CN114856045A - Photovoltaic curtain wall with controllable light transmission strength - Google Patents

Abstract

The application relates to the field of photoelectric curtain walls, in particular to a photovoltaic curtain wall with controllable light transmission intensity, which comprises an outer layer light-transmitting plate for transmitting light, two adhesive films arranged on one side of the outer layer light-transmitting plate and capable of transmitting the light, and a solar cell piece arranged between the two adhesive films and converting light energy into electric energy, locate the back light-passing board that solar wafer kept away from outer light-passing board one side, solar wafer sets up the array and all has the interval between adjacent two sets of, back light-passing board one side is equipped with the main color changing board that can produce the change of reversible color and transparency, main color changing board orientation supplies the position department that the light sees through between adjacent two sets of solar wafer, it becomes the color changing board to possess light, the inside personnel of building can be according to getting into to the inside light intensity of building with main color changing board from transparent, adjust between light and the dark, so that the inside light intensity of building obtains the effect of certain regulation.

Description

Photovoltaic curtain wall with controllable light transmission strength

Technical Field

The utility model belongs to the technical field of photoelectric curtain wall and specifically relates to a photovoltaic curtain wall of controllable printing opacity intensity is related to.

Background

The existing high-rise building can be decorated by using glass curtain walls in order to improve the aesthetic property of the outer surface of the whole building. In order to utilize solar energy, a photovoltaic curtain wall is used to replace part of a glass curtain wall in many buildings so as to generate electricity by using light energy.

Photovoltaic curtain on some current buildings can also be to the indoor natural illumination that provides of building in order to utilize illumination electricity generation, can reserve some positions on photovoltaic curtain and do not set up solar wafer in this position, and the glass board is chooseed for use to the base plate of photovoltaic curtain simultaneously and is replaced to make sunshine shine to photovoltaic curtain on the wall, and the set position on the photovoltaic curtain can see through light, for indoor natural illumination that provides.

According to the related technology, when the sunlight illumination intensity is high, the light intensity emitted into the building through the photovoltaic curtain wall is high, and the defect that the whole light intensity inside the building is high exists.

Disclosure of Invention

In order to make the inside whole light intensity of building difficult bigger than normal, this application provides a photovoltaic curtain of controllable printing opacity intensity.

The application provides a photovoltaic curtain wall of controllable printing opacity intensity adopts following technical scheme.

The utility model provides a photovoltaic curtain wall of controllable printing opacity intensity, includes the outer light-passing board that supplies the light to see through, locate outer light-passing board one side and can supply two glued membranes that the light passed through, locate between two glued membranes and convert light energy into solar wafer of electric energy, locate the back light-passing board of solar wafer back from outer light-passing board one side, solar wafer sets up the array and all has the interval between adjacent two sets of, and back light-passing board one side is equipped with the main look board that becomes that can produce the change of reversible color and transparency, and main look board orientation supplies the position department that the light passed through between adjacent two sets of solar wafer.

Through adopting above-mentioned technical scheme, when the peripheral corresponding position department of every group solar wafer of light directive, light can be earlier inside through main color changing board then reentrant to the building for when light intensity is suitable, main color changing board can become transparent, and when light intensity is great, main color changing board can become the light color according to the demand, dark or black and white, carry out certain regulation and control with the light intensity that gets into the building inside, make the inside light intensity of building difficult bigger than normal.

Optionally, both sides of the solar cell can convert light energy into electric energy, and the main color changing plate is inclined to reflect light to the side of the solar cell facing the main color changing plate.

Through adopting above-mentioned technical scheme for when not needing outside light to shine, can become the color palette with the change and convert white, make the main color palette can better reflect light, make light shine to the side that solar wafer is close to the main color palette on, make solar wafer carry out two-sided luminous, promoted solar wafer's generating efficiency.

Optionally, the main color changing plate is provided with a group corresponding to each group of solar cells.

Through adopting above-mentioned technical scheme, each group becomes the color palette homoenergetic and can reflect light to a set of solar cell piece that corresponds on for every group becomes the color palette and every group solar cell panel and sets up the form comparatively homogeneous, so that produce in batches.

Optionally, two sets of main color changing plates are arranged between two adjacent sets of solar cells, and the two sets of main color changing plates respectively correspond to two sets of adjacent solar cells.

Through adopting above-mentioned technical scheme for the holistic periphery department homoenergetic of photovoltaic curtain wall sets up solar wafer, sets up solar wafer with area as big as possible, promotes the generated energy.

Optionally, each main variable color plate of each group is provided with a plurality of main variable color plates, and every two main variable color plates of the same group are parallel.

