Drive device for an inflatable toy and inflatable toy system with drive device
By introducing a drive device and moving mechanism into inflatable toys, and using air and electricity to drive them, a variety of dynamic changes in inflatable toys are realized, solving the problems of insufficient fun and flexibility in existing technologies, and providing a wealth of toy play methods and interactive effects.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- 曾迪
- Filing Date
- 2021-07-26
- Publication Date
- 2026-06-09
AI Technical Summary
Existing inflatable toy connection components cannot drive inflatable toys to change dynamically in real time, resulting in insufficient fun and flexibility.
A driving device is designed, including a moving mechanism and a power unit, which drives an inflatable toy to achieve various dynamic changes through an air source and a power source. The power unit is connected to the air source and the power source. The moving mechanism is fixed or detachable by a mounting base. The action output end is coupled to the inflatable toy to achieve various actions.
It achieves various dynamic effects for inflatable toys, such as swinging, stretching, rotating, and launching, enriching the play and interactivity of the toys. It is suitable for various scenarios and is easy to replace and repair.
Smart Images

Figure CN115671753B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of inflatable toy technology, and more particularly to a drive device for inflatable toys, an inflatable toy, and an inflatable toy system with a drive device. Background Technology
[0002] Among the current categories of inflatable toys, one type is pre-constructed, usually with a fixed structure and shape; the other type is detachable and assembleable, with changeable shapes or structures, typically allowing users to alter the toy's shape and structure to some extent. Detachable inflatable toy components can employ various connection methods and come in two types: mutual airflow and independent inflation. However, current connecting components generally only function to connect two inflatable toy components and cannot drive real-time dynamic changes in the inflatable toy, resulting in limited fun and flexibility.
[0003] The above background information is provided only to aid in understanding the concept and technical solution of this invention. It does not necessarily belong to the prior art of this patent application. In the absence of clear evidence that the above information was disclosed on the filing date of this patent application, the above background information should not be used to evaluate the novelty and inventiveness of this application. Summary of the Invention
[0004] The main objective of this invention is to overcome the deficiencies of the prior art and provide a driving device for inflatable toys, an inflatable toy, and an inflatable toy system with a driving device.
[0005] To achieve the above objectives, the present invention adopts the following technical solution:
[0006] A driving device for an inflatable toy is provided for driving the inflatable toy to move. The inflatable toy includes a support cavity and a mounting base. The mounting base is provided with a cavity connection portion for fixedly or repeatedly detachably connecting the support cavity. The driving device includes a mounting head and a movable mechanism. The movable mechanism is fixedly or repeatedly detachably connected to the mounting base through the mounting head. The movable mechanism is provided with an action output end, which is located on the side of the movable mechanism adjacent to or opposite to the mounting head. The action output end is used to couple with the driven inflatable toy to realize the movement of the inflatable toy according to a set action.
[0007] Furthermore, the active mechanism includes a first air inlet, which is connected to an air source via the mounting base.
[0008] Furthermore, there are two or more first air inlets, with at least two first air inlets forming a pair, which are respectively connected to a positive pressure air source and a negative pressure air source to achieve inflation and deflation respectively.
[0009] Furthermore, the actuating mechanism also includes a second air inlet disposed at or near the action output end; one end of the second air inlet is connected to the first air inlet via an air passage, and the other end is used to deliver gas from the air source to the gas-using toy or other objects besides the gas-using toy. This allows the gas from the air source to not only supply the actuating mechanism but also flow through it to supply devices located downstream of the actuating mechanism (such as gas-using toys), thus solving the problem that when an actuating mechanism lacking this feature is installed on the air path, the gas is blocked by the actuating mechanism and cannot continue to flow downwards.
[0010] Furthermore, there are at least two air channels, with at least two first air inlets and at least two second air inlets. The two ends of each air channel are respectively connected to their respective first air inlets and second air inlets. At least two air channels form a pair, which are used to inflate and de-inflate the gas toy or other objects other than the gas toy.
[0011] Furthermore, the active mechanism includes a power unit connected to the action output end, which is used to provide driving force to the action output end.
[0012] Furthermore, the power device is a pneumatic power device, which is connected to an air source.
[0013] Furthermore, the power unit is provided with a power air port, which is connected to the air source via the mounting base, for supplying gas from the air source to the power unit.
[0014] Furthermore, the power air port is provided with two ports, each of which is connected to a positive pressure air source and a negative pressure air source respectively, so as to be used to inflate and evacuate the power device respectively.
[0015] Furthermore, the active mechanism includes a power unit airflow control device, which is disposed at the power air inlet and is used to control the direction and / or flow rate of the gas flowing through the power air inlet.
[0016] Furthermore, the movable mechanism includes a first electrical contact, which is electrically connected to a power source and / or signal source via the mounting base to introduce current and / or electrical signals into the movable mechanism, thereby providing working power to the movable mechanism.
[0017] Furthermore, the moving mechanism also includes a second electrical contact, one end of which is electrically connected to the first electrical contact, and the other end is used to electrically connect to the gas toy or other objects to supply power or transmit electrical signals to the gas toy or other objects. This allows electrical / signal sources from the power / signal source to supply power to the moving mechanism while simultaneously supplying power to devices located downstream of the moving mechanism (such as gas toys), thus solving the problem that when a moving mechanism lacking this feature is installed on a circuit / signal line, the electrical / signal signal is blocked by the moving mechanism and cannot continue to be transmitted.
[0018] Furthermore, the power device is an electric power device, an electromagnetic induction power device, or a magnetic power device, and the power device is electrically connected to a power source and / or a signal source via the mounting base.
[0019] Furthermore, the activity mechanism includes a first motion conversion component. One end of the first motion conversion component is fixedly or removably connected to the power device, and the other end is provided with the motion output end. The first motion conversion component is used to convert the power motion mode and state generated by the power device into the desired motion mode and state. This allows the power generated by the drive device to produce changes in direction, amplitude, frequency, speed, etc., thereby achieving more motion states and richer play effects.
[0020] Furthermore, the drive device also includes a first docking member disposed on the movable mechanism, the first docking member being used for fixed or removable connection with the inflatable toy. This can save costs and improve convenience; that is, without replacing the drive device, the same drive device can be used, and different motion effects can be produced simply by installing different first transmission components.
[0021] Furthermore, the first docking member is disposed on the motion output end, and can cause the inflatable toy to move along with it under the action of the motion output end. The air pipe / electrical cable connecting the mounting base and the movable mechanism has a predetermined length and is provided with a movable pull-out structure, allowing the movable mechanism to be detached from the mounting base. The movable mechanism is not necessarily confined to the mounting base, but can be detached from the mounting base and placed in different positions according to changes in play, thereby producing richer play methods and effects.
[0022] An inflatable toy includes a body and an action receiving end connected to the body. The action receiving end is used to couple with the aforementioned action output end to receive driving force from the action output end to drive the body to move.
[0023] Furthermore, the gas toy includes a gas toy ventilation port disposed at or near the action receiving end; one end of the gas toy ventilation port is used to connect with the second gas inlet to receive gas from the gas source, and the other end is used to connect with the main body to supply gas to the main body.
[0024] Furthermore, the air toy has at least two vents, each of which is connected to a positive pressure air source and a negative pressure air source via different second air inlets, so as to inflate and de-inflate the body respectively.
[0025] Furthermore, the main body includes an inflatable cavity, which is a soft, deformable inflatable cavity and is connected to the air vent of the inflatable toy.
[0026] Furthermore, the gas toy also includes a gas toy airflow control device, which is fixedly or removably connected to the gas toy's air inlet for controlling the direction and / or flow rate of the gas flowing through it.
[0027] Furthermore, the air inlet of the gas toy supplies and evacuates air to multiple bodies in a time-sharing and independent manner through a gas toy airflow control device.
[0028] Furthermore, the gas toy includes a gas toy electrical contact; the gas toy electrical contact is electrically connected to a second electrical contact of the moving mechanism provided on the moving mechanism, for transmitting current and / or electrical signals between the two contacts.
[0029] Furthermore, the gas toy also includes a second docking member disposed on the action receiving end, the second docking member being used to be fixedly or repeatedly detachably connected to the driving device and / or the mounting base. Even when the second docking member is securely locked to the moving mechanism or mounting base (at which point the second docking member cannot move), the driven cavity can still generate the required movement under the drive of the power output end.
[0030] Furthermore, one end of the second docking member is hinged to the mounting base. This allows the docking base to be securely installed on the support cavity, thus withstanding the violent impacts of children during play.
[0031] Furthermore, the second docking member is a second recessed structure, used to accommodate at least part of the action receiving end within the second recessed structure.
[0032] Furthermore, the main body is provided with a second receiving portion, and the action receiving end is received inside the second receiving portion.
[0033] Furthermore, the gas toy also includes a second motion conversion component. The motion receiving end is connected to the main body via the second motion conversion component. The second motion conversion component is used to convert the power motion mode and state received by the motion receiving end into the required motion mode and state.
[0034] An inflatable toy system includes: a support cavity, a mounting base, and the aforementioned driving device; the mounting base is provided with a cavity connection portion for fixedly or repeatedly detachably connecting the support cavity; the driving device is fixedly or repeatedly detachably connected to the mounting base.
[0035] Furthermore, the supporting cavity is a soft, deformable, inflatable cavity. The supporting cavity is equipped with a ventilation port. The end of the ventilation port located outside the supporting cavity is connected to an air source, while the end located inside the supporting cavity is connected to both the interior of the supporting cavity and the mounting base. This allows air pipes from outside the supporting cavity to enter the interior, preventing the air pipes from being exposed, thus improving safety and aesthetics. Simultaneously, this method of inserting external air pipes into the cavity is simpler and easier to implement in the manufacturing process.
[0036] Furthermore, an airflow control device for the support cavity is connected between the air vent of the support cavity and the mounting base. The mounting base and the airflow control device of the support base can be detachably connected by means of snap-fit connection, threaded connection, or other methods.
[0037] Furthermore, the support cavity is provided with an access component to improve the stability and airtightness of the connection; the access component is airtightly connected to the support cavity, and the access component is provided with a first airflow control device mounting structure and a ventilation interface of the support cavity; the first airflow control device mounting structure is used for repeatedly detaching and installing the airflow control device of the support cavity.
[0038] Furthermore, the support cavity ventilation interface is provided with at least two, wherein at least two support cavity ventilation interfaces form a pair, which are respectively connected to a positive pressure air source and a negative pressure air source, so as to realize the use of inflation and deflation respectively.
[0039] Furthermore, the support cavity is provided with a support cavity electrical contact; one end of the support cavity electrical contact located outside the support cavity is electrically connected to a power source and / or a signal source, and the other end of the support cavity electrical contact located inside the support cavity is electrically connected to the mounting base.
