Signal processing subboard with multi-interface integrated structure
By designing a multi-interface integrated structure on the signal processing daughterboard and using sliding and locking mechanisms to expand the number of interfaces, the problem of insufficient interfaces on the signal processing daughterboard when multiple devices are connected is solved, achieving stable data transmission and flexible interface use.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Filing Date
- 2025-07-31
- Publication Date
- 2026-07-10
AI Technical Summary
The signal processing daughterboard cannot form multiple interfaces for simultaneous connection when multiple devices need to be connected at the same time, and its small size makes it impossible to solder multiple sets of interfaces, resulting in inconvenience in use.
A signal processing sub-board with a multi-interface integrated structure was designed. Multiple sets of second interfaces are provided on the top of the interface board, and the interface board can be slid out to increase the number of interfaces. Electrical connections are formed using metal sliders and slide plates to ensure stability during the sliding process. Locking and separation of the interface board are achieved through locking rods and locking holes.
It achieves the effect of providing simultaneous connection and transmission of multiple sets of data without increasing the size, solves the problem of insufficient interfaces, and ensures the stability of data transmission and the flexible use of interfaces.
Smart Images

Figure CN224481895U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of signal processing board technology, specifically to a signal processing sub-board with a multi-interface integrated structure. Background Technology
[0002] Currently, signal processing daughterboards are responsible for performing complex calculations on large amounts of data, performing rapid calculations on control systems, managing peripherals quickly, managing external communications in real time, and supporting operating systems.
[0003] During normal use, the signal processing daughterboard needs to connect to various devices or computers through interfaces. Especially when multiple devices need to be connected at the same time, it is impossible to form multiple interfaces for simultaneous connection, causing inconvenience during use. Moreover, the signal processing daughterboard is generally too small to allow for the soldering of multiple sets of interfaces to meet the needs of use. In order to solve the above problems, we propose a signal processing daughterboard with a multi-interface integrated structure. Utility Model Content
[0004] In view of the problems existing in the signal processing sub-board with multi-interface integrated structure, this utility model is proposed.
[0005] Therefore, the purpose of this utility model is to provide a signal processing sub-board with a multi-interface integrated structure. By providing multiple sets of second interfaces on the top of the interface board, the interface board can be slid out when there are insufficient interfaces, which can directly increase the number of interfaces of the processing board, forming the effect of simultaneous connection and transmission of multiple sets of data. While ensuring that the size remains unchanged, it also solves the problem of insufficient interface usage of traditional processing boards, thus solving the problem of signal processing sub-boards with multi-interface integrated structures.
[0006] To achieve the above objectives, this utility model provides the following technical solution:
[0007] A signal processing sub-board with a multi-interface integrated structure includes a processing board. A board shell is installed on the right side of the top of the processing board. A board groove is formed on the top of the board shell. A sliding groove is formed on the bottom of the board groove. A limiting groove is formed in the middle of the top of the sliding groove. Multiple sets of metal sliding strips are built into the limiting groove. An interface board is built into the board groove. A first interface is installed on the left side of the interface board. A second interface is provided on the top of the interface board, and multiple sets of the second interface are evenly arranged. A sliding plate is fixed to the bottom of the interface board. Multiple sets of metal sliding pieces are provided at the bottom of the sliding plate.
[0008] Preferably, the bottom end of the metal slider is attached to the top of the metal slider strip, the metal slider strip is in the shape of a circular strip, the first interface, the second interface, the metal slider strip and the metal slider strip are electrically connected, and the metal slider strip is connected to the data receiving end of the processing board.
[0009] Preferably, the size of the sliding plate and the sliding groove are adapted to each other, and the sliding plate and the sliding groove form a sliding mechanism. Mounting holes are provided at the four corners of the top of the processing plate.
[0010] Preferably, a rod groove is provided at the top left side of the interface plate, and a spring and a locking rod are built into the rod groove. The left end of the locking rod passes through the back of the interface plate, and a push handle is fixed to the outer wall of the locking rod.
[0011] Preferably, a lock hole is provided at the top of the inner wall of the plate groove, one end of the lock rod is semi-circular and is inserted into the lock hole, one end of the spring is fixed to the other end of the lock rod, and the other end of the spring is fixedly connected to the inner wall of the rod groove.
