A highly integrated hand controller
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- CHANGXING JINGSHI TECH CO LTD
- Filing Date
- 2025-08-21
- Publication Date
- 2026-06-30
Smart Images

Figure CN224436858U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of hand controller technology, specifically a highly integrated hand controller. Background Technology
[0002] As a core component of human-computer interaction, the ease of operation, structural integration, and reliability of the hand controller directly affect the user experience. In existing technologies, traditional hand controllers mostly adopt a split structure design, with the control circuit board and operation panel separated, resulting in a large overall size and complex assembly process. At the same time, conventional hand controllers have a single operation mode, relying on long-stroke pressing buttons to achieve function control, which is not only laborious to operate, but also prone to false triggering due to stroke errors. To achieve expanded operation modes, some products require additional auxiliary circuit boards. For example, each operation mode requires a corresponding set of circuit boards, further increasing structural complexity and production costs. Moreover, compatibility issues are prone to occur when multiple boards work together. Therefore, it is necessary to design a hand controller with a high degree of integration to solve the above problems. Utility Model Content
[0003] The purpose of this invention is to provide a highly integrated hand controller to solve the problems mentioned in the background art.
[0004] To achieve the above objectives, this utility model provides the following technical solution: a highly integrated hand controller, comprising a handle, an integrated circuit board, and a housing. The integrated circuit board is detachably mounted on one end of the handle. A digital display component is provided in the middle of the integrated circuit board. The housing is rotatably connected to the handle. The integrated circuit board is provided with two sets of control switches, one above the other. By operating the housing, the corresponding control switch is triggered to achieve the lifting or lowering operation. The integrated circuit board is a single circuit board used to simultaneously adapt to multiple operating modes of the housing to achieve corresponding functional control.
[0005] Preferably, the shell operation mode includes two methods:
[0006] Method 1: Fix the handle in a predetermined position, press the upper or lower end of the outer shell to trigger the corresponding control switch to achieve the lifting or lowering operation;
[0007] Method 2: Hold the lower end of the handle and flick the outer shell up or down to trigger the corresponding control switch to lift or lower the shell.
[0008] Preferably, a set of brackets is installed on the inner side of one end of the handle, the brackets are used to fix the integrated circuit board with bolts, and the integrated circuit board is placed in the inner cavity of the outer shell.
[0009] Preferably, two sets of rotating shafts are symmetrically arranged on the inner side of one end of the handle. The rotating shafts can be inserted into the mounting holes reserved in the outer shell, and the outer shell is provided with limiting members corresponding to the rotating shafts.
[0010] Preferably, the outer casing includes an upper casing and a lower casing, wherein the upper casing is located above the bracket and the lower casing is located below the bracket. The upper casing and the lower casing are fastened together by bolts to form the outer casing, and two sets of mounting holes are reserved on the outer casing. The upper casing is provided with a display area corresponding to the position of the digital display component.
[0011] Preferably, the limiting component includes two sets of mirror-arranged L-shaped plates. In the inner cavities of the upper and lower shells, one set of the L-shaped plates is provided on each side of the rotating shaft. The two sets of L-shaped plates cooperate with the bracket to limit the rotation of the outer shell.
[0012] Preferably, two sets of preset buttons are symmetrically arranged at the bottom of the handle, and a set of preset switches is installed at the bottom of the integrated circuit board corresponding to each of the two sets of preset buttons.
[0013] Compared with the prior art, the beneficial effects of this utility model are:
[0014] 1. This utility model integrates the control switch and digital display components into a single integrated circuit board, eliminating the need for additional auxiliary circuit boards, thus simplifying the structure. It abandons the traditional split structure where the control circuit board and operation panel are separate, reducing the assembly space between components and resulting in a smaller overall size. Due to the integrated structure, it reduces the assembly steps of multiple components and lowers the complexity of the assembly process. The operation mode of triggering the switch by moving the outer shell replaces the long-stroke pressing button, making operation more effortless and reducing false triggering caused by stroke error. It also reduces the use of auxiliary circuit boards and other components, simplifies the assembly process, helps reduce production costs, eliminates the need for multiple boards to work together, avoids compatibility issues that may occur between multiple boards, and improves the stability of the equipment.
[0015] 2. This utility model features a bracket that uses bolts to fix an integrated circuit board. The upper and lower housings are fastened together to form an outer shell. Multiple fixing methods ensure that all components are firmly connected, reducing the risk of loosening. The handle's rotating shaft is inserted into the mounting hole of the outer shell, and a limiting component restricts the rotation range, ensuring stability during the rotation of the outer shell and preventing damage to components due to excessive rotation. This also ensures the accuracy of operation. The integrated circuit board is placed inside the outer shell, with the upper and lower housings located above and below the bracket, respectively. The layout of each component is reasonable, further compressing the overall space and reducing the volume. The upper housing has a display area corresponding to the digital display component, ensuring that digital information is clearly transmitted to the user and improving ease of use. The outer shell is formed by fastening the upper and lower housings together with bolts. The installation and connection of each component is simple, facilitating production assembly and subsequent maintenance.
