CN113715588A

CN113715588A - Window glass, door and car

Info

Publication number: CN113715588A
Application number: CN202110972016.9A
Authority: CN
Inventors: 余德桢; 郭才; 李风华; 易子越
Original assignee: Shenzhen Wicue Optoelectronics Co Ltd
Current assignee: Shenzhen Wicue Optoelectronics Co Ltd
Priority date: 2021-08-23
Filing date: 2021-08-23
Publication date: 2021-11-30
Also published as: WO2023024491A1

Abstract

The invention discloses window glass, a vehicle door and a vehicle, wherein the window glass comprises a controller, an adjusting device, a first outer layer, a first substrate, a liquid crystal layer, a second substrate and a second outer layer which are sequentially stacked; the first outer layer, the first substrate, the second substrate and the second outer layer are all light-transmitting layers, one surface of the first substrate, facing the liquid crystal layer, is provided with a plurality of first conductive strips arranged at intervals, and one surface of the second substrate, facing the liquid crystal layer, is provided with a plurality of second conductive strips arranged in a staggered mode with the first conductive strips; each first conductive strip and each second conductive strip are electrically connected with a controller, the adjusting device is in signal connection with the controller, the controller determines a dimming area according to an input signal of the adjusting device, and corresponding dimming voltage signals are applied to two sides of the liquid crystal layer part opposite to the dimming area so as to adjust the brightness and darkness states of the dimming area. According to the technical scheme, the brightness of different areas of the car window glass can be independently adjusted, and more requirements of users are met.

Description

Window glass, door and car

Technical Field

The invention relates to the technical field of automobiles, in particular to window glass, an automobile door and an automobile.

Background

The automobile window is an automobile window, and the interior of a carriage forms a relatively closed whole, so that the effects of keeping out wind and rain, keeping the temperature in the automobile and allowing passengers in the automobile to observe the surrounding environment are achieved. The vehicle window is usually made of glass materials, and with the progress and breakthrough of vehicle window glass material technology, more new functional vehicle window glass appears, such as dimmable vehicle window glass. At present, the brightness of the window glass of adjustable light can be adjusted together in the area of the whole window glass, and the brightness of different areas of the window glass can not be adjusted independently, so that more requirements of users can not be met.

Disclosure of Invention

The invention provides vehicle window glass, and aims to solve the problem that the brightness of different areas of the vehicle window glass cannot be independently adjusted.

The invention provides vehicle window glass, which comprises a controller, an adjusting device, a first outer layer, a first substrate, a liquid crystal layer, a second substrate and a second outer layer, wherein the first outer layer, the first substrate, the liquid crystal layer, the second substrate and the second outer layer are sequentially stacked; the first outer layer, the first substrate, the second substrate and the second outer layer are all light-transmitting layers, one surface of the first substrate, facing the liquid crystal layer, is provided with a plurality of first conductive strips arranged at intervals, and one surface of the second substrate, facing the liquid crystal layer, is provided with a plurality of second conductive strips arranged in a staggered mode with the first conductive strips;

each first conductive strip and each second conductive strip are electrically connected with the controller, the adjusting device is in signal connection with the controller, the controller determines a dimming area according to an input signal of the adjusting device, and corresponding dimming voltage signals are applied to two sides of the liquid crystal layer part opposite to the dimming area so as to adjust the brightness and darkness states of the dimming area.

Preferably, the adjusting device includes a first adjusting knob, and the controller determines the corresponding dimming region according to a rotation amount signal of the first adjusting knob.

Preferably, the adjusting device includes a plurality of first dimming keys, and the controller determines the corresponding dimming region according to a key signal of one of the first dimming keys, or the controller determines the corresponding dimming region according to a combination of key signals of a plurality of the first dimming keys.

Preferably, the controller further determines the magnitude of the dimming voltage signal according to an input signal of the adjusting device.

Preferably, the adjusting device further comprises a second adjusting knob, and the controller determines the magnitude of the dimming voltage signal according to a rotation amount signal of the second adjusting knob.

Preferably, the adjusting device further comprises a plurality of second dimming keys, and the controller determines the magnitude of the dimming voltage signal according to a key signal of one of the second dimming keys, or determines the magnitude of the dimming voltage signal according to a combination of key signals of a plurality of the second dimming keys.

Preferably, the corner of the window glass is provided with a receiving part, and the controller is installed in the receiving part.

