JP6808117B1 - Protective fixing equipment that reduces vibration to the HDD - Google Patents

Abstract

PROBLEM TO BE SOLVED: To disclose a protective fixing device for reducing vibration with respect to an HDD. SOLUTION: The vibration suppression box of an HDD is included, a vibration suppression space opened upward is installed in the vibration suppression box, and a vibration suppression device capable of suppressing vibration is installed in the vibration suppression space. A vertical vibration suppression mechanism capable of suppressing vertical vibration is installed in the vibration suppressor, and an HDD fixture capable of quickly holding an HDD is slidably connected to the vibration suppressor, according to the present invention. The HDD fixture causes the HDD to push the holding plate and the pushing rod downward, and the insertion mechanism can automatically fix the pushing rod and restrict the movement of the holding plate, and at the same time, the cam on the pushing rod is the holding rod. The left and right sides of the HDD are sandwiched, and the gear rack mechanism on the holding rod drives and rotates the rotating block to bring the rotating block into contact with the upper end surface of the HDD, so that the HDD can be quickly fixed. [Selection diagram] Fig. 1

Description

The present invention takes up the field of protection and fixing technology for reducing vibration to HDD, and specifically is protection and fixing equipment for reducing vibration to HDD.

An HDD is a type of storage device in a computer system, and is a device that reads and writes data by a magnetic storage method. It is installed as standard as an external storage device for personal computers. The HDD is in a state in which a disk called a "platter", which is a storage medium, and a reading / writing mechanism such as a magnetic head and an access arm are sealed in one case. HDD is an important component of a personal computer, vibration has a great influence on the mechanical structure of HDD, even a slight vibration affects the life of HDD, it is easy to cause damage to the truck, and violent vibration damages the platter and the magnetic head. The HDD is also broken, and most of the devices that reduce the vibration to the existing HDD cannot completely fix the HDD, and there is a difficulty in attaching / detaching the device that reduces the vibration. The present invention is a device that can solve the above problems. Is.

Chinese Patent Application Publication No. 102237124

Most of the devices for reducing vibration with respect to the existing HDD cannot completely fix the HDD, and there is a difficulty in attaching / detaching the device for reducing vibration.

In order to solve the above problem, this example designs a protective fixing facility that reduces vibration to the HDD, includes a vibration suppression box, and a vibration suppression space opened upward is installed in the vibration suppression box. A vibration suppressor capable of suppressing vibration is installed in the vibration suppression space, a vertical vibration suppression mechanism capable of suppressing vertical vibration is installed in the vibration suppressor, and the vibration suppressor is equipped with a vertical vibration suppression mechanism. The HDD fixture that can quickly hold the HDD is slidably connected, and the HDD fixture is a fixed box installed in the vibration suppression space and a fixed box installed in the fixed box and opened upward. An elevating plate that is slidably connected to the space and the rear inner wall of the fixed space, and an elevating rod that is fixedly connected to the lower inner wall of the elevating plate and extends downward to the outside of the end face of the fixed space. To the left and right pinholes installed in the elevating rod, the symmetrical insertion box installed on the lower end surface of the fixed space, and the symmetrical center side installed in the insertion box. The HDD fixture includes an open insertion space and an insertion that is slidably connected into the insertion space and can come into contact with the pinhole. The HDD fixture lowers the elevating plate by the weight of the HDD itself. It is driven and lowered, and the elevating rod is further lowered, and the insertion is quickly brought into contact with the elevating rod to fix the elevating rod, and the HDD can be quickly mounted in the HDD fixture. A holding claw that can hold and fix the HDD is installed, and the holding claw is composed of two symmetrical L-shaped rods slidably connected to the rear inner wall of the fixed space and the L-shaped rod. A rotating space installed inside that penetrates left and right and opens upward, and a gear shaft rotatably connected to the front inner wall of the rotating space and extending to the rear outside the rear end surface of the rotating space. The L-shaped rod is located on both the left and right sides of the elevating plate, and the holding claw is the L-shaped rod, including a sandwiching block fixedly connected to the gear shaft and partially located in the rotating space. It is possible to sandwich and fix the HDD through the movement of the sandwiching block to the side close to the center of symmetry and the rotation of the sandwiching block to the side close to the center of symmetry.

