CN114834886A

CN114834886A - Probe test clamping device

Info

Publication number: CN114834886A
Application number: CN202210417848.9A
Authority: CN
Inventors: 方经军
Original assignee: Suzhou Stende Electronic Technology Co ltd
Current assignee: Suzhou Stende Electronic Technology Co ltd
Priority date: 2022-04-20
Filing date: 2022-04-20
Publication date: 2022-08-02

Abstract

The invention provides a probe test clamping device, which comprises: the device comprises a mounting frame, a vertical telescopic cylinder, a fixing frame and a transverse telescopic cylinder; the mounting shell is arranged on the front side of the fixing frame in a sliding mode, and one end of an output shaft of the transverse telescopic cylinder is fixedly connected with the mounting shell through a pushing arm; the clamping mechanism comprises a sliding arm, a sliding sleeve, a clamping part, an adjusting arm, a positioning mechanism and a positioning hole, wherein the sliding arm is fixed in the mounting shell. According to the probe test clamping device provided by the invention, the sleeving arm is matched with the strip-shaped hole, so that when the transverse telescopic cylinder pushes the mounting shell to move forward, the two clamping parts can be driven to be closed to clamp the probe, and the positioning mechanism is matched with the positioning hole to limit the two clamping parts, so that the two clamping parts can stably clamp the probe, and therefore, the transverse distance adjustment of the clamping mechanism and the clamping of the probe can be realized by arranging one drive, and the probe test clamping device is more power-saving, energy-saving and environment-friendly.

Description

Probe test clamping device

Technical Field

The invention relates to the field of probe detection, in particular to a probe test clamping device.

Background

The probe is a high-end precise electronic hardware component, the appearance and performance of the probe are required to be tested after the probe is manufactured, the performance test mainly comprises an elastic test and an impedance test, and automatic probe test equipment is required in the process of testing the performance of the probe. The automatic probe test equipment comprises a material supply area and a detection area, wherein a probe in the material supply area is operated to the detection area by a mechanical arm, and another mechanical arm in the detection area needs to clamp a probe material in the mechanical arm in the material supply area and transfer the probe material to a detection station for detection.

In the detection area, the probes are mostly operated in a multi-station mode, the probes to be detected are clamped and conveyed to the detection area from the feeding end through a manipulator, the probes are conveyed to the probe collection area after detection, and the manipulator is loosened to the collection container;

present a press from both sides and get mechanism for pressing from both sides get probe, through including lift adjustment portion, flexible adjustment portion with press from both sides the portion of getting, wherein flexible adjustment portion with press from both sides the portion of getting and all need set up the operation that the drive realized the function, need a plurality of drives promptly, consume more electric power energy.

Therefore, it is necessary to provide a probe test clamping device to solve the above technical problems.

Disclosure of Invention

The invention provides a probe test clamping device, which solves the problem that the conventional probe test clamping device consumes high electric power and energy.

In order to solve the above technical problem, the probe test clamping device provided by the invention comprises: the device comprises a mounting frame, a vertical telescopic cylinder, a fixing frame and a transverse telescopic cylinder;

the mounting shell is arranged on the front side of the fixing frame in a sliding mode, and one end of an output shaft of the transverse telescopic cylinder is fixedly connected with the mounting shell through a pushing arm;

the clamping mechanism comprises a sliding arm, a sliding sleeve, a clamping part, an adjusting arm, a positioning mechanism and a positioning hole, the sliding arm is fixed inside the mounting shell, the sliding sleeve is connected to two sides of the sliding arm in a sliding mode, the clamping part is fixed to one side of the sliding sleeve through a fixing shaft, the positioning mechanism is arranged on the sliding sleeve, the positioning hole is symmetrically formed in the sliding arm, and one end of the adjusting arm penetrates through the fixing frame and the mounting shell through a strip-shaped hole in sequence and then is fixedly connected with the other side of the sliding sleeve;

and the elastic mechanism is arranged between the two adjusting arms and is positioned in the fixing frame.

