Firing device and firing toy
By designing a launching device with detachable parts and a slider clutch mechanism, the problem of insufficient playability of launching toys is solved, realizing diverse launching forms and play fun, and enhancing children's interactive and teamwork experience.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- GUANGDONG AULDEY ANIMATION & TOY CO LTD
- Filing Date
- 2024-12-12
- Publication Date
- 2026-06-12
AI Technical Summary
Existing launching toys lack playability and fail to offer diverse launching patterns and playful fun.
Design a launching device including a launcher and detachable accessories. The launcher is connected to the launcher through different accessories to realize the rotation and launch of the object to be launched. The accessories include an acceleration position and a launch position. The rotation and launch of the acceleration gear are controlled by a slider and a clutch mechanism, providing a variety of launch modes.
It enhances the fun of launching toys by enriching the ways to play with detachable parts and different connection methods, making it suitable for a variety of play scenarios and enhancing children's interactive and teamwork experiences.
Smart Images

Figure CN122183180A_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of toys, and more particularly to a launching device and a launching toy. Background Technology
[0002] Launching toys can launch objects, providing children with entertainment and playful fun, improving their motor skills and coordination, promoting interaction and teamwork among children, and benefiting their growth and development. However, currently available launching toys can only launch objects directly, and their playability still needs improvement. Summary of the Invention
[0003] This application aims to at least partially solve one of the technical problems in the related art. To this end, this application proposes a launching device.
[0004] To achieve the above objectives, this application discloses a launching device, the launching device comprising:
[0005] A transmitter adapted to mount an object to be launched thereon, the transmitter including an acceleration position and a launch position, the launch position being used to mount and launch the object to be launched, and the acceleration position being used to drive the object to be launched to rotate;
[0006] Accessories, which are detachably mounted on the transmitter, are adapted to cooperate with the launch position and / or the acceleration position to enable the transmitter to drive the object to be launched to rotate and / or launch the object to be launched.
[0007] In some embodiments of this application, the transmitter further includes at least one connection point adapted to be detachably connected to the accessory, and the transmitting device has different transmitting modes depending on the accessory connected to the connection point.
[0008] In some embodiments of this application, at least one of the accessories can be detachably mounted on the transmitter, and the transmitting device has different transmitting modes depending on the different accessories installed.
[0009] In some embodiments of this application, the acceleration position includes an acceleration gear, the accessory is adapted to drive the acceleration gear to rotate, and the acceleration gear is adapted to drive the object to be launched to rotate.
[0010] In some embodiments of this application, the accessory includes a first body, the first body including a first slide, the first slide being reciprocating;
[0011] When the first body and the transmitter are connected, the first slide is adapted to drive the acceleration position, so that the acceleration position drives the object to be launched to rotate.
[0012] In some embodiments of this application, the first slide handle is adapted to reciprocate along a first direction and a second direction, the first direction and the second direction being opposite, and the first body further includes a first clutch mechanism and a first stop mechanism, the first stop mechanism having a first stop state and a second stop state;
[0013] When the first stop mechanism is in the first stop state, the first slide handle is adapted to move along the first direction to drive the first clutch mechanism so that the first clutch mechanism drives the acceleration gear to rotate. When the first slide handle is adapted to move along the second direction, it drives the first clutch mechanism so that the first clutch mechanism and the acceleration gear are separated.
[0014] When the first stop mechanism is in the second stop state, the first slide handle is adapted to move along the first direction to drive the first clutch mechanism so that the first clutch mechanism and the acceleration gear are separated. When the first slide handle is adapted to move along the second direction, it drives the first clutch mechanism so that the first clutch mechanism drives the acceleration gear to rotate in the opposite direction.
[0015] In some embodiments of this application, the first clutch mechanism includes:
[0016] The first movable component is rotatable.
[0017] The first drive gear is rotatably configured and coaxial with the first movable part;
[0018] A first clutch gear, rotatably disposed on the first movable member and meshing with the first drive gear; and
[0019] The second clutch gear is rotatably disposed on the first movable member and meshes with the first drive gear;
[0020] When the first stop mechanism is in the first stop state:
[0021] The first slide handle is adapted to drive the first drive gear to rotate when moving along the first direction, so as to make the first movable member swing, and to make the first clutch gear and the acceleration gear mesh and drive, and the second clutch gear and the acceleration gear disengage;
[0022] When the first slide handle moves along the second direction, it drives the first drive gear to rotate in the opposite direction, so that the first movable part swings in the opposite direction and is stopped by the first stop mechanism, so that the first clutch gear and the acceleration gear are separated, and the second clutch gear and the acceleration gear are separated.
[0023] When the first stop mechanism is in the second stop state;
[0024] When the first slide handle moves along the first direction, it drives the first drive gear to rotate, so that the first movable part swings and is stopped by the first stop mechanism, thereby disengaging the first clutch gear and the acceleration gear, and disengaging the second clutch gear and the acceleration gear.
[0025] When the first slide handle moves along the second direction, it drives the first drive gear to rotate in the opposite direction, so that the first movable part swings in the opposite direction, and causes the first clutch gear and the acceleration gear to separate, and the second clutch gear and the acceleration gear to mesh and drive.
[0026] In some embodiments of this application, the first stop mechanism includes a slot, and the first movable member is inserted into the slot;
[0027] When the first stop mechanism is in the first stop state, the first movable member is adapted to be stopped by one side of the slot, so that the first clutch gear and the second clutch gear are respectively separated from the acceleration gear;
[0028] When the first stop mechanism is in the second stop state, the first movable member is adapted to be stopped by the other side of the slot, so that the first clutch gear and the second clutch gear are respectively separated from the acceleration gear.
[0029] In some embodiments of this application, the first movable member is rotatably configured to switch between the first stop state and the second stop state, thereby changing the position of the slot.
[0030] In some embodiments of this application, the first body further includes a first rack, the first slide is connected to the first rack and can drive the first rack to reciprocate, and the first rack is connected to the first drive gear in a transmission connection.
[0031] In some embodiments of this application, the launching device further includes a first extension member adapted to be detachably connected to the first body, and the first slide is adapted to reciprocate to the first extension member when the first extension member and the first body are connected.
[0032] In some embodiments of this application, the first body further includes a first limiting mechanism, which is adapted to avoid the first slide handle when the first extension member and the first body are connected, so that the first slide handle can reciprocate to the first extension member, and is also adapted to stop the first slide handle when the first extension member and the first body are disassembled, so as to prevent the first slide handle from coming off.
[0033] In some embodiments of this application, the first extension component includes a first protruding rod, and the first limiting mechanism includes a first movable pin;
[0034] The first protruding rod is adapted to drive the first movable pin away from the movement path of the first slide handle when the first extension component and the first body are connected, so as to avoid the first slide handle;
[0035] The first movable pin is adapted to move into the movement path of the first slide under the action of elastic force when the first extension member and the first body are disassembled, so as to stop the first slide.
[0036] In some embodiments of this application, the accessory includes a handle adapted for gripping, and the handle includes a first release mechanism;
[0037] When the handle and the transmitter are connected, the first release mechanism is adapted to drive the launch position, so that the launch position drives the object to be launched to be launched.
[0038] In some embodiments of this application, the accessory includes a second body, the second body including a second slider and a second release mechanism, the second slider being reciprocating;
[0039] When the second body and the transmitter are connected, the second slider is adapted to drive the acceleration position, so that the acceleration position drives the object to be launched to rotate, and the second release mechanism is adapted to drive the launch position, so that the launch position drives the object to be launched to be launched.
[0040] In some embodiments of this application, the second slider is adapted to reciprocate along a third direction and a fourth direction, the third direction and the fourth direction being opposite, and the second body further includes a second clutch mechanism and a second stop mechanism, the second stop mechanism having a third stop state and a fourth stop state;
[0041] When the second stop mechanism is in the third stop state, the second slider is adapted to drive the second clutch mechanism when moving along the third direction, so that the second clutch mechanism drives the acceleration gear to rotate. When the second slider is adapted to drive the second clutch mechanism when moving along the fourth direction, so that the second clutch mechanism and the acceleration gear are separated.
[0042] When the second stop mechanism is in the fourth stop state, the second slider is adapted to drive the second clutch mechanism when moving along the third direction, so that the second clutch mechanism and the acceleration gear are separated. When the second slider is adapted to drive the second clutch mechanism when moving along the fourth direction, so that the second clutch mechanism drives the acceleration gear to rotate in the opposite direction.
[0043] In some embodiments of this application, the second clutch mechanism includes:
[0044] The second movable part is rotatable.
[0045] The second drive gear is rotatably configured and coaxial with the second movable part;
[0046] A third clutch gear, rotatably disposed on the second movable member and meshing with the second drive gear; and
[0047] The fourth clutch gear is rotatably mounted on the second movable member and meshes with the second drive gear;
[0048] When the second stop mechanism is in the third stop state:
[0049] The second slider is adapted to drive the second drive gear to rotate when it moves along the third direction, so as to make the second movable member swing, and to make the third clutch gear and the acceleration gear mesh and drive, and the fourth clutch gear and the acceleration gear disengage;
[0050] When the second slider moves along the fourth direction, it drives the second drive gear to rotate in the opposite direction, so that the second movable part swings in the opposite direction and is stopped by the second stop mechanism, thereby separating the third clutch gear and the acceleration gear, and separating the fourth clutch gear and the acceleration gear.
[0051] When the second stop mechanism is in the fourth stop state;
[0052] The second slider is adapted to drive the second drive gear to rotate when it moves along the third direction, so that the second movable part swings and is stopped by the second stop mechanism, thereby separating the third clutch gear and the acceleration gear, and separating the fourth clutch gear and the acceleration gear;
[0053] When the second slider moves along the fourth direction, it drives the second drive gear to rotate in the opposite direction, so that the second movable part swings in the opposite direction, and causes the third clutch gear and the acceleration gear to separate, and the fourth clutch gear and the acceleration gear to mesh and drive.
[0054] In some embodiments of this application, the second stop mechanism includes a first stop groove and a second stop groove;
[0055] When the second stop mechanism is in the third stop state, the second movable member is inserted into the first stop groove to be stopped by the first stop groove during swinging.
[0056] When the second stop mechanism is in the fourth stop state, the second movable member is inserted into the second stop groove to be stopped by the second stop groove during swinging.
[0057] In some embodiments of this application, the first stop groove and the second stop groove are connected, and the second stop mechanism is adapted to reciprocate so that the second movable member can move from the first stop groove into the second stop groove, and from the second stop groove into the first stop groove.
[0058] In some embodiments of this application, the second body further includes a second rack, the second slider is connected to the second rack and can drive the second rack to reciprocate, and the second rack is connected to the second drive gear in a transmission connection.
[0059] In some embodiments of this application, the second body further includes a second limiting mechanism;
[0060] The second slider includes a first gear mechanism and a second gear mechanism, which are arranged alternately along the reciprocating direction of the second slider. The first gear mechanism and the second gear mechanism are adapted to follow the movement of the second slider and can be selectively abutted against the second limiting mechanism.
[0061] In some embodiments of this application, the second body further includes a second rack, the second slider and the second rack are movably connected and can drive the second rack to reciprocate, and the second rack is connected to the acceleration position transmission;
[0062] The second rack is adapted to selectively drive one of the first gear mechanism and the second gear mechanism to a position abutting against the second limiting mechanism when moving relative to the second slider.
[0063] In some embodiments of this application, the second slider further includes a groove and a locking member, the second rack being movably connected to the groove, and the locking member being adapted to lock the second rack relative to the second slider and to unlock the second rack relative to the second slider.
[0064] The second rack is adapted to move from one end of the slide groove toward the other end when the locking member is unlocked, so as to drive one of the first gear mechanism and the second gear mechanism to switch to the position abutting against the second limiting mechanism. It is also adapted to move from the other end of the slide groove toward the first end when the locking member is unlocked, so as to drive the other of the first gear mechanism and the second gear mechanism to switch to the position abutting against the second limiting mechanism.
[0065] In some embodiments of this application, the launching device further includes a second extension component, the second extension component being adapted to be detachably connected to the second body, and the second slider being adapted to reciprocate to the second extension component when the second extension component and the second body are connected.
[0066] In some embodiments of this application, the second body further includes a second limiting mechanism, which is adapted to avoid the second slider when the second extension member and the second body are connected, so that the second slider can reciprocate to the second extension member, and is also adapted to stop the second slider when the second extension member and the second body are disassembled, so as to prevent the second slider from falling out.
[0067] In some embodiments of this application, the second extension member includes a second protruding rod, and the second limiting mechanism includes a second movable pin;
[0068] The second protruding rod is adapted to drive the second movable pin away from the movement path of the second slider when the second extension component and the second body are connected, so as to avoid the second slider;
[0069] The second movable pin is adapted to move into the movement path of the second slider under the action of elastic force when the second extension member and the second body are disassembled, so as to stop the second slider.
[0070] In some embodiments of this application, the accessory includes a pull member adapted to insert into and pull out of the transmitter, the pull member including an acceleration end and a launch end;
[0071] When the pull member and the launcher are connected, the acceleration end is adapted to drive the acceleration position during the process of the pull member being inserted into and / or pulled out of the launcher, so that the acceleration position drives the object to be launched to rotate, and the launch end is adapted to drive the launch position during the process of the pull member being inserted into and / or pulled out of the launcher, so that the launch position drives the object to be launched to launch.
[0072] In some embodiments of this application, the object to be launched is adapted to be launched forward; the launcher is provided with guide holes, the pull member is adapted to be inserted into and pulled out of the guide holes, and at least two guide holes are arranged alternately in the left-right direction.
[0073] In some embodiments of this application, the acceleration end is adapted to drive the acceleration gear to rotate.
[0074] In some embodiments of this application, the acceleration position further includes a first transmission gear, the acceleration end being adapted to mesh with the first transmission gear to drive the first transmission gear to rotate, and the first transmission gear and the acceleration gear meshing to drive the acceleration gear to rotate.
[0075] In some embodiments of this application, the pulling member is adapted to first drive the acceleration position and then the launch position when pulled out;
[0076] Alternatively, the pull member is adapted to first drive the acceleration position and then the launch position during insertion.
[0077] In some embodiments of this application, the transmit bit includes:
[0078] A push plate, wherein when the object to be launched is installed on the launcher, the object to be launched is adapted to abut against the push plate and drive the push plate to move;
[0079] A locking element is adapted to lock the push plate when the push plate moves to a preset position, and is adapted to be driven by the accessory to unlock the push plate;
[0080] A first elastic element is adapted to generate force on the push plate so as to drive the push plate to reset when the locking element unlocks the push plate, thereby causing the push plate to drive the object to be launched to be launched.
[0081] In some embodiments of this application, when a handle is included, the first release mechanism of the handle is adapted to actuate the locking member to unlock the push plate;
[0082] And / or, when a second body is included, the second release mechanism of the second body is adapted to actuate the locking member to unlock the push plate;
[0083] And / or, when a pull member is included, the launching end of the pull member is adapted to actuate the locking member to unlock the push plate.
[0084] In some embodiments of this application, the transmitting position further includes a rotating member, which is provided with a lug and a second contact portion;
[0085] When a handle is included, the first release mechanism of the handle includes a reciprocating pusher adapted to push the lug to rotate the rotating member and cause the second contact portion to drive the locking member to unlock the push plate.
