CN218289451U - Transport mechanism for testing cables - Google Patents

Abstract

A transport mechanism for testing cables, comprising: the cable fixing device comprises a conveying belt, a first carrier and a second carrier, wherein the first carrier is used for fixing one end of a cable, the second carrier is used for fixing the other end of the cable, the first carrier and the second carrier are both located on the conveying belt, and the first carrier and the second carrier are both provided with electrodes for electric connection. Because the electrode positions of the first carrier and the second carrier are relatively fixed, the testing head of the testing equipment can be accurately electrically connected with the electrodes of the first carrier and the second carrier, and the testing effectiveness is ensured. Because the first carrier and the second carrier are conveyed through the conveyor belt, the first carrier and the second carrier can be connected with the mechanical arms of the corresponding equipment in the front and rear processes, the insertion and pulling operation of the cables can be automatically completed, and the production efficiency is improved.

Description

Transport mechanism for testing cables

Technical Field

The utility model relates to a cable transport mechanism especially relates to a transport mechanism that test cable used.

Background

In the production process of the cable, after two ends of the wire core are connected with the metal sheet, the electrical property needs to be tested firstly, and then the encapsulation process is carried out. At present, most cable manufacturers insert the wire core of the cable into the testing equipment in a manual plugging mode, so as to test the electrical performance.

However, the manual plugging mode is prone to poor contact, which affects the test result, and the mode cannot be connected with the equipment in the front and rear processes, which restricts the overall production efficiency of the cable.

SUMMERY OF THE UTILITY MODEL

The utility model discloses technical scheme is to above-mentioned condition, provides a transport mechanism that test cable used in order to solve above-mentioned problem, transport mechanism includes: the cable fixing device comprises a conveying belt, a first carrier and a second carrier, wherein the first carrier is used for fixing one end of a cable, the second carrier is used for fixing the other end of the cable, the first carrier and the second carrier are both located on the conveying belt, and the first carrier and the second carrier are both provided with electrodes for electric connection.

Further, the conveyor belt includes: the motor shaft of the motor is fixedly connected with the main belt pulley, the belt is wound on the main belt pulley and the auxiliary belt pulley, and the first carrier and the second carrier are both located on the belt.

Further, the conveyor belt further includes: the motor shaft and the rotating shaft of the motor form fixed connection through the shaft coupling, and the main belt pulley and the rotating shaft form fixed connection.

Further, the conveyor belt further includes: the inductor, the inductor is located the side of belt.

Furthermore, the first carrier is provided with a first positioning groove, a conductive bolt, a first pin and a first clamping jaw, the first positioning groove and the pin are respectively positioned on two opposite surfaces of the first carrier, the conductive bolt protrudes from the side wall of the first positioning groove, the conductive bolt and the first pin form an electric connection to form an electrode of the first carrier, and the first clamping jaw is positioned at the lower end of the first carrier and forms a fixed connection with the belt; the second carrier is provided with a second positioning groove, a jack, a second pin and a second clamping jaw, the second positioning groove and the second pin are respectively located on two opposite surfaces of the second carrier, the jack is sunken from the side wall of the second positioning groove, a conductive piece is arranged in the jack, the conductive piece and the second pin form an electric connection to form an electrode of the second carrier, and the second clamping jaw is located at the lower end of the second carrier and forms a fixed connection with a belt.

Furthermore, the first carriers and the second carriers are multiple, and the multiple first carriers and the multiple second carriers are arranged on the belt in a staggered mode.

Further, the transport mechanism further comprises: the pressing devices are arranged in a row along the conveying direction of the belt and are positioned right above the belt.

Further, the pressing device includes: the piston rod of the compaction cylinder is arranged along the vertical direction and is fixedly connected with the pressing block.

Further, the transfer mechanism further comprises: two injection molding devices, the two injection molding devices are arranged along the conveying direction of the belt, and the two injection molding devices are both close to the tail end of the belt.

