CN209860331U - Socket processing equipment - Google Patents

Abstract

The utility model relates to the technical field of socket assembly, and discloses socket processing equipment, which comprises a workbench, a rotary platform arranged on the workbench, and a first needle feeding mechanism, a second needle feeding mechanism, a glue core loading mechanism, a first sheet feeding mechanism, a second sheet feeding mechanism, a third sheet feeding mechanism and a riveting mechanism which are sequentially arranged along the rotary direction of the rotary platform, wherein the rotary platform is configured to drive a socket semi-finished product to rotate; the first needle feeding mechanism and the second needle feeding mechanism are configured to respectively obtain a current-carrying copper needle and a grounding copper needle, and respectively load the current-carrying copper needle and the grounding copper needle on the socket semi-finished product; the glue core loading mechanism is configured to load the glue core on the socket semi-finished product; the first piece feeding mechanism, the second piece feeding mechanism and the third piece feeding mechanism are configured to respectively obtain a first current-carrying fork piece, a grounding fork piece and a second current-carrying fork piece and are inserted into the socket semi-finished product; the riveting mechanism is configured to rivet and fix the first current-carrying fork piece, the grounding fork piece and the second current-carrying fork piece on the socket semi-finished product.

Description

Socket processing equipment

Technical Field

The utility model relates to a socket equipment technical field especially relates to a socket processing equipment.

Background

Sockets are electrical connectors used in a wide variety of electrical circuits and are important electromechanical components for connecting two devices to transmit current or signals, connecting conductors or wires to appropriate mating components, and completing electrical circuits.

As shown in fig. 1, the socket includes an insulative housing 10 and a current-carrying copper pin 20, a grounding copper pin 30 and a three-pole conductive terminal 40 thereon. At present, when assembling the socket, the current-carrying copper pin 20, the grounding copper pin 30 and the three-pole conductive terminal 40 are usually inserted into the insulating body 10 manually, and then are riveted and fixed by using a riveting press machine. The mode of manual assembly wastes time and energy, and when the punching press, needs the manual work to put into the riveting machine with the socket, has the potential safety hazard.

In view of the above-mentioned drawbacks, the present designer actively makes research and innovation to create a socket processing apparatus, which has industrial application value.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a socket processing equipment can assemble the socket automatically, promotes machining precision and efficiency.

To achieve the purpose, the utility model adopts the following technical proposal:

the utility model provides a socket processing equipment, includes the workstation, set up in the rotary platform of workstation and follow first needle mechanism, second that send needle mechanism, dress rubber core mechanism, first piece mechanism, second send piece mechanism, third to send piece mechanism and riveting mechanism that send that rotary platform direction of rotation set gradually, wherein:

the rotary platform is configured to bear a socket semi-finished product and drive the socket semi-finished product to rotate;

the first needle feeding mechanism and the second needle feeding mechanism are configured to respectively obtain a current-carrying copper needle and a grounding copper needle, and respectively load the current-carrying copper needle and the grounding copper needle on the socket semi-finished product;

the glue core loading mechanism is configured to load a glue core on the socket semi-finished product;

the first piece feeding mechanism, the second piece feeding mechanism and the third piece feeding mechanism are configured to respectively obtain a first current-carrying fork piece, a grounding fork piece and a second current-carrying fork piece, and respectively insert and join the first current-carrying fork piece, the grounding fork piece and the second current-carrying fork piece into the socket semi-finished product;

the riveting mechanism is configured to rivet and fix the first current-carrying forked piece, the grounding forked piece and the second current-carrying forked piece to the socket semi-finished product.

As a preferable mode of the socket processing apparatus, a moving-out mechanism is further disposed on the workbench between the riveting mechanism and the first needle feeding mechanism, and the moving-out mechanism is configured to move out the socket riveted by the riveting mechanism from the rotary platform.

As a preferable mode of the above socket processing apparatus, the removing mechanism has a first channel configured to output the qualified socket and a second channel configured to output the unqualified socket.

