CN116131065B - Assembling equipment for connector production - Google Patents

Abstract

The application relates to the technical field of connector production equipment and discloses assembly equipment for connector production, which comprises a frame, a first material channel arranged on the frame and a horizontal transmission interface unit, wherein the first material channel is arranged on the frame; the second material channel is used for vertically stacking the base; a third material channel for horizontally conveying the base; a fourth material channel for horizontally conveying the base assembled with the interface unit; the horizontal pushing mechanism is used for horizontally pushing the base in the second material channel into the third material channel; the rotating mechanism comprises a rotating seat and a driving assembly for driving the rotating seat to circumferentially rotate, and a fixed cavity for the base to move in or out is formed in the rotating seat; the conveying mechanism is used for pushing the base in the third material channel into the rotating seat; the feeding mechanism is used for pushing the base in the rotating seat into the fourth material channel; the assembling mechanism is used for pushing the interface units of the first material channel into the base of the fourth material channel in sequence. The automatic control system has the effects of high automation degree and small occupied space.

Description

Assembling equipment for connector production

Technical Field

The application relates to the technical field of connector production equipment, in particular to assembly equipment for connector production.

Background

Connectors, also known as connectors, function to connect two active devices to enable the transmission of current or signals. Network interfaces are one of the commonly used connectors and are widely used in network devices such as computers.

In the related art, as shown in fig. 1, there is disclosed a network interface including a base 1, a plurality of interface units 2 embedded in the base 1, each interface unit 2 including a hub 21 and a plurality of conductive pins 22 inserted on the hub 21. When the network interface is produced, the conductive pins 22 need to be pushed into the needle seat 21 by using the pin equipment to form the interface unit 2; the needle seat 21 of each interface unit 2 is embedded into the base 1 by using the assembling equipment, so that the assembly of the interface units 2 and the base 1 is completed.

At present, the assembly equipment for producing the network interface on the market generally adopts a horizontal feeding mode, namely, an interface unit and a base are respectively placed in different material channels which are transported along the horizontal direction. However, for a network interface including multiple sets of interface units, the greater the number of sets of interface units and the greater the length of the bases, the fewer the number of bases that can be transported on the material path.

To reduce the frequency of loading the susceptor, the lanes for transporting the susceptor are typically lengthened to increase the number of susceptors that can be transported on the lanes. However, the whole occupied space of the equipment after the material channel is lengthened can be correspondingly increased, so that space resource waste is caused, and the improvement is needed.

Disclosure of Invention

In order to reduce the overall occupied space of the device, the application provides assembling equipment for connector production.

The application provides an equipment is used in connector production adopts following technical scheme:

an assembling device for connector production comprises a frame, a plurality of connectors and a plurality of connectors, wherein the connectors are arranged on the frame

The first material channel is used for horizontally transmitting the interface unit;

the second material channel is used for vertically stacking the base;

the third material channel is communicated with one side of the second material channel and is used for horizontally conveying the base;

the fourth material channel is communicated with one side of the first material channel and is used for horizontally conveying the base assembled with the interface unit;

the horizontal pushing mechanism is used for horizontally pushing the base in the second material channel into the third material channel;

the rotating mechanism comprises a rotating seat and a driving assembly for driving the rotating seat to circumferentially rotate, and a fixed cavity for the base to move in or out is formed in the rotating seat; when the driving assembly works, the rotating seat can rotate to a feeding station for enabling the fixed cavity to be communicated with the third material channel and a discharging station for enabling the fixed cavity to be communicated with the fourth material channel;

the conveying mechanism is used for pushing the base in the third material channel into the rotating seat at the feeding station;

the feeding mechanism is used for pushing the base in the rotating seat of the discharging station into the fourth material channel;

the assembling mechanism is used for pushing the interface units of the first material channel into the base of the fourth material channel in sequence.

