A computer memory module processing equipment and production system

By integrating material carriers, transfer mechanisms, and conveyor belts, highly efficient automation of computer memory module engraving and sealing detection is achieved, solving the problem of low automation in existing technologies and improving production efficiency and accuracy.

CN224424574UActive Publication Date: 2026-06-30YUDING (SUZHOU) INTELLIGENT ELECTRONICS CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
YUDING (SUZHOU) INTELLIGENT ELECTRONICS CO LTD
Filing Date
2025-06-30
Publication Date
2026-06-30

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Abstract

This utility model provides a computer memory module processing equipment and production system, comprising: multiple material carriers; two first material transfer mechanisms; a feeding conveyor belt, wherein the first material transfer components can move between the feeding conveyor belt and the material carriers; a laser engraving mechanism, including a laser engraver; a second material transfer mechanism; a leakage testing mechanism, wherein the second material transfer components can move between the laser engraving mechanism and the leakage testing platform; and a discharging conveyor belt, wherein another first material transfer mechanism is disposed between the leakage testing mechanism and the discharging conveyor belt. This utility model can complete a complete set of high-precision engraving, leakage detection, and transfer processes. The various structures in this application are rationally laid out and highly coordinated. Compared with conventional independent processing technologies, this application has significant advantages such as high automation, ease of operation, significantly improved processing accuracy and efficiency, and wide applicability.
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Description

Technical Field

[0001] This utility model relates to the field of computer component processing technology, specifically to a computer memory module processing equipment and production system. Background Technology

[0002] In the manufacturing process of computer memory modules (DIMMs), QR code engraving and leak detection are key steps to ensure product traceability and reliability. Currently, traditional DIMM production lines generally suffer from low automation, broken process connections, and lagging data management in the engraving and leak detection stages, which seriously restricts production efficiency and quality control.

[0003] In existing technologies, the DIMM engraving and leak testing processes mostly adopt a segmented operation mode: on the one hand, the efficiency of single-batch engraving is low, making it difficult to meet the needs of large-scale mass production; on the other hand, the sealing test is often separated from the engraving process, the coordination between each step is not high, and the intermediate turnaround time between different processing processes is too long. This not only results in excessive processing errors, but also seriously restricts production efficiency. Based on this, the industry urgently needs a fully automated solution that integrates engraving, leak testing, and transmission to break through the technical bottlenecks of traditional processes. Summary of the Invention

[0004] Therefore, the technical problem to be solved by this utility model is to overcome the problem of low processing efficiency and precision of computer memory modules in the prior art, and to provide a computer memory module processing equipment and production system.

[0005] To solve the above-mentioned technical problems, this utility model provides a computer memory module processing device, comprising: multiple material carriers, in which computer memory modules are placed; two first transfer mechanisms, one of which is disposed at one end of a material carrier, and the first transfer mechanism includes a support and multiple first transfer components connected to the support; a feeding conveyor belt, the feeding end of which is disposed near the first transfer mechanism, and the first transfer components are movable between the feeding conveyor belt and the material carriers; a laser engraving mechanism, which is disposed near the discharging end of the feeding conveyor belt and includes a laser engraver; a second transfer mechanism, which includes a transfer arm and multiple second transfer components connected to the transfer arm; a leakage testing mechanism, which includes multiple leakage testing tables, and the second transfer components are movable between the laser engraving mechanism and the leakage testing tables; and a discharging conveyor belt, the feeding end of which is disposed near the leakage testing mechanism, and the other first transfer mechanism is disposed between the leakage testing mechanism and the discharging conveyor belt.

[0006] In one embodiment of the present invention, the material carrier includes a base and a container rack. The base is provided with a slide rail, and the container rack can drive the internal computer memory module to move synchronously along the slide rail.

[0007] In one embodiment of the present invention, the material carrier further includes a material detector, which is disposed at one end of the slide rail and faces the interior of the container rack.

[0008] In one embodiment of the present invention, the first material transfer mechanism includes a first horizontal module, a second horizontal module, and a material transfer lifting module. The first horizontal module extends along a first direction, the second horizontal module is slidably connected to the first horizontal module, the material transfer lifting module is slidably connected to the second horizontal module, and a plurality of the first material transfer components are slidably connected to the material transfer lifting module.

