CN220085785U - Supporting structure of cooling device of extra-high voltage shunt reactor - Google Patents

Abstract

The utility model relates to a supporting structure of an extra-high voltage shunt reactor cooling device, and belongs to the technical field of transformers. The technical proposal is as follows: the fans (4) are arranged at the lower parts of the sheet powder (3), the sheet powder (3) is divided into two groups, each group of sheet powder (3) is provided with an upper collecting pipe (1) and a lower collecting pipe (2), the upper collecting pipe (1) and the lower collecting pipe (2) in each group of sheet powder (3) are connected together through supporting brackets (6), and the supporting brackets (6) in the two groups of sheet powder (3) are connected through a diagonal bracket A (7); the upper collecting pipes (1) in each group of the powder (3) are respectively provided with an upper collecting pipe hanging ring (9), the lower collecting pipes (2) in each group of the powder (3) are respectively fixed on two fixing brackets (5), and the four fixing brackets (5) are connected through a diagonal bracket B (8). The beneficial effects of the utility model are as follows: simple structure, area is little, can satisfy the whole requirement of lifting by crane and transporting.

Description

Supporting structure of cooling device of extra-high voltage shunt reactor

Technical Field

The utility model relates to a supporting structure of an extra-high voltage shunt reactor cooling device, and belongs to the technical field of transformers.

Background

Along with the progress of the times, energy conservation and emission reduction become the international development trend, the ultra-high voltage transmission line is continuously built in China every year, and the high-capacity ultra-high voltage shunt reactor is an indispensable device in the ultra-high voltage transmission line.

The cooling device of the high-capacity ultra-high voltage shunt reactor comprises an upper collecting pipe, a lower collecting pipe, a sheet radiator and a sheet radiator fan, wherein the sheet radiator is arranged between the upper collecting pipe and the lower collecting pipe, the upper collecting pipe and the lower collecting pipe are supported by an upper collecting pipe supporting bracket and a lower collecting pipe supporting bracket, and the fan is arranged at the lower part of the sheet radiator. The two groups of fins are connected and fixed with the 17 small brackets through the down collecting pipe, so that the whole cooling device is arranged on the foundation. The whole structure occupies a large area, is complex in structure and cannot be transported between an assembly workshop and a test station by adopting an air cushion vehicle. This results in the cooling device having to be disassembled and assembled at the test station, which greatly increases the overall installation cycle of the reactor, and occupies the test station for too long, severely wasting test resources. Therefore, the support structure of the cooling device is simplified, and the whole lifting and the whole transferring are realized, so that the work is urgent.

Disclosure of Invention

The utility model aims to provide a supporting structure of an extra-high voltage shunt reactor cooling device, which has the advantages of simple structure and small occupied area, can meet the requirements of integral lifting and transferring, and solves the problems in the prior art.

The technical scheme of the utility model is as follows:

the supporting structure of the cooling device of the extra-high voltage shunt reactor comprises an upper collecting pipe, a lower collecting pipe, a piece of powder, a fan, a fixed bracket, a supporting bracket, a diagonal bracket A, a diagonal bracket B and an upper collecting pipe hanging ring, wherein the fan is arranged at the lower part of the piece of powder, the piece of powder is divided into two groups, each group of powder is provided with an upper collecting pipe and a lower collecting pipe, the upper collecting pipe and the lower collecting pipe in each group of piece of powder are connected together through the supporting bracket, and the supporting brackets in the two groups of piece of powder are connected through the diagonal bracket A;

and the upper collecting pipes in each group of the fins are respectively provided with an upper collecting pipe hanging ring, the lower collecting pipes in each group of the fins are respectively fixed on two fixing brackets, and the four fixing brackets are connected through a diagonal bracket B.

The fixed support is an integrated structure composed of an upright post and a base fixed at the bottom of the upright post.

The support brackets between the upper collecting pipe and the lower collecting pipe in each group of the scattered sheets are three support columns.

The cable-stayed bracket A and the cable-stayed bracket B are both composed of two connecting rods which are crossed together.

And two upper collecting pipe hanging rings are arranged on the upper collecting pipe in each group of the fins.

The beneficial effects of the utility model are as follows: the support structure is simplified, the assembly period is shortened, free transfer between an assembly workshop and a test station can be realized, and the test station resources are saved. Meanwhile, the requirements of integral lifting and transferring can be met, and the assembly workload is greatly reduced.

