CN219180702U - Lithium battery module stacks frock - Google Patents

Abstract

The utility model provides a lithium battery module stacking tool which comprises a mounting panel, two first side extrusion tools, two second side extrusion tools and a sliding assembly, wherein a battery cell module is supported on the mounting panel. Through setting up slide damper, when using, place two rows of electric core modules respectively on the installation faceplate to make two rows of electric core module be located slide damper's relative both sides respectively, slide damper shelters from between two rows of electric core module between this, then extrude two rows of electric core modules from four sides through adjusting first side extrusion frock and second side extrusion frock, this time because slide damper shelters from between two rows of electric core module, can prevent that two rows of electric core module from taking place direct contact and lead to extrusion stacking effect relatively poor and electric core module extrudees each other and take place to damage, should pile up the frock and conveniently pile up the processing when two rows of electric core module, pile up efficiently, facilitate the use.

Description

Lithium battery module stacks frock

Technical Field

The utility model relates to the technical field of lithium battery module stacking, in particular to a lithium battery module stacking tool.

Background

The general mode of grouping of lithium cell group is that forms the module with a plurality of single electric core through the mode of series-parallel connection combination, and a plurality of modules establish ties again and form the module, and in the in-process that a plurality of modules establish ties and form the module, it is required to fix a position the plastic to a plurality of modules to compress it to appointed distance, then use steel band or packing belt tensioning fixed, accomplish the module and pile up.

The utility model of the publication No. CN209183665U provides a lithium battery module stacking tool, which replaces manual operation by adopting a side pushing cylinder and a main pushing cylinder to effectively reduce positioning errors and rapidly and accurately stack a plurality of modules together to form a module, but stacks a plurality of battery cells to form a module in a four-side extrusion mode.

Disclosure of Invention

In view of this, the present utility model provides a lithium battery module stacking tool, wherein a slidable sliding baffle is disposed between two rows of module core cells, when two rows of core cells need to be stacked, the sliding baffle is blocked between the two rows of core cells, the two rows of core cells cannot directly contact, row-by-row alignment stacking of the two rows of core cells can be completed simultaneously through four-sided extrusion, then the sliding baffle is adjusted to slide out of between the two rows of core cells, and the aligned two rows of core cells are stacked together through four-sided extrusion, thereby completing rapid stacking processing between the two rows of core cells.

The technical scheme of the utility model is realized as follows: the utility model provides a lithium battery module stacking tool, which comprises a mounting panel, two first side extrusion tools, two second side extrusion tools and a sliding assembly, wherein,

the mounting panel is supported with a battery core module;

the sliding assembly comprises a sliding baffle plate, wherein the sliding baffle plate is arranged on the mounting panel in a sliding manner and is perpendicular to the mounting panel and slides towards or away from the mounting panel;

the two first side extrusion tools are arranged on the mounting panel and are positioned on two opposite sides of the sliding baffle plate and used for pushing the battery cell module towards the side of the sliding baffle plate;

the two second side extrusion tools are arranged on the mounting panel and are positioned on two opposite sides of the sliding baffle, and the two second side extrusion tools are respectively arranged adjacent to the two first side extrusion tools and are used for pushing the battery cell module to the side of the sliding baffle.

On the basis of the technical proposal, the sliding component preferably further comprises a first mounting seat and a positioning bolt, wherein,

the first mounting seat is detachably arranged on the mounting panel, the sliding baffle is arranged on the first mounting seat in a sliding manner, and a plurality of positioning jacks are formed in the first mounting seat and the sliding baffle;

the positioning plug pin penetrates through the sliding baffle and the positioning jack formed in the first mounting seat and is used for positioning the sliding position of the sliding baffle relative to the first mounting seat.

On the basis of the above technical solution, preferably, the sliding assembly further comprises an assembly screw, wherein,

the assembly screw rod is movably arranged on the first installation seat and is in threaded connection with the installation panel, and the assembly screw rod is used for positioning the position of the first installation seat relative to the installation panel.