[0009] In one embodiment of this utility model, the feeding conveyor belt and the unloading conveyor belt both extend along a first direction and are arranged parallel to each other along a second direction, and the transmission direction of the feeding conveyor belt is opposite to that of the unloading conveyor belt.

[0010] In one embodiment of the present invention, the laser engraving mechanism further includes an engraving lifting module, and the laser engraver is slidably connected to the engraving lifting module.

[0011] In one embodiment of this utility model, the computer memory module processing equipment further includes a barcode scanning and detection mechanism. The barcode scanning and detection mechanism includes an adjustment frame and a barcode detector. The adjustment frame is disposed on one side of the laser engraving mechanism, and the barcode detector is disposed on the adjustment frame and faces the discharge end of the feeding conveyor belt.

[0012] In one embodiment of this utility model, the computer memory module processing equipment further includes a machine base and a waste recycling box. The material carrier, the first material transfer mechanism, the feeding conveyor belt, the laser engraving mechanism, the second material transfer mechanism, the leakage testing mechanism, the unloading conveyor belt, and the waste recycling box are all disposed on the machine base, and the waste recycling box is disposed on one side of the leakage testing mechanism.

[0013] In one embodiment of this utility model, the computer memory module processing equipment further includes a control mechanism, and the material carrier, the first material transfer mechanism, the loading conveyor belt, the laser engraving mechanism, the second material transfer mechanism, the leakage testing mechanism, and the unloading conveyor belt are respectively connected to the control mechanism.

[0014] This utility model also provides a computer memory module production system, which includes the above-mentioned computer memory module processing equipment.

[0015] The above-mentioned technical solution of this utility model has the following advantages compared with the prior art:

[0016] The computer memory module processing equipment and production system described in this utility model uses a material carrier to hold computer memory modules. A first material transfer tool moves the modules to a loading conveyor belt, which then guides them into the working area of ​​a laser engraving mechanism. After laser engraving, the modules pass through a second material transfer mechanism to a leak testing mechanism for internal sealing testing. Qualified modules then pass through another first material transfer mechanism to an unloading conveyor belt, thus completing a high-precision engraving, leak detection, and transfer process. The various structures in this application are rationally laid out and highly integrated. Compared to conventional independent processing technologies, this application offers significant advantages such as high automation, ease of operation, significantly improved processing accuracy and efficiency, and wide applicability. Attached Figure Description

[0017] To make the content of this utility model easier to understand, the present utility model will be further described in detail below with reference to specific embodiments and accompanying drawings.

[0018] Figure 1 This is a three-dimensional structural diagram of the computer memory module processing equipment in a preferred embodiment of the present invention;

[0019] Figure 2 yes Figure 1 A three-dimensional structural diagram of the material carrier in the computer memory module processing equipment shown.

[0020] Figure 3 yes Figure 1 A three-dimensional structural diagram of the first material transfer mechanism in the computer memory module processing equipment shown.

[0021] Figure 4 yes Figure 1 A three-dimensional structural diagram of the loading and unloading conveyor belts in the computer memory module processing equipment shown.

[0022] Figure 5 yes Figure 1 A three-dimensional structural diagram of the laser engraving mechanism in the computer memory module processing equipment shown.

[0023] Figure 6 yes Figure 1 The diagram shows a three-dimensional structural schematic of the second material transfer structure in the computer memory module processing equipment.

[0024] Explanation of reference numerals in the accompanying drawings: 100, Material carrier; 110, Container rack; 120, Base; 130, Slide rail; 140, Material detector; 200, First material transfer mechanism; 210, Support; 220, First horizontal module; 230, Second horizontal module; 240, Material transfer lifting module; 250, First material transfer assembly; 300, Loading conveyor belt; 400, Laser engraving mechanism; 410, Engraving lifting module; 420, Laser engraver; 500, Barcode scanning and detection mechanism; 510, Barcode detector; 520, Adjustment frame; 600, Second material transfer mechanism; 610, Material transfer arm; 620, Second material transfer assembly; 700, Leakage testing mechanism; 710, Leakage testing platform; 800, Unloading conveyor belt; 900, Waste recycling box; X, First direction; Y, Second direction; Z, Third direction. Detailed Implementation

[0025] The present invention will be further described below with reference to the accompanying drawings and specific embodiments, so that those skilled in the art can better understand and implement the present invention. However, the embodiments are not intended to limit the present invention.

