CN221078291U - Push-pull force testing machine platform capable of automatically clamping - Google Patents

Abstract

The utility model relates to a push-pull force testing machine platform capable of automatically clamping, which comprises a fixed base, a sliding mechanism, a rotating mechanism, a clamp body and an induction mechanism, wherein the sliding mechanism comprises a chute and a sliding block, the rotating mechanism comprises a rotating seat, a rotating ring and a fastening bolt, the clamp body comprises a shell, a clamping plate, a motor, a first worm wheel and a first worm, and the induction mechanism comprises a pressure-sensitive sensor, a photoelectric sensor and a control circuit board.

Description

Push-pull force testing machine platform capable of automatically clamping

Technical Field

The utility model belongs to the field of electronic device testing, and particularly relates to a push-pull force testing machine platform capable of automatically clamping.

Background

The performance test of the electronic device is an important process in the production process of the electronic device, the performance test comprises a tension test, a welding spot thrust test, a shearing force test and the like, the push-pull force tester is suitable for the various tests, but the push-pull force tester in the prior art has a clamp platform which still needs to be manually operated to clamp the electronic device, so that the workload of workers can be increased, and the test and the production efficiency of the electronic device can be influenced to a certain extent, so that the push-pull force tester platform which can always be automatically clamped after manufacturing is one of improvement directions which are valued by manufacturers at present.

In chinese patent publication No. CN218349972U, a push-pull force fixing clamp and a push-pull force testing machine are disclosed, and the application realizes the clamping of adapting to various electronic devices, but the application still has some defects in structure, specifically, in its composition structure, an induction mechanism and a motor are absent, which can be predicted, and this can lead to the application not being able to automatically identify electronic devices and automatically clamp, and if the induction mechanism is simply added, the instability of the overall structure may be caused due to the lack of assembly space of wire holes and accessories in the application, which can have a certain influence on testing and production efficiency.

Disclosure of utility model

Aiming at the problems in the background technology, the utility model provides a push-pull force testing machine platform capable of automatically clamping, and the specific technical scheme is as follows:

The utility model provides a push-pull force test machine platform that can automatic centre gripping, includes unable adjustment base, slide mechanism, slewing mechanism, anchor clamps body and induction system, unable adjustment base is square and is located the below, slide mechanism includes first spout, first slider, second spout and second slider, be equipped with first connecting plate on the unable adjustment base, first spout has been seted up to the top surface of first connecting plate;

The rotating mechanism comprises a rotating seat, a rotating ring and a fastening bolt, wherein a first sliding block is arranged on the bottom surface of the rotating seat and is limited in a first sliding groove, the rotating seat is connected with a first connecting plate in a sliding manner through the first sliding block, the rotating ring is sleeved outside the rotating seat and is fixedly connected with a second connecting plate, and a second sliding groove is formed in the top surface of the second connecting plate;

The clamp body comprises a shell, clamping plates, a motor, first worm wheels and first worms, wherein a second sliding block is arranged at the bottom of the shell and is limited in a second sliding groove, the shell is connected with a second connecting plate in a sliding way through the second sliding block, the clamping plates are arranged at the top of the shell, the motor, the first worm wheels and the first worms are respectively provided with four and are arranged in the shell, each first worm wheel is fixedly sleeved with a shaft of each motor, each first worm wheel is meshed with each first worm, and each first worm is vertically arranged and penetrates through one corner of the shell and is fixedly connected with one corner of the clamping plate; the sensing mechanism comprises a pressure-sensitive sensor, a photoelectric sensor and a control circuit board, wherein the pressure-sensitive sensor is arranged at the top in the shell, the photoelectric sensor is arranged at the bottom surface of the clamping plate, and the control circuit board is arranged at the bottom surface in the shell.

Further, two sides in the first chute and the second chute are respectively provided with a second worm, two sides of the first sliding block and the second sliding block are respectively provided with a second worm wheel, and each second worm wheel is correspondingly meshed and connected with each worm.

Further, the rotating seat 31 is in a shape of a circular cap, the rotating ring 32 is in a shape of a circular ring, and the diameter of the outer circle of the cap body of the rotating seat 31 is smaller than that of the outer circle of the rotating ring 32.

