A game device with adjustable table surface angle
By introducing an electric telescopic rod and a dynamic star disk assembly into the spin ball game device, combined with a light-emitting rotating star disk and an angle sensor, the table angle can be precisely adjusted and dynamically changed, solving the problem of the single trajectory of existing devices and enhancing the diversity of the game and the player's sense of participation.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- QINGDAO ZHENGYUAN DONGLI TECHNOLOGY CO LTD
- Filing Date
- 2025-07-28
- Publication Date
- 2026-06-26
AI Technical Summary
Existing spin ball game devices have a fixed horizontal table structure, which cannot adjust the tilt angle. The trajectory is linear or a simple parabola, lacking dynamic changes, making it difficult to maintain players' interest and interaction. The gameplay is inflexible, the game rules are monotonous, and the sensory experience is insufficient.
An adjustable tabletop game device was designed, which uses an electric telescopic rod angle adjustment component, a dynamic star disk component and an LED light source. The tabletop angle can be precisely adjusted and dynamically changed through a computer control box. Combined with the full-angle rotation of the light-emitting rotating star disk and the groove array design, diverse game paths can be formed. Real-time monitoring and control are achieved through angle sensors and telescopic drive devices.
It achieves diverse and dynamic changes in the trajectory of the game marbles, enhancing player participation and challenge, and improving the game's immersion and visual appeal. Players can strategically adjust the table angle and starboard rotation to create diverse game rules, thereby increasing the game's interactivity and fun.
Smart Images

Figure CN224404308U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the technical field of sports and entertainment equipment, and in particular to a game device with an adjustable tabletop angle. Background Technology
[0002] As a form of leisure and entertainment that combines competition and fun, spin ball games have become increasingly popular worldwide in recent years. Its unique ball trajectory and varied tactical combinations not only test players' hand-eye coordination and reaction speed, but also bring an immersive entertainment experience to users of different ages through dynamic interactive gameplay. As a result, it has gained a large following in scenarios such as family gatherings, arcades, and online competitions. Therefore, there is a particular need for a game device with an adjustable table angle.
[0003] However, existing spin ball game devices are mostly fixed horizontal structures, unable to adjust the tilt angle, and only affected by the initial push and table friction. The trajectory is linear or a simple parabola, lacking dynamic changes, making it difficult to maintain sustained interest. They also lack dynamic interaction mechanisms with players, cannot be adjusted as the game progresses, and players cannot change the game's course through strategic adjustments. The gameplay is inflexible, making it difficult to develop diverse game rules. Furthermore, it is difficult to clearly observe the movement trajectory of props and the guiding structure, further reducing the game's sensory experience and fun. Utility Model Content
[0004] The purpose of this invention is to provide a game device with an adjustable tabletop angle, in order to solve the problems mentioned in the background art. Existing spinning ball game devices are mostly fixed horizontal structures, unable to adjust the tilt angle, and only affected by the initial push and table friction. The trajectory is linear or a simple parabola, lacking dynamic changes, making it difficult to maintain continuous interest. They lack a dynamic interaction mechanism with the player, cannot be adjusted with the game progress, and players cannot change the game's direction through strategic adjustments. The gameplay is inflexible, making it difficult to develop diverse game rules and clearly observe the movement trajectory of props and the guiding structure, further reducing the sensory experience and fun of the game.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a game device with an adjustable tabletop angle, comprising a tabletop panel, a hinge on the outer side of the tabletop panel, an electric telescopic rod angle adjustment assembly at the bottom of the tabletop panel, a table body connected to the tabletop panel via the hinge, a computer control box fixedly installed at the bottom of the table body, a desktop angle sensor on the top of the computer control box, an LED light-emitting control device fixedly installed on the inner side of the table body, and a dynamic star disk assembly on the outer side of the tabletop panel; the dynamic star disk assembly includes a rotary motor, the rotary motor being disposed on the outer side of the tabletop panel, a rotating shaft fixedly installed at the output end of the rotary motor, a connecting bearing on the outer side of the rotating shaft, a light-emitting rotating star disk fixedly installed at the top of the rotating shaft, a connecting plate fixedly installed on the outer side of the rotary motor, and an LED light-emitting device on the outer side of the connecting plate.
