CN211127682U - Floating type photovoltaic power station - Google Patents

Abstract

The utility model relates to a solar energy field discloses a float formula photovoltaic power plant, this photovoltaic power plant includes two articulated photovoltaic panels, the articulated shaft, the kickboard subassembly, the damping piece, the support, flexible motor and flexible link assembly, every photovoltaic panel one side all is articulated with the articulated shaft, and two photovoltaic panel place planes intersect and form a contained angle, the damping piece is installed between every photovoltaic panel's opposite side and kickboard subassembly, flexible motor is installed in the support and is connected with flexible link assembly, flexible link assembly props up respectively and holds the surface that two photovoltaic panels deviate from light, flexible motor removes so that flexible link assembly adjusts the contained angle between two photovoltaic panels through drawing flexible link assembly. Through the mode, can make photovoltaic power plant can bear great external force and not fragile, the contained angle between two photovoltaic panels of accessible regulation is in order to improve conversion efficiency simultaneously.

Description

Floating type photovoltaic power station

Technical Field

The utility model relates to a solar energy field especially relates to a float formula photovoltaic power plant.

Background

With the increasing world population, the contradiction between energy crisis and environmental problems and many people and few land is more and more prominent, the problem of energy and environment has been alleviated to a certain extent in solar energy power generation's appearance, because most of current solar power station are built on land, will certainly aggravate the shortage of land resource, consequently, some solar power stations are built on the sea, however, these solar power stations mostly have the problem that bear the external force poor ability or solar energy conversion inefficiency.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the embodiment of the utility model provides a float formula photovoltaic power station can solve traditional solar power station and install the technical problem that the ability of bearing external force is poor or solar energy conversion efficiency is low that exists when the surface of water.

The embodiment of the utility model provides a float formula photovoltaic power plant includes: the photovoltaic module comprises a first floating plate assembly, a first damping piece and a first photovoltaic panel, wherein one end of the first damping piece is installed on the first floating plate assembly, and the other end of the first damping piece is installed on one side of the first photovoltaic panel; the other side of the first photovoltaic panel is hinged to the hinged shaft; the second floating plate assembly, the second damping piece and the second photovoltaic panel are arranged, one end of the second damping piece is arranged on the second floating plate assembly, the other end of the second damping piece is arranged on one side of the second photovoltaic panel, the other side of the second photovoltaic panel is hinged to the hinged shaft, and the plane where the first photovoltaic panel is located and the plane where the second photovoltaic panel is located are intersected to form an included angle; the support can float on the water surface; the telescopic motor is arranged on the support; and the telescopic connecting rod assembly is connected with the telescopic motor, one end of the telescopic connecting rod assembly is respectively supported by the other end of the telescopic connecting rod assembly, the first photovoltaic panel deviates from the surface of light, and the second photovoltaic panel deviates from the surface of light, and the telescopic motor moves by pulling the telescopic connecting rod assembly so that the telescopic connecting rod assembly adjusts the included angle between the first photovoltaic panel and the second photovoltaic panel.

Optionally, the telescopic link assembly comprises: one end of the positioning column is mounted on the support, wherein a sliding rail is arranged inside the positioning column; the first connecting rod is accommodated in the positioning column, one end of the first connecting rod is connected with the telescopic motor, and can be driven by the telescopic motor to move in the sliding rail along the vertical direction; one end of the second connecting rod is hinged with the other end of the first connecting rod, and the other end of the second connecting rod supports the surface of the first photovoltaic panel, which is far away from the light; one end of the third connecting rod is hinged with the other end of the first connecting rod, and the other end of the third connecting rod supports the surface of the second photovoltaic panel, which is far away from the light; when the first connecting rod moves in the sliding rail along the vertical direction, the second connecting rod and the third connecting rod can be pulled to move so as to adjust an included angle between the second connecting rod and the third connecting rod.

Optionally, the first float plate assembly comprises: a first floating plate; and the second floating plate is abutted against the first floating plate and can move relative to the first floating plate along a preset direction, so that the first floating plate and the second floating plate form a folding structure, or the first floating plate and the second floating plate are mutually unfolded.

