CN114509252A

CN114509252A - Multifunctional computer motherboard connector detection device

Info

Publication number: CN114509252A
Application number: CN202210051572.7A
Authority: CN
Inventors: 苗华祥; 彭卫华
Original assignee: Shenzhen Guoshuohong Electronics Co ltd
Current assignee: Shenzhen Guoshuohong Electronics Co ltd
Priority date: 2022-01-17
Filing date: 2022-01-17
Publication date: 2022-05-17

Abstract

The invention relates to the field of connector detection, in particular to a multifunctional computer motherboard connector detection device. The technical problem is as follows: connector pin end up phenomenon can appear in artifical the putting, and detection device can't detect out the position of connector pin when detecting to needle up connector, leads to appearing the false retrieval phenomenon. The technical scheme is as follows: a multifunctional computer motherboard connector detection device comprises a bottom plate, pin detection components and the like; the stitch detection component is arranged on the right part of the upper side of the bottom plate. Realized during the use that automatic stitch to the connector detects to automatically, select the connector that the stitch was put up automatically, the follow-up secondary detection of being convenient for avoids appearing the false retrieval phenomenon, prevents simultaneously in the screening process that the connector from appearing the phenomenon of perk down because of the atress is uneven, simultaneously, carries out the shockproof detection to the connector under multiple vibration range and vibration frequency automatically, and resets to the connector after detecting automatically, avoids influencing follow-up detection operation.

Description

Multifunctional computer motherboard connector detection device

Technical Field

The invention relates to the field of connector detection, in particular to a multifunctional computer motherboard connector detection device.

Background

Electrical connectors, also commonly referred to as circuit connectors, bridge two conductors in a circuit so that current or signals can flow from one conductor to the other. An electrical connector is an electromechanical system that provides a separable interface for connecting two sub-electronic systems, simply, components for completing an electrical connection between a circuit or an electronic machine, referred to as a connector, i.e., a bridge between the two.

Among the prior art, when preparing the packing after one of them connector for computer mainboard production is accomplished, need earlier detect the process, detect the process including the stitch detects, antidetonation detects and plug detects etc, and current device can only carry out a function detection to the connector, make and need artifically shift the connector to next function detection device after detecting the completion on, prolong the detection process greatly, therefore, the efficiency is low, and simultaneously, need artifically put the connector before detecting in the material dish, and guarantee connector pin end down, and the phenomenon that connector pin end up can appear in the manual work putting unavoidably, when detection device detects to pin-up connector, can't detect out the position of connector pin, lead to appearing the false retrieval phenomenon.

Therefore, it is necessary to design a detecting device for a connector of a motherboard of a multifunctional computer.

Disclosure of Invention

The invention provides a multifunctional computer mainboard connector detection device, aiming at overcoming the defects that the phenomenon that the pin end of a connector is upward can occur when the connector is manually placed, and the position of the pin of the connector cannot be detected when a detection device detects the connector with the pin upward, so that the phenomenon of false detection can occur.

The technical scheme of the invention is as follows: a multifunctional computer motherboard connector detection device comprises a bottom plate, a first support frame, a side plate, a top plate, a pin detection assembly, an anti-falling assembly, an anti-seismic detection assembly, an adjusting assembly, a reset assembly and a transfer assembly; two first supporting frames are fixedly connected to the lower side of the bottom plate; a side plate is fixedly connected with the rear part of the upper side of the bottom plate; the upper side of the side plate is fixedly connected with a top plate; a pin detection assembly for detecting the pin of the connector is arranged at the right part of the upper side of the bottom plate; the anti-falling component for preventing the falling-off phenomenon when the connector with upward pins is screened out is arranged at the right part of the upper side of the bottom plate, and the anti-falling component is positioned at the right side of the pin detection component; an anti-seismic detection assembly for detecting the anti-seismic property of the connector is arranged in the middle of the upper side of the bottom plate; an adjusting component for adjusting the vibration frequency and the vibration amplitude is arranged in the middle of the upper side of the bottom plate, and the adjusting component is positioned below the anti-seismic detection component; the middle part of the side plate is provided with a reset assembly for resetting the connector after the earthquake resistance detection is finished; the front part of the lower side of the top plate is provided with a transfer component for transferring the connector.

As a further preferable scheme, the pin detection assembly comprises a pin detector, a first diversion cabin body, a connecting block, a limiting groove block, a connecting frame, a second supporting frame, a screw rod, a first motor, a sliding block, a first linkage plate, a first pushing block, a first limiting rod, a first spring, a second linkage plate and a second pushing block; a pin detector is arranged at the right part of the upper side of the bottom plate; two first diversion capsule bodies penetrate through the right part of the upper side of the bottom plate and are respectively positioned on the front side and the rear side of the pin detector; the right part of the upper side of the bottom plate is fixedly connected with a connecting frame, and the connecting frame is positioned in front of the first diversion cabin body; the upper side of the connecting frame is fixedly connected with a second supporting frame; the second support frame is rotatably connected with a screw rod; a first motor is arranged on the front side of the second support frame; the output end of the first motor is fixedly connected with the screw rod; the second support frame is connected with a sliding block in a sliding manner; a first linkage plate is fixedly connected to the lower side of the sliding block; a first pushing block is fixedly connected to the middle of the lower side of the first linkage plate; two first limiting rods are fixedly connected to the rear part of the upper side of the first linkage plate; the upper ends of the two first limiting rods are fixedly connected with a first spring; the two first limiting rods are connected with a second linkage plate in a sliding manner; the second linkage plate is fixedly connected with the two first springs; a second pushing block is fixedly connected to the lower side of the second linkage plate; the second push block is connected with the first linkage plate in a sliding manner; the first linkage plate is connected with the anti-falling component.

