Doll ejection game machine
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- GUANGZHOU SHENGMENG TECHNOLOGY CO LTD
- Filing Date
- 2025-07-29
- Publication Date
- 2026-06-26
AI Technical Summary
Existing doll ejection game machines are not conducive to the circular rotation of the dolls, and the ejection mechanism design is not conducive to driving the dolls to rotate from multiple positions, which affects the display and entertainment value of the dolls.
Employing a multi-layer rotating disk and servo motor drive system, the combination of worm gear, gear plate and servo motor enables convenient circular rotation and multi-position drive of the doll. Combined with the design of sliding arm and top material rod, it enables the doll to be ejected and displayed.
It enables convenient circular rotation drive and multi-position display of the dolls, improves the eye-catching and entertaining nature of the dolls popping out of the game machine, and enhances the convenience of popping out the dolls.
Smart Images

Figure CN224404306U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of game console technology, specifically to a doll-pushing game console. Background Technology
[0002] With the continuous prosperity of my country's commodity market and the continuous improvement of urban modernization, a large number of game machines have appeared in places such as playgrounds, shopping malls, airports, train stations, and commercial streets. These game machines, also known as claw machines, have multiple functions and are a type of entertainment equipment. Players use the buttons on the game machine to eject their favorite toys or gifts. These simple and easy-to-understand game machines are usually set up in places with high traffic, such as shopping malls and cinemas, thus attracting a large number of players, especially children and adults.
[0003] The doll-lifting game machine is simple to operate and suitable for a wide range of people, including children and adults. With the improvement of people's living standards and the diversification of entertainment methods, the market demand for claw machines is increasing. The ejection mechanism of the doll-lifting game machine plays an important role in the equipment. The quality of the ejection mechanism directly affects the lifespan and popularity of the game machine. Existing such game machines are generally not convenient for driving the doll to rotate in a circular motion, making it difficult for the doll to be ejected and exposed, not convenient for driving the doll to rotate from multiple positions, and not convenient for viewing the doll in a circular motion. This affects the eye-catching and entertaining nature of the doll-lifting game machine. Utility Model Content
[0004] The purpose of this utility model is to provide a doll-pushing game machine to solve the problems mentioned in the background art, such as the game machine not being convenient to drive the doll to rotate in a convenient circular manner, not being convenient to push the doll out to expose it, not being convenient to drive the doll to rotate from multiple positions, and not being convenient to watch the doll rotating in a circular manner, which affects the eye-catching and entertaining nature of the doll-pushing game machine when in use.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a doll ejection game machine, comprising a base and a first-layer rotating disk. The first-layer rotating disk is disposed outside the base. A positioning disk is movably installed at the center of the first-layer rotating disk. A positioning seat is installed at the bottom of the positioning disk and is fixedly connected to the base. A rotating sleeve is installed at the center of the positioning disk. A push rod is installed at the center of the rotating sleeve, and both ends of the push rod extend to the outside of the rotating sleeve. A top buckle is installed at the top of the push rod. A branch sleeve is fitted onto the top of the rotating sleeve. Three sets of connecting arms are installed at equal intervals on the outer wall of the branch sleeve. An end block is installed at the end of each connecting arm away from the branch sleeve. A hollow arm is installed at the top of the connecting arm between the end block and the branch sleeve. A sliding arm is slidably installed inside the hollow arm. Both ends of the sliding arm extend to the outside of the hollow arm. One end of the sliding arm is equipped with... The system includes a shield and a second rotating disk surrounding the first rotating disk. The top of the second rotating disk has multiple sets of equally spaced large first holes, each with a top block at its top. A second gear is mounted on the outer wall of the second rotating disk. A second servo motor is mounted on the outer wall of the first rotating disk on one side of the second gear. A second gear is mounted on the top of the second servo motor and meshes with the second gear. Four sets of equally spaced limit rods are mounted on the outer wall of the second rotating disk. A groove is provided inside the first rotating disk below the limit rods, and the limit rods are slidably connected to the grooves. A top rod is slidably mounted inside the chassis. A threaded block is mounted at the bottom of the top rod. Threaded rods are symmetrically mounted inside the threaded block. A third servo motor is mounted at the bottom of each threaded rod and connected to the chassis. A second hole is provided inside the first rotating disk below the top block.
[0006] Preferably, a transmission arm is installed at the bottom end of the top material rod, and electric push rods are symmetrically installed at the top of the chassis below the transmission arm, and the output ends of the electric push rods are all connected to the transmission arm.