[0026] Example 1:

[0027] See Figure 1 As shown, this embodiment provides a computer memory module processing device, which includes: multiple material carriers 100, in which computer memory modules are placed; two first transfer mechanisms 200, one of which is disposed at one end of a material carrier 100, and each first transfer mechanism 200 includes a support 210 and multiple first transfer components 250 connected to the support 210; a feeding conveyor belt 300, the feeding end of which is disposed near the first transfer mechanism 200, and the first transfer components 250 are movable between the feeding conveyor belt 300 and the material carriers 100; and a laser engraving mechanism 400. A first material transfer mechanism 400 is located near the discharge end of the feeding conveyor belt 300 and includes a laser engraving device 420; a second material transfer mechanism 600, which includes a material transfer arm 610 and multiple second material transfer components 620 connected to the material transfer arm 610; a leakage testing mechanism 700, which includes multiple leakage testing platforms 710, and the second material transfer components 620 are movable between the laser engraving mechanism 400 and the leakage testing platforms 710; and a discharge conveyor belt 800, whose feed end is located near the leakage testing mechanism 700, and another first material transfer mechanism 200 is located between the leakage testing mechanism 700 and the discharge conveyor belt 800.

[0028] The computer memory module processing equipment described in this embodiment uses a material carrier 100 to hold computer memory modules. A first transfer tool then moves the modules to be processed to a loading conveyor belt 300, which then enters the working area of ​​the laser engraving mechanism 400. After laser engraving, the computer memory modules pass through a second transfer mechanism 600 to a leakage testing mechanism 700 for internal sealing testing. Products that pass the test pass through another first transfer mechanism 200 to an unloading conveyor belt 800, thus completing a complete set of high-precision engraving, leakage detection, and transfer processes. The various structures in this application are rationally laid out and highly integrated. Compared to conventional independent processing technologies, this application has significant advantages such as high automation, ease of operation, significantly improved processing accuracy and efficiency, and wide applicability.

[0029] It should be noted that, for ease of description, in this embodiment, the extension direction of the feeding conveyor belt 300 or the unloading conveyor belt 800 is defined as the first direction X, the width direction of the feeding conveyor belt 300 or the unloading conveyor belt 800 is defined as the second direction Y, and the height direction of the device is defined as the third direction Z. The first direction X, the second direction Y and the third direction Z are arranged perpendicular to each other, and the first direction X and the second direction Y are located in the same plane.

[0030] See Figure 1 and Figure 2 As shown, this embodiment includes multiple material carriers 100, some of which are used to hold computer memory modules to be processed, and the rest are used to hold processed computer memory modules. In this embodiment, the multiple material carriers 100 are arranged at intervals along the second direction Y, and any material carrier 100 can hold multiple stacked computer memory modules. Further, each material carrier 100 includes a base 120 and a holding rack 110. The base 120 is provided with a slide rail 130, and the holding rack 110 can drive the computer memory modules inside it to move synchronously along the slide rail 130, thereby improving its flexibility of use and improving the coordination accuracy between it and the first material transfer mechanism 200. Furthermore, to ensure that the first material transfer mechanism 200 can accurately connect and pick up materials, the material carrier 100 in this embodiment also includes a material detector 140. The material detector 140 is disposed at one end of the slide rail 130 and faces the interior of the holding rack 110. This utility model does not specifically limit the type of material detector 140.

