CN212412412U - Automatic assembly machine for EMI shielding sleeve on connector - Google Patents

Automatic assembly machine for EMI shielding sleeve on connector Download PDF

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Publication number
CN212412412U
CN212412412U CN202021244508.3U CN202021244508U CN212412412U CN 212412412 U CN212412412 U CN 212412412U CN 202021244508 U CN202021244508 U CN 202021244508U CN 212412412 U CN212412412 U CN 212412412U
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CN
China
Prior art keywords
block
emi shielding
shielding sleeve
cylinder
connector
Prior art date
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Active
Application number
CN202021244508.3U
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Chinese (zh)
Inventor
曹建平
陆文天
王胜
李垚
张建明
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Shenzhen Chuangyitong Technology Co ltd
Original Assignee
Shenzhen Chuangyitong Technology Co ltd
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Priority to CN202021244508.3U priority Critical patent/CN212412412U/en
Application granted granted Critical
Publication of CN212412412U publication Critical patent/CN212412412U/en
Active legal-status Critical Current
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Abstract

The utility model discloses an automatic assembly machine of an EMI shielding sleeve used on a connector, which comprises a frame, a conveying device, a cutting device, a positioning device, a feeding device and an assembly device used for dividing and positioning the EMI shielding sleeve and assembling the EMI shielding sleeve on a semi-finished product of the connector; the conveying device is arranged on the frame; the cutting device is arranged on the rack and positioned beside the conveying device; the positioning device is arranged on the rack and positioned beside the material cutting device; the feeding device is arranged on the frame; the assembling device is arranged on the rack and behind the output end of the feeding device, and the assembling device and the positioning device are arranged oppositely. Through the setting of conveyor, cutting device and positioner, realized cutting and the location to the transport of connector semi-manufactured goods, material area, through material feeding unit and assembly device's setting, realized the automation to the transport, location, transfer and the equipment action of EMI shielding cover to improve production efficiency greatly, guaranteed the goodness rate of product.

