阅读说明：本技术 一种固态硬盘生产线中的检测辅助装置 (Detection auxiliary device in solid state hard drives production line ) 是由 顾能华 叶文通 陈勇 徐拥华 于 2021-06-25 设计创作，主要内容包括：本发明提供了一种固态硬盘生产线中的检测辅助装置,属于固态硬盘技术领域。本固态硬盘生产线中的检测辅助装置,包括机架,机架包括底板、竖板一和竖板二,竖板一和竖板二上设置有传输机构,传输机构包括输送带一、输送带二、电机一、电机二、电机三、电机四、输送辊一、输送辊二；机架上设置有检测台,检测台位于输送带一、输送带二之间,检测台的两端滑动设置有夹块一、夹块二,夹块一上滑动设置有检测接块,夹块一上水平开设有长条孔,工作台上还设有变位调节结构。本发明具有能够便捷高效的对固态硬盘进行质检。(The invention provides a detection auxiliary device in a solid state disk production line, and belongs to the technical field of solid state disks. The detection auxiliary device in the solid state disk production line comprises a rack, wherein the rack comprises a bottom plate, a first vertical plate and a second vertical plate, a transmission mechanism is arranged on the first vertical plate and the second vertical plate, and the transmission mechanism comprises a first conveying belt, a second conveying belt, a first motor, a second motor, a third motor, a fourth motor, a first conveying roller and a second conveying roller; the detection table is arranged on the rack and located between the first conveying belt and the second conveying belt, a first clamping block and a second clamping block are arranged at two ends of the detection table in a sliding mode, a detection connecting block is arranged on the first clamping block in a sliding mode, a strip hole is formed in the first clamping block in an upper horizontal mode, and a displacement adjusting structure is further arranged on the workbench. The invention can conveniently and efficiently carry out quality inspection on the solid state disk.)

1. A detection auxiliary device in a solid state disk production line comprises a rack and is characterized in that the rack comprises a bottom plate, a first vertical plate and a second vertical plate, one ends of the first vertical plate and the second vertical plate are vertically fixed on the bottom plate, and transmission mechanisms are arranged on the first vertical plate and the second vertical plate and comprise a first conveying belt, a second conveying belt, a first motor, a second motor, a third motor, a fourth motor, a plurality of first conveying rollers and a plurality of second conveying rollers; the detection device comprises a rack, a first conveying belt, a second conveying belt, a first clamping block, a second clamping block, a detection connecting block and a detection connecting block, wherein the rack is provided with a detection table, the detection table is positioned between the first conveying belt and the second conveying belt, two ends of the detection table are provided with the first clamping block and the second clamping block in a sliding manner, the first clamping block is provided with the detection connecting block in a sliding manner, and the first clamping block is horizontally provided with a long hole for the detection connecting block to pass through; the workbench is also provided with a displacement adjusting structure which overturns the solid state disk to enable the interface to be matched with the detection connecting block.

2. The auxiliary detection device in the solid state disk production line according to claim 1, wherein a first sliding groove and a second sliding groove are formed in the lower surface of the detection table along the length direction, a first sliding block and a second sliding block are respectively arranged on the first sliding groove and the second sliding groove in a sliding manner, a first clamping block and a second clamping block are respectively fixed on the first sliding block and the second sliding block, a first air cylinder and a second air cylinder are fixed on the lower surface of the detection table, and piston rods of the first air cylinder and the second air cylinder are respectively fixed on the first clamping block and the second clamping block.

3. The auxiliary detection device in the solid state disk production line as claimed in claim 2, wherein a support plate is fixed on the upper surface of the detection table, the support plate is located between the first cylinder and the second cylinder, and a temperature sensor is arranged on the support plate.

4. The auxiliary detection device in the solid state disk production line according to claim 1, wherein a third sliding groove is formed in the first clamping block, a third sliding block is arranged on the third sliding groove in a sliding manner, a support is arranged on the third sliding block in a sliding manner, a third air cylinder is fixed on the support, a piston rod of the third air cylinder is fixed on the detection connecting block, a fourth air cylinder is fixed on the first clamping block, and a piston rod of the fourth air cylinder is fixed on the support.