The vibration suppressor includes an elevating table slidably connected between the left and right inner walls of the vibration suppression space, and a lateral moving box is slidably connected to the upper end surface of the elevating table. A lateral moving space opened upward is installed inside, a heat radiating plate is fixedly connected to the opening of the lateral moving space, and heat can be dissipated from left to right on the upper end surface of the heat radiating plate. One fin is arranged, a heat conductive copper tube is fixedly connected to the lower end surface of the heat radiation plate, and a heat conductive plate capable of contacting the HDD is fixedly connected to the lower end of the heat conductive copper tube. Two symmetrical slide boxes are fixedly connected to the inner walls on the left and right sides of the vibration suppression space, and a slide space opened in the direction of the center of symmetry is installed in the slide box. A slide rod is slidably connected between the upper and lower inner walls of the space, and the one end surface of the slide rod away from the center of symmetry is vertically symmetrical between the left inner wall or the right inner wall of the vibration suppression space. Two pressure springs are connected, and a spring is connected between the side end surface of the slide rod close to the center of symmetry and the lateral moving box.

Preferably, the pressure spring has a higher elastic modulus than the spring, allowing suppression of secondary vibrations.

The vertical vibration suppression mechanism includes an elevating block fixedly connected to the lower inner wall of the elevating table, and two symmetrical swing rods are connected to the front end surface of the elevating block by a hinge. Two symmetrical vibration suppression blocks are slidably connected to the lower inner wall of the vibration suppression space, and the vibration suppression block is connected to the lower end of the vibration suppression rod by a hinge to be connected to the lower end of the vibration suppression space by a hinge. Two symmetrical blocking blocks are fixedly connected to the end face, the blocking block is located on the side of the vibration suppression block away from the center of symmetry, and between the blocking block and the vibration suppression block. A compression spring is connected, and a vibration suppression spring located symmetrically and distant from the center of symmetry in the shielding block is connected between the lower inner wall of the vibration suppression space and the lift. ..

The HDD fixture includes the fixing box slidably connected to the inner wall of the lateral movement space, and a trapezoidal cam located above the pinhole is fixedly connected to the elevating rod, and the trapezoidal cam is connected to the elevating rod. Two symmetrical slide grooves are formed in the elevating rod, and a push block located between the trapezoidal cam and the pin hole is fixedly connected to the elevating rod, and the push block and the fixed space are fixedly connected. A return spring is connected to the lower inner wall, two symmetrical swing arms are connected to the push block by a hinge, and two symmetrical racks are connected to the lower inner wall of the fixed space. Is slidably connected, the rack is hinged to the lower end of the swing arm, and an insertion spring is connected between the insertion and the side inner wall away from the center of symmetry in the insertion space, under the insertion. A turning rod extending to the outside of the lower end surface of the insertion space is fixedly connected to the side end surface.

Preferably, the slide between the fixed box and the inner wall of the laterally moving space has a certain amount of damping, and after the fixed box is mounted in the laterally moved space, the fixed box and the said fixed box are subjected to external vibration. It is unlikely that the lateral movement space will be displaced relative to each other, and the slide groove and the horizontal plane form a forty-five degree attenuation angle.

The holding claw includes a driven rod fixedly connected to a side end surface close to the center of symmetry in the L-shaped rod, and the L-shaped rod can only move left and right along the rear inner wall of the fixed space. Instead, a sliding wheel slidably connected to the slide groove is connected to the driven rod by a hinge, a short rod is fixedly connected to the lower end surface of the L-shaped rod, and the front end surface of the short rod is fixedly connected. A rotating shaft extending forward is rotatably connected to the rotating shaft, a gear connected so as to mesh with the rack is fixedly connected to the rotating shaft, and a crank located on the front side of the gear is connected to the rotating shaft. Is fixedly connected, a connecting rod is connected to the upper end of the crank with a hinge, and a slider is slidably connected to the side end surface of the L-shaped rod away from the center of symmetry, and is separated from the center of symmetry in the slider. A sub-rack is fixedly connected to the side end surface, the sub-rack and the connecting rod are hinged, the sub-gear is fixedly connected to the gear shaft, and the sub-gear is the rear end face of the rotating space. A rubber block is fixedly connected to both the sandwiching block and the side end surface of the L-shaped rod separated from the center of symmetry, which are located outside and are connected so as to mesh with the sub rack.