As a further preferable scheme, the lower part of the rear side of the second pushing block is an inclined plane.

As a further preferable scheme, the anti-drop assembly comprises a third support frame, a first L-shaped plate, a second spring, an anti-drop plate, a first linkage block and a deflector rod; a third support frame is fixedly connected to the right part of the upper side of the bottom plate; the upper side of the third support frame is connected with a first L-shaped plate in a sliding manner; two second springs are fixedly connected to the left part of the upper side of the third support frame; the right ends of the two second springs are fixedly connected with the first L-shaped plate; the left part of the upper side of the first L-shaped plate is fixedly connected with an anti-drop plate; a first linkage block is fixedly connected to the middle part of the right side of the first linkage plate; a deflector rod is inserted on the right side of the first linkage block; the deflector rod is contacted with the anti-drop plate.

As a further preferable scheme, the front side surface of the anti-dropping plate is a slope.

As a further preferable scheme, the transfer assembly comprises an electric slide rail, an electric slide block, a second L-shaped plate, a third telescopic cylinder and an electric clamp; the front part of the lower side of the top plate is fixedly connected with an electric slide rail; the electric sliding rail is connected with an electric sliding block in a sliding way; a second L-shaped plate is fixedly connected to the lower side of the electric sliding block; a third telescopic cylinder is fixedly connected to the front side of the second L-shaped plate; the telescopic end of the third telescopic cylinder is fixedly connected with an electric clamp.

As a further preferable scheme, the anti-seismic detection assembly comprises a second limiting rod, a third spring, a third linkage plate, a first limiting block, a first detection socket, a fixing bolt and a camera; two second limiting rods are fixedly connected to the middle of the upper side of the bottom plate; the two second limiting rods are connected with a third linkage plate in a sliding manner; a third spring is sleeved on each of the two second limiting rods; one end of the third spring is fixedly connected with the third linkage plate, and the other end of the third spring is fixedly connected with the bottom plate; the front part of the upper side of the third linkage plate is fixedly connected with a first limiting block; a first detection socket is inserted on the first limiting block; two fixing bolts are connected to the lower side of the first detection socket in a threaded manner; two fixing bolts are in threaded connection with the first limiting block.

As a further preferred scheme, the adjusting component comprises a first telescopic cylinder, a linkage frame, a transmission rod, a cam, a transmission wheel and a second motor; two first telescopic cylinders are arranged in the middle of the upper side of the bottom plate; the telescopic ends of the two first telescopic cylinders are fixedly connected with a linkage frame; the front side and the rear side of the linkage frame are both rotatably connected with a transmission rod; a cam is fixedly connected to the middle parts of the two transmission rods; the right ends of the two transmission rods are fixedly connected with a transmission wheel; a belt is wound between the two driving wheels; a second motor is arranged at the right part of the rear side of the linkage frame; the output end of the second motor is fixedly connected with a transmission rod positioned behind the second motor.

As a further preferable scheme, the reset assembly comprises a second telescopic cylinder, a second linkage block, a push plate and a fourth spring; a second telescopic cylinder is inserted in the middle of the side plate; the telescopic end of the second telescopic cylinder is fixedly connected with a second linkage block; a push plate is connected to the second linkage block in a sliding manner; two fourth springs are fixedly connected to the rear part of the lower side of the push plate; the lower ends of the two fourth springs are fixedly connected with the second linkage block.

As a further preferable scheme, the device further comprises a pulling and inserting detection assembly, the pulling and inserting detection assembly is mounted at the left part of the upper side of the bottom plate, and comprises a fourth support frame, a third limiting rod, a fifth spring, a fourth linkage plate, a limiting frame, a second detection socket, a fifth support frame, a sliding plate, a sixth spring, a second limiting block, a laser emitter, a light source sensor, a third L-shaped plate and a second diversion cabin body; a fourth support frame is fixedly connected to the left part of the upper side of the bottom plate; two third limiting rods are fixedly connected to the middle of the upper side of the fourth supporting frame; a fourth linkage plate is connected to the two third limiting rods in a sliding manner; the lower side of the fourth linkage plate is in contact with the fourth support frame; the upper ends of the two third limiting rods are fixedly connected with a fifth spring; the lower ends of the two fifth springs are fixedly connected with the fourth linkage plate; the middle part of the upper side of the fourth linkage plate is fixedly connected with a limit frame; a second detection socket is inserted into the inner side of the limiting frame; the lower side of the second detection socket is contacted with the fourth linkage plate; a fifth support frame is fixedly connected to the front part of the upper side and the rear part of the upper side of the fourth linkage plate; a sliding plate is connected to each of the two fifth supporting frames in a sliding manner; two opposite sides of the two sliding plates are fixedly connected with a second limiting block; the two second limiting blocks are inserted into the second detection socket; a sixth spring is fixedly connected to the back sides of the two sliding plates; the back ends of the two sixth springs are fixedly connected with the two fifth supporting frames respectively; the front part of the upper side of the fourth linkage plate is provided with a laser emitter; a light source sensor is arranged at the front part of the upper side of the fourth support frame; a third L-shaped plate is fixedly connected to the front part of the upper side and the rear part of the upper side of the fourth supporting frame; three second diversion capsule bodies penetrate through the middle part of the left side of the bottom plate, and every two adjacent second diversion capsule bodies are in contact.

The invention has the following advantages: realized automatic stitch to the connector during the use and detected, and select the connector that the stitch was put up automatically, be convenient for follow-up retest, the phenomenon is avoided appearing the false retrieval, prevent simultaneously in the screening process that the connector from appearing the perk phenomenon because of the atress is uneven, and then the connector obscission phenomenon is avoided appearing, simultaneously, automatic to the connector carry out the shock-proof detection under multiple vibration range and vibration frequency, and reset the connector after detecting automatically, avoid influencing follow-up detection operation, still realized inserting the connector again and detect to the second and detect the socket in the power of plugging in after fixing a position the level state automatically, avoided inserting the problem that the testing result is bigger because of connecting crooked the inserting and leading to simultaneously, can detect the connector of different grade type, improve the commonality.