5. The auxiliary detection device in the solid state disk production line according to claim 1, wherein the rotating shaft is rotatably arranged on a first vertical plate and a second vertical plate, a fifth motor is fixed on the first vertical plate, an output shaft of the fifth motor is fixedly connected with one end of the rotating shaft, a frame is fixed on the rotating shaft, a side wall of the frame is fixed with a fifth cylinder, piston rods of the fifth cylinder penetrate through the frame to be in clearance fit with the frame, the piston rods of the fifth cylinder are fixed on a third clamping block, a sixth cylinder is fixed on the other side wall of the frame, the piston rods of the sixth cylinder penetrate through the frame to be in clearance fit with the frame, and the piston rods of the sixth cylinder are fixed on a fourth clamping block.

6. The auxiliary detection device in the solid state disk production line of claim 5, wherein the shift adjusting structure further comprises a sixth motor, a sliding rod and a lead screw, the lead screw is rotatably arranged on the bottom plate through a bearing seat, the lead screw is parallel to the conveying direction of the first conveying belt and the second conveying belt, the sixth motor is fixed on the bottom plate, an output shaft of the sixth motor is fixedly connected with one end of the lead screw, the sliding rod is in threaded connection with the lead screw, the first vertical plate is provided with a third sliding groove, the second vertical plate is provided with a fourth sliding groove, and two ends of the sliding rod are respectively slidably arranged in the third sliding groove and the fourth sliding groove.

7. The auxiliary detection device in the solid state disk production line of claim 6, wherein a seventh motor is fixed on the sliding rod, an output shaft of the seventh motor is vertically upward, a seventh cylinder is fixed at an end of an output shaft of the seventh motor, and an end of a piston rod of the seventh cylinder is fixed at a lower surface of the detection table.

8. The auxiliary detection device in the solid state disk production line as claimed in claim 1, wherein the first conveying rollers are rotatably disposed on the first vertical plate, the first motor and the second motor are fixed on the first vertical plate, output shafts of the first motor and the second motor are fixedly connected with any two first conveying rollers, and each first conveying roller is in transmission connection with one conveying belt.

9. The auxiliary detection device in the solid state disk production line of claim 8, wherein the second conveying rollers are rotatably arranged on the second vertical plate, the third motor and the fourth motor are both fixed on the second vertical plate, output shafts of the third motor and the fourth motor are fixedly connected with any two second conveying rollers, and each second conveying roller is in transmission connection through a conveying belt.

Technical Field

The invention belongs to the technical field of solid state disks, and relates to a detection auxiliary device in a solid state disk production line.

Background

The solid state disk is widely applied to various fields such as military affairs, vehicle-mounted, industrial control, video monitoring, network terminals, electric power, medical treatment, aviation, navigation equipment and the like due to the technical advantages of the solid state disk.

For the rapid development of the solid state disk, how to ensure the stable operation of the performance, the function and the reading and writing of the solid state disk on the server is required to meet the diversified requirements of different users and ensure the stability and the reliability of application, so that the solid state disk needs to be fully tested for the performance, the function and the reading and writing stability no matter in the innovation and the production processing.

In view of this, the invention provides a detection auxiliary device in a solid state disk production line, so that the performance of a solid state disk can be actively and flexibly tested in the production and processing of the solid state disk, and a test result can be more conveniently and efficiently obtained, thereby ensuring the quality of the product.

Disclosure of Invention

The invention aims to solve the problems in the prior art, and provides a detection auxiliary device in a solid state disk production line.

The purpose of the invention can be realized by the following technical scheme:

a detection auxiliary device in a solid state disk production line comprises a rack and is characterized in that the rack comprises a bottom plate, a first vertical plate and a second vertical plate, one ends of the first vertical plate and the second vertical plate are vertically fixed on the bottom plate, the first vertical plate and the second vertical plate are parallel to each other, a transmission mechanism is arranged on the first vertical plate and the second vertical plate, and the transmission mechanism comprises a first conveying belt, a second conveying belt, a first motor, a second motor, a third motor, a fourth motor, a plurality of first conveying rollers and a plurality of second conveying rollers; the detection device comprises a rack, a first conveying belt, a second conveying belt, a first clamping block, a second clamping block, a detection connecting block and a detection connecting block, wherein the rack is provided with a detection table, the detection table is positioned between the first conveying belt and the second conveying belt, the two ends of the detection table are provided with the first clamping block and the second clamping block in a sliding manner, the first clamping block is provided with the detection connecting block in a sliding manner, and the first clamping block is horizontally provided with a long hole for the detection connecting block to pass through; the workbench is also provided with a displacement adjusting structure which overturns the solid state disk to enable the solid state disk interface to be matched with the detection connecting block.

