CN210908590U - Battery module end side plate welding platform - Google Patents

Abstract

The utility model discloses a battery module end side plate welding platform, which comprises a frame, wherein a working platform is fixedly connected with the top surface of the frame, symmetrical side plate positioning mechanisms are fixedly arranged at two sides of one end of the top surface of the working platform, a battery module is placed between the symmetrical side plate positioning mechanisms, an end plate positioning mechanism is arranged at the end side of the battery module, and welding positioning mechanisms corresponding to the symmetry of the battery module are arranged at two sides of the top surface of the end plate positioning mechanism; the other end of the top surface of the working platform is provided with a shaping mechanism; the utility model provides a can adapt to the module end curb plate welded platform of different length and width to can realize online automatic adjustment, thereby satisfied the module automated production flow of high efficiency, high quality and many sizes customization.

Description

Battery module end side plate welding platform

Technical Field

The utility model relates to a welded platform especially relates to a battery module end curb plate welded platform.

Background

In recent years, the power battery industry has been rapidly developed, and the requirements on the production efficiency and quality of the battery module are higher and higher. At present, the welding of battery module end plate and curb plate mostly all adopts the higher laser welding of degree of automation. At present, in the prior art, most of module end side plate welding platforms with high automation degree can only adapt to the welding of module end side plates with single size, and the reason is that the platforms can not finish the automatic adjustment of different module length directions and width directions during the welding.

SUMMERY OF THE UTILITY MODEL

In order to overcome the not enough of prior art, the utility model provides a battery module end curb plate welded platform, the technical defect who exists in the background art that can solve.

In order to solve the technical problem, the utility model provides a following technical scheme: a battery module end side plate welding platform comprises a rack, wherein the top surface of the rack is fixedly connected with a working platform, symmetrical side plate positioning mechanisms are fixedly arranged on two sides of one end of the top surface of the working platform, a battery module is placed between the symmetrical side plate positioning mechanisms, an end plate positioning mechanism is arranged on the end side of the battery module, and welding positioning mechanisms corresponding to the battery module are arranged on two sides of the top surface of the end plate positioning mechanism; and the other end of the top surface of the working platform is provided with a shaping mechanism.

As a preferred technical scheme of the utility model, the side plate positioning mechanism comprises a symmetrical lower guide rail, the top surface of the lower guide rail is connected with a lower mounting plate in a sliding way, and the top surface of the lower mounting plate is fixedly connected with an upper mounting plate above through a plurality of guide pillars; symmetrical clamping air claws and upper and lower positioning reference blocks are arranged on two sides of the top surface of the upper mounting plate, and the clamping air claws are positioned between the symmetrical upper and lower positioning reference blocks; a lower air cylinder is fixedly arranged on the working platform between the lower guide rails, and the output end of the lower air cylinder is connected with an upper mounting plate in a transmission manner; the working platform at one side of the lower guide rail is also provided with a mounting seat, the top surface of the mounting seat is provided with symmetrical upper guide rails along the length direction, the top surface of the mounting seat between the upper guide rails is fixedly connected with an upper air cylinder, the output end of the upper air cylinder is fixedly connected with a sliding plate at the top surface of the upper guide rail, the top surface of the sliding plate is fixedly connected with a tightening plate at one side of the top surface of the sliding plate through a tightening bracket, one surface of the tightening plate is movably attached to a side plate, and the other surface of the tightening plate is fixedly connected with a plurality of upper and lower positioning rotary air cylinders, a front and rear pressing rotary air cylinder and a side plate, and is; the surface of the side plate and the clamping air claw are movably attached to the upper and lower positioning reference blocks.

As a preferred technical solution of the present invention, the end plate positioning mechanism includes symmetrical first guide rails on the top surface of the working platform, the sides of the first guide rails are provided with first motors, the first motors are connected with first lead screws through coupling transmission, the first lead screws are fixedly connected with a first slide plate above, and the bottom surface of the first slide plate is slidably connected with the first guide rails fixedly arranged on the top surface of the working platform; the first sliding plate is perpendicular to the symmetrical first guide rail, and two groups of the first guide rail are arranged in parallel and symmetrical; the working platform between the first guide rails is also fixedly provided with a mounting frame, the top end of the mounting frame is fixedly connected with a module mounting plate, the module mounting plate is provided with a clearance structure, and the module is arranged above the first sliding plate in a hanging manner; the first sliding plate is also provided with a second motor, the second motor is in transmission connection with a second lead screw through a speed reducer, the second lead screw is arranged on the top surface of the first sliding plate, and an end plate positioning plate is fixedly connected to a nut of the second lead screw; the first sliding plate top surface is further fixedly provided with a second guide rail, the second guide rail is connected with an end plate positioning plate in a sliding mode, and the end plate positioning plate is tightly clamped with the battery module in the clearance structure.