On the basis of the technical proposal, preferably, the first side extrusion tooling comprises a second mounting seat, a first positioning screw and a side extrusion assembly, wherein,

the second mounting seat is arranged on the mounting panel;

the first positioning screw rod is in threaded connection with the second mounting seat;

the side extrusion assembly is arranged on the mounting panel in a sliding manner, the battery cell module is abutted to one side of the side extrusion assembly, the side extrusion assembly slides towards the direction close to or far away from the battery cell module, and one end of the first positioning screw rod is rotationally connected with the side extrusion assembly.

On the basis of the technical proposal, preferably, the first side extrusion tooling further comprises a position-adjusting rotary rod, wherein,

the positioning rotating rod is arranged at one end of the first positioning screw rod, which is far away from the side extrusion assembly.

On the basis of the technical proposal, preferably, the side extrusion assembly comprises a sliding seat and a sliding connection plate, and also comprises a single-row electric core extrusion tool, wherein the single-row electric core extrusion tool comprises an assembly seat and a second positioning screw rod,

the sliding seat is arranged on the mounting panel in a sliding manner and is rotationally connected with the first positioning screw rod;

the number of the sliding plates is four, two sliding plates are arranged on each sliding seat in a sliding manner, the battery cell module is abutted against one side of the sliding plates, and the sliding plates slide towards the direction approaching or far away from the battery cell module;

the four assembly seats are respectively arranged on the two sliding seats and are respectively arranged on adjacent sides of the four sliding plates;

the second positioning screw rod is in threaded connection with the assembly seat and is in rotary connection with the sliding seat.

On the basis of the technical proposal, preferably, the second side extrusion tooling comprises a third installation seat, a third positioning screw rod and a side extrusion block, wherein,

the third mounting seat is arranged on the mounting panel;

the third positioning screw rod is in threaded connection with the third mounting seat;

the side extrusion piece is arranged on the mounting panel in a sliding manner, the battery cell module is abutted to one side of the side extrusion piece and slides towards the direction close to or far away from the battery cell module, and one end of the third positioning screw rod is rotationally connected with the side extrusion piece.

On the basis of the technical proposal, the device also preferably comprises a pressure detection mechanism, wherein the pressure detection mechanism comprises a pressure sensor and a pressure sensor digital display, wherein,

the pressure sensors are respectively arranged on one side of the sliding connection plate close to the battery cell module and one side of the side extrusion block close to the battery cell module;

the pressure sensors are digital display, are arranged on the mounting panel in number and are respectively and electrically connected with the pressure sensors, and are used for displaying pressure detection data of the pressure sensors.

On the basis of the technical proposal, the utility model preferably further comprises an end insulating sheet, wherein the end insulating sheet comprises a pushing core part and a limiting part, and the pushing core part is provided with a pushing groove,

the pushing core part is arranged on the pressure sensor and is abutted against the battery cell module, and one side surface of the pushing core part abutted against the battery cell module is a plane;

and the limiting part is arranged on the pushing core part and is shielded on one side of the battery cell module, which is far away from the mounting panel, and is used for limiting the battery cell module in the vertical direction.

On the basis of the technical proposal, the utility model also comprises a bump, wherein,

the lug is arranged on one side of the side extrusion block, which is close to the battery cell module, and the lug is abutted against the battery cell module.

Compared with the prior art, the lithium battery module stacking tool has the following beneficial effects:

(1) Through setting up slide damper, when using, place two rows of electric core modules respectively on the installation panel to make two rows of electric core module be located slide damper's relative both sides respectively, slide damper shelters from between two rows of electric core module, then extrude two rows of electric core modules from four sides through adjusting first side extrusion frock and second side extrusion frock, slide damper separates two rows of electric core module between this, can prevent that two rows of electric core module from taking place direct contact and lead to extrusion stacking effect relatively poor and electric core module extrudees each other and take place to damage. Two rows of cell modules are extruded from four sides through the first side extrusion tooling and the second side extrusion tooling, so that each row of cell modules are aligned and stacked relative to the sliding baffle plate in each area, after the alignment and stacking of the two rows of cell modules are completed, the sliding baffle plate is adjusted to slide until the two rows of cell modules are separated, and then the rows of cell modules which are already aligned and stacked are stacked together, and therefore simultaneous stacking processing of the two rows of cell modules is completed, the stacking efficiency is high, and the use is convenient.