Drawings

FIG. 1 is a schematic diagram of a first structure of a detecting device for a connector of a multi-function computer motherboard according to the present invention;

FIG. 2 is a schematic diagram of a second structure of the detecting device for the connector of a multi-function computer motherboard according to the present invention;

FIG. 3 is a front view of the detecting device for the connector of the multi-function computer motherboard according to the present invention;

FIG. 4 is a schematic view of the construction of a stitch detection assembly according to the present invention;

FIG. 5 is a schematic view of a portion of the pin detection assembly of the present invention;

FIG. 6 is a schematic view of the anti-separation assembly of the present invention;

FIG. 7 is a schematic structural view of the seismic detection assembly of the present invention;

FIG. 8 is a schematic structural view of the adjustment assembly and the reset assembly of the present invention;

FIG. 9 is a schematic structural view of a transfer unit of the present invention;

FIG. 10 is a schematic view of the insertion/removal detection assembly of the present invention;

FIG. 11 is a schematic view of a first partial structure of the insertion and extraction detection assembly of the present invention;

fig. 12 is a schematic view of a second partial structure of the plugging detection assembly of the present invention.

Wherein: 1-a bottom plate, 2-a first support frame, 3-a side plate, 4-a top plate, 201-a pin detector, 202-a first diversion cabin body, 203-a connecting block, 204-a limiting groove block, 205-a connecting frame, 206-a second support frame, 207-a screw rod, 208-a first motor, 209-a sliding block, 2010-a first linkage plate, 2011-a first push block, 2012-a first limiting rod, 2013-a first spring, 2014-a second linkage plate, 2015-a second push block, 301-a third support frame, 302-a first L-shaped plate, 303-a second spring, 304-an anti-dropping plate, 305-a first linkage block, 306-a driving rod, 401-a second limiting rod, 402-a third spring, 403-a third linkage plate, 404-a first limiting block, 405-a first detection socket, 406-a fixing bolt, 407-a camera, 501-a first telescopic cylinder, 502-a linkage frame, 503-a transmission rod, 504-a cam, 505-a transmission wheel, 506-a second motor, 601-a second telescopic cylinder, 602-a second linkage block, 603-a push plate, 604-a fourth spring, 701-an electric sliding rail, 702-an electric sliding block, 703-a second L-shaped plate, 704-a third telescopic cylinder, 705-an electric clamp, 801-a fourth support frame, 802-a third limit rod, 803-a fifth spring, 804-a fourth linkage plate, 805-a limit frame, 806-a second detection socket, 807-a fifth support frame, 808-a sliding plate, 809-a sixth spring and 8010-a second limit block, 8011-laser emitter, 8012-light source sensor, 8013-third L-shaped plate, 8014-second guide cabin.

Detailed Description

The following further describes the technical solution with reference to specific embodiments, and it should be noted that: the words upper, lower, left, right, and the like used herein to indicate orientation are merely for the location of the illustrated structure in the corresponding figures. The serial numbers of the parts are themselves numbered herein, for example: first, second, etc. are used solely to distinguish one from another as to objects described herein, and do not have any sequential or technical meaning. The application states that: the connection and coupling, unless otherwise indicated, include both direct and indirect connections (couplings).

Example 1

A multifunctional computer motherboard connector detection device is shown in figures 1-6 and 9 and comprises a bottom plate 1, a first support frame 2, a side plate 3, a top plate 4, a pin detection assembly, an anti-drop assembly, an anti-seismic detection assembly, an adjusting assembly, a reset assembly and a transfer assembly; two first supporting frames 2 are connected with the lower side of the bottom plate 1 through bolts; the rear part of the upper side of the bottom plate 1 is connected with a side plate 3 through a bolt; the upper side of the side plate 3 is connected with a top plate 4 through bolts; a stitch detection component is arranged on the right part of the upper side of the bottom plate 1; the anti-falling component is arranged on the right part of the upper side of the bottom plate 1 and is positioned on the right side of the stitch detection component; the middle part of the upper side of the bottom plate 1 is provided with an anti-seismic detection assembly; an adjusting assembly is arranged in the middle of the upper side of the bottom plate 1 and is positioned below the anti-seismic detection assembly; the middle part of the side plate 3 is provided with a reset component; the front part of the lower side of the top plate 4 is provided with a transfer component.

The pin detection assembly comprises a pin detector 201, a first diversion capsule body 202, a connecting block 203, a limiting groove block 204, a connecting frame 205, a second supporting frame 206, a screw rod 207, a first motor 208, a sliding block 209, a first linkage plate 2010, a first push block 2011, a first limiting rod 2012, a first spring 2013, a second linkage plate 2014 and a second push block 2015; a pin detector 201 is arranged at the right part of the upper side of the bottom plate 1; two first diversion capsule bodies 202 penetrate through the right part of the upper side of the base plate 1, and the two first diversion capsule bodies 202 are respectively positioned on the front side and the rear side of the pin detector 201; the right part of the upper side of the bottom plate 1 is connected with a connecting frame 205 through bolts, and the connecting frame 205 is positioned in front of the first diversion chamber body 202; the upper side of the connecting frame 205 is connected with a second supporting frame 206 through bolts; the second supporting frame 206 is rotatably connected with a screw rod 207; a first motor 208 is arranged on the front side of the second support frame 206; the output end of the first motor 208 is fixedly connected with the screw rod 207; a sliding block 209 is connected on the second support frame 206 in a sliding way; a first linkage plate 2010 is connected to the lower side of the sliding block 209 through bolts; a first push block 2011 is connected to the middle of the lower side of the first linkage plate 2010 through bolts; two first limiting rods 2012 are welded at the rear part of the upper side of the first linkage plate 2010; a first spring 2013 is welded at the upper ends of the two first limiting rods 2012; the two first limiting rods 2012 are slidably connected with a second linkage plate 2014; the second linkage plate 2014 is welded with the two first springs 2013; a second pushing block 2015 is welded to the lower side of the second linkage plate 2014; the second push block 2015 is slidably connected with the first linkage plate 2010; the first linkage plate 2010 is connected with the anti-falling assembly; the lower part of the back side of the second push block 2015 is an inclined plane.