Further, the injection molding apparatus includes: go up mould subassembly and lower mould subassembly, it includes to go up the mould subassembly: the upper die comprises an upper die cylinder, an upper die support and an upper die plate, wherein a piston rod of the upper die cylinder is arranged along the vertical direction and is fixedly connected with the upper die support, and the upper die support is fixedly connected with the upper die plate; the lower die assembly includes: the piston rod of the lower die cylinder is arranged along the vertical direction and is fixedly connected with the lower die support, the lower die support is fixedly connected with the lower die plate, and the lower die plate is located right below the upper die plate.

After the technical scheme is adopted, the beneficial effects of the utility model are that:

1. because the electrode positions of the first carrier and the second carrier are relatively fixed, the testing head of the testing equipment can be accurately electrically connected with the electrodes of the first carrier and the second carrier, and the testing effectiveness is ensured.

2. Because first carrier and second carrier convey through the conveyer belt, consequently can link up with the manipulator of preceding, the corresponding equipment of back process, the operation is inserted, is pulled out to the automatic completion cable, promotes production efficiency.

Drawings

Fig. 1 is a schematic view of a transfer mechanism according to the present invention;

fig. 2 is a schematic view of a conveyor belt according to the present invention;

fig. 3 is a schematic view of a first carrier according to the present invention;

fig. 4 is a schematic view of a second carrier according to the present invention;

fig. 5 is a schematic view of a pressing device according to the present invention;

fig. 6 is a schematic view of the injection molding apparatus according to the present invention.

Detailed Description

It is specifically noted that, in the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise; the meaning of "several" is at least one. In the embodiment of the present invention, all the directional indicators (such as upper, lower, left, right, front, and rear … …) are only used to explain the relative position relationship between the components, the motion situation, and the like in a specific posture, and if the specific posture changes, the directional indicator changes accordingly.

The technical solution of the present invention is further described below by way of examples:

the utility model provides a transport mechanism that test cable used, as shown in FIG. 1, this transport mechanism includes: the cable fixing device comprises a conveyor belt 1, a first carrier 2 used for fixing one end of a cable and a second carrier 3 used for fixing the other end of the cable, wherein the first carrier 2 and the second carrier 3 are both located on the conveyor belt 1, and the first carrier 2 and the second carrier 3 are both provided with electrodes used for electric connection.

When the transmission mechanism works, the manipulator of the previous process fixes the two ends of the cable on the first carrier 2 and the second carrier 3 respectively, the electrodes of the first carrier 2 and the second carrier 3 are electrically connected with the metal sheets at the two ends of the cable respectively, and when the cable is transmitted to a test position, the test equipment arranged on the side of the transmission mechanism electrically connects the two test heads with the electrodes of the first carrier 2 and the second carrier 3 respectively, so that the electrical performance test of the cable is realized.

Because the electrode positions of the first carrier 2 and the second carrier 3 are relatively fixed, the testing head of the testing equipment can accurately form electrical connection with the electrodes of the first carrier and the second carrier, so that the testing effectiveness is ensured.

Because first carrier 2 and second carrier 3 convey through conveyer belt 1, consequently can link up with the manipulator of the corresponding equipment of preceding, back process, accomplish the operation of inserting, pulling out of cable voluntarily, promote production efficiency.

As shown in fig. 2, the conveyor belt 1 includes: the device comprises a motor 11, a coupler 12, a rotating shaft 13, a main belt pulley 14, an auxiliary belt pulley 15, a belt 16 and an inductor 17, wherein a motor shaft of the motor 11 is fixedly connected with the rotating shaft 13 through the coupler, the main belt pulley 14 is fixedly connected with the rotating shaft 13, the belt 16 is wound on the main belt pulley 14 and the auxiliary belt pulley 15, the first carrier 2 and the second carrier 3 are both located on the belt 16, and the inductor 17 is located on the side of the belt 16. The motor 11 is used for driving the rotating shaft 13 to rotate and driving the belt 16 to perform closed-loop transmission through the main belt pulley 14, so as to realize the transmission operation of the first carrier 2 and the second carrier 3. When the cable passes the sensor 17, the sensor 17 generates a sensing signal, thereby detecting whether the cable is successfully transmitted.

