A hardware detection device for electronic information engineering

Abstract

This invention discloses a hardware testing device for electronic information engineering, relating to the field of server hard drive testing technology. It includes a desktop with a hard drive testing machine placed on top. A drive motor is placed on one side of the hard drive testing machine, and a rotating disk is fixedly connected to the output end of the drive motor. Two fixed workstations are set on the surface of the rotating disk, and four fixed boxes are installed on each fixed workstation. A first motor is fixedly connected to one side of the inner cavity of each fixed box. This hardware testing device for electronic information engineering, by setting up a track, drive box, and mounting plate, only requires fixing the server hard drive on the top of the rotating disk to automatically perform connector insertion, thus eliminating the need for manual insertion testing. Furthermore, it can limit the movement of server hard drives of different sizes and select appropriate connectors for connection.

Description

Technical Field

[0001] This invention relates to the field of server hard drive testing technology, specifically to a hardware testing device for electronic information engineering. Background Technology

[0002] Electronic information engineering primarily studies information acquisition and processing, as well as the design, development, application, and integration of electronic equipment and information systems. In electronic information engineering, server hardware testing is a tool used to detect and verify the functionality and performance of server hardware. It is commonly used in quality control and product testing phases during the manufacturing process, and the hard drive of an electronic information server is a core storage component of a data center. When a server's hard drive is installed in its chassis, performance testing is required. When using a Centrino Electronics hard drive tester, the test connector needs to be plugged into the hard drive under test to allow the tester to perform the tests. However, when a large number of tests are required, manually plugging and unplugging the cables one by one is necessary, which can easily lead to damage to the interface of the hard drive under test due to negligence. Summary of the Invention

[0003] To address the shortcomings of existing technologies, this invention provides a hardware testing device for electronic information engineering, which solves the problems mentioned in the background section.

[0004] To achieve the above objectives, the present invention provides the following technical solution: a hardware testing device for electronic information engineering, comprising a desktop, a hard disk tester placed on the top of the desktop, a drive motor placed on one side of the hard disk tester, a rotating disk fixedly connected to the output end of the drive motor, two fixed workstations on the surface of the rotating disk, and four fixed boxes installed on each fixed workstation, a first motor fixedly connected to one side of the inner cavity of each fixed box, and a first threaded rod rotatably connected to the other side of the inner cavity of each fixed box via bearings, the output end of the first motor being connected to one end of the first threaded rod via a coupling, a clamping block threadedly connected to the outer side of the first threaded rod, one end of each clamping block extending to the outer side of the fixed box, and a suction cup fixedly connected to the bottom of each fixed box.

[0005] Preferably, a track is fixedly connected to the back of the drive motor, a drive box is fixedly connected to one side of the track, a slider is slidably connected inside the track, a first tension sensor is fixedly connected to the top of the inner cavity of the track, the pull rope end of the first tension sensor is fixedly connected to the top of the slider, a third threaded rod is rotatably connected inside the drive box via a bearing, a fourth motor is fixedly connected to the top of the drive box, the output end of the fourth motor is connected to the top of the third threaded rod via a coupling, a drive block is threadedly connected to the outer side of the third threaded rod, a storage box is fixedly connected to one end of the drive block, a fifth motor is fixedly connected to one side of the inner cavity of the storage box, a fourth threaded rod is rotatably connected to the other side of the inner cavity of the storage box via a bearing, the output end of the fifth motor is connected to one end of the fourth threaded rod via a coupling, a first drive member is threadedly connected to the outer side of the fourth threaded rod, and the upper and lower ends of the first drive member extend above and below the slider, respectively.

[0006] Preferably, one end of the slider extends to the outside of the track and is fixedly connected to a telescopic arm. A telescopic column is slidably connected inside the telescopic arm. One end of the telescopic column extends to the outside of the telescopic arm and is fixedly connected to an equipment box. A second tension sensor is fixedly connected to one side of the inner cavity of the telescopic arm. The pull rope end of the second tension sensor is fixedly connected to one side of the telescopic column. A sixth motor is fixedly connected to one side of the inner cavity of the telescopic arm. A fifth threaded rod is rotatably connected to the other side of the inner cavity of the telescopic arm via a bearing. The output end of the sixth motor is connected to one end of the fifth threaded rod via a bearing. A connecting block is threadedly connected to the outside of the fifth threaded rod. A slot is opened at one end of the telescopic column. One end of the connecting block is inserted into the slot. An electric telescopic rod is fixedly connected to the bottom of the inner cavity of the slot. A locking block is fixedly connected to the telescopic end of the electric telescopic rod. The top of the locking block extends above the connecting block and into the slot.