Description

Automatic assembly machine for EMI shielding sleeve on connector
Technical Field
The utility model belongs to the technical field of connector equipment and specifically relates to indicate an automatic kludge of EMI shield cover for on connector.
Background
EMI shielding piece among the connector among the prior art is manual assembly or equipment, because the human factor equipment will have deviation and efficiency problem, influences the productivity output value of totality, and wherein the assembly of tiny part is very difficult to people's frock assembly, and is higher to workman's proficiency requirement, influences the quality of product moreover easily. However, the EMI shielding sheet assembling mechanism of the existing device can only assemble the sheet EMI shielding sheet, but cannot assemble the annular EMI shielding sleeve.
SUMMERY OF THE UTILITY MODEL
In view of the above, the present invention is directed to the deficiency of the prior art, and the main objective of the present invention is to provide an automatic assembling machine for an EMI shielding sleeve on a connector, which effectively solves a series of problems caused by manual assembly, and can realize the assembly of an annular EMI shielding sleeve.
In order to achieve the above purpose, the utility model adopts the following technical scheme:
an automatic assembly machine for an EMI (electro-magnetic interference) shielding sleeve on a connector comprises a rack, a conveying device for conveying a semi-finished connector, a material cutting device for cutting a front end material belt in the semi-finished connector, a positioning device for positioning the semi-finished connector, a feeding device for conveying the EMI shielding sleeve and an assembly device for distributing and positioning the EMI shielding sleeve and assembling the EMI shielding sleeve on the semi-finished connector; the conveying device is arranged on the rack; the cutting device is arranged on the rack and positioned beside the conveying device; the positioning device is arranged on the rack and positioned beside the material cutting device; the feeding device is arranged on the frame; the assembling device is arranged on the rack and behind the output end of the feeding device, and the assembling device and the positioning device are arranged oppositely.
As a preferable scheme, the conveying device comprises an air cylinder and a conveying unit; the cylinder is arranged on the frame; the conveying unit comprises a sliding block, a sliding rail, a mounting block and a pusher dog, wherein the sliding block is arranged on an output shaft of the cylinder, and the cylinder drives the sliding block to slide back and forth; the sliding rail is arranged on the frame and is in sliding fit with the sliding block; the mounting block is arranged on the sliding block and moves along with the sliding block; the lower end of the pusher dog is inserted into a positioning hole of a material belt in the semi-finished connector to drive the semi-finished connector to be conveyed backwards; and the two conveying units are arranged at intervals in the front-back direction and are connected through a connecting rod, and the conveying unit positioned in the front direction drives the conveying unit positioned in the rear direction to synchronously move through the connecting rod.
As a preferred scheme, the material cutting device comprises a cylinder, a pivoting block, a connecting block, an installation block, a pressing block for pressing the semi-finished connector and a punching block for punching and cutting a front end material belt in the semi-finished connector; the cylinder is arranged on the frame; the middle section of the pivoting block is pivoted on the rack, one end of the pivoting block is connected to the output shaft of the cylinder, and the cylinder drives the pivoting block to swing up and down; the connecting block is arranged at the other end of the pivoting block and swings up and down along with the pivoting block; the mounting block is arranged on the bottom surface of the connecting block; the pressing block is arranged on the bottom surface of the mounting block and is positioned right above the semi-finished connector; the punching block penetrates through the mounting block and the pressing block, the lower end of the punching block extends out of the pressing block, and the punching block moves up and down along with the mounting block.
Preferably, a recycling cylinder for recycling the cut material belt is arranged on the machine frame under the material cutting device.
As a preferred scheme, the positioning device comprises a positioning cylinder and a pressing block, and the positioning cylinder is arranged on the rack; the pressing block is arranged on an output shaft of the positioning cylinder, and the positioning cylinder drives the pressing block to move up and down back and forth above the semi-finished product of the connector.
As a preferred scheme, the EMI shielding sleeve assembly device further comprises a detection device for detecting whether the EMI shielding sleeve is assembled in place, wherein the detection device comprises an installation block and an inductor, and the installation block is arranged on the outer side surface of the pressing block and moves up and down along with the pressing block; the inductor is arranged on the mounting block and moves up and down along with the mounting block above the EMI shielding sleeve.