[0007] Preferably, a worm gear is fitted onto the rotating sleeve surface on one side of the positioning seat, and a stepper motor is installed at the bottom end of the positioning disk on one side of the worm gear.
[0008] Preferably, the output end of the stepper motor is equipped with a worm gear, and the worm gear meshes with a worm wheel.
[0009] Preferably, a first toothed disc is installed at the bottom of the first rotating disk, and multiple sets of positioning posts with equal spacing are installed at the top of the base on one side of the first toothed disc. A track is installed at the bottom of the first rotating disk above the positioning posts, and the positioning posts are slidably connected to the track.
[0010] Preferably, a support block is installed on the top of the chassis on one side of the first gear plate, and a first servo motor is installed on the top of the support block.
[0011] Preferably, a first gear is mounted on the top of the first servo motor, and the first gear meshes with the first gear plate.
[0012] Preferably, the top of the first rotating disk is equipped with multiple sets of equally spaced pads, and the pads are fixedly connected to the first rotating disk.
[0013] Compared with the prior art, the beneficial effects of this utility model are: the game machine not only realizes the convenient circular rotation drive of the doll ejection game machine, which facilitates the ejection and exposure of the rotating doll, and facilitates the rotation of the doll from multiple positions, but also facilitates the circular rotation of the doll for viewing and appreciation, and facilitates the convenient control of ejecting the doll, thus improving the convenience of ejecting the doll and enhancing the eye-catching and entertaining nature of the doll ejection game machine.
[0014] (1) Place different dolls on the surface of pad blocks and end blocks. In the initial stage, the cover covers the dolls on the surface of the end blocks. The stepper motor drives the worm gear to rotate. The worm wheel drives the rotating sleeve to rotate on the surface of the top material rod. The rotating sleeve drives the branch sleeve and connecting arm to rotate. The connecting arm drives the doll to rotate through the end blocks. The connecting arm drives the cover to rotate synchronously in a circular motion through the hollow arm and sliding arm. The sliding arm slides on the surface of the top buckle. When the rotating cover needs to be pushed out, and the doll on the surface of the corresponding end block needs to be exposed, the stepper motor stops rotating and the electric push rod is opened. The electric push rod drives the top material rod to move through the transmission arm. The top material rod slides inside the rotating sleeve to drive the top buckle to move. The top buckle drives the sliding arm to slide inside the hollow arm. The sliding arm pushes the cover out to a high position, realizing the convenient circular rotation drive of the dolls in the doll ejection game machine. This facilitates the ejection of the rotating dolls and improves the eye-catching and entertainment value of the doll ejection game machine.
[0015] (2) By turning on the first servo motor, the chassis supports the support block. The first servo motor drives the first gear to rotate. Under the meshing of the first gear and the first gear disk, the first gear disk drives the first layer of rotating disk to rotate. The first layer of rotating disk drives the doll on the surface to rotate through the pad block. The chassis supports the positioning column. The positioning column slides on the surface of the track to provide sliding support for the first layer of rotating disk. This realizes that the doll is pushed out of the game machine and the doll is driven to rotate in multiple positions, which facilitates the doll's circumferential rotation for viewing.
[0016] (3) The third servo motor drives the threaded rod to rotate. The threaded rod and the threaded block are connected by a thread, which drives the threaded block to move. The threaded block drives the push rod to move. The push rod passes through the second hole and pushes out the top block. The top block pushes out the doll on the surface. Alternatively, the push rod pushes out the pad block to move. The pad block drives the doll to be pushed out from the first large hole. When it is necessary to adjust the push-out of different dolls, the second servo motor drives the second gear to rotate. Under the meshing of the second gear and the second gear plate, the second gear plate and the second layer of rotating disk rotate to facilitate the push rod to push out the dolls on the surface of different top blocks. When the dolls on the surface of the pad block are pushed out, the dolls on the pad block need to correspond to the holes of the first large hole. The rotation of the second layer of rotating disk is controlled by the second servo motor. The rotation of the first layer of rotating disk is controlled by the first servo motor. This realizes the convenient control of the doll push-out game machine and improves the convenience of the doll push-out. Attached Figure Description
[0017] Figure 1 This is a three-dimensional structural diagram of the present invention;
[0018] Figure 2 This is a front view structural diagram of the present utility model;
[0019] Figure 3 This is a three-dimensional structural diagram of the positioning seat of this utility model;
[0020] Figure 4 This is a three-dimensional structural diagram of the top material rod of this utility model, viewed from the front.