[0086] In some embodiments of this application, when a second body is included, the second release mechanism of the second body includes a reciprocating trigger adapted to actuate the locking member to unlock the push plate.
[0087] In some embodiments of this application, the transmitting position further includes a rotating component;
[0088] When a pull member is included, the launching end of the pull member is adapted to drive the rotating member to rotate when the pull member moves in one of the directions of insertion and withdrawal, such that the rotating member drives the locking member to unlock the push plate. The launching end is adapted to drive the rotating member to rotate in the opposite direction when the pull member moves in the other direction of insertion and withdrawal, such that the rotating member and the locking member separate.
[0089] In some embodiments of this application, the rotating member is provided with a first contact portion and a second contact portion, and the transmitting end forms a groove;
[0090] The first contact portion is adapted to sequentially engage with and disengage from the groove when the pull member moves in one of the directions of insertion and disengagement, so as to rotate the rotating member and cause the second contact portion to drive the locking member to unlock the push plate;
[0091] The first contact portion is adapted to sequentially engage and disengage from the groove when the pull member moves in the opposite direction of insertion and disengagement, so as to cause the rotating member to rotate in the opposite direction and to separate the second contact portion from the locking member.
[0092] In some embodiments of this application, the launching position further includes a third elastic member, which is adapted to generate a force on the rotating member to cause the rotating member to have a rotational tendency. The rotating member is adapted to abut against the pulling member under the action of the rotational tendency, and is adapted to drive the first contact portion into the groove under the action of the rotational tendency when the groove and the first contact portion correspond.
[0093] The second aspect of this application discloses a launching toy, which includes an object to be launched and the launching device described above.
[0094] The launching device of this application can both rotate the object to be launched and launch it, thus enhancing the fun of playing.
[0095] Other advantages of this application will be set forth in part in the description which follows, and in part will be obvious from the description or may be learned by practice of this application. Attached Figure Description
[0096] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this application. For those skilled in the art, other designs can be obtained based on the structures shown in these drawings without creative effort.
[0097] Figure 1 This is a schematic diagram of the launching device (in blade shape) in some embodiments;
[0098] Figure 2 for Figure 1 The diagram shows a launch device (the first slide is located on the first main body);
[0099] Figure 3 for Figure 1 The diagram shows a launching device (the first slide is located on the first extension component);
[0100] Figure 4 for Figure 1 The diagram shows a launching device launching an object.
[0101] Figure 5 for Figure 1 Exploded view of the launching device shown;
[0102] Figure 6 This is a schematic diagram showing the coordination between the acceleration position and the object to be launched in some embodiments;
[0103] Figure 7 for Figure 1 The diagram shows a partial structural schematic of the launching device.
[0104] Figure 8 for Figure 1 A schematic diagram showing the engagement of the first stop mechanism, the first clutch mechanism, and the acceleration gear in the launching device shown.
[0105] Figure 9 for Figure 8 Another perspective view of the structure shown;
[0106] Figure 10 for Figure 1 A schematic diagram showing the reciprocating movement of the first slide handle when the first stop mechanism in the launching device is in the first stop state.
[0107] Figure 11 for Figure 1 A schematic diagram showing the reciprocating movement of the first slide handle when the first stop mechanism in the launching device is in the second stop state.
[0108] Figure 12 for Figure 1 A schematic diagram of the first release mechanism and the launch position in the launching device shown;
[0109] Figure 13 for Figure 12 The diagram shown is an exploded view of the structure.
[0110] Figure 14 This is a schematic diagram of the rotating component of the launch position in some embodiments;
[0111] Figure 15 for Figure 1A schematic diagram of the first release mechanism in the launching device driving the launching position to launch the object to be launched;
[0112] Figure 16 for Figure 1 A schematic diagram of the first main body of the launching device before it is connected to the first extension component;
[0113] Figure 17 for Figure 1 A schematic diagram of the state of the first main body of the launching device when it is connected to the first extension component (the first extension component is omitted in the figure for clarity);
[0114] Figure 18 for Figure 1 A schematic diagram showing the cooperation between the first extension component and the first limiting mechanism in the launching device shown;
[0115] Figure 19 This is a schematic diagram of the launching device (in gun mode) in some embodiments;
[0116] Figure 20 for Figure 19 Exploded view of the launching device shown;
[0117] Figure 21 for Figure 19 The diagram shows the launching device (the second slider is located in the second main body);
[0118] Figure 22 for Figure 19 The diagram shows a launching device (the second slider is located in the second extension component);
[0119] Figure 23 for Figure 19 The diagram shows a launching device launching an object.
[0120] Figure 24 for Figure 19 A schematic diagram showing the engagement of the second slider, second rack, second clutch mechanism, and acceleration gear in the launching device shown.
[0121] Figure 25 for Figure 19 A schematic diagram showing the cooperation between the second stop mechanism and the second clutch mechanism in the launching device shown.
[0122] Figure 26 for Figure 25 Another perspective view of the structure shown;
[0123] Figure 27 for Figure 19 A schematic diagram of the second stop mechanism in the launching device shown;
[0124] Figure 28 for Figure 19A schematic diagram showing the reciprocating movement of the second slider when the second stop mechanism in the launching device is in the third stop state.
[0125] Figure 29 for Figure 19 A schematic diagram showing the reciprocating movement of the second slider when the second stop mechanism in the launching device is in the fourth stop state.
[0126] Figure 30 for Figure 19 The diagram shown illustrates the launch device without the second extension component.
[0127] Figure 31 for Figure 19 A schematic diagram of the engagement between the second slider and the second rack in the launching device shown (the first stop mechanism abuts against the second limit mechanism when moving);
[0128] Figure 32 for Figure 31 Another angle view of the structure shown;
[0129] Figure 33 for Figure 19 A schematic diagram of the engagement between the second slider and the second rack in the launching device shown (the second stop mechanism abuts against the second limit mechanism when moving);
[0130] Figure 34 for Figure 33 Another angle view of the structure shown;
[0131] Figure 35 for Figure 19 A schematic diagram showing the engagement of the second rack, the first gear mechanism, the second gear mechanism, and the locking element in the launching device shown.
[0132] Figure 36 for Figure 19 A schematic diagram showing the coordination of the second release mechanism, the launch position, and the object to be launched in the launch device shown.
[0133] Figure 37 for Figure 36 The diagram shown is an exploded view of the structure.
[0134] Figure 38 for Figure 19 The diagram shows a second release mechanism controlling the launch position to launch the object to be launched in the launching device.
[0135] Figure 39 for Figure 19 The second extension component in the launching device shown is connected to the second main body.
[0136] Figure 40 This is a schematic diagram of the launching device in some embodiments (in its basic form);
[0137] Figure 41 for Figure 40 Exploded view of the launching device shown;
[0138] Figure 42 for Figure 40 The diagram shows a launching device launching an object.
[0139] Figure 43 for Figure 40 The schematic diagram shows the handle of the launching device located on the left side of the launcher;
[0140] Figure 44 for Figure 40 The schematic diagram shows the handle of the launching device located on the right side of the launcher.
[0141] Figure 45 for Figure 40 The diagram shows a partial structural schematic of the launching device.
[0142] Figure 46 for Figure 45 The diagram shown is an exploded view of the structure.
[0143] Figure 47 for Figure 40 A schematic diagram of the engagement between the acceleration position and the pulling component in the launching device shown;
[0144] Figure 48 for Figure 40 A schematic diagram of the pulling component in the launching device shown;
[0145] Figure 49 for Figure 40 The diagram shows the insertion process of the launching device.
[0146] Figure 50 for Figure 40 The diagram shows the process of removing the launching device.
[0147] Explanation of icon numbers:
[0148] Launching device 100, object to be launched 200, pulling component 1000, launching end / groove 1100, accelerating end 1200, first main body 2000, first slide rail 2001, first guide groove 2002, first sliding handle 2100, first rack 2101, first clutch mechanism 2200, first drive gear 2210, first moving part 2220, first clutch gear 2230, second clutch gear 2240, first stop mechanism 2300, slot 2310. First limiting mechanism 2400, first movable pin 2410, first extension component 2500, first extension slide rail 2501, first extension guide groove 2502, first protruding rod 2510, second body 3000, second slide rail 3001, second slider 3100, second rack 3101, first gear mechanism 3110, second gear mechanism 3120, slide groove 3130, locking component 3140, second clutch mechanism 3200, second drive gear 3210, second movable pin 2400, second movable pin 2500, first extension guide groove 2501, first extension guide groove 2502, first extension guide groove 2502, first extension guide groove 2502, second extension guide groove 2503, second extension guide groove 2504, second extension guide groove 2505, second extension guide groove 2502, first extension guide groove 2502, first extension guide groove 2503, second extension guide groove 2504, second extension guide groove 2505, second extension guide groove 2502, second ... Moving part 3220, third clutch gear 3230, fourth clutch gear 3240, second stop mechanism 3300, first stop groove 3310, second stop groove 3320, second limit mechanism 3400, second movable pin 3410, second extension component 3500, second extension slide rail 3501, second protruding rod 3510, second release mechanism 3600, trigger 3610, launcher 4000, acceleration position 4100, acceleration gear 4110, first transmission gear 41 20, launching position 4200, push plate 4210, locking member 4220, rotating member 4230, first contact part 4231, second contact part 4232, central shaft part 4233, lug 4234, first elastic member 4291, second elastic member 4292, third elastic member 4293, first connecting position 4310, second connecting position 4320, third connecting position 4330, guide hole 4400, handle 5000, first release mechanism 5100, pushing member 5110.
[0149] The realization of the purpose, functional features and advantages of this application will be further explained in conjunction with the embodiments and with reference to the accompanying drawings. Detailed Implementation
[0150] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only a part of the embodiments of this application, and not all of the embodiments. Based on the embodiments of this application, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the scope of protection of this application.
[0151] It should be noted that all directional indicators (such as up, down, left, right, front, back, etc.) in the embodiments of this application are only used to explain the relative positional relationship and movement of each component in a certain specific posture (as shown in the figure). If the specific posture changes, the directional indicator will also change accordingly.
[0152] In this application, unless otherwise expressly specified and limited, the terms "connection," "fixed," etc., should be interpreted broadly. For example, "fixed" can mean a fixed connection, a detachable connection, or an integral part; it can mean a mechanical connection or an electrical connection; it can mean a direct connection or an indirect connection through an intermediate medium; it can mean the internal communication of two components or the interaction between two components, unless otherwise expressly limited. Those skilled in the art can understand the specific meaning of the above terms in this application according to the specific circumstances.
[0153] Furthermore, the use of terms such as "first" and "second" in this application is for descriptive purposes only and should not be construed as indicating or implying their relative importance or implicitly specifying the number of technical features indicated. Therefore, a feature defined as "first" or "second" may explicitly or implicitly include at least one of those features. Additionally, the technical solutions of the various embodiments can be combined with each other, but only on the basis of being achievable by those skilled in the art. If the combination of technical solutions is contradictory or impossible to implement, such a combination of technical solutions should be considered non-existent and not within the scope of protection claimed in this application.
[0154] The first aspect of this application discloses a launching device 100, combined with... Figure 1 , Figure 5 , Figure 19 , Figure 20 , Figure 40 and Figure 41 As shown, the launching device 100 includes a launcher 4000 and accessories. The launcher 4000 is adapted to mount an object to be launched 200 thereon. The launcher 4000 includes an acceleration position 4100 and a launch position 4200. The launch position 4200 is used to mount and launch the object to be launched 200. The acceleration position 4100 is used to drive the object to be launched 200 to rotate. The accessories are detachably mounted on the launcher 4000. The accessories are adapted to cooperate with the launch position 4200 and / or the acceleration position 4100 to enable the launcher 4000 to drive the object to be launched 200 to rotate and / or launch the object to be launched 200.
[0155] The launch object 200 can be installed on or launched from the launcher 4000. Specifically, the launch object 200 is installed in the launch position 4200. The launch position 4200 is a structure for mounting and launching the launch object 200. After installation, the launch object 200, in addition to cooperating with the launch position 4200, also cooperates with the acceleration position 4100, which is used to rotate the launch object 200. The launch object 200 can be installed on the launcher 4000 and launched by controlling the launch position 4200, or the launch object 200 can be rotated first by the acceleration position 4100 and then launched by controlling the launch position 4200.
[0156] The triggering of the acceleration position 4100 and / or the launch position 4200 is achieved by an accessory. This accessory is detachably mounted to the launcher 4000 to cooperate with the launch position 4200 and / or the acceleration position 4100. The accessory drives the launch position 4200 and / or the acceleration position 4100, which in turn drives the object to be launched 200, achieving the launch and / or rotation of the object 200. The detachable design of the accessory facilitates replacement, and the rotation and launch of the object 200 enhances the fun of using the launching device 100. The object 200 can be of various types, such as a gyroscope. A gyroscope has a rotating part and a fixed part. The rotating part can rotate relative to the fixed part. The gyroscope is mounted to the launcher 4000 and the launch position 4200 via the fixed part. The acceleration position 4100 drives the rotating part of the gyroscope to rotate, and the launch position 4200 acts on the fixed part of the gyroscope to launch the entire gyroscope.
[0157] In some embodiments, at least one accessory may be detachably mounted on the transmitter 4000, and the transmitter 100 may have different transmission configurations depending on the accessory mounted.
[0158] It is understandable that not being exactly the same does not necessarily mean being different. For example, different components may have different shapes, sizes, or materials, which would cause the launching device 100 to form different launching configurations.
[0159] The accessories can be one, two, three, or more. For example, there are three accessories: a first accessory, a second accessory, and a third accessory. The first accessory can be installed on or removed from the transmitter 4000. The second accessory can be installed on or removed from the transmitter 4000. The third accessory can be installed on or removed from the transmitter 4000. At least one of the first, second, and third accessories is detachably connected to the transmitter 4000. When the first accessory is installed on the transmitter 4000, the transmitter 100 forms a first firing mode; or when the second accessory is installed on the transmitter 4000, the transmitter 100 forms a second firing mode; or when the third accessory is installed on the transmitter 4000, the transmitter 100 forms a third firing mode; or when the first and second accessories are installed on the transmitter 4000, the transmitter 100 forms a fourth firing mode, and so on.
[0160] The launcher 4000 can be equipped with different accessories, which allows the launch device 100 to form different launch patterns, thus enriching the gameplay, making it suitable for more play scenarios, and increasing the fun of playing.
[0161] In some embodiments, the transmitter 4000 further includes at least one connection point adapted for detachable connection with an accessory. Depending on the accessory connected to the connection point, the transmitter 100 has different launching modes. The connection point is a structure for connecting with an accessory, such as a latch, snap-fit, or other forms. Since the accessory and the connection point are detachably connected, different accessories can be connected to the connection point. Furthermore, since there is at least one connection point, accessories can be connected to the corresponding connection point, further enriching the gameplay.
[0162] Taking an accessory comprising a first body 2000, a second body 3000, a pull member 1000, and a handle 5000 (the first body 2000, the second body 3000, the pull member 1000, and the handle 5000 are all accessories, each detachably connected to the launcher) as an example, the connection points include a first connection point 4310, a second connection point 4320, and a third connection point 4330. The object to be launched 200 is launched forward from the launcher 4000.
