisocyanurate foam,wherein the composition (B) has coated at least 50% of the coated surface of the outer layer, andwherein the composition (B) comprises from 70 to 95% by weight of a pulverulent inorganic material and from 5 to 30% by weight of a binder, based in each case on the entire composition (B), andwherein the outer layer is impermeable to diffusion.2. The process according to claim 1 , wherein the treatment in step ii) is selected from the group consisting of corona treatment claim 1 , plasma treatment claim 1 , flame treatment claim 1 , and application of a composition (Z1) comprising at least one adhesion promoter.3. The process according to claim 1 , wherein the treatment in step ii) comprises ...

INFRARED ATTENUATION AGENT BLENDS

Inorganic infrared attenuation agent blends have been developed to improve the thermal insulation properties of polymeric foams such as polystyrene low density foams. The inorganic infrared attenuation agent blends can include two or more metal oxides such as silicon dioxide, manganese (IV) oxide, iron (III) oxide, magnesium oxide, bismuth (III) oxide, cobalt oxide, zirconium (IV) oxide, molybdenum (III) oxide, titanium oxide, and calcium oxide. In some preferred embodiments, the inorganic infrared attenuation agent blends can include four or more of these metal oxides. 1. A method of preparing an insulating polymer foam having increased thermal resistance comprising the steps of:a) providing a polymer;b) adding an inorganic infrared attenuation agent blend comprising two or more metal oxides selected from the group consisting of silicon dioxide, zirconium (IV) oxide, magnesium oxide, iron (III) oxide, bismuth trioxide, manganese (IV) oxide, calcium oxide, molybdenum trioxide, vanadium pentoxide, and yttrium oxide to the polymer;c) melting the polymer to form a polymer melt; andd) extruding the polymer melt to form an insulating polymer foam,wherein the inorganic infrared attenuation agent blend is present in an amount from about 0.1 to about 3 wt. %, based upon the total weight of the insulating polymer foam.2. The method of claim 1 , wherein the infrared attenuation agent blend comprises two or more metal oxides selected from the group consisting of silicon dioxide claim 1 , manganese (IV) oxide claim 1 , iron (III) oxide claim 1 , bismuth (III) oxide claim 1 , cobalt oxide claim 1 , zirconium (IV) oxide claim 1 , molybdenum (III) oxide claim 1 , titanium oxide claim 1 , and calcium oxide.3. The method of claim 1 , wherein the infrared attenuation agent blend comprises four or more metal oxides selected from the group consisting of silicon dioxide claim 1 , manganese (IV) oxide claim 1 , titanium oxide claim 1 , and iron (III) oxide.4. The method of claim 1 , ...

FOIL-WRAPPED VACUUM INSULATION ELEMENT

The invention is directed to a foil-wrapped vacuum insulation element having a core and an air-tight shell surrounding the core. One or more layers of paper, cardboard, and/or paperboard are also provided between the core and the shell, and these layers completely envelop the core, preferably in a powder-tight manner. 1. A foil-wrapped vacuum insulation element having a core and an air-tight shell surrounding the core , characterized in that one or more layers of paper , cardboard , and/or paperboard are also provided between the core and the shell , and these layers completely envelop the core , preferably in a powder-tight manner.2. The foil-wrapped vacuum insulation element according to claim 1 , characterized in that a single layer of paper or cardboard has a grammage of 40 g/mor more claim 1 , for example 50 g/mor more claim 1 , preferably 60 g/mor more claim 1 , in particular 80 g/mor more claim 1 , or even 100 g/mor more.3. The foil-wrapped vacuum insulation element according to claim 1 , characterized in that a single layer of paper or cardboard has a grammage of 250 g/mor less claim 1 , for example 225 g/mor less claim 1 , preferably 200 g/mor less claim 1 , in particular 175 g/mor less claim 1 , or even 150 g/mor less.4. The foil-wrapped vacuum insulation element according to claim 1 , characterized in that multiple claim 1 , preferably three claim 1 , layers of paper and/or cardboard are provided.5. The foil-wrapped vacuum insulation element according to claim 1 , characterized in that at least one paper layer is joined claim 1 , preferably glued claim 1 , to one or two adjoining paper layers to form a single layer.6. The foil-wrapped vacuum insulation element according to claim 1 , characterized in that at least one of multiple paper or cardboard layers claim 1 , preferably an inner paper or cardboard layer claim 1 , has a corrugated profile.7. The foil-wrapped vacuum insulation element according to claim 4 , characterized in that a total of three paper ...

COMPOSITE MATERIALS WITH TAILORED ELECTROMAGNETIC SPECTRAL PROPERTIES, STRUCTURAL ELEMENTS FOR ENHANCED THERMAL MANAGEMENT, AND METHODS FOR MANUFACTURING THEREOF

Disclosed is a method to produce composite materials, which contain customized mixes of nano- and/or micro-particles with tailored electromagnetic spectral properties, structural elements based thereon, in particular layers, but also bulk materials including inhomogeneous bulk materials. In some embodiments the IR-reflectivity is enhanced predominantly independently of reflectivity for visible wavelength. The enhanced IR-reflectivity is achieved by combining spectral properties from a plurality of nano- and/or micro-particles of distinct size distribution, shape distribution, chemical composition, crystal structure, and crystallinity distribution. This enables to approximate desired target spectra better than know solutions, which comprise only a single type of particles and/or an uncontrolled natural size distribution. Furthermore disclosed are methods of manufacturing such materials, including ceramics, clay, and concrete, as well as applications related to design and construction of buildings or other confined spaces. 132-. (canceled)33. A method , comprisingmeasuring a broadband spectral reflectance within the visible (VIS) and Near Infrared (NIR) range at one or more locations within the vicinity of an object;providing a plurality of distinct populations of nano- or micro-particles and/or of nano- or micro-cavities, a first population of said plurality of distinct populations comprising distinct size distributions, shape distributions, chemical compositions, crystal structures, and crystallinity distributions, relative to a second population of said plurality of distinct populations;forming a composite material comprising a. mixture of the first population and the second population in a carrier material, the composite material having a selected composition ratio of the first population to the second population, and a selected density of the mixture relative to a carrier material such that resulting broadband spectral reflectance of said composite material ...

BUILDING INSULATION SYSTEM

The building insulation system includes a reflective, non-porous bag filled with thermal insulation material. The covering of the bag is made from reflective polymeric facer or plastic, which facilitates reflection of thermal energy radiation. The reflective non-porous bag provides a thermal barrier for conduction, convection and radiation aspects of thermal energy transfer. 1. A building insulation system , comprising at least one bag having:a reflective, non-porous single ply outer covering disposed over the entire bag;only one type of insulation material disposed inside the at least one bag, whereby, the bag provides a thermal barrier for conduction, radiation and convection factors of thermal energy transfer;a pair of adjacent studs in a building; andthe at least one bag installed between the pair of adjacent studs, wherein the non-porous integrity of the at least one bag is maintained.2. The building insulation system according to claim 1 , wherein said non-porous outer covering comprises reflective polymeric plastic material for reflecting thermal energy.3. The building insulation system according to claim 2 , wherein said reflective polymeric plastic material comprises polymeric sheet material with reflective metal mixed therein.4. The building insulation system according to claim 1 , wherein said insulation material comprises at least one material selected from a group consisting of fiberglass claim 1 , cellulose claim 1 , rockwool claim 1 , expanded polystyrene claim 1 , and recycled materials.5. The building insulation system according to further comprising a wrap for capping a cut end of said bag.6. The building insulation system according to claim 5 , further comprising at least one adhesive strip for sealing said wrap around said cut end of said bag.7. The building insulation system according to claim 1 , wherein said non-porous outer covering comprises reflective polymeric plastic material for reflecting thermal energy claim 1 , the system further ...

INSULATED SHEATHING PANEL AND METHODS FOR USE AND MANUFACTURE THEREOF

Insulated wall and roof sheathing systems for use in building construction designed to provide moisture permeable wall panels that protect from bulk water, excess air, and thermal transfer. 120-. (canceled)22. The system of claim 21 , wherein the insulation layer is foam insulation comprising polyisocyanurate foam claim 21 , polystyrene foam claim 21 , polyurethane foam claim 21 , or a combination thereof.23. The system of claim 21 , wherein the insulation layer has a density in the range of about 1 to about 20 pounds per cubic feet (pcf) according to ASTM D1622.24. The system of claim 21 , wherein the insulation layer has a water absorption of less than about 10% according to ASTM C209 or ASTM C2842.25. The system of claim 21 , wherein the insulation layer has a water vapor permeance from about 0.1 to about 20 perms as determined according to ASTM E96.26. The system of claim 21 , wherein the insulation layer has a thickness of about 0.25 in. to about 3 in.27. The system of claim 21 , wherein the system exhibits a thermal resistance value (R-value) from about 1 to about 15 according to ASTM C1289-02.28. The system of claim 21 , wherein the insulation layer further comprises a membrane layer.29. The system of claim 28 , wherein the insulation membrane layer comprises radiant barrier material claim 28 , polymeric film claim 28 , polymeric fabric claim 28 , paper claim 28 , cellulosic material claim 28 , reinforcing scrim claim 28 , or a combination thereof.30. The system of claim 21 , wherein the insulation layer is secured to the panel using an adhesive selected from a phenol-formaldehyde resin claim 21 , hot-melt adhesive claim 21 , polyvinyl acetate (PVA) resin claim 21 , or a combination thereof.31. The system of claim 21 , wherein the insulation layer has a dimensional stability of about less than 5% according to ASTM D2126.32. The system of claim 21 , wherein the insulation layer has a compressive strength of at least about 5 pounds per square inch (psi) ...