[0021] Figure 5 This is a three-dimensional structural diagram of the shield of this utility model;
[0022] Figure 6 This is a three-dimensional structural diagram of the pad block of this utility model;
[0023] Figure 7 This is a three-dimensional structural diagram of the hollow arm of this utility model;
[0024] Figure 8 This is a three-dimensional structural diagram of the transmission arm of this utility model;
[0025] Figure 9 This is a three-dimensional structural diagram of the rotating sleeve of this utility model;
[0026] Figure 10 This is a three-dimensional structural diagram of the first toothed disc of this utility model;
[0027] Figure 11 This is a three-dimensional structural diagram of the pad block of this utility model;
[0028] Figure 12 This is a three-dimensional structural diagram of the first doll of this utility model;
[0029] Figure 13 This is a three-dimensional structural diagram of the second doll of this utility model;
[0030] Figure 14 This is a three-dimensional structural diagram of the third doll of this utility model;
[0031] Figure 15 This is a three-dimensional structural diagram of the positioning seat of this utility model;
[0032] Figure 16 This is a three-dimensional structural diagram of the second-layer rotating disk of this utility model;
[0033] Figure 17 This is a three-dimensional structural diagram of the top rod of this utility model;
[0034] Figure 18 This is a front view cross-sectional structural diagram of the groove of this utility model;
[0035] Figure 19 This is a three-dimensional structural diagram of the second toothed disc of this utility model.
[0036] In the diagram: 1. Chassis; 2. First-layer rotating disk; 3. Positioning disk; 4. Support block; 5. First servo motor; 6. First gear; 7. First gear plate; 8. Positioning column; 9. Track; 10. Electric push rod; 11. Transmission arm; 12. Top rod; 13. Branch sleeve; 14. Connecting arm; 15. End block; 16. Hollow arm; 17. Sliding arm; 18. Baffle; 19. Top buckle; 20. Positioning seat; 21. Worm gear; 22. Rotating sleeve; 23. Worm; 24. Stepper motor; 25. Pad block; 26. First large hole; 27. Top block; 28. Second gear plate; 29. Second gear; 30. Second servo motor; 31. Second hole; 32. Top rod; 33. Threaded block; 34. Threaded rod; 35. Third servo motor; 36. Limiting rod; 37. Groove; 38. Second-layer rotating disk. Detailed Implementation
[0037] To further illustrate the technical means and effects adopted by this utility model in order to achieve the intended utility model purpose, the following detailed description of the specific implementation methods, structure, features and effects of this utility model is provided in conjunction with the accompanying drawings and preferred embodiments.
[0038] Please see Figure 1-19This utility model provides an embodiment of a toy ejection game machine, comprising a base 1 and a first-layer rotating disk 2. The first-layer rotating disk 2 is disposed on the outside of the base 1. A positioning disk 3 is movably installed at the center of the first-layer rotating disk 2. A positioning seat 20 is installed at the bottom of the positioning disk 3 and is fixedly connected to the base 1. A rotating sleeve 22 is installed at the center of the positioning disk 3. A push rod 12 is installed at the center of the rotating sleeve 22, and both ends of the push rod 12 extend to the rotating disk 3. Outside the rotating sleeve 22, the top of the top of the top rod 12 is fitted with a top buckle 19, and the top of the rotating sleeve 22 is fitted with a branch sleeve 13. Three sets of connecting arms 14 with equal spacing are installed on the outer wall of the branch sleeve 13. An end block 15 is installed at the end of the connecting arm 14 away from the branch sleeve 13. A hollow arm 16 is installed at the top of the connecting arm 14 between the end block 15 and the branch sleeve 13. A sliding arm 17 is slidably installed inside the hollow arm 16. Both ends of the sliding arm 17 extend to the outside of the hollow arm 16. A baffle 18 is installed at one end of the sliding arm 17.
[0039] A transmission arm 11 is installed at the bottom end of the top material rod 12, and electric push rods 10 are symmetrically installed at the top of the chassis 1 below the transmission arm 11, and the output ends of the electric push rods 10 are all connected to the transmission arm 11.
[0040] A worm gear 21 is fitted on the surface of the rotating sleeve 22 on one side of the positioning seat 20, and a stepper motor 24 is installed at the bottom of the positioning disk 3 on one side of the worm gear 21.
