CN216169895U

CN216169895U - Gyro transmitting device

Info

Publication number: CN216169895U
Application number: CN202121852576.2U
Authority: CN
Inventors: 徐微
Original assignee: Zhejiang Rongjun Animation Technology Co ltd
Current assignee: Zhejiang Rongjun Animation Technology Co ltd
Priority date: 2021-08-09
Filing date: 2021-08-09
Publication date: 2022-04-05
Anticipated expiration: 2031-08-09

Abstract

The utility model relates to the technical field of toys, in particular to a gyroscope launching device which comprises a launching seat, an energy storage assembly, a gyroscope locking mechanism and a triggering ejection mechanism, wherein after a gyroscope enters a launching channel, the gyroscope can enter a mounting groove of a sliding seat, the gyroscope is limited and clamped by a clamping assembly in the mounting groove, after the gyroscope is mounted in the mounting groove, an output gear of the energy storage assembly can be meshed with the gyroscope, then a handle is rotated by external force, the handle drives the output gear to rotate through a driving gear, so that the gyroscope is accelerated to rotate and store energy, after the energy storage is completed, the ejection mechanism is triggered by the external force, and the ejection mechanism can relieve the limitation of the clamping assembly on the gyroscope and eject the gyroscope. The gyro launcher adopts the hand formula to carry out the energy storage, utilizes the transmission power between the gear, need not to set up clockwork spring device, and its structure is simpler, has got rid of the long banding clockwork spring in the past, and it is more convenient to carry, and the operation is more swift and convenient, has improved the security of operation, and gear drive is more wear-resisting, and life is longer.

Description

Gyro transmitting device

Technical Field

The utility model relates to the technical field of toys, in particular to a gyroscope launching device.

Background

The top is a toy rich in dynamic sense and aesthetic feeling, the top in the prior art can emit different lights or different sounds in a rotating state, and the top can also collide in a fixed field and the like, so that the top is deeply loved by children.

The existing gyroscope has no power source, cannot rotate by the gyroscope, and can rotate only by applying a rotating power to the gyroscope through the gyroscope transmitting device. When the gyroscope is used, the gyroscope is installed in the installation position of the gyroscope launching device, the gyroscope is driven by the gyroscope launching device to rotate in an accelerated mode, and after the gyroscope is driven by other mechanisms to be separated from the gyroscope launching device, the gyroscope falls on the ground or a specific field and independently rotates.

The existing top launching device accelerates the top through a built-in clockwork, most of the prior top launching devices are long auxiliary components such as a pull rope and a rack, so that the game can be played only by carrying a long clockwork at each time, or the clockwork is stored in the launching device and is stored through a torsion spring, but the clockwork is easy to wear and even break. Therefore, the existing gyro launching device has the problems of inconvenient carrying, short service life, troublesome operation and the like, thereby causing the problem of poor experience of consumers.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects, and provides a gyroscope transmitting device which is simple and safe to operate.

The purpose of the utility model is realized by the following technical scheme:

provided is a gyro emission device including: the launching seat is provided with a launching channel for mounting the gyroscope; the energy storage assembly comprises a gear set arranged in the launching seat and a handle positioned on the outer side of the launching seat, the handle can rotate relative to the launching seat, the gear set comprises a driving gear and an output gear, the handle is fixedly connected with the driving gear, the driving gear is in transmission engagement with the output gear, the output gear is rotatably arranged in the launching seat and protrudes into the launching channel, and the output gear is used for rotating the gyroscope; the gyroscope locking mechanism comprises a sliding seat capable of sliding along the emission channel, the sliding seat is provided with a mounting groove for embedding a gyroscope, and the wall of the mounting groove is provided with a clamping component for locking the gyroscope; the trigger ejection mechanism comprises a trigger button capable of reciprocating in the vertical direction, a locking hook piece capable of reciprocating in the vertical direction and aligned with the trigger button in the vertical direction, and an ejection spring for driving the sliding seat to eject towards the ejection direction, wherein the locking hook piece is provided with a hook part for hooking the sliding seat.