HIGH THERMAL RESISTANCE AND PERMEANCE INSULATION MATERIAL

A low-emittance material having improved energy efficiency protection against air infiltration and moisture build-up in buildings is disclosed. The aforementioned low-emittance material utilizes existing framing openings or without increasing the wall profile of a building. The present invention provides a low-emittance material which may be implemented on traditional 2×4 framing having R-15 mass insulation material within existing or newly constructed framing cavities. The material of the present invention also meets requirements for serving as a water resistive barrier as defined by ICC AC38. 125-. (canceled)26. A reflective insulation , comprising:a first layer and a second layer;the first layer being a reflective layer that reflects radiant heat; andthe second layer being an insulating layer having a side adjoined to the first layer by flame lamination or heat roller lamination to bond directly or indirectly the first layer and the second layer together.27. The reflective insulation of claim 26 , further comprising a third layer being a reflective layer that reflects radiant heat claim 26 , where another side of the second layer is adjoined to the third layer by flame lamination or heat roller lamination.28. The reflective insulation of claim 26 , further comprising a third layer including a polyolefin claim 26 , where another side of the second layer is adjoined to the third layer by flame lamination or heat roller lamination.29. The reflective insulation of claim 27 , wherein the third layer includes polyethylene.30. The reflective insulation of claim 28 , further comprising a plurality of perforations through both the first layer and through the second layer claim 28 , the perforations providing the reflective insulation to have a permeance and water vapor transmission between about 5 to about 20 perm.31. The reflective insulation of claim 30 , where the perforations are formed from punchers having a diameter to prevent the perforations from resealing.32. The ...

AEROGEL LAMINATE AND THERMAL INSULATION MATERIAL

The present invention relates to an aerogel laminate having a structure in which an aerogel layer and a support having a heat ray reflective function or a heat ray absorbing function are laminated. 2. The production method according to claim 1 , wherein the aerogel layer is a layer containing an aerogel having a structure derived from polysiloxane.3. The production method according to claim 1 , wherein the aerogel layer is a layer prepared by drying a wet gel formed from a sol containing at least one selected from the group consisting of polysiloxane compounds having a reactive group in the molecule and hydrolysis products of the polysiloxane compounds.4. The production method according to claim 1 , wherein the aerogel layer is a layer prepared by drying a wet gel formed from a sol containing silica particles.5. The production method according to claim 4 , wherein an average primary particle diameter of the silica particles is 1 nm or more and 500 nm or less.6. The production method according to claim 1 , wherein the support has a layer composed of a material comprising at least one selected from the group consisting of carbon graphite claim 1 , aluminum claim 1 , magnesium claim 1 , silver claim 1 , titanium claim 1 , carbon black claim 1 , metal sulfates claim 1 , and antimony compounds.7. The production method according to claim 1 , wherein the support is an aluminum foil claim 1 , an aluminum deposited film claim 1 , a silver deposited film claim 1 , or an antimony oxide containing film.8. The production method according to claim 1 , wherein the aerogel layer has a thickness of 1 to 200 μm. This application is a divisional application of U.S. Ser. No. 15/546,763 filed Jul. 27, 2017, which is a U.S. national phase application filed under 35 U.S.C. § 371 of International Application PCT/JP2016/052182, filed on Jan. 26, 2016, designating the United States, which claims benefit of the filing date of JP 2015-013056, filed Jan. 27, 2015, which is hereby incorporated ...

Web Frame

The web frame is a bonded assembly of panels and porous blanket layers, separated by an arrangement of isolated spacers. The panels and spacers are covered with a bonding means. A coating covers inner surfaces of the panels and spacers. The porous blanket is compressed and pinned between these panels, by spacers that are arranged as isolated nodes or columns The spacers have sharpened ends that penetrate the blanket and connect with the opposing panel. The web frame assembly provides thermal and sound insulation for buildings and other solid objects. These web frames are lightweight, durable, and permeable. Capillaries and passages throughout the panels and fibres of the blanket allow passage of moisture and air, thereby assisting in the management of condensation within the web frame. 138-. (canceled)39. A web frame , being an assembly of stacked , bonded materials , the web frame comprising:an inner panel having an inner surface and an outer surface;an opposing panel disposed parallel to and apart from the inner panel to form a open space therebetween, the opposing panel having an inward surface adjacent the open space;a plurality of spacers in the open space between the inner panel and the opposing panel to maintain the open space therebetween;a first surface covering bonded to the inner surface of the inner panel; anda second surface covering bonded to the inward surface of the opposing panel.40. The web frame according to claim 39 , wherein the opposing panel is an outer panel claim 39 , the outer panel is made from a resilient claim 39 , durable material.41. The web frame according to claim 39 , wherein the opposing panel is an inner panel of an adjacent web frame claim 39 , wherein the inner panel is made from a resilient claim 39 , flexible claim 39 , durable material.42. The web frame according to claim 39 , wherein the plurality of spacers are integral with the inner panel and are covered by and bonded to the first surface covering.43. The web frame ...

STRUCTURAL INSULATED SHEATHING PANEL AND METHODS OF USE AND MANUFACTURE THEREOF

Structural insulated wall and roof sheathing systems for use in building construction designed to provide a structural building envelope that is moisture permeable but protects from bulk water, excess air, and thermal transfer. 2. The system of claim 1 , wherein the insulation layer of each panel assembly is foam insulation comprising polyisocyanurate foam claim 1 , polystyrene foam claim 1 , polyurethane foam claim 1 , or a combination thereof.3. The system of claim 1 , wherein the insulation layer of each panel assembly has a density in the range of about 1 to about 20 pounds per cubic feet (pcf) according to ASTM D1622.4. The system of claim 1 , wherein the insulation layer of each panel assembly has a water absorption of less than about 10% according to ASTM C209 or ASTM C2842 and a water vapor permeance from about 0.1 to about 20 perms as determined according to ASTM E96.5. The system of claim 1 , wherein in use the installed structural sheathing and insulating system exhibits a thermal resistance value (R-value) from about 1 to about 15 according to ASTM C1289-02.6. The system of claim 1 , wherein the insulation layer of each panel assembly is secured to the respective structural panel by an adhesive selected from a phenol-formaldehyde resin claim 1 , hot-melt adhesive claim 1 , polyvinyl acetate (PVA) resin claim 1 , or a combination thereof.7. The system of claim 1 , wherein the insulation layer of each panel assembly has a dimensional stability of about less than 5% according to ASTM D2126.8. The system of claim 1 , wherein the insulation layer of each panel assembly has a compressive strength of at least about 5 pounds per square inch (psi) according to ASTM D1621.9. The system of claim 1 , wherein the insulation layer of each panel assembly has a tensile strength of greater than about 300 pounds per cubic foot (pcf) according to ASTM D1623.10. The system of claim 1 , wherein the structural panel and the reinforcing layer of each panel assembly are made of ...

Composite materials with tailored electromagnetic spectral properties, structural elements for enhanced thermal management, and methods for manufacturing thereof

Disclosed is a method to produce composite materials, which contain customized mixes of nano- and/or micro-particles with tailored electromagnetic spectral properties, structural elements based thereon, in particular layers, but also bulk materials including inhomogeneous bulk materials. In some embodiments the IR-reflectivity is enhanced predominantly independently of reflectivity for visible wavelength. The enhanced IR-reflectivity is achieved by combining spectral properties from a plurality of nano- and/or micro-particles of distinct size distribution, shape distribution, chemical composition, crystal structure, and crystallinity distribution. This enables to approximate desired target spectra better than know solutions, which comprise only a single type of particles and/or an uncontrolled natural size distribution. Furthermore disclosed are methods of manufacturing such materials, including ceramics, clay, and concrete, as well as applications related to design and construction of buildings or other confined spaces.

Method to Meter a Thermal Barrier Upon a Surface

A manner by which to form a thermal barrier upon a surface, utilizes a pneumatic blower to form a layer of thermal insulation material and a layer of radiant barrier material. The pneumatic blower is first charged with the thermal insulation material, and the thermal insulation material is metered upon the surface. Then, the pneumatic blower is charged with the radiant barrier material, and the radiant barrier material is metered upon the thermal insulation material. 119-. (canceled)20. A method for installing a thermal barrier upon a surface , said method comprising:charging a pneumatic blower with processed pieces of thermal insulation material;pneumatically metering the processed pieces of the thermal insulation material to form a thermal insulation layer upon the surface; thereaftercharging the pneumatic blower with the processed pieces of radiant barrier material; andpneumatically metering the processed pieces of the radiant barrier material to form a radiant barrier layer upon the thermal insulation layer; wherein the pieces of radiant barrier are deposited on the pieces of the thermal insulation material such that the pieces of radiant barrier settle at varying angles thereby mitigating degradation of the reflective properties of the radiant barrier layer due to dust.21. The method of wherein the radiant barrier material reflects more than the thermal insulation material.22. The method of wherein the radiant barrier material emits less than the thermal insulation.23. The method of wherein the radiant barrier material comprises aluminum foil.23. The method of wherein the aluminum foil comprises loose bits and pieces of aluminum foil.24. The method of wherein the radiant barrier material comprises low emissivity (low-e) material.25. The method of wherein the low-e material comprises foil material.26. The method of wherein the foil material comprises aluminum foil.27. A method for installing a thermal barrier upon a surface claim 25 , said method comprising: ...

Insulation Material Arrangement And Method For Forming An Insulation Material

A material arrangement ( 10 ) for insulating a building structure ( 50 ) in an installed condition, the material arrangement ( 10 ) including first and second flexible polymer foam layers ( 12 ) and a flexible phase change material layer ( 16 ) between the first and second flexible polymer foam layers ( 12 ), and at least one flexible reflective layer ( 14 ) extending over at least one of the first and second flexible polymer foam layers ( 12 ). A method of forming and installing such a material arrangement ( 10 ) is also disclosed.