As a preferred scheme, the assembling device includes a shift mechanism for blocking and positioning the EMI shielding sleeve, a shift mechanism for transferring the EMI shielding sleeve, an assembling mechanism for assembling the EMI shielding sleeve onto the connector semi-finished product, and a positioning mechanism for positioning the EMI shielding sleeve when transferring the EMI shielding sleeve to the assembling mechanism; the gear mechanism is arranged on the rack and positioned beside the output end side of the feeding device; the shifting mechanism is connected between the gear mechanism and the assembling mechanism, the shifting mechanism is arranged on the gear mechanism, and the gear mechanism drives the shifting mechanism to move; the assembling mechanism is arranged on the rack and positioned beside the shifting mechanism; the positioning mechanism is arranged on the frame and positioned beside the assembling mechanism.
As a preferred scheme, the gear mechanism comprises a first cylinder, a first sliding block, a first sliding rail, an installation block, a guide block, a stop block for blocking a previous EMI shielding sleeve and a pressing block for abutting against and fixing a next EMI shielding sleeve; the first cylinder is arranged on the frame; the first sliding block is arranged on an output shaft of the first air cylinder, the first air cylinder drives the first sliding block to move, and the shifting mechanism is arranged on the first sliding block and moves along with the first sliding block; the first sliding rail is arranged on the frame and is in sliding fit with the first sliding block; the mounting block is arranged on the first sliding block and moves along with the first sliding block; the guide block is arranged on the mounting block, a guide groove with a forward opening is formed in the front end of the guide block, and the front section and the rear section of the guide groove are communicated in a vertically staggered mode; the stop block is movably arranged on the frame up and down, is arranged in the guide groove through a shaft body and moves up and down along the guide groove; the briquetting sets up on the installation piece and is located the side of guide block.
As a preferred scheme, the shifting mechanism comprises a second slide rail, a second cylinder, a second slide block and a transfer block; the second slide rail is arranged on the first slide block; the second cylinder is arranged on the second slide rail; the second sliding block is arranged on an output shaft of the second air cylinder and is in sliding fit with the second sliding rail, and the second air cylinder drives the second sliding block to slide; the transfer block is arranged on the second slide block and is positioned beside the pressing block.
As a preferred scheme, the assembling mechanism comprises a first cylinder, a sliding plate, an installation block, an elastic pressing block and a resisting block; the first cylinder is arranged on the frame; the sliding plate is slidably arranged on the rack, and the first cylinder drives the sliding plate to slide; the mounting block is arranged on the sliding plate and moves along with the sliding plate, an EMI shielding sleeve mounting station is arranged on the mounting block, a front opening of the EMI shielding sleeve mounting station is opposite to the positioning device, and a side opening of the EMI shielding sleeve mounting station is opposite to the shifting mechanism; the elastic pressing block is movably arranged on the mounting block up and down, and the upper end of the elastic pressing block extends into the EMI shielding sleeve mounting station and abuts against the bottom surface of the EMI shielding sleeve; the supporting block is provided with the bottom surface of the mounting block, and the elastic pressing block is mounted on the supporting block through a spring; the positioning mechanism comprises a second cylinder and a baffle plate, and the second cylinder is arranged on the rack; this baffle sets up on the output shaft of second cylinder, and the cylinder drives the baffle and makes a round trip to move about from top to bottom in the side of the front opening side of EMI shield cover installation station.
Compared with the prior art, the utility model obvious advantage and beneficial effect have, particularly, can know by above-mentioned technical scheme:
through the setting of conveyor, cutting device and positioner, realized cutting and the location to the transport of connector semi-manufactured goods, material area, through material feeding unit and assembly device's setting, realized the automation to the transport, location, transfer and the equipment action of EMI shielding cover to improve production efficiency greatly, guaranteed the goodness rate of product.
To illustrate the structural features and functions of the present invention more clearly, the present invention will be described in detail with reference to the accompanying drawings and specific embodiments.
Drawings
FIG. 1 is a perspective view of a preferred embodiment of the present invention;
FIG. 2 is a partial assembly view of the preferred embodiment of the present invention;
FIG. 3 is a perspective view of the conveyor in the preferred embodiment of the invention;
FIG. 4 is a perspective view of the material cutting device and the recycling bin according to the preferred embodiment of the present invention;
FIG. 5 is a cross-sectional view of FIG. 4;
FIG. 6 is a perspective view of the positioning device in accordance with the preferred embodiment of the present invention;
FIG. 7 is another partial assembled view of the preferred embodiment of the present invention;
FIG. 8 is a perspective view of the assembly device in a preferred embodiment of the present invention;