Optionally, a surface of the first floating plate facing the second floating plate is provided with a first sliding block; the surface of the second floating plate facing the first floating plate is provided with a first guide rail, the first sliding block is contained in the first guide rail and can be arranged in the first guide rail, and the second floating plate is driven to move relative to the first floating plate along a preset direction.

Optionally, the first floating plate assembly further comprises a first motor assembly, a first guide groove is formed in a surface of the first floating plate facing the second floating plate, and the first motor assembly is installed in the first guide groove; the surface of the second floating plate facing the first floating plate is provided with a first bulge, at least part of the first bulge protrudes out of the first guide groove, and the first motor component is connected with the first bulge; the first motor assembly can pull the first protrusion to move back and forth along the extending direction of the first guide groove, so that the first floating plate and the second floating plate form a folding structure, or the first floating plate and the second floating plate are mutually unfolded.

Optionally, the first motor assembly comprises: the first motor is arranged in the first guide groove; and the first push stopping piece is connected with the output end of the first motor and is also connected with the first protrusion.

Optionally, the second float plate assembly comprises: a third floating plate; and the fourth floating plate is abutted against the third floating plate and can move relative to the third floating plate along a preset direction, so that the third floating plate and the fourth floating plate form a folding structure, or the third floating plate and the fourth floating plate are mutually unfolded.

Optionally, a second sliding block is arranged on the surface, facing the fourth floating plate, of the third floating plate; the surface of the fourth floating plate facing the third floating plate is provided with a second guide rail, the second slide block is contained in the second guide rail, the second guide rail can be arranged in the second guide rail, and the fourth floating plate is driven to move relative to the third floating plate along the preset direction.

Optionally, the second floating plate assembly further comprises a second motor assembly, a second guide groove is formed in a surface, facing the fourth floating plate, of the third floating plate, and the second motor assembly is installed in the second guide groove; a second bulge is arranged on the surface, facing the third floating plate, of the fourth floating plate, at least part of the second bulge protrudes out of the second guide groove, and the second motor assembly is connected with the second bulge; the second motor assembly can pull the second protrusion to move back and forth along the extending direction of the second guide groove, so that the third floating plate and the fourth floating plate form a folding structure, or the third floating plate and the fourth floating plate are mutually unfolded.

Optionally, the second motor assembly comprises: the second motor is arranged in the second guide groove; and the second pushing and blocking part is connected with the output end of the second motor and is also connected with the second protrusion.

The embodiment of the utility model provides a beneficial effect is: be different from prior art, the embodiment of the utility model provides a float formula photovoltaic power plant, this photovoltaic power plant includes two articulated photovoltaic panels, the articulated shaft, the kickboard subassembly, the damper, the support, flexible motor and flexible link assembly, every photovoltaic panel one side all is articulated with the articulated shaft, and two photovoltaic panel place planes intersect and form a contained angle, the damper is installed between every photovoltaic panel's opposite side and kickboard subassembly, flexible motor is installed in the support and is connected with flexible link assembly, flexible link assembly props up respectively and holds the surface that two photovoltaic panels deviate from light, flexible motor removes so that flexible link assembly adjusts the contained angle between two photovoltaic panels through drawing flexible link assembly. Through the mode, can make photovoltaic power plant can bear great external force and not fragile, the contained angle between two photovoltaic panels of accessible regulation is in order to improve conversion efficiency simultaneously.

Drawings

The embodiments are illustrated by way of example only in the accompanying drawings, in which like reference numerals refer to similar elements and which are not to be construed as limiting the embodiments, and in which the figures are not to scale unless otherwise specified.