Further, the rotating ring is provided with a threaded hole in a penetrating mode, and the fastening bolt is connected with the rotating ring through the threaded hole in a threaded mode.

Further, the top surface both sides of casing extend there is the loading board, be equipped with protruding line on the loading board.

Further, a groove is formed in the clamping plate, a pair of openings are formed in the groove in a penetrating mode, and the groove and the two openings form a Chinese character 'ri'.

Further, a button is arranged on one side of the shell, and the control circuit board is electrically connected with the button, the pressure-sensitive sensor, the photoelectric sensor and each motor in parallel.

Further, a wiring hole is formed in one side of the shell, the photoelectric sensor is connected with the control circuit board through the wiring hole by adopting a pipeline, and the control circuit board is connected with an external power supply through the wiring hole.

The technical scheme or schemes in the push-pull force testing machine platform capable of automatically clamping provided by the embodiment of the utility model at least have one of the following technical effects:

The utility model realizes the technical purpose of automatically clamping the electronic device by reasonably arranging the sliding mechanism, the rotating mechanism and the sensing mechanism, and simultaneously, the design can facilitate the free change of the position and the angle of the clamp on the platform of the push-pull force testing machine by a worker, and when the electronic device is placed under the clamping plate, the lifting of the clamping plate can be controlled by the photoelectric sensor and the pressure-sensitive sensor. Compared with the traditional push-pull force testing machine platform, the push-pull force testing machine platform can reduce the times of manual operation of staff and improve the working efficiency.

Drawings

Fig. 1 is a schematic perspective view of the present utility model.

Fig. 2 is a schematic side perspective view of the clamp body of the present utility model.

Fig. 3 is a schematic diagram of a front perspective structure of a clamp body according to the present utility model.

Fig. 4 is a schematic bottom view of the splint according to the present utility model.

Fig. 5 is a schematic top view of the rotating mechanism of the present utility model.

Fig. 6 is a schematic perspective view of the rotating mechanism of the present utility model after being disassembled.

Fig. 7 is a schematic view showing the structure of the sliding mechanism of the present utility model after being disassembled.

Wherein: the fixing base 1, the sliding mechanism 2, the first sliding chute 21, the first sliding block 22, the second sliding chute 23, the second sliding block 24, the rotating mechanism 3, the rotating seat 31, the rotating ring 32, the fastening bolt 33, the clamp body 4, the housing 41, the clamping plate 42, the motor 43, the first worm wheel 44, the first worm 45, the sensing mechanism 5, the pressure sensor 51, the photoelectric sensor 52, the control circuit board 53, the first connecting plate 7, the second connecting plate 8, the bearing plate 9, the grain 10, the groove 11, the opening 12, the button 13, the wiring hole 14, the second worm 15, and the second worm wheel 16.

Detailed Description

Embodiments of the present utility model will be described below with reference to the accompanying drawings and examples, but the embodiments of the present utility model are not limited to the following examples, and the present utility model relates to the relevant essential parts in the art, and should be regarded as known and understood by those skilled in the art.

In one embodiment of the present utility model, as shown in fig. 1 to 7, a push-pull force testing machine platform capable of automatically clamping, comprising a fixed base 1, a sliding mechanism 2, a rotating mechanism 3, a clamp body 4 and an induction mechanism 5, is characterized in that: the fixed base 1 is square and is positioned at the lowest part, the sliding mechanism 2 comprises a first sliding groove 21, a first sliding block 22, a second sliding groove 23 and a second sliding block 24, the fixed base 1 is provided with a first connecting plate 7, and the top surface of the first connecting plate 7 is provided with the first sliding groove 21;

The rotating mechanism 3 comprises a rotating seat 31, a rotating ring 32 and a fastening bolt 33, wherein a first sliding block 22 is arranged on the bottom surface of the rotating seat 31, the first sliding block 22 is limited in a first sliding groove 21, the rotating seat 31 is connected with a first connecting plate 7 in a sliding way through the first sliding block 22, the rotating ring 32 is sleeved outside the rotating seat 31, the rotating ring 32 is fixedly connected with a second connecting plate 8, and a second sliding groove 23 is formed in the top surface of the second connecting plate 8;

