An ultra-thin heat pipe powder surface positioning device

By designing a support plate and translation component for the ultra-thin heat pipe powder positioning device, a long rod driven by a motor is used to move a cylindrical eccentric strip plate to fix the ultra-thin heat pipe, and a marking device is used to mark the powder surface. This solves the problem of simultaneous marking in existing technologies and improves processing efficiency.

CN224407537UActive Publication Date: 2026-06-26KUNSHAN JIANGHONG PRECISION ELECTRONIC CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
KUNSHAN JIANGHONG PRECISION ELECTRONIC CO LTD
Filing Date
2025-08-12
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

Existing technology cannot mark the powder surface while fixing the ultra-thin heat pipe, resulting in low processing efficiency.

Method used

An ultra-thin heat pipe powder positioning device was designed, including a support plate, lifting components, and translation components. A long rod driven by a motor drives a cylindrical eccentric strip plate for fixing, and a marking device is used to mark the powder surface.

Benefits of technology

This technology enables efficient powder marking while fixing ultra-thin heat pipes, thus improving processing efficiency.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to the technical field of super -thin heat pipe provides a super -thin heat pipe powder surface positioning device, including operation platform, still include: support plate, fixed mounting in operation platform's top, lift spare, the inside of support plate is movably embedded, including strip board, the inside of support plate is movably embedded, wherein, through the strip board downward movement to realize the fixed heat pipe. The utility model discloses, in the process of long rod rotation, because the moving block is connected through the thread with long rod, and the moving block is guided and restrained along the horizontal direction under the slide and track groove linear motion, this movement drives the marker device gradually close to super -thin heat pipe, realizes the mark of powder surface, after marking, start motor again, make long rod reverse, spring begins to reset, lift clamping block to the fixed super -thin heat pipe is removed to the fixed super -thin heat pipe, simultaneously, the moving block moves along the reverse trajectory, completes the whole marking process.
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Description

Technical Field

[0001] This utility model relates to the field of ultra-thin heat pipe technology, and in particular to an ultra-thin heat pipe powder positioning device. Background Technology

[0002] An ultrathin heat pipe is a type of heat pipe with a very thin wall structure. It utilizes the principle of heat pipes to achieve efficient heat conduction and heat exchange through the evaporation and condensation process of the internal working fluid. However, existing ultrathin heat pipes have a powdery end, which needs to be manually marked after sintering for subsequent identification.

[0003] In the prior art, such as Chinese patent number CN219667772U, the cooperation of the mounting block, the tail limiting component, the head marking component and the driving component enables rapid positioning on the ultra-thin heat pipe. Through the cooperation of the tail limiting and driving components, combined with the stamping of the pressing mechanism, the positioning and marking efficiency is improved, and the problems of low production capacity and high cost are solved.

[0004] While the above-mentioned solution has the advantages mentioned above, its disadvantage lies in the inability to fix the ultra-thin heat pipe while marking the powder surface, which greatly reduces the processing efficiency. Utility Model Content

[0005] The purpose of this invention is to solve the problem in the prior art that it is impossible to fix ultra-thin heat pipes while marking the powder surface.

[0006] To achieve the above objectives, the present invention adopts the following technical solution: an ultra-thin heat pipe powder positioning device, including an operating table and a support plate, which is fixedly installed on the top of the operating table;

[0007] The lifting component, which is movably embedded inside the support plate, includes a strip plate that is movably embedded inside the support plate;

[0008] The heat pipe is fixed by moving the strip plate downwards.

[0009] A translation component, located at the top of the worktable near the edge, includes a moving block that moves horizontally to mark the powder surface of the heat pipe.

[0010] In a preferred embodiment, the lifting member includes: a clamping block for fixing the heat pipe, which is movably embedded inside the support plate;

[0011] A long rod is movably embedded inside the support plate, and a circular piece is fixedly sleeved on its outer surface to limit the movement of the long rod;

[0012] The spring is fixedly connected to the inside of the support plate, and one end is fixedly connected to the outer surface of the support plate.

[0013] The technical effect of adopting the above-mentioned further solution is that the circular plate constrains the long rod, preventing the long rod from shifting.

[0014] In a preferred embodiment, a cylinder is fixedly sleeved on the outer surface of the long rod, and the long rod penetrates the interior of the cylinder and is located above the center of the cylinder.

