CN117684860B

CN117684860B - Solar photovoltaic window

Info

Publication number: CN117684860B
Application number: CN202410146808.4A
Authority: CN
Inventors: 徐燊; 何秋国; 廖维; 崔国游; 吴玉杰; 李辉; 沈念俊; 陈淑琴
Original assignee: Huazhong University of Science and Technology; Guangdong University of Technology
Current assignee: Huazhong University of Science and Technology; Guangdong University of Technology
Priority date: 2024-02-02
Filing date: 2024-02-02
Publication date: 2024-04-30
Anticipated expiration: 2044-02-02
Also published as: CN117684860A

Abstract

The invention belongs to the technical field of solar windows for buildings, and particularly relates to a solar photovoltaic window, which comprises a frame main body and a plurality of shutter blades movably arranged on the frame main body along the vertical direction, wherein an outer window and an inner window are respectively arranged at two sides of the frame main body, the shutter blades are arranged between the outer window and the inner window, the shutter blades are commonly connected with a driving component for driving the shutter blades to deflect and move up and down along the vertical direction, a plurality of first solar panels are arranged on one side surface of each shutter blade, a first reflecting piece is arranged on one side surface of each shutter blade close to the outer window, a second reflecting piece is arranged on one side surface of each shutter blade close to the inner window, one end of each first reflecting piece is obliquely arranged upwards along the vertical direction, and one end of each second reflecting piece is obliquely arranged downwards along the vertical direction.

Description

Solar photovoltaic window

Technical Field

The invention belongs to the technical field of solar windows for buildings, and particularly relates to a solar photovoltaic window.

Background

Solar energy is used as a renewable new energy source, has wide distribution range, is clean and safe, does not cause atmospheric pollution and carbon emission in the use process, has natural advantages compared with the traditional fossil energy source, and is one of the important methods for solving the energy shortage and avoiding the environmental pollution for human beings at present; at present, the solar power generation equipment in the building industry is various, the technical cases of combining the shutter with the photovoltaic power generation are more and more, the traditional energy consumption in the building can be effectively slowed down, the light and the temperature in the house can be better controlled, and therefore, the photovoltaic power generation plate arranged on the shutter gradually replaces the traditional shutter, and the energy conservation and emission reduction are contributed.

For example, chinese patent discloses a louver for photovoltaic power generation (CN 110959062 a), which includes a fixed frame fixed to a ceiling or window frame, and a plurality of louver blades spaced apart from each other and disposed at a lower side of the fixed frame, and having a solar panel mounted on one surface thereof, the solar panel being disposed on one surface of the louver blades to perform solar power generation, and the solar panel being individually replaceable and maintainable by being assembled, and the solar panel being disposed on the louver blades to receive light and perform power generation when the louver is unfolded and sun-shaded, and the plurality of solar panels being mutually coupled to generate electric power, thereby being capable of effectively providing power for electric lamps, electric appliances, etc. in a room.

According to the technical scheme, although the shutter and the solar cell panels are combined, the utilization of the shutter is effectively improved, when the shutter is in an open state, the solar cell panels on the surfaces of the shutter blades cannot fully and effectively receive solar rays, and when any two adjacent shutter blades rotate to an optimal angle to receive the solar rays, as shown in the figure 1, the shutter blades above can shield part of the solar rays, so that shadow areas exist on the partial surfaces of the solar cell panels on the shutter blades below, and the solar rays cannot be maximally utilized for effectively generating electricity;

Of course, this is only one of the states that shutter blades shelter from solar rays, but it is undeniable that, when the shutter blades at present are unfolded, if they are not in a vertical state, a part of solar rays will be always shielded, so that the solar panels cannot be maximally and effectively utilized, and the solar panels on the shutter blades are exposed to the external environment for a long time, are easy to adhere to dust, and need to be cleaned at regular time to ensure the power generation efficiency.