[0041] The output end of the stepper motor 24 is equipped with a worm gear 23, and the worm gear 23 meshes with the worm wheel 21;
[0042] Different dolls are placed on the surfaces of pad 25 and end block 15. For example, in this scheme, 15 dolls can be arranged in the following order: sparrow doll, turtle doll, sparrow doll, turtle doll, dragon doll. In the initial stage, the cover 18 covers the dolls on the surface of end block 15. The stepper motor 24 is turned on, and the chassis 1 is fixedly supported by the positioning seat 20. The stepper motor 24 drives the worm gear 23 to rotate. Under the meshing of the worm gear 23 and the worm wheel 21, the worm wheel 21 is driven to rotate. The worm wheel 21 drives the rotating sleeve 22 to rotate on the surface of the top material rod 12. The rotating sleeve 22 drives the branch sleeve 13 and the connecting arm 14 to rotate. The connecting arm 14 drives the doll to rotate through the end block 15. The connecting arm 14 drives the doll to rotate through the hollow arm 16 and the sliding arm 14. Arm 17 drives the cover 18 to rotate synchronously. The sliding arm 17 slides on the surface of the top buckle 19. When the rotating cover 18 needs to be pushed out, and the doll on the surface of the corresponding end block 15 of the cover 18 needs to be exposed, the stepper motor 24 stops rotating and opens the electric push rod 10. The electric push rod 10 drives the push rod 12 to move through the transmission arm 11. The push rod 12 slides inside the rotating sleeve 22 and drives the top buckle 19 to move. The top buckle 19 drives the sliding arm 17 to slide inside the hollow arm 16. The sliding arm 17 pushes the cover 18 out to a high position, realizing the convenient circular rotation drive of the doll in the doll ejection game machine. This facilitates the ejection and exposure of the rotating doll and improves the eye-catching and entertaining nature of the doll ejection game machine.
[0043] The bottom of the first rotating disk 2 is equipped with a first toothed disk 7. The top of the base 1 on one side of the first toothed disk 7 is equipped with multiple sets of positioning posts 8 at equal intervals. The bottom of the first rotating disk 2 above the positioning posts 8 is equipped with a track 9, and the positioning posts 8 and the track 9 are slidably connected.
[0044] A support block 4 is installed on the top of the chassis 1 on one side of the first gear disk 7. A first servo motor 5 is installed on the top of the support block 4. A first gear 6 is installed on the top of the first servo motor 5, and the first gear 6 meshes with the first gear disk 7.
[0045] The top of the first rotating disk 2 is equipped with multiple sets of equally spaced pads 25, and the pads 25 are fixedly connected to the first rotating disk 2.
[0046] By activating the first servo motor 5, the chassis 1 supports the support block 4. The first servo motor 5 drives the first gear 6 to rotate. Under the meshing of the first gear 6 and the first gear 7, the first gear 7 drives the first rotating disk 2 to rotate. The first rotating disk 2 drives the doll on the surface to rotate via the pad block 25. The chassis 1 supports the positioning post 8. The positioning post 8 slides on the surface of the track 9 to provide sliding support for the first rotating disk 2. This realizes the multi-position drive of the doll to rotate out of the game machine, which facilitates the circumferential rotation of the doll for viewing.
[0047] A second rotating disk 38 is disposed outside the first rotating disk 2. Multiple sets of equally spaced first large holes 26 are installed at the top of the second rotating disk 38. A top block 27 is installed at the top of each first large hole 26. A second gear disk 28 is installed on the outer wall of the second rotating disk 38. A second servo motor 30 is installed on the outer wall of the first rotating disk 2 on one side of the second gear disk 28. A second gear 29 is installed at the top of the second servo motor 30, and the second gear 29 meshes with the second gear disk 28. The outer wall of the second rotating disk 38... Four sets of equally spaced limiting rods 36 are installed on the top. The first layer of rotating disk 2 below the limiting rods 36 has a groove 37 inside, and the limiting rods 36 are slidably connected to the grooves 37. A top rod 32 is slidably installed inside the chassis 1. A threaded block 33 is installed at the bottom end of the top rod 32. Threaded rods 34 are symmetrically installed inside the threaded block 33. A third servo motor 35 is installed at the bottom end of each threaded rod 34, and the third servo motor 35 is connected to the chassis 1. A second hole 31 is provided inside the first layer of rotating disk 2 below the top block 27.
