CN214114093U - Automatic batch feeding mechanism for battery top cover plate electrode columns - Google Patents

Abstract

The utility model discloses an automatic batch feed mechanism of battery top plate electrode post, including the frame, install material loading transport mechanism, material loading elevating system and material loading clamping mechanism in the frame, the last material loading that is used for bearing a plurality of electrode post holding plate that pile up in proper order of installing of material loading elevating system bears the frame, and material loading transport mechanism's output and material loading bear the removal route of frame and intersect, still set up material loading clamping mechanism on material loading elevating system's the removal route. The utility model discloses a material loading elevating system drive material loading bears the frame and moves to material loading transport mechanism's output, material loading transport mechanism will pile up electrode column containing plate and convey to the material loading and bear the frame, material loading elevating system drive material loading bears the frame and moves to material loading clamping mechanism department, material loading clamping mechanism presss from both sides the electrode column containing plate at top tightly, the manipulator of being convenient for presss from both sides at fixed position and gets the electrode column and carry out follow-up processing operation, but the not unidimensional electrode column of adaptation holds the centre gripping needs of board simultaneously, realize automatic feeding, the material loading efficiency and the material loading precision have been improved.

Description

Automatic batch feeding mechanism for battery top cover plate electrode columns

Technical Field

The utility model relates to a battery top cap piece equipment technical field, concretely relates to automatic batch feeding mechanism of battery top cap piece electrode post.

Background

Under the large background of sustainable development, the dependence on renewable energy resources is gradually weakened, and the fuel vehicles are continuously sold in all countries of the world in a policy of forbidding sale, so that the market prospect of new energy vehicles is promoted to be good. At present, domestic new energy passenger vehicles are in a starting stage, and the increment of the new energy passenger vehicles is increased explosively in the next 5-8 years. Therefore, the demand of the lithium battery precision part is increased in a geometric series manner, conditions such as high safety, low cost, high production efficiency and the like are urgently needed for processing and assembling the lithium battery precision part, and the production of the lithium battery precision part is inevitably developed to automatic production. Therefore, it is necessary to provide a mechanism for automatically feeding the electrode column.

Disclosure of Invention

In view of the above analysis, the utility model provides an automatic batch feed mechanism of battery top plate electrode post is in order to solve the not enough of prior art.

The utility model discloses mainly realize through following technical scheme:

the utility model provides an automatic batch feeding mechanism of battery top cover plate electrode posts, which comprises a frame, a feeding conveying mechanism, a feeding lifting mechanism and a feeding clamping mechanism are installed on the frame, a feeding bearing frame for bearing a plurality of electrode post containing plates stacked in sequence is installed on the feeding lifting mechanism, the output end of the feeding conveying mechanism is intersected with the moving path of the feeding bearing frame, and the feeding clamping mechanism is also arranged on the moving path of the feeding lifting mechanism; the feeding clamping mechanism comprises at least two first driving cylinders, a first clamping block is mounted on a piston rod of each first driving cylinder, and a first clamping groove is formed in each first clamping block.

Further, still install handling mechanism in the frame, install unloading clamping mechanism in the handling mechanism, material loading clamping mechanism is located unloading clamping mechanism's removal route.

The carrying mechanism comprises a horizontal moving mechanism and a third lifting mechanism, the third lifting mechanism is installed on the horizontal moving mechanism, and the blanking clamping mechanism is installed on the third lifting mechanism.

Furthermore, still install unloading elevating system and unloading transport mechanism in the frame, the unloading bears the frame on the unloading elevating system, unloading clamping mechanism is located the removal route that the unloading bore, the input of unloading transport mechanism is crossing with the removal route that the unloading bore.

Further, the feeding conveying mechanism comprises a first driving motor and a transmission mechanism, the transmission mechanism comprises a driving wheel, a driven wheel and a conveyor belt, the driving wheel is installed on an output shaft of the first driving motor and is in transmission connection with the driven wheel through the conveyor belt, at least two groups of transmission mechanisms are arranged oppositely, the two driving wheels are connected through the transmission shaft, a receiving plate is arranged between the two transmission mechanisms and is located between the transmission shaft and the upper surface of the conveyor belt, and the feeding bearing frame is connected with the receiving plate when being intersected between the two transmission mechanisms.

Furthermore, a supporting frame for supporting the conveying belt is arranged between the two transmission mechanisms, and the bearing plate is arranged on the supporting frame.