Rooftop Heat Reflector System

A roof reflector system that is used to reflect solar radiation away from a rooftop. The system uses lines of flags that are strung across the rooftop in parallel rows. Each line of flags contains a plurality of flags that are aligned side-by-side. The flags are reflective to solar radiation. A common ribbon joins the flags into a line of flags. The base of each flag is coupled to the ribbon so that the flags hang away from the bottom edge of the ribbon. Brackets are provided that that can be selectively mounted to the roof. Each of the brackets has a connector that receives and retains the ribbon, therein supporting the ribbon at a first elevation above the roof. The length of each of the flags is greater than that first elevation. As a result, the flags touch the roof and fold along the roof, therein shielding the roof from the heat of the sun. 1. A roof reflector system comprising:a plurality of flags, wherein each of said plurality of flags has a base, a length, and exterior surfaces along said length that are reflective to solar radiation;a common ribbon having a top edge and a bottom edge, wherein said base of each of said plurality of flags are coupled to said ribbon so that said length of each of said plurality of flags hang away from said bottom edge of said ribbon;a plurality of brackets that can be selectively mounted to a roof, wherein each of said plurality of brackets has a connector that receives and retains said ribbon, therein supporting said ribbon at a first elevation, wherein said length of each of said plurality of flags is greater than said first elevation.2. The system according to claim 1 , wherein each of said plurality of flags has side edges along said length claim 1 , wherein said side edges between each of said plurality of flags are in direct abutment when hanging from said ribbon.3. The system according to claim 1 , wherein each of said plurality of flags has side edges along said length claim 1 , wherein said side edges between each ...

COMPOSITE MATERIAL FOR PASSIVE RADIATIVE COOLING

A composite material for passive radiative cooling including a base layer, and at least one emissive layer located adjacent to a surface of the base layer, wherein the at least one emissive layer is affixed to the surface of the base layer via a binding agent. Also disclosed are methods of applying passive coolers to articles and surfaces to be adapted for passive radiative cooling. 152-. (canceled)53. A method of providing a composite material for passive radiative cooling to a roof surface , said method comprising:applying to said roof surface a liquid suspension of microparticles in a liquid binding agent andcuring said binding agent so as to form a thermally-emissive layer on said roof surface, whereby said thermally-emissive layer is affixed to said roof surface via said binding agent.54. The method of claim 53 , wherein said object comprises a base layer to which said liquid suspension is applied claim 53 , said base layer comprising a reflective substrate.55. The method of claim 54 , wherein said reflective substrate is composed of at least one of aluminum claim 54 , silver claim 54 , glass claim 54 , polyurethane claim 54 , nylon claim 54 , and polyethylene fibers.56. The method of claim 54 , wherein said reflective substrate comprises paint.57. The method of claim 53 , wherein said binding agent is composed of a polymer material.58. The method of claim 53 , wherein said binding agent is transparent.59. The method of claim 53 , wherein said binding agent includes a characteristic thickness less than or equal to approximately 50 μm.60. The method of claim 53 , wherein said at least one emissive layer is composed of silica material.61. The method of claim 53 , wherein said at least one emissive layer comprises a plurality of microparticles.62. The method of claim 61 , wherein each of said plurality of microparticles is composed of silica material.63. The method of claim 61 , wherein each of said plurality of microparticles includes a characteristic dimension ...

Ventilated and draining foam insulation panel for building construction

A method for facilitating ventilation and/or drainage in a building wall, floor, and/or roof by the step of: placing a foam insulation board with an interior board face and an exterior board face, at least one board face having ventilation and/or drainage grooves and/or protrusions into the building wall, floor, and/or roof; providing vents in the building wall, floor, and/or roof adjacent end portions of the insulation board, whereby ventilation is facilitated within the wall, floor, and/or roof of the building by air moving through the vents, along the grooves and/or protrusions of the foam insulation board, and out of the vents, drainage of water is facilitated within the wall or the roof of the building by a pathway created by the grooves and/or protrusions, and moisture removal is facilitated by the passage of air during ventilation.

THERMAL INSULATING COATING FILM AND THERMAL INSULATING PAINT COMPOSITION

To provide a thermal insulating coating film, which can achieve excellent thermal insulating performance and far-infrared ray reflection performance when formed on, for example, the surface of an outer wall or inner wall of a house and which has excellent adhesiveness and durability. The thermal insulating coating film of the present invention contains a styrene-alkyl acrylate copolymer or a butyl acrylate-styrene copolymer, a white pigment, and hollow acrylic beads. The mass ratio of styrene-alkyl acrylate copolymer or butyl acrylate-styrene copolymer and hollow acrylic beads (hollow acrylic beads/styrene-alkyl acrylate copolymer or butyl acrylate-styrene copolymer) is 1 or less. 1. A thermal insulating coating film , comprising a styrene-alkyl acrylate copolymer or a butyl acrylate-styrene copolymer , a white pigment , and hollow acrylic beads , wherein the mass ratio of the styrene-alkyl acrylate copolymer or the butyl acrylate-styrene copolymer and the hollow acrylic beads (the hollow acrylic beads/the styrene-alkyl acrylate copolymer or the butyl acrylate-styrene copolymer) is 1 or less.2. The thermal insulating coating film according to claim 1 , comprising 45 to 85 parts by mass of the hollow acrylic beads with respect to 100 parts by mass of the styrene-alkyl acrylate copolymer or the butyl acrylate-styrene copolymer.3. The thermal insulating coating film according to claim 1 , comprising 60 to 70 parts by mass of the hollow acrylic beads with respect to 100 parts by mass of the styrene-alkyl acrylate copolymer or the butyl acrylate-styrene copolymer.4. The thermal insulating coating film according to claim 1 , wherein the white pigment is rutile titanium dioxide claim 1 , the rutile titanium dioxide is contained in an amount of 74 to 143 parts by mass with respect to 100 parts by mass of the styrene-alkyl acrylate copolymer or the butyl acrylate-styrene copolymer claim 1 , and the rutile titanium dioxide has an average particle diameter of 0.1 to 10 mm.5. ...

Waterproofing membrane

防水膜

本发明公开了一种防水膜，所述防水膜包括载体片、在该载体片一个表面上的压敏黏合剂层，和在该黏合剂层上的保护涂层。所述保护涂层包括高度反射的保护涂层以有效黏合向其浇注的混凝土，特别是由包含丙烯酸类乳液、填料和白色颜料的水性涂料制得的保护涂层。所述填料加上白色颜料的颜料体积浓度按体积计大于或等于55%。该保护涂层保护该膜免受气候的侵蚀、适合行走并牢固粘附于向其浇注的混凝土。另外本发明公开了一种包括载体片、压敏黏合剂层、保护涂层和高度可剥离性黏合层的防水膜。该优选的高度可剥离性黏合层包含纳米级二氧化硅和黏合剂。

Multi functional adiabatic material

본 고안은 부직포 양면에 방습필름을 부착하여 외부로부터 발생되는 습기가 실내 측으로 전달되는 현상이나 결로현상을 방지할 수 있고, 부직포의 재활용이 가능하게 한 다기능 단열재에 관한 것으로, 본 고안의 바람직한 실시예에 따른 다기능 단열재는 결로 및 습기를 흡수할 수 있도록 구비된 부직포; 상기 부직포의 양면에 부착되며, 상기 부직포에서 흡수된 습기가 내측으로 전달되지 않도록 구비된 방습필름; 상기 방습필름에 각각 부착되어 열의 전달을 차단하는 PE폼; 그리고 상기 PE폼에 각각 부착되어 PE폼을 보호하고, 복사열을 차단하는 외측필름을 포함하여 이루어짐이 바람직하다. The present invention is attached to the non-woven fabric on both sides of the moisture-proof film to prevent the phenomenon or condensation that is transferred to the indoor side moisture, and relates to a multi-functional insulating material that enables the recycling of the nonwoven fabric, preferred embodiment of the present invention Multifunctional insulation according to the non-woven fabric provided to absorb condensation and moisture; A moisture proof film attached to both sides of the nonwoven fabric and provided to prevent moisture absorbed from the nonwoven fabric from being transferred to the inside; PE foam attached to each of the moisture-proof film to block the transfer of heat; And it is preferably made to include an outer film is attached to each of the PE foam to protect the PE foam, blocking the radiant heat. 방습, 재활용, 부직포 Moisture-Proof, Recycled, Non-Woven

Insulated sheathing panel and methods for use and manufacture thereof

Insulated wall and roof sheathing systems for use in building construction designed to provide moisture permeable wall panels that protect from bulk water, excess air, and thermal transfer.

