TRANSPARENT FRICTION ELECTRICITY NANO GENERATION DEVICE AND GENERATION UNIT USING SAME
The present invention refers to transparent triboelectric nano photovoltaic device and power generation unit using the same relates to. More specifically a transparent electrode is coated 2 each includes a transparent substrate having two friction charged layer is formed as nano-rod by frictional contact, two transparent substrate 2 frictional contact generated by the electricity two transparent substrate 2 b the tray to an and can be recovered, nano-rod for enhanced permeability through transparent substrate having softening temperature, its transparency to entire device, improved robot body is reduced by increasing a, number 1 of transparent substrates friction charged layer fine nano patterns, additional ergonomic circular the polydimethylsiloxane using an number 2 transparent substrate by forming a nano-rod, discontinuous of nanorods surface characteristics by the to expose each with an acid polydimethylsiloxane 2 two transparent substrate contact and spacing the axis line, being projected for friction of electrical generation may comprise stabilized in operation and having a, the n-type semiconductor layer the transparent triboelectric nano photovoltaic device and power generation unit using the same relates to. For recent high energy of resources various overrun method energy production which is this approach are, in particular, recent energy harvest general outline above the slot part (energy harvest) that acid with energy recovery is installed between a system a higher melting and drinks are. either progressing. Energy harvest vibration, light, heat, is installed between daily living such as an electromagnetic wave energy gather at available converted into electrical energy a technique for 200b, harvest this energy is a wide variety of, in particular in the fields of. but the method can not study appointed. This energy is harvest kind of the technique, by using piezo effect of nanowires recent techniques are is which, for responding a human, such as repeatedly a pressure which is transmitted to the wherein as a technique for converted into electrical energy, has been modified by pressure nano wires has a first manner consists of collecting electricity. A new technology to a technology, which includes such a piezoelectric effect generated by friction in daily living addition an electric is very much has the improved strength and engineering properties.. Therefore, human recent motion around method harvesting electricity small amount of from 2 in friction object has different grain size ranges are present, as an electronic when studied techniques are that capture the of wet liquid to flow down. However, the supernatant may be processed to recover triboelectric unmounted a technique converted into electrical energy or very record media receipt tray levels are very low so efficiency used, easily manufacture, is transmits a. In particular, triboelectric generation efficiency and reduced as has a polydimethylsiloxane (PDMS: polydimethylsiloxane) material friction electric power generator which is doubly formed development supplying power to the handset, polydimethylsiloxane of nano patterns thereof a bonding layer is the semiconductor manufacturing method as well as expensive as a response of the request manufacturing equipment of a position where a manufacturing such as there has been a problem that difficult. Prior art the present invention refers to one of the upper and lower surfaces efficacy as an anti-invention, the present purpose of the invention is coated with a transparent electrode 2 each includes a transparent substrate having two friction charged layer is formed as nano-rod by frictional contact, two transparent substrate 2 frictional contact generated by the electricity two transparent substrate 2 b the tray to an and can be recovered, for transparent substrate having through nano-rod improved enhanced permeability softening temperature, its transparency to entire device, the transparent triboelectric nano photovoltaic device and provides power generation unit using the same by a rope.. It is another object of the present invention friction charged of transparent substrates number 1 nano patterns, fine layer additional ergonomic circular the polydimethylsiloxane using an number 2 transparent substrate by forming a nano-rod, discontinuous of nanorods surface characteristics by the to expose each with an acid polydimethylsiloxane 2 two transparent substrate contact and spacing the axis line, being projected for friction of electrical generation may comprise stabilized in operation and having a, the n-type semiconductor layer the transparent triboelectric nano photovoltaic device and provides power generation unit using the same by a rope.. The present invention refers to, 110 electrode is formed transparent substrate number 1 ; said number 1 transparent substrate and said number 1 which is emitted in two facing surfaces of transparent substrate having formed a transparent electrode is transparent substrate number 2 ; said number 1 transparent substrate transparent electrode formed on the surface friction pacing information transfers; and said number 2 transparent substrate a transparent electrode includes nano-rod, said number 1 number 2 the transparent substrate includes a transparent substrate and said, which is pretensioned by an external pressurized is nanorods said friction charged layer is disposed with respect to the back and it is contactable with, said number 1 number 2 of transparent substrates having a transparent electrode transparent substrate and is connected at the first side of the friction charged layer is nanorods said contact and separated triboelectric being generated characterized by transparent triboelectric nano photovoltaic device provides. The, said number 1 number 2 transparent substrate and the transparent substrate includes a PET film is formed, said transparent electrodes are formed upon a ITO material can be applied. Furthermore, friction charged layer said polydimethylsiloxane (PDMS: polydimethylsiloxane) curing simple solution further fine pattern a separate manner the circular state may be formed as. Furthermore, a nanorods said zinc an oxide coating on the surface of said transparent electrode (Zno) growth nano-rod can be formed in a manner. Furthermore, said number 1 transparent substrate and are resilient the transparent substrate includes said number 2 are an external pressurized be apart from the plate when is released can be elastic. Furthermore, said number 2 transparent substrate and said number 1 separate spacer block is inserted between the transparent substrate is disposed, said number 1 transparent substrate and said spacer block are mutually spaced transparent substrate number 2 can be separately arranged on the. Furthermore, the spacer block said error or one said number 1 number 2 transparent substrate and is arranged at the end, said number 1 transparent substrate and number 2 of transparent substrates other side end free end is provided with spaced-apart fixed state can be the. Furthermore, the spacer block said sponge material may be formed as. While, the present invention refers to, said transparent triboelectric nano photovoltaic device; and said triboelectric nano photovoltaic device from friction created so that they can be stored electricity said number 1 number 2 friction friction body and electrically connected to the body including the battery by lifting the battery from to provides power generation unit nano triboelectric characterized by. According to the present invention, a transparent electrode is coated 2 each includes a transparent substrate having two friction charged layer is formed as nano-rod by frictional contact, two transparent substrate 2 frictional contact generated by the electricity two transparent substrate 2 b the tray to an and can be recovered, for transparent substrate having through nano-rod improved enhanced permeability to improve softening temperature, its transparency to entire device, .. Furthermore, fine layer friction charged of transparent substrates number 1 nano patterns, additional ergonomic circular the polydimethylsiloxane using an number 2 transparent substrate by forming a nano-rod, discontinuous of nanorods surface characteristics by the to expose each with an acid polydimethylsiloxane 2 two transparent substrate contact and spacing the axis line, being projected for friction of electrical generation may comprise stabilized in operation and having a, to simplify producing processes.. Figure 1 shows a one embodiment of the present invention also: an transparent triboelectric nano power generation layers outlines shown a perspective view, Also Figure 2 shows a one embodiment of the present invention: an transparent triboelectric nano power generation layers shown cross-sectional outlines, Figure 3 shows a one embodiment of the present invention also: an transparent triboelectric nano photovoltaic device in operating modes of the internal outlines shown one side, Also 4 and also Figure 5 shows a one embodiment of the present invention: an transparent triboelectric nano photovoltaic device for testing the performance of an saturated in range where R has considerable results side the, Also 6 to Figure 8 shows a one embodiment of the present invention also: an transparent triboelectric nano photovoltaic device of forming a nano-rod number 2 transparent substrate having method of. the shown general outline. Hereinafter, a preferred embodiment of the present invention thereby, the cold air flows with an. as further described in reference to drawing. First each of the drawings by adding references components in, a structure similar to that of the elements displayed on drawings sheet other although for even as possible has the same sign is to. to significantly different. Furthermore, the present invention describes the, associated with the function for configurations or publicly known a description is the present subject matter of invention a microscopic wall of the rectangular the when a mobile station is determined to a dispensed the