Fig. 1 is a structural diagram of a floating photovoltaic power plant according to an embodiment of the present invention;

fig. 2 is a block diagram of a floating photovoltaic power plant according to another embodiment of the present invention;

fig. 3 is a top view of a first floating plate according to an embodiment of the present invention;

fig. 4 is a top view of a second floating plate according to an embodiment of the present invention;

fig. 5 is a side view of a first float plate assembly in accordance with an embodiment of the present invention;

fig. 6 is a top view of a third floating plate according to an embodiment of the present invention;

fig. 7 is a top view of a fourth floating plate according to an embodiment of the present invention;

fig. 8 is a side view of a second float plate assembly according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

Referring to fig. 1 and 2 together, as shown in fig. 1 and 2, an embodiment of the present invention provides a floating photovoltaic power plant 100 including a first floating plate assembly 10, a first damper 11, a first photovoltaic panel 12, a hinge shaft 13, a second floating plate assembly 14, a second damper 15, a second photovoltaic panel 16, a support 17, a telescopic motor 18, and a telescopic link assembly 19, wherein one end of the first damper 11 is mounted on the first floating plate assembly 10, the other end is mounted on one side of the first photovoltaic panel 12, the other side of the first photovoltaic panel is hinged to the hinge shaft 13, one end of the second damper 15 is mounted on the second floating plate assembly 14, the other end is mounted on one side of the second photovoltaic panel 16, the other side of the second photovoltaic panel 16 is hinged to the hinge shaft 13, the plane of the first photovoltaic panel 12 intersects with the plane of the second photovoltaic panel 16 to form an included angle, the support 17 floats on the water surface, the telescopic motor 18 is installed to telescopic motor 18 installing support 17, and telescopic link assembly 19's one end is connected with telescopic motor 18, and the other end supports the surface that first photovoltaic panel 12 deviates from the light and the surface that second photovoltaic panel 16 deviates from the light respectively, and telescopic motor 18 removes so that telescopic link assembly 19 adjusts the contained angle between first photovoltaic panel 12 and the second photovoltaic panel 16 through drawing telescopic link assembly 19.

It is understood that the first and second float plate assemblies 10 and 14 may be formed in any shape or structure, and may be made of a material having a large buoyancy, so long as the first and second float plate assemblies float on water and support the first and second photovoltaic panels 12 and 16 in cooperation with the first and second dampers 11 and 15 so that the first and second photovoltaic panels 12 and 16 do not sink under water.

The first shock absorbing members 11 are installed between the first floating plate assembly 10 and one side of the first photovoltaic panel 12, and the second shock absorbing members 15 are installed between the second floating plate assembly 14 and one side of the second photovoltaic panel 16, wherein the number of the first shock absorbing members 11 or the second shock absorbing members 15 is not limited, and may be one, or more than two, for example. The first and second shock absorbing members 11 and 15 may be made of a material having shock absorbing or buffering properties, and preferably, the first and second shock absorbing members 11 and 15 are made of a polyethylene material, which is widely used for absorbing shock or impact, and the first and second shock absorbing members 11 and 15 made of the polyethylene material can absorb more than 80% of shock from the water surface, so that the floating photovoltaic power station 100 can bear huge shock and is not easily damaged.

The support 17 may be of any shape and made of any material as long as it can float on water while bearing a certain mass. It will be appreciated that when the floating photovoltaic power plant 100 is installed in the ocean, to avoid erosion by seawater, the telescopic motor 18 may be mounted inside the support 17 (as shown in fig. 2), and the telescopic link assembly 19 is moved under the traction of the telescopic motor 18 to adjust the angle between the first photovoltaic panel 12 and the second photovoltaic panel 16. It is understood that in some other embodiments, other structures may be used in place of the telescopic motor 18 and the telescopic link assembly 19, as long as the angle between the first photovoltaic panel 12 and the second photovoltaic panel 16 can be adjusted.

Install the bumper shock attenuation piece between kickboard subassembly and photovoltaic panel, can bear huge external force impact like the vibrations from the surface of water at to a great extent to make photovoltaic power plant obtain fine protection, flexible motor and flexible link assembly mutually support simultaneously, can freely adjust the contained angle between two photovoltaic panels, so that photovoltaic panel obtains better solar illumination, effectively improves solar energy conversion efficiency.

The first photovoltaic panel 12 or the second photovoltaic panel 16 includes a tempered glass (not shown), a cell (not shown), and a back sheet (not shown), wherein the cell is located between the tempered glass and the back sheet.