[0007] Preferably, a rotating motor is fixedly connected to the top of the inner cavity of the equipment box, and a rotating rod is rotatably connected to the top of the inner cavity of the equipment box via a bearing. A clutch sleeve is provided on the outer side of the rotating rod. Gears that mesh with each other are fixedly sleeved on the outer side of the clutch sleeve and the output end of the rotating motor. The bottom end of the rotating rod extends to the bottom of the equipment box and is fixedly connected to a transverse guide rail. An angle sensor is installed on the top of the inner cavity of the equipment box. Several driving cavities are opened inside the rotating rod. Push blocks are slidably connected to the inner cavity of each driving cavity. A clutch pin is fixedly connected to one end of each push block. A spring is sleeved on the outer side of each clutch pin. One end of each spring is fixedly connected to one end of each push block. The other end of each spring is fixedly connected to one side of the inner cavity of each driving cavity. An electromagnet is fixedly connected to one side of the inner cavity of each driving cavity and one end of each push block. One end of each clutch pin is inserted into a clutch groove opened inside the clutch sleeve.

[0008] Preferably, a guide block is slidably connected inside the transverse guide rail. A third pull rope sensor is fixedly connected to one side of the transverse guide rail cavity. The pull rope end of the third pull rope sensor is fixedly connected to one side of the guide block. A sixth threaded rod is rotatably connected to one side of the transverse guide rail cavity via a bearing. An eighth motor is fixedly connected to the other side of the transverse guide rail cavity. The output ends of the eighth motor are all connected to one end of the sixth threaded rod via a coupling. A storage block is threadedly connected to the outer side of the sixth threaded rod. A seventh motor is fixedly connected to the top of the storage block cavity. A clutch sleeve is rotatably connected to the bottom of the storage block cavity via a bearing. The output end of the seventh motor is connected to the top of the clutch sleeve via a coupling. A second driving member is threadedly connected to the outer side of the clutch sleeve. Both ends of the second driving member extend to the left and right sides of the guide block.

[0009] Preferably, a mounting plate is fixedly connected to the bottom end of the guide block. Two first moving slots are formed inside the mounting plate. A second motor is fixedly connected to one side of each first moving slot's inner cavity, and a second threaded rod is rotatably connected to the other side of each first moving slot's inner cavity via a bearing. The output end of the second motor is connected to one end of the second threaded rod via a coupling. A first clamping plate is threadedly connected to the outer side of each second threaded rod, and one end of each first clamping plate extends below the mounting plate. A second moving slot is formed inside the mounting plate. A bidirectional threaded rod is rotatably connected to one side of the inner cavity of the second moving slot via a bearing, and a third motor is fixedly connected to the other side of the inner cavity of the second moving slot. The output end of the third motor is connected to one end of the bidirectional threaded rod via a coupling. Two second clamping plates are provided on the outer side of the bidirectional threaded rod, and each second clamping plate cooperates with the bidirectional threaded rod. The bottom ends of each second clamping plate extend below the mounting plate.

[0010] Preferably, a controller is fixedly connected to one side of the drive motor.

[0011] Preferably, the interface of the hard disk tester is connected to a connector via a wire, and the connector is located below the mounting plate.

[0012] This invention provides a hardware testing device for electronic information engineering, which has the following beneficial effects: 1. This hardware testing equipment for electronic information engineering, equipped with a track, drive box and mounting plate, can automatically perform connector insertion and connection work by simply fixing the server hard drive on the top of the rotating disk, thus eliminating the need for manual insertion and testing. It can also limit the connection of server hard drives of different sizes and select the appropriate connector for connection.