By adopting the technical scheme, the interface units are continuously distributed in the first material channel along the horizontal direction and are transmitted to the assembly mechanism along the first material channel; the base is stacked in the second material channel along the vertical direction. When the interface unit and the base are assembled, the base in the second material channel is horizontally pushed into the third material channel through the flat pushing mechanism, and then the rotary seat is driven to rotate to the feeding station through the driving assembly, so that the mounting cavity is aligned with the third material channel; then the base in the third material channel is pushed into the rotary seat through the conveying mechanism, and then the rotary seat is driven to rotate to the discharging station through the driving component, so that the base in the rotary seat can rotate to be aligned with the fourth material channel along with the rotary seat. And then gradually pushing the base in the rotary seat into the fourth material channel through the feeding mechanism, and simultaneously, working the assembling mechanism to sequentially push the interface units of the first material channel into the base of the fourth material channel until the assembly of a plurality of interface units on the base is completed. After the interface units on the single base are assembled, the actions are repeated, so that the batch assembly of the network interfaces is realized, and the automation degree and the assembly efficiency are high.

Because the base among this application vertically stacks in the second material way before the material loading, compare in the mode of horizontal transmission, can fully rationally utilize the vertical space in place to reach the purpose of saving space resource, the integration of equipment is high, occupation space is little.

Optionally, the flat pushing mechanism comprises a flat pushing block and a flat pushing force piece for driving the flat pushing block to reciprocate towards a third material channel, a material inlet communicated with the bottom of the second material channel is formed in the third material channel, and a base in the second material channel can enter the third material channel along the material inlet.

Through adopting above-mentioned technical scheme, flat pushing force spare during operation, flat pushing block can be to the reciprocating motion of third material way to with the base of second material way bottom along the pan feeding mouth push rapidly in the third material way, thereby accomplish the first step material loading of base. After the former base is pushed to the third material channel, the latter base can move to be aligned with the material inlet under the action of self gravity, so that the automatic material supplementing of the base is realized.

Optionally, the conveying mechanism comprises a conveying block and a conveying power piece for driving the conveying block to reciprocate along the third material channel, and the conveying block is positioned on one side of the material inlet far away from the rotating mechanism.

Through adopting above-mentioned technical scheme, when conveying power spare during operation, the transfer block can follow the third material and say to rotary mechanism reciprocating motion to with the base in the third material says in pushing gradually the roating seat, thereby accomplish the second step material loading of base. The direction of the base is adjusted through a plurality of procedures during feeding, so that the interface unit is aligned with an adaptive socket on the base during subsequent assembly, the transmission stability is high, and the assembly effect is good.

Optionally, the rotating seat comprises a bottom plate and a fixing plate detachably arranged on the bottom plate, and the fixing cavity is formed in the fixing plate; the middle part of bottom plate has seted up the festival material hole, the through-hole with fixed chamber intercommunication has been seted up to the upper side wall of fixed plate, the extending direction of through-hole is parallel to the extending direction of fixed chamber.

Through adopting above-mentioned technical scheme, the fixed plate can dismantle the setting on the bottom plate, when transmitting the base of equidimension, only need correspond the installation be equipped with the fixed plate in equidimension fixed chamber can, rotary mechanism's application scope is wide, the practicality is strong. The through hole is communicated with one side of the fixed cavity, so that the effect of facilitating the observation of the transmission position of the base in the rotating seat by workers is achieved. The material saving hole is formed in the middle of the bottom plate, so that the weight of the rotating seat can be reduced, and the driving load of the driving assembly can be reduced; and the consumable of the rotating seat can be reduced, and the resource is saved.

Optionally, the drive assembly includes driven gear, meshing at the initiative rack of driven gear one side, is used for driving the drive cylinder of initiative rack reciprocating motion, be provided with the pivot with bottom plate fixed connection on the driven gear coaxial.

Through adopting above-mentioned technical scheme, when driving the cylinder during operation, initiative rack can reciprocating motion, and then makes driven gear drive pivot circumference rotation to realize the circumference rotation of roating seat. The rotary seat in this application is driven by rack and pinion formula structure, and not only the transmission precision is high, remove stability good, and the rotary seat can also stop rotating at arbitrary rotation position to adapt to the base of accepting by different orientation afferent, thereby further improve rotary mechanism's suitability.

