Modular debugging operation platform for intelligent software development

The modularly designed intelligent software development debugging console solves the problem of developers frequently switching between different hardware devices, enabling convenient motherboard replacement and flexible monitor adjustment, thus improving debugging efficiency and accuracy.

CN224483341UActive Publication Date: 2026-07-14XINGCHUANG TIMES (FUJIAN) TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
XINGCHUANG TIMES (FUJIAN) TECHNOLOGY CO LTD
Filing Date
2025-07-31
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

In existing technologies, during the development of intelligent software, developers need to frequently switch between different hardware devices, which increases the complexity and time cost of debugging.

Method used

A modular debugging console was designed, which enables flexible replacement and heat dissipation of the motherboard through a rotating mounting box and a servo motor-driven fan. The adjustable support structure supports multi-angle adjustment of the display, providing a convenient debugging environment.

Benefits of technology

It enables convenient motherboard replacement and heat dissipation, flexible monitor adjustment, improves debugging efficiency and accuracy, and adapts to diverse debugging needs.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224483341U_ABST
    Figure CN224483341U_ABST
Patent Text Reader

Abstract

The utility model relates to industrial production and manufacturing field discloses a modular debugging operation platform for intelligent software development, including operation platform body, the operation platform body upper surface one end is provided with debugging mechanism, the operation platform body upper surface is provided with support mechanism away from debugging mechanism one end, the debugging mechanism includes first installation box, first installation box one side is fixedly connected with rotating shaft sleeve, rotating sleeve in rotation sleeve connection has second rotating shaft. The utility model discloses through first installation box and second installation box in debugging mechanism through rotating sleeve and second rotating shaft rotation connection, second installation box can rotate flexibly, and it is convenient for developer to replace the required test mainboard to can heat dissipation to mainboard through the setting servo motor drive fan rotation to the simulation mainboard normal use's working environment, makes debugging more convenient and accurate.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model relates to the field of industrial production and manufacturing, specifically to a modular debugging console for intelligent software development. Background Technology

[0002] Modular design has been widely applied and recognized in the industrial and electronic equipment manufacturing fields. It decomposes complex systems into several modules with independent functions. These modules can be flexibly combined and configured as needed, thereby improving the system's scalability, maintainability, and reliability. Introducing modular design into the design of debugging consoles for intelligent software development can effectively solve the problems of traditional debugging methods and provide developers with an efficient, convenient, and flexible debugging environment.

[0003] In the prior art, ordinary office desks and chairs are often used with various debugging equipment. In order to debug different hardware, developers need to frequently switch between different devices, which increases the complexity and time cost of debugging. The art is to provide a modular debugging console for intelligent software development to solve the problems mentioned in the background. Utility Model Content

[0004] The purpose of this invention is to provide a modular debugging console for intelligent software development, which solves the problem in the prior art that it is not possible to conveniently assist in debugging different hardware.

[0005] This utility model provides the following technical solution: a modular debugging console for intelligent software development, including a console body, a debugging mechanism is provided at one end of the upper surface of the console body, and a support mechanism is provided at the end of the upper surface of the console body away from the debugging mechanism.

[0006] The debugging mechanism includes a first mounting box fixedly installed on one end of the upper surface of the operating table body. A rotating bushing is fixedly connected to one side of the first mounting box. A second rotating shaft is rotatably sleeved inside the rotating bushing. A second mounting box is provided on the first mounting box. The second mounting box is rotatably connected to the first mounting box through the second rotating shaft. A grid plate is fixedly installed on the upper surface of the second mounting box.

[0007] As a preferred embodiment of the above technical solution, a ventilation groove is provided at the center of the second mounting box, the ventilation groove is connected to the grid plate, and two mounting rods are symmetrically fixedly connected at the center line of the ventilation groove. A servo motor is fixedly installed at one end of the two mounting rods, and a fan is fixedly connected to the output end of the servo motor. A motherboard is inserted into the lower end face of the second mounting box, and the motherboard moves inside the first mounting box. A transmission box is fixedly connected to the side of the first mounting box opposite to the second mounting box, and a temperature sensor is fixedly installed on the inner wall of the first mounting box opposite to the second mounting box.