Preferably, the vertical telescopic cylinder is fixedly installed at the top of the mounting frame, the fixing frame is connected to the inside of the mounting frame in a sliding mode, one end of an output shaft of the vertical telescopic cylinder is connected with the fixing frame, and the transverse telescopic cylinder is fixedly installed inside the fixing frame.

Preferably, positioning mechanism is including an installation section of thick bamboo, piston piece, first elastic component and location axle, an installation section of thick bamboo is fixed in the upside of sliding sleeve, the inside of an installation section of thick bamboo slides and is provided with the piston piece, the bottom of piston piece is provided with the location axle, the inside that the sliding sleeve just extended to the sliding sleeve is run through to the one end of location axle, first elastic component set up in the inside of an installation section of thick bamboo and be located the upside of piston piece.

Preferably, the adjusting arm comprises a straight rod part and an inclined rod part, one end of the straight rod part is fixedly connected with the sliding sleeve, and the inclined rod part is connected with the other end of the straight rod part.

Preferably, elastic mechanism includes flexible arm, fender dish and second elastic component, the both ends of flexible arm through fixed respectively with the straight pole portion fixed connection of two regulating arms, the equal fixedly connected with fender dish in both ends of flexible arm, the surface of flexible arm just is located and overlaps between two fender dishes and is equipped with the second elastic component.

Preferably, the installation shell includes casing, first spout and second spout, first spout has all been seted up to the front side symmetry of casing, the one end of fixed axle through first spout run through behind the casing with sliding sleeve fixed connection, the second spout is seted up in the bottom of casing.

Preferably, the inside of installation shell is provided with release mechanism, release mechanism includes ejector pad, push arm, sloping piece and L shape catch bar, the ejector pad is located the inside of locating hole, the bottom fixedly connected with push arm of ejector pad, the one end of push arm runs through the sliding sleeve and extends to the outside of sliding sleeve, the bottom of push arm sets up to the inclined plane.

Preferably, the inclined plane block is slidably connected to the inside of the installation shell, a second chute through which one end of the L-shaped push rod passes extends to the inside of the installation shell and then is fixedly connected with the inclined plane block, and the inclined plane side of the push arm is attached to the inclined plane of the inclined plane block.

Preferably, the straight rod part comprises an internal thread cylinder, a thread rod part, a driving lug, a sliding rod and a positioning ring, one end of the internal thread cylinder is fixedly connected with the sliding sleeve, the thread rod part is rotatably connected with one end of the inclined rod part, and the thread rod part is in threaded connection with the internal thread cylinder.

Preferably, the surface of the threaded rod part and the end located outside the internal thread cylinder are provided with driving lugs, the straight rod part is connected with a sliding rod, the positioning ring is sleeved on the surface of the sliding rod, and one side of the positioning ring is fixedly connected with the internal thread cylinder.

Compared with the related art, the probe test clamping device provided by the invention has the following beneficial effects:

the invention provides a probe test clamping device, which is characterized in that a sleeving arm is arranged to be matched with a strip-shaped hole, when a transverse telescopic cylinder pushes a mounting shell to move forward, two clamping parts can be driven to be closed to clamp a probe, and the two clamping parts can be limited by a positioning mechanism matched with a positioning hole, so that the two clamping parts can stably clamp the probe, and therefore, the transverse distance adjustment of a clamping mechanism and the clamping of the probe can be realized by arranging a drive, and the probe test clamping device is more power-saving, energy-saving and environment-friendly.

Drawings

Fig. 1 is a schematic structural diagram of a probe test gripping device according to a first embodiment of the present invention;

FIG. 2 is a side view of the ensemble shown in FIG. 1;

FIG. 3 is a schematic view of the interior of the mounting housing shown in FIG. 1;

FIG. 4 is a schematic structural view of the elastic mechanism shown in FIG. 2;

FIG. 5 is a schematic view of a portion of the clamping mechanism shown in FIG. 3;

FIG. 6 is a cross-sectional view of the clamping mechanism shown in FIG. 3;

FIG. 7 is a schematic structural diagram of a probe test gripping apparatus according to a second embodiment of the present invention;

fig. 8 is a schematic structural diagram of a probe test gripping device according to a third embodiment of the present invention.