Preferably, a photovoltaic cell assembly for supplying power to the controller is arranged on the controller.

Preferably, the photovoltaic cell assembly comprises a photovoltaic power generation module and an energy storage module, wherein an output end of the photovoltaic power generation module is electrically connected with a charging end of the energy storage module so as to store the converted electric energy into the energy storage module; the detection end of the controller is electrically connected with the output end of the photovoltaic power generation module so as to detect the voltage of the output end of the photovoltaic power generation module;

in the automatic dimming mode, the controller determines the intensity of ambient light according to the voltage of the detection end of the controller, and determines a corresponding dimming mode according to the intensity of the ambient light in a preset mode to perform dimming, wherein the dimming mode comprises the position of a dimming area and the magnitude of a dimming voltage signal.

Preferably, the controller turns off the automatic dimming mode when receiving an input signal of the adjusting device.

The invention further provides a vehicle door, which comprises a door body and door glass, wherein the door glass is the vehicle window glass, and the adjusting device of the vehicle window glass is arranged on the inner side of the door body.

The invention further provides an automobile, wherein at least one of the front windshield glass, the rear windshield glass, the skylight glass and each door glass of the automobile is the automobile window glass.

In the technical scheme of the vehicle window glass, a first substrate on one side of a liquid crystal layer is provided with a plurality of first conductive strips arranged at intervals, a second substrate on the other side of the liquid crystal layer is provided with a plurality of second conductive strips arranged in a staggered manner with the first conductive strips, and the first substrate and the second substrate form latticed electrode pairs on two sides of the liquid crystal layer, so that a controller can control the brightness degree of a corresponding liquid crystal layer grid area of the electrode pair by independently applying a dimming voltage signal on any electrode pair; a user operates the adjusting device according to requirements, so that the adjusting device generates corresponding electric signals to be input into the controller, the controller determines a corresponding dimming area according to the input signals of the adjusting device, and applies dimming voltage signals to the electrode pairs corresponding to the determined dimming area so as to apply the dimming voltage signals to two sides of the liquid crystal layer part opposite to the dimming area to adjust the bright and dark states of the dimming area; so, effectual solved can't be to the problem of the bright dark independent control in window glass's different regions, better satisfying more demands of user.

Drawings

FIG. 1 is a schematic structural view of one embodiment of a vehicle glazing of the present invention;

FIG. 2 is a schematic structural diagram of a first conductive strip, a liquid crystal layer and a second conductive strip in an embodiment of the window pane of the present invention;

FIG. 3 is a schematic structural view of an embodiment of the present invention in which a window glass is mounted to a vehicle door;

FIG. 4 is a schematic structural view of another embodiment of the present invention for mounting a window pane to a vehicle door;

FIG. 5 is a schematic view of a zone division of the dimming area in an embodiment of the window glass of the present invention;

FIG. 6 is a schematic view of a zone division of the dimming area in an embodiment of the window glass of the present invention;

FIG. 7 is another schematic structural view of an embodiment of the window pane of the present invention;

fig. 8 is a schematic block diagram of a photovoltaic module according to an embodiment of the present invention.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary and intended to be illustrative of the present invention and should not be construed as limiting the present invention, and all other embodiments that can be obtained by one skilled in the art based on the embodiments of the present invention without inventive efforts shall fall within the scope of protection of the present invention.

The invention provides a vehicle window glass which is mainly applied to an automobile.

Referring to fig. 1, in the present embodiment, the window glass 100 includes a controller 10, an adjustment device 20, and a first outer layer 30, a first substrate 40, a liquid crystal layer 50, a second substrate 60, and a second outer layer 70, which are sequentially stacked.

The first outer layer 30, the first substrate 40, the second substrate 60, and the second outer layer 70 are transparent layers made of transparent material. For example, the first outer layer 30 and the second outer layer 70 are glass layers, typically rigid structures, but may be flexible in some particular application requirements; the first and

second substrates

40 and 60 may be formed of one of flexible materials of Polycarbonate (PC), polyethylene terephthalate (PET), or Triacetylcellulose (TAC).

