CN213407741U - Press toy - Google Patents

Abstract

The utility model discloses a pressing toy, which comprises a toy shell, a pressing piece, a rotating part and a driving mechanism; the pressing piece and the driving mechanism are fixedly connected or detachably connected or integrally formed, and the pressing piece and the driving mechanism can slide along a first axial direction relative to the shell; the rotating portion is at least partially within the housing and is rotatable relative to the housing, and the rotating portion is drivable in rotational movement about the first axis when the drive mechanism slides in at least one direction extending in the first axial direction. The user can make through operating the pressing piece the rotation portion rotates, so increase the user and play interactivity when pressing the toy improves the taste of playing, improves the object for appreciation nature of pressing the toy.

Description

Press toy

Technical Field

The utility model relates to a toy technical field especially relates to a press toy.

Background

Toys are indispensable entertainment tools in people's lives, and with the development of society, the types of toys in the market are more and more.

There are many types of toys that mimic the appearance of a figure in the existing toy. Such as a toy of a car, airplane, house, etc., which satisfies the user's visual enjoyment but lacks interactivity with the user, and is liable to reduce the user's interest in playing.

In view of the above, improvements are needed.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects of the prior art and provide a pressing toy which increases the playability and the interestingness.

The technical proposal of the utility model provides a pressing toy, which comprises a toy shell, a pressing piece, a rotating part and a driving mechanism; the pressing piece and the driving mechanism are fixedly connected or detachably connected or integrally formed, and the pressing piece and the driving mechanism can slide along a first axial direction relative to the toy shell; the rotating portion is at least partially within the toy housing and is rotatable relative to the toy housing to drive the rotating portion to rotate about the first axial direction when the drive mechanism slides in at least one direction extending along the first axial direction.

Further, the rotating part comprises a rotating part and a driving disc, the driving disc is driven to rotate by the driving mechanism when the driving mechanism slides along the first direction, and the driving disc is combined with the rotating part and drives the rotating part to rotate; the drive disk disengages from the rotatable member when the drive mechanism slides in a second direction opposite the first direction; the driving mechanism comprises a screw rod, the driving disc comprises a through hole, and the screw rod can move up and down in the through hole and drive the driving disc to rotate.

Furthermore, a clamping block is arranged in the direction in which the driving disc is close to the rotating part, a clamping groove is arranged on one side of the rotating part close to the driving disc, when the driving mechanism slides along the first direction, the clamping groove is combined with the clamping block, and when the driving mechanism moves along the second direction, the clamping groove is separated from the clamping block; the clamping block comprises a right-angle slope and an acute-angle slope, and when the driving mechanism moves along the first direction, the clamping block is combined with the clamping groove through the right-angle slope; the driving mechanism moves along the second direction, and the clamping block is separated from the clamping groove through the acute angle slope.

Furthermore, the toy shell is provided with a guide sleeve extending towards the rotating piece, at least part of the rotating piece is sleeved in or out of the guide sleeve and is in rotating connection with the guide sleeve, and at least one of the pressing piece and the driving mechanism is in sliding connection with the guide sleeve.

Furthermore, a return spring is arranged between the toy shell and the pressing piece, when the pressing piece is pressed, the rotating piece is driven by the pressing piece through the driving mechanism to rotate in the positive direction, and the return spring is compressed; when the pressing piece is released, the return spring pushes the pressing piece to return, so that the screw rod is lifted towards the direction opposite to the pressing direction.

Furthermore, the outer surface of the rotating part is provided with a helical blade, and a sliding track is formed between the helical blade and the inner wall of the toy shell.

Furthermore, balls are placed in the sliding track, and when the rotating piece rotates, the balls roll up and down along the sliding track.

Further, the rotating part comprises at least two rotating modules, and any two adjacent rotating modules are detachably connected.

Further, the toy shell comprises a shell seat and a shell main body connected to the shell seat; a connecting hole is formed in one end, facing the pressing piece, of the shell body, and the pressing piece is connected with the connecting hole in a sliding mode; the shell seat is provided with a connecting column facing the rotating piece, and the rotating piece is rotatably connected to the connecting column;

furthermore, a guide groove communicated with the connecting hole is arranged in the connecting hole; the pressing piece is provided with a guide block, and the guide block is inserted into the guide groove and slides back and forth along the guide groove.

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

the utility model provides a press toy, which comprises a toy shell, a press piece, a rotating part and a driving mechanism. The pressing piece and the driving mechanism are fixedly connected or detachably connected or integrally formed, and the pressing piece and the driving mechanism can slide along the first axial direction relative to the shell. The rotating portion is at least partially within the housing and is rotatable relative to the housing to drive the rotating portion in a rotational motion about the first axis when the drive mechanism slides in at least one direction extending in the first axial direction. The user can make the rotation portion rotate through operating the pressing piece, so the interactivity of the user when playing and pressing the toy is increased, and the interest of playing is improved.