Reference numbers in the figures:

1. a mounting frame is arranged on the base plate,

2. a vertical telescopic cylinder is arranged on the upper portion of the frame,

3. a fixed frame is arranged on the upper portion of the frame,

4. a transverse telescopic cylinder is arranged on the upper end of the horizontal telescopic cylinder,

5. the mounting of the housing is carried out,

6. a clamping mechanism 61, a sliding arm 62, a sliding sleeve 63, a clamping part 64, an adjusting arm 65 and a positioning mechanism,

66. a positioning hole 651, a mounting cylinder 652, a piston block 653, a first elastic element 654, a positioning shaft,

7. an elastic mechanism 71, a telescopic arm 72, a baffle disc 73, a second elastic piece,

8. a disassembly mechanism 81, a push block 82, a push arm 83, a bevel block 84, an L-shaped push rod,

10. a strip-shaped hole is formed in the upper surface of the base,

11. a supporting rod is arranged on the supporting rod,

91. the device comprises an internal thread cylinder 92, a thread rod part 93, an inclined rod part 94, a driving lug 95, a sliding rod 96 and a positioning ring.

Detailed Description

The invention is further described with reference to the following figures and embodiments.

First embodiment

Please refer to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5 and fig. 6 in combination, in which fig. 1 is a schematic structural diagram of a probe test gripping device according to a first embodiment of the present invention; FIG. 2 is a side view of the ensemble shown in FIG. 1; FIG. 3 is a schematic view of the interior of the mounting housing shown in FIG. 1; FIG. 4 is a schematic structural view of the elastic mechanism shown in FIG. 2; FIG. 5 is a schematic view of a portion of the clamping mechanism shown in FIG. 3; fig. 6 is a cross-sectional view of the clamping mechanism shown in fig. 3. Device is got to probe test clamp includes: the device comprises a mounting frame 1, a vertical telescopic cylinder 2, a fixing frame 3 and a transverse telescopic cylinder 4;

the mounting shell 5 is arranged on the front side of the fixing frame 3 in a sliding mode, and one end of an output shaft of the transverse telescopic cylinder 4 is fixedly connected with the mounting shell 5 through a pushing arm;

the clamping mechanism 6, the clamping mechanism 6 includes a slide arm 61, a sliding sleeve 62, a clamping portion 63, an adjusting arm 64, a positioning mechanism 65 and a positioning hole 66, the slide arm 61 is fixed inside the mounting shell 5, the sliding sleeve 62 is slidably connected to both sides of the slide arm 61, the clamping portion 63 is fixed to one side of the sliding sleeve 62 through a fixed shaft, the positioning mechanism 65 is arranged on the sliding sleeve 62, the positioning hole 66 is symmetrically formed on the slide arm 61, and one end of the adjusting arm 64 is fixedly connected to the other side of the sliding sleeve 62 after sequentially penetrating through the fixed frame 3 and the mounting shell 5 through a strip-shaped hole 10;

and the elastic mechanism 7 is arranged between the two adjusting arms 64 and positioned inside the fixed frame 3.

The vertical telescopic cylinder 2 and the transverse telescopic cylinder 4 can be air cylinders, hydraulic cylinders or electric cylinders;

the cross section of the slide arm 61 is preferably rectangular, so that the sliding sleeve 62 can only slide horizontally along the surface of the slide arm 61;

in the re-starting state, as shown in fig. 2, the sides of the two adjusting arms 64 are respectively in contact with the two sides of the inner wall of the strip-shaped hole 10;

wherein the back of the fixed mount 3 and the mounting shell 5 is correspondingly provided with a strip-shaped hole.

The bottom of the mounting shell 5 is symmetrically provided with sleeves, the lower part of the front side of the fixing frame 3 is symmetrically provided with supporting rods, and the sleeves are sleeved on the supporting rods.

The vertical telescopic cylinder 2 is fixedly installed at the top of the mounting frame 1, the fixing frame 3 is connected to the inside of the mounting frame 1 in a sliding mode, one end of an output shaft of the vertical telescopic cylinder 2 is connected with the fixing frame 3, and the transverse telescopic cylinder 4 is fixedly installed inside the fixing frame 3.