[0006] Preferably, the connecting plate is fixedly connected to the tabletop, the surface of the luminous rotating star disk is provided with a groove array, and the luminous rotating star disk can be moved to any position on the tabletop with adjustable angle.
[0007] Preferably, the dynamic star disk assembly is provided with two identical sets, and the two sets of luminous rotating star disks are equidistantly distributed on the top of the platform.
[0008] Preferably, the hinge includes a fixed plate, which is installed on the outside of the table body. A rotating roller is rotatably installed on the outside of the fixed plate, and a rotating plate is fixedly installed on the outside of the rotating roller.
[0009] Preferably, the rotating plate is fixedly connected to the tabletop, and the computer control box controls the horizontal angle adjustment of the desktop.
[0010] Preferably, the electric telescopic rod angle adjustment assembly includes a fixed base, which is installed on the inner side of the table body. An electric cylinder is fixedly installed on the outer side of the fixed base. A telescopic electric rod is fixedly installed on the movable end of the electric cylinder. A connecting block is fixedly installed on the end of the telescopic electric rod away from the electric cylinder.
[0011] Preferably, the connecting block is fixedly connected to the tabletop, and the electric telescopic rod angle adjustment component controls the telescopic electric rod to extend and retract through the telescopic drive device of the computer control box, adjusts the tabletop angle, and verifies the adjusted angle through the angle sensor to achieve accuracy.
[0012] Compared with existing technologies, the beneficial effects of this utility model are as follows: This game device with an adjustable tabletop angle, through the setting of a dynamic star disk component, the full-angle rotation of the luminous rotating star disk and the groove array design, allows the movement trajectory of the game marble to break through the limitations of the traditional fixed plane, forming diverse and dynamic path changes. Players can obtain a rich gaming experience by adjusting the tabletop angle and the rotation state of the star disk, solving the problem of the single trajectory of traditional devices. The computer control box integrates a tabletop angle sensor and a telescopic drive device, which can monitor the tilt angle of the tabletop in real time and accurately control the extension and retraction of the electric telescopic rod, realizing stepless adjustment and stable control of the tabletop angle. At the same time, the star disk can move at any position on the tabletop, allowing players to form dynamic interactions with the device through operation, enhancing the sense of participation and challenge in the game. The groove diameter of the luminous rotating star disk is adapted to the size of the marble, further ensuring the smoothness of the marble's movement. The luminous effect is triggered synchronously during the game, and together with the dynamic rotation of the luminous rotating star disk, it forms a visual dynamic light and shadow change, enhancing the immersion and visual appeal of the game, and improving the player's sensory experience. The modular design of each component makes the assembly, disassembly and subsequent maintenance of the device more convenient, reducing production and usage costs. Attached Figure Description
[0013] Figure 1 This is a three-dimensional structural diagram of the present invention;
[0014] Figure 2 This is a schematic diagram of the interlocking structure of the tabletop and table body of this utility model;
[0015] Figure 3 This is a schematic diagram of the computer control box and desktop angle sensor of this utility model;
[0016] Figure 4 This is a schematic diagram of the structure of the telescopic electric pole and the connecting block of this utility model.
[0017] Figure 5 This is a schematic diagram of the dynamic star disk component structure of this utility model.
[0018] In the diagram: 1. Tabletop; 2. Hinge; 201. Fixing plate; 202. Rotating roller; 203. Rotating plate; 3. Electric telescopic rod angle adjustment assembly; 301. Fixing base; 302. Electric cylinder; 303. Telescopic electric rod; 304. Connecting block; 4. Table body; 5. Computer control box; 6. Desktop angle sensor; 7. LED lighting control device; 8. Dynamic star disk assembly; 801. Rotating motor; 802. Rotating shaft; 803. Connecting bearing; 804. Illuminated rotating star disk; 805. Connecting plate; 806. LED lighting device. Detailed Implementation
[0019] 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.