Drawings

The disclosure of the present invention 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 disclosure. In the figure:

FIG. 1 is a perspective view of a press toy according to an embodiment of the present invention;

FIG. 2 is an exploded view of a press toy according to an embodiment of the present invention;

FIG. 3 is a partial cross-sectional view of a press toy according to an embodiment of the present invention;

FIG. 4 is a schematic view of a pressing member according to an embodiment of the present invention;

FIG. 5 is a schematic cross-sectional view of a pressing member according to an embodiment of the present invention;

fig. 6 is an exploded view of the drive mechanism in an embodiment of the invention;

fig. 7 is an exploded view of a rotating member in an embodiment of the invention;

fig. 8 is a schematic view of a slot and a block according to an embodiment of the present invention.

Reference symbol comparison table:

press toy 10

Toy casing 1:

connecting hole 113 of baffle 111 and guide sleeve 112 of housing body 11

Guide groove 114 guide groove 115

Connecting column 121 of shell base 12

Pressing piece 2:

the pressing cap 21 presses the installation groove 222 of the guide block 221 of the connecting rod 22

Limiting groove 223

The rotating member 3:

groove 31, connecting part 32, clamping groove 321, communication hole 322

Mounting groove 33 rotates module 34

The driving mechanism 4:

screw rod 42 for driving disk 41 through hole 411 fixture 412

Elastic arm 421 projection 422

The return spring 5:

the helical blade 6:

stop plate 61 blade module 62

Ball 7

Detailed Description

The following describes the present invention with reference to the accompanying drawings.

It is easily understood that, according to the technical solution of the present invention, a plurality of structural modes and implementation modes that can be mutually replaced by those of ordinary skill in the art can be achieved without changing the spirit of the present invention. Therefore, the following detailed description and the accompanying drawings are only exemplary illustrations of the technical solutions of the present invention, and should not be construed as limiting or restricting the technical solutions of the present invention in its entirety or as a limitation of the present invention.

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.

The first axial direction in this application is the direction of extension of the press member relative to the direction of movement of the toy housing, with particular reference to the direction of extension of the axis of the toy housing in fig. 1; the first direction is a direction moving towards the direction close to the inner part of the toy shell along the first axial direction; the second direction is a direction moving toward the outside of the toy housing along the first axial direction.

In one embodiment of the present invention, as shown in fig. 1-4, a press toy 10 includes a toy housing 1, a press member 2, a rotating portion, and a driving mechanism 4.

The pressing member 2 is fixedly connected or detachably connected or integrally formed with the driving mechanism 4, and both can slide along the first axial direction relative to the toy shell 1.

The rotor is at least partially within the toy housing 1 and is rotatable relative to the toy housing 1, and is capable of being driven in a rotational movement about a first axial direction when the drive mechanism 4 is slid in at least one direction along the first axial extension.

The pressing toy 10 is intended to enhance the interest of people playing. It has a toy housing 1, a pressing member 2, a rotating portion and a driving mechanism 4.

Alternatively, the shape of the toy casing 1 may be an automobile, an airplane, a train, a rocket, or the like, without limitation.

The driving mechanism 4 is arranged in the toy shell 1, and a part of the pressing piece 2 extends into the toy shell 1 and is connected with the driving mechanism 4. The pressing element 2 is fixed or integrally formed or detachably connected with the driving mechanism 4, wherein the detachable connection is defined as that the pressing element 2 and the driving mechanism can be connected or separated. The press member 2 is slidably connected to the toy housing 1 and slides back and forth in a first axial direction. As shown in fig. 1, a central axis of the toy casing 1 is defined as a first axial direction. When the pressing piece 2 drives the driving mechanism 4 to slide in the first axial direction, the driving part rotates by taking the first axial direction as an axis.

Preferably, as shown in fig. 1 to 3, the rotating part includes the rotating member 3 and a driving disk 41, the driving disk 41 is driven to rotate when the driving mechanism 4 slides along the first direction, and the driving disk 41 is combined with the rotating member 3 and drives the rotating member 3 to rotate. When the driving mechanism 4 slides in a second direction opposite to the first direction, the driving disc 41 is disengaged from the rotation member 3. The driving mechanism 4 includes a screw rod 42, the driving disk 41 includes a through hole 411, and the screw rod 42 can move up and down in the through hole 411 and drive the driving disk 41 to rotate.

As shown in fig. 1 and 3, the direction in which the pressing member 2 moves toward the inside of the toy housing 1 is a first direction. The direction in which the pressing member 2 moves toward the outside of the toy housing 1 is the second direction. The driving disk 41 can be coupled to and separated from the rotating member 3, and a through hole 411 is formed in the driving disk 41, and the screw 42 is engaged with the through hole 411. When the driving mechanism 4 moves along the first direction, the screw rod 42 contacts with the hole wall of the through hole 411, the screw rod 42 couples the driving disk 41 with the rotating member 3 and drives the driving disk 41 to rotate, and then the driving disk 41 drives the rotating member 3 to rotate. When the driving mechanism 4 moves in the second direction, the screw rod 42 drives the driving disc 41 to separate from the rotating member 3.

