CN219205047U - Reactive compensation generator convenient to heat dissipation - Google Patents

Abstract

The utility model relates to the technical field of reactive compensation generators, and discloses a reactive compensation generator convenient for heat dissipation, which comprises a packaging box, wherein a plurality of separation mechanisms are clamped in the packaging box in a sliding way through a sliding groove and a clamping assembly, an integrated mounting plate is embedded in the back of the packaging box, a plurality of rubber plates are movably mounted in the integrated mounting plate, the rubber plates are mutually overlapped in a head-to-tail way, and the front projection area of the rubber plates is the same as the front projection area of an inner cavity of the integrated mounting plate. According to the utility model, the inside of the packaging box is divided into the spaces with independent heat by the plurality of separation mechanisms, so that the heat generated by each part of parts flows in the inside of the packaging box to prolong the retention time of the heat in the inside of the equipment, and meanwhile, the influence on the parts in different areas caused by the flow of the heat in the whole inside of the packaging box is avoided, thereby reducing the probability of thermal damage of the high Wen Duiling parts.

Description

Reactive compensation generator convenient to heat dissipation

Technical Field

The utility model relates to the technical field of reactive compensation generators, in particular to a reactive compensation generator convenient for heat dissipation.

Background

At present, the reactive compensation generator is often installed in a large-scale power grid to stabilize a circuit, improve the power factor of the power grid, improve the utilization rate of electric energy sources, reduce reactive power transmission, save energy and reduce consumption, improve voltage quality and the like, so that when the reactive compensation generator works, a lot of heat is usually generated, but not all parts in the reactive compensation generator can generate a lot of heat when in operation, but the inside of the reactive compensation generator used in the prior art is an integral body, the heat generated by any part can be gathered in the equipment and influence all parts, and meanwhile, the larger space increases the time for retaining the heat in the equipment, so that the heat damage of the parts is further increased, and the reactive compensation generator needs to be improved.

Moreover, the reactive compensation generator used in the prior art can only naturally dissipate heat through the fixed heat dissipation window, the heat dissipation efficiency is extremely limited, the heat generated by the reactive compensation generator running at high power cannot be adapted for a long time, and the heat damage of parts is caused by the fact that a large amount of heat is reserved in the reactive compensation generator, so that the reactive compensation generator needs to be improved.

Disclosure of Invention

In order to overcome the defects of the prior art, the utility model provides the reactive compensation generator which is convenient for heat dissipation and has the advantages of low heat loss rate and convenient regulation and control.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a reactive compensation generator convenient to heat dissipation, includes the encapsulation case, the inside of encapsulation case has a plurality of separating mechanism through spout and joint subassembly joint that slides, the back embedding of encapsulation case has integrated mounting panel, the inside movable mounting of integrated mounting panel has a plurality of rubber plates, a plurality of the overlap joint each other of rubber plate head and tail, a plurality of rubber plate front projection area is the same with integrated mounting panel inner chamber's front projection area, the mounting groove one that is located the rubber plate below has been seted up in integrated mounting panel's front, the inside movable mounting of mounting groove one has a plurality of movable sliding frame, a plurality of movable sliding frame and a plurality of rubber plate one-to-one and through the movable minor axis fixed connection of cup jointing in integrated mounting panel inside.

As a preferable technical scheme of the utility model, the separation mechanism comprises a separation plate arranged in the packaging box, an upper communication groove and a lower communication groove are formed in the side face of the separation plate, an upper elastic blocking piece and a lower elastic blocking piece are fixedly arranged in the communication groove, and the opposite faces of the two elastic blocking pieces are mutually attached.

As a preferred technical scheme of the utility model, the clamping assembly comprises a front reset groove and a rear reset groove which are arranged at the bottom of the partition plate, the top of the inner cavity of the reset groove is fixedly provided with a plug-in block, the bottom of the inner cavity of the reset groove is movably provided with a sliding clamping block, the sliding clamping block is in sliding clamping connection with the inside of the chute, the bottom of the plug-in block is movably embedded with a front reset spring and a rear reset spring, the lower end of the reset spring is connected with the sliding clamping block, the inside of the reset groove is provided with two plug boards positioned at the left side and the right side of the plug-in block, the bottom of the plug board is fixedly connected with the sliding clamping block, the left side and the right side of the plug-in block are respectively provided with a limit groove, and a limit block is in sliding clamping connection with the inside of the limit groove and is fixedly connected with the plug boards.