[0040] Furthermore, the support cavity is provided with a first receiving portion, and the mounting seat is accommodated inside the first receiving portion. By providing the first receiving portion, a rigid mounting seat can be wrapped with a soft inflatable cavity, thereby making it safer for playing children.
[0041] Furthermore, the mounting base includes a mounting base ventilation interface, one end of which is connected to a gas source, and the other end is connected to a first air guide interface provided on the movable mechanism to transmit gas to the movable mechanism.
[0042] Furthermore, one end of the venting interface of the mounting base is located inside the support cavity and extends out of the support cavity through an air pipe to communicate with the air source.
[0043] Furthermore, the mounting base has at least two ventilation ports, with at least two mounting base ventilation ports forming a pair, which are respectively connected to a positive pressure air source and a negative pressure air source to achieve inflation and deflation respectively.
[0044] Furthermore, a second airflow control device mounting structure is provided at the venting interface of the mounting base for repeatedly detaching and installing the airflow control device.
[0045] Furthermore, the inflatable toy system also includes a mounting base electrical contact. One end of the mounting base electrical contact is disposed inside the support cavity and is electrically connected to a power source and / or signal source via a wire passing through the support cavity. The other end of the mounting base electrical contact is electrically connected to the first electrical contact of the movable mechanism disposed on the movable mechanism to supply power to the movable mechanism or provide an electrical signal.
[0046] Furthermore, the mounting base is a first recessed structure, and the driving device is at least partially housed within the first recessed structure to improve safety and aesthetics.
[0047] Furthermore, the inflatable toy system also includes the inflatable toy, which is mounted on the inflatable toy system via the driving device and is driven by the driving device. By increasing the number of inflatable toys, the play scenarios are enriched, the interactive variations are increased, and the game becomes more interesting. In some embodiments, each inflatable toy can be an independently inflatable cavity that can be inflated and deflated at different times.
[0048] Furthermore, the inflatable toy is equipped with independent, time-controlled inflatable cavities. For example, the support cavity and other inflatable cavities can be connected using any of the following methods: heat sealing, adhesive bonding, connection via air pipes, connection via connectors, connection via valves, or connection via pneumatic or electric devices. In actual play scenarios, a single cavity can make the gameplay monotonous, the plot simple, and the variations dull. However, with multiple cavities, the different shapes, combinations, actions, and plot interactions of each cavity offer much richer variety, making the gameplay more interesting. Each inflatable cavity is connected to the air source via an independent air pipe, allowing the support cavity and other inflatable cavities to perform their own actions, resulting in asynchronous and more varied movements.
[0049] Furthermore, the inflatable toy system also includes an entertainment aid device, which is disposed on the support cavity and / or the inflatable toy and is connected to a power source via an electrical wire or to an air source via an air pipe.
[0050] Furthermore, the inflatable toy system also includes other cavities that are fixedly or repeatedly detachably connected to the support cavity.
[0051] Furthermore, the load-bearing structure of the supporting cavity is configured to withstand the weight of the player after inflation, and is provided with a space structure of a size that allows the player to play on it.
[0052] Compared with the prior art, this application has the following beneficial effects: On the one hand, by independently setting the moving mechanism to drive the inflatable toy, it can present a variety of dynamic effects of inflatable toys, such as swinging, stretching, rotating, and launching; on the other hand, by setting the mounting base on the support cavity in a fixed or removable manner, and installing the moving mechanism in a fixed or removable manner on the mounting base, it is not only convenient to replace and maintain the moving mechanism, but also makes the moving mechanism suitable for various different application scenarios, such as realizing the long-distance driving of inflatable toys.
[0053] In a further embodiment, this application also has the following advantages:
[0054] 1. This application utilizes an air source to inflate and deflate the support cavity, other cavities, and the inflatable toy through independent air tubes. By changing the inflation and deflation, the inflatable toy presents a dynamic changing effect.
[0055] 2. By setting electrical wire contacts on the support cavity, mounting base, drive device and inflatable toy respectively, this application enables the inflatable toy to perform multiple actions while simultaneously powering the entertainment auxiliary device on the inflatable toy, thereby achieving a richer and more dynamic interactive effect for the inflatable toy.
[0056] 3. The gas toys and supporting cavities of this application can be designed and assembled according to the needs of the usage scenario. The gas circuits and electrical circuits of each gas toy are connected at the same time, allowing participants to play, stimulate their imagination, exercise their bodies, and operate in a simple and portable manner. Attached Figure Description
[0057] Figure 1 This is a schematic diagram of the inflatable toy in Example 1.
[0058] Figure 2 yes Figure 1 A partial exploded view.
[0059] Figure 3 This is a schematic diagram of the inflatable toy in Example 2.
[0060] Figure 4 This is a schematic diagram of the inflatable toy in Example 3.
[0061] Figure 5 This is a schematic diagram of the inflatable toy in Example 4.
[0062] Figure 6 This is a schematic diagram of the inflatable toy in Example 5.
[0063] Figure 7 This is a schematic diagram of the inflatable toy in Example 6.
[0064] Figure 8 This is a schematic diagram of the inflatable toy in Example 7.
[0065] Figure 9 This is a schematic diagram of the inflatable toy in Example 8.
[0066] Figure 10 This is a schematic diagram of the inflatable toy in Example 9.
[0067] Figure 11 yes Figure 10 A partial exploded view.
[0068] Figure 12 This is a schematic diagram of the inflatable toy of Example 10.
[0069] Figure 13 yes Figure 12 A partial exploded view.
[0070] Figure 14 This is a schematic diagram of the inflatable toy in Example 11.
[0071] Figure 15 yes Figure 14 A partial exploded view.
[0072] Figure 16 This is a schematic diagram of the inflatable toy in Example 12.
[0073] Figure 17 yes Figure 16 A partial exploded view.
[0074] Figure 18 This is a schematic diagram of the inflatable toy in Example 13.
[0075] Figure 19 This is a schematic diagram of the inflatable toy in Example 14.
[0076] Figure 20 This is a schematic diagram of the inflatable toy in Example 15.
[0077] Figure 21 This is a schematic diagram of the inflatable toy of Example 16.
[0078] Explanation of reference numerals in the attached figures:
[0079]
[0080] Detailed Implementation
[0081] To make the technical problems, technical solutions, and beneficial effects of the embodiments of the present invention clearer, the present invention will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present invention and are not intended to limit the present invention.
[0082] It should be noted that when a component is referred to as "fixed to" or "set on" another component, it can be directly on or indirectly on that other component. When a component is referred to as "connected to" another component, it can be directly connected to or indirectly connected to that other component. Furthermore, a connection can be for both fixing and circuit connection purposes.
[0083] It should be understood that the terms "length", "width", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", and "outer" indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing the embodiments of the present invention and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on the present invention.
[0084] Furthermore, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of embodiments of the present invention, "a plurality of" means two or more, unless otherwise explicitly specified.
[0085] Example 1
[0086] like Figures 1 to 2 As shown, this embodiment discloses an inflatable toy, which includes a support cavity 200, a mounting base 300, a drive device 1900, an air-operated toy 800, and an entertainment auxiliary device 1100. The mounting base 300 is provided with a cavity joint 360, which is used to fix or repeatedly disassemble and assemble to the support cavity 200. The cavity joint 360 can adopt a snap-fit, threaded, or interference fit structure, or it can adopt a heat-sealing or adhesive connection method. The drive device 1900 is fixedly or repeatedly disassembled and assembled to the mounting base 300. The inflatable toy of this embodiment can work by connecting to an air source 100 through an air pipe 900. The air source 100 is divided into a positive pressure air source and a negative pressure air source.
[0087] in:
[0088] The support cavity 200 is a soft, deformable, inflatable cavity. The support cavity 200 is equipped with a support cavity ventilation port 220. The end of the support cavity ventilation port 220 located outside the support cavity 200 is connected to the air source 100 via an air pipe 900. The end of the support cavity ventilation port 220 located inside the support cavity 200 is connected to the interior of the support cavity 200 and the mounting base 300 via a support cavity airflow control device 1300. The support cavity airflow control device 1300 specifically employs a distributor and an air valve. At least two support cavity ventilation ports 220 are provided, with at least two ports forming a pair. These ports are connected to a positive pressure air source and a negative pressure air source via different air pipes 900, respectively, to enable inflation and deflation. The support cavity 200 is provided with a support cavity electrical contact 230; one end of the support cavity electrical contact 230 located outside the support cavity 200 is electrically connected to a power source and / or a signal source, and the other end of the support cavity electrical contact 230 located inside the support cavity 200 is electrically connected to the mounting base electrical contact 320 via a wire 1000. The support cavity 200 is provided with an access component 260, which increases the contact area between the support cavity ventilation interface 220 and the support cavity 200 to improve the stability and airtightness of the connection; the access component 260 is airtightly connected to the support cavity 200, and the access component 260 is fixedly provided with the support cavity ventilation interface 220, the support cavity electrical contact 230, and the first airflow control device mounting structure 270. The first airflow control device mounting structure 270 is used for repeatedly detaching and installing the support cavity airflow control device 1300 when needed. The support cavity 200 is provided with a first receiving portion 210, and the mounting base 300 is housed inside the first receiving portion 210, so that the rigid mounting base 300 is wrapped with a soft inflatable cavity, thereby making it safer for children to play on. The load-bearing structure of the support cavity is configured to support the weight of the player when inflated, and is provided with a space structure sized to allow the player to play on it. The support cavity 200 can be fixed to the ground or be used as an inflatable toy. When the support cavity 200 is fixed to the ground, it can support the weight of the player and allow the player to move on the support cavity 200, so that the player maintains a safe distance between the support cavity 200 and the ground. In addition, the support cavity 200 can also be used as a driven inflatable toy 800.
[0089] The mounting base 300 includes a mounting base ventilation port 320 and a mounting base electrical contact 320. One end of the mounting base ventilation port 320 is connected to the air source 100, and the other end is connected to the first air guide port 410, for transmitting gas to the drive device 1900. One end of the mounting base ventilation port 320 is located inside the support cavity 200 and extends out of the support cavity 200 through the air pipe 900 to communicate with the air source 100. The other end of the mounting base ventilation port 320 is located outside the support cavity 200. There are at least two mounting base ventilation ports 320, with at least two mounting base ventilation ports 320 forming a pair, respectively connected to a positive pressure air source and a negative pressure air source, so as to realize the functions of inflation and deflation respectively. A second airflow control device mounting structure 370 is provided at the mounting base ventilation port 320 for repeatedly detaching and installing the air guide airflow control device 1800 as needed. The inflatable toy also includes an airflow control device 1800 mounted on the second airflow control device mounting structure 370. The airflow control device 1800 is connected between the mounting base air inlet 320, the first air inlet 410, and the power air outlet 451. Specifically, the airflow control device 1800 employs two distributors. Each mounting base air inlet 320 is connected to the first air inlet 410 and the power airflow control device 1700 respectively through a distributor, for diverting the gas in the mounting base air inlet 320 to the first air inlet 410 and the power air outlet 451. One end of the mounting base electrical contact 320 is located inside the support cavity 200 and is electrically connected to a power source and / or signal source via a wire 1000 passing through the support cavity 200. The other end of the mounting base electrical contact 320 is electrically connected to the first electrical contact 430 of the moving mechanism, for transmitting current or electrical signals to the moving mechanism 400. Mounting base 300 is a first recessed structure 310, and the drive device 1900 is at least partially housed within the first recessed structure 310 to improve safety and aesthetics. Mounting base 300 and drive device 1900 are detachably connected.