Preferably, the lower surface of the detection platform is provided with a first sliding groove and a second sliding groove along the length direction, the first sliding groove and the second sliding groove are collinear, the first sliding block and the second sliding block are respectively arranged on the first sliding groove and the second sliding groove in a sliding mode, the first clamping block and the second clamping block are respectively fixed on the first sliding block and the second sliding block, the lower surface of the detection platform is fixedly provided with a first air cylinder and a second air cylinder, the directions of piston rods of the first air cylinder and the second air cylinder are opposite, and the piston rods of the first air cylinder and the second air cylinder are respectively fixed on the first clamping block and the second clamping block. The first air cylinder and the second air cylinder can drive the first clamping block and the second clamping block to move in the same direction or in the opposite direction, so that the solid state disk is clamped and positioned or loosened.

Preferably, the upper surface of the detection table is fixed with a support plate, the support plate is positioned between the first cylinder and the second cylinder, and the support plate is provided with a temperature sensor. The backup pad plays the effect that supports to solid state hard drives, makes interface on the solid state hard drives and rectangular hole level height, ensures towards rectangular hole, and temperature sensor can look over solid state hard drives's the situation of generating heat in the testing process in the backup pad simultaneously.

Preferably, a third sliding groove is horizontally formed in one side face, back to the second clamping plate, of the first clamping block, a third sliding block is arranged on the third sliding groove in a sliding mode, a support is arranged on the third sliding block in a sliding mode, a third air cylinder is fixed to the support, a piston rod of the third air cylinder faces towards the strip hole, a piston rod of the third air cylinder is fixed to the detection connecting block, a fourth air cylinder is horizontally fixed to one side face, back to the second clamping plate, of the first clamping block, a piston rod of the fourth air cylinder is parallel to the third sliding groove, and a piston rod of the fourth air cylinder is fixed to the support. The cylinder four can drive the support to slide along the spout three, according to the interface position on the solid state hard disk to indirectly drive and detect the joint block and carry out longitudinal movement along rectangular hole and adjust, the cylinder three can drive and detect that the joint block is horizontal.

Preferably, the structure of adjusting that shifts include pivot, motor five, frame, clamp splice three, clamp splice four, the both ends of pivot are passed through the bearing respectively the horizontal rotation and are set up on riser one and riser two, motor five is fixed on riser one, output shaft and pivot one end fixed connection of motor five, in the fixed pivot of frame lateral wall, be fixed with a plurality of cylinders five on the frame and the pivot looks perpendicular lateral wall, the five piston rods of cylinder all pass frame and frame clearance fit, and the five piston rods of cylinder all fix on clamp splice three, frame and pivot looks vertically another lateral wall on be fixed with a plurality of cylinders six, the six piston rods of cylinder all pass frame and frame clearance fit, and the six piston rods of cylinder all fix on clamp splice four.

Preferably, the structure of adjusting that shifts still include motor six, slide bar, lead screw, the lead screw pass through the bearing frame and rotate the setting on the bottom plate, the direction of transfer of lead screw and conveyer belt one, conveyer belt two is parallel, motor six is fixed on the bottom plate, the output shaft of motor six and the one end fixed connection of lead screw, slide bar threaded connection is on the lead screw, riser one has seted up spout three towards the one side of riser two on the level, riser two has seted up spout four towards a side of riser one on the level, the both ends of slide bar slide respectively and set up in spout three and spout four.

Preferably, a seventh motor is fixed on the sliding rod, an output shaft of the seventh motor is vertically upward, a seventh cylinder is fixed at the end part of the output shaft of the seventh motor, and the end part of a piston rod of the seventh cylinder is fixed on the lower surface of the detection table.

