CN115815158A

CN115815158A - Material transfer device for battery assembly production line

Info

Publication number: CN115815158A
Application number: CN202211183634.6A
Authority: CN
Inventors: 朱金荣; 苑乾坤; 杨振宇; 杨丙鹏
Original assignee: Anhui Zhongneng Power Supply Co ltd
Current assignee: Anhui Zhongneng Power Supply Co ltd
Priority date: 2022-09-27
Filing date: 2022-09-27
Publication date: 2023-03-21

Abstract

The invention discloses a material transfer device for a battery assembly production line, and relates to the technical field of material transfer devices. The invention comprises a first conveying mechanism and two second conveying mechanisms arranged at two sides of the tail end of the first conveying mechanism; the at least two material transfer mechanisms are arranged at the tail end of the first conveying mechanism and used for grabbing and placing the materials from the first conveying mechanism onto the second conveying mechanism; the tail end of the first conveying mechanism positioned right below any material transfer mechanism is provided with a stop structure which can lift; the stop structure comprises a stop lever, and an induction component is arranged on the stop lever. According to the invention, the tail end of the first conveying mechanism is provided with at least two material transfer mechanisms for grabbing and placing materials from the first conveying mechanism onto the second conveying mechanism, and the first conveying mechanism right below the material transfer mechanisms is provided with the stopping structure for limiting the battery shell conveyed along the first conveying mechanism, so that the problem of low overall working efficiency caused by the adoption of a single material transfer mechanism in the prior art is solved.

Description

Material transfer device for battery assembly production line

Technical Field

The invention belongs to the technical field of material transfer devices, and particularly relates to a material transfer device for a battery assembly production line.

Background

The battery case is used as an external assembly of the battery, and has high requirements on the external smoothness in the manufacturing process, so that the battery case cannot have defects such as pits and scratches. Therefore, the appearance of the product is often required to be checked after the production is completed so as to meet the production requirements. The appearance of the existing battery case is generally detected through machinery, and the battery cases meeting the production requirements and not meeting the production requirements are respectively conveyed to corresponding destinations to be placed according to detection results after detection.

In the existing production, a material transfer mechanism is arranged on a detection conveying line and used for grabbing a battery case on the detection conveying line and placing the battery case on a good product conveying line or a defective product conveying line, a certain amount of time is needed due to the action of the material transfer mechanism when a single material transfer mechanism is adopted for use, the detection speed of the battery case is high, the detection speed of the battery case is generally needed to be reduced to adapt to the action speed of the material transfer mechanism in order to use the material transfer mechanism in actual operation, and therefore the overall working efficiency is low.

Disclosure of Invention

The invention aims to provide a material transfer device for a battery assembly production line, which solves the problem of low overall working efficiency caused by the adoption of a single material transfer mechanism in the prior art by arranging at least two material transfer mechanisms at the tail end of a first conveying mechanism for grabbing and placing materials from the first conveying mechanism onto a second conveying mechanism and arranging a stop structure for limiting the conveying of a battery shell along the first conveying mechanism on the first conveying mechanism right below the material transfer mechanisms.

In order to solve the technical problems, the invention is realized by the following technical scheme:

the invention relates to a material transfer device for a battery assembly production line, which comprises a first conveying mechanism and two second conveying mechanisms arranged on two sides of the tail end of the first conveying mechanism; the at least two material transfer mechanisms are arranged at the tail end of the first conveying mechanism and used for grabbing and placing the materials from the first conveying mechanism onto the second conveying mechanism; the tail end of the first conveying mechanism positioned right below any material transfer mechanism is provided with a stopping structure capable of limiting the conveying of the battery shell along the first conveying mechanism in a lifting manner; the stop structure comprises a stop lever horizontally arranged right above the first conveying mechanism, the length direction of the stop lever is vertical to the conveying direction of the first conveying mechanism, and an induction assembly used for detecting whether a battery case abuts against the cross rod is arranged on the stop lever; the sensing assembly is connected with a controller, and the controller is connected with the stop structure and the material transfer mechanism.

Further, the pin includes a rectangle body, one side of rectangle body is provided with a plurality of trompils, the movable rod of activity along trompil department is installed in the cooperation of trompil department, is located be provided with a piston section of thick bamboo on the rectangle body inside wall of trompil department, the tip of movable rod is provided with along the gliding piston of piston section of thick bamboo inside wall, the bottom of piston section of thick bamboo is provided with the business turn over gas port, and is a plurality of a piston section of thick bamboo all communicates a setting in the inside detection chamber of rectangle body, it is provided with the baroceptor of being connected with the controller to detect the intracavity.

