High-stability big data server terminal

Abstract

The application relates to the technical field of server terminals, and discloses a high-stability big-data server terminal which comprises a protective shell, a fixing device, a buffer device, a driving device and a movable plate, characterized in that the buffer device is provided with two buffer devices which are fixedly connected to the left side and the right side in the interior of the protective shell respectively, the buffer device is provided with a supporting rod, an expansion piece and a buffer piece, the buffer device is fixedly connected to the bottom of the fixing device, the fixing device is connected to the interior of the protective shell through the buffer device, the fixing device is composed of a fixing block, a movable rod and a fixing clamp, the driving device is arranged on the left side and the right side of the top layer of the interior of the protective shell, the driving device is provided with a driving motor, a guide rod and a push rod, the driving device is externally connected with a power supply, and the device has the advantages of improving the fixing effect, reducing the vibration, reducing the influence of the collision and force of external objects, spontaneously detecting the heat dissipation, improving the operation stability and the like.

Description

Technical Field

[0001] This invention relates to the field of server terminal technology, specifically to a highly stable big data server terminal. Background Technology

[0002] With the development of technology and the improvement of people's living standards, the application scenarios of server terminals are becoming more and more diverse. A server terminal is hardware that connects serial devices on a network. It can be used as a connection point for endpoints to connect to a local area network or a wide area network, allowing users to log in and access remote computers anytime and anywhere. It has strong processing power, stability, reliability, security, scalability, and manageability.

[0003] Existing server terminals consist of components such as CPU, memory, hard drive, and RAID card. During operation, the device vibrates. If the server terminal is not properly secured or there are gaps in the fixation, the vibration can cause the bottom of the server terminal to collide, leading to server terminal failure and inability to operate normally, reducing the stability of the device. After prolonged operation, the server terminal generates a lot of heat. If heat is not dissipated in time, it will lead to a decrease in the operating efficiency of the server terminal or failure. Existing heat dissipation devices use cooling fans to dissipate heat internally. In actual use, the heat dissipation on the surface of the server terminal is slow, which is not conducive to the stable daily operation of the server terminal. Summary of the Invention

[0004] Existing server terminals, composed of components such as CPU, memory, hard drive, and RAID card, experience vibrations during operation. If the server terminal is not properly secured or has gaps in its fixation, this vibration can cause the bottom surface of the server to collide, leading to malfunctions and reduced stability. Furthermore, prolonged operation generates significant heat; insufficient heat dissipation can result in decreased efficiency or malfunctions. Current cooling systems, which use internal cooling fans, suffer from slow heat dissipation on the server terminal surface, hindering stable daily operation. This invention provides a highly stable big data server terminal with advantages such as improved fixation, reduced vibration and impact from external objects, and self-detected heat dissipation for enhanced operational stability.

[0005] To achieve the above objectives, the present invention provides the following technical solution: a highly stable big data server terminal, comprising: a protective shell, a bracket, a server terminal, a control center, a groove, a slide, a temperature sensor, a fixing device, a fixing block, a first spring, a movable rod, a clamping plate, a fixing clamp, a movable clamp, a tightening bolt, a rubber ring, a connecting column, a support rod, a telescopic component, a buffer component, a receiving rod, a clamping component, a second spring, a clamping rod, a partition, a cooling fan, a driving device, a driving motor, a guide rod, a through hole, a screw, a limit rod, a push rod, an internal threaded hole, a movable plate, a connecting rod, and a slider.

[0006] The positions and connections of the above structures are as follows: A high-stability big data server terminal includes a protective shell, a fixing device, a buffer device, a drive device, and a movable plate. Two buffer devices are provided, which are fixedly connected to the left and right sides inside the protective shell, respectively. The buffer device is provided with a support rod, a telescopic component, and a buffer component. The buffer device is fixedly connected to the bottom of the fixing device. The fixing device is connected to the inside of the protective shell through the buffer device. The fixing device consists of a fixing block, a movable rod, and a fixing clamp. The drive device is located on the left and right sides of the top layer inside the protective shell. The drive device is provided with a drive motor, a guide rod, and a push rod. The drive motor is connected to an external power supply.

