CN113413620A

CN113413620A - Body-building synchronous toy

Info

Publication number: CN113413620A
Application number: CN202110710038.8A
Authority: CN
Inventors: 梁文建; 李德铭; 李晓锋
Original assignee: Guangdong Aofei Industrial Co ltd; Alpha Group Co Ltd; Guangzhou Alpha Culture Co Ltd
Current assignee: Guangdong Aofei Industrial Co ltd; Alpha Group Co Ltd; Guangzhou Alpha Culture Co Ltd
Priority date: 2021-06-25
Filing date: 2021-06-25
Publication date: 2021-09-21

Abstract

The application discloses synchronous toy of body-building, including body-building piece and toy spare, body-building piece with toy spare communication connection or linkage are connected, when body-building piece is in the user state, trigger toy spare synchronization action. The body-building piece and the toy piece are arranged, the toy piece is triggered to synchronously act when the body-building piece is in a use state, when a player stops using the body-building piece, the toy piece is not triggered to stop acting, the actions of the player and the toy piece are kept synchronous, and the body-building piece has strong interactivity and can improve the body-building strength of the player; the toy piece comprises a main body and a simulation piece, wherein the main body simulates a player, the simulation piece simulates a body-building piece, and when the player uses the body-building piece, the main body in the toy piece is triggered to drive the simulation piece to act, so that the toy piece simulates the state that the player uses the body-building piece, and the toy piece has strong interestingness.

Description

Body-building synchronous toy

Technical Field

The application relates to the technical field of toys, in particular to a body-building synchronous toy.

Background

Most dynamic model toys at present are driven through screwing up a clockwork spring, or are driven by turning on a motor switch, or are driven by turning on the motor switch through remote control, and a player of the dynamic model toys can trigger the action of the toys only by operating once, so that the interactivity is poor, the interest in playing is reduced, and the interest of the player is lost easily.

The prior children body-building toy is provided with a music player, a flash lamp and the like in order to improve the interestingness when in use, but most children toys are very easy to lose interest in the body-building toy because the music playing and the flash light mode are adopted to increase the interestingness.

Disclosure of Invention

The application aims to overcome the defects that the dynamic simulation toy in the prior art is poor in interactivity and the body-building toy is poor in interestingness, and provides a body-building synchronous toy which is combined with the dynamic simulation toy and the body-building toy and is strong in interactivity and high in interestingness.

The technical scheme of this application provides a synchronous toy of body-building, including body-building piece and toy spare, body-building piece with toy spare communication connection or linkage are connected, when body-building piece is in the user state, trigger toy spare synchronization action.

Further, the toy piece comprises a main body and a simulation piece linked with the main body, and when the toy piece is triggered, the main body drives the simulation piece to simulate the action of the body building piece.

Furthermore, the body-building piece is provided with a trigger assembly, the main body is provided with a driving assembly, and the trigger assembly is in communication connection or linkage connection with the driving assembly;

the trigger assembly is triggered when the body building element is in a use state, and the trigger assembly controls the driving assembly to drive the simulation element to act.

Furthermore, the driving assembly comprises a driving motor and a start-stop device electrically connected with the driving motor, the triggering assembly is in communication connection or linkage connection with the start-stop device, the triggering assembly controls the driving motor to start and stop through the start-stop device, and the driving motor is used for driving the simulation piece to act.

Further, the trigger component is a wireless remote control switch, and the wireless remote control switch has a power-on state and a power-off state;

when the body-building piece is in a use state, the wireless remote control switch is in a power-on state, and the wireless remote control switch is in communication connection with the driving assembly and controls the driving assembly to drive the simulation piece to act.

Furthermore, the trigger assembly is an elastic electric contact switch, and the elastic electric contact switch is electrically connected with the driving assembly through a lead;

when the body-building piece is in a use state, the elastic electric touch switch is closed, the power supply of the driving component is switched on, and the driving component starts to drive the simulation piece to act.

Further, the trigger assembly is in linkage fit with the driving assembly;

when the body-building piece is in a use state, the trigger assembly drives the driving assembly to synchronously displace after displacing, and the driving assembly drives the simulation piece to act when displacing.

Further, the simulation piece is movably arranged on the main body relatively, and the driving assembly is in linkage fit with the simulation piece; or

The simulation piece and the main body are of mutually independent split structures, and the driving assembly drives the main body to act so that the main body drives the simulation piece to act.

Further, the body-building piece and the toy piece are mutually independent split structures, and the body-building piece is in wireless communication connection with the toy piece.

Further, a mounting part is further included, and the body building element and the toy element are both mounted on the mounting part;

the mounting piece is provided with a connecting piece, and two ends of the connecting piece are respectively connected with the body-building piece and the toy piece.

Further, the toy piece is installed on the body-building piece, and the toy piece and the body-building piece are in wired communication connection or wireless communication connection or linkage connection.

Further, the body-building piece is any one of a hula hoop, a skipping rope, a sandbag, a dumbbell and a bicycle.

