CN221185400U - Liquid cooling energy storage cabinet removes frock - Google Patents

Abstract

The application discloses a liquid cooling energy storage cabinet moving tool, which relates to the technical field of liquid cooling energy storage cabinet moving tools and comprises a tool body, wherein the tool body is connected with a carrier plate in a sliding manner, the tool body is connected with a driving assembly for driving the carrier plate to slide in the vertical direction, the carrier plate is connected with a push rod for abutting against an energy storage cabinet in a sliding manner, and the carrier plate is connected with a pushing assembly for driving the push rod to slide in the direction approaching to or far from the energy storage cabinet. According to the application, the driving assembly drives the carrier plate to slide in the vertical direction, namely the energy storage cabinet slides in the vertical direction, so that the corresponding positions of the energy storage cabinet and the energy storage box are aligned. The pushing component drives the push rod to slide towards the direction close to the energy storage box, the push rod is abutted with the energy storage cabinet and drives the energy storage cabinet to slide towards the direction close to the energy storage box, so that the energy storage cabinet is pushed into the corresponding position of the energy storage box, and the moving efficiency of the energy storage cabinet is improved.

Description

Liquid cooling energy storage cabinet removes frock

Technical Field

The application relates to the technical field of liquid cooling energy storage cabinet moving tools, in particular to a liquid cooling energy storage cabinet moving tool.

Background

A liquid energy storage cabinet is an energy storage system that stores and releases energy through a liquid medium. It is an emerging energy storage technology that can provide an effective solution in large-scale energy storage and scheduling.

As shown in fig. 1, positioning grooves 101 are formed on two opposite sides of the energy storage cabinet 10.

The energy storage boxes are assembled by stacking the energy storage cabinets from top to bottom, the energy storage cabinets are placed on the lifting mechanism, the energy storage cabinets are lifted to corresponding heights by the lifting mechanism, and then the energy storage cabinets are pushed into the energy storage boxes. At present, the worker manually pushes the energy storage cabinet into the energy storage box, and the moving efficiency is influenced due to the large volume of the energy storage cabinet, so that the improvement is needed.

Disclosure of utility model

The application aims to provide a liquid cooling energy storage cabinet moving tool, which aims to improve the moving efficiency of an energy storage cabinet body.

The application provides a liquid cooling energy storage cabinet moving tool which adopts the following technical scheme: including the frock body, the frock body slides and is connected with the support plate, the frock body is connected with and is used for the drive assembly that the vertical direction of support plate slided, the support plate slides and is connected with the push rod that is used for with the energy storage cabinet butt, the support plate is connected with and is used for the drive the push rod is towards the promotion subassembly that is close to or keeps away from the direction slip of energy storage case.

Through adopting above-mentioned technical scheme, external equipment places the energy storage cabinet on the support plate, and the energy storage cabinet of this moment is located between push rod and the energy storage cabinet, and the slip of the vertical direction of drive assembly drive support plate, the energy storage cabinet carries out the slip of vertical direction promptly for the energy storage cabinet aligns with the corresponding position of energy storage cabinet. The pushing component drives the push rod to slide towards the direction close to the energy storage box, the push rod is abutted with the energy storage cabinet and drives the energy storage cabinet to slide towards the direction close to the energy storage box, so that the energy storage cabinet is pushed into the corresponding position of the energy storage box, and the moving efficiency of the energy storage cabinet is improved.

Optionally, the support plate rotates and is connected with a plurality of ball that is used for with the butt of energy storage cabinet.

Through adopting above-mentioned technical scheme, when the energy storage cabinet removed, energy storage cabinet and ball activity butt, the energy storage cabinet drove the ball and rotates, compare in energy storage cabinet direct with support plate activity butt, energy storage cabinet and ball activity butt reduce area of contact, reduce frictional force for the energy that needs to consume when the energy storage cabinet removed is less, and the push rod of being convenient for drives the energy storage cabinet and removes, thereby improves the efficiency that the energy storage cabinet removed.

Optionally, the support plate is provided with and is used for with ball normal running fit holds the chamber, the support plate is connected with and is used for covering hold the limiting plate in chamber, the limiting plate is provided with supplies the convex spacing hole of ball.