[0008] As a preferred embodiment of the above technical solution, the support mechanism includes a support column fixedly connected to the upper surface of the operating table body at the end opposite to the debugging mechanism. Two connecting blocks are symmetrically fixedly connected to the upper surface of the support column. A first rotating shaft is rotatably connected to the center of the opposite surfaces of the two connecting blocks. A movable plate is fixedly connected to the first rotating shaft. A rotating shaft is rotatably connected to the end of the movable plate opposite to the connecting block through the first rotating shaft. A connecting rod is fixedly connected to the center of one side of the rotating shaft. A mounting plate is fixedly connected to the end of the connecting rod opposite to the rotating shaft.

[0009] As a preferred embodiment of the above technical solution, a placement hole is provided on the upper surface of the operating table body near one corner of the support mechanism.

[0010] As a preferred embodiment of the above technical solution, a mounting bracket is fixedly connected to one end of the lower surface of the control panel body, and a drawer is fixedly connected to the end of the lower surface of the control panel body away from the mounting bracket.

[0011] As a preferred embodiment of the above technical solution, a transmission line is fixedly connected to the center line of the side of the transmission box facing away from the first mounting box.

[0012] Compared with the prior art, the beneficial effects of this utility model are:

[0013] This utility model uses a debugging mechanism in which the first mounting box and the second mounting box are rotatably connected by a rotating sleeve and a second rotating shaft. The second mounting box can rotate flexibly, which makes it easy for developers to replace the required test motherboard. By setting a servo motor to drive the fan to rotate, the motherboard can be cooled, thereby simulating the working environment of the motherboard under normal use, making debugging more convenient and accurate.

[0014] This utility model uses a connecting block fixedly connected to the support column of the support mechanism and a first rotating shaft to connect the movable plate. The movable plate is then connected to the mounting plate via a rotating shaft and a connecting rod. This structure allows the display mounted on the mounting plate to flexibly adjust its position and angle, providing stable and suitable support according to actual debugging needs and adapting to diverse debugging scenarios. Attached Figure Description

[0015] Figure 1A schematic diagram of a modular debugging console for intelligent software development;

[0016] Figure 2 A cross-sectional structural diagram of the first mounting box of a modular debugging console for intelligent software development;

[0017] Figure 3 A modular debugging console for intelligent software development Figure 1 A magnified structural diagram of A in the middle;

[0018] Figure 4 A modular debugging console for intelligent software development Figure 2 A magnified structural diagram of B in the diagram;

[0019] Figure 5 This is a schematic diagram of the servo motor structure of a modular debugging console for intelligent software development.

[0020] 1. Control panel body; 2. Support mechanism; 21. Support column; 22. Connecting block; 23. First rotating shaft; 24. Movable plate; 25. Rotating shaft; 26. Connecting rod; 27. Mounting plate; 3. Debugging mechanism; 31. First mounting box; 32. Second mounting box; 33. Rotating bushing; 34. Second rotating shaft; 35. Grid plate; 36. Transmission box; 37. Main board; 38. Mounting rod; 39. Servo motor; 310. Fan; 4. Drawer; 5. Mounting bracket; 6. Transmission line; 7. Placement hole; 8. Temperature sensor. Detailed Implementation

[0021] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention.

[0022] Please see Figures 1-5 As shown, this utility model provides a technical solution: a modular debugging workbench for intelligent software development, including a workbench body 1, a debugging mechanism 3 is provided at one end of the upper surface of the workbench body 1, and a support mechanism 2 is provided at the end of the upper surface of the workbench body 1 away from the debugging mechanism 3.

[0023] The debugging mechanism 3 includes a first mounting box 31 fixedly installed on one end of the upper surface of the operating table body 1. A rotating bushing 33 is fixedly connected to one side of the first mounting box 31. A second rotating shaft 34 is rotatably sleeved inside the rotating bushing 33. A second mounting box 32 is provided on the first mounting box 31. The second mounting box 32 is rotatably connected to the first mounting box 31 through the second rotating shaft 34. A grid plate 35 is fixedly installed on the upper surface of the second mounting box 32.

