CN207283488U - Structure, sunshading board and mobile power are received in opening up for solar power generation component - Google Patents

Abstract

Photovoltaic technology field is the utility model is related to, disclosing open up receipts structure, sunshading board and mobile power, the structure of a kind of solar power generation component includes base material and solar cell；Base material has the second fold line of the first fold line of N bars and M bars；Solar cell is electrically connected；First fold line is straight line, and adjacent two the first fold lines are parallel to each other；Second fold line is broken line, and adjacent two the second fold lines are parallel to each other；Second fold line includes some, and alternately the first line segment of connection and second line segment, the first line segment are connected the second intersection point to be formed with second line segment and are overlapped with the first intersection point.Solar power generation component in the present embodiment can simply, quickly reach the effect of expansion or storage, avoid the problem that component repeatedly fold caused by material thickness accumulate, reduce fold and expansion in spillage of material.The rear plate of member collapses completion at the same time is neat, reduces the occupied space after member collapses, is conducive to the storage and application of component.

Description

Foldable structure of solar power generation assembly, sun shield and mobile power supply

Technical Field

The utility model relates to the field of photovoltaic technology, in particular to solar energy power generation component's structure, sunshading board and portable power source can open up and receive.

Background

The modern society mainly depends on traditional fossil energy, and 74 percent of the global total energy consumption comes from mineral energy such as coal, petroleum, natural gas and the like. The application of fossil energy promotes the development of society, but the resources are increasingly exhausted. Meanwhile, the use of fossil energy without control causes serious environmental pollution and climate change. The development of renewable energy and new energy is taken as an important component of a future energy strategy by various countries in the world, and solar energy is an important development target.

Due to the nature problem of the solar power generation assembly in the current market, the bending radius of the solar power generation assembly cannot be too small, the curvature cannot be too large, if the curvature is too large, the solar power generation assembly can be damaged, and certainly, the solar power generation assembly cannot be directly folded. As technology has developed, many portable solar power generation assemblies have been developed, such as right angle multiple folded or rolled structures. However, the unfolding and folding actions of the solar power generation assembly in the right-angle folding or curling structure are complicated, the time consumption is long, and the layout space of the solar power generation assembly is wasted.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a solar energy power generation subassembly of folding and expansion that can be quick, and adopt but solar energy power generation subassembly's expansion and contraction structure, sunshading board and portable power source.

In order to solve the above technical problem, an embodiment of the present invention provides a foldable structure of a solar power generation assembly, which includes a substrate and a plurality of solar cells; the base material is provided with N first folding lines and M second folding lines, and N, M are all non-zero natural numbers; the first folding lines and the second folding lines are criss-cross to form a plurality of first intersection points, the base material is divided into a plurality of sub base materials, and each of the plurality of solar cells is assembled on the sub base materials; the plurality of solar cells are electrically connected with each other; the base material is repeatedly folded and unfolded according to a preset folding configuration and a preset unfolding configuration which are formed by the first folding line and the second folding line; the first folding lines are straight lines, and two adjacent first folding lines are parallel to each other; the second folding lines are folding lines, and two adjacent second folding lines are parallel to each other; the second folding line comprises a plurality of first line segments and second line segments which are alternately connected, two adjacent first line segments are parallel to each other, two adjacent second line segments are parallel to each other, and the first line segments and the second line segments are intersected at a first intersection point.

The embodiment of the utility model also provides a sun shield, which comprises a fixing piece and the solar power generation assembly; wherein, the fixing piece is arranged at two opposite edges of the base material.

The embodiment of the utility model also provides a mobile power supply, which comprises a box body, a box cover and the solar power generation assembly, wherein the box cover is arranged on the box body; the box body and the box cover form an accommodating cavity for accommodating the solar power generation assembly; the opposite ends of the base material are respectively fixed on the box body and the box cover; the accommodating cavity is also internally provided with a printed circuit board which is electrically connected with the solar cell; the box body or the box cover is provided with an interface which is electrically connected with the printed circuit board; when the box body and the box cover are separated, the solar power generation assembly is in an unfolded state; when the box body and the box cover are combined, the solar power generation assembly is in a folded state.