Wherein, holding the subassembly and including rotationally installing the elastic positioning element in the slide, elastic positioning element extends first elastic arm towards the mounting groove, and the tip of first elastic arm is formed with the butt portion that extends to in the mounting groove, and butt portion is equipped with the guide cambered surface and the locating surface that links to each other with the guide cambered surface.

The abutting part extends downwards to form a clamping part, and the side wall of the emission channel is provided with a bayonet; under the state that does not install the top, joint portion and bayonet socket support.

The clamping component also comprises an elastic limiting piece which is rotatably arranged in the sliding seat, the elastic limiting piece extends out of a second elastic arm towards the mounting groove, and a limiting part which extends into the mounting groove is formed at the end part of the second elastic arm;

under the state of installing the top, the limiting part props against the outward side surface of the top.

The elastic positioning piece and the elastic limiting piece are respectively positioned on the left side and the right side in the sliding seat, a first guide salient point protruding out of the sliding seat is formed on the side surface, back to the first elastic arm, of the elastic positioning piece, and a second guide salient point protruding out of the sliding seat is formed on the side surface, back to the second elastic arm, of the elastic limiting piece.

The bottom surface of the launching channel is provided with a guide groove for mounting the sliding seat, and the groove width of the guide groove is gradually increased along the launching direction of the gyroscope; in an assembling state, the first guide salient point and the second guide salient point respectively abut against the groove wall of the guide groove.

The gear set further comprises a plurality of auxiliary gears which are sequentially in meshing transmission, the driving gear is in meshing transmission with one of the auxiliary gears, and the output gear is in meshing transmission with one of the auxiliary gears.

Wherein, the triggering ejection mechanism also comprises a first return spring for driving the triggering button to move upwards and a second return spring for driving the locking hook piece to move upwards

The transmitting seat is further provided with a turnover cover for covering the transmitting channel, one end of the turnover cover is hinged to the transmitting seat through a torsion spring, and the torsion spring drives the turnover cover to turn towards the opening direction.

The trigger ejection mechanism further comprises an L-shaped locking rod which is arranged in the launching seat and can slide, a first inclined plane is arranged at the end part of the transverse section of the L-shaped locking rod, a second inclined plane which is complementary with the first inclined plane is formed on the bottom surface of the trigger button, the end part of the longitudinal section of the L-shaped locking rod penetrates out of the launching seat, and a stop block which is clamped with the end part of the longitudinal section of the L-shaped locking rod is formed on the inner side surface of the flip cover; when the trigger button is used for launching, the trigger button drives the L-shaped lock rod to slide inwards, and the L-shaped lock rod is clamped with the stop block.

The utility model has the beneficial effects that:

when the gyro launching device is used, a gyro is installed in the launching seat, the gyro enters the launching channel and then enters the mounting groove of the sliding seat, the clamping component in the mounting groove is used for limiting and clamping the gyro, the output gear of the energy storage component is meshed with the gyro after the gyro is installed in the mounting groove, then the handle is rotated by external force, the handle drives the output gear to rotate through the driving gear, so that the gyro is accelerated to rotate and store energy, after the energy storage is finished, the external force triggers the launching mechanism, and the launching mechanism can release the limiting of the clamping component on the gyro and enable the gyro to be ejected. Compared with the prior art, the top emitter of this application adopts hand formula to carry out the energy storage, utilizes the transmission power between the gear, need not to set up clockwork spring device, and its structure is simpler, has got rid of the long banding clockwork spring in the past, and it is more convenient to carry, and the operation is more swift and convenient, has improved the security of operation, and gear drive is more wear-resisting, and life is longer.

Drawings

The utility model is further illustrated by means of the attached drawings, but the embodiments in the drawings do not constitute any limitation to the utility model, and for a person skilled in the art, other drawings can be obtained on the basis of the following drawings without inventive effort.