Further, the electrode column holding plate comprises a plate body, a plurality of electrode column holding areas are arranged on the plate body, a plurality of first positioning portions are arranged on the upper surface of the plate body, a plurality of second positioning portions are arranged on the lower surface of the plate body, and the second positioning portions are matched with the first positioning portions so as to stack the plurality of electrode column holding plates.

Furthermore, a plurality of first clamping blocks arranged at intervals and a plurality of second clamping blocks arranged at intervals are arranged on the plate body, the first clamping blocks and the second clamping blocks are arranged in a staggered mode, arc-shaped clamping grooves are formed in the side faces of the first clamping blocks and the side faces of the second clamping blocks respectively, and the first clamping blocks and the second clamping blocks are matched to form an electrode column accommodating area.

Furthermore, the plate body is provided with an opening, the opening is provided with a plurality of first grid bars arranged at intervals and a plurality of second grid bars arranged at intervals, the first grid bars and the second grid bars are arranged in a crossed mode, the first clamping blocks are arranged on the first grid bars, and the second clamping blocks are arranged on the second grid bars.

Further, be equipped with the casing in the frame, be equipped with material loading mouth and feed opening on the casing, material loading clamping mechanism sets up at the material loading mouth, the material loading mouth sets up respectively on the removal route that material loading clamping mechanism and material loading bore, the feed opening sets up respectively on the removal route that material loading clamping mechanism and material loading bore.

Furthermore, a third clamping mechanism is further installed on the rack, and the third clamping mechanism is respectively located on the moving paths of the blanking clamping mechanism and the blanking bearing frame.

Compared with the prior art the utility model discloses technical scheme's beneficial effect does:

1. the output that material loading elevating system drive material loading bore and remove to material loading transport mechanism, material loading transport mechanism will pile up electrode column container board conveys to the material loading and bears the frame, material loading elevating system drive material loading bears the frame and removes to material clamping mechanism department, material loading clamping mechanism presss from both sides the electrode column container board at top tightly, the manipulator of being convenient for is got the electrode column at fixed position clamp and is carried out follow-up processing operation, but the not unidimensional electrode column of adaptation holds the centre gripping needs of board simultaneously, realize large batch electrode column automatic feeding, the material loading efficiency and material loading precision have been improved, be favorable to the assembly precision and the assembly efficiency of follow-up lithium cell.

2. Realize horizontal migration through horizontal migration mechanism, realize reciprocating through third elevating system, unloading clamping mechanism presss from both sides the electrode post holding plate and gets, will press from both sides empty electrode post holding plate after the electrode post on the unloading elevating system of feed opening department from the material loading mouth transport to the unloading of feed opening department, and automatic unloading is realized to the conveying of unloading transport mechanism at last, has improved lithium cell electrode post's production efficiency.

3. Through setting up material loading clamping mechanism at the material loading mouth respectively, the feed opening sets up third clamping mechanism, and the clamp splice on material loading clamping mechanism, the third clamping mechanism all sets up with the clamp splice dislocation on the unloading clamping mechanism for electrode post holding plate is in clamping state all the time at the in-process of material loading, transport and unloading, falls when avoiding electrode post holding plate to shift or go up unloading, and can guarantee the uniformity of unloading on the electrode post holding plate.

4. Through set up the support frame between two drive mechanism, form effective support to the conveyer belt, when preventing that the electrode column holding board that piles up from pressing on the conveyer belt, the conveyer belt sinks downwards and leads to the conveying failure, guarantees the assembly efficiency of follow-up lithium cell.

5. The upper surface and the lower surface of the electrode column containing plate are respectively provided with the positioning parts, so that the electrode column containing plates can be conveniently stacked together, and the electrode columns on the electrode column containing area can be prevented from being extruded and damaged by the surfaces of the electrode column containing plates, and the assembly quality of subsequent lithium batteries is influenced.

Drawings

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

Fig. 1 is a perspective view (one) of an automatic batch loading mechanism for battery top cover plate electrode columns provided by the embodiment of the invention;

fig. 2 is a perspective view (two) of the automatic batch loading mechanism for battery top-cover plate electrode columns provided by the embodiment of the present invention;

fig. 3 is a cross-sectional view of an automatic batch loading mechanism for battery top-cover plate electrode columns provided by the embodiment of the present invention;

fig. 4 is a schematic structural diagram (one) of a feeding and conveying mechanism provided by the embodiment of the present invention;

fig. 5 is a schematic structural view (ii) when the feeding conveying mechanism provided by the embodiment of the present invention is connected to the feeding carrier;

fig. 6 is a schematic structural diagram of an electrode column accommodating plate according to an embodiment of the present invention.