As a preferred technical solution of the present invention, the welding positioning mechanism includes a fourth cylinder fixedly disposed between a third guide rail and a third guide rail, which are symmetrical to each other, on the top surface of the first slide plate, and an output end of the fourth cylinder is in transmission connection with the second slide plate on the top surface of the third guide rail; a pneumatic sliding table is fixedly arranged on the top surface of the second sliding plate, a second mounting plate is vertically fixed on the pneumatic sliding table, the surface of the second mounting plate is fixedly connected with a first mounting plate, and the surface of the first mounting plate is slidably connected with an air blowing mechanism through a fourth guide rail; the surface of the first mounting plate at one side of the air blowing mechanism is provided with a second air cylinder corresponding to the first mounting plate, the output end of the second air cylinder faces the air blowing mechanism, one side of the first mounting plate is also provided with a third air cylinder, and the output end of the third air cylinder is vertical to the plane of the side plate; the surface of the second sliding plate is fixedly provided with a first cylinder, and the output direction of the first cylinder is perpendicular to the plane of the side plate and is located at the side.

As a preferred technical scheme of the utility model, the cross beam guide rails on both sides of the working platform and the fixing plate on one side between the cross beam guide rails; the movable cross beam is connected to the cross beam guide rail in a sliding mode and driven by a platform lead screw in the cross beam guide rail, and the platform lead screw is connected with a platform motor outside the cross beam guide rail in a rotating mode.

As a preferred technical scheme of the utility model, the shaping mechanism comprises a partition plate fixedly connected below the top end of the movable beam, a gas claw driving cylinder and a pressing plate driving cylinder are penetrated through the top surface of the partition plate in a sliding manner, the output end of the gas claw driving cylinder is fixedly connected with gas claws at two sides through a transmission plate, the gas claws are meshed with a second pressing plate, the side of the second pressing plate is fixedly connected with a side plate, and a clamping strip is vertically fixed inwards at the bottom end of the side plate; the output end of the pressing plate driving cylinder is connected with a first pressing plate in a transmission mode, and the first pressing plate is located between the symmetrically arranged clamping strips and located above the clamping strips.

Compared with the prior art, the utility model discloses the beneficial effect that can reach is: the utility model provides a can adapt to module end curb plate welded platform of different length and width to can realize online automatic adjustment, need not shut down, thereby satisfied the module automated production flow of high efficiency, high quality and many sizes customization.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a view of the side plate positioning mechanism according to the present invention;

fig. 3 is another view angle appearance structure diagram of the side plate positioning mechanism of the present invention;

fig. 4 is a schematic structural view of the end plate positioning mechanism of the present invention;

FIG. 5 is a view of the external structure of the welding positioning mechanism of the present invention;

fig. 6 is an appearance structure diagram of another view angle of the welding positioning mechanism of the present invention;

FIG. 7 is a schematic structural view of the working platform of the present invention;

fig. 8 is a schematic structural diagram of the front side of the shaping structure of the present invention;

fig. 9 is a structural diagram of the shaping structure of the present invention;

fig. 10 is a schematic top view of the present invention;

fig. 11 is a front view of the structure of the present invention;