[0020] Please see Figure 1-5 This utility model provides a technical solution: a game device with an adjustable tabletop angle, including a tabletop 1, a hinge 2 on the outer side of the tabletop 1, an electric telescopic rod angle adjustment assembly 3 at the bottom of the tabletop 1, a table body 4 connected to the tabletop 1 via the hinge 2, a computer control box 5 fixedly installed at the bottom inside the table body 4, a desktop angle sensor 6 on the top of the computer control box 5, an LED lighting control device 7 fixedly installed on the inner side of the table body 4, and a dynamic star disk assembly 8 on the outer side of the tabletop 1; the dynamic star disk assembly 8 includes a rotary motor 801, the rotary motor 801 is located on the outer side of the tabletop 1, a rotating shaft 802 is fixedly installed at the output end of the rotary motor 801, and a connecting bearing 803 is provided on the outer side of the rotating shaft 802. A luminous rotating star disk 804 is fixedly installed on the top of the device. A connecting plate 805 is fixedly installed on the outside of the rotating motor 801. An LED lighting device 806 is set on the outside of the connecting plate 805. By setting the dynamic star disk assembly 8, the rotating motor 801 can drive the rotating shaft 802 to rotate the luminous rotating star disk 804 at all angles. The connecting bearing 803 can reduce the frictional resistance when the rotating shaft 802 rotates, ensuring the stability of the star disk rotation. During the rotation of the luminous rotating star disk 804, the groove array on its surface can dynamically guide the game marbles. Combined with the angle change of the table panel 1, it can greatly increase the diversity of the marbles' movement trajectory. At the same time, the LED lighting device 806 can emit light synchronously with the rotation of the star disk, enhancing the visual appeal of the game and improving the player's immersion.
[0021] Furthermore, the connecting plate 805 is fixedly connected to the tabletop 1, and the surface of the luminous rotating star disk 804 is provided with a groove array. The luminous rotating star disk 804 can move to any position on the table with an adjustable angle. By setting the connecting plate 805 and the tabletop 1, it is ensured that the star disk will not shift or shake when rotating and subjected to force. The design that the luminous rotating star disk 804 can move to any position on the table allows players to flexibly adjust the placement of the star disk according to the game requirements. Combined with the guiding effect of the groove array on the marbles, more diverse game rules and gameplay can be derived, breaking the limitations of the traditional fixed guiding structure.
[0022] Furthermore, the dynamic star disk component 8 is provided with two identical sets. The two sets of luminous rotating star disks 804 are equidistantly distributed on the top of the table panel 1. By setting two sets of luminous rotating star disks 804, a multi-node marble guiding structure can be formed on the table panel 1. The two sets of star disks can rotate independently or run synchronously, so that the marble is subjected to multiple dynamic guidance effects during the movement, significantly increasing the trajectory complexity. The equidistant distribution design ensures the balance of force on the table and provides players with a symmetrical game layout, enhancing the fairness and strategy of the game. Players need to consider the movement state of the two sets of star disks at the same time to plan the marble path, increasing the challenge of the game.
[0023] Furthermore, the hinge 2 includes a fixed plate 201, which is installed on the outside of the table body 4. A rotating roller 202 is rotatably installed on the outside of the fixed plate 201, and a rotating plate 203 is fixedly installed on the outside of the rotating roller 202. By setting the hinge 2, the cooperation between the rotating roller 202 and the rotating plate 203 realizes the flexible rotation between the tabletop 1 and the table body 4, so that the tabletop 1 can smoothly adjust the tilt angle around the hinge 2. Moreover, the friction is small and the noise is low during the rotation, which ensures the stability of the angle adjustment and avoids the impact of structural jamming on the game experience.
[0024] Furthermore, the rotating plate 203 is fixedly connected to the tabletop 1. The computer control box 5 controls the horizontal angle adjustment of the desktop. By setting the rotating plate 203 and the tabletop 1, it is ensured that the tabletop 1 can accurately adjust its angle by following the rotation of the rotating plate 203, avoiding angle deviation caused by loose connection. The computer control box 5 controls the desktop angle, realizing the automation and precision of angle adjustment. Players can adjust the desktop state through commands without manual operation, improving the convenience and interactivity of the game.