The embodiment of the utility model provides a for prior art, through setting up vertically and horizontally staggered's first fold line and second fold line on the substrate, the substrate is cut apart into a plurality of and is installed solar cell's child base material, and the effect that solar energy power generation subassembly can be simply, quick realization expand or accomodate like this, avoids the problem of the material thickness accumulation that the subassembly was folded many times and is caused, reduces the material loss folding and in the expansion. Meanwhile, the flat plate is neat after the assembly is folded, so that the occupied space of the folded assembly is reduced, and the storage and application of the assembly are facilitated.

In addition, the first folding line is divided into a plurality of third line segments by the second folding line, valley folds and peak folds on the first folding line on the base material are alternately arranged, and each third line segment is used as a valley fold or a peak fold of the base material; the two adjacent first folding lines are completely opposite in folding property arrangement, and the whole second folding line is used as a valley fold or a peak fold of the base material.

In addition, the first folding line divides the second folding line into a first line segment and a second line segment, each first line segment and each second line segment on each second folding line are the same peak fold or valley fold, and two second folding lines adjacent to each other are opposite in folding property.

In addition, the first line segment and the first folding line form a first included angle, the second line segment and the first folding line form a second included angle, the first included angle and the second included angle are opposite to each other, and the sum of the first included angle and the second included angle is equal to 180 degrees.

In addition, the first included angle and the second included angle are both non-right angles.

In addition, the first included angle is 82-85 degrees, and the second included angle is 95-98 degrees.

In addition, the solar cells are electrically connected by a foldable metal foil or a foldable flat cable.

In addition, the solar cell is a thin film solar cell.

Drawings

Fig. 1 is a schematic structural view of a base material according to a first embodiment of the present invention;

figure 2 is a schematic view of a substrate not fully folded according to a first embodiment of the present invention;

figure 3 is a schematic view of a substrate folded according to a first embodiment of the present invention;

fig. 4 is a schematic view of an expanded structure of a solar power generation module according to a first embodiment of the present invention;

fig. 5 is a schematic structural view of a sun visor according to a fourth embodiment of the present invention;

fig. 6 is a schematic structural diagram of a mobile power supply according to a fifth embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, embodiments of the present invention will be described in detail below with reference to the accompanying drawings. However, it will be appreciated by those of ordinary skill in the art that in the embodiments of the present invention, numerous technical details are set forth in order to provide a better understanding of the present application. However, the technical solution claimed in the present application can be implemented without these technical details and various changes and modifications based on the following embodiments.

The first embodiment of the present invention relates to a foldable structure of a solar power generation module, as shown in fig. 1 to 4, the structure includes a substrate 1 and a plurality of solar cells 2; the substrate 1 is provided with N first folding lines 1-1 and M second folding lines 1-2, N, M which are all non-zero natural numbers; the first folding lines 1-1 and the second folding lines 1-2 are criss-cross to form a plurality of first intersection points 1-3, the base material is divided into a plurality of sub base materials 1-4, and each of the plurality of solar cells 2 is fixedly arranged on the sub base materials 1-4; the plurality of solar cells 2 are electrically connected to each other; the base material 1 is repeatedly folded and unfolded according to a preset folding configuration and a preset unfolding configuration which are formed by a first folding line 1-1 and a second folding line 1-2; the first folding lines 1-1 are straight lines, and two adjacent first folding lines 1-1 are parallel to each other; the second folding lines 1-2 are folding lines, and two adjacent second folding lines 1-2 are parallel to each other; the second folding line 1-2 comprises a plurality of first line segments 1-2-1 and second line segments 1-2-2 which are alternately connected, two adjacent first line segments 1-2-1 are parallel to each other, two adjacent second line segments 1-2-2 are parallel to each other, and the first line segments 1-2-1 and the second line segments 1-2-2 are intersected at a first intersection point 1-3.

It should be noted that the broken line in this embodiment is a zigzag connection line formed by connecting a plurality of line segments end to end in sequence. In addition, the spacing distance between two adjacent first folding lines 1-1 or two adjacent second folding lines 1-2 in the embodiment may be the same, so that the substrate 1 may be divided into a plurality of parallelograms with the same size by the first folding lines 1-1 and the second folding lines 1-2, and the parallelograms with the same size are more beneficial to the rapid folding and unfolding of the substrate 1. However, the present embodiment is not limited thereto, and the distance between two adjacent first folding lines 1-1 or two adjacent second folding lines 1-2 may be different. This embodiment is not described herein in detail.