[0007] Preferably, the protective shell has a support at its bottom, which is fixedly connected to the protective shell. A server terminal is located inside the protective shell, and a control center is located at the front end and bottom layer of the protective shell. The control center is connected to an external power supply. A groove is located at the top of the protective shell, extending through the top to the interior. Sliding grooves are provided at both the front and rear ends of the groove, and through slots are provided on both the left and right sides of the groove. A temperature sensor is located inside the protective shell, positioned on the outer surface of the front end of the fixed device. The temperature sensor is electrically connected to the control center. The support is used to maintain the balance and stability of the device. The temperature sensor is used to continuously monitor the temperature of the server terminal. The groove is used to cooperate with the movable plate to control the drive device to adjust the position of the movable plate when the device detects that the temperature has risen to a certain limit, ensuring the normal operation of the device.

[0008] Preferably, the fixing device has fixing blocks at both the front and rear ends. A first spring is located at the end of the fixing block furthest from the server terminal, and the first spring is fixedly connected to the inside of the fixing block. A locking plate is located at the end of the first spring closest to the server terminal, and a movable rod is located at the end of the locking plate furthest from the first spring. The movable rod is sleeved inside the fixing block, and a fixing clamp is located at the end of the movable rod closest to the server terminal, and the fixing clamp is fixedly connected to the movable rod. When the fixing clamp clamps and fixes the server terminal, the movable rod is pushed outward by the server terminal and moves inward into the fixing block. The movement of the movable rod drives the locking plate to move, and the movement of the locking plate compresses the first spring, causing it to elastically deform. The elastic force generated by the elastic deformation of the first spring buffers the vibration when the server terminal vibrates during operation. Simultaneously, the elastic force acts in the opposite direction on the movable rod and the fixing clamp to fix and clamp the server terminal, improving the fixing effect and preventing unstable connections between the server terminals during normal operation from causing damage, operational errors, or malfunctions, thus improving the stability of the server terminal operation.

[0009] Preferably, the fixed clamp has a movable clamp at its bottom, which is fitted inside the fixed clamp. A tensioning bolt is located at the end of the fixed clamp near the server terminal. The movable clamp is movably connected to the fixed clamp via the tensioning bolt. Several rubber rings are located at the bottom of the fixing device, and these rubber rings are fixedly connected to the bottom of the fixing device. When the server terminal is placed inside the fixing device, the tensioning bolt is loosened to allow the movable clamp to extend and retract at the bottom of the fixed clamp. After placing the server terminal on top of the movable clamp, the movable clamp is adjusted to tighten the server terminal using both the movable and fixed clamps. Then, the tensioning bolt is tightened to secure it. This design allows for easy installation and disassembly of the server terminal in case of malfunction, and also enables the installation of server terminals of different sizes, improving the applicability of the device.

[0010] Preferably, the buffer device has support rods on both the left and right sides of its top, which are fixedly connected to the buffer device. A telescopic component, shaped like a "∪", is provided at the top of the support rod and is fixedly connected to the support rod. A buffer component, shaped like a "∩", is provided at the top of the telescopic component. Receiving rods are provided on both the left and right sides of the bottom of the buffer component. The protrusion at the top of the telescopic component fits inside the receiving rod. A second spring is provided between the left and right receiving rods, with its top and bottom fixedly connected to the bottom of the buffer component and the top of the telescopic component. The outer surfaces of both the buffer component and the telescopic component are provided with… It has a locking mechanism and a locking rod. The locking rod is movably connected between the locking mechanisms on the upper and lower sides. When an external object collides with the protective shell or an external force acts on it, the telescopic component moves towards the receiving rod through the locking mechanism and the locking rod. The second spring at the top of the telescopic component undergoes elastic deformation and generates elastic force when the telescopic rod retracts into the receiving rod. The elastic force generated by the second spring buffers the vibration. When the second spring returns to its original shape, it causes the telescopic component to extend out of the receiving rod and return to its original shape. This reduces the adverse effects of external object collisions or external forces acting on the protective shell on the server terminal, which may lead to server terminal failure and unstable operation, and improves the stability of the device operation.

[0011] Preferably, the buffer device has a partition at one end near the control center, and a cooling fan is installed inside the partition. The cooling fan is electrically connected to the control center. When the temperature sensor detects that the temperature on the server terminal has risen to a predetermined value, the temperature sensor converts it into an electrical signal and transmits it to the control center. The control center controls the drive motor to move the movable plate so that the protective shell no longer forms a closed space. At the same time, the control center controls the cooling fan to turn on to dissipate heat and blow it into the groove, preventing the server terminal from overheating and causing the device to malfunction, thus improving the stability of the device operation.

