CN118610826A - Energy storage connector - Google Patents

Abstract

The application relates to the technical field of electric elements, and provides an energy storage connector, which comprises: the wire holding cylinder is fixed on the connector body and comprises an inner cylinder body, an outer cylinder body, a first locking piece and a second locking piece, wherein the outer cylinder body is sleeved on and connected with the outside of the inner cylinder body; one end of the connecting cylinder is sleeved outside the cable and connected with the cable, the other end of the connecting cylinder is sleeved outside the cable accommodating cylinder, and the first locking piece is used for locking the connecting cylinder; the wire clamping assembly is connected to the inner cylinder body in a sliding manner, the wire clamping assembly is used for clamping a cable, and the second locking piece is used for locking the wire clamping assembly; the driving piece is connected to the wire clamping assembly; the alignment sliding block penetrates through the outer cylinder body and is in sliding connection with the outer cylinder body, an alignment hole is formed in the connecting cylinder, and the driving piece is used for driving the alignment sliding block to penetrate out of the alignment hole. The application can improve the installation efficiency of the cable.

Description

Energy storage connector

Technical Field

The application relates to the technical field of electrical elements, in particular to an energy storage connector.

Background

Energy storage connectors are an important component in the electrical field, mainly for connecting and transmitting electrical energy. With the rapid development of renewable energy sources and the popularization of electric vehicles, energy storage technologies are becoming increasingly important. The energy storage connector is required to have high reliability, high efficiency and good compatibility as a key component of the energy storage system. The energy storage connector is generally composed of four parts, namely a contact, an insulator, a shell and a locking mechanism, wherein the contact is responsible for the transmission of electric energy and is generally made of copper or copper alloy; insulators are used to protect contacts from short circuits and electrical shock, and are typically made of plastic or other insulating materials; a housing to protect the internal components, providing mechanical support, typically made of metal or plastic; the locking mechanism ensures that the connector is stable and reliable in the connected state.

When the energy storage connector is used, the sub-end of the energy storage connector is connected with a cable; in the connection process of the cable, the cable needs to be inserted into the inner part of the sub-end of the energy storage connector to be fully contacted with the conductor in the inner part. However, the existing energy storage connector cannot intuitively confirm whether the cable is plugged in place in the cable installation process, if the cable is not installed in place, the conductive effect is affected, and the cable needs to be reinstalled after the locking mechanism is released, so that the installation efficiency of the cable is definitely reduced, and the operation complexity is increased.

Disclosure of Invention

In order to improve the installation efficiency of the cable, the application provides an energy storage connector.

The application provides an energy storage connector, which adopts the following technical scheme:

An energy storage connector, comprising:

the connector body is provided with a plurality of connecting grooves,

The wire accommodating cylinder is fixed on the connector body and comprises an inner cylinder body, an outer cylinder body, a first locking piece and a second locking piece, wherein the outer cylinder body is sleeved and connected with the outer side of the inner cylinder body;

One end of the connecting cylinder is sleeved outside the cable and connected with the cable, the other end of the connecting cylinder is sleeved outside the cable accommodating cylinder, and the first locking piece is used for locking the connecting cylinder;

The wire clamping assembly is connected to the inner cylinder body in a sliding manner, the wire clamping assembly is used for clamping a cable, and the second locking piece is used for locking the wire clamping assembly;

the driving piece is connected to the wire clamping assembly;

the alignment sliding block penetrates through the outer cylinder body and is in sliding connection with the outer cylinder body, an alignment hole is formed in the connecting cylinder, and the driving piece is used for driving the alignment sliding block to penetrate out of the alignment hole.