FIG. 9 is an assembled perspective view of the shifting mechanism and the shifting mechanism in the preferred embodiment of the present invention;
FIG. 10 is an assembled perspective view of the guide block and stop block in the preferred embodiment of the present invention;
FIG. 11 is a perspective view of a guide block in a preferred embodiment of the present invention;
FIG. 12 is an assembled perspective view of the assembly mechanism and the positioning mechanism in the preferred embodiment of the present invention;
fig. 13 is a process assembly step diagram of the connector.
The attached drawings indicate the following:
10. frame 20, conveyor
21. Air cylinder 22 and conveying unit
221. Slider 222 and slide rail
223. Mounting block 224, pusher dog
23. Connecting rod 30 and cutting device
31. Cylinder 32, pivot block
33. Connecting block 34, mounting block
35. Pressing block 36 and punching block
40. Positioning device 41 and positioning cylinder
42. Pressing block 50 and feeding device
60. Assembling device 61 and gear mechanism
611. First cylinder 612 and first slide block
613. First slide rail 614 and mounting block
615. Guide block 601 and guide groove
616. Stop block 617 and pressing block
618. Shaft body 62 and displacement mechanism
621. Second slide rail 622, second cylinder
623. Second slide block 624, transfer block
63. Assembly mechanism 631 and first cylinder
632. Slide 633, mounting block
602. EMI shielding sleeve mounting station 634 and elastic pressing block
635. Abutting block 64 and positioning mechanism
641. Second cylinder 642, baffle
70. Connector semi-finished product 80 and EMI shielding sleeve
91. Recovery cylinder 92 and detection device
921. Mounting block 922, inductor.
Detailed Description
Referring to fig. 1 to 13, a specific structure of a preferred embodiment of the present invention is shown, which includes a frame 10, a conveying device 20 for conveying a connector semi-finished product, a cutting device 30 for cutting a front material strip in the connector semi-finished product, a positioning device 40 for positioning the connector semi-finished product, a feeding device 50 for conveying an EMI shielding sleeve, and an assembling device 60 for separating the EMI shielding sleeve, positioning the EMI shielding sleeve and assembling the EMI shielding sleeve onto the connector semi-finished product.
The conveying device 20 is disposed on the frame 10, and the conveying device 20 includes a cylinder 21 and a conveying unit 22. The cylinder 21 is provided on the frame 10. The conveying unit 22 includes a slider 221, a slide rail 222, a mounting block 223, and a pusher dog 224, the slider 221 is disposed on an output shaft of the cylinder 21, and the cylinder 21 drives the slider 221 to slide back and forth. The slide rail 222 is disposed on the frame 10 and slidably engaged with the slide block 221. The mounting block 223 is arranged on the sliding block 221 and moves along with the sliding block 221; the pusher dog 224 is arranged on the mounting block 223, and the lower end of the pusher dog 224 is inserted into the positioning hole of the material belt in the connector semi-finished product to drive the connector semi-finished product to be conveyed backwards. The two conveying units 22 are arranged at intervals in the front-back direction, the two conveying units 22 are connected through a connecting rod 23, and the conveying unit 22 located in the front direction drives the conveying unit 22 located in the rear direction to move synchronously through the connecting rod 23, so that the connector semi-finished product 70 is conveyed smoothly.
The cutting device 30 is disposed on the frame 10 and beside the conveying device 20. The cutting device 30 includes a cylinder 31, a pivot block 32, a connecting block 33, a mounting block 34, a pressing block 35 for pressing the connector semi-finished product, and a punching block 36 for punching the front end material belt in the connector semi-finished product. The cylinder 31 is arranged on the frame 10; the middle section of the pivot block 32 is pivoted to the frame 10, one end of the pivot block 32 is connected to the output shaft of the cylinder 31, and the cylinder 31 drives the pivot block 32 to swing up and down. The connecting block 33 is disposed at the other end of the pivoting block 32 and swings up and down with the pivoting block 32. The mounting block 34 is disposed on the bottom surface of the connecting block 33; the pressing block 35 is provided on the bottom surface of the mounting block 34 and directly above the connector semi-finished product 70. The punching block 36 penetrates through the mounting block 34 and the pressing block 35, the lower end of the punching block 36 extends out of the pressing block 35, and the punching block 36 moves up and down along with the mounting block 35, so that the front-end material belt of the semi-finished connector 70 is punched, and interference of the front-end material belt is avoided when the EMI shielding sleeve is assembled. And a recovery cylinder 91 for recovering the cut material belt is arranged on the frame 10 just below the cutting device 30.