[0031] See Figure 1 and Figure 3As shown, in this embodiment, two first transfer mechanisms 200 are symmetrically arranged along the second direction Y. One is used to load the computer memory module to be processed, and the other is used to unload the processed computer memory module. The two first transfer mechanisms 200 have the same structure. Here, one of them is used as an example for specific description. The first transfer mechanism 200 in this embodiment includes a first horizontal module 220, a second horizontal module 230, and a transfer lifting module 240. The first horizontal module 220 extends along the first direction X. The second horizontal module 230 is slidably connected to the first horizontal module 220. The transfer lifting module 240 is slidably connected to the second horizontal module 230. Multiple first transfer components 250 are slidably connected to the transfer lifting module 240, thereby realizing the three-dimensional movement process of the first transfer components 250. Specifically, the first transfer component 250 in this embodiment is preferably a multi-point suction cup. In different embodiments, it can also be configured as other transfer structures with connecting functions. This utility model does not impose specific limitations on this.

[0032] See Figure 1 and Figure 4 As shown, in this embodiment, both the feeding conveyor belt 300 and the unloading conveyor belt 800 extend along the first direction X and are arranged parallel to each other along the second direction Y. The transmission direction of the feeding conveyor belt 300 is opposite to that of the unloading conveyor belt 800. Furthermore, in this embodiment, both the feeding conveyor belt 300 and the unloading conveyor belt 800 are configured as motor-driven conveyor belts.

[0033] See Figure 1 and Figure 5 As shown, the laser engraving mechanism 400 in this embodiment further includes an engraving lifting module 410. The laser engraver 420 is slidably connected to the engraving lifting module 410. Furthermore, the laser engraver 420 can move up and down along the engraving lifting module 410, and can also extend and retract horizontally via a connected transverse drive motor, thereby increasing its engraving working range. To ensure the engraving quality, the computer memory module processing equipment in this embodiment also includes a barcode scanning and detection mechanism 500. The barcode scanning and detection mechanism 500 includes an adjustment frame 520 and a barcode detector 510. The adjustment frame 520 is disposed on one side of the laser engraving mechanism 400, and the barcode detector 510 is disposed on the adjustment frame 520 and faces the discharge end of the feeding conveyor belt 300 to perform engraving quality detection on the computer memory module after engraving.

[0034] See Figure 1 and Figure 6As shown, the second transfer mechanism 600 in this embodiment includes a transfer arm 610 with multiple degrees of freedom and a plurality of second transfer components 620 connected to the transfer arm 610, thereby enabling flexible movement of the computer memory module that has completed the engraving process to the leakage testing mechanism 700. The leakage testing mechanism 700 in this embodiment includes four leakage testing stations 710 arranged around the transfer arm 610, thereby improving its detection efficiency through alternating operations and adapting to different production cycles. This embodiment does not limit the specific type of leakage testing station 710.

[0035] The computer memory module processing equipment in this embodiment also includes a machine base and a waste recycling box 900. The material carrier 100, the first material transfer mechanism 200, the feeding conveyor belt 300, the laser engraving mechanism 400, the second material transfer mechanism 600, the leakage testing mechanism 700, the unloading conveyor belt 800, and the waste recycling box 900 are all disposed on the machine base, and the waste recycling box 900 is disposed on one side of the leakage testing mechanism 700. This improves the integration level and layout rationality of this application, and reduces the overall space occupied by the various mechanisms without interfering with each other.

[0036] Furthermore, the computer memory module processing equipment in this embodiment also includes a control mechanism. The material carrier 100, the first material transfer mechanism 200, the loading conveyor belt 300, the laser engraving mechanism 400, the second material transfer mechanism 600, the leakage testing mechanism 700, and the unloading conveyor belt 800 are respectively connected to the control mechanism. In actual production and processing, operators can adjust the above structures in real time through the control mechanism, thereby improving the flexibility of the equipment. Parameters can also be preset through the control mechanism, thereby improving the automation level of the equipment.

[0037] Example 2:

[0038] This embodiment provides a computer memory module manufacturing system, which includes the computer memory module processing equipment described above.

[0039] In summary, the computer memory module processing equipment and production system described in this utility model uses a material carrier 100 to hold computer memory modules. A first transfer tool then moves the modules to be processed to a loading conveyor belt 300, which in turn moves them into the working area of ​​the laser engraving mechanism 400. After laser engraving, the computer memory modules pass through a second transfer mechanism 600 to a leakage testing mechanism 700 for internal sealing testing. Products that pass the test pass through another first transfer mechanism 200 to an unloading conveyor belt 800, thus completing a complete set of high-precision engraving, leakage detection, and transfer processes. The various structures in this application are rationally laid out and highly coordinated. Compared to conventional independent processing technologies, this application has significant advantages such as high automation, ease of operation, significantly improved processing accuracy and efficiency, and wide applicability.

