Memory fixing structure
By adjusting the batch fixing components and guide holes, the problem of poor compatibility of existing memory fixing structures is solved, achieving simultaneous fixing and heat dissipation of multiple memories, and reducing costs and resource consumption.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHANGHAI OBIT AEROSPACE TECH CO LTD
- Filing Date
- 2025-07-08
- Publication Date
- 2026-07-07
AI Technical Summary
Existing memory mounting structures have poor compatibility, making it difficult to adapt to memory of different specifications and unable to mount multiple memory devices simultaneously, resulting in frequent fixture changes, increased costs, and resource consumption.
The system employs a batch fixing assembly, using screws and pressure plates to secure memory modules of different sizes. Multiple memory modules can be fixed simultaneously using multiple support plates. The spacing between the pressure plates can be adjusted using guide holes, and the system incorporates protective pads and heat-conducting holes to improve compatibility and heat dissipation.
It improves the compatibility of memory mounting structures, reduces manufacturing costs and resource consumption, enables the simultaneous mounting of multiple memories, and enhances the mounting effect and heat dissipation performance.
Smart Images

Figure CN224472195U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of fixed structure technology, and in particular relates to a memory fixed structure. Background Technology
[0002] Memory is a hardware device in a computer system used to store program instructions, data, and processing results; it's like the computer's "memory warehouse." The core function of memory is to ensure that the computer can efficiently access information and support the operation of the entire system. There are many types of memory, with the hard drive used in computers being one of the most common.
[0003] When a memory is in use, it needs to be fixed to prevent vibration from causing poor contact or damage. There are many types of fixing structures on the market. For example, a memory fixing device with publication number CN106557129B is disclosed on the Chinese Patent Network. This fixing device can be used to fix memory, but it has some defects and shortcomings that need to be improved: (1) Most of the existing fixing structures are designed for specific sizes, with poor compatibility. They are often difficult to adapt to memory of different specifications and require frequent replacement of the corresponding size clamps, which not only reduces efficiency but also limits the scope of use of the entire fixing structure; (2) Due to structural design, most of the existing fixing structures can only fix a single memory. When multiple memory needs to be fixed, multiple fixing structures are often required, which increases manufacturing costs and resource consumption. Moreover, the fixing must be done one by one in sequence, and multiple memory cannot be fixed at the same time, which is cumbersome and inconvenient. Therefore, the memory fixing structure provided by this utility model is of great significance in addressing the above problems. Utility Model Content
[0004] This invention provides a memory fixing structure. The pressure applied by the pressure plate in the batch fixing assembly firmly presses the memory against the tray, achieving a fixing effect. Moving the screw up and down along the guide hole moves the pressure plate up and down as well, allowing adjustment of the distance between the pressure plate and the tray according to the memory's thickness. This effectively fixes memories of different sizes and specifications without frequent fixture changes, greatly improving the compatibility of the fixing structure and effectively expanding its application range. Multiple trays can simultaneously hold multiple memories, allowing for batch fixing by multiple pressure plates in the batch fixing assembly, eliminating the need for multiple fixing structures and individual fixing of each memory sequentially. This not only effectively reduces manufacturing costs and resource consumption but also makes memory fixing more convenient and faster, thus solving the problems in the prior art.
[0005] To solve the above-mentioned technical problems, this utility model is achieved through the following technical solution:
[0006] This utility model discloses a memory fixing structure, including a fixing frame. The fixing frame has L-shaped sides and several mounting holes at its bottom. Several support plates are fixedly connected between the inner walls of the two sides of the fixing frame. A pair of limiting blocks are fixedly connected to the top of each support plate. Sliding grooves are provided on both side walls of the fixing frame. Fixing blocks are fixedly connected to the outer walls of the top of both sides of the fixing frame. Guide holes are provided on the fixing blocks. A batch fixing assembly is provided on the fixing frame.
[0007] The batch fixing assembly includes a pair of screws, each of which is inserted into a corresponding guide hole. The screw body is threaded with a nut that mates with it, and the side wall of the screw is fixedly connected with several connecting blocks. The end of each connecting block passes through a corresponding slide groove and is fixedly connected with a pressure plate. Each pressure plate is located directly above the corresponding support plate.
[0008] Furthermore, the diameter of the screw is equal to the diameter of the guide hole, the slide groove is rectangular, and the cross-section of the connecting block is rectangular, with its width being equal to the width of the slide groove.
[0009] Furthermore, a protective pad is provided on the bottom surface of each of the pressure plates.
