CN217278535U - Auxiliary alignment device for probe test device - Google Patents

Abstract

The utility model discloses an auxiliary alignment device for a probe test device, which relates to the technical field of auxiliary alignment devices and comprises a bottom plate and an adjusting unit; the right end of the upper side of the bottom plate is provided with a lifting unit, the upper end of the left side of the lifting unit is provided with a first electric telescopic rod, the left end of the first electric telescopic rod is provided with a square block, the lower side of the square block is provided with a probe, and the information output end of the probe is connected with the information input end of an external controller in a matched manner; the adjusting unit includes spout two, power component, standing groove, electric telescopic handle two and chucking board, spout two has been seted up along the fore-and-aft direction to the upside left end of bottom plate, drives the probe through the lift unit and slides along upper and lower direction, drives the standing groove and slides along the fore-and-aft direction under power component's effect, drives the chucking board through electric telescopic handle two and realizes the gliding effect around realizing to the adjustment effect of the fore-and-aft position of the article of treating to detect is realized, and then the effect of alignment detection is realized.

Description

Auxiliary alignment device for probe test device

Technical Field

The utility model relates to a probe test technical field specifically is a probe testing arrangement is with supplementary aligning device.

Background

The circuit arrangement and the structure of the existing intelligent terminal product are more and more complex, so the requirement on test equipment is higher and higher in the production process, probes are often used when related products are tested, because the to-be-tested points of the products are different in height from the test equipment, probes with different lengths need to be prepared to meet different test requirements, and because the probes are manually assembled in the test process, errors are easy to occur, so the test efficiency is lower;

the auxiliary alignment device for the probe testing device, which is provided by the application publication number CN207301262U in the prior art, comprises a probe and a PCB, and further comprises a connection structure, wherein the probe is electrically connected with the PCB through the connection structure, the connection structure comprises conductive layers and connection layers which are alternately stacked, the bottommost layer of the connection structure is fixedly connected with one end of the probe, and the topmost layer of the connection structure is fixedly connected with the PCB;

although the probe testing device in the prior art well realizes the effect of testing an object, the existing probe testing device cannot realize the effect of quickly aligning a detection position, so that the detection efficiency is influenced.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to overcome current defect, a probe testing arrangement is with supplementary alignment device is provided, it slides along upper and lower direction to drive the probe through the lift unit, it slides along the fore-and-aft direction to drive the standing groove under power component's effect, it realizes the gliding effect around the chucking board is realized to drive through electric telescopic handle two to the realization is treated the adjustment effect of the fore-and-aft position of detecting article, and then the effect of detection is aimed at in the realization, can effectively solve the problem in the background art.

In order to achieve the above object, the utility model provides a following technical scheme: an auxiliary alignment device for a probe test device comprises a bottom plate and an adjusting unit;

a bottom plate: the right end of the upper side of the lifting unit is provided with a lifting unit, the upper end of the left side of the lifting unit is provided with a first electric telescopic rod, the left end of the first electric telescopic rod is provided with a square block, the lower side of the square block is provided with a probe, and the information output end of the probe is connected with the information input end of an external controller in a matched manner;

an adjustment unit: include spout two, power component, standing groove, electric telescopic handle two and chucking board, spout two has been seted up along the fore-and-aft direction to the upside left end of bottom plate, the inside of spout two is provided with power component, the standing groove has been seted up to power component's upside, both sides are provided with electric telescopic handle two respectively around the inside of standing groove, and the inner of two electric telescopic handle two sets up respectively with a chucking board, two chucking boards respectively with sliding connection between the inboard of standing groove.

Drive electric telescopic handle effect of gliding from top to bottom through the lift unit, the probe that slides through electric telescopic handle one and drive the setting of square downside slides along upper and lower direction, drive the slip that the probe realized the horizontal direction through electric telescopic handle, it slides along the fore-and-aft direction to drive the standing groove under power component's effect, it realizes fore-and-aft gliding effect through electric telescopic handle two drive chucking boards, thereby the realization is treated the adjustment effect of the fore-and-aft position of detecting article, and then the effect of alignment detection is realized.

Further, power component includes second slider and threaded shaft, the inside of spout two has second slider along fore-and-aft direction sliding connection, the both ends side respectively with the inside of spout two around sliding connection between the both sides, threaded shaft's outside and the middle part of slider two between threaded connection.

Under the effect of threaded connection between the outer side of the threaded shaft and the middle of the second sliding block, the second sliding block is driven to slide in the front-back direction in the second sliding groove through rotation of the threaded shaft, and the placing groove is driven to slide in the front-back direction through sliding of the second sliding block.