Preferably, as shown in fig. 1 to 3 and fig. 6 to 8, the driving disc 41 includes a latch 412 in a direction approaching the rotating element 3, a side of the rotating element 3 approaching the driving disc 41 is provided with a latch slot 321, when the driving mechanism 4 slides in the first direction, the latch slot 321 is engaged with the latch 412, and when the driving mechanism 4 moves in the second direction, the latch slot 321 is disengaged from the latch 412. The latch 412 includes a right-angled slope and an acute-angled slope, and when the driving mechanism 4 moves in the first direction, the latch 412 is engaged with the latch slot 321 through the right-angled slope. The driving mechanism 4 moves in the second direction, and the latch 412 is disengaged from the latch groove 321 through the acute slope.

The latch 412 is formed to protrude from the driving disc 41 toward the rotation member 3, and the catch 321 is formed to be recessed downward from the surface of the rotation member 3. The latch 412 is matched with the latch slot 321. As shown in fig. 8, the latch 412 has a right triangle shape having a right slope and an acute slope. Accordingly, the engaging groove 321 has a vertical surface and a slope surface, the right-angle slope may contact with the vertical surface, and the acute-angle slope may contact with the slope surface. When the drive mechanism 4 moves in the first direction, the right-angled slope comes into contact with the vertical surface, thereby pushing the drive disc 41 to rotate. When the driving mechanism 4 moves in the second direction, the right-angled slope separates from the vertical surface, the acute-angled slope slides along the slope surface, and the latch 412 separates from the latch slot 321.

In one embodiment of the present invention, as shown in fig. 1-4, a push toy 10 includes a toy housing 1, a push member 2, a rotating member 3, and a driving mechanism 4.

The toy housing 1 is provided with a guide sleeve 112 extending towards the rotor 3, at least a part of the rotor 3 being arranged in or outside the guide sleeve 112 and being rotatably connected to the guide sleeve 112.

At least one of the pressing element 2 and the drive mechanism 4 is connected to the guide sleeve 112 in a sliding manner.

The guide sleeve 112 has a guide groove 115 opening toward the pressing member 2, the pressing member 2 at least partially extends into the guide groove 115 and is slidably connected with the guide groove 115, and another portion of the pressing member 2 is fixedly connected with the driving mechanism 4 or detachably connected or integrally formed.

The drive mechanism 4 is rotatably connected to the rotor 3.

When the pressing member 2 is operated, the pressing member 2 drives the driving mechanism 4 to move in the extending direction of the guide sleeve 112, so that the driving mechanism 4 drives the rotating member 3 to rotate in the forward direction or the reverse direction.

The toy housing 1 has a housing cavity in which the rotor 3 is mounted for rotation within the housing cavity. Optionally, a guide sleeve 112 is provided in the housing cavity, and the rotating member 3 is sleeved on the guide sleeve 112 and is in clearance fit with the guide sleeve 112, so that the rotating member 3 can rotate around the guide sleeve 112. One end of the toy shell 1 is connected with a slidable pressing piece 2, wherein a connecting hole 113 communicated with the shell cavity is formed in the toy shell 1, a sliding groove or a sliding rail is arranged in the connecting hole 113, and the pressing piece 2 is matched with the sliding groove or the sliding rail, so that the sliding of the pressing piece 2 is realized. The guide sleeve 112 is provided with a guide groove 115, a part of the pressing member 2 is exposed outside the connecting hole 113, and the other part of the pressing member extends into the guide groove 115 through the connecting hole 113 and is connected with the driving mechanism 4. The guide groove 115 serves to guide the movement of the pressing member 2.

The drive mechanism 4 is connected between the rotating part 3 and the pressing part 2, and the drive mechanism 4 has a fixed end and an action end, wherein the fixed end is connected with the pressing part 2, and the action end is rotatably connected with the rotating part 3. When a user operates the pressing piece 2 to slide, the pressing piece 2 drives the driving mechanism 4 to move, and the action end of the driving mechanism 4 acts on the rotating piece 3 to enable the rotating piece 3 to rotate. The driving mechanism 4 may be a gear set structure or a worm and gear structure, as long as the driving mechanism can drive the rotating member 3 to rotate under the driving of the pressing member 2.

Alternatively, the rotation member 3 is always in a rotated state during the sliding of the pressing member 2 by the user's repeated operation.

Alternatively, when the user presses the pressing piece 2, the driving mechanism 4 drives the rotating piece 3 to rotate in the forward direction; when the user pulls up the pressing member 2, the driving mechanism 4 drives the rotation member 3 to rotate reversely.

