CN211791377U - Solar panel adjusting device for solar photovoltaic water pump - Google Patents

Abstract

The utility model is suitable for a solar photovoltaic water pump device field provides a solar panel adjusting device for solar photovoltaic water pump, including solar panel, first frame, first recess, second frame, second recess, cylinder pole, bracing piece, first cylinder through-hole, supporting shoe, mounting hole, first lug, second cylinder through-hole, horizontal pole, second lug, third cylinder through-hole, telescopic link, fourth cylinder through-hole, fifth cylinder through-hole, first round pin axle and second round pin axle; the utility model has the advantages that: through the cooperation of bracing piece and frame, support solar panel aloft, reduced solar panel impaired probability, through the cooperation between telescopic link and the lug, can adjust solar panel's angle, improve daylighting efficiency.

Description

Solar panel adjusting device for solar photovoltaic water pump

Technical Field

The utility model belongs to solar photovoltaic water pump device field especially relates to a solar panel adjusting device for solar photovoltaic water pump.

Background

The photovoltaic water pump is also called a solar water pump and mainly comprises a photovoltaic pumping inverter and a water pump. When the solar water pumping system is applied specifically, solar cell arrays with corresponding power are matched according to the requirements of different lifts and daily water consumption, and the solar cell arrays are collectively called as a photovoltaic water pumping system. In recent years, with the increasing severity of global "food problems" and "energy problems", it is gradually praised as the most effective industrial integration product for improving the yield of effective cultivated land and replacing fossil energy with clean energy. The method becomes a new economic mode for comprehensively developing the photovoltaic industry and the traditional industries of agricultural water conservancy, desert control, domestic water, urban waterscape and the like. The photovoltaic water pump utilizes the lasting energy from the sun, works day by day, and stays day by day, does not need personnel to watch, does not need diesel oil, does not need the electric wire netting, can be applied with irrigation facilities such as drip irrigation, spray irrigation, filtration irrigation and the like in a matching way, saves water and energy, and can greatly reduce the input cost of using fossil energy power. Is a new energy and new technology application product of a global comprehensive system solution of 'food problems' and 'energy problems'.

The solar panel of the existing solar photovoltaic water pump has a fixed angle, the lighting efficiency is not high, and in addition, the existing solar panel is directly placed on the ground beside a water pool, so that the probability of damage of the solar panel is high.

SUMMERY OF THE UTILITY MODEL

The utility model provides a solar panel adjusting device for solar photovoltaic water pump aims at solving the solar panel angle fixation and the solar panel that proposes in the background art and directly places subaerial problem.

The utility model is realized in such a way, a solar panel adjusting device for a solar photovoltaic water pump is characterized in that the solar panel adjusting device for the solar photovoltaic water pump comprises a solar panel and a telescopic rod; the solar panel is characterized in that two first frames are arranged on two long edges of the solar panel, the two first frames are symmetrically arranged, a first groove is formed on one side, close to the solar panel, of each of the two first frames, the two long edges of the solar panel are arranged in the two first grooves, a second frame is arranged between the two first frames, the two second frames are symmetrically arranged, a second groove is formed on one side, close to the solar panel, of each of the two second frames, two short edges of the solar panel are arranged in the two second grooves, a cylindrical rod is formed in the middle of one side, away from the solar panel, of each of the two first frames, a first cylindrical through hole is formed in one end, away from the ground, of each of the two support rods, the cylindrical rod is arranged in the first cylindrical through hole, and a support block is formed in one end, away from the cylindrical rod, of each of the two support rods, four mounting holes are averagely formed on each supporting block along the circumferential direction, two first lifting lugs are symmetrically formed on the lower surfaces of the two second frames, a second cylindrical through hole is formed on each first lifting lug, a cross bar is arranged between the two supporting rods, two second lifting lugs are symmetrically formed on two sides of the middle position of the cross bar, a third cylindrical through hole is formed on each second lifting lug, the telescopic rod is arranged between the two first lifting lugs and the two second lifting lugs, the telescopic rods are arranged in a bilateral symmetry way, a fourth cylindrical through hole is formed at one end of each telescopic rod close to the first lifting lug, a fifth cylindrical through hole is formed at one end, close to the second lifting lug, of the telescopic rod, a first pin shaft is installed in the second cylindrical through hole and the fourth cylindrical through hole, and a second pin shaft is installed in the third cylindrical through hole and the fifth cylindrical through hole.