The positioning device 40 is disposed on the frame 10 and beside the material cutting device 30. The positioning device 40 includes a positioning cylinder 41 and a pressing block 42, and the positioning cylinder 41 is disposed on the frame 10. The pressing block 42 is disposed on the output shaft of the positioning cylinder 41, and the positioning cylinder 41 drives the pressing block 42 to move up and down and back and forth above the semi-finished connector 70. The positioning cylinder 41 drives the pressing block 42 to press down against the connector semi-finished product 70, thereby positioning the connector semi-finished product 70 and facilitating the subsequent assembly of the EMI shielding sleeve 80. The apparatus further comprises a detecting device 92 for detecting whether the EMI shielding sleeve is assembled in place, wherein the detecting device 92 comprises a mounting block 921 and an inductor 922, and the mounting block 921 is arranged on the outer side surface of the pressing block 42 and moves up and down along with the pressing block 42. The inductor 922 is disposed on the mounting block 921 and moves up and down and back and forth above the EMI shielding sleeve 80 along with the mounting block 921, and when the inductor 922 contacts the EMI shielding sleeve 80, it indicates that the EMI shielding sleeve 80 is assembled in place, otherwise. By skillfully arranging the detection device 92 on the positioning device 40, the sensor 922 is driven to detect without redundant cylinders, which is beneficial to saving cost.
The feeding device 50 is disposed on the frame 10. in this embodiment, the feeding device 50 is a vibrating tray that vibrates and positions the EMI shielding sleeve 80. The assembling device 60 is disposed on the frame 10 and behind the output end of the feeding device 50, and the assembling device 60 is arranged opposite to the positioning device 40.
The assembling device 60 includes a shift mechanism 61 for blocking and positioning the EMI shielding sleeve, a shift mechanism 62 for transferring the EMI shielding sleeve, an assembling mechanism 63 for assembling the EMI shielding sleeve to the connector semi-finished product, and a positioning mechanism 64 for positioning the EMI shielding sleeve when transferring the EMI shielding sleeve to the assembling mechanism. The shift mechanism 61 is disposed on the frame 10 and located near the output end side of the feeding device 50. The shifting mechanism 62 is connected between the shifting mechanism 61 and the assembling mechanism 63, the shifting mechanism 62 is disposed on the shifting mechanism 61, and the shifting mechanism 62 is driven by the shifting mechanism 61 to move. The assembling mechanism 63 is disposed on the frame 10 and beside the shifting mechanism 62. The positioning mechanism 64 is arranged on the frame and positioned beside the assembling mechanism 63.
The gear mechanism 61 includes a first cylinder 611, a first sliding block 612, a first sliding rail 613, a mounting block 614, a guiding block 615, a stop 616 for stopping a previous EMI shielding sleeve, and a pressing block 617 for pressing and fixing a next EMI shielding sleeve. The first cylinder 611 is provided on the frame 10. The first sliding block 612 is disposed on the output shaft of the first cylinder 611, the first cylinder 611 drives the first sliding block 612 to move, and the shifting mechanism 62 is disposed on the first sliding block 612 and moves along with the first sliding block 612. The first slide rail 613 is disposed on the frame 10 and is slidably engaged with the first slide block 612. The mounting block 614 is disposed on the first slider 612 and moves with the first slider 612. The guide block 615 is disposed on the mounting block 614, a guide groove 601 with a forward opening is formed at the front end of the guide block 615, and the front section and the rear section of the guide groove 601 are communicated in a staggered manner. The stopper 616 is movably disposed on the chassis 10, and the stopper 616 is mounted in the guiding groove 601 through a shaft 618 and moves up and down along the guiding groove 601, so as to block the EMI shielding cover 80 when the stopper 616 is exposed outside the chassis. A press block 617 is disposed on the mounting block 614 and is located laterally to the guide block 615.
The shift mechanism 62 includes a second slide rail 621, a second cylinder 622, a second slider 623, and a transfer block 624. The second slide rail 621 is disposed on the first slider 612. The second cylinder 622 is disposed on the second slide rail 621. The second slider 623 is disposed on the output shaft of the second cylinder 622 and is in sliding fit with the second slide rail 621, and the second cylinder 622 drives the second slider 623 to slide. The transfer block 624 is disposed on the second slider 623 and located beside the pressing block 617, and the front end of the transfer block 624 is inserted into the EMI shielding sleeve 80, and then the EMI shielding sleeve 80 is transferred to the assembling mechanism 63.
The assembling mechanism 63 includes a first cylinder 631, a sliding plate 632, a mounting block 633, an elastic pressing block 634, and a pressing block 635. The first cylinder 631 is disposed on the frame 10. The sliding plate 632 is slidably disposed on the frame 10, and the first cylinder 631 drives the sliding plate 632 to slide. The mounting block 633 is disposed on the sliding plate 632 and moves along with the sliding plate 632, an EMI shielding sheath mounting station 602 is disposed on the mounting block 633, a front opening of the EMI shielding sheath mounting station 602 is opposite to the positioning device 40, and a side opening of the EMI shielding sheath mounting station 602 is opposite to the shifting mechanism 62. The elastic pressing block 634 is disposed on the mounting block 633 in a vertically movable manner, and an upper end of the elastic pressing block 634 extends into the EMI shielding sleeve mounting station 602 and abuts against a bottom surface of the EMI shielding sleeve 80, so that the EMI shielding sleeve 80 is stably disposed in the EMI shielding sleeve mounting station 602. The pressing block 635 is provided on the bottom surface of the mounting block 633, and the elastic pressing block 634 is mounted on the pressing block 635 by a spring (not shown), so that the elastic pressing block 634 always maintains elastic pressure against the EMI shielding case 80.