Preferably, the first conveying roller all rotates through the bearing level and sets up in a side of riser one towards riser two, and the interval between each conveying roller is equal, motor one and motor two are all fixed in a side of riser one dorsad riser two, and the output shaft of motor one and motor two and arbitrary two conveying roller fixed connection, each conveying roller one is through a conveyer belt drive connection.

Preferably, conveying roller two all rotate the setting through the bearing level and establish two sides towards riser one at the riser, and the interval between each conveying roller two equals, motor three and motor four are all fixed in two sides of riser one dorsad, and motor three and motor four's output shaft and two arbitrary two conveying roller two fixed connection, each conveying roller two is through a transmission connection of conveyer belt.

The motor I and the motor II can drive the conveyer belt I to transmit through the conveying rollers I, and the motor III and the motor II can drive the conveyer belt II to transmit through the conveying rollers II.

Compared with the prior art, the auxiliary detection device in the solid state disk production line has the following advantages:

1. in the production line, the solid state disk to be detected is transmitted on the rack by the first conveying belt and the second conveying belt, when the front surface of the interface of the solid state disk faces the detection connecting block, the first clamping block and the second clamping block on the detection table are used for directly clamping and positioning, and the detection connecting block is directly inserted into the interface of the solid state disk to acquire data for quality inspection.

2. According to the invention, the position of the solid state disk and the detection table can be adjusted through the displacement adjusting structure, so that the detection connection block is inserted into the solid state disk interface to acquire data more efficiently and conveniently.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic front view of the present invention.

Fig. 3 is a left side view of the present invention.

Fig. 4 is a schematic top view of the present invention.

Fig. 5 is a partially enlarged schematic view of a portion a of fig. 1.

In the figure, 1, a bottom plate; 2. a first vertical plate; 3. a second vertical plate; 4. a first conveying belt; 5. a second conveying belt; 6. a first motor; 7. a fourth motor; 8. a first conveying roller; 9. a second conveying roller; 10. a detection table; 11. a support plate; 12. a temperature sensor; 13. a first clamping block; 14. a second clamping block; 15. a strip hole; 16. a first sliding block; 17. a first cylinder; 18. a second air cylinder; 19. a support; 20. a third air cylinder; 21. a cylinder IV; 22. detecting a connecting block; 23. a rotating shaft; 24. a frame; 25. a fifth cylinder; 26. a third clamping block; 27. a sixth air cylinder; 28. a fourth clamping block; 29. a fifth motor; 30. a sixth motor; 31. a lead screw; 32. a slide bar; 33. a third chute; 34. a seventh motor; 35. and a seventh cylinder.

Detailed Description

The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.

As shown in fig. 1-4, a detection auxiliary device in solid state hard drives production line, including the frame, its characterized in that, the frame includes bottom plate 1, riser one 2 and riser two 3, the one end of riser one 2 and riser two 3 is vertical to be fixed on bottom plate 1, riser one 2 and riser two 3 are parallel to each other, be provided with transmission device on riser one 2 and the riser two 3, transmission device includes conveyer belt one 4, conveyer belt two 5, motor one 6, motor two, motor three, motor four 7, a plurality of conveying roller 8, a plurality of conveying roller two 9. Conveying roller 8 all sets up in a side of riser 2 towards riser two 3 through the bearing horizontal rotation, and the interval between each conveying roller 8 equals, and motor 6 and motor two are all fixed in a side of riser 2 two 3 dorsad, and the output shaft of motor 6 and motor two and arbitrary two conveying roller 8 fixed connection, and each conveying roller 8 is connected through 4 transmissions of conveyer belt. Two 9 conveying rollers all rotate the setting through the bearing level and establish two 3 sides towards riser one 2 in the riser, and the interval between each two 9 conveying rollers equals, and motor three and motor four 7 are all fixed in two 3 sides of riser one 2 dorsad in the riser, and motor three and motor four 7's output shaft and two 9 fixed connection of arbitrary two conveying rollers, and each two 9 conveying rollers are connected through 4 transmissions of conveyer belt. The first motor 6 and the second motor can drive the first conveying belt to transmit 4 through the first conveying rollers 8, and the third motor and the fourth motor 7 can drive the second conveying belt to transmit 5 through the second conveying rollers 9.