Referring to fig. 2, a plurality of first conductive strips 41 are disposed on the first substrate 40 at intervals, and a plurality of second conductive strips 61 are disposed on the second substrate 60 and are staggered with respect to the first conductive strips 41, so that the first substrate 40 and the second substrate 60 form a grid-shaped electrode pair on two sides of the liquid crystal layer 50. In a preferred embodiment of the window glass 100, the first conductive strips 41 and the second conductive strips 61 are vertically staggered, and the first conductive strips 41 on the first substrate 40 and the second conductive strips 61 on the second substrate 60 are uniformly spaced, so that the grid-shaped electrode pairs formed on both sides of the liquid crystal layer 50 are uniformly distributed; of course, in other embodiments, the first conductive strips 41 and the second conductive strips 61 may also be disposed in a non-perpendicular staggered manner, and the first conductive strips 41 and the second conductive strips 61 may also be disposed in a non-equidistant spacing arrangement. It should be noted that the figures are only schematic diagrams of the first substrate 40, the liquid crystal layer 50 and the two conductive layers, and in practice, the number of the first conductive strips 41 and the second conductive strips 61 may be greater, and the distribution density may be greater. Of course, first conductive strips 41 and second conductive strips 61 are formed of a transparent conductive material, such as indium tin oxide ITO or nano silver.

Wherein the controller 10 is electrically connected to each of the first conductive strips 41 and each of the second conductive strips 61, the controller is in signal connection (i.e., electrically connected or wirelessly connected) with the adjusting device 20, the controller 10 determines a dimming area according to an input signal of the adjusting device 20, and applies corresponding dimming voltage signals to two sides of a portion of the liquid crystal layer 50 opposite to the dimming area to adjust a brightness state of the dimming area. By operating the adjusting device 20, the adjusting device 20 generates a corresponding electrical signal and inputs the electrical signal to the controller 10, the controller 10 determines a dimming region corresponding to the input signal according to the input signal of the adjusting device 20, identifies each of the first conductive strips 41 and each of the second conductive strips 61 corresponding to the dimming region according to the position of the dimming region, applies the corresponding electrical signal to each of the identified first conductive strips 41 and each of the identified second conductive strips 61 (i.e. applies a dimming voltage signal to the pair of electrodes corresponding to the dimming region), applies the dimming voltage signal to both sides of the portion of the liquid crystal layer 50 opposite to the dimming region, and changes the states of all liquid crystal cells of the portion of the liquid crystal layer 50 opposite to the dimming region, thereby changing the transmittance of the portion of the liquid crystal layer 50 opposite to the dimming region, i.e. changing the bright and dark states of the dimming region.

In the window glass 100 of the present embodiment, the first substrate 40 on one side of the liquid crystal layer 50 is provided with a plurality of first conductive strips 41 arranged at intervals, the second substrate 60 on the other side of the liquid crystal layer 50 is provided with a plurality of second conductive strips 61 arranged in a staggered manner with the first conductive strips 41, and the first substrate 40 and the second substrate 60 form a latticed electrode pair on two sides of the liquid crystal layer 50, so that the controller 10 can apply a dimming voltage signal on any electrode pair individually to control the brightness of the corresponding grid area of the liquid crystal layer 50 of the electrode pair. The user can operate the adjusting device 20 according to the requirement, so that the adjusting device 20 generates a corresponding electric signal to be input to the controller 10, the controller 10 determines a corresponding dimming region according to the input signal of the adjusting device 20, and then applies a dimming voltage signal to the electrode pair corresponding to the determined dimming region, so as to apply the dimming voltage signal to both sides of the part of the liquid crystal layer 50 opposite to the dimming region, so as to adjust the bright and dark states of the dimming region; therefore, the problem that the brightness of different areas of the window glass 100 cannot be adjusted independently is effectively solved, and more requirements of users are better met.

Further, referring to fig. 3, in an embodiment, the adjusting device 20 includes a first adjusting knob 21, and the controller 10 determines the corresponding dimming region according to a rotation amount signal of the first adjusting knob 21. For example, the first adjusting knob 21 may have a plurality of gears, when the first adjusting knob 21 is rotated to different gears, the magnitude of the rotation amount signal (e.g., voltage signal) output to the controller 10 is different, and the controller 10 determines the dimming areas at different positions or different magnitudes according to the received voltage signals with different magnitudes. For another example, each angular position to which the first adjusting knob 21 is rotated corresponds to a rotation quantity signal, the voltage of the rotation quantity signal gradually changes along with the rotation angle of the first adjusting knob 21, and the controller 10 determines the dimming regions at different positions or different sizes according to the received rotation quantity signals with different voltage magnitudes.