Optionally, the feeding mechanism comprises a feeding block and a feeding power piece for driving the feeding block to move along the extending direction of the fourth material channel, and a feeding opening for the feeding block to move into the fixed cavity is formed in the rotating seat.

Through adopting above-mentioned technical scheme, when the roating seat is in ejection of compact station, the material loading piece is located the one side that the roating seat kept away from fourth material way. After the feeding power piece is started, the feeding block can push the base in the rotating seat into the fourth material channel step by step, so that the third-step feeding of the base is completed, the interface unit is pushed into the base by a subsequent assembly mechanism, and the feeding effect is good.

Optionally, the feed mechanism still includes the connecting rod that is controlled by the material loading power spare, sets up the dog on the connecting rod, dog and material loading piece all include the installation department of fixing on the connecting rod, set up the material loading shell fragment in installation department upside, the interval of material loading shell fragment and installation department gets into the direction of fourth material way along the base and increases gradually.

Through adopting above-mentioned technical scheme, when the base was pushed into the fourth material way by the material loading piece, the dog was located one side that the base deviates from the material loading piece, played the effect of control base motion distance to avoid the base to slide along the fourth material way under self inertial action, help the socket on the follow-up equipment mechanism during operation base to align with the interface unit. After one-time feeding of the base is finished, the feeding block and the stop block are driven to move to one side far away from the fourth material channel by using the feeding power piece, and at the moment, the feeding elastic sheet in the stop block is pressed by the bottom of the base to deform, so that the stop block is prevented from pushing out the base in the fourth material channel.

Optionally, the cavity wall of fourth material way has seted up the groove of stepping down in its one end that is close to the roating seat, be provided with spacing shell fragment in the groove of stepping down, spacing shell fragment to the groove diapire of stepping down increases gradually along the direction that the base got into fourth material way.

Through adopting above-mentioned technical scheme, the in-process that the base moved into fourth material way, spacing shell fragment received the extrusion of base and can deform to the groove of stepping down in, can not influence the material loading of base. After the interface unit on the previous base is assembled, the base is pushed to one side, deviating from the rotating seat, of the limiting elastic piece by the feeding block, the limiting elastic piece can reset to extend out of the yielding groove under the elastic action of the limiting elastic piece, and at the moment, the limiting elastic piece resists one side, facing the rotating seat, of the base, and the effect of further preventing the base from being brought out of the fourth material channel by the stop block is achieved.

Optionally, the assembling mechanism comprises an assembling table, a movable pushing block arranged on the assembling table in a sliding manner, and an assembling power piece for driving the movable pushing block to pass through the first material channel and reciprocate towards the fourth material channel; the device comprises a first material channel, a fourth material channel, a limiting block, a lifting power piece, a connecting port, a limiting block, a lifting power piece and a connecting port, wherein the connecting port is used for enabling an interface unit to move, the limiting block is arranged on the lower side of the connecting port in a vertical sliding mode, the lifting power piece is used for driving the limiting block to vertically move, and the limiting block can move in or out of the connecting port under the action of the lifting power piece.

Through adopting above-mentioned technical scheme, after the interface unit moved to the equipment platform, start the equipment power spare, the activity ejector pad can push the interface unit along the intercommunication mouth in the fourth material way to accomplish the equipment of interface unit and base, simple structure, degree of automation are high. After the former interface unit is assembled, the movable pushing block is reset to one side of the communication port, which is away from the fourth material channel, and the jacking power piece is used for driving the limiting block to extend out of the communication port, so that the limiting block plays a role in resisting the movement of the latter interface unit to the communication port, and the interface unit is prevented from being frequently and mistakenly pushed into the fourth material channel when the assembled power piece breaks down.

