CN218422162U

CN218422162U - Lithium cell production is with batching agitating unit

Info

Publication number: CN218422162U
Application number: CN202221639249.3U
Authority: CN
Inventors: 时敏杰
Original assignee: Cornex New Energy Co ltd
Current assignee: Cornex New Energy Co ltd
Priority date: 2022-06-28
Filing date: 2022-06-28
Publication date: 2023-02-03
Anticipated expiration: 2032-06-28

Abstract

The utility model provides a batching and stirring device for lithium battery production, which comprises an operation table, a tank body, a stirring mechanism, a stand column, a guide rod, a cover body and a feeding mechanism; a tank body is arranged at the top of the operating platform; the upright column is arranged at the edge of the horizontal length extending direction of the operating platform, and a hollow cavity is arranged inside the upright column; one end of the stirring mechanism is arranged at one end of the upright column far away from the operating platform, and the other end of the stirring mechanism horizontally extends to the position right above the center of the tank body along the radial direction of the upright column; the guide rod is embedded in the cavity; the feeding mechanism is arranged at one end of the guide rod, which extends out of the upright post, one end of the feeding mechanism is fixedly connected with the guide rod, and the other end of the feeding mechanism extends outwards horizontally along the radial direction of the guide rod; the cover body is covered on the top of the tank body, and a first through hole and a second through hole which are communicated are formed in the cover body; the stirring mechanism penetrates through the first through hole and extends into the tank body; the feeding mechanism rotates relatively along with the guide rod and extends into the tank body through the second through hole.

Description

Lithium cell production is with batching agitating unit

Technical Field

The utility model relates to a lithium cell coating dispensing equipment technical field especially relates to a lithium cell production is with batching agitating unit.

Background

In the experimental research stage or the batch production stage of the battery, it is often necessary to frequently prepare coatings of different formulations, apply the coatings on the surfaces of foils in a manner of a bar scraper, a scraper, extrusion or roll coating, and further obtain pole pieces after rolling, drying or shearing so as to perform subsequent production after the battery core. During a paint preparation test, a plurality of different reagents or raw materials need to be quantitatively filled, manual stirring or continuous stirring by adopting stirring equipment is needed, a paint container is heated, high-temperature paint can splash, operators are burnt, and splashed raw materials are wasted.

Therefore, it is very necessary to develop a batching and stirring device which is convenient for filling and replacing reagent and not easy to splash and burn operators.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a lithium cell production that can not splash when convenient operation, reinforced accurate, heating stirring is with batching agitating unit.

The technical scheme of the utility model is realized like this: the utility model provides a batching and stirring device for lithium battery production, which comprises an operation platform (1), a tank body (2), a stirring mechanism (3), a stand column (4), a guide rod (5), a cover body (6) and a feeding mechanism (7); the top of the operating platform (1) is provided with a tank body (2), and the top of the tank body (2) is relatively fixedly provided with a stirring mechanism (3);

the upright post (4) is arranged at the edge position of the horizontal length extending direction of the operating platform (1), one end of the upright post (4) is fixedly connected with the operating platform (1), and the other end of the upright post (4) vertically extends upwards in the direction far away from the operating platform (1); a hollow cavity (100) is arranged in the upright post (4);

one end of the stirring mechanism (3) is arranged at one end of the upright post (4) far away from the operating platform (1), and the other end of the stirring mechanism (3) horizontally extends to the position right above the center of the tank body (2) along the radial direction of the upright post (4);

the guide rod (5) is embedded in the cavity (100), and the outer surface of the guide rod (5) is connected with the inner surface of the cavity (100) in a sliding or rotating manner; one end of the guide rod (5) extends into the cavity (100), and the other end of the guide rod (5) vertically penetrates through the upright post (4) and extends outwards;

the feeding mechanism (7) is arranged at one end, extending out of the upright post (4), of the guide rod (5), one end of the feeding mechanism (7) is fixedly connected with the guide rod (5), and the other end of the feeding mechanism (7) extends outwards horizontally along the radial direction of the guide rod (5);