Furthermore, an end cover is connected to the port of the piston cylinder through threads, and the end cover is connected with a convex ring arranged on the movable rod through a return spring; the end part of the movable rod, which is positioned outside the rectangular pipe body, is provided with a wrapping foam layer.

Furthermore, a transverse plate is installed on the bottom side face of the rack of the first conveying mechanism, two ends of the transverse plate are respectively provided with a downward bent L-shaped installation plate, a telescopic cylinder and a guide sleeve rod are respectively installed on the two L-shaped installation plates, and the end parts of the telescopic cylinder and the guide sleeve rod are respectively fixed at two ends of the transverse rod; and both ends of the transverse plate are provided with through holes for the telescopic air cylinder and the guide sleeve rod to movably penetrate through.

Furthermore, two ends of the transverse plate are respectively connected with a hanging fixing piece, each hanging fixing piece comprises a fixing ring A movably sleeved on the transverse plate, one side of each fixing ring A is connected with a fixing ring B movably sleeved on the transverse plate through a connecting plate, and the connecting plate is provided with a locking bolt A; the fixing ring A and the fixing ring B are respectively positioned on two sides of the rack; just it has an L shaped plate body to fix solid last integrated into one piece of ring A, the top of L shaped plate body covers directly over the frame, just the top of L shaped plate body is provided with the locking bolt B that leans on in the frame.

Further, material shifts mechanism includes a crossbeam that strides first conveying mechanism end and two second conveying mechanism, the pillar is connected at the both ends of crossbeam, be provided with the horizontal displacement mechanism that sets up along its length direction on the crossbeam, be connected with vertical displacement mechanism on the horizontal displacement mechanism, the tip of vertical displacement mechanism is installed and is used for carrying on the mechanism that snatchs of battery case.

Furthermore, the grabbing mechanism comprises a well-shaped support, a plurality of vacuum suckers arranged on the well-shaped support, and a connecting seat arranged on the well-shaped support and used for being connected with the vertical displacement mechanism.

Further, the well-type bracket comprises a pair of cross rods arranged in parallel and a pair of longitudinal rod assemblies arranged in parallel; the vacuum chuck is arranged on the longitudinal rod assembly; the longitudinal rod assembly is connected with the transverse rod through a connecting piece A.

Furthermore, the longitudinal rod assembly comprises a first longitudinal rod connected with the cross rod through a connecting piece, and a second longitudinal rod is connected to the position right below the first longitudinal rod through a connecting piece B; the first longitudinal rod and the second longitudinal rod are both square tubes, and two adjacent side surfaces of the end part of each square tube are respectively provided with a locking bolt C; the connecting piece B comprises inserting rods inserted into the first longitudinal rod and the second longitudinal rod and a connecting rod connected between the two inserting rods; the connecting piece A comprises two integrally formed rectangular rings which are respectively sleeved on the transverse rod and the first longitudinal rod, and locking bolts are respectively arranged on two adjacent side surfaces of the rectangular rings; the axial directions of the two rectangular rings are perpendicular.

Further, the vacuum chuck comprises a movable sleeve movably sleeved on the second longitudinal rod, a mounting plate is arranged on one side of the movable sleeve, a vacuum chuck body is connected onto the mounting plate, a bolt hole is formed in the movable sleeve, and a locking bolt E is connected onto the bolt hole.

The invention has the following beneficial effects:

according to the invention, the tail end of the first conveying mechanism is provided with at least two material transfer mechanisms for grabbing and placing materials from the first conveying mechanism onto the second conveying mechanism, and the first conveying mechanism right below the material transfer mechanisms is provided with the stopping structure for limiting the battery shell conveyed along the first conveying mechanism, so that the problem of low overall working efficiency caused by the adoption of a single material transfer mechanism in the prior art is solved.

Of course, it is not necessary for any product in which the invention is practiced to achieve all of the above-described advantages at the same time.

Drawings

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

FIG. 1 is a schematic view of a material transfer device according to the present invention;

FIG. 2 is a schematic structural diagram of a first conveying mechanism according to the present invention;

FIG. 3 is a side view of FIG. 2;

FIG. 4 is a schematic view of the structure of the stop lever of the present invention;

FIG. 5 is an enlarged view of a portion A of FIG. 4;

fig. 6 is a schematic structural view of the grasping mechanism of the present invention.

