CN220323465U - Automatic testing device for joint - Google Patents

Abstract

The utility model discloses an automatic connector testing device which is characterized by comprising a testing platform, wherein a working end and a transplanting end are arranged on the testing platform, and the transplanting end is arranged on one side of the working end; be provided with feed mechanism, first transplanting mechanism and testing mechanism on the work end, it is provided with second transplanting mechanism and tool mechanism to transplant the end, and during operation, snatchs the material that awaits measuring from feed mechanism through first transplanting mechanism and places in tool mechanism, transplants the joint on the tool mechanism through the second transplanting mechanism and transmits to relevant position carry out withstand voltage test to it under testing mechanism's effect, then through the second transplanting mechanism moves to plant the unloading to it, realizes the automatic transmission and the detection to the joint.

Description

Automatic testing device for joint

Technical Field

The utility model relates to the field of joint processing equipment, in particular to an automatic testing device for a joint.

Background

Along with the rapid development of electronic power technology, various electronic devices are rapidly developed, power transmission and data transmission in the electronic power devices are not separated from various transmission wires, the wires are connected with the electronic devices through connectors, the wires are required to be tested through various procedures in the processing process, one procedure required to be detected during pressure resistance test is required, in the existing pressure resistance test device, manual feeding and discharging and workpiece transferring are generally required, a large amount of manpower is required to be consumed, and the degree of automation is relatively low.

Disclosure of Invention

In view of the above, the utility model discloses an automatic connector testing device which can realize automatic testing and loading and unloading of connectors.

The utility model discloses an automatic connector testing device which comprises a testing platform, wherein a working end and a transplanting end are arranged on the testing platform, and the transplanting end is arranged on one side of the working end; the working end is provided with a feeding mechanism, a first transplanting mechanism and a testing mechanism, and the transplanting end is provided with a second transplanting mechanism and a jig mechanism; wherein,

the jig mechanism can move between the working end and the transplanting end, a plurality of jig platforms are arranged on the jig mechanism along a first direction, the first transplanting mechanism is used for moving a joint to be detected of the feeding mechanism to one of the jig platforms, and the second transplanting mechanism is used for grabbing the joint from one of the jig platforms and placing the joint on the other jig platforms in the first direction;

the test mechanism is arranged on one side of the first transplanting mechanism in a first direction.

Further, the feeding mechanism comprises a driving source, a transmission belt and a transmission support, wherein the transmission belt is arranged on the transmission support through a belt pulley, and the driving source drives the transmission belt to rotate through the belt pulley.

Further, the first transplanting mechanism comprises a first transplanting support, a first air cylinder and a first clamping component, the first transplanting support is fixed on the test platform, and the first air cylinder is fixed on the first transplanting support and can drive the first clamping component to move along a first direction.

Further, the first clamping assembly comprises a first clamping bracket, a first lifting cylinder and at least one first clamping jaw, and the first clamping bracket is in sliding fit with the first transplanting bracket in a first direction; the first clamping jaw is in sliding connection with the first clamping bracket through a first sliding plate, and the first lifting cylinder can drive the first sliding plate to move relative to the first clamping bracket in the vertical direction.

Further, the testing mechanism comprises a testing support, a second lifting cylinder, a connecting plate and a testing compression bar, wherein the testing support is fixed on the testing platform, the connecting plate is in sliding connection with the testing support in the vertical direction, the testing compression bar is fixed on the connecting plate, and the second lifting cylinder drives the testing compression bar in the vertical direction through the connecting plate.

Further, the test compression bar comprises a compression bar main body and a pressure head, wherein the compression bar main body is fixed on the connecting plate, the pressure head is arranged below the compression bar main body, the top of the pressure head stretches into the compression bar main body and is connected through an elastic piece, and the bottom of the pressure head is provided with a compression joint part.

Further, the jig mechanism comprises a jig plate and a first driving cylinder, the jig plate is in sliding connection with the test platform through a sliding rail, and the first driving cylinder can drive the jig plate to slide between the working end and the transplanting end; the jig platforms are distributed on the jig plate along a first direction.

