A high-efficiency heat dissipation fin for computer solid-state drives
By designing an adjustable sliding and threaded rod mechanism for the heat dissipation fins, the problem that heat dissipation fins cannot be adapted to hard drives of different lengths in the existing technology is solved, achieving comprehensive heat dissipation and stable clamping of solid-state drives, and improving the heat dissipation effect.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- DONGGUAN ZHENGCHUANG ELECTRONICS CO LTD
- Filing Date
- 2025-07-11
- Publication Date
- 2026-06-30
AI Technical Summary
Existing computer solid-state drives (SSDs) have high-efficiency heat dissipation fins that are difficult to adapt to hard drives of different lengths, resulting in incomplete heat dissipation and affecting user experience.
A heat dissipation fin structure including a frame, a slide bar, an adjustment mechanism, and a clamping plate was designed. The movement of the crossbar and the spacing of the clamping plate can be realized through sliding fit and adjustment of the threaded rod, which is compatible with hard drives of different lengths. The heat dissipation area is increased by wavy fins and staggered distribution.
It achieves comprehensive heat dissipation for solid-state drives of different lengths, improves heat dissipation effect and clamping stability, and enhances the adaptability and practical value of the heat dissipation fins.
Smart Images

Figure CN224437186U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of solid-state drive technology, specifically to a high-efficiency heat dissipation fin for computer solid-state drives. Background Technology
[0002] With the continuous improvement of computer performance, solid-state drives (SSDs) have seen significant increases in read / write speeds and data processing capabilities. However, the heat generated during operation has also increased significantly. High temperatures can lead to decreased read / write speeds, shortened lifespan, and even data errors in SSDs. Traditional cooling methods, such as simple heat sinks or thermal pads, are no longer sufficient to meet the cooling requirements of high-performance SSDs.
[0003] Based on the above, the inventors have discovered the following problem: the high-efficiency heat dissipation fins used in current computer solid-state drives are difficult to adapt to computer solid-state drives of different lengths, making it difficult to fully dissipate heat from the computer solid-state drives and affecting user experience.
[0004] Therefore, in view of this, we have studied and improved the existing structure and its shortcomings, and provided a high-efficiency heat dissipation fin for computer solid-state drives, in order to achieve a more practical purpose. Utility Model Content
[0005] The purpose of this utility model is to provide a high-efficiency heat dissipation fin for computer solid-state drives (SSDs) to solve the problem mentioned in the background art that current high-efficiency heat dissipation fins for computer SSDs are difficult to adapt to SSDs of different lengths, thus making it difficult to fully dissipate heat from the SSDs and affecting user experience.
[0006] In view of the above problems, the technical solution proposed by this utility model is as follows:
[0007] A high-efficiency heat dissipation fin for a computer solid-state drive includes a frame. Crossbars are provided at both ends of the frame. First sliding holes are formed on both sides of each end of the frame. First sliding rods are slidably connected to the inner sides of the first sliding holes. One end of each first sliding rod is fixedly connected to one side of a crossbar. Second sliding holes are formed at the middle of both ends of the frame. Second sliding rods are slidably connected to the inner sides of the second sliding holes. One end of each second sliding rod is fixedly connected to one side of a crossbar. A plurality of first heat dissipation fins are mounted at the bottom of one of the crossbars, and a plurality of second heat dissipation fins are mounted at the bottom of the other crossbar. An adjustment mechanism for adjusting the distance between a pair of second sliding rods is provided inside the frame. A pair of connecting plates are mounted on the other side of each crossbar, and a clamping plate is mounted on the bottom of one side of each connecting plate.
[0008] Furthermore, the adjusting mechanism includes a bidirectional threaded rod, the two ends of which are rotatably connected to the inner sides of the frame. Both ends of the bidirectional threaded rod are fitted with sliders, and both sides of the sliders are hinged with connecting rods. One end of a pair of connecting rods is hinged with a connecting plate, and one side of the pair of connecting plates is fixedly connected to the other end of the second slider.
[0009] The beneficial effect of adopting the above-mentioned further solution is that, through the cooperation of the bidirectional threaded rod, slider, connecting rod, and connecting plate, when the bidirectional threaded rod rotates, the sliders at both ends move in opposite directions, and the connecting rod pulls the connecting plate, which in turn drives the second slider and crossbar to move in parallel.
[0010] Furthermore, an adjustment knob is provided on one side of the frame, and one end of the adjustment knob is fixedly connected to one end of the bidirectional threaded rod.