The present embodiment provides a pressing toy 10 including a toy case 1, a pressing member 2, and a rotation member 3. The rotation member 3 is rotatably coupled in the toy case 1, and the pressing member 2 is slidably coupled to the toy case 1. A driving mechanism 4 for driving the rotating piece 3 to rotate is connected between the pressing piece 2 and the rotating piece 3. When the pressing member 2 is operated, the pressing member 2 controls the driving mechanism 4, so that the driving mechanism 4 drives the rotation member 3 to rotate. So set up, improved with the toy between the interdynamic, the user realizes through the pressing piece 2 that the control rotates the pivoted purpose of piece 3, has increased the enjoyment of playing and pressing toy 10 to improve the interest of user's playing. The pressure-reducing device also has the function of reducing pressure in the process of continuously pressing by the user, and helps the user to reduce the pressure.

Preferably, as shown in fig. 2-3 and fig. 6, the driving mechanism 4 includes a driving disk 41 for driving the rotating member 3 to rotate and a screw rod 42 for driving the driving disk 41 to rotate. The screw rod 42 is connected to the pressing member 2, and the driving disk 41 is connected to the rotation member 3 and is rotatably connected to the screw rod 42. When pressing the pressing member 2, the pressing member 2 drives the screw rod 42 to move along the pressing direction, the screw rod 42 drives the driving disk 41 to rotate, and the driving disk 41 drives the rotating member 3 to rotate.

The driving mechanism 4 comprises a screw rod 42 and a driving disk 41, wherein the screw rod 42 is a fixed end of the driving mechanism 4, the driving disk 41 is an acting end of the driving mechanism 4, and the screw rod 42 is matched with the driving disk 41. As shown in fig. 6, a through hole 411 having a "∞" shape is provided in the drive disk 41, and when the screw 42 is inserted into the through hole 411 and the screw 42 slides in the through hole 411, the screw of the screw 42 is engaged with the through hole 411 having the "∞" shape, and the drive disk 41 can be driven to rotate. The driving mechanism 4 is simple in structure and convenient to produce and manufacture.

Preferably, as shown in fig. 2-3 and 6, the rotating member 3 is provided with a groove 31 opening toward the screw rod 42, and when the pressing member 2 is pressed, the pressing member 2 drives the screw rod 42 to move, and the screw rod 42 extends into the groove 31 through the driving disk 41.

Specifically, the drive disk 41 is connected to the end of the rotating member 3 facing the pressing member 2, and the recess 31 is recessed in the end of the rotating member 3 facing the pressing member 2, and the recess 31 communicates with the through hole 411 of the drive disk 41. One end of the screw rod 42 is connected to the pressing member 2, and the other end thereof passes through the through hole 411. When a user applies force to press the pressing piece 2, the pressing piece 2 drives the screw rod 42 to move towards the direction close to the groove 31, the screw rod 42 extends into the groove 31, and the groove 31 is used for avoiding the movement of the screw rod 42. When the screw rod 42 extends into the groove 31, the screw rod 42 cooperates with the through hole 411 to drive the driving disk 41 to rotate in the forward direction, the driving disk 41 is connected with the rotating member 3, and the driving disk 41 rotates in the forward direction to drive the rotating member 3 to rotate in the forward direction. When the user pulls the pressing member 2, the pressing member 2 drives the screw rod 42 to move away from the groove 31, and at this time, the screw rod 42 drives the driving disk 41 to rotate in the opposite direction, and the driving disk 41 drives the rotating member 3 to rotate in the opposite direction.

Preferably, as shown in fig. 2 to 3 and 6, the rotating member 3 has a connecting portion 32 for connecting with the driving disk 41, and the recess 31 is located on a side of the connecting portion 32 away from the pressing member 2. A baffle 111 is provided on the end of the guide sleeve 112 near the connection 32. The driving disk 41 is located between the connecting portion 32 and the baffle 111, and is detachably connected with the connecting portion 32, and the screw rod 42 passes through the baffle 111 and is connected with the driving disk 41.

Specifically, the rotating member 3 has a connecting portion 32, and the recess 31 is located on a side of the connecting portion 32 away from the pressing member 2. A communication hole 322 is provided in the connecting portion 32, and the communication hole 322 communicates with the recess 31. A baffle 111 is provided on the side of the connecting portion 32 close to the pusher 2, and the baffle 111 is connected to an end of a guide sleeve 112. An installation space is formed between the baffle 111 and the connecting part 32, the driving disk 41 is positioned in the installation space and is detachably connected with the connecting part 32, and the screw rod 42 penetrates through the baffle 111 and is connected with the driving disk 41. When the screw rod 42 moves toward the direction close to the groove 31, the screw rod 42 first presses the driving disk 41, so that the driving disk 41 is connected to the connecting portion 32. Then, after the screw rod 42 continues to move, the screw rod 42 drives the driving disk 41 to rotate in the forward direction, and the driving disk 41 drives the rotating member 3 to rotate in the forward direction.

When the screw rod 42 moves away from the groove 31, the baffle 111 stops the driving disk 41 to prevent the driving disk 41 from separating from the rotating member 3. At this time, the screw rod 42 drives the driving disk 41 to rotate reversely, and the driving disk 41 drives the rotating member 3 to rotate reversely.