[0048] By activating the third servo motor 35, the third servo motor 35 drives the threaded rod 34 to rotate. The threaded connection between the threaded rod 34 and the threaded block 33 drives the threaded block 33 to move. The threaded block 33 then moves the push rod 32, which passes through the second hole 31 and pushes out the top block 27. The top block 27 then pushes out the doll on the surface. Alternatively, the push rod 32 pushes out the pad block 25, which then moves the pad block 25, causing the doll to be pushed out through the first large hole 26. When it is necessary to adjust the ejection of different dolls, the second servo motor 30 is activated, which drives the second gear 29 to rotate. The rotation of the second gear 29 and the second gear disk 28, driven by the meshing of the second gear 29 and the second gear disk 28, drives the second gear disk 28 and the second layer rotating disk 38 to rotate, so that the dolls on the different surfaces of the top block 27 can be ejected when the top rod 32 is ejected. When the doll on the surface of the pad block 25 is ejected, the doll on the pad block 25 needs to correspond to the hole of the first large hole 26. The rotation of the second layer rotating disk 38 is controlled by the second servo motor 30, and the rotation of the first layer rotating disk 2 is controlled by the first servo motor 5. This realizes the convenient control of ejecting the dolls from the game machine and improves the convenience of ejecting the dolls.
[0049] In this embodiment, when in use: An external power supply is connected, and different dolls are placed on the surfaces of the pad 25 and end block 15. Initially, the cover 18 covers the dolls on the surface of the end block 15. The stepper motor 24 drives the worm gear 23 to rotate, and the worm wheel 21 drives the rotating sleeve 22 to rotate on the surface of the ejector rod 12. The rotating sleeve 22 drives the branch sleeve 13 and connecting arm 14 to rotate. The connecting arm 14, via the end block 15, drives the doll to rotate. The connecting arm 14, via the hollow arm 16 and sliding arm 17, drives the cover 18 to rotate synchronously in a circular motion. The sliding arm 17 slides on the surface of the top buckle 19. When the rotating cover 18 needs to be ejected... When the doll on the surface of the corresponding end block 15 of the cover 18 needs to be exposed, the stepper motor 24 stops rotating, and the electric push rod 10 drives the push rod 12 to move via the transmission arm 11. The push rod 12 slides inside the rotating sleeve 22, driving the top buckle 19 to move. The top buckle 19 drives the sliding arm 17 to slide inside the hollow arm 16. The sliding arm 17 pushes the cover 18 to a high position. By turning on the first servo motor 5, the chassis 1 supports the support block 4. The first servo motor 5 drives the first gear 6 to rotate, and the first gear disk 7 drives the first layer rotating disk 2 to rotate. The first layer rotating disk 2 drives the surface via the pad block 25. The doll rotates, the base 1 supports the positioning post 8, and the positioning post 8 slides on the surface of the track 9 to support the first rotating disk 2. By turning on the third servo motor 35, the third servo motor 35 drives the threaded rod 34 to rotate. The threaded connection between the threaded rod 34 and the threaded block 33 drives the threaded block 33 to move. The threaded block 33 drives the push rod 32 to move. The push rod 32 passes through the second hole 31 and pushes out the top block 27. The top block 27 pushes out the doll on the surface. Alternatively, the push rod 32 pushes out the pad 25 to move. The pad 25 drives the doll to be pushed out from the first large hole 26. When it is necessary to adjust the ejection, the doll can be ejected from the first large hole 26. When the same doll is in use, the second servo motor 30 is turned on, and the second servo motor 30 drives the second gear 29 to rotate. Under the meshing of the second gear 29 and the second gear disk 28, the second gear disk 28 and the second layer rotating disk 38 are driven to rotate, so that the dolls on the different surfaces of the top block 27 can be ejected when the top rod 32 is ejected. When the doll on the surface of the pad block 25 is ejected, the doll on the pad block 25 needs to correspond to the hole of the first large hole 26. The rotation of the second layer rotating disk 38 is controlled by the second servo motor 30, and the rotation of the first layer rotating disk 2 is controlled by the first servo motor 5, so as to complete the operation of the game machine.