Disclosure of Invention

In view of the above, the present invention aims to provide a solar photovoltaic window, which solves the problems that the surface of the solar panel on the existing shutter is shielded, dust is easy to adhere, and power generation cannot be maximized.

In order to achieve the above purpose, the present invention provides the following technical solutions:

A solar photovoltaic window comprises a frame main body and a plurality of shutter blades movably arranged on the frame main body along the vertical direction; the method is characterized in that: an outer window and an inner window are respectively arranged on two sides of the frame main body; the shutter blades are arranged between the outer window and the inner window; all the shutter blades are commonly connected with a driving component for driving the shutter blades to deflect and move up and down along the vertical direction, and the driving component is arranged on the frame main body; a plurality of first solar panels are arranged on one side surface of each shutter blade, and the plurality of first solar panels are arranged at intervals along the length direction of the shutter blade; a first reflecting piece is arranged on the surface of one side, close to the outer window, of each shutter blade, a second reflecting piece is arranged on the surface of one side, close to the inner window, of each shutter blade, and the first reflecting piece and the second reflecting piece are arranged along the length direction of each shutter blade; one end of the first reflecting piece is arranged in an upward inclined mode along the vertical direction, one end of the second reflecting piece is arranged in a downward inclined mode along the vertical direction, and when the surface of the first solar cell panel moves to be perpendicular to solar rays, part of solar rays sequentially pass through the first reflecting piece on any louver blade and the second reflecting piece adjacent to the first reflecting piece and located above the first reflecting piece, and then irradiate the surface of the first solar cell panel.

Further, a plurality of second solar panels are arranged on the surface, far away from the first solar panels, of each shutter blade, and the plurality of second solar panels are arranged at intervals along the length direction of the shutter blade; the side surface of each shutter blade, which is close to the outer window, is provided with a third reflecting piece; the third reflecting piece is made of a light-transmitting material, and one end of the third reflecting piece is positioned outside the shutter blade and is obliquely arranged upwards along the vertical direction; when the surface of the first solar cell panel moves to be perpendicular to solar rays, part of solar rays are reflected by the surface of the third reflecting piece and then irradiate the surface of the adjacent second solar cell panel positioned above, and part of solar rays are refracted by the third reflecting piece and then irradiate the surface of the adjacent first solar cell panel positioned below.

Further, the first solar cell panels and the second solar cell panels which are arranged on any two adjacent shutter blades in opposite directions are mutually staggered; light guide plates are arranged between two adjacent first solar panels and between two adjacent second solar panels on each shutter blade; the light guide plate is fixed on the surface of the shutter blade, and the surfaces of the two sides of the light guide plate, which are close to the inner window and the outer window, are positioned outside the shutter blade and can receive light.

Further, a fourth reflecting piece which is arc-shaped is arranged on the bottom surface of the inner side of the frame body; one end of the fourth reflecting piece, which is close to the inner window, is vertically and obliquely arranged upwards.

Further, limiting grooves which are arranged along the vertical direction are formed in the two opposite side surfaces of the frame main body; limiting blocks which mutually slide with the limiting grooves are arranged on the surfaces of two sides of each shutter blade; the limiting block is rotationally connected with the shutter blades.

The invention has the beneficial effects that:

1. According to the solar cell panel, through the cooperation of the first reflecting piece and the second reflecting piece, solar rays can be reflected twice, and finally the solar rays irradiate the surface of the first solar cell panel, so that the area of the surface of the first solar cell panel, which is shielded by the adjacent louver blades positioned above, is effectively reduced, the irradiation dead angle of the solar rays is reduced, the power generation efficiency is improved, and the solar cell panel is arranged in a relatively sealed cavity formed by the frame main body, the outer window and the inner window, and dust or sundries are effectively reduced from being attached to the surface of the solar cell panel;

2. The second solar cell panel is arranged on the surface of the other side of the shutter blade, and solar rays can be reflected through the matching of the third reflecting piece and the first reflecting piece, so that the reflected solar rays irradiate on the surface of the second solar cell panel, the solar ray irradiation dead angle is reduced, and meanwhile, the power generation efficiency of the solar photovoltaic window is further improved.