[0090] The drive device 1900 includes a mounting head 500, a movable mechanism 400, and a first docking member 4110. The movable mechanism 400 is fixedly or repeatedly detachably connected to the mounting base 300 via the mounting head 500. The mounting head 500 can adopt a threaded, snap-fit, or interference fit connection structure. The movable mechanism 400 is provided with an action output end 460, which is located on the side of the movable mechanism 400 adjacent to or opposite to the mounting head 300, for coupling with the driven gas toy 800 to realize the gas toy 800 moving according to a set action. The movable mechanism 400 includes a first air inlet 410 and a second air inlet 420. One end of the first air inlet 410 is connected to the second air inlet 420, and the other end is connected to the air source 100 via the mounting base 300. There are two or more first air inlets 410, with at least two first air inlets 410 forming a pair, respectively connected to a positive pressure air source and a negative pressure air source, for inflation and deflation respectively. A second air inlet 420 is located at or near the action output end. One end of the second air inlet 420 is connected to the first air inlet 410 via an air passage 4100, and the other end is used to deliver gas from the air source 100 to the inflatable toy 800 or other objects besides the inflatable toy 800. There are at least two air passages 4100, with at least two first air inlets 410 and two second air inlets 420. Each air passage 4100 has its two ends connected to its respective first air inlet 410 and second air inlet 420, with at least two air passages forming a pair. One of these two air passages 4100 is used to inflate the inflatable toy 800, and the other is used to deflate it. The actuating mechanism 400 includes a power unit 450, which provides driving force to the actuation output end 460. The power unit 450 is a pneumatic power unit and has a power air port 451. A power unit airflow control device 1700 is installed at the power air port 451. The power unit airflow control device 1700 is specifically an air valve and is connected between the power air port 451 and the airflow control device 1800 to supply gas from the air source 100 to the power unit. The actuating mechanism 400 also includes a first electrical contact 430, which is electrically connected to a power source and / or signal source via a mounting base electrical contact 320 to introduce current and / or electrical signals into the actuating mechanism 400. The motion output terminal 460 also includes a second electrical contact 440 of the motion mechanism. One end of the second electrical contact 440 of the motion mechanism is electrically connected to the first electrical contact 430 of the motion mechanism, and the other end is used to electrically connect to the gas toy 800 or other objects other than the gas toy 800, so as to supply power or transmit electrical signals to the gas toy 800 or other objects other than the gas toy 800.The activity mechanism 400 includes a first motion conversion component 470. One end of the first motion conversion component 470 is fixedly or removably connected to the power device 450, and the other end is provided with a motion output end 460. The motion output end 460 is coupled to the gas toy 800. The first motion conversion component 470 is used to convert the power motion mode and state generated by the power device 450 into the required motion mode and state to drive the motion output end 460. The power motion mode includes motion direction, amplitude, and frequency. The first docking component 4110 is mounted on the movable mechanism 400. The first docking component 4110 is fixedly installed and does not move with the action output end 460. The second air inlet 420 and the second electrical contact 440 of the movable mechanism are both mounted on the first docking component 4110. The first action conversion component 470 is not connected to the first docking component 4110. The first docking component 4110 and the second docking component 700 are fixedly or repeatedly detached and reassembled. The detachable and repeatedly detachable connection can be achieved by threaded or snap-fit connection. When the first docking component 4110 and the second docking component 700 are docked, the second air inlet 420 is simultaneously docked with the air inlet 710 of the gas toy, the second electrical contact 440 of the movable mechanism is docked with the electrical contact 720 of the gas toy, and the first action conversion component 470 is docked with the second action conversion component 750, thereby improving the convenience, firmness and reliability of docking.
[0091] The gas toy 800 includes a body 820, an action receiving end 830, a second docking member 700, a gas toy air inlet 710, a gas toy electrical contact 720, a second action conversion component 750, and a gas toy airflow control device 1600. The action receiving end 830 is disposed on the body 820 and is coupled to the action output end 460 to receive driving force from the action output end 460 to drive the body 820 to move. The gas toy air inlet 710 is disposed on or near the action receiving end 830. One end of the gas toy air inlet 710 is connected to the second air inlet 420 to receive gas from the gas source 100, and the other end is connected to the body 820 to supply and evacuate gas from the body 820. The main body 820 includes an inflatable cavity, which is a soft and deformable inflatable cavity, and its interior is connected to the air vent 710 of the gas toy. The air flow control device 1600 of the gas toy is fixedly or repeatedly detached and connected to the air vent 710 of the gas toy, and is used to control the flow direction and / or flow rate of the gas flowing through it. When the gas toy 800 includes multiple main bodies 320, the air vent 710 of the gas toy supplies air and evacuates air to multiple main bodies 820 independently and in a time-sharing manner through one air flow control device 1600. The airflow control device 1600 for the gas toy specifically employs a solenoid valve. Positive and negative pressure air sources are connected to the main body 820 via air pipes 900, which sequentially pass through the support cavity 200, mounting base 300, and movable mechanism 400. The main body 820 is inflated or deflated via the air pipes 900, and the airflow control device 1600 controls the direction and / or flow rate of the gas between the main body 820 and the gas toy's air inlet, thereby enabling the movement of the main body 820. A second docking member 700 is disposed on the action receiving end 830 and is used to connect to the first docking member 4110 and mounting base 300 in a fixed or removable manner to increase the stability of the connection between the gas toy and the movable mechanism. The second docking member 700 is a second recessed structure 760, which at least partially accommodates the action receiving end 830 within the second recessed structure 760, preventing the action receiving end 830 from being directly seen or touched from the outside. One end of the gas toy's electrical contact 720 is electrically connected to the second electrical contact 440 of the moving mechanism, and the other end is electrically connected to the gas toy's airflow control device 1600 and the entertainment auxiliary device 1100 provided on the main body 820, respectively. The gas toy's electrical contact 720 is used to transmit current and / or electrical signals between itself and the second electrical contact 440 of the moving mechanism, thereby supplying power to the entertainment auxiliary device 1100 and the gas toy's airflow control device 1600 on the gas toy 800 or transmitting electrical signals.The motion receiving end 830 is connected to the main body 820 via the second motion conversion component 750. The second motion conversion component 750 and the first motion conversion component 470 are detachably replaceable. The second motion conversion component 750 is used to convert the power motion mode and state received by the motion receiving end 830 into the required motion mode and state to drive the main body 820 to move. The inflatable toy 800 may also be equipped with any one or more of the following: plush toys, plastic items, electric items, soft items, light-emitting items, sound-emitting items, pneumatic items, and electronic products, or any combination thereof. The inflatable toy 800 is mounted on the inflatable toy via the moving mechanism 400 and is driven by the moving mechanism 400. The same driving device 1900 can drive two or more inflatable toys 800 simultaneously. Furthermore, the main body 820 may also be equipped with an inflation chamber that can accept independent inflation and deflation.
[0092] The inflatable toy also includes other cavities 1400 that are fixedly or repeatedly detached from the support cavity 200. The connection between the support cavity 200 and other cavities 1400 is one of the following: heat sealing, adhesive bonding, connection via air pipe 900, connection via connector, connection via air valve, or connection via pneumatic or electric device. The support cavity 200 and other cavities 1400 are respectively connected to the air source 100 via different air pipes 900, and can be independently and time-divided for inflation / deflation.
[0093] The inflatable toy also includes an entertainment auxiliary device 1100, which is disposed on the support cavity 200 and / or the inflatable toy 800 and is connected to a power source via a wire 1000 or to an air source 100 via an air tube 900. The entertainment auxiliary device 1100 can be any one or more of the following: projector, bubble blower, paper sprayer, smoke sprayer, ball blower, water sprayer, magnetic device, heating nozzle, AR environmental sensing camera, projection screen, display screen, LED light, projection spotlight, moving load-bearing component, electrostatic generator, multi-functional balloon, ordinary camera, speaker, audio device, additional toy, ultraviolet disinfection device, plasma disinfection device, inflatable cavity, electromechanical device, and pneumatic device.
[0094] The airflow control device 1300 for the support cavity, the airflow control device 1600 for the air toy, the airflow control device 1700 for the power unit, and the airflow control device 1800 for the air guide can be any one or a combination of two or more of the following, depending on the specific application requirements: air valve (group), multi-way distributor, one-way valve, and plug.
[0095] The working process of this embodiment:
[0096] 1. Install the drive unit 1900 on the mounting base 300 and connect the various air pipes 900 and wires 1000 in the system. Various airflow control devices can be installed in the corresponding positions according to the application scenario.
[0097] 2. The support cavity 200, other cavities 1400, and inflatable toy 800 are connected to the air source 100 through different air pipes 900, and can be independently and time-divided for inflation / deflation. By using the air source 100 to inflate and deflate them respectively, the inflatable toy presents a dynamic changing effect.
[0098] 3. The air source 100 controls the power device 450 to work through the air pipe 900. The first action conversion component 470 converts the telescopic motion mode of the power output by the power device 450 into the swing motion mode. Then, the second action conversion component 750 drives the gas toy 800 to move. The second air inlet 420 controls the inflation and deflation of the gas toy 800 through the gas toy airflow control device 1600.
[0099] 4. The power supply is provided through the wire 1000 to the support cavity 200 and / or the various entertainment auxiliary devices 1100 on the inflatable toy 800, so that the inflatable toy can light up or make sounds while performing multiple actions, so as to achieve a richer and more dynamic interactive effect of the inflatable toy.
[0100] 5. When it is necessary to change the application scenario of the inflatable toy, or to replace or repair the drive device 1900, simply remove the drive device 1900 from the mounting base 300, replace and assemble it, and then reinstall it on the mounting base 300 to achieve the change of application scenario and the repair or replacement of the drive device 1900.