the cover body (6) is covered on the top of the tank body (2), a first through hole (200) and a second through hole (300) which are communicated are formed in the cover body (6), and an openable cover plate (61) is arranged at the second through hole (300); the stirring mechanism (3) penetrates through the first through hole (200) and extends into the tank body (2); the feeding mechanism (7) rotates clockwise or anticlockwise relative to the upright post (4) along with the guide rod (5) and abuts against the side surface of the stirring mechanism (3); the feeding mechanism (7) selectively opens the cover plate (61) and penetrates through the second through hole (300) to feed materials into the tank body (2); the cover body (6) is detachably connected with the tank body (2).

On the basis of the above technical solution, preferably, the stirring mechanism (3) includes a first fixing ring (31), a first support plate (32), a driving motor (33), and a stirring part (34); the first fixing ring (31) is embedded in the cavity (100) of the upright post (4), a through third through hole (400) is formed in the center of the first fixing ring (31), and the third through hole (400) is communicated with the cavity (100) of the upright post (4); the fixed surface that sets up in first solid fixed ring (31) of first backup pad (32), the one end that first solid fixed ring (31) was kept away from in first backup pad (32) is provided with the first heavy groove that link up, driving motor (33) inlay is established in first heavy inslot, first through-hole (200) and the downward extension of along jar body (2) center pin direction are passed to the axis of rotation vertical of driving motor (33), the tip of the axis of rotation of driving motor (33) is provided with curved stirring portion (34).

Preferably, the stirring part (34) is plate-shaped, and a plurality of through turbulence holes are formed in the edge of the stirring part (34).

Preferably, the guide rod (5) is embedded in the third through hole (400), one end of the guide rod (5) extends towards the inside of the cavity (100), and the other end of the guide rod (5) vertically extends upwards; at least two clamping grooves (401) are arranged at the edge of the outline of the third through hole (400) at intervals, and each clamping groove (401) vertically extends along the axial direction of the third through hole (400); the outer surface of the guide rod (5) is provided with a clamping plate (51), the clamping plate (51) extends outwards along the radial direction of the guide rod (5), the clamping plate (51) is matched with the profile of the clamping groove (401), and the clamping plate (51) is in sliding connection with the clamping groove (401).

Further preferably, the feeding mechanism (7) comprises a second fixing ring (71), a second supporting plate (72), a material pipe (73) and a pushing cylinder (74); the second fixing ring (71) is arranged around the outer surface of the guide rod (5), one end of the second supporting plate (72) is fixedly connected with the outer surface of the second fixing ring (71), and the other end of the second supporting plate (72) horizontally extends along the radial direction of the guide rod (5); a through second sinking groove is formed in the second supporting plate (72), a hollow material pipe (73) is embedded in the second sinking groove, and a push cylinder (74) is arranged in the material pipe (73); the push cylinder (74) is connected with the inner surface of the material pipe (73) in a sliding manner along the axial direction of the material pipe (73); the end part of the material pipe (73) penetrates through the second through hole (300) to push the cover plate (61) and extend into the tank body (2).

Further preferably, the side surface of the first supporting plate (32) is provided with an arc-shaped positioning part (321), and the side surface of the positioning part (321) is adapted to the contour of the material pipe (73).

Further preferably, the side surface of the positioning part (321) is detachably connected with the outer surface of the material pipe (73).

Preferably, the diameter of the rotating shaft of the driving motor (33) does not exceed the diameter of the first through hole (200), and the diameter of the end of the push cylinder (74) far away from the second supporting plate (72) does not exceed the diameter of the second through hole (300).

Preferably, the horizontal included angle of the clamping groove (401) corresponding to the arc-shaped positioning part (321) relative to the initial position of the clamping plate (51) is 150-155 degrees.

On the basis of the technical scheme, preferably, the material pipe (73) is provided with scale marks.

On the basis of the technical scheme, preferably, a heater is further arranged in the operating platform (1), the heater is arranged close to the bottom of the tank body (2), and a heat conducting layer (500) is arranged between the bottom of the tank body (2) and the heater.