Heat reflection insulation

본 고안은 열반사 단열재를 개선하여 외부로부터 전도되는 복사열이나 외부열기의 용이한 차단은 물론, 내부의 열기가 외부로 유출되는 것을 방지할 수 있도록 한 열반사 단열재에 관한 것으로서, The present invention relates to a heat reflection insulation material to improve the heat reflection insulation material to facilitate the easy blocking of radiant heat or external heat conducted from the outside, as well as to prevent the internal heat from leaking to the outside, 건축물의 외벽에 시공되어 외부 열기의 유입을 차단하고 내부 열기의 유출을 차단하는 것이 열반사 단열재(50)를 구성함에 있어서; It is constructed on the outer wall of the building to block the inflow of external heat and to block the outflow of the internal heat in configuring the heat reflection insulating material (50); 상기 열반사 단열재(50)는 보온성과 형체안정성이 좋은 부직포 재질로 형성하는 1단열층(51)과; The heat reflection insulating material 50 is one insulation layer 51 formed of a non-woven material having good heat retention and mold stability; 상기 1단열층(51)의 일면에 방음성과 단열성, 완충성 및 내화학적 특성을 가지는 발포가교 재질로 형성하여 접착하는 2단열층(52)과; A second insulating layer 52 formed on one surface of the first insulating layer 51 and bonded to a foamed crosslinked material having sound insulation, heat insulating property, buffering property, and chemical resistance property; 상기 2단열층(52)의 다른 면에 베이스시트(53)에 많은 수의 에어셀(Air Cell;54,55)을 구비하여 에어셀(54,55)에 존재하는 공기에 의하여 내,외부 열기의 유입과 유출을 차단할 수 있도록 하는 3단열층(56)과; On the other side of the second insulating layer 52 is provided with a large number of air cells 54, 55 in the base sheet 53, the inflow of internal and external heat by the air present in the air cells 54, 55 and A third insulating layer 56 to block outflow; 상기 1단열층(51)과 3단열층(56)의 외면에 복사열의 차단할 수 있도록 반사성이 우수한 알미늄시트(57)를 부착하여 구성하는 것이 특징이다. An aluminum sheet 57 having excellent reflectivity is attached to the outer surfaces of the first insulation layer 51 and the third insulation layer 56 so as to block radiant heat. 열반사, 단열재 Heat reflection, insulation

Finishing structure for house inside wall

PURPOSE: An internal wall finishing structure is provided to adsorb and purify toxic gas generated from offensive odors, organic compounds, cement, and concrete. CONSTITUTION: An internal wall finishing structure(100) comprises an insulation layer(102), multiple supporters(103), adsorption layers(104), a finishing layer(105), and purification spaces(B). The insulation layer is attached on an internal wall(101). The supporters are fixed to the inner surface of the insulation layer. The adsorption layers are formed between the supporters. The finishing layer is formed on the inner surface of the supporters and has sterilization and mold removal functions. The purification spaces are formed between the adsorption layers and the finishing layer.

High-efficiency flame-processed heat-insulating panel for buildings roofs

FIELD: construction. SUBSTANCE: invention relates to construction, in particular, to building roof panels. Flame-treated heat insulation panel for roofs of buildings is presented, consisting of a layer of a heat-insulating material made of rigid polyurethane foam (PUF) or another equivalent material and, in particular, preferably from polyisocyanurate. Panel consists of an intermediate insulating layer, preferably in the form of a parallelepiped with flat surfaces, moreover, the above-mentioned intermediate insulating layer on at least two opposite surfaces, characterized by a larger surface area, provides a multilayer coating consisting of at least the following layers: a) one layer of metallized polyester film; b) one layer of plastic film; c) one layer of waterproof paper; d) one film layer based on a bitumen compound; e) one layer of non-woven polypropylene fabric. EFFECT: technical result consists in heat loss reduction of a building. 11 cl, 3 dwg РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (13) 2 683 734 C2 (51) МПК E04D 3/35 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ОПИСАНИЕ ИЗОБРЕТЕНИЯ К ПАТЕНТУ (52) СПК E04D 3/35 (2018.08) (21)(22) Заявка: 2017128449, 15.01.2015 (24) Дата начала отсчета срока действия патента: 01.04.2019 Приоритет(ы): (22) Дата подачи заявки: 15.01.2015 (43) Дата публикации заявки: 15.02.2019 Бюл. № 5 (56) Список документов, цитированных в отчете о поиске: FR 1362853 A, 05.06.1964. DE 2 6 8 3 7 3 4 Дата регистрации: (73) Патентообладатель(и): АЙВИС ИНСУЛЕЙТИОН ВАТЕРПРУФИНГ ИНДАСТРИАЛ СИСТЕМС С.Р.Л. (IT) R U 15.01.2015 (72) Автор(ы): МАЗЗЕР Лучиано (IT) 1559358 A1, 21.08.1969. CH 202787536 U, 13.03.2013. SU 661083 A1, 05.05.1979. (45) Опубликовано: 01.04.2019 Бюл. № 10 (85) Дата начала рассмотрения заявки PCT на национальной фазе: 15.08.2017 IB 2015/000025 (15.01.2015) C 2 C 2 (86) Заявка PCT: (87) Публикация заявки PCT: R U 2 6 8 3 7 3 4 WO 2016/113581 (21.07.2016) Адрес для переписки: 121069, Москва, Хлебный пер., 19Б, пом. ...

Exterior insulation panel

Multi-layer coating film and method for forming multi-layer coating film

Shear panel building material

A shear panel building material that includes a first facing membrane, a core matrix disposed on a face of the first facing membrane, and a semi-rigid or rigid material attached to the core matrix. The core matrix can include microspheres having a size of about 200 microns to about 800 microns, sodium silicate, and ethylene vinyl acetate. In one aspect, the shear panel is substantially free from glue and cement.

Insulating composite materials and methods for producing and using same

A composite material wherein one or more backing materials are disposed in generally contiguous relation to an insulating material. Methods for forming composite materials comprising securing one or more backing materials to an insulating material such that the backing materials are in generally contiguous relation to the insulating material. Methods for using the composite materials of the present invention wherein a structure is wrapped with a composite material of the present invention.

Insulating composite materials and methods for producing and using same

A composite material wherein one or more backing materials are disposed in generally contiguous relation to an insulating material. Methods for forming composite materials comprising securing one or more backing materials to an insulating material such that the backing materials are in generally contiguous relation to the insulating material. Methods for using the composite materials of the present invention wherein a structure is wrapped with a composite material of the present invention.

Heat resistant insulation composite, and method for preparing the same

本发明提供一种耐热绝缘复合物，它包括(a)绝缘基层和(b)热反射层，该绝缘基层包括中空非多孔颗粒和基体粘结剂，热反射层包括红外反射剂和保护粘结剂，其中耐热绝缘复合物具有导热性约50mW/(m－K)或更低。本发明还提供一种制备耐热绝缘复合物的方法。

Exterior insulation finish

본 발명은 외벽단열 마감재에 관한 것으로서, 보다 상세히는 건물이나 구조물 외벽에 스프레이 타입으로 도포하는 외벽 단열 마감재에 있어서, 팽창 질석과 아크릴 에멀젼을 교반 혼합하는 외벽 단열 마감재에 관한 것이다. 본 발명은 건물이나 구조물 외벽에 스프레이 타입으로 도포하는 외벽 단열 마감재에 있어서, 팽창 질석가루와; 아크릴 에멀젼을 혼합하되, 상기 팽창 질석가루와 아크릴 에멀젼은 중량기준으로 1~3:1로 교반 혼합하는 것을 특징으로 하는 외벽 단열 마감재이다. 본 발명의 모든 소재 성분이 무기질 소재로 구성되어, 인체 유해성이 없어 친환경적이며, 단열효과가 뛰어나, 외벽에 2-3mm만 도포하여도 샌드위치 판넬 200mm와 동등한 단열효과를 가지며, 내화성, 불연성 및 내부식성이 강하여, 샌드위치 판넬에 1~2mm 만 도포하여도 1200℃화염에 5분 이상 노출되어도 화염전파가 발생하지 않으며, 본 발명의 아크릴 에멀젼 접착력은 우수하여, 시멘트, 목재, 철재, 흙벽 및 유리소재에도 강한 접착력을 보이며, 외부온도에 구애 없이 외부에 노출된 상태에서 장기간 접착력을 유지할 수 있다.

Fireproof outer wall finishing method

본 발명은 습식 불연 외장 단열 마감 공법에 관련되며, 이때 습식 불연 외장 단열 마감 공법은 불연 단열패널을 접착 모르타르와 고정구를 이용하여 이중 구조로 고정됨과 더불어 결로수 배출라인에 의해 건물 외벽 및 불연 단열패널 내벽을 타고 내리는 결로수를 포집처리하므로 수분에 의한 불연 단열패널 변형 및 곰팡이를 포함하는 세균 번식, 오염 방지는 물론 태풍, 지진에 의한 외력 및 접착력 저하로 인한 탈락현상이 방지되며, 또 불연 단열패널 사이 열교 현상이 긴밀하게 차단되어 단열성능이 향상되며, 특히 화재 시 유독가스 방지와 더불어 건물 외벽을 통한 불길 확산을 미연에 차단하여 비상 대피 시간을 확보하면서 질식사로 인한 대형 인명 피해를 최소화 하기 위해 불연 단열패널(100)을 제조하는 단계(S1), 결로수 배출라인(10)을 시공하는 단계(S2), 불연 단열패널(100)을 건물 외벽(1)에 시공하는 단계(S3), 고정구(200)를 체결하여 고정하는 단계(S4)를 포함하여 주요구성으로 이루어진다.

Building insulation

본 고안은 건축용 단열재에 관한 것으로서 투명PET필름이 접착된 알미늄은박지와 부직포를 합성수지로 접착하여 수지접착층이 형성되게 하고 부직포와 발포 PE수지를 열접착하고 알미늄은박지에 엠보싱을 형성하여 생산성이 높고 견고하면서 수명이 길고 단열 및 방음효과가 높도록 한 것이다. The present invention relates to a heat insulating material for building, and the transparent PET film is bonded to the aluminum silver foil and the non-woven fabric with a synthetic resin to form a resin adhesive layer, heat-bonding the non-woven fabric and the foamed PE resin, and the aluminum silver foil is embossed to form a high productivity and firm Long life and high insulation and sound insulation.

Construction method for waterproof material with thermal shield function and structure constructed by same

The present invention provides a method for constructing a heat insulating and waterproofing material, which has excellent heat insulating and waterproofing performance so that energy can be saved and durability can be improved. According to the present invention, provided is the heat insulating and waterproofing method, which includes the following steps of: applying the heat insulating and waterproofing material to a surface of an object to be applied; attaching fiber sheets onto a surface of the heat insulating and waterproofing material; attaching glass fiber to a joint between the fiber sheets; and applying the heat insulating and waterproofing material onto surfaces of the fiber sheets and the glass fiber at least once.

