CN212163181U - High-power high-pressure cascade type energy storage converter is with mounting structure convenient to adjust - Google Patents

Abstract

The utility model discloses a high-power high-pressure cascade type energy storage converter is with mounting structure convenient to adjust, including main part and track, the main part bottom is fixed with the backup pad, wherein, backup pad one side is fixed with the supporting shoe, first rotary trough has been seted up to the supporting shoe bottom, the inside gomphosis of first rotary trough has the spin ball. This high-power high pressure cascade type energy storage converter is with mounting structure convenient to adjust is provided with the threaded rod and can rotates through rotating the turning block to the threaded rod can drive the sliding plate when rotatory and carry out the screw thread slip, the sliding plate can slide with the guide bar when screw thread slip, the sliding plate can drive the movable block and slide with the shifting chute when screw thread slip, the movable block can drive the track when sliding, the fixed block carries out the back-and-forth movement with the main part, can also promote the main part and can drive the fixed block and remove, can carry out the horizontal slip through pulley and track when the fixed block removes, make things convenient for the main part to adjust mounted position in the.

Description

High-power high-pressure cascade type energy storage converter is with mounting structure convenient to adjust

Technical Field

The utility model relates to an electric power conditioning equipment technical field specifically is a high-power high pressure cascade type energy storage converter is with mounting structure who is convenient for adjust.

Background

The energy storage converter can control the charging and discharging processes of the storage battery, carry out alternating current-direct current conversion, and can directly supply power for alternating current loads under the condition of no power grid. The PCS is composed of a DC/AC bidirectional converter, a control unit and the like. The PCS controller receives a background control instruction through communication, and controls the converter to charge or discharge the battery according to the symbol and the size of the power instruction, so that the active power and the reactive power of the power grid are adjusted. The PCS controller is communicated with the BMS through the CAN interface to acquire the state information of the battery pack, so that the protective charging and discharging of the battery CAN be realized, and the running safety of the battery is ensured.

The mounting structure for the high-power high-voltage cascading energy storage converter on the market at present has many defects, the position is inconvenient to adjust, the main body is inconvenient to support, and the main body is inconvenient to fix, so that a technology capable of improving the mounting structure for the high-power high-voltage cascading energy storage converter, which is convenient to adjust, is urgently needed on the market to perfect the equipment.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a high-power high-pressure cascade energy storage converter is with mounting structure who is convenient for adjust to there are many defects, inconvenient adjusting position, the inconvenient support of main part, the inconvenient fixed problem of main part in the mounting structure for the high-power high-pressure cascade energy storage converter on solving the existing market that above-mentioned background art provided.

In order to achieve the above object, the utility model provides a following technical scheme: a mounting structure convenient to adjust for a high-power high-voltage cascading energy storage converter comprises a main body and a track, wherein a supporting plate is fixed at the bottom of the main body,

a supporting block is fixed on one side of the supporting plate, a first rotating groove is formed in the bottom of the supporting block, a rotating ball is embedded in the first rotating groove, a threaded groove is formed in one side of the first rotating groove, limiting grooves are formed in two sides of the threaded groove, limiting blocks are embedded in the limiting grooves, a connecting block is fixed between the limiting blocks, an extrusion pad is fixed at the bottom of the connecting block, a rotating block is fixed at the top of the connecting block, a bolt is connected in the threaded groove, a second rotating groove is formed in one end of the bolt close to the rotating block, and a fixing block is fixed at the bottom of the main body close to the supporting plate;

the third swivelling chute has been seted up to the fixed block bottom, third swivelling chute internal connection has the rotary rod, rotary rod one side is connected with the pulley, the fixed block bottom is provided with the installation piece, the inside operation groove of having seted up of installation piece, the shifting chute has been seted up at operation groove top, the threaded rod runs through to operation inslot portion, threaded rod one end is fixed with the turning block, is close to the threaded rod operation inslot internal connection has the guide bar, be connected with the sliding plate between guide bar and the threaded rod, be close to the shifting chute sliding plate one side is fixed with the movable block, is close to the pulley the track is fixed in movable block one side.

Preferably, four groups of the first rotating grooves and the rotating balls are arranged, and the arc of the first rotating grooves is matched with the arc of the rotating balls.

Preferably, the limiting grooves and the limiting blocks are provided with four groups, the limiting grooves are in sliding connection with the limiting blocks, and the maximum sliding distance of the limiting blocks is not more than the length of the limiting grooves.

