Debugging apparatus for silicon-based coarse wavelength division multiplexer

By introducing a fixed frame and support mechanism into the silicon-based coarse wavelength division multiplexer commissioning device, the problems of interface protection and stability are solved, achieving effective protection and stability on connections and uneven surfaces, and ensuring normal operation of the device.

CN224342612UActive Publication Date: 2026-06-09ZHUHAI HAOXUN PHOTOELECTRIC TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ZHUHAI HAOXUN PHOTOELECTRIC TECH CO LTD
Filing Date
2025-05-23
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

Existing silicon-based coarse wavelength division multiplexer debugging devices lack effective protection at the interface, making them susceptible to damage from dust and water splashes. They also exhibit poor stability when placed on uneven surfaces, making them prone to slipping or shaking.

Method used

An adjustment device comprising a fixed frame, a protective mechanism, and a support mechanism is designed. The protective mechanism provides protection when the plug is connected to the interface through components such as slide rods, pull plates, and stops. The support mechanism maintains the stability of the device on uneven surfaces through components such as support legs and rotating rods.

Benefits of technology

It effectively prevents dust and water from splashing into the interface, maintains the stability of the device on uneven surfaces, avoids slippage or tipping, and ensures normal use.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a debugging device for silicon base coarse wave division multiplexer relates to wave division multiplexer technical field, and this debugging device includes debugging mechanism body, the outer wall fixedly connected with fixed frame of debugging mechanism body, the outer wall of debugging mechanism body is close to the interface that fixed frame has seted up, the position of fixed frame corresponding interface has seted up through -hole, and the inner wall of fixed frame is close to the upper surface of debugging mechanism body and is provided with the protection mechanism. The utility model discloses the cooperation of fixed frame and protection mechanism, reached can be in the state of plug and interface insertion, still can have played the effect of effective protection, when the plug and interface are connected state, the protection mechanism can effectively avoid dust and water splash into the interface, when the plug and interface are connected, the protection mechanism can also carry out the protection to the interface that has connected, and simultaneously the interface department that is not connected, still can be protected, will not be affected.
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Description

Technical Field

[0001] This utility model relates to the field of wavelength division multiplexer technology, specifically a debugging device for silicon-based coarse wavelength division multiplexers. Background Technology

[0002] A wavelength division multiplexer (WDM) is a communication technology that combines a series of optical signals carrying information but with different wavelengths into a single beam and transmits it along a single optical fiber. At the receiving end, a certain method is used to separate the optical signals of different wavelengths. When using a WDM, a debugging mechanism is required to debug the WDM. However, existing debugging mechanisms do not have effective protection at their interfaces, making them susceptible to dust intrusion and water splashes, whether in use or not, causing damage to the interfaces. In addition, when placing the debugging mechanism on an uneven surface, the device may slip, affecting its normal operation.

[0003] For example, a debugging device for a silicon-based coarse wavelength division multiplexer described in patent CN221842781U uses bolts to install a second fixing frame on the back of a first fixing frame. At this time, the wire hole is located inside the box. When the debugging device for the silicon-based coarse wavelength division multiplexer is placed for a long time, the torque provided by the torsion spring can be used to close the cover plate on the back of the box, thereby hiding the wire hole and providing a protective effect, so that external dust or water stains will not splash in. It has strong protection when in use. However, when the wire hole is plugged into the connector, the protective effect is lost, and dust and water stains can still affect the wire hole. At the same time, when the debugging mechanism body is placed, if the place is not flat, the stability of the device will decrease, and it may shake or slip, affecting the normal use of the device.

[0004] Based on this, a commissioning device for silicon-based coarse wavelength division multiplexers is now provided, which can eliminate the drawbacks of existing devices. Utility Model Content

[0005] The purpose of this invention is to provide a debugging device for silicon-based coarse wavelength division multiplexers to solve the problems in the background art.

[0006] To achieve the above objectives, this utility model provides the following technical solution:

[0007] A debugging device for a silicon-based coarse wavelength division multiplexer includes a debugging mechanism body, a fixing frame fixedly connected to the outer wall of the debugging mechanism body, an interface provided on the outer wall of the debugging mechanism body near the fixing frame, a through hole opened on the fixing frame at the position corresponding to the interface, a protective mechanism provided on the inner wall of the fixing frame near the upper surface of the debugging mechanism body, and a support mechanism provided on the lower surface of the debugging mechanism body.