The reference numbers are as follows:

1. a frame, 2, a feeding conveying mechanism, 21, a first driving motor, 22, a transmission mechanism, 221, a driving wheel, 222, a driven wheel, 223, a conveying belt, 224, a transmission shaft, 23, a bearing plate, 24, a speed reducing mechanism, 25, a support frame, 251, a support bottom plate, 252, a side plate, 253, a second support plate, 3, a feeding lifting mechanism, 4, a feeding clamping mechanism, 41, a first driving cylinder, 42, a first clamping block, 42a, a first clamping groove, 5, a feeding bearing frame, 51, a fixing plate, 52, a bearing plate, 53, a first support plate, 6, a conveying mechanism, 61, a horizontal moving mechanism, 62, a third lifting mechanism, 7, a blanking clamping mechanism, 71, a second driving cylinder, 72, a second clamping block, 72a, a second clamping groove, 73, a mounting frame, 8, a blanking lifting mechanism, 9, a blanking bearing frame, 10, a blanking conveying mechanism, 11, a shell, 11a, a feeding port, 11b, a discharging port, 12, a third clamping mechanism, 121, a third driving cylinder, 122, a third clamping block, 122a, a third clamping groove, 13, a feeding baffle, 14, a discharging baffle, 20, an electrode column accommodating plate, 210, a plate body, 21a, an electrode column accommodating area, 21b, an opening, 211, a first positioning part, 212, a second positioning part, 213, a first clamping block, 214, a second clamping block, 215, an arc-shaped clamping groove, 216, a first grid bar, 217, a second grid bar, 218, a support grid bar, 219 and a limiting block.

Detailed Description

In order to better understand the invention for those skilled in the art and to define the claimed scope more clearly, the invention will be described in detail below with respect to certain specific embodiments of the invention. It should be noted that the following description is only a few examples of the present invention, and the specific and direct descriptions of the related structures are only for the convenience of understanding the present invention, and the specific features do not naturally and directly limit the scope of the present invention. Conventional alternatives and substitutions made by those skilled in the art in light of the teachings of the present disclosure should be considered as within the scope of the present disclosure.

The invention will be further explained with reference to the drawings and the specific embodiments.

Example 1

As shown in fig. 1-3, the utility model provides an automatic batch feed mechanism of battery top cap piece electrode post, including frame 1, install material loading transport mechanism 2, material loading elevating system 3 and material loading clamping mechanism 4 in the frame 1, install the material loading that is used for bearing a plurality of electrode post holding plate 20 that pile up in proper order on the material loading elevating system 3 and bear frame 5, the output of material loading transport mechanism 2 is crossing with the removal route that the material loading bore frame 5, still sets up material loading clamping mechanism 4 on the removal route of material loading elevating system 3. A plurality of electrode columns are mounted on the electrode column housing plate 20.

Specifically, the loading bearing frame 5 includes a fixing plate 51 and a bearing plate 52, the fixing plate 51 is mounted on the loading lifting mechanism 3, the bearing plate 52 is mounted on the fixing plate 51, and a first supporting plate 53 is disposed between the bearing plate 52 and the fixing plate 51.

Preferably, a conveying mechanism 6 is further installed on the frame 1, a blanking clamping mechanism 7 is installed on the conveying mechanism 6, and the feeding clamping mechanism 4 is located on a moving path of the blanking clamping mechanism 7.

Specifically, a blanking lifting mechanism 8 and a blanking conveying mechanism 10 are further mounted on the frame 1, a blanking bearing frame 9 is mounted on the blanking lifting mechanism 8, the blanking clamping mechanism 7 is located on a moving path of the blanking bearing frame 9, and an input end of the blanking conveying mechanism 10 is intersected with the moving path of the blanking bearing frame 9.

Preferably, the conveying mechanism 6 includes a horizontal moving mechanism 61 and a third lifting mechanism 62, the third lifting mechanism 62 is mounted on the horizontal moving mechanism 61, and the blanking clamping mechanism 7 is mounted on the third lifting mechanism 62.

