JP2015093789A - Exothermic glass panel and exothermic glass system including the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an exothermic glass panel capable of improving thermal insulation properties while reducing power consumption, and an exothermic glass system including the same.SOLUTION: The exothermic glass panel comprises: a first glass plate; a second glass plate arranged so as to face the first glass plate at a predetermined interval; a first space part sealed between the first glass plate and the second glass plate and decompressed; a third glass plate arranged so as to face the second glass plate at a predetermined interval; a second space part sealed between the second glass plate and the third glass plate and enclosed with dry air or rare gas; and a conductive layer formed on at least one of the first glass plate or the third glass plate.

Description

  The present invention relates to a heat generating glass panel and a heat generating glass system including the same.

  Multi-layer glass composed of a plurality of glass plates is provided with a hollow layer between the glass plates, and thus has a high heat insulating effect. Among them, in recent years, a coating with a low-emission film (Low-E film) has been proposed, but since it can also be expected to have a heat shielding effect and increase the efficiency of cooling and heating, it is particularly widespread as residential window glass. doing.

  However, even in such a glass, there is a problem that in winter, the glass surface temperature on the indoor side tends to decrease due to a low outside air temperature, causing condensation. Furthermore, the indoor air cooled by the glass surface descends from the window along the wall and spreads over the floor surface, so-called cold draft phenomenon may occur.

  As one of means for suppressing the occurrence of these phenomena, the use of exothermic glass has been proposed. For example, as shown in Patent Document 1, the heat generating glass is composed of a glass provided with a heat generating layer having conductivity such as a metal thin film, and the surface temperature of the glass can be increased by energization. It is possible to suppress the occurrence of condensation and the cold draft phenomenon.

JP-A-11-345677

  However, the lower the outside air temperature, the greater the power required to maintain the glass surface temperature. That is, even in the case of double-glazed glass, the heat insulation performance is inferior to that of the outer wall, and there is a problem that when the outside air temperature is low, heat loss is large and the glass temperature on the indoor side is low. The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a heat generation glass panel and a heat generation glass system including the same, which can improve heat insulation performance while reducing power consumption. And

  An exothermic glass panel according to the present invention includes a first glass plate, a second glass plate arranged to face the first glass plate at a predetermined interval, and between the first glass plate and the second glass plate. A first space part that is depressurized, a third glass plate disposed to face the second glass plate at a predetermined interval, the second glass plate, and the second glass plate A second space that is sealed between the third glass plate and filled with dry air or a rare gas; and a conductive layer formed on at least one of the first glass plate and the third glass plate. Yes.

  According to this structure, since the 1st space part decompressed is formed between the 1st glass plate and the 2nd glass plate in addition to the electrically conductive layer which generate | occur | produces heat, the heat insulation effect can be improved. Therefore, the heat insulation performance of the entire heat generating glass panel can be improved without greatly increasing the power supplied to the conductive layer.

  In the heat generating glass panel, the conductive layer may be formed on any surface. For example, in the third glass plate, the conductive layer can be formed on a surface facing the second space portion. Thereby, the temperature of the 2nd space part between a 2nd glass plate and a 3rd glass plate can be raised by the heat_generation | fever of a conductive layer. As a result, the heat insulation effect can be further improved by the combination with the first space portion. Further, when the third glass plate is attached to the window so that it faces the indoor side, since the cold air from the outside is blocked by the first space portion and the second space portion, the surface temperature of the third glass on the indoor side is maintained. It is possible to further save the electric power required.

  The exothermic glass panel may further include a low radioactive film formed on at least one of the surfaces of the first to third glass plates. By providing such a low radioactive film, the heat flow rate of the glass plate can be reduced, and the heat insulation effect can be further improved.

  The exothermic glass system according to the present invention includes any one of the exothermic glass panels described above and a power supply unit that supplies electric power to the exothermic glass panel.

  The exothermic glass system may further include a frame configured to support the exothermic glass panel and be movable with respect to the window frame. The power supply unit includes: a power transmission module that generates an alternating current; an alternating current supplied from the power transmission module; the power transmission electrode that is attached to the window frame; the power supply unit that is attached to the frame; And a power receiving module that converts an alternating current supplied from the power receiving electrode into a direct current and supplies the direct current to the conductive layer of the heat-generating glass panel. A capacitor is configured by disposing the electrode at a predetermined interval, and power can be transmitted from the power transmission electrode to the power reception electrode via the capacitor.