Through the technical scheme, the connecting cylinder is connected with the cable, when the cable is installed on the connector body, the clamping mechanism is locked through the second locking piece, and then the connecting cylinder is sleeved outside the cable accommodating cylinder, so that the cable is arranged in the cable accommodating cylinder in a penetrating manner, the connecting cylinder is slid towards the direction close to the connector body, and the cable is driven to move towards the direction close to the connector body; in the process that the cable moves in the cable accommodating cylinder, the cable clamping assembly gradually clamps the cable, and the cable clamping assembly can be unlocked after the cable clamping assembly clamps the cable; when the cable continues to slide in the wire accommodating cylinder, the wire clamping assembly and the driving piece can be driven to move together; before installing the cable, the distance between the counterpoint slider and the inner barrel is nearest, and when the cable drives the driving piece to move to the counterpoint slider, the driving piece drives the counterpoint slider to slide towards the direction of keeping away from the inner barrel, and the cable is installed in place until the counterpoint slider passes out of the counterpoint hole, and the position of the connecting barrel is locked through the first locking piece at this moment, so that the installation position of the cable is kept unchanged. If the cable is not installed in place, the alignment sliding block cannot penetrate out of the alignment hole; an operator can judge the plugging condition of the cable by judging the position of the alignment slide block.

Optionally, the driving piece includes the drive ring, the drive ring cover establish and sliding connection in outside the inner tube body, counterpoint slider is close to one side of drive ring is provided with the guide surface, when the drive ring promotes the guide surface, can drive counterpoint slider is kept away from the direction removal of inner tube body.

Through adopting above-mentioned technical scheme, press from both sides behind line subassembly holding cable, unblock press from both sides line subassembly, press from both sides the line subassembly and can slide along with the slip of cable to drive the drive ring and slide, after the drive ring slides to offseting with the guide surface, continue to slide the drive ring, can drive the counterpoint slider and remove towards the direction of keeping away from interior barrel, make counterpoint slider wear out the counterpoint hole gradually.

Optionally, the device also comprises a reset component, wherein the reset component comprises a magnetic attraction piece and a traction piece which are oppositely arranged, the magnetic attraction piece is fixed on the inner cylinder body, the traction piece is fixed at one end of the alignment sliding block, which is close to the inner cylinder body, and is made of ferromagnetic materials.

By adopting the technical scheme, before the cable is installed, the traction piece on the alignment sliding block is mutually attracted with the magnetic attraction piece under the action of the magnetic attraction piece, the alignment sliding block is positioned at the initial position, and the interval between the alignment sliding block and the inner cylinder body is minimum; when the slip ring slides to prop against the alignment sliding block, the alignment sliding block is driven to move in a direction away from the inner cylinder body, and the traction piece and the magnetic attraction piece are gradually separated; when the cable is removed early, the sliding ring slides to be separated from the counterpoint sliding block, and the counterpoint sliding block can move to the initial position again under the action of the traction piece and the magnetic attraction piece, so that the installation condition of the cable in the next installation is convenient to judge.

Optionally, the wire clamping assembly comprises a slip ring, a first force application member and a wire clamping block, wherein the slip ring is sleeved and connected outside the inner cylinder in a sliding manner, and the driving ring is fixed on one side of the slip ring, which is close to the alignment sliding block;

the wire clamping blocks are connected to the slip ring in a sliding mode, a plurality of wire clamping blocks are arranged around the axis of the slip ring at intervals, and the first force application piece is used for driving the wire clamping blocks to abut against the cable.

By adopting the technical scheme, after the cable is inserted into the cable accommodating cylinder, when the cable is slid to the cable clamping assembly, the first force application part can drive each cable clamping block to slide in the direction away from the outer cylinder body so as to clamp the cable, so that one end of the cable is stably connected in the cable accommodating cylinder; and after the clamping mechanism is unlocked, the clamping mechanism can move along with the cable so as to drive the driving ring to move to the position of the aligning sliding block.

Optionally, the first locking piece comprises a locking strip and a plurality of locking protrusions arranged on the end face of the locking strip, and a locking groove for plugging the locking protrusions is formed in the inner side wall of the connecting cylinder;

One end of the locking strip is fixedly connected with the counterpoint slide block, and a storage groove for accommodating the locking strip is formed in the side wall of the outer cylinder body.

Through adopting above-mentioned technical scheme, when counterpoint slider wears out the counterpoint hole under the effect of driving piece, the locking strip that is connected with counterpoint slider also moves along with counterpoint slider for locking strip roll-off accomodates the groove, and after the locking strip roll-off accomodates the groove, locking protrusion on the locking strip peg graft to the locking inslot of connecting cylinder inside wall, with the restriction connecting cylinder continues to take place to slide for outer barrel, locks the position of connecting cylinder, makes the cable be in the installation state in place with the persistence.