Optionally, one side of fourth material way is provided with extrusion subassembly, is used for compressing tightly interface unit in the base, extrusion subassembly includes extrusion platform, slides and sets up the slide on extrusion platform, fixes at the briquetting of slide towards fourth material way one side, is used for driving the extrusion power spare of slide to fourth material way reciprocating movement, the direction of motion perpendicular to of slide is said and is expected the extending direction of saying.

By adopting the technical scheme, when the semi-finished product of the interface unit assembled behind the base is conveyed along the fourth material channel, the extrusion power piece can drive the sliding seat to reciprocate towards the fourth material channel, and then the pressing block further compresses each interface unit in the base, so that the assembling stability of the connector is further improved, and the quality of the connector is high.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the base is vertically stacked in the second material channel, so that compared with a horizontal transmission mode, the vertical space of the field can be fully and reasonably utilized, the purpose of saving space resources is achieved, the automation and integration of the equipment are high, and the occupied space is small;

2. the rotating seat comprises a bottom plate and a fixed plate which are detachably connected, and when in actual use, the fixed plate provided with the fixed cavities with different sizes can be arranged on the bottom plate so as to adapt to the transmission of the bases with different sizes, so that the practicability is strong; the material saving hole not only can lighten the weight of the rotating seat and reduce the driving load of the driving assembly; the material consumption of the rotating seat can be reduced, and the resources are saved;

3. the extrusion component can further compress each interface unit in the base, so that the assembly stability of the connector is improved, and the quality of the connector is high.

Drawings

Fig. 1 is a schematic diagram of a network interface in the related art.

Fig. 2 is a schematic structural view of an embodiment of the present application.

Fig. 3 is a schematic structural diagram of the second material channel, the third material channel, the pushing mechanism and the conveying mechanism in the embodiment of the application.

Fig. 4 is a schematic structural diagram of a rotating mechanism and a feeding mechanism in the embodiment of the present application.

Fig. 5 is a schematic structural view of a rotating mechanism in an embodiment of the present application.

FIG. 6 is a partial schematic view of a fourth lane in an embodiment of the present application.

FIG. 7 is a partial schematic diagram illustrating an assembly mechanism, a stop block, and a lift-up power member in an embodiment of the present application.

FIG. 8 is a partial schematic diagram illustrating a compression assembly in an embodiment of the present application.

Reference numerals illustrate:

1. a base; 2. an interface unit; 21. a needle stand; 22. a conductive needle; 3. a frame; 31. a first material channel; 32. a second material channel; 33. a third material channel; 331. a feed inlet; 34. a fourth material channel; 341. a relief groove; 342. a limiting spring plate; 35. a communication port; 4. a flat pushing mechanism; 41. a horizontal pushing block; 42. a flat pushing force member; 5. a rotation mechanism; 51. a rotating seat; 511. a bottom plate; 512. a fixing plate; 513. a fixed cavity; 514. a through hole; 515. a material saving hole; 516. a feeding port; 52. a drive assembly; 521. a driven gear; 522. a driving rack; 523. a driving cylinder; 524. a rotating shaft; 6. a conveying mechanism; 61. a transfer block; 62. transmitting the power piece; 7. a feeding mechanism; 71. a connecting rod; 72. feeding a material block; 73. a stop block; 74. a feeding power piece; 75. a mounting part; 76. a feeding spring plate; 8. an assembly mechanism; 81. an assembly table; 82. a movable pushing block; 83. assembling a power piece; 84. a limiting block; 85. lifting the power piece; 9. an extrusion assembly; 91. an extrusion station; 92. a slide; 93. briquetting; 94. and extruding the power piece.

Detailed Description

The present application is described in further detail below in conjunction with figures 2-8.

The embodiment of the application discloses an assembling device for connector production, which is applied to assembling an interface unit 2 in a network interface shown in fig. 1 in a base 1.