Wherein, the two sides of the bottom of the mounting rack 1 are symmetrically provided with sliding arms, and one side of the fixing rack 3 is sleeved on the two sliding arms to form sliding fit.

The positioning mechanism 65 includes a mounting cylinder 651, a piston block 652, a first elastic member 653 and a positioning shaft 654, the mounting cylinder 651 is fixed on the upper side of the sliding sleeve 62, the piston block 652 is slidably disposed in the mounting cylinder 651, the positioning shaft 654 is disposed at the bottom of the piston block 652, one end of the positioning shaft 654 penetrates through the sliding sleeve 62 and extends into the sliding sleeve 62, and the first elastic member 653 is disposed in the mounting cylinder 651 and located on the upper side of the piston block 652.

The first elastic member 653 is preferably a spring, wherein when the positioning shaft 654 moves to correspond to the positioning hole 66, the two clamping portions 63 clamp the probe, the rubber pad is adhered to the inner sides of the clamping portions 63, and the clamping grooves are correspondingly formed on the inner sides of the clamping portions 63 and are adapted to the size of the probe.

The adjusting arm 64 comprises a straight rod part and an inclined rod part 93, one end of the straight rod part is fixedly connected with the sliding sleeve 62, and the inclined rod part 93 is connected with the other end of the straight rod part.

Elastic mechanism 7 includes flexible arm 71, fender dish 72 and second elastic component 73, the both ends of flexible arm 71 through fixed respectively with two straight rod portion fixed connection of adjusting arm 64, the equal fixedly connected with fender dish 72 in both ends of flexible arm 71, the surface of flexible arm 71 just is located and overlaps between two fender dishes 72 and is equipped with second elastic component 73.

The telescopic arm 71 comprises an outer cylinder and an inner rod, one end of the inner rod extends into the outer cylinder, wherein two stop discs 72 are respectively located on the outer cylinder and the inner rod, and the second elastic member 73 is preferably provided as a spring.

The mounting shell 5 comprises a shell 51, a first sliding groove 52 and a second sliding groove 53, wherein the first sliding groove 52 is symmetrically formed in the front side of the shell 51, one end of the fixing shaft penetrates through the shell 51 through the first sliding groove 52 and then is fixedly connected with the sliding sleeve 62, and the second sliding groove 53 is formed in the bottom of the shell 51.

The length of the first chute 52 is the same as the distance of the traverse when the gripping portion 63 grips.

The working principle of the probe test clamping device provided by the invention is as follows:

mounting bracket 1 is installed on the rotary disk, and the rotary disk is connected on servo motor's output shaft to can drive whole clamp and get the device and remove to the station that does not pass through.

When the detection needle needs to be clamped, the height of the clamping mechanism 6 can be adjusted to correspond to the position of the probe through the vertical telescopic cylinder 2;

at the moment, the transverse telescopic cylinder 4 pushes the mounting shell 5 to move forwards and move towards the direction of the probe, wherein in the moving process, the sliding sleeve 62 drives the adjusting arm 64 to move along with the movement;

when the inclined rod parts 93 of the adjusting arms 64 move to correspond to the outer side walls of the strip-shaped holes 10, the transverse telescopic cylinder 4 continues to push, and at the moment, the inclined rod parts 93 of the two adjusting arms 64 act on the side walls of the two strip-shaped holes 10 to drive the two sliding sleeves 62 to move towards the opposite sides along the sliding arms 61;

when the clamping mechanism 6 moves to the clamping groove on the clamping part 63 to correspond to the probe, the two clamping parts 63 clamp the probe;

at this time, the positioning shaft 654 in the positioning mechanism 65 corresponds to the positioning hole 66 on the slide arm 61, and the positioning shaft 654 is pushed into the positioning hole 66 by the action of the first elastic element 653 to limit the positioning shaft, that is, the two clamping portions 63 are limited, so that the clamping portions 63 can stably clamp the probe;

meanwhile, when the two adjusting arms 64 are retracted to the opposite sides, the telescopic arm 71 is retracted and drives the two blocking discs 72 to compress the second elastic element 73;

the clamping mechanism 6 can be pulled back through the transverse telescopic cylinder 4, and the whole clamping device can be driven to move to other stations through the rotating disc.