Through adopting above-mentioned technical scheme, the setting of the several that parallel becomes the color board for compare in the setting of the main color board of a monoblock slope, divide into the main color board of a set of several, make when the inclination of main color board is great, the main color board that becomes also can arrange in the less region in the notch is seted up to the back light-passing board.

Optionally, a connection color-changing plate for light to penetrate is fixedly connected between every two adjacent main color-changing plates in the same group.

Through adopting above-mentioned technical scheme, make inside dust impurity of building difficult direct entering to between back light-passing board and the close glued membrane, play better guard action to glued membrane and solar cell panel, simultaneously, when light shines on a main color changing board, this main color changing board keeps away from the one end of glued membrane can reflect light to adjacent one main color changing board and deviate from in the side of glued membrane, make partial light constantly reflect and enter into to the building inside from between two adjacent main color changing boards easily, and connect the setting of color changing board, make between two adjacent main color changing boards can not directly reflect the light that corresponds on the solar cell piece by connecting the color changing board reflection, make the light that deviates from to connect the color changing board reflection have the probability and can reflect to another group solar cell piece.

Optionally, each group of the main color changing plates is fixedly connected with a group of light-transmitting plates correspondingly, and the group of light-transmitting plates are fixedly connected with a back light-transmitting plate.

Through adopting above-mentioned technical scheme, need not set up between two adjacent main discolour boards and connect the discolour board, reduce the cost that sets up of each main discolour board of group, simultaneously, the connection between each main discolour board and the back light-passing board sets up comparatively difficultly, locates a whole group's light-passing board earlier, will organize the light-passing board again and correspond and locate the back light-passing board to reduce the installation degree of difficulty that main discolour board becomes.

Optionally, each main color changing plate is arc-shaped, and the arc-shaped concave side of each main color changing plate faces to a corresponding group of solar cells.

Through adopting above-mentioned technical scheme, the arc inner concave surface of main look board can be with the better reflection gathering of light on a set of solar wafer that corresponds to the setting of a monoblock main look board also is convenient for go on of the installation work of main look board.

Optionally, the back light-transmitting plates are provided with two, and the main color-changing plate is located between the two back light-transmitting plates and fixed.

Through adopting above-mentioned technical scheme, place between two back light-passing boards with the main color board that becomes, then stabilize between two back light-passing boards and be connected for the main color board that becomes can obtain better protection, the going on of the installation work of the main color board that also is convenient for simultaneously.

Optionally, a color dielectric film is attached to one side of the back light-transmitting plate close to the adhesive film, and the color dielectric film is arranged between the back light-transmitting plate and the main color-changing plate.

Through adopting above-mentioned technical scheme for shine to the light on the main color changing board will pass through between the back light-passing board that is close to the glued membrane after the reflection, can pass through the colour dielectric film earlier, so that the light through the back light-passing board that is close to the glued membrane is more, helps promoting solar wafer's generating efficiency.

In summary, the present application includes at least one of the following benefits:

1. when the light intensity is appropriate, the main variable color plate can be changed into transparent, and when the light intensity is high, the main variable color plate can be changed into light color, dark color or black and white according to requirements so as to regulate and control the light intensity entering the interior of the building to a certain extent, so that the light intensity in the interior of the building is not easy to be large;

2. light irradiates to the side face, close to the main color changing plate, of the solar cell, so that the solar cell can emit light on two sides, and the power generation efficiency of the solar cell is improved.

Drawings

FIG. 1 is a schematic view of a vertical cross-sectional structure of the side of the present application where the thickness direction of the controllable light transmission strength is located;

FIG. 2 is a schematic diagram of a vertical cross-sectional structure of two groups of solar cells which are farthest away and are close to two sides of an adhesive film respectively;

FIG. 3 is a schematic view of a vertical cross-sectional view of the light-transmitting panel with the attached color-changing panel removed and the main color-changing panel disposed in the light-transmitting panel;

fig. 4 is a schematic view of a vertical sectional structure in which two main color changing plates are arranged in an arc shape and two back light-transmitting plates are arranged.

Description of reference numerals: 1. an outer layer light-transmitting plate; 2. a glue film; 3. a solar cell sheet; 4. a back light-transmitting plate; 41. a main color changing plate; 42. connecting a color changing plate; 43. assembling light transmission plates; 44. a color dielectric film; 45. a plate groove; 46. mounting grooves; 47. an arc-shaped slot; 48. an arc-shaped block.

Detailed Description

The present application is described in further detail below with reference to the attached drawings.

