KR102061578B1 - Window with energy re-generation - Google Patents

Abstract

The present invention is provided on the driving roller disposed between the glass fixing frame and the rail of the window frame portion, the piezoelectric element power generation unit for producing electricity and the solar power generation unit provided outside the glass fixing frame and the glass fixing frame provided inside the photovoltaic power generation It is a window capable of producing energy, including a battery that is charged by the unit and the piezoelectric element generator.

Description

Window for Energy Regeneration Method {WINDOW WITH ENERGY RE-GENERATION}

The present invention relates to a window and, in particular, a piezoelectric element power generation unit which is provided on a drive roller disposed between the glass fixing frame and the rail of the window frame to generate electricity and the solar power generating unit and the glass fixing frame provided outside the glass fixing frame. It is provided with a window that can produce energy, including a battery that is provided and charged by the photovoltaic unit and the piezoelectric element generator.

Generally referred to as a window includes a glass fixing frame (GF) to which the glass (G) is fixed as shown in Figure 1 and the window frame portion (F) to which the glass fixing frame (GF) is movable. The window frame portion (F) is formed with a protruding rail (R), the glass fixing frame (GF) is formed with a groove portion and a roller (RR) is installed so that the roller (RR) is in contact with the rail (R) The glass fixing frame GF is installed to be movable.

In addition, the rail R includes a first rail R1 formed at the indoor side and a second rail R2 formed at the outdoor side. Insect screen fixing frame (IF) is installed on the second rail (R2), the insect screen (I) is installed on the screen screen fixing frame (IF), the glass (G) is opened and closed by the window of this configuration.

By the way, the conventional windows and doors as described above have a problem in that it does not have the function of energy regeneration required in recent years merely serves to prevent rainstorm or insects.

The present invention is to solve the above problems, the piezoelectric element power generation unit provided on the drive roller disposed between the glass fixing frame and the rail of the window frame to generate electricity and the solar power generation unit and the glass provided outside the glass fixing frame An object of the present invention is to provide a window capable of producing energy, including a battery provided inside the fixing frame and charged by the solar power generation unit and the piezoelectric element power generation unit.

However, the object of the present invention is not limited to the above-mentioned object, and although not mentioned, other objects according to the following means or specific configurations in the embodiments will be clearly understood by those skilled in the art from the description. will be.

In order to achieve the above object, the present invention is provided with a piezoelectric element power generation unit 100 is provided in the drive roller RR disposed between the glass fixing frame (GF) and the rail (R) of the window frame portion (F) and The solar power generating unit 500 and the glass fixing frame GF which are provided outside the glass fixing frame GF and are provided in the solar power generating unit 500 and the piezoelectric element power generating unit 100 and the solar power generating unit. The battery BAT is charged by the (500), the piezoelectric element power generation unit 100 is a housing 160 accommodated in the mounting groove (RR1) of the drive roller (RR), and the housing 160 A piezoelectric element 110 installed therein and stacked in a plurality of layers, an internal electrode 120 provided between the piezoelectric elements 110 to receive power generated from the piezoelectric element 110, and inside the housing 160. Installed in and fixed to both sides of the piezoelectric element 110, and to the internal electrode 120. A pair of external electrodes 130 receiving power and a connection part 150 provided on the uppermost layer of the piezoelectric element 110 and in contact with the rail part R, wherein the connection part 150 is the rail part. Pressurized by contact with (R) to pressurize the piezoelectric element 110, and both ends of the piezoelectric element 110 are fixed to the pair of external electrodes 130 and pressed by the rail portion (R) It provides a window of the energy regeneration method for generating power and transferring electricity to the external electrode (130).

In the above, the solar power generation unit 500 and the piezoelectric element power generation unit 100 are connected to the control unit CON, respectively, and the solar power generation unit 500 and the piezoelectric element power generation unit 100 are the control unit CON. Each is controlled by to selectively charge the battery BAT or to charge the battery BAT altogether.

The external electrode 130 includes a first external electrode 130-1 receiving + polarity power and a second external electrode 130-2 receiving -polarity power, and the external electrode. 130 is formed of a plate-shaped external electrode body 131 and the insertion groove 132 formed in the longitudinal direction of the piezoelectric element 110 in the external electrode body 131, the insertion groove 132 is a piezoelectric A plurality of elements 110 are formed in a stacking direction, and both side ends of the piezoelectric elements 110 protrude in the direction of the external electrode 130 and are respectively inserted into the insertion grooves 132.

