CN215581065U - Outdoor test support of photovoltaic module power generation performance - Google Patents

Abstract

The utility model relates to the technical field of photovoltaic module testing, in particular to an outdoor testing bracket for the power generation performance of a photovoltaic module, which comprises a first bracket, a second bracket and a third bracket, wherein the first bracket is arranged on the first bracket; a support bracket; the support bracket is also provided with a first bolt, a stabilizing mechanism is arranged between the first support and the support bracket, the stabilizing mechanism comprises a stabilizing rod, one end of the stabilizing rod is provided with a first slot corresponding to the first bolt, and the other end of the stabilizing rod is also provided with a second slot; and the sliding frame is sleeved on the first support, and a second bolt corresponding to the second slot is further arranged on the sliding frame. This application promotes the support bracket through external force and carries out angle modulation, makes to rotate on the support bracket, and the stabilizer bar can remove through first slot, and later the stabilizer bar then can drive the sliding frame rather than being connected, makes the sliding frame slide from top to bottom on first support, stabilizes the angle accommodation process to can also play the supporting role after angle modulation accomplishes, solved the technical problem of how to stabilize photovoltaic module's angle adjustment process.

Description

Outdoor test support of photovoltaic module power generation performance

Technical Field

The utility model relates to the technical field of photovoltaic module testing, in particular to an outdoor testing support for the power generation performance of a photovoltaic module.

Background

Because the light source of the photovoltaic module testing machine cannot completely simulate the spectrum of sunlight, the optical module often needs to be tested outdoors to research the actual performance of the module under the sunlight, and thus, a support is indispensable for mounting the optical module.

In the existing outdoor test bracket, for example, patent No. CN202022257346.3 discloses an outdoor test bracket for a photovoltaic module, which can adjust an angle during a test process, but the angle adjustment process is not stable, and an irradiation angle may deviate under the action of gravity, thereby affecting a test result.

Therefore, an outdoor test support for the power generation performance of the photovoltaic module is needed.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, an outdoor test support for the power generation performance of the photovoltaic module is provided.

In order to achieve the above purposes, the technical scheme adopted by the utility model is as follows:

an outdoor test bracket for the power generation performance of a photovoltaic module comprises,

a first bracket;

the supporting bracket is arranged on the first bracket and is movably connected with the first bracket;

the support bracket is also provided with a first bolt, a stabilizing mechanism is arranged between the first bracket and the support bracket, the stabilizing mechanism comprises,

One end of the stabilizer bar is provided with a first slot corresponding to the first bolt, the stabilizer bar is movably connected with the bearing bracket through the first slot, and the other end of the stabilizer bar is also provided with a second slot;

the sliding frame is sleeved on the first support and movably connected with the first support, a second bolt corresponding to the second slot is further arranged on the sliding frame, and the sliding frame is movably connected with the other end of the stabilizer bar through the second bolt.

Preferably, the first support is composed of a fixed base and a stretching rod, the fixed base is arranged on the ground, a through hole is formed in the bottom end of the fixed base, a first sliding groove is formed in the fixed base, and the sliding rod is movably arranged on the first sliding groove.

Preferably, the fixed base is provided with an internal thread cylinder communicated with the first sliding groove, the internal thread cylinder is further provided with a thread column corresponding to the internal thread cylinder, and the thread column is provided with a handle.

Preferably, be provided with the third slot on the tensile pole, the support bracket comprises first backup pad and second backup pad, is provided with the third bolt that corresponds with the third slot on the first backup pad, and first backup pad passes through third bolt and tensile pole swing joint, and second backup pad fixed mounting is on first backup pad.

Preferably, a second sliding groove is formed in the second supporting plate, a plurality of uniformly distributed fourth slots are formed in the bottom end of the second sliding groove, sliding fixtures corresponding to the second sliding groove are arranged at two ends of the second sliding groove respectively, and a fourth bolt corresponding to the fourth slot is arranged at the bottom end of each sliding fixture.