Structure of material for selectively absorbing and reflecting solar thermal radiation

本发明公开了一种对太阳热辐射选择性吸收与反射材料的构造，其结构如下：a根据建筑所在区域的纬度以及建筑表面的放置方位，计算出太阳入射角的范围。b根据太阳入射角的范围以及玻璃微珠的直径计算出玻璃微珠上光线入射的范围及界限，将玻璃微珠等分为两个半球形区域，其中一个区域涂布涂层，另一个区域不做处理。c根据计算结果，玻璃微珠的相应区域涂布热反射涂层，剩余部分涂布热吸收涂层。d涂覆完成后，将涂有反射涂层的玻璃微珠固定在基层上。本发明既能够减少建筑在夏季的太阳辐射得热，减少室内冷负荷，同时又能增大建筑在冬季通过太阳辐射获得的热量，减少室内热负荷，有效的降低了建筑能耗，且具有原理简单，可操作性强的优点。

Heat insulating material for building

본 고안은 건축용 단열재에 관한 것으로, 더욱 상세하게는 단열재의 표면 측에 구성된 제1알루미늄층 이외에, 단열재의 내부에 제2알루미늄층을 구성하고, 제2알루미늄층의 양측에 코팅 방습층을 코팅하고, 성형강화제층을 포함하는 건축용 단열재에 관한 것이다. The present invention relates to a building heat insulating material, and more particularly, in addition to the first aluminum layer formed on the surface side of the heat insulating material, a second aluminum layer is formed inside the heat insulating material, and the coating moisture proof layer is coated on both sides of the second aluminum layer, The present invention relates to a building insulation material comprising a molding reinforcement layer. 본 고안은 건축물의 벽면에 시공되는 단열재에 있어서, 단열재의 표면 측(실내)에서 외부로 빠져나가는 열기 및 냉기, 복사열을 차단하거나, 실외에서 내부로 투입되는 열기 및 냉기, 복사열을 차단하는 제1알루미늄층; 이면 측을 벽면에 접착하기 위한 접착층; 상기 제1알루미늄층과 상기 접착층의 사이에 구성되며, 상기 제1알루미늄층과 함께 이중구조로서 열기 및 냉기, 복사열을 차단하는 제2알루미늄층; 상기 제1알루미늄층과 상기 접착층의 사이에 구성되며, 단열재를 견고하게 하여 구조의 분리현상을 방지하는 성형강화제층; 상기 제1알루미늄층과 상기 접착층의 사이에 구성되며, 실내의 온도를 보온하고 습기를 방지하기 위한 PE 폼층; 상기 제2알루미늄층의 양측에 구성되며, 습기(수분)의 침투억제와 금속의 산화방지를 하기 위한 코팅 방습층으로 이루어지는 것을 특징으로 한다. The present invention is a heat insulating material that is installed on the wall surface of the building, the first side to block the heat and cold air, radiant heat to escape to the outside from the surface side (indoor) of the heat insulating material, or to block the heat and cold air, radiant heat introduced into the interior from the outside Aluminum layer; An adhesive layer for bonding the back side to the wall surface; A second aluminum layer disposed between the first aluminum layer and the adhesive layer and blocking heat, cold, and radiant heat as a double structure together with the first aluminum layer; A forming reinforcing layer formed between the first aluminum layer and the adhesive layer and for strengthening the heat insulating material to prevent separation of the structure; A PE foam layer formed between the first aluminum layer and the adhesive layer and for insulating a room temperature and preventing moisture; It is comprised on ...

Patent RU2017128449A3

РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (13) 2017 128 449 A (51) МПК E04D 3/35 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ЗАЯВКА НА ИЗОБРЕТЕНИЕ (21)(22) Заявка: 2017128449, 15.01.2015 (71) Заявитель(и): АЙВИС ИНСУЛЕЙТИОН ВАТЕРПРУФИНГ ИНДАСТРИАЛ СИСТЕМС С.Р.Л. (IT) Приоритет(ы): (22) Дата подачи заявки: 15.01.2015 (43) Дата публикации заявки: 15.02.2019 Бюл. № (72) Автор(ы): МАЗЗЕР Лучиано (IT) (85) Дата начала рассмотрения заявки PCT на национальной фазе: 15.08.2017 R U 05 (86) Заявка PCT: (87) Публикация заявки PCT: WO 2016/113581 (21.07.2016) R U (54) ВЫСОКОЭФФЕКТИВНАЯ ОБРАБАТЫВАЕМАЯ ПЛАМЕНЕМ ТЕПЛОИЗОЛЯЦИОННАЯ ПАНЕЛЬ ДЛЯ КРЫШ ЗДАНИЙ (57) Формула изобретения 1. Высокоэффективная обрабатываемая пламенем теплоизоляционная панель (1) для крыш зданий многослойного типа, содержащая сэндвич-структуру с предусмотренным промежуточным слоем (2) из жесткого пенополиуретана типа ППУ или ПИР или эквивалентного материала, каждая верхняя поверхность (21) и нижняя поверхность (22) которого снабжена многослойным покрытием, отличающаяся тем, что многослойное покрытие (3) является газонепроницаемым и обрабатываемым пламенем и соединено с промежуточным изоляционным слоем (2) теплоизоляционной панели (1), по меньшей мере, в соответствии с верхней поверхностью (21) и нижней поверхностью (22). 2. Высокоэффективная обрабатываемая пламенем теплоизоляционная панель (1) для крыш зданий по п. 1, отличающаяся тем, что многослойное покрытие (3) изготовлено из следующих слоев, соединенных последовательно: a) по меньшей мере, один слой, состоящий из металлизированной полиэфирной пленки; b) по меньшей мере, один слой, состоящий из полиэтиленовой пленки; c) по меньшей мере, один слой, состоящий из влагонепроницаемого бумажного листа; d) по меньшей мере, один слой, состоящий из пленки битумного компаунда битумного полимера; e) по меньшей мере, один слой, состоящий из нетканой полипропиленовой ткани, Стр.: 1 A 2 0 1 7 1 2 8 4 4 9 A Адрес для переписки: 121069, Москва, Хлебный пер ...

Insulation material arrangement and method for forming an insulation material

A material arrangement (10) is disclosed for insulating a building structure (50) in an installed condition. As shown in Figure 2, the material arrangement (10) includes first and second flexible polymer foam layers (12) and a flexible phase change material (PCM) layer (16) between the first and second flexible polymer foam layers (12), and at least one flexible reflective layer (14) extending over at least one of the first and second flexible polymer foam layers (12). The PCM layer (16) includes a fire-retardant flexible silicone foamed polymer material which is impregnated with a solid/liquid PCM (114) as shown in Figure 2, with a particular example of a solid/liquid PCM (114) also being shown in the detailed view in Figure 3. When the polymer is formed it will retain the PCM dispersed through the PCM layer (16) as shown in Figure 2. The silicone foam polymer is either flame or fire-retardant to provide safe use when using a flammable solid/liquid PCM, such as paraffin, without the need to add any additional fire-retardant chemicals. Additionally, silicone foam polymer has a relatively low thermal conductivity and therefore a relatively high specific heat storage capacity of its own to help with heat absorption and release. A method of forming and installing such a material arrangement (10) is also disclosed.

Wall sheathing system and method of installation

The invention comprises a wall sheathing barrier system having moisture permeability and simple improved installation method. The system comprises adjoined structural panels. Each panel has an overlay paper bonded permanently to the structural panel, which provides a moisture permeable barrier and a textured skid-resistant surface. The skid resistant surface may include indicia for aligning strips of tape or for aligning fasteners. Further, the seams of adjoining panels are sealed with a sealing means to complete the moisture barrier.

Thermal insulating wall board and wall constructions thereof

Insulation structure for appliances

The breathable and incombustible reflective heat insulator with advanced performance

유리섬유, 실리카섬유, 유리면, 암면 등과 같은 무기섬유계 단열재(1)의 양면을 열반사 효율이 우수한 알루미늄호일, 각종 알루미늄 증착필름, 알루미늄 합포등과 같은 반사층(3)을 접착함에 있어서 면적당 중량이 30g/m2 이하인 핫멜트계 접착제(2)를 사용하여 가열압착 방식으로 제조되는 단열성이 우수한 열반사단열재로서, 무기섬유계 단열재를 기초로 하여 저온에서의 복사열의 비율이 상대적으로 낮은 저온에서의 단열성이 종래의 반사단열재에 비해 우수하며, 전체 단열재에서 유기물의 총량이 면적당 중량이 100g/m2 이하여서 화염의 전파속도 및 잔염의 유지시간이 낮을 뿐 아니라 고온의 온도에서도 열분해에 의해 인화가능한 물질의 배출이나 인체에 위험한 유독가스의 발생이 적어 실질적인 적극적 불연성을 만족시킬 수 있으며, 핫멜트계 접착제(2)를 이용한 무기섬유계 단열재(1)와 반사층(3)의 합지 공정에서 표면에 요철이 있는 가압롤을 사용하여 합지함으로서 열반사 단열재의 표면에 요철이 형성되어 종래의 열반사 단열재에 비해 한층 열반사 효율이 높아져 단열성이 개선되며, 반사형 단열재가 가지는 단점인 결로문제를 해결하기 위해 방수성을 가지면서 습기투과가 가능한 면특성을 가진 단열성 및 불연성이 우수한 통기성 열반사 단열재에 관한 것이다. 단열재 무기섬유 반사층 알루미늄 저온단열성 불연성 표면요철 통기성 When bonding both sides of the inorganic fiber-based heat insulating material (1) such as glass fiber, silica fiber, glass wool, rock wool, etc. to the reflective layer 3 such as aluminum foil having excellent heat reflection efficiency, various aluminum deposition films, aluminum composites, etc. A heat reflection insulating material having excellent heat insulating property manufactured by hot pressing method using a hot melt adhesive (2) of 30 g / m2 or less, and based on an inorganic fiber insulating material, heat insulating property at low temperature with a relatively low ratio of radiant heat at low temperature. It is superior to conventional reflective insulation materials, and the total amount of organic matter in the entire insulation material is less than 100g / m2 per weight, so that the flame propagation speed and residual flame retention time are low, and the discharge of flammable materials by pyrolysis at high temperature It is possible to satisfy the practical active non-combustibility because there is little generation of toxic gas that is dangerous to the human body. In the lamination process of the inorganic fiber-based heat insulating material (1) and the reflective layer (3) using the (2) by laminating by using a pressure roll with a concave-convex surface on the surface of the heat ...