Further, the second transplanting mechanism comprises a second transplanting bracket, a second driving air cylinder, a first driving plate, a second driving plate, a third lifting air cylinder and a plurality of second clamping jaws, wherein,

the second transplanting support is fixedly connected with the test platform;

the first driving plate is in sliding connection with the second transplanting support, and the second driving cylinder is used for driving the first driving plate to slide in a first direction relative to the second transplanting support;

the second driving plate is in sliding connection with the first driving plate in the vertical direction, a plurality of second clamping jaws are distributed on the second driving plate along the first direction, and the third lifting cylinder can drive the second driving plate to slide in the vertical direction relative to the first driving plate.

Compared with the prior art, the technical scheme disclosed by the utility model has the beneficial effects that:

the first transplanting mechanism is used for grabbing the material to be tested from the feeding mechanism and placing the material in the jig mechanism, the second transplanting mechanism is used for transplanting and transmitting the connector on the jig mechanism to the corresponding position, the pressure-resistant test is carried out on the material under the action of the testing mechanism, and then the second transplanting mechanism is used for transplanting and discharging the material, so that automatic transmission and detection of the connector are realized.

Drawings

FIG. 1 is a schematic diagram of a test apparatus;

FIG. 2 is a top view of the test device;

fig. 3 is a schematic structural view of a first transplanting mechanism;

FIG. 4 is a schematic diagram of a fixture mechanism;

FIG. 5 is a schematic structural view of a test mechanism;

FIG. 6 is a schematic diagram of a test strut;

fig. 7 is a schematic structural view of a second transplanting mechanism.

Detailed Description

The following description of the embodiments of the present utility model will be made with reference to the drawings in which the embodiments of the present utility model are clearly and fully described, it should be noted that when one component is considered to be "connected" to another component, it may be directly connected to the other component, or there may be an intervening component at the same time. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. It should also be noted that the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, unless otherwise specifically defined and limited; either mechanically or electrically, or by communication between two components. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art. The terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model.

It should be further noted that, in the description of the present utility model, it should be noted that, directions or positional relationships indicated by terms such as "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., are based on directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific direction, be configured and operated in the specific direction, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

As shown in fig. 1 and 2, the utility model discloses an automatic joint testing device 100, which comprises a testing platform 10, wherein a working end and a transplanting end are arranged on the testing platform 10, and the transplanting end is arranged on one side of the working end.

Specifically, the working end is provided with a feeding mechanism 20, a first transplanting mechanism 30 and a testing mechanism 40, the transplanting end is provided with a second transplanting mechanism 60 and a jig mechanism 50, during working, a material to be tested is grabbed from the feeding mechanism 20 through the first transplanting mechanism 30 and placed in the jig mechanism 50, the joint of the jig mechanism 50 is transplanted and transmitted to a corresponding position through the second transplanting mechanism 60, the pressure-resistant test is conducted on the joint under the action of the testing mechanism 40, and then the joint is transplanted and discharged through the second transplanting mechanism 60, so that automatic transmission and detection of the joint are realized.

Further, the feeding mechanism 20 includes a driving source 22, a transmission belt 23 and a transmission support 21, the transmission support 21 is fixedly disposed on the test platform 10, the transmission belt 23 is disposed on the transmission support 21 through a belt pulley, and the driving source 22 drives the transmission belt 23 to rotate through the belt pulley, so as to transmit the material to be tested placed on the transmission belt 23. Specifically, a photoelectric sensor is disposed at the grabbing position of the first transplanting mechanism 30, and the photoelectric sensor is used for identifying the position of the material at the grabbing position on the feeding mechanism 20.

When the feeding mechanism 20 moves the material to the preset position, the feeding mechanism 20 stops the transmission work and waits for the first transplanting mechanism 30 to grasp the material to be detected. As shown in fig. 3, the first transplanting mechanism 30 includes a first transplanting support 31, a first cylinder 32, and a first clamping assembly 33, the first transplanting support 31 is fixed on the test platform 10, and the first cylinder 32 is fixed on the first transplanting support 31 and can drive the first clamping assembly 33 to move along a first direction a. Specifically, after the first clamping assembly 33 clamps the material on the feeding mechanism 20, the first cylinder 32 drives the first clamping assembly 33 to move along the first direction a, so that the first clamping assembly 33 moves to a position above the jig mechanism 50, and the material is placed on the jig mechanism 50.