Preferably, the third bolt is also provided with a square perpendicular to the horizontal plane of the first supporting plate.

Compared with the prior art, the application has the beneficial effects that:

1. this application carries out angle modulation through the support bracket, makes the first bolt on the support bracket can rotate, and the stabilizer bar can remove through first slot, and later the stabilizer bar then can drive the sliding frame rather than being connected through the second slot, makes the sliding frame slide from top to bottom on first support, stabilizes angle accommodation process to can also play the supporting role after angle modulation accomplishes, solved the technical problem of how to stabilize photovoltaic module's angle adjustment process.

2. This application is fixed with ground through the through-hole of the fixed bolster that the screw will pass, and later foreign force draws and rises tensile pole, makes it rise or descend to drive the support bracket of rather than being connected and rise or descend and be convenient for people's installation photovoltaic module, solved how be convenient for people's installation photovoltaic module's of more technical problem, rise or the decline process simultaneously, stabilizer bar and sliding frame also can remove and still also played the supporting role to the support bracket.

3. This application is through rotating the handle, and the screw post is inwards removed to support tensile pole messenger tensile pole fixed including making the screw post, perhaps outwards removes to make it loosen tensile pole and make its regulation, and the handle can give people and provide the resultant force of grabbing better, has solved the technical problem of how to fix the technical problem of movable rod.

4. This application passes through the first backup pad of external force promotion, makes first backup pad rotate on tensile pole through the third bolt to adjust the photovoltaic module who installs on supporting the bracket and shine the angle, solved how angle regulation's technical problem.

5. This application lays photovoltaic module through the second backup pad, rethread fourth spout supports the slip anchor clamps at photovoltaic module's both ends and fixes it, the external screw of rethread passes fourth bolt and fourth slot, make the slip anchor clamps also fixed, it is required to explain if the photovoltaic module who tests is too big, can change first backup pad into second backup pad structure, make the second backup pad slide from top to bottom, thereby fix great photovoltaic module, how to fix different size photovoltaic module's technical problem has been solved.

6. This application can make the staff can more clearly survey turned angle through the square with first backup pad vertically, has solved how to measure the technical problem who shines the angle.

Drawings

FIG. 1 is a first perspective view of the present invention;

FIG. 2 is a second perspective view of the present invention;

fig. 3 is a partial enlarged view at a of fig. 2;

fig. 4 is a partial enlarged view at B of fig. 2;

FIG. 5 is a first side view of the present invention;

FIG. 6 is a second side view of the present invention;

the reference numbers in the figures are:

1-a first scaffold; 1 a-a stationary base; 1a1 — first runner; 1a 2-internal threaded cartridge; 1a 3-threaded post; 1a 4-handle; 1 b-a stretch rod; 1b 1-third slot; 1 c-a via;

2-a support bracket; 2 a-a first bolt; 2 b-a first support plate; 2b 1-third latch; 2b 2-square; 2 c-a second support plate; 2c 1-second runner; 2c 2-fourth slot; 2 d-sliding clamp; 2d 1-fourth latch;

3-a stabilizer bar; 3 a-a first slot; 3 b-a second slot;

4-a sliding frame; 4 a-second pin.

Detailed Description

The following description is presented to disclose the utility model so as to enable any person skilled in the art to practice the utility model. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art.

In order to solve the technical problem of how to stabilize the angle adjustment process of the photovoltaic module, as shown in fig. 1 to 6, the following preferred technical solutions are provided:

An outdoor test bracket for the power generation performance of a photovoltaic module comprises,

a first support 1;

the supporting bracket 2 is arranged on the first bracket 1 and is movably connected with the first bracket 1;

the support bracket 2 is also provided with a first bolt 2a, a stabilizing mechanism is arranged between the first bracket 1 and the support bracket 2, the stabilizing mechanism comprises,

one end of the stabilizer bar 3 is provided with a first slot 3a corresponding to the first bolt 2a, the stabilizer bar 3 is movably connected with the support bracket 2 through the first slot 3a, and the other end of the stabilizer bar 3 is also provided with a second slot 3 b;

the sliding frame 4 is sleeved on the first support 1 and movably connected with the first support 1, a second bolt 4a corresponding to the second slot 3b is further arranged on the sliding frame 4, and the sliding frame 4 is movably connected with the other end of the stabilizer bar 3 through the second bolt 4 a.