[0008] Based on the above technical solutions, this utility model also provides the following optional technical solutions:

[0009] Preferably, the protective mechanism includes a sliding rod, the outer wall of which is slidably connected to the inner wall of the fixed frame, a pull plate fixedly connected to the right end of the sliding rod, a limit block slidably connected to the inner wall of the sliding rod, the outer wall of the limit block slidably connected to the inner wall of the fixed frame, a stop block fixedly connected to the bottom end of the limit block, and the stop block corresponds to a through hole opened on the outer wall of the fixed frame, the outer wall of the stop block slidably connected to the inner wall of the fixed frame, and a second spring fixedly connected to the outer wall of the stop block, the outer wall of the second spring being fixedly connected to the inner cavity of the fixed frame.

[0010] Preferably, a plug is fixedly connected to the outer wall of the pull plate near the fixed frame. The outer wall of the plug is inserted into the inner wall of the fixed frame. A limit rod is inserted into the inner wall of the plug. The outer wall of the limit rod is inserted into the inner wall of the fixed frame. A spring is sleeved on the outer wall of the limit rod. One end of the spring is fixedly connected to the outer wall of the fixed frame, and the other end is fixedly connected to the outer wall of the limit rod.

[0011] Preferably, the outer wall of the fixed frame is provided with a groove that matches the shape of the limiting block, and the length of the groove is greater than the effective retraction distance of the second spring.

[0012] Preferably, the inner wall of the stop is fixedly connected with an elastic band.

[0013] Preferably, the size of the stop block is larger than the through hole opened on the outer wall of the fixed frame.

[0014] Preferably, the support mechanism includes a support leg, the top end of which is fixedly connected to the lower surface of the debugging mechanism body. A rotating rod is rotatably connected to the support leg near the inner wall of the debugging mechanism body. An active bevel tooth is fixedly connected to the outer wall of the rotating rod. A driven bevel tooth meshes with the outer wall of the active bevel tooth. A threaded rod is fixedly connected to the axis of the driven bevel tooth. The top end of the threaded rod is rotatably connected to the inner cavity of the support leg. A slider is threadedly connected to the outer wall of the threaded rod. The outer wall of the slider is slidably connected to the inner wall of the support leg. A pad is fixedly connected to the bottom end of the slider.

[0015] Preferably, the slider is T-shaped, and the inner cavity of the support leg is provided with a groove for the slider to slide. The part of the groove away from the pad is adapted to the larger part of the slider, and the part close to the pad is adapted to the smaller part of the slider.

[0016] Compared with the prior art, the beneficial effects of this utility model are as follows:

[0017] 1. This utility model, through the cooperation of a fixed frame and a protective mechanism, achieves effective protection even when the plug and interface are connected. When the plug and interface are not connected, the protective mechanism can effectively prevent dust and water from splashing into the interface. When the plug and interface are connected, the protective mechanism can also protect the connected interface. At the same time, the unconnected interface can still be protected and will not be affected.

[0018] 2. This utility model achieves the effect of keeping the device stable even on uneven surfaces through the support mechanism. The support mechanism can provide stable support for the device. When the device is placed on an uneven surface, causing the device to sway or tilt, the support mechanism can be adjusted according to the tilt direction of the device to keep the device stable, thereby preventing the device from swaying or slipping. Attached Figure Description

[0019] Figure 1 This is a schematic diagram of the overall structure of this utility model.

[0020] Figure 2 This is a cross-sectional structural diagram of the present invention.

[0021] Figure 3 This is a schematic diagram of the protective mechanism of this utility model.

[0022] Figure 4 This is a schematic diagram of the structure of the fixing frame of this utility model.

[0023] Figure 5 This is a schematic diagram of the support mechanism of this utility model.

[0024] Attached Figure Labels: 1. Debugging Mechanism Body; 11. Fixed Frame; 2. Protective Mechanism; 21. Slide Rod; 22. Pull Plate; 23. Insert Block; 24. Limiting Rod; 25. Spring One; 26. Limiting Block; 27. Stop Block; 28. Elastic Band; 29. ​​Spring Two; 3. Support Mechanism; 31. Support Leg; 32. Rotating Rod; 33. Active Bevel Gear; 34. Driven Bevel Gear; 35. Threaded Rod; 36. Slider; 37. Pad Block. Detailed Implementation

[0025] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to the accompanying drawings and embodiments.