The clamp body 4 comprises a shell 41, a clamping plate 42, a motor 43, a first worm wheel 44 and a first worm 45, wherein a second sliding block 24 is arranged at the bottom of the shell 41, the second sliding block 24 is limited in a second sliding groove 23, the shell 41 is connected with a second connecting plate 8 in a sliding way through the second sliding block 24, the clamping plate 42 is arranged at the top of the shell 41, the motor 43, the first worm wheel 44 and the first worm 45 are respectively provided with four and are arranged in the shell 41, each first worm wheel 44 is fixedly sleeved with the shaft of each motor 43, each first worm wheel 44 is meshed with each first worm 45, and each first worm 45 is vertically arranged and fixedly connected with one corner of the clamping plate 42 through the shell 41; the sensing mechanism 5 comprises a pressure sensor 51, a photoelectric sensor 52 and a control circuit board 53, wherein the pressure sensor 51 is arranged at the top part in the shell 41, the photoelectric sensor 52 is arranged at the bottom surface of the clamping plate 42, and the control circuit board 53 is arranged at the bottom surface in the shell 41.

With the above structure, it should be further explained that, with the fixing base as a bottom, the first connecting plate 7 is provided with a plurality of bolt holes, the fixing base 1 is also provided with a plurality of bolt holes corresponding to the first connecting plate 7, the first connecting plate 7 and the fixing base 1 are fixedly connected through bolt holes by bolts, which contributes to the structural stability of the utility model, the rotating base 31 is limitedly connected to the top surface of the first connecting plate 7 through the first sliding block 22, the rotating base 31 is non-rotatable due to the limitation of the first sliding block 22, but the rotating base 31 can freely move along the first sliding groove 21 on the first connecting plate 7 through the first sliding block 22, which contributes to the movement of the electronic device to be tested in the test process of the utility model, the rotating ring 32 is provided with a plurality of bolt holes, the second connecting plate 8 is provided with a plurality of bolt holes corresponding to the rotating ring 32, the second connecting plate 8 is fixedly connected with the rotating ring 32 through a plurality of bolt holes by bolts, and the surface of the rotating base 31 connected with the rotating ring 32 is coated with a smooth coating, which contributes to the movement of the fastening clamp 33 to provide more directions of the electronic device to be tested;

The first connecting plate 7 and the second connecting plate 8 are respectively provided with a first chute 21 and a second chute 23, the first chute 21 and the second chute 23 are in a cross orthogonal structure in space position, and the first chute 21 and the second chute 23 are matched with a first sliding block 22 and a second sliding block 24, so that the clamp can freely displace in four directions of front, back, left and right, which is beneficial to more complete testing of electronic devices to be tested, multiple disassembly and reclamping are not needed, and the testing efficiency is improved;

Each motor 43 is fixedly connected with the bottom of the shell 41, the photoelectric sensors 52 are located at two sides of the bottom surface of the clamping plate 42, the photoelectric sensors 52 are arranged in the clamping plate 42, and the transmitting and receiving parts of the photoelectric sensors extend out of the clamping plate 42, so that the photoelectric sensors 52 are helpful for identifying electronic devices to be tested and judging the distance between the electronic devices to be tested and the clamping plate 42;

When the electronic device to be tested stretches into the lower part of the clamping plate 42, the pressure-sensitive sensor 51 firstly senses the pressure change, then the pressure-sensitive sensor 51 transmits an electric signal to the control circuit board 53, the control circuit board 53 judges the signal, after confirming that the electronic device to be tested is positioned under the clamping plate 42, the control circuit board 53 transmits an electric signal, each motor 43 is controlled to operate and drive each first worm wheel 44 to rotate, each first worm 45 is meshed with each first worm wheel 44, so that each first worm 45 can ascend and descend under the drive of each first worm wheel 44, each first worm 45 penetrates through the shell 41 and is connected with the clamping plate 42, the clamping plate 42 also ascends and descends along with each first worm 45, the photoelectric sensor 52 is used for measuring the distance between the electronic device to be tested and the clamping plate 42, when the clamping plate 42 descends to a certain degree, the photoelectric sensor 52 transmits an electric signal to the control circuit board 52, the electronic device to be tested is stopped, and the electronic device to be tested can be automatically stopped at the position of the clamping plate 53, and the automatic test efficiency is improved.

