WO2019169657A1

WO2019169657A1 - Toy car with parts capable of bouncing when running

Info

Publication number: WO2019169657A1
Application number: PCT/CN2018/079219
Authority: WO
Inventors: 谢国华
Original assignee: 广州灵动创想文化科技有限公司
Priority date: 2018-03-08
Filing date: 2018-03-16
Publication date: 2019-09-12
Also published as: CN108295484A

Abstract

Disclosed is a toy car with parts capable of bouncing when running, comprising a shell, driving wheels (2), a bouncing part, a driving shaft and a transmission part. The driving shaft is connected with the driving wheels (2) and the transmission part respectively. the transmission part is installed in the shell and fixedly provided with a first magnet (63). The bouncing part is installed on the shell and comprises a containing piece (41) and a bouncing piece (42) arranged in the containing piece (41), and the bouncing piece (42) is fixedly provided with a second magnet (421). The first magnet (63) and the second magnet (421) have the same magnetic polarity. The driving shaft receives a rotational input of the driving wheels (2) and can drive the transmission part to move, the first magnet (63) on the transmission part can move along with the transmission part, and the second magnet (421) is driven to bounce. The driving shaft rotates to drive the transmission part to move, so that the magnet on the transmission part move along with the transmission part, and then the mutual repulsion effect of the magnets are utilized to make the bouncing part on the toy car bounce.

Description

A toy car that can be beaten while driving

Technical field

The present invention relates to a toy, and more particularly to a toy vehicle.

Background technique

The toy cars that are common in the market can only achieve the simple function of advancement. The components on the car are usually fixed, the gameplay is single, the visual effects are monotonous, and the fun is low.

Summary of the invention

Based on this, it is an object of the present invention to provide a toy vehicle in which a running component can be beaten.

The technical solution adopted by the invention is:

A toy vehicle that can be bouncing in a running component includes a casing, a driving wheel, a beating portion, a driving shaft and a transmission portion; the driving shaft is respectively connected to the driving wheel and the transmission portion; the transmission portion is mounted on the casing a first magnet is fixed on the transmission portion; the jumping portion is mounted on the outer casing, and includes a receiving member and a jumping member disposed in the receiving member, and the second magnet is fixed on the jumping member The first magnet and the second magnet are the same magnetic poles; the driving shaft receives the rotation input of the driving wheel, can drive the transmission portion to move, and the first magnet on the transmission portion moves and drives The second magnet produces a jump.

The toy vehicle with the running component in the running part drives the transmission part to move by the rotation of the driving shaft, so that the magnet on the transmission part moves accordingly, and then the mutual repulsive action between the magnets is used to make the jumping piece on the toy car beat. The structure is simple, the gameplay is novel, the visual effect is rich, and the interest is strong.

Further, further comprising a tooth box fixed in the outer casing, the tooth box including an input/output shaft, the drive shaft being the input/output shaft; the input/output shaft and the driving wheel respectively a transmission portion is connected; after the tooth box receives the rotation input of the drive wheel through the input/output shaft, the drive wheel can be driven to rotate by the input/output shaft, and the transmission portion is driven to move. The first magnet on the transmission portion moves with it and drives the second magnet to generate a jump.

Further, the transmission portion includes a cam, a first transmission lever and a first lever shaft, the cam is sleeved on the drive shaft, and the first transmission lever is hinged to the outer casing through the first lever shaft The first end is connected to the cam, and the second end is fixed with a first magnet.

Further, the bounce portion is disposed at a top of the outer casing, and the cam can drive the first end of the first transmission lever to move up and down, so that the first transmission lever is fixed with the second magnet of the first magnet The end moves up and down accordingly.

Further, the jumping portion includes a first receiving member, a second receiving member, a first jumping member and a second jumping member, wherein the first receiving member is provided with a first jumping member, and the first jumping member is fixed with the second rotating member a second jumping member is disposed in the second receiving member, and a fourth magnet is fixed on the second jumping member; the first jumping member is alternately bouncing or synchronously beating.

Further, the transmission portion further includes a second transmission lever and a second lever shaft, the second transmission lever being hinged in the outer casing by a second lever shaft; a first end of the second transmission lever and the a second end of the first transmission lever is coupled, the second end of which is fixed with a third magnet; the second end of the first transmission lever can drive the first end of the second transmission lever to move up and down, so that the second The second end of the transmission lever is correspondingly moved up and down; the third magnet and the fourth magnet are isotropic magnetic poles.

Further, the second end of the first transmission lever is provided with a transverse through hole, and the first end of the second transmission lever is provided with a lap plate, and the size of the lateral through hole is larger than the size of the lap plate The lap plate is inserted into the lateral through hole.

Further, the transmission portion further includes a spring and a fixing member; one end of the spring is fixed on a bottom surface of the outer casing, and the other end is fixed at a second end of the first transmission lever; On the first lever shaft.