Referring to fig. 2, the connector production assembly apparatus includes a frame 3, and a first lane 31, a second lane 32, a third lane 33, a fourth lane 34, a push mechanism 4, a rotation mechanism 5, a transfer mechanism 6, a loading mechanism 7, and an assembly mechanism 8 which are disposed on the frame 3, wherein the frame 3 in this embodiment is designed to be split according to the arrangement orientations of the first lane 31, the second lane 32, etc., and in other embodiments, the frame 3 may be disposed as a single piece.

Referring to fig. 2, the first material path 31 extends in a horizontal direction, and the interface units 2 are continuously arranged in the first material path 31. In use, the feed end of the first channel 31 is connected to a drive device, such as a vibrating disc, so that each interface unit 2 can be transported in a horizontal direction.

Referring to fig. 2 and 3, the second material channel 32 is vertically arranged, and an opening for the base 1 to extend into is formed at the upper side, and the base 1 is vertically stacked in the second material channel 32.

Referring to fig. 3, the third material path 33 extends in a horizontal direction, and an extending direction of the third material path 33 is perpendicular to an extending direction of the first material path 31. The third material channel 33 is provided with a material inlet 331 communicated with the bottom of the second material channel 32, and the size of the material inlet 331 is slightly larger than that of the base 1, so that the base 1 can enter the third material channel 33 along the material inlet 331.

Referring to fig. 2, the fourth lane 34 extends in a direction parallel to the first lane 31 for horizontally conveying the base 1 assembled with the interface unit 2.

Referring to fig. 3, the flat pushing mechanism 4 includes a flat pushing block 41 and a flat pushing force member 42 for driving the flat pushing block 41 to reciprocate toward the third material channel 33, the flat pushing force member 42 in this embodiment is a flat pushing cylinder, a piston rod of the flat pushing cylinder is fixedly connected with the flat pushing block 41, and a movement direction of the piston rod of the flat pushing cylinder is perpendicular to an extending direction of the third material channel 33. When the flat pushing force piece 42 works, the flat pushing block 41 pushes the base 1 at the bottom of the second material channel 32 horizontally into the third material channel 33.

Referring to fig. 3, the transfer mechanism 6 includes a transfer block 61, and a transfer power member 62 for driving the transfer block 61 to reciprocate along the third lane 33, the transfer block 61 being located on a side of the feed port 331 away from the rotary mechanism 5. The transmission power member 62 in this embodiment is a transmission cylinder, a piston rod of which is fixedly connected to the transmission block 61, and a telescopic direction of the piston rod of which is parallel to the extending direction of the third lane 33. When the transmission power member 62 is operated, the transmission block 61 pushes the base 1 in the third material path 33 toward the rotation mechanism 5.

Referring to fig. 4 and 5, the rotating mechanism 5 includes a rotating base 51 rotatably disposed on the frame 3, and a driving assembly 52 for driving the rotating base 51 to rotate circumferentially, the rotating base 51 includes a bottom plate 511, and a fixing plate 512 detachably disposed on the bottom plate 511, and a fixing cavity 513 for moving the base 1 in or out is formed in the fixing plate 512. When the fixed chamber 513 is in communication with the third channel 33, the rotary seat 51 is in the feeding station; when the stationary chamber 513 is in communication with the fourth conduit 34, the rotary seat 51 is in the outfeed station. It should be noted that, in the present embodiment, the fixing plate 512 is connected to the bottom plate 511 by using a fastening bolt, and in other embodiments, the fixing plate 512 and the bottom plate 511 may be connected by using a clamping or other manners.

Referring to fig. 5, in order to facilitate a worker's view of the position of the base 1 in the fixing chamber 513, a through hole 514 communicating with the fixing chamber 513 is formed in an upper sidewall of the fixing plate 512, and an extending direction of the through hole 514 is parallel to an extending direction of the fixing chamber 513. In order to reduce the dead weight of the rotary seat 51 and save the production materials of the rotary seat 51, a material saving hole 515 is formed in the middle of the bottom plate 511.