[0026] In one embodiment, such as Figures 1-5As shown, the debugging device for a silicon-based coarse wavelength division multiplexer includes a debugging mechanism body 1, a fixing frame 11 fixedly connected to the outer wall of the debugging mechanism body 1, an interface provided on the outer wall of the debugging mechanism body 1 near the fixing frame 11, a through hole opened at the position of the fixing frame 11 corresponding to the interface, a protective mechanism 2 provided on the inner wall of the fixing frame 11 near the upper surface of the debugging mechanism body 1, and a support mechanism 3 provided on the lower surface of the debugging mechanism body 1.

[0027] In this embodiment, the interface of the debugging mechanism body 1 is protected by the protective mechanism 2, so that it can be dustproof and waterproof when not in use, and can also play a certain protective role when in use. Subsequently, the placement of the debugging mechanism body 1 can be adjusted by the support mechanism 3 to keep the debugging mechanism body 1 stable and prevent the debugging mechanism body 1 from sliding or tipping over.

[0028] In an optional embodiment, such as Figures 2-4 As shown, the protective mechanism 2 includes a slide rod 21. The outer wall of the slide rod 21 is slidably connected to the inner wall of the fixed frame 11. A pull plate 22 is fixedly connected to the right end of the slide rod 21. A limit block 26 is slidably connected to the inner wall of the slide rod 21. The outer wall of the limit block 26 is slidably connected to the inner wall of the fixed frame 11. A stop block 27 is fixedly connected to the bottom end of the limit block 26, and the stop block 27 corresponds to a through hole opened on the outer wall of the fixed frame 11. The outer wall of the stop block 27 is slidably connected to the inner wall of the fixed frame 11. A second spring 29 is fixedly connected to the outer wall of the stop 27. The outer wall of the second spring 29 is fixedly connected to the inner cavity of the fixed frame 11. By pulling the pull plate 22, the pull plate 22 drives the slide rod 21 to slide on the inner wall of the fixed frame 11. The slide rod 21 drives the limiting block 26 to move synchronously, so that the limiting block 26 drives the stop 27 to slide on the inner wall of the fixed frame 11, causing the second spring 29 to retract. When the stop 27 no longer blocks the through hole, the plug and the interface can be connected (wherein, with Figure 2 With the perspective as the main focus, the position of the through hole is slightly to the right relative to the interface position, so that when the plug is connected to the interface, the connecting wire of the plug is located at the elastic band 28. After connection, the pull plate 22 is released, and under the action of the elastic force of the second spring 29, the stop block 27 is driven to slide on the inner wall of the fixed frame 11, so that the outer wall of the elastic band 28 contacts the connecting wire of the plug. The elastic band 28 deforms and fixes the connecting wire of the plug, so that the plug can also play a protective role when connected to the interface.

[0029] In an optional embodiment, such as Figure 2 and Figure 4As shown, a plug 23 is fixedly connected to the outer wall of the pull plate 22 near the fixed frame 11. The outer wall of the plug 23 is inserted into the inner wall of the fixed frame 11. A limit rod 24 is inserted into the inner wall of the plug 23. The outer wall of the limit rod 24 is inserted into the inner wall of the fixed frame 11. A spring 25 is sleeved on the outer wall of the limit rod 24. One end of the spring 25 is fixedly connected to the outer wall of the fixed frame 11, and the other end is fixedly connected to the outer wall of the limit rod 24. By pulling the limit rod 24, the spring 25 is extended, so that the outer wall of the limit rod 24 is no longer inserted into the outer wall of the plug 23, and then the pull plate 22 can be pulled.

[0030] In an optional embodiment, such as Figure 2 and Figure 3 As shown, the outer wall of the fixed frame 11 is provided with a groove that matches the shape of the limiting block 26, and the length of the groove is greater than the effective contraction distance of the spring 29. In this way, when the elastic band 28 fixes the connector wire of the plug, the sliding of the limiting block 26 on the inner wall of the slide bar 21 will not be obstructed.