The anti-drop component comprises a third support frame 301, a first L-shaped plate 302, a second spring 303, an anti-drop plate 304, a first linkage block 305 and a shifting lever 306; the right part of the upper side of the bottom plate 1 is connected with a third support frame 301 through a bolt; a first L-shaped plate 302 is connected to the upper side of the third supporting frame 301 in a sliding manner; two second springs 303 are welded on the left part of the upper side of the third support frame 301; the right ends of the two second springs 303 are welded with the first L-shaped plate 302; the left part of the upper side of the first L-shaped plate 302 is connected with an anti-drop plate 304 through a bolt; a first linkage block 305 is welded in the middle of the right side of the first linkage plate 2010; a shift lever 306 is inserted at the right side of the first linkage block 305; the deflector rod 306 is in contact with the anti-drop plate 304; the front side of the anti-drop plate 304 is an inclined surface.

The transfer component comprises an electric sliding rail 701, an electric sliding block 702, a second L-shaped plate 703, a third telescopic cylinder 704 and an electric clamp 705; an electric slide rail 701 is fixedly connected to the front part of the lower side of the top plate 4; an electric sliding block 702 is connected on the electric sliding rail 701 in a sliding manner; a second L-shaped plate 703 is fixedly connected to the lower side of the electric slider 702; a third telescopic cylinder 704 is connected to the front side of the second L-shaped plate 703 through a bolt; the telescopic end of the third telescopic cylinder 704 is fixedly connected with an electric clamp 705.

The anti-seismic detection assembly comprises a second limiting rod 401, a third spring 402, a third linkage plate 403, a first limiting block 404, a first detection socket 405, a fixing bolt 406 and a camera 407; two second limiting rods 401 are welded in the middle of the upper side of the bottom plate 1; a third coupling plate 403 is slidably connected to the two second limiting rods 401; a third spring 402 is sleeved on each of the two second limiting rods 401; one end of the third spring 402 is welded to the third coupling plate 403, and the other end of the third spring 402 is welded to the base plate 1; a first limit block 404 is connected to the front part of the upper side of the third linkage plate 403 through a bolt; a first detection socket 405 is inserted into the first limiting block 404; two fixing bolts 406 are connected to the lower side of the first detection socket 405 through threads; both the fixing bolts 406 are threadedly connected with the first stopper 404.

When the device is ready to work, the first support frame 2 is arranged on a workbench through bolts, a power supply is switched on, five external material bags are respectively sleeved on the three second guide cabin bodies 8014 and the two first guide cabin bodies 202, the power supply is switched on, a material tray provided with a connector is manually placed at the right side of the device, the connector is in a cuboid shape, the longer side of the connector is parallel to the edge of the right part of the upper side of the bottom plate 1, then the third telescopic cylinder 704 drives the electric clamp 705 to move downwards, the electric clamp 705 moves to the outer side of the connector, then the electric clamp 705 clamps the connector tightly, at the moment, the electric clamp 705 respectively contacts the middle part of the left side and the middle part of the right side of the connector, a cavity is formed between the upper side of the connector and the middle part of the electric clamp 705, then the third telescopic cylinder 704 drives the electric clamp to move upwards, the electric clamp 705 drives the connector to move upwards, then the electric slide block 702 slides leftwards on the electric slide rail 705, the electric sliding block 702 drives the second L-shaped plate 703 to move leftwards, the second L-shaped plate 703 drives the third telescopic cylinder 704 to move leftwards, the third telescopic cylinder 704 drives the electric clamp 705 to move leftwards, so that the electric clamp 705 drives the connector to move leftwards to be right above the pin detector 201, then the electric clamp 705 drives the connector to move downwards to contact with the upper side surface of the pin detector 201, the pin detector 201 detects the pin position of the connector, then the electric clamp 705 drives the connector to move upwards, so that the lower side of the connector is higher than the bottom of the groove of the limiting groove block 204, if the pin detector 201 detects that the pin position of the connector deviates, the first motor 208 is started, the first motor 208 drives the sliding block 207 to rotate, the sliding block 207 drives the sliding block 209 to slide backwards on the second supporting frame 206, the sliding block 209 drives the first linkage plate 2010 to move backwards, the first linkage plate 2010 drives the second pushing block 2015 to move backwards, the inclined surface of the second pushing block 2015 is contacted with the edge of the upper side of the connector, the first linkage plate 2010 continues to drive the second pushing block 2015 to move backwards, the connector limits the second pushing block 2015, the second pushing block 2015 drives the second linkage plate 2014 to slide upwards on the two first limiting rods 2012 and compress the two first springs 2013, then the first linkage plate 2010 continues to pass backwards through a cavity formed by the upper side of the connector and the electric clamp 705, when the second pushing block 2015 moves to the upper part of the rear side surface of the connector, the connector stops limiting the second pushing block 2015, so that the two first springs 2013 simultaneously drive the second linkage plate 2014 to move downwards, the second linkage plate 2014 drives the second pushing block 2015 to move downwards, the front side surface of the second pushing block 2015 is contacted with the rear side surface of the connector, meanwhile, the first linkage plate 2010 drives the first linkage block 305 to move backwards, and the first linkage block 305 drives the shifting rod 306 to move backwards, the driving lever 306 pushes the anti-falling plate 304 to move leftwards, the anti-falling plate 304 drives the first L-shaped plate 302 to slide leftwards on the third support frame 301, and two second springs 303 are compressed, so that the anti-falling plate 304 moves to the lower side of the connector, then the electric clamp 705 reduces the clamping force on the connector, the first motor 208 drives the screw rod 207 to rotate reversely, so that the first linkage plate 2010 drives the second push block 2015 to move forwards, so that the second push block 2015 pushes the connector to the limiting groove block 204 in front, because the upper part of the rear side of the connector is pushed, the front side of the connector is prone to tilt downwards, so that the second push block 2015 pushes the connector to the limiting groove block 204 in front, at the moment, the anti-falling plate 304 is still located at the lower side of the connector, and further the phenomenon that the connector tilts downwards due to uneven stress is avoided, then the connector is prevented from falling off, then the second push block 2015 continuously pushes the connector to move leftwards, so that the connector falls into the first diversion cabin body 202 in the front through the limit groove block 204 in the front, then the connector flows into the external material bag from the first diversion cabin body 202 in the front, if the pin detector 201 cannot detect the position of the pin of the connector, the pin of the connector is upward, so as to place the connector with errors, then the first linkage plate 2010 drives the first push block 2011 to move backwards to contact the front side surface of the connector, then the first push block 2011 continuously moves backwards to push the connector to move backwards to the limit groove block 204 in the rear, then the first diversion cabin body 202 in the rear falls into the first diversion cabin body 202 in the rear, then the first diversion cabin body 202 in the rear falls into the material bag to be tightened, and then the connector with errors is detected again, the phenomenon of false detection is avoided appearing, first motor 208 drives lead screw 207 and reverses, make first linkage board 2010 move forward and return to the normal position, close first motor 208, if it is qualified to examine stitch detector 201 and measure connector pin position, then electronic anchor clamps 705 drives connector upward movement and keeps away from stitch detector 201, then electronic anchor clamps 705 drives the connector and moves to antidetonation detection subassembly top left, realized automatic stitch to the connector when using and detected, and select the connector that the stitch was put up voluntarily, be convenient for follow-up retest once more, the phenomenon of false detection is avoided appearing, prevent simultaneously in the screening process that the connector from appearing warping down because of the atress is uneven, and then avoid appearing the connector obscission phenomenon.