(2) Through sliding on every slide holder and setting up two sliding connection plates, when placing two rows of electric core module respectively in slide damper's opposite both sides, can at first adjust the second positioning screw of threaded connection on the assembly seat and rotate, the second positioning screw promotes each sliding connection plate to be close to the direction removal of electric core module, thereby accomplish the counterpoint stack processing to every row of electric core module, after every row of electric core module counterpoint stack is accomplished, adjust slide damper and slide to breaking away from two electric core modules, then adjust the first positioning screw rotation of threaded connection on the second mount pad, first positioning screw promotes simultaneously to be close to the direction removal of electric core module through promoting the slide holder under threaded connection, thereby accomplish the whole extrusion stack processing to two rows of electric core modules, facilitate the use.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a perspective view of a lithium battery module stacking tool according to the present utility model;

fig. 2 is a front view of the lithium battery module stacking tool of the present utility model;

fig. 3 is a schematic perspective view of the lithium battery module stacking tool of the present utility model after the battery module is detached in fig. 1;

fig. 4 is a schematic perspective view illustrating a connection manner between a sliding baffle and a mounting seat of a lithium battery module stacking tool according to the present utility model;

fig. 5 is a schematic perspective view of the lithium battery module stacking tool of the present utility model after the sliding baffle in fig. 4 slides relative to the mounting seat;

fig. 6 is a schematic perspective view of a connection structure at a first side extrusion tooling of the lithium battery module stacking tooling of the present utility model;

fig. 7 is a schematic perspective view of a connection structure at a second side extrusion tooling of the lithium battery module stacking tooling of the present utility model;

fig. 8 is a schematic perspective view of an end insulating sheet of the lithium battery module stacking tool of the present utility model.

In the figure: 1. installing a panel; 2. a first side extrusion tooling; 21. a second mounting base; 22. a first positioning screw; 23. a side extrusion assembly; 231. a sliding seat; 232. a sliding plate; 24. a position-adjusting rotary rod; 3. the second side extrusion tooling; 31. a third mount; 32. a third positioning screw; 33. a side extrusion block; 4. a sliding assembly; 41. a sliding baffle; 42. a first mount; 43. positioning the jack; 44. positioning a bolt; 45. assembling a screw; 5. single-row cell extrusion tooling; 51. an assembly seat; 52. a second positioning screw; 6. a pressure detection mechanism; 61. a pressure sensor; 62. the pressure sensor is digitally displayed; 7. an end insulating sheet; 71. pushing the core; 72. a limit part; 8. and a bump.

Detailed Description

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

As shown in fig. 1 to 8, the lithium battery module stacking tool comprises a mounting panel 1, two first side extrusion tools 2, two second side extrusion tools 3 and a sliding component 4, wherein a battery cell module is supported on the mounting panel 1; the sliding assembly 4 comprises a sliding baffle 41, wherein the sliding baffle 41 is arranged on the mounting panel 1 in a sliding manner and is perpendicular to the mounting panel 1 and slides towards or away from the mounting panel 1; the two first side extrusion tools 2 are arranged on the mounting panel 1 and are positioned on two opposite sides of the sliding baffle 41 and used for pushing the battery cell module towards the sliding baffle 41; the two second side extrusion tools 3 are all arranged on the mounting panel 1 and are positioned on two opposite sides of the sliding baffle 41, and are respectively arranged adjacent to the two first side extrusion tools 2 and are used for pushing the battery cell module towards the sliding baffle 41.

In specific implementation, two rows of cell modules are respectively placed on the installation panel 1, and the two rows of cell modules are respectively located on two opposite sides of the sliding baffle 41, the sliding baffle 41 is shielded between the two rows of cell modules, then the two rows of cell modules are extruded from four sides by adjusting the first side extrusion tool 2 and the second side extrusion tool 3, and the sliding baffle 41 separates the two rows of cell modules, so that the two rows of cell modules can be prevented from being in direct contact, and the extrusion stacking effect is poor and the cell modules are mutually extruded to be damaged. Two rows of cell modules are extruded from four sides through the first side extrusion tooling 2 and the second side extrusion tooling 3, so that each row of cell modules are aligned and stacked relative to the sliding baffle 41 in respective areas, after the alignment and stacking of the two rows of cell modules are completed, the sliding baffle 41 is adjusted to slide until the two rows of cell modules are separated, and then the rows of cell modules which are already aligned and stacked are stacked together, and therefore simultaneous stacking processing of the two rows of cell modules is completed, the stacking efficiency is high, and the use is convenient.