[0012] The technical effects and advantages provided by this utility model in the above technical solution are as follows:
[0013] 1. This utility model has multiple sets of second interfaces on the top of the interface board. When there are not enough interfaces, the interface board can be slid out to directly increase the number of interfaces on the processing board, forming the effect of simultaneous connection and transmission of multiple sets of data. This ensures that the size remains unchanged while solving the problem of insufficient interface usage in traditional processing boards. Attached Figure Description
[0014] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments recorded in this utility model. For those skilled in the art, other drawings can be obtained based on these drawings.
[0015] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0016] Figure 2 This is a schematic diagram of the joint structure between the shell and the slide plate of this utility model;
[0017] Figure 3 This is a schematic diagram of the internal structure of the plate shell of this utility model;
[0018] Figure 4 This is a schematic diagram of the bottom structure of the interface board of this utility model;
[0019] Figure 5 This is an enlarged schematic diagram of the structure at point A of this utility model.
[0020] Explanation of reference numerals in the attached figures:
[0021] 1. Processing plate; 2. Plate shell; 3. Plate groove; 4. Metal slider; 5. Mounting hole; 6. Interface plate; 7. Slide plate; 8. First interface; 9. Rod groove; 10. Push handle; 11. Locking rod; 12. Second interface; 13. Slide groove; 14. Locking hole; 15. Limiting groove; 16. Metal slider; 17. Spring. Detailed Implementation
[0022] To enable those skilled in the art to better understand the technical solution of this utility model, the present utility model will be further described in detail below with reference to the accompanying drawings.
[0023] This utility model embodiment discloses a signal processing sub-board with a multi-interface integrated structure.
[0024] This utility model provides, for example Figure 1-5 The signal processing sub-board with a multi-interface integrated structure shown includes a processing board 1. A board shell 2 is installed on the right side of the top of the processing board 1. A board groove 3 is opened on the top of the board shell 2. A sliding groove 13 is opened at the bottom of the board groove 3. A limiting groove 15 is opened in the middle of the top of the sliding groove 13. Multiple sets of metal sliders 16 are built into the limiting groove 15. An interface board 6 is built into the board groove 3. A first interface 8 is installed on the left side of the interface board 6. A second interface 12 is provided on the top of the interface board 6, and multiple sets of second interfaces 12 are evenly arranged. A sliding plate 7 is fixed to the bottom of the interface board 6. Multiple sets of metal sliders 4 are provided at the bottom of the sliding plate 7. By providing multiple sets of second interfaces 12 on the top of the interface board 6, the interface board 6 can be slid out when there are not enough interfaces, which can directly provide the number of interfaces of the processing board 1, forming the effect of simultaneous connection and transmission of multiple sets of data. This solves the problem of insufficient interface usage of traditional processing boards 1 while maintaining the same size.
[0025] To ensure data can be transmitted normally during movement: such as Figure 1 , Figure 3 and Figure 4 As shown, the bottom end of the metal slider 4 is attached to the top of the metal slider 16. The metal slider 4 is in the shape of a round bar. The first interface 8, the second interface 12, the metal slider 16 and the metal slider 4 are electrically connected. The metal slider 16 is connected to the data receiving end of the processing board 1. By sliding and docking the metal slider 16 with the metal slider 4, data transmission can be guaranteed during the sliding process, thereby forming the effect of expanding the interface connection data.
[0026] To ensure stability during the sliding process of the interface board: such as Figure 2 and Figure 3 As shown, the size of the slide plate 7 is adapted to the slide groove 13, and the slide plate 7 and the slide groove 13 form a sliding mechanism. The four corners of the top of the processing plate 1 are provided with mounting holes 5. The slide plate 7 slides in the slide groove 13, thereby ensuring the stability of the interface plate 6 during the movement process.