[0016] 3. The two sets of mirrored L-shaped plates of this utility model cooperate with the bracket from both sides of the rotating shaft, which can restrict the rotation of the outer shell from different directions, accurately prevent excessive rotation, ensure the stability and safety of the outer shell rotation, and reduce the risk of damage to components due to excessive rotation. The corresponding settings of preset buttons and preset switches add extra operating functions to the hand controller, enrich the operating modes, make it adaptable to more diverse usage scenarios, and improve the practicality of the hand controller. The L-shaped plates are built into the inner cavity of the outer shell, and the preset buttons and preset switches are respectively installed at the bottom of the handle and the bottom of the integrated circuit board, without taking up too much extra space, ensuring the compactness of the overall structure of the hand controller. Attached Figure Description
[0017] Figure 1 This is a side-view exploded view of the overall structure of this utility model;
[0018] Figure 2 This is an exploded view of the outer shell of this utility model;
[0019] Figure 3 This is a side-view diagram of the overall structure of this utility model;
[0020] Figure 4 This is a side-view diagram of the overall structure of this utility model;
[0021] Figure 5 This is a side-view exploded view of the overall structure of this utility model.
[0022] In the diagram: 1. Handle; 2. Integrated circuit board; 3. Control switch; 4. Digital display component; 5. Bracket; 6. Bolt; 7. Upper housing; 8. Lower housing; 9. Rotating shaft; 10. L-shaped plate; 11. Mounting hole; 12. Display area; 13. Preset button; 14. Preset switch. Detailed Implementation
[0023] 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.
[0024] Example 1
[0025] Please refer to Figure 1-5As shown, this utility model provides a highly integrated hand controller, including a handle 1, an integrated circuit board 2, and a housing. The integrated circuit board 2 is detachably mounted on one end of the handle 1. A digital display component 4 is provided in the middle of the integrated circuit board 2. The housing is rotatably connected to the handle 1. The integrated circuit board 2 has two sets of control switches 3, one above the other. By operating the housing, the corresponding control switch 3 is triggered to achieve the lifting or lowering operation. The integrated circuit board 2 is a single circuit board used to simultaneously adapt to multiple operating modes of the housing to achieve corresponding function control. The housing operating modes include two types:
[0026] Method 1: Fix handle 1 in the predetermined position, press the upper or lower end of the outer shell to trigger the corresponding control switch 3 to achieve the lifting or lowering operation;
[0027] Method 2: Hold the lower end of handle 1 and flick the outer shell up or down to trigger the corresponding control switch 3 to lift or lower the shell.
[0028] The core of the hand controller is an integrated circuit board 2, which integrates a digital display component 4 and two sets of control switches 3. No additional auxiliary circuit boards are required. The two operation modes of the outer shell correspond to the traditional seesaw operation and the paddle operation, respectively, and the functions are controlled by the same set of integrated circuit boards 2. Compared with the traditional solution of using two sets of circuit boards to adapt to the two operation modes, the structural complexity and production cost are reduced. The outer shell is connected to the handle 1 by a limit rotation, fixing the handle 1 in a predetermined position. Pressing the upper or lower end of the outer shell triggers the corresponding control switch 3 to achieve the lifting or lowering operation. Or when the user holds the lower end of the handle 1 and moves the outer shell up or down, the outer shell will trigger the corresponding control switch 3 on the integrated circuit board 2. Specifically, moving the outer shell up triggers the corresponding switch to achieve the lifting operation, and moving the outer shell down triggers the corresponding switch to achieve the lowering operation. The digital display component 4 can display relevant information in real time.
[0029] The integrated circuit board 2 integrates the control switch 3 and the digital display component 4, eliminating the need for additional auxiliary circuit boards, simplifying the structure, and abandoning the traditional separate structure where the control circuit board and operation panel are separate. This reduces the assembly space between components, resulting in a smaller overall size. Due to the integrated structure, the assembly steps of multiple components are reduced, lowering the complexity of the assembly process. The operation mode of triggering the switch by tossing the outer shell replaces the long-stroke pressing button, making operation more effortless and reducing false triggering caused by stroke error. It also reduces the use of auxiliary circuit boards and other components, simplifies the assembly process, helps reduce production costs, eliminates the need for multiple boards to work together, avoids compatibility issues that may arise between multiple boards, and improves the stability of the equipment.