Referring to fig. 5, the driving assembly 52 includes a driven gear 521, a driving rack 522 engaged on one side of the driven gear 521, and a driving cylinder 523 for driving the driving rack 522 to reciprocate, the driving cylinder 523 is mounted on the frame 3 and a piston rod is fixedly connected with the driving rack 522, a rotation shaft 524 is coaxially disposed on the driven gear 521, and the rotation shaft 524 is fixedly connected with the bottom plate 511. When the driving cylinder 523 works, the driving rack 522 moves horizontally, so that the driven gear 521 drives the rotating seat 51 to rotate circumferentially, and the rotating seat 51 rotates alternately to the feeding station or the discharging station.

Referring to fig. 2 and 4, the feeding mechanism 7 includes a connecting rod 71, a feeding block 72 and a stop 73 fixed on the connecting rod 71, and a feeding power member 74 for driving the connecting rod 71 to move along the extending direction of the fourth material channel 34, wherein the feeding power member 74 in this embodiment is preferably an electric cylinder, an output shaft of the electric cylinder is fixedly connected with the connecting rod 71, and a feeding port 516 for moving the feeding block 72 is arranged at one side of the fixed cavity 513.

Referring to fig. 4, the distance between the stopper 73 and the loading block 72 is greater than the length of the base 1, so that a space for accommodating the base 1 is formed therebetween. The stop block 73 and the feeding block 72 comprise a mounting portion 75 and a feeding elastic sheet 76 arranged on the upper side of the mounting portion 75, the mounting portion 75 is fixed on the connecting rod 71, and the distance between the feeding elastic sheet 76 and the mounting portion 75 is gradually increased along the direction that the base 1 enters the fourth material channel 34. When the base 1 moves to the discharging station along with the rotating seat 51, the feeding power piece 74 drives the connecting rod 71 to move towards the fourth material channel 34, so that the feeding block 72 extends into the fixed cavity 513 along the feeding hole 516 to push the base 1 into the fourth material channel 34. The stopper 73 is located at the side of the base 1 facing the fourth material channel 34, and is used for preventing the base 1 from sliding under the action of inertia, so as to facilitate alignment of the socket on the subsequent base 1 with the interface unit 2.

Referring to fig. 6, in order to prevent the stopper 73 from pushing the base 1 when moving toward the rotating mechanism 5, a relief groove 341 is formed in the cavity wall of the fourth material channel 34 at one end thereof close to the rotating seat 51, a limiting elastic piece 342 is disposed in the relief groove 341, and the distance from the limiting elastic piece 342 to the bottom wall of the relief groove 341 gradually increases along the direction of entering the fourth material channel 34 from the base 1. After the base 1 moves to be separated from the limiting elastic piece 342, the limiting elastic piece 342 moves out of the yielding groove 341 under the elastic action of the limiting elastic piece 342 so as to limit the base 1 to synchronously move along with the stop block 73.

Referring to fig. 7, a communication port 35 is provided in communication between the first channel 31 and the fourth channel 34 for moving the interface unit 2 along the first channel 31 into the fourth channel 34. The assembly mechanism 8 comprises an assembly table 81, a movable push block 82 slidably arranged on the assembly table 81, and an assembly power piece 83 for driving the movable push block 82 to reciprocate towards the fourth material channel 34 through the first material channel 31, wherein the assembly power piece 83 in the embodiment comprises an assembly cylinder, and a piston rod of the assembly cylinder is fixedly connected with the movable push block 82. When the assembly power piece 83 works, the movable pushing block 82 can push the interface unit 2 in the first material channel 31 into the base 1 of the fourth material channel 34 along the communication port 35, so that the assembly of the interface unit 2 and the base 1 is completed.

Referring to fig. 7, in order to prevent the interface unit 2 from being pushed into the fourth material channel 34 by mistake when the assembly power member 83 fails, a limiting block 84 is provided on the lower side of the communication port 35 in a vertically sliding manner, a lifting power member 85 for driving the limiting block 84 to move vertically is provided on the assembly table 81, the lifting power member 85 in this embodiment is preferably a lifting cylinder, and a piston rod of the lifting cylinder is upwards fixedly connected with the limiting block 84, so that the limiting block 84 can move into or out of the communication port 35 under the action of the lifting power member 85, so that the interface unit 2 plays a limiting role before the assembly power member 83 is started.