The utility model provides a pair of lithium cell production is with batching agitating unit for prior art, has following beneficial effect:

(1) The batching and stirring device for lithium battery production can quantitatively add batching on the premise of not moving the tank body and the stirring mechanism, reduce the possibility of direct contact between an operator and the batching, and ensure the personal safety of the operator;

(2) Can carry on spacingly by the draw-in groove that corresponds the position and the side surface of location portion after reinforced mechanism reachs designated position, prevent because of the rabbling mechanism vibration, the reinforced mechanism position change that leads to promotes the stability of throwing the material process.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a front view of the batching and stirring device for lithium battery production of the present invention;

FIG. 2 is a front view of a half-section of a feeding mechanism and a guide rod of a batching and stirring device for lithium battery production, which vertically move along an upright post;

FIG. 3 is a sectional view taken along line A-A of FIG. 1;

FIG. 4 is a partial sectional view taken along line B-B of FIG. 1;

FIG. 5 is an enlarged view of a portion C of FIG. 2;

FIG. 6 is an enlarged view of a portion D of FIG. 2;

FIG. 7 is a front view of a cover body of a batching and stirring device for lithium battery production according to the present invention;

fig. 8 is the utility model relates to a lithium cell production is with batching agitating unit's reinforced mechanism's rotational position schematic diagram.

Detailed Description

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

As shown in fig. 1, 2 and 7, the utility model provides a batching and stirring device for lithium battery production, which comprises an operation table 1, a tank body 2, a stirring mechanism 3, a stand column 4, a guide rod 5, a cover body 6 and a feeding mechanism 7; the top of the operating platform 1 is provided with a tank body 2, and the top of the tank body 2 is relatively fixedly provided with a stirring mechanism 3; the operation platform 1 is a foundation for placing the tank body 2 and supporting the stirring mechanism 3 and the feeding mechanism 7.

The upright post 4 is arranged at the edge position of the horizontal length extending direction of the operating platform 1, one end of the upright post 4 is fixedly connected with the operating platform 1, and the other end of the upright post 4 vertically extends upwards towards the direction far away from the operating platform 1; a hollow cavity 100 is arranged in the upright post 4; the column 4 is used for accommodating the guide rod 5 and providing a lifting space for the guide rod 5.

One end of the stirring mechanism 3 is arranged at one end of the upright post 4 far away from the operating platform 1, and the other end of the stirring mechanism 3 horizontally extends to the position right above the center of the tank body 2 along the radial direction of the upright post 4; the stirring mechanism 3 is used for stirring various materials in the tank body 2.

The guide rod 5 is embedded in the cavity 100, and the outer surface of the guide rod 5 is connected with the inner surface of the cavity 100 in a sliding or rotating manner; one end of the guide rod 5 extends into the cavity 100, and the other end of the guide rod 5 vertically penetrates through the upright post 4 and extends outwards; the guide rod 5 is used for driving the feeding mechanism to lift or rotate to reach a specified position above the tank body 2.

The feeding mechanism 7 is arranged at one end of the guide rod 5 extending out of the upright post 4, one end of the feeding mechanism 7 is fixedly connected with the guide rod 5, and the other end of the feeding mechanism 7 extends outwards horizontally along the radial direction of the guide rod 5;

the cover body 6 is covered on the top of the tank body 2, a first through hole 200 and a second through hole 300 which are communicated are arranged on the cover body 6, and an openable cover plate 61 is arranged at the second through hole 300; the stirring mechanism 3 passes through the first through hole 200 and extends into the tank body 2; the feeding mechanism 7 rotates clockwise or anticlockwise relative to the upright post 4 along with the guide rod 5 and abuts against the side surface of the stirring mechanism 3; the feeding mechanism 7 selectively opens the cover plate 61 and penetrates through the second through hole 300 to feed materials into the tank body 2; the cover body 6 is detachably connected with the tank body 2. As can be seen, the first through hole 200 is correspondingly disposed at the center of the cover 6. Because the feeding mechanism 7 rotates to a certain angle, the feeding mechanism 7 can be abutted to the stirring mechanism 3, and the feeding mechanism 7 can penetrate through the second through hole 300 and the cover plate 61 and extend into the tank body 2 for feeding.