Example 2

On the basis of the embodiment 1, as shown in fig. 1 and fig. 7-9, the adjusting assembly comprises a first telescopic cylinder 501, a linkage frame 502, a transmission rod 503, a cam 504, a transmission wheel 505 and a second motor 506; two first telescopic cylinders 501 are arranged in the middle of the upper side of the bottom plate 1; the telescopic ends of the two first telescopic cylinders 501 are fixedly connected with a linkage frame 502; the front side and the rear side of the linkage frame 502 are both rotatably connected with a transmission rod 503; the middle parts of the two transmission rods 503 are fixedly connected with a cam 504; a driving wheel 505 is fixedly connected to the right ends of the two driving rods 503; a belt is wound between the two driving wheels 505; a second motor 506 is arranged at the right part of the rear side of the linkage frame 502; the output end of the second motor 506 is fixedly connected with the transmission rod 503 positioned at the rear.

The reset assembly comprises a second telescopic cylinder 601, a second linkage block 602, a push plate 603 and a fourth spring 604; a second telescopic cylinder 601 is inserted in the middle of the side plate 3; the telescopic end of the second telescopic cylinder 601 is fixedly connected with a second linkage block 602; a push plate 603 is connected on the second linkage block 602 in a sliding manner; two fourth springs 604 are welded at the rear part of the lower side of the push plate 603; the lower ends of the two fourth springs 604 are welded to the second linkage block 602.