The beneficial effect of the present invention is: The HDD fixture of the present invention causes the HDD to push the holding plate and the pushing rod downward, and the insertion mechanism can automatically fix the pushing rod to limit the movement of the holding plate. At the same time, the cam on the push rod drives and moves the holding rod to sandwich the left and right sides of the HDD, and the gear rack mechanism on the holding rod drives and rotates the rotating block to connect the rotating block and the upper end face of the HDD. The HDD can be fixed quickly by making contact, and by manually turning the insertion, the position restriction on the push rod of the insertion mechanism is released, the holding plate and the push rod are restored, the fixed HDD is released, and the HDD can be removed. The HDD fixture can be directly inserted into or removed from the vibration suppression device, so that the present invention is a device that can completely fix the HDD and quickly attach and detach the HDD.

In order to explain the present invention in detail with reference to FIGS. 1 to 4 below and to explain the present invention in a convenient manner, the following directions are defined as follows: FIG. 1 is a front view of the apparatus of the present invention, and is described above and below. The left-right front-back direction and the up-down, left-right front-back direction of the self-projection relationship in FIG. 1 are the same.

FIG. 1 is a schematic diagram of the overall configuration of a protective fixing facility that reduces vibration of the HDD of the present invention. FIG. 2 is a schematic configuration diagram of the hard disk fixture of FIG. FIG. 3 is a schematic configuration diagram from the direction AA of FIG. FIG. 4 is an enlarged schematic view of the configuration of B in FIG.

The present invention relates to a protective fixing facility for reducing vibration to an HDD, and mainly includes a vibration suppression box 11, and a vibration suppression space 12 opened upward is installed in the vibration suppression box 11, and the vibration suppression space 12 A vibration suppressor 101 capable of suppressing vibration is installed in the vibration suppressor 101, and a vertical vibration suppression mechanism 102 capable of suppressing vertical vibration is installed in the vibration suppressor 101. The HDD fixture 103 capable of quickly holding the HDD is slidably connected, and the HDD fixture 103 is installed in the fixed box 21 installed in the vibration suppression space 12 and in the fixed box 21. The fixed space 31 opened upward, the elevating plate 45 slidably connected to the rear inner wall of the fixed space 31, and the fixed space fixedly connected to the lower inner wall of the elevating plate 45 and downward. An elevating rod 46 extending to the outside of the end face of the elevating rod 46, pinholes 54 penetrating left and right installed in the elevating rod 46, and a symmetrical insertion box 56 installed on the lower end surface of the fixed space 31. Including an insertion space 57 installed in the insertion box 56 that opens toward the center of symmetry, and an insertion 59 that is slidably connected into the insertion space 57 and can come into contact with the pinhole 54. The HDD fixture 103 drives and lowers the elevating plate 45 by lowering the HDD by its own weight, further lowers the elevating rod 46, and the insertion 59 quickly comes into contact with the elevating rod 46. The elevating rod 46 is fixed, the HDD can be quickly mounted, and a holding claw 104 capable of holding and fixing the HDD is installed in the HDD fixing device 103, and the holding claw 104 is a holding claw 104. Two symmetrical L-shaped rods 38 slidably connected to the rear inner wall of the fixed space 31, and a rotating space 61 installed in the L-shaped rod 38 that penetrates left and right and opens upward. A gear shaft 43 rotatably connected to the front inner wall of the rotating space 61 and extending to the rear outside the rear end surface of the rotating space 61, and a part thereof fixedly connected to the gear shaft 43. The L-shaped rod 38 is located on both the left and right sides of the elevating plate 45, and the holding claw 104 is located on the side close to the center of symmetry of the L-shaped rod 38, including the sandwiching block 44 located in the rotating space 61. It is possible to sandwich and fix the HDD through the movement to and the rotation of the sandwiching block 44 toward the side close to the center of symmetry.