3. Through the setting of light guide plate, can make shutter blade also can give the surface of first solar cell panel, second solar cell panel with external light transmission when folding, and then improve generating efficiency.

Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention. The objects and other advantages of the invention may be realized and obtained by means of the instrumentalities and combinations particularly pointed out in the specification.

Drawings

In order to make the objects, technical solutions and advantageous effects of the present invention more clear, the present invention provides the following drawings for description:

FIG. 1 is a schematic view of a solar panel of the present invention occluded by a louver blade;

FIG. 2 is a schematic diagram of the structure of the present invention;

FIG. 3 is an enlarged schematic view of FIG. 2 at A;

FIG. 4 is a schematic view of a path of solar rays passing through the first and second reflectors according to an embodiment of the present invention;

FIG. 5 is a schematic view illustrating a path of solar rays passing through a third reflective element according to an embodiment of the present invention;

FIG. 6 is a schematic view of a path of solar rays through a fourth reflector according to an embodiment of the present invention;

Fig. 7 is a path diagram of solar rays passing through the light guide plate according to an embodiment of the present invention.

The figures are marked as follows:

1a frame main body, 2 shutter blades, 3 an outer window, 4 an inner window, 5 lifting ropes, 6 deflection ropes, 7 a first solar panel, 8 a first reflecting piece, 9 a second reflecting piece, 10 a second solar panel, 11 a third reflecting piece, 12 a light guide plate, 13 a fourth reflecting piece and 14 a limit groove.

Detailed Description

As shown in figures 1-7 of the drawings,

A solar photovoltaic window comprises a frame body 1and a plurality of shutter blades 2 movably arranged on the frame body 1 along the vertical direction; an outer window 3 and an inner window 4 are respectively arranged on two sides of the frame main body 1; the shutter blades 2 are arranged between the outer window 3 and the inner window 4; all the shutter blades 2 are commonly connected with a driving component for driving the shutter blades 2 to deflect and move up and down along the vertical direction, the driving component comprises a lifting rope 5 and a deflection rope 6 which are connected with each shutter blade 2, the lifting rope 5 and the deflection rope 6 are respectively connected with a winding machine (not shown in the figure), and the winding machine is fixedly arranged on the frame main body 1 through bolts; a plurality of first solar panels 7 are arranged on one side surface of each shutter blade 2, and the plurality of first solar panels 7 are arranged at intervals along the length direction of the shutter blade 2; each shutter blade 2 is provided with a light sensor; the light sensor and the winding machine are electrically connected with a control unit (the light sensor and the control unit are not shown in the figure); a first reflecting piece 8 is arranged on the surface of one side, close to the outer window 3, of each shutter blade 2, a second reflecting piece 9 is arranged on the surface of one side, close to the inner window 4, of each shutter blade 2, and the first reflecting piece 8 and the second reflecting piece 9 are arranged along the length direction of the shutter blade 2; one end of the first reflecting piece 8 is arranged in an upward inclined manner along the vertical direction, one end of the second reflecting piece 9 is arranged in a downward inclined manner along the vertical direction, and when the surface of the first solar cell panel 7 moves to be perpendicular to solar rays, part of the solar rays sequentially pass through the first reflecting piece 8 on any louver blade 2and the second reflecting piece 9 adjacent to the first reflecting piece 8 and above the first reflecting piece 8, and irradiate the surface of the area, covered by the louver blade 2 above, of the first solar cell panel 7.