As a preferable embodiment of the above socket processing apparatus, the removing mechanism has a detection component for detecting whether the socket is good.

As a preferable scheme of the socket processing equipment, an air blowing mechanism is further arranged on the workbench between the riveting mechanism and the moving-out mechanism, and the air blowing mechanism can be over against the socket on the rotary platform.

As a preferable scheme of the socket processing equipment, a copper needle detection mechanism is further disposed on the workbench between the glue core loading mechanism and the first sheet feeding mechanism, and the copper needle detection mechanism can be in butt joint with the current-carrying copper needle and the grounding copper needle loaded on the socket semi-finished product.

As a preferable scheme of the socket processing equipment, a fork piece detection mechanism is further disposed on the workbench between the third piece feeding mechanism and the riveting mechanism, and the fork piece detection mechanism can be in butt joint with the first current-carrying fork piece, the grounding fork piece and the second current-carrying fork piece which are inserted into the semi-finished socket product.

As a preferable solution of the above socket processing apparatus, the rotating platform is provided with a plurality of die holders at uniform intervals in the circumferential direction, and the die holders are configured to carry the socket semi-finished product.

As a preferable mode of the socket processing device, a detachable support seat is provided at a bottom of the riveting mechanism, and the support seat is configured to support the die holder during riveting.

As a preferable scheme of the socket processing equipment, a man-machine control box is further arranged on the workbench.

The utility model has the advantages that: utilize rotary platform to drive socket semi-manufactured goods and turn to each processing station in proper order, and each processing station can insert the operation of closing to socket semi-manufactured goods automatically, and after inserting the operation of closing, the socket semi-manufactured goods can be fixed in automatically and carry out the riveting on the riveting mechanism, and degree of automation is high, convenient operation, and energy-conserving the manpower, promoted machining precision and efficiency.

Drawings

Fig. 1 is a schematic structural diagram of a socket according to the present invention;

fig. 2 is a schematic structural diagram of a socket processing apparatus according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a rotating platform in the socket processing equipment according to an embodiment of the present invention;

fig. 4 is a schematic structural view of a first needle feeding mechanism in the socket processing device according to the embodiment of the present invention;

fig. 5 is a schematic structural view of a second needle feeding mechanism in the socket processing apparatus according to the embodiment of the present invention;

fig. 6 is a schematic structural diagram of a glue core loading mechanism in socket processing equipment according to an embodiment of the present invention;

fig. 7 is a schematic structural diagram of a first sheet feeding mechanism in the socket processing apparatus according to the embodiment of the present invention (the second sheet feeding mechanism, the third sheet feeding mechanism and the first sheet feeding mechanism have the same structure);

fig. 8 is a schematic structural diagram of a riveting mechanism in socket processing equipment according to an embodiment of the present invention;

fig. 9 is a schematic structural diagram of a removing mechanism in the socket processing apparatus according to the embodiment of the present invention.

In the figure: 10-an insulating body, 20-a current-carrying copper pin, 30-a grounding copper pin, 40-a three-pole conductive terminal, 100-a workbench, 110-a rotating platform, 111-a die holder, 120-a first needle feeding mechanism, 121-a first vibrating disk, 122-a first vibrator, 123-a first clamping jaw, 124-a first moving module, 130-a second needle feeding mechanism, 140-a rubber core loading mechanism, 141-a rubber core conveyor belt, 142-a second clamping jaw, 143-a second moving module, 150-a first sheet feeding mechanism, 151-a second vibrating disk, 152-a second vibrator, 153-a third clamping jaw, 154-a third moving module, 160-a second sheet feeding mechanism, 170-a third sheet feeding mechanism, 180-a riveting mechanism, 181-a supporting seat, 182-a stamping module, 190-a moving-out mechanism, 191-a first channel, 192-a second channel, 193-a detection component, 194-a fourth clamping jaw, 195-a fourth moving module, 196-a toggle component, 200-a blowing mechanism, 300-a copper needle detection mechanism, 400-a fork piece detection mechanism and 500-a man-machine control box.