[0163] When the first body 2000 and the transmitter 4000 are connected, the handle 5000 is connected to the first connection position 4310 and protrudes rearward from the transmitter 4000. Figures 1 to 5 As shown, when the first body 2000 and the transmitter 4000 are connected, the first body 2000 protrudes forward from the transmitter 4000, and the handle 5000 is connected to the first connection position 4310 and protrudes backward from the transmitter 4000, so that the launching device 100 forms a knife shape.
[0164] When the second body 3000 and the transmitter 4000 are connected, the handle 5000 is connected to the second connection position 4320 and protrudes downward from the transmitter 4000. Figures 19 to 23 As shown, when the second body 3000 and the launcher 4000 are connected, the second body 3000 protrudes forward from the launcher 4000, and the handle 5000 is connected to the second connection position 4320 and protrudes downward from the launcher 4000, so that the launching device 100 is in the form of a gun.
[0165] When the pull member 1000 and the transmitter 4000 are connected, the handle 5000 is connected to the third connection position 4330 and protrudes from the transmitter 4000 to the left or right. This establishes the basic configuration of the launching device 100. The handle 5000's protrusion from the transmitter 4000 to the left or right facilitates increased force application to the pull member 1000 during gripping, improving the user experience. Optionally, the transmitter 4000 has third connection positions 4330 on both its left and right sides, and the handle 5000 is adapted to connect to either the left or right third connection position 4330. Different users have different usage habits with their left and right hands. Therefore, in this embodiment, by setting third connection positions 4330 on both sides of the transmitter 4000, users can connect the handle 5000 to the third connection position 4330 on the left or the third connection position 4330 on the right according to their own situation and usage scenario, thereby improving the user experience.
[0166] By setting the first connection position 4310, the second connection position 4320, and the third connection position 4330, the position of the handle 5000 relative to the transmitter 4000 is changed. When the first main body 2000 and the transmitter 4000 are connected, the handle 5000 is connected to the first connection position 4310, thus placing the transmitter 100 in the corresponding usage mode. When the second main body 3000 and the transmitter 4000 are connected, the handle 5000 is connected to the second connection position 4320, thus placing the transmitter 100 in the corresponding usage mode. When the pull member 1000 and the transmitter 4000 are connected, the handle 5000 is connected to the third connection position 4330, thus placing the transmitter 100 in the corresponding usage mode.
[0167] It is understood that the accessories include a first body 2000, a second body 3000, a pull member 1000 and a handle 5000, and the connection positions include a first connection position 4310, a second connection position 4320 and a third connection position 4330 as an example, but are not limited to the above examples.
[0168] Combination Figures 1 to 7 , Figures 19 to 24 as well as Figures 40 to 47 As shown, in some embodiments, the acceleration position 4100 includes an acceleration gear 4110, and the accessory is adapted to drive the acceleration gear 4110 to rotate. The acceleration gear 4110 is adapted to drive the object to be launched 200 to rotate. The cooperation between the accessory and the acceleration position 4100 is reflected in the fact that the accessory can drive the acceleration gear 4110 to rotate, so that the acceleration gear 4110 drives the object to be launched 200 to rotate. The rotation of the acceleration gear 4110 drives the object to be launched 200 to rotate. For example, the object to be launched 200 has a toothed structure. When the object to be launched 200 is installed on the launcher 4000, the toothed structure of the object to be launched 200 meshes with the acceleration gear 4110. When the acceleration gear 4110 rotates, it can drive the object to be launched 200 to rotate. Furthermore, when the object to be launched 200 is launched, it facilitates the rapid separation between the object to be launched 200 and the acceleration gear 4110.
[0169] Combination Figures 1 to 6 as well as Figures 12 to 15 As shown, in some embodiments, the accessory includes a first body 2000, which includes a first slide 2100 that is reciprocating; when the first body 2000 is connected to the transmitter 4000, the first slide 2100 is adapted to drive the acceleration position 4100, so that the acceleration position 4100 drives the object to be launched 200 to rotate.
[0170] The first main body 2000 includes a first slide 2100, which can reciprocate. That is, the first slide 2100 can move along a first direction or along a second direction, which are opposite. During the reciprocating movement of the first slide 2100, the first slide 2100 can drive the acceleration position 4100, thereby causing the acceleration position 4100 to drive the object to be launched 200 to rotate.
[0171] When the first body 2000 and the transmitter 4000 are connected, the reciprocating movement of the first slide handle 2100 is converted into the rotation of the acceleration gear 4110. For example, the first body 2000 also includes a first rack 2101. The first slide handle 2100 and the first rack 2101 are connected to drive the first rack 2101 to reciprocate. The first rack 2101 and the acceleration gear 4110 are connected in a transmission, thereby causing the acceleration gear 4110 to rotate. In this way, the reciprocating movement of the first slide handle 2100 is converted into the rotation of the acceleration gear 4110. The first body 2000 can generate force on the first slide handle 2100 by setting an elastic element to provide elastic force for the first slide handle 2100 to return to its original position.
[0172] Combination Figures 7 to 11As shown, in some embodiments, the first slide 2100 is adapted to reciprocate along a first direction and a second direction, the first direction and the second direction being opposite. The first body 2000 also includes a first clutch mechanism 2200 and a first stop mechanism 2300, the first stop mechanism 2300 having a first stop state and a second stop state.
[0173] When the first stop mechanism 2300 is in the first stop state, the first slide handle 2100 is adapted to move in the first direction to drive the first clutch mechanism 2200, so that the first clutch mechanism 2200 drives the acceleration gear 4110 to rotate. When the first slide handle 2100 is adapted to move in the second direction, it drives the first clutch mechanism 2200 to disengage from the acceleration gear 4110. When the first stop mechanism 2300 is in the second stop state, the first slide handle 2100 is adapted to move in the first direction to drive the first clutch mechanism 2200, so that the first clutch mechanism 2200 disengages from the acceleration gear 4110. When the first slide handle 2100 is adapted to move in the second direction, it drives the first clutch mechanism 2200 to drive the acceleration gear 4110 to rotate in the opposite direction.
[0174] By setting a first clutch mechanism 2200, during the reciprocating movement of the first slider 2100, only one direction of the reciprocating movement can drive the acceleration gear 4110 to rotate, while the other direction of the reciprocating movement cannot drive the acceleration gear 4110 to rotate. Thus, through multiple reciprocating movements of the first slider 2100, the acceleration gear 4110 can achieve continuous acceleration. Furthermore, by setting a first stop mechanism 2300, switching between different stop states can cause the acceleration gear 4110 to rotate in different directions, thereby changing the rotation direction of the object to be launched 200.
[0175] For example, see Figure 10 When the first stop mechanism 2300 is in the first stop state: during the first reciprocating movement of the first slide handle 2100, when the first slide handle 2100 moves along the first direction, the first clutch mechanism 2200 acts on the acceleration gear 4110, thereby driving the acceleration gear 4110 to rotate (clockwise). When the first slide handle 2100 moves along the second direction, the first clutch mechanism 2200 disengages from the acceleration gear 4110. During the second reciprocating movement of the first slide handle 2100, when the first slide handle 2100 moves along the first direction, the first clutch mechanism 2200 acts on the acceleration gear 4110, thereby driving the acceleration gear 4110 to rotate (clockwise). When the first slide handle 2100 moves along the second direction, the first clutch mechanism 2200 disengages from the acceleration gear 4110, and so on.
[0176] See Figure 11When the first stop mechanism 2300 is in the second stop state: during the first reciprocating movement of the first slide handle 2100, when the first slide handle 2100 moves in the first direction, the first clutch mechanism 2200 disengages from the acceleration gear 4110, and when the first slide handle 2100 moves in the second direction, the first clutch mechanism 2200 acts on the acceleration gear 4110, thereby driving the acceleration gear 4110 to rotate in the opposite direction (counterclockwise rotation); during the second reciprocating movement of the first slide handle 2100, when the first slide handle 2100 moves in the first direction, the first clutch mechanism 2200 disengages from the acceleration gear 4110, and when the first slide handle 2100 moves in the second direction, the first clutch mechanism 2200 acts on the acceleration gear 4110, thereby driving the acceleration gear 4110 to rotate in the opposite direction (counterclockwise rotation), and so on.
[0177] Combination Figures 7 to 11 As shown, in some embodiments, the first clutch mechanism 2200 includes a first movable member 2220, a first drive gear 2210, a first clutch gear 2230, and a second clutch gear 2240. The first movable member 2220 is rotatably disposed, the first drive gear 2210 is rotatably disposed and coaxial with the first movable member 2220, the first clutch gear 2230 is rotatably disposed on the first movable member 2220 and meshes with the first drive gear 2210, and the second clutch gear 2240 is rotatably disposed on the first movable member 2220 and meshes with the first drive gear 2210.
[0178] When the first stop mechanism 2300 is in the first stop state:
[0179] When the first slide handle 2100 moves in the first direction, it drives the first drive gear 2210 to rotate, causing the first movable member 2220 to swing, and causing the first clutch gear 2230 and the acceleration gear 4110 to mesh and drive, and the second clutch gear 2240 and the acceleration gear 4110 to disengage; when the first slide handle 2100 moves in the second direction, it drives the first drive gear 2210 to rotate in the opposite direction, causing the first movable member 2220 to swing in the opposite direction and be stopped by the first stop mechanism 2300, causing the first clutch gear 2230 and the acceleration gear 4110 to disengage, and the second clutch gear 2240 and the acceleration gear 4110 to disengage.
[0180] When the first stop mechanism 2300 is in the second stop state;
[0181] When the first slide handle 2100 moves in the first direction, it drives the first drive gear 2210 to rotate, causing the first movable member 2220 to swing and be stopped by the first stop mechanism 2300, thereby disengaging the first clutch gear 2230 and the acceleration gear 4110, and disengaging the second clutch gear 2240 and the acceleration gear 4110; when the first slide handle 2100 moves in the second direction, it drives the first drive gear 2210 to rotate in the reverse direction, causing the first movable member 2220 to swing in the reverse direction, and disengaging the first clutch gear 2230 and the acceleration gear 4110, and engaging the second clutch gear 2240 and the acceleration gear 4110.
[0182] Specifically, the first movable member 2220 is rotatable and can swing within a certain range, which is limited by the first stop mechanism 2300. The first drive gear 2210 is rotatable and coaxial with the first movable member 2220. The first drive gear 2210 may or may not be located on the first movable member 2220. The coaxiality of the first drive gear 2210 and the first movable member 2220 means that the rotation axis of the first drive gear 2210 is coaxial with the rotation axis of the first movable member 2220. The first clutch gear 2230 is disposed on the first movable member 2220 and can rotate relative to the first movable member 2220. The second clutch gear 2240 is disposed on the first movable member 2220 and can rotate relative to the first movable member 2220. Since the first movable member 2220 is rotatably disposed and the first drive gear 2210 is coaxial with the first movable member 2220, the first drive gear 2210 and the first clutch gear 2230 can always be engaged, and the first drive gear 2210 and the second clutch gear 2240 can always be engaged, regardless of how the first movable member 2220 swings. In this way, when the first drive gear 2210 rotates in different directions, it can drive the first movable member 2220 to swing in different directions. When the first movable member 2220 swings in different directions, it can drive the first clutch gear 2230 and the second clutch gear 2240 to swing accordingly.
[0183] The reciprocating movement of the first slide handle 2100 drives the first drive gear 2210 to rotate in different directions. For example, the first slide handle 2100 can drive the first drive gear 2210 to rotate through the first rack 2101 (the first rack 2101 and the first drive gear 2210 are connected by transmission). Since the first slide handle 2100 can reciprocate, the rotation direction of the first drive gear 2210 when the first slide handle 2100 moves in the first direction is different from the rotation direction of the first drive gear 2210 when the first slide handle 2100 moves in the second direction.
[0184] See Figure 10The orientation, when the first stop mechanism 2300 is in the first stop state:
[0185] When the first slide handle 2100 moves along the first direction, it drives the first drive gear 2210 to rotate clockwise. The first drive gear 2210 drives the first clutch gear 2230 and the second clutch gear 2240 to rotate counterclockwise. The first drive gear 2210 also drives the first movable member 2220 to swing clockwise. The first clutch gear 2230 and the second clutch gear 2240 swing accordingly, so that the first clutch gear 2230 and the acceleration gear 4110 mesh and transmit power (which also limits the first movable member 2220 from continuing to swing clockwise), while the second clutch gear 2240 and the acceleration gear 4110 disengage. Finally, the first clutch gear 2230 drives the acceleration gear 4110 to rotate clockwise, so as to drive the object to be launched 200 to rotate (counterclockwise). It is understandable that if the first slide bar 2100 moves to its limit along the first direction and comes to a stop, the first drive gear 2210 does not move. Since the first movable member 2220 is rotatable and the object to be launched 200 is still rotating, the first movable member 2220 is forced to swing counterclockwise, thereby causing the first clutch gear 2230 and the acceleration gear 4110 to separate.
[0186] When the first slide bar 2100 moves along the first direction and then switches to move along the second direction, it drives the first drive gear 2210 to rotate counterclockwise. The first drive gear 2210 drives the first clutch gear 2230 and the second clutch gear 2240 to rotate clockwise. At the same time, the first drive gear 2210 drives the first movable member 2220 to swing counterclockwise until the first movable member 2220 is stopped by the first stop mechanism 2300. The first clutch gear 2230 and the second clutch gear 2240 swing together, causing the first clutch gear 2230 to separate from the acceleration gear 4110 and the second clutch gear 2240 to separate from the acceleration gear 4110.
[0187] See Figure 11 The orientation, when the first stop mechanism 2300 is in the second stop state:
[0188] When the first slide handle 2100 moves along the first direction, it drives the first drive gear 2210 to rotate clockwise. The first drive gear 2210 drives the first clutch gear 2230 and the second clutch gear 2240 to rotate counterclockwise. At the same time, the first drive gear 2210 drives the first movable member 2220 to swing clockwise until the first movable member 2220 is stopped by the first stop mechanism 2300. The first clutch gear 2230 and the second clutch gear 2240 swing together, causing the first clutch gear 2230 to separate from the acceleration gear 4110 and the second clutch gear 2240 to separate from the acceleration gear 4110.
[0189] When the first slide bar 2100 moves along the first direction and then switches to move along the second direction, it drives the first drive gear 2210 to rotate counterclockwise. The first drive gear 2210 drives the first clutch gear 2230 and the second clutch gear 2240 to rotate clockwise. The first drive gear 2210 also drives the first movable part 2220 to swing counterclockwise. The first clutch gear 2230 and the second clutch gear 2240 swing along with it, so that the second clutch gear 2240 and the acceleration gear 4110 mesh and drive (which also limits the first movable part 2220 from continuing to swing counterclockwise). The first clutch gear 2230 and the acceleration gear 4110 disengage. Finally, the second clutch gear 2240 drives the acceleration gear 4110 to rotate counterclockwise, so as to drive the object to be launched 200 to rotate (clockwise). It is understandable that if the first slide bar 2100 moves to its limit in the second direction and comes to a stop, the first drive gear 2210 does not move. Since the first movable member 2220 is rotatably set and the object to be launched 200 is still rotating, the first movable member 2220 is forced to swing clockwise, causing the second clutch gear 2240 and the acceleration gear 4110 to separate.