Referring to fig. 8, a pressing assembly 9 is provided at one side of the fourth material path 34 for pressing the interface unit 2 into the base 1. The extrusion assembly 9 includes an extrusion table 91, a sliding seat 92 slidably disposed on the extrusion table 91, a pressing block 93 fixed on a side of the sliding seat 92 facing the fourth material channel 34, and an extrusion power member 94 for driving the sliding seat 92 to reciprocate toward the fourth material channel 34, wherein the extrusion power member 94 in this embodiment is preferably an extrusion cylinder, a piston rod of the extrusion cylinder is fixedly connected with the sliding seat 92, and a movement direction of the sliding seat 92 is perpendicular to an extending direction of the fourth material channel 34. After the interface unit 2 is assembled on the base 1, the pressing block 93 can move along with the sliding seat 92 towards the fourth material channel 34 under the driving of the extrusion power piece 94, so as to further press the interface unit 2 on the base 1.

The implementation principle of the assembly equipment for connector production in the embodiment of the application is as follows: when the interface unit 2 and the base 1 are assembled, the interface unit 2 is horizontally conveyed along the direction from the first material channel 31 to the fourth material channel 34, the base 1 is vertically stacked in the second material channel 32, the base 1 in the second material channel 32 is horizontally pushed into the third material channel 33 through the flat pushing mechanism 4, and then the rotary seat 51 is driven to rotate to a feeding station through the driving component 52, so that the mounting cavity is aligned with the third material channel 33; the base 1 in the third material channel 33 is pushed into the rotating seat 51 by the conveying mechanism 6, and then the rotating seat 51 is driven by the driving component 52 to drive the base 1 to rotate to the discharging station. The base 1 in the rotary seat 51 is pushed into the fourth material channel 34 step by step through the feeding mechanism 7, and meanwhile, the limiting block 84 moves out of the communication port 35 under the action of the jacking power piece 85. The assembly mechanism 8 is then activated to push the interface units 2 in the first lane 31 into the base 1 of the fourth lane 34 successively until assembly of the plurality of interface units 2 on the base 1 is completed, and finally the interface units 2 are further compacted on the base 1 by means of the pressing assembly 9. The steps are repeated to realize batch assembly of the network interfaces, and the automation degree and the assembly efficiency are high, and the quality of finished products is good.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (7)

1. An assembling device for connector production, which is characterized in that: comprises a frame (3), a plurality of guide rails arranged on the frame (3)

A first material channel (31) for horizontally conveying the interface unit (2);

a second material channel (32) for vertically stacking the bases (1);

a third material channel (33) communicated with one side of the second material channel (32) and used for horizontally conveying the base (1);

a fourth material channel (34) communicated with one side of the first material channel (31) and used for horizontally conveying the base (1) assembled with the interface unit (2);

the horizontal pushing mechanism (4) is used for horizontally pushing the base (1) in the second material channel (32) into the third material channel (33);

the rotating mechanism (5) comprises a rotating seat (51) and a driving assembly (52) for driving the rotating seat (51) to circumferentially rotate, wherein a fixed cavity (513) for the base (1) to move in or out is formed in the rotating seat (51); when the driving assembly (52) works, the rotating seat (51) can rotate to a feeding station for enabling the fixed cavity (513) to be communicated with the third material channel (33) and a discharging station for enabling the fixed cavity (513) to be communicated with the fourth material channel (34); the rotating seat (51) comprises a bottom plate (511) and a fixed plate (512) detachably arranged on the bottom plate (511), and the fixed cavity (513) is formed in the fixed plate (512); a material saving hole (515) is formed in the middle of the bottom plate (511), a through hole (514) communicated with the fixed cavity (513) is formed in the upper side wall of the fixed plate (512), and the extending direction of the through hole (514) is parallel to the extending direction of the fixed cavity (513); the driving assembly (52) comprises a driven gear (521), a driving rack (522) meshed with one side of the driven gear (521) and a driving cylinder (523) for driving the driving rack (522) to reciprocate, and a rotating shaft (524) fixedly connected with the bottom plate (511) is coaxially arranged on the driven gear (521);