As a preferred embodiment, the sliding assembly 4 further includes a first mounting seat 42 and a positioning bolt 44, where the first mounting seat 42 is detachably disposed on the mounting panel 1, the sliding baffle 41 is slidably disposed on the first mounting seat 42, and a plurality of positioning jacks 43 are formed on the first mounting seat 42 and the sliding baffle 41; the positioning bolt 44 passes through the sliding baffle 41 and the positioning insertion hole 43 formed on the first mounting seat 42, and is used for positioning the sliding position of the sliding baffle 41 relative to the first mounting seat 42.

In specific implementation, the sliding baffle 41 slides relative to the first mounting seat 42, and when the sliding baffle 41 slides to the side closest to the mounting panel 1, the sliding baffle 41 is separated from the two core die groups, and as the first mounting seat 42 and the sliding baffle 41 are provided with a plurality of positioning jacks 43, when the sliding baffle 41 is adjusted to slide to an ideal position and the positioning jacks 43 formed on the sliding baffle 41 and the first mounting seat 42 are aligned with each other, the positioning plug 44 can be adjusted to pass through the positioning jacks 43, so that the positioning processing of the sliding position of the sliding baffle 41 relative to the first mounting seat 42 is completed.

As a preferred embodiment, the sliding assembly 4 further comprises a mounting screw 45, wherein the mounting screw 45 is movably arranged on the first mounting seat 42 and is in threaded connection with the mounting panel 1 for positioning the first mounting seat 42 relative to the mounting panel 1.

In specific implementation, the first mounting seat 42 is provided with a through hole through which the assembly screw 45 passes, and the mounting panel 1 is provided with a threaded hole, when the first mounting seat 42 needs to be assembled on the mounting panel 1, the assembly screw 45 is adjusted to pass through the through hole and be in threaded connection with the threaded hole, so that the assembly connection treatment of the first mounting seat 42 is completed, the first mounting seat 42 is connected and assembled through the assembly screw 45, and the assembly and disassembly treatment of the first mounting seat 42 are facilitated.

As a preferred embodiment, the first side extrusion tooling 2 comprises a second mounting seat 21, a first positioning screw 22 and a side extrusion assembly 23, wherein the second mounting seat 21 is arranged on the mounting panel 1; the first positioning screw 22 is in threaded connection with the second mounting seat 21; the side extrusion assembly 23 is slidably arranged on the mounting panel 1, the battery cell module is abutted against one side of the side extrusion assembly 23, the side extrusion assembly 23 slides towards a direction close to or far away from the battery cell module, and one end of the first positioning screw 22 is rotatably connected with the side extrusion assembly 23.

In specific implementation, the first positioning screw 22 is turned, and at this time, the first positioning screw 22 pushes the side extrusion assembly 23 to slide towards a direction close to the battery cell module under the action of threaded connection, so that the extrusion stacking process of the battery cell module is completed by adjusting the sliding of the extrusion side extrusion assembly 23.

As a preferred embodiment, the first side extrusion tooling 2 further comprises a positioning screw 24, wherein the positioning screw 24 is arranged at an end of the first positioning screw 22 remote from the side extrusion assembly 23.

By the design, when the first positioning screw 22 needs to be adjusted to rotate, the quick rotation treatment of the first positioning screw 22 can be completed by adjusting the rotation of the positioning rotary rod 24, so that the use is convenient.

As a preferred embodiment, the side extrusion assembly 23 comprises a sliding seat 231 and a sliding connection plate 232, and further comprises a single-row cell extrusion tooling 5, wherein the single-row cell extrusion tooling 5 comprises an assembly seat 51 and a second positioning screw 52, and the sliding connection seat 231 is slidably arranged on the mounting panel 1 and is rotationally connected with the first positioning screw 22; the number of the sliding connection plates 232 is four, two sliding connection plates 232 are arranged on each sliding connection seat 231 in a sliding manner, the cell module is abutted against one side of the sliding connection plates 232, and the sliding connection plates 232 slide in a direction approaching or separating from the cell module; the number of the assembly seats 51 is four, and the assembly seats are respectively arranged on the two sliding seats 231 and are respectively arranged on adjacent sides of the four sliding plates 232; the second positioning screw 52 is screwed on the assembly seat 51 and is rotatably connected with the sliding seat 231.