[0010] Furthermore, each of the trays has several pads on its top surface. The pads are cylindrical and have herringbone anti-slip patterns on their top surfaces.
[0011] Furthermore, each of the trays has several heat-conducting holes at its bottom. These heat-conducting holes are square holes and are distributed linearly at equal intervals along the length of the tray.
[0012] Furthermore, the limiting block is elongated and symmetrically distributed on both sides of each heat-conducting hole, and a buffer pad is provided on the inner surface of the limiting block.
[0013] Furthermore, each of the trays has a pair of reinforcing blocks fixedly connected to its bottom sides. The reinforcing blocks are triangular, with one side fixedly connected to the inner wall of the fixing frame, and the reinforcing blocks are symmetrically distributed on the front and rear sides of the bottom of the tray.
[0014] The present invention has the following advantages over the prior art:
[0015] (1) When using the memory fixing structure of this utility model, the pressure applied by the pressure plate in the batch fixing assembly can tightly press the memory against the tray to achieve the effect of fixing the memory. By moving the screw up and down along the guide hole, the pressure plate can be moved up and down together, so as to adjust the distance between the pressure plate and the tray according to the thickness of the memory. It can effectively fix memory of different sizes and specifications without frequently changing the clamps, thereby greatly improving the compatibility of the fixing structure and effectively expanding its application range.
[0016] (2) When using the memory fixing structure of this utility model, multiple memory devices can be placed at the same time through multiple trays, so that multiple memory devices can be batch-fixed at the same time through multiple pressure plates in the batch fixing component, without the need for multiple fixing structures, and without the need to fix each memory device individually in sequence. This not only effectively reduces manufacturing costs and resource consumption, but also makes the fixing of memory devices more convenient and faster.
[0017] Of course, any product implementing this utility model does not necessarily need to achieve all of the advantages described above at the same time. Attached Figure Description
[0018] To more clearly illustrate the technical solutions of the embodiments of this utility model, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0019] Figure 1 This is a schematic diagram of a memory fixing structure according to the present invention;
[0020] Figure 2 This is a schematic diagram of the structure of the fixing frame in this utility model;
[0021] Figure 3 This is a schematic diagram of the top structure of the tray in this utility model;
[0022] Figure 4 This is a schematic diagram of the bottom structure of the tray in this utility model;
[0023] Figure 5 This is a schematic diagram of the top structure of the batch fixing assembly in this utility model;
[0024] Figure 6 This is a schematic diagram of the bottom structure of the batch fixing components in this utility model.
[0025] The attached diagram lists the components represented by each number as follows:
[0026] 1. Fixing bracket; 2. Mounting hole; 3. Support plate; 4. Limiting block; 5. Slide groove; 6. Fixing block; 7. Guide hole; 8. Screw; 9. Nut; 10. Connecting block; 11. Pressure plate; 12. Protective pad; 13. Pad block; 14. Heat conduction hole; 15. Buffer pad; 16. Reinforcing block. Detailed Implementation
[0027] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those skilled in the art without creative effort are within the protection scope of the present utility model.
[0028] In the description of this utility model, it should be understood that the terms "relative", "one end", "inner", "lateral", "end", "both ends", "both sides", "front", "one end face", "the other end face", etc., which indicate orientation or positional relationship, are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the components or elements referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this utility model.
[0029] Please see Figure 1-6 As shown, a memory fixing structure of this utility model includes a fixing frame 1. The fixing frame 1 has L-shaped sides and several mounting holes 2 at its bottom. Fasteners such as bolts can be inserted into the mounting holes 2 to fix the fixing frame 1 together with the fixing structure in a designated position. Several trays 3 are fixedly connected between the inner walls of the two sides of the fixing frame 1. The trays 3 are used to place the memory. A pair of limiting blocks 4 are fixedly connected to the top of each tray 3. When placing the memory, the limiting blocks 4 can play a limiting and guiding role so that the placement position of the memory is biased towards the middle of the top surface of the tray 3. Sliding grooves 5 are opened on both side walls of the fixing frame 1, and fixing blocks 6 are fixedly connected to the outer walls of the top of both sides of the fixing frame 1. The fixing blocks 6 are provided with guide holes 7. A batch fixing assembly is provided on the fixing frame 1.