After adopting above-mentioned technical scheme, have following beneficial effect:

the body-building piece and the toy piece are arranged, the toy piece is triggered to synchronously act when the body-building piece is in a use state, when a player stops using the body-building piece, the toy piece is not triggered to stop acting, the actions of the player and the toy piece are kept synchronous, and the body-building piece has strong interactivity and can improve the body-building interest and the body-building strength of the player;

the toy piece comprises a main body and a simulation piece, wherein the main body simulates a player, the simulation piece simulates a body-building piece, when the player uses the body-building piece, the main body in the toy piece is triggered to drive the simulation piece to act, so that the toy piece simulates the state that the player uses the body-building piece, and the toy piece has strong interestingness and interactivity.

Drawings

The disclosure of the present application will become more readily understood by reference to the drawings. It should be understood that: these drawings are for illustrative purposes only and are not intended to limit the scope of the present application. In the figure:

FIG. 1 is a schematic view of a toy article according to one or both of the embodiments of the present application;

FIG. 2 is an exploded view of a toy article according to one or both of the embodiments of the present application;

FIG. 3 is an exploded view of the interior of the toy components of the first and second embodiments of the present application;

FIG. 4 is an exploded view of a portion of the drive assembly of one or both of the toy members of the first and second embodiments of the present application;

FIG. 5 is an exploded view of the mounting plate and turntable of the toy members of the first and second embodiments of the present application

FIG. 6 is an exploded view of the inner portion of a toy article according to one or both of the first and second embodiments of the present application;

FIG. 7 is a hardware circuit diagram of a driving component in the first and second embodiments of the present application;

FIG. 8 is a schematic view of a hula hoop according to an embodiment of the present disclosure;

FIG. 9 is a schematic view of a trigger assembly of the exercise member of FIG. 8;

FIG. 10 is a schematic view of a hula hoop according to a second embodiment of the present application;

FIG. 11 is a schematic view of the trigger assembly of the exercise member of FIG. 10;

FIG. 12 is a schematic view of a body-building synchronizing toy according to a third embodiment of the present application;

FIG. 13 is a schematic view of a trigger assembly and a drive assembly in a third embodiment of the present application;

fig. 14 is a partially enlarged view of fig. 13.

Reference symbol comparison table:

FIGS. 1 to 11:

the body-building piece 001:

the triggering component 02: the actuating member 21, the control member 22, the mounting case 23, the sliding groove 231, the case body 24, the conductive spring 25, the metal cylinder 26, and the insulating ring 27.

Toy 002:

a main body 201:

the shell 01: a left shell 11, a right shell 12, a hemispherical shell 13 and a balancing weight 14;

the driving assembly 03: the device comprises a driving motor 31, an output shaft 311, a start-stop device 32, a battery 33, a power switch 34, a rotary disc 35, a magnetic adsorption piece 351, a rotary tooth 352, a circular groove 353, an inner convex ring 354, an arc convex column 355, a transmission gear set 36, a driving gear 361 and a middle gear 362;

mounting plate 04: an outer convex ring 41 and a connecting column 42;

cover plate 05: a connection hole 51;

mounting bracket 06: a battery mounting groove 61 and a switch mounting groove 62;

a PCB circuit board 07;

the simulation 202: a connecting member 08.

FIGS. 12-14:

the body-building component 003:

trigger assembly 09, connecting rod 91, pivot 92.

Toy 004:

a main body 401, a drive lever 010, a dummy 402, a slide holder 403, an escape groove 011, and a spring 012;

a bracket 005.

Detailed Description

Embodiments of the present application are further described below with reference to the accompanying drawings.

It is easily understood that according to the technical solutions of the present application, those skilled in the art can substitute various structures and implementations without changing the spirit of the present application. Therefore, the following detailed description and the accompanying drawings are merely illustrative of the technical solutions of the present application, and should not be construed as limiting or restricting the technical solutions of the present application in their entirety.

The terms of orientation of up, down, left, right, front, back, top, bottom, and the like referred to or may be referred to in this specification are defined relative to the configuration shown in the drawings, and are relative terms, and thus may be changed correspondingly according to the position and the use state of the device. Therefore, these and other directional terms should not be construed as limiting terms. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Throughout the description of the present application, it is to be noted that, unless otherwise expressly specified or limited, the terms "mounted," "connected," and "coupled" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; the two components can be directly connected or indirectly connected through an intermediate medium, and the two components can be communicated with each other. The foregoing is to be understood as belonging to the specific meanings in the present application as appropriate to the person of ordinary skill in the art.

The body-building synchronous toy comprises a body-building piece and a toy piece, wherein the body-building piece is in communication connection or linkage connection with the toy piece, and when the body-building piece is in a use state, the toy piece is triggered to synchronously act;

the toy piece comprises a main body and a simulation piece linked with the main body, and when the toy piece is triggered, the main body drives the simulation piece to simulate the action of the body building piece.