When power generation is required, the control unit adjusts the deflection angle of the louver blades 2 according to the data acquired by the light sensors, so that the surface of all the first solar cell panels 7 is perpendicular to the incidence angle of the solar rays, part of the solar rays can directly irradiate on part of the surface of the first solar cell panels 7, the other part of the surface can be shaded under the shielding of the adjacent louver blades 2, and because part of the solar rays can directly irradiate on the surface of the obliquely arranged first reflecting piece 8, the first reflecting piece 8 reflects the incident solar rays towards the direction of the upper adjacent second reflecting piece 9 (the first reflection of the solar rays and the second reflecting piece 9 arranged obliquely (the second reflection of the solar rays) respectively), the solar rays after the secondary reflection just irradiate on the area of the first solar cell panels 7 shielded by the adjacent louver blades 2, the solar rays can be received mostly, the problem that the shielded area is low in efficiency is greatly reduced, the solar rays can pass through the first reflecting piece 7 and the first reflecting piece 7 in turn, and the real solar rays can be prevented from being transmitted out of the first reflecting piece 7, and the real solar rays can pass through the first reflecting piece 7, and the first reflecting piece 7 are prevented from passing through the first reflecting piece 7; the light sensor arranged on the shutter blade 2 can detect the incident angle of solar light and the irradiation angle between the surfaces of the first solar cell panel 7 at any time, so that the first solar cell panel 7 can receive solar light at an optimal angle, and the power generation efficiency is further ensured; the frame body 1, the inner window 4 and the outer window 3 form a relatively sealed space, so that all the shutter blades 2 and the first solar panel 7 are protected, stains such as external dust, sundries and rainwater are prevented from adhering to the surface of the first solar panel 7, and a favorable environment is provided for normal power generation and temperature operation of the first solar panel 7.

In this embodiment, only the irradiation of solar rays and the propagation path diagram thereof are shown after the shutter blade 2 rotates to a certain angle, and as can be seen from the figure, when the control unit adjusts the shutter blade 2 in real time, the surface of the first solar panel 7 is perpendicular to the incident solar rays, and then the propagation path of part of the solar rays passing through the first reflective member 8 and the second reflective member 9 in sequence is fixed, so that the solar photovoltaic window can work stably.

In this embodiment, a plurality of second solar panels 10 are mounted on the surface of each shutter blade 2 far from the first solar panel 7, and the plurality of second solar panels 10 are arranged at intervals along the length direction of the shutter blade 2; a third reflecting piece 11 is arranged on the side surface of each shutter blade 2 close to the outer window 3; the third reflecting member 11 is made of a transparent glass material (a transparent material is glass in the present embodiment), and one end of the third reflecting member 11 is located outside the louver blades 2 and is disposed obliquely upward in the vertical direction; when the surface of the first solar panel 7 moves to be perpendicular to the solar rays, part of the solar rays are reflected by the surface of the third reflecting piece 11 and then irradiate on the surface of the adjacent second solar panel 10 positioned above, and part of the solar rays are refracted by the third reflecting piece 11 and then irradiate on the surface of the adjacent first solar panel 7 positioned below.

As shown in fig. 5, when the surface of the first solar panel 7 is perpendicular to the incident angle of the solar rays, part of the solar rays will irradiate the surface of the third reflecting member 11 which is obliquely arranged, and as the surface of the third reflecting member 11 is made of transparent glass, the incident solar rays will be reflected towards the adjacent second solar panel 10 positioned above, and the reflected solar rays can just irradiate the surface of the second solar panel 10, so that the second solar panel 10 generates electric energy, and the first solar panel 7 and the second solar panel 10 generate electricity at the same time, so that the louver blades 2 and the solar panels can be utilized to the maximum, and the total electricity generating efficiency is greatly improved in an effective space; wherein, partial solar rays are refracted after entering the third reflecting piece 11, and the refracted solar rays are refracted again after entering the air, and the solar rays after secondary refraction irradiate the surface of the adjacent first solar cell panel 7 positioned below, so that the shielding area of the first solar cell panel 7 due to the shutter blades 2 is further reduced, and the power generation efficiency is ensured;