Detailed Description

Referring to fig. 1, a material transfer device for a battery assembly line comprises a first conveying mechanism 1, two second conveying mechanisms 2 arranged at two sides of the tail end of the first conveying mechanism 1; the three material transfer mechanisms 3 are arranged at the tail end of the first conveying mechanism 1 and used for grabbing and placing materials from the first conveying mechanism 1 onto the second conveying mechanism 2; the tail end of the first conveying mechanism 1 positioned under any material transfer mechanism 3 is provided with a stopping structure capable of limiting the conveying of the battery shell along the first conveying mechanism 1 in a lifting manner; the stopping structure comprises a stop lever 5 horizontally arranged right above the first conveying mechanism 1, the length direction of the stop lever 5 is vertical to the conveying direction of the first conveying mechanism 1, and an induction assembly used for detecting whether a battery shell abuts against the stop lever 5 is arranged on the stop lever 5; the sensing assembly is connected with a controller, and the controller is connected with the stop structure and the material transfer mechanism 3.

When the battery case is used, when the battery case passing the detection is conveyed to the tail end of the battery case along the first conveying mechanism 1, according to the detection result of the detection mechanism connected with the controller and used for detecting the battery case, when the judged battery case moves and abuts against the first cross rod 4, the second cross rod 4 positioned on one side of the first cross rod 4 descends downwards, and the battery case can be grabbed onto the corresponding second conveying mechanism 2 according to the detection result through the material transfer mechanism 3; when a second battery case moves and abuts against the third cross rod 4, the third cross rod 4 is controlled to descend downwards, the battery case is grabbed to the corresponding second conveying mechanism 2 through the material transfer mechanism 3 according to the detection result of the battery case, when the second battery case moves and abuts against the third cross rod 4, the transfer mechanism 3 is controlled to grab the battery case to the corresponding second conveying mechanism 2 according to the detection result of the battery case, and meanwhile the second cross rod 4 and the third cross rod 4 are controlled to ascend upwards.

As shown in fig. 4, the blocking rod 5 includes a rectangular tube 51, one side of the rectangular tube 51 is provided with a plurality of openings 52, the openings 52 are provided with movable rods 53 moving along the openings 52, an inner side wall of the rectangular tube 51 at the openings 52 is provided with a piston cylinder 54, an end of each movable rod 53 is provided with a piston 55 sliding along the inner side wall of the piston cylinder 54, the bottom of the piston cylinder 54 is provided with an air inlet and an air outlet, the plurality of piston cylinders 54 are all communicated with a detection chamber 56 arranged inside the rectangular tube 51, and an air pressure sensor connected with a controller is arranged in the detection chamber 56; when the battery case leans on the pin 5, when the battery case strikes on the movable rod 53 this moment, control movable rod 53 and move to the inboard, then the effective space that piston cylinder 54 and detection chamber 56 constitute this moment obtains compressing, then the baroceptor detects atmospheric pressure change fast, then the surface battery case removes and leans on the pin 5 to conveniently control material transfer mechanism 3 and move.

As shown in fig. 5, an end cap 57 is screwed to the port of the piston cylinder 54, and the end cap 57 is connected to a convex ring 59 provided on the movable rod 53 through a return spring 58; the end part of the movable rod 53 positioned outside the rectangular pipe body 51 is provided with a wrapping foam layer; through the arrangement of the return spring 58, the initial state is conveniently recovered under the self-elastic action of the return spring 58 after the return spring 58 completes compression and the battery shell is removed.

As in fig. 2 and 3; a transverse plate 10 is installed on the bottom side face of a rack of the first conveying mechanism 1, two ends of the transverse plate 10 are respectively provided with a downward bent L-shaped installation plate 11, two L-shaped installation plates 11 are respectively provided with a telescopic cylinder 12 and a guide sleeve rod 13, and the end parts of the telescopic cylinder 12 and the guide sleeve rod 13 are respectively fixed at two ends of a transverse rod 4; both ends of the transverse plate 10 are provided with a through hole 14 for the flexible penetration of the telescopic cylinder 12 and the guide sleeve rod 13; the two ends of the transverse plate 10 are also respectively connected with a hanging fixing piece, the hanging fixing piece comprises a fixing ring A15 movably sleeved on the transverse plate 10, one side of the fixing ring A15 is connected with a fixing ring B17 movably sleeved on the transverse plate 10 through a connecting plate 16, and a locking bolt A161 is arranged on the connecting plate 16; the fixing ring A15 and the fixing ring B17 are respectively positioned at two sides of the frame; an L-shaped plate body 18 is integrally formed on the fixing ring A15, the top end of the L-shaped plate body 18 covers the right upper side of the rack, and a locking bolt B181 which is abutted against the rack is arranged at the top of the L-shaped plate body 18; through the arrangement of the telescopic cylinder 12 and the guide sleeve rod 13, the telescopic cylinder 12 is conveniently controlled to be telescopic according to the parameter change of the air pressure sensor and an actual production control program; simultaneously, through the arrangement of the hanging fixing piece, the installation of the transverse plates 10 is adjustable, and the gap between every two adjacent transverse plates 10 can be conveniently adjusted according to actual requirements.