[0050] The above description is merely a preferred embodiment of the present utility model and is not intended to limit the present utility model in any way. Although the present utility model has been disclosed above with reference to a preferred embodiment, it is not intended to limit the present utility model. Any person skilled in the art can make some modifications or alterations to the above-disclosed technical content to create equivalent embodiments without departing from the scope of the present utility model. Any indirect modifications, equivalent changes, and alterations made to the above embodiments based on the technical essence of the present utility model without departing from the scope of the present utility model shall still fall within the scope of the present utility model.
Claims
1. A doll-shaped pop-out game machine, characterized in that: The system includes a chassis (1) and a first-layer rotating disk (2). The first-layer rotating disk (2) is disposed on the outside of the chassis (1). A positioning disk (3) is movably installed at the center of the first-layer rotating disk (2). A positioning seat (20) is installed at the bottom end of the positioning disk (3), and the positioning seat (20) is fixedly connected to the chassis (1). A rotating sleeve (22) is installed at the center of the positioning disk (3). A top material rod (12) is installed at the center of the rotating sleeve (22), and both ends of the top material rod (12) extend to the outside of the rotating sleeve (22). A top buckle is installed at the top end of the top material rod (12). (19) A branch sleeve (13) is fitted onto the top of the rotating sleeve (22). Three sets of connecting arms (14) with equal spacing are installed on the outer wall of the branch sleeve (13). An end block (15) is installed at the end of each connecting arm (14) away from the branch sleeve (13). A hollow arm (16) is installed at the top of the connecting arm (14) between the end block (15) and the branch sleeve (13). A sliding arm (17) is slidably installed inside the hollow arm (16). Both ends of the sliding arm (17) extend to the outside of the hollow arm (16). A baffle (18) is installed at one end of each sliding arm (17). The outside of the first layer rotating disk (2) A second rotating disk (38) is provided, and multiple sets of first large holes (26) with equal spacing are installed on the top of the second rotating disk (38). A top block (27) is provided on the top of the first large hole (26). A second gear disk (28) is installed on the outer wall of the second rotating disk (38). A second servo motor (30) is installed on the outer wall of the first rotating disk (2) on one side of the second gear disk (28). A second gear (29) is installed on the top of the second servo motor (30), and the second gear (29) meshes with the second gear disk (28). Four equally spaced... A limiting rod (36) is provided. The first rotating disk (2) below the limiting rod (36) has a groove (37) inside, and the limiting rod (36) is slidably connected to the groove (37). A top rod (32) is slidably installed inside the chassis (1). A threaded block (33) is installed at the bottom end of the top rod (32). Threaded rods (34) are symmetrically installed inside the threaded block (33). A third servo motor (35) is installed at the bottom end of each threaded rod (34), and the third servo motor (35) is connected to the chassis (1). A second hole (31) is provided inside the first rotating disk (2) below the top block (27).
2. The doll-pushing game machine according to claim 1, characterized in that: The bottom end of the top material rod (12) is equipped with a transmission arm (11), and the top of the chassis (1) below the transmission arm (11) is symmetrically equipped with electric push rods (10), and the output ends of the electric push rods (10) are all connected to the transmission arm (11).
3. The doll-pushing game machine according to claim 2, characterized in that: A worm gear (21) is fitted on the surface of the rotating sleeve (22) on one side of the positioning seat (20), and a stepper motor (24) is installed at the bottom of the positioning disk (3) on one side of the worm gear (21).
4. The doll-pushing game machine according to claim 3, characterized in that: The output end of the stepper motor (24) is equipped with a worm (23), and the worm (23) meshes with the worm wheel (21).
5. The doll-pushing game machine according to claim 4, characterized in that: The bottom end of the first layer rotating disk (2) is equipped with a first toothed disk (7), and the top of the chassis (1) on one side of the first toothed disk (7) is equipped with multiple sets of positioning columns (8) at equal intervals. The bottom end of the first layer rotating disk (2) above the positioning columns (8) is equipped with a track (9), and the positioning columns (8) are slidably connected to the track (9).
6. The doll-pushing game machine according to claim 5, characterized in that: A support block (4) is installed on the top of the chassis (1) on one side of the first gear plate (7), and a first servo motor (5) is installed on the top of the support block (4).
7. A doll-pushing game machine according to claim 6, characterized in that: The first servo motor (5) is equipped with a first gear (6) at its top end, and the first gear (6) meshes with the first gear plate (7).
8. A doll-pushing game machine according to claim 7, characterized in that: The top of the first layer rotating disk (2) is equipped with multiple sets of equally spaced pads (25), and the pads (25) are fixedly connected to the first layer rotating disk (2).