CN218975351U - Automatic assembly device of magnetic latching relay - Google Patents

Abstract

The utility model relates to the field of relays, and discloses an automatic assembly device of a magnetic latching relay, which comprises a support frame, wherein an operation table is arranged at the top of the support frame, two conveyor belts are arranged on the operation table, a blanking assembly for staggered discharging of an upper relay shell and a lower relay shell is also arranged on the operation table, the blanking assembly comprises a storage box and a blanking block which are matched, and a blanking cylinder for driving the blanking block to move, a transfer cylinder for picking up the upper relay shell and being adhered to the lower relay shell is also arranged on the operation table, and a sucking disc is connected to the telescopic end of the transfer cylinder; still install the rubberizing subassembly that is used for coating glue in the relay upper housing bottom on the operation panel, install the rubber coating sponge in the rubber coating board, adsorb glue on the rubber coating sponge, be equipped with elastic component on the electronic slider, elastic component is used for drawing to transport the cylinder and removes. Compared with the prior art, the magnetic latching relay assembly method solves the series of problems of low assembly efficiency and the like of the magnetic latching relay.

Description

Automatic assembly device of magnetic latching relay

Technical Field

The utility model relates to the field of relays, in particular to an automatic assembly device of a magnetic latching relay.

Background

The magnetic latching relay is a novel relay developed in recent years and is also an automatic switch. Like other electromagnetic relays, the electromagnetic relay has the function of automatically switching on and off the circuit. The magnetic latching relay is characterized in that the normally closed or normally open state of the magnetic latching relay is completely dependent on the action of permanent magnet steel, and the switching state is switched by triggering a pulse electric signal with a certain width.

In the prior art, the Chinese patent document with the publication number of CN106531557B proposes an assembly structure of a magnetic latching relay and an assembly method thereof, and the assembly structure of the magnetic latching relay can assemble and form the magnetic core assembly only by small-amplitude displacement during assembly, so that the assembly is simple, the assembly efficiency is high, meanwhile, the contact area between a bolt and a base is reduced as much as possible during the assembly process, the stability during assembly is improved, the assembly efficiency of electronic elements such as coils and the like in the relay is optimized, but the assembly structure does not propose how to realize the rapid assembly between the outer shells of the magnetic latching relay, and in actual operation, a large number of magnetic latching relays still need manual adhesive clamping of operators, and the overall assembly efficiency on an assembly line is low.

Disclosure of Invention

(one) solving the technical problems

Aiming at the defects of the prior art, the utility model provides an automatic assembly device of a magnetic latching relay, which has the advantages of improving the assembly efficiency of the magnetic latching relay and the like, and solves the series problems of low assembly efficiency of the magnetic latching relay and the like in the prior art.

(II) technical scheme

In order to achieve the above purpose, the present utility model provides the following technical solutions: the automatic assembly device for the magnetic latching relay comprises a supporting frame, wherein an operation table is arranged at the top of the supporting frame, two conveying belts used for conveying an upper relay shell and a lower relay shell are arranged on the operation table, a blanking assembly used for staggered discharging of the upper relay shell and the lower relay shell is further arranged on the operation table, the blanking assembly comprises a storage box and a blanking block which are matched, and a blanking cylinder used for driving the blanking block to move, a transfer cylinder used for picking up the upper relay shell and being adhered to the lower relay shell, a guide sliding rail and an electric sliding block used for driving the transfer cylinder to move are further arranged on the operation table, and a sucking disc is connected to the telescopic end of the transfer cylinder; still install on the operation panel and be used for the rubberizing subassembly of casing bottom coating glue on the relay, rubberizing subassembly include with the rubberizing board of casing looks adaptation on the relay, install the rubberizing sponge in the rubberizing board, adsorb the glue on the rubberizing sponge, be equipped with elastic component on the electronic slider, elastic component is used for drawing transfer cylinder removes to including reset spring.

Preferably, the driving rollers located at the same height are rotatably installed at two ends of the operating platform, the two conveying belts are sleeved on the two driving rollers, and the outer walls of the two driving rollers are fixedly sleeved with baffle rings used for preventing the conveying belts from falling off.

Preferably, one end of one of the driving rollers extends out of one side of the operating table, and is fixedly sleeved with a driving sprocket, and the driving sprocket is connected with an external driving sprocket through a driving chain.