description. Figure 1 shows a one embodiment of the present invention also: an transparent triboelectric nano power generation layers and outlines shown a perspective view, one Figure 2 of the present invention: an embodiment power generation nano triboelectric transparent outlines layers shown in the cross-sectional drawing and, one Figure 3 of the present invention: an embodiment in operating modes of the internal generation element nano triboelectric transparent outlines and shown in the drawing, one embodiment also 4 and Figure 5 of the present invention: an transparent triboelectric nano photovoltaic device for testing the performance of an saturated in range where R has considerable results. plane from the. One embodiment of the present invention: an transparent triboelectric nano photovoltaic device a 2 two transparent made of steel object to the friction the as device for producing electricity, number 1 transparent substrate (100), number 2 transparent substrate (200), friction charged layer (300) and nanorods (400) consists of including. Number 1 transparent substrate (100) and number 2 transparent substrate (200) friction phosphor layers as object of 2, also 1 and 2 confront as shown in is disposed apart from one in the form. Number 1 transparent substrate (100) and number 2 transparent substrate (200) made of a transparent material to each other in such a way in two facing surfaces of transparent electrode (110,210) is formed. I.e., number 1 transparent substrate (100) and number 2 transparent substrate (200) made of steel transparent each transparent electrodes on PET film (110,210) are respectively deposited can be being formed with a configuration that, the, transparent electrodes are formed upon a ITO (Indium Tin Oxide, indium tin oxide) is can be applied. Scooped out various display devices touch screen, panel, or the like in the optical drive system and thereby to be used in the prevalence of such a transparent electrode substrate using the transparent small amount, this regard in addition techniques the active mode, and for conserving is being grown very quickly, PET film such as ITO transparent electrode is deposited a transparent substrate itself since in similar to an in selling outside as they are article of mass-producing, one embodiment of the present invention: an number 1 transparent substrate (100) and number 2 transparent substrate (200) may purchase and such mass production article can be panel supports a. Be friction and 2 of the first and second transparent substrate object, touch screen panel is applied display device or the like may be applied as a of the active sensor, the 2000. Friction charged layer (300) the number 1 transparent substrate (100) transparent electrode (110) formed on the surface, nanorods (400) the number 2 transparent substrate (200) transparent electrode (210) is formed grown surface. Friction charged layer (300) is formed in the friction with other objects is made of a material main body is preferably, in a desired triboelectric are easily produced, and a patch, plastic, such as hair can be general outline the found believe, one in the embodiment of the present invention the friction charged layer (300) poly polydimethylsiloxane (PDMS: polydimethylsiloxane) material 2000. Background art acids are polydimethylsiloxane as taught triboelectric generation efficiency and reduced period of time and thus utilized as generation element nano triboelectric high advertisement information having a high utility value to the typical material, polymeric drug delivery systems via these polydimethylsiloxane a metal or plastic on contact with vertically attached the enclosed state is maintained not has a property of admitting therethrough a. I.e., polydimethylsiloxane a metal or plastic has a property of admitting therethrough a be easily affixed to. Therefore, polymeric drug delivery systems via these polydimethyl siloxane triboelectric nano photovoltaic device comprising the, polydimethylsiloxane of forming a nano patterns, each of which has undergone the machining step of machining the by fixing the entire steering manufacture of, injection sample using, thereby increasing cost and processing time poses problems, such as a strong. However, one in the embodiment of the present invention to contact the outer periphery of polydimethylsiloxane in fine nano patterns, which is not subject to, use an Resourced piece circular. I.e., in case of the fixed temperature an acidic solution polydimethylsiloxane curing Resourced piece circular that are shaped in a manner that is used. Nanorods (400) the number 2 transparent substrate (200) transparent electrode (210) which is formed in such a manner that the apparatus surface, zinc oxide (ZnO) may be formed as material. Of such rod (400) the hydrothermal or electrochemical deposition such as which may be formed by using, number 2 transparent substrate (200) direction perpendicular to the light guide plate from one surface of the LCD panel, i.e., downwardly protruding in a direction in which the growth is formed. With this structure, the transparent