Through adopting above-mentioned technical scheme, the ball is holding the chamber and is rotating, and the limiting plate prevents that the ball from breaking away from holding the chamber at pivoted in-process, improves ball pivoted stability.

Optionally, the inner wall of holding the chamber is connected with a plurality of protruding that is circular arc.

Through adopting above-mentioned technical scheme, compare in the ball direct with hold the inner wall activity butt in chamber, ball and protruding activity butt reduce area of contact, reduce frictional force for the energy that needs to consume when the ball rotates is less, the ball of being convenient for takes place to rotate.

Optionally, the limiting plate is connected with the carrier plate through a locking piece.

Through adopting above-mentioned technical scheme, when the ball takes place to damage because of wearing and tearing, unclamp the retaining member, alright take out the ball from holding the intracavity, place new ball in holding the chamber, the limiting plate covers and carries out the ball, the rethread retaining member makes the limiting plate be connected with the carrier plate, improves the efficiency that the ball was changed.

Optionally, a cushion pad is connected to the outer peripheral surface of the push rod.

Through adopting above-mentioned technical scheme, the blotter is used for preventing push rod and the direct butt of energy storage cabinet, and the blotter can absorb and disperse energy when the energy storage cabinet receives the impact, alleviates the impact of push rod to the energy storage cabinet, also reduces the frictional force of the surface of energy storage cabinet, plays the effect of protection to the energy storage cabinet.

Optionally, the pushing component comprises a rack fixedly connected to the carrier plate and a rotating gear fixedly connected to the push rod, the rack is meshed with the rotating gear, the carrier plate is slidingly connected with a connecting plate, and the connecting plate is connected with a first driving piece for driving the push rod to rotate.

Through adopting above-mentioned technical scheme, when needs push rod removes, open first driving piece, first driving piece drive push rod rotates around self axial lead, and the rotation gear rotates around the axial lead of push rod promptly, because rotation gear and rack meshing. Because the rack is motionless, the rotation gear moves along the length direction of the rack, namely, the connecting plate and the push rod slide along the length direction of the rack, so that the movement of the energy storage cabinet is realized.

Optionally, the carrier plate is provided with a guide groove for sliding fit with the push rod.

Through adopting above-mentioned technical scheme, when the push rod slides, the push rod slides along the guide way, and the cooperation of sliding of push rod and guide way plays direction and spacing effect to the sliding of push rod to improve the stability that the push rod slided.

Optionally, the carrier plate is connected with the locating lever in a sliding way, and the carrier plate is provided with a through hole for the locating lever to pass through.

Through adopting above-mentioned technical scheme, when the energy storage cabinet moved to the one end that is close to the energy storage case, the constant head tank and the locating lever alignment of energy storage cabinet, with the locating lever card into the constant head tank to restrict the removal of energy storage cabinet, improve the stability that the energy storage cabinet was placed. When the energy storage cabinet deviates from the corresponding area of the energy storage box, the driving assembly adjusts the height of the energy storage cabinet, and the positioning rod is used for preventing the situation that the energy storage cabinet is separated from the carrier plate in the height adjusting process.

Optionally, the drive assembly is including rotating the initiative helical gear and the driven helical gear of connecting on the frock body, initiative helical gear with driven helical gear meshing, driven helical gear fixedly connected with lead screw, the support plate be provided with be used for with lead screw thread fit's screw hole, the frock body is connected with and is used for the drive initiative helical gear pivoted second driving piece.

Through adopting above-mentioned technical scheme, when needing the vertical direction of support plate to slide, open the second driving piece, the second driving piece drive initiative helical gear rotates round self axial lead, because initiative helical gear and driven helical gear meshing, initiative helical gear drives driven helical gear rotation at pivoted in-process, and the lead screw rotates round self axial lead promptly, because support plate and lead screw thread fit to realize the vertical direction of support plate's slip, be convenient for adjust the height position of energy storage cabinet.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the driving component drives the carrier plate to slide in the vertical direction, namely the energy storage cabinet slides in the vertical direction, so that the corresponding positions of the energy storage cabinet and the energy storage box are aligned. The pushing component drives the push rod to slide towards the direction close to the energy storage box, the push rod is abutted with the energy storage cabinet and drives the energy storage cabinet to slide towards the direction close to the energy storage box, so that the energy storage cabinet is pushed into the corresponding position of the energy storage box, and the moving efficiency of the energy storage cabinet is improved.