The positioning mechanism 64 includes a second cylinder 641 and a baffle 642, and the second cylinder 641 is disposed on the frame 10. The baffle 642 is disposed on the output shaft of the second cylinder 641, and the cylinder 641 drives the baffle 642 to move up and down and back and forth beside the front opening side of the EMI shielding sleeve mounting station 602. When the transfer block 624 transfers the EMI shielding sleeve 80 to the EMI shielding sleeve mounting station 602, the second cylinder 641 drives the baffle 642 upward to seal the front opening of the MI mounting station 602 with the baffle 642, thereby preventing the EMI shielding sleeve 80 from falling out of the front opening of the EMI shielding sleeve mounting station 602.
Detailed description the working principle of the present embodiment is as follows:
step one, starting the equipment, wherein the cylinder 21 drives the pusher dog 224 to drive the connector semi-finished product 70 to convey backwards;
step two, after the connector semi-finished product 70 is conveyed to the position below the material cutting device 30, the air cylinder 31 drives the pressing block 35 to compress the connector semi-finished product 70, meanwhile, the air cylinder drives the punching block 36 to punch the front end material belt of the connector semi-finished product 70, and punched excess materials fall into the recovery cylinder 91 to be recovered;
thirdly, after the front end material belt is punched, the material cutting device 30 is reset, the connector semi-finished product 70 is conveyed to the position below the positioning device 40, the positioning cylinder 41 drives the pressing block 42 to press downwards, and the pressing block 42 is pressed against the rear end plastic of the connector semi-finished product 70, so that the connector semi-finished product 70 is fixed;
step four, conveying the EMI shielding sleeve 80 simultaneously while conveying the connector semi-finished product 70, and vibrating the EMI shielding sleeve 80 by a vibrating disk and placing the EMI shielding sleeve 80;
step five, the EMI shielding sleeve 80 is conveyed into the gear mechanism 61 and abuts against the side face of the stop block 616, and meanwhile, after the sensor senses that the EMI shielding sleeve 80 is conveyed in place, the first air cylinder 611 drives the guide block 615 to extend out, and the stop block 616 moves downwards along with the extension of the guide block 615, so that the stop block 616 does not block the EMI shielding sleeve 80; and the upper surface of the stopper 616 is flush with the bottom surface of the EMI shielding sleeve 80; at the same time, the press block 617 presses the next EMI shield 80;
step six, the shifting mechanism 62 starts to work, and in step five, when the first cylinder 611 drives the guide block 615 to extend out, the first cylinder also drives the transfer block 624 to be inserted into the EMI shielding sleeve 80 to be transferred; the second cylinder 622 drives the transfer block 624 to move towards the assembly mechanism 63, and the EMI shielding sleeve 80 moves along with the transfer block 624;
seventhly, the EMI shielding sleeve 80 is transferred to the EMI shielding sleeve mounting station 602, the shifting mechanism 62 is reset, and before the EMI shielding sleeve 80 is transferred, the second air cylinder 641 in the positioning mechanism 64 drives the baffle 642 to extend upwards, so that the baffle 642 seals the front side opening of the EMI shielding sleeve mounting station 602, the EMI shielding sleeve 80 is prevented from falling off from the EMI shielding sleeve mounting station 602, and after the EMI shielding sleeve 80 is mounted, the positioning mechanism 64 is reset; and the elastic pressing block 634 elastically abuts against the bottom surface of the EMI shielding sleeve 80, so that the EMI shielding sleeve 80 is kept in a stable state;
step eight, the first cylinder 631 drives the mounting block 633 to move towards the positioning device 40, the EMI shielding sleeve 80 located in the EMI shielding sleeve mounting station 602 moves along with the mounting block 63, the EMI shielding sleeve 80 penetrates through the front end of the connector semi-finished product 70, then the EMI shielding sleeve 80 is fastened and fixed with the connector semi-finished product 70, the assembly is completed, and the assembly mechanism 63 resets.
The utility model discloses a design focus lies in: through the setting of conveyor, cutting device and positioner, realized cutting and the location to the transport of connector semi-manufactured goods, material area, through material feeding unit and assembly device's setting, realized the automation to the transport, location, transfer and the equipment action of EMI shielding cover to improve production efficiency greatly, guaranteed the goodness rate of product.
The above description is only a preferred embodiment of the present invention, and is not intended to limit the technical scope of the present invention, so that any slight modifications, equivalent changes and modifications made by the technical spirit of the present invention to the above embodiments are all within the scope of the technical solution of the present invention.