The exercise device in the embodiments of the present application includes, but is not limited to, a hula hoop, a jump rope, a sandbag, a dumbbell, a bicycle, etc., and is used by a player in the same manner as a conventional hula hoop, a jump rope, a sandbag, a dumbbell, a bicycle, etc. The embodiment of the application sets up the action that the toy piece simulated player used the body-building piece, and wherein the main part is used for simulating the player, and the simulation piece is used for simulating the body-building piece, through the communication connection or the linkage connection of body-building piece and toy piece, realizes that the toy piece simulates the action synchronization action that the player used the body-building piece.

Specifically, the body-building piece is provided with a triggering assembly, the main body is provided with a driving assembly, and the triggering assembly is in communication connection or linkage connection with the driving assembly;

when the body-building piece is in a use state, the trigger assembly is triggered, and the trigger assembly controls the driving assembly to drive the simulation piece to act.

The driving assembly can comprise a driving motor and a start-stop device electrically connected with the driving motor, and the triggering assembly is in communication connection or linkage connection with the start-stop device. When the body-building piece is in a use state, for example, the hula hoop is rotated, the skipping rope is swung, a sandbag is beaten and the like, the trigger assembly is triggered, the trigger assembly controls the start and stop of the driving motor through the start and stop device, and the driving motor is used for driving the simulation piece to act.

For different body-building pieces, according to the specific use modes, the body-building piece and the toy piece can be arranged into mutually independent split structures or integrated structures; correspondingly, the main body and the simulation piece in the toy piece can also be arranged in a split structure and an integrated structure.

When the body-building piece is a hula hoop, a skipping rope and a dumbbell, the body-building piece and the toy piece are arranged into mutually independent split structures, and the body-building piece is connected with the toy piece through wireless communication. The simulation piece in the toy piece can be installed on the main body in a relatively movable mode, and the driving assembly on the main body is in linkage fit with the simulation piece so as to simulate the use states of a hula hoop, a skipping rope and a dumbbell.

When the body-building piece is a sandbag, the body-building piece and the toy piece are arranged into an integrated structure, and the sandbag can further comprise an installation piece, wherein the installation piece is specifically a support, and the body-building piece and the toy piece are both arranged on the support; the connecting piece is arranged on the mounting piece, and the two ends of the connecting piece are respectively connected with the body-building piece and the toy piece so as to realize linkage between the body-building piece and the toy piece. The simulation piece and the main part in the toy piece are of mutually independent split structures, the simulation piece and the main part are both installed on the support, and the driving assembly drives the main part to move, so that the main part drives the simulation piece to move to simulate the using state of the sandbag.

When the body-building piece is a bicycle, the body-building piece and the toy piece are arranged into an integrated structure, the toy piece is arranged on the body-building piece, and the toy piece and the body-building piece can be connected in a wired communication mode or a wireless communication mode or in a linkage mode. The toy piece is characterized in that the main body is mounted on the simulation piece in a relatively movable mode, and the driving assembly on the main body is in linkage fit with the simulation piece so as to simulate the use state of the bicycle.

Optionally, the triggering assembly and the driving assembly can be in wireless communication connection or wired communication connection or linkage connection.

As an example, the triggering component is a wireless remote control switch, and the wireless remote control switch has a power-on state and a power-off state; when the body-building piece is in a use state, the wireless remote control switch is in a power-on state, and the wireless remote control switch is in communication connection with the driving assembly to control the driving assembly to drive the simulation piece to act. The wireless remote control switch sends a control signal to establish connection with the driving component when in a power-on state, and the driving component starts and drives the simulation piece to act after receiving the control signal. The wireless communication connection between the wireless remote control switch and the driving component comprises but is not limited to infrared rays, Bluetooth, a wireless local area network, a mobile communication network and the like.

As an example, the triggering component is an elastic electric touch switch, and the elastic electric touch switch is electrically connected with the driving component through a lead; when the body-building piece is in a use state, the elastic electric touch switch is closed, the power supply of the driving component is switched on, and the driving component starts to drive the simulation piece to act. The elastic electric contact switch triggers the switch to be switched on and off through the elastic piece, and the switch is switched on when external force presses the elastic piece; the elastic electric touch switch is connected with the driving component and the power supply in series, and when the body-building piece is in a use state, the body-building piece is triggered to be closed by the action of external force.

As an example, the triggering component is in linkage fit with the driving component; when the body-building piece is in a use state, the trigger assembly drives the driving assembly to synchronously displace after displacing, and the driving assembly drives the simulation piece to act when displacing. The scheme of linkage cooperation between the trigger assembly and the driving assembly is applicable to the integral structure of the body-building piece and the toy piece, the trigger assembly can be directly connected with the driving assembly or indirectly connected with the driving assembly through a connecting piece, and the driving assembly is driven to synchronously act when the trigger assembly acts through the linkage cooperation of a mechanical mechanism.

When a player uses the body-building piece, the main body in the toy piece is triggered to drive the simulation piece to act, so that the toy piece simulates the state of the player using the body-building piece and has strong interestingness; when the player stops using the body-building piece, the toy piece is not triggered, the action is stopped, the actions of the player and the toy piece are kept synchronous, the interactivity is strong, and the body-building interest of children can be improved.