Drawings

Fig. 1 is a schematic diagram of the overall structure of an energy storage cabinet.

Fig. 2 is a schematic overall structure of an embodiment of the present application.

Fig. 3 is a cross-sectional view of an embodiment of the application and an energy storage cabinet.

Fig. 4 is a schematic view of a part of the structure of an embodiment of the present application.

FIG. 5 is one of the cross-sectional views of FIG. 4, showing the cushion pad.

Fig. 6 is an enlarged view of area a of fig. 5.

FIG. 7 is a second cross-sectional view of FIG. 4 showing the sliding chamber.

Fig. 8 is a third cross-sectional view of fig. 4, showing the spacing cavity.

Reference numerals illustrate: 1. a tool body; 2. a carrier plate; 21. a threaded hole; 22. a cavity; 23. a through hole; 24. a receiving chamber; 25. a protrusion; 26. a thread groove; 27. a slideway; 28. a chute; 29. a waist-shaped hole; 200. a guide groove; 201. a spacing cavity; 3. a drive assembly; 31. a driving helical gear; 32. a screw rod; 33. driven helical gears; 34. a second driving member; 4. a positioning rod; 5. a ball; 6. a limiting plate; 61. a limiting hole; 62. a mounting hole; 63. a locking member; 7. a push rod; 71. a cushion pad; 72. a turntable; 8. a pushing assembly; 81. rotating the gear; 82. a first driving member; 83. a rack; 84. a connecting plate; 841. a groove; 842. a limiting block; 9. a convex strip; 91. a sliding cavity; 10. an energy storage cabinet; 101. and a positioning groove.

Detailed Description

The present application will be described in further detail with reference to fig. 2 to 8.

The embodiment of the application discloses a liquid cooling energy storage cabinet moving tool.

The combined drawing is shown in fig. 2 and 3, and comprises a tool body 1, wherein the tool body 1 is connected with a carrier plate 2 in a sliding manner, and the tool body 1 is relatively connected with two groups of driving assemblies 3 for driving the carrier plate 2 to slide in the vertical direction. The driving assembly 3 comprises a driving bevel gear 31 and a screw rod 32 which are rotatably connected to the tool body 1, a driven bevel gear 33 is fixedly connected to the outer peripheral surface of the screw rod 32, the driven bevel gear 33 is meshed with the driving bevel gear 31, a threaded hole 21 for being in threaded fit with the screw rod 32 is formed in the concave portion of the carrier plate 2, a second driving part 34 for driving the driving bevel gear 31 to rotate is fixedly connected to the outer surface of the tool body 1, the second driving part 34 is a motor, a controller is externally connected to the second driving part 34, a signal output end of the controller is connected with a signal input end of the second driving part 34, an output end of the second driving part 34 penetrates through the tool body 1, and one side, close to the second driving part 34, of the driving bevel gear 31 is fixedly connected with an output end of the second driving part 34.

As shown in fig. 4, the upper surface of the carrier plate 2 is concavely provided with a cavity 22 for placing the energy storage cabinet 10, the carrier plate 2 is relatively slidably connected with two L-shaped positioning rods 4, the carrier plate 2 is concavely provided with a through hole 23 for the positioning rods 4 to pass through, and the through hole 23 is communicated with the cavity 22. When the energy storage cabinet 10 moves to the corresponding position, one end of the positioning rod 4 can be clamped into the positioning groove 101 of the energy storage cabinet 10.