[0015] The technical effect of adopting the above-mentioned further solution is that the eccentric design enables the strip plate to move up and down, thereby assisting in the fixation of the ultra-thin heat pipe.

[0016] In a preferred embodiment, the cylinder is provided with a plurality of rollers for reducing friction, and the plurality of rollers are linearly distributed inside the cylinder.

[0017] The technical effect of adopting the above-mentioned further solution is that multiple rollers are linearly distributed inside the cylinder, which extends the service life, and lubricants, including but not limited to, can be applied to the inside of the rollers.

[0018] In a preferred embodiment, a support base is fixedly installed on the top of the operating table near the edge, and a motor is installed on the top of the support base;

[0019] The output end of the motor is fixedly connected to one side of the outer surface of the long rod.

[0020] The technical effect of adopting the above-mentioned further solution is that the motor can stably output power to drive the long rod to rotate.

[0021] In a preferred embodiment, the translation component includes: a marking device, installed on one side of the outer surface of the moving block, which can mark the powder surface of the heat pipe;

[0022] A threaded hole is provided on the outer surface of the long rod, and the moving block is threadedly connected to the long rod.

[0023] The technical effect of adopting the above-mentioned further solution is that the threaded hole is set on the outer surface of the long rod, so that the moving block can move.

[0024] In one preferred embodiment, the operating table has an internal track groove, and a slider is fixedly connected to the bottom of the moving block;

[0025] The slider is movably embedded inside the track groove.

[0026] The technical effect of adopting the above-mentioned further solution is that the moving block is restricted by the slider and the track groove, so that it can move horizontally in a straight line.

[0027] Compared with the prior art, the advantages and positive effects of this utility model are as follows:

[0028] 1. In this utility model, the motor is started, which drives the long rod to rotate, thereby causing the cylinder to rotate. Due to the eccentric design of the cylinder, its rotation causes the strip plate to move in a straight line in the vertical direction inside the support plate, thereby applying vertical downward pressure to the clamping block. This pressure further compresses the spring, causing the clamping block to fit tightly with the support plate, thereby fixing the ultra-thin heat pipe.

[0029] 2. In this utility model, during the rotation of the long rod, the moving block is connected to the long rod by a thread. Under the guidance and constraint of the slider and the track groove, the moving block moves linearly in the horizontal direction. This movement drives the marking device to gradually approach the ultra-thin heat pipe to mark the powder surface. After marking is completed, the motor is started again to reverse the long rod, the spring begins to reset, and the clamping block is lifted, thereby releasing the fixation of the ultra-thin heat pipe. At the same time, the moving block moves along the reverse trajectory to complete the entire marking process. Attached Figure Description

[0030] Figure 1 A schematic diagram of the main structure of an ultra-thin heat pipe powder surface positioning device provided by this utility model;

[0031] Figure 2 A schematic diagram of the internal structure of an ultra-thin heat pipe powder surface positioning device provided by this utility model;

[0032] Figure 3 A schematic diagram of the eccentric structure of an ultra-thin heat pipe powder surface positioning device provided by this utility model;

[0033] Figure 4 A cross-sectional view of the track groove structure of an ultra-thin heat pipe powder surface positioning device provided by this utility model;

[0034] Figure 5 A top view schematic diagram of the main structure of an ultra-thin heat pipe powder positioning device provided by this utility model.

[0035] Legend:

[0036] 1. Operating table; 101. Support plate; 102. Clamping block; 103. Long rod; 104. Strip plate; 105. Spring; 106. Circular piece; 107. Cylinder; 108. Roller; 201. Moving block; 202. Marking device; 203. Threaded hole; 204. Motor; 205. Support seat; 206. Slider; 207. Track groove. Detailed Implementation

[0037] 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.

[0038] Example 1:

[0039] Please see Figures 1-5 This embodiment provides an ultra-thin heat pipe powder positioning device, the specific idea of ​​which is as follows:

[0040] In one specific embodiment, the device includes an operating table 1 and a support plate 101, which is fixedly installed on the top of the operating table 1.

[0041] The lifting component, which is movably embedded inside the support plate 101, includes a strip plate 104, which is movably embedded inside the support plate 101.

[0042] The heat pipe is fixed by moving downward through the strip plate 104.

