CN210075128U - Distributed power generation system with dispatch control - Google Patents

Abstract

The utility model provides a distributed power generation system with allotment control belongs to mechanical technical field. It has solved prior art and has had the poor problem of stability. This distributed power generation system with allotment control, support and the solar photovoltaic board of connection on the support form a power generation unit, and a plurality of power generation units link together and form distributed power generation system, have between one of them support in two adjacent power generation units and another support and enable both can dismantle the connection's connection structure, still include flexible buffer block, and the buffer block is compressed tightly between two adjacent supports under above-mentioned connection structure's effect. The distributed power generation system with the dispatching control has high stability.

Description

Distributed power generation system with dispatch control

Technical Field

The utility model belongs to the technical field of machinery, a distributed generation system with allotment control is related to.

Background

The support and the solar photovoltaic panel connected to the support form a power generation unit, and the power generation units are connected together to form a distributed power generation system.

In order to stably connect two adjacent power generation units together, a fastener is generally used to connect two adjacent brackets.

It can be seen that this connection is detachable. However, the gap between two adjacent brackets is small, so that the distance between two adjacent solar photovoltaic panels is small, and the two adjacent solar photovoltaic panels may touch together, thereby affecting the stability of the solar photovoltaic panels.

Disclosure of Invention

The utility model aims at the above-mentioned problem that prior art exists, provide a loading and unloading convenience and compact structure's distributed power generation system with allotment control.

The purpose of the utility model can be realized by the following technical proposal:

the utility model provides a distributed power generation system with allotment control, support and the solar photovoltaic board of connecting on the support form a power generation unit, and a plurality of power generation units link together and form distributed power generation system, its characterized in that has between one of them support of two adjacent power generation units and another support and enables both can dismantle the connection's connection structure, still includes flexible buffer block, and the buffer block is compressed tightly between two adjacent supports under above-mentioned connection structure's effect.

This power generation system creatively links together two adjacent supports through connection structure is stable, because the buffer block is located between two adjacent supports, enables to possess suitable interval between two adjacent supports and two adjacent solar photovoltaic boards under the effect of buffer block.

Of course, under the action of the buffer block, rigid contact between two adjacent brackets can be avoided.

In the above distributed power generation system with allocation control, the connection structure includes a connecting rod and a positioning nut, the outer end of the connecting rod has a plate-shaped pressing plate, the positioning nut is sleeved at the inner end of the connecting rod and is in threaded connection with the inner end of the connecting rod, the connecting rod is arranged on two adjacent supports in a penetrating manner, the pressing plate abuts against one of the supports, and the positioning nut abuts against the other support.

The connecting rod is arranged on two adjacent supports in a penetrating mode, the pressing plate is abutted against one of the supports, the positioning nut is abutted against the other support, and the two adjacent supports can be stably connected together through the structure.

Certainly, after the positioning nut is loosened, the connecting rod can be conveniently disassembled between two adjacent brackets.

In the above-mentioned distributed power generation system with deployment control, the pressure plate and the connecting rod are of an integrated structure.

In the above-mentioned distributed power generation system with allocation control, the buffer block is cylindrical and has a through hole running through along the axis direction of the buffer block, and the connecting rod is arranged in the through hole in a penetrating manner and two ends of the buffer block are respectively abutted against two adjacent brackets.

The connecting rod plays a positioning role in the buffer block, and the buffer block is tightly pressed between two adjacent supports, so that the structure can avoid rigid contact between the two adjacent supports.

In the above-mentioned distributed power generation system with allocation control, the pressure plate is plate-shaped, and the outer end of the above-mentioned connecting rod is sleeved with a first gasket, which is tightly pressed between the pressure plate and the bracket.

And the rigid contact between the pressure plate and the bracket can be avoided under the action of the first gasket.

In the above-mentioned distributed power generation system with allocation control, the inner end of the connecting rod is sleeved with the second gasket, and the second gasket is tightly pressed between the positioning nut and the bracket.