The first embodiment is as follows:

the synchronous toy of body-building in this application embodiment, including body-building piece 001 as shown in fig. 8 and toy piece 002 as shown in fig. 1, body-building piece 001 and toy piece 002 are the split type structure of mutual independence, and wherein body-building piece 001 is the hula hoop, and toy piece 002 includes main part 201 and simulation piece 202, and main part 201 is public young for simulate the player, and simulation piece 202 cover is established outside main part 201, sets up to the hula hoop for simulate body-building piece 001.

The body building piece 001 is in wireless communication connection with the toy piece 002, and when the body building piece 001 is in a use state, the toy piece 002 is triggered; when the toy 002 is triggered, the main body 201 drives the dummy 202 to rotate against the outer circumferential surface of the main body 201.

Specifically, the body-building element 001 and the toy element 002 are connected through wireless communication in the modes of infrared rays, Bluetooth, wireless networks and the like, the body-building element 001 is used by a player, and when the player rotates the body-building element 001, the body-building element 001 sends a trigger signal to the toy element 002. When the toy 002 is triggered, the main body 201 drives the simulation piece 202 in a manner simulating the motion of the player, and the simulation piece 202 rotates against the outer peripheral surface of the main body 201.

The synchronous toy of hula hoop in this application embodiment sets up the action that toy piece 002 simulation player rotated body-building piece 001 to rotate body-building piece 001 through the player and trigger toy piece 002 action, increased the interdynamic between player and the toy piece 002, improve the interest of hula hoop motion, increase children's amount of exercise.

Further, as shown in fig. 1, a hemispherical shell 13 (see fig. 2) is disposed at the bottom of the main body 201, and a weight block 14 is installed in the hemispherical shell 13;

when the simulation member 202 rotates along the outer peripheral surface of the main body 201, the main body 201 is driven to swing with the bottom of the hemispherical shell 13 as a fulcrum.

As shown in fig. 2, the housing 01 of the main body 201 includes a left housing 11, a right housing 12 and a hemispherical housing 13 connected below the left housing 11 and the right housing 12, a weight 14 is installed in the hemispherical housing 13, the weight 14 is made of a metal material, so that the center of gravity of the main body 201 is lowered to the weight 14, and the main body 201 forms a tumbler which can rock with the bottom of the hemispherical housing 13 as a pivot.

When toy 002 is triggered, and simulation 202 rotates along the outer peripheral surface of main part 201, simulation 202 drives main part 201 to rock, and the simulation player rotates the form of body-building 001, has increased the interesting of toy 002.

Further, as shown in fig. 8, the exercise device 001 is provided with a triggering component 02, as shown in fig. 2, the main body 201 is provided with a driving component 03, and the triggering component 02 is in communication connection with the driving component 03;

when the body building element 001 is in a use state, the trigger component 02 is triggered, and the trigger component 02 controls the driving component 03 to drive the simulation element 202 to act.

Body-building piece 001 triggers the drive assembly 03 communication connection of subassembly 02 and toy piece 002 through setting up, realizes the linkage of body-building piece 001 and toy piece 002.

Specifically, as shown in fig. 9, the triggering assembly 02 includes an actuating member 21 and a control member 22, and the control member 22 is in communication connection with the driving assembly 03;

when the body-building element 001 is in a use state, the action element 21 is driven to act and the control element 22 is triggered, and the control element 22 controls the driving assembly 03 to drive the simulation element 202 to act.

The action part 21 and the control part 22 are arranged in the mounting box 23, and the mounting box 23 is fixed on the outer side of the body building part 001, so that the use of the body building part 001 is prevented from being influenced.

In the embodiment of the application, a sliding groove 231 is arranged in the mounting box 23, two ends of the sliding groove 231 are respectively provided with a control member 22, the control members 22 are wireless remote control switches and have an energized state and a de-energized state, and the control members 22 are triggered to be switched to the energized state by pressing springs on the control members 22; both control members 22 are in communication connection with the driving assembly 03 in the power-on state, and when any one of the control members 22 is pressed to be switched to the power-on state, a trigger signal is sent to the driving assembly 03. The operating member 21 is located between the two control members 22, and the operating member 21 is configured as a round ball, and the diameter of the round ball is slightly smaller than the width of the sliding slot 231, so that the round ball can slide in the sliding slot 231.

When the player rotates the exercise device 001, the action member 21 is swung to one end of the sliding slot 231, the action member 21 continuously presses and triggers the control member 22 at the end to send a signal to the driving assembly 03, so as to control the driving assembly 03 to drive the simulation member 202 to rotate. The player stops rotating the exercise member 001, the operating member 21 is no longer subjected to the whipping force, the push on the control member 22 stops, the control member 22 no longer sends a signal to the driving assembly 03, and the simulation member 202 stops rotating. A synchronized action of the player and the toy element 002 is achieved, enabling the child to actively move by enhancing the interactivity.