When the electric clamp 705 drives the connector to move leftwards to a position right above the first detection socket 405, the electric clamp 705 drives the connector to move downwards, the connector is inserted into the first detection socket 405, then the electric clamp 705 stops fixing the connector, then the third telescopic cylinder 704 drives the electric clamp 705 to move upwards to a home position, the second motor 506 is started, the second motor 506 drives the driving rod 503 positioned at the rear to rotate, the driving rod 503 positioned at the rear drives the driving wheel 505 positioned at the rear to move, the driving wheel 505 positioned at the rear drives the driving wheel 505 positioned at the front to rotate through a belt, the driving wheel 505 positioned at the front drives the driving rod 503 positioned at the front to rotate, the two driving rods 503 drive the two cams 504 to rotate respectively, and the cams 504 contact the third linkage plate 403 when rotating, so that the cams 504 push the third linkage plate 403 to slide upwards on the two second limiting rods 401, and the two third springs 402 are stretched, when the cam 504 rotates to the home position, the two third springs 402 simultaneously drive the third link plate 403 to move downwards to the home position, so that the third link plate 403 vibrates, the third link plate 403 drives the first limit block 404 to vibrate, the first limit block 404 drives the first detection socket 405 to vibrate, the first detection socket 405 drives the connector to vibrate, the vibration frequency of the first detection socket 405 and the connector is controlled by adjusting the rotating speed of the output shaft of the second motor 506, then the two first telescopic cylinders 501 simultaneously drive the link frame 502 to move downwards, the link frame 502 drives the two transmission rods 503 to move downwards, the two transmission rods 503 respectively drive the two cams 504 to move downwards, thereby increasing the distance from the cam 504 to the third link plate 403, further controlling the distance of the up-and-down movement of the third link plate 403, and further adjusting the vibration amplitude of the first detection socket 405 and the connector, therefore, the connector is subjected to shockproof detection under various vibration amplitudes and vibration frequencies, the second motor 506 is turned off, then the camera 407 detects the sliding distance of the connector on the first detection socket 405, and further the shock resistance of the connector is detected, then the two fixing bolts 406 are screwed out, then the first detection socket 405 is pulled out backwards, then the first detection socket 405 is replaced, and further various types of connectors can be detected, so that the universality is greatly improved, the positions of the detected connectors are different due to different sliding distances of the connectors on the first detection socket 405, the electric clamp 705 cannot be clamped at the designated position of the connector, and further the subsequent detection process is influenced, at the moment, the second telescopic cylinder 601 drives the second linkage block 602 to move forwards, the second linkage block 602 drives the push plate 603 to move forwards, and the push plate 603 moves to the upper part of the connector, then the third telescopic cylinder 704 drives the electric clamp 705 to move downwards, so that the electric clamp 705 contacts the upper side of the push plate 603, then the electric clamp 705 pushes the push plate 603 to move downwards, the push plate 603 slides downwards on the second linkage block 602 and compresses the two fourth springs 604, the push plate 603 contacts the connector downwards, then the push plate 603 pushes the connector to move downwards, so that the connector is inserted into the first detection socket 405, so that the connector is accurately positioned, then the electric clamp 705 moves upwards to be far away from the push plate 603, the two fourth springs 604 drive the push plate 603 to move upwards to return to the original position at the same time, the second telescopic cylinder 601 drives the second linkage block 602 to move leftwards to return to the original position, then the electric clamp 705 moves downwards to clamp the connector, then the electric clamp 705 drives the connector to move upwards to be far away from the first detection socket 405, so that the connector can be automatically subjected to shockproof detection under various vibration amplitudes and vibration frequencies during use, and can detect the connector of different grade type, improve general usefulness, simultaneously, reset the connector after detecting automatically, avoid influencing follow-up detection operation.

Example 3

On the basis of embodiment 2, as shown in fig. 1 and fig. 9 to 12, the air conditioner further includes a plugging detection assembly, the plugging detection assembly is installed at the left portion of the upper side of the bottom plate 1, and the plugging detection assembly includes a fourth supporting frame 801, a third limiting rod 802, a fifth spring 803, a fourth linkage plate 804, a limiting frame 805, a second detection socket 806, a fifth supporting frame 807, a sliding plate 808, a sixth spring 809, a second limiting block 8010, a laser emitter 8011, a light source sensor 8012, a third L-shaped plate 8013 and a second diversion chamber 8014; the left part of the upper side of the bottom plate 1 is connected with a fourth supporting frame 801 through a bolt; two third limiting rods 802 are welded in the middle of the upper side of the fourth supporting frame 801; a fourth linkage plate 804 is connected to the two third limiting rods 802 in a sliding manner; the lower side of the fourth linkage plate 804 contacts the fourth supporting frame 801; the upper ends of the two third limiting rods 802 are welded with a fifth spring 803; the lower ends of the two fifth springs 803 are welded with the fourth linkage plate 804; the middle of the upper side of the fourth linkage plate 804 is welded with a limit frame 805; a second detection socket 806 is inserted into the inner side of the limit frame 805; the lower side of the second sensing socket 806 contacts the fourth linkage plate 804; a fifth support frame 807 is bolted to both the front upper side and the rear upper side of the fourth linkage plate 804; a sliding plate 808 is connected to each of the two fifth supporting frames 807 in a sliding manner; two second limiting blocks 8010 are welded on the opposite sides of the two sliding plates 808; the two second limiting blocks 8010 are plugged into the second detection socket 806; a sixth spring 809 is welded on the opposite sides of the two sliding plates 808; the opposite ends of the two sixth springs 809 are respectively welded with the two fifth supporting frames 807; the laser emitter 8011 is arranged at the front part of the upper side of the fourth linkage plate 804; a light source sensor 8012 is arranged at the front part of the upper side of the fourth supporting frame 801; a third L-shaped plate 8013 is bolted to the front part of the upper side and the rear part of the upper side of the fourth supporting frame 801; three second flow guide chambers 8014 penetrate through the middle part of the left side of the bottom plate 1, and every two adjacent second flow guide chambers 8014 are in contact with each other.

When the electric clamp 705 drives the connector to move upward and away from the first detection socket 405, the electric clamp 705 drives the connector to move leftward to a position right above the second detection socket 806, the connector is located below the two third L-shaped plates 8013, then the electric clamp 705 drives the connector to move upward, so that the front part of the upper side and the rear part of the upper side of the connector respectively contact the two third L-shaped plates 8013, then the electric clamp 705 moves upward, the connector is aligned under the limiting action of the two third L-shaped plates 8013, then the electric clamp 705 drives the connector to move downward, the connector is inserted into the second detection socket 806, then the electric clamp 705 drives the connector to move upward, the connector drives the second detection socket 806 to move upward, the second detection socket 806 drives the two second limiting blocks 8010 to move upward, and the two second limiting blocks 8010 respectively drive the two sliding plates 808 to move upward, the two sliding plates 808 respectively drive the two fifth supporting frames 807 to move upwards, the two fifth supporting frames 807 simultaneously drive the fourth linkage plate 804 to move upwards, so that the fourth linkage plate 804 slides upwards on the two third limiting rods 802 and compresses the two sixth springs 809, the fourth linkage plate 804 drives the laser emitter 8011 to move upwards, the laser emitter 8011 always generates laser towards the light source sensor 8012, when the upward pulling force of the connector on the second detection socket 806 is smaller than the sum of gravity and the elastic force of the two sixth springs 809, the connector is separated from the second detection socket 806, then the two fifth springs 803 drive the second detection socket 806 to move downwards to the original position, the light source sensor 8012 detects the maximum distance of the upward movement of the light source sensor 8012, so that the magnitude of the plugging force of the connector is judged, and according to the magnitude range of the plugging force, the electric fixture 705 conveys the connector to the three second flow guide pods 8014, then the fluid flows into the external material bag from the second fluid guiding chamber 8014 for classification and collection, and then the sliding plate 808 is pulled manually to move away from the second detecting socket 806, the sliding plate 808 drives the second limiting block 8010 to move away from the second detecting socket 806, and compresses the sixth spring 809, then, the second testing socket 806 is taken out, and a new second testing socket 806 is put into the limiting frame 805, then, the sixth spring 809 drives the sliding plate 808 to move back to the original position, so that the two second limiting blocks 8010 are inserted into the new limiting frame 805 to fix the same, and then can carry out the plug power to the connector of different grade type and detect, realized during the use automatically with the connector location to the horizontality after insert to the second and detect socket 806 in the plug power detect, avoided inserting the problem that the testing result is bigger because of connecting askew, can detect the connector of different grade type simultaneously, improve general use nature.

Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present invention and not for limiting the protection scope of the present invention, and although the present invention is described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions can be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention.

Claims

1. A multifunctional computer motherboard connector detection device comprises a bottom plate (1), a first support frame (2), side plates (3) and a top plate (4); two first supporting frames (2) are fixedly connected to the lower side of the bottom plate (1); a side plate (3) is fixedly connected with the rear part of the upper side of the bottom plate (1); a top plate (4) is fixedly connected to the upper side of the side plate (3); the method is characterized in that: the anti-falling anti-seismic device also comprises a pin detection assembly, an anti-falling assembly, an anti-seismic detection assembly, an adjusting assembly, a resetting assembly and a transfer assembly; a pin detection assembly for detecting the pin of the connector is arranged at the right part of the upper side of the bottom plate (1); the anti-falling component for preventing the falling-off phenomenon when the connector with upward pins is screened out is arranged at the right part of the upper side of the bottom plate (1), and the anti-falling component is positioned at the right side of the pin detection component; the middle part of the upper side of the bottom plate (1) is provided with an anti-seismic detection assembly for detecting the anti-seismic property of the connector; an adjusting component for adjusting vibration frequency and vibration amplitude is arranged in the middle of the upper side of the bottom plate (1), and the adjusting component is positioned below the anti-seismic detection component; the middle part of the side plate (3) is provided with a reset assembly for resetting the connector after the earthquake resistance detection is finished; the front part of the lower side of the top plate (4) is provided with a transfer component for transferring the connector.

2. The detecting device for the connector of a multifunctional computer motherboard according to claim 1, wherein: the pin detection assembly comprises a pin detector (201), a first diversion cabin body (202), a connecting block (203), a limiting groove block (204), a connecting frame (205), a second supporting frame (206), a screw rod (207), a first motor (208), a sliding block (209), a first linkage plate (2010), a first push block (2011), a first limiting rod (2012), a first spring (2013), a second linkage plate (2014) and a second push block (2015); a pin detector (201) is arranged at the right part of the upper side of the bottom plate (1); two first diversion capsule bodies (202) penetrate through the right part of the upper side of the base plate (1), and the two first diversion capsule bodies (202) are respectively positioned on the front side and the rear side of the pin detector (201); a connecting frame (205) is fixedly connected to the right part of the upper side of the bottom plate (1), and the connecting frame (205) is positioned in front of the first diversion chamber body (202); a second support frame (206) is fixedly connected to the upper side of the connecting frame (205); the second support frame (206) is rotatably connected with a screw rod (207); a first motor (208) is arranged on the front side of the second support frame (206); the output end of the first motor (208) is fixedly connected with the screw rod (207); a sliding block (209) is connected on the second support frame (206) in a sliding way; a first linkage plate (2010) is fixedly connected to the lower side of the sliding block (209); a first push block (2011) is fixedly connected to the middle of the lower side of the first linkage plate (2010); two first limiting rods (2012) are fixedly connected to the rear part of the upper side of the first linkage plate (2010); the upper ends of the two first limiting rods (2012) are fixedly connected with a first spring (2013); the two first limiting rods (2012) are connected with a second linkage plate (2014) in a sliding way; the second linkage plate (2014) is fixedly connected with the two first springs (2013); a second pushing block (2015) is fixedly connected to the lower side of the second linkage plate (2014); the second push block (2015) is connected with the first linkage plate (2010) in a sliding mode; the first linkage plate (2010) is connected with the anti-drop assembly.

3. The detecting device for the connector of a multifunctional computer motherboard according to claim 2, wherein: the lower part of the rear side of the second push block (2015) is an inclined plane.

4. The detecting device for the connector of a multifunctional computer motherboard according to claim 2, wherein: the anti-drop assembly comprises a third support frame (301), a first L-shaped plate (302), a second spring (303), an anti-drop plate (304), a first linkage block (305) and a shifting rod (306); a third support frame (301) is fixedly connected to the right part of the upper side of the bottom plate (1); a first L-shaped plate (302) is connected to the upper side of the third support frame (301) in a sliding manner; two second springs (303) are fixedly connected to the left part of the upper side of the third support frame (301); the right ends of the two second springs (303) are fixedly connected with the first L-shaped plate (302); the left part of the upper side of the first L-shaped plate (302) is fixedly connected with an anti-drop plate (304); a first linkage block (305) is fixedly connected to the middle part of the right side of the first linkage plate (2010); a shifting lever (306) is inserted at the right side of the first linkage block (305); the deflector rod (306) is in contact with the anti-drop plate (304).