substrate number 1 according to (100) and number 2 transparent substrate (200) to an external pressurized in a direction are in contact with one another under the effect of a force, number 1 transparent substrate (100) and number 2 transparent substrate (200) is coil wire contact each other. More particularly, transparent substrate number 2 (200) formed on a rod (400) and a transparent substrate number 1 (100) formed friction pacing information transfers (300) is coil wire contact each other. The movable member is driven by member, friction charged layer (300) the nano-rods (400) each by friction in a negative electrode, a positive electrode is charged. A negative electrode, a positive electrode and charged in transparent substrate number 1 (100) and number 2 transparent substrate (200) when separation is under the second epitaxial region, i.e., friction charged layer (300) the nano-rods (400) when separation are separated, number 1 transparent substrate (100) and number 2 transparent substrate (200) each cathode and anode is enabled the power supply condition. The, number 1 transparent substrate (100) and number 2 transparent substrate (200) each transparent electrode (110,210) to thus, separate from the control unit via the of electrical circuits may be connected, in this case, transparent substrate number 1 (100) and number 2 transparent substrate (200) are each cathode and anode acts in the manner of. current. Number 1 and transparent substrate (100) and number 2 transparent substrate (200) repeatedly spacing and coil wire contact each other next, by using iteratively friction successfully continuing the first electrode and the second electrode is moveable between an, similarly, current is principle is flow. To generate the separate battery for storing (600) is electrical circuit may be connected to through. I.e., also 1 and 2 as shown in transparent substrate number 1 (100) transparent electrode (110) and number 2 transparent substrate (200) transparent electrode (210) to electric wiring is connected with a, battery on electric wiring (600) is connecting the, each friction charged layer (300) the nano-rods (400) charged by number 1 transparent substrate (100) and number 2 transparent substrate (200) current passes through the battery (600) are stored in. Electricity stored and the user fills in various forms depending on the can be used in. While, one embodiment of the present invention: an friction charged layer (300) by establishing an optical fiber at a polydimethylsiloxane is circular without nano patterns, which starch is octenyl succinate anhydride ester, in this case number 1 transparent substrate (100) and number 2 transparent substrate (200) the contact between a surface, polydimethylsiloxane by the characteristics of transparent substrate number 1 (100) and number 2 transparent substrate (200) continue uninterrupted contact the contact to and spaced from one another can be advantageously retained in the shifted state. However, one embodiment of the present invention: an number 2 transparent substrate (200) the friction charged layer (300) nanorods at a portion at which contact with (400) is a semiconductor layer is formed on, the aforementioned polydimethylsiloxane adhesion properties that the attenuated for accessibly and contact can be can be to simplify a processing. I.e., nanorods (400) in the end thereof an object by using a histogram critical for growing the same the irregular surfaces and since region is, friction charged layer (300) the nano-rods (400) is encapsulation may be spaced easy again. In other words, an identifying polydimethylsiloxane of nano patterns have been formed, is complicating the manufacturing processes that is displayed the upper part of the handle, in the present invention friction charged layer (300) to process of polydimethyl siloxane may simply do not form nano patterns, number 2 transparent substrate (200) nanorods on the surface of (400) by growing, , and relatively simple joint located at an by a simple process and enables to, excellent friction. efficiency and electric power generator. On the other hand, number 1 transparent substrate (100) and number 2 transparent substrate (200) by establishing an optical fiber at a an external pressurized force the interconnected by, an external pressurized force and the opening of the drain with adjacent to the Bulletin elastic be apart from the plate, are resilient made the hydrogen preferably is, establishing an optical fiber at a side a wireless send-receive part material PET, may have elastic force sufficient 2000. Furthermore, transparent substrate number 1 (100) and number 2 transparent substrate (200) is arranged away from the reference, number 1 for such spaced transparent substrate (100) and number 2 transparent substrate (200) between the separate spacer block (500) is inserted can be arranged. Such spacer block (500) also the 1 and 2 as shown in transparent substrate number 1 (100) and number 2 transparent substrate (200) is arranged at the end one side of, transparent substrate number 1 (100) and number 2 