Preferably, the rotating block and the second rotating groove are arranged in two groups, the rotating block and the second rotating groove are in a circular ring shape, the size of the rotating block is matched with that of the second rotating groove, and a rotating structure is formed between the rotating block and the second rotating groove.

Preferably, a rotating structure is formed between the third rotating groove and the pulley through a rotating rod, and the pulley is in sliding connection with the rail.

Preferably, the guide rods and the sliding plates are arranged in two groups, the guide rods are in sliding connection with the sliding plates, and the sliding plates are in threaded connection with the threaded rods.

Compared with the prior art, the beneficial effects of the utility model are that: this high-power high pressure cascade energy storage converter is with mounting structure convenient to adjust:

1. the threaded rod can rotate by rotating the rotating block, so that the threaded rod can drive the sliding plate to perform threaded sliding when rotating, the sliding plate can slide with the guide rod when performing threaded sliding, the sliding plate can drive the moving block to slide with the moving groove when performing threaded sliding, the moving block can drive the track, the fixed block and the main body to move back and forth when sliding, the main body can be pushed to drive the fixed block to move, the fixed block can slide left and right through the pulley and the track when moving, and the main body can be conveniently adjusted in installation position;

2. the supporting plate can be driven to move when the main body is pushed to move, so that the supporting plate can be driven to move when the supporting plate moves, the first rotating groove can be driven to move when the supporting plate moves, the rotating ball can be driven to slide with the ground when the first rotating groove moves, and the rotating ball can rotate with the first rotating groove when the rotating ball slides with the ground, so that the main body can be supported at an adjusting position conveniently;

3. when the main part moves to the assigned position, the bolt can be rotated to perform thread sliding with the thread groove, so that the bolt can be driven to rotate in the thread sliding process, the second rotating groove can rotate with the rotating block when rotating, the second rotating groove can push the connecting block to move when rotating with the rotating block, the connecting block can be driven to slide with the limiting groove when moving, the extruding pad can be pushed to move when moving, the rotating ball can be extruded when moving, the friction force between the rotating ball and the extruding pad can be increased when extruding, and the main part can be fixed after moving to the assigned position conveniently.

Drawings

FIG. 1 is a front view of the cross-sectional structure of the present invention;

FIG. 2 is a schematic side view of the cross-sectional structure of the present invention;

FIG. 3 is an enlarged schematic view of part A of the present invention;

fig. 4 is an enlarged schematic view of the part B of the present invention.

In the figure: 1. a main body; 2. a support plate; 3. a support block; 4. a first rotary tank; 5. rotating the ball; 6. a thread groove; 7. a limiting groove; 8. a limiting block; 9. connecting blocks; 10. pressing the cushion; 11. rotating the block; 12. a bolt; 13. a second rotary tank; 14. a fixed block; 15. a third rotary tank; 16. rotating the rod; 17. a pulley; 18. mounting blocks; 19. an operation slot; 20. a moving groove; 21. a threaded rod; 22. rotating the block; 23. a guide bar; 24. a sliding plate; 25. a moving block; 26. a track.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a mounting structure convenient to adjust for a high-power high-voltage cascading energy storage converter comprises a main body 1, a support plate 2, a support block 3, a first rotating groove 4, a rotating ball 5, a thread groove 6, a limiting groove 7, a limiting block 8, a connecting block 9, a squeezing pad 10, a rotating block 11, a bolt 12, a second rotating groove 13, a fixed block 14, a third rotating groove 15, a rotating rod 16, a pulley 17, a mounting block 18, an operating groove 19, a moving groove 20, a threaded rod 21, a rotating block 22, a guide rod 23, a sliding plate 24, a moving block 25 and a track 26, wherein the support plate 2 is fixed at the bottom of the main body 1,