As shown in fig. 5 and 6, the inner wall of the cavity 22 is rotatably connected with a plurality of balls 5, and when the energy storage cabinet 10 is in the cavity 22, the energy storage cabinet 10 abuts against the balls 5. The inner wall of the cavity 22 is concavely provided with a containing cavity 24 which is used for being in running fit with the ball 5, the containing cavity 24 is arc-shaped, and the containing cavity 24 is communicated with the cavity 22. The inner wall of the accommodating cavity 24 is fixedly connected with five cylindrical protrusions 25 (the number of the protrusions 25 is selected according to actual requirements), and the protrusions 25 are abutted with the balls 5. The carrier plate 2 is detachably connected with a limiting plate 6 for covering the accommodating cavity 24, the limiting plate 6 is cylindrical, and a limiting hole 61 for the protrusion of part of the balls 5 is concavely formed in the center of the limiting plate 6. Each limiting plate 6 is connected with the carrier plate 2 through two locking pieces 63, the locking pieces 63 are bolts, the limiting plate 6 is concavely provided with a mounting hole 62 for the locking pieces 63 to pass through, the carrier plate 2 is concavely provided with a thread groove 26 for being matched with the locking pieces 63 in a threaded mode, and the thread groove 26 is communicated with the cavity 22.

As shown in fig. 5 and 6, the carrier plate 2 is slidably connected with a push rod 7 for abutting against the energy storage cabinet 10, the push rod 7 is cylindrical, and a buffer pad 71 is fixedly connected to the outer surface of the push rod 7. The carrier plate 2 is connected with a pushing component 8 for driving the push rod 7 to slide towards a direction close to or far away from the energy storage box, and the energy storage box is placed at the opening of the cavity 22. One side of the carrier plate 2 is sunken to be offered and to supply push rod 7 card to go into and slide the slide 27, slide 27 and cavity 22 intercommunication, promote the subassembly 8 and include fixed connection at push rod 7 peripheral face's rotation gear 81 and be used for driving push rod 7 round the pivoted first driving piece 82 of self axial lead, one side of carrier plate 2 is sunken to be offered and be used for with rotation gear 81 rotation and slide complex spout 28, spout 28 and slide 27 intercommunication, the inner wall fixedly connected with rack 83 of spout 28, rack 83 and rotation gear 81 meshing. The surface of carrier plate 2 slides and is connected with connecting plate 84, and the surface fixedly connected with of carrier plate 2 is the sand grip 9 of cuboid form, and connecting plate 84 is close to the one side of sand grip 9 towards keeping away from the sunken recess 841 that is used for with sand grip 9 sliding fit of seting up of direction of sand grip 9, the inner wall relative fixedly connected with stopper 842 of recess 841, the surface of sand grip 9 is sunken to be offered and is supplied spacing card to go into and the sliding chamber 91 that slides. The first driving piece 82 is fixedly connected to the upper surface of the connecting plate 84, the first driving piece 82 is a motor, the signal output end of the controller is connected with the signal input end of the first driving piece 82, the output end of the first driving piece 82 penetrates through the carrier plate 2, the carrier plate 2 is concavely provided with the waist-shaped hole 29 for the output end of the first driving piece 82 to clamp in and slide, the waist-shaped hole 29 is communicated with the sliding groove 28, and one side, close to the first driving piece 82, of the rotating gear 81 is fixedly connected with the output end of the first driving piece 82.

Referring to fig. 5, 6, 7 and 8, a guiding groove 200 for clamping and sliding one end of the push rod 7 is provided in a recess on one side of the carrier plate 2, the turntable 72 is fixedly connected with one end of the push rod 7 away from the first driving member 82, a limiting cavity 201 for rotating and sliding matching with the turntable 72 is provided in a recess on the carrier plate 2, and the limiting cavity 201 and the cavity 22 are both communicated with the guiding groove 200. The sliding cooperation of carousel 72 and spacing chamber 201 plays spacing effect to the slip of carousel 72, prevents that carousel 72 from appearing breaking away from the condition emergence in spacing chamber 201 at the in-process of sliding, improves push rod 7 rotation and the stability of sliding.

The implementation principle of the liquid cooling energy storage cabinet moving tool provided by the embodiment of the application is as follows:

The external equipment places the energy storage cabinet 10 on the carrier plate 2, and the energy storage cabinet 10 at this moment is located between push rod 7 and the energy storage case, and two second driving pieces 34 are opened to the controller control, and every second driving piece 34 drives corresponding initiative helical gear 31 and rotates around self axial lead, and initiative helical gear 31 drives driven helical gear 33 and rotates around self axial lead at pivoted in-process, and lead screw 32 rotates around self axial lead promptly to realize the slip of carrier plate 2 vertical direction, when the energy storage cabinet 10 removes to corresponding height, second driving piece 34 stop operation. The controller controls the first driving member 82 to be opened, the first driving member 82 drives the rotating gear 81 to rotate around the own axis, namely the push rod 7 rotates around the own axis, and as the rack 83 is not moved, the rotating gear 81, the push rod 7, the connecting plate 84 and the first driving member 82 slide along the length direction of the rack 83 until the energy storage cabinet 10 moves to the corresponding position.