The vibration suppressor 101 will be described in detail below according to an embodiment, and the vibration suppressor 101 includes an elevating table 19 slidably connected between the left and right inner walls of the vibration suppressing space 12, and the elevating table 19 is included. A lateral moving box 20 is slidably connected to the upper end surface of the above, a lateral moving space 26 opened upward is installed in the lateral moving box 20, and a heat radiating plate 27 is installed in the opening of the lateral moving space 26. Are fixedly connected, eleven fins 28 capable of radiating heat from left to right are arranged on the upper end surface of the heat radiating plate 27, and a heat conductive copper tube 29 is arranged on the lower end surface of the heat radiating plate 27. A heat conductive plate 30 that is fixedly connected and can come into contact with the HDD is fixedly connected to the lower end of the heat conductive copper tube 29, and two symmetrical inner walls on the left side and the right side of the vibration suppression space 12. The slide box 62 is fixedly connected, a slide space 22 opened in the direction of the center of symmetry is installed in the slide box 62, and a slide rod 24 can slide between the upper and lower inner walls of the slide space 22. Two pressure springs 23 that are vertically symmetrical are connected between the one-sided end surface of the slide rod 24 that is separated from the center of symmetry and the left inner wall or the right inner wall of the vibration suppression space 12, and the slide rod 24. A spring 25 is connected between the side end face close to the center of symmetry and the lateral moving box 20.
The vibration in the left-right direction is converted into elastic energy by the compression or tension of the spring 25 and the pressure spring 23, and the vibration can be suppressed.

Advantageously, the pressure spring 23 has a higher elastic modulus than the spring 25, allowing suppression of secondary vibrations.

The vertical vibration suppression mechanism 102 will be described in detail below according to an embodiment, and the vertical vibration suppression mechanism 102 includes an elevating block 18 fixedly connected to the lower inner wall of the elevating table 19, and the elevating block. Two symmetrical vibration rods 17 are connected to the front end surface of 18 by a hinge, and two symmetrical vibration suppression blocks 16 are slidably connected to the lower inner wall of the vibration suppression space 12. The vibration suppression block 16 is connected to the lower end of the swing rod 17 by a hinge, and two symmetrical shielding blocks 14 are fixedly connected to the lower end surface of the vibration suppression space 12, and the shielding block 14 is fixedly connected. Is located on the side of the vibration suppression block 16 away from the center of symmetry, a compression spring 15 is connected between the shielding block 14 and the vibration suppression block 16, and the lower inner wall of the vibration suppression space 12 and the vibration suppression block 16 are connected. A vibration suppression spring 13 that is bilaterally symmetrical and is located on the side away from the center of symmetry in the shielding block 14 is connected to the elevating table 19.
The lift block 19 drives the lift block 18 to move it up and down, the swing rod 17 drives the vibration suppression block 16 to move it, and the vibration in the vertical direction is suppressed by the compression spring 15 and the vibration suppression. It is converted into spring energy with the spring 13 and can suppress vibration.

The HDD fixture 103 will be described in detail below according to an embodiment. The HDD fixture 103 includes the fixing box 21 slidably connected to the inner wall of the lateral moving space 26, and the elevating rod 46 includes the fixing box 21. A trapezoidal cam 47 located above the pin hole 54 is fixedly connected, two symmetrical slide grooves 48 are formed in the trapezoidal cam 47, and the elevating rod 46 is connected to the trapezoidal cam 47. A push block 49 located between the pin hole 54 is fixedly connected, and a return spring 55 is connected between the push block 49 and the lower inner wall of the fixed space 31, and the push block 49 is connected to the push block 49. Two symmetrical swing arms 52 are connected by a hinge, and two symmetrical racks 32 are slidably connected to the lower inner wall of the fixed space 31, and the rack 32 is the swing arm 52 of the swing arm 52. It is connected to the lower end by a hinge, and an insertion spring 60 is connected between the insertion 59 and the inner wall on the side away from the center of symmetry in the insertion space 57, and the lower end surface of the insertion 59 is below the insertion space 57. The turning rod 58 extending to the outside of the side end face is fixedly connected,
The elevating plate 45 is pushed downward by the HDD, and the elevating rod 46 is further driven to move downward, and the insertion 59 is inserted into the pinhole 54 so that the elevating rod 46 can be quickly fixed and at the same time symmetrical. The turning rod 58 is pulled toward a side away from the center, and under the action of the return spring 55, the elevating rod 46 moves upward so that the HDD can be quickly attached and detached.