Further, the power assembly further comprises a rotary table, the front end of the threaded shaft is provided with the rotary table, and the rotary table is located on the front side of the bottom plate.

The rotary table is driven to rotate under the action of external force, and the rotation of the rotary table drives the threaded shaft to rotate.

Further, the lifting unit includes backup pad, spout one, slider one and power structure, the upside right-hand member of bottom plate is provided with the backup pad, spout one has been seted up along upper and lower direction in the upper end of backup pad, the inside of spout one has slider one along upper and lower direction sliding connection, the left side upper end of slider one is provided with electric telescopic handle one, the right side of backup pad is provided with power structure, the cooperation is connected between the rear side right-hand member of power structure and slider one.

Under the supporting effect of the supporting plate, the first sliding block is driven to slide in the first sliding groove along the vertical direction through the power structure, and the first electric telescopic rod is driven to slide through the sliding of the first sliding block to achieve the vertical sliding effect.

Further, the power structure includes rack, square groove, axis of rotation and rotating gear, the rear side right-hand member of slider one is provided with the rack along upper and lower direction, the square groove has been seted up on the right side of backup pad, both ends side rotates between the inside left and right sides with the square groove respectively about the axis of rotation and is connected, the outside fixedly connected with rotating gear of axis of rotation, the meshing is connected between rotating gear and the rack.

The rotating gear is driven to rotate through rotation of the rotating shaft, the rack is driven to slide along the up-down direction through rotation of the rotating gear under the meshing connection effect between the rotating gear and the rack, and the first sliding block is driven to slide along the up-down direction inside the first sliding groove through sliding of the rack.

Furthermore, the power structure further comprises an arc-shaped fixing block and a motor, the motor is fixedly connected to the right side of the supporting plate through the arc-shaped fixing block, an output shaft of the motor is fixedly connected with the right end of the rotating shaft, and an input end of the motor is electrically connected with an output end of an external power supply through an external control switch group.

The output shaft of the motor is driven to rotate under the action of the external power supply, and the rotation of the rotating shaft is driven through the rotation of the output shaft of the motor.

Compared with the prior art, the beneficial effects of the utility model are that: this probe testing arrangement is with supplementary aligning device has following benefit:

1. the auxiliary alignment device for the probe testing device is provided with a lifting unit, a rotating gear is driven to rotate through rotation of a rotating shaft, a rack is driven to slide along the up-down direction through rotation of the rotating gear, a first sliding block is driven to slide along the up-down direction in a first sliding groove through sliding of the rack, and a first electric telescopic rod is driven to slide up and down through sliding of the first sliding block;

2. the auxiliary alignment device for the probe testing device is provided with an adjusting unit, under the threaded connection action between the outer side of the threaded shaft and the middle part of the second sliding block, the second sliding block is driven to slide in the front-back direction in the second sliding groove through the rotation of the threaded shaft, and the placing groove is driven to slide in the front-back direction through the sliding of the second sliding block;

3. the lifting unit drives the probe to slide along the up-down direction, the placing groove is driven to slide along the front-back direction under the action of the power assembly, and the electric telescopic rod drives the clamping plate to realize the front-back sliding effect, so that the front-back position of an object to be detected is adjusted, and the detection is aligned.

Drawings

FIG. 1 is a schematic structural view of the present invention;

fig. 2 is a schematic view of the rear view structure of the present invention.

In the figure: the device comprises a base plate 1, a lifting unit 2, a support plate 21, a first sliding groove 22, a first sliding block 23, a rack 24, a square groove 25, a rotating shaft 26, a rotating gear 27, an arc-shaped fixed block 28, a motor 29, a first electric telescopic rod 3, a square block 4, a probe 5, a 6 adjusting unit, a second sliding groove 61, a second sliding block 62, a 63 placing groove, a second electric telescopic rod 64, a clamping plate 65, a threaded shaft 66 and a turntable 67.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts all belong to the protection scope of the present invention.

Referring to fig. 1-2, the present embodiment provides a technical solution: an auxiliary alignment device for a probe test device comprises a base plate 1 and an adjusting unit 6;

bottom plate 1: the right end of the upper side is provided with a lifting unit 2, the upper end of the left side of the lifting unit 2 is provided with an electric telescopic rod I3, the left end of the electric telescopic rod I3 is provided with a square block 4, the lower side of the square block 4 is provided with a probe 5, and the information output end of the probe 5 is connected with the information input end of an external controller in a matching manner;

lifting unit 2 includes backup pad 21, spout one 22, slider one 23 and power structure, and the upside right-hand member of bottom plate 1 is provided with backup pad 21, and spout one 22 has been seted up along upper and lower direction in the upper end of backup pad 21, and the inside of spout one 22 has slider one 23 along upper and lower direction sliding connection, and the left side upper end of slider one 23 is provided with electric telescopic handle one 3, and the right side of backup pad 21 is provided with power structure, and the cooperation is connected between the rear side right-hand member of power structure and slider one 23.