Further, the tooth box is an inertia tooth box or a back force tooth box; and further includes a driven wheel mounted on the outer casing.

Further, the outer casing is a vehicle type outer casing or a ship type outer casing; the receiving member is a transparent member.

For a better understanding and implementation, the invention will be described in detail below with reference to the drawings.

DRAWINGS

1 is a perspective view of a toy vehicle according to a first embodiment of the present invention;

Figure 2 is an exploded view of the toy vehicle of the first embodiment of the present invention;

3 is a partial exploded view of a toy vehicle according to Embodiment 1 of the present invention;

Figure 4 is a partial exploded view of the toy vehicle according to the first embodiment of the present invention;

Figure 5 is a perspective view of the lower case of the toy vehicle according to the first embodiment of the present invention;

Figure 6 is a perspective view of a toy vehicle according to a second embodiment of the present invention;

Figure 7 is an exploded view of the toy vehicle of the second embodiment of the present invention;

Figure 8 is a partial exploded view of the toy vehicle according to the second embodiment of the present invention;

Figure 9 is a partial exploded view of the toy vehicle according to the second embodiment of the present invention;

Figure 10 is a third partial exploded view of the toy vehicle according to the second embodiment of the present invention.

Reference mark:

Upper shell 11. Lower case 12. Drive the wheel 2. Drive wheel 3. The receiving member 41. Jumper 42. Second magnet 421 (Example 1) / 451 (Example 2). Tooth box 5. Input/output shaft 51. Cam 61. First transmission lever 62 (Embodiment 1) / 620 (Embodiment 2). Transverse through hole 621. The first magnet 63. The first lever shaft 64. Fixing member 65. Spring 66. The first receiving member 43. The second receiving member 44. The first jumper 45. The second jumper 46. The fourth magnet 461. The second transmission lever 67. The third magnet 671. The second lever shaft 68.

Detailed ways

Embodiment 1

Referring to FIG. 1-5, the toy vehicle that can be beaten in the running component of the present embodiment (referred to as a toy vehicle) includes a casing, a driving wheel 2, a driven wheel 3, a beating portion, a driving shaft, a tooth box 5, and a transmission portion.

The outer casing is a model outer casing including an upper casing 11 and a lower casing 12. There are two driving wheel 2 and driven wheel 3, respectively, which are respectively mounted on the lower casing 12. The bounce portion is disposed on the upper casing 11, and includes a receiving member 41 and a bounce member 42. The accommodating member 41 is a transparent hollow cylinder closed at the top end, and is fixed on the top surface of the upper casing 11, the bounce member 42. It is placed in the accommodating member 41, which may be provided as an image of a figure or other object, on which the second magnet 421 is fixed.

The tooth box 5 is fixed on the lower case 12, and the tooth box 5 can adopt an inertial tooth box which is common in the market, and the tooth box 5 includes an input/output shaft 51, the drive shaft and the input in this embodiment. The output shaft 51 is the same shaft body. The operation of the tooth box 5 is to perform an initial rotation input to the inertia tooth box 5 through the input/output shaft 51. After the input is stopped, the inertia tooth box 5 continues through the input/output shaft 51. Outputs rotational motion in the same direction. The input/output shaft 51 is fixed to the drive wheel 2.

The transmission portion is mounted in the housing and includes a cam 61, a first transmission lever 62, a first lever shaft 64, a fixing member 65, and a spring 66. The cam 61 is fixed to the input/output shaft 51, the first lever shaft 64 is fixed to the first transmission lever 62, and the first transmission lever 62 is hinged by the first lever shaft 64. On the lower case 12. The first end of the first transmission lever 62 is sleeved on the cam 61, and the second end thereof extends upward, is adjacent to the upper casing 11, and is located directly below the receiving member 41, and the end of the second end is fixed at the end A magnet 63. One end of the spring 66 is fixed on the bottom surface of the lower casing 12, and the other end is fixed under the second end of the first transmission lever 62. The spring 66 functions to move the first transmission lever 62 upward. The second end of the second arm can automatically return to the initial position after the movement to prevent the first transmission lever 62 from being in a freely loose state. The fixing member 65 is capped on the first lever shaft 64, but still allows the first lever shaft 64 to rotate for preventing the first lever shaft 64 from jumping. The first magnet 63 and the second magnet 421 are isotropic magnetic poles.

During play, the toy car is pushed forward to drive the driving wheel 2 to rotate, and the tooth box 5 receives the rotation input of the driving wheel 2 through the input/output shaft 51. After the user releases the hand, the tooth box 5 continues to pass through. The input/output shaft 51 outputs a rotational motion that drives the drive wheel 2 to continue moving forward while driving the cam 61 to rotate, the cam 61 driving the first end of the first transmission lever 62 to move up and down, the first The second end of the transmission lever 62 is moved up and down accordingly, and the first magnet 63 moves accordingly, and the second magnet 421 located above it is bouncing, thereby causing the jumping member 42 to have an upper and lower bouncing effect.