[0101] Example 2
[0102] To enhance the flexibility and applicability of the drive device 1900, this embodiment removes other cavities 1400 based on embodiment 1, and removes the airflow control device 1600 and the second action conversion component 750 from the air toy 800. The drive device 1900 adopts a different structure.
[0103] like Figure 3 As shown in the figure, this embodiment discloses an inflatable toy, which includes a support cavity 200, a mounting base 300, a driving device 1900, an air-operated toy 800, and an entertainment auxiliary device 1100.
[0104] in:
[0105] The drive unit 1900 includes a mounting head 500 and a movable mechanism 400. The movable mechanism 400 is fixedly or removably connected to the mounting base 300 via the mounting head 500. The movable mechanism 400 includes an action output end 460, a first docking member 4110, a first air inlet 410, a second air inlet 420, a first electrical contact 430, a second electrical contact 440, a first action conversion component 470, and a power unit airflow control device 1700. The action output end 460 is used to couple with the action receiving end 830 to realize the movement of the gas toy 800 according to a set action. The first motion conversion component 470 drives the motion output end 460 to move. The first docking part 4110 is set on the motion output end 460. The first docking part 4110 adopts a movable installation method, which can make the gas toy 800 move together with it under the drive of the motion output end 460. The second air inlet 420 and the second electrical contact 440 of the movable mechanism are both set on the first docking part 4110 and move together with the first docking part 4110. The first docking part 4110 and the second docking part 700 are repeatedly detached and connected. When the first docking part 4110 and the second docking part 700 are docked, the second air inlet 420 is docked with the gas toy's air inlet 710 and the second electrical contact 440 of the movable mechanism is docked with the gas toy's electrical contact 720, which improves the convenience, firmness and reliability of docking. The air passage 4100 connecting the first air inlet 410 and the second air inlet 420, and the wire 1000 connecting the first energized contact 430 and the second energized contact 440 of the moving mechanism are all located inside the first motion conversion component 470 and cannot be observed or touched from the outside.
[0106] One end of the second air inlet 420 is connected to the first air inlet 410 via an air passage 4100, and the other end is used to deliver gas from the gas source 100 to the gas-using toy 800 or other objects besides the gas-using toy 800. There are two air passages 4100, and at least two of each of the first air inlet 410 and the second air inlet 420. The two ends of each air passage 4100 are respectively connected to their respective first air inlet 410 and second air inlet 420. An airflow control device 1800 is connected between the first air inlet 410, the mounting base air inlet 320, and the power device airflow control device 1700. The airflow control device 1800 includes an air valve and two distributors. Two mounting base air inlets are provided on the mounting base 300. Each mounting base air inlet 320 is connected to an air valve and a power device airflow control device 1700 respectively through a gas distributor. The other end of the air valve is connected to the first air guide inlet 410. Each air channel can both inflate and de-inflate the air toy 800. In this embodiment, the air toy airflow control device is not required. The air guide airflow control device 1800 alone can be used to inflate and de-inflate the two bodies 820 in a time-sharing and independent manner, thereby realizing the movement of the bodies 820.
[0107] The active mechanism 400 includes a power unit 450, which provides driving force to the action output end 460. The power unit 450 is a pneumatic power unit, specifically a cylinder. The pneumatic power unit has two power air ports 451. A power unit airflow control device 1700 is installed at the power air ports 451. The power unit airflow control device 1700 is specifically an air valve. The power unit airflow control device 1700 is connected between the power air ports 451 and the gas distributor of the airflow control device 1800, and is used to control the direction and flow rate of the gas flowing through the power air ports 451. Each power air port 451 is connected to a positive pressure air source and a negative pressure air source through the power unit airflow control device 1700, so as to realize the charging and depressurization of the pneumatic power unit respectively.
[0108] The inflatable toy 800 includes a main body 820, an action receiving end 830, a second docking member 700, an inflatable toy air inlet 710, and an inflatable toy electrical contact 720. The main body 820 includes two inflatable cavities, which are soft and deformable inflatable cavities, and their interiors are connected to the inflatable toy air inlet 710. There are at least two inflatable toy air inlets 710, and each inflatable toy air inlet 710 is connected to a corresponding second air inlet 420 to enable inflation and deflation of each main body 820, thereby enabling the movement of the main body 820.
[0109] A first airflow control device mounting structure 270 is provided on the access piece 260 at the air vent 220 of the support cavity, for installing the required airflow control device 1300 of the support cavity according to the usage needs. In this embodiment, the airflow control device 1300 of the support cavity is specifically an air valve (group). The air vent 220 of the support cavity is connected to the interior of the support cavity 200 and the air vent 320 of the mounting seat through the airflow control device 1300, for controlling the flow direction and / or flow rate of the gas flowing through it.
[0110] The working process of this embodiment:
[0111] 1. Install the drive unit 1900 on the mounting base 300 and connect the air pipes 900 and wires 1000 in the system. The required airflow control device can be installed according to the application scenario.
[0112] 2. The support cavity 200 and the inflatable toy 800 are connected to the air source 100 through different air pipes 900, and can be independently and time-divided for inflation / deflation. By using the air source 100 to inflate and deflate them respectively, the inflatable toy presents a dynamic changing effect.
[0113] 3. The power device 450 is controlled by the air source 100 through the air pipe 900. The first action conversion component 470 converts the telescopic motion mode of the power output by the power device 450 into the swing motion mode, which then drives the first docking member 4110 to move. The first docking member 4110 then drives the main body 820 to move through the second docking member 700.
[0114] 4. The power supply is provided through the wire 1000 to the support cavity 200 and / or the various entertainment auxiliary devices 1100 on the inflatable toy 800, so that the inflatable toy can light up or make sounds while performing multiple actions, so as to achieve a richer and more dynamic interactive effect of the inflatable toy.
[0115] 5. When it is necessary to change the application scenario of the inflatable toy, or to replace or repair the drive device 1900, simply remove the drive device 1900 from the mounting base 300, replace and assemble it, and then reinstall it on the mounting base 300 to achieve the change of application scenario and the repair or replacement of the drive device 1900.
[0116] Example 3
[0117] To enhance the flexibility and applicability of the drive device 1900, this embodiment adopts a different structure for the drive device 1900 based on Embodiment 2. In this embodiment, the pneumatic toy is also the support cavity 200 itself; that is, the support cavity 200 is driven to move by the drive device 1900.
[0118] like Figure 4 As shown in the figure, an inflatable toy disclosed in this embodiment includes a support cavity 200, a mounting base 300, and a driving device 1900.
[0119] The mounting base 300 is disposed on the support cavity 200 (horse belly), and the second docking member 700 is disposed on the support cavity 200 (horse leg); the drive device 1900 includes a mounting head 500 and an actuating mechanism 400, the actuating mechanism 400 being fixedly or repeatedly detachably connected to the mounting base 300 via the mounting head 500; the actuating mechanism 400 includes an action output end 460, a first docking member 4110, and a power device 450. The action output end 460 is coupled to the action receiving end 830 to drive its swing. The power device 450 is specifically an inflatable cavity. The power device 450 drives the action output end 460 to move. The first docking member 4110 is set on the action output end 460 and moves together with the action output end 460. The first docking member 4110 and the second docking member 700 are fixedly or repeatedly detached and assembled. One end of the second docking member 700 is hinged to the mounting base 300. As the volume of the power device 450 increases or decreases, the included angle between the second docking member 700 and the mounting base 300 gradually increases or decreases, thereby achieving the effect of supporting the swing of the cavity 200 (horse leg).
[0120] Example 4
[0121] To enhance the flexibility and applicability of the drive device 1900 and facilitate its application to air toys 800 that are far from the support cavity 200, this embodiment divides the mounting base 300 into a first mounting base 301 and a second mounting base 302 based on embodiment 2. Furthermore, both the air pipe 900 and the wire 1000 are movable and retractable, and the drive device 1900 adopts a different structure.
[0122] like Figure 5 As shown, this embodiment discloses an inflatable toy, which includes a support cavity 200, a mounting base 300, a drive device 1900, an inflatable toy 800, and an entertainment auxiliary device 1100; the support cavity 200 is disposed on the top of the housing cavity, wherein:
[0123] The drive unit 1900 includes a mounting head 500 and a moving mechanism 400, which is fixedly or removably connected to the mounting base 300 via the mounting head 500. The action output end 460 is used to couple with the action receiving end 830 to realize the movement of the gas toy 800 according to the set action.
[0124] The mounting base 300 is divided into a first mounting base 301 and a second mounting base 302. The first mounting base 301 is set on the support cavity 200, and the second mounting base 302 is set at a designated position far away from the support cavity 200. The air tube 900 / electrical cable 1000 connecting the mounting base 300 and the drive device 1900 has a reserved length and a movable pull-out structure, so that the movable mechanism 400 can be removed from the mounting base 300 as needed during play. The electrical cable 1000 can be a spiral electrical cable 1000, and the air tube 900 can be a spiral air tube 900, so that the drive device 1900 can be detached from the first mounting base 301 and pulled to the second mounting base 302.
[0125] The gas toy 800 includes a body 820, an action receiving end 830, a second docking member 700, a gas toy vent 710, and a gas toy electrical contact 720. The body 820 is an inflatable cavity and is located at a position far from the supporting cavity 200. The body 820 has an inwardly recessed second receiving portion 810, in which the action receiving end 830 is received. The action receiving end 830 is disposed on the second docking member 700 and is used to couple with the action output end 460. The gas toy vent 710 and the gas toy electrical contact 720 are disposed on the second docking member 700.
[0126] The working process of this embodiment:
[0127] 1. Install the drive unit 1900 on the first mounting base 301 and connect the air pipes 900 and wires 1000 in the system.
[0128] 2. When it is necessary to change the game scene and connect the drive device 1900 to the gas toy 800 which is far away from the support cavity 200, remove the drive device 1900 from the first mounting base 301, install it on the second mounting base 302, and connect it to the gas toy 800 to drive the gas toy 800 to extend and retract.
[0129] 3. The support cavity 200 and the main body 820 are connected to the air source 100 through different air pipes 900, and can be independently and time-divided for inflation / deflation. By using the air source 100 to inflate and deflate them respectively, the inflatable toy can present a dynamic changing effect.
[0130] 4. The power device 450 is controlled by the air source 100 through the air pipe 900, and the power device 450 drives the air toy 800 to move through the second docking part 700.
[0131] 5. The power supply is provided to the various entertainment auxiliary devices 1100 on the support cavity 200 or the main body 820 through the power cord 1000, so that the inflatable toy can light up or make sounds while performing multiple actions, so as to achieve a richer and more dynamic interactive effect of the inflatable toy.