through setting up grafting arm 64 cooperation bar hole 10, promote the installation shell 5 when horizontal telescoping cylinder 4 and advance the in-process, can drive two clamping parts 63 and close and carry out the centre gripping to the probe, and can be spacing to two clamping parts 63 through positioning mechanism 65 cooperation locating hole 66, make it stabilize to the probe centre gripping, thereby can realize the transverse distance of fixture 6 through setting up a drive and adjust and the centre gripping to the probe, more power saving, energy saving and environmental protection.

Second embodiment

Referring to fig. 2 and 7, in particular, the probe test clamping device provided in the second embodiment of the present application is different in that an unlocking mechanism 8 is disposed inside the mounting housing, the unlocking mechanism 8 includes a push block 81, a push arm 82, an inclined block 83 and an L-shaped push rod 84, the push block 81 is located inside the positioning hole 66, the push arm 82 is fixedly connected to the bottom of the push block 81, one end of the push arm 82 penetrates through the sliding sleeve 62 and extends to the outside of the sliding sleeve 62, and the bottom of the push arm 82 is set to be an inclined surface.

The inclined block 83 is slidably connected to the inside of the mounting shell 5, the second sliding slot 53 through which one end of the L-shaped push rod 84 passes extends to the inside of the mounting shell 5 and then is fixedly connected to the inclined block 83, and the inclined surface of the push arm 82 is attached to the inclined surface of the inclined block 83.

Wherein, a positioning plate is correspondingly arranged in the blanking area or a station needing to loosen the probe, and the like, and corresponds to the position of the L-shaped push rod 84;

when the clamping part 63 is required to loosen the probe, the transverse telescopic cylinder 4 pushes the mounting shell 5 forwards again for a certain distance, the distance is the distance that the L-shaped pushing rod 84 exceeds the front side of the mounting shell 5, the pushing rod 82 is contacted with the positioning plate and is acted by the positioning plate, and the L-shaped pushing rod 82 drives the inclined block 83 to move towards the inner side of the mounting shell 5;

at the moment, the inclined plane block 83 and the inclined plane at the bottom of the push arm 82 act on and push upwards, at the moment, the push arm 82 pushes the push block 81 upwards, the push block pushes the positioning shaft 654 out of the positioning hole 66, at the moment, the two adjusting arms 64 are pushed to move towards two sides under the action of the second elastic part 73, and the adjusting arms 64 drive the two sliding sleeves 62 to move towards two sides along the sliding arms 61, so that the two clamping parts 63 are driven to open, and the probe is released to perform blanking;

thereby realize loosening and unloading convenient to use to the probe automatically.

When the transverse telescopic cylinder 4 is used for clamping and loosening, the stretching stroke of the transverse telescopic cylinder 4 is controlled by PLC (programmable logic controller) or by matching with a photoelectric switch through two times of stretching control.

Third embodiment

Referring to fig. 8, in particular, the probe test clamping device provided in the third embodiment of the present application is different in that the straight rod portion includes an internal thread cylinder 91, a thread rod portion 92, a driving lug 94, a sliding rod 95 and a positioning ring 96, one end of the internal thread cylinder 91 is fixedly connected to the sliding sleeve 62, the thread rod portion 92 is rotatably connected to one end of the inclined rod portion 93, and the thread rod portion 92 is in threaded connection with the internal thread cylinder 91.

The surface of the threaded rod part 92 and one end positioned outside the internal thread cylinder 91 are provided with a driving lug 94, the straight rod part is connected with a sliding rod 95, the positioning ring 96 is sleeved on the surface of the sliding rod 95, and one side of the positioning ring 96 is fixedly connected with the internal thread cylinder 91.