Preferably, as shown in fig. 3 and 6-7, a catch 321 is provided on the surface of the connecting portion 32 facing the drive disc 41. The driving disc 41 is provided with a latch 412 engaged with the latch slot 321. When the pressing member 2 is pressed, the latch 412 is engaged with the latch groove 321. When the pressing member 2 is released, the latch 412 is separated from the latch groove 321.

The connecting portion 32 is concavely provided with a locking groove 321, the driving disk 41 is provided with a locking block 412, and the locking block 412 is matched with the locking groove 321. When the driving disc 41 is connected to the connecting portion 32, the driving disc 41 is spaced apart from the baffle 111. Thus, when the screw rod 42 moves away from the groove 31, the screw rod 42 drives the driving disc 41 to separate from the connecting portion 32, so that the driving disc 41 does not drive the rotating member 3 to rotate. The flap 111 then stops the drive plate 41 so that the screw 42 cannot continue to move with the drive plate 41. With this arrangement, when the user operates the pressing member 2 to slide repeatedly, the rotary member 3 always rotates in the same direction.

In another embodiment, the connecting portion 32 is provided with a latch 412, and the driving disk 41 is provided with a latch slot 321, which is selected according to the actual situation. Of course, the detachable connection of the driving disc 41 and the connecting portion 32 is not limited to the above two methods, and other structures may be adopted as long as the driving disc 41 and the connecting portion 32 can be connected and separated.

Preferably, as shown in fig. 3 and 6, a return spring 5 is connected between the shutter 111 and the pressing member 2. When the pressing piece 2 is pressed, the pressing piece 2 drives the rotating piece 3 to rotate in the positive direction through the driving mechanism 4, and the return spring 5 is compressed. When the pressing member 2 is released, the return spring 5 pushes the pressing member 2 to return, so that the screw rod 42 is lifted in a direction opposite to the pressing direction, and the screw rod 42 drives the rotating member 3 to rotate reversely.

The return spring 5 is sleeved outside the screw rod 42. When the pressing member 2 is pressed down, the pressing member 2 moves toward the direction close to the rotating member 3, and the return spring 5 is compressed to generate elastic deformation. After the pressing member 2 slides to the extreme end, the pressing member 2 is released, the pressing member 2 stops being pressed, and at this time, the return spring 5 recovers its shape, and pushes the pressing member 2 to move to the initial position in a direction away from the rotation member 3. The arrangement is convenient for the user to operate and use. Specifically, please refer to the related contents in the foregoing description, and details are not repeated herein, how to drive the rotating member 3 to rotate forward and backward by the driving mechanism 4.

Alternatively, as shown in fig. 5, the pressing member 2 includes a pressing cap 21 and a pressing link 22, the pressing link 22 is connected to the pressing cap 21, a mounting groove 222 opened toward the return spring 5 is provided on the pressing link 22, and at least a portion of the return spring 5 is located in the mounting groove 222, so that the return spring 5 is more stably mounted.

Alternatively, as shown in fig. 5-6, the screw rod 42 is coupled within the mounting slot 222. A stopper groove 223 is formed in a groove wall of the mounting groove 222, an end of the screw rod 42 facing the pressing member 2 is connected to an elastic arm 421, and an end of the elastic arm 421 is connected to a projection 422. When the screw rod 42 is installed, the protrusion 422 is clamped in the limiting groove 223, so that the screw rod 42 is connected with the pressing link 22. So set up for hob 42 can dismantle with pressing piece 2 and be connected, easy to assemble.

Preferably, as shown in fig. 3, the rotation member 3 is provided with a fitting groove 33. The fitting groove 33 is located on the side of the connecting portion 32 close to the pressing member 2, and communicates with the recess 31 through the connecting portion 32. The toy case 1 is provided with a guide sleeve 112 extending toward the fitting groove 33, a baffle 111 is provided on an end portion of the guide sleeve 112 toward the connecting portion 32, and the guide sleeve 112 and the baffle 111 are inserted into the fitting groove 33.

As shown in fig. 2 to 3, a fitting groove 33 is further provided at an end of the rotation member 3 facing the pressing member 2, the fitting groove 33 and the groove 31 are respectively located at both sides of the connecting portion 32, wherein the groove 31 is located at a side of the connecting portion 32 away from the pressing member 2, the fitting groove 33 is located at a side of the connecting portion 32 close to the pressing member 2, and the fitting groove 33 and the groove 31 communicate through the communication hole 322. The inside of the toy housing 1 is provided with a guide sleeve 112 extending toward the fitting groove 33. When the rotation member 3 is mounted with the toy case 1, the guide sleeve 112 and the blocking plate 111 are inserted into the fitting groove 33, and the guide sleeve 112 is fitted with the fitting groove 33 so that the rotation member 3 can be accurately mounted, ensuring the mounting quality of the pressing toy 10.