  According to this configuration, electric power can be supplied to the heat generating glass panel by non-contact power feeding between the power receiving electrode and the power transmitting electrode, so that the heat generating glass panel can be configured to be openable and closable. That is, the heat generating glass panel can be moved by non-contact power supply. When the window frame is opened by the heat generating glass panel, no power is supplied, and when the inside of the window frame is closed, the power is not supplied. It can be configured to be supplied. As a result, when the inside of the window frame is open, power is not supplied, and power is supplied only when the inside of the window frame is closed to cut off heat transfer, thus reducing power consumption. can do.

  In the heat generating glass system, the power transmitting electrode and the power receiving electrode can be covered with an insulating cover member, respectively. Thereby, the said power transmission electrode and power receiving electrode can be hold | maintained at predetermined distance between both electrodes via each cover member. As a result, non-contact power feeding can be performed accurately.

  According to the present invention, it is possible to improve heat insulation performance while reducing power consumption.

It is a block diagram of the exothermic glass system which concerns on one Embodiment of this invention. It is sectional drawing of the exothermic glass panel used for the exothermic glass system of FIG. It is the sectional view on the AA line of FIG. FIG. 3 is a front view of FIG. 2. It is a block diagram which shows schematic structure of an electric power supply apparatus.

  Hereinafter, an embodiment of a heat generating glass system according to the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing a schematic configuration of a heat generating glass system according to the present embodiment.

  As shown in FIG. 1, the heat generation glass system according to the present embodiment includes a heat generation glass panel 1 and a power supply device 2 that supplies power to the heat generation glass panel 1. As will be described later, the power supply device 2 includes a power transmission unit 21 and a power reception unit 22, and non-contact power feeding is performed between them.

<1. Exothermic glass panel>
2 is a cross-sectional view of the heat generating glass panel, and FIG. 3 is a cross-sectional view taken along the line AA of FIG. As shown in FIG. 2, the heat generating glass panel 1 according to the present embodiment is composed of three glass plates formed of a known float glass or the like. The periphery of the heat generating glass panel 1 is supported by a rectangular frame 3. Further, the frame 3 is provided with a power receiving unit 22 for supplying power to the heat generating glass panel 1.

  First, the exothermic glass panel will be described. This exothermic glass panel includes a vacuum multilayer glass 11 constituted by two glass plates, and a base glass plate 12 disposed so as to face the vacuum multilayer glass 11 and has an overall thickness. For example, it is 15 to 40 mm. The vacuum double-glazed glass 11 and the base glass plate 12 have substantially the same outer shape, and are connected to each other by a sealing material 13 arranged at the peripheral edge. That is, by disposing the sealing material 13 between the vacuum double-glazed glass 11 and the base glass plate 12, an internal space (second space portion) 14 having a thickness S1 is formed between the two. . Therefore, the sealing material 13 plays a role of sealing the internal space 14 and a role of a spacer that forms a gap therebetween. Further, a conductive layer 15 is formed on the surface of the base glass plate 12 facing the vacuum multilayer glass 11, and the conductive layer 15 is electrically connected to the power receiving unit 22 described above. In the exothermic glass unit according to the present embodiment, the vacuum double-glazed glass 11 is arranged to face the outdoors, and the base glass plate 12 is arranged to face the indoors. Hereinafter, each member mentioned above is demonstrated in detail.

  Next, the frame 3 will be described with reference to FIG. FIG. 4 is a front view showing a state in which the frame is attached to the window frame. The frame 3 is formed in a rectangular shape extending along the outer peripheral edge of the heat generating glass panel 1. The two frames 3 to which the heat generating glass panel 1 is attached are fitted into the window frame 4 so as to be movable in the horizontal direction. Thereby, the inside of the window frame 4 can be closed or opened by the two heat-generating glass panels.