[0012] Preferably, the drive device is internally equipped with a drive motor, which is electrically connected to the control center. A guide rod is located at the end of the drive device closest to the server terminal, and the guide rod is fixedly connected to the drive device. A through hole is located at the end of the guide rod furthest from the drive motor. A screw is located at the end of the drive motor closest to the server terminal. A limit rod is located at the end of the screw furthest from the drive motor. A push rod is located at the end of the limit rod furthest from the screw. Both the limit rod and the push rod have internal threaded holes at their ends closest to the screw. The limit rod and the push rod are movably connected to the screw through the internal threaded holes. The control center controls the drive motor to drive the screw to rotate forward. The forward rotation of the screw causes the limit rod and the push rod to move along the guide tube in a direction furthest from the server terminal, providing power for heat dissipation and preventing the server terminal from failing to operate normally due to temperature issues. The limit rod, the push rod, and the internal threaded holes form a self-locking structure with the screw. The limit rod limits the maximum distance the push rod and the movable rod can move, and the guide tube guides the direction of movement of the push rod and the movable plate.

[0013] Preferably, a connecting rod is provided at the top of the push rod, and the connecting rod is fixedly connected to the push rod. A movable plate is provided at the top of the connecting rod. Slider blocks are provided on the outer surfaces of the front and rear ends of the movable plate. The movable plate is movably connected to the slide groove through the sliders. The movable plate is fitted into the through slots at both ends of the slide groove. When the push rod moves downward along the guide rod, the movable plate moves into the through slots provided in the groove through the sliders and slide groove under the drive of the push rod. The movable plate is retracted, so that the protective shell is no longer a closed space. The cooling fan turns on and blows the heat of the server terminal out through the groove. When the temperature sensor detects that the temperature of the server terminal has returned to normal, it stops transmitting electrical signals. The control center controls the drive motor to drive the screw to reverse. The screw reverses and drives the push rod and the movable plate to move along the guide tube and extend through the through hole to close the two movable plates. The protective shell re-forms a closed space to protect the server terminal. The device can automatically dissipate heat to ensure the device can operate normally with high stability and improve the heat dissipation performance of the device. Beneficial effects

[0014] 1. This highly stable big data server terminal has fixing blocks at both the front and rear ends of the fixing device. A first spring is installed at the end of the fixing block away from the server terminal, and the first spring is fixedly connected to the inside of the fixing block. A locking plate is installed at the end of the first spring near the server terminal, and a movable rod is installed at the end of the locking plate away from the first spring. The movable rod is sleeved inside the fixing block, and a fixing clamp is installed at the end of the movable rod near the server terminal. The fixing clamp is fixedly connected to the movable rod, which improves the fixing effect and prevents the server terminal from being damaged by bumps or collisions due to unstable connection during normal operation vibration, resulting in operational errors or failure to operate normally, thus improving the stability of the server terminal operation.

[0015] 2. This highly stable big data server terminal features support rods on both the left and right sides of the top of the buffer device, which are fixedly connected to the buffer device. A telescopic component, shaped like a "∪", is located at the top of the support rod and is also fixedly connected to the support rod. A buffer component, shaped like a "∩", is located at the top of the telescopic component. Receiving rods are located on both the left and right sides of the bottom of the buffer component. The protrusion at the top of the telescopic component fits inside the receiving rod. A second spring is located between the receiving rods on both sides, with its top and bottom fixedly connected to the bottom of the buffer component and the top of the telescopic component. Clamps and levers are located on the outer surfaces of both sides of the buffer component and the telescopic component. The levers are movably connected between the clamps on the upper and lower sides. This design reduces the adverse effects of external objects colliding with or exerting external forces on the protective shell, preventing server terminal malfunctions and unstable operation, thus improving the stability of the device.

[0016] 3. This high-stability big data server terminal has a connecting rod at the top of the push rod, which is fixedly connected to the push rod. A movable plate is set at the top of the connecting rod. Sliders are set on the outer surfaces of the front and rear ends of the movable plate. The movable plate is movably connected to the slide groove through the sliders. The movable plate is fitted into the through grooves at both ends of the slide groove, so that the device can automatically dissipate heat to ensure the device can operate normally with high stability and improve the heat dissipation performance of the device. Attached Figure Description

[0017] Figure 1 This is a schematic diagram of the external structure of a high-stability big data server terminal according to the present invention;

[0018] Figure 2 This is a schematic diagram of the internal structure of a highly stable big data server terminal according to the present invention;

[0019] Figure 3 This is a schematic diagram of a high-stability big data server terminal fixing device according to the present invention;

[0020] Figure 4 This is a schematic diagram of a high-stability big data server terminal buffer device according to the present invention.