[0024] Specifically, the second mounting box 32 on the first mounting box 31 is rotatably connected to the first mounting box 31, so that the motherboard 37 that needs to be debugged can be placed in the first mounting box 31. The grid plate 35 ensures good ventilation. The operating table body 1 is made of high-strength aluminum alloy frame combined with engineering plastic panel. The surface is anodized, which has good wear resistance and antistatic properties. The upper surface is provided with antistatic silicone pad to effectively protect electronic components from static damage. The grid plate 35 adopts magnetic design, which can be quickly disassembled and cleaned, which can effectively dissipate heat and prevent foreign objects from entering.

[0025] As one implementation method in this embodiment, please refer to Figure 1 and Figure 2 As shown, a ventilation groove is provided at the center of the second mounting box 32, which is connected to the grid plate 35. Two mounting rods 38 are symmetrically fixedly connected at the center line of the ventilation groove. A servo motor 39 is fixedly installed at one end of the two mounting rods 38. A fan 310 is fixedly connected to the output end of the servo motor 39. A main board 37 is inserted into the lower end face of the second mounting box 32. The main board 37 is movable in the first mounting box 31. A transmission box 36 is fixedly connected to the side of the first mounting box 31 opposite to the second mounting box 32. A temperature sensor 8 is fixedly installed on the inner wall of the first mounting box 31 opposite to the second mounting box 32.

[0026] Specifically, temperature sensor 8 monitors the temperature inside the first mounting box 31 in real time, providing real-time monitoring of the motherboard 37 temperature under normal use for easy observation. The motherboard 37 adopts a rail-mounted structure for easy and quick plug-and-play replacement. The transmission box 36 is equipped with a surge protector that can withstand pulse voltage and effectively protect the internal circuitry. The drawer 4 uses a damped slide rail with maximum load-bearing capacity to meet requirements. Built-in dividers allow for the categorized storage of tools. The transmission box 36 has a motherboard 37 interface on the side adjacent to the first mounting box 31, allowing for the connection of motherboards 37 different from those plugged into the second mounting box 32, thus facilitating better debugging of different motherboards 37.

[0027] As one implementation method in this embodiment, please refer to Figures 1-3 As shown, the support mechanism 2 includes a support column 21 fixedly connected to the upper surface of the operating table body 1 at the end opposite to the debugging mechanism 3. Two connecting blocks 22 are symmetrically fixedly connected to the upper surface of the support column 21. A first rotating shaft 23 is rotatably connected at the center of the opposite surfaces of the two connecting blocks 22. A movable plate 24 is fixedly connected to the first rotating shaft 23. A rotating shaft 25 is rotatably connected to the end of the movable plate 24 opposite to the connecting block 22 through the first rotating shaft 23. A connecting rod 26 is fixedly connected to the center of one side of the rotating shaft 25. A mounting plate 27 is fixedly connected to the end of the connecting rod 26 opposite to the rotating shaft 25.

[0028] In practice, the pivot 25 and the connecting rod 26 are connected by a universal joint, so that the mounting plate 27 can be adjusted to multiple angles such as pitch and lateral rotation to meet different viewing angle requirements.

[0029] As one implementation method in this embodiment, please refer to Figure 1 As shown, a placement hole 7 is provided on the upper surface of the control panel body 1 near one corner of the support mechanism 2.

[0030] In a specific implementation, the placement hole 7 can be used to fix a water cup or temporarily place debugging tools; a drainage hole is provided at the bottom of the hole to prevent liquid residue.

[0031] As one implementation method in this embodiment, please refer to Figure 1 As shown, a mounting bracket 5 is fixedly connected to one end of the lower surface of the control panel body 1, and a drawer 4 is fixedly connected to the end of the lower surface of the control panel body 1 away from the mounting bracket 5.

[0032] Specifically, the mounting bracket 5 on the lower surface of the control panel body 1 adopts an L-shaped metal bracket, which can be used to install external devices such as the host and printer.

[0033] As one implementation method in this embodiment, please refer to Figure 1 As shown, a transmission line 6 is fixedly connected to the center line of the side of the transmission box 36 facing away from the first mounting box 31.