Further, the first clamping assembly 33 includes a first clamping bracket 331, a first lifting cylinder 332, and at least one first clamping jaw 333, where the first clamping bracket 331 is slidably engaged with the first transplanting bracket 31 in a first direction a; the first clamping jaw 33 is slidably connected with the first clamping bracket 331 through a first sliding plate 334, and the first lifting cylinder 332 may drive the first sliding plate 334 to move in a vertical direction relative to the first clamping bracket 331. When the material to be tested moves to the position right below the first clamping jaw 333, the first lifting cylinder 332 drives the first clamping jaw 333 to move downward and clamp the material by the first clamping jaw 333, then the first lifting cylinder 332 drives the material to lift by the first clamping jaw 333, and then the first cylinder 32 drives the first clamping bracket 331 to move.

The test mechanism 40 is disposed on one side of the first transplanting mechanism 30, and the jig assembly 50 can be moved to the lower side of the first transplanting mechanism 30 and the test mechanism 40 at the same time. As shown in fig. 4, the jig mechanism 50 includes a jig plate 52 and a first driving cylinder 51, the jig plate 52 is slidably connected with the test platform 10 through a sliding rail, and the first driving cylinder 51 can drive the jig plate 52 to slide between the working end and the transplanting end; the plurality of jig stages 53 are distributed along the first direction a on the jig plate 52. Specifically, the first driving cylinder 51 drives the jig platform 53 to move to the lower side of the first transplanting mechanism 30 through the jig plate 52, the first transplanting mechanism 30 places the clamped material on one of the jig platforms 53, then the jig mechanism 50 resets, the second transplanting mechanism 60 moves the material to be tested forward along the first direction a by one station, places the material on the jig platform 53 corresponding to the testing mechanism 40, and then the first driving cylinder 51 moves the jig platform 53 to the working end through the jig plate 52, so that the material to be tested is located under the testing mechanism 50, and the testing mechanism 50 performs pressure testing on the material to be tested.

As shown in fig. 5 and 6, further, the test mechanism 40 includes a test stand 41, a second lifting cylinder 42, a connection plate 43, and a test compression bar 44, where the test stand 41 is fixed on the test platform 10, the connection plate 43 is slidably connected with the test stand 41 in a vertical direction, the test compression bar 44 is fixed on the connection plate 43, and the second lifting cylinder 42 drives the test compression bar 44 in a vertical direction through the connection plate 43. When the material to be tested is located right below the test compression bar 44, the second lifting cylinder 42 drives the test compression bar 44 to move downwards through the connecting plate belt 43, and the material to be tested is pressed down through the test compression bar 44 to perform pressure test.

Further, the test compression bar 44 includes a compression bar main body 441 and a compression head 442, the compression bar main body 441 is fixed on the connection board 43, the compression head 442 is disposed below the compression bar main body 441, the top of the compression head 442 extends into the compression bar main body 441 and is connected through an elastic member 443, and a compression joint portion 444 is disposed at the bottom of the compression head 442. When the joint is held by the press-fit portion 444, the elastic member 443 can cushion it from damage to the joint due to rigid contact.

Further, the compression joint portion 444 is made of plastic material, or is covered with a soft rubber.

Further, the elastic member 43 is a spring.

Further, a pressure sensor is disposed between the elastic member 43 and the compression bar body 441.

As shown in fig. 7, the second transplanting mechanism 60 includes a second transplanting bracket, a second driving cylinder 61, a first driving plate 62, a second driving plate 63, a third lifting cylinder 64, and a plurality of second clamping jaws 65, where the second transplanting bracket is fixedly connected with the test platform 10; the first driving plate 62 is slidably connected with the second transplanting support, and the second driving cylinder 61 is used for driving the first driving plate 62 to slide in a first direction a relative to the second transplanting support; the second driving plate 63 is slidably connected with the first driving plate 62 in a vertical direction, a plurality of second clamping jaws 65 are distributed on the second driving plate 63 along a first direction, and the third lifting cylinder 64 can drive the second driving plate 63 to slide relative to the first driving plate 62 in the vertical direction.