[0021] Figure 5 This is a schematic diagram of a high-stability big data server terminal driver device according to the present invention;

[0022] Figure 6 This is a schematic diagram of a high-stability big data server terminal slide structure according to the present invention;

[0023] Figure 7 This is a schematic diagram of the active board structure of a high-stability big data server terminal according to the present invention.

[0024] In the diagram: 1. Protective casing; 10. Bracket; 11. Server terminal; 12. Control center; 13. Groove; 130. Slide groove; 14. Temperature sensor; 2. Fixing device; 20. Fixing block; 200. First spring; 21. Movable rod; 210. Clamping plate; 22. Fixing clamp; 220. Movable clamp; 23. Tightening bolt; 24. Rubber ring; 3. Buffer device; 30. Support rod; 31. Telescopic component; 32. Buffer component; 320. Receiving rod; 33. Clamping component; 34. Second spring; 35. Clamping rod; 4. Partition plate; 40. Cooling fan; 5. Drive device; 50. Drive motor; 51. Guide rod; 510. Through hole; 52. Screw; 53. Limiting rod; 530. Push rod; 54. Internal threaded hole; 6. Movable plate; 60. Connecting rod; 61. Slider. Detailed Implementation

[0025] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention. Example 1

[0026] Please see Figure 1-7 A highly stable big data server terminal 11 includes a protective shell 1, a fixing device 2, a buffer device 3, a drive device 5, and a movable plate 6. The buffer device 3 is characterized by having two units, fixedly connected to the left and right sides inside the protective shell 1 respectively. Each buffer device 3 includes a support rod 30, a telescopic component 31, and a buffer component 32. The buffer device 3 is fixedly connected to the bottom of the fixing device 2, which is connected to the interior of the protective shell 1 via the buffer device 3. The fixing device 2 consists of a fixing block 20, a movable rod 21, and a fixing clamp 22. The drive device 5 is located on the left and right sides of the top layer inside the protective shell 1. The drive device 5 includes a drive motor 50, a guide rod 51, and a push rod 530. The drive motor 50 is externally powered. A bracket 10 is fixedly connected to the bottom of the protective shell 1. The protective casing 1 houses a server terminal 11. A control center 12 is located at the front end and bottom layer of the protective casing 1, and is powered by an external power source. A groove 13 extends from the top of the protective casing 1 to its interior. Slide grooves 130 are provided at both the front and rear ends of the groove 13. Through grooves are provided on both the left and right sides of the groove 13. A temperature sensor 14 is located inside the protective casing 1 and is mounted on the outer surface of the front end of the fixing device 2. The temperature sensor 14 is electrically connected to the control center 12. A bracket 10 is used to maintain the balance and stability of the device. The temperature sensor 14 is used to continuously monitor the temperature of the server terminal 11. The groove 13, in conjunction with the movable plate 6, controls the drive device 5 to adjust the position of the movable plate 6 when the device detects that the temperature has risen to a certain limit, ensuring the normal operation of the device.

[0027] Fixing devices 2 have fixing blocks 20 at both the front and rear ends. A first spring 200 is located at the end of each fixing block 20 furthest from the server terminal 11, and is fixedly connected to the fixing block 20. A locking plate 210 is located at the end of the first spring 200 closest to the server terminal 11, and a movable rod 21 is located at the end of the locking plate 210 furthest from the first spring 200. The movable rod 21 is sleeved inside the fixing block 20. A fixing clip 22 is located at the end of the movable rod 21 closest to the server terminal 11, and is fixedly connected to the movable rod 21. When the fixing clip 22 clamps and fixes the server terminal 11, the movable rod 21 is subjected to force from the server terminal 11. The outward squeezing force moves the movable rod 21 towards the interior of the fixed block 20, causing the clamping plate 210 to move. The movement of the clamping plate 210 compresses the first spring 200, causing it to undergo elastic deformation. The elastic force generated by the elastic deformation of the first spring 200 buffers the vibration when the server terminal 11 vibrates during operation. At the same time, the elastic force acts in the opposite direction on the movable rod 21 and the fixed clamp 22 to clamp and fix the server terminal 11, improving the fixing effect and preventing the server terminal 11 from being damaged by bumps or malfunctions or failing to operate normally due to unstable connections during normal operation vibration, thus improving the stability of the server terminal 11 operation.