[0030] Specifically, a set of brackets 5 are installed on the inner side of one end of the handle 1. The brackets 5 are used with bolts 6 to fix the integrated circuit board 2, and the integrated circuit board 2 is placed in the inner cavity of the outer shell. Two sets of rotating shafts 9 are symmetrically arranged on the inner side of one end of the handle 1. The rotating shafts 9 can be inserted into the mounting holes 11 reserved in the outer shell. The outer shell is provided with limiting parts corresponding to the rotating shafts 9. The outer shell includes an upper shell 7 and a lower shell 8. The upper shell 7 is located above the brackets 5, and the lower shell 8 is located below the brackets 5. After the upper shell 7 and the lower shell 8 are joined together, they are fastened with bolts 6 to form the outer shell. Two sets of mounting holes 11 are reserved on the outer shell. The upper shell 7 is provided with a display area 12 corresponding to the position of the digital display component 4.
[0031] The integrated circuit board 2 is fixed by the bracket 5 and bolts 6 on the inner side of the handle 1, and is encased in the inner cavity of the outer shell formed by the assembly of the upper shell 7 and the lower shell 8 and the fastening of the bolts 6, achieving stable installation. The two sets of rotating shafts 9 on the inner side of the handle 1 are inserted into the reserved mounting holes 11 of the outer shell. The outer shell limits the rotation range of the rotating shafts 9 by the limiting component, so that the outer shell can rotate relative to the handle 1 in a limited manner. When the lower end of the handle 1 is held and the outer shell is pushed up or down, the rotation of the outer shell will trigger the corresponding control switch 3 on the integrated circuit board 2 to complete the lifting or lowering operation. The digital display component 4 on the integrated circuit board 2 displays relevant information through the display area 12 corresponding to the upper shell 7 for easy viewing by the user.
[0032] The bracket 5, together with bolts 6, secures the integrated circuit board 2. The upper housing 7 and the lower housing 8 are fastened together by bolts 6 to form the outer shell. Multiple fixing methods ensure that the connection of each component is firm and reduce the risk of loosening. The rotating shaft 9 of the handle 1 is inserted into the mounting hole 11 of the outer shell, and the rotation range is limited by the limiting component to ensure the stability of the outer shell during rotation and avoid damage to the components caused by excessive rotation. At the same time, it ensures the accuracy of operation. The integrated circuit board 2 is placed in the inner cavity of the outer shell. The upper housing 7 and the lower housing 8 are located above and below the bracket 5, respectively. The layout of each component is reasonable, further compressing the overall space and reducing the volume. The upper housing 7 is set with a display area 12 corresponding to the digital display component 4 to ensure that the digital display information can be clearly transmitted to the user and improve the ease of use. The outer shell is formed by the upper housing 7 and the lower housing 8 being joined together and fastened together by bolts 6. The installation and connection of each component is simple, which facilitates production assembly and later maintenance.
[0033] Among them: the limiting component includes two sets of mirror-arranged L-shaped plates 10. In the inner cavity of the upper shell 7 and the lower shell 8, a set of L-shaped plates 10 is provided on both sides of the rotating shaft 9. The two sets of L-shaped plates 10 cooperate with the bracket 5 and can play a limiting role when the shell rotates. Two sets of preset buttons 13 are symmetrically arranged at the bottom of the handle. A set of preset switches 14 is installed at the bottom of the integrated circuit board 2 corresponding to the two sets of preset buttons 13.
[0034] The two sets of mirrored L-shaped plates 10 of the limiting component are respectively located on both sides of the pivot 9 in the inner cavity of the upper housing 7 and the lower housing 8. When the housing rotates relative to the handle 1, the L-shaped plate 10 will contact the bracket 5 and press against the bracket 5, thereby limiting the rotation angle of the housing and preventing excessive rotation. The two sets of preset buttons 13 at the bottom of the handle correspond one-to-one with the two sets of preset switches 14 at the bottom of the integrated circuit board 2. When the preset button 13 is pressed, the corresponding preset switch 14 will be triggered, thereby realizing the preset function operation of the hand controller.
[0035] Two sets of mirrored L-shaped plates 10 cooperate with the bracket 5 from both sides of the pivot 9, which can restrict the rotation of the outer shell from different directions, precisely prevent excessive rotation, ensure the stability and safety of the outer shell rotation, and reduce the risk of damage to components due to excessive rotation. The corresponding settings of preset buttons 13 and preset switches 14 add extra operating functions to the hand controller, enrich the operating modes, make it adaptable to more diverse usage scenarios, and improve the practicality of the hand controller. The L-shaped plates 10 are built into the inner cavity of the outer shell, and the preset buttons 13 and preset switches 14 are respectively installed at the bottom of the handle 1 and the bottom of the integrated circuit board 2, without taking up too much extra space, ensuring the compactness of the overall structure of the hand controller.