Further, as shown in fig. 7, the driving assembly 03 includes a driving motor 31 and a start-stop device 32 electrically connected to the driving motor 31, the triggering assembly 02 is in communication connection with the start-stop device 32, the triggering assembly 02 controls the driving motor 31 to start and stop through the start-stop device 32, and the driving motor 31 is used for driving the simulation 202 to move.

The driving assembly 03 is provided with the driving motor 31 for driving, the starting and stopping of the driving motor 31 are controlled through the starting and stopping device 32, the starting and stopping device 32 is controlled by the trigger assembly 02 on the body building piece 001, and the communication connection between the body building piece 001 and the toy piece 002 is realized.

In particular, the drive assembly 03 further comprises a battery 33 for supplying electrical energy to the drive motor 31, and a power switch 34 connected in series between the drive motor 31 and the battery 33, in which circuit the start-stop device 32 is likewise connected in series. The start-stop device 32 directly controls the start-stop of the drive motor 31 with the power switch 34 open.

Alternatively, the start-stop device 32 may be configured as an inductive switch that completes the circuit by receiving a trigger signal from the trigger assembly 02. The start-stop device 32 can also be set to be a control circuit comprising a control chip, a wireless communication module and a switch piece, wherein the wireless communication module and the switch piece are electrically connected with the control chip, as an example, the control chip can adopt a single chip microcomputer, the wireless communication module can adopt a Bluetooth communication module or an infrared communication module, the switch piece can adopt switch tubes such as a triode, the switch piece is connected in series in a circuit formed by the driving motor 31, the battery 33 and the power switch 34, the wireless communication module receives a trigger signal of the trigger component 02 and sends the trigger signal to the control chip to control the switch piece to be switched on. The start stop 32 may be mounted within the body 201 integrated in the PCB board 07 (see fig. 3).

Further, as shown in fig. 3, a connecting member 08 is disposed on the simulation member 202, a driving assembly 03 is disposed on the main body 201, the simulation member 202 is sleeved outside the main body 201, and the connecting member 08 and the driving assembly 03 are in linkage fit, so that when the toy 002 is triggered, the driving assembly 03 drives the connecting member 08 to rotate along the outer peripheral surface of the main body 201.

The simulation piece 202 is connected with the main body 201 through the connecting piece 08, linkage matching of the simulation piece 202 and the driving component 03 is achieved, and when the driving component 03 drives the connecting piece 08 to rotate along the outer peripheral surface of the main body 201, the simulation piece 202 is driven to rotate along the outer peripheral surface of the main body 201.

Specifically, the driving assembly 03 includes a turntable 35 disposed in the main body 201, and a magnetic attraction member 351 for attracting the connection member 08 is mounted on an outer circumference of the turntable 35;

when the toy 002 is triggered, the rotating disc 35 rotates, and the magnetic attraction member 351 attracts the connection member 08 to rotate along the outer circumferential surface of the main body 201.

Specifically, the rotating disc 35 is installed in the housing 01, the simulation member 202 is sleeved outside the housing 01, the connecting member 34 is made of an iron material, the connecting member 34 can be attracted by the magnetic attraction member 351, and when the driving motor 31 drives the rotating disc 35 to rotate, the magnetic attraction member 351 attracts the connecting member 34 to rotate along the outer peripheral surface of the housing 01, so that the rotating effect of the hula hoop is simulated.

Preferably, the magnetic absorption member 351 is provided with three pieces, three pieces of the magnetic absorption member 351 are uniformly arranged at the periphery of the rotating disk 35, wherein one piece of the magnetic absorption member 351 absorbs the connection member 08. Three magnetic attraction members 351 are provided for equalizing the weight of the toy piece 002 so that the center of gravity of the toy piece 002 is located on the axis.

Alternatively, a circumferential sliding groove may be formed in the housing 01, and the magnetic attraction member 351 is installed in the sliding groove, so that the connecting member 08 can rotate against the magnetic attraction member 351, and the simulation member 202 can be prevented from being separated from the main body 201.

Further, as shown in fig. 3 and 4, a rotary tooth 352 is arranged on the rotary disc 35, the driving assembly 03 further includes a transmission gear set 36, the transmission gear set 36 is connected between the rotary tooth 352 and an output shaft 311 of the driving motor 31, the output shaft 311 of the driving motor 31 rotates to drive the transmission gear set 36 to rotate, and the transmission gear set 36 drives the rotary disc 35 to rotate through the rotary tooth 352.

The driving motor 31 is a rotating motor, and the transmission gear set 36 is connected with the output shaft 311 and the turntable 35 to realize the transmission of the driving motor 311 and the turntable 35.

Specifically, as shown in fig. 4, the transmission gear set 36 includes a driving gear 361 and three intermediate gears 362, the driving gear 361 is mounted on the output shaft 311 of the driving motor 31, the three intermediate gears 362 are uniformly arranged around the driving gear 361 and are meshed with the driving gear 361, the three intermediate gears 362 are also meshed with the rotary teeth 352 at the same time, the driving gear 361 is driven by the driving motor 31 to rotate, and the driving gear 361 drives the rotary plate 35 to rotate through the three intermediate gears 362.