[0028] A movable clip 220 is provided at the bottom of the fixed clip 22, and the movable clip 220 is sleeved inside the fixed clip 22. A tightening bolt 23 is provided at the end of the fixed clip 22 near the server terminal 11. The movable clip 220 is movably connected to the fixed clip 22 through the tightening bolt 23. Several rubber rings 24 are provided at the bottom of the fixed device 2. The rubber rings 24 are fixedly connected to the bottom of the fixed device 2. When the server terminal 11 is placed inside the fixed device 2, the tightening bolt 23 is loosened to allow the movable clip 220 to move back and forth at the bottom of the fixed clip 22. After the server terminal 11 is placed on top of the movable clip 220, the movable clip 220 is adjusted to tighten the server terminal 11 with the fixed clip 220. Then the tightening bolt 23 is tightened to fix it. This allows for easy installation and disassembly of the server terminal 11 in case of failure, and also allows for the installation of server terminals 11 of different sizes, improving the applicability of the device. Example 2

[0029] Please see Figure 1-4Further, based on Embodiment 1, support rods 30 are provided on both the left and right sides of the top of the buffer device 3. The support rods 30 are fixedly connected to the buffer device 3. A telescopic member 31 is provided on the top of the support rod 30. The telescopic member 31 is shaped like a "∪". The telescopic member 31 is fixedly connected to the support rod 30. A buffer member 32 is provided on the top of the telescopic member 31. The buffer member 32 is shaped like a "∩". Receiving rods 320 are provided on both the left and right sides of the bottom of the buffer member 32. The protrusion on the top of the telescopic member 31 is sleeved inside the receiving rod 320. A second spring 34 is provided between the left and right receiving rods 320. The top of the second spring 34 is fixedly connected to the bottom of the buffer member 32. The bottom of the second spring 34 is fixedly connected to the top of the telescopic member 31. The buffer member 32 and the telescopic member 31 are... Both the left and right outer surfaces are provided with clips 33 and clips 35. The clips 35 are movably connected between the clips 33 on the upper and lower sides. When an object collides or an external force acts on the protective shell 1, the telescopic member 31 moves towards the receiving rod 320 through the clips 33 and clips 35. The second spring 34 at the top of the telescopic member 31 undergoes elastic deformation and generates elastic force when the telescopic rod retracts into the receiving rod 320. The elastic force generated by the second spring 34 buffers the vibration. When the second spring 34 returns to its original shape, it drives the telescopic member 31 to extend out of the receiving rod 320 and return to its original shape. This reduces the adverse effects of external objects colliding or external forces acting on the protective shell 1 on the server terminal 11, which may cause the server terminal 11 to malfunction and become unstable, thus improving the stability of the device operation. Example 3

[0030] Please see Figure 1-7 Furthermore, based on Embodiment 2, a partition 4 is provided at one end of the buffer device 3 near the control center 12. A cooling fan 40 is provided inside the partition 4. The cooling fan 40 is electrically connected to the control center 12. When the temperature sensor 14 detects that the temperature on the server terminal 11 has risen to a predetermined value, the temperature sensor 14 converts it into an electrical signal and transmits it to the control center 12. The control center 12 controls the drive motor 50 to move the movable plate 6 so that the protective shell 1 no longer forms a closed space. At the same time, the control center 12 controls the cooling fan 40 to turn on to dissipate heat and blow it to the groove 13, preventing the server terminal 11 from overheating and causing the device to malfunction, thus improving the stability of the device operation.