Under the supporting action of the supporting plate 21, the power structure drives the first sliding block 23 to slide in the first sliding groove 22 along the vertical direction, and the sliding of the first sliding block 23 drives the first electric telescopic rod 3 to realize the vertical sliding action.

The power structure includes rack 24, square groove 25, axis of rotation 26 and rotating gear 27, and the rear side right-hand member of slider 23 is provided with rack 24 along upper and lower direction, and square groove 25 has been seted up on the right side of backup pad 21, and both ends side is rotated respectively between the inside left and right sides with square groove 25 about axis of rotation 26 and is connected, and the outside fixedly connected with rotating gear 27 of axis of rotation 26 meshes between rotating gear 27 and the rack 24 and is connected.

The rotation of the rotating gear 27 is driven by the rotation of the rotating shaft 26, the rack 24 is driven to slide in the up-down direction by the rotation of the rotating gear 27 under the meshing connection effect between the rotating gear 27 and the rack 24, and the slide block one 23 is driven to slide in the up-down direction inside the sliding groove one 22 by the sliding of the rack 24.

The power structure further comprises an arc-shaped fixing block 28 and a motor 29, the motor 29 is fixedly connected to the right side of the supporting plate 21 through the arc-shaped fixing block 28, an output shaft of the motor 29 is fixedly connected with the right end of the rotating shaft 26, and an input end of the motor 29 is electrically connected with an output end of an external power supply through an external control switch group.

The output shaft of the motor 29 is rotated by the external power source, and the rotation of the output shaft of the motor 29 drives the rotation of the rotation shaft 26.

The adjusting unit 6: include two 61 of spout, power component, standing groove 63, two 64 of electric telescopic handle and chucking board 65, two 61 of spout have been seted up along the fore-and-aft direction to the upside left end of bottom plate 1, the inside of two 61 of spout is provided with power component, standing groove 63 has been seted up to power component's upside, both sides are provided with two 64 of electric telescopic handle respectively around the inside of standing groove 63, the inner of two 64 of electric telescopic handle sets up respectively with a chucking board 65, sliding connection between two chucking boards 65 respectively and the inboard of standing groove 63.

Drive electric telescopic handle 3 through lifting unit 2 and realize gliding effect from top to bottom, the slip through electric telescopic handle 3 drives the probe 5 that the 4 downside of square set up and slides along upper and lower direction, drive the slip that probe 5 realized the horizontal direction through electric telescopic handle 3, drive standing groove 63 and slide along the fore-and-aft direction under power component's effect, it realizes gliding effect from front to back to drive chucking board 65 through electric telescopic handle two 64, thereby the adjustment effect of the fore-and-aft position of the article of treating to detect is realized, and then the effect of alignment detection is realized.

The power assembly comprises a second sliding block 62 and a threaded shaft 66, the inside of the second sliding groove 61 is connected with the second sliding block 62 in a sliding mode in the front-back direction, the side faces of the front end and the back end of the threaded shaft 66 are connected with the front side and the back side of the inside of the second sliding groove 61 in a sliding mode respectively, and the outer side of the threaded shaft 66 is connected with the middle of the second sliding block 62 in a threaded mode.

Under the effect of the threaded connection between the outer side of the threaded shaft 66 and the middle part of the second sliding block 62, the second sliding block 62 is driven to slide in the front-back direction in the second sliding groove 61 through the rotation of the threaded shaft 66, and the placing groove 63 is driven to slide in the front-back direction through the sliding of the second sliding block 62.

The power assembly further comprises a rotating disc 67, the front end of the threaded shaft 66 is provided with the rotating disc 67, and the rotating disc 67 is located on the front side of the bottom plate 1.

The rotating disc 67 is driven to rotate by the external force, and the rotation of the rotating disc 67 drives the rotation of the threaded shaft 66.