  The frame 3 includes a pair of side members 31 and 32 extending in the vertical direction, a lower member 33 connecting the lower ends of the side members 31 and 32 and extending in the horizontal direction, and upper ends of the side members 31 and 32. The upper member 34 is connected and extends in the horizontal direction. On the lower surface of the upper member 34 and the upper surface of the lower member 33, grooves (not shown) for fitting the upper edge and the lower edge of the heat generating glass panel 1 are formed. On the other hand, rails (not shown) for engaging with the window frame 4 and moving in the horizontal direction are formed on the upper surface of the upper member 34 and the lower surface of the lower member 33. Further, as shown in FIG. 2, one side member 31 is formed with an internal space 311 extending in the vertical direction, and faces both sides thereof, that is, the surface facing the heat generating glass panel 1 and the window frame 4. A first groove portion 312 and a second groove portion 313 are formed on the surface, respectively. The side edge of the heat generating glass panel 1 is fitted in the first groove 312. On the other hand, a first electrode module, which will be described later, is attached near the upper end of the second groove 313. A second electrode module is attached to the window frame 4 at a position facing the first electrode module.

Next, the vacuum multilayer glass 11 will be described. As shown in FIG. 1, this vacuum double-glazed glass 11 is configured by arranging a first glass plate 111 facing the outdoors and a second glass plate 112 facing the indoors at a predetermined interval, and having a thickness. Is, for example, 6 to 16 mm. The thickness of each glass plate 111,112 can be 3-8 mm, for example. The 1st glass plate 111 and the 2nd glass plate 112 are mutually connected by the solder glass 113 arrange | positioned at the peripheral part. For example, the solder glass 113 is melted at a high temperature of 400 to 500 ° C., and both the glass plates 111 and 112 are fused to form a space (first space portion) 114 between the glass plates 111 and 112. . In addition, a plurality of spacers 115 formed of a metal such as SUS, ceramics, hard resin, or the like are disposed between the glass plates 111 and 112, thereby maintaining the thickness of the space 114 constant. ing. The space 114 is depressurized to form a depressurized layer that is in a vacuum state of, for example, 10 ⁻² Torr or less.

  Next, the internal space 14 will be described. The sealing material 13 for forming the internal space 14 between the vacuum multilayer glass 11 and the base glass plate 12 is formed of an insulating material, and can be formed of, for example, two types of seals. That is, as shown in FIG. 2, it can be comprised by the primary sealing material 131 arrange | positioned at the side which faces the internal space 14, and the secondary sealing material 132 which covers the periphery of this primary sealing material 131 from the outer side. . The primary sealing material 131 can be formed of, for example, butyl rubber, and the secondary sealing material 132 can be formed of, for example, a polysulfide-based sealant, a silicon-based sealant, or the like. The internal space 14 thus formed is filled with a rare gas such as argon or krypton in addition to dry air. The layer thickness of the internal space 14 thus configured, that is, the distance between the vacuum double-glazed glass 11 and the base glass plate 12 (the thickness S1 described above) can be set to, for example, 6 to 22 mm.

Next, the base glass plate 12 and the conductive layer 15 disposed thereon will be described. The base glass 12 is formed of float glass or the like as described above, and the thickness can be 3 to 8 mm, for example. Further, as described above, the rectangular conductive layer 15 is formed on the surface of the base glass plate 12 facing the vacuum multilayer glass 11 side. The conductive layer 15 is not particularly limited as long as it is a transparent and conductive material. For example, SnO ₂ , ITO film, or the like can be used. As shown in FIG. 3, in the rectangular conductive layer 15, ribbon-like electrodes 16 are arranged on two opposite sides extending in the left-right direction or the up-down direction, and leads attached to the respective electrodes 16. Each of the wires 17 passes through any position of the sealing material 13 and is drawn to the outside of the heat generating glass panel 1. A power receiving unit 22 that supplies power to the heat generating glass panel 1 is attached to the outside of the heat generating glass panel 1, that is, the frame 3. Hereinafter, the power transmission unit 21 and the power reception unit 22 that constitute the power supply device 2 will be described.

<2. Power receiving unit>
FIG. 5 is a block diagram showing a schematic configuration of the power supply apparatus. As illustrated in FIG. 5, the power reception unit 22 includes a DC-DC converter module 221, a power reception module 222, and a first electrode module 223. Among these, the DC-DC converter module 221 and the power receiving module 222 are disposed in the internal space 331 formed in the side member 31 of the frame 3 described above. The DC-DC converter module 221 is connected with two lead wires 17 drawn from the heat generating glass panel 1 and includes a voltage regulator 2211 for generating a constant voltage. The conductive layer 15 of the heat generating glass panel 1 generates heat by the voltage output from the voltage regulator 2211. The power receiving module 222 is provided with a step-down transformer 2221 and a rectifier circuit 2222. The alternating current flowing from the first electrode module 223 is dropped to a low voltage by the step-down transformer 2221, and after the alternating current is converted into direct current rectification by the rectifier circuit 2222, the alternating current is sent to the DC-DC converter module 221 described above. .