Preferably, the second folding line 1-2 divides the first folding line 1-1 into a plurality of third line segments, valley folds and peak folds on the first folding line on the substrate 1 are alternately arranged, and each third line segment is used as a valley fold or a peak fold of the substrate 1; the two adjacent first folding lines 1-1 are completely opposite in folding property arrangement, and the whole second folding line 1-2 is used as a valley fold or a peak fold of the base material 1. The term "folding property" in the present embodiment refers to the arrangement of the valley fold and the peak fold in the first folding line 1-1 or the second folding line 1-2. Specifically, when the folding property arrangement on one first folding line 1-1 is "peak-valley-peak … …", the folding property arrangement on the other first folding line 1-adjacent thereto must be "valley-peak-valley … …". Wherein the first folding line 1-1 is a second folding line 1-2 in folding property distribution dividing line.

Specifically, as shown in fig. 2 to 4, in this embodiment, N is equal to 4, and M is equal to 6, it should be noted that this embodiment is not limited thereto, N may be a natural number other than 4, and M may be a natural number other than 6, and a person skilled in the art may flexibly select the values of N and M according to actual needs.

More specifically, the first folding line 1-1 and the second folding line 1-2 may be formed on the base material 1 by die stamping. Valley folding means that the substrate 1 is folded down along the fold, and the fold is recessed like a valley; the peak folding is to make the base material 1 rise upward along the folding line like a ridge. When the base material 1 needs to be folded, the base material 1 is folded in an alternate and cyclic mode of valley fold, peak fold, valley fold and peak fold, and the base material 1 can be folded in a shrinkage mode at one time. When the base material 1 needs to be unfolded, the two opposite corners of the base material 1 are pulled outwards, the base material 1 can be unfolded at one time, after the base material 1 is unfolded and used, the two opposite corners of the base material 1 are pushed inwards, and the base material 1 can be folded into a small module at one time.

It should be noted that the first line segment 1-2-1 and the first folding line 1-1 form a first included angle a, and the second line segment 1-2-1 and the first folding line 1-1 form a second included angle b, where the first included angle a and the second included angle b are opposite to each other, and the sum of the first included angle a and the second included angle b is equal to 180 °. The first included angle and the second included angle are both non-right angles, the first included angle a can be 82-85 degrees, and correspondingly, the second included angle b can be 95-98 degrees. However, this embodiment is not limited thereto, and the first included angle a and the second included angle b may also be set to other angles, and those skilled in the art may flexibly select the angles of the first included angle a and the second included angle b according to needs.

Preferably, the solar cells 2 can be fixed to the same side of the sub-substrates 1-4 by means of encapsulation. Specifically, the solar cells 2 can be located on the same side of the substrates 1 to 4 after the substrate 1 is unfolded, so that when one side of the solar cell 2 faces sunlight, the solar cells 2 on the substrates 1 to 4 can all receive the sunlight, and the electric conversion power of the solar cells 2 is improved. The solar cell 2 may be fixed to the sub-substrates 1 to 4 by other means, for example, the solar cell 2 may be fixed to each sub-substrate 1 to 4 by adhesion, and the solar cell 2 may be fixed to each sub-substrate 1 to 4 by detachable means. This has the advantage that if the solar cell 2 is damaged during use, the solar cell 2 can be easily removed by a service person for service or replacement.

It is worth mentioning that the solar cells 2 may be electrically connected by a foldable metal foil or a foldable flat cable. Of course, the solar cells 2 may be electrically connected in other ways. The present invention is not limited to the above two modes, and the present invention is not limited thereto.

In addition, the solar cell 2 may be a thin film solar cell. Specifically, the thin-film solar cell has the advantages of low production cost, light weight, less material consumption, good weak light response and the like. However, the present embodiment is not limited thereto, and the solar cell 2 may also be a crystalline silicon solar cell, and the present embodiment is not limited thereto.

It should be noted that the substrate 1 may be made of materials such as polyethylene terephthalate (PET), polyvinyl chloride (PVC), silver coated paper, and coated paper, but the present invention is not limited to the material, size, and shape of the substrate 1 in this embodiment, and those skilled in the art can flexibly select the material, size, and shape of the substrate 1 as needed. This embodiment is not described herein.