[0043] In this embodiment, the specific type of lifting component can be varied, and this application does not limit it. As an example of a lifting component, one optional solution includes: a clamping block 102, a long rod 103, and a spring 105, the specific quantities of which are as follows: Figures 1-2 As shown, the settings are as follows:

[0044] The clamp 102, which fixes the heat pipe by moving up and down, is movably embedded inside the support plate 101, and a through hole is opened on one side of the outer surface of the clamp 102 to better fix the ultra-thin heat pipe.

[0045] The long rod 103 is movably embedded inside the support plate 101, and a circular piece 106 is fixedly sleeved on its outer surface to limit the long rod 103. The circular piece 106 constrains the long rod 103 to prevent displacement of the long rod 103.

[0046] Spring 105 is fixedly connected to the inside of support plate 101, and one end is fixedly connected to the outer surface of clamp 102. For example, spring 105 enhances the reset effect so as to support clamp 102.

[0047] As a specific implementation method, such as Figure 5 As shown, a support base 205 is fixedly installed on the top of the control panel 1 near the edge, and a motor 204 is installed on the top of the support base 205.

[0048] The output end of the motor 204 is fixedly connected to one side of the outer surface of the long rod 103.

[0049] In the above implementation, motor 204 is a servo motor that can stably output power. It can be a Siemens model 1FK7063-5AF71-1PH0, which drives the long rod 103 to rotate. Motor 204 is started by the controller.

[0050] For example, such as Figure 3 As shown, a cylinder 107 is fixedly sleeved on the outer surface of the long rod 103, and the long rod 103 passes through the inside of the cylinder 107 and is located above the center of the cylinder 107. The purpose is to achieve the effect of the strip plate 104 moving up and down through the eccentric design, thereby assisting in the fixation of the ultra-thin heat pipe.

[0051] In addition, the cylinder 107 can also take other shapes in other implementations, and this application does not limit this.

[0052] In the above implementation, in order to reduce friction and wear, a plurality of rollers 108 are provided inside the cylinder 107, and the plurality of rollers 108 are linearly distributed inside the cylinder 107. In order to extend service life, a lubricant, including but not limited to, can be applied inside the rollers 108.

[0053] In this embodiment, the motor 204 is started, driving the long rod 103 to rotate, which in turn drives the cylinder 107 to rotate. Since the cylinder 107 adopts an eccentric design, its rotation causes the strip plate 104 to move linearly in the vertical direction inside the support plate 101, thereby applying vertical downward pressure to the clamping block 102. This pressure further compresses the spring 105, causing the clamping block 102 to fit tightly with the support plate 101, thereby fixing the ultra-thin heat pipe.

[0054] Example 2:

[0055] like Figures 1-5 As shown, based on Embodiment 1, this embodiment also provides a structure for marking the powder surface of an ultrathin heat pipe. A translation component is provided at the top of the operating table 1 near the edge, including a moving block 201. The moving block 201 moves horizontally to mark the powder surface of the heat pipe.

[0056] As one specific implementation, the translation component includes a marking device 202, which is installed on one side of the outer surface of the moving block 201 and can mark the powder surface of the heat pipe.

[0057] In this embodiment, the marking device 202 can be a marking machine of Suzhou Optics Valley Optoelectronic Technology Co., Ltd., model number: SG-YLP20-ZM.

[0058] A threaded hole 203 is provided on the outer surface of the long rod 103, and the moving block 201 is threadedly connected to the long rod 103.

[0059] In addition, such as Figure 4 As shown, the operating table 1 has a track groove 207 inside, and a slider 206 is fixedly connected to the bottom of the moving block 201. The slider 206 is movably embedded in the track groove 207, which is intended to restrict the moving block 201 through the slider 206 and the track groove 207, so that it can move horizontally in a straight line.

[0060] In this embodiment, during the rotation of the long rod 103, the moving block 201 is connected to the long rod 103 by a thread. Under the guidance and constraint of the slider 206 and the track groove 207, the moving block 201 moves linearly in the horizontal direction. This movement drives the marking device 202 to gradually approach the ultra-thin heat pipe to mark the powder surface. After the marking is completed, the motor 204 is started to reverse the long rod 103, the spring 105 begins to reset, and the clamping block 102 is lifted, thereby releasing the fixation of the ultra-thin heat pipe. At the same time, the moving block 201 moves along the reverse trajectory to complete the entire marking process.

[0061] In addition, a battery pack may be provided in this application to provide power to the internal components of the motor 204, the marking device 202 and other devices, and to start them through the controller. The circuit connection adopts the conventional connection method in the prior art, which will not be described in detail here.