[0190] Combination Figures 7 to 11 As shown, in some embodiments, the first stop mechanism 2300 includes a slot 2310, and the first movable member 2220 is inserted into the slot 2310;
[0191] When the first stop mechanism 2300 is in the first stop state, the first movable member 2220 is adapted to be stopped by one side of the slot 2310, so that the first clutch gear 2230 and the second clutch gear 2240 are respectively separated from the acceleration gear 4110; when the first stop mechanism 2300 is in the second stop state, the first movable member 2220 is adapted to be stopped by the other side of the slot 2310, so that the first clutch gear 2230 and the second clutch gear 2240 are respectively separated from the acceleration gear 4110.
[0192] In this embodiment, the first movable member 2220 is restricted in different stopping states of the first stopping mechanism 2300 through the same slot 2310, which simplifies the structure.
[0193] Since the first movable member 2220 is inserted into the slot 2310 when the first stop mechanism 2300 is in the first stop state and the second stop state, in order to enable the opposite sides of the slot 2310 to stop the first movable member 2220 in the corresponding stop state, the position of the slot 2310 is different when the first stop mechanism 2300 is in the first stop state and the second stop state. For example, the first movable member 2220 can be rotatably configured to switch between the first stop state and the second stop state, thereby changing the position of the slot 2310. For example, the first movable member 2220 can be rotatably swung back and forth at a certain angle, thus changing the position of the slot 2310. The rotatability of the first movable member 2220 is achieved, for example, by using screws. When the screws are loosened, the first movable member 2220 can be rotated to adjust the position of the slot 2310. When the screws are tightened, the first movable member 2220 is fixed to position the slot 2310.
[0194] Combination Figures 1 to 5 as well as Figures 16 to 18 As shown, in some embodiments, the launching device 100 further includes a first extension member 2500, which is adapted to be detachably connected to the first body 2000, and a first slide 2100 is adapted to reciprocate to the first extension member 2500 when the first extension member 2500 and the first body 2000 are connected.
[0195] Specifically, the first extension member 2500 is adapted to be detachably connected to the first main body 2000, meaning that the first extension member 2500 and the first main body 2000 can be both connected and fixed, and can also be detached. When the first extension member 2500 and the first main body 2000 are detached, the first slider 2100 reciprocates on the first main body 2000, meaning that the reciprocating stroke of the first slider 2100 is determined by the first main body 2000 itself. When the first extension member 2500 is connected to the first main body 2000, the first slider 2100 can reciprocate to the first extension member 2500, meaning that the reciprocating stroke of the first slider 2100 is jointly determined by the first main body 2000 and the first extension member 2500. In this case, the reciprocating stroke of the first slider 2100 can be increased, which is more conducive to the rotational acceleration of the object to be launched 200.
[0196] When the first extension component 2500 and the first main body 2000 are connected, the first slider 2100 can reciprocate to the first extension component 2500. Therefore, when the first extension component 2500 and the first main body 2000 are disassembled, it is undesirable for the first slider 2100 to reciprocate to the position of the first extension component 2500; otherwise, the first slider 2100 will detach from the first main body 2000. Figures 16 to 18As shown, in some embodiments, the first body 2000 further includes a first limiting mechanism 2400, which is adapted to avoid the first slide handle 2100 when the first extension member 2500 and the first body 2000 are connected, so that the first slide handle 2100 can reciprocate to the first extension member 2500, and is also adapted to stop the first slide handle 2100 when the first extension member 2500 and the first body 2000 are disassembled, so as to prevent the first slide handle 2100 from coming off.
[0197] Specifically, the first limiting mechanism 2400 is a movable component that can both restrict the movement of the first slide 2100 and release the restriction on the movement of the first slide 2100.
[0198] When the first extension component 2500 and the first main body 2000 are connected, the first limiting mechanism 2400 undergoes a corresponding change. At this time, the first limiting mechanism 2400 avoids the first slider 2100, thereby releasing the restriction on the first slider 2100. The first slider 2100 can move from the first main body 2000 to the first extension component 2500, or from the first extension component 2500 to the first main body 2000. For example, in this case, the first limiting mechanism 2400 leaves the movement path of the first slider 2100, so that the first slider 2100 will not be stopped by the first limiting mechanism 2400 when it moves.
[0199] When the first extension component 2500 and the first main body 2000 are disassembled, the first limiting mechanism 2400 undergoes a corresponding change. At this time, the first limiting mechanism 2400 stops the first slider 2100, thereby restricting the first slider 2100. The first slider 2100 can only move back and forth within the first main body 2000. When the first slider 2100 moves in the direction of movement toward the first extension component 2500, it will be stopped by the first limiting mechanism 2400 and cannot detach from the first main body 2000. For example, in this case, the first limiting mechanism 2400 is located in the movement path of the first slider 2100, so the first slider 2100 will be stopped by the first limiting mechanism 2400 when it moves.
[0200] Combination Figure 18 As shown, in some embodiments, the first extension member 2500 includes a first protrusion 2510, and the first limiting mechanism 2400 includes a first movable pin 2410.
[0201] The first protruding rod 2510 is adapted to drive the first movable pin 2410 away from the movement path of the first slide 2100 to avoid the first slide 2100 when the first extension member 2500 and the first body 2000 are connected; the first movable pin 2410 is adapted to move into the movement path of the first slide 2100 under the action of elastic force to stop the first slide 2100 when the first extension member 2500 and the first body 2000 are disassembled.
[0202] Specifically, see Figure 18 As shown, when the first extension member 2500 and the first main body 2000 are connected, the first protruding rod 2510 pushes the first movable pin 2410 backward, forcing the first movable pin 2410 to press down and thus leave the movement path of the first slide handle 2100 (for example, the first movable pin 2410 is provided with a slope, and the first protruding rod 2510 has a thrust slope, forcing the first movable pin 2410 to press down), thus avoiding the movement of the first slide handle 2100. When the first extension member 2500 and the first main body 2000 are disassembled, the first movable pin 2410 returns to its original position (rises) under the action of elastic force, thus stopping the movement of the first slide handle 2100.
[0203] Combination Figure 2 and Figure 3 As shown, in some embodiments, the first body 2000 is provided with a first slide rail 2001, and the first extension member 2500 is provided with a first extension slide rail 2501. The first extension slide rail 2501 and the first slide rail 2001 are adapted to communicate when the first extension member 2500 and the first body 2000 are connected, so that the first slide handle 2100 can reciprocate between the first slide rail 2001 and the first extension slide rail 2501.
[0204] The first slide bar 2100 can be locked onto the first slide rail 2001. When the first extension component 2500 and the first main body 2000 are disassembled, the first slide bar 2100 can only reciprocate on the first slide rail 2001. When the first extension component 2500 and the first main body 2000 are connected, the first slide bar 2100 can move from the first slide rail 2001 to the first extension slide rail 2501, and can also move from the first extension slide rail 2501 to the first slide rail 2001, increasing the reciprocating stroke of the first slide bar 2100.
[0205] Combination Figures 1 to 5 As shown, in some embodiments, the first body 2000 is provided with a first guide groove 2002, and the first extension member 2500 is provided with a first extension guide groove 2502. The first guide groove 2002 and the first extension guide groove 2502 are adapted to communicate when the first extension member 2500 and the first body 2000 are connected. The object to be launched 200 is adapted to be launched along the first guide groove 2002 and the first extension guide groove 2502, so as to guide the launch of the object to be launched 200.
[0206] Combination Figures 1 to 5 as well as Figures 12 to 15 As shown, in some embodiments, the accessory includes a handle 5000, which is adapted for gripping and includes a first release mechanism 5100.
[0207] When the handle 5000 and the transmitter 4000 are connected, the first release mechanism 5100 is adapted to drive the launch position 4200, so that the launch position 4200 drives the object to be launched 200 to be launched.
[0208] Specifically, the handle 5000 includes a first release mechanism 5100, which can drive the launch position 4200. That is, the first release mechanism 5100 is movable, and its movement can drive the launch position 4200, thereby causing the launch position 4200 to launch the object to be launched 200. For example, when the handle 5000 and the first body 2000 are connected to the launcher 4000, the first slider 2100 and the first release mechanism 5100 do not interfere with each other. The object to be launched 200 can be controlled to rotate first, and then the object to be launched can be controlled to launch, or the object to be launched can be controlled to launch directly without controlling the rotation of the object to be launched 200.
[0209] For example, see Figures 1 to 5 The user holds the handle 5000 with one hand and the first slide 2100 with the other, controlling the first slide 2100 to move back and forth in the front-to-back direction (from front to back is the first direction and from back to front is the second direction, or from front to back is the second direction and from back to front is the first direction), thereby driving the acceleration position 4100, causing the object to be launched 200 to rotate. The hand holding the handle 5000 controls the first release mechanism 5100, causing the first release mechanism 5100 to drive the launch position 4200, thus launching the object to be launched 200. After launch, the launch object 200 continues to rotate upon landing. It will not tip over until it stops rotating, enhancing the fun of the game. Alternatively, multiple launch objects 200 can be launched and land in a concave area. They will move towards the bottom of the concave area, and because they continue to rotate, they can collide with each other, creating competitive situations and increasing playability. In particular, the faster the first slider 2100 reciprocates, the faster the launch object 200 rotates, thus facilitating competitive action.
[0210] Combination Figures 19 to 24 As shown, in some embodiments, the accessory includes a second body 3000, which includes a second slider 3100 and a second release mechanism 3600, the second slider 3100 being reciprocating;
[0211] When the second body 3000 and the transmitter 4000 are connected, the second slider 3100 is adapted to drive the acceleration position 4100, so that the acceleration position 4100 drives the object to be launched 200 to rotate, and the second release mechanism 3600 is adapted to drive the launch position 4200, so that the launch position 4200 drives the object to be launched 200 to launch.
[0212] Specifically, the second body 3000 includes a second slider 3100, which is reciprocating. That is, the second slider 3100 can move in either a third or fourth direction, with the third and fourth directions being opposite. During the reciprocating movement of the second slider 3100, it drives an acceleration position 4100, which in turn causes the object to be launched 200 to rotate. The second body 3000 also includes a second release mechanism 3600, which drives a launch position 4200. The second release mechanism 3600 is movably configured, and its movement drives the launch position 4200, thereby causing the launch position 4200 to launch the object to be launched. In this embodiment, the second slider 3100 and the second release mechanism 3600 do not interfere with each other. The object to be launched 200 can be controlled to rotate first, and then launched, or it can be launched directly without controlling its rotation.
[0213] For example, see Figures 19 to 23 With the user holding the handle 5000 in one hand and the second slider 3100 in the other, the user controls the second slider 3100 to move back and forth in the front-to-back direction (from front to back is the third direction and from back to front is the fourth direction, or from front to back is the fourth direction and from back to front is the third direction), thereby driving the acceleration position 4100, causing the object to be launched 200 to rotate. The hand holding the handle 5000 controls the second release mechanism 3600, which drives the launch position 4200, thus launching the object to be launched 200. After being launched, the launch object 200 continues to rotate upon landing. It will not tip over until it stops rotating, enhancing the fun of the game. Alternatively, multiple launch objects 200 can be launched and land in a concave area. The launch objects 200 will move towards the bottom of the concave area. Because they continue to rotate, they can collide with each other, creating competitive situations and increasing playability. In particular, the faster the second slider 3100 reciprocates, the faster the launch object 200 rotates, thus facilitating competitive gameplay.
[0214] When the second body 3000 and the transmitter 4000 are connected, the reciprocating movement of the second slider 3100 is converted into the rotation of the acceleration gear 4110. For example, the second body 3000 also includes a second rack 3101. The second slider 3100 and the second rack 3101 are connected to drive the second rack 3101 to reciprocate. The second rack 3101 and the acceleration gear 4110 are connected in a transmission, thereby causing the acceleration gear 4110 to rotate. In this way, the reciprocating movement of the second slider 3100 is converted into the rotation of the acceleration gear 4110. The second body 3000 can generate force on the second slider 3100 by setting an elastic element to provide elastic force for the second slider 3100 to reset.
[0215] Combination Figures 24 to 29 As shown, in some embodiments, the second slider 3100 is adapted to reciprocate along a third direction and a fourth direction, with the third direction and the fourth direction being opposite. The second body 3000 also includes a second clutch mechanism 3200 and a second stop mechanism 3300, with the second stop mechanism 3300 having a third stop state and a fourth stop state.
[0216] When the second stop mechanism 3300 is in the third stop state, the second slider 3100 is adapted to drive the second clutch mechanism 3200 when moving in the third direction, so that the second clutch mechanism 3200 drives the acceleration gear 4110 to rotate. When the second slider 3100 is adapted to drive the second clutch mechanism 3200 when moving in the fourth direction, so that the second clutch mechanism 3200 and the acceleration gear 4110 are separated.
[0217] When the second stop mechanism 3300 is in the fourth stop state, the second slider 3100 is adapted to drive the second clutch mechanism 3200 when moving in the third direction, so that the second clutch mechanism 3200 and the acceleration gear 4110 are separated. When the second slider 3100 is adapted to drive the second clutch mechanism 3200 when moving in the fourth direction, so that the second clutch mechanism 3200 drives the acceleration gear 4110 to rotate in the opposite direction.
[0218] By setting a second clutch mechanism 3200, during the reciprocating movement of the second slider 3100, only one direction of the reciprocating movement can drive the acceleration gear 4110 to rotate, while the other direction of the reciprocating movement cannot drive the acceleration gear 4110 to rotate. Thus, through multiple reciprocating movements of the second slider 3100, the acceleration gear 4110 can achieve continuous rotational acceleration. Furthermore, by setting a second stop mechanism 3300, switching between different stop states can cause the acceleration gear 4110 to rotate in different directions, thereby changing the rotation direction of the object to be launched 200.
[0219] For example, see Figure 28When the second stop mechanism 3300 is in the third stop state: during the first reciprocating movement of the second slider 3100, when the second slider 3100 moves along the third direction, the second clutch mechanism 3200 acts on the acceleration gear 4110, thereby driving the acceleration gear 4110 to rotate (clockwise). When the second slider 3100 moves along the fourth direction, the second clutch mechanism 3200 disengages from the acceleration gear 4110. During the second reciprocating movement of the second slider 3100, when the second slider 3100 moves along the third direction, the second clutch mechanism 3200 acts on the acceleration gear 4110, thereby driving the acceleration gear 4110 to rotate (clockwise). When the second slider 3100 moves along the fourth direction, the second clutch mechanism 3200 disengages from the acceleration gear 4110, and so on.
[0220] See Figure 29 When the second stop mechanism 3300 is in the fourth stop state: during the first reciprocating movement of the second slider 3100, when the second slider 3100 moves in the third direction, the second clutch mechanism 3200 disengages from the acceleration gear 4110, and when the second slider 3100 moves in the fourth direction, the second clutch mechanism 3200 acts on the acceleration gear 4110, thereby causing the acceleration gear 4110 to rotate in the opposite direction (counterclockwise); during the second reciprocating movement of the second slider 3100, when the second slider 3100 moves in the third direction, the second clutch mechanism 3200 disengages from the acceleration gear 4110, and when the second slider 3100 moves in the fourth direction, the second clutch mechanism 3200 acts on the acceleration gear 4110, thereby causing the acceleration gear 4110 to rotate in the opposite direction (counterclockwise), and so on.