[0011] The advantage of adopting the above-mentioned further solution is that by fixing one end of the adjustment knob to one end of the bidirectional threaded rod, it is convenient for the user to rotate the bidirectional threaded rod.
[0012] Furthermore, the bottom end of the first heat dissipation fin is fixedly connected to the top end of one of the clamping plates, and the bottom end of the second heat dissipation fin is fixedly connected to the top end of the other clamping plate.
[0013] The beneficial effect of adopting the above-mentioned further solution is that, through the cooperation of the first heat dissipation fin, the second heat dissipation fin, and the clamping plate, the heat dissipation fin and the clamping plate are fixedly connected, thereby facilitating heat dissipation on the side of the computer solid-state drive.
[0014] Furthermore, a rubber pad is installed on one side of the clamping plate, and the rubber pad has an anti-slip texture on one side.
[0015] The beneficial effect of adopting the above-mentioned further solution is that by installing a rubber pad on one side of the clamping plate, the clamping anti-slip property of the clamping plate is improved.
[0016] Furthermore, both the first and second heat dissipation fins have a wavy pattern.
[0017] The beneficial effect of adopting the above-mentioned further solution is that, by having both the first and second heat dissipation fins in a wavy shape, the heat dissipation surface area of the first and second heat dissipation fins is effectively increased, thereby enhancing the heat dissipation effect.
[0018] Furthermore, the first and second heat dissipation fins are staggered.
[0019] The beneficial effect of adopting the above-mentioned further solution is that, by staggering the first heat dissipation fins and the second heat dissipation fins, collisions between the first heat dissipation fins and the second heat dissipation fins are avoided when the spacing of a pair of crossbars is adjusted.
[0020] Compared with the prior art, the beneficial effects of this utility model are as follows: The computer solid-state drive uses high-efficiency heat dissipation fins. Through the sliding cooperation of the first sliding hole and the first sliding rod, and the second sliding hole and the second sliding rod, the crossbar can move laterally, driving the clamping plate to adjust the spacing, thus accommodating solid-state drives of different lengths. The first and second heat dissipation fins are respectively installed at the bottom ends of a pair of crossbars to dissipate heat for the computer solid-state drive. Through the cooperation of the bidirectional threaded rod, slider, connecting rod, and connecting plate, when the bidirectional threaded rod rotates, the sliders at both ends move in opposite directions. The connecting rod pulls the connecting plate, synchronously driving the second sliding rod and the crossbar to move horizontally. One end of the adjusting knob is fixedly connected to one end of the bidirectional threaded rod, facilitating user rotation of the bidirectional threaded rod. The first heat dissipation fin, the second heat dissipation fin, and the clamping plate work together to fix the heat dissipation fins to the clamping plate, thus facilitating heat dissipation from the side of the computer solid-state drive. A rubber pad is installed on one side of the clamping plate to improve its grip and anti-slip properties. The wavy design of both the first and second heat dissipation fins effectively increases their heat dissipation surface area, enhancing the heat dissipation effect. The staggered distribution of the first and second heat dissipation fins prevents collisions when adjusting the spacing of the crossbars. This invention can effectively adapt to computer solid-state drives of different lengths, improving the overall heat dissipation of the computer solid-state drive and possessing high practical value. Attached Figure Description
[0021] Figure 1 This is one of the three-dimensional structural schematic diagrams disclosed in the embodiments of this utility model;
[0022] Figure 2 This is the second three-dimensional structural schematic diagram disclosed in the embodiment of this utility model;
[0023] Figure 3 This is a top view of an embodiment of the present utility model;
[0024] Figure 4 The embodiments disclosed herein Figure 1 Enlarged schematic diagram of structure A in the middle;
[0025] Figure 5 The embodiments disclosed herein Figure 1 A magnified schematic diagram of the B-structure.