Referring to fig. 5 and 6, for example, in an example, the first adjusting knob 21 has a plurality of shift positions, wherein when the first adjusting knob 21 is rotated to the first shift position, the second shift position, and the third shift position, the controller 10 correspondingly determines that the I region, the II region, and the III region of the window glass 100 are dimming regions, respectively; when the first adjusting knob 21 is rotated to the zero gear position, no signal is output to the controller 10 by the adjusting device 20, and no darkened area exists on the window glass 100; when the first dial knob 21 is rotated to the fourth gear, the fifth gear, and the sixth gear, respectively, the controller 10 determines the regions I and II, the regions II and III, and the entire region of the window glass 100 as the dimming region, respectively.

Further, referring to fig. 4, in an embodiment, the adjusting device 20 includes a plurality of first dimming keys 22, and the controller 10 determines the corresponding dimming region according to a key signal of one first dimming key 22. For example, the key signal is a voltage signal generated after the first dimming key 22 is pressed, the voltage of the voltage signal generated after each first dimming key 22 is pressed is different, and the controller 10 determines the corresponding dimming area according to the voltage of the received key signal; for another example, the key signal is a high level signal generated after the first dimming key 22 is pressed, the first dimming keys 22 are electrically connected to the plurality of input terminals of the controller 10 in a one-to-one correspondence manner, when a user presses one of the first dimming keys 22, the input terminals of the controller 10 corresponding to the first dimming key 22 receive the high level signal, and the controller 10 determines the corresponding dimming area according to the input terminal of the received high level signal. Alternatively, in the present embodiment, the controller 10 determines the corresponding dimming region according to a combination of key signals of the plurality of first dimming keys 22; for example, the key signal is a high level signal generated after the first dimming key 22 is pressed, the plurality of first dimming keys 22 are electrically connected to the plurality of input terminals of the controller 10 in a one-to-one correspondence manner, when the user presses the plurality of first dimming keys 22, the controller 10 receives the high level signal from the plurality of input terminals corresponding to the plurality of pressed first dimming keys 22, and the controller 10 determines the corresponding dimming region according to a combination of the input terminals of the received high level signal.

Referring to fig. 5 and 6, for example, in an example, the adjusting device 20 includes three first dimming keys 22, wherein when the first dimming key 22, the second dimming key 24 and the third dimming key are pressed, the controller 10 correspondingly determines the I region, the II region and the III region of the window glass 100 as dimming regions; when none of the first dimming keys 22 is pressed, the regulator 20 outputs no signal to the controller 10, and there is no darkened area on the window glass 100; when all of the three first dimming keys 22 are pressed, the controller 10 determines that the entire area of the window glass 100 is a dimming area.

Further, referring to fig. 3, in the present embodiment, the controller 10 further determines the magnitude of the dimming voltage signal according to the input signal of the adjusting device 20. The user operates the adjusting device 20 to make the adjusting device 20 generate a corresponding electric signal to be input to the controller 10, and the controller 10 determines the magnitude of the dimming voltage signal corresponding to the input signal according to the input signal of the adjusting device 20, so that the dimming voltage signal with the determined magnitude is applied to both sides of the portion of the liquid crystal layer 50 opposite to the dimming region. The greater the voltage of the dimming voltage signal applied to both sides of the portion of the liquid crystal layer 50 opposite to the dimming region, the lower the transmittance of the portion of the liquid crystal layer 50 opposite to the dimming region, and the heavier the dimming degree, so that the user can not only select the dimming region of the window glass 100 by operating the adjusting device 20, but also control the dimming degree of the dimming region, and can better meet more requirements of the user.

Further, in an embodiment, the adjusting device 20 further includes a second adjusting knob 23, and the controller 10 determines the magnitude of the dimming voltage signal according to a rotation amount signal of the second adjusting knob 23. For example, the second adjustment knob 23 may have a plurality of gears, when the second adjustment knob 23 is rotated to different gears, the rotation amount signal (e.g., voltage signal) output to the controller 10 is different in magnitude, and the controller 10 determines the dimming voltage signal with different voltage magnitudes according to the received voltage signals with different voltage magnitudes. For another example, each rotated angle position of the second adjusting knob 23 corresponds to a rotation amount signal, the voltage of the rotation amount signal gradually changes along with the rotation angle of the second adjusting knob 23, and the controller 10 determines the dimming voltage signals with different voltages according to the received rotation amount signals with different voltages.