Preferably, the top of the operation table is fixedly provided with a supporting table, the conveyor belt is sleeved on the supporting table, the top side of the supporting table is fixedly connected with two limiting strips which are respectively attached to the side walls of the conveyor belt, and the two sides of the operation table are respectively provided with a guide plate attached to the other side wall of the conveyor belt.

Preferably, the top of the operation desk is also fixedly provided with two storage boxes corresponding to the positions through a fixing frame, the upper relay shell and the lower relay shell which are uniformly distributed are respectively positioned in the storage boxes at the corresponding sides, and the bottom ends of the two storage boxes are respectively matched with the positions of the conveyor belts at the corresponding sides.

Preferably, the end of the operation table is fixedly provided with a vertical plate through a bolt, two blanking cylinders are arranged on the vertical plate, the telescopic ends of the two blanking cylinders are fixedly connected with blanking blocks which are respectively positioned at the bottom ends of the storage boxes, and the width of each blanking block is matched with the inner diameter of the bottom ends of the storage boxes.

Preferably, the guide slide rail is fixedly installed at the top of the operating platform, the electric sliding block is sleeved on the guide slide rail in a sliding mode, one side of the electric sliding block is fixedly connected with an extension seat through a bolt, a sliding block is arranged on the extension seat in a sliding mode, the transfer cylinder is installed on the sliding block, and the sucker is matched with the top end of the upper shell of the relay.

Preferably, both sides of the glue coating plate are all curved, the glue coating plate is located between the two conveyor belts, the bottom of the glue coating plate is arranged on the supporting table through a connecting rod sliding sleeve, the bottom of the connecting rod penetrates through the supporting table and extends to the outside of the bottom side of the supporting table, a vertical spring is further sleeved on the connecting rod, both ends of the vertical spring are respectively connected on the glue coating plate and the supporting table, an installation groove is formed in the top end of the glue coating plate, and the glue coating sponge is located in the installation groove.

Preferably, the extension seat is also fixedly connected with a guide rod, the sliding block is sleeved on the guide rod in a sliding manner, the guide rod is also sleeved with a return spring, and two ends of the return spring are respectively connected with the inner wall of one side of the extension seat and the sliding block.

(III) beneficial effects

Compared with the prior art, the utility model provides an automatic assembly device of a magnetic latching relay, which has the following beneficial effects:

1. the automatic assembly device of the magnetic latching relay and the method thereof synchronously pull the driving chain wheel to rotate through the external driving chain wheel and the driving chain, so that one driving roller rotates, two conveyor belts synchronously rotate under the action of the other driving roller, and simultaneously blanking cylinders on two sides alternately run, so that the upper relay shell and the lower relay shell in the two storage boxes alternately blanking onto the conveyor belts on the corresponding sides below, when the upper relay shell moves to the position right below the transferring cylinder, the transferring cylinder operates forward and backward firstly and reversely, the upper relay shell below is absorbed by a sucker, then the electric sliding block slides to one side on a guiding sliding rail and indirectly drives the transferring cylinder to move to one side, and after the absorbed upper relay shell touches a glue coating plate, as the two sides of the glue coating plate are arranged in a cambered surface, under the vertical guiding action of the connecting rod, the gluing plate moves downwards, so that the bottom end of the upper relay shell continuously moves to one side and contacts with the gluing sponge, under the elastic supporting action of the vertical spring, the bottom end of the upper relay shell is tightly attached to the gluing sponge, thus completing the gluing operation of the bottom end of the upper relay shell, then, the electric sliding block pulls the upper relay shell to the position right above the lower relay shell at the other side, then, the transfer cylinder operates again, the upper relay shell is pressed at the top end of the lower relay shell, the quick assembly of the outer relay shell is completed through the adhesive action of the glue at the bottom end of the upper relay shell, then, the electric sliding block drives the transfer cylinder to restore to the initial position, the upper relay shell is adsorbed, and compared with the traditional manual assembly technology, the gluing assembly operation is carried out, the assembly efficiency of the magnetic latching relay is improved.

2. According to the automatic assembly device and the method for the magnetic latching relay, in the process of assembling the upper relay shell and the lower relay shell through the sucking disc, after the upper relay shell and the lower relay shell are bonded, the continuous operation of the corresponding side conveyor belt is accompanied, under the guiding action of the guide rod, the upper relay shell drives the transfer cylinder to move in the direction away from the electric sliding block, the bonding time of the upper relay shell and the lower relay shell is prolonged, and the assembly effect of the magnetic latching relay is improved.