a supporting block 3 is fixed on one side of the supporting plate 2, a first rotating groove 4 is formed in the bottom of the supporting block 3, four groups of first rotating grooves 4 and rotating balls 5 are arranged, the arc shape of each first rotating groove 4 is matched with the arc shape of each rotating ball 5, the supporting block 3 can drive the first rotating grooves 4 to move when moving, the rotating balls 5 can be driven to slide with the ground when moving the first rotating grooves 4, the rotating balls 5 can rotate with the first rotating grooves 4 when sliding with the ground, the rotating balls 5 are embedded in the first rotating grooves 4, a thread groove 6 is formed in one side of each first rotating groove 4, limiting grooves 7 are formed in two sides of each thread groove 6, four groups of limiting grooves 7 and limiting blocks 8 are arranged, the limiting grooves 7 are in sliding connection with the limiting blocks 8, and the maximum sliding distance of the limiting blocks 8 is not more than the length of the limiting grooves 7, the connecting block 9 can drive the limiting block 8 to move when moving, the limiting block 8 can slide with the limiting groove 7 when moving, the limiting block 8 is embedded in the limiting groove 7, the connecting block 9 is fixed between the limiting blocks 8, the bottom of the connecting block 9 is fixed with the extrusion pad 10, the top of the connecting block 9 is fixed with the rotating block 11, two groups of rotating blocks 11 and second rotating grooves 13 are arranged, the rotating blocks 11 and the second rotating grooves 13 are in a circular ring shape, the size of the rotating blocks 11 is identical to that of the second rotating grooves 13, a rotating structure is formed between the rotating blocks 11 and the second rotating grooves 13, the bolts 12 can drive the second rotating grooves 13 to rotate when sliding in threads, the second rotating grooves 13 can rotate with the rotating blocks 11 when rotating, the second rotating grooves 13 and the rotating blocks 11 can push the connecting block 9 to move when rotating, a bolt 12 is connected inside the thread groove 6, a second rotating groove 13 is formed at one end of the bolt 12 close to the rotating block 11, and a fixed block 14 is fixed at the bottom of the main body 1 close to the support plate 2;

a third rotating groove 15 is formed at the bottom of the fixed block 14, a rotating structure is formed between the third rotating groove 15 and the pulley 17 through a rotating rod 16, the pulley 17 is connected with the track 26 in a sliding manner, the main body 1 is pushed to drive the fixed block 14 to move, the fixed block 14 can drive the third rotating groove 15 to move when moving, the third rotating groove 15 can drive the rotating rod 16 to move when moving, the rotating rod 16 can drive the pulley 17 to rotate when moving, the pulley 17 can slide with the track 26 when rotating, the rotating rod 16 is connected inside the third rotating groove 15, one side of the rotating rod 16 is connected with the pulley 17, an installation block 18 is arranged at the bottom of the fixed block 14, an operation groove 19 is formed inside the installation block 18, a moving groove 20 is formed at the top of the operation groove 19, a threaded rod 21 penetrates through the inside the operation groove 19, and a rotating block 22 is fixed at one end of the threaded, the guide rod 23 is connected to the inner portion of the operation groove 19 close to the threaded rod 21, two sets of guide rods 23 are arranged on the guide rods 23 and the sliding plate 24, the guide rods 23 are connected with the sliding plate 24 in a sliding mode, the sliding plate 24 is connected with the threaded rod 21 in a threaded mode, the threaded rod 21 can be driven to rotate by rotating the rotating block 22, the sliding plate 24 can be driven to slide in a threaded mode when the threaded rod 21 rotates, the sliding plate 24 can slide with the guide rods 23 when sliding in a threaded mode, the sliding plate 24 can drive the moving block 25 to move while sliding in a threaded mode, the sliding plate 24 is connected between the guide rods 23 and the threaded rod 21, the moving block 25 is fixed to one side of the sliding plate 24 close to the moving groove 20, and.

The working principle is as follows: when the installation structure convenient to adjust for the high-power high-voltage cascading energy storage converter is used, firstly, the installation structure convenient to adjust for the high-power high-voltage cascading energy storage converter needs to be simply known, when the installation structure is used, the rotating block 22 can be rotated to drive the threaded rod 21 to rotate, the threaded rod 21 can be rotated to drive the sliding plate 24 to perform threaded sliding, the sliding plate 24 can slide with the guide rod 23 when performing threaded sliding, the sliding plate 24 can drive the moving block 25 to slide with the moving groove 20 when performing threaded sliding, the moving block 25 can drive the track 26, the fixed block 14 and the main body 1 to perform front-back movement when sliding, the fixed block 14 can be driven to move by pushing the main body 1, the fixed block 14 can slide left and right with the track 26 when moving, and the supporting plate 2 can be driven to move when the, the supporting plate 2 can drive the supporting block 3 to move when moving, the supporting block 3 can drive the first rotary groove 4 to move when moving, the first rotary groove 4 can drive the rotary ball 5 to slide with the ground when moving, the bolt 12 can be rotated to perform threaded sliding with the threaded groove 6 when the main body 1 moves to a designated position, the bolt 12 can drive the second rotary groove 13 to rotate when performing threaded sliding, the second rotary groove 13 can rotate with the rotary block 11 when rotating, the second rotary groove 13 can drive the connecting block 9 to move when rotating with the rotary block 11, the connecting block 9 can drive the limiting block 8 to slide with the limiting groove 7 when moving, the extruding pad 10 can be driven to move when moving the connecting block 9, the rotary ball 5 can be extruded when moving the extruding pad 10, the rotary ball 5 can increase the friction force with the extruding pad 10 when being extruded, the main body 1 may be fixed after moving to a designated position, and the contents not described in detail in this specification belong to the prior art well known to those skilled in the art.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (6)