[0132] 6. When it is necessary to change the application scenario of the inflatable toy, or to replace or repair the drive device 1900, remove the drive device 1900 from the first mounting base 301 or the second mounting base 302, replace and assemble it, and then reinstall it on the first mounting base 301 or the second mounting base 302. This will enable the application scenario to be changed and the drive device 1900 to be repaired or replaced.
[0133] Example 5
[0134] In order to increase the entertainment scenarios of inflatable toys and enable the inflatable toy 800 to move longitudinally and laterally, thereby achieving richer and more complex dynamic effects, this embodiment replaces the drive device 1900 of embodiment 4 with another structure. The drive device 1900 includes two power devices 450.
[0135] like Figure 6 As shown in the figure, this embodiment discloses an inflatable toy, which includes a support cavity 200, a mounting base 300, a driving device 1900, an air-operated toy 800, and an entertainment auxiliary device 1100.
[0136] The drive device 1900 includes a mounting head 500 and a moving mechanism 400. The moving mechanism 400 includes a power unit 450, which includes a cylinder and a bellows. The bottom of the bellows is mounted on the mounting base 300, and the top is mounted on the cylinder. The cylinder rod is the action output end 460, which is connected to the air toy 800 and drives the air toy 800 to move. The air pipe 900 passes through the support cavity 200 and is connected to the inside of the bellows and the gas input end of the cylinder. The gas input end of the cylinder is equipped with an air valve. The air source 100 charges and depresses the power unit 450 through the air pipe 900, thereby changing the height of the drive device 1900 and driving the air toy 800 to extend and retract.
[0137] The working process of this embodiment:
[0138] 1. Install the drive unit 1900 on the mounting base 300 and connect all the air pipes 900 and wires 1000 in the system;
[0139] 2. Using air source 100, air is supplied to support cavity 200, power device 450 and air toy 800 through air pipe 900, causing bellows to expand and contract. When bellows extends, air toy 800 rises together with the cylinder connected to the upper end of bellows. By controlling the cylinder, air toy 800 is driven to perform lateral expansion and contraction, thereby achieving complex dynamic change effects of air toy 800.
[0140] 3. The power supply is provided to the entertainment auxiliary device 1100 through the power cord 1000. The inflatable toy 800 can perform a variety of actions while also emitting light or sound, so as to achieve a richer and more dynamic interactive effect of the inflatable toy.
[0141] 4. When it is necessary to change the application scenario of the inflatable toy, or to replace or repair the drive device 1900, remove the drive device 1900 from the mounting base 300, replace and assemble it, and then reinstall it on the mounting base 300. This will enable the application scenario to be changed and the drive device 1900 to be repaired or replaced.
[0142] Example 6
[0143] In order to increase the entertainment scenarios of inflatable toys and achieve the dynamic launching effect of inflatable toy 800, this embodiment replaces the drive device 1900 in embodiment 5 with another structure, using only a corrugated pipe as the power device 450.
[0144] like Figure 7 As shown in the figure, an inflatable toy disclosed in this embodiment includes a support cavity 200, a mounting base 300, a driving device 1900, and an air-operated toy 800;
[0145] The drive device 1900 includes a mounting head 500 and a movable mechanism 400. The movable mechanism 400 is a structure that can change its external shape. The movable mechanism 400 includes a power unit 450, which is a bellows. Its external shape can be changed by inflating or deflating the bellows. The bottom of the power unit 450 is mounted on the mounting base 300, and the top of the power unit 450 is provided with an action output end 460. It is non-fixedly connected to the gas toy 800. The air pipe 900 passes through the support cavity 200 and enters the interior of the power unit 450. Then the gas passes through the power unit 450 and enters the gas toy 800. The air source 100 inflates or deflates the power unit 450 through the air pipe 900, and also provides air to the gas toy 800. The power unit 450 and the gas toy 800 are non-fixedly connected. When the gas toy 800 is ejected by the power unit 450, the power unit 450 can automatically separate from the gas toy 800.
[0146] In this embodiment, the power unit 450 can also be other pushing devices with ejection function besides bellows.
[0147] The working process of this embodiment:
[0148] 1. Install the drive unit 1900 on the mounting base 300 and connect all the air pipes 900 in the system;
[0149] 2. Using air source 100, air is supplied to support cavity 200 and air toy 800 through air pipe 900 respectively. Then, air is supplied to power device 450 (i.e. bellows) through air pipe 900, causing it to expand and contract. After the bellows is inflated, it extends and provides a pushing force to air toy 800, which is then ejected, realizing the dynamic change of ejection.
[0150] 3. When it is necessary to change the application scenario of the inflatable toy, or to replace or repair the drive device 1900, remove the drive device 1900 from the mounting base 300, replace and assemble it, and then reinstall it on the mounting base 300. This will enable the application scenario to be changed and the drive device 1900 to be repaired or replaced.
[0151] Example 7
[0152] To increase the entertainment scenarios of inflatable toys, the power unit 450 can be either pneumatically driven or electrically driven, so that the appropriate moving mechanism 400 can be adopted according to different usage scenarios of inflatable toys. In this embodiment, the power unit 450 of embodiment 6 is replaced with an electric power unit.
[0153] like Figure 8 As shown in the figure, an inflatable toy disclosed in this embodiment includes a support cavity 200, a mounting base 300, a driving device 1900, and an air-operated toy 800;
[0154] The support cavity 200 has a 7-shaped or arch-shaped structure. The mounting base 300 is located on the top of the support cavity 200 with its opening facing downwards. The drive device 1900 is mounted on the support cavity 200 through the mounting base 300. The drive device 1900 and the second docking member 700 are detachably connected. The inflatable toy 800 is hung below the drive device 1900, and the drive device 1900 drives the inflatable toy 800 to move up and down.
[0155] The drive device 1900 includes a mounting head 500 and a movable mechanism 400. The movable mechanism 400 includes a power unit 450, which is specifically an electric reel. The rope on the electric reel is connected to the inflatable toy 800, enabling the dynamic effect of raising and lowering the inflatable toy 800. To facilitate the free raising and lowering of the inflatable toy 800 with the help of the rope, the lengths of the wire 1000 and the air tube 900 are extendable, providing air and power to the inflatable toy 800. In addition, this embodiment can also use pulleys, or it can use two or more movable mechanisms 400 working together to present richer and more complex dynamic movement effects of the inflatable toy 800.
[0156] The working process of this embodiment:
[0157] 1. Install the drive unit 1900 on the mounting base 300 and connect all the air pipes 900 and wires 1000 in the system;
[0158] 2. The air source 100 is used to inflate and deflate the support cavity 200 and the air toy 800 through the air pipe 900 respectively. The power supply is provided to the electric winding machine through the wire 1000. The electric winding machine moves up and down when lifting the air toy 800 by winding and unwinding the rope, so as to achieve the dynamic effect of lifting and lowering the air toy 800.
[0159] 3. The power supply provides power to each entertainment auxiliary device 1100 through the power cord 1000. The inflatable toy 800 can perform multiple actions while also emitting light or sound, so as to achieve a richer and more dynamic interactive effect of the inflatable toy.
[0160] 4. When it is necessary to change the application scenario of the inflatable toy, or to replace or repair the drive device 1900, remove the drive device 1900 from the mounting base 300, replace and assemble it, and then reinstall it on the mounting base 300. This will enable the application scenario to be changed and the drive device 1900 to be repaired or replaced.
[0161] Example 8
[0162] In order to increase the entertainment scenarios of inflatable toys and achieve the dynamic effect of rotating the inflatable toy 800 at a specified height, this embodiment replaces the mounting base 300 and the drive device 1900 in embodiment 7 with another structure.
[0163] like Figure 9 As shown in the figure, an inflatable toy disclosed in this embodiment includes a support cavity 200, a mounting base 300, a driving device 1900, and an air-operated toy 800;
[0164] The mounting base 300 has a structure with an adjustable external shape. The height of the mounting base 300 is telescopic and adjustable, and the height adjustment of the mounting base 300 can be electric, pneumatic, or manual. The drive device 1900 includes a mounting head 500 and a movable mechanism 400. The movable mechanism 400 includes a power device 450, which is an electric power device, specifically a geared motor. The motor shaft of the geared motor is connected to the gas toy 800 and drives the gas toy 800 to rotate, so as to achieve the dynamic effect of the gas toy 800 rotating at a specified height. In order to be suitable for mounting bases 300 of different heights, the lengths of the wire 1000 and the air tube 900 are telescopic and adjustable, providing air and power sources for the gas toy 800.
[0165] The air tube 900 and the wire 1000 are connected to the air toy 800. To prevent the air toy 800 from failing to rotate due to the pulling of the air tube 900 and the wire 1000 when the power device 450 drives the air toy 800 to rotate, a rotary joint is provided on the air toy 800 in this embodiment, so that the air tube 900 and the wire 1000 both pass through the rotary joint.
[0166] The working process of this embodiment:
[0167] 1. Install the drive unit 1900 on the mounting base 300 and connect all the air pipes 900 and wires 1000 in the system;
[0168] 2. Using air source 100, air is supplied to support cavity 200 and air toy 800 through air pipe 900. Power is supplied to power device 450 through wire 1000. The height of air toy 800 is adjusted through mounting base 300. Then power device 450 (gear motor) drives air toy 800 to rotate, achieving the dynamic effect of air toy 800 rotating at a specified height.
[0169] 3. The power supply provides power to each entertainment auxiliary device 1100 through the power cord 1000. The inflatable toy 800 can perform multiple actions while also emitting light or sound, so as to achieve a richer and more dynamic interactive effect of the inflatable toy.
[0170] 4. When it is necessary to change the application scenario of the inflatable toy, or to replace or repair the drive device 1900, remove the drive device 1900 from the mounting base 300, replace and assemble it, and then reinstall it on the mounting base 300. This will enable the application scenario to be changed and the drive device 1900 to be repaired or replaced.
[0171] Example 9
[0172] In order to change the power output mode of the power device 450 from telescopic to rotational drive mode, so as to make it suitable for various entertainment use scenarios of inflatable toys and improve the compatibility of the power device 450, this embodiment replaces the drive device 1900 in embodiment 6 with another structure, and the moving mechanism 400 also includes a first motion conversion component 470 that is detachably connected to the power device 450.
[0173] like Figures 10 to 11 As shown in the figure, this embodiment discloses an inflatable toy, which includes a support cavity 200, a mounting base 300, a driving device 1900, and an air-operated toy 800.
[0174] The driving device 1900 includes a mounting head 500 and a movable mechanism 400. The movable mechanism 400 includes a power unit 450 and a first motion conversion component 470. The power unit 450 is a cylinder. One end of the first motion conversion component 470 is detachably connected to the power unit 450, such as using a snap-fit connection, threaded connection, or interference fit connection. The other end of the first motion conversion component 470 is provided with a motion output end 460, which is detachably connected to the inflatable toy 800, such as using a snap-fit connection, threaded connection, or interference fit connection. The first motion conversion component 470 is used to convert the motion mode of the power output by the power unit 450 into the required motion mode to drive the inflatable toy 800. In this embodiment, the motion mode conversion is to convert the telescopic motion into rotational motion, thereby driving the inflatable toy 800 to rotate, achieving the dynamic effect of the inflatable toy 800 rotating.