In addition, the surface of the solar panel is usually made of a protective material such as toughened glass and transparent plastic, and a part of light rays are always reflected on the surface of the solar panel (even if the protective material is made of a material with good light transmittance and low enough reflectivity), then a part of solar light rays are reflected again on the surface of the first solar panel 7 after passing through the first reflecting member 8 and the second reflecting member 9, the reflected solar light rays are reflected for a plurality of times between the surfaces of the adjacent first solar panel 7 and the adjacent second solar panel 10, and after being reflected and refracted by the third reflecting member 11, a part of solar light rays are reflected for a plurality of times between the surfaces of the adjacent first solar panel 7 and the adjacent second solar panel 10 as described above, so that the irradiation dead angles of the surfaces of the first solar panel 7 and the second solar panel 10 are further reduced, and the power generation efficiency is ensured.

In the embodiment, the first solar cell panel 7 and the second solar cell panel 10 which are arranged on any two adjacent shutter blades 2 in opposite directions are mutually staggered; light guide plates 12 are arranged between two adjacent first solar panels 7 and two adjacent second solar panels 10 on each shutter blade 2; the light guide plate 12 is fixed on and covers the surface of the shutter blade 2, and the two side surfaces of the light guide plate 12, which are close to the inner window 4 and the outer window 3, are positioned outside the shutter blade 2 and can receive light.

As shown in fig. 7, when the louver blades 2 are in the retracted state, a gap exists between the adjacent louver blades 2, at this time, each louver blade 2 is in a horizontal state, external solar rays cannot irradiate the surfaces of all the first solar cell panels 7 and the second solar cell panels 10, but the light guide plate 12 is close to the inner window 4 and both ends of the outer window 3 are positioned outside the louver blades 2 and can receive light rays, the light guide plate 12 can guide and diffuse the solar rays on one side of the outer window 3 or the light rays generated by illumination of household appliances positioned on one side of the inner window 4 outwards, so that the light guide plate 12 can emit a part of the light rays, and as the first solar cell panel 7 and the second solar cell panel 10 on the adjacent louver blades 2 are staggered, the surfaces on the upper side and the lower side of the light guide plate 12 can simultaneously irradiate the second solar cell panels 10 and the first solar cell panel 7 on the upper side and the lower side of the second solar cell panel respectively (because the first solar cell panels 7 and the second solar cell panels 10 on the adjacent louver blades 2 are staggered, and the louver blades 2 are combined with the louver blades 2, so that the solar cell panels 7 can receive the solar cells in the maximum power generation efficiency of the first solar cell panels 10 and the first solar cell panels 10 are not generated when the louver blades 2 are in the staggered state; and at night, after the household illumination appliance positioned at one side of the inner window 4 is started, the emitted light can be absorbed and utilized by the first solar cell panel 7 and the second solar cell panel 10 under the action of the light guide plate 12, so that electric energy is generated, and the application range of the solar photovoltaic window is improved.

In the present embodiment, the bottom surface of the inner side of the frame body 1 is provided with a fourth reflecting member 13 having an arc shape; one end of the fourth reflecting piece 13 close to the inner window 4 is vertically upwards inclined; the surface of the fourth reflecting member 13 facing the louver blades 2 is a rough surface with irregularities.

As shown in fig. 6, when the louver blades 2 near the bottom of the inner side of the frame body 1 are in an inclined state, diffuse reflection occurs after the sun rays irradiate the surface of the fourth reflecting member 13, the sun rays after diffuse reflection are reflected towards the periphery, the surface of the second solar cell panel 10 above can be maximally irradiated, and the sun rays after being reflected by the surface of the second solar cell panel 10 are diffusely reflected after passing through the fourth reflecting member 13, and the sun rays form multiple reflections on the surfaces of the fourth reflecting member 13 and the second solar cell panel 10 adjacent to the fourth reflecting member 13, so that the second solar cell panel 10 at the position can generate power with light, the irradiation dead angle of the solar photovoltaic window is reduced, and the power generation efficiency is ensured.