wherein: 100. a side plate positioning mechanism; 101. a lower cylinder; 102. a lower mounting plate; 103. a lower guide rail; 104. a guide post; 105. an upper mounting plate; 106. clamping the air claw; 107. a side plate; 108. positioning the reference block up and down; 109. an up-down positioning rotary cylinder; 110. a mounting seat; 112. a front and rear pressing rotary cylinder; 113. a pushing plate is tightly pressed; 114. pushing the bracket tightly; 115. a slide plate; 116. an upper guide rail; 117. an upper cylinder; 200. an end plate positioning mechanism; 201. a first guide rail; 202. a second guide rail; 203. a second lead screw; 204. a first motor; 205. a coupling; 206. a first lead screw; 207. a first slide plate; 208. An end plate positioning plate; 209. a module mounting plate; 210. a speed reducer; 211. a second motor; 212. a mounting frame; 300. a welding positioning mechanism; 301. a third guide rail; 302. a blowing mechanism; 303. a fourth guide rail; 304. a first cylinder; 305. a first mounting plate; 306. a second cylinder; 307. a second slide plate; 308. a pneumatic sliding table; 309. a second mounting plate; 310. a third cylinder; 313. a fourth cylinder; 400. a working platform; 401. a platform motor; 402. a fixing plate; 403. a cross beam guide rail; 405. moving the beam; 406. a platform lead screw; 500. a shaping mechanism; 501. a first platen; 502. a side mounting plate; 503. a second platen; 504. a drive plate; 505. a partition plate; 506. the air claw drives the air cylinder; 507. the pressing plate drives the air cylinder; 508. a pneumatic claw; 509. and (5) clamping the strip.

Detailed Description

In order to make the technical means, the creation features, the achievement purposes and the functions of the invention easy to understand, the invention is further explained below with reference to the specific embodiments, but the following embodiments are only the preferred embodiments of the invention, not all. Based on the embodiments in the implementation, other embodiments obtained by those skilled in the art without any creative work belong to the protection scope of the present invention. The experimental methods in the following examples are conventional methods unless otherwise specified, and materials, reagents and the like used in the following examples are commercially available unless otherwise specified.

Referring to fig. 1-11, the present invention provides a battery module end side plate 107 welding platform, which includes a frame installed on a horizontal ground, wherein the top surface of the frame is fixedly connected to a working platform 400, symmetrical side plate 107 positioning mechanisms 100 are fixedly disposed on two sides of one end of the top surface of the working platform 400, a battery module is placed between the symmetrical side plate 107 positioning mechanisms 100, an end plate positioning mechanism 200 is disposed on the end side of the battery module, and two sides of the top surface of the end plate positioning mechanism 200 are disposed with welding positioning mechanisms 300 corresponding to the battery module symmetry; the other end of the top surface of the working platform 400 is provided with a shaping mechanism 500.

Specifically, the side plate 107 positioning mechanism 100 comprises symmetrical lower guide rails 103, the top surfaces of the lower guide rails 103 are slidably connected with a lower mounting plate 102, and the top surfaces of the lower mounting plate 102 are fixedly connected with an upper mounting plate 105 above through a plurality of guide posts 104; symmetrical clamping air claws 106 and upper and lower positioning reference blocks 108 are arranged on two sides of the top surface of the upper mounting plate 105, and the clamping air claws 106 are positioned between the symmetrical upper and lower positioning reference blocks 108; a lower air cylinder 101 is fixedly arranged on the working platform 400 between the lower guide rails 103, and the output end of the lower air cylinder 101 is connected with an upper mounting plate 105 in a transmission manner; the working platform 400 at one side of the lower guide rail 103 is also provided with a mounting seat 110, the top surface of the mounting seat 110 is provided with symmetrical upper guide rails 116 along the length direction, the top surface of the mounting seat 110 between the upper guide rails 116 is fixedly connected with an upper air cylinder 117, the output end of the upper air cylinder 117 is fixedly connected with a sliding plate 115 at the top surface of the upper guide rail 116, the top surface of the sliding plate 115 is fixedly connected with a pushing plate 113 positioned at one side of the top surface of the sliding plate 115 through a pushing bracket 114, one surface of the pushing plate 113 is movably attached to the side plate 107, the other surface is fixedly connected with a plurality of upper and lower positioning rotary air cylinders 109 and front and rear pressing rotary air cylinders 112, and the upper and lower; the surface of the side plate 107 and the clamping air claw 106 are movably attached to an upper positioning reference block 108 and a lower positioning reference block 108;

the lower mounting plate 102 is mounted on the lower rail 103 and can move forward and backward by the cylinder (not shown). The upper mounting plate 105 is connected to the lower mounting plate 102 by a guide post 104 and can move up and down under the control of the lower cylinder 101. The clamping air claw 106 is mounted on the upper mounting plate 105 and is used for clamping the side plate 107 when the side plate 107 is loaded, and then the lower mounting plate 102 slides to the position where the side plate 107 is close to the pushing plate 113. Upper and lower positioning reference blocks 108 are mounted on the upper mounting plate 105 for lower positioning reference of the side plates 107. The pushing plate 113 is provided with a negative pressure suction hole thereon for tightly sucking the side plate 107. The pushing plate 113 is also provided with a front and rear pressing rotary cylinder 112 and an up and down positioning rotary cylinder 109. The pushing plate 113 is mounted on the pushing bracket 114. The thrust bracket 114 is mounted on a sled 115. The sled 115 is mounted on the upper rail 116. The slide plate 115 can be moved back and forth by the upper cylinder 117.