Furthermore, the first frame is connected with the second frame through bolts, the mounting holes in the supporting blocks are connected with the ground through inserting bolts, and the supporting rods are connected with the cross rods through bolts.

Furthermore, two sides of the first pin shaft and the second pin shaft are respectively provided with a bolt.

Furthermore, when the solar panel is in a horizontal position, an included angle between the solar panel and the telescopic rod is forty-five degrees.

Furthermore, the telescopic rod is a three-section telescopic rod.

Further, the telescopic rod is connected with an external controller.

The utility model has the advantages that: through the cooperation of bracing piece and frame, support solar panel aloft, reduced solar panel impaired probability, through the cooperation between telescopic link and the lug, can adjust solar panel's angle, improve daylighting efficiency.

Drawings

Fig. 1 is a schematic view of a first viewing angle structure provided by the present invention;

fig. 2 is a schematic view of a second viewing angle structure provided by the present invention;

fig. 3 is a schematic structural diagram of a first frame provided by the present invention;

fig. 4 is a schematic view of a second frame structure provided by the present invention;

fig. 5 is a schematic view of the telescopic rod structure provided by the present invention;

fig. 6 is a schematic view of a cross bar structure provided by 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 in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1 to 6, a solar panel adjusting device for a solar photovoltaic water pump is characterized in that the solar panel adjusting device for the solar photovoltaic water pump comprises a solar panel 1 and a telescopic rod 16; the solar panel is characterized in that two first frames 2 are arranged on two long edges of a solar panel 1, the two first frames 2 are symmetrically arranged, a first groove 3 is formed on one side of each first frame 2 close to the solar panel 1, two long edges of the solar panel 1 are arranged in the two first grooves 3, a second frame 4 is arranged between the two first frames 2, the two second frames 4 are symmetrically arranged, a second groove 5 is formed on one side of each second frame 4 close to the solar panel 1, two short edges of the solar panel 1 are arranged in the two second grooves 5, a cylindrical rod 6 is formed in the middle position of one side of each first frame 2 far from the solar panel 1, a first cylindrical through hole 8 is formed at one end of each supporting rod 7 far from the ground, the cylindrical rod 6 is arranged in the first cylindrical through hole 8, and a supporting block 9 is formed at one end of each supporting rod 7 far from the cylindrical rod 6, four mounting holes 10 are averagely formed in the circumferential direction of each supporting block 9, two first lifting lugs 11 are symmetrically formed on the lower surfaces of the two second frames 4, a second cylindrical through hole 12 is formed in each first lifting lug 11, a cross rod 13 is installed between the two supporting rods 7, two second lifting lugs 14 are symmetrically formed on the two sides of the middle position of the cross rod 13, a third cylindrical through hole 15 is formed in each second lifting lug 14, telescopic rods 16 are arranged between the two first lifting lugs 11 and the two second lifting lugs 14, the telescopic rods 16 are symmetrically arranged in the left-right direction, a fourth cylindrical through hole 17 is formed at one end, close to the first lifting lug 11, of each telescopic rod 16, a fifth cylindrical through hole 18 is formed at one end, close to the second lifting lug 14, a first pin shaft 19 is installed in each second cylindrical through hole 12 and each fourth cylindrical through hole 17, and a second pin shaft 20 is installed in each third cylindrical through hole 15 and each fifth cylindrical through hole 18.

The first frame 2 is connected with the second frame 4 through bolts, the mounting holes 10 in the supporting blocks 9 are connected with the ground through inserting bolts, the supporting rods 7 are connected with the cross rods 13 through bolts, and the first frame and the second frame are convenient to detach through bolt connection.

A bolt is mounted on each of the two sides of the first pin 19 and the second pin 20 to prevent the pins from sliding out.

When the solar panel 1 is in the horizontal position, the included angle between the solar panel 1 and the telescopic rod 16 is forty-five degrees, and the solar panel 1 and the other telescopic rod 16 form a right-angled triangle, so that the telescopic rod 16 can move conveniently.

