KR200420311Y1 - Insulated Glass PV - Google Patents

Abstract

This design is for curtain wall system among building exterior materials. It integrates the outer skin of building with solar cell (PV: Photovoltaic) to prevent excessive input of materials, space and cost as it does not need electric finishing and separate finishing materials. The present invention relates to an integrated multilayer glass solar cell (PV) for building exterior.

The present invention, unlike the conventional solar cell (PV) is not only to replace and integrate the solar cell (PV) with the building finish of the building, but also to satisfy the performance required in the building materials.

Integral multilayer glass PV, building materials, outer finishing materials, heat transmission rate, heat insulation layer, solar cell (PV: Photovoltaic), BIPV (Building Integrated Photovoltaics)

Description

Integral glass PV for building exterior

1a is a conceptual diagram of an integrated multilayer glass PV according to the present invention

1B is a schematic diagram of an integrated multilayer glass PV according to the present invention

2 is a schematic diagram of a sandwich glass PV according to the prior art

Figure 3 is a standard diagram of the integrated multilayer glass PV according to the present invention

Figure 4a is a manufacturing detail (A-A ') of the integrated multilayer glass PV according to the present invention

Figure 4b is a manufacturing detail (B-B ') of an integrated multilayer glass PV according to the present invention

Figure 4c is a coupling detail of the integral laminated glass PV according to the present invention

5 is an application of the integral multilayer glass PV according to the present invention (applied to the vertical outer wall surface)

Figure 6a is a comparison of power generation efficiency according to the vertical solar radiation of the integrated multilayer glass PV and the conventional sandwich glass PV according to the present invention

6b is a comparison of power generation efficiency and changes in the outer surface temperature of the integrated multilayer glass PV and the conventional sandwich glass PV according to the present invention.

Figure 6c is a comparison of the effect of the air layer temperature and power generation efficiency of the integrated multilayer glass PV and conventional sandwich glass PV according to the present invention

Figure 6d is a comparison of power generation efficiency and the change in the inner surface temperature of the integrated multilayer glass PV and conventional sandwich glass PV according to the present invention

<Description of the code | symbol about the principal part of drawing>

100a, 100b: plate glass 101: solar cell (PV) cell

103: interior glass pane 104: electrical wiring

105: Spacer

106: heat insulation layer (air layer, argon gas layer, krypton gas layer, vacuum layer)

107: Polyisobutylen 108: Desiccant

201, 202, 203, 204, 205: constituent hardware of aluminum windows and doors

301: average solar radiation in the vertical plane 302: external surface temperature

303: temperature of the insulation layer (air layer) 304: internal surface temperature

310: efficiency of integrated multilayer glass PV according to the present invention

320: efficiency of conventional sandwich glass PV

This design is for curtain wall system among building exterior materials. It integrates the outer shell of building with solar cell (PV: Photovoltaic) to prevent excessive input of material, space and cost as it does not need electric finishing and separate finishing materials. The present invention relates to an integrated multilayer glass solar cell (PV) for building exterior.

Photovoltaic power generation is a technology that produces electricity directly using photovoltaic (PV), but there are various application fields. Among them, building integrated photovoltaic (BIPV) uses solar cell (PV) as a finishing material for buildings. The development technology is a promising new technology in the 21st century and has attracted considerable attention in the world. Building integration technology is a more aggressive technology that breaks down the existing building envelope as a concept of protection of external stimulus and views it as a tool for energy generation. The existing shell must be built through the materialization of PV modules. It can meet the required performance and at the same time can take charge of building power supply through building its own power generation can expect a dual effect to reduce the cost of installing the existing solar cell (PV) system. The most important component of dual solar cell (PV) system materialization requirements is insulation performance. Insulation performance of the shell finish is to save energy by reducing cooling and heating loads and to prevent condensation. Invasion into the room by solar radiation, outside air, heat transfer, etc., some of them heat the air to raise the room temperature, and the rest of the heat accumulate in the building structure and then gradually raises the room air. At this time, the heat that increased the room temperature corresponds to the load and acts as an important factor that greatly affects the cooling and heating load of the building. On the other hand, since PV has the property of lowering power generation efficiency when exposed to heat, the performance of the designed system should be verified.

The present invention is to solve the problems of the prior art, by replacing the exterior material such as the wall or roof of the building with an integrated double-layer glass PV system, utilizing the existing building envelope as a tool for energy generation and the solar cell (PV) of The building materialization can satisfy the required performance of the outer shell of the building, and at the same time, it can play the role of supply and demand of building power by generating its own power, thereby reducing the materials, space, and cost required for the installation of the existing solar power generation system. Its purpose is to ensure thermal insulation performance as a building material that conventional building integrated products (sandwich glass PV) do not have. In addition, the performance of the present invention will be verified by experimenting the relationship between the solar radiation, the temperature around the PV module and the conversion efficiency.