Preferably, as shown in fig. 2 and 7, the rotating member 3 is provided with a spiral blade 6 on an outer surface thereof, and the spiral blade 6 and an inner wall of the toy housing 1 form a sliding track therebetween. The entire rotation member 3 is cylindrical, the entire spiral blade 6 is spiral, and the spiral blade 6 extends in the up-down direction along the rotation member 3 on the outer surface of the rotation member 3. A user may place objects, such as marbles, toy balls, toy carts, etc., within the sliding track. Thus, when the rotating piece 3 rotates, the object can move in the sliding track, and the fun of playing is added.

Preferably, as shown in fig. 2 and 7, the balls 7 are placed in a sliding track along which the balls 7 roll up and down when the rotating member 3 rotates. When the rotating member 3 rotates, the helical blade 6 also rotates, and the balls 7 can roll along the helical blade 6. In one embodiment, when the pressing member 2 is pressed to rotate the rotating member 3 in the forward direction, the balls 7 move upward, and when the pressing member 2 is released to separate the driving disk 41 from the connecting portion 32, the rotating member 3 rotates at a slower speed, and at this time, the balls 7 roll downward along the spiral blade 6 under the influence of gravity. The smooth surface of the balls 7 reduces the friction force during rolling, so that the rolling is smoother.

Preferably, as shown in fig. 2 and 7, at least two stop plates 61 for stopping the balls 7 are disposed on the screw blade 6, and at least one ball 7 is disposed between two adjacent stop plates 61. The two stop plates 61 are arranged on the helical blade 6 at intervals, the stop plates 61 stop the rolling of the ball 7, so that the ball 7 can only roll between the two stop plates 61, the two stop plates 61 limit the effective stroke of the ball 7, and the ball 7 can be ensured to roll up and down between the two stop plates 61.

Alternatively, a plurality of stop plates 61 are provided at intervals on the screw blade 6, and the ball 7 is provided between any two adjacent stop plates 61. The plurality of stoppers 61 divide the spiral blade 6 into a plurality of stages, so that the rolling stroke of the balls 7 is shortened, and the balls 7 can smoothly move upward when the rotating member 3 rotates in the reverse direction.

Preferably, as shown in fig. 2 and 7, the rotating member 3 includes at least two rotating modules 34, and any two adjacent rotating modules 34 are detachably connected to each other. One end of each rotating module 34 is provided with a connecting rod and the other end is provided with a connecting groove. When any adjacent two of the rotating modules 34 are installed, the connecting rod of one of the rotating modules 34 is inserted into the connecting groove of the other rotating module 34. So configured, the modular design of the rotor 3 is facilitated and the user can select the number of rotor modules 34 to be incorporated based on the length of the toy housing 1.

Alternatively, a blade module 62 is provided on the outer side of each of the rotation modules 34, and when the plurality of rotation modules 34 are assembled into the rotation member 3, the plurality of blade modules 62 are assembled to form the helical blade 6.

Preferably, as shown in fig. 1-2 and 4, the toy housing 1 includes a housing seat 12 and a housing body 11 coupled to the housing seat 12. A connection hole 113 is provided on an end of the housing main body 11 facing the pressing piece 2, and the pressing piece 2 is slidably connected to the connection hole 113. The housing base 12 is provided with a connecting column 121 facing the rotating member 3, and the rotating member 3 is rotatably connected to the connecting column 121.

The toy shell 1 is assembled by a shell seat 12 and a shell body 11, and a rotating groove matched with the connecting column 121 is arranged on the end part of the rotating piece 3 facing the shell seat 12. When the toy 10 is assembled, the pressing member 2 is inserted into the coupling hole 113, the rotation member 3 is positioned in the housing body 11, and the coupling post 121 of the housing seat 12 is inserted into the coupled rotation groove. So configured, press assembly of toy 10 is facilitated.

Optionally, a mounting hole is formed in the housing seat 12, a mounting post is formed on the housing body 11, and when the housing body 11 is mounted on the housing seat 12, the mounting post is inserted into the mounting hole, so that the housing body 11 is fixed to the housing seat 12.

Preferably, as shown in fig. 4, a guide groove 114 communicating with the connection hole 113 is provided in the connection hole 113. The pressing member 2 is provided with a guide block 221, and the guide block 221 is inserted into the guide groove 114 and slides back and forth along the guide groove 114. The pressing piece 2 has a pressing cap 21 and a pressing link 22 extending toward the connection hole 113, and the pressing cap 21 and the pressing link 22 are connected to form the pressing piece 2. A guide block 221 is provided on an outer surface of the pressing link 22, and when the pressing member 2 is assembled with the connection hole 113, the pressing link 22 is located in the connection hole 113, and the guide block 221 is inserted into the guide groove 114 and is in clearance fit with the guide groove 114, so that the guide block 221 can slide back and forth in the guide groove 114. The guide groove 114 is engaged with the guide block 221, so that the pressing member 2 can slide along a predetermined track in the connection hole 113, and the sliding of the pressing member 2 is more stable.

Preferably, as shown in fig. 1, the toy housing 1 is in the form of a rocket model. The pressing piece 2 is the end of a rocket model. The toy shell 1 is designed into the shape of a rocket model and is more popular with users.