Optionally, a fastener is further disposed on the alignment slider, and the fastener is used for preventing the locking strip from sliding.

Through adopting above-mentioned technical scheme, when the locking protrusion on the locking strip slides to the locking inslot, locks the locking strip through the fastener, prevents that the locking strip from continuing to slide, improves the locking strength of locking strip.

Optionally, the fastening piece comprises a fastening inserted bar and a second force application piece, and the fastening inserted bar is connected to the alignment sliding block in a sliding manner; the clamping groove for the fastening inserted rod to be inserted is formed in the inner side wall of the alignment hole, and the second force application piece is used for driving the fastening inserted rod to slide.

Through adopting above-mentioned technical scheme, when the locking protruding grafting on the locking strip to the in-process fastening inserted bar of locking groove also slides along with counterpoint slider towards the direction that is close to the draw-in groove, after locking protruding grafting to the locking groove, fastening inserted bar also slides to draw-in groove one side, and second application of force spare drive fastening inserted bar one end slides to in the draw-in groove to the position of counterpoint slider locks to indirectly hinder the locking strip to continue to remove.

Optionally, one end of the wire clamping block located in the inner cylinder body tapers towards a direction away from the outer cylinder body, the first force application member comprises a first force application spring, the first force application spring is sleeved outside the wire clamping block, and a limiting plate is arranged at one end of the wire clamping block close to the outer cylinder body;

one end of the first force application spring is connected with the slip ring, and the other end of the first force application spring is connected with the limiting plate.

By adopting the technical scheme, before the cable is inserted into the inner cylinder, the first force application spring is in a loose state; when the cable is propped against the wire clamping block, the wire clamping block is driven to move towards the direction close to the outer cylinder until one end of the cable moves to the other side of the wire clamping block along one side of the wire clamping block, the first force application spring is in an extension state, and the wire clamping block is propped against the cable under the action of the first force application spring, so that the clamping of the cable is realized.

Optionally, a sliding groove is formed in the alignment sliding block, the fastening inserting rod is slidably arranged in the sliding groove, the second force application piece comprises a second force application spring, and the second force application spring is connected between the fastening inserting rod and the inner side wall of the sliding groove.

By adopting the technical scheme, before the locking protrusion on the locking strip is inserted into the locking groove, the fastening inserted bar is completely positioned in the sliding groove, and the second force application spring is in a contracted state; when the locking protrusion on the locking strip is inserted into the locking groove, the fastening inserted bar slides to the clamping groove, and the second force application spring gradually stretches to drive the fastening inserted bar to slide, so that one end of the fastening inserted bar is inserted into the clamping groove.

Optionally, the second locking member includes a locking pin, the locking pin is located at an end of the outer cylinder body away from the connector body, and one end of the locking pin is inserted into the slip ring through the outer cylinder body.

By adopting the technical scheme, when the wire clamping assembly is required to be locked, the locking pin is inserted into the slip ring after passing through the outer cylinder body, so that the slip ring is limited to slide relative to the inner cylinder; when the wire clamping assembly is required to be unlocked, the locking pin is slid, and the locking pin is pulled out of the slip ring.

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

1. The cable clamping assembly and the alignment sliding block are arranged in the cable clamping device, the cable clamping assembly is unlocked or locked by the second locking piece, after the cable clamping assembly clamps the cable in a locked state, the cable clamping assembly is unlocked, so that the cable clamping assembly can move together with the cable, and if the cable is installed in place, the driving piece drives the alignment sliding block to penetrate out of the alignment hole so as to provide an installation in place reminding for an operator to judge the installation position of the cable;

2. the first locking piece is connected to the alignment sliding block, and when the alignment sliding block passes through the alignment hole under the action of the driving piece, the locking piece moves together with the alignment sliding block, and the locking protrusion in the locking piece is inserted into the locking groove in the inner side wall of the connecting cylinder so as to lock the connecting cylinder;

3. the alignment sliding block is also provided with the fastener, when the locking protrusion on the locking strip slides into the locking groove, the locking strip is locked through the fastener, so that the locking strip is prevented from sliding continuously, and the locking strength of the locking strip is improved.