1. A high-power high pressure cascade energy storage converter is with mounting structure convenient to adjust, includes main part (1) and track (26), its characterized in that: a supporting plate (2) is fixed at the bottom of the main body (1), wherein,

a supporting block (3) is fixed on one side of the supporting plate (2), a first rotating groove (4) is formed at the bottom of the supporting block (3), a rotating ball (5) is embedded in the first rotating groove (4), a thread groove (6) is formed in one side of the first rotating groove (4), limiting grooves (7) are formed in two sides of the thread groove (6), a limiting block (8) is embedded in each limiting groove (7), connecting blocks (9) are fixed between the limiting blocks (8), a squeezing pad (10) is fixed at the bottom of each connecting block (9), a rotating block (11) is fixed at the top of the connecting block (9), a bolt (12) is connected inside the thread groove (6), a second rotating groove (13) is formed in one end of the bolt (12) close to the rotating block (11), and a fixed block (14) is fixed at the bottom of the main body (1) close to the supporting plate (2);

a third rotating groove (15) is formed in the bottom of the fixed block (14), a rotating rod (16) is connected inside the third rotating groove (15), one side of the rotating rod (16) is connected with a pulley (17), the bottom of the fixed block (14) is provided with a mounting block (18), an operation groove (19) is arranged in the mounting block (18), a moving groove (20) is arranged at the top of the operation groove (19), a threaded rod (21) penetrates through the interior of the operating groove (19), a rotating block (22) is fixed at one end of the threaded rod (21), a guide rod (23) is connected inside the operating groove (19) close to the threaded rod (21), a sliding plate (24) is connected between the guide rod (23) and the threaded rod (21), a moving block (25) is fixed on one side of the sliding plate (24) close to the moving groove (20), and a track (26) close to the pulley (17) is fixed on one side of the moving block (25).

2. The mounting structure for the high-power high-voltage cascaded energy storage converter convenient to adjust as claimed in claim 1, wherein: four groups of first rotating grooves (4) and rotating balls (5) are arranged, and the arc of the first rotating grooves (4) is matched with the arc of the rotating balls (5).

3. The mounting structure for the high-power high-voltage cascaded energy storage converter convenient to adjust as claimed in claim 1, wherein: the limiting groove (7) and the limiting block (8) are provided with four groups, the limiting groove (7) is in sliding connection with the limiting block (8), and the maximum sliding distance of the limiting block (8) does not exceed the length of the limiting groove (7).

4. The mounting structure for the high-power high-voltage cascaded energy storage converter convenient to adjust as claimed in claim 1, wherein: the rotary block (11) and the second rotary groove (13) are arranged in two groups, the rotary block (11) and the second rotary groove (13) are in the shape of a circular ring, the size of the rotary block (11) is matched with that of the second rotary groove (13), and a rotary structure is formed between the rotary block (11) and the second rotary groove (13).

5. The mounting structure for the high-power high-voltage cascaded energy storage converter convenient to adjust as claimed in claim 1, wherein: a rotating structure is formed between the third rotating groove (15) and the pulley (17) through a rotating rod (16), and the pulley (17) is in sliding connection with the track (26).

6. The mounting structure for the high-power high-voltage cascaded energy storage converter convenient to adjust as claimed in claim 1, wherein: the guide rods (23) and the sliding plates (24) are arranged in two groups, the guide rods (23) and the sliding plates (24) are in sliding connection, and the sliding plates (24) and the threaded rods (21) are in threaded connection.

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