[0026] In the diagram: 100, frame; 10001, first sliding hole; 10002, second sliding hole; 101, crossbar; 102, first sliding rod; 103, second sliding rod; 104, adjusting mechanism; 10401, bidirectional threaded rod; 10402, slider; 10403, connecting rod; 10404, connecting plate; 10405, adjusting knob; 105, first heat dissipation fin; 106, second heat dissipation fin; 107, side plate; 108, clamping plate; 109, rubber pad. 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 of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0028] Please see Figures 1-5 This utility model provides a technical solution: a high-efficiency heat dissipation fin for a computer solid-state drive, comprising a frame 100, with crossbars 101 at both ends of the frame 100, and first sliding holes 10001 on both sides of both ends of the frame 100. A first sliding rod 102 is slidably connected to the inner side of the first sliding hole 10001, and one end of the first sliding rod 102 is fixedly connected to one side of the crossbar 101. A second sliding hole 10002 is opened in the middle of both ends of the frame 100, and a second sliding rod 103 is slidably connected to the inner side of the second sliding hole 10002. One end of the second sliding rod 103 is fixedly connected to one side of the crossbar 101. A plurality of first heat dissipation fins 105 are installed at the bottom end of one of the crossbars 101. Several second heat dissipation fins 106 are installed at the bottom of another crossbar 101. The frame 100 is provided with an adjustment mechanism 104 for adjusting the distance between a pair of second slide rods 103. A pair of side plates 107 are installed on the other side of the crossbar 101. A clamping plate 108 is installed at the bottom of one side of the side plate 107. The crossbar 101 can be moved laterally by sliding the first slide hole 10001 with the first slide rod 102 and the second slide hole 10002 with the second slide rod 103, thereby driving the clamping plate 108 to adjust the distance and making it compatible with solid-state drives of different lengths. The first heat dissipation fins 105 and the second heat dissipation fins 106 are respectively installed at the bottom of the pair of crossbars 101 to dissipate heat for the computer solid-state drive.
[0029] 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 of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0030] Please see Figures 1-5 The adjusting mechanism 104 includes a bidirectional threaded rod 10401. Both ends of the bidirectional threaded rod 10401 are rotatably connected to the inner sides of the frame 100. Slider 10402 is fitted onto both ends of the bidirectional threaded rod 10401. Connecting rods 10403 are hinged to both sides of each slider 10402. Connecting plates 10404 are hinged to one end of each pair of connecting rods 10403. One side of each pair of connecting plates 10404 is fixedly connected to the other end of the second slider 103. An adjusting knob 10405 is provided on one side of the frame 100. One side of the adjusting knob 10405... One end of the bidirectional threaded rod 10401 is fixedly connected to the other end. Through the cooperation of the bidirectional threaded rod 10401, the slider 10402, the connecting rod 10403, and the connecting plate 10404, when the bidirectional threaded rod 10401 rotates, the sliders 10402 at both ends move in opposite directions. The connecting rod 10403 pulls the connecting plate 10404, which simultaneously drives the second slider 103 and the crossbar 101 to move. One end of the adjusting knob 10405 is fixedly connected to one end of the bidirectional threaded rod 10401, which makes it convenient for the user to rotate the bidirectional threaded rod 10401.
[0031] 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 of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0032] Please see Figures 1-5The bottom end of the first heat dissipation fin 105 is fixedly connected to the top end of one of the clamping plates 108, and the bottom end of the second heat dissipation fin 106 is fixedly connected to the top end of another clamping plate 108. A rubber pad 109 is installed on one side of the clamping plate 108, and the rubber pad 109 has an anti-slip texture on one side. Both the first heat dissipation fin 105 and the second heat dissipation fin 106 are wavy in shape and are staggered. Through the cooperation of the first heat dissipation fin 105, the second heat dissipation fin 106, and the clamping plate 108, the heat dissipation fins and the clamping plate 108 are connected. The 08 fixed connection facilitates heat dissipation from the side of the computer's solid-state drive. A rubber pad 109 is installed on one side of the clamping plate 108 to improve the clamping anti-slip performance of the clamping plate 108. The first heat dissipation fin 105 and the second heat dissipation fin 106 are both wavy, which effectively increases the heat dissipation surface area of the first heat dissipation fin 105 and the second heat dissipation fin 106 and enhances the heat dissipation effect. The staggered distribution between the first heat dissipation fin 105 and the second heat dissipation fin 106 prevents collision between the first heat dissipation fin 105 and the second heat dissipation fin 106 when the pair of crossbars 101 are adjusted.