Drawings

FIG. 1 is a schematic diagram of an energy storage connector prior to plugging a cable according to an embodiment of the present application;

FIG. 2 is a schematic diagram of an energy storage connector according to an embodiment of the present application after a cable is plugged in place;

FIG. 3 is a schematic cross-sectional view of an energy storage connector according to an embodiment of the present application;

FIG. 4 is a schematic cross-sectional view of a slip ring according to an embodiment of the present application;

FIG. 5 is a schematic view of a partial cross-sectional structure of a wire accommodating cylinder showing an alignment slider according to an embodiment of the present application;

FIG. 6 is a schematic diagram of a cross-sectional structure of an alignment slider according to an embodiment of the present application;

FIG. 7 is a schematic view of a partial enlarged structure at A in FIG. 1;

Reference numerals illustrate: 1. a connector body; 2. a wire accommodating cylinder; 21. an inner cylinder; 22. an outer cylinder; 221. a guide groove; 222. a storage groove; 23. a locking bar; 231. a locking protrusion; 24. a locking pin; 3. a connecting cylinder; 31. an alignment hole; 311. a clamping groove; 32. a locking groove; 33. a hole for the abdication strip; 4. a wire clamping assembly; 41. a slip ring; 42. a first force application spring; 43. a wire clamping block; 431. a clamping part; 432. an adjusting rod; 433. a limiting plate; 5. a drive ring; 6. aligning the sliding block; 61. a guide surface; 62. a chute; 7. a reset assembly; 71. a magnetic attraction piece; 72. a pulling piece; 8. a fastener; 81. fastening the inserted link; 811. a rod body; 812. fastening the plug; 82. a second force application spring; 9. a cable.

Detailed Description

The application is described in further detail below with reference to fig. 1-7.

The embodiment of the application provides an energy storage connector.

Referring to fig. 1 and 2, an energy storage connector comprises a connector body 1, a wire accommodating cylinder 2, a connecting cylinder 3 and a wire clamping assembly 4, wherein one end of the connecting cylinder 3 is sleeved and fixedly connected to a cable 9, and an alignment hole 31 is formed in the outer side wall of the connecting cylinder 3. Referring to fig. 3, the wire accommodating tube 2 includes an inner tube 21 and an outer tube 22 sleeved and fixedly connected to the outside of the inner tube 21.

Referring to fig. 3 and 4, the wire clamping assembly 4 includes a slip ring 41, a wire clamping block 43 and a first force application member, the slip ring 41 is sleeved and slidably connected to the outside of the inner cylinder 21, and a guide groove 221 for sliding the slip ring 41 is formed on the inner side wall of the outer cylinder 22. The wire clamping block 43 is arranged on the slip ring 41 in a penetrating manner and is in sliding connection with the slip ring 41, the wire clamping block 43 comprises a clamping portion 431 and an adjusting rod 432 fixed at one end of the clamping portion 431, and one end, away from the adjusting rod 432, of the clamping portion 431 is located inside the inner cylinder 21. One end of the holding portion 431 tapers in a direction approaching the axis of the inner cylinder 21, and in this embodiment, the holding portion 431 is specifically configured as an arc-shaped strip. One end of the adjusting rod 432, which is far away from the clamping part 431, is provided with a limiting plate 433, the first force application member is specifically provided with a first force application spring 42, the first force application spring 42 is sleeved outside the adjusting rod 432, one end of the first force application spring 42 is fixedly connected with the limiting plate 433, and the other end of the first force application spring 42 is fixedly connected with the slip ring 41. In the present embodiment, three wire clamping blocks 43 are provided at equal intervals around the axis of the slip ring 41, three first urging springs 42 are also provided, and the wire clamping blocks 43 are in one-to-one correspondence with the first urging springs 42.