And the positioning nut can be prevented from being in rigid contact with the bracket under the action of the second gasket.

In the above distributed power generation system with allocation control, the buffer block includes a first cylindrical body, a second cylindrical body and a third cylindrical body, the second cylindrical body is located between the first cylindrical body and the third cylindrical body, both the first cylindrical body and the third cylindrical body are made of rubber materials, and the second cylindrical body is made of cast iron materials.

The second barrel can improve the strength of the whole buffer block, and the first barrel and the third barrel can enable the buffer block to be in stable flexible contact with the support.

In the above-described distributed power generation system with deployment control, one end of the cylinder is in surface contact with the side of one of the supports, and the three ends of the cylinder are in surface contact with the side of the other support.

In the above-mentioned distributed power generation system with blending control, the length of the first cylinder is the same as that of the third cylinder, and the length of the second cylinder is 2-4 times that of the first cylinder.

Such a structure enables the whole buffer block to have enough strength and also be stably flexibly contacted by the bracket.

In the above-described distributed power generation system with deployment control, the inner end of the connecting rod has a smoothly-transiting lead-in portion.

The leading-in part is a chamfer at the inner end of the connecting rod, and the leading-in part can enable the positioning nut to be smoothly connected to the connecting rod.

Compared with the prior art, this distributed generation system with allotment control is owing to can be in the same place two adjacent support stable connections under connection structure's effect, simultaneously, can avoid two adjacent support rigid contact under the effect of buffer block, consequently, its stability is not only than higher, compact structure moreover.

Meanwhile, after the positioning nut is loosened, the connecting rod can be conveniently assembled and disassembled between two adjacent connecting rods, and the buffer block is sleeved at the middle part of the connecting rod, so that the structure is convenient to assemble and disassemble, and has high practical value.

Drawings

FIG. 1 is a schematic cross-sectional view of the present distributed power generation system with dispatch control.

In the figure, 1, a bracket; 2. a solar photovoltaic panel; 3. a buffer block; 3a, a first cylinder; 3b, a second cylinder body; 3c, a third cylinder; 4. a connecting rod; 4a, a pressing plate; 4b, an introduction part; 5. positioning a nut; 6. a first gasket; 7. and a second gasket.

Detailed Description

As shown in fig. 1, a support 1 and a solar photovoltaic panel 2 connected to the support 1 form a power generation unit, a plurality of power generation units are connected together to form a distributed power generation system, a connection structure enabling the two power generation units to be detachably connected is arranged between one support 1 and the other support 1 in two adjacent power generation units, the power generation system further comprises a flexible buffer block 3, and the buffer block 3 is tightly pressed between the two adjacent supports 1 under the action of the connection structure.

The connecting structure comprises a connecting rod 4 and a positioning nut 5, a plate-shaped pressing plate 4a is arranged at the outer end of the connecting rod 4, the positioning nut 5 is sleeved at the inner end of the connecting rod 4 and is in threaded connection with the connecting rod 4, the connecting rod 4 penetrates through two adjacent supports 1, the pressing plate 4a abuts against one of the supports 1, and the positioning nut 5 abuts against the other support 1.

The pressing plate 4a and the connecting rod 4 are of an integrated structure.

The buffer block 3 is cylindrical and has a through hole running through along the axis direction of the buffer block 3, the connecting rod 4 is arranged in the through hole in a penetrating manner, and two ends of the buffer block 3 are respectively abutted against the two adjacent brackets 1.

The pressing plate 4a is plate-shaped, a first gasket 6 is sleeved at the outer end of the connecting rod 4, and the first gasket 6 is tightly pressed between the pressing plate 4a and the support 1.

The inner end of the connecting rod 4 is sleeved with a second gasket 7, and the second gasket 7 is tightly pressed between the positioning nut 5 and the bracket 1.

The buffer block 3 comprises a first cylindrical body 3a, a second cylindrical body 3b and a third cylindrical body 3c, the second cylindrical body 3b is located between the first cylindrical body 3a and the third cylindrical body 3c, the first cylindrical body 3a and the third cylindrical body 3c are made of rubber materials, and the second cylindrical body 3b is made of cast iron materials.