[0036] Working principle: The integrated circuit board 2 is fixed by the bracket 5 and bolts 6 on the inner side of the handle 1, and is encased in the inner cavity of the outer shell formed by the assembly of the upper shell 7 and the lower shell 8 and the fastening of the bolts 6, achieving stable installation. The two sets of rotating shafts 9 on the inner side of the handle 1 are inserted into the reserved mounting holes 11 of the outer shell. The outer shell limits the rotation range of the rotating shafts 9 by limiting components, allowing the outer shell to rotate relative to the handle 1 in a limited manner, fixing the handle 1 in a predetermined position. Pressing the upper or lower end of the outer shell triggers the corresponding control switch 3 to achieve the lifting or lowering operation. Alternatively, when the lower end of the handle 1 is held and the outer shell is pushed up or down, the rotation of the outer shell will trigger the corresponding control switch on the integrated circuit board 2. When the handle is closed (position 3), the lifting or lowering operation is completed. The digital display component 4 on the integrated circuit board 2 displays relevant information through the display area 12 corresponding to the upper housing 7 for easy viewing by the user. The two sets of mirrored L-shaped plates 10 of the limiting component are respectively located on both sides of the rotating shaft 9 inside the upper housing 7 and the lower housing 8. When the housing rotates relative to the handle 1, the L-shaped plate 10 will contact and press against the bracket 5, thereby limiting the rotation angle of the housing and preventing excessive rotation. The two sets of preset buttons 13 at the bottom of the handle correspond one-to-one with the two sets of preset switches 14 at the bottom of the integrated circuit board 2. When the preset button 13 is pressed, the corresponding preset switch 14 will be triggered, thereby realizing the preset function operation of the hand controller.
[0037] The contents not described in detail in this specification are existing technologies known to those skilled in the art.
[0038] Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.
Claims
1. A hand controller with high integration, comprising a handle (1), an integrated circuit board (2) and a housing, characterized in that: The integrated circuit board (2) can be detachably installed at one end of the handle (1). A digital display component (4) is provided in the middle of the integrated circuit board (2). The outer shell is limited to the handle (1) and rotated. The integrated circuit board (2) is provided with two sets of control switches (3). By operating the outer shell, the corresponding control switch (3) is triggered to realize the lifting or lowering operation. The integrated circuit board (2) is a single circuit board used to simultaneously adapt to multiple operation modes of the outer shell to realize corresponding function control.
2. The hand controller of claim 1, wherein: The outer casing can be operated in two ways: Method 1: Fix the handle (1) in a predetermined position, press the upper or lower end of the outer shell, and trigger the corresponding control switch (3) to achieve the lifting or lowering operation; Method 2: Hold the lower end of the handle (1) and flick the outer shell up or down to trigger the corresponding control switch (3) to lift or lower the shell.
3. The highly integrated hand controller according to claim 1, characterized in that: A set of brackets (5) is installed on the inner side of one end of the handle (1). The brackets (5) are used in conjunction with bolts (6) to fix the integrated circuit board (2), and the integrated circuit board (2) is placed in the inner cavity of the outer shell.
4. A highly integrated hand controller according to claim 3, characterized in that: Two sets of rotating shafts (9) are symmetrically arranged on the inner side of one end of the handle (1). The rotating shafts (9) can be inserted into the mounting holes (11) reserved in the outer shell, and the outer shell is provided with limiting members corresponding to the rotating shafts (9).
5. A highly integrated hand controller according to claim 4, characterized in that: The outer shell includes an upper shell (7) and a lower shell (8), wherein the upper shell (7) is located above the bracket (5) and the lower shell (8) is located below the bracket (5). The upper shell (7) and the lower shell (8) are fastened together by bolts (6) to form the outer shell. Two sets of mounting holes (11) are reserved on the outer shell. The upper shell (7) has a display area (12) corresponding to the position of the digital display component (4).
6. A highly integrated hand controller according to claim 4, characterized in that: The limiting component includes two sets of mirror-arranged L-shaped plates (10). In the inner cavity of the upper shell (7) and the lower shell (8), one set of the L-shaped plates (10) is provided on each side of the rotating shaft (9). The two sets of L-shaped plates (10) cooperate with the bracket (5) and can play a limiting role when the shell rotates.
7. A highly integrated hand controller according to claim 1, characterized in that: Two sets of preset buttons (13) are symmetrically arranged at the bottom of the handle (1), and a set of preset switches (14) are installed at the bottom of the integrated circuit board (2) corresponding to each of the two sets of preset buttons (13).