The photovoltaic panel is generally prepared by sequentially laying toughened glass, EVA, battery pieces, EVA and a back plate and then laminating, and in order to further improve the conversion efficiency, preferably, the toughened glass is high-light-transmittance glass with the thickness of 1.6mm, the battery pieces are polycrystalline silicon battery III-V compound semiconductors, and the back plate is high-reflectivity glass.

The first photovoltaic panel 12 or the second photovoltaic panel 16 further includes a frame (not shown) made of aluminum bronze alloy, and the photovoltaic panel body is fixed in the aluminum bronze alloy frame, so that seawater corrosion can be prevented, and marine organism adsorption can be avoided.

As shown in fig. 2, the telescopic link assembly 19 includes a positioning column 191, a sliding rail 192 disposed inside the positioning column 191, a first connecting rod 193 housed inside the positioning column 191, a second connecting rod 194 and a third connecting rod 195, one end of which is hinged to one end of the first connecting rod 193, the other end of the first connecting rod 193 is connected to the telescopic motor 18, the first connecting rod 193 is driven by the telescopic motor 18 to move in the sliding rail 192 along the vertical direction, the other end of the second connecting rod 194 supports the surface of the first photovoltaic panel 12 facing away from the light, and the other end of the third connecting rod 195 supports the surface of the second photovoltaic panel 16 facing away from the light.

The first photovoltaic panel 12 and the second photovoltaic panel 16 are supported by the second link 194 and the third link 195, and intersect each other in a plane to form an included angle, when the first link 193 moves in the slide rail 192 along the vertical direction, the second link 194 and the third link 195 are pulled to move to adjust the included angle between the second link 194 and the third link 195, so that the opening angle between the first photovoltaic panel 12 and the second photovoltaic panel 16 changes with the change of the included angle between the second link 194 and the third link 195, and therefore, the surfaces of the first photovoltaic panel 12 and the second photovoltaic panel 16 facing the light rays can receive sufficient sunlight by adjusting the included angle between the second link 194 and the third link 195.

Referring to fig. 3 to 5, the first floating plate assembly 10 includes a first floating plate 101 and a second floating plate 102, the second floating plate 102 abuts against the first floating plate 101, and the second floating plate 102 can move relative to the first floating plate 101 along a predetermined direction, so that the first floating plate 101 and the second floating plate 102 form a folding structure, or the first floating plate 101 and the second floating plate 102 are unfolded.

The preset direction may be a direction away from the first photovoltaic panel 12 or the second photovoltaic panel 16, when the first floating plate 101 and the second floating plate 102 are unfolded, the first floating plate 101 and the second floating plate 102 are both in contact with the water surface, and at this time, compared with a case where the first floating plate 101 and the second floating plate 102 form a folding structure, the contact area between the first floating plate 101 and the water surface is greatly increased, so that the buoyancy is enhanced to adapt to photovoltaic panels of various qualities.

The first slider 1011 is disposed on a surface of the first floating plate 101 facing the second floating plate 102, the first guide rail 1021 is disposed on a surface of the second floating plate 102 facing the first floating plate 101, and the first slider 1011 is accommodated in the first guide rail 1021, and drives the second floating plate 102 to move relative to the first floating plate 101 along a predetermined direction.

In order to facilitate the movement of the second floating plate 102 relative to the first floating plate 101, a plurality of sets of the first slider 1011 and the first guide rail 1021, such as two sets shown in fig. 3 to 5, may be provided.

The first floating plate assembly 10 further includes a first motor assembly 103, a first guide groove 1012 is formed on a surface of the first floating plate 101 facing the second floating plate 102, the first motor assembly 103 is installed in the first guide groove 1012, a first protrusion 1022 is formed on a surface of the second floating plate 102 facing the first floating plate 101, the first protrusion 1022 at least partially protrudes from the first guide groove 1012, and the first motor assembly 103 is connected to the first protrusion 1022. Wherein, the first motor assembly 103 may draw the first protrusion 1022 to move back and forth along the extending direction of the first guide groove 1012, so that the first floating plate 101 and the second floating plate 102 constitute a folded structure, or, so that the first floating plate 101 and the second floating plate 102 are unfolded from each other.