Detailed Description

In order to make the technical problems, technical solutions and technical effects achieved by the present invention more clear, the embodiments of the present invention will be described in further detail with reference to the accompanying drawings, and obviously, the described embodiments are only some embodiments, not all embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by those skilled in the art without creative efforts belong to the protection scope of the present invention.

In the description of the present invention, unless expressly stated or limited otherwise, the terms "connected," "connected," and "fixed" are to be construed broadly, e.g., as meaning permanently connected, detachably connected, or integral to one another; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

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

As shown in fig. 2, the socket processing equipment of the present invention includes a workbench 100, a first needle feeding mechanism 120, a second needle feeding mechanism 130, a glue core loading mechanism 140, a first piece feeding mechanism 150, a second piece feeding mechanism 160, a third piece feeding mechanism 170 and a riveting mechanism 180, which are arranged on a rotary platform 110 of the workbench 100 and are sequentially arranged along a rotation direction of the rotary platform 110.

Additionally, the utility model discloses still be provided with shift-out mechanism 190 between riveting mechanism 180 and first needle feeding mechanism 120 on workstation 100, still be provided with blow mechanism 200 between riveting mechanism 180 and shift-out mechanism 190, still be provided with copper needle detection mechanism 300 between dress rubber core mechanism 140 and first piece mechanism 150, still be provided with fork piece detection mechanism 400 between third piece mechanism 170 and riveting mechanism 180.

Specifically, as shown in fig. 3, the rotating platform 110 is configured to carry the socket semi-finished product and rotate the socket semi-finished product. In order to facilitate the socket semi-manufactured goods to rotate along with rotary platform 110 and process on each station, the utility model discloses evenly be provided with a plurality of die holders 111 at rotary platform 110's circumference interval, die holder 111 is configured to bear socket semi-manufactured goods. During processing, the semi-finished socket product can be placed on the die holder 111 manually or by a manipulator, and the die holder 111 positions the semi-finished socket product, so that the semi-finished socket product is prevented from shaking to influence the processing precision. Therefore, the mold base 111 can be a structure matched with the bottom of the socket semi-finished product.

As shown in fig. 4 and 5, the first needle feeding mechanism 120 and the second needle feeding mechanism 130 are configured to take a current-carrying copper needle and a grounding copper needle, respectively, and load the current-carrying copper needle and the grounding copper needle on the socket semi-finished product, respectively. The first needle feeding mechanism 120 and the second needle feeding mechanism 130 both utilize the structure of the first vibration plate 121 and the first vibrator 122 to cooperate to realize the transmission of the current-carrying copper needle and the grounding copper needle, and the first clamping jaw 123 cooperates with the first moving module 124 to realize the operation of grabbing and loading. The difference between the first needle feeding mechanism 120 and the second needle feeding mechanism 130 is that the structure of the first clamping jaw 123 is different, the structure of the first clamping jaw 123 can be determined according to the structure of the copper needle to be gripped, and the structures of the first clamping jaw 123 and the first moving module 124 are common designs, which is not described herein again.

As shown in fig. 6, the core loading mechanism 140 is configured to load the cores into the socket blanks. The glue core loading mechanism 140 includes a glue core conveyor belt 141, a second clamping jaw 142 and a second moving module 143, the glue core conveyor belt 141 is used for conveying the glue core, the second clamping jaw 142 can grab the glue core from the glue core conveyor belt 141, and the second moving module 143 drives the second clamping jaw 142 to move horizontally and lift, so that the second clamping jaw 142 brings the grabbed glue core to the position above the socket semi-finished product, and then descends to press the glue core on the socket semi-finished product.