A detection table 10 is arranged on the rack, the detection table 10 is positioned between the first conveying belt 4 and the second conveying belt 5, a first clamping block 13 and a second clamping block 14 are arranged at two ends of the detection table 10 in a sliding mode, a detection connecting block 22 is arranged on the first clamping block 13 in a sliding mode, and a long hole 15 for the detection connecting block 22 to penetrate through is horizontally formed in the first clamping block 13; the workbench is also provided with a displacement adjusting structure which overturns the solid state disk to enable the solid state disk interface to be matched with the detection connecting block 22. The production processing line transmits the solid state disk to be detected on the rack through the first conveying belt 4 and the second conveying belt 5, when the front face of the interface of the solid state disk faces the detection connecting block 22, the solid state disk is directly clamped and positioned through the first clamping block 13 and the second clamping block 14 on the detection table 10, and the detection connecting block 22 is directly inserted into the interface to acquire data for quality detection.

Specifically, as shown in fig. 5, a first sliding groove and a second sliding groove are formed in the upper surface of the detection table 10 along the length direction, the first sliding groove and the second sliding groove are collinear, a first sliding block 16 and a second sliding block are respectively slidably arranged on the first sliding groove and the second sliding groove, a first clamping block 13 and a second clamping block 14 are respectively fixed on the first sliding block 16 and the second sliding block, a first air cylinder 17 and a second air cylinder 18 are fixed on the lower surface of the detection table 10, the directions of piston rods of the first air cylinder 17 and the second air cylinder 18 are opposite, and the piston rods of the first air cylinder 17 and the second air cylinder 18 are respectively fixed on the first clamping block 13 and the second clamping block 14. The first air cylinder 17 and the second air cylinder 18 can drive the first clamping block 13 and the second clamping block 14 to move in the same direction or in the opposite direction, so that the solid state disk is clamped and positioned or loosened.

A third sliding groove 33 is horizontally formed in one side face, back to the second clamping plate, of the first clamping block 13, a third sliding block 33 is arranged on the third sliding groove 33 in a sliding mode, a support 19 is arranged on the third sliding block in a sliding mode, a third air cylinder 20 is fixed on the support 19, a piston rod of the third air cylinder 20 faces the long hole 15, a piston rod of the third air cylinder 20 is fixed on the detection connecting block 22, a fourth air cylinder 21 is horizontally fixed on one side face, back to the second clamping plate, of the first clamping block 13, a piston rod of the fourth air cylinder 21 is parallel to the third sliding groove 33, and a piston rod of the fourth air cylinder 21 is fixed on the support 19. The cylinder four 21 can drive the support 19 to slide along the sliding groove three 33, and according to the interface position on the solid state disk, the detection connecting block 22 is indirectly driven to move longitudinally along the strip hole 15, and the cylinder three 20 can drive the detection connecting block 22 to move transversely.

The position-changing adjusting structure comprises a rotating shaft 23, a motor five 29, a frame 24, a clamping block three 26 and a clamping block four 28, two ends of the rotating shaft 23 are respectively horizontally rotated and arranged on a vertical plate one 2 and a vertical plate two 3 through bearings, the motor five 29 is fixed on the vertical plate one 2, an output shaft of the motor five 29 is fixedly connected with one end of the rotating shaft 23, the rotating shaft 23 is fixed on one side wall of the frame 24, three cylinders five 25 are fixed on one vertical side wall of the frame 24 and the rotating shaft 23, piston rods of the cylinders five 25 penetrate through the frame 24 and the frame 24 in clearance fit, piston rods of the cylinders five 25 are fixed on the clamping block three 26, three cylinders six 27 are fixed on the other vertical side wall of the frame 24 and the rotating shaft 23, piston rods of the cylinders six 27 penetrate through the frame 24 and the frame 24 in clearance fit, and piston rods of the cylinders six 27 are fixed on the clamping block four 28.