[0013] 2. This hardware testing equipment for electronic information engineering, equipped with a drive box, telescopic arm, and equipment box, allows for manual initial connection to server hard drives of different sizes. The movement trajectory is recorded, and subsequent server hard drive connection tests can then be performed based on this trajectory. Attached Figure Description

[0014] Figure 1 This is a schematic diagram of the overall structure of the present invention; Figure 2 This is a schematic diagram of the drive motor and rotating disk structure of the present invention; Figure 3 This is a bottom view of the internal structure of the mounting plate of the present invention; Figure 4 This is a schematic diagram of the internal structure of the fixing box of the present invention; Figure 5 This is a schematic diagram of the connection structure between the rotating rod and the clutch sleeve of the present invention; Figure 6 This is a schematic diagram of the internal structure of the track and drive box of the present invention; Figure 7 This is a schematic diagram of the internal structure of the telescopic arm, equipment box, and transverse guide rail of the present invention; Figure 8 This is a side view of the internal structure of the transverse guide rail of the present invention.

[0015] In the diagram: 1. Desktop; 2. Hard disk tester; 3. Electromagnet; 4. Push block; 5. Connector; 6. Drive motor; 7. Rotating disk; 8. Fixing box; 10. First motor; 11. First threaded rod; 12. Clamping block; 13. Drive cavity; 14. Suction cup; 15. Mounting plate; 16. First moving slot; 17. Second threaded rod; 18. Second motor; 19. First clamping plate; 20. Second moving slot; 21. Bidirectional threaded rod; 22. Second clamping plate; 23. Third motor; 24. Drive box; 25. Drive block; 26. Third threaded rod; 27. Fourth motor; 28. Storage box; 29. ​​Fourth threaded rod; 30. Fifth motor 31. First driving component; 32. Slider; 33. First tension sensor; 34. Rail; 35. Telescopic arm; 36. Sixth motor; 37. Fifth threaded rod; 38. Connecting block; 39. Slot; 40. Electric telescopic rod; 41. Locking block; 42. Telescopic column; 43. Second tension sensor; 44. Equipment box; 45. Rotating motor; 46. Gear; 47. Rotating rod; 48. Transverse guide rail; 49. Third pull rope sensor; 50. Guide block; 51. Storage block; 52. Seventh motor; 53. Second driving component; 54. Spring; 55. Clutch column; 56. Clutch sleeve; 57. Sixth threaded rod; 58. Eighth motor. Detailed Implementation

[0016] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments.

[0017] Please see Figures 1 to 8 This invention provides a technical solution: a hardware testing device for electronic information engineering, including a desktop 1, a hard disk tester 2 placed on the top of the desktop 1, a drive motor 6 placed on one side of the hard disk tester 2, a rotating disk 7 fixedly connected to the output end of the drive motor 6, two fixed stations set on the surface of the rotating disk 7, and four fixed boxes 8 installed on each fixed station, a first motor 10 fixedly connected to one side of the inner cavity of each fixed box 8, and a first threaded rod 11 rotatably connected to the other side of the inner cavity of each fixed box 8 via bearings, the output end of the first motor 10 being connected to one end of the first threaded rod 11 via a coupling, a clamping block 12 threadedly connected to the outer side of the first threaded rod 11, one end of each clamping block 12 extending to the outer side of the fixed box 8, and a suction cup 14 fixedly connected to the bottom of each fixed box 8.

[0018] The drive motor 6 is fixedly connected to a track 34 on its back. A drive box 24 is fixedly connected to one side of the track 34. A slider 32 is slidably connected inside the track 34. A first tension sensor 33 is fixedly connected to the top of the inner cavity of the track 34. The pull rope end of the first tension sensor 33 is fixedly connected to the top of the slider 32. A third threaded rod 26 is rotatably connected inside the drive box 24 via a bearing. A fourth motor 27 is fixedly connected to the top of the drive box 24. The output end of the fourth motor 27 is connected to the top of the third threaded rod 26 via a coupling. A drive block 25 is threadedly connected to the outer side of the third threaded rod 26. One end of the drive block 25 is fixedly connected to... A storage box 28 is connected to the storage box 28. A fifth motor 30 is fixedly connected to one side of the inner cavity of the storage box 28. A fourth threaded rod 29 is rotatably connected to the other side of the inner cavity of the storage box 28 via a bearing. The output end of the fifth motor 30 is connected to one end of the fourth threaded rod 29 via a coupling. A first driving member 31 is threadedly connected to the outer side of the fourth threaded rod 29. The upper and lower ends of the first driving member 31 extend above and below the slider 32, respectively. The output end of the fifth motor 30 drives the fourth threaded rod 29 to reset and rotate, so that the fourth threaded rod 29 drives the first driving member 31 to move into the storage box 28, and the first driving member 31 is disengaged from the slider 32.