[0034] In practice, the interface of transmission line 6 is equipped with a waterproof and dustproof rubber cover to protect the interface when not in use, and transmission line 6 can connect the data on the motherboard 37 to different devices.

[0035] Working principle: First, the computer host and monitor are installed in the mounting bracket 5 and mounting plate 27 respectively. When debugging begins, the first mounting box 31 is rotated and connected to the second mounting shaft 34, causing the first mounting box 31 to separate from the second mounting box 32. Then, the developer places the motherboard 37 to be debugged in the first mounting box 31 and connects it to the second mounting box 32 for electrical connection. Then, the servo motor 39 is started to drive the fan 310 to cool the motherboard 37. When debugging the program through the motherboard 37, the temperature of the motherboard 37 can be monitored in real time by the temperature sensor 8 to determine whether the developed software is suitable for the motherboard 37. When the debugging scene changes and the monitor needs to be adjusted, the movable plate 24 can be connected through the connecting block 22 fixed on the support column 21 and the first rotating shaft 23. The movable plate 24 is then connected to the mounting plate 27 through the rotating shaft 25 and the connecting rod 26, so that the mounting plate 27 can be adjusted to a suitable position to meet the position adjustment of the monitor.

[0036] The above embodiments are only used to illustrate the technical solution of this utility model, and are not intended to limit it.

Claims

1. A modular debugging console for intelligent software development, comprising a console body (1), characterized in that: An adjustment mechanism (3) is provided at one end of the upper surface of the operating table body (1), and a support mechanism (2) is provided at the end of the upper surface of the operating table body (1) away from the adjustment mechanism (3). The debugging mechanism (3) includes a first mounting box (31) fixedly installed on one end of the upper surface of the operating table body (1). A rotating bushing (33) is fixedly connected to one side of the first mounting box (31). A second rotating shaft (34) is rotatably sleeved inside the rotating bushing (33). A second mounting box (32) is provided on the first mounting box (31). The second mounting box (32) is rotatably connected to the first mounting box (31) through the second rotating shaft (34). A grid plate (35) is fixedly installed on the upper surface of the second mounting box (32).

2. The modular debugging console for intelligent software development according to claim 1, characterized in that: The second mounting box (32) has a ventilation groove at its center, which is connected to the grid plate (35). Two mounting rods (38) are symmetrically fixedly connected at the center line of the ventilation groove. A servo motor (39) is fixedly installed at one end of the two mounting rods (38). A fan (310) is fixedly connected to the output end of the servo motor (39). A motherboard (37) is inserted into the lower end face of the second mounting box (32). The motherboard (37) moves inside the first mounting box (31). A transmission box (36) is fixedly connected to the side of the first mounting box (31) away from the second mounting box (32). A temperature sensor (8) is fixedly installed on the inner wall of the first mounting box (31) away from the second mounting box (32).

3. The modular debugging console for intelligent software development according to claim 1, characterized in that: The support mechanism (2) includes a support column (21) fixedly connected to the upper surface of the operating table body (1) at one end away from the debugging mechanism (3). Two connecting blocks (22) are symmetrically fixedly connected to the upper surface of the support column (21). A first rotating shaft (23) is rotatably connected to the center of the opposite face of the two connecting blocks (22). A movable plate (24) is fixedly connected to the first rotating shaft (23). A rotating shaft (25) is rotatably connected to the end of the movable plate (24) away from the connecting block (22) through the first rotating shaft (23). A connecting rod (26) is fixedly connected to the center of one side of the rotating shaft (25). A mounting plate (27) is fixedly connected to the end of the connecting rod (26) away from the rotating shaft (25).

4. The modular debugging console for intelligent software development according to claim 1, characterized in that: The upper surface of the control panel body (1) near the support mechanism (2) has a placement hole (7).

5. A modular debugging console for intelligent software development according to claim 1, characterized in that: A mounting bracket (5) is fixedly connected to one end of the lower surface of the control panel body (1), and a drawer (4) is fixedly connected to the end of the lower surface of the control panel body (1) away from the mounting bracket (5).

6. A modular debugging console for intelligent software development according to claim 2, characterized in that: A transmission line (6) is fixedly connected to the center line of the side of the transmission box (36) facing away from the first mounting box (31).