HEAT INSULATION PLATE

1. Теплоизоляционная плита, включающая высокоэффективный изолирующий слой, расположенный по меньшей мере на одной стороне с облицовкой, и базовый слой, расположенный по меньшей мере на одной из поверхностей облицовки, в которой указанный базовый слой выполнен из полиизоцианата.2. Теплоизоляционная плита по п. 1, в которой высокоэффективный изолирующий слой представляет собой жесткую полиуретановую или полиизоциануратную пену.3. Теплоизоляционная плита по п. 1 или 2, в которой облицовка расположена на обеих сторонах высокоэффективного изолирующего слоя.4. Теплоизоляционная плита по п. 1 или 2, в которой облицовка является газонепроницаемой, такой как алюминий, и базовый слой расположен на одной из облицовок.5. Теплоизоляционная плита по п. 1 или 2, в которой облицовка представляет собой бумагу, при этом базовый слой расположен на обеих облицовках.6. Теплоизоляционная плита по п. 1, в которой базовый слой представляет собой полиуретановый слой или полиизоциануратный слой.7. Теплоизоляционная плита по п. 6, в которой покрытие изготовлено способом, в котором проводят реакцию полиизоцианата и реакционноспособной в отношении изоцианатов композиции при изоцианатном индексе от 150 до 1500, причем полиизоцианат состоит из а) от 80 до 100% по весу дифенилметандиизоцианата, включающего по меньшей мере 40%, предпочтительно по меньшей мере 60% по весу 4,4’-дифенилметандиизоцианата, и/или варианта указанного дифенилметандиизоцианата, каковой вариант представляет собой жидкость при температуре 25°С, и имеет NCO-индекс по меньшей мере 20% по весу (полиизоцианат "а"), и b) от 20 до 0% по весу еще одного полиизоцианата (полиизоцианат "b"), и причем реакционноспособная в отношении изоцианатов композиция РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (13) 2014 142 988 A (51) МПК B32B 15/08 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ЗАЯВКА НА ИЗОБРЕТЕНИЕ (21)(22) Заявка: 2014142988, 27.02.2013 (71) Заявитель(и): ХАНТСМЭН ИНТЕРНЭШНЛ ЛЛС (US) Приоритет(ы): (30) ...

Flexible fire- and heat-resistant material and article made therefrom

FIELD: production of new, high-technology materials. SUBSTANCE: material comprises homogeneous mixture of organic expansible filler and organic fibers capable of undergoing intensive charring over temperature from 200 to 500 C. Addition of inorganic fibrous components increases structural integrity of material both during phase of charcoal formation up to 500 C, and during phase of charcoal oxidation at temperatures up to 1200 C. Article made of this material consists of homogeneous mixture of organic expansible filler and organic fibers capable to undergo intensive charring over temperature range 200-500 C. EFFECT: provision by the material of effective barrier against fire and heat without changing structurally intact. 23 cl, 13 dwg , 7 tbl бд Ес ПЫ Го РОССИЙСКОЕ АГЕНТСТВО ПО ПАТЕНТАМ И ТОВАРНЫМ ЗНАКАМ (19) ВИ” 21141 779‘ 13) СЛ 5) МК А 62 С 8/06, В 32 В 3/26 12) ОПИСАНИЕ ИЗОБРЕТЕНИЯ К ПАТЕНТУ РОССИЙСКОЙ ФЕДЕРАЦИИ (21), (22) Заявка: 94041953/12, 19.03.1993 (30) Приоритет: 20.03.1992 СВ 9206060.7 10.11.1992 СВ 9223545.6 (46) Дата публикации: 27.05.1998 (56) Ссылки: Ц, патент, 3934066, кл. В 32 В 3/26, 1976. (71) Заявитель: Бритиш Текнолоджи Груп Лтд. (СВ) (72) Изобретатель: Артур Ричард Хоррокс[СВ], Субаш Чандер Ананд[СВ], Барри Джейкман Хилл[СВ] (73) Патентообладатель: Бритиш Текнолоджи Груп Лтд. (СВ) С1 (54) ГИБКИЙ ОГНЕСТОЙКИЙ И ТЕПЛОСТОЙКИЙ МАТЕРИАЛ И ИЗДЕЛИЕ ИЗ НЕГО (57) Реферат: Гибкий огне- и теплостойкий материал содержит однородную смесь из органического расширяющегося наполнителя и органических волокон, интенсивно обугливающихся в температурном интервале от 200 до 500°С. Добавление неорганических волокнистых компонентов повышает структурную целостность структуры как во время формирования угля вплоть до 500 °С, так и при окислении угля при температурах вплоть до 1200°С. Изделие из гибкого огнестойкого и теплостойкого материала — состоит из однородной смеси органического расширяющегося наполнителя и органических волокон, интенсивно обугливающихся в ...

Composite aerogel thermal insulation system

The present invention provides methods and systems to effectively insulate hot or cold surfaces in industrial, domestic and building systems. It provides composite thermal insulation systems, which comprises an at least two-layer thermal insulation cladding, with at least two layers each containing from 25 to 95% by weight of aerogel and from 5 to 75% by weight of inorganic fibres, wherein the layers of the thermal insulation cladding are joined to one another by means of an inorganic binder.

Heat insulating board for building

본 고안은 건축용 단열보드에 관한 것이다. The present invention relates to a building insulation board. 본 고안의 주요구성은, 통상의 건축용 단열보드에 있어서, 일정두께를 갖는 판상의 스티렌폼(styrenefoam)과; 상기 스티렌폼의 상면에 부착되는 알루미늄포일과; 상기 알루미늄포일의 상면에 부착되고, 시트부 및 상기 시트부 상측에 간격을 두고 세워지고 관상으로 형성되어 내부에 공기방이 형성되는 다수의 셀부로 이루어져 상기 각 공기방에 의해 공기층을 형성하는 이중 공기층 형성시트와; 상기 이중 공기층 형성시트의 상면에 부착되는 일정두께를 갖는 판상의 스티렌폼과; 상기 스티렌폼의 상면에 부착되는 알루미늄포일로 이루어진 것을 특징으로 한다. The main constitution of the present invention, in a common building insulation board, plate-shaped styrene foam (styrenefoam) having a certain thickness; An aluminum foil attached to an upper surface of the styrene foam; A double air layer forming sheet attached to an upper surface of the aluminum foil, and formed of a plurality of cell portions formed at intervals on the sheet portion and the upper portion of the sheet and formed in a tubular shape to form an air chamber therein, thereby forming an air layer by each air chamber. Wow; A plate-shaped styrene foam having a predetermined thickness attached to an upper surface of the double air layer forming sheet; Characterized in that the aluminum foil is attached to the upper surface of the styrene foam. 따라서, 본 고안은 내부에 이중으로 공기층을 형성하고, 그 상·하측에 스티렌폼과 알루미늄포일을 각각 부착시킴으로써, 이중으로 된 공기층과 스티렌폼 및 알루미늄포일에 의해 단열효과를 극대화시키고, 이중 공기층에 의해 한층 더 나은 방음효과를 얻을 수 있음과 동시에 층간바닥에 설치하여 층간 전달되는 진동과 소음을 흡수시켜 쾌적한 실내환경을 얻을 수 있는 효과가 있다. Therefore, the present invention forms an air layer in the interior and attaches styrene foam and aluminum foil to the upper and lower, respectively, to maximize the thermal insulation effect by the double air layer, styrene foam and aluminum foil, It is possible to obtain a better soundproofing effect, and at the same time, it is installed on the floor to absorb vibrations and noises transmitted between the floors, thereby obtaining a comfortable indoor environment.

Thermal insulation mat, especially for building construction

Wärmedämmstoffmatte (10), insbesondere für den Gebäudebau, die aus lose übereinander angeordneten Lagen (1, 2, 3, 4 ...) aus ausschließlich unter der Hitze einer Normflamme eines gemäß DIN EN ISO 11925-2 normierten Brenntests in sich zusammen schmelzenden Dämmmaterialien gebildet ist, die mittels wenigstens einer in Längs- (X) und/oder Querrichtung (Y) der Matte (10) wellenförmig ausgeführten Naht (31, 32, 33), bei der wenigstens ein Faden (20, 21, 22) durch die Lagen (1, 2, 3, 4 ...) geführt ist, zusammengehalten sind, wobei die Wellenform der Naht (31, 32, 33) dergestalt bemessen ist, dass sie bezüglich der lokalen Fläche der Normflamme stetig ihre Lage ändernd aus der lokalen Flächenbeflammung herauswandert. Thermal insulation mat (10), in particular for building construction, which consists of layers (1, 2, 3, 4 ...) loosely arranged one above the other in which insulating materials melt together, only under the heat of a standard flame, according to DIN EN ISO 11925-2 is formed by means of at least one seam (31, 32, 33) which is undulated in the longitudinal (X) and / or transverse direction (Y) of the mat (10) and in which at least one thread (20, 21, 22) passes through the Layers (1, 2, 3, 4 ...) are held together, the wave shape of the seam (31, 32, 33) is dimensioned such that it constantly changes its position with respect to the local area of the standard flame from the local one Surface flames migrate out.