The internal electrode 120 may include a first internal electrode 121 and a second internal electrode 122 stacked between the piezoelectric elements 110, and the first internal electrode 121 and a second internal electrode. Comprising an insulating layer 123 provided between (122), the first inner electrode 121 is in contact with the first outer electrode 130-1, and transmits + polarity power, the second inner electrode ( 122 is in contact with the second external electrode 130-2 and transmits a negative polarity power, and an end of the first external electrode 130-1 side of the insulating layer 123 is bent to form the second internal electrode 122. To cover the first inner electrode 121 so that the first outer electrode 130-1 is not in contact with the first outer electrode 130-1, and the end portion of the insulating layer 123 is bent in the opposite direction to cover the first inner electrode 121. Do not contact the second external electrode 130-2.

In the above description, the connection part 150 includes a contact plate 151 which contacts the rail R, a pair of brackets 152 provided on the piezoelectric element 110 of the uppermost layer, and the contact plate 151. The hinge 153 is provided on the bottom surface and is pin-coupled to the bracket 152.

In the above, the housing 160 has a hollow shape and one side thereof is opened to provide a housing main body 161 into which the piezoelectric element 110 and the external electrode 130 are inserted, and are provided inside the housing main body 161. A partition plate 162 partitions the inside of the housing body 161 and the piezoelectric element 110 is seated therein, and an auxiliary battery AUX is provided in a space between the partition plate 162 and the bottom of the housing body 161. It is provided and connected to the external electrode 130, both sides of the partition plate 262 is open so that the lower end of the external electrode 130 enters contact with the auxiliary battery (AUX), the auxiliary battery (AUX) is the glass The battery BAT is connected to the battery BAT provided in the fixing frame GF.

In the above, the piezoelectric element power generation unit 100 includes a power connection unit 170 which is provided outside the glass fixing frame GF and rotates in association with the shaft RR2 of the driving roller RR, and the power connection unit The 170 is made of a conductor and is electrically connected to the external electrode 130. The power connection unit 170 has the shaft RR2 housed therein and is interlocked by the shaft RR2. The connecting portion main body 171 of the, the groove portion 172 is formed on the outer side of the connecting portion main body 171, the transmission portion 173 is inserted into the groove portion 172 and electrically connected to the connecting portion main body 171. ), One side of the transfer unit 173 is fixed to the glass fixing frame (GF) and the other side is inserted into the recess 172 to maintain a fixed state, the transfer unit 173 is the battery ( BAT).

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings.

Prior to this, the terms or words used in the present specification and claims should not be interpreted in the ordinary and dictionary sense, and the inventors may appropriately define the concept of terms in order to best explain their own invention. It should be noted that the technical terms used in the present specification based on the principle of the present invention are merely used to describe specific embodiments, and are not intended to limit the present invention.

In addition, the technical terms used in the present specification should be interpreted as meanings generally understood by those skilled in the art to which the present invention belongs, unless specifically defined otherwise in the present specification, and excessively comprehensive It should not be construed in meaning or in excessively reduced sense.

Also, the singular forms used herein include the plural forms unless the context indicates otherwise. In the present application, terms such as “consisting of” or “comprising” should not be construed as necessarily including all of the various components or steps described in the specification, and some of the components or some steps It should not be included or should be construed to include additional components or steps and should be interpreted as meanings and concepts consistent with the technical idea.

The present invention described above has the effect of producing energy in accordance with the use of windows and doors.

1 is a schematic diagram illustrating a general window and doors,
2 is a schematic view showing a window of the energy recovery method according to an embodiment of the present invention,
3 to 5 are a perspective view and a schematic view showing a piezoelectric element power generation unit of the window of the energy regeneration method according to an embodiment of the present invention,
6 is a piezoelectric element power generation unit according to an embodiment of the present invention;

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description.

In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary depending on the intention or convention of a user or an operator. Therefore, the definitions of these terms should be made based on the contents throughout the specification.

In addition, the following examples are not intended to limit the scope of the present invention, but merely illustrative of the components set forth in the claims of the present invention, which are included in the technical spirit throughout the specification of the present invention and constitute the claims Embodiments that include components substitutable as equivalents in the elements may be included in the scope of the present invention.