In other embodiments, the manual play mode for pushing the toy car forward can be used without the use of a tooth box. The structure of the toy car is the same as that of the above embodiment. The drive shaft is connected with the drive wheel, and when the toy car is pushed, the drive is driven. The rotation of the wheel is transmitted to the drive shaft, and then the cam of the drive shaft drives the first transmission lever and the first magnet to move, thereby causing the second magnet and the jumper to jump.

Embodiment 2

Referring to FIG. 6-10, the toy vehicle of this embodiment is substantially the same as that of the first embodiment, and the main differences are as follows:

The outer casing is a boat-shaped outer casing. There are two drive wheels 2 and one of the driven wheels 3. The jumping portion includes a first receiving member 43, a second receiving member 44, a first jumping member 45 and a second jumping member 46, and the first receiving member 43 and the second receiving member 44 are hollow cylinders whose top end is closed. The first accommodating member 43 is fixed to the top surface of the upper casing 11. The first pulsating member 45 is fixed with a second magnet 451, and the second accommodating member 44 is provided with a second pulsating member. 46. The fourth jumper 46 is fixed with a fourth magnet 461. The first jumper 45 and the second jumper 46 can be disposed as an image of a figure or other object.

The transmission portion further includes a second transmission lever 67 and a second lever shaft 68, the second transmission lever 67 being hinged in the outer casing by a second lever shaft 68; the first end of the second transmission lever 67 is The second end of the first transmission lever 620 is connected, and the second end is fixed with a third magnet 671, and the third magnet 671 is located directly below the fourth magnet 461; specifically, the second of the first transmission lever 620 The end of the second transmission lever 67 is provided with a lap plate, the lateral through hole 621 has a size larger than the size of the lap plate, and the lap plate is inserted into the a lateral through hole 621, the first end of the second transmission lever 67 can be moved up and down by the second end of the first transmission lever 620, and the first end of the second transmission lever 67 has the lateral end hole 621 There is room for movement to prevent jamming. Leverage causes the second end of the second transmission lever 67 to move up and down accordingly; the third magnet 671 and the fourth magnet 461 are isotropic magnetic poles.

During play, the toy car is pushed forward to drive the driving wheel 2 to rotate, and the tooth box 5 receives the rotation input of the driving wheel 2 through the input/output shaft 51. After the user releases the hand, the tooth box 5 continues to pass through. The input/output shaft 51 outputs a rotational motion that drives the drive wheel 2 to continue moving forward while driving the cam 61 to rotate, the cam 61 driving the first end of the first transmission lever 620 to move up and down, the first The second end of the transmission lever 620 is correspondingly moved up and down, the first magnet 63 moves accordingly, and the second magnet 451 located above it generates a jump, thereby causing the first jumper 45 to have an upper and lower jump effect, and the first transmission The second end of the lever 620 drives the first end of the second transmission lever 67 to move up and down, so that the second end of the second transmission lever 67 moves up and down accordingly, and the third magnet 671 moves accordingly, and the fourth magnet 461 above it So that the second jumper 46 has the effect of jumping up and down; in addition, since the upper and lower positions of the first magnet 63 and the third magnet 671 are exactly reversed, when the first magnet 63 is located above, the third magnet 671 is located below When the first magnet 63 is located below, the third magnet 671 is located above, and accordingly, the jumps of the second magnet 451 and the fourth magnet 461 are also turned upside down, so that the first jumper 45 and the second jumper 46 are alternately beaten. .

In other embodiments, the first jumper can be synchronized with the second jumper, and the structure of the magnet and the lever can be changed accordingly, such as a magnet that moves synchronously with the first magnet; the transmission portion can also include More than two transmission levers, the beating portion may include more than two sets of accommodating members and bounce members to generate the effect of a plurality of bounce members; the tooth box may also adopt a common return tooth box on the market, and the return tooth box includes an input/output shaft The working process is that the initial rotation input is performed on the returning force box through the input/output shaft. After the input is stopped, the inertial tooth box outputs the opposite direction of the rotary motion through the input/output shaft, and when used, the toy car is pulled backwards. After the hand is released, the returning force box drives the toy car to move forward; the transmission portion can also be driven by transmission members of other structures than the cam and the lever; the outer casing can also be a casing of other shapes, such as a spacecraft, a carriage, and the like.