The first motor assembly 103 includes a first motor 1031 and a first push-stop member 1032, the first motor 1031 is installed in the first guide groove 1012, and the first push-stop member 1032 is connected to an output end of the first motor 1031 and is also connected to the first protrusion 1022. The first motor 1031 can move back and forth along the extending direction of the first guide groove 1012 by the first pushing piece 1032 and the first protrusion 1022, so as to drive the second floating plate 102 to move together in the same direction relative to the first floating plate 101. It is understood that the first motor assembly 103 can be other suitable types of drive mechanisms and the first motor 1031 can be any type of linear motor.

Referring to fig. 6 to 8, the second floating plate assembly 14 includes a third floating plate 141 and a fourth floating plate 142, the fourth floating plate 142 abuts against the third floating plate 141, and the fourth floating plate 142 can move relative to the third floating plate 141 along a predetermined direction, so that the third floating plate 141 and the fourth floating plate 142 form a folding structure, or the third floating plate 141 and the fourth floating plate 142 are unfolded.

The surface of the third floating plate 141 facing the fourth floating plate 142 is provided with a second slider 1411, the surface of the fourth floating plate 142 facing the third floating plate 141 is provided with a second guide rail 1421, and the second slider 1411 is accommodated in the second guide rail 1421, and can drive the fourth floating plate 142 to move relative to the third floating plate 141 along a predetermined direction in the second guide rail 1421.

The second floating plate assembly 14 further includes a second motor assembly 143, a second guide groove 1412 is formed on a surface of the third floating plate 141 facing the fourth floating plate 142, the second motor assembly 143 is installed in the second guide groove 1412, a second protrusion 1422 is formed on a surface of the fourth floating plate 142 facing the third floating plate 141, the second protrusion 1422 at least partially protrudes out of the second guide groove 1412, and the second motor assembly 143 is connected to the second protrusion 1422. The second motor assembly 143 may pull the second protrusion 1422 to move back and forth along the extending direction of the second guide slot 1412, so that the third floating plate 141 and the fourth floating plate 142 form a folded structure, or the third floating plate 141 and the fourth floating plate 142 are unfolded from each other.

The second motor assembly 143 includes a second motor 1431 and a second push-stop member 1432, the second motor 1431 is installed in the second guide slot 1412, and the second push-stop member 1432 is connected to an output end of the second motor 1431 and is further connected to the second protrusion 1422. The second motor 1431 can move back and forth along the extending direction of the second guide slot 1412 through the second push stopper 1432 and the second protrusion 1422, so as to drive the fourth floating plate 142 to move together in the same direction with respect to the third floating plate 141.

Finally, it is to be understood that the invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, which are intended as additional limitations on the scope of the invention, as these embodiments are provided so that the disclosure will be thorough and complete. In addition, under the idea of the present invention, the above technical features are combined with each other continuously, and many other variations of the present invention in different aspects as described above are considered as the scope of the present invention; further, modifications and variations will occur to those skilled in the art in light of the foregoing description, and it is intended to cover all such modifications and variations as fall within the true spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. A floating photovoltaic power plant, comprising:

the photovoltaic module comprises a first floating plate assembly, a first damping piece and a first photovoltaic panel, wherein one end of the first damping piece is installed on the first floating plate assembly, and the other end of the first damping piece is installed on one side of the first photovoltaic panel;

the other side of the first photovoltaic panel is hinged to the hinged shaft;

the second floating plate assembly, the second damping piece and the second photovoltaic panel are arranged, one end of the second damping piece is arranged on the second floating plate assembly, the other end of the second damping piece is arranged on one side of the second photovoltaic panel, the other side of the second photovoltaic panel is hinged to the hinged shaft, and the plane where the first photovoltaic panel is located and the plane where the second photovoltaic panel is located are intersected to form an included angle;

the support can float on the water surface;

the telescopic motor is arranged on the support; and

the telescopic connecting rod assembly is connected with the telescopic motor, one end of the telescopic connecting rod assembly is connected with the other end of the telescopic connecting rod assembly respectively supports the surface of the first photovoltaic panel deviating from light and the surface of the second photovoltaic panel deviating from light, and the telescopic motor moves through traction of the telescopic connecting rod assembly so that the telescopic connecting rod assembly adjusts the included angle between the first photovoltaic panel and the second photovoltaic panel.