a conveying mechanism (6) for pushing the base (1) in the third material channel (33) into a rotating seat (51) at the feeding station;

the feeding mechanism (7) is used for pushing the base (1) in the rotating seat (51) at the discharging station into the fourth material channel (34);

the assembling mechanism (8) is used for pushing the interface units (2) of the first material channel (31) into the base (1) of the fourth material channel (34) in sequence;

one side of fourth material way (34) is provided with extrusion subassembly (9), is used for compressing tightly interface unit (2) in base (1), extrusion subassembly (9) are including extrusion platform (91), slide (92) of sliding setting on extrusion platform (91), fix at briquetting (93) of slide (92) towards fourth material way (34) one side, be used for driving slide (92) to the extrusion power piece (94) of fourth material way (34) reciprocating motion, the direction of motion of slide (92) is perpendicular to the extending direction of fourth material way (34).

2. The connector production assembly apparatus according to claim 1, wherein: the flat pushing mechanism (4) comprises a flat pushing block (41) and a flat pushing force piece (42) for driving the flat pushing block (41) to reciprocate towards the third material channel (33), a material inlet (331) communicated with the bottom of the second material channel (32) is formed in the third material channel (33), and the base (1) in the second material channel (32) can enter the third material channel (33) along the material inlet (331).

3. The connector production assembly apparatus according to claim 2, wherein: the conveying mechanism (6) comprises a conveying block (61) and a conveying power piece (62) used for driving the conveying block (61) to reciprocate along the third material channel (33), and the conveying block (61) is positioned on one side of the material inlet (331) far away from the rotating mechanism (5).

4. The connector production assembly apparatus according to claim 1, wherein: the feeding mechanism (7) comprises a feeding block (72) and a feeding power piece (74) for driving the feeding block (72) to move along the extending direction of the fourth material channel (34), and a feeding opening (516) for moving the feeding block (72) into the fixed cavity (513) is formed in the rotating seat (51).

5. The connector production assembly apparatus according to claim 4, wherein: the feeding mechanism (7) further comprises a connecting rod (71) controlled by a feeding power piece (74), and a stop block (73) arranged on the connecting rod (71), wherein the stop block (73) and the feeding block (72) comprise a mounting part (75) fixed on the connecting rod (71), and a feeding elastic piece (76) arranged on the upper side of the mounting part (75), and the distance between the feeding elastic piece (76) and the mounting part (75) is gradually increased along the direction that the base (1) enters the fourth material channel (34).

6. The connector production assembly apparatus according to claim 5, wherein: the cavity wall of the fourth material channel (34) is provided with a yielding groove (341) at one end of the cavity wall, which is close to the rotating seat (51), the yielding groove (341) is internally provided with a limiting elastic piece (342), and the distance from the limiting elastic piece (342) to the bottom wall of the yielding groove (341) is gradually increased along the direction from the base (1) to the fourth material channel (34).

7. The connector production assembly apparatus according to claim 1, wherein: the assembly mechanism (8) comprises an assembly table (81), a movable pushing block (82) arranged on the assembly table (81) in a sliding manner, and an assembly power piece (83) for driving the movable pushing block (82) to reciprocate towards the fourth material channel (34) through the first material channel (31); a communication port (35) for allowing the interface unit (2) to move is formed between the first material channel (31) and the fourth material channel (34), a limiting block (84) is vertically arranged on the lower side of the communication port (35) in a sliding mode, a jacking power piece (85) for driving the limiting block (84) to vertically move is arranged on the assembly table (81), and the limiting block (84) can move in or out of the communication port (35) under the action of the jacking power piece (85).