Specifically, the horizontal moving mechanism 61 and the third lifting mechanism 62 are both screw rod slider structures. The horizontal moving mechanism 61 is provided with a drag chain, so that the horizontal movement of the blanking clamping mechanism 7 is more stable and reliable.

Specifically, the frame 1 is further provided with a third clamping mechanism 12, and the third clamping mechanism 12 is respectively located on the moving paths of the blanking clamping mechanism 7 and the blanking bearing frame 9.

Preferably, the third clamping mechanism 12 includes at least two third driving cylinders 121, a piston rod of each third driving cylinder 121 is provided with a third clamping block 122, and the third clamping block 122 is provided with a third clamping groove 122 a.

Further, the third clamping block 122 is disposed in a staggered manner with respect to the second clamping block 72. When the second clamping blocks 72 clamp the topmost electrode column accommodating plate 20 on the feeding carrier 5 and place the feeding carrier 9 on the blanking port 11b, the third driving air cylinder 121 drives the third clamping blocks 122 to move to the sides of the electrode column accommodating plate 20 for clamping, and then the second driving air cylinder 71 drives the second clamping blocks 72 to release, so that the third clamping mechanism 12 clamps the electrode column accommodating plate 20 to align the electrode column accommodating plate 20 to be transferred to the blanking carrier 9.

The number of the third driving cylinders 121 is three, two third clamping blocks 122 are respectively arranged on a piston rod of each third driving cylinder 121 at intervals, wherein the two third driving cylinders 121 are oppositely arranged on two outer sides of the discharging opening 11b, and the third driving cylinders 121 are arranged on one outer side of one end of the discharging opening 11b to form a three-point positioning clamp.

Specifically, a housing 11 is arranged on the frame 1, a feeding port 11a and a discharging port 11b are arranged on the housing 11, the feeding clamping mechanism 4 is arranged on the feeding port 11a, the feeding port 11a is respectively arranged on the moving paths of the discharging clamping mechanism 7 and the feeding bearing frame 5, and the discharging port 11b is respectively arranged on the moving paths of the discharging clamping mechanism 7 and the discharging bearing frame 9.

The carrying mechanism 6 drives the blanking clamping mechanism 7 to move back and forth between the feeding port 11a and the blanking port 11b, the empty electrode column containing plate 20 is clamped to the blanking port 11b from the feeding port 11a, the blanking bearing frame 9 is driven to move through the blanking lifting mechanism 8, the empty electrode column containing plate 20 is enabled to bear the electrode column containing plate 20 carried to the blanking port 11b by the blanking clamping mechanism 7, after the electrode column containing plate 20 is completely stacked, the blanking bearing frame 9 is driven to move into the blanking conveying mechanism 10, the electrode column containing plate 20 protruding from the two ends of the blanking bearing frame 9 is enabled to be in contact with the conveying belt of the blanking conveying mechanism 10, and the electrode column containing plate is driven by the conveying belt to be transferred to the conveying belt from the blanking bearing frame 9, automatic blanking is achieved, and the production efficiency of lithium battery electrode columns is improved.

Preferably, the feeding clamping mechanism 4, the third clamping mechanism 12 and the carrying mechanism 6 are all mounted on the top of the housing 11.

Specifically, the feeding clamping mechanism 4 includes at least two first driving cylinders 41, a first clamping block 42 is mounted on a piston rod of the first driving cylinder 41, and a first clamping groove 42a is formed in the first clamping block 42.

Preferably, there are three first driving cylinders 41, and two first clamping blocks 42 are respectively disposed on the piston rod of each first driving cylinder 41 at intervals, wherein two first driving cylinders 41 are disposed on two outer sides of the feeding opening 11a, and the third first driving cylinder 41 is disposed on one end outer side of the feeding opening 11a, so as to form a three-point positioning clamp.

Specifically, the blanking clamping mechanism 7 includes a second driving cylinder 71, two piston rods of the second driving cylinder 71 are respectively and oppositely provided with a second clamping block 72, and the second clamping block 72 is provided with a second clamping groove 72 a.