  Next, the first electrode module 223 will be described. The first electrode module 223 is disposed in the second groove portion 313 of the frame 3, and the first cushion member 2231 and the second cushion are arranged in the horizontal direction from the back end portion of the second groove portion 313 toward the window frame 4 side. A member 2232 and an electrode portion 2233 are included. Both cushion members 2231, 2232 are formed in a rectangular parallelepiped shape with an elastic material such as rubber and resin, and the first cushion member 2231 is formed with a softer material than the second cushion member 2232. The electrode portion 2233 includes a power receiving electrode 2234 that is electrically connected to the step-down transformer 2221 of the power receiving module 222 and a cover member 2235 made of a cured resin that covers the power receiving electrode 2234. The power receiving electrode 2234 is formed in a plate shape, is disposed on the surface of the second cushion member 2232 facing the window frame 4 side, and is connected to the step-down transformer 2221 via a conducting wire. Note that the cover member 2235 may be formed of a material that is insulative and hardly elastically deforms, such as a cured resin.

<3. Power transmission unit>
Next, the power transmission unit 21 for supplying power to the power reception unit 22 will be described. As shown in FIG. 5, the power transmission unit 21 includes an AC adapter 211, a power transmission module 212, and a second electrode module 213 connected to an AC power source. Among these, the AC adapter 211 and the power transmission module 212 are disposed, for example, inside the window frame 4, inside a wall in which the window frame 4 is fitted, or in a room in which the window frame 4 is fitted. On the other hand, the second electrode module 213 is arranged at a position facing the first electrode module 223 in the window frame 4. These will be described in detail below.

  The AC adapter 211 converts an alternating current sent from an alternating current power source (not shown) into a direct current, and the converted direct current is sent to the power transmission module 212. The power transmission module 212 includes an overvoltage protection circuit 2121, a controller 2122, an inverter circuit 2123, and a step-up transformer 2124. With this configuration, the direct current sent from the AC adapter 211 is converted into an alternating current by the inverter circuit 2123, boosted by the step-up transformer 2124, and then sent to the second electrode module 213. The controller 2122 controls these currents, and the overvoltage protection circuit 2121 protects an excessive voltage from acting on the inverter circuit 2123.

  The second electrode module 213 is configured in the same manner as the first electrode module 223, and includes a first cushion member 2131, a second cushion member 2132, which are arranged in a horizontal direction from the window frame 4 toward the first electrode module 223 side, and The electrode portion 2133 is configured. The electrode portion 2133 includes a plate-shaped power transmission electrode 2134 electrically connected to the step-up transformer 2124 of the power transmission module 212 and a cover member 2135 made of a cured resin that covers the power transmission electrode 2134 and has insulation properties. Has been. In addition, since these structures are substantially the same as the 1st electrode module 223 mentioned above, detailed description is abbreviate | omitted.

  In the power reception unit 22 and the power transmission unit 21 configured as described above, the power reception electrode 2234 and the power transmission electrode 2134 are opposed to each other through the cover members 2135 and 2235 when the window frame is closed. Yes. That is, the power receiving electrode 2234 and the power transmitting electrode 2134 form a capacitor, and the power converted into alternating current by the power transmitting module 212 is transmitted to the power receiving module 222 via the capacitor. That is, non-contact power feeding by an electric field coupling method is performed. In this method, for example, power can be supplied even if the power receiving electrode 2234 and the power transmitting electrode 2134 are slightly shifted in the surface direction.