Fig. 1 is a schematic structural diagram of a spinning top according to the present invention.

Fig. 2 is a schematic view of the construction of a toy figure of the present invention.

Fig. 3 is a schematic structural diagram of a gyro emission device of the present invention.

Fig. 4 is a schematic structural diagram of the gyro launching device of the present invention after the flip cover and the gyro are hidden.

Fig. 5 is an exploded view of the energy storage assembly of the present invention.

FIG. 6 is an exploded view of the locking gyro mechanism of the present invention.

Fig. 7 is a schematic structural diagram of the gyro locking mechanism of the present invention after the gyro is locked.

Fig. 8 is a cross-sectional view taken at a-a in fig. 7.

Fig. 9 is a schematic structural view of the trigger ejection mechanism of the present invention.

Fig. 10 is an exploded view of the trigger ejection mechanism of the present invention.

Fig. 11 is an exploded view of the gyroscopic transmitter of the present invention.

Fig. 12 is a schematic structural view of the gyro launching device of the present invention after a part of the launching base is hidden.

Reference numerals: the gyroscope comprises a gyroscope body 11, a gyroscope tip 12, an engagement tooth 13, a prism 14, an emission base 2, an emission platform 20, an emission channel 21, a guide groove 22, a bayonet 23, a handle 31, a driving gear 32, an output gear 33, an auxiliary gear 34, a gyroscope locking mechanism 4, a mounting groove 41, an elastic positioning piece 5, a first elastic arm 51, a butting part 52, a guide arc surface 53, a positioning surface 54, a clamping part 55, a first guide salient point 56, an emission spring 60, an elastic limiting piece 6, a second elastic arm 61, a limiting part 62, a second guide salient point 63, a trigger button 71, a locking hook piece 72, a hook part 73, a first reset spring 74, a second reset spring 75, a flip cover 91, an L-shaped locking rod 92, a torsion spring 93, a stopper 94, a toy figure 100 and a head 101.

Detailed Description

The utility model is further described with reference to the following examples.

In an embodiment of the gyro emission device of the present invention, the gyro emission device of this embodiment is required to be used in cooperation with a specific gyro. Referring to fig. 1, the gyroscope includes a gyroscope body 11 and a gyroscope tip 12 capable of rotating relative to the gyroscope body 11, the gyroscope body 11 is provided with meshing teeth 13 for accelerating rotation, a prism 14 for positioning is formed on the upper portion of the gyroscope tip 12, and the prism 14 is a polygonal structure and can be selectively arranged according to actual requirements.

Referring to fig. 2, the top launcher of the present embodiment is mounted on a transformable toy figure 100, and the top launcher is mounted on the chest of the toy figure 100, so that the interest and beauty of the top launcher can be increased. The toy figure 100 may be transformed into other forms, such as a human, animal, or motorcycle type.

The gyro launching device comprises a launching seat 2, an energy storage component, a gyro locking mechanism 4 and a triggering ejection mechanism.

In this embodiment, referring to fig. 3, the transverse section of the launching base 2 is L-shaped, the launching base 2 is provided with a launching platform 20, and a launching channel 21 for installing and launching the gyroscope is opened in the middle of the launching platform 20. In the condition of the top mounted, the top body 11 is located above the launch platform 20, while the meshing teeth 13, the top tip 12 and the prism 14 are all located inside the launch channel 21.

Referring to fig. 4 and 5, the energy storage assembly includes a gear set installed in the launching base 2 and a handle 31 located outside the launching base 2, the handle 31 is rotatable relative to the launching base 2, and specifically, the handle 31 may be rotatably connected to the launching base 2 through a bearing, a rotating shaft, and other auxiliary components. The gear set comprises a driving gear 32, an output gear 33 and a plurality of auxiliary gears 34 which are sequentially in meshing transmission, the handle 31 is fixedly connected with the driving gear 32, the driving gear 32 is in meshing transmission with one of the auxiliary gears 34, and the output gear 33 is in meshing transmission with one of the auxiliary gears 34. Output gear 33 rotationally installs in launching seat 2 and protrusion in launching passageway 21, and output gear 33 is used for meshing with the interlock tooth 13 of top body 11, and through hand rotation handle 31, handle 31 rotates and indirectly makes top body 11 rotate for top 12 to the realization is accelerated the rotation to the top.