Beneficially, the slide between the fixed box 21 and the inner wall of the laterally moving space 26 has a constant damping, and after the fixed box 21 is mounted in the laterally moved space 26, external vibrations occur. The fixed box 21 and the lateral movement space 26 are unlikely to be displaced relative to each other, and the slide groove 48 and the horizontal plane form an attenuation angle of 45 degrees.

The holding claw 104 will be described in detail below according to an embodiment, and the holding claw 104 includes a driven rod 51 fixedly connected to a side end surface of the L-shaped rod 38 close to the center of symmetry, and the L-shaped rod 38. The rod 38 has no choice but to move left and right along the rear inner wall of the fixed space 31, and a sliding wheel 50 slidably connected to the slide groove 48 is connected to the driven rod 51 by a hinge, and the L-shape. A short rod 36 is fixedly connected to the lower end surface of the rod 38, a rotating shaft 34 extending forward is rotatably connected to the front end surface of the short rod 36, and the rack 32 is connected to the rotating shaft 34. A gear 33 connected so as to mesh with the gear 33 is fixedly connected, a crank 35 located on the front side of the gear 33 is fixedly connected to the rotating shaft 34, and a conrod 37 is hinged to the upper end of the crank 35. The slider 40 is slidably connected to the side end face of the L-shaped rod 38 away from the center of symmetry, and the sub rack 39 is fixedly connected to the side end face of the slider 40 away from the center of symmetry. The sub-rack 39 and the conrod 37 are hinged, the sub-gear 42 is fixedly connected to the gear shaft 43, the sub-gear 42 is located outside the rear end surface of the rotating space 61, and The rubber block 41 is fixedly connected to the sandwiching block 44 and the side end surface of the L-shaped rod 38 away from the center of symmetry, which are connected so as to mesh with the sub rack 39.
By lowering the elevating rod 46, the driven rod 51 and the L-shaped rod 38 can be moved to a side close to the center of symmetry, enabling pinching and fixing to both the left and right sides of the HDD, and at the same time, the rack 32 It moves to the side away from the center of symmetry and drives and rotates the gear 33, and the sandwiching block 44 rotates downward and cooperates with the elevating plate 45 to enable pinching and fixing of the HDD to both the upper and lower sides. To do.

The procedure for using the protective fixing equipment for reducing the vibration of the HDD of the present invention will be described in detail below with reference to FIGS.

First, the fixed box 21 is not slidably connected to the lateral movement space 26, the elevating block 18 and the push block 49 are at the upper limit positions, and the slide rod 24 and the insertion 59 are maximally displaced close to the center of symmetry. At the position, the L-shaped rod 38 is located at the maximum displacement position away from the center of symmetry, the sub rack 39 is at the lower limit position, and the sandwiching block 44 is at the vertical position.

At the time of operation, the HDD is placed on the elevating plate 45, the elevating plate 45 and the elevating rod 46 are pushed downward, and the insertion 59 is inserted into the pin hole 54 to limit the movement of the elevating rod 46, and at the same time, the elevating rod 46 is a trapezoidal cam. 47 is driven to lower, and the sliding wheel 50 moves along the slide groove 48 to the side close to the center of symmetry, and drives the driven rod 51 and the L-shaped rod 38 to move to the side close to the center of symmetry. The L-shaped rod 38 sandwiches both the left and right sides of the HDD, and at the same time, the elevating rod 46 drives the push block 49 to lower it, and the push block 49 pushes the rack 32 with the swing arm 52 to move it away from the center of symmetry. The rack 32 drives and rotates the gear 33 by meshing connection, the gear 33 drives and rotates the crank 35 and the conrod 37 on the rotating shaft 34, and pushes the sub rack 39 and the slider 40 to rotate the L-shaped rod 38. The sub-rack 39 drives and rotates the sub-gear 42 and the gear shaft 43 by engaging with each other, and the gear shaft 43 drives the sandwiching block 44 to drive the pinching block 44 to rotate along the side end face away from the center of symmetry. Rotate 90 degrees to the side closer to, and cooperate with the elevating plate 45 to enable fixing to both the upper and lower sides of the HDD, and put the fixing box 21 in the lateral movement space 26 to quickly install the HDD at the same time. The upper end surface of the HDD is in contact with the heat conductive plate 30, and the heat conductive plate 30 transmits the amount of heat generated by the HDD to the heat radiating plate 27 and the fins 28 by the heat conductive copper tube 29, increasing the heat radiating area and increasing the heat radiating capacity of the HDD. When the vibration suppression box 11 receives vibration, it absorbs the vibration in the left-right direction by the left-right expansion and contraction movement of the spring 25 and the pressure spring 23 and the left-right movement of the slide 24, and the up-and-down movement of the elevating block 18 and the swing rod 17 Drives the vibration suppression block 16 to move it to the left and right to enable the compression spring 15 to expand and contract left and right, and the vibration suppression spring 13 can absorb the vibration in the vertical direction by the vertical expansion and contraction movement to suppress the vibration. The fixed box 21 is pushed out from the lateral movement space 26, the fixed box 21 is taken out, and the insertion 59 and the pin hole 54 are separated from the connected state by further turning the fixed box 21 to a side away from the center of symmetry and pulling the rod 58. The elevating rod 46 is raised and returned by the return spring 55, and the sandwiched HDD is released so that the HDD can be quickly attached and detached.