Drawings

FIG. 1 is a schematic perspective view of an automated assembly device for a magnetic latching relay of the present utility model;

FIG. 2 is a schematic view of a portion of the enlarged structure of FIG. 1 according to the present utility model;

FIG. 3 is a schematic perspective view of an operation table according to the present utility model;

FIG. 4 is a schematic perspective view of a sizing assembly according to the present utility model;

FIG. 5 is a schematic perspective view of a blanking assembly of the present utility model;

fig. 6 is a schematic perspective view of an elastic component of the present utility model.

In the figure: 1. a support frame; 2. an operation table; 3. a driving roller; 4. a conveyor belt; 5. a baffle ring; 6. a limit bar; 7. a drive sprocket; 8. a fixing frame; 9. a reserve box; 10. a blanking cylinder; 11. a blanking block; 12. a guide plate; 13. a support table; 14. an upper relay case; 15. a relay lower case; 16. a guide rail; 17. an electric slide block; 18. an extension base; 19. a sliding block; 20. a transfer cylinder; 21. a suction cup; 22. a guide rod; 23. a return spring; 24. coating a glue plate; 25. a vertical spring; 26. and (5) gluing a sponge.

Detailed Description

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

As described in the background art, the present application provides an automatic assembly device for a magnetic latching relay in order to solve the above technical problems.

In a typical embodiment of the present application, as shown in fig. 1-6, an automatic assembly device of a magnetic latching relay includes a support frame 1, an operation table 2 is installed on the top of the support frame 1, two conveyor belts 4 for conveying an upper relay housing 14 and a lower relay housing 15 are installed on the operation table 2, a blanking assembly for staggered discharging of the upper relay housing 14 and the lower relay housing 15 is also installed on the operation table 2, the blanking assembly includes an adaptive storage box 9 and a blanking block 11, and a blanking cylinder 10 for driving the blanking block 11 to move, a transfer cylinder 20 for picking up the upper relay housing 14 and adhering to the lower relay housing 15 is also installed on the operation table 2, a guide slide rail 16 and an electric slide block 17 for driving the transfer cylinder 20 to move are also installed on the operation table 2, and a sucker 21 is connected to a telescopic end of the transfer cylinder 20; the operation panel 2 is last still to install the rubberizing subassembly that is used for coating glue in the upper relay casing 14 bottom, rubberizing subassembly includes the rubberizing board 24 with upper relay casing 14 looks adaptation, install the rubberizing sponge 26 in the rubberizing board 24, adsorb glue on the rubberizing sponge 26, be equipped with elastic component on the electric slider 17, elastic component is used for drawing and transport cylinder 20 and remove, and including reset spring 23, during operation, through the synchronous operation of two conveyer belts 4, cooperation blanking subassembly, make upper relay casing 14 and lower relay casing 15 crisscross blanking to correspond on the conveyer belt 4, and when upper relay casing 14 carries to the relay under transporting cylinder 20, transport cylinder 20 cooperation sucking disc 21 adsorb the upper relay casing 14 of below immediately, transfer to the relay under the relay casing 15 of opposite side top, transfer in-process, accomplish the rubber coating through rubberizing subassembly to the lower extreme of upper relay casing 14, and then through transporting cylinder 20 function, after pressing down the relay upper relay casing 14 after the rubber coating on the relay under casing 15, accomplish the quick operation of magnetic latching relay casing, compare the manual assembly with the relay casing 15, the manual assembly efficiency is improved, the manual assembly is compared with the relay casing is improved, the manual assembly is realized, and the magnetic assembly is improved, and the magnetic assembly is convenient, and the relay is easy to install.