In the present embodiment, the number of the inductors 17 is two, and the two inductors 17 are arranged along the conveying direction of the belt 16. The cable needs to go through two testing processes, and two sensors 17 can detect whether the cable arrives at the testing position respectively.

In this embodiment, the sensor 17 is a pressure sensor, and when the cable passes through, pressure is applied to the elastic sheet of the pressure sensor, so as to detect the transmission condition of the cable.

As shown in fig. 3 and 4, the first carrier 2 has a first positioning groove 21, a conductive pin 22, a first pin 23 and a first claw 24, the first positioning groove 21 and the pin 23 are respectively located on two opposite surfaces of the first carrier 2, the conductive pin 22 protrudes from a sidewall of the first positioning groove 21, the conductive pin 22 and the first pin 23 form an electrical connection to form an electrode of the first carrier 2, and the first claw 24 is located at a lower end of the first carrier 2 and forms a fixed connection with the belt 16; the second carrier 3 has a second positioning groove 31, an insertion hole 32, a second pin 33 and a second claw 34, the second positioning groove 31 and the second pin 33 are respectively located on two opposite surfaces of the second carrier 3, the insertion hole 32 is recessed from a side wall of the second positioning groove 31, the insertion hole 32 has a conductive piece therein, the conductive piece is electrically connected with the second pin 33 to form an electrode of the second carrier 3, and the second claw 34 is located at a lower end of the second carrier 3 and is fixedly connected with the belt 16. One end of the cable having the connection hole is fixed in the first seating groove 21, the conductive pins 22 are inserted into the connection hole and electrically connected, one end of the cable having the pins is fixed in the second seating groove 31, the pins are inserted into the insertion holes 32 and electrically connected to the conductive member, and the two test heads of the test equipment are electrically connected to the first pins 23 and the second pins 33, respectively, thereby testing the electrical properties of the cable.

In the present embodiment, the first carrier 2 and the second carrier 3 are plural, and the plural first carriers 2 and the plural second carriers 3 are arranged on the belt 16 in a staggered manner. The conveyor belt 1 can simultaneously convey a plurality of cables.

With continued reference to fig. 1, the transfer mechanism further includes: a plurality of pressing devices 4, the plurality of pressing devices 4 are arranged in a row along the conveying direction of the belt 16, and the plurality of pressing devices 4 are positioned right above the belt 16. In the testing process, the conveying belt 1 stops conveying, the first carrier 2 and the second carrier 3 are respectively located below the corresponding pressing devices 4 at the moment, and the pressing devices 4 press the first carrier 2 and the second carrier 3 tightly to avoid shaking so as to ensure the testing stability.

As shown in fig. 5, the pressing device 4 includes: the pressing device comprises a pressing cylinder 41 and a pressing block 42, wherein a piston rod of the pressing cylinder 41 is arranged along the vertical direction and is fixedly connected with the pressing block 42. The pressing cylinder 41 is used for driving the pressing block 42 to move up and down, so that the pressing and releasing functions are realized.

With continued reference to fig. 1, the transfer mechanism further includes: two injection molding devices 5, the two injection molding devices 5 being arranged in the conveying direction of the belt 16, and both injection molding devices 5 being located near the trailing end of the belt 16. I.e. in the transport direction, the tail end of the counter belt 16 is closer to both injection moulding devices 5 than the head end, and after the test is completed, the injection moulding devices 5 can encapsulate both ends of the cable by means of an injection moulding process.

As shown in fig. 6, the injection molding apparatus 5 includes: an upper die assembly 51 and a lower die assembly 52, the upper die assembly 51 including: the device comprises an upper die cylinder 511, an upper die support 512 and an upper die plate 513, wherein a piston rod of the upper die cylinder 511 is arranged along the vertical direction and is fixedly connected with the upper die support 512, and the upper die support 512 is fixedly connected with the upper die plate 513; the lower die assembly 52 includes: the die comprises a lower die cylinder 521, a lower die support 522 and a lower die plate 523, wherein a piston rod of the lower die cylinder 521 is arranged along the vertical direction and is fixedly connected with the lower die support 522, the lower die support 522 is fixedly connected with the lower die plate 523, and the lower die plate 523 is positioned right below the upper die plate 513. When one end of the cable reaches the position of the injection molding device 5, the upper mold cylinder 511 drives the upper mold plate 513 to move downwards through the upper mold support 512, the lower mold cylinder 521 drives the lower mold plate 523 to move upwards through the lower mold support 522, the mold closing operation is realized, and the injection molding is performed on one end of the cable to complete the encapsulation. Wherein, the die cavity shape of injection moulding device 5 can be made according to actual need to form the cable tip of corresponding shape.