The toy vehicle with the running component in the running part drives the transmission part to move by the rotation of the driving shaft, so that the magnet on the transmission part moves accordingly, and then the mutual repulsive action between the magnets is used to make the jumping piece on the toy car beat. The structure is simple, the gameplay is novel, the visual effect is rich, and the interest is strong; further, through the setting of the tooth box, the toy car is provided with more lasting power without the human hand pushing all the time; further, through the cam and the transmission lever The transmission is simple in structure and high in reliability; further, by providing two sets of cams and transmission levers, and two sets of accommodating members and jumping members, staggering or synchronous jumping of a plurality of objects can be realized.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "upper", "lower", "front", "back", "left", "right", " The orientation or positional relationship of the indications of "upright", "horizontal", "top", "bottom", "inside", "outside", etc. is based on the orientation or positional relationship shown in the drawings, only for the convenience of describing the present invention and The simplification of the description is not intended to limit or imply that the device or component that is referred to has a particular orientation, is constructed and operated in a particular orientation, and thus is not to be construed as limiting. In the description of the present invention, "a plurality" means two or more unless otherwise stated.

The above-described embodiments are merely illustrative of several embodiments of the present invention, and the description thereof is more specific and detailed, but is not to be construed as limiting the scope of the invention. It should be noted that a number of variations and modifications may be made by those skilled in the art without departing from the spirit and scope of the invention.

Claims

A toy vehicle capable of beating in a running component, comprising: a casing, a driving wheel, a beating portion, a driving shaft and a transmission portion; the driving shaft is respectively connected with the driving wheel and the transmission portion; the transmission portion is installed In the outer casing, a first magnet is fixed on the transmission portion; the bounce portion is mounted on the outer casing, and includes a receiving member and a bounce member disposed in the accommodating member, the bounce member is fixed on the baffle a second magnet; the first magnet and the second magnet are isotropic poles; the drive shaft receives a rotational input of the drive wheel to drive the transmission portion, and the first magnet on the transmission portion follows Move and drive the second magnet to produce a beat.
A toy vehicle capable of beating in a running component according to claim 1, further comprising a tooth box fixed in said outer casing, said tooth box comprising an input/output shaft, said drive shaft being said An input/output shaft; the input/output shaft is respectively connected to the driving wheel and the transmission portion; and the tooth box passes through the input/output shaft to receive the rotation input of the driving wheel, and the input/output is passed through the input/output shaft The shaft drives the drive wheel to rotate and drives the transmission portion to move, the first magnet on the transmission portion moves with it, and drives the second magnet to generate a jump.
The toy vehicle capable of beating in a running component according to claim 1, wherein the transmission portion comprises a cam, a first transmission lever and a first lever shaft, and the cam is sleeved on the drive shaft. The first transmission lever is hinged in the outer casing through the first lever shaft, the first end of which is connected to the cam, and the second end of which is fixed with a first magnet.
The toy vehicle capable of beating in a running component according to claim 3, wherein: the bounce portion is disposed at a top of the outer casing, and the cam drives the first end of the first transmission lever to move up and down, The second end of the first transmission lever to which the first magnet is fixed is correspondingly moved up and down.
The toy vehicle capable of beating in a running component according to claim 4, wherein the jumping portion comprises a first receiving member, a second receiving member, a first jumping member and a second jumping member, and the first receiving member is inside a first jumping member is disposed, a second magnet is fixed on the first jumping member, a second jumping member is disposed in the second receiving member, and a fourth magnet is fixed on the second jumping member; the first jumping member is staggered or Synchronous beating.
A toy vehicle capable of beating in a running component according to claim 5, wherein said transmission portion further comprises a second transmission lever and a second lever shaft, said second transmission lever being hinged to the second lever shaft The first end of the second transmission lever is connected to the second end of the first transmission lever, and the second end is fixed with a third magnet; the second end of the first transmission lever can drive the The first end of the second transmission lever moves up and down, so that the second end of the second transmission lever moves up and down correspondingly; the third magnet and the fourth magnet are the same magnetic poles.
The toy vehicle capable of beating in a running component according to claim 6, wherein the second end of the first transmission lever is provided with a transverse through hole, and the first end of the second transmission lever is provided with a lap joint. a plate, the lateral through hole having a size larger than a size of the lap plate, the lap plate being inserted into the lateral through hole.
A toy vehicle capable of beating in a running component according to claim 3, wherein said transmission portion further comprises a spring and a fixing member; one end of said spring is fixed on a bottom surface of said outer casing, and the other end is fixed at said The second end of the first transmission lever; the fixing member is disposed on the first lever shaft.
The toy vehicle capable of beating in a running component according to any one of claims 1 to 8, characterized in that: the tooth box is an inertial tooth box or a back force tooth box; further comprising a driven wheel mounted on the On the outer casing.
A toy vehicle that can be beaten in a running component according to any one of claims 1 to 8, wherein the outer casing is a vehicle type outer casing or a ship type outer casing; and the receiving member is a transparent member.