As shown in fig. 2 and 3, the stirring mechanism 3 includes a first fixing ring 31, a first support plate 32, a drive motor 33, and a stirring section 34; the first fixing ring 31 is embedded in the cavity 100 of the upright post 4, a through third through hole 400 is formed in the center of the first fixing ring 31, and the third through hole 400 is communicated with the cavity 100 of the upright post 4; the fixed surface that sets up at first solid fixed ring 31 of first backup pad 32, the one end that first backup pad 32 kept away from first solid fixed ring 31 is provided with the first heavy groove that link up, and driving motor 33 inlays and establishes in first heavy inslot, and driving motor 33's the vertical first through-hole 200 of passing of axis of rotation just extends along jar body 2 center pin direction downwardly, and the tip of driving motor 33's axis of rotation is provided with curved stirring portion 34. The drive motor 33 may be a servo motor. The first sunken groove is used for limiting the fixing position of the driving motor 33 on the first fixing ring 31, and in order to reduce the adverse effect caused by the vibration of the motor, a rubber cushion pad can be arranged between the driving motor 33 and the first fixing ring 31, and a bearing can be further arranged between the output shaft of the driving motor 33 and the first fixing ring 31. As shown in the enlarged partial view of fig. 5, the stirring portion 34 is plate-shaped, and a plurality of flow disturbing holes are formed at the edge of the stirring portion 34. The stirring part is U-shaped as a whole, and the center of the stirring part is close to the inner surface of the center of the tank body 2.

As shown in fig. 2 and 3, a structure of the guide rod 5 is schematically shown, the guide rod 5 is embedded in the third through hole 400, one end of the guide rod 5 extends towards the inside of the chamber 100, and the other end of the guide rod 5 extends vertically upwards; at least two clamping grooves 401 are arranged at the edge of the outline of the third through hole 400 at intervals, and each clamping groove 401 vertically extends along the axial direction of the third through hole 400; the outer surface of the guide rod 5 is provided with a clamping plate 51, the clamping plate 51 extends outwards along the radial direction of the guide rod 5, the clamping plate 51 is matched with the contour of the clamping groove 401, and the clamping plate 51 is connected with the clamping groove 401 in a sliding mode. The guide rod 5 can rotate relative to the first fixing ring 31, in order to limit the rotation angle of the guide rod 5 and prevent the shaking of the feeding mechanism 7 caused by the vibration of the driving motor 33 when the guide rod 5 rotates, clamping grooves 401 are formed in the edges of the third through

hole

400, 3 clamping grooves 401 are shown in the figure, one clamping groove is in an initial position, the other two clamping grooves 401 are symmetrically distributed at positions adjacent to the stirring mechanism 3, and the distribution corresponds to the limit angle of clockwise or counterclockwise rotation of the guide rod 5. The length of the catch plate 51 is smaller than that of the guide rods 5, and when the catch plate 51 is completely pulled out of the catch groove 401, the guide rods 5 can rotate freely.

In order to prevent interference with the first fixing ring 31 when the guide rod 5 is rotated to the limit position, the feeding process is preferably prevented. An arc-shaped positioning part 321 is specially arranged on the side surface of the first support plate 32, and the side surface of the positioning part 321 is adapted to the contour of the material pipe 73. The arc-shaped positioning portion 321 corresponds to the slot 401 when the guide rod 5 rotates to the extreme position. As can be seen from FIG. 3, the included angle between the card slot 401 at the horizontal position on the left side and the card slots symmetrically arranged on the other two sides is 150-155 degrees, namely the maximum angle of clockwise rotation or counterclockwise rotation.