The end part of the cylinder body one 3a is contacted with the side surface of one bracket 1, and the end part of the cylinder body three 3c is contacted with the side surface of the other bracket 1.

The length of the first cylinder body 3a is the same as that of the third cylinder body 3c, and the length of the second cylinder body 3b is 2-4 times that of the first cylinder body 3 a.

The inner end of the connecting rod 4 is provided with a smoothly transiting lead-in part 4 b.

Of course, under the action of the buffer block, rigid contact between two adjacent brackets can be avoided.

In the above distributed power generation system with allocation control, the connection structure includes a connecting rod and a positioning nut, the outer end of the connecting rod has a plate-shaped pressing plate, the positioning nut is sleeved at the inner end of the connecting rod and is in threaded connection with the inner end of the connecting rod, the connecting rod is arranged on two adjacent supports in a penetrating manner, the pressing plate abuts against one of the supports, and the positioning nut abuts against the other support.

The connecting rod is arranged on two adjacent supports in a penetrating mode, the pressing plate is abutted against one of the supports, the positioning nut is abutted against the other support, and the two adjacent supports can be stably connected together through the structure.

Certainly, after the positioning nut is loosened, the connecting rod can be conveniently disassembled between two adjacent brackets.

The set amount of the generating units can be reserved according to the actual situation after the positioning nuts are loosened, so that the purpose of actually allocating and controlling the generating units according to the specific situation is achieved.

Claims (10)

1. The utility model provides a distributed power generation system with allotment control, support and the solar photovoltaic board of connecting on the support form a power generation unit, and a plurality of power generation units link together and form distributed power generation system, its characterized in that has between one of them support of two adjacent power generation units and another support and enables both can dismantle the connection's connection structure, still includes flexible buffer block, and the buffer block is compressed tightly between two adjacent supports under above-mentioned connection structure's effect.

2. The distributed power generation system with blending control of claim 1, wherein the connecting structure comprises a connecting rod and a positioning nut, the outer end of the connecting rod is provided with a plate-shaped pressing plate, the positioning nut is sleeved at the inner end of the connecting rod and is in threaded connection with the inner end of the connecting rod, the connecting rod is arranged on two adjacent brackets in a penetrating way, the pressing plate abuts against one bracket, and the positioning nut abuts against the other bracket.

3. The distributed power generation system with blending control of claim 2, wherein the pressure plate and tie rod are a unitary structure.

4. The distributed power generation system with dispatching control as claimed in claim 3, wherein the buffer block is cylindrical and has a through hole along the axis direction of the buffer block, the connecting rod is inserted into the through hole and the two ends of the buffer block are respectively abutted against the two adjacent brackets.

5. The distributed power generation system with blending control of claim 4, wherein said pressure plate is plate-shaped, and a first spacer is sleeved at an outer end of said connecting rod, said first spacer being compressed between said pressure plate and said bracket.

6. The distributed power generation system with blending control of claim 5, wherein the inner end of the connecting rod is sleeved with a second spacer, and the second spacer is tightly pressed between the positioning nut and the bracket.

7. The distributed power generation system with blending control of claim 6, wherein the buffer block comprises a first cylindrical body, a second cylindrical body and a third cylindrical body, wherein the first cylindrical body is located between the first cylindrical body and the third cylindrical body, the first cylindrical body and the third cylindrical body are both made of rubber material, and the second cylindrical body is made of cast iron material.

8. The distributed power generation system with blending control of claim 7, wherein one end of the canister is in face contact with a side of one of the brackets and the three ends of the canister are in face contact with the other bracket side.

9. The distributed power generation system with blending control of claim 8, wherein said barrel one and barrel three are the same length, and said barrel two has a length dimension 2-4 times the length dimension of barrel one.

10. The distributed power generation system with blending control of claim 9, wherein said connecting rod inner end has a smooth transition lead-in.

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