The beneficial effect of the present invention is: The HDD fixture of the present invention causes the HDD to push the holding plate and the pushing rod downward, and the insertion mechanism can automatically fix the pushing rod to limit the movement of the holding plate. At the same time, the cam on the push rod drives and moves the holding rod to sandwich the left and right sides of the HDD, and the gear rack mechanism on the holding rod drives and rotates the rotating block to connect the rotating block and the upper end face of the HDD. The HDD can be fixed quickly by making contact, and by manually turning the insertion, the position restriction on the push rod of the insertion mechanism is released, the holding plate and the push rod are restored, the fixed HDD is released, and the HDD can be removed. The HDD fixture can be directly inserted into or removed from the vibration suppression device, so that the present invention is a device that can completely fix the HDD and quickly attach and detach the HDD.

According to the above method, an engineer in this field can make various changes depending on the operation mode within the scope of the present invention.

Claims (7)

A vibration suppression space including a vibration suppression box, which is open upward, is installed in the vibration suppression box, and a vibration suppression device capable of suppressing vibration is installed in the vibration suppression space. A vertical vibration suppression mechanism capable of suppressing vibration in the vertical direction is installed in the vibration suppressor, and an HDD fixture capable of quickly holding an HDD is slidably connected to the vibration suppressor, and the HDD fixture suppresses the vibration. A fixed box installed in the space, an upwardly open fixed space installed in the fixed box, an elevating plate slidably connected to the rear inner wall of the fixed space, and the elevating plate. An elevating rod that is fixedly connected to the lower inner wall and extends downward to the outside of the end face of the fixed space, pinholes that penetrate to the left and right installed in the elevating rod, and the lower side of the fixed space. A symmetrical insertion box installed on the end face, an insertion space opened in the insertion box that opens toward the center of symmetry, and a slideable connection into the insertion space and contact with the pinhole. The HDD fixture drives and lowers the elevating plate by lowering the HDD by its own weight, further lowering the elevating rod, and the insertion quickly abuts on the elevating rod. The elevating rod is fixed, the HDD can be quickly attached, and a holding claw that can hold and fix the HDD is installed in the HDD fixing device.
The holding claws are two symmetrical L-shaped rods slidably connected to the rear inner wall of the fixed space, and a rotation that penetrates left and right and is opened upward in the L-shaped rod. A space, a gear shaft rotatably connected to the front inner wall of the rotating space, and a gear shaft extending rearward outside the rear end surface of the rotating space, and a part thereof fixedly connected to the gear shaft and partially connected to the rotating space. The L-shaped rod is located on both the left and right sides of the elevating plate, and the holding claws move toward the side close to the center of symmetry of the L-shaped rod and the symmetry of the sandwiching block. Protective fixing equipment that reduces vibration to the HDD, which is characterized by enabling the HDD to be sandwiched and fixed through rotation toward the side close to the center. The vibration suppressor includes an elevating table slidably connected between the left and right inner walls of the vibration suppression space, and a lateral moving box is slidably connected to the upper end surface of the elevating table. A lateral moving space opened upward is installed inside, a heat radiating plate is fixedly connected to the opening of the lateral moving space, and heat can be dissipated from left to right on the upper end surface of the heat radiating plate. One fin is arranged, a heat conductive copper tube is fixedly connected to the lower end surface of the heat radiation plate, and a heat conductive plate capable of contacting the HDD is fixedly connected to the lower end of the heat conductive copper tube. Two symmetrical slide boxes are fixedly connected to the inner walls on the left and right sides of the vibration suppression space, and a slide space opened in the direction of the center of symmetry is installed in the slide box. A slide rod is slidably connected between the upper and lower inner walls of the space, and the one end surface of the slide rod away from the center of symmetry is vertically symmetrical between the left inner wall