[0031] The drive unit 5 houses a drive motor 50, which is electrically connected to the control center 12. A guide rod 51 is located at the end of the drive unit 5 closest to the server terminal 11, and is fixedly connected to the drive unit 5. A through hole 510 is located at the end of the guide rod 51 furthest from the drive motor 50. A screw 52 is located at the end of the drive motor 50 closest to the server terminal 11. A limit rod 53 is located at the end of the screw 52 furthest from the drive motor 50. A push rod 530 is located at the end of the limit rod 53 furthest from the screw 52. Both the limit rod 53 and the push rod 530 have internal threaded holes 54 at their ends closest to the screw 52. The limiting rod 53 and the push rod 530 are movably connected to the screw 52 through the internal threaded hole 54. The control center 12 controls the drive motor 50 to drive the screw 52 to rotate forward. The forward rotation of the screw 52 drives the limiting rod 53 and the push rod 530 to move along the guide tube in a direction away from the server terminal 11, providing power for heat dissipation of the device and preventing the server terminal 11 from failing to operate normally due to temperature. The limiting rod 53, the push rod 530 and the internal threaded hole 54 form a self-locking structure with the screw 52. The limiting rod 53 is used to limit the maximum distance of movement of the push rod 530 and the movable rod 21. The guide tube is used to guide the direction of movement of the push rod 530 and the movable plate 6.

[0032] A connecting rod 60 is provided at the top of the push rod 530, and the connecting rod 60 is fixedly connected to the push rod 530. A movable plate 6 is provided at the top of the connecting rod 60. Slider 61 is provided on the outer surfaces of the front end and the left and right sides of the rear end of the movable plate 6. The movable plate 6 is movably connected to the slide groove 130 through the slider 61. The movable plate 6 is fitted into the through grooves at the left and right ends inside the slide groove 130. When the push rod 530 moves downward along the guide rod 51, the movable plate 6 moves into the through groove inside the groove 13 through the slider 61 and the slide groove 130 under the drive of the push rod 530, so that the protective shell 1 is no longer In the enclosed space, the cooling fan 40 turns on to blow the heat of the server terminal 11 out through the groove 13. When the temperature sensor 14 detects that the temperature of the server terminal 11 has returned to normal, it stops transmitting electrical signals. The control center 12 controls the drive motor 50 to drive the screw 52 to reverse. The reverse rotation of the screw 52 drives the push rod 530 and the movable plate 6 to move along the guide tube and extend through the through hole 510. The movable plates 6 on both sides close together, and the protective shell 1 re-forms an enclosed space to protect the server terminal 11. This allows the device to automatically dissipate heat to ensure the device can operate normally with high stability and improve the heat dissipation performance of the device.

[0033] Working principle: When the fixing clamp 22 clamps and fixes the server terminal 11, the movable rod 21 is pushed outward by the server terminal 11 and moves inward toward the fixing block 20. The movement of the movable rod 21 drives the clamping plate 210 to move. The movement of the clamping plate 210 compresses the first spring 200, causing the first spring 200 to undergo elastic deformation. The elastic force generated by the elastic deformation of the first spring 200 buffers the vibration when the server terminal 11 vibrates during operation. When an object collides or an external force acts on the protective shell 1, the telescopic member 31 moves inward toward the receiving part through the clamping member 33 and the clamping rod 35. When the rod 320 moves in the direction of the telescopic component 31, the second spring 34 at the top of the telescopic component 31 undergoes elastic deformation and generates elastic force when the telescopic rod retracts to accommodate the rod 320. The elastic force generated by the second spring 34 buffers the vibration. When the temperature sensor 14 detects that the temperature on the server terminal 11 has risen to a predetermined value, the temperature sensor 14 converts it into an electrical signal and transmits it to the control center 12. The control center 12 controls the drive motor 50 to move the movable plate 6 so that the protective shell 1 no longer forms a closed space. At the same time, the control center 12 controls the cooling fan 40 to turn on to dissipate heat and blow the heat to the groove 13.