When the energy storage cabinet 10 is aligned with the corresponding position of the energy storage box, the pushing assembly 8 pushes the energy storage cabinet 10 into the energy storage box. When the corresponding positions of the energy storage cabinet 10 and the energy storage box are staggered, the positioning rod 4 is clamped into the positioning groove 101 of the energy storage cabinet 10, so that the movement of the energy storage cabinet 10 is limited, the driving assembly 3 drives the slippage of the energy storage cabinet 10 in the vertical direction, the energy storage cabinet 10 can be accurately positioned, and the energy storage cabinet 10 is conveniently pushed into the energy storage box.

The above embodiments are not intended to limit the scope of the present application, so: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims (10)

1. Liquid cooling energy storage cabinet removes frock, its characterized in that: including frock body (1), frock body (1) slides and is connected with carrier plate (2), frock body (1) are connected with and are used for the drive assembly (3) that carrier plate (2) vertical direction slided, carrier plate (2) slide and are connected with push rod (7) that are used for with energy storage cabinet (10) butt, carrier plate (2) are connected with and are used for the drive push rod (7) are close to or keep away from the promotion subassembly (8) that the direction of energy storage case slided.

2. The liquid cooling energy storage cabinet removes frock according to claim 1, characterized in that: the support plate (2) is rotationally connected with a plurality of balls (5) which are used for being abutted with the energy storage cabinet (10).

3. The liquid cooling energy storage cabinet removes frock according to claim 2, characterized in that: the support plate (2) is provided with a containing cavity (24) for being in running fit with the balls (5), the support plate (2) is connected with a limiting plate (6) for covering the containing cavity (24), and the limiting plate (6) is provided with limiting holes (61) for the balls (5) to protrude.

4. The liquid cooling energy storage cabinet removes frock according to claim 3, wherein: the inner wall of the accommodating cavity (24) is connected with a plurality of arc-shaped bulges (25).

5. The liquid cooling energy storage cabinet removes frock according to claim 3, wherein: the limiting plate (6) is connected with the carrier plate (2) through a locking piece (63).

6. The liquid cooling energy storage cabinet removes frock according to claim 1, characterized in that: the outer peripheral surface of the push rod (7) is connected with a buffer pad (71).

7. The liquid cooling energy storage cabinet removes frock according to claim 1, characterized in that: the pushing assembly (8) comprises a rack (83) fixedly connected to the carrier plate (2) and a rotating gear (81) fixedly connected to the push rod (7), the rack (83) is meshed with the rotating gear (81), the carrier plate (2) is connected with a connecting plate (84) in a sliding mode, and the connecting plate (84) is connected with a first driving piece (82) used for driving the push rod (7) to rotate.

8. The liquid cooling energy storage cabinet removes frock according to claim 1, characterized in that: the support plate (2) is provided with a guide groove (200) which is used for being in sliding fit with the push rod (7).

9. The liquid cooling energy storage cabinet removes frock according to claim 1, characterized in that: the support plate (2) is connected with a positioning rod (4) in a sliding manner, and the support plate (2) is provided with a through hole (23) for the positioning rod (4) to pass through.

10. The liquid cooling energy storage cabinet removes frock according to claim 1, characterized in that: the driving assembly (3) comprises a driving bevel gear (31) and a driven bevel gear (33) which are rotatably connected to the tool body (1), the driving bevel gear (31) is meshed with the driven bevel gear (33), the driven bevel gear (33) is fixedly connected with a screw rod (32), the carrier plate (2) is provided with a threaded hole (21) which is in threaded fit with the screw rod (32), and the tool body (1) is connected with a second driving piece (34) which is used for driving the driving bevel gear (31) to rotate.