[0040] Obviously, the above embodiments are merely illustrative examples for clear explanation and are not intended to limit the implementation. Those skilled in the art will recognize that other variations or modifications can be made based on the above description. It is neither necessary nor possible to exhaustively list all possible implementations here. However, obvious variations or modifications derived therefrom are still within the protection scope of this invention.

Claims

1. A computer memory module processing device, characterized in that: include: Multiple material carriers, with a computer memory module housed within each of the multiple material carriers; Two first material transfer mechanisms, one of which is disposed at one end of the material carrier, and the first material transfer mechanism includes a bracket and a plurality of first material transfer components connected to the bracket; A feeding conveyor belt, the feeding end of which is located near the first material transfer mechanism, and the first material transfer component can move between the feeding conveyor belt and the material carrier; A laser marking mechanism is provided near the discharge end of the feeding conveyor belt, and includes a laser marking device. The second material transfer mechanism includes a material transfer arm and a plurality of second material transfer components connected to the material transfer arm; A leakage testing mechanism, comprising multiple leakage testing stations, wherein the second material transfer component is movable between the laser engraving mechanism and the leakage testing stations; A feeding conveyor belt is provided, with its feed end located near the leakage testing mechanism. Another first material transfer mechanism is located between the leakage testing mechanism and the feeding conveyor belt.

2. The computer memory module processing equipment according to claim 1, characterized in that: The material carrier includes a base and a container rack. The base is equipped with a slide rail, and the container rack can drive the internal computer memory module to move synchronously along the slide rail.

3. The computer memory module processing equipment according to claim 2, characterized in that: The material carrier also includes a material detector, which is located at one end of the slide rail and faces the interior of the container rack.

4. The computer memory module processing equipment according to claim 1, characterized in that: The first material transfer mechanism includes a first horizontal module, a second horizontal module, and a material transfer lifting module. The first horizontal module extends along a first direction, the second horizontal module is slidably connected to the first horizontal module, and the material transfer lifting module is slidably connected to the second horizontal module. A plurality of the first material transfer components are slidably connected to the material transfer lifting module.

5. The computer memory module processing equipment according to claim 1, characterized in that: The feeding conveyor belt and the unloading conveyor belt both extend along a first direction and are arranged parallel to each other along a second direction. The transmission direction of the feeding conveyor belt is opposite to that of the unloading conveyor belt.

6. The computer memory module processing equipment according to claim 1, characterized in that: The laser coding mechanism also includes a coding lifting module, and the laser coding device is slidably connected to the coding lifting module.

7. The computer memory module processing equipment according to claim 1, characterized in that: The computer memory module processing equipment also includes a barcode scanning and detection mechanism, which includes an adjustment frame and a barcode detector. The adjustment frame is located on one side of the laser engraving mechanism, and the barcode detector is located on the adjustment frame and faces the discharge end of the feeding conveyor belt.

8. The computer memory module processing equipment according to claim 1, characterized in that: The computer memory module processing equipment also includes a machine base and a waste recycling box. The material carrier, the first material transfer mechanism, the feeding conveyor belt, the laser engraving mechanism, the second material transfer mechanism, the leakage testing mechanism, the unloading conveyor belt, and the waste recycling box are all disposed on the machine base, and the waste recycling box is disposed on one side of the leakage testing mechanism.

9. The computer memory module processing equipment according to claim 1, characterized in that: The computer memory module processing equipment also includes a control mechanism, and the material carrier, the first material transfer mechanism, the loading conveyor belt, the laser engraving mechanism, the second material transfer mechanism, the leakage testing mechanism, and the unloading conveyor belt are respectively connected to the control mechanism.

10. A computer memory module manufacturing system, characterized in that: The computer memory module processing equipment includes any one of claims 1 to 9.