[0030] The batch fixing assembly includes a pair of screws 8, each inserted into a corresponding guide hole 7. The screws 8 are threadedly connected to nuts 9 that mate with them. Several connecting blocks 10 are fixedly connected to the side walls of the screws 8. The end of each connecting block 10 passes through a corresponding groove 5 and is fixedly connected to a pressure plate 11. Each pressure plate 11 is located directly above a corresponding support plate 3. After the memory is placed on the support plate 3, the screws 8 can be moved downwards along the guide holes 7. As the screws 8 move downwards, they cause the connecting blocks 10 to move downwards as well. When the connecting blocks 10 move downwards, they cause the pressure plates 11 to move downwards as well, until the bottom surface of the pressure plate 11 contacts the top surface of the memory. Then, the nuts 9 are threaded onto each screw 8 and tightened to fix the position of each pressure plate 11. At this time, the pressure applied by the pressure plate 11 can firmly press the memory against the tray 3 to achieve the effect of fixing the memory. Multiple trays 3 can be used to place multiple memories at the same time, and multiple pressure plates 11 can be used to fix multiple memories in batches at the same time, without the need for multiple fixing structures or to fix each memory individually in sequence. This not only effectively reduces manufacturing costs and resource consumption, but also makes the fixing of the memory more convenient and quick. By moving the screw 8 up and down along the guide hole 7, the pressure plate 11 can be moved up and down together, so as to adjust the distance between the pressure plate 11 and the tray 3 according to the size of the memory. Memory of different sizes and specifications can be effectively fixed without frequent changes of clamps, thereby greatly improving the compatibility of the fixing structure and effectively expanding its application range.
[0031] The diameter of the screw 8 is equal to the diameter of the guide hole 7. The slide 5 is rectangular, and the cross-section of the connecting block 10 is rectangular, with its width being equal to the width of the slide 5. When the screw 8 drives each connecting block 10 together with each pressure plate 11 to move up and down, the connecting block 10 can fit against the inner wall of the slide 5 and move vertically in a straight line. At this time, the mutual cooperation between the slide 5 and the connecting block 10 can play a limiting role to prevent the batch fixing components from shaking and tilting when moving up and down.
[0032] Each pressure plate 11 has a protective pad 12 on its bottom surface. The protective pad 12 can be made of elastic materials such as sponge and is fixed by adhesives. When the memory is fixed by the batch fixing components, the protective pad 12 can play a flexible protection role to prevent the pressure applied by the pressure plate 11 from acting directly on the top of the memory and causing damage to the memory.
[0033] Each tray 3 has several pads 13 on its top surface. The pads 13 are cylindrical and have herringbone anti-slip textures on their top surfaces. The pads 13 can be made of elastic materials such as rubber and are fixed by adhesives. When the memory is placed on the tray 3, each pad 13 can be placed on the bottom of the memory to cushion and prevent wear, thus avoiding direct contact between the bottom of the memory and the top of the tray 3 during fixing and causing wear. At the same time, the anti-slip textures on the surface of each pad 13 can increase the friction between the memory and the tray 3 to prevent slipping, thereby further improving the fixing effect of the memory and preventing it from slipping and shifting.
[0034] Each tray 3 has several heat-conducting holes 14 at its bottom. The heat-conducting holes 14 are square holes and are equidistantly distributed linearly along the length of the tray 3. When the memory is placed on the tray 3, the memory can be lifted by the pads 13 so that a certain gap is created between the bottom of the memory and the tray 3. When the memory is used for a long time, the heat generated by it can be dissipated to the bottom of the tray 3 in a timely manner through the heat-conducting holes 14 to accelerate the heat dissipation effect. This can effectively prevent the heat from accumulating at the bottom of the memory and causing the memory to malfunction due to overheating.
[0035] The limiting block 4 is elongated and symmetrically distributed on both sides of each heat conduction hole 14. A buffer pad 15 is provided on the inner surface of the limiting block 4. The buffer pad 15 can be made of elastic materials such as rubber and is fixed by adhesives. The buffer pad 15 can play a role in buffering and absorbing energy to avoid the memory from directly contacting the inner surface of the limiting block 4 and causing a collision when it is placed on the tray 3.
[0036] Each tray 3 has a pair of reinforcing blocks 16 fixedly connected to the bottom of both sides. The reinforcing blocks 16 are triangular, with one side fixedly connected to the inner wall of the fixing frame 1. The reinforcing blocks 16 are symmetrically distributed on the front and rear sides of the bottom of the tray 3. The reinforcing blocks 16 can support and reinforce the tray 3 to improve the structural strength of the tray 3, thereby preventing it from bending and deforming after being subjected to force for a long time, which would affect its service life and the fixing effect of the memory.
[0037] All standard parts used in the application documents can be purchased from the market. All components in this application document can be customized according to the description and drawings. The specific connection methods of each part adopt conventional methods such as bolts, rivets, and welding that are mature in the prior art. The machinery, parts and equipment adopt conventional models in the prior art. The electrical components mentioned in this document are all electrically connected to the external main controller and power supply, and the main controller is a conventional known device that can play a control role.