The addition of an air layer and back glass to the sandwich glass PV makes it possible to create a new combination that simply improves thermal performance, which is also suitable for the insulation performance standard of the domestic envelope. The schematic diagram and conceptual view of the integrated multilayer glass PV of the present invention are the same as those of [FIG. 1A] and [FIG. 1B].

As shown in FIG. 1A and FIG. 1B, the fabrication of an integrated multilayer glass PV consists of two 4mm panes 100a, 100b and a solar cell (PV) cell 101, which are laminated to face each other. A 12 mm heat insulation layer 106 and a 6 mm plate glass 103 are disposed on the back of the solar cell (PV) module 110. The front glass 100a facing the sun should be made of white glass so that the solar light (PV) cell 101 can reach the solar cell (PV) cell 101 having high light transmittance and heat resistance. It should also be made of low iron glass to prevent lightning. The glass 103 on the indoor side may use reflective glass or may be low-E coated. When the reflective glass is used, visible light is reduced, but it is uneven in terms of the visual environment, and it has the effect of solar radiation shielding from excessively excessive sunlight, thereby improving the comfort of the occupants.

The solar cell (PV) cell 101 may use a crystalline silicon solar cell (PV) cell or an amorphous (amorphous force) or thin film solar cell (PV) cell. In the case of using a crystalline silicon solar cell (PV) cell 101, it is manufactured to a thickness of 0.3mm ~ 0.5mm for mechanical strength. As a material for fixing the solar cell (PV) cell 101, a very transparent resin 102 called EVA (Ethylene Vinyl Acetate) is used. The EVA 102 should be very transparent in order not to affect the power generation efficiency of the solar cell (PV) cell 101. The wiring 104 of the solar cell (PV) module passes through a spacer through the wiring box 104 of the rear insulation layer 106, passes through the pores of the aluminum frame, and is extracted from the edge.

The heat insulation layer 106 is composed of air, argon gas. It is also possible to configure krypton gas and vacuum.

In order to maintain the heat insulation layer 106 between the glass, a 12 mm aluminum spacer 105 is disposed between the two panes 100b and 103 to maintain the spacing. At this time, in order to prevent leakage to the heat insulating layer 106, the outer surface of the outside by using a leak-proof adhesive called polyisobutylene (107) on the adhesive surface between the aluminum spacer (105) and each of the plate glass (100b), 103 The silicon 109 is bonded and finished. The aluminum spacer 105 is used as the material for the container of the moisture absorbent 108 while maintaining the gap of glass (joint welding part should be one place). The aluminum spacer 105 is hollow and puts a desiccant 108 in the space. This is a device for preventing moisture penetration into the heat insulation layer 106.

FIG. 3 is a standard view of an integrated multilayer glass PV in a curtain wall wall to which the present invention is applied, and AA 'and BB' cross-sectional views are constructed as shown in FIGS. 4A and 4B and are vertically cut. The surface [FIG. 4A] is characterized in that the support 205 is contained to withstand the weight of the glass compared to the horizontally cut surface [FIG. 4B]. Curtain wall frames (mullions and transoms) have small protruding lengths on the sides so that their shades do not reach the module.

The application of the vertical outer wall surface is the same as [Fig. 5] can also be used for roofs and slopes. When the integrated multilayer glass PV of the present invention is applied to the curtain wall, it can be used for both the vision part and the spandrel part, and it is also easy to combine with the existing skin of different thicknesses (glass). The aluminum frame is more advantageous for the heat insulating performance of the seal if the product including the heat insulation bar is used.

According to the regulations on the facility standards of domestic buildings, etc. that prescribed the thermal performance (Ministry of Construction and Transportation Ordinance No. 328, Partial Amendment 2002.08.31), Article 21. Silver flow rate should be below 3.30kcal / m²h ℃ in central region, 3.60kcal / m²h ℃ in southern region and 4.50kcal / m²h ℃ in Jeju Island. The thermal transmittances of the prototype of the integrated multilayer glass PV and the conventional sandwich glass PV are calculated as shown in Table 5 below. In the central and southern regions, sandwich glass PV is not suitable and a solution is required. In addition, the integrated multilayer glass PV of the present invention may be an alternative.

Table 1 Composition and Heat Transmission Rate of Integrated Solar Cell (PV)

Heat permeability is used as an index for evaluating the thermal insulation performance.

In heat transfer through a structure composed of several materials, a single value that combines all the factors is called U-Value. The unit is W / m 2 ℃ (㎉ / ㎡ h ℃) is a heat flow rate through the structure is measured in watts when the temperature difference is 1 ℃ with a structure having a surface area of 1 m 2. The lower the heat transmission rate, the better the thermal insulation performance. In addition, the thermal permeability is calculated from the thermal resistance values of the materials constituting each part of the structure. In areas of buildings such as walls, the heat transfer rates through the layers and surfaces of each material are different, and this difference is explained by the thermal resistance. Heat resistance is a measure of the ability of a particular component to resist heat flow in a building site, in units of m 2 h / ㎉ (= m 2 h / W). The thermal resistance R of the portion is a value obtained by dividing the thickness d of the material by the thermal conductivity k of the material.