5. The device for detecting the connector of a motherboard of a multifunctional computer as claimed in claim 4, wherein: the front side surface of the anti-drop plate (304) is an inclined surface.

6. The device for detecting connector of motherboard of multifunctional computer as claimed in claim 4, wherein: the transfer component comprises an electric slide rail (701), an electric slide block (702), a second L-shaped plate (703), a third telescopic cylinder (704) and an electric clamp (705); the front part of the lower side of the top plate (4) is fixedly connected with an electric slide rail (701); an electric sliding block (702) is connected on the electric sliding rail (701) in a sliding way; a second L-shaped plate (703) is fixedly connected to the lower side of the electric slider (702); a third telescopic cylinder (704) is fixedly connected to the front side of the second L-shaped plate (703); and the telescopic end of the third telescopic cylinder (704) is fixedly connected with an electric clamp (705).

7. The device for detecting the connector of a motherboard of a multifunctional computer as claimed in claim 6, wherein: the anti-seismic detection assembly comprises a second limiting rod (401), a third spring (402), a third linkage plate (403), a first limiting block (404), a first detection socket (405), a fixing bolt (406) and a camera (407); two second limiting rods (401) are fixedly connected to the middle of the upper side of the bottom plate (1); the two second limiting rods (401) are connected with a third linkage plate (403) in a sliding manner; a third spring (402) is sleeved on each of the two second limiting rods (401); one end of a third spring (402) is fixedly connected with the third linkage plate (403), and the other end of the third spring (402) is fixedly connected with the bottom plate (1); a first limiting block (404) is fixedly connected to the front part of the upper side of the third linkage plate (403); a first detection socket (405) is inserted into the first limiting block (404); two fixing bolts (406) are connected to the lower side of the first detection socket (405) in a threaded manner; the two fixing bolts (406) are in threaded connection with the first limiting block (404).

8. The detecting device for the connector of a multifunctional computer motherboard according to claim 7, wherein: the adjusting component comprises a first telescopic cylinder (501), a linkage frame (502), a transmission rod (503), a cam (504), a transmission wheel (505) and a second motor (506); two first telescopic cylinders (501) are arranged in the middle of the upper side of the bottom plate (1); the telescopic ends of the two first telescopic cylinders (501) are fixedly connected with a linkage frame (502); the front side and the rear side of the linkage frame (502) are both rotatably connected with a transmission rod (503); a cam (504) is fixedly connected to the middle parts of the two transmission rods (503); the right ends of the two transmission rods (503) are fixedly connected with a transmission wheel (505); a belt is wound between the two driving wheels (505); a second motor (506) is arranged at the right part of the rear side of the linkage frame (502); the output end of the second motor (506) is fixedly connected with a transmission rod (503) positioned at the rear.

9. The detecting device for the connector of a multifunctional computer motherboard according to claim 8, wherein: the reset assembly comprises a second telescopic cylinder (601), a second linkage block (602), a push plate (603) and a fourth spring (604); a second telescopic cylinder (601) is inserted in the middle of the side plate (3); the telescopic end of the second telescopic cylinder (601) is fixedly connected with a second linkage block (602); a push plate (603) is connected on the second linkage block (602) in a sliding way; two fourth springs (604) are fixedly connected to the rear part of the lower side of the push plate (603); the lower ends of the two fourth springs (604) are fixedly connected with the second linkage block (602).

10. The detecting device for the connector of a multifunctional computer motherboard according to claim 9, wherein: the detection device is characterized by further comprising a pulling and inserting detection assembly, the pulling and inserting detection assembly is mounted on the left portion of the upper side of the bottom plate (1), and comprises a fourth supporting frame (801), a third limiting rod (802), a fifth spring (803), a fourth linkage plate (804), a limiting frame (805), a second detection socket (806), a fifth supporting frame (807), a sliding plate (808), a sixth spring (809), a second limiting block (8010), a laser emitter (8011), a light source sensor (8012), a third L-shaped plate (8013) and a second flow guide cabin body (8014); a fourth supporting frame (801) is fixedly connected to the left part of the upper side of the bottom plate (1); two third limiting rods (802) are fixedly connected to the middle of the upper side of the fourth supporting frame (801); a fourth linkage plate (804) is connected to the two third limiting rods (802) in a sliding manner; the lower side of the fourth linkage plate (804) is contacted with a fourth supporting frame (801); the upper ends of the two third limiting rods (802) are fixedly connected with a fifth spring (803); the lower ends of the two fifth springs (803) are fixedly connected with the fourth linkage plate (804); the middle part of the upper side of the fourth linkage plate (804) is fixedly connected with a limit frame (805); a second detection socket (806) is inserted into the inner side of the limit frame (805); the lower side of the second detection socket (806) is contacted with the fourth linkage plate (804); a fifth support frame (807) is fixedly connected to the front part and the rear part of the upper side of the fourth linkage plate (804); a sliding plate (808) is connected to each of the two fifth supporting frames (807) in a sliding manner; two opposite sides of the two sliding plates (808) are fixedly connected with a second limiting block (8010); the two second limiting blocks (8010) are connected with a second detection socket (806) in an inserted mode; a sixth spring (809) is fixedly connected to the back sides of the two sliding plates (808); the opposite ends of the two sixth springs (809) are fixedly connected with the two fifth supporting frames (807) respectively; a laser emitter (8011) is arranged at the front part of the upper side of the fourth linkage plate (804); a light source sensor (8012) is arranged at the front part of the upper side of the fourth supporting frame (801); a third L-shaped plate (8013) is fixedly connected to the front part of the upper side and the rear part of the upper side of the fourth supporting frame (801); three second diversion capsule bodies (8014) penetrate through the middle part of the left side of the bottom plate (1), and every two adjacent second diversion capsule bodies (8014) are in contact.