The above-mentioned embodiments are merely preferred examples of the present invention, and do not limit the scope of the present invention, so all equivalent changes or modifications made by the structure, features and principles of the present invention should be included in the claims of the present invention.

Claims (10)

1. A transport mechanism for testing cables, characterized in that: the transfer mechanism includes: the cable fixing device comprises a conveyor belt, a first carrier and a second carrier, wherein the first carrier is used for fixing one end of a cable, the second carrier is used for fixing the other end of the cable, the first carrier and the second carrier are both located on the conveyor belt, and the first carrier and the second carrier are both provided with electrodes used for electric connection.

2. The transport mechanism for test cables of claim 1, wherein: the conveyor belt includes: the motor shaft of the motor is fixedly connected with the main belt pulley, the belt is wound on the main belt pulley and the auxiliary belt pulley, and the first carrier and the second carrier are both located on the belt.

3. The transport mechanism for test cables of claim 2, wherein: the conveyor belt further comprises: the motor shaft and the rotating shaft of the motor form fixed connection through the shaft coupling, and the main belt pulley and the rotating shaft form fixed connection.

4. The transport mechanism for test cables of claim 2, wherein: the conveyor belt further comprises: the inductor, the inductor is located the side of belt.

5. The transport mechanism for test cables of claim 2, wherein: the first carrier is provided with a first positioning groove, a conductive bolt, a first pin and a first clamping jaw, the first positioning groove and the pin are respectively positioned on two opposite surfaces of the first carrier, the conductive bolt protrudes from the side wall of the first positioning groove, the conductive bolt and the first pin form electric connection to form an electrode of the first carrier, and the first clamping jaw is positioned at the lower end of the first carrier and is fixedly connected with a belt; the second carrier is provided with a second positioning groove, a jack, a second pin and a second clamping jaw, the second positioning groove and the second pin are respectively located on two opposite surfaces of the second carrier, the jack is sunken from the side wall of the second positioning groove, a conductive piece is arranged in the jack, the conductive piece and the second pin form an electric connection to form an electrode of the second carrier, and the second clamping jaw is located at the lower end of the second carrier and forms a fixed connection with a belt.

6. The transport mechanism for test cables of claim 2, wherein: the first carriers and the second carriers are multiple, and the multiple first carriers and the multiple second carriers are arranged on the belt in a staggered mode.

7. The transport mechanism for test cables of claim 2, wherein: the transfer mechanism further comprises: the pressing devices are arranged in a row along the conveying direction of the belt and are positioned right above the belt.

8. The transport mechanism for test cables of claim 7, wherein: the pressing device includes: the piston rod of the compaction cylinder is arranged along the vertical direction and is fixedly connected with the pressing block.

9. The transport mechanism for test cables of claim 2, wherein: the transfer mechanism further comprises: two injection molding devices, the two injection molding devices are arranged along the conveying direction of the belt, and the two injection molding devices are both close to the tail end of the belt.

10. The transport mechanism for test cables of claim 9, wherein: the injection molding device comprises: go up mould subassembly and lower mould subassembly, it includes to go up the mould subassembly: the upper die comprises an upper die cylinder, an upper die support and an upper die plate, wherein a piston rod of the upper die cylinder is arranged along the vertical direction and is fixedly connected with the upper die support, and the upper die support is fixedly connected with the upper die plate; the lower die assembly includes: the piston rod of the lower die cylinder is arranged along the vertical direction and is fixedly connected with the lower die support, the lower die support is fixedly connected with the lower die plate, and the lower die plate is located right below the upper die plate.

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