[0019] One end of the slider 32 extends to the outside of the track 34 and is fixedly connected to a telescopic arm 35. A telescopic column 42 is slidably connected inside the telescopic arm 35. One end of the telescopic column 42 extends to the outside of the telescopic arm 35 and is fixedly connected to an equipment box 44. A second tension sensor 43 is fixedly connected to one side of the inner cavity of the telescopic arm 35. The pull rope end of the second tension sensor 43 is fixedly connected to one side of the telescopic column 42. A sixth motor 36 is fixedly connected to one side of the inner cavity of the telescopic arm 35. A fifth threaded rod 37 is rotatably connected to the other side of the inner cavity of the telescopic arm 35 via a bearing. The sixth motor 36... The output end is connected to one end of the fifth threaded rod 37 via a bearing. A connecting block 38 is threaded to the outer side of the fifth threaded rod 37. A slot 39 is provided at one end of the telescopic column 42. One end of the connecting block 38 is inserted into the slot 39. An electric telescopic rod 40 is fixedly connected to the bottom of the inner cavity of the slot 39. A locking block 41 is fixedly connected to the telescopic end of the electric telescopic rod 40. The top of the locking block 41 extends above the connecting block 38 and into the slot 39. The locking block 41 is moved down by the telescopic end of the electric telescopic rod 40, so that the connecting block 38 is separated from the telescopic column 42.

[0020] The equipment box 44 has a rotating motor 45 fixedly connected to the top of its inner cavity. A rotating rod 47 is rotatably connected to the top of the inner cavity via a bearing. A clutch sleeve 56 is provided on the outer side of the rotating rod 47. Gears 46 that mesh with each other are fixedly fitted on the outer side of both the clutch sleeve 56 and the output end of the rotating motor 45. The bottom end of the rotating rod 47 extends to the bottom of the equipment box 44 and is fixedly connected to a transverse guide rail 48. An angle sensor is installed on the top of the inner cavity of the equipment box 44. Several drive cavities 13 are opened inside the rotating rod 47. Push blocks 4 are slidably connected to the inner cavity of each drive cavity 13. One end of each push block 4 is fixedly connected to... There is a clutch column 55, and springs 54 are sleeved on the outside of the clutch column 55. One end of each spring 54 is fixedly connected to one end of the push block 4, and the other end of each spring 54 is fixedly connected to one side of the inner cavity of the drive cavity 13. An electromagnet 3 is fixedly connected to one side of the inner cavity of the drive cavity 13 and one end of the push block 4. One end of each clutch column 55 is inserted into the clutch groove opened inside the clutch sleeve 56. By closing the electromagnet 3, the repulsive magnetic field between the two electromagnets 3 disappears, causing the spring 54 to push the push block 4 to move one end of the clutch column 55 out of the clutch groove, thus separating the rotating rod 47 from the clutch sleeve 56.

[0021] The transverse guide rail 48 has a guide block 50 slidably connected inside. A third pull rope sensor 49 is fixedly connected to one side of the inner cavity of the transverse guide rail 48, and the pull rope end of the third pull rope sensor 49 is fixedly connected to one side of the guide block 50. A sixth threaded rod 57 is rotatably connected to one side of the inner cavity of the transverse guide rail 48 via a bearing. An eighth motor 58 is fixedly connected to the other side of the inner cavity of the transverse guide rail 48. The output ends of the eighth motor 58 are all connected to one end of the sixth threaded rod 57 via a coupling. A storage block 51 is threadedly connected to the outer side of the sixth threaded rod 57. A seventh motor 52 is fixedly connected to the top of the inner cavity. A clutch sleeve 56 is rotatably connected to the bottom of the inner cavity of the storage block 51 via a bearing. The output end of the seventh motor 52 is connected to the top of the clutch sleeve 56 via a coupling. A second driving member 53 is threadedly connected to the outer side of the clutch sleeve 56. Both ends of the second driving member 53 extend to the left and right sides of the guide block 50. The clutch sleeve 56 is reset and rotated by the output end of the seventh motor 52, so that the clutch sleeve 56 drives the second driving member 53 to move into the inside of the storage block 51, separating the storage block 51 from the guide block 50.