As a preferred implementation manner in this embodiment, referring to fig. 2-5, the two ends of the operation table 2 are rotatably provided with driving rollers 3 located at the same height, two conveyor belts 4 are sleeved on the two driving rollers 3, the outer walls of the two driving rollers 3 are fixedly sleeved with baffle rings 5 for preventing the conveyor belts 4 from falling off, one end of one driving roller 3 extends to the outside of one side of the operation table 2 and is fixedly sleeved with a driving sprocket 7, the driving sprocket 7 is connected with an external driving sprocket through a driving chain, the top end of the operation table 2 is fixedly provided with a supporting table 13, the conveyor belts 4 are sleeved on the supporting table 13, the top side of the supporting table 13 is fixedly connected with two limiting strips 6 respectively attached to the side walls of the corresponding conveyor belts 4, two sides of the operation table 2 are provided with guide plates 12 attached to the other side walls of the corresponding conveyor belts 4, the top of the operation table 2 is fixedly provided with two storage boxes 9 corresponding to the positions through a fixing frame 8, a plurality of evenly distributed relay upper shells 14 and relay lower shells 15 are respectively positioned in the storage boxes 9 on the corresponding sides, the bottom ends of the two storage boxes 9 are respectively matched with the positions of the conveyor belts 4 on the corresponding sides, the end parts of the operation table 2 are fixedly provided with vertical plates through bolts, the two blanking cylinders 10 are respectively arranged on the vertical plates, the telescopic ends of the two blanking cylinders 10 are respectively fixedly connected with blanking blocks 11 respectively positioned at the bottom ends of the different storage boxes 9, the width of the blanking blocks 11 is matched with the inner diameter of the bottom ends of the storage boxes 9, a guide sliding rail 16 is fixedly arranged at the top of the operation table 2, an electric sliding block 17 is sleeved on the guide sliding rail 16, one side of the electric sliding block 17 is fixedly connected with an extension seat 18 through bolts, a sliding block 19 is arranged on the extension seat 18 in a sliding way, the transfer cylinder 20 is arranged on the sliding block 19, the sucking disc 21 is matched with the top end of the relay upper shell 14, two sides of the glue coating plate 24 are respectively in bending arrangement, the glue coating plate 24 is positioned between two transmission belts 4, the bottom end of the glue coating plate 24 is slidably sleeved on the supporting table 13 through a connecting rod, the bottom end of the connecting rod penetrates through the supporting table 13 and extends out of the bottom side of the supporting table 13, the connecting rod is sleeved with a vertical spring 25, two ends of the vertical spring 25 are respectively connected on the glue coating plate 24 and the supporting table 13, the top end of the glue coating plate 24 is provided with a mounting groove, the glue coating sponge 26 is positioned in the mounting groove, when in assembly, the glue coating sponge is synchronously pulled to drive the sprocket 7 to rotate through an external driving sprocket and a driving chain, and then one driving roller 3 is enabled to rotate, and under the action of the other driving roller 3, the two transmission belts 4 are enabled to synchronously rotate, meanwhile, the blanking cylinders 10 on two sides are operated in a staggered manner, so that the relay upper shells 14 and the relay lower shells 15 in the two storage boxes 9 are blanked on the conveyor belt 4 on the corresponding side below in a staggered manner, when the relay upper shells 14 are moved to the position right below the transfer cylinder 20 (the starting position of the transfer cylinder 20 is positioned right above the conveyor belt 4 for conveying the relay upper shells 14), the transfer cylinder 20 is operated in the forward and backward directions firstly, the lower relay upper shells 14 are adsorbed by the sucking disc 21, then the electric sliding block 17 slides to one side on the guide sliding rail 16 and indirectly drives the transfer cylinder 20 to move to one side, after the adsorbed relay upper shells 14 touch the rubberizing plate 24, the two sides of the rubberizing plate 24 are arranged in an arc surface manner, under the vertical guiding effect of the connecting rod, the rubberizing plate 24 is moved downwards, the bottom of the upper relay shell 14 is contacted with the gluing sponge 26 in the process of continuously moving to one side, the bottom of the upper relay shell 14 is tightly attached to the gluing sponge 26 under the action of the elastic force support of the vertical spring 25, so that gluing operation on the bottom of the upper relay shell 14 is completed, then the upper relay shell 14 is pulled to the position right above the lower relay shell 15 on the other side by the electric sliding block 17, then the transfer cylinder 20 operates again, the upper relay shell 14 is pressed on the top of the lower relay shell 15 below, rapid assembly of the outer shell of the magnetic latching relay is completed through the adhesive action of glue on the bottom of the upper relay shell 14, then the electric sliding block 17 drives the transfer cylinder 20 to return to the initial position, the next upper relay shell 14 is adsorbed, and gluing assembly operation is carried out, so that compared with the existing manual assembly technology, the assembly efficiency of the magnetic latching relay is improved.