[0062] Working principle: The ultra-thin heat pipe is placed at the notch of the support plate 101. Then, the motor 204, which is fixedly installed on the top of the load-bearing seat 205, is started by the controller to output power stably and drive the long rod 103 to rotate. The long rod 103 then drives the cylinder 107 to rotate. Since the cylinder 107 adopts an eccentric design, the cylinder 107 drives the strip plate 104 to move downward in a straight line inside the support plate 101, thereby giving the clamping block 102 a vertical downward pressure, compressing the spring 105. Under the action of the clamping block 102 and the support plate 101, the ultra-thin heat pipe is fixed.

[0063] While the long rod 103 rotates, the moving block 201 is connected to the long rod 103 by a thread. Therefore, the moving block 201 moves horizontally in a straight line under the constraint of the slider 206 and the track groove 207, and drives the marking device 202 to move closer to the ultra-thin heat pipe, thereby marking the powder surface of the ultra-thin heat pipe. After that, the controller starts the motor 204 to reverse the long rod 103, the spring 105 resets, the clamping block 102 is lifted, the fixation of the ultra-thin heat pipe is released, and the moving block 201 is driven to move in the opposite direction.

[0064] This design allows for easy and convenient marking of the powder surface of the ultra-thin heat pipe while simultaneously fixing it in place, and it also speeds up the production process.

[0065] All standard parts used in this utility model can be purchased from the market, and irregular parts 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. In addition, the circuit connection adopts conventional connection methods in the prior art, which will not be described in detail here. The contents not described in detail in this specification belong to the prior art known to those skilled in the art.

[0066] The above description is merely a preferred embodiment of the present utility model and is not intended to limit the present utility model in any other way. Any person skilled in the art may make changes or modifications to the above-disclosed technical content to create equivalent embodiments for application in other fields. However, any simple modifications, equivalent changes, and modifications made to the above embodiments based on the technical essence of the present utility model without departing from the technical solution of the present utility model shall still fall within the protection scope of the technical solution of the present utility model.

Claims

1. A positioning device for ultra-thin heat pipe powder, comprising an operating table (1), characterized in that, Also includes: A support plate (101) is fixedly installed on the top of the operating table (1); The lifting component is movably embedded inside the support plate (101), including a strip plate (104) movably embedded inside the support plate (101); The heat pipe is fixed by moving downward through the strip plate (104); A translation component, located at the top of the operating table (1) near the edge, includes a moving block (201) that moves horizontally to mark the powder surface of the heat pipe.

2. The ultra-thin heat pipe powder positioning device according to claim 1, characterized in that, The lifting component includes: The clamp (102) used to fix the heat pipe is movably embedded inside the support plate (101); The long rod (103) is movably embedded inside the support plate (101), and a circular piece (106) is fixedly sleeved on its outer surface to limit the long rod (103). The spring (105) is fixedly connected to the inside of the support plate (101), and one end is fixedly connected to the outer surface of the clamp (102).

3. The ultra-thin heat pipe powder positioning device according to claim 2, characterized in that, A cylinder (107) is fixedly sleeved on the outer surface of the long rod (103), and the long rod (103) penetrates the inside of the cylinder (107) and is located above the center of the cylinder (107).

4. The ultra-thin heat pipe powder positioning device according to claim 3, characterized in that, The cylinder (107) is provided with a plurality of rollers (108) for reducing friction, and the plurality of rollers (108) are linearly distributed inside the cylinder (107).

5. The ultra-thin heat pipe powder positioning device according to claim 1, characterized in that, A load-bearing base (205) is fixedly installed on the top of the operating table (1) near the edge, and a motor (204) is installed on the top of the load-bearing base (205). The output end of the motor (204) is fixedly connected to one side of the outer surface of the long rod (103).

6. The ultra-thin heat pipe powder positioning device according to claim 5, characterized in that, The translation component includes: A marking device (202) is installed on one side of the outer surface of the movable block (201) and can mark the powder surface of the heat pipe; A threaded hole (203) is provided on the outer surface of the long rod (103), and the moving block (201) is threadedly connected to the long rod (103).

7. The ultra-thin heat pipe powder positioning device according to claim 6, characterized in that, The operating table (1) has a track groove (207) inside, and the bottom of the moving block (201) is fixedly connected to a slider (206). The slider (206) is movably embedded inside the track groove (207).