[0022] The bottom end of the guide block 50 is fixedly connected to a mounting plate 15. Two first moving slots 16 are formed inside the mounting plate 15. A second motor 18 is fixedly connected to one side of the inner cavity of each first moving slot 16. A second threaded rod 17 is rotatably connected to the other side of the inner cavity of each first moving slot 16 via bearings. The output end of the second motor 18 is connected to one end of the second threaded rod 17 via a coupling. A first clamping plate 19 is threadedly connected to the outer side of each second threaded rod 17. One end of each first clamping plate 19 extends below the mounting plate 15. The mounting plate 15 has a second moving slot 16 inside. The moving groove 20 and the inner cavity of the second moving groove 20 are rotatably connected to a bidirectional threaded rod 21 via a bearing on one side. The inner cavity of the second moving groove 20 is fixedly connected to a third motor 23. The output end of the third motor 23 is connected to one end of the bidirectional threaded rod 21 via a coupling. Two second clamping plates 22 are provided on the outer side of the bidirectional threaded rod 21, and the second clamping plates 22 cooperate with the bidirectional threaded rod 21. The bottom ends of the second clamping plates 22 extend to the bottom of the mounting plate 15. The server's hard drive is limited and fixed by the two first clamping plates 19 and the two second clamping plates 22.

[0023] A controller is fixedly connected to one side of the drive motor 6, and the device is controlled by the controller.

[0024] The interface of the hard drive tester 2 is connected to a connector 5 via a wire. The connector 5 is located below the mounting plate 15. By replacing the connector 5, connection tests can be performed on the hard drives of different servers.

[0025] In summary, when using this hardware testing equipment for electronic information engineering, the server hard drive is placed above the rotating disk 7. According to the size of the server hard drive, the fixing box 8 is placed on top of the rotating disk 7 and is attached to the top of the rotating disk 7 by the suction cup 14. Then, the output end of the first motor 10 drives the first threaded rod 11 to rotate, so that the first threaded rod 11 drives the clamping blocks 12 to move, so that the four clamping blocks 12 clamp the server hard drive. Connect the connector 5, which matches the hard drive interface of the server, to the interface of the hard drive tester 2. Then place the connector 5 under the mounting plate 15. Drive the second threaded rod 17 to rotate through the output end of the second motor 18, so that the second threaded rod 17 drives the first clamping plate 19 to move. Drive the bidirectional threaded rod 21 through the output end of the third motor 23, so that the bidirectional threaded rod 21 drives the two second clamping plates 22 to move, thereby clamping the server hard drive through the two second clamping plates 22 and the two first clamping plates 19. At this time, the user pulls the mounting plate 15 to move, causing the slider 32 to move inside the track 34. The first tension sensor 33 detects the moving distance of the slider 32. The telescopic column 42 moves inside the telescopic arm 35. The second tension sensor 43 detects the moving distance of the telescopic column 42. The transverse guide rail 48 drives the rotating rod 47 to rotate. The angle sensor detects the rotation angle of the rotating rod 47. The guide block 50 moves inside the transverse guide rail 48. The third pull rope sensor 49 detects the moving distance of the guide block 50. Insert connector 5 into the server hard drive interface, then remove connector 5 from the server hard drive interface and reset it; Then, the electromagnet 3 is activated, causing a repulsive magnetic field to be generated between the two electromagnets 3. This causes the pusher block 4 to push one end of the clutch column 55 into the clutch groove, connecting the rotating rod 47 to the clutch sleeve 56. The output end of the fifth motor 30 drives the fourth threaded rod 29 to rotate, causing the fourth threaded rod 29 to drive the first driving member 31 to move. This causes the upper and lower ends of the first driving member 31 to be located above and below one end of the slider 32. The telescopic end of the electric telescopic rod 40 pushes the locking block 41 to move upward, causing one end of the locking block 41 to be inserted into the slot 39, connecting the connecting block 38 to the telescopic column 42. The output end of the seventh motor 52 drives the clutch sleeve 56 to rotate, causing the clutch sleeve 56 to drive the second driving member 53 to move downward, causing the left and right ends of the second driving member 53 to be located on the left and right sides of the top of the guide block 50, connecting the storage block 51 to the guide block 50. At this time, the output end of the sixth motor 36 drives the fifth threaded rod 37 to rotate, causing the fifth threaded rod 37 to drive the connecting block 38 and the telescopic column 42 to extend. Through the output end of the rotating motor 45, the gear 46, the clutch sleeve 56, the rotating rod 47, and the transverse guide rail 48 are driven to rotate. Through the output end of the eighth motor 58, the sixth threaded rod 57 is driven to rotate, causing the sixth threaded rod 57 to drive the storage block 51. This causes the storage block 51, the second driving component 53, and the guide block 50 to move the mounting plate 15 and the connector 5. Then the fourth motor 2 The output end of motor 7 drives the third threaded rod 26 to rotate, causing the third threaded rod 26 to drive the drive block 25, the storage box 28, the first drive component 31, and the slider 32 to move downwards. This causes the telescopic arm 35, the equipment box 44, the mounting plate 15, and the connector 5 to move downwards, connecting the connector 5 to the interface of the server hard drive. The hard drive is then tested by the hard drive tester 2. After the test is completed, the connector 5 resets and moves, driving the rotating disk 7 to rotate through the output end of the drive motor 6. This causes another server hard drive to rotate below the connector 5 for further testing.