The embodiment of the application discloses controllable printing opacity intensity's photovoltaic curtain wall, refer to fig. 1, including towards the outside outer light-passing board 1 of building, outer light-passing board 1 can be optical toughened glass, the side coating that outer light-passing board 1 is inside towards the building has colour dielectric film 44, colour dielectric film 44 can be silicon nitride, colour dielectric film 44 deviates from the side of outer light-passing board 1 and closely bonds there is glued membrane 2, glued membrane 2 can be EVA glued membrane or PVB glued membrane, glued membrane 2 deviates from the side of colour dielectric film 44 and glues and be equipped with solar wafer 3, solar wafer 3 can be the double-sided battery piece of thin-film solar, make light shine to solar wafer 3 orientation or deviate from the side homoenergetic of outer light-passing board 1 and convert light energy into the electric energy. The side of the solar cell 3 departing from the outer layer light-transmitting plate 1 is adhered with another adhesive film 2, that is, the solar cell 3 is located between the two adhesive films 2.

Referring to fig. 1, a back light-passing plate 4 is installed at a side, away from the solar cell 3, of the adhesive film of the outer light-passing plate 1, the back light-passing plate 4 can be made of optical toughened glass, the outer light-passing plate 1, the two adhesive films 2, the solar cell 3 and the back light-passing plate 4 are parallel, and the same aluminum alloy frame (not shown in the figure) is installed at the periphery of the outer light-passing plate 1, the two adhesive films 2, the solar cell 3 and the back light-passing plate 4. Solar wafer 3 sets up the array, 3 length direction of every group solar wafer can be the level or vertical, solar wafer 3 is the level in this embodiment and arranges, a set of in two sets of solar wafer 3 furthest apart is close to in 2 side departments of glued membrane, interval between two sets of adjacent solar wafer 3 equals, back light-passing board 4 just has all seted up board groove 45 towards each side department in the space between two sets of adjacent solar wafer 3, board groove 45 runs through in back light-passing board 4, board groove 45 length direction and 3 length direction of solar wafer are unanimous, every board groove 45 all corresponds a set of solar wafer 3, all install a set of main look board 41 in every board groove 45, main look board 41 can be for the electrochromic glass that can produce the change of reversible colour and transparency.

Referring to fig. 2, in another embodiment of this embodiment, two sets of solar cells 3 that are farthest apart are respectively close to two opposite sides of the adhesive film 2 in a one-to-one correspondence manner, two sets of main color changing plates 41 are disposed between two adjacent sets of solar cells 3, the two sets of main color changing plates 41 respectively correspond to one set of close solar cells 3, the arrangement form of the solar cells 3 may be a rectangular frame shape in addition to horizontal and vertical, and each set of main color changing plates 41 also correspondingly is a rectangular frame shape.

Referring to fig. 1 and 2, each main color changing plate 41 is inclined, each main color changing plate 41 faces to a corresponding group of solar cells 3, and the plane where each main color changing plate 41 is located is parallel to the solar cells 3, so that the space occupied by each main color changing plate 41 along the thickness direction of the solar cells 3 is not easily large when a single main color changing plate 41 has a certain inclination angle. The projection sideline of two adjacent main discolour boards 41 on glued membrane 2 coincides in the same group, fixedly connected with connects the discolour board 42 with one between two adjacent main discolour boards 41 in the same group, it also is the slope to connect the discolour board 42, connect the discolour board 42 and the main discolour board 41 that one end that self kept away from glued membrane 2 is connected and be same group, the connection discolour board 42 and the main discolour board 41 of the same group are towards adjacent two sets of solar wafer 3 respectively, make light difficult follow two adjacent main discolour boards 41 between jet out, can be connected the better reflection of discolour board 42. The connecting color-changing plate 42 and the main color-changing plate 41 can be fixedly connected to the inner wall of the plate groove 45 by sticking.

Referring to fig. 3, in another embodiment of the present embodiment, each of the main color changing plates 41 is correspondingly provided with a block group of transparent plates 43, the group of transparent plates 43 can be made of optical glass, a mounting groove 46 can be opened on a side of the group of transparent plates 43 facing the adhesive film 2, and the main color changing plates 41 can be fixedly connected to an inner wall of the mounting groove 46 by adhesion, so that the main color changing plates 41 can be conveniently mounted and fixed.

Referring to fig. 4, in another embodiment of the present embodiment, the main color changing plates 41 are arc-shaped, each main color changing plate 41 can be a single piece of electrochromic glass, and the arc-shaped concave surface of the main color changing plate 41 faces to a corresponding group of solar cells 3, so that light can be focused on the solar cells 3.