Specifically, the end plate positioning mechanism 200 includes first guide rails 201 that are symmetrical on the top surface of the working platform 400, the sides of the first guide rails 201 are provided with first motors 204, the first motors 204 are connected with first lead screws 206 through couplings 205 in a transmission manner, the first lead screws 206 are fixedly connected with first sliding plates 207 above, and the bottom surfaces of the first sliding plates 207 are slidably connected with the first guide rails 201 that are fixedly arranged on the top surface of the working platform 400; the first sliding plate 207 is vertically arranged with the symmetrical first guide rail 201, and two groups of parallel symmetrical first guide rail 201 are arranged; the working platform 400 between the first guide rails 201 is also fixedly provided with a mounting rack 212, the top end of the mounting rack 212 is fixedly connected with a module mounting plate 209, the module mounting plate 209 is provided with a clearance structure, and the module is mounted and suspended above the first sliding plate 207; the first sliding plate 207 is also provided with a second motor 211, the second motor 211 is in transmission connection with a second lead screw 203 positioned on the top surface of the first sliding plate 207 through a speed reducer 210, and an end plate positioning plate 208 is fixedly connected to a nut of the second lead screw 203; the top surface of the first sliding plate 207 is further fixedly provided with a second guide rail 202, the second guide rail 202 is slidably connected with an end plate positioning plate 208, and the end plate positioning plate 208 is clamped with the battery module in the clearance structure.

Specifically, the welding positioning mechanism 300 includes a fourth cylinder 313 fixedly disposed between a third guide rail 301 and the third guide rail 301, where the top surface of the first sliding plate 207 is symmetrical, and an output end of the fourth cylinder 313 is in transmission connection with a second sliding plate 307 on the top surface of the third guide rail 301; a pneumatic sliding table 308 is fixedly arranged on the top surface of the second sliding plate 307, a second mounting plate 309 is vertically fixed on the pneumatic sliding table 308, the surface of the second mounting plate 309 is fixedly connected with the first mounting plate 305, and the surface of the first mounting plate 305 is slidably connected with the blowing mechanism through a fourth guide rail 303; a second air cylinder 306 corresponding to the first mounting plate 305 is arranged on the surface of the first mounting plate 305 on one side of the air blowing mechanism, the output end of the second air cylinder 306 faces the air blowing mechanism, a third air cylinder 310 is arranged on one side of the first mounting plate 305, and the output end of the third air cylinder 310 is vertical to the plane of the side plate 107; the second slide plate 307 has a first cylinder 304 fixed to the surface thereof, and the first cylinder 304 serves to position the side plate 107 in the longitudinal direction.

Specifically, the cross beam guide rails 403 on both sides of the work platform 400 and the fixing plate 402 on one side between the cross beam guide rails 403; the beam guide rails 403 are slidably connected with a movable beam 405, the movable beam 405 is driven by a platform lead screw 406 in the beam guide rails 403, and the platform lead screw 406 is rotatably connected with a platform motor 401 outside the beam guide rails 403.

Specifically, the shaping mechanism 500 comprises a partition 505 fixedly connected below the top end of the movable beam 405, an air claw 508 driving air cylinder 506 and a pressing plate driving air cylinder 507 are slidably penetrated through the top surface of the partition 505, the output end of the air claw 508 driving air cylinder 506 is fixedly connected with the air claws 508 at two sides through a driving plate 504, the air claws 508 are occluded with a second pressing plate 503, the side of the second pressing plate 503 is fixedly connected with a side mounting plate 502, and a clamping bar 509 is vertically fixed inwards at the bottom end of the side mounting plate 502; the output end of the pressing plate driving cylinder 507 is connected with a first pressing plate 501 in a transmission manner, and the first pressing plate 501 is arranged between the symmetrically arranged clamping bars 509 and is positioned above the clamping bars 509.