The three intermediate gears 362 are all duplicate gears, and include large gears and small gears which rotate coaxially, the large gears are meshed with the driving gears 361, the small gears are meshed with the rotary teeth 352 of the rotary disc 35, and the intermediate gears 362 are used for achieving linkage between the driving gears 361 and the rotary teeth 352.

Preferably, the rotary plate 35 is annular, the rotary teeth 352 are arranged on the inner wall of the rotary plate 35, and the pinions of the three intermediate gears 362 extend into the rotary plate 35. The occupation of main part 201 inner space has been saved in so setting up, and carousel 35 can play limiting displacement to three intermediate gear 362 simultaneously, has improved the stability of structure.

The transmission gear set 36 of the embodiment of the application adopts a structure that three intermediate gears 362 are circumferentially arranged around the driving gear 361, so that the rotation stability of the turntable 35 is improved, the balance of the weight of the toy piece 002 is considered, and the gravity center of the toy piece 002 is controlled to be positioned on the axis.

Further, as shown in fig. 3, a mounting plate 04 and a cover plate 05 are further disposed in the main body 201, the transmission gear set 36 and the rotary plate 35 are mounted on the mounting plate 04, the cover plate 05 is covered above the transmission gear set 36 and the rotary plate 35 and connected with the mounting plate 04, and the rotary plate 35 rotates relative to the mounting plate 04 and the cover plate 05 when the toy 002 is triggered.

Specifically, as shown in fig. 5, an inner collar 354 is disposed on a lower surface of the turntable 35, an outer collar 41 is disposed on an upper surface of the mounting plate 04, the inner collar 354 is mounted in the outer collar 41, an outer circumferential surface of the inner collar 354 is made to abut against an inner circumferential surface of the outer collar 41, the inner collar 354 rotates relative to the outer collar 41 when the turntable 35 rotates, and the outer collar 41 is used for limiting rotation of the turntable 35.

Preferably, the outer circumferential surface of the inner collar 354 is uniformly provided with convex arc-shaped protruding columns 355 at intervals, and the arc-shaped protruding columns 355 are in contact with the inner circumferential surface of the outer collar 41, so that the contact area between the turntable 35 and the outer collar 41 is reduced, and the friction resistance when the turntable 35 rotates is reduced.

As shown in fig. 3, a convex connection column 42 is arranged on the mounting plate 04, a connection hole 51 is arranged on the cover plate 05 corresponding to the connection column 42, the transmission gear set 36 and the rotary plate 35 are sequentially arranged on the mounting plate 04, a circular groove 353 which is concave downwards is arranged on the upper surface of the rotary plate 35, the cover plate 05 covers the rotary teeth 352 and the transmission gear set 36, the connection column 42 is inserted into the corresponding connection hole 51, and the mounting plate 04 is connected with the cover plate 05.

The installation disc 04 and the cover plate 05 are arranged in the embodiment of the application, and the turntable 35 and the middle gear 362 can be prevented from shaking up and down.

Further, as shown in fig. 6, a mounting bracket 06 is further disposed in the main body 201, and the driving assembly 03 further includes a battery 33 and a power switch 34 electrically connected to the driving motor 31;

the mounting bracket 06 is provided with a battery mounting groove 61, a switch mounting groove 62, and a driving motor groove (not shown), the battery 33 is mounted in the battery mounting groove 61, the power switch 34 is mounted in the switch mounting groove 62, and the driving motor 31 is mounted in the driving motor groove.

Specifically, the driving motor groove is recessed downward from the mounting bracket 06, and the driving motor 31 is mounted into the driving motor groove from top to bottom; the battery mounting grooves 61 are recessed upwards from the mounting bracket 06, the batteries 33 are mounted in the battery mounting grooves 61 from bottom to top, preferably, three batteries 33 are provided, the mounting bracket 06 is correspondingly provided with three battery mounting grooves 61, and the three battery mounting grooves 61 are distributed in a triangular shape, so that the weight of the toy piece 002 is balanced; the switch mounting groove 62 is a notch, and a pin of the power switch 34 is inserted into the switch mounting groove 62 from bottom to top to be electrically connected with the driving motor 31.

When the battery 33 is replaced or the power switch 34 is turned on or off, the assembly of the hemispherical shell 13 and the weight 14 is removed, and the battery 33 and the power switch 34 are exposed.