[0221] Combination Figures 24 to 29 As shown, in some embodiments, the second clutch mechanism 3200 includes a second movable member 3220, a second drive gear 3210, a third clutch gear 3230, and a fourth clutch gear 3240. The second movable member 3220 is rotatably disposed, the second drive gear 3210 is rotatably disposed and coaxial with the second movable member 3220, the third clutch gear 3230 is rotatably disposed on the second movable member 3220 and meshes with the second drive gear 3210, and the fourth clutch gear 3240 is rotatably disposed on the second movable member 3220 and meshes with the second drive gear 3210.
[0222] When the second stop mechanism 3300 is in the third stop state:
[0223] When the second slider 3100 moves along a third direction, it drives the second drive gear 3210 to rotate, causing the second movable member 3220 to swing, and causing the third clutch gear 3230 and the acceleration gear 4110 to mesh and drive, and the fourth clutch gear 3240 and the acceleration gear 4110 to disengage; when the second slider 3100 moves along a fourth direction, it drives the second drive gear 3210 to rotate in the opposite direction, causing the second movable member 3220 to swing in the opposite direction and be stopped by the second stop mechanism 3300, causing the third clutch gear 3230 and the acceleration gear 4110 to disengage, and the fourth clutch gear 3240 and the acceleration gear 4110 to disengage;
[0224] When the second stop mechanism 3300 is in the fourth stop state;
[0225] When the second slider 3100 moves along a third direction, it drives the second drive gear 3210 to rotate, causing the second movable member 3220 to swing and be stopped by the second stop mechanism 3300, thereby disengaging the third clutch gear 3230 and the acceleration gear 4110, and disengaging the fourth clutch gear 3240 and the acceleration gear 4110; when the second slider 3100 moves along a fourth direction, it drives the second drive gear 3210 to rotate in the opposite direction, causing the second movable member 3220 to swing in the opposite direction, and disengaging the third clutch gear 3230 and the acceleration gear 4110, and engaging the fourth clutch gear 3240 and the acceleration gear 4110.
[0226] Specifically, the second movable member 3220 is rotatable and can swing within a certain range, which is limited by the second stop mechanism 3300. The second drive gear 3210 is rotatable and coaxial with the second movable member 3220. The second drive gear 3210 may or may not be located on the second movable member 3220. The coaxiality of the second drive gear 3210 and the second movable member 3220 means that the rotation axis of the second drive gear 3210 is coaxial with the rotation axis of the second movable member 3220. The third clutch gear 3230 is mounted on the second movable member 3220 and can rotate relative to the second movable member 3220. The fourth clutch gear 3240 is mounted on the second movable member 3220 and can rotate relative to the second movable member 3220. Since the second movable member 3220 is rotatably mounted and the second drive gear 3210 is coaxial with the second movable member 3220, the second drive gear 3210 and the third clutch gear 3230 can always be engaged, and the second drive gear 3210 and the fourth clutch gear 3240 can always be engaged, regardless of how the second movable member 3220 swings. This allows the second movable member 3220 to swing in different directions when the second drive gear 3210 rotates in different directions, and the third clutch gear 3230 and the fourth clutch gear 3240 to swing in the same direction. The reciprocating movement of the second slider 3100 can drive the second drive gear 3210 to rotate in different directions. The second slider 3100 can drive the second drive gear 3210 to rotate through the second rack 3101 (the second rack 3101 and the second drive gear 3210 are connected by transmission). Since the second slider 3100 can reciprocate, the rotation direction of the second drive gear 3210 when the second slider 3100 moves in a third direction is different from the rotation direction of the second drive gear 3210 when the second slider 3100 moves in a fourth direction.
[0227] See Figure 28 The orientation of the second stop mechanism 3300 when it is in the third stop state:
[0228] When the second slider 3100 moves along a third direction, it drives the second drive gear 3210 to rotate clockwise. The second drive gear 3210 drives the third clutch gear 3230 and the fourth clutch gear 3240 to rotate counterclockwise. The second drive gear 3210 also drives the second movable part 3220 to swing clockwise. The third clutch gear 3230 and the fourth clutch gear 3240 swing along with it, so that the third clutch gear 3230 and the acceleration gear 4110 mesh and transmit power (which also limits the second movable part 3220 from continuing to swing clockwise). The fourth clutch gear 3240 and the acceleration gear 4110 disengage. Finally, the third clutch gear 3230 drives the acceleration gear 4110 to rotate clockwise, so as to drive the object to be launched 200 to rotate (counterclockwise). It is understandable that if the second slider 3100 moves to its limit and stops along the third direction, the second drive gear 3210 does not move. Since the second movable part 3220 is rotatable and the object to be launched 200 is still rotating, the second movable part 3220 is forced to swing counterclockwise, causing the third clutch gear 3230 and the acceleration gear 4110 to separate.
[0229] When the second slider 3100 moves along the third direction and then switches to moving along the fourth direction, it drives the second drive gear 3210 to rotate counterclockwise. The second drive gear 3210 drives the third clutch gear 3230 and the fourth clutch gear 3240 to rotate clockwise. At the same time, the second drive gear 3210 drives the second movable part 3220 to swing counterclockwise until the second movable part 3220 is stopped by the second stop mechanism 3300. The third clutch gear 3230 and the fourth clutch gear 3240 swing along with it, causing the third clutch gear 3230 to separate from the acceleration gear 4110 and the fourth clutch gear 3240 to separate from the acceleration gear 4110.
[0230] See Figure 29 The orientation, when the second stop mechanism 3300 is in the fourth stop state:
[0231] When the second slider 3100 moves along a third direction, it drives the second drive gear 3210 to rotate clockwise. The second drive gear 3210 drives the third clutch gear 3230 and the fourth clutch gear 3240 to rotate counterclockwise. At the same time, the second drive gear 3210 drives the second movable member 3220 to swing clockwise until the second movable member 3220 is stopped by the second stop mechanism 3300. The third clutch gear 3230 and the fourth clutch gear 3240 swing along with it, so that the third clutch gear 3230 and the acceleration gear 4110 are separated, and the fourth clutch gear 3240 and the acceleration gear 4110 are separated.
[0232] When the second slider 3100 moves along a third direction and then switches to moving along a fourth direction, it drives the second drive gear 3210 to rotate counterclockwise. The second drive gear 3210 drives the third clutch gear 3230 and the fourth clutch gear 3240 to rotate clockwise. The second drive gear 3210 also drives the second movable part 3220 to swing counterclockwise. The third clutch gear 3230 and the fourth clutch gear 3240 swing along with it, so that the fourth clutch gear 3240 and the acceleration gear 4110 mesh and transmit power (which also limits the second movable part 3220 from continuing to swing counterclockwise). The third clutch gear 3230 and the acceleration gear 4110 disengage. Finally, the fourth clutch gear 3240 drives the acceleration gear 4110 to rotate counterclockwise, so as to drive the object to be launched 200 to rotate (clockwise). It is understandable that if the second slider 3100 moves to the limit of stillness along the fourth direction, the second drive gear 3210 does not move. Since the second movable member 3220 is rotatably set and the object to be launched 200 is still rotating, the second movable member 3220 is forced to swing clockwise, causing the fourth clutch gear 3240 and the acceleration gear 4110 to separate.
[0233] Combination Figures 25 to 29 As shown, in some embodiments, the second stop mechanism 3300 includes a first stop groove 3310 and a second stop groove 3320;
[0234] When the second stop mechanism 3300 is in the third stop state, the second movable member 3220 is inserted into the first stop groove 3310 to be stopped by the first stop groove 3310 during swinging; when the second stop mechanism 3300 is in the fourth stop state, the second movable member 3220 is inserted into the second stop groove 3320 to be stopped by the second stop groove 3320 during swinging.
[0235] Specifically, the swing amplitude of the second movable member 3220 when the second stop mechanism 3300 is in the third stop state is limited by the width of the first stop groove 3310. The swing amplitude of the second movable member 3220 when the second stop mechanism 3300 is in the fourth stop state is limited by the width of the second stop groove 3320. Since the second stop mechanism 3300 forms different stops on the second movable member 3220 when it is in the third stop state and the fourth stop state, the positions of the first stop groove 3310 and the second stop groove 3320 are different, for example, attached... Figure 27 The first stop groove 3310 and the second stop groove 3320 are arranged in a Z-shape to be staggered.
[0236] Furthermore, combined Figure 27 As shown, in some embodiments, the first stop groove 3310 and the second stop groove 3320 are connected, and the second stop mechanism 3300 is adapted to reciprocate so that the second movable member 3220 can move from the first stop groove 3310 into the second stop groove 3320, and from the second stop groove 3320 into the first stop groove 3310.
[0237] Specifically, the second movable part 3220 is inserted into the second stop mechanism 3300. The user can control the second stop mechanism 3300 to move back and forth. For example, the user can directly operate the second stop mechanism 3300. When the second stop mechanism 3300 moves in one direction of its reciprocating movement, the second movable part 3220 can be moved into the first stop groove 3310. When the second stop mechanism 3300 moves in the other direction of its reciprocating movement, the second movable part 3220 can be moved into the second stop groove 3320, which is convenient and quick.
[0238] Combination Figures 30 to 35 As shown, in some embodiments, the second body 3000 further includes a second limiting mechanism 3400;
[0239] The second slider 3100 includes a first gear mechanism 3110 and a second gear mechanism 3120. The first gear mechanism 3110 and the second gear mechanism 3120 are arranged alternately along the reciprocating movement direction of the second slider 3100. The first gear mechanism 3110 and the second gear mechanism 3120 are adapted to follow the movement of the second slider 3100 and one of them can abut against the second limiting mechanism 3400.
[0240] See Figures 31 to 35 As the second slider 3100 reciprocates in the front-to-back direction, the first gear mechanism 3110 and the second gear mechanism 3120 are arranged alternately in the front-to-back direction. The first gear mechanism 3110 and the second gear mechanism 3120 move with the second slider 3100 as it reciprocates. The first gear mechanism 3110 and the second gear mechanism 3120 can either abut against the second limiting mechanism 3400. That is, when the second slider 3100 moves, it can abut against the second limiting mechanism 3400 through the first gear mechanism 3110 or through the second gear mechanism 3120.
[0241] For example, the second slider 3100 can move from back to front by abutting against the second limiting mechanism 3400 via the first stop mechanism 3110, thus preventing the second slider 3100 from continuing to move from back to front. As another example, the second slider 3100 can move from back to front by abutting against the second limiting mechanism 3400 via the second stop mechanism 3120, thus preventing the second slider 3100 from continuing to move from back to front. Since the first stop mechanism 3110 and the second stop mechanism 3120 are arranged alternately in the front-back direction, the stroke of the second slider 3100 can be changed, allowing the launching device 100 to adapt to different play scenarios.
[0242] The selection of the first gear mechanism 3110 and the second gear mechanism 3120 is achieved by cooperating with the second rack 3101, in combination with... Figures 31 to 35As shown, in some embodiments, the second body 3000 further includes a second rack 3101, the second slider 3100 and the second rack 3101 are movably connected and can drive the second rack 3101 to reciprocate, the second rack 3101 and the acceleration position 4100 are connected in a transmission manner; the second rack 3101 is adapted to selectively drive one of the first gear mechanism 3110 and the second gear mechanism 3120 to switch to the position abutting against the second limiting mechanism 3400 when it moves relative to the second slider 3100.
[0243] For example, the second rack 3101 can move relative to the second slider 3100 along the reciprocating direction of the second slider 3100, see [reference]. Figure 35 The first gear mechanism 3110 is located in front of the second gear mechanism 3120. Under the action of elasticity, the first gear mechanism 3110 tends to switch to a position to avoid the second limiting mechanism 3400, and the second gear mechanism 3120 also tends to switch to a position to avoid the second limiting mechanism 3400 under the action of elasticity. When the second rack 3101 moves forward relative to the second slider 3100, it causes the first gear mechanism 3110 to switch to a position abutting against the second limiting mechanism 3400. When the second slider 3100 moves forward, it abuts against the second limiting mechanism 3400 through the first gear mechanism 3110, thereby preventing the second slider 3100 from continuing to move forward. When the second rack 3101 moves backward relative to the second slider 3100, it drives the second gear mechanism 3120 to switch to the position that abuts against the second limit mechanism 3400. When the second slider 3100 moves forward, the first gear mechanism 3110 avoids the second limit mechanism 3400, and the second gear mechanism 3120 abuts against the second limit mechanism 3400, thereby preventing the second slider 3100 from continuing to move forward.
[0244] Combination Figures 31 to 35 As shown, in some embodiments, the second slider 3100 further includes a groove 3130 and a locking member 3140. The second rack 3101 is movably connected to the groove 3130, and the locking member 3140 is adapted to lock the second rack 3101 relative to the second slider 3100 and to unlock the second rack 3101 relative to the second slider 3100.
[0245] The second rack 3101 is adapted to move from one end of the slide groove 3130 to the other end when the locking member 3140 is unlocked, so as to drive one of the first gear mechanism 3110 and the second gear mechanism 3120 to switch to the position abutting against the second limit mechanism 3400. It is also adapted to move from the other end of the slide groove 3130 to one end when the locking member 3140 is unlocked, so as to drive the other of the first gear mechanism 3110 and the second gear mechanism 3120 to switch to the position abutting against the second limit mechanism 3400.
[0246] Specifically, when the locking member 3140 locks the second rack 3101, the second rack 3101 cannot move relative to the second slider 3100, and the first gear mechanism 3110 and the second gear mechanism 3120 cannot be switched. When the locking member 3140 unlocks the second rack 3101, the second rack 3101 can move relative to the second slider 3100, specifically, it can reciprocate within the groove 3130 of the second slider 3100, and the first gear mechanism 3110 and the second gear mechanism 3120 can be switched. The locking member 3140 can unlock the movement of the second rack 3101 by pressing.
[0247] When the locking member 3140 is unlocked, the second rack 3101 can move from the rear end of the slide groove 3130 to the front end of the slide groove 3130. The locking member 3140 then locks to prevent the second rack 3101 from moving from the front end of the slide groove 3130 to the rear end of the slide groove 3130. At this time, the first gear mechanism 3110 switches to the position that abuts against the second limit mechanism 3400. When the second slider 3100 moves forward, it abuts against the second limit mechanism 3400 through the first gear mechanism 3110, thereby preventing the second slider 3100 from continuing to move forward.
[0248] When the locking member 3140 is unlocked, the second rack 3101 can move from the front end of the slide groove 3130 to the rear end of the slide groove 3130. The locking member 3140 then locks to prevent the second rack 3101 from moving from the rear end of the slide groove 3130 to the front end of the slide groove 3130. At this time, the second gear mechanism 3120 switches to the position that abuts against the second limit mechanism 3400. When the second slider 3100 moves forward, it abuts against the second limit mechanism 3400 through the second gear mechanism 3120, thereby preventing the second slider 3100 from continuing to move forward.
[0249] Combination Figures 19 to 23 as well as Figure 30 As shown, in some embodiments, the launching device 100 further includes a second extension member 3500, which is adapted to be detachably connected to the second body 3000, and the second slider 3100 is adapted to reciprocate to the second extension member 3500 when the second extension member 3500 and the second body 3000 are connected.