The specific principle is as follows: the utility model realizes the clamping and fixing of the middle battery module through the side plate 107 positioning mechanisms 100 on both sides of the top surface of the working platform 400, ensures the platforms on both sides, and realizes the upper and lower butting of the battery module by the positioning reference block and the upper and lower positioning rotary cylinders 109 on the platform; the platform adjustment of the end part of the battery module is realized through the end plate positioning mechanism 200, and the end plate positioning plate 208 on the end plate positioning mechanism clamps the battery module on the module mounting plate 209 and then slowly moves the battery module; in addition, the middle of the module mounting plate 209 is a clearance structure, which is convenient for the long-range movement of the end plate positioning plate 208 to adapt to the welding of modules with different length sizes; the welding positioning mechanism 300 adopts a slidable blowing mechanism, and plays roles of blowing shielding gas and pressing the side plate 107 to control the welding misalignment; the third cylinder 310 is indirectly arranged on the first mounting plate 305, and the third cylinder 310 extends out during welding to tightly push against the side plate 107 near the welding area on the side surface of the module, so that the function of controlling the welding gap is achieved; the movable beam 405 moves back and forth in a long distance, and retreats to the farthest position for avoiding a welding head during welding, and the movable beam 405 moves right above the module to complete a positioning function during positioning; the clamping and shaping work on the side face of the module is finished through the clamping strip 509; when the first pressing plate 501 moves downward, the upper surface of the die set can be pressed and shaped. The first pressing plate 501 is not limited to a simple straight plate, and a structure for independently pressing a single battery cell in pair can be improved according to the size of a module.

In the present disclosure, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact between the first and second features, or may comprise contact between the first and second features not directly. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It should be understood by those skilled in the art that the present invention is not limited by the above embodiments, and the description in the above embodiments and the description is only preferred examples of the present invention, and is not intended to limit the present invention, and that the present invention can have various changes and modifications without departing from the spirit and scope of the present invention, and these changes and modifications all fall into the scope of the claimed invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (6)

1. The utility model provides a battery module end curb plate welded platform, includes the frame, its characterized in that: the top surface of the rack is fixedly connected with a working platform (400), two sides of one end of the top surface of the working platform (400) are fixedly provided with symmetrical side plate positioning mechanisms (100), a battery module is placed between the symmetrical side plate positioning mechanisms (100), the end side of the battery module is provided with an end plate positioning mechanism (200), and two sides of the top surface of the end plate positioning mechanism (200) are provided with welding positioning mechanisms (300) which are symmetrical corresponding to the battery module; the other end of the top surface of the working platform (400) is provided with a shaping mechanism (500).

2. The battery module end side plate welding platform of claim 1, wherein: the side plate positioning mechanism (100) comprises symmetrical lower guide rails (103), the top surfaces of the lower guide rails (103) are connected with a lower mounting plate (102) in a sliding mode, and the top surfaces of the lower mounting plate (102) are fixedly connected with an upper mounting plate (105) above through a plurality of guide columns (104); symmetrical clamping air claws (106) and upper and lower positioning reference blocks (108) are arranged on two sides of the top surface of the upper mounting plate (105), and the clamping air claws (106) are positioned between the symmetrical upper and lower positioning reference blocks (108); a lower air cylinder (101) is fixedly arranged on the working platform (400) between the lower guide rails (103), and the output end of the lower air cylinder (101) is connected with an upper mounting plate (105) in a transmission manner; the working platform (400) on one side of the lower guide rail (103) is further provided with a mounting seat (110), the top surface of the mounting seat (110) is provided with symmetrical upper guide rails (116) along the length direction, the top surface of the mounting seat (110) between the upper guide rails (116) is fixedly connected with an upper air cylinder (117), the output end of the upper air cylinder (117) is fixedly connected with a sliding plate (115) on the top surface of the upper guide rail (116), the top surface of the sliding plate (115) is fixedly connected with a tightening plate (113) on one side of the top surface of the sliding plate (115) through a tightening support (114), one surface of the tightening plate (113) is movably attached to the side plate (107), the other surface of the tightening plate is fixedly connected with a plurality of upper and lower positioning rotary air cylinders (109) and front and rear pressing rotary cylinders (112), and the upper and lower positioning rotary cylinders (109) and the; the surface of the side plate (107) and the clamping air claw (106) are movably jointed with an upper positioning reference block (108) and a lower positioning reference block (108).