The synchronous toy of body-building in this application embodiment, be equipped with battery 33 in toy spare 002, and when switch 34 was opened, when the player rotated body-building spare 001, the action 21 that triggers subassembly 02 on body-building spare 001 pressed control piece 22 under the effect of whipping and continuously sent start signal to the start-stop device 32 of toy spare 002, start-stop device 32 control driving motor 31 rotates, driving motor 31 drives carousel 35 through drive gear group 36 and rotates, magnetic adsorption piece 351 on the carousel 35 adsorbs the connecting piece 08 rotation on the simulation piece 202, make simulation piece 202 present the outer peripheral face pivoted motion state that pastes main part 201, along with the rotation of simulation piece 202, it uses hemisphere casing 13 bottom as the fulcrum to rock to drive main part 201, the motion state that the simulation player rotated the hula hoop. When the player stops rotating the exercise member 001, the operating member 21 in the exercise member 001 no longer presses the control member 22, the control member 22 stops sending the start signal, the driving motor 31 stops rotating, and the simulation member 202 stops rotating.

The synchronous toy of body-building in this application embodiment uses the body-building piece to trigger through the player, and the action that the player rotated the hula hoop can be simulated to the toy piece, realizes the synchronization of toy piece and player action, and the player stops to use the body-building piece then the action of toy piece stop, has strengthened the interdynamic between player and the toy piece, and the interest of reinforcing motion can effectively guide children's initiative motion.

Example two:

the hula hoop synchronizing toy in the embodiment of the present application includes a body building member 001 shown in fig. 10 and a toy member 002 shown in fig. 1 to 7, wherein the structure of the toy member 002 is the same as that of the toy member in the second embodiment, and is not described again in the present embodiment, the body building member 001 in the embodiment of the present application is also set as a hula hoop, and the structure of the body building member 001 is described below.

As shown in fig. 10, the exercise member 001 is provided with a trigger assembly 02, and the trigger assembly 02 is in an elliptical ball shape, is mounted on the exercise member 001 and extends outward.

As shown in fig. 11, the trigger assembly 02 includes a case 24, and an actuating member and a control member (not shown) installed in the case 24, the actuating member including a conductive spring 25, a metal tube 26, and an insulating ring 27, the conductive spring 25 and the metal tube 26 being electrically connected to the control member.

The conductive spring 25 is arranged in the metal cylinder 26, the conductive spring 25 is not in contact with the metal cylinder 26 under the action of no external force, the pins of the conductive spring 25 and the metal cylinder 26 are separated by the insulating ring 27, when a player rotates the hula hoop 003, the conductive spring 25 moves towards the metal cylinder 26 under the action of whipping force, the conductive spring 25 is in contact with the metal cylinder 26, and the trigger control member sends out a trigger signal to control the toy member 002 to move.

The trigger assembly in the body-building member in the embodiment of the application triggers the control member through the contact of the conductive spring and the metal tube, the conductive spring and the metal tube can keep a contact state when the body-building member rotates, and the body-building member is disconnected when not rotating, so that the toy member can be accurately triggered to act.

Example three:

the body-building synchronous toy in the embodiment of the application is shown in fig. 12 and comprises a body-building piece 003, a toy piece 004 and a mounting piece 005, wherein the body-building piece 003 and the toy piece 004 are both mounted on the mounting piece 005, the mounting piece 005 is a bracket, the body-building piece 003 is a sandbag, the sandbag is suspended on the bracket, the body-building piece 003 and the toy piece 004 are connected in a linkage manner, and when the body-building piece 003 is in a use state, the toy piece 004 is triggered to act;

the toy piece 004 comprises a main body 401 and a simulation piece 402 connected with the main body 401, the main body 401 is a doll for simulating a player, and the simulation piece 402 is a small sandbag for simulating a body-building piece 003.

When a player strikes the body-building element 003, the body-building element 003 is in a use state, the body-building element 003 drives the main body 401 to act, so that the main body 401 strikes the simulation element 402, and the motion state of the player is simulated.

As shown in fig. 13, the body-building element 003 is connected with the trigger assembly 09, the main body 401 is provided with a driving assembly, when the body-building element 003 is hit, the trigger assembly 09 is driven to move, the trigger assembly 09 drives the main body 401 to move forward through the driving assembly, and the main body 401 hits the simulation piece 402.

Specifically, trigger assembly 09 includes connecting rod 91 and rotation fulcrum 92, and connecting rod 91 is L shape, and body-building piece 003 is connected to its one end, and the drive assembly is connected to the other end, and the flex point of connecting rod 91 is installed on rotation fulcrum 92, and when body-building piece 003 was hit to be beaten and is rocked, drive connecting rod 91 revoluted and rotate fulcrum 92 for connecting rod 91 promotes drive assembly and drives main part 401 and move towards simulator 402.

The drive assembly is the drive lever 010 of rotationally installing on installed part 005, and the lower extreme and the connecting rod 91 of drive lever 010 are connected, and the upper end is contradicted at the rear of main part 401, and when the lower extreme of drive lever 010 was promoted to connecting rod 91, the upper end of drive lever 010 promoted main part 401 and moved towards simulator 402.

As shown in fig. 14, a sliding seat 403 is fixedly connected to a lower end of the main body 401, the sliding seat 403 is mounted on the mounting member 005 through a spring 012, and when the driving lever 010 pushes the main body 401 and the sliding seat 403 to move toward the dummy 402, the sliding seat 403 compresses the spring 012, and then the sliding seat 403 and the main body 401 are reset by the elastic force of the spring 012.