Window 10 according to an embodiment of the present invention is provided in the drive roller (RR) disposed between the glass fixing frame (GF) and the rail (R) of the window frame portion (F) as shown in Figs. And the piezoelectric element generator 100 to produce electricity and the solar power generating unit 500 and the glass fixing frame GF provided outside the glass fixing frame GF and the solar power generating unit 500. The battery BAT is charged by the piezoelectric element generator 100 and the photovoltaic generator 500. That is, electricity is produced by the piezoelectric element generator 100, and electricity is also generated by the solar power generator 500.

Conventional windows and doors merely perform the traditional function of preventing the weather as described above, according to the present invention can be added to the ability to produce electricity.

The piezoelectric element power generation unit 100 includes a housing 160 accommodated in the mounting groove RR1 of the driving roller RR, a piezoelectric element 110 installed in the housing 160 and stacked in multiple layers, The internal electrode 120 provided between the piezoelectric elements 110 to receive power generated from the piezoelectric element 110, and installed and fixed inside the housing 160, respectively, on both sides of the piezoelectric element 110. A pair of external electrodes 130 are disposed and receives power from the internal electrode 120, and a connection part 150 provided on the uppermost layer of the piezoelectric element 110 and in contact with the rail part R.

The piezoelectric element, as is well known, means that power is generated when the size is changed by an input of a power source or when the size is changed by an external voltage. The present invention uses the piezoelectric element to produce electricity.

That is, the driving roller RR is pressed by the weight of the glass fixing frame GF in which the glass GF is installed, and contacts the rail R1. The piezoelectric element power generation unit 100 of the present invention is installed in the seating groove RR1 of the driving roller RR, is pressed by the weight of the glass fixing frame GF, is pressed by the rail R1, and is subjected to electric power. Will produce.

In more detail, the piezoelectric element 110 is pressed to generate electricity. The generated electrode is delivered to the inner electrode 120 and to the outside through the outer electrode 130.

On the other hand, the connecting portion 150 is pressed by the contact with the rail portion (R) to press the piezoelectric element 110, both ends of the piezoelectric element 110 to the pair of external electrodes 130, respectively It is fixed and pressurized by the rail part R to generate power and transfer electricity to the external electrode 130 as described above.

On the other hand, as described above, after stacking a plurality of piezoelectric elements, the technique of disposing the internal electrodes between the piezoelectric elements and the external electrodes on the outside is well known, and in particular, US Patent No. 8,237,333 and Japanese Patent No. 3881474. As described in, a detailed description and illustration thereof are omitted.

The external electrode 130 includes a first external electrode 130-1 receiving + polarity power and a second external electrode 130-2 receiving -polarity power. The external electrode 130 is formed of a plate-shaped external electrode body 131 and the insertion groove 132 formed in the longitudinal direction of the piezoelectric element 110 in the external electrode body 131, the insertion groove 132 ) Are formed in plural in the stacking direction of the piezoelectric element 110. Both side ends of the piezoelectric element 110 protrude in the direction of the external electrode 130 and are respectively inserted into the insertion grooves 132. That is, as shown, the width of the piezoelectric element 110 is larger than the width of the internal electrode 120 so that both side ends of the piezoelectric element 110 protrude.

The internal electrode 120 includes a first internal electrode 121 and a second internal electrode 122 stacked between the piezoelectric elements 110, and the first internal electrode 121 and a second internal electrode 122. It consists of an insulating layer 123 provided in between. The first internal electrode 121 is in contact with the first external electrode 130-1 to transmit a positive polarity power, and the second internal electrode 122 is in contact with the second external electrode 130-2 -polar. Pass the power. At this time, the end portion of the first external electrode 130-1 of the insulating layer 123 is bent to cover the second internal electrode 122 so as not to contact the first external electrode 130-1, and the insulating layer An end portion of the second external electrode 130-2 side of 123 is bent in the opposite direction to cover the first internal electrode 121 so as not to contact the second external electrode 130-2.