In this way, when two rows of core modules are respectively placed on two opposite sides of the sliding baffle 41, the second positioning screw 52 in threaded connection with the assembly seat 51 can be adjusted to rotate, the second positioning screw 52 pushes each sliding plate 232 to move towards the direction close to the core modules, so that the alignment stacking process of each row of core modules is completed, after the alignment stacking of each row of core modules is completed, the sliding baffle 41 is adjusted to slide to be separated from two core modules, then the first positioning screw 22 in threaded connection with the second installation seat 21 is adjusted to rotate, and the first positioning screw 22 pushes the two sliding plates 232 to synchronously move towards the direction close to the core modules under the action of the threaded connection by pushing the sliding seat 231, so that the whole extrusion stacking process of the two rows of core modules is completed, and the use is convenient.

As a preferred embodiment, the second side extrusion tooling 3 comprises a third mounting seat 31, a third positioning screw 32 and a side extrusion block 33, wherein the third mounting seat 31 is arranged on the mounting panel 1; the third positioning screw 32 is in threaded connection with the third mounting seat 31; the side extrusion piece 33 is slidably disposed on the mounting panel 1, the cell module is abutted against one side of the side extrusion piece 33 and slides in a direction approaching or separating from the cell module, and one end of the third positioning screw 32 is rotatably connected with the side extrusion piece 33.

In specific implementation, the third positioning screw 32 is rotated, and at this time, the third positioning screw 32 pushes the side extrusion block 33 to slide in a direction approaching to the battery cell module under the action of threaded connection, so as to complete extrusion stacking processing of the battery cell module.

As a preferred embodiment, the device further comprises a pressure detection mechanism 6, wherein the pressure detection mechanism 6 comprises a pressure sensor 61 and a pressure sensor digital display 62, and the number of the pressure sensors 61 is plural and is respectively arranged at one side of the sliding plate 232 close to the battery cell module and one side of the side extrusion block 33 close to the battery cell module; the number of the pressure sensor digital displays 62 is plural, and the pressure sensor digital displays 62 are all arranged on the mounting panel 1 and are respectively electrically connected with the pressure sensors 61 for displaying pressure detection data of the pressure sensors 61.

In specific implementation, when the sliding plate 232 or the lateral extrusion block 33 is adjusted to slide in a direction approaching to the cell module, the pressure sensor 61 is stressed and gradually increased, the pressure sensor digital display 62 displays the pressure detection data of the pressure sensor 61, and when the data displayed by the pressure sensor digital display 62 reach an ideal value, the rotation of the second positioning screw 52 or the third positioning screw 32 is stopped, so that the cell module can be protected, the extrusion force is prevented from being too large, and a user can be helped to judge whether the cell module is aligned.

As a preferred embodiment, the device further comprises an end insulating sheet 7, wherein the end insulating sheet 7 comprises a pushing core part 71 and a limiting part 72, and the pushing core part 71 is arranged on the pressure sensor 61 and is in contact with the cell module, and one side surface of the pushing core part, which is in contact with the cell module, is a plane; the limiting portion 72 is disposed on the pushing core portion 71 and is shielded at a side of the cell module away from the mounting panel 1, for limiting the cell module in a vertical direction.

By means of the design, when the battery cell module is pushed through the end insulating sheet 7, the battery cell module can be protected by arranging the pushing core 71 to abut against one side surface of the battery cell module to be a plane, meanwhile, the mutual stacking effect of the battery cell module is improved, the battery cell module is prevented from being far away from one side of the installation panel 1 by arranging the limiting part 72, the limiting part 72 can limit the battery cell module from the top when the battery cell module is extruded, the battery cell module is prevented from moving towards the top under the action of extrusion force, and the mutual stacking stability of the battery cell module is improved.

As a preferred embodiment, the battery cell module further comprises a bump 8, wherein the bump 8 is arranged on one side of the side extrusion block 33 close to the battery cell module, and the bump 8 is abutted against the battery cell module.