Drawings

FIG. 1 is a front view of the present utility model;

FIG. 2 is a side view of the present utility model;

in the figure: the device comprises an upper collecting pipe 1, a lower collecting pipe 2, a sheet 3, a fan 4, a fixed bracket 5, a supporting bracket 6, a diagonal bracket A7, a diagonal bracket B8 and an upper collecting pipe hanging ring 9.

Detailed Description

The utility model is further illustrated by way of example with reference to the accompanying drawings.

Referring to fig. 1 and 2, a supporting structure of an extra-high voltage shunt reactor cooling device comprises an upper collecting pipe 1, a lower collecting pipe 2, a sheet 3, a fan 4, a fixed bracket 5, a supporting bracket 6, a diagonal bracket A7, a diagonal bracket B8 and an upper collecting pipe hanging ring 9, wherein the fan 4 is arranged at the lower part of the sheet 3, the sheet 3 is divided into two groups, each group of sheet 3 is provided with the upper collecting pipe 1 and the lower collecting pipe 2, the upper collecting pipe 1 and the lower collecting pipe 2 in each group of sheet 3 are connected together through the supporting bracket 6, and the supporting brackets 6 in the two groups of sheet 3 are connected through the diagonal bracket A7;

the upper collecting pipes 1 in each group of the sheet powder 3 are respectively provided with an upper collecting pipe hanging ring 9, the lower collecting pipes 2 in each group of the sheet powder 3 are respectively fixed on two fixing brackets 5, and the four fixing brackets 5 are connected through a diagonal bracket B8.

In this example, referring to fig. 1 and 2, the support frames 6 between the upper manifold 1 and the lower manifold 2 in each group of the powder 3 are three support columns, and two groups are six.

The fixing support 5 is an integral structure formed by upright posts and bases fixed at the bottoms of the upright posts, and the number of the fixing support is four, and two fixing supports are arranged on each lower collecting pipe 2.

The cable-stayed bracket A7 and the cable-stayed bracket B8 are composed of two connecting rods which are crossed together so as to strengthen the supporting stability.

The number of the upper collecting pipe hanging rings 9 is four, and two upper collecting pipes 1 are welded, so that the whole lifting and transferring of the cooling device after the assembly is completed can be realized.

Claims (5)

1. The utility model provides a extra-high voltage shunt reactor cooling device's bearing structure which characterized in that: the device comprises an upper collecting pipe (1), a lower collecting pipe (2), a piece powder (3), a fan (4), a fixed support (5), a supporting support (6), a diagonal support A (7), a diagonal support B (8) and an upper collecting pipe hanging ring (9), wherein the fan (4) is arranged at the lower part of the piece powder (3), the piece powder (3) is divided into two groups, each group of piece powder (3) is provided with an upper collecting pipe (1) and a lower collecting pipe (2), the upper collecting pipe (1) and the lower collecting pipe (2) in each group of piece powder (3) are connected together through the supporting support (6), and the supporting supports (6) in the two groups of piece powder (3) are connected through the diagonal support A (7);

the upper collecting pipes (1) in each group of the sheet powder (3) are respectively provided with an upper collecting pipe hanging ring (9), the lower collecting pipes (2) in each group of the sheet powder (3) are respectively fixed on two fixing brackets (5), and the four fixing brackets (5) are connected through a diagonal bracket B (8).

2. The support structure of an extra-high voltage shunt reactor cooling device according to claim 1, wherein: the fixed support (5) is an integrated structure formed by an upright post and a base fixed at the bottom of the upright post.

3. The support structure of an extra-high voltage shunt reactor cooling device according to claim 1, wherein: the support brackets (6) between the upper collecting pipe (1) and the lower collecting pipe (2) in each group of the fins (3) are three support columns.

4. The support structure of an extra-high voltage shunt reactor cooling device according to claim 1, wherein: the cable-stayed bracket A (7) and the cable-stayed bracket B (8) are composed of two connecting rods which are crossed together.

5. The support structure of an extra-high voltage shunt reactor cooling device according to claim 1, wherein: the number of the upper collecting pipe hanging rings (9) on the upper collecting pipe (1) in each group of the powder pieces (3) is two.