[0026] The above description is only a preferred embodiment of the present invention, but the scope of protection of the present invention is not limited thereto. Any equivalent substitutions or modifications made by those skilled in the art within the scope of the technology disclosed in the present invention, based on the technical solution and inventive concept of the present invention, should be covered within the scope of protection of the present invention.

Claims

1. A hardware testing device for electronic information engineering, comprising a desktop (1), characterized in that: A hard disk tester (2) is placed on the top of the desktop (1). A drive motor (6) is placed on one side of the hard disk tester (2). A rotating disk (7) is fixedly connected to the output end of the drive motor (6). Two fixed stations are set on the surface of the rotating disk (7), and four fixed boxes (8) are installed on each fixed station. A first motor (10) is fixedly connected to one side of the inner cavity of each fixed box (8). A first threaded rod (11) is rotatably connected to the other side of the inner cavity of each fixed box (8) through a bearing. The output end of the first motor (10) is connected to one end of the first threaded rod (11) through a coupling. A clamping block (12) is threadedly connected to the outer side of the first threaded rod (11). One end of the clamping block (12) extends to the outer side of the fixed box (8). A suction cup (14) is fixedly connected to the bottom of each fixed box (8).

2. The hardware testing equipment for electronic information engineering according to claim 1, characterized in that: A track (34) is fixedly connected to the back of the drive motor (6). A drive box (24) is fixedly connected to one side of the track (34). A slider (32) is slidably connected inside the track (34). A first tension sensor (33) is fixedly connected to the top of the inner cavity of the track (34). The pull rope end of the first tension sensor (33) is fixedly connected to the top of the slider (32). A third threaded rod (26) is rotatably connected inside the drive box (24) through a bearing. A fourth motor (27) is fixedly connected to the top of the drive box (24). The output end of the fourth motor (27) is connected to the third threaded rod (26) through a coupling. The top ends are connected, and the outer side of the third threaded rod (26) is threadedly connected to a drive block (25). One end of the drive block (25) is fixedly connected to a storage box (28). One side of the inner cavity of the storage box (28) is fixedly connected to a fifth motor (30). The other side of the inner cavity of the storage box (28) is rotatably connected to a fourth threaded rod (29) through a bearing. The output end of the fifth motor (30) is connected to one end of the fourth threaded rod (29) through a coupling. The outer side of the fourth threaded rod (29) is threadedly connected to a first drive member (31). The upper and lower ends of the first drive member (31) extend to the top and bottom of the slider (32), respectively.

3. The hardware testing equipment for electronic information engineering according to claim 2, characterized in that: One end of the slider (32) extends to the outside of the track (34) and is fixedly connected to a telescopic arm (35). A telescopic column (42) is slidably connected inside the telescopic arm (35). One end of the telescopic column (42) extends to the outside of the telescopic arm (35) and is fixedly connected to an equipment box (44). A second tension sensor (43) is fixedly connected to one side of the inner cavity of the telescopic arm (35). The pull rope end of the second tension sensor (43) is fixedly connected to one side of the telescopic column (42). A sixth motor (36) is fixedly connected to one side of the inner cavity of the telescopic arm (35). The other side of the inner cavity of the telescopic arm (35) rotates through a bearing. A fifth threaded rod (37) is connected. The output end of the sixth motor (36) is connected to one end of the fifth threaded rod (37) through a bearing. A connecting block (38) is threaded on the outer side of the fifth threaded rod (37). A slot (39) is opened at one end of the telescopic column (42). One end of the connecting block (38) is inserted into the slot (39). An electric telescopic rod (40) is fixedly connected to the bottom of the inner cavity of the slot (39). A locking block (41) is fixedly connected to the telescopic end of the electric telescopic rod (40). The top of the locking block (41) extends above the connecting block (38) and into the slot (39).