The battery core module is extruded by arranging the convex blocks 8, and gaps are reserved between the convex blocks 8 and the battery core module, so that later-stage users can conveniently carry out steel belt sleeving treatment on the battery core module which is stacked.

The working principle of the utility model is described as follows:

two rows of cell modules are respectively placed on the mounting panel 1, the two rows of cell modules are respectively positioned on two opposite sides of the sliding baffle 41, then the second positioning screw 52 and the third positioning screw 32 are rotated, at this time, the second positioning screw 52 pushes the end insulating sheet 7 to move towards the direction close to the cell modules, so that the respective extrusion stacking treatment of each row of cell modules is completed, the third positioning screw 32 pushes the side extrusion block 33 to slide towards the direction close to the cell modules from two sides, and each row of cell modules acts on the sliding baffle 41, so that the simultaneous extrusion stacking treatment of each row of cell modules is completed. Because tip insulating piece 7 comprises pushing away core 71 and spacing portion 72 two parts, pushing away core 71 and contradicting a side of electric core module and be the plane, can protect electric core module, increased electric core module's mutual stacking effect simultaneously, shelter from the one side of keeping away from installation panel 1 at electric core module through setting up spacing portion 72, when pressing electric core module, spacing portion 72 can follow the top and carry out spacingly to electric core module, prevents that electric core module from receiving the extrusion force effect to remove to the top, has increased the stability that electric core module piles up each other. In the stacking process, the pressure sensor digital display 62 displays pressure detection data of the pressure sensor 61, and when the data displayed by the pressure sensor digital display 62 reach an ideal value, the rotation of the second positioning screw 52 or the third positioning screw 32 is stopped, so that the cell module can be protected, the extrusion force is prevented from being too large, and a user can be helped to judge whether the cell module is aligned. After the mutual alignment stacking of each row of cell modules is completed, the sliding baffle 41 is adjusted to slide to be separated from the two rows of cell modules, the positioning plug pins 44 can be adjusted to pass through the positioning insertion holes 43, the positioning processing of the sliding position of the sliding baffle 41 relative to the first mounting seat 42 is completed, the middle separation sheet is stuck on one side of the single row of cell modules close to the adjacent cell modules, the first positioning screw 22 and the third positioning screw 32 are adjusted to rotate, at the moment, the first positioning screw 22 pushes the two end insulation sheets 7 to synchronously move towards the direction close to the cell modules by pushing the sliding seat 231, and the third positioning screw 32 pushes the two rows of cell modules to move towards the side close to each other, so that the stacking processing of the two rows of cell modules can be completed at the same time by the whole stacking tool, and the stacking efficiency is high and the use is convenient.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (10)

1. A lithium battery module stacks frock, its characterized in that: comprises a mounting panel (1), two first side extrusion tools (2), two second side extrusion tools (3) and a sliding component (4), wherein,

the mounting panel (1) is supported with a battery core module;

the sliding assembly (4) comprises a sliding baffle (41), wherein the sliding baffle (41) is arranged on the mounting panel (1) in a sliding manner and is perpendicular to the mounting panel (1) and slides towards or away from the mounting panel (1);

the two first side extrusion tools (2) are arranged on the mounting panel (1) and are positioned on two opposite sides of the sliding baffle (41) and used for pushing the battery cell module towards the sliding baffle (41);

two second side extrusion frock (3) all set up on installation panel (1), and be located slide damper (41) are relative both sides, respectively with two first side extrusion frock (2) are adjacent setting, are used for to slide damper (41) side push cell module.

2. The lithium battery module stacking tool as claimed in claim 1, wherein: the sliding assembly (4) further comprises a first mounting seat (42) and a positioning bolt (44), wherein,

the first mounting seat (42) is detachably arranged on the mounting panel (1), the sliding baffle (41) is slidably arranged on the first mounting seat (42), and a plurality of positioning jacks (43) are formed in the first mounting seat (42) and the sliding baffle (41);

the positioning bolt (44) passes through the sliding baffle (41) and the positioning insertion hole (43) formed in the first mounting seat (42) and is used for positioning the sliding position of the sliding baffle (41) relative to the first mounting seat (42).