[0250] Specifically, the second extension member 3500 is adapted to be detachably connected to the second main body 3000, meaning that the second extension member 3500 and the second main body 3000 can be both connected and fixed, and can also be detached. When the second extension member 3500 and the second main body 3000 are detached, the second slider 3100 reciprocates on the second main body 3000, meaning that the reciprocating stroke of the second slider 3100 is determined by the second main body 3000 itself. When the second extension member 3500 is connected to the second main body 3000, the second slider 3100 can reciprocate to the second extension member 3500, meaning that the reciprocating stroke of the second slider 3100 is jointly determined by the second main body 3000 and the second extension member 3500. In this case, the reciprocating stroke of the second slider 3100 can be increased, which is more conducive to the rotational acceleration of the object to be launched 200.
[0251] When the second extension member 3500 and the second main body 3000 are connected, the second slider 3100 can reciprocate to the second extension member 3500. Therefore, when the second extension member 3500 and the second main body 3000 are disassembled, it is undesirable for the second slider 3100 to reciprocate to the position of the second extension member 3500; otherwise, the second slider 3100 will detach from the second main body 3000. Figure 21 and Figure 30 As shown, in some embodiments, the second body 3000 further includes a second limiting mechanism 3400, which is adapted to avoid the second slider 3100 when the second extension member 3500 and the second body 3000 are connected, so that the second slider 3100 can reciprocate to the second extension member 3500. It is also adapted to stop the second slider 3100 when the second extension member 3500 and the second body 3000 are disassembled, so as to prevent the second slider 3100 from coming out.
[0252] Specifically, the second limiting mechanism 3400 is a movable component that can both restrict the movement of the second slider 3100 and release the restriction on the movement of the second slider 3100.
[0253] When the second extension member 3500 is connected to the second main body 3000, the second limiting mechanism 3400 undergoes a corresponding change. At this time, the second limiting mechanism 3400 avoids the second slider 3100, thereby releasing the restriction on the second slider 3100. The second slider 3100 can move from the second main body 3000 to the second extension member 3500, or vice versa. For example, in this case, the second limiting mechanism 3400 leaves the movement path of the second slider 3100, so that the second slider 3100 is not stopped by the second limiting mechanism 3400 when it moves.
[0254] When the second extension member 3500 and the second main body 3000 are disassembled, the second limiting mechanism 3400 undergoes a corresponding change. At this time, the second limiting mechanism 3400 stops the second slider 3100, thereby restricting the second slider 3100. The second slider 3100 can only reciprocate within the second main body 3000. When the second slider 3100 moves in the direction of movement toward the second extension member 3500, it will be stopped by the second limiting mechanism 3400 and cannot detach from the second main body 3000. For example, in this case, the second limiting mechanism 3400 is located in the movement path of the second slider 3100, so the second slider 3100 will be stopped by the second limiting mechanism 3400 when it moves.
[0255] Combination Figure 39 As shown, in some embodiments, the second extension member 3500 includes a second protrusion 3510, and the second limiting mechanism 3400 includes a second movable pin 3410.
[0256] The second protruding rod 3510 is adapted to drive the second movable pin 3410 away from the movement path of the second slider 3100 to avoid the second slider 3100 when the second extension member 3500 and the second body 3000 are connected; the second movable pin 3410 is adapted to move into the movement path of the second slider 3100 under the action of elastic force to stop the second slider 3100 when the second extension member 3500 and the second body 3000 are disassembled.
[0257] Specifically, see Figure 39 As shown, when the second extension member 3500 and the second main body 3000 are connected, the second protruding rod 3510 pushes the second movable pin 3410 backward, forcing the second movable pin 3410 to press down and thus leave the movement path of the second slider 3100 (for example, the second movable pin 3410 is provided with an inclined surface, and the second protruding rod 3510 has a thrust inclined surface, forcing the second movable pin 3410 to press down), thus avoiding the movement of the second slider 3100. When the second extension member 3500 and the second main body 3000 are disassembled, the second movable pin 3410 returns to its original position (rises) under the action of elastic force, thus stopping the movement of the second slider 3100.
[0258] Combination Figure 21 and Figure 22 As shown, in some embodiments, the second body 3000 is provided with a second slide rail 3001, and the second extension member 3500 is provided with a second extension slide rail 3501. The second extension slide rail 3501 and the second slide rail 3001 are adapted to communicate when the second extension member 3500 and the second body 3000 are connected, so that the second slider 3100 can reciprocate between the second slide rail 3001 and the second extension slide rail 3501.
[0259] The second slider 3100 can be engaged with the second slide rail 3001. When the second extension member 3500 and the second main body 3000 are disassembled, the second slider 3100 can only reciprocate on the second slide rail 3001. When the second extension member 3500 and the second main body 3000 are connected, the second slider 3100 can move from the second slide rail 3001 to the second extension slide rail 3501, and can move from the second extension slide rail 3501 to the second slide rail 3001, increasing the reciprocating stroke of the second slider 3100.
[0260] Combination Figures 40 to 42 as well as Figures 45 to 47 As shown, in some embodiments, the accessory includes a pull member 1000, which is adapted to be inserted into and removed from the transmitter 4000. The pull member 1000 includes an acceleration end 1200 and a launch end 1100.
[0261] When the pull member 1000 and the transmitter 4000 are connected, the acceleration end 1200 is adapted to drive the acceleration position 4100 during the process of the pull member 1000 being inserted into and / or pulled out of the transmitter 4000, so that the acceleration position 4100 drives the object to be launched 200 to rotate. The launching end 1100 is adapted to drive the launching position 4200 when the pull member 1000 is inserted into and / or pulled out of the transmitter 4000, so that the launching position 4200 drives the object to be launched 200 to launch.
[0262] Specifically, the pull member 1000 can be inserted into or removed from the transmitter 4000. The rotation of the object to be launched 200 can be achieved through the insertion process of the pull member 1000, that is, during the insertion of the pull member 1000 into the transmitter 4000, the acceleration end 1200 drives the acceleration position 4100, thereby causing the acceleration position 4100 to rotate the object to be launched 200. The rotation of the object to be launched 200 can also be achieved through the removal process of the pull member 1000, that is, during the removal of the pull member 1000 from the transmitter 4000, the acceleration end 1200 drives the acceleration position 4100, thereby causing the acceleration position 4100 to rotate the object to be launched 200. The launch of the object to be launched 200 can be achieved through the insertion process of the pull member 1000. That is, during the process of the pull member 1000 being inserted into the launcher 4000, the launch end 1100 drives the launch position 4200, thereby causing the launch position 4200 to rotate. The launch of the object to be launched 200 can also be achieved through the removal process of the pull member 1000. That is, during the process of the pull member 1000 being removed from the launcher 4000, the launch end 1100 drives the launch position 4200, thereby causing the launch position 4200 to rotate.
[0263] Optionally, the pulling member 1000 is adapted to first drive the acceleration position 4100 when pulled out, so that the acceleration position 4100 drives the object to be launched 200 to rotate, and then drive the launching position 4200, so that the launching position 4200 drives the object to be launched 200 to launch.
[0264] When the pulling member 1000 is pulled away from the transmitter 4000 (i.e., the pulling member 1000 is pulled away from the transmitter 4000 from the state of being inserted into the transmitter 4000), the pulling member 1000 first drives the acceleration position 4100 through the acceleration end 1200, and then drives the launch position 4200 through the launch end 1100. The acceleration end 1200 drives the acceleration position 4100, thereby causing the acceleration position 4100 to drive the object to be launched 200 to rotate. The launch end 1100 drives the launch position 4200, thereby causing the launch position 4200 to drive the object to be launched 200 to launch. Because the pull member 1000 first drives the acceleration position 4100 and then the launch position 4200 when it is pulled out, the object to be launched 200 will rotate on the launcher 4000 under the action of the acceleration end 1200 until the pull member 1000 is pulled out to the preset position. Then, the launch end 1100 drives the launch position 4200, so that the launch position 4200 carries the object to be launched 200 out. The object to be launched 200 continues to rotate when it is launched, which helps to improve playability and fun. Similarly, the pull member 1000 can also be adapted to drive the acceleration position 4100 first and then the launch position 4200 when it is inserted, which will not be explained again.
[0265] After being launched, the launch object 200 continues to rotate upon landing. It will not tip over until it stops rotating, enhancing the fun of playing. For example, when multiple (two or more) launch objects 200 land in a concave area, they will move towards the bottom of the area. Because they continue to rotate, collisions can occur between them, creating competitive situations and increasing playability. In particular, the faster the pulling component 1000 is pulled out, the faster the launch object 200 accelerates, and the faster it rotates, the better for competitive play.
[0266] Combination Figures 40 to 44 As shown, in some embodiments, the object to be launched 200 is adapted to be launched forward; the launcher 4000 is provided with a guide hole 4400, and the pull member 1000 is adapted to be inserted into and pulled out of the guide hole 4400, with at least two guide holes 4400 arranged alternately in the left-right direction. When the user holds the handle 5000, if the grip point remains unchanged, different operating experiences can be produced by the pull member 1000 passing through different guide holes 4400, and the user can choose according to the actual situation.
[0267] Combination Figure 47As shown, in some embodiments, the acceleration end 1200 is adapted to drive the acceleration gear 4110 to rotate.
[0268] When the pull member 1000 and the transmitter 4000 are connected, the pull member 1000 drives the acceleration gear 4110 to rotate through the acceleration end 1200. In this way, the linear movement of the pull member 1000 is converted into the rotation of the acceleration gear 4110. The acceleration end 1200 can directly drive the acceleration gear 4110 to rotate, or it can indirectly drive the acceleration gear 4110 to rotate.
[0269] For example, the acceleration position 4100 also includes a first transmission gear 4120. The acceleration end 1200 is adapted to mesh with the first transmission gear 4120 to drive the first transmission gear 4120 to rotate. The first transmission gear 4120 meshes with the acceleration gear 4110 to drive the acceleration gear 4110 to rotate. The acceleration end 1200 is adapted to mesh with the first transmission gear 4120, that is, the acceleration end 1200 has a gear tooth structure. The movement of the pulling member 1000 is a linear motion. Through the cooperation between the acceleration end 1200 and the first transmission gear 4120, it can be converted into the rotation of the first transmission gear 4120. With this arrangement, the pulling member 1000 can be moved more quickly, which makes the rotation speed of the first transmission gear 4120 faster, and thus makes the rotation speed of the object to be launched 200 faster. The first transmission gear 4120 meshes with the acceleration gear 4110, so the acceleration end 1200 drives the first transmission gear 4120 to rotate, the first transmission gear 4120 drives the acceleration gear 4110 to rotate, and the acceleration gear 4110 drives the object to be launched 200 to rotate.
[0270] Combination Figures 45 to 46 As shown, in some embodiments, the launch position 4200 includes a push plate 4210, a locking member 4220, and a first elastic member 4291. When the object to be launched 200 is installed on the launcher 4000, the object to be launched 200 is adapted to abut against the push plate 4210 and drive the push plate 4210 to move. The locking member 4220 is adapted to lock the push plate 4210 when the push plate 4210 moves to a preset position, and is adapted to be driven by an accessory to unlock the push plate 4210. The first elastic member 4291 is adapted to generate force on the push plate 4210 so as to drive the push plate 4210 to reset when the locking member 4220 unlocks the push plate 4210, so that the push plate 4210 drives the object to be launched 200 to launch.
[0271] Specifically, the object to be launched 200 is mounted movably on the transmitter 4000, see [reference]. Figure 40The launch object 200 is moved backward and installed on the launcher 4000. When the launch object 200 is installed on the launcher 4000, the launch object 200 and the push plate 4210 abut together. The launch object 200 drives the push plate 4210 to move backward. During the backward movement of the push plate 4210, the first elastic element 4291 is elastically deformed and accumulates elastic potential energy. The first elastic element 4291 generates a forward force on the push plate 4210. When the push plate 4210 moves to a preset position (i.e., the position where it can be locked by the locking element 4220), it will be locked by the locking element 4220. Due to the locking by the locking element 4220, the push plate 4210 will not reset (resetting here means that the push plate 4210 moves to the position where the launch object 200 is installed in front of the launcher 4000, i.e., the push plate 4210 moves forward) and will drive the launch object 200 to be launched. It is understandable that the force exerted by the first elastic element 4291 on the target can be direct or indirect. That is, the force exerted by the first elastic element 4291 on the push plate 4210 can be applied directly to the push plate 4210 or indirectly. The same applies to the forces exerted by other elastic elements in this article, and will not be repeated here. The launching position 4200 can also be provided with a second elastic element 4292. The second elastic element 4292 acts on the locking element 4220 to drive the locking element 4220 to reset after the launch object 200 is launched, so as to facilitate locking the push plate 4210 when the launch object 200 is installed again.
[0272] The locking member 4220 can be driven by the first release mechanism 5100, the second release mechanism 3600 and the launching end 1100 of the pulling member 1000, thereby unlocking the push plate 4210.
[0273] Specifically, when the handle 5000 is included, the first release mechanism 5100 of the handle 5000 is adapted to actuate the locking member 4220 to unlock the push plate 4210.
[0274] When the second body 3000 is included, the second release mechanism 3600 of the second body 3000 is adapted to drive the locking member 4220 to unlock the push plate 4210.
[0275] When the pull member 1000 is included, the launching end 1100 of the pull member 1000 is adapted to drive the locking member 4220 to unlock the push plate 4210.
[0276] Combination Figures 12 to 15As shown, when the first main body 2000 and the transmitter 4000 are connected, the launch of the object to be launched 200 is achieved by the first release mechanism 5100 driving the locking member 4220 to unlock the push plate 4210. The user can operate the first release mechanism 5100, which drives the locking member 4220, thereby unlocking the push plate 4210. When the push plate 4210 is unlocked, the elastic potential energy of the first elastic member 4291 is released, and the first elastic member 4291 can drive the push plate 4210 to reset (move forward). When the push plate 4210 is reset, it supports the object to be launched 200, thereby generating force on the object to be launched 200 and launching it.
[0277] Combination Figures 36 to 38 As shown, when the second body 3000 and the transmitter 4000 are connected, the launch of the object to be launched 200 is achieved by the second release mechanism 3600 driving the locking member 4220 to unlock the push plate 4210. The user can operate the second release mechanism 3600, which drives the locking member 4220, thereby unlocking the push plate 4210. When the push plate 4210 is unlocked, the elastic potential energy of the second elastic member 4292 is released, and the second elastic member 4292 can drive the push plate 4210 to reset (move forward). When the push plate 4210 is reset, it supports the object to be launched 200, thereby generating force on the object to be launched 200 and launching it.
[0278] Combination Figures 45 to 47 As shown, when the pull member 1000 and the launcher 4000 are connected, the launch of the object to be launched 200 needs to be achieved by the launch end 1100 of the pull member 1000 driving the locking member 4220 to unlock the push plate 4210. When the pull member 1000 moves, the launch end 1100 drives the locking member 4220, thereby unlocking the push plate 4210. When the push plate 4210 is unlocked, the elastic potential energy of the first elastic member 4291 is released, and the first elastic member 4291 can drive the push plate 4210 to reset (move forward). When the push plate 4210 is reset, it supports the object to be launched 200, thereby generating force on the object to be launched 200, so that the object to be launched 200 is launched.