As shown in fig. 7, two sides in the first chute 21 and the second chute 23 are respectively provided with a second worm 15, two sides of the first slider 22 and the second slider 24 are respectively provided with a second worm wheel 16, and each second worm wheel 16 is correspondingly meshed with each worm 15.

With the above structure, it should be further explained that the two sides of the first slider 22 and the second slider 24 are respectively provided with a notch and a roller, each roller is fixedly connected with the first slider 22 and the second slider 24, each roller is sleeved with the axle center of each second worm wheel 16, and each second worm wheel 16 is correspondingly engaged and connected with each second worm 15 through the notch, which is helpful for ensuring good stability and instant stop effect while the clamp of the utility model freely moves through the first chute 21 and the second chute 23, and avoiding the condition that the clamp of the utility model slides freely due to slight external force.

As shown in fig. 5 and fig. 6, the rotating seat 31 is in a shape of a circular cap, the rotating ring 32 is in a shape of a circular ring, and the diameter of the outer circle of the cap portion of the rotating seat 31 is smaller than that of the outer circle of the rotating ring 32.

As shown in fig. 5 and 6, the rotating ring 32 is provided with a screw hole therethrough, and the fastening bolt 33 is screwed to the rotating ring 32 through the screw hole.

With the above structure, it should be further noted that the rotating seat 31 is generally in a shape of a circular cap, the surface of the rotating seat 31 is coated with a smooth coating, and the rotating ring 32 is slidably connected with the protruding portion of the rotating seat 31, i.e. the cap body, so that the angle of the clamp of the present utility model can be changed by pushing the fastening bolt 33, and after the fastening bolt 33 is tightened, the fastening bolt 33 extends into the rotating ring 32 and abuts against the rotating seat 31, thereby fixing the rotating ring 32.

As shown in fig. 1, the two sides of the top surface of the housing 41 extend to form a bearing plate 9, and the bearing plate 9 is provided with raised grains 10.

As shown in fig. 1, the clamping plate 42 is provided with a groove 11, a pair of openings 12 are arranged in the groove in a penetrating way, and the groove 11 and the two openings 12 form a Chinese character 'ri'.

With the above structure, it should be further explained that the carrying plate 9 may be used for placing an electronic device, when the electronic device to be tested needs to be moved, the carrying plate 9 may then be used for placing an extra portion of the electronic device to be tested, the lines 10 help to further position and stabilize the electronic device to be tested, prevent errors caused by small displacement of the electronic device to be tested, and the grooves 11 and the openings 12 may correspond to the electronic device to be tested, which helps to test the electronic device to be tested by the test port of the push-pull force tester.

As shown in fig. 1, a button 13 is disposed on one side of the housing 41, and the control circuit board 53 is electrically connected to the button 13, the pressure sensor 51, the photoelectric sensor 52, and each of the motors 43 in parallel.

As shown in fig. 1, a wiring hole 14 is formed on one side of the housing 41, the photoelectric sensor 52 is connected with a control circuit board 53 through the wiring hole 14 by using a pipeline, and the control circuit board 53 is connected with an external power supply through the wiring hole 14.

With the above structure, it should be further noted that the parallel connection is used to help the control circuit board 53 to better control the electric appliances of each part, the button 13 is used to reset the height of the clamping plate 42, when the button 13 is pressed, the control circuit board 53 will emit an electric signal and control each motor 43 to reversely run and drive each first worm 45 to rise, and the wiring hole 14 is used to connect the pipeline between the photoelectric sensor 52 and the control circuit board 53, or connect the pipeline of the external power supply through the control circuit board 53.

The foregoing is merely a preferred embodiment of the present utility model and it should be noted that modifications and adaptations to those skilled in the art may be made without departing from the principles of the present utility model, which are intended to be comprehended within the scope of the present utility model.