[0025] Furthermore, the electric telescopic rod angle adjustment component 3 includes a fixed base 301, which is installed on the inner side of the table body 4. An electric cylinder 302 is fixedly installed on the outer side of the fixed base 301. A telescopic electric rod 303 is fixedly installed on the movable end of the electric cylinder 302. A connecting block 304 is fixedly installed on the end of the telescopic electric rod 303 away from the electric cylinder 302. By setting the electric telescopic rod angle adjustment component 3, the fixed base 301 stably fixes the electric cylinder 302 on the table body 4. The electric cylinder 302 drives the telescopic electric rod 303 to perform telescopic movement, which in turn drives the tabletop 1 to rotate around the hinge 2 through the connecting block 304, realizing the mechanical adjustment of the tilt angle of the tabletop 1. The adjustment efficiency is higher, and the angle can be steplessly adjusted through the precise control of the electric cylinder 302, meeting the diverse needs of different game scenarios for the tabletop angle.
[0026] Furthermore, the connecting block 304 is fixedly connected to the tabletop 1. The electric telescopic rod angle adjustment component 3 controls the telescopic electric rod 303 through the telescopic drive device of the computer control box 5 to adjust the tabletop angle. The angle adjustment is verified by the angle sensor to achieve accuracy. By setting the connecting block 304 and the tabletop 1, it is ensured that the telescopic force of the electric rod 303 can be efficiently transmitted to the tabletop 1, avoiding adjustment lag or angle deviation caused by loose connection. The cooperation between the telescopic drive device of the computer control box 5 and the tabletop angle sensor 6 forms a closed-loop control system. The sensor monitors the actual angle of the tabletop 1 in real time and feeds it back to the control box. The control box adjusts the telescopic electric rod 303 according to the preset value to achieve precise angle adjustment with less error, ensuring the stability and controllability of the tabletop angle during the game.
[0027] Working principle: First, the operator places the table body 4 on a level surface. The hinge 2 is fixed to the outside of the table body 4 using the fixing plate 201. Then, the rotating plate 203 is fixed to the bottom edge of the tabletop 1, allowing the tabletop 1 to be movably connected to the hinge 2 via the rotating roller 202, ensuring that the tabletop 1 can rotate freely around the hinge 2. An electric telescopic rod angle adjustment assembly 3 is installed inside the table body 4 via the fixing base 301. The electric cylinder 302 is fixed to the fixing base 301. The connecting block 304 at the top of the telescopic electric rod 303 is fixed to the center area of the bottom of the tabletop 1, ensuring that the telescopic electric rod 303 can tilt the tabletop 1 when it extends or retracts. A computer control box 5 is fixed to the bottom inside the table body 4. The desktop angle sensor 6 is installed on the top of the computer control box 5 and aligned with it. At the bottom of the tabletop 1, the LED lighting control device 7 is fixed to the inner side wall of the table body 4 and connected to the computer control box 5 via wiring. Two sets of dynamic star disk assemblies 8 are symmetrically fixed to the top of the tabletop 1 via a connecting plate 805, ensuring that the rotating shaft 802 of the output end of the rotary motor 801 passes through the connecting bearing 803, and the luminous rotating star disk 804 is fixed to the top of the rotating shaft 802. The LED lighting device 806 is installed on the outside of the connecting plate 805 and connected to the LED lighting control device 7 via wiring. The computer control box 5 activates the electric telescopic rod angle adjustment assembly 3 to control the extension and retraction of the telescopic electric rod 303. Simultaneously, the desktop angle sensor 6 monitors the angle data in real time to ensure that the value displayed on the computer control box 5 matches the actual tilt angle. Rotating motor 801 is used to test the smoothness of the rotation of the luminous rotating star disk 804, adjusting it from 0-360°. The connecting bearing 803 is checked to ensure reduced rotational friction. LED lighting device 806 is activated via LED lighting control device 7 to verify that the light illuminates synchronously with the star disk's rotation. The groove array is checked to ensure it fits the diameter of the game marbles. The tabletop 1 is tilted, and the two sets of luminous rotating star disks 804 are controlled to rotate in opposite directions. The trajectory of the marbles on the tabletop 1 is observed to ensure it is guided by both the tabletop angle and the star disk grooves. The stability of all components is ensured. The player inputs the target tilt angle of the tabletop 1 via computer control box 5. Computer control box 5 drives the telescopic electric rod 303 to extend and retract, tilting the tabletop 1 to the set angle. Tabletop angle sensor 6... The angle data is fed back in real time, and the control box is finely adjusted to the precise value. The rotary motor 801 drives the luminous rotating star disk 804 to rotate at the set speed. The groove array dynamically guides the marble. The player places the marble on the tabletop 1. The marble slides under the action of gravity and the tilt of the table. The trajectory is changed by the grooves of the luminous rotating star disk 804. If the gameplay needs to be adjusted, the tabletop angle or the rotation direction of the star disk can be changed in real time through the computer control box 5. The position of the luminous rotating star disk 804 can also be moved manually to generate new game paths. After the game ends, the computer control box 5 issues a reset command, the telescopic electric rod 303 retracts to return the tabletop 1 to a horizontal state, the rotary motor 801 and the LED lighting device 806 stop working, and the device returns to its initial state.