The utility model provides a pair of probe testing arrangement is with supplementary aligning device's theory of operation as follows:

under the supporting action of the supporting plate 21, the output shaft of the motor 29 is driven to rotate under the action of an external power supply, the rotation of the output shaft of the motor 29 drives the rotation of the rotating shaft 26, the rotation of the rotating gear 27 is driven by the rotation of the rotating gear 27, under the meshing connection action between the rotating gear 27 and the rack 24, the rack 24 is driven to slide in the vertical direction by the rotation of the rotating gear 27, the sliding block one 23 is driven to slide in the vertical direction in the sliding groove one 22 by the sliding of the rack 24, the electric telescopic rod one 3 is driven to slide in the vertical direction by the sliding of the sliding block one 23, the probe 5 arranged on the lower side of the square block 4 is driven to slide in the vertical direction by the sliding of the electric telescopic rod one 3, the probe 5 is driven to slide in the horizontal direction by the electric telescopic rod one 3, the rotating disc 67 is driven to rotate under the action of the external power supply, and the rotating screw shaft 66 is driven to rotate by the rotating disc 67, under the threaded connection effect between the outside of threaded shaft 66 and the middle part of the second slider 62, the second slider 62 is driven to slide along the front-back direction in the second sliding groove 61 through the rotation of the threaded shaft 66, the placing groove 63 is driven to slide along the front-back direction through the sliding of the second slider 62, and the clamping plate 65 is driven to slide along the front-back direction through the second electric telescopic rod 64, so that the front-back position of an object to be detected is adjusted, and the alignment detection effect is realized.

It should be noted that the motor 29 disclosed in the above embodiments is a stepping motor, and the control switch set is used to control the operation of the motor 29 by a method commonly used in the art.

The above only is the embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structures or equivalent processes of the present invention are used in the specification and the attached drawings, or directly or indirectly applied to other related technical fields, and the same principle is included in the protection scope of the present invention.

Claims (6)

1. The utility model provides a probe testing arrangement is with supplementary aligning device which characterized in that: comprises a bottom plate (1) and an adjusting unit (6);

base plate (1): the right end of the upper side of the device is provided with a lifting unit (2), the upper end of the left side of the lifting unit (2) is provided with a first electric telescopic rod (3), the left end of the first electric telescopic rod (3) is provided with a square block (4), the lower side of the square block (4) is provided with a probe (5), and the information output end of the probe (5) is connected with the information input end of an external controller in a matching manner;

adjusting means (6): include two (61) of spout, power component, standing groove (63), electric telescopic handle two (64) and chucking board (65), two (61) of spout have been seted up along the fore-and-aft direction to the upside left end of bottom plate (1), the inside of two (61) of spout is provided with power component, standing groove (63) have been seted up to power component's upside, both sides are provided with two (64) of electric telescopic handle respectively around the inside of standing groove (63), the inner of two (64) of electric telescopic handle set up respectively with one chucking board (65), two chucking boards (65) respectively with standing groove (63) inboard between sliding connection.

2. The auxiliary alignment device for a probe test apparatus according to claim 1, wherein: the power assembly comprises a second sliding block (62) and a threaded shaft (66), the inside of the second sliding groove (61) is connected with the second sliding block (62) in a sliding mode in the front-back direction, the side faces of the front end and the back end of the threaded shaft (66) are connected with the front side and the back side of the inside of the second sliding groove (61) in a sliding mode respectively, and the outer side of the threaded shaft (66) is connected with the middle of the second sliding block (62) in a threaded mode.

3. The auxiliary alignment device for a probe test apparatus according to claim 2, wherein: the power assembly further comprises a turntable (67), the front end of the threaded shaft (66) is provided with the turntable (67), and the turntable (67) is located on the front side of the bottom plate (1).

4. The auxiliary alignment device for a probe test apparatus according to claim 1, wherein: lifting unit (2) include backup pad (21), spout (22), slider (23) and power structure, the upside right-hand member of bottom plate (1) is provided with backup pad (21), spout (22) have been seted up along upper and lower direction in the upper end of backup pad (21), the inside of spout (22) has slider (23) along upper and lower direction sliding connection, the left side upper end of slider (23) is provided with electric telescopic handle (3), the right side of backup pad (21) is provided with the power structure, the cooperation is connected between the rear side right-hand member of power structure and slider (23).

5. The auxiliary alignment device for a probe test apparatus according to claim 4, wherein: the power structure includes rack (24), square groove (25), axis of rotation (26) and rotating gear (27), the rear side right-hand member of slider (23) is provided with rack (24) along upper and lower direction, square groove (25) have been seted up on the right side of backup pad (21), both ends side rotates between the inside left and right sides with square groove (25) respectively about axis of rotation (26) and is connected, the outside fixedly connected with rotating gear (27) of axis of rotation (26), the meshing is connected between rotating gear (27) and rack (24).

6. The auxiliary alignment device for a probe test apparatus according to claim 5, wherein: the power structure further comprises an arc-shaped fixing block (28) and a motor (29), the motor (29) is fixedly connected to the right side of the supporting plate (21) through the arc-shaped fixing block (28), an output shaft of the motor (29) is fixedly connected with the right end of the rotating shaft (26), and the input end of the motor (29) is electrically connected with the output end of an external power supply through an external control switch group.

Images