[0279] Combination Figures 12 to 15 As shown, in some embodiments, the launch position 4200 further includes a rotating member 4230, which is provided with a lug 4234 and a second contact portion 4232. The first release mechanism 5100 includes a reciprocating pusher 5110, which is adapted to push the lug 4234 to rotate the rotating member 4230 and cause the second contact portion 4232 to drive the locking member 4220 to unlock the push plate 4210.
[0280] Specifically, the rotating member 4230 is designed to be rotatable, and the lug 4234 and the second contact portion 4232 are designed to rotate about the rotation axis of the rotating member 4230. For example, the rotating member 4230 includes a central shaft portion 4233 and a lug 4234 and a second contact portion 4232 disposed on the central shaft portion 4233. The rotation axis of the rotating member 4230 is formed by the central shaft portion 4233. The first release mechanism 5100 includes a reciprocating pusher 5110, see [link to relevant documentation]. Figure 15 When the pusher 5110 moves forward, it pushes the lug 4234, forcing the rotating member 4230 to rotate counterclockwise. The counterclockwise rotation of the rotating member 4230 causes the second contact part 4232 to push the locking member 4220. The locking member 4220 presses down to unlock the push plate 4210. By setting the rotating member 4230, it is convenient to arrange and cooperate between various structures.
[0281] Combination Figures 36 to 38 As shown, in some embodiments, the second release mechanism 3600 includes a reciprocating trigger 3610 adapted to actuate the locking member 4220 to unlock the push plate 4210. See also Figure 38 The trigger 3610 moves back and forth in the direction of the back and forth. When the trigger 3610 moves backward, it drives the locking member 4220 to unlock the push plate 4210. The trigger 3610 and the locking member 4220 can be in direct contact, or additional components can be set for transmission.
[0282] Combination Figure 14 , Figure 45 and Figure 46 As shown, in some embodiments, the transmitting position 4200 further includes a rotating member 4230. The transmitting end 1100 is adapted to drive the rotating member 4230 to rotate when the pulling member 1000 moves in one of the directions of insertion and removal, so that the rotating member 4230 drives the locking member 4220 to unlock the push plate 4210. The transmitting end 1100 is adapted to drive the rotating member 4230 to rotate in the opposite direction when the pulling member 1000 moves in the other direction of insertion and removal (reverse rotation means that the rotation direction of the rotating member 4230 when the pulling member 1000 is inserted is opposite to the rotation direction of the rotating member 4230 when the pulling member 1000 is removed), so that the rotating member 4230 and the locking member 4220 are separated.
[0283] The following description uses the example of the transmitter 1100 driving the rotating member 4230 to rotate when the pull member 1000 is pulled out, so that the rotating member 4230 drives the locking member 4220 to unlock the push plate 4210, and driving the rotating member 4230 to rotate in the opposite direction when the pull member 1000 is inserted, so that the rotating member 4230 and the locking member 4220 are separated.
[0284] For example, the object to be launched 200 is first installed on the transmitter 4000. At this time, the push plate 4210 is locked by the locking member 4220. Then, the pull member 1000 is inserted into the transmitter 4000. When the pull member 1000 is inserted, it drives the rotating member 4230 to rotate through the transmitter end 1100, and causes the rotating member 4230 and the locking member 4220 to separate. The rotating member 4230 will not act on the locking member 4220 and will cause the locking member 4220 to unlock the push plate 4210. When the pull member 1000 is pulled out, the pull member 1000 drives the rotating member 4230 to rotate through the transmitter end 1100 (in the opposite direction of rotation), so that the rotating member 4230 can act on the locking member 4220 and cause the locking member 4220 to unlock the push plate 4210. The pull member 1000 can drive the rotating member 4230 to rotate when it is inserted and when it is pulled out. The rotation direction of the rotating member 4230 when the pull member 1000 is inserted is opposite to the rotation direction when the pull member 1000 is pulled out. In this way, the locking member 4220 can be locked to the push plate 4210 when the pull member 1000 is inserted, and the locking member 4220 can be driven to unlock the push plate 4210 when it is pulled out.
[0285] Optionally, the pulling member 1000 and the rotating member 4230 are coupled through the following scheme. Figures 45 to 48 As shown, in some embodiments, the rotating member 4230 is provided with a first contact portion 4231 and a second contact portion 4232, and the transmitting end 1100 forms a groove 1100.
[0286] The first contact portion 4231 is adapted to sequentially engage and disengage from the groove 1100 when the pulling member 1000 moves in one of the directions of insertion and disengagement, so as to rotate the rotating member 4230 and cause the second contact portion 4232 to drive the locking member 4220 to unlock the push plate 4210; the first contact portion 4231 is adapted to sequentially engage and disengage from the groove 1100 when the pulling member 1000 moves in the other direction of insertion and disengagement, so as to rotate the rotating member 4230 in the opposite direction and cause the second contact portion 4232 and the locking member 4220 to separate.
[0287] The following description uses the example of the transmitter 1100 driving the rotating member 4230 to rotate when the pull member 1000 is pulled out, so that the rotating member 4230 drives the locking member 4220 to unlock the push plate 4210, and driving the rotating member 4230 to rotate in the opposite direction when the pull member 1000 is inserted, so that the rotating member 4230 and the locking member 4220 are separated.
[0288] The first contact portion 4231 and the second contact portion 4232 can rotate around the rotation axis of the rotating member 4230. For example, the rotating member 4230 includes a central shaft portion 4233 and a first contact portion 4231 and a second contact portion 4232 disposed on the central shaft portion 4233. The rotation axis of the rotating member 4230 is formed by the central shaft portion 4233, and the first contact portion 4231 and the second contact portion 4232 present a certain angle in space.
[0289] See Figure 49 and Figure 50 As shown, when the pull member 1000 is inserted, the first contact part 4231 is engaged in the groove 1100. As the pull member 1000 continues to be inserted, the first contact part 4231 is disengaged from the groove 1100. During the process of the first contact part 4231 disengaging from the groove 1100, the rotating member 4230 rotates (clockwise). The rotation of the rotating member 4230 causes the second contact part 4232 to rotate as well, so that the second contact part 4232 is separated from the locking member 4220. Since the second contact part 4232 is separated from the locking member 4220, the second contact part 4232 will not drive the locking member 4220 to unlock the push plate 4210. In this way, the locking member 4220 remains locked to the push plate 4210. When the puller 1000 is pulled away, the first contact part 4231 is engaged in the groove 1100. As the puller 1000 continues to be pulled away, the first contact part 4231 is dislodged from the groove 1100. During the process of the first contact part 4231 dislodging from the groove 1100, the rotating part 4230 rotates (counterclockwise). The rotation of the rotating part 4230 causes the second contact part 4232 to rotate as well, so that the second contact part 4232 drives the locking part 4220 to unlock the push plate 4210.
[0290] Combination Figures 45 to 50 As shown, in some embodiments, the launch position 4200 further includes a third elastic member 4293, which is adapted to generate a force on the rotating member 4230 to make the rotating member 4230 have a tendency to rotate. The rotating member 4230 is adapted to abut against the pulling member 1000 under the action of the rotational tendency, and is adapted to drive the first contact portion 4231 into the groove 1100 under the action of the rotational tendency when the groove 1100 and the first contact portion 4231 correspond.
[0291] The following description uses the example of the transmitter 1100 driving the rotating member 4230 to rotate when the pull member 1000 is pulled out, so that the rotating member 4230 drives the locking member 4220 to unlock the push plate 4210, and driving the rotating member 4230 to rotate in the opposite direction when the pull member 1000 is inserted, so that the rotating member 4230 and the locking member 4220 are separated.
[0292] See Figure 49 and Figure 50In the orientation, before the pull member 1000 is inserted into the transmitter 4000, the first contact part 4231 protrudes downwards, and the locking member 4220 is located on the counterclockwise rotation path of the second contact part 4232. When the rotating member 4230 rotates clockwise, the second contact part 4232 leaves the locking member 4220. When the rotating member 4230 rotates counterclockwise, the second contact part 4232 drives the locking member 4220 to unlock the push plate 4210.
[0293] That is, when the pull member 1000 is inserted into the transmitter 4000, the pull member 1000 pushes the first contact part 4231 to make the rotating member 4230 rotate clockwise until the groove 1100 and the first contact part 4231 correspond. Then, the third elastic member 4293 drives the rotating member 4230 to rotate counterclockwise so that the first contact part 4231 is inserted into the groove 1100 (at this time, the first contact part 4231 protrudes downward). As the pull member 1000 continues to be inserted, it pushes the first contact part 4231 to make the rotating member 4230 rotate clockwise so that the first contact part 4231 is dislodged from the groove 1100. Under the action of the third elastic member 4293, the first contact part 4231 and the pull member 1000 slide and abut against each other.
[0294] When the puller 1000 is pulled away from the transmitter 4000, the first contact part 4231 and the puller 1000 slide in contact under the action of the third elastic member 4293 until the groove 1100 and the first contact part 4231 correspond. The third elastic member 4293 drives the rotating member 4230 to rotate counterclockwise, so that the first contact part 4231 is stuck into the groove 1100 (at this time, the first contact part 4231 protrudes downward). As the puller 1000 continues to be pulled away, it pushes the first contact part 4231 to rotate counterclockwise, so that the first contact part 4231 is dislodged from the groove 1100. During this process, the rotating member 4230 drives the locking member 4220 to unlock the push plate 4210 through the second contact part 4232. When the puller 1000 is completely pulled away, the third elastic member 4293 drives the rotating member 4230 to rotate clockwise, so that the first contact part 4231 is reset to protrude downward.
[0295] This application also discloses a launching toy, combined with Figures 1 to 50 As shown, the launching toy includes a launch object 200 and the launching device 100 described above. It is understood that the launching device 100 of the launching toy in this embodiment adopts the technical solution of the above embodiment, and therefore has at least the beneficial effects brought about by the technical solution of the above embodiment, which will not be repeated here.
[0296] The above description is merely a preferred embodiment of this application and does not limit the patent scope of this application. Any equivalent structural transformations made based on the concept of this application and the contents of the specification and drawings of this application, or direct / indirect applications in other related technical fields, are included within the patent protection scope of this application.
Claims
1. A launching device (100), characterized in that, include: A transmitter (4000) is adapted to mount an object to be launched (200) thereon. The transmitter (4000) includes an acceleration position (4100) and a launch position (4200). The launch position (4200) is used to mount and launch the object to be launched (200). The acceleration position (4100) is used to drive the object to be launched (200) to rotate. Accessories, which are detachably mounted on the transmitter (4000), are adapted to cooperate with the launch position (4200) and / or the acceleration position (4100) to enable the transmitter (4000) to drive the object to be launched (200) to rotate and / or launch the object to be launched (200).
2. The launching device (100) as claimed in claim 1, characterized in that, The transmitter (4000) also includes at least one connection point adapted to be detachably connected to the accessory, and the transmitter (100) has different transmission modes depending on the accessory connected to the connection point.
3. The launching device (100) as claimed in claim 1, characterized in that, At least one of the accessories can be detachably installed on the transmitter (4000), and the transmitter (100) has different transmission modes depending on the different accessories installed.
4. The launching device (100) as claimed in claim 1, characterized in that, The acceleration position (4100) includes an acceleration gear (4110), the accessory is adapted to drive the acceleration gear (4110) to rotate, and the acceleration gear (4110) is adapted to drive the object to be launched (200) to rotate.
5. The launching device (100) as claimed in claim 1, characterized in that, The accessory includes a first body (2000), the first body (2000) includes a first slide (2100), the first slide (2100) is reciprocating; When the first body (2000) and the transmitter (4000) are connected, the first slide (2100) is adapted to drive the acceleration position (4100), so that the acceleration position (4100) drives the object to be launched (200) to rotate.
6. The launching device (100) as claimed in claim 5, characterized in that, The first slide bar (2100) is adapted to reciprocate along a first direction and a second direction, the first direction and the second direction being opposite. The first body (2000) also includes a first clutch mechanism (2200) and a first stop mechanism (2300), the first stop mechanism (2300) having a first stop state and a second stop state. When the first stop mechanism (2300) is in the first stop state, the first slide (2100) is adapted to move along the first direction to drive the first clutch mechanism (2200) so that the first clutch mechanism (2200) drives the acceleration gear (4110) of the acceleration position (4100) to rotate. When the first slide (2100) is adapted to move along the second direction, it drives the first clutch mechanism (2200) so that the first clutch mechanism (2200) and the acceleration gear (4110) of the acceleration position (4100) are separated. When the first stop mechanism (2300) is in the second stop state, the first slide (2100) is adapted to drive the first clutch mechanism (2200) when moving along the first direction, so that the first clutch mechanism (2200) and the acceleration gear (4110) of the acceleration position (4100) are separated. When the first slide (2100) is adapted to drive the first clutch mechanism (2200) when moving along the second direction, so that the first clutch mechanism (2200) drives the acceleration gear (4110) of the acceleration position (4100) to rotate in the opposite direction.
7. The launching device (100) as claimed in claim 6, characterized in that, The first clutch mechanism (2200) includes: The first movable component (2220) is rotatable; The first drive gear (2210) is rotatably configured and coaxial with the first movable part (2220); A first clutch gear (2230) is rotatably disposed on the first movable member (2220) and meshes with the first drive gear (2210); and The second clutch gear (2240) is rotatably disposed on the first movable member (2220) and meshes with the first drive gear (2210); When the first stop mechanism (2300) is in the first stop state: The first slide bar (2100) is adapted to drive the first drive gear (2210) to rotate when it moves along the first direction, so that the first movable member (2220) swings, and the first clutch gear (2230) and the acceleration gear (4110) mesh and drive, and the second clutch gear (2240) and the acceleration gear (4110) disengage; When the first slide bar (2100) moves along the second direction, it drives the first drive gear (2210) to rotate in the opposite direction, so that the first movable member (2220) swings in the opposite direction and is stopped by the first stop mechanism (2300), so that the first clutch gear (2230) and the acceleration gear (4110) are separated, and the second clutch gear (2240) and the acceleration gear (4110) are separated; When the first stop mechanism (2300) is in the second stop state; The first slide bar (2100) is adapted to drive the first drive gear (2210) to rotate when it moves along the first direction, so that the first movable member (2220) swings and is stopped by the first stop mechanism (2300), so that the first clutch gear (2230) and the acceleration gear (4110) are separated, and the second clutch gear (2240) and the acceleration gear (4110) are separated; When the first slide bar (2100) moves along the second direction, it drives the first drive gear (2210) to rotate in the opposite direction, so that the first movable part (2220) swings in the opposite direction, and causes the first clutch gear (2230) and the acceleration gear (4110) to separate, and the second clutch gear (2240) and the acceleration gear (4110) to mesh and drive.
8. The launching device (100) as claimed in claim 7, characterized in that, The first stop mechanism (2300) includes a slot (2310), and the first movable member (2220) is inserted into the slot (2310); When the first stop mechanism (2300) is in the first stop state, the first movable member (2220) is adapted to be stopped by one side of the slot (2310) so that the first clutch gear (2230) and the second clutch gear (2240) are respectively separated from the acceleration gear (4110); When the first stop mechanism (2300) is in the second stop state, the first movable member (2220) is adapted to be stopped by the other side of the slot (2310) so that the first clutch gear (2230) and the second clutch gear (2240) are respectively separated from the acceleration gear (4110).