Referring to fig. 2 and 3, the wire accommodating tube 2 is provided with a second locking piece, the second locking piece comprises a locking pin 24, one end of the locking pin 24 passes through the outer tube 22 and is then inserted into the sliding ring 41, so that the sliding ring 41 can be locked, and the sliding ring 41 is prevented from moving; the connecting cylinder 3 is provided with a relief hole 33 for sliding the locking pin 24. The second locking piece locks the slip ring 41, and then the connecting cylinder 3 is sleeved outside the wire containing cylinder 2, and the limiting pin is positioned in the abdicating strip hole 33, so that the connecting cylinder 3 can be pushed to move towards the direction close to the connector body 1. When the connecting cylinder 3 slides, the cable 9 connected in the connecting cylinder 3 is inserted into the inner cylinder 21 along with the movement of the connecting cylinder 3; when the cable 9 moves to be abutted against the wire clamping block 43, the wire clamping block 43 is gradually driven to move in a direction away from the axis of the inner cylinder 21; the connecting cylinder 3 continues to slide until the wire clamping block 43 abuts against the cable 9, and after the cable 9 is clamped, the locking pin 24 can be pulled out to unlock the slip ring 41. When the connecting cylinder 3 continues to slide towards the direction approaching the connector body 1, the wire clamping assembly 4 can be driven to slide together.

Referring to fig. 5, the wire accommodating tube 2 is provided with an alignment slider 6, and one end of the alignment slider 6 is inserted into the outer tube 22 and is slidably connected with the outer tube 22. The guide surface 61 is provided on the side of the alignment slider 6 near the slip ring 41, the guide is inclined, and the distance between the guide surface 61 and the axis of the inner cylinder 21 gradually increases toward the slip ring 41. A reset component 7 is arranged between the counterpoint slide block 6 and the inner cylinder 21, and the reset component 7 comprises a magnetic attraction piece 71 and a traction piece 72; the magnetic sheet 71 is fixed to the side wall of the inner cylinder 21 in a built-in manner, and the magnetic sheet 71 is made of a magnet. The pulling tab 72 is fixed to the guide surface 61, and the pulling tab 72 is made of a ferromagnetic material, in this embodiment iron being used in particular. The alignment slide block 6 is close to the inner cylinder 21 under the action of the reset assembly 7, and at this time, the distance between the alignment slide block 6 and the inner cylinder 21 is the shortest. A driving member is fixed on one side of the slip ring 41, which is close to the alignment slide block 6, the driving member is specifically configured as a driving ring 5, and the driving ring 5 is sleeved outside the inner cylinder 21 and is in sliding connection with the inner cylinder 21.

When the connecting cylinder 3 continues to slide towards the direction approaching the connector body 1, the sliding ring 41 is driven to move together, so that the driving ring 5 connected to one side of the sliding ring 41 slides towards the direction approaching the alignment slider 6. The driving ring 5 gradually slides to abut against the guide surface 61 and drives the alignment slider 6 to slide in a direction away from the inner cylinder 21 until the alignment slider 6 passes through the alignment hole 31, and the cable 9 is inserted in place.

Referring to fig. 5, after the cable 9 is inserted in place, a first locking member and a fastener 8 are further provided in order to lock the position of the connection cylinder 3. The first locking member includes a locking bar 23 and locking projections 231 fixed to a surface of the locking bar 23, the locking projections 231 being provided in plurality at equal intervals in an axial direction of the outer cylinder 22. One end of the locking strip 23 is fixed on the side wall of the alignment slide block 6, and the locking strips 23 are fixed on both sides of the alignment. The side wall of the outer cylinder 22 is provided with a storage groove 222, and when the alignment slide block 6 abuts against the inner side wall, the locking strip 23 is clamped into the storage groove 222. The inner side wall of the connecting cylinder 3 is provided with a locking groove 32 for the locking protrusion 231 to be inserted.