Preferably, the second clamping block 72 is offset from the first clamping block 42. When the first clamping blocks 42 clamp the topmost electrode column accommodating plate 20 on the feeding carrier 5, the second driving air cylinder 71 drives the second clamping blocks 72 to move to the sides of the electrode column accommodating plate 20 for clamping, and then the first driving air cylinder 41 drives the first clamping blocks 42 to loosen, so that the blanking clamping mechanism 7 clamps the electrode column accommodating plate 20, and drives the blanking clamping mechanism 7 to carry to the blanking port 11b through the carrying mechanism 6.

One second driving cylinder 71 is provided, two piston rods of each third driving cylinder 121 are provided with mounting brackets 73, and two second clamping blocks 72 are arranged on each mounting bracket 73 at intervals. When the electrode column accommodating plate 20 is clamped at the feeding port 11a, the second clamping blocks 72 are positioned at the outer sides of the two first clamping blocks 42 on the first driving cylinders 41 at the two sides of the feeding port 11 a; when the electrode column accommodating plate 20 is gripped at the feed opening 11b, the second clamping blocks 72 are respectively located outside the two third clamping blocks 122 on the third driving cylinders 121 on both sides of the feed opening 11 b. The mounting bracket 73 is L-shaped.

The feeding mechanism composed of the feeding conveying mechanism 2, the feeding lifting mechanism 3, the feeding bearing frame 5 and the feeding clamping mechanism 4 is the same as the blanking mechanism composed of the blanking conveying mechanism 10, the blanking lifting mechanism 8, the blanking bearing frame 9 and the third clamping mechanism 12 in structure, the feeding mechanism and the blanking mechanism can be used as the feeding mechanism and can also be used as the blanking mechanism, the feeding mechanism and the blanking mechanism are transported through the carrying mechanism 6, the equipment is guaranteed not to be stopped in the operation process, and therefore the utilization rate of the equipment is improved. The feeding lifting mechanism 3 and the discharging lifting mechanism 8 are of screw rod sliding block structures.

Be equipped with on frame 1 and be located material loading transport mechanism 2, material loading baffle 13 and the unloading baffle 14 of unloading transport mechanism 10 top, material loading baffle 13, unloading baffle 14 respectively along vertical extension to material loading mouth 11a, feed opening 11b, material loading baffle 13 sets up and bears 5 through at the both sides and the front end of 5 upper portions removal route of material loading, unloading baffle 14 sets up and bears 9 through at the both sides and the front end of 9 upper portions removal route of unloading and support the unloading, bear 5 to the material loading, the removal route of unloading bearing frame 9 leads, can prevent simultaneously that material loading from bearing 5, the in-process that a plurality of electrode post that pile up on the unloading bearing frame 9 hold board 20 and fall at reciprocating on the unloading bearing frame 9.

As shown in fig. 4 and 5, preferably, the feeding conveying mechanism 2 includes a first driving motor 21 and a transmission mechanism 22, the transmission mechanism 22 includes a driving wheel 221, a driven wheel 222 and a transmission belt 223, the driving wheel 221 is mounted on an output shaft of the first driving motor 21, the driving wheel 221 is in transmission connection with the driven wheel 222 through the transmission belt 223, at least two sets of transmission mechanisms 22 are oppositely disposed, the two driving wheels 221 are connected through a transmission shaft 224, a receiving plate 23 is disposed between the two transmission mechanisms 22, the receiving plate 23 is disposed between the transmission shaft 224 and an upper surface of the transmission belt 223, and the feeding carrier 5 is connected with the receiving plate 23 when moving between the two transmission mechanisms 22. Facilitating smooth transfer of the electrode column receiving plate 20 to the loading carrier 5.

Specifically, a support frame 25 for supporting the conveyor belt 223 is provided between the two transmission mechanisms 22, and the receiving plate 23 is provided on the support frame 25. Through setting up support frame 25, form effective support to conveyer belt 223, prevent that electrode post from holding board 20 and pressing when on conveyer belt 223, conveyer belt 223 sinks downwards and leads to the conveying failure, guarantees the assembly efficiency of follow-up lithium cell.

Preferably, the supporting frame 25 includes a supporting bottom plate 251, a side plate 252 and a second supporting plate 253, the supporting bottom plate 251 is vertically installed on the first driving motor 21, the side plate 252 located in the conveyor 223 is installed at both sides of the supporting bottom plate 251, and the second supporting plate 253 in contact with the upper inner wall of the conveyor 223 is disposed on the upper surface of the side plate 252.