The rotation shaft of the drive lever 010 is disposed below the slide holder 403. The slide holder 403 is provided with an escape groove 011, and the drive lever 010 passes through the escape groove 011, and moves along the escape groove 011 when the main body 401 and the slide holder 403 move toward the dummy 402.

In the synchronous body-building toy in the embodiment of the application, when a player strikes the body-building piece 003, the body-building piece 003 drives the connecting rod 91 to rotate around the rotating fulcrum 92, so that the connecting rod 91 pushes the driving rod 010 to rotate around the rotating shaft thereof, the driving rod 010 pushes the main body 401 and the sliding seat 403 to move towards the simulation piece 402, the main body 401 strikes the simulation piece 402, and then the main body 401 and the sliding seat 403 reset under the elastic action of the spring 012, thereby realizing the synchronous action of the player striking the body-building piece 003 and the main body 401 striking the simulation piece 402. The player keeps synchronous with the action of the toy 004, has stronger interactivity, and can improve the body-building interest of children.

What has been described above is merely the principles and preferred embodiments of the present application. It should be noted that, for those skilled in the art, the embodiments obtained by appropriately combining the technical solutions respectively disclosed in the different embodiments are also included in the technical scope of the present invention, and several other modifications may be made on the basis of the principle of the present application and should be regarded as the protective scope of the present application.

Claims

1. The utility model provides a synchronous toy of body-building which characterized in that, includes body-building piece (001) and toy spare (002), body-building piece (001) with toy spare (002) communication connection or linkage are connected, when body-building piece (001) is in the user state, trigger toy spare (002) synchronization action.

2. The synchronized exercise toy of claim 1, wherein said toy member (002) includes a body (201) and a simulator member (202) coupled to said body (201), said body (201) driving said simulator member (202) to simulate movement of said exercise member (001) when said toy member (002) is activated.

3. The synchronized fitness toy according to claim 2, wherein the fitness member (001) is provided with a trigger assembly (02), the main body (201) is provided with a driving assembly (03), and the trigger assembly (02) is in communication or linkage connection with the driving assembly (03);

when the body building element (001) is in a use state, the trigger component (02) is triggered, and the trigger component (02) controls the driving component (03) to drive the simulation element (202) to act.

4. The fitness synchronization toy according to claim 3, wherein the driving assembly (03) comprises a driving motor (31) and a start-stop device (32) electrically connected with the driving motor (31), the triggering assembly (02) is in communication connection or linkage connection with the start-stop device (32), the triggering assembly (02) controls the driving motor (31) to start and stop through the start-stop device (32), and the driving motor (31) is used for driving the simulation piece (202) to act.

5. A fitness synchronizing toy according to claim 3, wherein the triggering member (02) is a wireless remote control switch having an energized state and a de-energized state;

when the body building piece (001) is in a use state, the wireless remote control switch is in a power-on state, the wireless remote control switch is in communication connection with the driving assembly (03), and the driving assembly (03) is controlled to drive the simulation piece (202) to act.

6. The body-building synchronous toy according to claim 3, wherein the trigger component (02) is an elastic electric contact switch, and the elastic electric contact switch is electrically connected with the driving component (03) through a lead;

when the body building piece (001) is in a use state, the elastic electric touch switch is closed, the power supply of the driving component (03) is switched on, and the driving component (03) starts to drive the simulation piece (202) to act.

7. A fitness synchronizing toy according to claim 3, wherein the trigger assembly (02) cooperates in a linkage with the drive assembly (03);

when the body building piece (001) is in a use state, the trigger component (02) drives the driving component (03) to synchronously displace after displacing, and the driving component (03) drives the simulation piece (202) to act when displacing.

8. A fitness synchronizing toy according to claim 3, wherein the dummy member (202) is mounted on the main body (201) in a relatively movable manner, the drive assembly (03) cooperating with the dummy member (202); or

The simulation piece (202) and the main body (201) are mutually independent split structures, and the driving component (03) drives the main body (201) to act so that the main body (201) drives the simulation piece (202) to act.

9. A body-building synchronizing toy according to any of the claims 1-8, characterized in that the body-building element (001) and the toy element (002) are separate split structures independent of each other, the body-building element (001) being in wireless communication connection with the toy element (002).

10. An exercise synchronization toy according to any of claims 1-8, further comprising a mounting member (005), said exercise member (001) and said toy member (002) each being mounted on said mounting member (005);

the installation part (005) is provided with a connecting piece, and two ends of the connecting piece are respectively connected with the body-building piece (001) and the toy piece (002).

11. A synchronized exercise toy according to any of claims 1-8, wherein said toy element (002) is mounted on said exercise element (001), said toy element (002) being in wired communication or in wireless communication or in a ganged connection with said exercise element (001).

12. A fitness synchronizing toy according to any of the claims 1-8, wherein the fitness article (001) is any of a hula hoop, a jump rope, a sandbag, a dumbbell, a bicycle.