[0031] In an optional embodiment, such as Figure 2 and Figure 3 As shown, the inner wall of the stop 27 is fixedly connected with an elastic band 28. The elastic band 28 can fix and protect the plug connection line that has been connected to the interface. In the unconnected state, it can also effectively protect against dust and water splashing in.

[0032] In an optional embodiment, such as Figure 2 and Figure 3 As shown, the size of the stop block 27 is larger than the through hole opened on the outer wall of the fixed frame 11, thereby avoiding incomplete coverage by the stop block 27 and the appearance of gaps.

[0033] In an optional embodiment, such as Figure 2 and Figure 5 As shown, the support mechanism 3 includes a support leg 31. The top end of the support leg 31 is fixedly connected to the lower surface of the debugging mechanism body 1. A rotating rod 32 is rotatably connected to the support leg 31 near the inner wall of the debugging mechanism body 1. An active bevel tooth 33 is fixedly connected to the outer wall of the rotating rod 32. A driven bevel tooth 34 meshes with the outer wall of the active bevel tooth 33. A threaded rod 35 is fixedly connected to the axis of the driven bevel tooth 34. The top end of the threaded rod 35 is rotatably connected to the inner cavity of the support leg 31. A slider 36 is threadedly connected to the outer wall of the threaded rod 35. The outer wall of the slider 36 is slidably connected to the inner wall of the support leg 31. A pad 37 is fixedly connected to the bottom end of the slider 36. By rotating the rotating rod 32, the active bevel tooth 33 meshes with the driven bevel tooth 34, causing the driven bevel tooth 34 to drive the threaded rod 35 to rotate. This causes the slider 36 to move downward on the outer wall of the threaded rod 35. The slider 36 drives the pad 37 to move downward synchronously, thereby changing the support height of the support leg 31, keeping the device stable, and preventing it from slipping or tipping over.

[0034] In an optional embodiment, such as Figure 2 and Figure 5 As shown, the slider 36 is T-shaped, and the inner cavity of the support leg 31 has a groove for the slider 36 to slide. The part of the groove away from the pad 37 is adapted to the larger part of the slider 36, and the part close to the pad 37 is adapted to the smaller part of the slider 36. Thus, when the height of the support leg 31 is changed, the slider 36 can be prevented from coming out of the inner cavity of the support leg 31.

[0035] The above embodiments disclose a debugging device for a silicon-based coarse wavelength division multiplexer. When it is necessary to connect the plug to the interface, pulling the limiting rod 24 causes the spring 25 to extend, so that the outer wall of the limiting rod 24 is no longer inserted into the outer wall of the plug block 23. Then, the pull plate 22 can be pulled, causing the pull plate 22 to slide the sliding rod 21 against the inner wall of the fixed frame 11. The sliding rod 21 drives the limiting block 26 to move synchronously, causing the limiting block 26 to slide against the stop block 27 against the inner wall of the fixed frame 11. When spring 29 retracts and stop 27 no longer blocks the through hole, the plug can be connected to the interface. After connection, release pull plate 22. Under the elastic force of spring 29, stop 27 slides against the inner wall of fixed frame 11, causing the outer wall of elastic band 28 to contact the connector wire of the plug. Elastic band 28 deforms and fixes the connector wire of the plug. At this time, slide rod 21 returns to its original position. Then, limit rod 24 is inserted into plug block 23 to ensure the plug is properly seated. Even when the interface is connected, it still provides protection. When the debugging mechanism body 1 is placed on an uneven surface, the height of the corresponding support leg 31 can be adjusted according to the tilt direction of the device to keep it stable. By rotating the rotating rod 32, the active bevel gear 33 and the driven bevel gear 34 are engaged, causing the driven bevel gear 34 to drive the threaded rod 35 to rotate. This causes the slider 36 to move downward on the outer wall of the threaded rod 35, and the slider 36 drives the pad 37 to move downward synchronously, thereby changing the support height of the support leg 31 to keep the device stable and prevent it from slipping or tipping over. In summary, the protective mechanism 2 protects the interface of the debugging mechanism body 1, making it dustproof and waterproof when not in use, and also providing a certain degree of protection when in use. Subsequently, the support mechanism 3 can be used to adjust the placement of the debugging mechanism body 1 to keep it stable and prevent it from slipping or tipping over.