Further, the feeding and conveying mechanism 2 further includes a speed reducing mechanism 24, and an output shaft of the first driving motor 21 is in transmission connection with the driving wheel 221 through the speed reducing mechanism 24.

As shown in fig. 6, preferably, the electrode column accommodating plate 20 includes a plate body 210, a plurality of electrode column accommodating regions 21a are disposed on the plate body 210, the upper surface of the plate body 210 is provided with a plurality of first positioning portions 211, the lower surface of the plate body 210 is provided with a plurality of second positioning portions 212, the second positioning portions 212 are matched with the first positioning portions 211 to stably stack the plurality of electrode column accommodating plates 20, and the electrode column accommodating plates 20 are prevented from extruding and damaging the electrode columns, which affects the assembly quality of the subsequent lithium battery.

Specifically, the first positioning portion 211 may be a positioning block or a positioning slot, and the second positioning portion 212 may be a positioning slot or a positioning block.

Preferably, the first positioning portion 211 is an L-shaped positioning block and a positioning through groove, the L-shaped positioning block is disposed at four corners of the upper surface of the plate body 210, the positioning through groove is disposed at two sides of the upper surface of the plate body 210, the second positioning portion 212 is an L-shaped positioning block and a T-shaped positioning block, the L-shaped positioning block is disposed at four corners of the lower surface of the plate body 210, and the T-shaped positioning block is disposed at two sides of the lower surface of the plate body 210.

Specifically, the plate body 210 is provided with a plurality of first clamping blocks 213 arranged at intervals and a plurality of second clamping blocks 214 arranged at intervals, the first clamping blocks 213 and the second clamping blocks 214 are arranged in a staggered manner, the side surfaces of the first clamping blocks 213 and the second clamping blocks 214 are respectively provided with arc-shaped clamping grooves 215, and the first clamping blocks 213 and the second clamping blocks 214 are matched to form the electrode column accommodating area 21 a. The electrode column is convenient to stably arrange, and the side wall of the electrode column can not be extruded.

Preferably, the first clamping block 213 and the second clamping block 214 are both provided with a limiting block 219. The upper surface of the electrode column on the lower electrode column holding plate 20 is prevented from being extruded by the upper electrode column holding plate 20.

Specifically, an opening 21b is formed in the plate body 210, a plurality of first grid bars 216 arranged at intervals and a plurality of second grid bars 217 arranged at intervals are arranged on the opening 21b, the first grid bars 216 and the second grid bars 217 are arranged in a crossed manner, the first clamping blocks 213 are arranged on the first grid bars 216, and the second clamping blocks 214 are arranged on the second grid bars 217. The weight of the plate body 210 is reduced by providing the grill bars.

Preferably, a support grid strip 218 is further disposed between the two second grid strips 217 having the second clamping blocks 214, the support grid strip 218 is disposed to intersect with the first grid strip 216, and the first clamping blocks 213 are disposed at the connection between the first grid strip 216 and the support grid strip 218. The lower surface of the electrode column is separated from the lower electrode column receiving plate 20, so that the lower surface of the electrode column is prevented from being extruded.

It is above only the utility model discloses a preferred embodiment, the utility model discloses a scope of protection does not only confine above-mentioned embodiment, the all belongs to the utility model discloses a technical scheme under the thinking all belongs to the utility model discloses a scope of protection. It should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims (10)

1. The utility model provides an automatic feed mechanism in batches of battery top cap piece electrode post which characterized in that: the electrode column storage device comprises a rack (1), wherein a feeding conveying mechanism (2), a feeding lifting mechanism (3) and a feeding clamping mechanism (4) are installed on the rack (1), a feeding bearing frame (5) used for bearing a plurality of sequentially stacked electrode column containing plates (20) is installed on the feeding lifting mechanism (3), the output end of the feeding conveying mechanism (2) is intersected with the moving path of the feeding bearing frame (5), and the feeding clamping mechanism (4) is further arranged on the moving path of the feeding lifting mechanism (3); the feeding clamping mechanism (4) comprises at least two first driving cylinders (41), a first clamping block (42) is mounted on a piston rod of each first driving cylinder (41), and a first clamping groove (42 a) is formed in each first clamping block (42).