Claims (10)

1. The utility model provides an automatic kludge of EMI shield cover for on connector which characterized in that: the connector semi-finished product cutting device comprises a rack, a conveying device for conveying a connector semi-finished product, a material cutting device for cutting a front end material belt in the connector semi-finished product, a positioning device for positioning the connector semi-finished product, a feeding device for conveying an EMI shielding sleeve and an assembling device for distributing and positioning the EMI shielding sleeve and assembling the EMI shielding sleeve on the connector semi-finished product; the conveying device is arranged on the rack; the cutting device is arranged on the rack and positioned beside the conveying device; the positioning device is arranged on the rack and positioned beside the material cutting device; the feeding device is arranged on the frame; the assembling device is arranged on the rack and behind the output end of the feeding device, and the assembling device and the positioning device are arranged oppositely.
2. The automatic assembling machine for an EMI shielding sleeve on a connector according to claim 1, wherein: the conveying device comprises an air cylinder and a conveying unit; the cylinder is arranged on the frame; the conveying unit comprises a sliding block, a sliding rail, a mounting block and a pusher dog, wherein the sliding block is arranged on an output shaft of the cylinder, and the cylinder drives the sliding block to slide back and forth; the sliding rail is arranged on the frame and is in sliding fit with the sliding block; the mounting block is arranged on the sliding block and moves along with the sliding block; the lower end of the pusher dog is inserted into a positioning hole of a material belt in the semi-finished connector to drive the semi-finished connector to be conveyed backwards; and the two conveying units are arranged at intervals in the front-back direction and are connected through a connecting rod, and the conveying unit positioned in the front direction drives the conveying unit positioned in the rear direction to synchronously move through the connecting rod.
3. The automatic assembling machine for an EMI shielding sleeve on a connector according to claim 1, wherein: the cutting device comprises an air cylinder, a pivoting block, a connecting block, an installation block, a pressing block for pressing the semi-finished connector and a punching block for punching a front-end material belt in the semi-finished connector; the cylinder is arranged on the frame; the middle section of the pivoting block is pivoted on the rack, one end of the pivoting block is connected to the output shaft of the cylinder, and the cylinder drives the pivoting block to swing up and down; the connecting block is arranged at the other end of the pivoting block and swings up and down along with the pivoting block; the mounting block is arranged on the bottom surface of the connecting block; the pressing block is arranged on the bottom surface of the mounting block and is positioned right above the semi-finished connector; the punching block penetrates through the mounting block and the pressing block, the lower end of the punching block extends out of the pressing block, and the punching block moves up and down along with the mounting block.
4. The automatic assembling machine for an EMI shielding sleeve on a connector according to claim 1, wherein: and a recovery cylinder for recovering the cut material belt is arranged under the cutting device on the frame.
5. The automatic assembling machine for an EMI shielding sleeve on a connector according to claim 1, wherein: the positioning device comprises a positioning cylinder and a pressing block, and the positioning cylinder is arranged on the rack; the pressing block is arranged on an output shaft of the positioning cylinder, and the positioning cylinder drives the pressing block to move up and down back and forth above the semi-finished product of the connector.
6. The automatic assembling machine for an EMI shielding sleeve on a connector according to claim 5, wherein: the detection device comprises an installation block and an inductor, wherein the installation block is arranged on the outer side surface of the pressing block and moves up and down along with the pressing block; the inductor is arranged on the mounting block and moves up and down along with the mounting block above the EMI shielding sleeve.