As a preferred embodiment in this embodiment, referring to fig. 6, a guide rod 22 is fixedly connected to the extension seat 18, a sliding block 19 is slidably sleeved on the guide rod 22, a return spring 23 is further sleeved on the guide rod 22, two ends of the return spring 23 are respectively connected to an inner wall of one side of the extension seat 18 and the sliding block 19, the electric sliding block 17 pulls the transfer cylinder 20 to move, and in the process of assembling the relay upper shell 14 and the relay lower shell 15 through the suction disc 21, after the relay upper shell 14 and the relay lower shell 15 are adhered, the transfer cylinder 20 is driven to move away from the electric sliding block 17 along with continuous operation of the corresponding side conveyor belt 4 under the guiding action of the guide rod 22, so that the adhesion time between the relay upper shell 14 and the relay lower shell 15 is longer, the assembly effect of the magnetic latching relay is improved, meanwhile, the return spring 23 deforms and holds the force, after the transfer cylinder 20 moves along with the conveyor belt 4 for a certain distance, the operation of the transfer cylinder 20 is controlled, the compression action of the suction disc 21 on the relay upper shell 14 is relieved, and under the elastic sliding block 23, the elastic sliding block of the transfer cylinder 17 is matched, and the assembly operation is restored to the initial position of the transfer cylinder 20.

The working principle of the utility model is as follows: during assembly, the driving sprocket 7 is synchronously pulled to rotate through the external driving sprocket and the driving chain, one driving roller 3 rotates, so that under the action of the other driving roller 3, the two conveyor belts 4 synchronously rotate, meanwhile, the blanking cylinders 10 at two sides alternately run, the upper relay shell 14 and the lower relay shell 15 in the two storage boxes 9 alternately blanking onto the conveyor belts 4 at the corresponding sides below, when the upper relay shell 14 moves to the position right below the transfer cylinder 20, the transfer cylinder 20 positively and reversely runs at first, the lower upper relay shell 14 is adsorbed by the sucking disc 21, then the electric sliding block 17 slides to one side on the guide sliding rail 16 and indirectly drives the transfer cylinder 20 to move to one side, after the adsorbed upper relay shell 14 touches the glue coating plate 24, as the two sides of the glue coating plate 24 are cambered surfaces, under the vertical guiding action of the connecting rod, the glue spreading plate 24 moves downwards, so that the bottom end of the upper relay shell 14 is contacted with the glue spreading sponge 26 in the process of continuously moving to one side, the bottom end of the upper relay shell 14 is tightly attached to the glue spreading sponge 26 under the elastic supporting action of the vertical spring 25, so that the glue spreading operation on the bottom end of the upper relay shell 14 is completed, then the upper relay shell 14 is pulled to the right upper side of the lower relay shell 15 by the electric sliding block 17, then the transfer cylinder 20 operates again, the upper relay shell 14 is pressed on the top end of the lower relay shell 15, the quick assembly of the outer relay shell of the magnetic latching relay is completed under the adhesive action of glue at the bottom end of the upper relay shell 14, the transfer cylinder 20 is driven by the electric sliding block 17 to restore to the initial position, the next upper relay shell 14 is adsorbed, and compared with the existing manual assembly technology, the assembly efficiency of the magnetic latching relay is improved by performing gluing assembly operation.

The electric sliding block 17 pulls the transfer air cylinder 20 to move, and in the process of assembling the relay upper shell 14 and the relay lower shell 15 through the sucker 21, after the relay upper shell 14 and the relay lower shell 15 are adhered, the relay upper shell 14 is driven to move in the direction away from the electric sliding block 17 along with the continuous operation of the corresponding side conveyor belt 4 under the guiding action of the guide rod 22, so that the relay upper shell 14 drives the transfer air cylinder 20 to move in the direction away from the electric sliding block 17, the adhesion time of the relay upper shell 14 and the relay lower shell 15 is prolonged, and the assembly effect of the magnetic latching relay is improved.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. An automatic assembly device of magnetic latching relay which characterized in that: the automatic feeding device comprises a supporting frame (1), an operation table (2) is arranged at the top of the supporting frame (1), two conveying belts (4) used for conveying an upper relay shell (14) and a lower relay shell (15) are arranged on the operation table (2), a blanking assembly used for staggered discharging of the upper relay shell (14) and the lower relay shell (15) is further arranged on the operation table (2), the blanking assembly comprises a storage box (9) and a blanking block (11) which are matched, and a blanking cylinder (10) used for driving the blanking block (11) to move, a transfer cylinder (20) used for picking up the upper relay shell (14) and adhering the upper relay shell (15) and a guide sliding rail (16) and an electric sliding block (17) used for driving the transfer cylinder (20) to move are further arranged on the operation table (2), and a telescopic end of the transfer cylinder (20) is connected with a sucker (21);