The structure of adjusting that shifts still includes six 30 of motor, slide bar 32, lead screw 31 rotate through the bearing frame and set up on bottom plate 1, lead screw 31 and conveyer belt 4, the direction of transfer of conveyer belt two 5 is parallel, six 30 of motor are fixed on bottom plate 1, the output shaft of six 30 of motor and the one end fixed connection of lead screw 31, slide bar 32 threaded connection is on lead screw 31, riser one 2 is improved level and has been seted up spout three 33 towards a side of riser two 3, riser two 3 is improved level and has been seted up spout four towards a side of riser one 2, slide bar 32's both ends slide respectively and set up in spout three 33 and spout four. A motor seven 34 is fixed on the sliding rod 32, an output shaft of the motor seven 34 is vertically upward, an air cylinder seven 35 is fixed at the end part of the output shaft of the motor seven 34, and the end part of a piston rod of the air cylinder seven 35 is fixed at the lower surface of the detection table 10.

In addition, a support plate 11 is fixed on the upper surface of the detection table 10, the support plate 11 is located between the first air cylinder 17 and the second air cylinder 18, and a temperature sensor 12 is arranged on the support plate 11. The backup pad 11 plays the effect of support to solid state hard drives, makes interface on the solid state hard drives and rectangular hole 15 level, ensures towards rectangular hole 15, and temperature sensor 12 can look over the situation of generating heat of solid state hard drives in the testing process on the backup pad 11 simultaneously.

Example one

When production Type-A or Type-B class solid state hard drives need to examine, under the initial condition, frame 24 all is located the left side of pivot 23 with examining test table 10, examine test table 10 height and be less than conveyer belt one 4, conveyer belt two 5, when solid state hard drives's interface openly detected the splice 22, seven 35 drive of cylinder examine test table 10 rebound to solid state hard drives with a clamp splice 13, clamp splice two 14 flush, cylinder one 17, cylinder two 18 drive a clamp splice 13, clamp splice two 14 press from both sides tight solid state hard drives, adjust and detect splice 22, will detect splice 22 disect insertion interface.

The position of the Type-A or Type-B solid state disk needs to be adjusted when the following three conditions occur:

when the reverse side of the interface of the solid state disk faces the detection connecting block 22, the air cylinder seven 35 drives the solid state disk on the detection table 10 to move upwards to be flush with the clamping block three 26 and the clamping block four 28, the air cylinder five 25 and the air cylinder six 27 drive the clamping block three 26 and the clamping block four 28 to clamp the solid state disk, the motor five 29 drives the frame 24 to rotate and turn over 180 degrees to the right side of the rotating shaft 23, the air cylinder seven 35 drives the detection table 10 to move upwards to be higher than the frame, the motor seven 34 drives the detection table 10 to horizontally rotate 180 degrees and then to descend to be flush with the conveyor belt one 4 and the conveyor belt two 5, the motor six 30 drives the screw rod 31 to rotate, the detection table 10 is driven by the sliding rod 32 to move to be under the frame 24, the air cylinder seven 35 drives the detection table 10 to move upwards to be flush with the solid state disk and the clamping block one 13 and the clamping block two 14, the air cylinder one 17 and the air cylinder two 18 drive the clamping block one 13 and the clamping block two 14 to clamp the solid state disk, the interface of the solid state disk faces the detection connecting block 22, the test block 22 is adjusted and the test block 22 is inserted directly into the interface.

When the front of the interface of the solid state disk is opposite to the detection connecting block 22, the six motors 30 drive the screw rods 31 to rotate, the slide rods 32 drive the detection table 10 to move to the right side of the rotating shaft 23, the seven cylinders 35 drive the detection table 10 to continuously move upwards to be higher than the rack, the seven motors 34 drive the detection table 10 to horizontally rotate 180 degrees and then to descend to be flush with the first conveying belt 4 and the second conveying belt 5, the detection table 10 moves back to the position right below the left solid state disk of the rotating shaft 23, the first cylinders 17 and the second cylinders 18 drive the first clamping blocks 13 and the second clamping blocks 14 to clamp the solid state disk, the interface of the solid state disk faces the detection connecting block 22 in the forward direction, the detection connecting block 22 is adjusted, and the detection connecting block 22 is directly inserted into the interface.