As a preferable technical scheme of the utility model, two sliding grooves positioned in front of the movable sliding frame and at the top and the bottom of the first mounting groove are formed in the integrated mounting plate, the two sliding grooves are mutually communicated with the first mounting groove, the two sliding grooves and a part of the space communicated with the first mounting groove are in sliding clamping connection with the sliding frame, and the inner sliding of the sliding frame is in sliding clamping connection with a poking block.

As a preferable technical scheme of the utility model, the front surface of the stirring block is provided with a left stirring groove and a right stirring groove, the back surface of the stirring block is provided with a meshing rack, the meshing rack is meshed with the movable sliding frame, and the top and the bottom of the stirring block are fixedly connected with a connecting block.

As a preferable technical scheme of the utility model, an upper mounting groove II and a lower mounting groove II are formed in the sliding frame, the connecting block is in sliding clamping connection with the inside of the mounting groove II, and a positioning spring positioned on one side, far away from the movable sliding frame, of the surface of the connecting block is arranged in the mounting groove II.

Compared with the prior art, the utility model has the following beneficial effects:

1. according to the utility model, the inside of the packaging box is divided into the spaces with independent heat by the plurality of separation mechanisms, so that the heat generated by each part of parts flows in the inside of the packaging box to prolong the retention time of the heat in the inside of the equipment, and meanwhile, the influence on the parts in different areas caused by the flow of the heat in the whole inside of the packaging box is avoided, thereby reducing the probability of thermal damage of the high Wen Duiling parts.

2. According to the utility model, the adjustable ventilation system can be conveniently formed on the back of the whole packaging box through the rubber plate, so that the requirements of different areas in the packaging box on heat dissipation efficiency can be met, an operator can conveniently drive the rubber plate to turn over under the cooperation of the meshing rack and the movable sliding frame through the shifting block, and the operator can conveniently move the shifting block back and forth through the sliding frame, so that the effect of discontinuously turning over a plurality of rubber plates is achieved, and the sealing box is suitable for the discontinuity of heat dissipation space in the packaging box.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

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

FIG. 3 is a schematic view illustrating the disassembly of the clamping assembly of the separation mechanism;

FIG. 4 is a schematic view of the internal structure of the integrated mounting plate of the present utility model;

FIG. 5 is a side cross-sectional view of a portion of a toggle block of the present utility model;

fig. 6 is a schematic diagram illustrating the disassembly of the sliding frame and the toggle block according to the present utility model.

In the figure: 1. packaging the box; 2. a chute; 3. a partition mechanism; 31. a partition plate; 32. a communication groove; 33. an elastic blocking piece; 4. a clamping assembly; 41. a reset groove; 42. a sliding clamping block; 43. a return spring; 44. a plug block; 45. a plug board; 46. a limit groove; 47. a limiting block; 5. an integrated mounting plate; 6. a rubber plate; 7. a first mounting groove; 8. a movable sliding frame; 9. a slip groove; 10. a sliding frame; 11. a poking block; 12. a toggle groove; 13. a meshing rack; 14. a second mounting groove; 15. a connecting block; 16. and positioning a spring.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1 to 6, the reactive compensation generator convenient for heat dissipation provided by the utility model comprises a packaging box 1, wherein a plurality of separation mechanisms 3 are slidably clamped in the packaging box 1 through a sliding chute 2 and a clamping assembly 4, an integrated mounting plate 5 is embedded in the back of the packaging box 1, a plurality of rubber plates 6 are movably mounted in the integrated mounting plate 5, the head and the tail of the plurality of rubber plates 6 are mutually overlapped, the front projection area of the plurality of rubber plates 6 is the same as the front projection area of the inner cavity of the integrated mounting plate 5, a first mounting groove 7 positioned below the rubber plates 6 is formed in the front of the integrated mounting plate 5, a plurality of movable sliding frames 8 are movably mounted in the first mounting groove 7, and the plurality of movable sliding frames 8 are in one-to-one correspondence with the plurality of rubber plates 6 and are fixedly connected with a short shaft in the integrated mounting plate 5 through movable sleeve joints;

the inside of the packaging box 1 is divided into heat independent spaces through the plurality of separation mechanisms 3, so that heat generated by each part of parts flows in the packaging box 1 to prolong the retention time of the heat in the equipment, and meanwhile, the influence on the parts in different areas caused by the flow of the heat in the whole packaging box 1 is avoided, and the probability of thermal damage to the high Wen Duiling parts is reduced; by means of the rubber sheet 6, an adjustable ventilation system can be formed on the back of the whole packaging box 1, so as to meet the requirements of different areas inside the packaging box 1 on heat dissipation efficiency.