still install on operation panel (2) and be used for the rubberizing subassembly of casing (14) bottom coating glue on the relay, rubberizing subassembly include with rubberizing board (24) of casing (14) looks adaptation on the relay, install rubberizing sponge (26) in rubberizing board (24), adsorb on rubberizing sponge (26) and have glue, be equipped with elastic component on electronic slider (17), elastic component is used for drawing transfer cylinder (20) remove to including reset spring (23).

2. An automated assembly device for a magnetic latching relay according to claim 1, wherein: the two ends of the operating table (2) are rotatably provided with driving rollers (3) positioned at the same height, the two conveying belts (4) are sleeved on the two driving rollers (3), and baffle rings (5) used for preventing the conveying belts (4) from falling off are fixedly sleeved on the outer walls of the driving rollers (3).

3. An automated assembly device for a magnetic latching relay according to claim 2, wherein: one end of one driving roller (3) extends to the outside of one side of operation panel (2) to fixedly cup joint driving sprocket (7), driving sprocket (7) are connected through the drive chain with outside driving sprocket.

4. An automated assembly device for a magnetic latching relay according to claim 3, wherein: the top of operation panel (2) still fixed mounting has brace table (13), conveyer belt (4) cover is established on brace table (13), just the top side of brace table (13) still fixedly connected with two respectively with correspond spacing (6) that conveyer belt (4) lateral wall laminated mutually, deflector (12) that laminate mutually with corresponding another lateral wall of conveyer belt (4) are all installed to the both sides of operation panel (2).

5. An automated assembly device for a magnetic latching relay as recited in claim 4, wherein: the top of the operation table (2) is also fixedly provided with two storage boxes (9) corresponding to the two positions through a fixing frame (8), a plurality of evenly distributed relay upper shells (14) and relay lower shells (15) are respectively positioned in the storage boxes (9) at the corresponding sides, and the bottom ends of the two storage boxes (9) are respectively matched with the positions of the conveyor belt (4) at the corresponding sides.

6. An automated assembly device for a magnetic latching relay according to claim 1, wherein: the end of the operating platform (2) is fixedly provided with a vertical plate through bolts, the two blanking cylinders (10) are all installed on the vertical plate, the telescopic ends of the two blanking cylinders (10) are fixedly connected with blanking blocks (11) which are respectively located at the bottoms of the storage boxes (9), and the width of each blanking block (11) is matched with the inner diameter of the bottom of each storage box (9).

7. An automated assembly device for a magnetic latching relay according to claim 1, wherein: the guide sliding rail (16) is fixedly arranged at the top of the operating platform (2), the electric sliding block (17) is sleeved on the guide sliding rail (16) in a sliding mode, one side of the electric sliding block (17) is fixedly connected with an extension seat (18) through a bolt, a sliding block (19) is clamped on the extension seat (18) in a sliding mode, the transfer cylinder (20) is arranged on the sliding block (19), and the sucker (21) is matched with the top end of the upper relay shell (14).

8. An automated assembly device for a magnetic latching relay as recited in claim 4, wherein: the two sides of the gluing plate (24) are respectively arranged in a bending manner, the gluing plate (24) is located between the two conveyor belts (4), the bottom of the gluing plate (24) is slidably sleeved on the supporting table (13) through a connecting rod, the bottom of the connecting rod penetrates through the supporting table (13) and extends to the outside of the bottom side of the supporting table (13), a vertical spring (25) is further sleeved on the connecting rod, two ends of the vertical spring (25) are respectively connected with the Tu Jiaoban (24) and the supporting table (13), a mounting groove is formed in the top end of the gluing plate (24), and the gluing sponge (26) is located in the mounting groove.

9. An automated assembly device for a magnetic latching relay as recited in claim 7, wherein: the extension seat (18) is fixedly connected with a guide rod (22), the sliding block (19) is sleeved on the guide rod (22) in a sliding mode, the guide rod (22) is sleeved with a return spring (23), and two ends of the return spring (23) are respectively connected with the inner wall of one side of the extension seat (18) and the sliding block (19).

Images