As shown in fig. 7, the first blade feeding mechanism 150, the second blade feeding mechanism 160, and the third blade feeding mechanism 170 are configured to respectively obtain the first current-carrying prong, the grounding prong, and the second current-carrying prong (the first current-carrying prong, the grounding prong, and the second current-carrying prong are three-pole conductive terminals 40), and respectively insert the first current-carrying prong, the grounding prong, and the second current-carrying prong into the socket semi-finished product. The first sheet feeding mechanism 150, the second sheet feeding mechanism 160 and the third sheet feeding mechanism 170 all utilize the structure of the second vibrating plate 151 and the second linear vibrator 152 to cooperate to realize the transportation of the first current-carrying fork sheet, the grounding fork sheet and the second current-carrying fork sheet, and the third clamping jaw 153 cooperates with the third moving module 154 to realize the grabbing and plugging operation. The structure of the third clamping jaw 153 is determined according to the structure of the fork piece to be grabbed, and the structures of the third clamping jaw 153 and the third moving module 154 are all of conventional design and are not described herein again.

As shown in fig. 8, the riveting mechanism 180 is configured to rivet and fix the first current-carrying prong, the grounding prong, and the second current-carrying prong to the socket semi-finished product. The bottom of the riveting mechanism 180 is provided with a supporting seat 181, and the supporting seat 181 is configured to support the die holder 111 during riveting; the stamping module 182 of the riveting mechanism 180 is located above the die holder 111 and can reciprocate relative to the die holder 111. During riveting, the rotary platform 110 drives the corresponding die holder 111 to move to the support seat 181, and the stamping module 182 presses down to rivet and fix the first current-carrying prong, the grounding prong and the second current-carrying prong to the semi-finished socket. In order to promote the universality of the riveting mechanism 180, the utility model discloses all set up supporting seat 181 and punching press module 182 into detachable connected mode.

After the riveting and fixing are finished, the processed socket can be taken away manually, and the socket can be automatically discharged. The utility model discloses take automatic discharging's mode, promptly, utilize to shift out mechanism 190 and carry out the ejection of compact. As shown in fig. 9, the removing mechanism 190 is configured to remove the socket riveted by the riveting mechanism 180 from the rotary platform 110, and the removing mechanism 190 has a first channel 191 and a second channel 192, the first channel 191 is configured to output qualified sockets, and the second channel 192 is configured to output unqualified sockets; the acceptance of the finished socket is detected by the detection component 193 on the removal mechanism 190. During discharging, the fourth clamping jaw 194 of the removing mechanism 190 is driven by the fourth moving module 195 to grab the processed socket from the corresponding module 111 of the rotating platform 110, and then the socket is brought to the detecting component 193, and according to the detection result of the detecting component 193, the toggle component 196 of the removing mechanism 190 toggles the detected socket to the first channel 191 or the second channel 192. The fourth clamping jaw 194, the fourth moving module 195 and the toggle assembly 196 are all of conventional design and will not be further described herein.

The utility model provides a blowing mechanism 200 is used for blowing to the socket after the riveting to ensure the cleanliness factor of socket, blowing mechanism 200's position can be just to the socket on rotary platform 110. The blowing mechanism 200 is a conventional structure and will not be described herein.

Of course, after the current-carrying copper needle and the grounding copper needle are loaded on the socket semi-finished product, the copper needle detection mechanism 300 is used for detecting, namely, the copper needle detection mechanism 300 is butted with the current-carrying copper needle and the grounding copper needle loaded on the socket semi-finished product so as to grasp the loading precision of the current-carrying copper needle and the grounding copper needle; after the first current-carrying fork piece, the grounding fork piece and the second current-carrying fork piece are inserted into the semi-finished socket product, the fork piece detection mechanism 400 is used for detecting, namely the fork piece detection mechanism 400 is in butt joint with the first current-carrying fork piece, the grounding fork piece and the second current-carrying fork piece which are inserted into the semi-finished socket product, so that the insertion accuracy of the first current-carrying fork piece, the grounding fork piece and the second current-carrying fork piece can be mastered. Therefore, the arrangement of the copper needle detection mechanism 300 and the fork piece detection mechanism 400 can ensure the installation effect of the current-carrying copper needle, the grounding copper needle, the first current-carrying fork piece, the grounding fork piece and the second current-carrying fork piece, and the processing precision is improved; the copper pin detection mechanism 300 and the fork detection mechanism 400 are conventional structures and will not be described herein.