[0027] To achieve a locking effect on the interface board: For example Figure 5 As shown, a rod groove 9 is provided at the top left side of the interface plate 6. A spring 17 and a locking rod 11 are built into the rod groove 9. The left end of the locking rod 11 passes through the back of the interface plate 6. A push handle 10 is fixed to the outer wall of the locking rod 11. A lock hole 14 is provided at the top of the inner wall of the plate groove 3. One end of the locking rod 11 is semi-circular and is inserted into the inside of the lock hole 14. One end of the spring 17 is fixed to the other end of the locking rod 11, and the other end of the spring 17 is fixedly connected to the inner wall of the rod groove 9. Through the adaptive connection between the locking rod 11 and the lock hole 14, the locking rod 11 can quickly form a locked and separated state with the lock hole 14, which is conducive to the fixed storage of the interface plate 6 after extension and retraction.
[0028] During operation, the processing board 1 is installed in the housing that adapts to the processing board 1 through the mounting hole 5. During normal use, data is connected to the external data cable through the first interface 8. Data is electrically connected through the first interface 8, the metal slider 4, the metal slider 16, and the data terminal of the processing board 1. When it is necessary to expand the interface, firstly, the push handle 10 drives the locking rod 11 to move based on the inside of the rod groove 9, so that the locking rod 11 compresses the spring 17. The end of the locking rod 11 will separate from the lock hole 14. Pulling the push handle 10 moves the interface plate 6 out of the plate groove 3. At this time, the top of the interface plate 6 The second interface 12 will be removed from the housing of the processing board 1. Multiple sets of second interfaces 12 can perform simultaneous data docking and processing. During the sliding of the interface board 6, the slide plate 7 will move inside the slide groove 13 to ensure the stability of the interface board 6 during the movement. When sliding, the metal slide piece 4 will move against the metal slide strip 16 to ensure the stability of the electrical connection during sliding. After use, the interface board 6 is pushed into the interior of the board housing 2, and the end of the locking rod 11 will automatically insert into the interior of the locking hole 14 to complete the use of the interface board 6. The design is simple and practical.
[0029] The foregoing description only illustrates certain exemplary embodiments of the present invention. Undoubtedly, those skilled in the art can modify the described embodiments in various ways without departing from the spirit and scope of the present invention. Therefore, the above drawings and descriptions are illustrative in nature and should not be construed as limiting the scope of protection of the claims of the present invention.
Claims
1. A signal processing sub-board with a multi-interface integrated structure, comprising a processing board (1), characterized in that, A plate shell (2) is installed on the right side of the top of the processing plate (1). A plate groove (3) is opened on the top of the plate shell (2). A sliding groove (13) is opened at the bottom of the plate groove (3). A limiting groove (15) is opened in the middle of the top of the sliding groove (13). Multiple sets of metal slide strips (16) are built into the limiting groove (15). An interface plate (6) is built into the plate groove (3). A first interface (8) is installed on the left side of the interface plate (6). A second interface (12) is provided on the top of the interface plate (6). Multiple sets of the second interface (12) are evenly arranged. A sliding plate (7) is fixed at the bottom of the interface plate (6). Multiple sets of metal slide pieces (4) are provided at the bottom of the sliding plate (7).
2. The signal processing sub-board with multi-interface integrated structure according to claim 1, characterized in that, The bottom end of the metal slider (4) is attached to the top of the metal slider (16). The metal slider (4) is in the shape of a round bar. The first interface (8), the second interface (12), the metal slider (16) and the metal slider (4) are electrically connected. The metal slider (16) is connected to the data receiving end of the processing board (1).
3. The signal processing sub-board with multi-interface integrated structure according to claim 1, characterized in that, The size of the slide plate (7) and the slide groove (13) are adapted to each other, and the slide plate (7) and the slide groove (13) constitute a sliding mechanism. The four corners of the top of the processing plate (1) are provided with mounting holes (5).
4. The signal processing sub-board with multi-interface integrated structure according to claim 1, characterized in that, The top left side of the interface plate (6) has a rod groove (9), which contains a spring (17) and a locking rod (11). The left end of the locking rod (11) passes through the back of the interface plate (6), and a push handle (10) is fixed to the outer wall of the locking rod (11).
5. The signal processing sub-board with multi-interface integrated structure according to claim 4, characterized in that, A lock hole (14) is provided at the top of the inner wall of the plate groove (3). One end of the lock rod (11) is semi-circular and is inserted into the lock hole (14). One end of the spring (17) is fixed to the other end of the lock rod (11) and the other end of the spring (17) is fixedly connected to the inner wall of the rod groove (9).