Specifically, the solar power generation assembly can be unfolded and folded in such a way that the acting force in the same direction is applied to two opposite angles of the base material, that is, the base material can be folded and folded along the crease, and the acting force in the opposite direction is applied to the two opposite angles of the base material, that is, the solar power generation assembly can be unfolded. Therefore, the solar power generation assembly can receive the irradiation of sunlight to the maximum extent.

Compared with the prior art, the solar power generation assembly in the embodiment has the following advantages: the folding solar power generation assembly can be unfolded and stored quickly only by simply applying unidirectional force to the two ends of the folded solar power generation assembly, multiple folding of the solar power generation assembly is avoided, and loss in the folding and unfolding processes is reduced. In addition, in the traditional right-angle folding process, each time the solar module is folded, the outer folding unit needs more radians at the crease to accommodate the thickness of the material of the inner layer, so that the installation area of the solar module is reduced, and when the solar module is folded to a certain number of layers at right angles, the solar module can not be folded any more, so that the number of foldable layers of the solar module is limited. And each parallelogram-shaped sub-substrate in the embodiment can just avoid the defect of accumulated material thickness at the crease, so that the number of foldable layers of the solar power generation assembly is greatly increased compared with the traditional right-angle folding, and the effective use area of the solar power generation assembly is increased. In addition, the solar power generation assembly in the embodiment is flat and tidy after being folded, so that the occupied space of the folded solar power generation assembly is reduced, and the storage and the application of the solar power generation assembly are facilitated.

A second embodiment of the present invention relates to a solar power generation module foldable structure. The second embodiment is substantially the same as the first embodiment, with the main differences being: in the first embodiment, the second folding line divides the first folding line into a plurality of line segments, valley folds and peak folds on the base material are alternately arranged, and each line segment is used as a valley fold or a peak fold of the base material; the entire second fold line acts as a valley or a peak of the substrate. And in the second embodiment of the present invention, the first folding line divides the second folding line into a first line segment and a second line segment, each of the first line segment and the second line segment on each of the second folding lines is the same peak or valley, and two adjacent second folding lines are opposite in folding property.

Specifically, fold the substrate along first fold line earlier, after folding the completion, the folding of solar energy power generation subassembly has been accomplished promptly to the folding substrate of will folding the completion according to the folding of second fold line, when needs expand the substrate, pulls two opposite angles of substrate, can expand solar energy power generation subassembly fast.

A third embodiment of the present invention relates to a method for unfolding and folding a solar power generation module, the method comprising the steps of: the base material is divided into a plurality of sub-base materials by the first folding line and the second folding line; fixing the solar cell on the sub-substrate; folding the unfolded base material according to a preset folding configuration formed by a first folding line and a second folding line; unfolding the folded base material according to a preset unfolding configuration formed by the first folding line and the second folding line

A fourth embodiment of the present invention relates to a sun visor, as shown in fig. 5; the sun visor comprises a fixing member 3 and the solar power generation module as described in the first embodiment; wherein, the fixing members 3 are disposed at two opposite edges of the substrate 1.

Specifically, the fixing member 3 in this embodiment is used for fixing the sun visor, and when the sun visor is applied to the front windshield of the automobile, the fixing member 3 can be hung on the front view mirror of the automobile, so that the sun visor can be firmly fixed on the automobile, and the influence of the external environment on the use of the sun visor is avoided. Of course, the sun visor may also be used alone without being attached to the vehicle, and only the scene where the sun visor is applied to the vehicle is described here, but this embodiment is not limited thereto, and the sun visor may also be used alone without being limited to the above-mentioned scene. The skilled person can flexibly select the desired one.

A fifth embodiment of the present invention relates to a solar mobile power source, as shown in fig. 6; the mobile power supply comprises a box body 4, a box cover 5 and the solar power generation assembly 6, wherein the box cover is arranged on the box body 4 in a covering mode; the box body 4 and the box cover 5 form an accommodating cavity for accommodating the solar power generation assembly 6; the opposite ends of the base material 1 are respectively fixed on the box body 4 and the box cover 5; a printed circuit board (not shown in the figure) is arranged in the accommodating cavity and is electrically connected with the solar cell; the box body 4 or the box cover 5 is provided with an interface which is electrically connected with the printed circuit board; when the box body 4 and the box cover 5 are separated, the solar power generation assembly 6 is in an unfolded state; when the box body 4 and the box cover 5 are combined, the solar power generation assembly 6 is in a folding state.