Referring to fig. 1 to 6, the present invention will be described with reference to a press toy 10 according to the present embodiment.

The pressing toy 10 of the present example includes a toy case 1, a pressing member 2, a rotating member 3, and a driving mechanism 4.

The toy shell 1 is rocket-shaped as a whole, the toy shell 1 is provided with a shell body 11 and a shell seat 12, and the shell body 11 is connected to the shell seat 12 and connected with the shell seat 12 to form a shell cavity.

The pressing member 2 includes a pressing cap 21 and a pressing link 22, and the pressing cap 21 is connected to the pressing link 22. A connection hole 113 is provided at an end of the housing body 11 facing the pressing member 2, and the pressing link 22 is inserted into the connection hole 113 and is in clearance fit with the connection hole 113. The connection hole 113 is provided therein with a guide groove 114 extending in the extending direction of the connection hole 113, and the pressing link 22 is provided thereon with a guide block 221 extending in the extending direction of the pressing link 22. When the pressing link 22 is located in the connection hole 113, the guide block 221 is fitted in the guide groove 114.

The rotating part 3 is arranged in the shell cavity, a connecting column 121 extending towards the rotating part 3 is arranged on the shell seat 12, and a rotating groove is formed in the bottom of the rotating part 3. When the rotating member 3 is mounted on the housing base 12, the connecting column 121 is inserted into the rotating groove and is in clearance fit with the rotating groove, so that the rotating member 3 can rotate with the connecting column 121 as an axis.

The rotor 3 has a groove 31 and a fitting groove 33, a connecting portion 32 is provided between the groove 31 and the fitting groove 33, a communicating hole 322 is provided in the connecting portion 32, and the groove 31 and the fitting groove 33 communicate through the communicating hole 322. A guide sleeve 112 extending toward the fitting groove 33 is attached to the case main body 11, and when the rotor 3 is mounted in the case main body 11, the guide sleeve 112 extends into the fitting groove 33. A baffle 111 is provided at an end of the guide sleeve 112, and an installation space is formed between the baffle 111 and the connection portion 32.

The guide sleeve 112 is provided with a guide groove 115 opening toward the pressing link 22, and the pressing link 22 is inserted into the guide groove 115 to be in clearance fit with the guide groove 115.

The rotation member 3 includes three rotation modules 34, and a vane module 62 is provided on an outer surface of each rotation module 34. The three rotary modules 34 are connected in series to form the rotary member 3, and the three vane modules 62 are also connected in series to form the helical vane 6 connected to the rotary member 3. Two stop plates 61 are arranged on the helical blade 6 at intervals, three balls 7 are arranged between the two stop plates 61, the balls 7 can roll on the helical blade 6, and the stop plates 61 stop the balls 7 to prevent the balls 7 from separating from the helical blade 6.

The drive mechanism 4 includes a screw 42 and a drive plate 41, and the drive plate 41 has a through hole 411 of "∞". The driving disc 41 is located in the installation space, the connecting portion 32 is provided with a plurality of slots 321 at intervals, the driving disc 41 is provided with a plurality of blocks 412 at intervals, and when the driving disc 41 is connected to the connecting portion 32, the plurality of blocks 412 are correspondingly matched with the plurality of slots 321. One end of the screw rod 42 is connected to the pressing link 22, and the other end thereof passes through the shutter 111 and engages with the through hole 411.

A return spring 5 is fitted around the outside of the screw rod 42, and one end of the return spring 5 is connected to the pressing link 22 and the other end is connected to the shutter 111.

For convenience of explanation, the play process of the pressing toy 10 is defined as below in which the pressing member 2 moves toward the rotating member 3 and the pressing member 2 moves away from the rotating member 3.

When the user presses down the pressing member 2, the pressing member 2 moves downward, and the screw rod 42 moves downward along with the pressing member 2. During the downward movement of the screw rod 42, the screw rod 42 drives the driving disk 41 to rotate forward. Because the latch 412 of the driving disc 41 is located in the latch slot 321, the driving disc 41 rotates to drive the rotating member 3 to rotate in the forward direction. When the rotary member 3 rotates in the forward direction, the balls 7 roll upward along the spiral vane 6.

In the process of pressing the pressing member 2, the return spring 5 is pressed and deformed. When the user stops applying the force to the pressing member 2, the return spring 5 is restored to be deformed, pushing the pressing member 2 to move upward, and the screw rod 42 follows the pressing member 2 to move upward. During the upward movement of the screw rod 42, the screw rod 42 drives the driving disk 41 to move upward, so that the driving disk 41 is separated from the connecting portion 32. At this time, the rotor 3 loses its driving force and the rotational speed becomes low. The balls 7 roll downwards under the influence of gravity. During the process that the screw rod 42 drives the driving disc 41 to move upwards, the baffle 111 stops the driving disc 41, and then the screw rod 42 moves upwards relative to the driving disc 41 continuously.