transparent substrate (200) other side end of free end is provided with spaced-apart fixed state can be the. Therefore, transparent substrate number 1 (100) and number 2 transparent substrate (200) to an external pressurized under the effect of a force, as shown in of Figure 3 (a) transparent substrate number 2 (200) a spacer block (500) by transparent substrate number 1 (100), facing away from a surge, other side end elastic deformed to allow a thick-transparent substrate number 1 (100) can be spring. Furthermore, spacer block (500) the are resilient a protrusion/recess shape and are, for example, sponge material may be formed, the number 1 transparent substrate (100) and number 2 transparent substrate (200) to an external pressurized when force acting, spacer block as shown in of Figure 3 (b) (500) itself is elastic deformed to allow a thick-transparent substrate number 1 (100) and number 2 transparent substrate (200) can be come into contact with the. On the other hand, number 2 transparent substrate (200) a nanorods (400) of a plaque has discontinuous as passivation layer is formed on the surface friction charged layer (300)/ out of contact with the transparent substrate number 2 as well as (200) softening temperature, its transparency to the objective compound.. I.e., transparent electrode (210) transparent substrate formed with to nanorods (400) when grown, permeability to light transparent substrate with improved circular plate of 1 mm thickness is, transparency of generation element nano triboelectric as a result the objective compound.. Of such rod (400) also fluorine of 4 to on which a driving to the graph experiments, simply PET film ITO is deposited overall light as compared to when a wave in nanorods (400) is provided with a degree that the reflected optical beam improved fluorine a main body lower. Furthermore, one embodiment of the present invention the 5 also: an triboelectric nano photovoltaic device on which a driving performance characteristics of, transparent substrate number 1 (100) and number 2 transparent substrate (200) for an external pressurized 1.35kgf size force, 3.75kgf, 5.65kgf more of increasing to high voltages are produced and it will be, an external pressurized mixture by the addition of an initiator repetition period force 1/2Hz frequency in a second frequency, 1Hz, 2Hz more of increasing to high voltages are produced. it will be. Therefore, one embodiment of the present invention: an triboelectric nano photovoltaic device a an external pressurized and repetitive cell size force middle of short period are higher voltages are produced. it will be. Also 6 to Figure 8 shows a one embodiment of the present invention also: an transparent triboelectric nano photovoltaic device of forming a nano-rod number 2 transparent substrate having method of. the shown general outline. Number 2 transparent substrate (200) forming a nano-rod to the method, first, number 2 transparent substrate (200) to seed layer, seed on the surface of the nano-rod and the processing advances in such a way as to produce. Seed on the surface of the manner in which the formed nano-rod and electrochemical hydrothermal can be metal tip using. First, also 6 and looking through my method with reference to a seed layer forming, also 7 and 8 with reference to a hydrothermal and nanorods formed by chemical vapor deposition method at a portion corresponding to the separable.. The present invention according to energy generating device also Figure 6 shows a seed layer is surface to explain the method. Also and consulting (6) a conductive fiber grown solution dip coating (Dip coating) by coating an surfaces of a more particularly, metal oxide seed solution (43) which are filled a coating formed from a water tank (41) to transparent substrate number 2 (200). immersed therein and cleaned. Placed at the rear side of the growth solution growth a metal component that is fitted with an aperture. For example, ZnO of nano-rod growth the seed solution (43) the 50 ml of water and 10 mm of zinc acetate dihydrate (zinc acetate dehydrate, ) Mixing the agitating the guiding rail. The amount of seed solution be coated a strength proportional to a conductive fiber, the same concentration that was in the. at low ratio of. Preferably, coating water tank (41) the lower surface of the ultrasonic vibrator (47) the local bus and the peripheral bus, ultrasonic vibrator (47) by the generation ultrasonic seeds solution (43) by applying the transparent substrate number 2 (200) and a seed solution (43) in facilitating the mixture of to. Ultrasonic the severity of the compressive force and pressure sensitive force seed solution (43) to the, seed solution (43) pressure sensitive force and compressive force applied to seed solution (43) of transparent substrate number 2 (200) is transmitted to the solenoid housing and number 2 transparent substrate (200) to the interior of of seed solution (43) coated to. Also 5 (b) with reference to a seed material layer and a nitration material layer surfaces of a more particularly, seed solution coated with a sintered transparent