As in fig. 1 and 6; the material transfer mechanism 3 comprises a beam 30 which spans the end of the first conveying mechanism 1 and the two second conveying mechanisms 2, two ends of the beam 30 are connected with a support 33, a horizontal displacement mechanism 31 arranged along the length direction of the beam 30 is arranged on the beam 30, a vertical displacement mechanism 32 is connected on the horizontal displacement mechanism 31, and a grabbing mechanism 4 used for grabbing the battery case is arranged at the end part of the vertical displacement mechanism 32; the grabbing mechanism 4 comprises a well-shaped bracket, a plurality of vacuum suckers 41 arranged on the well-shaped bracket, and a connecting seat 42 arranged on the well-shaped bracket and used for being connected with the vertical displacement mechanism 32; the well-type support comprises a pair of cross rods 43 arranged in parallel and a pair of longitudinal rod assemblies 44 arranged in parallel; the vacuum chuck 41 is arranged on the longitudinal rod assembly 44; the longitudinal rod assembly 44 is connected with the transverse rod 43 through a connecting piece A45; the vertical rod assembly 44 comprises a first vertical rod 441 connected with the cross rod 43 through a connecting piece 45, and a second vertical rod 443 is connected to the position right below the first vertical rod 441 through a connecting piece B442; the first longitudinal rod 441 and the second longitudinal rod 443 are both square tubes, and locking bolts C444 are respectively arranged on two adjacent side faces of the end portions of the square tubes; the connecting member B442 includes insertion rods inserted into the first and second

longitudinal rods

441 and 443, and a connecting rod connected between the two insertion rods; the connecting piece A45 comprises two integrally formed rectangular rings 451 which are respectively sleeved on the cross rod 43 and the first longitudinal rod 441, and two adjacent side surfaces of each rectangular ring 451 are respectively provided with a locking bolt 452; the axial directions of the two rectangular rings 451 are vertical; the vacuum chuck 41 comprises a movable sleeve 411 movably sleeved on the second longitudinal rod 443, one side of the movable sleeve 411 is provided with a mounting plate 412, the mounting plate 412 is connected with a vacuum chuck body 413, the movable sleeve 251 is provided with a bolt hole 414, and the bolt hole 414 is connected with a locking bolt E; through the well-type support provided by the longitudinal rod assemblies 44 and the cross rods 43, the gaps among the longitudinal rod assemblies 44, the gaps among the cross rods 43 and the gaps among the vacuum suction cups 41 arranged on the longitudinal rod assemblies 44 can be adjusted in practical operation, so that the requirements on battery cases with different sizes can be conveniently sucked.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims

1. The utility model provides a material transfer device for battery assembly production line which characterized in that: comprises a first conveying mechanism (1) and two second conveying mechanisms (2) arranged at two sides of the tail end of the first conveying mechanism (1);

the material transfer mechanisms (3) are arranged at the tail end of the first conveying mechanism (1) and used for grabbing and placing materials from the first conveying mechanism (1) onto the second conveying mechanism (2);

the tail end of the first conveying mechanism (1) positioned under any material transfer mechanism (3) is provided with a stopping structure capable of limiting the conveying of the battery shell along the first conveying mechanism (1) in a lifting manner;

the stopping structure comprises a stop lever (5) horizontally arranged right above the first conveying mechanism (1), the length direction of the stop lever (5) is vertical to the conveying direction of the first conveying mechanism (1), and an induction assembly used for detecting whether a battery case abuts against the stop lever (5) is arranged on the stop lever (5);

the induction assembly is connected with a controller, and the controller is connected with the stop structure and the material transfer mechanism (3).

2. The material transfer device for the battery assembling line according to claim 1, wherein the blocking rod (5) comprises a rectangular tube (51), one side of the rectangular tube (51) is provided with a plurality of openings (52), the openings (52) are provided with movable rods (53) which are movable along the openings (52) in a matching manner, an inner side wall of the rectangular tube (51) at the openings (52) is provided with a piston cylinder (54), the end part of each movable rod (53) is provided with a piston (55) which slides along the inner side wall of the piston cylinder (54), the bottom of the piston cylinder (54) is provided with an air inlet and an air outlet, the piston cylinders (54) are communicated with a detection cavity (56) arranged inside the rectangular tube (51), and an air pressure sensor connected with a controller is arranged in the detection cavity (56).