The extension rod 16 is a three-segment extension rod, so that the extension rod 16 has a sufficient extension length.

The telescoping rod 16 is connected to an external controller to facilitate control of the telescoping rod 16.

It should be noted that the solar panel 1 and the telescopic rod 16 are prior art and are not described herein.

When using the device, when solar panel 1 is in horizontal position and need rotate left, the telescopic link 16 on the right extends, and the telescopic link 16 on the left shortens, and solar panel 1 uses cylinder pole 6 to rotate as the rotation center, and when solar panel 1 needs rotate right, the telescopic link 16 on the left extends, and the telescopic link 16 on the right shortens, and solar panel 1 rotates with 6 rotation centers on cylinder pole, and the contained angle between two telescopic links 16 is ninety degrees all the time.

The utility model has the advantages that: through the cooperation of bracing piece 7 and frame, support solar panel 1 aloft, reduced the impaired probability of solar panel 1, through the cooperation between telescopic link 16 and the lug, can adjust solar panel 1's angle, improve daylighting efficiency.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (6)

1. A solar panel adjusting device for a solar photovoltaic water pump is characterized by comprising a solar panel (1) and a telescopic rod (16); two first frames (2) are arranged on two long edges of the solar panel (1), the two first frames (2) are symmetrically arranged, one side, close to the solar panel (1), of the two first frames (2) is respectively provided with a first groove (3), the two long edges of the solar panel (1) are arranged in the two first grooves (3), a second frame (4) is arranged between the two first frames (2), the two second frames (4) are symmetrically arranged, one side, close to the solar panel (1), of the two second frames (4) is respectively provided with a second groove (5), two short edges of the solar panel (1) are arranged in the two second grooves (5), and a cylindrical rod (6) is respectively formed in the middle position of one side, far away from the solar panel (1), of the two first frames (2), one end, far away from the ground, of each of the two support rods (7) is provided with a first cylindrical through hole (8), the cylindrical rod (6) is installed in the first cylindrical through hole (8), the two support rods (7) are far away from one end of the cylindrical rod (6) is provided with a support block (9), each support block (9) is provided with four mounting holes (10) along the circumferential direction on average, the two lower surfaces of the second frames (4) are symmetrically provided with two first lifting lugs (11), each first lifting lug (11) is provided with a second cylindrical through hole (12), the two support rods (7) are provided with a cross rod (13), the two middle positions of the cross rod (13) are symmetrically provided with two second lifting lugs (14), each second lifting lug (14) is provided with a third cylindrical through hole (15), and the two first lifting lugs (11) and the two second lifting lugs (14) are provided with one telescopic rod (16) The telescopic rod (16) is arranged in a bilateral symmetry mode, a fourth cylindrical through hole (17) is formed at one end, close to the first lifting lug (11), of the telescopic rod (16), a fifth cylindrical through hole (18) is formed at one end, close to the second lifting lug (14), of the telescopic rod (16), a first pin shaft (19) is installed in the second cylindrical through hole (12) and the fourth cylindrical through hole (17), and a second pin shaft (20) is installed in the third cylindrical through hole (15) and the fifth cylindrical through hole (18).

2. The solar panel adjusting device for the solar photovoltaic water pump according to claim 1, wherein the first frame (2) and the second frame (4) are connected by bolts, the mounting holes (10) on the supporting blocks (9) are connected with the ground by inserting bolts, and the supporting rods (7) are connected with the cross rods (13) by bolts.

3. The solar panel adjusting device for the solar photovoltaic water pump according to claim 1, wherein a pin is installed on each of two sides of the first pin (19) and the second pin (20).

4. The solar panel adjusting device for the solar photovoltaic water pump according to claim 1, wherein the angle between the solar panel (1) and the telescopic rod (16) is forty-five degrees when the solar panel is in a horizontal position.

5. The solar panel adjusting device for a solar photovoltaic water pump according to claim 4, wherein the telescopic rod (16) is a three-segment telescopic rod.

6. The solar panel adjusting device for the solar photovoltaic water pump according to claim 5, wherein the telescopic rod (16) is connected with an external controller.

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