Claims (8)

1. The utility model provides a push-and-pull force test machine platform that can automatic centre gripping, includes unable adjustment base (1), slide mechanism (2), slewing mechanism (3), anchor clamps body (4) and induction system (5), its characterized in that: the fixed base (1) is square and is positioned at the lowest part, the sliding mechanism (2) comprises a first sliding groove (21), a first sliding block (22), a second sliding groove (23) and a second sliding block (24), a first connecting plate (7) is arranged on the fixed base (1), and the first sliding groove (21) is formed in the top surface of the first connecting plate (7);

The rotating mechanism (3) comprises a rotating seat (31), a rotating ring (32) and a fastening bolt (33), wherein a first sliding block (22) is arranged on the bottom surface of the rotating seat (31), the first sliding block (22) is limited in a first sliding groove (21), the rotating seat (31) is slidably connected with a first connecting plate (7) through the first sliding block (22), the rotating ring (32) is sleeved outside the rotating seat (31), the rotating ring (32) is fixedly connected with a second connecting plate (8), and a second sliding groove (23) is formed in the top surface of the second connecting plate (8);

The fixture comprises a fixture body (4), wherein the fixture body comprises a shell (41), clamping plates (42), a motor (43), first worm wheels (44) and first worms (45), a second sliding block (24) is arranged at the bottom of the shell (41), the second sliding block (24) is limited in a second sliding groove (23), the shell (41) is slidably connected with a second connecting plate (8) through the second sliding block (24), the clamping plates (42) are arranged at the top of the shell (41), the motor (43), the first worm wheels (44) and the first worms (45) are respectively provided with four and are arranged in the shell (41), each first worm wheel (44) is fixedly sleeved with the shaft of each motor (43), each first worm wheel (44) is meshed with each first worm (45), and each first worm (45) is vertically arranged and fixedly connected with one corner of the clamping plates (42) in a penetrating manner;

the sensing mechanism (5) comprises a pressure-sensitive sensor (51), a photoelectric sensor (52) and a control circuit board (53), wherein the pressure-sensitive sensor (51) is arranged at the top in the shell (41), the photoelectric sensor (52) is arranged at the bottom surface of the clamping plate (42), and the control circuit board (53) is arranged at the bottom surface in the shell (41).

2. The automatically clampable push-pull force tester platform according to claim 1, wherein: second worms (15) are respectively arranged on two sides in the first sliding groove (21) and the second sliding groove (23), second worm gears (16) are respectively arranged on two sides of the first sliding block (22) and the second sliding block (24), and each second worm gear (16) is correspondingly meshed and connected with each worm (15).

3. The automatically clampable push-pull force tester platform according to claim 1, wherein: the rotating seat (31) is in a circular cap shape, the rotating ring (32) is in a circular ring shape, and the diameter of the outer circle of the cap body part of the rotating seat (31) is smaller than that of the rotating ring (32).

4. The automatically clampable push-pull force tester platform according to claim 1, wherein: the rotating ring (32) is provided with a threaded hole in a penetrating mode, and the fastening bolt (33) is connected with the rotating ring (32) through the threaded hole in a threaded mode.

5. The automatically clampable push-pull force tester platform according to claim 1, wherein: the bearing plates (9) extend from two sides of the top surface of the shell (41), and raised grains (10) are arranged on the bearing plates (9).

6. The automatically clampable push-pull force tester platform according to claim 1, wherein: a groove (11) is formed in the clamping plate (42), a pair of openings (12) are formed in the groove in a penetrating mode, and the groove (11) and the two openings (12) form a Chinese character 'ri'.

7. The automatically clampable push-pull force tester platform according to claim 1, wherein: one side of the shell (41) is provided with a button (13), and the control circuit board (53) is electrically connected with the button (13), the pressure-sensitive sensor (51), the photoelectric sensor (52) and each motor (43) in parallel connection.

8. The automatically clampable push-pull force tester platform according to claim 1, wherein: a wiring hole (14) is formed in one side of the shell (41), the photoelectric sensor (52) is connected with the control circuit board (53) through the wiring hole (14) through a pipeline, and the control circuit board (53) is connected with an external power supply through the wiring hole (14).