When the alignment slide block 6 passes through the alignment hole 31 under the action of the driving piece, the locking bar 23 moves together with the alignment slide block 6, so that the locking bar 23 slides out of the storage groove 222; after the locking bar 23 slides out of the accommodating groove 222, the locking protrusion 231 on the locking bar 23 is inserted into the locking groove 32 on the inner side wall of the connecting cylinder 3, so as to limit the connecting cylinder 3 to slide relative to the outer cylinder 22 continuously, and the position of the connecting cylinder 3 is locked. In this embodiment, three counterpoint sliders 6 are specifically provided, and the counterpoint sliders 6 and the wire clamping blocks 43 are arranged in a dislocation manner; correspondingly, the locking bar 23 is provided with six bars.

Referring to fig. 6 and 7, the fastener 8 includes a fastening insert rod 81 and a second force application member, a slide groove 62 is formed in a side wall of the alignment slider 6, the fastening insert rod 81 includes a rod 811 and a fastening plug 812 fixed to one end of the rod 811, and one end of the fastening plug 812 is specifically configured as a hemisphere. The second force application member is specifically configured as a second force application spring 82, and the second force application spring 82 is sleeved outside the rod 811; one end of the second force application spring 82 is fixedly connected with the fastening plug 812, and the other end is fixedly connected with the inner side wall of the sliding groove 62. The inner side wall of the alignment hole 31 is provided with a clamping groove 311, before the locking protrusion 231 on the locking strip 23 is inserted into the locking groove 32, the fastening inserted rod 81 is completely positioned in the sliding groove 62, and the second force application spring 82 is in a contracted state; when the locking protrusion 231 on the locking bar 23 is inserted into the locking groove 32, the fastening insert rod 81 slides to the clamping groove 311, and the second force application spring 82 gradually expands to drive the fastening insert rod 81 to slide, so that one end of the fastening insert rod 81 is inserted into the clamping groove 311 to lock the alignment slide block 6 and the locking bar 23. In this embodiment, the two sides of each alignment slider 6 are provided with fasteners 8, and the fasteners 8 are specifically provided with three fasteners.

The implementation principle of the energy storage connector of the embodiment of the application is as follows: one end of the locking pin 24 passes through the outer cylinder 22 and then is inserted into the sliding ring 41 to lock the sliding ring 41; and then the connecting cylinder 3 is sleeved outside the wire accommodating cylinder 2, the connecting cylinder 3 is pushed to slide towards the direction close to the connector body 1, and when the connecting cylinder 3 slides, the wire clamping assembly 4 positioned in the wire accommodating cylinder 2 gradually clamps the wire 9, so that the locking pin 24 can be taken out to unlock the wire clamping assembly 4. Continuously pushing the wire accommodating cylinder 2 to slide, and moving the wire clamping assembly 4 along with the cable 9 when the wire accommodating cylinder 2 slides; the driving ring 5 on one side of the thread clamping assembly 4 moves together with the thread clamping assembly 4 until the driving ring 5 abuts against the guide surface 61 of the alignment slider 6. And drives the alignment slide block 6 to slide in a direction away from the inner cylinder 21 until the alignment slide block 6 passes through the alignment hole 31, and the cable 9 is spliced in place. In the process that the alignment slide block 6 passes through the alignment hole 31, the locking bar 23 also moves along with the alignment slide block 6, and the locking protrusion 231 on the locking bar 23 is inserted into the locking groove 32 on the inner side wall of the connecting cylinder 3 to lock the position of the connecting cylinder 3.

While the locking protrusion 231 on the locking bar 23 is inserted into the locking groove 32, the fastening plunger 81 slides to the clamping groove 311, and the second force application spring 82 drives the fastening plunger 81 to slide, so that the fastening plug 812 is inserted into the clamping groove 311 to lock the alignment slider 6 and the locking bar 23.

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. An energy storage connector, comprising:

A connector body (1),

The wire accommodating cylinder (2) is fixed on the connector body (1) and comprises an inner cylinder body (21), an outer cylinder body (22) and a first locking piece and a second locking piece, wherein the outer cylinder body (22) is sleeved and connected outside the inner cylinder body (21);

one end of the connecting cylinder (3) is sleeved outside the cable (9) and connected with the cable (9), the other end of the connecting cylinder is sleeved outside the wire accommodating cylinder (2), and the first locking piece is used for locking the connecting cylinder (3);

The wire clamping assembly (4) is connected to the inner cylinder body (21) in a sliding mode, the wire clamping assembly (4) is used for clamping a cable (9), and the second locking piece is used for locking the wire clamping assembly (4);

the driving piece is connected to the wire clamping assembly (4);

the alignment slide block (6), the alignment slide block (6) is arranged on the outer cylinder body (22) in a penetrating way and is in sliding connection with the outer cylinder body (22), an alignment hole (31) is formed in the connecting cylinder (3), and the driving piece is used for driving the alignment slide block (6) to penetrate out of the alignment hole (31).