Specifically, when bearing bracket 2 carries out angle modulation, first bolt 2a on the bearing bracket 2 can rotate, stabilizer bar 3 can remove through first slot 3a, later stabilizer bar 3 then can drive the sliding frame 4 rather than being connected through second slot 3b, make sliding frame 4 slide from top to bottom on first support 1, stabilize angle accommodation process, and can also play the supporting role after angle modulation accomplishes, it is first slot 3a and first bolt 2a and second slot 3b and second bolt 4a to explain, not only can directly drive stabilizer bar 3 and sliding frame 4 direct movement at angle modulation in-process, but can carry out one section rotation accommodation process, prevent that the sliding rod from blocking the condition such as collapsing.

In order to solve the technical problem of how to facilitate people to install the photovoltaic module, as shown in fig. 1, 4, 5 and 6, the following preferred technical solutions are provided:

the first support 1 is composed of a fixed base 1a and a stretching rod 1b, the fixed base 1a is arranged on the ground, the bottom end of the fixed base is provided with a through hole 1c, a first sliding groove 1a1 is arranged inside the fixed base 1a, and the sliding rod is movably arranged on the first sliding groove 1a 1.

Specifically, the through hole 1c of the fixing support which is penetrated through by the screw is fixed with the ground, then the stretching rod 1b is pulled up by foreign force to be lifted up or lowered down, so that the supporting bracket 2 connected with the stretching rod is driven to be lifted up or lowered down to be convenient for people to install the photovoltaic module, it is to be noted that in the lifting or lowering process, as shown in fig. 5 and 6, the stabilizing rod 3 is driven by the supporting bracket 2 to be lifted up or lowered down, so that the sliding frame 4 slides on the first support 1, and the supporting bracket 2 is supported.

In order to solve the technical problem of how to fix the movable rod, as shown in fig. 2, the following preferred technical solutions are provided:

the fixed base 1a is provided with an internal thread cylinder 1a2 communicated with the first sliding chute 1a1, the internal thread cylinder 1a2 is further provided with a corresponding thread column 1a3, and the thread column 1a3 is provided with a handle 1a 4.

Specifically, by rotating the handle 1a4, the screw post 1a3 moves inward on the internal screw post 1a3 against the stretching rod 1b to fix the stretching rod 1b, or moves outward to release the stretching rod 1b for adjustment, and it should be noted that the handle 1a4 is to provide better gripping force to people.

In order to solve the technical problem of how to adjust the angle, as shown in fig. 1, the following preferred technical solutions are provided:

the stretching rod 1b is provided with a third slot 1b1, the support bracket 2 is composed of a first support plate 2b and a second support plate 2c, the first support plate 2b is provided with a third bolt 2b1 corresponding to the third slot 1b1, the first support plate 2b is movably connected with the stretching rod 1b through the third bolt 2b1, and the second support plate 2c is fixedly arranged on the first support plate 2 b.

Specifically, the first support plate 2b is pushed by an external force, so that the first support plate 2b is rotated on the stretching rod 1b through the third pin 2b1, thereby adjusting the irradiation angle of the photovoltaic module mounted on the support bracket 2.

In order to solve the technical problem of how to fix photovoltaic modules of different sizes, as shown in fig. 1 and 3, the following preferred technical solutions are provided:

the second support plate 2c is provided with a second sliding groove 2c1, the bottom end of the second sliding groove 2c1 is provided with a plurality of uniformly distributed fourth slots 2c2, two ends of the second sliding groove 2c1 are respectively provided with a sliding clamp 2d corresponding to the second sliding groove, and the bottom end of the sliding clamp 2d is provided with a fourth plug pin 2d1 corresponding to the fourth slot 2c 2.