substrate number 2 (200) for heat-treating a unit (50) of inner housing (53) that is arranged heating plate (55) after in other words from the to, coated number 2 transparent substrate (200). heat-treated and ground. A seed solution coating heat treatment conjunction with oxygen are converted metal oxide transparent substrate number 2 (200) applies a metal to a surface oxide seed layer (120) is formed on. Preferably, input valve (51) through transparent substrate number 2, implanting oxygen to (200) by the heat treatment, single crystal of metal oxide seed layer can be more uniform. At a portion corresponding to the separable heating conditions, high the application of heat increases, at consistently high quality metal oxide seed layer fiber layer can be formed on at the fibers depending on the material of body heat body is modified by causes neither an extent can be annealed. Also in the present invention according to Figure 7 shows a the nanoparticulate hydrothermal energy generating device of forming floating body transistor constructions. plane from the account for step. Also surfaces of a more particularly with reference to a 7, growth water tank (71) immersed in the growth solution (73) to seed layer formed on surface of exterior material transparent substrate number 2 (210'). immersed therein and cleaned. Heating plate (75) grown solution (73) the seed to the surface of the layer of nanorods (400). grown. ZnO of growing nano-rod surfaces of a more particularly, for example, ZnO has transparent conductive oxide semiconductor as, rky1 rich since the lower surface, chemical thermally stable electrical of optical quality field a optical element since by winding the. In particular, ZnO nanorods 1-dimensional structure of a high quality crystalline and an electronic short along the motion path has a, optical, electrically very good various solar cells or or tetrahydrofuran applied to the salts with high. Fiber in an seed layer (110') 78 °C -90 ° C a growth of solution (73) to time immersed into 5-12. Growth solution (73) zinc nitrate (zinc nitrate, Zn (NO3)2) powder powder and hexamethylene tetra amine (hexamethylene tetramine, (CH2)6 N4) concentration on the same powder are mixed together generates pure water (deionized water). Such growth solution (73) to seed layer formed on surface of exterior material so, the bu immersing cellulose, growth solution (73) generated in OH-, Zn2+ seed ion seed of time to cause density plasma chemical vapor deposition method on the surface of the ZnO determination is 1-dimensional structure is formed. The, 1-dimensional structure on the surfaces of the layers of the seed growth the course of ZnO c-plane-axis direction which, c-plane. subject to growth of ZnO nanorods axial direction. The ZnO or AZO c-plane structure of atoms (Wurzite structure) c in. axes. Growth solution (73) on the surface of the seed in when subject to growth of ZnO nanorods chemical reaction type as follows. (CH2)6 N4 + 6H2 O ⇒ 6CHOH + 4NH3 NH3 + H2 O ⇒ NH4+ + OH- Zn (NO3)2 + H2 O ⇒ Zn2+ + 2HNO3 2OH-+ Zn2+ ⇒ ZnO + H2 O As such, hydrothermal nanorods through in the grown, the materials comprising the nano-rod concentration of solution growth containing, it digests, solution growth substrate that time, by regulating the temperature thereof of solution growth, a substrate thickness and of nanorods can be adjusting the length. Also the present invention according to Figure 8 shows a electrical energy generating device is is formed a. plane from the account for. Also 8 surfaces of a more particularly with reference to a, seed layer formed on surface of exterior material transparent substrate number 2 (210 ') operating electrode (working electrode, 81) bind to growth solution (80) followed by immersed, power supply device (83) to working electrode (81)-voltage is added to the + to and relatively electrode (counter electrode, 82) by applying a voltage to the liquid growth solution (80) electric field by forming a conductive fibers (110') and the growth solution (80) is to promote a reaction chemical method. Growth solution (80) zinc nitrate (zinc nitrate, Zn (NO3)2), hexamethylene tetra amine (hexamethylene tetramine, (CH2)6 N4) and potassium chloride (KCL) is is controlled by a use for goods. Seed layer formed on surface of exterior material transparent substrate number 2 (210') to when subject to growth of ZnO nanorods chemical reaction type as follows. Zn (NO3)2 ⇔ Zn2+ + 2NO3- NO3- + H2 O + 2e- ⇔ NO2- + 2OH- Zn2+ + 2OH- ⇔ Zn (OH)2 Zn (OH)2 ⇔ ZnO + H2 O Such the electro-deposition rod the nanoparticulate the hydrothermal growth that about 2-5 temporal extent by quickly displacing the unit is off. Or more description techniques of the present invention describes illustratively event efficacy as an anti-to a modem, the present invention is in the field of the typically encountered in having knowledge of an essential element of the present invention grow or not the current source from deviating from variety of correction and will changeable. Therefore, in the embodiment of the present invention are a disclosure to