2. An energy storage connector according to claim 1, wherein the driving member comprises a driving ring (5), the driving ring (5) is sleeved and slidably connected to the outside of the inner cylinder (21), a guiding surface (61) is arranged on one side of the alignment slider (6) close to the driving ring (5), the guiding surface (61) is arranged on one side of the alignment slider (6), and when the driving ring (5) pushes the guiding surface (61), the alignment slider (6) can be driven to move in a direction away from the inner cylinder (21).

3. The energy storage connector according to claim 2, further comprising a reset assembly (7), wherein the reset assembly (7) comprises a magnetic attraction piece (71) and a traction piece (72) which are oppositely arranged, the magnetic attraction piece (71) is fixed on the inner cylinder body (21), the traction piece (72) is fixed on one end, close to the inner cylinder body (21), of the alignment slide block (6), and the traction piece (72) is made of ferromagnetic materials.

4. A power storage connector according to claim 3, wherein the wire clamping assembly (4) comprises a slip ring (41), a first force application member and a wire clamping block (43), the slip ring (41) is sleeved and slidingly connected outside the inner cylinder (21), and the driving ring (5) is fixed on one side of the slip ring (41) close to the alignment slide block (6);

The wire clamping block (43) is connected to the slip ring (41) in a sliding mode, a plurality of wire clamping blocks (43) are arranged around the axis of the slip ring (41) at intervals, and the first force application piece is used for driving the wire clamping block (43) to abut against the cable (9).

5. The energy storage connector as claimed in claim 4, wherein the first locking member comprises a locking bar (23) and a plurality of locking protrusions (231) arranged on the end surface of the locking bar (23), and a locking groove (32) for inserting the locking protrusions (231) is arranged on the inner side wall of the connecting cylinder (3);

One end of the locking strip (23) is fixedly connected with the counterpoint slide block (6), and a storage groove (222) for accommodating the locking strip (23) is formed in the side wall of the outer cylinder body (22).

6. Energy storage connector according to claim 5, characterized in that the counterpoint slide (6) is further provided with a fastener (8), which fastener (8) is adapted to hinder the sliding of the locking bar (23).

7. An energy storage connector according to claim 6, wherein the fastener (8) comprises a fastening spigot (81) and a second force application member, the fastening spigot (81) being slidably connected to the alignment slide (6); the inner side wall of the alignment hole (31) is provided with a clamping groove (311) for the fastening inserted rod (81) to be inserted, and the second force application piece is used for driving the fastening inserted rod (81) to slide.

8. The energy storage connector as claimed in claim 7, wherein one end of the wire clamping block (43) located in the inner cylinder (21) tapers away from the outer cylinder (22), the first force application member comprises a first force application spring (42), the first force application spring (42) is sleeved outside the wire clamping block (43), and a limiting plate (433) is arranged at one end of the wire clamping block (43) close to the outer cylinder (22);

One end of the first force application spring (42) is connected with the slip ring (41), and the other end of the first force application spring is connected with the limiting plate (433).

9. The energy storage connector as claimed in claim 8, wherein the alignment slider (6) is provided with a chute (62), the fastening insert rod (81) is slidably disposed in the chute (62), the second force application member comprises a second force application spring (82), and the second force application spring (82) is connected between the fastening insert rod (81) and an inner side wall of the chute (62).

10. An energy storing connector according to claim 9, wherein the second locking member comprises a locking pin (24), the locking pin (24) being located at an end of the outer cylinder (22) remote from the connector body (1), the locking pin (24) having one end inserted through the outer cylinder (22) into the slip ring (41).