Further, in order to prevent the positioning portion 321 and the material pipe 73 from being unintentionally separated during the feeding process, a side surface of the positioning portion 231 may be detachably connected to an outer surface of the material pipe 73. This kind of detachable connects, can adopt magic subsides or ferromagnetic material to make, and magic subsides or ferromagnetic material are fixed respectively and are set up the surface at the lateral surface of location portion 231 or material pipe 73 to improve material pipe 73 and follow the stability when guide arm 5 rotates extreme position.

As shown in fig. 2 and 4, the charging mechanism 7 includes a second fixing ring 71, a second support plate 72, a material pipe 73, and a push cylinder 74; the second fixing ring 71 is arranged around the outer surface of the guide rod 5, one end of the second supporting plate 72 is fixedly connected with the outer surface of the second fixing ring 71, and the other end of the second supporting plate 72 horizontally extends along the radial direction of the guide rod 5; a through second sinking groove is formed in the second supporting plate 72, a hollow material pipe 73 is embedded in the second sinking groove, and a push cylinder 74 is arranged in the material pipe 73; the push cylinder 74 is connected with the inner surface of the material pipe 73 in a sliding manner along the axial direction of the material pipe 73; the end of the pipe 73 passes through the second through hole 300, pushes the cover 61 and extends into the tank 2. The second support plate 72 is correspondingly provided with a second sinking groove, and the joint part of the second sinking groove and the material pipe 73 can also be isolated by using a rubber buffer. The material pipe 73 and the push cylinder 74 can slide in a damping mode, and can also realize axial movement along the material pipe 73 in a threaded connection mode. The tube 73 and the second support plate 72 are preferably removable to facilitate changing different types of materials.

As can be further understood from fig. 7, the diameter of the rotating shaft of the driving motor 33 does not exceed the diameter of the first through hole 200, and the diameter of the end of the pushing cylinder 74 away from the second supporting plate 72 does not exceed the diameter of the second through hole 300. The apron 61 of this scheme can adopt the torsional spring to be connected with the 6 hinges of lid, and when not reinforced, the output shaft of driving motor 33 can the shutoff almost first through-hole, and apron 61 can shield the second through-hole, combines with lid 6, can prevent that the raw materials from splashing, in order to dispel the heat or exhaust, can further set up one or more exhaust holes on lid 6 surface.

In order to observe the volume of the material fed into the material tank 73 conveniently, scale marks can be arranged on the material pipe 73. Of course, the corresponding tube 73 can be made of transparent material. Such as plastic or glass.

A heater is also arranged in the operating platform 1, the heater is arranged close to the bottom of the tank body 2, and a heat conducting layer 500 is arranged between the bottom of the tank body 2 and the heater. The bottom of the tank body 2 is a plane, and for uniform heat transfer, the heat conducting layer 500 can be an asbestos mesh or a pottery clay mesh instead of the asbestos mesh, so that the temperature of the bottom of the tank body 2 is uniform while heat transfer and heat insulation are realized.

The utility model discloses a use does: placing the tank body and the stirring mechanism 3 on the workbench 1, and covering the cover body 6; enabling an output shaft of a driving motor 33 of the stirring mechanism 3 to penetrate through the first window and extend into the tank body, and starting the driving motor 33 to stir the materials added in advance in the tank body 2; the guide rod 5 is arranged in a clamping groove 401 at an initial position far away from one side of the stirring mechanism 3, a material pipe 73 containing materials to be added and a push cylinder 74 are assembled and then placed in a second sinking groove of a second supporting plate 72, then the guide rod 5 is pulled vertically to enable a clamping plate 51 to be separated from the current clamping groove 401, the guide rod 5 is further rotated clockwise or anticlockwise to a limit position, the guide rod 5 is lowered to enable the clamping plate 51 at the current position to be clamped with one clamping groove 401 at the limit position, namely after the material tank 73 is attached and locked with a positioning part 321, the push cylinder 74 is rotated or pushed, the materials in the material tank 73 pass through a second through hole and a cover plate 61 and are sent into the tank body 2, namely the material adding is completed, then the guide rod 5 is pulled to enable the material tank 73 to be separated from the positioning part 321, the guide rod 5 is returned to the initial position to wait for the next material adding, or the material pipe 73 containing another material and the push cylinder 74 are replaced, and the next material adding is waited for the next material adding.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. A batching and stirring device for lithium battery production comprises an operation platform (1), a tank body (2) and a stirring mechanism (3), wherein the tank body (2) is arranged at the top of the operation platform (1), and the stirring mechanism (3) is relatively and fixedly arranged at the top of the tank body (2); the device is characterized by also comprising a stand column (4), a guide rod (5), a cover body (6) and a feeding mechanism (7);