[0038] The working principle of this utility model is as follows:
[0039] In use, the memory device can be placed on the tray 3, and then the screw 8 is moved downward along the guide hole 7. As the screw 8 moves downward, it drives the connecting blocks 10 downward as well. When the connecting blocks 10 move downward, they drive the pressure plates 11 downward as well, until the bottom surface of the pressure plates 11 contacts the top surface of the memory device. Then, the nuts 9 are threaded onto the screws 8 and tightened to fix the position of the pressure plates 11. The pressure applied by the pressure plates 11 firmly presses the memory device against the tray 3, thus securing it. Multiple trays 3 can hold multiple memory devices simultaneously, and multiple pressure plates 11 can simultaneously fix multiple memory devices in batches without the need for multiple fixing structures or individual fixing of each memory device sequentially. This not only effectively reduces manufacturing costs and resource consumption but also makes memory fixing more convenient and faster. The screw 8, which moves up and down along the guide hole 7, can move the pressure plate 11 up and down together, so as to adjust the distance between the pressure plate 11 and the support plate 3 according to the thickness of the memory. It can effectively fix memory of different sizes and specifications without frequent changes of the clamps, thereby greatly improving the compatibility of the fixing structure and effectively expanding its application range. When the memory is placed on the support plate 3, each pad 13 can be placed on the bottom of the memory to buffer and prevent wear, thereby avoiding direct contact between the bottom of the memory and the top of the support plate 3 during fixing and causing wear. In addition, the memory can be lifted by each pad 13 so that a certain gap is created between the bottom of the memory and the support plate 3. When the memory is used for a long time, the heat generated can be dissipated to the bottom of the support plate 3 in time through each heat conduction hole 14 to accelerate the heat dissipation effect, thereby effectively preventing the heat from accumulating at the bottom of the memory and causing the memory to malfunction due to overheating.
[0040] The preferred embodiments of this utility model disclosed above are merely illustrative of the present utility model. These preferred embodiments do not exhaustively describe all details, nor do they limit the utility model to the specific implementations described. Clearly, many modifications and variations can be made based on the content of this specification. This specification selects and specifically describes these embodiments to better explain the principles and practical applications of this utility model, thereby enabling those skilled in the art to better understand and utilize it. This utility model is limited only by the claims and their full scope and equivalents.
Claims
1. A memory fixed structure, characterized in that, The device includes a fixing frame with L-shaped sides and several mounting holes at its bottom. Several support plates are fixedly connected between the inner walls of the two sides of the fixing frame. A pair of limiting blocks are fixedly connected to the top of each support plate. Sliding grooves are provided on both side walls of the fixing frame, and fixing blocks are fixedly connected to the outer walls of the top of both sides of the fixing frame. Guide holes are provided on the fixing blocks. A batch fixing assembly is provided on the fixing frame. The batch fixing assembly includes a pair of screws, each of which is inserted into a corresponding guide hole. The screw body is threaded with a nut that mates with it, and the side wall of the screw is fixedly connected with several connecting blocks. The end of each connecting block passes through a corresponding slide groove and is fixedly connected with a pressure plate. Each pressure plate is located directly above the corresponding support plate.
2. The memory fixing structure according to claim 1, characterized in that, The diameter of the screw is equal to the diameter of the guide hole, the slide is rectangular, and the cross-section of the connecting block is rectangular, with its width being equal to the width of the slide.
3. The memory fixing structure according to claim 1, characterized in that, Each of the pressure plates has a protective pad on its bottom surface.
4. The memory fixing structure according to claim 1, characterized in that, Each of the trays has several pads on its top surface. The pads are cylindrical and have herringbone anti-slip patterns on their top surface.
5. A memory fixing structure according to claim 1, characterized in that, Each of the trays has several heat-conducting holes at its bottom. These holes are square and are distributed linearly at equal intervals along the length of the tray.
6. A memory fixing structure according to claim 1, characterized in that, The limiting block is elongated and symmetrically distributed on both sides of each heat conduction hole, and a buffer pad is provided on the inner surface of the limiting block.
7. A memory fixing structure according to claim 1, characterized in that, Each of the trays has a pair of reinforcing blocks fixedly connected to its bottom sides. The reinforcing blocks are triangular, with one side fixedly connected to the inner wall of the fixing frame, and the reinforcing blocks are symmetrically distributed on the front and rear sides of the bottom of the tray.