In this embodiment, the opposite side surfaces of the frame body 1 are provided with limiting grooves 14 arranged along the vertical direction; limiting blocks (not shown in the figure) sliding with the limiting grooves 14 are arranged on the two side surfaces of each shutter blade 2; the limiting block is rotationally connected with the shutter blades 2.

The spacing groove 14 cooperates with the stopper, when spacing to shutter blade 2, also can improve the stability when every shutter blade 2 moves, and when the deflection angle and the height of every shutter blade 2 are adjusted to the drive assembly, shutter blade 2 can not take place to rock, prevents that the solar ray from shining at appointed region after the reflection of first reflector 8, second reflector 9 and third reflector 11, has guaranteed the stability when this solar photovoltaic window uses.

Finally, it is noted that the above-mentioned preferred embodiments are only intended to illustrate rather than limit the invention, and that, although the invention has been described in detail by means of the above-mentioned preferred embodiments, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the invention as defined by the appended claims.

Claims

1. A solar photovoltaic window comprises a frame main body and a plurality of shutter blades movably arranged on the frame main body along the vertical direction; the method is characterized in that: an outer window and an inner window are respectively arranged on two sides of the frame main body; the shutter blades are arranged between the outer window and the inner window; all the shutter blades are commonly connected with a driving component for driving the shutter blades to deflect and move up and down along the vertical direction, and the driving component is arranged on the frame main body; a plurality of first solar panels are arranged on one side surface of each shutter blade, and the plurality of first solar panels are arranged at intervals along the length direction of the shutter blade; a first reflecting piece is arranged on the surface of one side, close to the outer window, of each shutter blade, a second reflecting piece is arranged on the surface of one side, close to the inner window, of each shutter blade, and the first reflecting piece and the second reflecting piece are arranged along the length direction of each shutter blade; one end of the first reflecting piece is obliquely arranged upwards along the vertical direction, one end of the second reflecting piece is obliquely arranged downwards along the vertical direction, and when the surface of the first solar cell panel moves to be vertical to solar rays, part of the solar rays sequentially pass through the first reflecting piece on any louver blade and the second reflecting piece adjacent to and above the first reflecting piece and are reflected, and then irradiate on the surface of the first solar cell panel;

The surface of each shutter blade far away from the first solar cell panel is provided with a plurality of second solar cell panels, and the plurality of second solar cell panels are arranged at intervals along the length direction of the shutter blade; the side surface of each shutter blade, which is close to the outer window, is provided with a third reflecting piece; the third reflecting piece is made of a light-transmitting material, and one end of the third reflecting piece is positioned outside the shutter blade and is obliquely arranged upwards along the vertical direction; when the surface of the first solar cell panel moves to be perpendicular to solar rays, part of solar rays are reflected by the surface of the third reflecting piece and then irradiate the surface of the adjacent second solar cell panel positioned above, and part of solar rays are refracted by the third reflecting piece and then irradiate the surface of the adjacent first solar cell panel positioned below.

2. A solar photovoltaic window according to claim 1, characterized in that: the first solar cell panels and the second solar cell panels which are arranged on any two adjacent shutter blades in opposite directions are mutually staggered; light guide plates are arranged between two adjacent first solar panels and between two adjacent second solar panels on each shutter blade; the light guide plate is fixed on the surface of the shutter blade, and the surfaces of the two sides of the light guide plate, which are close to the inner window and the outer window, are positioned outside the shutter blade and can receive light.

3. A solar photovoltaic window according to claim 2, characterized in that: the bottom surface of the inner side of the frame body is provided with a fourth arc-shaped reflecting piece; one end of the fourth reflecting piece, which is close to the inner window, is vertically and obliquely arranged upwards.

4. A solar photovoltaic window according to claim 3, characterized in that: limiting grooves arranged along the vertical direction are formed in the surfaces of two opposite sides of the frame main body; limiting blocks which mutually slide with the limiting grooves are arranged on the surfaces of two sides of each shutter blade; the limiting block is rotationally connected with the shutter blades.