2. The automatic batch charging mechanism for battery top cover plate electrode columns as claimed in claim 1, wherein: the feeding and clamping device is characterized in that the rack (1) is also provided with a conveying mechanism (6), the conveying mechanism (6) is provided with a discharging and clamping mechanism (7), and the feeding and clamping mechanism (4) is positioned on a moving path of the discharging and clamping mechanism (7);

the carrying mechanism (6) comprises a horizontal moving mechanism (61) and a third lifting mechanism (62), the third lifting mechanism (62) is installed on the horizontal moving mechanism (61), and the blanking clamping mechanism (7) is installed on the third lifting mechanism (62).

3. The automatic batch charging mechanism for battery top cover plate electrode columns as claimed in claim 2, wherein: still install unloading elevating system (8) and unloading transport mechanism (10) on frame (1), install the unloading on unloading elevating system (8) and bear frame (9), unloading clamping mechanism (7) are located the unloading and bear the removal route of bearing frame (9), the input of unloading transport mechanism (10) is crossing with the removal route that the unloading bore frame (9).

4. The automatic batch charging mechanism for battery top cover plate electrode columns as claimed in claim 1, wherein: the feeding conveying mechanism (2) comprises a first driving motor (21) and a transmission mechanism (22), the transmission mechanism (22) comprises a driving wheel (221), a driven wheel (222) and a conveying belt (223), the driving wheel (221) is installed on an output shaft of the first driving motor (21), the driving wheel (221) is in transmission connection with the driven wheel (222) through the conveying belt (223), at least two sets of transmission mechanisms (22) are oppositely arranged, the driving wheel (221) is connected with the driving wheel (224), a bearing plate (23) is arranged between the transmission mechanisms (22), the bearing plate (23) is located between the upper surfaces of the transmission shaft (224) and the conveying belt (223), and the feeding bearing frame (5) is connected with the bearing plate (23) when moving between the two transmission mechanisms (22).

5. The automatic batch charging mechanism for battery top cover plate electrode columns as claimed in claim 4, wherein: a supporting frame (25) used for supporting the conveying belt (223) is arranged between the two transmission mechanisms (22), and the bearing plate (23) is arranged on the supporting frame (25).

6. The automatic batch charging mechanism for battery top cover plate electrode columns as claimed in claim 1, wherein: the electrode column containing plate (20) comprises a plate body (210), a plurality of electrode column containing areas (21 a) are arranged on the plate body (210), a plurality of first positioning portions (211) are arranged on the upper surface of the plate body (210), a plurality of second positioning portions (212) are arranged on the lower surface of the plate body (210), and the second positioning portions (212) are matched with the first positioning portions (211) so as to stack the plurality of electrode column containing plates (20).

7. The automatic batch charging mechanism for battery top cover plate electrode columns as claimed in claim 6, wherein: be equipped with a plurality of interval arrangements's first clamp splice (213) and a plurality of interval arrangements's second clamp splice (214) on plate body (210), first clamp splice (213) and second clamp splice (214) dislocation set, the side of first clamp splice (213), second clamp splice (214) is equipped with arc clamp groove (215) respectively, first clamp splice (213) cooperate with second clamp splice (214) and form electrode post holding area (21 a).

8. The automatic batch charging mechanism for battery top cover plate electrode columns as claimed in claim 7, wherein: be equipped with opening (21 b) on plate body (210), be equipped with many interval arrangement's first grid strip (216) and many interval arrangement's second grid strip (217) on opening (21 b), first grid strip (216) and second grid strip (217) cross arrangement, first clamp splice (213) set up on first grid strip (216), second clamp splice (214) set up on second grid strip (217).

9. The automatic batch charging mechanism for battery top cover plate electrode columns as claimed in claim 3, wherein: be equipped with casing (11) on frame (1), be equipped with material loading mouth (11 a) and feed opening (11 b) on casing (11), material loading clamping mechanism (4) set up at material loading mouth (11 a), material loading mouth (11 a) set up respectively and bear on the removal route of frame (5) at material loading clamping mechanism (7) and material loading, feed opening (11 b) set up respectively and bear on the removal route of frame (9) at material loading clamping mechanism (7) and unloading.

10. The automatic batch charging mechanism for battery top cover plate electrode posts as claimed in claim 3 or 9, wherein: and a third clamping mechanism (12) is further installed on the rack (1), and the third clamping mechanism (12) is respectively positioned on the moving paths of the blanking clamping mechanism (7) and the blanking bearing frame (9).

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