Further, referring to fig. 4, in an embodiment, the adjusting device 20 further includes a plurality of second dimming keys 24, and the controller 10 determines a corresponding dimming voltage signal according to a key signal of one of the second dimming keys 24; for example, the key signal is a voltage signal generated after the second dimming key 24 is pressed, the voltage of the voltage signal generated after each second dimming key 24 is pressed is different, and the controller 10 determines the dimming voltage signal corresponding to the voltage according to the voltage of the received key signal; for another example, the key signal is a high level signal generated after the second dimming key 24 is pressed, the plurality of second dimming keys 24 are electrically connected to the plurality of input terminals of the controller 10 in a one-to-one correspondence manner, when the user presses one of the second dimming keys 24, the input terminals of the controller 10 corresponding to the second dimming key 24 receive the high level signal, and the controller 10 determines the corresponding dimming voltage signal with the preset magnitude according to the input terminal of the received high level signal. Alternatively, in the present embodiment, the controller 10 determines the corresponding dimming voltage signal according to a combination of the key signals of the plurality of second dimming keys 24; for example, the key signal is a high level signal generated after the second dimming key 24 is pressed, the plurality of second dimming keys 24 are electrically connected to the plurality of input terminals of the controller 10 in a one-to-one correspondence manner, when the user presses the plurality of second dimming keys 24, the controller 10 receives the high level signal from the plurality of input terminals corresponding to the plurality of pressed second dimming keys 24, and the controller 10 determines the corresponding dimming voltage signal with the preset magnitude according to a combination of the input terminals of the received high level signal.

Further, referring to fig. 7 (the controller 10 and the adjusting device 20 are not shown in this figure), in the present embodiment, the corner of the window glass 100 is provided with the accommodating portion 101, and the controller is installed in the accommodating portion 101 (i.e., the controller 10 is embedded in the window glass 100). By the controller 10 being embedded in the glazing 100, the connection between the controller 10 and each of the first and second bus bars 41, 61 is built-in, simplifying the wiring.

Further, in the present embodiment, a photovoltaic cell assembly (not shown in the figure) for supplying power to the controller 10 is disposed thereon. The photovoltaic cell assembly includes a cell portion for supplying power to the controller 10 and a photovoltaic charging portion for charging the cell portion with ambient light to store energy. Therefore, the photovoltaic new energy mode can be adopted for power supply, and energy conservation and environmental protection are realized.

Further, referring to fig. 8, the photovoltaic cell assembly 80 includes a photovoltaic power generation module 81 and an energy storage module 82, and an output terminal of the photovoltaic power generation module 81 is electrically connected to a charging terminal of the energy storage module 82 to store the converted electric energy into the energy storage module 82. The photovoltaic power generation module 81 absorbs ambient light, converts light energy into electric energy and outputs the electric energy to the energy storage module 82, and charges the energy storage module 82; the energy storage module 82 stores the electric energy output by the photovoltaic power generation module 81 for the controller 10 to supply power.

Wherein, the detection end of the controller 10 is electrically connected to the output end of the photovoltaic power generation module 81 to detect the voltage of the output end of the photovoltaic power generation module 81; in the automatic dimming mode, the controller 10 determines the intensity of the ambient light according to the voltage of the detection terminal, and determines the corresponding dimming mode according to the intensity of the ambient light in a preset manner to perform dimming.

Since the magnitude of the electric energy converted by the photovoltaic power generation module 81 (which can be known from the magnitude of the output voltage at the output end thereof) is in a proportional relationship with the amount of light incident on the photovoltaic power generation module 81, in this embodiment, the voltage magnitude at the output end of the photovoltaic power generation module 81 is detected by the detection end of the controller 10, so that the intensity level of the ambient light can be determined, and then the controller 10 determines the corresponding dimming mode according to the determined intensity of the ambient light in a preset manner to perform dimming. The preset manner may be a preset mapping relationship between the intensity of the ambient light and the dimming mode, for example, the intensity levels 1 to 5 of the ambient light correspond to the dimming modes 1 to 5, respectively. The dimming mode comprises the position of the dimming area and the magnitude of the dimming voltage signal, namely the dimming mode is determined, namely the position of the dimming area and the magnitude of the dimming voltage signal applied to the dimming area are determined, so that the bright and dark states of the area corresponding to the window glass are adjusted.