When the interface of the solid state disk presents a reverse side back to the detection block 22,

the seven 35 air cylinders drive the solid state disk on the detection table 10 to move upwards to be flush with the third clamping block 26 and the fourth clamping block 28, the five 25 air cylinders drive the third clamping block 26 and the fourth clamping block 28 to clamp the solid state disk, the five 29 motor drives the frame 24 to rotate, the solid state disk is turned over 180 degrees to the right side of the rotating shaft 23, the seven 35 air cylinders drive the detection table 10 to continuously move downwards to be flush with the first conveying belt 4 and the second conveying belt 5, the six 30 motor drives the lead screw 31 to rotate, the detection table 10 is driven to move to be under the frame 24 through the slide rod 32, the seven 35 air cylinders drive the detection table 10 to move upwards until the solid state disk is flush with the first clamping block 13 and the second clamping block 14, the first air cylinder 17 and the second air cylinder 18 drive the first clamping block 13 and the second clamping block 14 to clamp the solid state disk, the interface of the solid state disk faces towards the detection connecting block 22, the detection connecting block 22 is adjusted, and the detection connecting block 22 is directly inserted into the interface.

Example two

When detecting a Type-C Type solid state disk, the structure and principle of the embodiment are basically the same as those of the first embodiment, and the difference lies in that the Type solid state disk interface has no front side and back side:

in an initial state, the frame 24 and the detection table 10 are located on the left side of the rotating shaft 23, the height of the detection table 10 is lower than that of the first conveying belt 4 and that of the second conveying belt 5, when the interface of the solid state disk faces the detection connecting block 22, the air cylinder seven 35 drives the detection table 10 to move upwards until the solid state disk is flush with the first clamping block 13 and the second clamping block 14, the air cylinder one 17 and the air cylinder two 18 drive the first clamping block 13 and the second clamping block 14 to clamp the solid state disk, the detection connecting block 22 is adjusted, and the detection connecting block 22 is directly inserted into the interface.

The position of the Type-C solid state disk needs to be adjusted when one of the following situations occurs:

when the front of the interface of the solid state disk is opposite to the detection connecting block 22, the six motors 30 drive the screw rods 31 to rotate, the slide rods 32 drive the detection table 10 to move to the right side of the rotating shaft 23, the seven cylinders 35 drive the detection table 10 to continuously move upwards to be higher than the rack, the seven motors 34 drive the detection table 10 to horizontally rotate 180 degrees and then to descend to be flush with the first conveying belt 4 and the second conveying belt 5, the detection table 10 moves back to the position right below the left solid state disk of the rotating shaft 23, the first cylinders 17 and the second cylinders 18 drive the first clamping blocks 13 and the second clamping blocks 14 to clamp the solid state disk, the interface of the solid state disk faces the detection connecting block 22 in the forward direction, the detection connecting block 22 is adjusted, and the detection connecting block 22 is directly inserted into the interface.

The other scheme is as follows: the seven 35 air cylinders drive the solid state disk on the detection table 10 to move upwards to be flush with the third clamping block 26 and the fourth clamping block 28, the five 25 air cylinders drive the third clamping block 26 and the fourth clamping block 28 to clamp the solid state disk, the five 29 motor drives the frame 24 to rotate, the solid state disk is turned over 180 degrees to the right side of the rotating shaft 23, the seven 35 air cylinders drive the detection table 10 to continuously move downwards to be flush with the first conveying belt 4 and the second conveying belt 5, the six 30 motor drives the lead screw 31 to rotate, the detection table 10 is driven to move to be under the frame 24 through the slide rod 32, the seven 35 air cylinders drive the detection table 10 to move upwards until the solid state disk is flush with the first clamping block 13 and the second clamping block 14, the first air cylinder 17 and the second air cylinder 18 drive the first clamping block 13 and the second clamping block 14 to clamp the solid state disk, the interface of the solid state disk faces towards the detection connecting block 22, the detection connecting block 22 is adjusted, and the detection connecting block 22 is directly inserted into the interface.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the equipment or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.