3. The lithium battery module stacking tool as claimed in claim 2, wherein: the sliding assembly (4) further comprises a mounting screw (45), wherein,

the assembly screw rod (45) is movably arranged on the first mounting seat (42) and is in threaded connection with the mounting panel (1) and used for positioning the position of the first mounting seat (42) relative to the mounting panel (1).

4. The lithium battery module stacking tool as claimed in claim 1, wherein: the first side extrusion tooling (2) comprises a second mounting seat (21), a first positioning screw (22) and a side extrusion assembly (23), wherein,

a second mounting seat (21) arranged on the mounting panel (1);

the first positioning screw rod (22) is in threaded connection with the second mounting seat (21);

the side extrusion assembly (23) is arranged on the mounting panel (1) in a sliding manner, the battery cell module is abutted to one side of the side extrusion assembly (23), the side extrusion assembly (23) slides towards the direction close to or far away from the battery cell module, and one end of the first positioning screw (22) is rotationally connected with the side extrusion assembly (23).

5. The lithium battery module stacking tool as set forth in claim 4, wherein: the first side extrusion tooling (2) further comprises a positioning rotary rod (24), wherein,

the positioning rotating rod (24) is arranged at one end of the first positioning screw rod (22) far away from the side extrusion assembly (23).

6. The lithium battery module stacking tool as set forth in claim 4, wherein: the side extrusion assembly (23) comprises a sliding seat (231) and a sliding connection plate (232), and also comprises a single-row cell extrusion tool (5), wherein the single-row cell extrusion tool (5) comprises an assembly seat (51) and a second positioning screw (52),

the sliding seat (231) is arranged on the mounting panel (1) in a sliding manner and is rotationally connected with the first positioning screw rod (22);

the number of the sliding plates (232) is four, two sliding plates (232) are arranged on each sliding seat (231) in a sliding manner, the cell module is abutted to one side of the sliding plates (232), and the sliding plates (232) slide towards the direction approaching or far away from the cell module;

the four assembly seats (51) are respectively arranged on the two sliding connection seats (231) and are respectively arranged on adjacent sides of the four sliding connection plates (232);

the second positioning screw rod (52) is in threaded connection with the assembly seat (51) and is in rotary connection with the sliding seat (231).

7. The lithium battery module stacking tool as set forth in claim 6, wherein: the second side extrusion tooling (3) comprises a third mounting seat (31), a third positioning screw (32) and a side extrusion block (33), wherein,

a third mounting seat (31) arranged on the mounting panel (1);

the third positioning screw (32) is in threaded connection with the third mounting seat (31);

the side extrusion block (33) is arranged on the installation panel (1) in a sliding manner, the battery cell module is abutted to one side of the side extrusion block (33) and slides towards the direction close to or far away from the battery cell module, and one end of the third positioning screw (32) is rotationally connected with the side extrusion block (33).

8. The lithium battery module stacking tool of claim 7, wherein: the device also comprises a pressure detection mechanism (6), wherein the pressure detection mechanism (6) comprises a pressure sensor (61) and a pressure sensor digital display (62),

the pressure sensors (61) are arranged on one side, close to the battery cell module, of the sliding plate (232) and one side, close to the battery cell module, of the side extrusion block (33) respectively;

the pressure sensor digital displays (62) are arranged on the mounting panel (1) in a plurality, are respectively and electrically connected with the pressure sensors (61), and are used for displaying pressure detection data of the pressure sensors (61).

9. The lithium battery module stacking tool of claim 8, wherein: also comprises an end insulating sheet (7), wherein the end insulating sheet (7) comprises a pushing core part (71) and a limiting part (72),

the pushing core part (71) is arranged on the pressure sensor (61) and is abutted against the cell module, and one side surface of the pushing core part, which is abutted against the cell module, is a plane;

and the limiting part (72) is arranged on the pushing core part (71) and is shielded on one side of the battery cell module far away from the mounting panel (1) and used for limiting the battery cell module in the vertical direction.

10. The lithium battery module stacking tool of claim 7, wherein: also comprises a bump (8), wherein,

the lug (8) is arranged on one side, close to the battery cell module, of the side extrusion block (33), and the lug (8) is abutted against the battery cell module.

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