Wherein, the separation mechanism 3 comprises a separation plate 31 arranged in the packaging box 1, an upper communication groove 32 and a lower communication groove 32 are arranged on the side surface of the separation plate 31, an upper elastic blocking piece 33 and a lower elastic blocking piece 33 are fixedly arranged in the communication groove 32, and opposite surfaces of the two elastic blocking pieces 33 are mutually attached;

the inside of the packaging box 1 can be divided into independent spaces through the partition plates 31, heat flowing in different spaces inside the packaging box 1 is avoided, heat retention time is prolonged, operators are convenient to connect parts in adjacent independent spaces through wires and the like due to the arrangement of the communication grooves 32, wires and the like can be ensured to penetrate through the communication grooves 32 through the arrangement of the elastic sealing sheets 33, ventilation capacity of the communication grooves 32 is reduced as much as possible, and heat channeling is avoided.

The clamping assembly 4 comprises a front reset groove 41 and a rear reset groove 41 which are formed in the bottom of the partition plate 31, an inserting block 44 is fixedly arranged at the top of the inner cavity of the reset groove 41, a sliding clamping block 42 is movably arranged at the bottom of the inner cavity of the reset groove 41, the sliding clamping block 42 is in sliding clamping connection with the inside of the chute 2, the bottom of the inserting block 44 is movably embedded with a front reset spring 43 and a rear reset spring 43, the lower end of the reset spring 43 is connected with the sliding clamping block 42, two inserting plates 45 positioned on the left side and the right side of the inserting block 44 are arranged in the reset groove 41, the bottom of the inserting plate 45 is fixedly connected with the sliding clamping block 42, limit grooves 46 are formed in the left side and the right side of the inserting block 44, limit blocks 47 are in sliding clamping connection with the inside of the limit grooves 46, and the limit blocks 47 are fixedly connected with the inserting plates 45;

under the cooperation of the plug-in block 44, the plug-in plate 45, the limit groove 46 and the limit block 47, the sliding clamping block 42 can move upwards along the inside of the reset groove 41, and then the sliding clamping block 42 can slide and be clamped in the inside of the chute 2 under the action of the elastic force of the reset spring 43, so that the effect of stabilizing the inner space of the sealing box 1 separated by the separation mechanism 3 is achieved.

Wherein, two sliding grooves 9 positioned in front of the movable sliding frame 8 and at the top and the bottom of the first installation groove 7 are formed in the integrated installation plate 5, the two sliding grooves 9 are mutually communicated with the first installation groove 7, the two sliding grooves 9 and a part of the space communicated with the first installation groove 7 are in sliding clamping connection with a sliding frame 10, and a poking block 11 is in sliding clamping connection with the inside of the sliding frame 10;

the rubber plate 6 can be conveniently driven to turn over by an operator through the stirring block 11 under the cooperation of the meshing rack 13 and the movable sliding frame 8, and the stirring block 11 can be conveniently moved back and forth by the sliding frame 10 so as to achieve the effect of discontinuously turning over a plurality of rubber plates 6, so that the rubber plate is suitable for the discontinuity of the heat dissipation space required inside the packaging box 1.

The front surface of the poking block 11 is provided with a left poking groove 12 and a right poking groove 12, the back surface of the poking block 11 is provided with a meshing rack 13, the meshing rack 13 is meshed with the movable sliding frame 8, and the top and the bottom of the poking block 11 are fixedly connected with a connecting block 15;

due to the arrangement of the connecting blocks 15, an operator is ensured to pull the poking block 11 through the poking groove 12, so that the meshing rack 13 is separated from the meshing with the corresponding part of the movable sliding frame 8, and then the positioning spring 16 can be compressed through the connecting blocks 15, and the elastic recovery performance of the positioning spring is enhanced, so that the poking block 11 is driven to integrally reset at any time, and the meshing rack 13 can be meshed with the movable sliding frame 8 again.

The sliding frame 10 is internally provided with an upper mounting groove II and a lower mounting groove II, the connecting block 15 is in sliding clamping connection with the inside of the mounting groove II 14, and the inside of the mounting groove II 14 is provided with a positioning spring 16 positioned on one side, far away from the movable sliding frame 8, of the surface of the connecting block 15;

the toggle block 11 can drive the meshing rack 13 to move under the limit of the sliding groove 9 and the sliding frame 10 under the elastic restoring action of the positioning spring 16, so that the meshing rack 13 always has a trend of moving towards the movable sliding frame 8, and the meshing rack 13 can be always meshed with the movable sliding frame 8.