3. The battery module end side plate welding platform of claim 1, wherein: the end plate positioning mechanism (200) comprises first guide rails (201) which are symmetrical on the top surface of the working platform (400), first motors (204) are arranged on the sides of the first guide rails (201), the first motors (204) are in transmission connection with first lead screws (206) through couplers (205), the first lead screws (206) are fixedly connected with first sliding plates (207) above, and the bottom surfaces of the first sliding plates (207) are in sliding connection with the first guide rails (201) which are fixedly arranged on the top surface of the working platform (400); the first sliding plate (207) and the symmetrical first guide rail (201) are vertically arranged, and two groups of parallel and symmetrical first guide rails (201) are arranged; a mounting rack (212) is further fixedly arranged on the working platform (400) between the first guide rails (201), a module mounting plate (209) is fixedly connected to the top end of the mounting rack (212), a clearance structure is arranged on the module mounting plate (209), and the module is mounted and suspended above the first sliding plate (207); the first sliding plate (207) is further provided with a second motor (211), the second motor (211) is in transmission connection with a second lead screw (203) through a speed reducer (210), the second lead screw (203) is arranged on the top surface of the first sliding plate (207), and an end plate positioning plate (208) is fixedly connected to a nut of the second lead screw (203); the top surface of the first sliding plate (207) is also fixedly provided with a second guide rail (202), the second guide rail (202) is connected with an end plate positioning plate (208) in a sliding manner, and the end plate positioning plate (208) is clamped with the battery module in the clearance structure.

4. The battery module end side plate welding platform of claim 1, wherein: the welding positioning mechanism (300) comprises a fourth air cylinder (313) fixedly arranged between a third guide rail (301) and a third guide rail (301) which are symmetrical on the top surface of the first sliding plate (207), and the output end of the fourth air cylinder (313) is in transmission connection with a second sliding plate (307) on the top surface of the third guide rail (301); a pneumatic sliding table (308) is fixedly arranged on the top surface of the second sliding plate (307), a second mounting plate (309) is vertically fixed on the pneumatic sliding table (308), the surface of the second mounting plate (309) is fixedly connected with the first mounting plate (305), and the surface of the first mounting plate (305) is slidably connected with the blowing mechanism (302) through a fourth guide rail (303); a second air cylinder (306) corresponding to the first mounting plate (305) is arranged on the surface of the first mounting plate (305) on one side of the air blowing mechanism (302), the output end of the second air cylinder (306) faces the air blowing mechanism (302), a third air cylinder (310) is arranged on one side of the first mounting plate (305), and the output end of the third air cylinder (310) is perpendicular to the plane of the side plate (107); the surface of the second sliding plate (307) is fixedly provided with a first air cylinder (304), and the output direction of the first air cylinder (304) is perpendicular to the plane of the side plate (107) and is located at the side.

5. The battery module end side plate welding platform of claim 1, wherein: a beam guide rail (403) at two sides of the working platform (400) and a fixing plate (402) at one side between the beam guide rails (403); sliding connection moving beam (405) on crossbeam guide rail (403), and moving beam (405) have platform lead screw (406) transmission in crossbeam guide rail (403), platform motor (401) outside platform lead screw (406) and crossbeam guide rail (403) rotate and connect.

6. The battery module end side plate welding platform of claim 1, wherein: the shaping mechanism (500) comprises a partition plate (505) fixedly connected with the lower portion of the top end of the movable cross beam (405), an air claw driving cylinder (506) and a pressing plate driving cylinder (507) penetrate through the top surface of the partition plate (505) in a sliding mode, the output end of the air claw driving cylinder (506) is fixedly connected with air claws (508) on two sides through a transmission plate (504), the air claws (508) are meshed with a second pressing plate (503), the side of the second pressing plate (503) is fixedly connected with a side mounting plate (502), and clamping strips (509) are vertically fixed to the bottom end of the side mounting plate (502) inwards; the output end of the pressing plate driving air cylinder (507) is connected with a first pressing plate (501) in a transmission mode, and the first pressing plate (501) is arranged between the symmetrically arranged clamping strips (509) and located above the first pressing plate.

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