3. The material transfer device for the battery assembly production line according to claim 1, wherein an end cover (57) is connected to a port of the piston cylinder (54) in a threaded manner, and a convex ring (59) arranged on the movable rod (53) is connected to the end cover (57) through a return spring (58); the end part of the movable rod (53) positioned outside the rectangular pipe body (51) is provided with a wrapping foam layer.

4. The material transfer device for the battery assembly production line is characterized in that a transverse plate (10) is installed on the side face of the bottom of a frame of the first conveying mechanism (1), two ends of the transverse plate (10) are respectively provided with a downward bent L-shaped installation plate (11), two L-shaped installation plates (11) are respectively provided with a telescopic cylinder (12) and a guide sleeve rod (13), and the end portions of the telescopic cylinder (12) and the guide sleeve rod (13) are respectively fixed at two ends of a transverse rod (4);

wherein, both ends of the transverse plate (10) are provided with a through hole (14) for the flexible penetration of the telescopic cylinder (12) and the guide sleeve rod (13).

5. The material transfer device for the battery assembly production line according to claim 4, wherein two ends of the transverse plate (10) are respectively connected with a hanging fixing piece, the hanging fixing piece comprises a fixing ring A (15) movably sleeved on the transverse plate (10), one side of the fixing ring A (15) is connected with a fixing ring B (17) movably sleeved on the transverse plate (10) through a connecting plate (16), and a locking bolt A (161) is arranged on the connecting plate (16); the fixing ring A (15) and the fixing ring B (17) are respectively positioned on two sides of the rack;

and an L-shaped plate body (18) is integrally formed on the fixing ring A (15), the top end of the L-shaped plate body (18) covers the right above the rack, and a locking bolt B (181) abutted against the rack is arranged at the top of the L-shaped plate body (18).

6. The material transfer device for the battery assembly line according to claim 1, wherein the material transfer mechanism (3) comprises a cross beam (30) spanning the first conveying mechanism (1) and the second conveying mechanisms (2), the two ends of the cross beam (30) are connected with a support column (33), a horizontal displacement mechanism (31) arranged along the length direction of the cross beam (30) is arranged on the cross beam (30), a vertical displacement mechanism (32) is connected on the horizontal displacement mechanism (31), and a grabbing mechanism (4) for grabbing a battery case is arranged at the end of the vertical displacement mechanism (32).

7. A material transfer device for a battery assembling line according to claim 6, characterized in that the gripping mechanism (4) comprises a well-shaped support, a plurality of vacuum suction cups (41) arranged on the well-shaped support, and a connecting seat (42) arranged on the well-shaped support for connecting with the vertical displacement mechanism (32).

8. A material transfer device for a battery assembly line according to claim 7, wherein the well-type support comprises a pair of parallel arranged cross bars (43) and a pair of parallel arranged side bar assemblies (44);

the vacuum chuck (41) is arranged on the longitudinal rod assembly (44);

the longitudinal rod assembly (44) is connected with the transverse rod (43) through a connecting piece A (45).

9. The material transfer device for the battery assembling line according to claim 8, wherein the vertical rod assembly (44) comprises a first vertical rod (441) connected with the cross rod (43) through a connecting piece (45), and a second vertical rod (443) is connected with the connecting piece B (442) right below the first vertical rod (441); the first longitudinal rod (441) and the second longitudinal rod (443) are both square tubes, and two adjacent side surfaces of the end part of each square tube are respectively provided with a locking bolt C (444); the connecting piece B (442) comprises inserting rods inserted into the first longitudinal rod (441) and the second longitudinal rod (443), and a connecting rod connected between the two inserting rods;

the connecting piece A (45) comprises two integrally formed rectangular rings (451) which are respectively sleeved on the cross rod (43) and the first longitudinal rod (441), and two adjacent side surfaces of each rectangular ring (451) are respectively provided with a locking bolt (452); the axial directions of the two rectangular rings (451) are perpendicular.

10. The material transfer device for the battery assembly line according to claim 9, wherein the vacuum chuck (41) comprises a movable sleeve (411) movably sleeved on the second longitudinal rod (443), a mounting plate (412) is arranged on one side of the movable sleeve (411), a vacuum chuck body (413) is connected onto the mounting plate (412), a bolt hole (414) is arranged on the movable sleeve (251), and a locking bolt E is connected onto the bolt hole (414).