To sum up, the utility model discloses a press toy, which comprises a toy shell, a press piece and a rotating piece. The rotary member is rotatably coupled within the toy housing and the press member is slidably coupled to the toy housing. A driving mechanism for driving the rotating piece to rotate is connected between the pressing piece and the rotating piece. When the pressing piece is operated, the pressing piece drives the driving mechanism to move, and the driving mechanism drives the rotating piece to rotate. The user enables to rotate through operating the pressing piece, so that the interactivity of the user when playing and pressing the toy is increased, and the interest of playing is improved.

It should be noted that the forward and reverse directions are only for illustrating that the rotating member can rotate in two opposite directions, and are not absolute forward and reverse directions.

The foregoing is considered as illustrative only of the principles and preferred embodiments of the invention. It should be noted that, for those skilled in the art, on the basis of the principle of the present invention, several other modifications can be made, and the protection scope of the present invention should be considered.

Claims (10)

1. A pressing toy (10) is characterized by comprising a toy shell (1), a pressing piece (2), a rotating part and a driving mechanism (4);

the pressing piece (2) and the driving mechanism (4) are fixedly connected or detachably connected or integrally formed, and the pressing piece and the driving mechanism can slide along a first axial direction relative to the shell (1);

the rotating part is at least partially arranged in the toy shell (1) and can rotate relative to the toy shell (1), and when the driving mechanism (4) slides along at least one direction of the first axial extension, the rotating part can be driven to rotate around the first axial extension.

2. The pressing toy (10) according to claim 1, wherein the rotating portion includes a rotating member (3) and a driving plate (41), the driving plate (41) is driven to rotate by the driving mechanism (4) when sliding in the first direction, and the driving plate (41) is combined with the rotating member (3) and drives the rotating member (3) to rotate;

when the driving mechanism (4) slides along a second direction opposite to the first direction, the driving disc (41) is disengaged from the rotating part (3);

the driving mechanism (4) comprises a screw rod (42), the driving disc (41) comprises a through hole (411), and the screw rod (42) can move up and down in the through hole (411) and drive the driving disc (41) to rotate.

3. The pressing toy (10) according to claim 2, wherein the driving plate (41) includes a latch (412) in a direction approaching the rotating member (3), a side of the rotating member (3) approaching the driving plate (41) is provided with a latch groove (321), the latch groove (321) and the latch (412) are engaged when the driving mechanism (4) slides in the first direction, and the latch groove (321) and the latch (412) are disengaged when the driving mechanism (4) moves in the second direction;

the clamping block (412) comprises a right-angle slope and an acute-angle slope, and when the driving mechanism (4) moves along the first direction, the clamping block (412) is combined with the clamping groove (321) through the right-angle slope;

the driving mechanism (4) moves along a second direction, and the clamping block (412) is separated from the clamping groove (321) through an acute slope.

4. A press toy (10) according to any of claims 1-3, wherein the toy housing (1) is provided with a guide sleeve (112) extending towards the rotary member (3), at least a part of the rotary member (3) being arranged in or outside the guide sleeve (112) and being rotatably connected to the guide sleeve (112), and wherein at least one of the press member (2) and the drive mechanism (4) is slidably connected to the guide sleeve (112).

5. A pressing toy (10) according to any one of claims 2-3, wherein a return spring (5) is arranged between the toy housing (1) and the pressing member (2), and when the pressing member (2) is pressed, the pressing member (2) drives the rotating member (3) to rotate in a forward direction through the driving mechanism (4), and the return spring (5) is compressed;

when the pressing piece (2) is released, the return spring (5) pushes the pressing piece (2) to return, so that the screw rod (42) is lifted in the direction opposite to the pressing direction.

6. The pressing toy (10) according to claim 2, wherein the rotating member (3) is provided with a helical blade (6) on its outer surface, and the helical blade (6) and the inner wall of the toy housing (1) form a sliding track therebetween.

7. The push toy (10) according to claim 6, wherein a ball (7) is placed in the sliding track, and when the rotating member (3) rotates, the ball (7) rolls up and down along the sliding track.

8. The press toy (10) according to claim 2, wherein the rotary member (3) comprises at least two rotary modules (34), and any adjacent two rotary modules (34) are detachably connected to each other.

9. The press toy (10) according to claim 2, wherein the toy housing (1) comprises a housing seat (12) and a housing body (11) connected to the housing seat (12);

a connecting hole (113) is formed in one end, facing the pressing piece (2), of the shell body (11), and the pressing piece (2) is connected with the connecting hole (113) in a sliding mode;

the shell base (12) is provided with a connecting column (121) facing the rotating part (3), and the rotating part (3) is rotatably connected to the connecting column (121).

10. The pressing toy (10) according to claim 9, wherein a guide groove (114) communicating with the connection hole (113) is provided in the connection hole (113);

the pressing piece (2) is provided with a guide block (221), and the guide block (221) is inserted into the guide groove (114) and slides back and forth along the guide groove (114).

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