Equation 1

R = d / k

R: Thermal resistance of the site (㎡h ℃ / ㎉)

d: thickness of the material (m)

k: thermal conductivity of the material (㎉a / mh ℃)

In general, the thermal permeability (U) is calculated as the inverse of the sum of the thermal resistances of all components (= thermal permeation resistance).

Equation 2

U = 1 / [Ri + R1 + R2 + ..... + Ro]

U: heat transmission rate (율 / ㎡h ℃)

Ri: heat resistance of the indoor surface

Ro: Thermal resistance of outdoor surface

R1, R2, .....: thermal resistance of constituent materials

If the wall or other structure consists of a multi-layered structure with different heat permeability values, the overall insulation performance is determined by the relative area of the multi-layered structure. In this case, the average heat permeation rate should be obtained.

Equation 3

U = [a1 × U1 + a2 × U2 + .....] / [a1 + a2 + .....]

U: average heat permeation rate (㎉ / ㎡h ℃)

area of a1: 1

Heat transmission rate of U1: 1

On the other hand, PV is less efficient when exposed to heat, so it is necessary to find out how the shape of the added detail affects the temperature and conversion efficiency of the module. Therefore, by comparing the existing sandwich glass PV and the integrated multilayer glass PV of the present invention under the same conditions, the relationship between the temperature and the conversion efficiency of the module and the surroundings was used as verification data for the practical use of the present invention.

The integrated multi-layered glass PV and the existing sandwich glass PV of the present invention were installed on the roof of the building at an inclined angle of 90 ° toward the south, and the amount of generation, the PV module, and the ambient temperature were measured. The measurement period is the period of maximum solar radiation in June, July and August. This is to measure the data value when the temperature of PV module is maximized by solar radiation. The average insolation of the vertical plane and the average of the results of the high temperature (average temperature 30˚ or more) and sunny weather with a large amount of insolation during the measurement period are as shown in FIG. 6A.

It is a result of measuring the conversion efficiency of the vertical solar radiation amount 301, the power generation amount 310 of the integrated multilayer glass PV of the present invention, the power generation amount 320 of the conventional sandwich glass PV.

As a result of the measurement experiments, both sandwich glass PV and adiabatic laminate glass PV show similar patterns in conversion efficiency. As a result, the shape of the added detail has little effect on module conversion efficiency.

In addition, at the same time, Figs. 6b, 6c, and 6d show the external surface temperature 302 of the windshield and the temperature 303 of the insulating layer (air layer) and the internal surface temperature 304 of the present invention. It is a graph summarizing the measurement results of the power generation amount 310 of the multilayer glass PV and the power generation amount 320 of the existing sandwich glass PV. As a result of measurement, the temperature and conversion efficiency of PV module can be judged to be the main cause of the temperature transfer through the front surface material. Therefore, the conversion efficiency of two products with the same thickness top plate on the front surface has the same result. Therefore, this system has no performance problem of conversion efficiency compared to the conventional sandwich glass PV and is superior in insulation performance.

The present invention aims to satisfy the thermal insulation performance of building envelopes required for building materials, as well as replacing and integrating PV (Photovoltaic) with building envelope finishing materials for curtain wall systems among building exterior materials.

The present invention utilizes the existing building envelope as a tool for energy generation, satisfies the required performance of the building envelope, and can play a role in supplying and receiving building power through its own power generation. In addition to reducing the materials, space and cost required, multiple effects can be expected to meet the performance of building facades.

The improvement of insulation performance also has the additional function of peak cut which suppresses increase of the amount of power received from the electric power company in response to the peak load which reduces the cooling / heating load and especially the demand of electric power such as cooling of buildings in summer. .

The present design has no performance problem of conversion efficiency compared to the conventional sandwich glass PV and is superior in insulation performance.

Claims (4)

In the building exterior material which integrated PV (Photovoltaic), It includes a solar cell (PV) module 110 composed of two panes (100a, 100b) on both sides with a solar cell (PV) cell 101 between, The solar cell (PV) module 110 is spaced apart by placing a heat insulating layer 106 made of air, Integral multilayer glass PV for building exterior, characterized in that another layer of plate glass 103 is added to the rear of the heat insulation layer 106. The method of claim 1, Integral multilayer glass PV for building exterior, characterized in that the argon gas is applied to the heat insulation layer 106. The method of claim 1, Integrated multilayer glass PV for building exterior, characterized in that the krypton gas is applied to the heat insulation layer 106. The method of claim 1, Integrated multilayer glass PV for building exterior, characterized in that the vacuum applied to the heat insulating layer 106.

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