<4. Operation of exothermic glass system>
Next, the operation of the exothermic glass system configured as described above will be described. First, the heat generating glass panel 1 is moved horizontally in the window frame 4 to close the window frame. Thereby, the cover member 2235 of the first electrode module 223 and the cover member 2135 of the second electrode module 213 come into contact with each other. As a result, the power reception electrode 2234 and the power transmission electrode 2134 form a capacitor, and power is supplied from the power transmission electrode 2134 of the power transmission unit 21 to the power reception electrode 2234 of the power reception unit 22 in a non-contact manner. At this time, since the cover members 2235 and 2135 are attached to the power receiving electrode 2234 and the power transmission electrode 2134, respectively, the distance between the electrodes 2234 and 2134 is kept constant via the cover members 2235 and 2135.

  This electric power is supplied from the power receiving unit 22 to the conductive layer 15 of the heat generating glass panel 1 through the lead wire 17, and the conductive layer 15 generates heat. Thereby, the surface temperature of the base glass plate 12 of the exothermic glass panel 1 rises. As a result, the occurrence of condensation and the cold draft phenomenon can be suppressed. Moreover, since the vacuum layer 114 is formed in the vacuum double-glazed glass 11, a heat insulating effect can be expected thereby. That is, the heat insulation performance of the heat generating glass panel 1 can be improved without applying large electric power. In addition, when the heat generating glass panel 1 moves and the inside of the window frame 4 is opened, the power receiving electrode 2234 and the power transmitting electrode 2134 are separated from each other, so that power feeding is stopped.

<5. Modification>
As mentioned above, although one Embodiment of this invention was described, this invention is not limited to the said embodiment, A various change is possible unless it deviates from the meaning. For example, the following changes can be made.

<5-1>
For example, a low radioactive film may be formed on at least one of the surfaces of the three glass plates shown in the above embodiment. If it does in this way, the heat flow rate of a glass plate can be reduced and the heat insulation effect can be improved further. For example, the low radioactive film vaporizes a tin organic compound such as tin tetrachloride (SnCl ₄ ) or dimethyltin dichloride ((CH ₃ ) ₂ SnCl ₂ ) on the surface of a glass plate heated to, for example, 500 to 700 ° C. Can be obtained by spraying with a carrier gas such as nitrogen gas. At this time, if fluorine is added to the film, the emissivity can be further reduced. By the above method, a fluorine-containing tin oxide film having a film thickness of, for example, about 0.2 to 1.0 μm (2000 to 10,000 mm) and having transparency and conductivity can be obtained. In this case, the conductive electrons in the film have a function of reflecting infrared rays, and the emissivity is about 0.20 to 0.15, so that a glass plate excellent in heat insulation can be formed.

<5-2>
As the glass plates 111, 112, and 12 used in the above-described embodiment, in addition to float glass, netted glass, tempered glass, laminated glass, and the like can be used.

<5-3>
In the above embodiment, the insulating material is used as the sealing material 13 for forming the internal space 14, but a conductive material can also be used. In this case, the conductive layer and the sealing material can be separated from each other, or an insulating material can be disposed between the two so as not to conduct. Alternatively, after the conductive layer is coated on the entire surface of the base glass plate, it can be disconnected so as not to come into contact with the sealing material with a laser or sandblast. Further, the conductive layer may be coated on the entire surface of the glass plate or may be coated on a part thereof.

<5-4>
In the said embodiment, although the conductive layer 15 is formed in the base glass plate 12, the conductive layer 15 can also be formed in the other glass plate 111. FIG. A conductive layer may be formed on a plurality of glass plates.

<5-5>
In the above embodiment, the heat generating glass panel is formed by three glass plates, but four or more glass plates can also be used. For example, an additional glass plate can be arrange | positioned at the 1st glass plate side or the base glass plate side, and also a space part can be formed. Thereby, the heat insulation performance can be further improved.

<5-6>
The configurations of the power transmission module 212 and the power reception module 222 of the power supply device 2 are not particularly limited, and an alternating current can be supplied to the power transmission electrode in the power transmission module, and the alternating current can be converted into a direct current and supplied to the conductive layer in the power reception module. What is necessary is just to be comprised. A DC-DC converter module can also be included in the power receiving module.

<5-7>
In the power supply device 2 in the above-described embodiment, the electric field coupling type non-contact power supply using a capacitor is performed. However, for example, an electromagnetic induction type non-contact power supply using a coil may be used.

<5-8>
In the power supply device 2 in the above embodiment, power is supplied to the heat generating glass panel 1 by non-contact power supply, but power can also be supplied by wire through a lead wire or the like. For example, when the heat generating glass panel is applied to a so-called fitting window, electric power can be supplied by wire.