That is, the first internal electrode 121 is disposed below the one piezoelectric element 110, and the second internal electrode 122 is disposed above the piezoelectric element 110. The first inner electrode 121 is energized by the first outer electrode 130-1 to supply a positive polarity power to the auxiliary battery 170, which will be described later, and the second inner electrode 122 may include a second outer electrode ( 130-2), and supplies -polar power to the auxiliary battery 170 side.

Since the first internal electrode 121 and the second internal electrode 122 receive power having opposite polarities, an insulating layer 123 is disposed therebetween. At this time, the end portion of the first external electrode 130-1 of the insulating layer 123 is bent to cover the second internal electrode 122 so as not to contact the first external electrode 130-1, and the insulating layer An end portion of the second external electrode 130-2 side of 123 is bent in the opposite direction to cover the first internal electrode 121 so as not to contact the second external electrode 130-2.

That is, since the first external electrode 130-1 is supplied with + polarity power and the second internal electrode 122 is supplied with -polar power, as described above, the first external electrode 130-1 should not be electrically connected to each other. To this end, the insulating layer 123 is bent to cover the second inner electrode 122, thereby insulating the second inner electrode 122 and the first outer electrode 131.

Similarly, an end portion of the insulating layer 123 of the second outer electrode 130-2 is bent in an opposite direction to cover the first inner electrode 121. As a result, the first inner electrode 121 to which + power is applied does not come into contact with the second outer electrode 130-2 to which −polar power is applied.

On the other hand, it is also possible to form an insulating coating 133 in the insertion groove 132 of the external electrode 130 so that power is applied only to the internal electrode 120.

The connection part 150 may include a contact plate 151 which contacts the rail R, a pair of brackets 152 provided on the piezoelectric element 110 of the uppermost layer, and a bottom surface of the contact plate 151. It is provided with a hinge 153 that is provided and pin coupled to the bracket 152. That is, when the contact plate 151 is pressed against the rail R, the force is transmitted to the piezoelectric element 110 through the bracket 152.

The housing 160 has a hollow shape and one side thereof is opened to provide a housing main body 161 into which the piezoelectric element 110 and the external electrode 130 are inserted, and are provided in the housing main body 161 to provide the housing main body ( 161 partitions the inside and consists of a partition plate 162 on which the piezoelectric element 110 is seated,

An auxiliary battery (AUX) is provided in a space between the partition plate 162 and the bottom of the housing body 161 to be connected to the external electrode 130, and both sides of the partition plate 262 are open to open the external electrode 130. A lower end of the lower surface enters and contacts the auxiliary battery AUX. The auxiliary battery AUX is connected to a battery BAT provided in the glass fixing frame GF to charge the battery BAT.

Opening slits 162a are formed at both sides of the partition plate 262 to be opened, and a lower end of the external electrode 130 enters through the open slits 162a to be in contact with the auxiliary battery AUX to transfer power. It is also possible.

Meanwhile, the external electrode 130 is fixed inside the housing 160, and for this purpose, a method such as bolting or welding may be used.

In addition, since the pair of external electrodes 130 are disposed to contact both sides of the elastic piezoelectric element 110, the distance D1 between the outer surfaces of the pair of external electrodes 130 is equal to that of the housing 160. It should be equal to or smaller than the median distance D2.

As described above, electricity is generated by the piezoelectric element generator 100 and the photovoltaic generator 500, respectively. In this case, the solar power generation unit 500 and the piezoelectric element power generation unit 100 are connected to the control unit CON, respectively, and the solar power generation unit 500 and the piezoelectric element power generation unit 100 are connected to the control unit CON. Respectively controlled to selectively charge the battery BAT or both to charge the battery BAT.

 For example, the battery BAT is charged by using the power generated by the solar power generation unit 500 by the controller CON, or the battery BAT is charged by using the power generated by the piezoelectric element power generation unit 100. do. Of course, the control unit CON may charge the battery BAT by using all of the power generated by the piezoelectric element generator 100 and the photovoltaic unit 500.

Since the control unit CON is a well-known configuration, detailed description and illustration are omitted.

Meanwhile, as illustrated in FIG. 6, the piezoelectric element power generation unit 100 and the solar power generation unit 500 are connected to the control unit CON through the connection terminal T. For example, the + polarity power and the -polar power generated in the piezoelectric element power generation unit 100 are connected to the + terminal and the-terminal of the connection terminal, respectively, through the control unit CON and a separate connection terminal T. It is connected to the battery 420 to charge the battery 420. Such a configuration itself is well known and is described in detail in Korean Patent Registration No. 10-1687399, which will not be described and illustrated.