Specifically, put photovoltaic module installation on second backup pad 2c, support slide fixture 2d at photovoltaic module's both ends and fix it through the fourth spout, the outside screw of rethread passes fourth bolt 2d1 and fourth slot 2c2, make slide fixture 2d also fixed, it is too big to explain if the photovoltaic module who tests, can change first backup pad 2b into second backup pad 2c structure, make second backup pad 2c slide from top to bottom, thereby fixed great photovoltaic module.

In order to solve the technical problem of how to measure the irradiation angle, as shown in fig. 5 and 6, the following preferred technical solutions are provided:

the third pin 2b1 is also provided with a square 2b2 perpendicular to the horizontal plane of the first support plate 2 b.

Specifically, when the irradiation angle needs to be measured, the square 2b2 perpendicular to the first support plate 2b enables the worker to observe the rotation angle more clearly.

The foregoing shows and describes the general principles, essential features, and advantages of the utility model. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are merely illustrative of the principles of the utility model, but that various changes and modifications may be made without departing from the spirit and scope of the utility model, which fall within the scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (6)

1. An outdoor test bracket for the power generation performance of a photovoltaic module comprises,

a first bracket (1);

the supporting bracket (2) is arranged on the first bracket (1) and is movably connected with the first bracket (1);

it is characterized in that the support bracket (2) is also provided with a first bolt (2a), a stabilizing mechanism is arranged between the first bracket (1) and the support bracket (2), the stabilizing mechanism comprises,

one end of the stabilizer bar (3) is provided with a first slot (3a) corresponding to the first bolt (2a), the stabilizer bar (3) is movably connected with the support bracket (2) through the first slot (3a), and the other end of the stabilizer bar (3) is also provided with a second slot (3 b);

the sliding frame (4) is sleeved on the first support (1) and is movably connected with the first support (1), a second bolt (4a) corresponding to the second slot (3b) is further arranged on the sliding frame (4), and the sliding frame (4) is movably connected with the other end of the stabilizer bar (3) through the second bolt (4 a).

2. An outdoor test support for the power generation performance of a photovoltaic module according to claim 1, characterized in that the first support (1) is composed of a fixed base (1a) and a stretching rod (1b), the fixed base (1a) is disposed on the ground and the bottom end of the fixed base is provided with a through hole (1c), the fixed base (1a) is internally provided with a first sliding chute (1a1), and the sliding rod is movably disposed on the first sliding chute (1a 1).

3. The outdoor test bracket for the power generation performance of the photovoltaic module as claimed in claim 2, wherein the fixing base (1a) is provided with an internal thread cylinder (1a2) communicated with the first sliding groove (1a1), the internal thread cylinder (1a2) is further provided with a corresponding thread column (1a3), and the thread column (1a3) is provided with a handle (1a 4).

4. An outdoor test support for photovoltaic module power generation performance according to claim 3, characterized in that the stretching rod (1b) is provided with a third slot (1b1), the support bracket (2) is composed of a first support plate (2b) and a second support plate (2c), the first support plate (2b) is provided with a third plug pin (2b1) corresponding to the third slot (1b1), the first support plate (2b) is movably connected with the stretching rod (1b) through the third plug pin (2b1), and the second support plate (2c) is fixedly mounted on the first support plate (2 b).

5. The outdoor test bracket for the power generation performance of the photovoltaic module according to claim 4, wherein the second support plate (2c) is provided with a second sliding groove (2c1), the bottom end of the second sliding groove (2c1) is provided with a plurality of uniformly distributed fourth slots (2c2), two ends of the second sliding groove (2c1) are respectively provided with a sliding clamp (2d) corresponding to the second sliding groove, and the bottom end of the sliding clamp (2d) is provided with a fourth plug pin (2d1) corresponding to the fourth slot (2c 2).

6. An outdoor test support for the power generation performance of photovoltaic modules according to claim 4, characterized in that the third pin (2b1) is further provided with a square (2b2) perpendicular to the horizontal plane of the first support plate (2 b).

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