<5-9>
In the above embodiment, each of the first electrode module 223 and the second electrode module 213 includes the first cushion member 2131 (2231) and the second cushion member 2132 (2232) having different hardnesses. Only two types of cushion members having different hardnesses may be provided. In this case, the other cushion member may be substantially the same hardness as the first cushion member.

Examples according to the present invention will be described below. However, the present invention is not limited to the following examples.
<1. Configuration of Examples and Comparative Examples>
Here, the exothermic glass panel which concerns on an Example and a comparative example was produced. The exothermic glass panel according to the example has the same configuration as that shown in the above embodiment, and the exothermic glass panel according to the comparative example forms a sealed internal space between two glass plates. The detailed configurations and thicknesses of these examples and comparative examples are as shown in Table 1. The heat transmissivity shown in Table 1 is a value when no current is supplied.

  The Low-E glass which concerns on an Example used what formed the tin oxide film into the film on the surface of the float glass. The exothermic glass is obtained by forming a conductive layer made of tin oxide on the surface of float glass. The sheet resistance value of the conductive layer is about 15Ω / □. In addition, the dimension of the glass used here is 900 mm x 600 mm. And the lead wire was connected with respect to the conductive layer, and electric power was supplied from the outside.

<2. Evaluation Test>
Electric power was supplied to the examples and comparative examples as described above under conditions of an indoor temperature of 20 degrees and an outside temperature of 0 degrees. And 1 hour after power supply, while measuring the glass temperature of the room inner side in an Example and a comparative example, the heat transmissivity was computed. The heat transmissibility was calculated based on JISR3107. The results are as shown in Table 2.

From the above results, the glass temperature on the indoor side of the example provided with the vacuum double-glazed glass is higher than that of the comparative example. Further, it was found that the comparative example has a higher heat transmissivity than the examples and is easily influenced by the outside air. Comparing the heat transmissivity before and after the power supply in each of the example and the comparative example, the glass panel of the comparative example has a heat transmissivity of 1.9 W / m ² K, but is about 1.7 W / m ² K due to the power supply. whereas was not only, in the embodiment, it is possible to what was 0.8 W / m ² K to achieve a free glass 0 W / m ² K, and the heat loss. It turns out that the exothermic glass panel of this invention exhibits the outstanding heat insulation performance.

1 Exothermic glass panel 12 Base glass plate (third glass plate)
111 First glass plate 112 Second glass plate 212 Power transmission module 2134 Power supply electrode 2135 Cover member 222 Power reception module 2234 Power reception electrode 2235 Cover member 3 Frame

Claims (6)

A first glass plate;
A second glass plate arranged to face the first glass plate at a predetermined interval;
A space sealed between the first glass plate and the second glass plate, the first space being decompressed;
A third glass plate disposed to face the second glass plate at a predetermined interval;
A second space that is sealed between the second glass plate and the third glass plate and sealed with dry air or a rare gas;
A conductive layer formed on at least one of the surfaces of the first glass plate and the third glass plate;
Equipped with an exothermic glass panel.   The heat generating glass panel according to claim 1, wherein the conductive layer is formed on a surface of the third glass plate that faces the second space portion.   The heat generating glass panel according to claim 1, further comprising a low radioactive film formed on at least one of the surfaces of the first to third glass plates. The exothermic glass panel according to any one of claims 1 to 3,
A power supply device for supplying power to the exothermic glass panel;
Equipped with a fever glass system. Further comprising a frame configured to support the heat generating glass panel and to be movable with respect to the window frame;
The power supply device
A power transmission module that generates alternating current;
A power transmission electrode attached to the window frame and supplied with an alternating current from the power transmission module;
A power receiving electrode attached to the frame and electrically connected to a conductive layer of the heat generating glass panel;
A power receiving module that converts an alternating current supplied from the power receiving electrode into a direct current and supplies it to the conductive layer of the heat generating glass panel; and
With
The capacitor is configured by arranging the power transmission electrode and the power reception electrode at a predetermined interval, and electric power is transmitted from the power transmission electrode to the power reception electrode via the capacitor. Fever glass system.   The heat generating glass system according to claim 5, wherein each of the power transmission electrode and the power reception electrode is covered with an insulating cover member.

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