In this application, the number of the second clamping jaws 65 is the same as the number of the jig platforms 53, and the spacing between two adjacent second clamping jaws 65 is the same as the spacing between two adjacent jig platforms 53.

The present utility model can be embodied in various forms and modifications without departing from the broad spirit and scope of the utility model, and the above-described embodiments are intended to be illustrative of the utility model, but not limiting the scope of the utility model.

Claims (8)

1. The automatic connector testing device is characterized by comprising a testing platform, wherein a working end and a transplanting end are arranged on the testing platform, and the transplanting end is arranged on one side of the working end; the working end is provided with a feeding mechanism, a first transplanting mechanism and a testing mechanism, and the transplanting end is provided with a second transplanting mechanism and a jig mechanism; wherein,

the jig mechanism can move between the working end and the transplanting end, a plurality of jig platforms are arranged on the jig mechanism along a first direction, the first transplanting mechanism is used for moving a joint to be detected of the feeding mechanism to one of the jig platforms, and the second transplanting mechanism is used for grabbing the joint from one of the jig platforms and placing the joint on the other jig platforms in the first direction;

the test mechanism is arranged on one side of the first transplanting mechanism in a first direction.

2. The automatic joint testing device according to claim 1, wherein the feeding mechanism comprises a driving source, a transmission belt and a transmission support, the transmission belt is arranged on the transmission support through a belt pulley, and the driving source drives the transmission belt to rotate through the belt pulley.

3. The automated joint testing device of claim 2, wherein the first transplanting mechanism comprises a first transplanting support, a first cylinder, and a first clamping assembly, the first transplanting support being secured to the test platform, the first cylinder being secured to the first transplanting support and being operable to drive the first clamping assembly to move in a first direction.

4. A joint automated testing apparatus according to claim 3, wherein the first gripping assembly comprises a first gripping bracket, a first lifting cylinder, and at least one first jaw, the first gripping bracket slidably engaging the first transplanting bracket in a first direction; the first clamping jaw is in sliding connection with the first clamping bracket through a first sliding plate, and the first lifting cylinder can drive the first sliding plate to move relative to the first clamping bracket in the vertical direction.

5. The automated joint testing device of claim 4, wherein the testing mechanism comprises a testing stand, a second lifting cylinder, a connecting plate and a testing compression bar, the testing stand is fixed on the testing platform, the connecting plate is slidably connected with the testing stand in the vertical direction, the testing compression bar is fixed on the connecting plate, and the second lifting cylinder drives the testing compression bar in the vertical direction through the connecting plate.

6. The automatic joint testing device according to claim 5, wherein the testing press rod comprises a press rod main body and a press head, the press rod main body is fixed on the connecting plate, the press head is arranged below the press rod main body, the top of the press head extends into the press rod main body and is connected through an elastic piece, and the bottom of the press head is provided with a press connection part.

7. The automated joint testing device of claim 6, wherein the jig mechanism comprises a jig plate and a first driving cylinder, the jig plate is slidably connected with the testing platform through a sliding rail, and the first driving cylinder can drive the jig plate to slide between the working end and the transplanting end; the jig platforms are distributed on the jig plate along a first direction.

8. The automated joint testing device of claim 7, wherein the second transplanting mechanism comprises a second transplanting support, a second drive cylinder, a first drive plate, a second drive plate, a third lift cylinder, and a plurality of second jaws, wherein,

the second transplanting support is fixedly connected with the test platform;

the first driving plate is in sliding connection with the second transplanting support, and the second driving cylinder is used for driving the first driving plate to slide in a first direction relative to the second transplanting support;

the second driving plate is in sliding connection with the first driving plate in the vertical direction, a plurality of second clamping jaws are distributed on the second driving plate along the first direction, and the third lifting cylinder can drive the second driving plate to slide in the vertical direction relative to the first driving plate.