[0175] Specifically, the first motion conversion assembly 470 includes a push rod 471, a sliding sleeve 472, a bolt 473, a guide post 474, and a rotating shaft 475; one end of the rotating shaft 475 is connected to the central axis of the guide post 474, and the other end is provided with a motion output end 460, which is repeatedly detached and reassembled with the inflatable toy 800; the outer surface of the guide post 474 is provided with a wave-shaped groove, which is connected end to end to form a closed-loop guide rail; the sliding sleeve 472 is fitted onto the outside of the guide post 474, and the bolt 473 is threadedly connected to the sliding sleeve 472 and extends through the sliding sleeve 472 into the wave-shaped groove. The bolt 473 slides along the wave-shaped groove, and the up and down movement of the sliding sleeve 472 can drive the guide post 474 to rotate through the bolt 473; one end of the push rod 471 is connected to the central axis of the sliding sleeve 472, and the other end is repeatedly detached and reassembled with the power device 450; in addition, in this embodiment, there are two bolts 473, which are symmetrically arranged on the sliding sleeve 472. The first motion conversion component 470 is used to convert the motion mode of the power output by the power device 450 into the required power motion mode to drive the gas toy 800. In this embodiment, the motion mode conversion is to convert the telescopic motion into rotational motion, and drive the gas toy 800 to rotate, so as to achieve the dynamic effect of the gas toy 800 rotating.
[0176] The working process of this embodiment:
[0177] 1. Install the drive unit 1900 on the mounting base 300 and connect all the air pipes 900 and wires 1000 in the system;
[0178] 2. Using air source 100, air is supplied to support cavity 200 and air toy 800 through air pipe 900 respectively. Then, the power device 450 is controlled to perform telescopic movement through air pipe 900. The telescopic movement of power device 450 is converted into rotational movement suitable for this game scene through first action conversion component 470, and the air toy 800 is driven to achieve rotational movement.
[0179] 3. The power supply is provided to the various entertainment auxiliary devices 1100 on the inflatable toy 800 through the power cord 1000. While performing multiple actions, the inflatable toy 800 can also light up or make sounds, so as to achieve a richer and more dynamic interactive effect for the inflatable toy.
[0180] 4. When it is necessary to change the application scenario of the inflatable toy and drive the inflatable toy 800 in a swinging manner, the first motion conversion component 470 is removed from the power unit 450 and replaced with another first motion conversion component 470 whose power output mode is swinging motion, so as to realize the device switching.
[0181] 5. When it is necessary to change the application scenario of the inflatable toy and drive the inflatable toy 800 in a telescopic manner, the first action conversion component 470 is removed from the power unit 450 and the power unit 450 is directly connected to the inflatable toy 800 to realize the device switching.
[0182] 6. When it is necessary to replace or repair the drive unit 1900, remove the drive unit 1900 from the mounting base 300, replace and assemble it, and then reinstall it on the mounting base 300 to achieve the repair and replacement of the drive unit 1900.
[0183] Example 10
[0184] In order to change the power output mode of the power device 450 from telescopic to swinging, so as to make it suitable for various entertainment use scenarios of inflatable toys and improve the compatibility of the power device 450, this embodiment replaces the first action conversion component 470 in embodiment 9 with another structure.
[0185] like Figures 12 to 13 As shown in the figure, this embodiment discloses an inflatable toy, which includes a support cavity 200, a mounting base 300, a driving device 1900, and an air-operated toy 800.
[0186] The drive unit 1900 includes a mounting head 500 and a moving mechanism 400. The moving mechanism 400 includes a power unit 450 and a first action conversion component 470. The power unit 450 is a cylinder.
[0187] Specifically, the first motion conversion assembly 470 includes a push rod 471, a sliding sleeve 472, and a swing rod 476; the sliding sleeve 472 is fitted over the swing rod 476 and can slide along the swing rod 476; one end of the push rod 471 is hinged to the sliding sleeve 472, and the other end is detachably connected to the power unit 450; the swing rod 476 has a 7-shaped structure, with its corners being hinge points, one end of the swing rod 476 is connected to the sliding sleeve 472, and a limiting block 477 is provided at the end to prevent the sliding sleeve 472 from sliding out of the swing rod 476. 76. The other end of the swing arm 476 is provided with a power action output end 460, which is repeatedly detached and reassembled with the gas toy 800; the first action conversion component 470 is used to convert the motion mode of the power output by the power device 450 into the required power motion mode to drive the gas toy 800. In this embodiment, the motion mode conversion is to convert the telescopic motion into the swing motion, and drive the gas toy 800 to swing, so as to achieve the dynamic effect of the gas toy 800 swinging.
[0188] The working process of this embodiment:
[0189] 1. Install the moving mechanism 400 on the mounting base 300, and connect all the air pipes 900 and wires 1000 in the system;
[0190] 2. Using air source 100, air is supplied to support cavity 200 and air toy 800 through air pipe 900 respectively. Then, the power device 450 is controlled to perform telescopic movement through air pipe 900. The power device 450 converts telescopic movement into swinging movement suitable for this game scene through first action conversion component 470, and drives air toy 800 to achieve swinging movement.
[0191] 3. The power supply provides power to the electrical appliances 1100 on the inflatable toy 800 through the power cord 1000. While performing multiple actions, the inflatable toy 800 can also emit light or sound, so as to achieve a richer and more dynamic interactive effect for the inflatable toy.
[0192] 4. When it is necessary to change the application scenario of the inflatable toy, the inflatable toy 800 needs to be driven by rotation. The first motion conversion component 470 is removed from the power unit 450 and replaced with another motion conversion component with rotational motion as the power output mode, so as to realize the switching of the equipment.
[0193] 5. When it is necessary to change the application scenario of the inflatable toy, the inflatable toy 800 needs to be driven in a telescopic manner. The first action conversion component 470 is removed from the power unit 450, and the power unit 450 is directly connected to the inflatable toy 800 to realize the device switching.
[0194] 6. When it is necessary to replace or repair the drive unit 1900, remove the drive unit 1900 from the mounting base 300, replace and assemble it, and then reinstall it on the mounting base 300 to achieve the repair and replacement of the drive unit 1900.
[0195] Example 11
[0196] In order to change the power output mode of the power device 450 from rotation to extension and retraction, so as to make it suitable for various entertainment use scenarios of inflatable toys and improve the compatibility of the power device 450, this embodiment replaces the drive device 1900 in embodiment 9 with another structure.
[0197] like Figures 14 to 15 As shown in the figure, this embodiment discloses an inflatable toy, which includes a support cavity 200, a mounting base 300, a driving device 1900, and an air-operated toy 800.
[0198] The drive unit 1900 includes a mounting head 500 and a movable mechanism 400. The movable mechanism 400 is a structure that can change its external shape. The movable mechanism 400 includes a power unit 450 and a first motion conversion component 470. The power unit 450 is a pneumatic motor.
[0199] Specifically, the first motion conversion assembly 470 includes an eccentric wheel 478, a push rod 471, a slide rail 479, a connecting rod 4710, and a flexible telescopic tube 4713. The central shaft of the eccentric wheel 478 is connected to the rotor of the pneumatic motor. One end of the connecting rod 4710 is hinged to the edge of the eccentric wheel 478 (detachably connected), and the other end is hinged to the push rod 471. The push rod 471 is mounted on the slide rail 479 and can slide along the slide rail 479. One end of the push rod 471 is hinged to the connecting rod 4710, and the other end is connected to the flexible telescopic tube 4713. The outer end of the flexible telescopic tube 4713 is provided with an action output end 460. The action output end 460 is repeatedly detached and connected to the gas toy 800. The flexible telescopic tube 4713 can be bent and deformed at any angle. The first action conversion component 470 is used to convert the motion mode of the power output by the power device 450 into the required power motion mode to drive the gas toy 800. In this embodiment, the motion mode conversion is to convert the rotational motion into the telescopic motion, and drive the gas toy 800 to perform telescopic motion, so as to achieve the dynamic effect of telescopic motion of the gas toy 800.
[0200] The working process of this embodiment:
[0201] 1. Install the drive unit 1900 on the mounting base 300 and connect all the air pipes 900 and wires 1000 in the system;
[0202] 2. Using air source 100, air is supplied to support cavity 200 and air toy 800 through air pipe 900 respectively. Then, the power device 450 is controlled to rotate through air pipe 900. The power device 450 converts the rotational motion into telescopic motion suitable for this game scene through first motion conversion component 470, and drives air toy 800 to achieve telescopic motion.
[0203] 3. The power supply is provided to the various entertainment auxiliary devices 1100 on the inflatable toy 800 through the power cord 1000. While performing multiple actions, the inflatable toy 800 can also light up or make sounds, so as to achieve a richer and more dynamic interactive effect for the inflatable toy.
[0204] 4. When it is necessary to change the application scenario of the inflatable toy and drive the inflatable toy 800 in a non-telescopic manner, the first motion conversion component 470 is removed from the power unit 450 and replaced with another first motion conversion component 470 to achieve the device switching.
[0205] 5. When it is necessary to replace or repair the drive unit 1900, remove the drive unit 1900 from the mounting base 300, replace and assemble it, and then reinstall it on the mounting base 300 to achieve the repair and replacement of the drive unit 1900.
[0206] Example 12
[0207] In order to change the power output mode of the power device 450 from rotation to swing drive mode, so as to make it suitable for various entertainment use scenarios of inflatable toys and improve the compatibility of the power device 450, this embodiment replaces the drive device 1900 in embodiment 11 with another structure.
[0208] like Figures 16 to 17 As shown in the figure, this embodiment discloses an inflatable toy, which includes a support cavity 200, a mounting base 300, a driving device 1900, and an air-operated toy 800.
[0209] The drive unit 1900 includes a mounting head 500 and a moving mechanism 400. The moving mechanism 400 includes a power unit 450 and a first motion conversion component 470. The power unit 450 is a pneumatic motor.