7. The automatic assembling machine for an EMI shielding sleeve on a connector according to claim 1, wherein: the assembling device comprises a gear mechanism for blocking and positioning the EMI shielding sleeve, a shifting mechanism for transferring the EMI shielding sleeve, an assembling mechanism for assembling the EMI shielding sleeve on the connector semi-finished product and a positioning mechanism for positioning the EMI shielding sleeve when the EMI shielding sleeve is transferred to the assembling mechanism; the gear mechanism is arranged on the rack and positioned beside the output end side of the feeding device; the shifting mechanism is connected between the gear mechanism and the assembling mechanism, the shifting mechanism is arranged on the gear mechanism, and the gear mechanism drives the shifting mechanism to move; the assembling mechanism is arranged on the rack and positioned beside the shifting mechanism; the positioning mechanism is arranged on the frame and positioned beside the assembling mechanism.
8. The automatic assembling machine for an EMI shielding sleeve on a connector according to claim 7, wherein: the gear mechanism comprises a first cylinder, a first sliding block, a first sliding rail, an installation block, a guide block, a stop block for stopping the previous EMI shielding sleeve and a pressing block for abutting and fixing the next EMI shielding sleeve; the first cylinder is arranged on the frame; the first sliding block is arranged on an output shaft of the first air cylinder, the first air cylinder drives the first sliding block to move, and the shifting mechanism is arranged on the first sliding block and moves along with the first sliding block; the first sliding rail is arranged on the frame and is in sliding fit with the first sliding block; the mounting block is arranged on the first sliding block and moves along with the first sliding block; the guide block is arranged on the mounting block, a guide groove with a forward opening is formed in the front end of the guide block, and the front section and the rear section of the guide groove are communicated in a vertically staggered mode; the stop block is movably arranged on the frame up and down, is arranged in the guide groove through a shaft body and moves up and down along the guide groove; the briquetting sets up on the installation piece and is located the side of guide block.
9. The automatic assembling machine for an EMI shielding cage on a connector according to claim 8, wherein: the shifting mechanism comprises a second slide rail, a second air cylinder, a second slide block and a transfer block; the second slide rail is arranged on the first slide block; the second cylinder is arranged on the second slide rail; the second sliding block is arranged on an output shaft of the second air cylinder and is in sliding fit with the second sliding rail, and the second air cylinder drives the second sliding block to slide; the transfer block is arranged on the second slide block and is positioned beside the pressing block.
10. The automatic assembling machine for an EMI shielding sleeve on a connector according to claim 7, wherein: the assembling mechanism comprises a first cylinder, a sliding plate, an installation block, an elastic pressing block and a resisting block; the first cylinder is arranged on the frame; the sliding plate is slidably arranged on the rack, and the first cylinder drives the sliding plate to slide; the mounting block is arranged on the sliding plate and moves along with the sliding plate, an EMI shielding sleeve mounting station is arranged on the mounting block, a front opening of the EMI shielding sleeve mounting station is opposite to the positioning device, and a side opening of the EMI shielding sleeve mounting station is opposite to the shifting mechanism; the elastic pressing block is movably arranged on the mounting block up and down, and the upper end of the elastic pressing block extends into the EMI shielding sleeve mounting station and abuts against the bottom surface of the EMI shielding sleeve; the supporting block is provided with the bottom surface of the mounting block, and the elastic pressing block is mounted on the supporting block through a spring; the positioning mechanism comprises a second cylinder and a baffle plate, and the second cylinder is arranged on the rack; this baffle sets up on the output shaft of second cylinder, and the cylinder drives the baffle and makes a round trip to move about from top to bottom in the side of the front opening side of EMI shield cover installation station.
CN202021244508.3U 2020-06-30 2020-06-30 Automatic assembly machine for EMI shielding sleeve on connector Active CN212412412U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202021244508.3U CN212412412U (en) 2020-06-30 2020-06-30 Automatic assembly machine for EMI shielding sleeve on connector

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202021244508.3U CN212412412U (en) 2020-06-30 2020-06-30 Automatic assembly machine for EMI shielding sleeve on connector

Publications (1)

Publication Number Publication Date
CN212412412U true CN212412412U (en) 2021-01-26

Family

ID=74405458

Family Applications (1)

Application Number Title Priority Date Filing Date
CN202021244508.3U Active CN212412412U (en) 2020-06-30 2020-06-30 Automatic assembly machine for EMI shielding sleeve on connector

Country Status (1)

Country Link
CN (1) CN212412412U (en)

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