The controller CON may be operated by a user by wire or wirelessly.

Meanwhile, the piezoelectric element power generation unit 100 is provided in the driving roller RR as shown in FIG. 2. The driving roller RR rotates in accordance with the movement of the glass fixing frame GF. As shown for smooth rotation of the driving roller RR, shafts RR2 are installed at both side ends of the driving roller RR, and the shaft RR2 penetrates both grooved side ends of the glass fixing frame GF. Are exposed to the outside. The glass fixing frame GF is provided with a bearing BRG to facilitate smooth rotation of the shaft RR2. On the other hand, in the piezoelectric element power generation unit 100 of the present invention as described above generates electricity by contact with the rail (R1) and the electricity produced in the piezoelectric element power generation unit 100 is supplied to the battery (BAT). .

In order to apply the electricity produced by the piezoelectric element power generation unit 100 to the battery BAT side, as shown in FIG. 7, the glass fixing frame GF is provided outside the shaft RR2 of the driving roller RR. It includes a power connection unit 170 that rotates in conjunction. The power connection unit 170 is made of a conductor and is electrically connected to the external electrode 130.

The power connection portion 170 is the yaw formed in the shaft RR2 is accommodated therein and interlocked by the shaft RR2, the connection body 171 of the rolling material material and the outside of the connection body 171. And a transmission part 173 inserted into the groove part 172 and electrically connected to the connection part main body 171. At this time, one side of the transmission unit 173 is fixed to the glass fixing frame (GF) and the other side is inserted into the groove portion 172 to maintain a fixed state.

That is, as illustrated in FIGS. 2 and 7, the electricity generated in the piezoelectric element power generation unit 100 is transferred to the shaft RR2 via an external electrode. The shaft RR2 is connected to the power connection unit 170 so that electricity is transferred from the shaft RR2 to the power connection unit 170.

The connection unit body 171 of the power connection unit 170 is rotated in conjunction with the shaft RR2. In addition, the transmission unit 173 is inserted into the recess 172 of the connecting unit body 171 and one side is fixed to the glass fixing frame (GF) to maintain a fixed state. That is, the transmission unit 173 maintains a fixed state while maintaining contact with the connection unit body 171, and electricity is transmitted from the connection unit body 171 to the transmission unit 173.

The transfer unit 173 may be connected to the battery BAT and may use a well-known wiring W for this purpose.

As shown in FIG. 2, the transfer unit 173 is provided at both sides of the glass fixing frame GF, and the + power source and the − power source are respectively connected to the battery to charge the battery.

Meanwhile, as described above, the shaft RR2 may receive electricity from the piezoelectric element power generation unit 100, and a wire disposed inside the shaft RR2 is connected to an external electrode of the piezoelectric element power generation unit 100. Can receive electricity. At this time, the wiring is disposed inside the shaft RR2 and connected to the connection body 171 of the power connection unit 170 so that electricity is transferred to the connection body 171 and then through the transfer unit 173 as described above. (BAT) can be charged.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, those skilled in the art to which the present invention pertains can realize that the present invention can be implemented in other specific forms without changing the technical spirit or essential features. I can understand.

Therefore, the embodiments described above are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention described in the above detailed description is represented by the following claims, and the meanings of the claims and All changes or modifications derived from the scope and equivalent concepts thereof should be construed as being included in the scope of the present invention.

100 piezoelectric element power generation unit 110 piezoelectric element
120: internal electrode 121: first internal electrode
122: second internal electrode 123: insulating layer
130: external electrode 131: external electrode body
132: insertion groove 150: connection portion
151: elastic contact plate 152: bracket
153: hinge 160: housing
161: housing body 162: partition plate
500: solar power generation unit

Claims (7)