[0036] The above description is merely a specific embodiment of this application, but the scope of protection of this application is not limited thereto. Any variations or substitutions that can be easily conceived by those skilled in the art within the technical scope disclosed in this application should be included within the scope of protection of this application. Therefore, the scope of protection of this application should be determined by the scope of the claims.

Claims

1. A debugging device for a silicon-based coarse wavelength division multiplexer, comprising a debugging mechanism body (1), wherein a fixing frame (11) is fixedly connected to the outer wall of the debugging mechanism body (1), characterized in that, The debugging mechanism body (1) has an interface on the outer wall near the fixed frame (11), and the fixed frame (11) has a through hole at the position corresponding to the interface. The fixed frame (11) has a protective mechanism (2) on the inner wall near the upper surface of the debugging mechanism body (1), and a support mechanism (3) is provided on the lower surface of the debugging mechanism body (1).

2. The debugging device for a silicon-based coarse wavelength division multiplexer according to claim 1, characterized in that, The protective mechanism (2) includes a slide rod (21), the outer wall of the slide rod (21) is slidably connected to the inner wall of the fixed frame (11), a pull plate (22) is fixedly connected to the right end of the slide rod (21), a limit block (26) is slidably connected to the inner wall of the slide rod (21), the outer wall of the limit block (26) is slidably connected to the inner wall of the fixed frame (11), a stop block (27) is fixedly connected to the bottom end of the limit block (26), and the stop block (27) corresponds to the through hole opened on the outer wall of the fixed frame (11), the outer wall of the stop block (27) is slidably connected to the inner wall of the fixed frame (11), a second spring (29) is fixedly connected to the outer wall of the stop block (27), and the outer wall of the second spring (29) is fixedly connected to the inner cavity of the fixed frame (11).

3. The debugging device for a silicon-based coarse wavelength division multiplexer according to claim 2, characterized in that, A plug (23) is fixedly connected to the outer wall of the pull plate (22) near the fixed frame (11). The outer wall of the plug (23) is inserted into the inner wall of the fixed frame (11). A limit rod (24) is inserted into the inner wall of the plug (23). The outer wall of the limit rod (24) is inserted into the inner wall of the fixed frame (11). A spring (25) is sleeved on the outer wall of the limit rod (24). One end of the spring (25) is fixedly connected to the outer wall of the fixed frame (11), and the other end is fixedly connected to the outer wall of the limit rod (24).

4. The debugging device for a silicon-based coarse wavelength division multiplexer according to claim 2, characterized in that, The outer wall of the fixed frame (11) is provided with a groove that matches the shape of the limiting block (26), and the length of the groove is greater than the effective contraction distance of the second spring (29).

5. The debugging device for a silicon-based coarse wavelength division multiplexer according to claim 2, characterized in that, An elastic band (28) is fixedly connected to the inner wall of the stop (27).

6. The debugging device for a silicon-based coarse wavelength division multiplexer according to claim 2, characterized in that, The size of the stop (27) is larger than the through hole opened on the outer wall of the fixed frame (11).

7. The debugging device for a silicon-based coarse wavelength division multiplexer according to claim 1, characterized in that, The support mechanism (3) includes a support leg (31). The top end of the support leg (31) is fixedly connected to the lower surface of the debugging mechanism body (1). The support leg (31) is rotatably connected to the inner wall of the debugging mechanism body (1). The outer wall of the rotating rod (32) is fixedly connected to an active bevel tooth (33). The outer wall of the active bevel tooth (33) is engaged with a driven bevel tooth (34). A threaded rod (35) is fixedly connected to the axis of the driven bevel tooth (34). The top end of the threaded rod (35) is rotatably connected to the inner cavity of the support leg (31). A slider (36) is threadedly connected to the outer wall of the threaded rod (35). The outer wall of the slider (36) is slidably connected to the inner wall of the support leg (31). A pad (37) is fixedly connected to the bottom end of the slider (36).

8. The debugging device for a silicon-based coarse wavelength division multiplexer according to claim 7, characterized in that, The slider (36) is T-shaped, and the inner cavity of the support leg (31) is provided with a groove for the slider (36) to slide. The part of the groove away from the pad (37) is adapted to the larger part of the slider (36), and the part close to the pad (37) is adapted to the smaller part of the slider (36).