[0033] Specifically, the working principle of this type of high-efficiency heat dissipation fin for computer solid-state drives is as follows: During use, the sliding engagement of the first sliding hole 10001 with the first sliding rod 102 and the second sliding hole 10002 with the second sliding rod 103 allows the crossbar 101 to move laterally, driving the clamping plate 108 to adjust its spacing, thus accommodating solid-state drives of different lengths. The first heat dissipation fin 105 and the second heat dissipation fin 106 are respectively installed at the bottom ends of a pair of crossbars 101 to dissipate heat from the computer solid-state drive. Through the cooperation of the bidirectional threaded rod 10401, the slider 10402, the connecting rod 10403, and the connecting plate 10404, when the bidirectional threaded rod 10401 rotates, the sliders 10402 at both ends move in opposite directions. The connecting rod 10403 pulls the connecting plate 10404, simultaneously driving the second sliding rod 103 and the crossbar 101 to move horizontally. The adjustment knob 10405 is fixedly connected to one end of the bidirectional threaded rod 10401. The device allows users to easily rotate the bidirectional threaded rod 10401. Through the cooperation of the first heat dissipation fin 105, the second heat dissipation fin 106, and the clamping plate 108, the heat dissipation fins are fixedly connected to the clamping plate 108, thus facilitating heat dissipation from the side of the computer solid-state drive. A rubber pad 109 is installed on one side of the clamping plate 108 to improve the clamping anti-slip performance. The wavy design of the first heat dissipation fin 105 and the second heat dissipation fin 106 effectively increases the heat dissipation surface area, enhancing the heat dissipation effect. The staggered distribution of the first heat dissipation fin 105 and the second heat dissipation fin 106 prevents collisions between the first heat dissipation fin 105 and the second heat dissipation fin 106 when adjusting the spacing of the pair of crossbars 101. This invention can effectively adapt to computer solid-state drives of different lengths, improve the overall heat dissipation of computer solid-state drives, and has high practical value.
Claims
1. A high-efficiency heat dissipation fin for a computer solid state drive, characterized in that, The system includes a frame (100), with crossbars (101) at both ends. First sliding holes (10001) are provided on both sides of both ends of the frame (100). A first sliding rod (102) is slidably connected to the inner side of each first sliding hole (10001). One end of the first sliding rod (102) is fixedly connected to one side of the crossbar (101). Second sliding holes (10002) are provided in the middle of both ends of the frame (100). A second sliding rod (103) is slidably connected to the inner side of each second sliding hole (10002). One end of the slide bar (103) is fixedly connected to one side of the crossbar (101). A plurality of first heat dissipation fins (105) are installed at the bottom end of one of the crossbars (101), and a plurality of second heat dissipation fins (106) are installed at the bottom end of the other crossbar (101). The frame (100) is provided with a distance adjustment mechanism (104) for adjusting the distance between a pair of second slide bars (103). A pair of side plates (107) are installed on the other side of the crossbar (101), and a clamping plate (108) is installed at the bottom end of one side of the side plate (107).
2. The high-efficiency heat dissipation fin for a computer solid state hard disk according to claim 1, characterized in that, The adjusting mechanism (104) includes a bidirectional threaded rod (10401), the two ends of which are rotatably connected to the inner sides of the frame (100). Both ends of the bidirectional threaded rod (10401) are fitted with sliders (10402), and both sides of the sliders (10402) are hinged with connecting rods (10403). One end of a pair of connecting rods (10403) is hinged with a connecting plate (10404), and one side of the pair of connecting plates (10404) is fixedly connected to the other end of the second slider (103).
3. The high-efficiency heat dissipation fin for a computer solid state hard disk according to claim 1, characterized in that, An adjustment knob (10405) is provided on one side of the frame (100), and one end of the adjustment knob (10405) is fixedly connected to one end of the bidirectional threaded rod (10401).
4. The high-efficiency heat dissipation fin for a computer solid state hard disk according to claim 1, characterized in that, The bottom end of the first heat dissipation fin (105) is fixedly connected to the top end of one of the clamping plates (108), and the bottom end of the second heat dissipation fin (106) is fixedly connected to the top end of the other clamping plate (108).
5. The high-efficiency heat dissipation fin for a computer solid state hard disk according to claim 1, characterized in that, A rubber pad (109) is installed on one side of the clamping plate (108), and the rubber pad (109) has an anti-slip texture on one side.
6. The high-efficiency heat dissipation fin for a computer solid state hard disk according to claim 1, characterized in that, Both the first heat dissipation fin (105) and the second heat dissipation fin (106) are wavy in shape.
7. The high-efficiency heat dissipation fin for a computer solid state hard disk according to claim 1, characterized in that, The first heat dissipation fins (105) and the second heat dissipation fins (106) are staggered.