Further, the controller 10 turns off the automatic dimming mode when receiving an input signal of the adjusting device 20. That is, the manual dimming mode is prioritized over the automatic dimming mode, and the automatic dimming mode does not interfere with the manual dimming performed by the user-friendly adjustment device. Of course, the controller 10 may switch to the automatic dimming mode upon detecting that the adjustment device 20 is off or no signal.

Referring to fig. 3 and 4, the present invention further provides a vehicle door, including a door body 200 and a door glass, where the door glass is the vehicle window glass 100 provided by the present invention, and the adjusting device 20 of the vehicle window glass 100 is installed at the inner side of the door body 200, and the specific structure of the vehicle window glass 100 refers to the above-mentioned embodiments, and since the vehicle door of the present invention adopts all technical solutions of all the above-mentioned embodiments, at least all the beneficial effects brought by the technical solutions of the above-mentioned embodiments are provided, and no further description is given here.

The present invention further provides an automobile, wherein at least one of a front windshield, a rear windshield, a sunroof and each door glass of the automobile is the window glass provided by the present invention, and the specific structure of the window glass refers to the above embodiments.

The above description is only a part of or preferred embodiments of the present invention, and neither the text nor the drawings should be construed as limiting the scope of the present invention, and all equivalent structural changes, which are made by using the contents of the present specification and the drawings, or any other related technical fields, are included in the scope of the present invention.

Claims

1. The vehicle window glass is characterized by comprising a controller, an adjusting device, a first outer layer, a first substrate, a liquid crystal layer, a second substrate and a second outer layer, wherein the first outer layer, the first substrate, the liquid crystal layer, the second substrate and the second outer layer are sequentially stacked; the first outer layer, the first substrate, the second substrate and the second outer layer are all light-transmitting layers, one surface of the first substrate, facing the liquid crystal layer, is provided with a plurality of first conductive strips arranged at intervals, and one surface of the second substrate, facing the liquid crystal layer, is provided with a plurality of second conductive strips arranged in a staggered mode with the first conductive strips;

2. The window glass of claim 1, wherein the adjusting means includes a first adjusting knob, and the controller determines the corresponding dimming region according to a rotation amount signal of the first adjusting knob.

3. The window glass of claim 1, wherein the adjusting device comprises a plurality of first dimming keys, and the controller determines the corresponding dimming region according to a key signal of one of the first dimming keys, or the controller determines the corresponding dimming region according to a combination of key signals of a plurality of the first dimming keys.

4. The glazing of any of claims 1 to 3, wherein the controller determines the magnitude of the dimming voltage signal also in dependence on an input signal to the adjustment device.

5. The window glass of claim 4, wherein the adjustment device further comprises a second adjustment knob, and the controller determines the magnitude of the dimming voltage signal according to a rotation amount signal of the second adjustment knob.

6. The window glass of claim 4, wherein the adjusting device further comprises a plurality of second dimming keys, and the controller determines the magnitude of the dimming voltage signal according to a key signal of one of the second dimming keys, or determines the magnitude of the dimming voltage signal according to a combination of key signals of a plurality of the second dimming keys.

7. The window glass according to claim 1, wherein a receiving portion is provided at a corner of the window glass, and the controller is installed in the receiving portion.

8. A glazing according to claim 7, characterised in that the controller is provided with a photovoltaic cell assembly for powering the controller.

9. The window pane of claim 8, wherein the photovoltaic cell assembly includes a photovoltaic power generation module and an energy storage module, an output terminal of the photovoltaic power generation module being electrically connected to a charging terminal of the energy storage module for storing the converted electrical energy in the energy storage module; the detection end of the controller is electrically connected with the output end of the photovoltaic power generation module so as to detect the voltage of the output end of the photovoltaic power generation module;

10. The window pane of claim 9, wherein the controller turns off the automatic dimming mode upon receiving an input signal from the adjustment device.

11. A vehicle door comprising a door body and a door glass, wherein the door glass is the window glass according to any one of claims 1 to 10, and an adjusting device for the window glass is mounted on the inner side of the door body.

12. An automobile characterized in that at least one of a front windshield, a rear windshield, a sunroof, and door glasses of the automobile is the window glass of any one of claims 1 to 10.