9. The launching device (100) as claimed in claim 8, characterized in that, The first movable part (2220) is rotatably configured to switch between the first stop state and the second stop state, thereby changing the position of the slot (2310).
10. The launching device (100) as claimed in claim 7, characterized in that, The first body (2000) also includes a first rack (2101), the first slide (2100) is connected to the first rack (2101) and can drive the first rack (2101) to reciprocate, and the first rack (2101) is connected to the first drive gear (2210) in a transmission connection.
11. The launching device (100) as claimed in claim 5, characterized in that, The launching device (100) further includes a first extension member (2500), which is adapted to be detachably connected to the first body (2000), and the first slide (2100) is adapted to reciprocate to the first extension member (2500) when the first extension member (2500) and the first body (2000) are connected.
12. The launching device (100) as claimed in claim 11, characterized in that, The first body (2000) further includes a first limiting mechanism (2400), which is adapted to avoid the first slider (2100) when the first extension member (2500) and the first body (2000) are connected, so that the first slider (2100) can reciprocate to the first extension member (2500), and is also adapted to stop the first slider (2100) when the first extension member (2500) and the first body (2000) are disassembled, so as to prevent the first slider (2100) from coming off.
13. The launching device (100) as claimed in claim 12, characterized in that, The first extension component (2500) includes a first protruding rod (2510), and the first limiting mechanism (2400) includes a first movable pin (2410); The first protruding rod (2510) is adapted to drive the first movable pin (2410) away from the movement path of the first slide (2100) to avoid the first slide (2100) when the first extension member (2500) and the first body (2000) are connected; The first movable pin (2410) is adapted to move into the movement path of the first slide (2100) under the action of elastic force when the first extension member (2500) and the first body (2000) are disassembled, so as to stop the first slide (2100).
14. The launching device (100) as claimed in claim 1, characterized in that, The accessory includes a handle (5000) adapted for gripping, and the handle (5000) includes a first release mechanism (5100); When the handle (5000) and the transmitter (4000) are connected, the first release mechanism (5100) is adapted to drive the launch position (4200), so that the launch position (4200) drives the object to be launched (200) to be launched.
15. The launching device (100) as claimed in claim 1, characterized in that, The accessory includes a second body (3000), the second body (3000) includes a second slider (3100) and a second release mechanism (3600), the second slider (3100) is reciprocating; When the second body (3000) and the transmitter (4000) are connected, the second slider (3100) is adapted to drive the acceleration position (4100), so that the acceleration position (4100) drives the object to be launched (200) to rotate, and the second release mechanism (3600) is adapted to drive the launch position (4200), so that the launch position (4200) drives the object to be launched (200) to be launched.
16. The launching device (100) as claimed in claim 15, characterized in that, The second slider (3100) is adapted to reciprocate along a third direction and a fourth direction, the third direction and the fourth direction being opposite. The second body (3000) also includes a second clutch mechanism (3200) and a second stop mechanism (3300), the second stop mechanism (3300) having a third stop state and a fourth stop state. When the second stop mechanism (3300) is in the third stop state, the second slider (3100) is adapted to drive the second clutch mechanism (3200) when moving along the third direction, so that the second clutch mechanism (3200) drives the acceleration gear (4110) of the acceleration position (4100) to rotate. When the second slider (3100) is adapted to drive the second clutch mechanism (3200) when moving along the fourth direction, so that the second clutch mechanism (3200) and the acceleration gear (4110) of the acceleration position (4100) are separated. When the second stop mechanism (3300) is in the fourth stop state, the second slider (3100) is adapted to drive the second clutch mechanism (3200) when moving along the third direction, so that the second clutch mechanism (3200) and the acceleration gear (4110) of the acceleration position (4100) are separated. When the second slider (3100) is adapted to drive the second clutch mechanism (3200) when moving along the fourth direction, so that the second clutch mechanism (3200) drives the acceleration gear (4110) of the acceleration position (4100) to rotate in the opposite direction.
17. The launching device (100) as claimed in claim 16, characterized in that, The second clutch mechanism (3200) includes: The second movable part (3220) is rotatable; The second drive gear (3210) is rotatably configured and coaxial with the second movable member (3220); The third clutch gear (3230) is rotatably disposed on the second movable member (3220) and meshes with the second drive gear (3210); and The fourth clutch gear (3240) is rotatably disposed on the second movable member (3220) and meshes with the second drive gear (3210); When the second stop mechanism (3300) is in the third stop state: The second slider (3100) is adapted to drive the second drive gear (3210) to rotate when it moves along the third direction, so that the second movable member (3220) swings, and the third clutch gear (3230) and the acceleration gear (4110) mesh and drive, and the fourth clutch gear (3240) and the acceleration gear (4110) disengage; When the second slider (3100) moves along the fourth direction, it drives the second drive gear (3210) to rotate in the opposite direction, so that the second movable member (3220) swings in the opposite direction and is stopped by the second stop mechanism (3300), so that the third clutch gear (3230) and the acceleration gear (4110) are separated, and the fourth clutch gear (3240) and the acceleration gear (4110) are separated; When the second stop mechanism (3300) is in the fourth stop state; The second slider (3100) is adapted to drive the second drive gear (3210) to rotate when it moves along the third direction, so that the second movable member (3220) swings and is stopped by the second stop mechanism (3300), so that the third clutch gear (3230) and the acceleration gear (4110) are separated, and the fourth clutch gear (3240) and the acceleration gear (4110) are separated; When the second slider (3100) moves along the fourth direction, it drives the second drive gear (3210) to rotate in the opposite direction, so that the second movable member (3220) swings in the opposite direction, and causes the third clutch gear (3230) and the acceleration gear (4110) to separate, and the fourth clutch gear (3240) and the acceleration gear (4110) to mesh and drive.
18. The launching device (100) as claimed in claim 17, characterized in that, The second stop mechanism (3300) includes a first stop groove (3310) and a second stop groove (3320); When the second stop mechanism (3300) is in the third stop state, the second movable member (3220) is inserted into the first stop groove (3310) to be stopped by the first stop groove (3310) during swinging; When the second stop mechanism (3300) is in the fourth stop state, the second movable member (3220) is inserted into the second stop groove (3320) to be stopped by the second stop groove (3320) during swinging.
19. The launching device (100) as claimed in claim 18, characterized in that, The first stop groove (3310) and the second stop groove (3320) are connected. The second stop mechanism (3300) is adapted to reciprocate so that the second movable member (3220) can move from the first stop groove (3310) into the second stop groove (3320) and from the second stop groove (3320) into the first stop groove (3310).
20. The launching device (100) as claimed in claim 17, characterized in that, The second body (3000) also includes a second rack (3101), the second slider (3100) and the second rack (3101) are connected and can drive the second rack (3101) to reciprocate, and the second rack (3101) and the second drive gear (3210) are connected in transmission.
21. The launching device (100) as claimed in claim 15, characterized in that, The second main body (3000) also includes a second limiting mechanism (3400); The second slider (3100) includes a first gear mechanism (3110) and a second gear mechanism (3120). The first gear mechanism (3110) and the second gear mechanism (3120) are arranged alternately along the reciprocating movement direction of the second slider (3100). The first gear mechanism (3110) and the second gear mechanism (3120) are adapted to follow the movement of the second slider (3100) and one of them can abut against the second limiting mechanism (3400).
22. The launching device (100) as claimed in claim 21, characterized in that, The second main body (3000) also includes a second rack (3101), the second slider (3100) and the second rack (3101) are movably connected and can drive the second rack (3101) to reciprocate, and the second rack (3101) and the acceleration position (4100) are connected in a transmission. The second rack (3101) is adapted to selectively drive one of the first gear mechanism (3110) and the second gear mechanism (3120) to a position abutting against the second limit mechanism (3400) when moving relative to the second slider (3100).
23. The launching device (100) as claimed in claim 22, characterized in that, The second slider (3100) further includes a groove (3130) and a locking member (3140), the second rack (3101) being movably connected to the groove (3130), and the locking member (3140) being adapted to lock the second rack (3101) relative to the second slider (3100) and also adapted to unlock the second rack (3101) relative to the second slider (3100); The second rack (3101) is adapted to move from one end of the slide (3130) toward the other end when the locking member (3140) is unlocked, so as to drive one of the first gear mechanism (3110) and the second gear mechanism (3120) to switch to a position abutting against the second limiting mechanism (3400), and is also adapted to move from the other end of the slide (3130) toward the first end when the locking member (3140) is unlocked, so as to drive the other of the first gear mechanism (3110) and the second gear mechanism (3120) to switch to a position abutting against the second limiting mechanism (3400).
24. The launching device (100) as claimed in claim 15, characterized in that, The launching device (100) further includes a second extension member (3500), which is adapted to be detachably connected to the second body (3000), and the second slider (3100) is adapted to reciprocate to the second extension member (3500) when the second extension member (3500) and the second body (3000) are connected.
25. The launching device (100) as claimed in claim 24, characterized in that, The second body (3000) further includes a second limiting mechanism (3400), which is adapted to avoid the second slider (3100) when the second extension member (3500) and the second body (3000) are connected, so that the second slider (3100) can reciprocate to the second extension member (3500), and is also adapted to stop the second slider (3100) when the second extension member (3500) and the second body (3000) are disassembled, so as to prevent the second slider (3100) from falling out.
26. The launching device (100) as claimed in claim 25, characterized in that, The second extension component (3500) includes a second protrusion (3510), and the second limiting mechanism (3400) includes a second movable pin (3410); The second protruding rod (3510) is adapted to drive the second movable pin (3410) away from the movement path of the second slider (3100) to avoid the second slider (3100) when the second extension member (3500) and the second body (3000) are connected; The second movable pin (3410) is adapted to move into the movement path of the second slider (3100) under the action of elastic force when the second extension member (3500) and the second body (3000) are disassembled, so as to stop the second slider (3100).
27. The launching device (100) as claimed in claim 1, characterized in that, The accessory includes a pull member (1000) adapted to insert into and remove from the transmitter (4000), the pull member (1000) including an acceleration end (1200) and a launching end (1100); When the pull member (1000) and the transmitter (4000) are connected, the acceleration end (1200) is adapted to drive the acceleration position (4100) during the process of the pull member (1000) being inserted into and / or pulled out of the transmitter (4000), so that the acceleration position (4100) drives the object to be launched (200) to rotate. The launching end (1100) is adapted to drive the launching position (4200) when the pull member (1000) is inserted into and / or pulled out of the transmitter (4000), so that the launching position (4200) drives the object to be launched (200) to be launched.
28. The launching device (100) as claimed in claim 27, characterized in that, The object to be launched (200) is adapted to be launched forward; the launcher (4000) is provided with a guide hole (4400), and the puller (1000) is adapted to be inserted into and pulled out of the guide hole (4400), and at least two guide holes (4400) are arranged alternately in the left-right direction.
29. The launching device (100) as claimed in claim 27, characterized in that, The acceleration end (1200) is adapted to drive the acceleration gear (4110) of the acceleration position (4100) to rotate.
30. The launching device (100) as claimed in claim 29, characterized in that, The acceleration position (4100) further includes a first transmission gear (4120), and the acceleration end (1200) is adapted to mesh with the first transmission gear (4120) to drive the first transmission gear (4120) to rotate. The first transmission gear (4120) and the acceleration gear (4110) mesh to drive the acceleration gear (4110) to rotate.
31. The launching device (100) as claimed in claim 27, characterized in that, The pulling member (1000) is adapted to first drive the acceleration position (4100) and then drive the launching position (4200) when pulled out; Alternatively, the pull member (1000) is adapted to first drive the acceleration position (4100) and then drive the launch position (4200) during insertion.
32. The launching device (100) according to any one of claims 1 to 31, characterized in that, The transmit position (4200) includes: When the object to be launched (200) is installed on the transmitter (4000), the push plate (4210) is adapted to abut against the push plate (4210) and drive the push plate (4210) to move. The locking element (4220) is adapted to lock the push plate (4210) when the push plate (4210) moves to a preset position, and is adapted to be driven by the accessory to unlock the push plate (4210); A first elastic element (4291) is adapted to generate force on the push plate (4210) to drive the push plate (4210) to reset when the locking element (4220) unlocks the push plate (4210), so that the push plate (4210) drives the object to be launched (200) to be launched.
33. The launching device (100) as claimed in claim 32, characterized in that, When a handle (5000) is included, the first release mechanism (5100) of the handle (5000) is adapted to actuate the locking member (4220) to unlock the push plate (4210); And / or, when the second body (3000) is included, the second release mechanism (3600) of the second body (3000) is adapted to actuate the locking member (4220) to unlock the push plate (4210); And / or, when a pull member (1000) is included, the launching end (1100) of the pull member (1000) is adapted to actuate the locking member (4220) to cause the locking member (4220) to unlock the push plate (4210).
34. The launching device (100) as claimed in claim 32, characterized in that, The launch position (4200) further includes a rotating component (4230), which is provided with a lug (4234) and a second contact portion (4232); When a handle (5000) is included, the first release mechanism (5100) of the handle (5000) includes a reciprocating pusher (5110) adapted to push the lug (4234) to rotate the rotating member (4230) and cause the second contact portion (4232) to drive the locking member (4220) to unlock the push plate (4210).
35. The launching device (100) as claimed in claim 32, characterized in that, When the second body (3000) is included, the second release mechanism (3600) of the second body (3000) includes a reciprocating trigger (3610) adapted to actuate the locking member (4220) to unlock the push plate (4210).
36. The launching device (100) as claimed in claim 32, characterized in that, The launch position (4200) also includes a rotating component (4230); When the pull member (1000) is included, the launching end (1100) of the pull member (1000) is adapted to drive the rotating member (4230) to rotate when the pull member (1000) moves in one of the directions of insertion and withdrawal, so that the rotating member (4230) drives the locking member (4220) to unlock the push plate (4210), and the launching end (1100) is adapted to drive the rotating member (4230) to rotate in the opposite direction when the pull member (1000) moves in the other direction of insertion and withdrawal, so that the rotating member (4230) and the locking member (4220) separate.
37. The launching device (100) as claimed in claim 36, characterized in that, The rotating component (4230) is provided with a first contact portion (4231) and a second contact portion (4232), and the transmitting end (1100) forms a groove (1100); The first contact portion (4231) is adapted to sequentially engage with and disengage from the groove (1100) when the pull member (1000) moves in one of the directions of insertion and disengagement, so as to rotate the rotating member (4230) and cause the second contact portion (4232) to drive the locking member (4220) to unlock the push plate (4210); The first contact portion (4231) is adapted to sequentially engage with and disengage from the groove (1100) when the pull member (1000) moves in the opposite direction of insertion and disengagement, so that the rotating member (4230) rotates in the opposite direction and the second contact portion (4232) and the locking member (4220) are separated.
38. The launching device (100) as claimed in claim 37, characterized in that, The launching position (4200) further includes a third elastic element (4293), which is adapted to generate a force on the rotating member (4230) to make the rotating member (4230) have a tendency to rotate. The rotating member (4230) is adapted to abut against the pulling member (1000) under the action of the rotational tendency, and is adapted to drive the first contact portion (4231) to engage in the groove (1100) under the action of the rotational tendency when the groove (1100) and the first contact portion (4231) correspond.
39. A launching toy, characterized in that, It includes the object to be launched (200) and the launching device (100) according to any one of claims 1 to 38.