the present invention and to limit the slimly is supported by the upper case and for described, such embodiment of the present invention and/or at least two different slimly range of limited not. If of the present invention scope of protection which must be interpreted by, and equivalent that lie within the ranges included within the scope rights of all technical idea of the present invention should be interpreted to will. 100: number 1 transparent substrate 110: transparent electrode 200: number 2 transparent substrate 210: transparent electrode 300: friction charged layer 400: nanorods 500: spacer block 600: battery The present invention relates to a transparent friction electricity nano generation device, and a generation unit using the same. A friction electrified layer and a nanorod are formed on two transparent substrates having a transparent electrode coated thereon, and frictionally come in contact with each other, so electricity generated by friction contact of two transparent substrates can be collected by constituting an electric circuit about the transparent substrates. Transmittance of the transparent substrates is improved through the nanorod, so transparency of the entire device may be improved. Polydimethylsiloxane in an original state in which a fine nano pattern is not additionally formed is used as a friction electrified layer of a first transparent substrate. At the same time, a nanorod is formed on a second transparent substrate. Accordingly, adhesion with polydimethylsiloxane is weakened through non-continuous surface properties of the nanorod, so contact and separation of two transparent substrates are activated and operation for generating friction electricity can be stably performed. A production process can be simplified. COPYRIGHT KIPO 2016 110 transparent substrate number 1 electrode is formed; said number 1 transparent substrate and said number 1 which is emitted in two facing surfaces of transparent substrate having formed a transparent electrode is transparent substrate number 2 ; said number 1 transparent substrate transparent electrode formed on the surface friction pacing information transfers; and said number 2 transparent substrate a transparent electrode includes nano-rod, said number 1 number 2 the transparent substrate includes a transparent substrate and said, which is pretensioned by an external pressurized is nanorods said friction charged layer is disposed with respect to the back and it is contactable with, said number 1 number 2 of transparent substrates having a transparent electrode transparent substrate and is connected at the first side of the friction charged layer is nanorods said contact and separated triboelectric being generated characterized by transparent triboelectric nano photovoltaic device. According to Claim 1, said number 1 number 2 transparent substrate and the transparent substrate includes a PET film is formed, said transparent electrodes are formed upon a ITO be applied material characterized by transparent triboelectric nano photovoltaic device. According to Claim 1, friction charged layer said polydimethylsiloxane (PDMS: polydimethylsiloxane) curing simple solution further fine pattern a separate manner the circular state coated with a characterized by transparent triboelectric nano photovoltaic device. According to Claim 1, a nanorods said zinc an oxide coating on the surface of said transparent electrode (Zno) nano-rod is formed in such a manner that the growing characterized by transparent triboelectric nano photovoltaic device. According to one of Claim 1 to Claim 4, said number 1 transparent substrate and are resilient the transparent substrate includes said number 2 are an external pressurized be apart from the plate when is released return things characterized by transparent triboelectric nano photovoltaic device. According to Claim 5, said number 2 transparent substrate and said number 1 separate spacer block is inserted between the transparent substrate is disposed, said spacer block said number 1 number 2 transparent substrate and cleaning agent suppliers are disposed are mutually spaced transparent substrate to characterized by transparent triboelectric nano photovoltaic device. According to Claim 6, the spacer block said error or one said number 1 number 2 transparent substrate and is arranged at the end, said number 1 transparent substrate and number 2 of transparent substrates other side end fixed state free end disposed a gate peeling phenomenon characterized by transparent triboelectric nano photovoltaic device. According to Claim 6, the spacer block said sponge coated with a material characterized by transparent triboelectric nano photovoltaic device. Number 5 described in claim transparent triboelectric nano photovoltaic device; and said triboelectric nano photovoltaic device from friction created so that they can be stored electricity said number 1 number 2 friction friction body and electrically connected to the body to the battery by lifting the battery from nano triboelectric characterized by including power generation unit.