Exterior wall heat-insulating paint construction method

本发明公开了一种外墙保温涂料施工方法，属于建筑施工领域。该外墙保温涂料施工方法使用碘钨灯或电筒在光照度为15勒克斯～100勒克斯的环境下从水平和垂直方向侧向照射检查砂平，使用两米靠尺，从多方向检查，确认墙面平面度误差小于3mm，用湿度仪测量确认墙面含水量小于10％，保证了底漆的施工质量。采用烘干灯烘烤墙面18小时～24小时，并且保温涂料涂完后采用鼓风扇吹干，加快了干燥速度，提高了施工效率。

Heat insulating board for building

본 고안은 건축용 단열보드에 관한 것으로서, 보다 상세하게는 내부에 공기층을 형성하고 그 상, 하측을 알루미늄으로 피복함과 동시에 상기 공기층에서 흡수시키지 못한 소음 및 진동을 상기 상, 하측에 피복된 알루미늄에 다수개의 통공을 형성하여 상기 소음 및 진동을 기초시트로 유도하여 전량 상쇄시킴으로서, 쾌적한 실내 환경을 유지시키는 효과를 제공할 수 있도록 한 건축용 단열보드에 관한 것이다. The present invention relates to a building insulation board, and more specifically, to form an air layer therein and to cover the upper and lower sides with aluminum, and at the same time the noise and vibration not absorbed by the air layer to the aluminum coated on the upper and lower sides By forming a plurality of through-holes by inducing the noise and vibration to the base sheet to offset all, relates to a building insulation board to provide an effect to maintain a comfortable indoor environment. 본 고안의 주요구성은, 건축물의 벽면 등에 설치되고 다수의 미세기공이 형성되는 기초시트와, 상기 기초시트 상측에 알루미늄 입자를 균일한 두께로 피복시킴으로써 형성되는 알루미늄 펄층과, 상기 알루미늄 펄층 상측에 부착되는 시트부 및 상기 시트부 상측에 간격을 두고 세워지고 관상으로 형성되어 내부에 공기방이 형성되는 다수의 셀부로 이루어져 상기 각 공기방에 의해 공기층을 형성하는 공기층 형성시트와, 상기 공기층 형성시트 상측에 부착되어 상기 공기방을 밀폐시키는 알루미늄 포일로 구성되는 건축용 단열보드에 있어서, 상기 기초시트와 공기층 형성시트사이에 소음및 진동을 흡수하여 상쇄시키기 위한 다수개의 통공이 형성된 알루미늄 펄층을 구성시킨 것을 특징으로 한다. The main structure of the present invention, the base sheet is installed on the wall surface of the building and formed a plurality of fine pores, the aluminum pearl layer formed by coating the aluminum particles with a uniform thickness on the upper base sheet, and attached to the upper side of the aluminum pearl layer An air layer forming sheet which is formed at intervals on the sheet portion and an upper side of the sheet portion, and is formed in a tubular shape, and has a plurality of cell portions having an air chamber therein, and forms an air layer by each of the air chambers, and is attached to the air layer forming sheet. In the building insulation board consisting of aluminum foil to seal the air chamber, characterized in that the aluminum sheet is formed with a plurality of through-holes for absorbing and offsetting noise and vibration between the base sheet and the air layer ...

Sound and thermal insulating non-woven synthetic sheet material

本发明描述了一种用于隔音和/或隔热的无纺合成片材。该片材是厚度基本上均匀的毛毡或垫子并定义了相对放置的平表面。该片材是从相对放置的平表面的至少一个表面上针刺，引起合成纤维纠缠形成柔韧的隔音和/或隔热片材。该绝缘片材的密度大约为100－1500g/m 2 ，并具有均匀的整体性来抵制分裂。优选，将聚合物膜通过进一步的针刺步骤与合成纤维片材的表面相互连接在一起。聚合物膜优选是金属化的聚乙烯膜。该片材在建筑业中具有大量应用。该毛毡也可以是长条形，用在木制结构的框架中来隔绝相连部件的噪音。

HIGH-EFFICIENT FLAME-PROCESSED HEAT-INSULATING PANEL FOR BUILDING ROOFS

РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (13) 2017 128 449 A (51) МПК E04D 3/35 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ЗАЯВКА НА ИЗОБРЕТЕНИЕ (21)(22) Заявка: 2017128449, 15.01.2015 (71) Заявитель(и): АЙВИС ИНСУЛЕЙТИОН ВАТЕРПРУФИНГ ИНДАСТРИАЛ СИСТЕМС С.Р.Л. (IT) Приоритет(ы): (22) Дата подачи заявки: 15.01.2015 (43) Дата публикации заявки: 15.02.2019 Бюл. № (72) Автор(ы): МАЗЗЕР Лучиано (IT) (85) Дата начала рассмотрения заявки PCT на национальной фазе: 15.08.2017 R U 05 (86) Заявка PCT: (87) Публикация заявки PCT: WO 2016/113581 (21.07.2016) R U (54) ВЫСОКОЭФФЕКТИВНАЯ ОБРАБАТЫВАЕМАЯ ПЛАМЕНЕМ ТЕПЛОИЗОЛЯЦИОННАЯ ПАНЕЛЬ ДЛЯ КРЫШ ЗДАНИЙ (57) Формула изобретения 1. Высокоэффективная обрабатываемая пламенем теплоизоляционная панель (1) для крыш зданий многослойного типа, содержащая сэндвич-структуру с предусмотренным промежуточным слоем (2) из жесткого пенополиуретана типа ППУ или ПИР или эквивалентного материала, каждая верхняя поверхность (21) и нижняя поверхность (22) которого снабжена многослойным покрытием, отличающаяся тем, что многослойное покрытие (3) является газонепроницаемым и обрабатываемым пламенем и соединено с промежуточным изоляционным слоем (2) теплоизоляционной панели (1), по меньшей мере, в соответствии с верхней поверхностью (21) и нижней поверхностью (22). 2. Высокоэффективная обрабатываемая пламенем теплоизоляционная панель (1) для крыш зданий по п. 1, отличающаяся тем, что многослойное покрытие (3) изготовлено из следующих слоев, соединенных последовательно: a) по меньшей мере, один слой, состоящий из металлизированной полиэфирной пленки; b) по меньшей мере, один слой, состоящий из полиэтиленовой пленки; c) по меньшей мере, один слой, состоящий из влагонепроницаемого бумажного листа; d) по меньшей мере, один слой, состоящий из пленки битумного компаунда битумного полимера; e) по меньшей мере, один слой, состоящий из нетканой полипропиленовой ткани, Стр.: 1 A 2 0 1 7 1 2 8 4 4 9 A Адрес для переписки: 121069, Москва, Хлебный пер ...

Method for constructing insulated exterior wall panel of eco-friendly apartment

본 발명은 친환경 아파트 단열 외벽 패널 시공방법에 관한 것으로서, 특히 기형성된 아파트 외벽에 철판이 미형성된 갱폼 프레임을 고정시키는 제 1공정과; 상기 갱폼 프레임의 내측면에 단열 외벽 패널을 긴결시키는 제 2공정과; 상기 단열 외벽 패널의 내측면에서 일정 간격 이격되어 벽철근을 배근하는 제 3공정과; 상기 벽철근의 내측에 일정 간격 이격되어 유로폼을 설치하되, 상기 갱폼 프레임과 단열 외벽 패널 및 유로폼을 긴결재로 긴결시키는 제 4공정과; 상기 단열 외벽 패널과 상기 유로폼 사이에 콘크리트를 타설하여 아파트 외 벽을 형성하고, 양생이 완료되면 상기 긴결재를 제거하여 상기 갱폼 프레임과 유로폼을 해체하는 제 5공정과; 상기 단열 외벽 패널과 이웃하는 단열 외벽 패널 사이의 조인트 부분 및 긴결 부분을 실링재로 실링하는 제 6공정; 및 상기 단열 외벽 패널에 열반사 도료를 도포하는 제 7공정으로 이루어지는 것을 특징으로 한다. 상기와 같은 본 발명에 따르면 열반사 기능을 갖는 무기질계 단열 외벽 패널을 아파트 벽체(외벽)와 함께 일체로 시공함으로써 아파트 벽체의 단열 및 차열 성능을 향상시키고, 화재 안전 성능 및 친환경 성능을 향상시킬 수 있다. The present invention relates to an environmentally friendly apartment insulation outer wall panel construction method, and in particular, the first step of fixing the gangform frame unformed iron plate on the outer wall of the already formed apartment; A second step of tightening an insulating outer wall panel on an inner surface of the gangform frame; A third step of reinforcing the wall reinforcement at regular intervals from an inner side surface of the insulation outer wall panel; A fourth step of installing flow paths spaced apart from the inside of the wall reinforcement by connecting the gangform frame, the heat insulating outer wall panel, and the flow path with a long binding material; A fifth process of pouring concrete between the insulating outer wall panel and the euroform to form an exterior wall of the apartment, and dismantling the gangform frame and the euroform by removing the binding material when curing is completed; A sixth step of sealing a joint portion and a tight portion between the insulating outer wall panel and a neighboring insulating outer wall panel with a sealing material; And a seventh step of applying a heat reflecting paint to the heat insulating outer wall panel. According to the present invention as described above by installing the inorganic insulation outer wall panel having a heat reflection function integrally with the apartment wall ( ...

Foil-wrapped vacuum insulation element

본 발명은 코어와, 코어를 둘러싸며 공기 밀봉된 외피를 구비한, 호일 포장된 진공 절연 요소에 관한 것으로서, 코어와 외피 사이에 종이, 마분지 및/또는 판지로 이루어진 하나 또는 복수의 시트가 제공되며, 상기 시트는 코어를 완전히 그리고 바람직하게는 분말 밀봉식으로 둘러싼다. The present invention relates to a foil-wrapped vacuum insulating element having a core and an air-sealed outer shell surrounding the core, wherein one or a plurality of sheets of paper, cardboard and/or cardboard are provided between the core and the shell, , The sheet completely and preferably powder-tightly surrounds the core.