The sliding rod 95 is arranged and matched with the positioning ring 96, so that the straight rod part and the inclined rod part 93 can be axially limited, and the inclined rod part 93 cannot rotate along with screwing of the threaded rod part 92 when the length of the straight rod part is adjusted;

the length of the straight rod part can be adjusted according to the position of the probe, so that the distance value of the clamping mechanism 6 pushed by the transverse telescopic cylinder 4 when the two clamping parts 63 are clamped can be adjusted, the distance value of the probe and the clamping mechanism 6 in a certain range can be adapted, and the clamping device is used;

during adjustment, the threaded rod part 92 is rotated by driving the lug 94 clockwise or anticlockwise, so that the threaded rod part 92 and the inner part of the inner threaded cylinder 91 are adjusted to enter or move out, the length value of the straight rod part is adjusted, and the adjusting operation is simple and convenient.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. A probe test clamping device is characterized by comprising: the device comprises a mounting rack, a vertical telescopic cylinder, a fixing rack and a transverse telescopic cylinder;

2. The probe test clamping device according to claim 1, wherein the vertical telescopic cylinder is fixedly mounted at the top of the mounting frame, the fixing frame is slidably connected inside the mounting frame, one end of an output shaft of the vertical telescopic cylinder is connected with the fixing frame, and the transverse telescopic cylinder is fixedly mounted inside the fixing frame.

3. The device is got to probe test clamp according to claim 1, characterized in that, positioning mechanism includes an installation section of thick bamboo, piston piece, first elastic component and location axle, the installation section of thick bamboo is fixed in the upside of sliding sleeve, the inside slip of installation section of thick bamboo is provided with the piston piece, the bottom of piston piece is provided with the location axle, the one end of location axle runs through the sliding sleeve and extends to the inside of sliding sleeve, first elastic component set up in the inside of installation section of thick bamboo and be located the upside of piston piece.

4. The probe test clamping device as claimed in claim 1, wherein the adjusting arm comprises a straight rod part and an inclined rod part, one end of the straight rod part is fixedly connected with the sliding sleeve, and the inclined rod part is connected to the other end of the straight rod part.

5. The device is got to probe test clamp according to claim 1, characterized in that, elastic mechanism includes flexible arm, fender dish and second elastic component, the both ends of flexible arm respectively with the straight pole portion fixed connection of two regulating arms through fixed, the both ends of flexible arm all fixedly connected with fender dish, the surface of flexible arm just is located the cover and is equipped with the second elastic component between two fender dishes.

6. The device is got to probe test clamp according to claim 1, characterized in that, the installation shell includes casing, first spout and second spout, first spout has all been seted up to the front side symmetry of casing, the one end of fixed axle is through first spout through casing after with sliding sleeve fixed connection, the second spout is seted up in the bottom of casing.

7. The probe test clamping device as claimed in claim 1, wherein an unlocking mechanism is arranged inside the mounting shell, the unlocking mechanism comprises a push block, a push arm, a slope block and an L-shaped push rod, the push block is located inside the positioning hole, the push arm is fixedly connected to the bottom of the push block, one end of the push arm penetrates through the sliding sleeve and extends to the outside of the sliding sleeve, and the bottom of the push arm is provided with a slope.

8. The probe test clamping device as claimed in claim 7, wherein the inclined block is slidably connected to the inside of the mounting housing, one end of the L-shaped pushing rod extends to the inside of the mounting housing through a second sliding slot and then is fixedly connected to the inclined block, and the inclined surface of the pushing arm is attached to the inclined surface of the inclined block.

9. The probe test clamping device as claimed in claim 4, wherein the straight rod portion comprises an internal thread cylinder, a threaded rod portion, a driving lug, a sliding rod and a positioning ring, one end of the internal thread cylinder is fixedly connected with the sliding sleeve, the threaded rod portion is rotatably connected to one end of the inclined rod portion, and the threaded rod portion is in threaded connection with the internal thread cylinder.

10. The probe test clamping device as claimed in claim 9, wherein a driving lug is disposed at one end of the surface of the threaded rod portion and located outside the internal thread cylinder, a sliding rod is connected to the straight rod portion, the positioning ring is sleeved on the surface of the sliding rod, and one side of the positioning ring is fixedly connected with the internal thread cylinder.