[0028] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of this utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claimed utility model.
Claims
1. A game device with an adjustable tabletop angle, comprising a tabletop (1), characterized in that: The tabletop (1) is provided with a hinge (2) on the outside, and an electric telescopic rod angle adjustment assembly (3) is provided at the bottom of the tabletop (1). The tabletop (1) is connected to the table body (4) through the hinge (2). A computer control box (5) is fixedly installed at the bottom inside the table body (4). A desktop angle sensor (6) is provided at the top of the computer control box (5). An LED light-emitting control device (7) is fixedly installed on the inside of the table body (4). A dynamic star disk assembly (8) is provided on the outside of the tabletop (1). The dynamic star disk assembly (8) includes a rotary motor (801), which is located on the outer side of the platform (1). A rotating shaft (802) is fixedly installed at the output end of the rotary motor (801). A connecting bearing (803) is provided on the outer side of the rotating shaft (802). A light-emitting rotating star disk (804) is fixedly installed on the top of the rotating shaft (802). A connecting plate (805) is fixedly installed on the outer side of the rotary motor (801). An LED light-emitting device (806) is provided on the outer side of the connecting plate (805).
2. The game device with an adjustable tabletop angle according to claim 1, characterized in that: The connecting plate (805) is fixedly connected to the tabletop (1). The surface of the luminous rotating star disk (804) is provided with a groove array. The luminous rotating star disk (804) can be moved to any position on the tabletop with adjustable angle.
3. The game device with an adjustable tabletop angle according to claim 1, characterized in that: The dynamic star disk assembly (8) is provided with two identical sets, and the two sets of luminous rotating star disks (804) are equidistantly distributed on the top of the platform (1).
4. The game device with an adjustable tabletop angle according to claim 1, characterized in that: The hinge (2) includes a fixing plate (201), which is installed on the outside of the table body (4). A rotating roller (202) is rotatably installed on the outside of the fixing plate (201), and a rotating plate (203) is fixedly installed on the outside of the rotating roller (202).
5. A game device with an adjustable tabletop angle according to claim 4, characterized in that: The rotating plate (203) is fixedly connected to the tabletop (1), and the computer control box (5) controls the horizontal angle adjustment of the desktop.
6. A game device with an adjustable tabletop angle according to claim 1, characterized in that: The electric telescopic rod angle adjustment assembly (3) includes a fixed base (301), which is installed on the inner side of the table body (4). An electric cylinder (302) is fixedly installed on the outer side of the fixed base (301). A telescopic electric rod (303) is fixedly installed on the movable end of the electric cylinder (302). A connecting block (304) is fixedly installed on the end of the telescopic electric rod (303) away from the electric cylinder (302).
7. A game device with an adjustable tabletop angle according to claim 6, characterized in that: The connecting block (304) is fixedly connected to the tabletop (1). The electric telescopic rod angle adjustment component (3) controls the telescopic electric rod (303) to extend and retract through the telescopic drive device of the computer control box (5), adjusts the tabletop angle, and verifies the adjusted angle through the angle sensor to achieve accuracy.