In order to facilitate human-computer interaction, the utility model discloses still be equipped with human-computer control box 500 on workstation 100.

To sum up, the utility model discloses a socket processing equipment can assemble the socket automatically, promotes machining precision and efficiency.

The technical principle of the present invention is described above with reference to specific embodiments. The description is made for the purpose of illustrating the principles of the invention and should not be construed in any way as limiting the scope of the invention. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without any inventive effort, which would fall within the scope of the present invention.

Claims (10)

1. The utility model provides a socket processing equipment, its characterized in that, includes workstation (100), set up in rotary platform (110) of workstation (100) and along first needle mechanism (120), second needle mechanism (130), dress rubber core mechanism (140), first piece mechanism (150), second piece mechanism (160), third piece mechanism (170) and riveting mechanism (180) that send that rotary platform (110) direction of rotation set gradually, wherein:

the rotary platform (110) is configured to bear the socket semi-finished product and drive the socket semi-finished product to rotate;

the first needle feeding mechanism (120) and the second needle feeding mechanism (130) are configured to respectively obtain a current-carrying copper needle and a grounding copper needle, and respectively load the current-carrying copper needle and the grounding copper needle on the socket semi-finished product;

the glue core loading mechanism (140) is configured to load glue cores to the socket semi-finished products;

the first wafer feeding mechanism (150), the second wafer feeding mechanism (160) and the third wafer feeding mechanism (170) are configured to respectively obtain a first current-carrying fork piece, a grounding fork piece and a second current-carrying fork piece, and respectively insert and join the first current-carrying fork piece, the grounding fork piece and the second current-carrying fork piece into the socket semi-finished product;

the riveting mechanism (180) is configured to rivet and fix the first current-carrying prong, the grounding prong, and the second current-carrying prong to the socket semi-finished product.

2. The socket processing apparatus according to claim 1, wherein a removing mechanism (190) is further disposed on the worktable (100) between the riveting mechanism (180) and the first needle feeding mechanism (120), and the removing mechanism (190) is configured to remove the socket riveted by the riveting mechanism (180) from the rotating platform (110).

3. The socket processing apparatus according to claim 2, wherein the removing mechanism (190) has a first channel (191) and a second channel (192), the first channel (191) being configured to output the qualified socket, the second channel (192) being configured to output the unqualified socket.

4. The socket processing apparatus according to claim 3, wherein the removing mechanism (190) has a detecting component (193) for detecting whether the socket is good.

5. The socket processing equipment according to claim 2, wherein a blowing mechanism (200) is further arranged on the workbench (100) between the riveting mechanism (180) and the removing mechanism (190), and the blowing mechanism (200) can be opposite to the socket on the rotating platform (110).

6. The socket processing equipment according to claim 1, wherein a copper pin detection mechanism (300) is further disposed on the worktable (100) between the glue core loading mechanism (140) and the first sheet feeding mechanism (150), and the copper pin detection mechanism (300) can be abutted to the current-carrying copper pins and the grounding copper pins loaded on the socket semi-finished product.

7. The socket processing equipment according to claim 1, wherein a fork piece detection mechanism (400) is further disposed on the worktable (100) between the third piece feeding mechanism (170) and the riveting mechanism (180), and the fork piece detection mechanism (400) can be abutted to the first current-carrying fork piece, the grounding fork piece and the second current-carrying fork piece which are plugged into the semi-finished socket.

8. Socket machining apparatus according to any of claims 1-7, characterized in that the rotating platform (110) is circumferentially provided with a number of mould shoes (111) at even intervals, the mould shoes (111) being configured to carry the socket semi-finished product.

9. The socket processing apparatus according to claim 8, wherein a bottom of the riveting mechanism (180) is provided with a detachable support seat (181), and the support seat (181) is configured to support the die holder (111) when riveting.

10. Socket processing equipment according to any one of claims 1 to 7, wherein a man-machine control box (500) is further provided on the work table (100).