It is provided on the driving roller RR disposed between the glass fixing frame GF and the rail R of the window frame part F and is provided outside the glass fixing frame GF and the piezoelectric element power generation unit 100 for producing electricity. A battery BAT provided in the solar power generation unit 500 and the glass fixing frame GF and charged by the solar power generation unit 500, the piezoelectric element power generation unit 100, and the solar power generation unit 500. ),
The piezoelectric element power generation unit 100 includes a housing 160 accommodated in the mounting groove RR1 of the driving roller RR, a piezoelectric element 110 installed in the housing 160 and stacked in multiple layers, The internal electrode 120 provided between the piezoelectric elements 110 to receive power generated from the piezoelectric element 110, and installed and fixed inside the housing 160, respectively, on both sides of the piezoelectric element 110. A pair of external electrodes 130 disposed on and received power from the internal electrodes 120, and a connection part 150 provided on the uppermost layer of the piezoelectric elements 110 and in contact with the rail part R,
The connection portion 150 is pressed by the contact with the rail portion (R) to press the piezoelectric element 110,
Both ends of the piezoelectric element 110 are respectively fixed to the pair of external electrodes 130 and pressurized by the rail unit R to generate power and transfer electricity to the external electrodes 130. Window. The method of claim 1,
The solar power generation unit 500 and the piezoelectric element power generation unit 100 are connected to the control unit CON, respectively.
The solar power generation unit 500 and the piezoelectric element power generation unit 100 are respectively controlled by the control unit (CON) to selectively charge the battery (BAT) or all windows of the energy regeneration method for charging the battery (BAT). The method of claim 1,
The external electrode 130 includes a first external electrode 130-1 receiving + polarity power and a second external electrode 130-2 receiving -polarity power,
The external electrode 130 is formed of a plate-shaped external electrode body 131 and the insertion groove 132 formed in the longitudinal direction of the piezoelectric element 110 in the external electrode body 131, the insertion groove 132 ) Are formed in plural in the stacking direction of the piezoelectric element 110,
Both side ends of the piezoelectric element 110 protrude in the direction of the external electrode 130, respectively, the windows of the energy regeneration method is inserted into the insertion groove (132). The method of claim 3,
The internal electrode 120 includes a first internal electrode 121 and a second internal electrode 122 stacked between the piezoelectric elements 110, and the first internal electrode 121 and a second internal electrode 122. It is made of an insulating layer 123 provided between,
The first internal electrode 121 is in contact with the first external electrode 130-1 to transmit a positive polarity power, and the second internal electrode 122 is in contact with the second external electrode 130-2 -polar. Power,
One end of the first external electrode 130-1 of the insulating layer 123 is bent to cover the second internal electrode 122 so as not to contact the first external electrode 130-1, and the insulating layer 123. The second external electrode 130-2 side end portion is bent in the opposite direction to cover the first internal electrode 121 so as not to contact the second external electrode 130-2. The method of claim 1,
The connection part 150 is a contact plate 151 in contact with the rail (R),
A pair of brackets 152 provided on the uppermost piezoelectric element 110 and a hinge 153 provided on the bottom surface of the contact plate 151 and pin-coupled to the brackets 152, Window. The method of claim 1,
The housing 160 has a hollow shape and one side thereof is opened to provide a housing main body 161 into which the piezoelectric element 110 and the external electrode 130 are inserted, and are provided in the housing main body 161 to provide the housing main body ( 161 partitions the inside and consists of a partition plate 162 on which the piezoelectric element 110 is seated.
An auxiliary battery (AUX) is provided in a space between the partition plate 162 and the bottom of the housing body 161 to be connected to the external electrode 130.
Both sides of the partition plate 162 are opened to enter a lower end of the external electrode 130 to contact the auxiliary battery AUX.
The auxiliary battery (AUX) is connected to a battery (BAT) provided in the glass fixing frame (GF) is a window of the energy recovery method for charging the battery (BAT). The method of claim 1,
The piezoelectric element power generation unit 100 includes a power connection unit 170 provided outside the glass fixing frame GF and rotated in association with the shaft RR2 of the driving roller RR.
The power connection unit 170 is made of a conductor and electrically connected to the external electrode 130,
The power connection unit 170 is accommodated therein, the shaft RR2 is interlocked by the shaft RR2, the rolling member body of the rolling material material 171 and the recess formed on the outer side of the connecting body (171) 172 and a transmission part 173 inserted into the recess 172 and electrically connected to the connection part main body 171.
One side of the transmission unit 173 is fixed to the glass fixing frame (GF) and the other side is inserted into the groove 172 to maintain a fixed state,
The transmission unit (173) is a window of the energy recovery method is connected to the battery (BAT).

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