[0034] Although embodiments of the invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A highly stable big data server terminal, comprising a protective shell (1), a fixing device (2), a buffer device (3), a driving device (5), and a movable plate (6), characterized in that: Two buffer devices (3) are provided, and the buffer devices (3) are fixedly connected to the left and right sides inside the protective shell (1) respectively. The buffer device (3) is provided with a support rod (30), a telescopic component (31) and a buffer component (32). The buffer device (3) is fixedly connected to the bottom of the fixing device (2). The fixing device (2) is connected to the inside of the protective shell (1) through the buffer device (3). The fixing device (2) is composed of a fixing block (20), a movable rod (21) and a fixing clamp (22). The driving device (5) is provided on the left and right sides of the top layer inside the protective shell (1). The device is equipped with a drive motor (50), a guide rod (51), and a push rod (530). The drive motor (50) is connected to an external power supply. The fixing device (2) has a fixing block (20) at both the front and rear ends. A first spring (200) is provided at the end of the fixing block (20) away from the server terminal (11). The first spring (200) is fixedly connected to the inside of the fixing block (20). A card plate (210) is provided at the end of the first spring (200) near the server terminal (11). A movable rod (21) is provided at the end of the card plate (210) away from the first spring (200). 21) The movable rod (21) is fitted inside the fixed block (20). A fixed clip (22) is provided at the end of the movable rod (21) near the server terminal (11). The fixed clip (22) is fixedly connected to the movable rod (21). Support rods (30) are provided on both the left and right sides of the top of the buffer device (3). The support rods (30) are fixedly connected to the buffer device (3). A telescopic component (31) is provided at the top of the support rod (30). The telescopic component (31) is set in the shape of "∪". The telescopic component (31) is fixedly connected to the support rod (30). A buffer component (32) is provided at the top of the telescopic component (31). The buffer component (32) is set in the shape of "∪". The buffer (32) is shaped like a "∩". Both sides of the bottom of the buffer (32) are provided with receiving rods (320). The protrusion at the top of the telescopic member (31) is fitted inside the receiving rods (320). A second spring (34) is provided between the receiving rods (320) on the left and right sides. The top of the second spring (34) is fixedly connected to the bottom of the buffer (32), and the bottom of the second spring (34) is fixedly connected to the top of the telescopic member (31). Both sides of the outer surfaces of the buffer (32) and the telescopic member (31) are provided with clips (33) and clips (35). The clips (35) are movably connected between the clips (33) on the upper and lower sides.

2. The highly stable big data server terminal according to claim 1, characterized in that: The protective shell (1) is provided with a bracket (10) at the bottom, and the bracket (10) is fixedly connected to the protective shell (1). The protective shell (1) is provided with a server terminal (11) inside. The protective shell (1) is provided with a control center (12) at the front end and the bottom of the inner layer. The control center (12) is connected to an external power supply. The protective shell (1) is provided with a groove (13) at the top. The groove (13) penetrates the top of the protective shell (1) to the inside. The groove (13) is provided with a sliding groove (130) at the front end and the rear end. The groove (13) is provided with a through groove on the left and right sides. The protective shell (1) is provided with a temperature sensor (14) inside. The temperature sensor (14) is provided on the outer surface of the front end of the fixing device (2). The temperature sensor (14) is electrically connected to the control center (12).

3. The high-stability big data server terminal according to claim 1, characterized in that: The fixed clamp (22) has a movable clamp (220) at its bottom. The movable clamp (220) is fitted inside the fixed clamp (22). The fixed clamp (22) has a tightening bolt (23) at one end near the server terminal (11). The movable clamp (220) is movably connected to the fixed clamp (22) through the tightening bolt (23). The bottom layer of the fixing device (2) has several rubber rings (24). The rubber rings (24) are fixedly connected to the bottom of the fixing device (2).

4. A highly stable big data server terminal according to claim 1, characterized in that: The buffer device (3) has a partition (4) at one end near the control center (12), and a cooling fan (40) is installed inside the partition (4). The cooling fan (40) is electrically connected to the control center (12).

5. A highly stable big data server terminal according to claim 1, characterized in that: The drive device (5) is equipped with a drive motor (50) inside. The drive motor (50) is electrically connected to the control center (12). A guide rod (51) is provided at one end of the drive device (5) near the server terminal (11). The guide rod (51) is fixedly connected to the drive device (5). A through hole (510) is provided at one end of the guide rod (51) away from the drive motor (50). A screw (52) is provided at one end of the drive motor (50) near the server terminal (11). A limit rod (53) is provided at one end of the screw (52) away from the drive motor (50). A push rod (530) is provided at one end of the limit rod (53) away from the screw (52). An internal thread hole (54) is provided at one end of the limit rod (53) and the push rod (530) near the screw (52). The limit rod (53) and the push rod (530) are movably connected to the screw (52) through the internal thread hole (54).

6. A highly stable big data server terminal according to claim 5, characterized in that: The push rod (530) is provided with a connecting rod (60) at the top. The connecting rod (60) is fixedly connected to the push rod (530). The connecting rod (60) is provided with a movable plate (6) at the top. The movable plate (6) is provided with sliders (61) on the outer surfaces of the front and rear ends. The movable plate (6) is movably connected to the slide groove (130) through the sliders (61). The movable plate (6) is fitted into the through grooves at the left and right ends inside the slide groove (130).

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