Specifically, when the portable power source needs to be charged, acting forces in opposite directions are applied to the box body 4 and the box cover 5 respectively, and then the solar power generation assembly 6 can be unfolded, the larger the acting force is, the larger the unfolding angle is, the more sunlight is received, the higher the electrical conversion rate of the solar power generation assembly 6 is, and conversely, the lower the electrical conversion rate of the solar power generation assembly 6 is. On the contrary, acting forces in the direction close to the solar power generation assembly 6 are respectively applied to the box body 4 and the box cover 5, so that the solar power generation assembly 6 can be folded and folded. Until the box cover 5 is covered on the box body.

It will be understood by those skilled in the art that the foregoing embodiments are specific examples for carrying out the invention, and that various changes in form and detail may be made therein without departing from the spirit and scope of the invention in practice.

Claims (10)

1. A foldable structure of a solar power generation assembly comprises a base material and a plurality of solar cells; it is characterized in that the preparation method is characterized in that,

the substrate is provided with N first folding lines and M second folding lines, and N, M are all non-zero natural numbers; the first folding lines and the second folding lines are criss-cross to form a plurality of first intersection points, the substrate is divided into a plurality of sub-substrates, and each of the plurality of solar cells is assembled on the sub-substrates; the plurality of solar cells are electrically connected with each other;

the base material is repeatedly folded and unfolded according to a preset folding configuration and a preset unfolding configuration formed by the first folding line and the second folding line;

the first folding lines are straight lines, and two adjacent first folding lines are parallel to each other;

the second folding lines are folding lines, and two adjacent second folding lines are parallel to each other;

the second folding line comprises a plurality of first line segments and second line segments which are alternately connected, two adjacent first line segments are parallel to each other, two adjacent second line segments are parallel to each other, and the first line segments and the second line segments are intersected at a first intersection point.

2. The collapsible structure of a solar power module as claimed in claim 1 wherein the second fold line divides the first fold line into a plurality of third line segments, the valley folds and the peak folds of the first fold line alternating on the substrate, each of the third line segments being a valley fold or a peak fold of the substrate; the two adjacent first folding lines are completely opposite in folding property arrangement, and the whole second folding line is used as a valley fold or a peak fold of the base material.

3. The solar power module collapsible structure of claim 1 wherein the first fold line divides the second fold line into the first line segment and the second line segment, each of the first line segment and the second line segment of each of the second fold lines being the same peak or valley fold, two second fold lines adjacent to each other being opposite in folding properties.

4. The solar power module deployable structure according to claim 2, wherein the first line segment forms a first included angle with the first fold line and the second line segment forms a second included angle with the first fold line, wherein the first included angle is opposite the second included angle, and the sum of the first included angle and the second included angle is equal to 180 °.

5. The solar power module deployable structure according to claim 4, wherein the first and second included angles are both non-orthogonal angles.

6. The solar power module deployable structure according to claim 5, wherein the first included angle is 82 ° to 85 ° and the second included angle is 95 ° to 98 °.

7. The collapsible structure of a solar power module as claimed in claim 1 wherein the solar cells are electrically connected by a foldable metal foil or a foldable flat cable.

8. The collapsible structure of a solar power module as claimed in claim 1 wherein the solar cell is a thin film solar cell.

9. A sun visor comprising a fastener and the solar module collapsible structure of any one of claims 1 to 8, wherein the fastener is disposed on opposite edges of a substrate.

10. A mobile power supply is characterized by comprising a box body, a box cover and a foldable structure, wherein the box cover is arranged on the box body in a covering mode, and the foldable structure of the solar power generation assembly is as claimed in any one of claims 1 to 8; wherein,

the box body and the box cover form an accommodating cavity for accommodating the solar power generation assembly; the opposite ends of the base material are respectively fixed on the box body and the box cover;

the accommodating cavity is internally provided with a printed circuit board which is electrically connected with the solar cell;

the box body or the box cover is provided with an interface which is electrically connected with the printed circuit board;

when the box body and the box cover are separated, the solar power generation assembly is in an unfolded state; when the box body and the box cover are combined, the solar power generation assembly is in a folded state.