2. The batching and stirring device for lithium battery production according to claim 1, wherein said stirring mechanism (3) comprises a first fixing ring (31), a first supporting plate (32), a driving motor (33) and a stirring part (34); the first fixing ring (31) is embedded in the cavity (100) of the upright post (4), a through third through hole (400) is formed in the center of the first fixing ring (31), and the third through hole (400) is communicated with the cavity (100) of the upright post (4); the fixed surface that sets up in first solid fixed ring (31) of first backup pad (32), the one end that first solid fixed ring (31) was kept away from in first backup pad (32) is provided with the first heavy groove that link up, driving motor (33) inlay is established in first heavy inslot, first through-hole (200) and the downward extension of along jar body (2) center pin direction are passed to the axis of rotation vertical of driving motor (33), the tip of the axis of rotation of driving motor (33) is provided with curved stirring portion (34).

3. The ingredients stirring device for lithium battery production as claimed in claim 2, wherein the stirring part (34) is plate-shaped, and a plurality of through flow disturbing holes are arranged at the edge of the stirring part (34).

4. The ingredients stirring device for lithium battery production as claimed in claim 2, wherein the guide rod (5) is embedded in the third through hole (400), one end of the guide rod (5) extends towards the inside of the cavity (100), and the other end of the guide rod (5) extends vertically upwards; at least two clamping grooves (401) are arranged at the edge of the outline of the third through hole (400) at intervals, and each clamping groove (401) vertically extends along the axial direction of the third through hole (400); the outer surface of the guide rod (5) is provided with a clamping plate (51), the clamping plate (51) extends outwards along the radial direction of the guide rod (5), the clamping plate (51) is matched with the profile of the clamping groove (401), and the clamping plate (51) is in sliding connection with the clamping groove (401).

5. The batching and stirring device for lithium battery production according to claim 4, wherein the feeding mechanism (7) comprises a second fixing ring (71), a second supporting plate (72), a material pipe (73) and a pushing cylinder (74); the second fixing ring (71) is arranged around the outer surface of the guide rod (5), one end of the second supporting plate (72) is fixedly connected with the outer surface of the second fixing ring (71), and the other end of the second supporting plate (72) horizontally extends along the radial direction of the guide rod (5); a through second sinking groove is formed in the second supporting plate (72), a hollow material pipe (73) is embedded in the second sinking groove, and a push cylinder (74) is arranged in the material pipe (73); the push cylinder (74) is connected with the inner surface of the material pipe (73) in a sliding manner along the axial direction of the material pipe (73); the end part of the material pipe (73) penetrates through the second through hole (300), pushes the cover plate (61) and extends into the tank body (2).

6. The batching and stirring device for the production of lithium batteries according to claim 5, characterized in that the side surface of the first supporting plate (32) is provided with an arc-shaped positioning part (321), and the side surface of the positioning part (321) is adapted to the profile of the material pipe (73).

7. The batching stirring device for lithium battery production according to claim 6, wherein the side surface of the positioning part (321) is detachably connected with the outer surface of the material pipe (73).

8. The ingredients stirring apparatus for lithium battery production as claimed in claim 5, wherein the diameter of the rotating shaft of the driving motor (33) does not exceed the diameter of the first through hole (200), and the diameter of the end of the pushing cylinder (74) away from the second supporting plate (72) does not exceed the diameter of the second through hole (300).

9. The batching and stirring device for lithium battery production as recited in claim 4, wherein the horizontal included angle of the clamping groove (401) corresponding to the arc-shaped positioning part (321) relative to the initial position of the clamping plate (51) is 150-155 °.