The working principle and the using flow of the utility model are as follows:

the inside of the packaging box 1 is divided into heat independent spaces through the plurality of separation mechanisms 3 according to the requirement of installing parts in the reactive compensation generator, then whether the rubber plate 6 of the corresponding part is opened or not is determined according to whether the heat is generated when the parts installed in each independent area are operated, the heat generated in each independent space can be directly discharged through the rubber plate 6 of the corresponding part, and the sealing space is formed inside the heat-free part because the rubber plate 6 of the corresponding part is not opened when the heat-free part is operated, so that dust interference is avoided.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. Reactive compensation generator convenient to heat dissipation, including encapsulation case (1), its characterized in that: the inside of encapsulation case (1) has a plurality of separating mechanism (3) through spout (2) and joint subassembly (4) joint that slides, the back embedding of encapsulation case (1) has integrated mounting panel (5), the inside movable mounting of integrated mounting panel (5) has a plurality of rubber slab (6), a plurality of rubber slab (6) overlap joint each other end to end, a plurality of rubber slab (6) front projection area is the same with the front projection area of integrated mounting panel (5) inner chamber, mounting groove one (7) that are located rubber slab (6) below have been seted up on the front of integrated mounting panel (5), the inside movable mounting of mounting groove one (7) has a plurality of movable sliding frame (8), a plurality of movable sliding frame (8) with a plurality of rubber slab (6) one-to-one and through the movable sleeve joint in the inside minor axis fixed connection of integrated mounting panel (5).

2. A heat dissipation facilitating reactive power compensation generator as defined in claim 1, wherein: the separation mechanism (3) comprises a separation plate (31) arranged in the packaging box (1), an upper communication groove (32) and a lower communication groove (32) are formed in the side face of the separation plate (31), an upper elastic blocking piece (33) and a lower elastic blocking piece (33) are fixedly arranged in the communication groove (32), and the opposite faces of the two elastic blocking pieces (33) are mutually attached.

3. A heat dissipation facilitating reactive power compensation generator as defined in claim 2, wherein: the utility model provides a joint subassembly (4) is including seting up in two front and back reset groove (41) of division board (31) bottom, the top fixed mounting in reset groove (41) inner chamber has joint piece (44), the bottom movable mounting in reset groove (41) inner chamber has joint piece (42) that slides, joint piece (42) that slides the joint in the inside of spout (2), two reset spring (43) around the bottom activity embedding of joint piece (44), the lower extreme of reset spring (43) is connected with joint piece (42) that slides, the inside of reset groove (41) is provided with two plugboards (45) that are located joint piece (44) left and right sides, the bottom and joint piece (42) fixed connection that slides of plugboard (45), limiting groove (46) are all seted up on the left and right sides of joint piece (44), the inside joint that slides of limiting groove (46) has stopper (47), stopper (47) and plugboard (45) fixed connection.

4. A heat dissipation facilitating reactive power compensation generator as defined in claim 1, wherein: the integrated mounting board (5) is internally provided with two sliding grooves (9) positioned in front of a movable sliding frame (8) and at the top and the bottom of a first mounting groove (7), the two sliding grooves (9) are mutually communicated with the first mounting groove (7), the two sliding grooves (9) are communicated with a sliding frame (10) in a sliding mode in part of space of the first mounting groove (7), and a poking block (11) is connected in a sliding mode in the sliding frame (10).

5. The reactive compensation generator of claim 4, wherein the reactive compensation generator is configured to facilitate heat dissipation, and wherein: the right side and the left side of the stirring block (11) are provided with a left stirring groove (12), the back of the stirring block (11) is provided with a meshing rack (13), the meshing rack (13) is meshed with the movable sliding frame (8), and the top and the bottom of the stirring block (11) are fixedly connected with a connecting block (15).

6. The reactive compensation generator of claim 5, wherein the reactive compensation generator is configured to facilitate heat dissipation, and wherein: the inside of sliding frame (10) has seted up two mounting groove two (14) from top to bottom, connecting block (15) slip joint in the inside of mounting groove two (14), the inside of mounting groove two (14) is provided with positioning spring (16) that are located connecting block (15) surface and keep away from movable sliding frame (8) one side.

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