[0210] Specifically, the first motion conversion assembly 470 includes a first bevel gear 4711, a second bevel gear 4712, an eccentric wheel 478, and a connecting rod 4710; the rotor of the pneumatic motor is coaxially connected to the central shaft of the first bevel gear 4711 to drive the first bevel gear 4711 to rotate; the second bevel gear 4712 is coaxially connected to the central shaft of the eccentric wheel 478, and the eccentric wheel 478 rotates together with the second bevel gear 4712, which meshes with the first bevel gear 4711; the middle part of the connecting rod 4710 is a hinge connection point, serving as the fulcrum for the swing of the connecting rod 4710; one end of the connecting rod 4710 is hinged to the edge of the eccentric wheel 478. The connecting rod 4710 and the eccentric wheel 478 are connected by a strip-shaped hole, which is used to make the eccentric wheel 478 drive the connecting rod 4710 to swing around the fulcrum. The other end of the connecting rod 4710 is provided with an action output end 460, which is connected to the gas toy 800. The first action conversion component 470 is used to convert the motion mode of the power output by the power device 450 into the required power motion mode to drive the gas toy 800. In this embodiment, the motion mode conversion is to convert the rotational motion into the swinging motion, and drive the gas toy 800 to swing, so as to achieve the dynamic effect of the gas toy 800 swinging.
[0211] The entertainment auxiliary device includes an electric entertainment auxiliary device and a gas-powered entertainment auxiliary device. The electric entertainment auxiliary device 1100 is electrically connected to a power source via a wire 1000, and the gas-powered entertainment auxiliary device is connected to a gas source via a gas pipe 900 for supplying power and gas to the entertainment auxiliary device 1100.
[0212] The working process of this embodiment:
[0213] 1. Install the drive unit 1900 on the mounting base 300 and connect all the air pipes 900 and wires 1000 in the system;
[0214] 2. Using air source 100, air is supplied to support cavity 200 and air toy 800 through air pipe 900 respectively. Then, the air pipe 900 controls power device 450 to rotate. Power device 450 converts rotational motion into swinging motion suitable for this game scene through first motion conversion component 470, and drives air toy 800 to achieve swinging motion.
[0215] 3. The power supply is provided to the various entertainment auxiliary devices 1100 on the inflatable toy 800 through the power cord 1000. While performing multiple actions, the inflatable toy 800 can also light up or make sounds, so as to achieve a richer and more dynamic interactive effect for the inflatable toy.
[0216] 4. When it is necessary to change the application scenario of the inflatable toy and drive the inflatable toy 800 in a telescopic manner, the first motion conversion component 470 is removed from the power unit 450 and replaced with another motion conversion component whose power output mode is telescopic motion, so as to realize the switching of the equipment.
[0217] 5. When it is necessary to change the application scenario of the inflatable toy and drive the inflatable toy 800 by rotation, the first action conversion component 470 is removed from the power unit 450 and the power unit 450 is directly connected to the inflatable toy 800 to realize the device switching.
[0218] 6. When it is necessary to replace or repair the drive unit 1900, remove the drive unit 1900 from the mounting base 300, replace and assemble it, and then reinstall it on the mounting base 300 to achieve the repair and replacement of the drive unit 1900.
[0219] Example 13
[0220] To enrich the application scenarios of inflatable toys, this embodiment sets the number of inflatable toys 800 in Embodiment 8 to four, and each inflatable toy 800 adopts a different driving device 1900 to achieve different movement modes.
[0221] like Figure 18 As shown, this embodiment discloses an inflatable toy, which includes a support cavity 200, a mounting base 300, a driving device 1900, and an air-using toy 800. The driving device 1900 can be any of the driving devices in Embodiments 9 to 12.
[0222] The mounting base 300 is divided into a primary mounting base 303 and a secondary mounting base 304. The inflatable toy 800 is divided into a primary inflatable toy 801 and a secondary inflatable toy 802. The driving device 1900 is divided into a primary driving device 1901 and a secondary driving device 1902. The primary mounting base 303 is disposed on the support cavity 200, and the secondary mounting base 304 is disposed on the primary inflatable toy 801. The primary inflatable toy 801 is connected to the primary mounting base 303 on the support cavity 200 through the primary driving device 1901, and the secondary inflatable toy 802 is connected to the primary inflatable toy 801 through the secondary driving device 1902. In this embodiment, the primary inflatable toy 801 and the secondary inflatable toy 802 adopt inflatable cavities. These two inflatable cavities are connected to the air source 100 through different air pipes 900, and can accept independent and time-sharing inflation and deflation. By using the air source 100 to inflate and deflate them separately, the inflatable toys exhibit a dynamic changing effect.
[0223] The working process of this embodiment:
[0224] 1. Install the drive unit 1900 on the mounting base 300 and connect all the air pipes 900 and wires 1000 in the system;
[0225] 2. Using the air source 100, the air is inflated and deflated to the support cavity 200 and each air-using toy 800 through the air pipe 900. Then, the air pipe 900 is used to control the movement of each drive device 1900 and drive each air-using toy 800 to achieve different movements.
[0226] 3. The power supply is provided to the various entertainment auxiliary devices 1100 on the inflatable toy 800 through the power cord 1000. While performing multiple actions, the inflatable toy 800 can also light up or make sounds, so as to achieve a richer and more dynamic interactive effect for the inflatable toy.
[0227] 4. When it is necessary to change the application scenario of the inflatable toy, the driving method of the drive device 1900 needs to be changed. Then, remove the drive device 1900 from the mounting base 300 and replace it with the required drive device 1900 to achieve the device switching.
[0228] 5. When it is necessary to replace or repair the drive unit 1900, remove the drive unit 1900 from the mounting base 300, replace and assemble it, and then reinstall it on the mounting base 300 to achieve the repair and replacement of the drive unit 1900.
[0229] Example 14
[0230] To enrich the application scenarios of inflatable toys, this embodiment removes the second docking part from the inflatable toy 800 in embodiment 10, sets the mounting base 300 as a flat structure, and replaces the first action conversion component with another structure.
[0231] like Figure 19 As shown in the figure, this embodiment discloses an inflatable toy, which includes a support cavity 200, a mounting base 300, a driving device 1900, and an air-operated toy 800.
[0232] The drive unit 1900 includes a mounting head 500 and a moving mechanism 400. The moving mechanism 400 includes a power unit 450 and a first action conversion component 470. The power unit 450 is a cylinder.
[0233] The first motion conversion component 470 includes a swing arm 476; a fulcrum is provided between the two ends of the swing arm 476, one end of the swing arm 476 is hinged to the power device 450, and the other end is used to connect or contact the gas toy 800. When the power device 450 moves telescopically, it drives the swing arm 476 to swing around the fulcrum, thereby driving the gas toy 800 to strike the support cavity 200, thus achieving the dynamic effect of the support cavity 200 shaking.
[0234] The mounting base 300 is designed as a flat plate structure, which is simpler and easier to install the mounting base drive device 1900. In this embodiment, the support cavity 200 does not have a support cavity ventilation interface. The air source is directly connected to the inside of the support cavity 200 through the air pipe 900, and the support cavity 200 and the air pipe 900 are sealed together. The mounting base 300 passes through the inside of the support cavity through the air pipe 900 and is connected to the air source 100.
[0235] Example 15
[0236] To broaden the application scenarios of inflatable toys, this embodiment adopts a non-physical connection structure between the driving device 1900 and the inflatable toy 800 in embodiment 6.
[0237] like Figure 20 As shown in the figure, an inflatable toy is disclosed in this embodiment. The inflatable toy includes a support cavity 200, a mounting base 300, a driving device 1900, and an air-using toy 800, which is a windmill set above the support cavity 200.
[0238] The drive device 1900 includes a mounting head 500 and a moving mechanism 400. The moving mechanism 400 includes a power unit 450 and a power unit airflow control device 1700. The power unit 450 is a blower nozzle. The power unit airflow control device 1700 is connected to the power air inlet 451. The power unit airflow control device 1700 controls the power unit 450 to blow air onto the air toy 800, thereby driving the air toy 800 to rotate.
[0239] Example 16
[0240] To broaden the application scenarios of inflatable toys, this embodiment adopts a non-physical connection structure between the driving device 1900 and the inflatable toy 800 in embodiment 6.
[0241] like Figure 21 As shown in the figure, this embodiment discloses an inflatable toy, which includes a support cavity 200, a mounting base 300, a driving device 1900, and an air-operated toy 800.
[0242] The drive device 1900 includes a mounting head 500 and a moving mechanism 400. The moving mechanism 400 includes a power device 450, which is an electromagnetic induction power device, specifically using an electromagnetic coil. The magnitude and direction of the magnetic force are controlled by controlling the conduction state and current direction of the electromagnetic coil. The action output terminal 460 is set on the power device 450 and is used to drive the movement of the gas toy 800.
[0243] The gas toy 800 includes a main body 820, a second docking member 700, and a second motion conversion component 750. One end of the second motion conversion component 750 is connected to the main body 820, and the other end is provided with a motion receiving end 830. The motion receiving end 830 is a magnet. The motion receiving end 830 interacts with the magnetic field generated by the power device 450, thereby driving the main body 820 to swing through the second motion conversion component 750.
[0244] In addition, the power device 450 in this embodiment may also be a magnetic power device, and a power receiving end that works in conjunction with it is provided on the gas toy 800 to drive the gas toy 800 to move.
[0245] In the above embodiments of this application, the air source 100 inflates and deflates the support cavity 200 and the inflatable toy 800 through the air pipe 900, respectively. The alternation of inflation and deflation creates a dynamic effect for the inflatable toy. A mounting base 300 for installing the drive device 1900 is provided on the support cavity 200, allowing for reusable installation and removal of the drive device 1900. This facilitates the replacement and maintenance of the drive device 1900, as well as the disassembly and assembly of the inflatable toy 800 and the drive device 1900, making the drive device 1900 suitable for various applications. Application scenarios include: enabling long-distance driving of the inflatable toy 800; mounting the driving device 1900 on the mounting base 300 to drive the inflatable toy 800 to perform actions such as swinging, stretching, rotating, and launching to achieve various dynamic effects of the inflatable toy; setting wire contacts on the support cavity 200, mounting base 300, driving device 1900, and inflatable toy 800 respectively, so that the inflatable toy 800 can perform multiple actions while simultaneously powering the entertainment auxiliary device 1100 on the inflatable toy 800, thereby achieving richer and more dynamic interactive effects of the inflatable toy.
[0246] The background section of this invention may include background information about the problems or circumstances surrounding the invention, rather than a description of prior art by others. Therefore, the content included in the background section is not an admission of prior art by the applicant.