2. The floating photovoltaic power plant of claim 1 wherein the telescoping link assembly comprises:

one end of the positioning column is mounted on the support, wherein a sliding rail is arranged inside the positioning column;

the first connecting rod is accommodated in the positioning column, one end of the first connecting rod is connected with the telescopic motor, and can be driven by the telescopic motor to move in the sliding rail along the vertical direction;

one end of the second connecting rod is hinged with the other end of the first connecting rod, and the other end of the second connecting rod supports the surface of the first photovoltaic panel, which is far away from the light;

one end of the third connecting rod is hinged with the other end of the first connecting rod, and the other end of the third connecting rod supports the surface of the second photovoltaic panel, which is far away from the light;

when the first connecting rod moves in the sliding rail along the vertical direction, the second connecting rod and the third connecting rod can be pulled to move so as to adjust an included angle between the second connecting rod and the third connecting rod.

3. The floating photovoltaic power plant of claim 2 wherein the first float plate assembly comprises:

a first floating plate;

and the second floating plate is abutted against the first floating plate and can move relative to the first floating plate along a preset direction, so that the first floating plate and the second floating plate form a folding structure, or the first floating plate and the second floating plate are mutually unfolded.

4. Floating photovoltaic power plant according to claim 3,

a first sliding block is arranged on the surface, facing the second floating plate, of the first floating plate;

the surface of the second floating plate facing the first floating plate is provided with a first guide rail, the first sliding block is contained in the first guide rail and can be arranged in the first guide rail, and the second floating plate is driven to move relative to the first floating plate along a preset direction.

5. Floating photovoltaic power plant according to claim 4,

the first floating plate assembly further comprises a first motor assembly, a first guide groove is formed in the surface, facing the second floating plate, of the first floating plate, and the first motor assembly is installed in the first guide groove;

the surface of the second floating plate facing the first floating plate is provided with a first bulge, at least part of the first bulge protrudes out of the first guide groove, and the first motor component is connected with the first bulge;

the first motor assembly can pull the first protrusion to move back and forth along the extending direction of the first guide groove, so that the first floating plate and the second floating plate form a folding structure, or the first floating plate and the second floating plate are mutually unfolded.

6. The floating photovoltaic power plant of claim 5 wherein the first motor assembly comprises:

the first motor is arranged in the first guide groove;

and the first push stopping piece is connected with the output end of the first motor and is also connected with the first protrusion.

7. The floating photovoltaic power plant of claim 2 wherein the second float plate assembly comprises:

a third floating plate;

and the fourth floating plate is abutted against the third floating plate and can move relative to the third floating plate along a preset direction, so that the third floating plate and the fourth floating plate form a folding structure, or the third floating plate and the fourth floating plate are mutually unfolded.

8. Floating photovoltaic power plant according to claim 7,

a second sliding block is arranged on the surface, facing the fourth floating plate, of the third floating plate;

the surface of the fourth floating plate facing the third floating plate is provided with a second guide rail, the second slide block is contained in the second guide rail, the second guide rail can be arranged in the second guide rail, and the fourth floating plate is driven to move relative to the third floating plate along the preset direction.

9. Floating photovoltaic power plant according to claim 8,

the second floating plate assembly further comprises a second motor assembly, a second guide groove is formed in the surface, facing the third floating plate, of the third floating plate, and the second motor assembly is installed in the second guide groove;

a second bulge is arranged on the surface, facing the third floating plate, of the fourth floating plate, at least part of the second bulge protrudes out of the second guide groove, and the second motor assembly is connected with the second bulge;

the second motor assembly can pull the second protrusion to move back and forth along the extending direction of the second guide groove, so that the third floating plate and the fourth floating plate form a folding structure, or the third floating plate and the fourth floating plate are mutually unfolded.

10. The floating photovoltaic power plant of claim 9 wherein the second motor assembly comprises:

the second motor is arranged in the second guide groove;

and the second pushing and blocking part is connected with the output end of the second motor and is also connected with the second protrusion.

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