4. The hardware testing equipment for electronic information engineering according to claim 3, characterized in that: A rotating motor (45) is fixedly connected to the top of the inner cavity of the equipment box (44). A rotating rod (47) is rotatably connected to the top of the inner cavity of the equipment box (44) via a bearing. A clutch sleeve (56) is provided on the outer side of the rotating rod (47). A meshing gear (46) is fixedly sleeved on the outer side of both the clutch sleeve (56) and the output end of the rotating motor (45). The bottom end of the rotating rod (47) extends to the bottom of the equipment box (44) and is fixedly connected to a transverse guide rail (48). An angle sensor is installed on the top of the inner cavity of the equipment box (44). Several drive points are opened inside the rotating rod (47). The driving cavity (13) is slidably connected to a push block (4). One end of the push block (4) is fixedly connected to a clutch column (55). A spring (54) is sleeved on the outside of the clutch column (55). One end of the spring (54) is fixedly connected to one end of the push block (4). The other end of the spring (54) is fixedly connected to one side of the driving cavity (13). An electromagnet (3) is fixedly connected to one side of the driving cavity (13) and one end of the push block (4). One end of the clutch column (55) is inserted into the clutch groove opened on the inside of the clutch sleeve (56).

5. The hardware testing equipment for electronic information engineering according to claim 4, characterized in that: A guide block (50) is slidably connected inside the transverse guide rail (48). A third pull rope sensor (49) is fixedly connected to one side of the inner cavity of the transverse guide rail (48). The pull rope end of the third pull rope sensor (49) is fixedly connected to one side of the guide block (50). A sixth threaded rod (57) is rotatably connected to one side of the inner cavity of the transverse guide rail (48) through a bearing. An eighth motor (58) is fixedly connected to the other side of the inner cavity of the transverse guide rail (48). The output end of the eighth motor (58) is connected to the sixth threaded rod (57) through a coupling. One end is connected to the outer thread of the sixth threaded rod (57), and a storage block (51) is threadedly connected to the outer side. A seventh motor (52) is fixedly connected to the top of the inner cavity of the storage block (51). A clutch sleeve (56) is rotatably connected to the bottom of the inner cavity of the storage block (51) through a bearing. The output end of the seventh motor (52) is connected to the top of the clutch sleeve (56) through a coupling. A second driving member (53) is threadedly connected to the outer side of the clutch sleeve (56). Both ends of the second driving member (53) extend to the left and right sides of the guide block (50).

6. The hardware testing equipment for electronic information engineering according to claim 5, characterized in that: The bottom end of the guide block (50) is fixedly connected to a mounting plate (15). Two first moving slots (16) are formed inside the mounting plate (15). A second motor (18) is fixedly connected to one side of the inner cavity of each of the first moving slots (16). A second threaded rod (17) is rotatably connected to the other side of the inner cavity of each of the first moving slots (16) via a bearing. The output end of the second motor (18) is connected to one end of the second threaded rod (17) via a coupling. A first clamping plate (19) is threadedly connected to the outer side of each of the second threaded rods (17). One end of each first clamping plate (19) extends to the mounting plate (15). Below, a second movable groove (20) is provided inside the mounting plate (15). A bidirectional threaded rod (21) is rotatably connected to one side of the inner cavity of the second movable groove (20) via a bearing. A third motor (23) is fixedly connected to the other side of the inner cavity of the second movable groove (20). The output end of the third motor (23) is connected to one end of the bidirectional threaded rod (21) via a coupling. Two second clamping plates (22) are provided on the outside of the bidirectional threaded rod (21), and the second clamping plates (22) cooperate with the bidirectional threaded rod (21). The bottom ends of the second clamping plates (22) extend to the bottom of the mounting plate (15).

7. The hardware testing equipment for electronic information engineering according to claim 1, characterized in that: A controller is fixedly connected to one side of the drive motor (6).

8. The hardware testing equipment for electronic information engineering according to claim 1, characterized in that: The interface of the hard disk tester (2) is connected to a connector (5) via a wire, and the connector (5) is located below the mounting plate (15).

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