[0247] The above description provides a further detailed explanation of the present invention in conjunction with specific / preferred embodiments, and it should not be construed that the specific implementation of the present invention is limited to these descriptions. For those skilled in the art, various substitutions or modifications can be made to these described embodiments without departing from the concept of the present invention, and all such substitutions or modifications should be considered within the scope of protection of the present invention. In the description of this specification, the reference to terms such as "an embodiment," "some embodiments," "preferred embodiment," "example," "specific example," or "some examples," etc., indicates that the specific features, structures, materials, or characteristics described in connection with that embodiment or example are included in at least one embodiment or example of the present invention. In this specification, the illustrative expressions of the above terms do not necessarily refer to the same embodiment or example. Moreover, the specific features, structures, materials, or characteristics described can be combined in any suitable manner in one or more embodiments or examples. Furthermore, those skilled in the art can combine and integrate different embodiments or examples and features of different embodiments or examples described in this specification without contradiction. Although the embodiments of the present invention and their advantages have been described in detail, it should be understood that various changes, substitutions, and modifications can be made herein without departing from the scope defined by the appended claims.
Claims
1. A driving device, characterized in that, This device is used to drive the movement of an inflatable toy. The inflatable toy includes a support cavity and a mounting base. The mounting base has a cavity connection portion for fixedly or repeatedly detachably connecting the support cavity. The driving device includes a mounting head and a movable mechanism. The movable mechanism is fixedly or repeatedly detachably connected to the mounting base via the mounting head. The movable mechanism has an action output end, which is located on the side of the movable mechanism adjacent to or opposite to the mounting head. The action output end is used to couple with the driven inflatable toy to realize the movement of the inflatable toy according to a set action. The driving device also includes a first docking member disposed on the movable mechanism. The first docking member has a second air inlet and a second electrical contact of the movable mechanism. The first docking member is used to repeatedly detachably connect with the second docking member disposed on the inflatable toy. During connection, the second air inlet is simultaneously docked with the air inlet of the inflatable toy, and the second electrical contact of the movable mechanism is docked with the electrical contact of the inflatable toy.
2. The driving device according to claim 1, characterized in that, The active mechanism includes a first air inlet, which is connected to an air source via the mounting base.
3. The driving device according to claim 2, characterized in that, The first air inlet is provided in two or more, with at least two first air inlets forming a pair, which are respectively connected to a positive pressure air source and a negative pressure air source to realize inflation and deflation respectively.
4. The driving device according to claim 2, characterized in that, The active mechanism also includes a second air inlet disposed at or near the action output end; one end of the second air inlet is connected to the first air inlet via an air passage, and the other end is used to deliver gas from the gas source to the gas toy or other objects other than the gas toy.
5. The driving device according to claim 4, characterized in that, The air passages are at least two, with at least two first air inlets and at least two second air inlets. Each air passage is connected to its respective first air inlet and second air inlet at both ends. At least two air passages form a pair, which are used to inflate and de-inflate the gas toy or other objects other than the gas toy.
6. The driving device according to claim 1, characterized in that, The active mechanism includes a power unit connected to the action output end, which provides driving force to the action output end.
7. The driving device according to claim 6, characterized in that, The power unit is a pneumatic power unit, which is connected to an air source.
8. The driving device according to claim 7, characterized in that, The power unit is provided with a power air port, which is connected to the air source via the mounting base, and is used to supply gas from the air source to the power unit.
9. The driving device according to claim 8, characterized in that, The power air port is provided in two parts, each of which is connected to a positive pressure air source and a negative pressure air source respectively, so as to be used to inflate and evacuate the power device respectively.
10. The driving device according to claim 8, characterized in that, The active mechanism includes a power unit airflow control device, which is located at the power air inlet and is used to control the direction and / or flow rate of the gas flowing through the power air inlet.
11. The driving device according to claim 1, characterized in that, The movable mechanism includes a first electrical contact, which is electrically connected to a power source and / or signal source via the mounting base, for introducing current and / or electrical signals into the movable mechanism.
12. The driving device according to claim 11, characterized in that, The active mechanism also includes a second electrical contact, one end of which is electrically connected to the first electrical contact of the active mechanism, and the other end is used to electrically connect to the gas toy or other objects to supply power or transmit electrical signals to the gas toy or other objects.
13. The driving device according to claim 6, characterized in that, The power device is an electric power device, an electromagnetic induction power device, or a magnetic power device, and the power device is electrically connected to a power source and / or a signal source via the mounting base.
14. The driving device according to claim 6, characterized in that, The active mechanism includes a first motion conversion component. One end of the first motion conversion component is fixedly or repeatedly detachably connected to the power device, and the other end is provided with the motion output end. The first motion conversion component is used to convert the power motion mode and state generated by the power device into the required motion mode and state.
15. The driving device according to claim 1, characterized in that, The first docking member is disposed on the motion output end, and can cause the gas toy to move along with it under the drive of the motion output end.
16. A gas-operated toy, characterized in that, It includes a body and an action receiving end connected to the body, the action receiving end being used to couple with the action output end in the driving device as described in any one of claims 1-15, so as to receive driving force from the action output end to drive the body to move.
17. The gas-operated toy according to claim 16, characterized in that, It includes a gas toy venting port located at or near the action receiving end; one end of the gas toy venting port is used to connect to a second gas inlet to receive gas from a gas source, and the other end is used to connect to the main body to supply gas to the main body.
18. The gas-operated toy according to claim 17, characterized in that, The gas toy has at least two air vents, and each air vent is connected to a positive pressure air source and a negative pressure air source through different second air guide interfaces, so as to be used to inflate and de-inflate the main body respectively.
19. The gas-operated toy according to claim 17, characterized in that, The main body includes an inflatable cavity, which is a soft, deformable inflatable cavity and is connected to the air vent of the inflatable toy.
20. The gas-operated toy according to claim 17, characterized in that, It also includes an airflow control device for the gas toy, which is fixedly or removably connected to the air inlet of the gas toy and is used to control the direction and / or flow rate of the gas flowing through it.
21. The gas-operated toy according to claim 20, characterized in that, The air inlet of the gas toy supplies and evacuates air to multiple bodies in a time-sharing and independent manner through an airflow control device.
22. The gas-operated toy according to claim 16, characterized in that, It includes an electrical contact for a gas toy; the gas toy electrical contact is electrically connected to a second electrical contact of the movable mechanism provided on the movable mechanism, for transmitting current and / or electrical signals between the two contacts.
23. The gas-operated toy according to claim 16, characterized in that, It also includes a second docking member disposed on the action receiving end, the second docking member being used to be fixedly or repeatedly detachably connected to the drive device and / or the mounting base.
24. The gas-operated toy according to claim 23, characterized in that, One end of the second mating member is hinged to the mounting base.
25. The gas-operated toy according to claim 23, characterized in that, The second docking member is a second recessed structure, which is used to accommodate at least part of the action receiving end within the second recessed structure.
26. The gas-operated toy according to claim 16, characterized in that, The main body is provided with a second receiving part, and the action receiving end is housed inside the second receiving part.
27. The gas-operated toy according to claim 16, characterized in that, It also includes a second motion conversion component, the motion receiving end is connected to the body via the second motion conversion component, the second motion conversion component is used to convert the power motion mode and state received by the motion receiving end into the required motion mode and state.
28. An inflatable toy system, characterized in that, include: Support cavity, mounting base, and drive device as described in any one of claims 1-15; The mounting base is provided with a cavity joint, which is used to fix or repeatedly detach and connect the support cavity; the driving device is fixed or repeatedly detach and connectable to the mounting base.
29. The inflatable toy system according to claim 28, characterized in that, The supporting cavity is a soft, deformable, inflatable cavity. The supporting cavity is provided with a supporting cavity ventilation port. One end of the supporting cavity ventilation port is connected to an air source, and the other end of the supporting cavity ventilation port is connected to the interior of the supporting cavity and the mounting base.
30. The inflatable toy system according to claim 29, characterized in that, A support cavity airflow control device is connected between the air vent of the support cavity and the mounting base.
31. The inflatable toy system according to claim 29, characterized in that, The supporting cavity is provided with an access component to improve the stability and airtightness of the connection; the access component is airtightly connected to the supporting cavity, and the access component is provided with a first airflow control device mounting structure and a ventilation interface of the supporting cavity; the first airflow control device mounting structure is used for repeatedly detaching and installing the airflow control device of the supporting cavity.
32. The inflatable toy system according to claim 29, characterized in that, The support cavity is provided with at least two ventilation ports, and at least two support cavity ventilation ports form a pair, which are respectively connected to a positive pressure air source and a negative pressure air source to realize inflation and deflation respectively.
33. The inflatable toy system according to claim 28, characterized in that, The support cavity is provided with a support cavity electrical contact; one end of the support cavity electrical contact located outside the support cavity is electrically connected to a power source and / or a signal source, and the other end of the support cavity electrical contact located inside the support cavity is electrically connected to the mounting base.
34. The inflatable toy system according to claim 28, characterized in that, The support cavity is provided with a first receiving part, and the mounting seat is received inside the first receiving part.
35. The inflatable toy system according to claim 28, characterized in that, The mounting base includes a mounting base ventilation interface, one end of which is connected to an air source, and the other end is connected to a first air guide interface provided on the movable mechanism.
36. The inflatable toy system according to claim 35, characterized in that, One end of the venting port of the mounting base is located inside the support cavity and extends out of the support cavity through an air pipe to communicate with the air source.
37. The inflatable toy system according to claim 35, characterized in that, The mounting base has at least two ventilation ports, with at least two mounting base ventilation ports forming a pair, which are respectively connected to a positive pressure air source and a negative pressure air source to achieve inflation and deflation respectively.
38. The inflatable toy system according to claim 35, characterized in that, The mounting base is equipped with a second airflow control device mounting structure at the ventilation interface, which is used for repeatedly detaching and installing the airflow control device.
39. The inflatable toy system according to claim 28, characterized in that, It also includes a mounting base electrical contact, one end of which is disposed inside the support cavity and extends out of the support cavity via a wire to be electrically connected to a power source and / or a signal source, and the other end of which is electrically connected to the first electrical contact of the movable mechanism disposed on the movable mechanism.
40. The inflatable toy system according to claim 28, characterized in that, The mounting base is a first recessed structure, and the driving device is at least partially housed within the first recessed structure.
41. The inflatable toy system according to claim 28, characterized in that, It also includes the gas toy, which is mounted on the inflatable toy system via the driving device and is driven by the driving device.
42. The inflatable toy system according to claim 41, characterized in that, The gas toy is also equipped with an inflation chamber that can accept independent, time-based inflation and deflation.
43. The inflatable toy system according to claim 41, characterized in that, It also includes an entertainment aid device, which is disposed on the support cavity and / or the gas toy and is connected to a power source via an electric wire or to a gas source via an air tube.
44. The inflatable toy system according to claim 28, characterized in that, It also includes other cavities that are fixedly or repeatedly detachably connected to the support cavity.
45. The inflatable toy system according to claim 28, characterized in that, The load-bearing structure of the supporting cavity is configured to withstand the weight of the player when inflated, and it is provided with a space structure of a size that allows the player to play on it.