or the right inner wall of the vibration suppression space. The vibration with respect to the HDD according to claim 1, wherein two pressure springs are connected, and a spring is connected between the side end surface of the slide rod close to the center of symmetry and the lateral moving box. Protective fixing equipment to let. The protective fixing facility for reducing vibration to an HDD according to claim 2, wherein the pressure spring has a larger elastic modulus than the spring and enables suppression of secondary vibration. The vertical vibration suppression mechanism includes an elevating block fixedly connected to the lower inner wall of the elevating table, and two symmetrical swing rods are connected to the front end surface of the elevating block by a hinge. Two symmetrical vibration suppression blocks are slidably connected to the lower inner wall of the vibration suppression space, and the vibration suppression block is connected to the lower end of the vibration suppression rod by a hinge to be connected to the lower end of the vibration suppression space by a hinge. Two symmetrical blocking blocks are fixedly connected to the end face, the blocking block is located on the side of the vibration suppression block away from the center of symmetry, and between the blocking block and the vibration suppression block. A compression spring is connected, and a vibration suppression spring located symmetrically and away from the center of symmetry in the shielding block is connected between the lower inner wall of the vibration suppression space and the lift. The protective fixing device according to claim 2, wherein the vibration to the HDD is reduced. The HDD fixture includes the fixing box slidably connected to the inner wall of the lateral movement space, and a trapezoidal cam located above the pinhole is fixedly connected to the elevating rod, and the trapezoidal cam is connected to the elevating rod. Two symmetrical slide grooves are formed in the elevating rod, and a push block located between the trapezoidal cam and the pin hole is fixedly connected to the elevating rod, and the push block and the fixed space are fixedly connected. A return spring is connected to the lower inner wall, two symmetrical swing arms are connected to the push block by a hinge, and two symmetrical racks are connected to the lower inner wall of the fixed space. Is slidably connected, the rack is hinged to the lower end of the swing arm, and an insertion spring is connected between the insertion and the side inner wall away from the center of symmetry in the insertion space, under the insertion. The protective fixing device according to claim 2, wherein a turning rod extending to the outside of the lower end surface of the insertion space is fixedly connected to the side end surface. The slide between the fixed box and the inner wall of the lateral movement space has a certain damping, and after the fixed box is mounted in the lateral movement space, the fixed box and the lateral movement space are subjected to external vibration. The protective fixing device according to claim 5, wherein the slide groove and the horizontal plane form an angle of 45 degrees with a low possibility of relative displacement. The holding claw includes a driven rod fixedly connected to a side end surface of the L-shaped rod close to the center of symmetry, and the L-shaped rod can only move left and right along the rear inner wall of the fixed space. Instead, a sliding wheel slidably connected to the slide groove is connected to the driven rod by a hinge, and a short rod is fixedly connected to the lower end surface of the L-shaped rod, and the front end surface of the short rod is connected. A rotating shaft extending forward is rotatably connected to the rotating shaft, a gear connected so as to mesh with the rack is fixedly connected to the rotating shaft, and a crank located on the front side of the gear is connected to the rotating shaft. Is fixedly connected, a connecting rod is hinged to the upper end of the crank, and a slider is slidably connected to the side end surface of the L-shaped rod away from the center of symmetry, and away from the center of symmetry in the slider. A sub-rack is fixedly connected to the side end surface, the sub-rack and the connecting rod are hinged, a sub-gear is fixedly connected to the gear shaft, and the sub-gear is the rear end face of the rotating space. It is characterized in that the rubber block is fixedly connected to both the sandwiching block and the side end surface of the L-shaped rod away from the center of symmetry, which are located outside and are connected so as to mesh with the sub rack. The protective fixing equipment for reducing the vibration of the HDD according to claim 6.

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