Referring to fig. 4, in order to install the main look board 41 that is the arc, back light-passing board 4 can set up and be two, an arc 47 that supplies to be the main look board 41 of arc to put into is seted up to back light-passing board 4, the back light-passing board 4 that does not set up arc 47 is towards the side fixedly connected with arc piece 48 of arc 47, arc piece 48 is through gluing mode fixed connection who establishes in back light-passing board 4, arc piece 48 cooperation is inserted to arc 47 in and is laminated in main look board 41, make main look board 41 receive fixedly, two 4 peripheral perusals of back light-passing board glue the mode of establishing and fix. In addition, the inner wall of the arc-shaped groove 47 is coated with the color dielectric film 44, so that the light reflected by the main color changing plate 41 can better penetrate through the back light-transmitting plate 4 close to the adhesive film 2. Meanwhile, the mounting manner of the two back light-transmitting plates 4 can also be applied to the mounting of the inclined main color changing plate 41.

The photovoltaic curtain wall implementation principle of the controllable light transmission intensity of the embodiment of the application is as follows: light rays irradiate to the main transformer color plate 41 from the space existing at the periphery of each group of solar cells 3, so that the light rays can penetrate into the building after passing through the main transformer color plate 41, and personnel in the building can regulate and control the color and the transparency of the main transformer color plate 41 according to the intensity of the light rays penetrating into the building. When the light intensity is too high, the main color changing plate 41 can be adjusted to be dark, so that the light intensity emitted into the building is reduced; when the light intensity is proper or too small, the main color changing plate 41 can be changed to light color or transparent, so that the light intensity emitted into the building is increased.

When light is not needed to be emitted into the building, the transparency of the main transformer color plate 41 can be reduced to the minimum, the color of the main transformer color plate 41 is changed into white, the light can be reflected by the main transformer color plate 41 and irradiates the corresponding solar cell 3, double-sided power generation is carried out on the solar cell 3, and the power generation efficiency is improved.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: equivalent changes in structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (10)

1. The utility model provides a photovoltaic curtain wall of controllable printing opacity intensity, includes outer light-passing board (1) that supplies the light to see through, locates outer light-passing board (1) one side and can supply two glued membranes (2) that the light sees through, locate between two glued membranes (2) and convert light energy into solar wafer (3) of electric energy, locate solar wafer (3) and deviate from back light-passing board (4) of outer light-passing board (1) one side, its characterized in that: the solar cell pieces (3) are provided with arrays, the distance exists between every two adjacent groups, a main color changing plate (41) capable of generating reversible colors and transparency is arranged on one side of the back light-transmitting plate (4), and the main color changing plate (41) faces to the position between every two adjacent groups of solar cell pieces (3) where light rays penetrate.

2. The photovoltaic curtain wall with controllable light transmission intensity as claimed in claim 1, is characterized in that: both sides face of the solar cell (3) can convert light energy into electric energy, and the main transformer color plate (41) is inclined so as to reflect light to the side face, facing the main transformer color plate (41), of the solar cell (3).

3. The photovoltaic curtain wall with controllable light transmission intensity as claimed in claim 2, is characterized in that: the main color changing plate (41) is arranged in a group corresponding to each group of solar cells (3).

4. The photovoltaic curtain wall with controllable light transmission intensity as claimed in claim 2, is characterized in that: two groups of main transformer color plates (41) are arranged between every two adjacent groups of solar cells (3), and the two groups of main transformer color plates (41) respectively correspond to the two groups of adjacent solar cells (3).

5. The photovoltaic curtain wall with controllable light transmission intensity as claimed in claim 3 or 4, wherein: each group of the main variable color plates (41) is provided with a plurality of main variable color plates, and every two main variable color plates (41) in the same group are parallel.

6. The photovoltaic curtain wall with controllable light transmission intensity as claimed in claim 5, is characterized in that: and a connecting color changing plate (42) for light to penetrate is fixedly connected between every two adjacent main color changing plates (41) in the same group.

7. The photovoltaic curtain wall with controllable light transmission intensity as claimed in claim 5, is characterized in that: each main color changing plate (41) is correspondingly and fixedly connected with a block group light-transmitting plate (43), and the block group light-transmitting plate (43) is fixedly connected with the back light-transmitting plate (4).

8. The photovoltaic curtain wall with controllable light transmission intensity as claimed in claim 3 or 4, wherein: each group of the main color changing plates (41) are arc-shaped, and the arc-shaped concave side faces of the main color changing plates (41) face to a corresponding group of solar cells (3).

9. The photovoltaic curtain wall with controllable light transmission intensity as claimed in claim 1, is characterized in that: the two back light-transmitting plates (4) are arranged, and the main color-changing plate (41) is located between the two back light-transmitting plates (4) and is fixed.

10. The photovoltaic curtain wall with controllable light transmission intensity as claimed in claim 9, wherein: a color dielectric film (44) is attached to one side of the back light-transmitting plate (4) close to the adhesive film (2), and the color dielectric film (44) is arranged between the back light-transmitting plate (4) and the main color-changing plate (41).

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