Composite elements

本发明涉及一种复合元件，包括：a)由泡沫或多孔材料制成的芯，b)施加至芯a)的顶涂层，和c)不同于顶涂层b)并且由热塑性材料制成的膜c)。

METHOD FOR OBTAINING EXTERIOR BUILDING DESIGN

1. Способ получения отражающей тепловое излучение наружной конструкции (1) для здания, включающий этапы:- образование наружной поверхности (4) здания из изоляционного слоя (11), который одновременно является пароизоляционным слоем (12), и коэффициент поглощения которого ε>0,6;- крепление дистанционных элементов (7) к наружной поверхности (4) здания;- подготовка опорного слоя (2), содержащего слой (3) с отражающим тепловое излучение материалом;- крепление опорного слоя к первому месту на дистанционных элементах (7)- натяжение вручную опорного слоя (2);- крепление натянутого опорного слоя (2) на других местах или поверхностях дистанционных элементов (7) таким образом, чтобы опорный слой был полностью натянут между дистанционными элементами (7) со сторон и параллельно наружной поверхности (4) здания, причем внутренняя сторона (5) опорного слоя (2), содержащая слой с отражающим тепловое излучение материалом, обращена к наружной поверхности (4) здания, при этом между опорным слоем (2) и наружной поверхностью (4) здания, а также между дистанционными элементами (7) образуется воздушная прослойка (6).2. Способ по п. 1, включающий этап:- крепление наружной обшивки (8) к наружной стороне (9) опорного слоя (2) и- крепление наружной обшивки крепежными средствами (10) к зданию, в частности, посредством дистанционных элементов (7).3. Способ по любому из пп. 1 или 2, в котором наружную поверхность здания выполняют из элемента из группы: изоляционный слой (11), пароизоляционный слой (12), слой бетона.4. Способ по п. 1, в котором наружная поверхность здания образует слой, коэффициент излучения которого ε>0,7, предпочтительно ε>0,8.5. Способ по п. 1, в котором наружную обшивку (8) выполняют из элемента группы: кровельное покрытие, панельный элемент, содержащи РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (51) МПК E04B 1/76 (13) 2014 137 452 A (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ЗАЯВКА НА ИЗОБРЕТЕНИЕ (21)(22) Заявка: 2014137452, 18.02.2013 (71) Заявитель(и ...

System and method of heat insulator manufacturing

Изобретение относится к системе и способу изготовления теплоизолятора и демонстрирует высокую отражательную способность и низкую излучательную способность при использовании отдельно или в качестве компонента в составе изолятора. Устройство включает в себя: питатель, предназначенный для подачи пенопластового полиэтиленового листа с поперечными связями; раму, имеющую моталки с ее передней и задней стороны для намотки готового теплоизолятора; режущую часть, помещенную на передней стороне рамы, предназначенную для выполнения щелей в пенопластовом полиэтиленовом листе, поступающем из питателя; расширительную часть, помещенную на задней стороне режущей части, предназначенную для превращения прорезных щелей в ячейки путем расширения пенопластового полиэтиленового листа; охлаждающую часть, помещенную с задней стороны расширительной части, которая имеет охлаждающие ролики для постоянного сохранения увеличенной ширины пенопластового полиэтиленового листа и формы ячеек, полученных путем превращения прорезных щелей; и часть для прикрепления листа, помещенную на задней стороне охлаждающей части, которая предназначена для прикрепления алюминиевой пленки на одной поверхности или обеих поверхностях расширенного пенопластового полиэтиленового листа. Изобретение обеспечивает улучшение качества теплоизолятора. 3 н. и 14 з.п. ф-лы, 13 ил. РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) 2 486 321 (13) C1 (51) МПК E04B B29C B32B B32B 1/80 (2006.01) 65/00 (2006.01) 37/00 (2006.01) 38/04 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ОПИСАНИЕ ИЗОБРЕТЕНИЯ К ПАТЕНТУ (21)(22) Заявка: 2011144506/05, 22.02.2010 (24) Дата начала отсчета срока действия патента: 22.02.2010 (73) Патентообладатель(и): СОНГ Дзеонг Гон (KR) R U Приоритет(ы): (30) Конвенционный приоритет: 06.04.2009 KR 10-2009-0029449 03.02.2010 KR 10-2010-0009964 (72) Автор(ы): СОНГ Дзеонг Гон (KR) (45) Опубликовано: 27.06.2013 Бюл. № 18 2 4 8 6 3 2 1 (56) Список документов, цитированных в отчете о поиске: ЕА 8760 B1, 31.08. ...

Insulation element for fire protection

Dämmelement für den Brandschutz aus nicht-brennbaren Fasern, insbesondere Mineralwolle oder Keramikfasern, und weiteren Zusatzstoffen, insbesondere einem Bindemittel, mit einer Kaschierung in Form einer Aluminiumfolie, dadurch gekennzeichnet, dass die Aluminiumfolie zumindest einseitig mit einem Material beschichtet ist, welches einen Emissionsgrad größer 0,6 aufweist. Insulating element for fire protection of non-combustible fibers, in particular mineral wool or ceramic fibers, and other additives, in particular a binder, with a lamination in the form of an aluminum foil, characterized in that the aluminum foil is coated on at least one side with a material having an emissivity greater than 0 , 6.

Fire hydrant thermal and acoustic insulation material

An open weave, air permeable fiber pad is formed from a plurality of compressed, interlocked fiber strands. A non-uniform, three dimensional grid of spaced apart, expandable graphite particles are secured at randomly spaced apart intervals to individual fiber strands with a particle distribution density sufficient to form a barrier to air flow through a defined area of the fiber pad when exposed to a source of heat causing the expandable graphite particles to be converted from their normal volume to a heat-activated, substantially expanded volume.

Adiabatic Sheet Integrated With Butyl Synthetic Rubber Sheet And Method For Heat-Insulating And Water-Proofing Concrete Structure Using The Sheet

PURPOSE: A heat reflective insulation sheet with a butyl synthetic rubber sheet and a heat insulating and waterproofing method of a concrete structure using the same are provided to improve construction quality and crack resistance. CONSTITUTION: A heat reflective insulation sheet(10) with a butyl synthetic rubber sheet is formed by attaching a butyl synthetic rubber sheet(3) to an aluminum heat reflective insulation sheet. The aluminum heat reflective insulation sheet is composed of an aluminum sheet(4), a polyethylene foam sheet(5), and a nonwoven fabric sheet(6). The polyethylene foam sheet and the nonwoven fabric sheet are cut from the end of the aluminum sheet and the butyl synthetic rubber sheet about 2.5-3.5cm.

The construction method of waterproof system is laid in a kind of toilet and toilet with waterproof system

本发明涉及室内防水技术领域，尤其涉及一种带有防水系统的卫生间及卫生间铺设防水系统的施工方法；包括底板和四面立墙；所述立墙包括立墙基体和由外向里依次置于所述立墙基体上的立墙找平层、立墙防水层和立墙保护层；所述底板包括钢混基板和由下至上依次设置于所述钢混基板上的第一找平层、第一防水层、保温隔热层、铝箔隔热层、地面辐射采暖层、找坡层、第二找平层、第二防水层和保护层；通过所述立墙防水层、所述第一找平层和所述第二找平层对卫生间内各管线、阴角等卫生间内需防水区域进行全面的防水处理，解决现有的地暖卫生间防水效果差的问题。

COMPOSITE ELEMENTS

1. Способ изготовления композитных элементов, содержащих а) сердцевину из пеноматериала или пористого материала; b) нанесенный на сердцевину а) покровный слой; а также с) отличную от покровного слоя b) пленку из термопластической пластмассы, включающий в себя следующие этапы:- размещение сердцевины а), покрытой покровным слоем b), в камере по меньшей мере с одной пленкой с) с промежутком между пленкой с) и сердцевиной а) с покрытием и их закрепление,- откачку воздуха из камеры,- нагрев пластиковой пленки с) выше точки размягчения,- прижатие пластиковой пленки с) к поверхности сердцевины с покрытием а) и- извлечение композитного элемента.2. Способ по п. 1, отличающийся тем, что сердцевина а) представляет собой пеноматериал, выбранный из группы, в состав которой входят полиуретановые жесткие пенопласты с открытыми ячейками, полиуретановые жесткие пенопласты с закрытыми ячейками и меламин-формальдегидные пеноматериалы.3. Способ по п. 1, отличающийся тем, что сердцевина а) представляет собой аэрогель.4. Способ по п. 1, отличающийся тем, что покровный слой b) выбран из группы, содержащей барьерные слои, препятствующие газам, огнезащитные слои и механически поддерживающие слои.5. Способ по п. 1, отличающийся тем, что покровный слой b) представляет собой металлическую фольгу или металлическую композитную фольгу.6. Способ по п. 1, отличающийся тем, что покровный слой b) представляет собой многослойную композитную фольгу с напыленным или нанесенным путем ламинирования слоем металла.7. Способ по пункту 5, отличающийся тем, что металлический слой покровного слоя b) состоит из алюминия.8. Способ по п. 1, отличающийся тем, что покровный слой b) пре� РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (13) 2013 144 410 A (51) МПК B32B 5/18 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ЗАЯВКА НА ИЗОБРЕТЕНИЕ (21)(22) Заявка: 2013144410/05, 29.02.2012 (71) Заявитель(и): БАСФ СЕ (DE) Приоритет(ы): (30) Конвенционный приоритет: 04.03.2011 EP 11156998.4 (85) Дата начала ...

Improvements in or relating to insulating sheet materials

Combined thermal and acoustic insulator

A combined thermal and acoustic insulator (10) comprises a first metallic material layer (20) formed, for example, from a metal foil, a fibrous low density material batt layer (30) adjacent the first metallic layer, a high density plastic material layer (40), and a second metallic foil layer (50). The first metallic material layer forms the heat exposed side (12) and the second metallic layer forms the shielded side of the insulator (14).