In this embodiment, fig. 6 to 8, the gyro locking mechanism 4 includes a sliding base capable of sliding along the launching channel 21, the sliding base is provided with an installation groove 41 for embedding the gyro, and a wall of the installation groove 41 is provided with a clamping component for locking the gyro. Specifically, the clamping assembly comprises an elastic positioning piece 5 which is rotatably installed in the sliding seat and an elastic limiting piece 6 which is rotatably installed in the sliding seat, and both the elastic positioning piece 5 and the elastic limiting piece 6 can rotate relative to the sliding seat through a rotating shaft. The elastic positioning piece 5 extends out of the first elastic arm 51 towards the installation groove 41, an abutting part 52 extending into the installation groove 41 is formed at the end part of the first elastic arm 51, and the abutting part 52 is provided with a guide arc surface 53 and a positioning surface 54 connected with the guide arc surface 53. The elastic limiting member 6 extends out of the second elastic arm 61 toward the mounting groove 41, and a limiting portion 62 extending into the mounting groove 41 is formed at an end of the second elastic arm 61. The elastic positioning piece 5 and the elastic limiting piece 6 are respectively positioned at the left side and the right side in the sliding seat, a first guide salient point 56 protruding out of the sliding seat is formed on the side surface of the elastic positioning piece 5 back to the first elastic arm 51, and a second guide salient point 63 protruding out of the sliding seat is formed on the side surface of the elastic limiting piece 6 back to the second elastic arm 61. The bottom surface of the launching channel 21 is provided with a guide groove 22 for mounting the slide carriage, and the groove width of the guide groove 22 is gradually increased along the launching direction of the gyroscope.

In the assembled state, the first guide projection 56 and the second guide projection 63 respectively abut against groove walls of the guide groove 22. Referring to fig. 8, the width of the guide slot 22 gradually increases along the launching direction, and since the elastic positioning element 5 and the elastic limiting element 6 both have elasticity, the first guide protrusion 56 and the second guide protrusion 63 are driven to pop out toward the slot wall of the guide slot 22 and abut against the slot wall of the guide slot 22, and since the gap between the slot wall and the slot wall changes, when the elastic positioning element 5 and the elastic limiting element 6 move to the exit of the guide slot 22, the elastic positioning element 5 and the elastic limiting element 6 both rotate inward and the first elastic arm 51 and the second elastic arm 61 are both accommodated in the slider. Referring to fig. 7, after the spinning top is placed in the mounting groove 41, the spinning top is continuously pushed into the mounting groove 41, the prism 14 will contact with the guiding arc 53 of the elastic positioning member 5, and pushes the sliding seat, the elastic positioning piece 5 and the elastic limiting piece 6 to slide towards the interior of the launching seat 2 together, during the sliding of the slide, due to the narrowing of the groove width of the guide groove 22, the groove wall of the guide groove 22 exerts a pushing force on the first guide protrusion 56 and the second guide protrusion 63, therefore, the elastic positioning element 5 and the elastic limiting element 6 rotate outwards, the abutting part 52 of the elastic positioning element 5 and the limiting part 62 of the elastic limiting element 6 both protrude in the installation groove 41, the guide arc surface 53 pops outwards and drives the prism 14 to rotate until the outer side surface of the prism 14 is attached to the positioning surface 54 of the elastic positioning element 5, the whole spinning top is pushed into the tail end of the installation groove 41, and the installation groove 41 and the elastic limiting element 6 limit the degree of freedom of rotation of the prism 14. When the prism 14 moves into the mounting groove 41, the elastic limiting member 6 rotates, so that the limiting portion 62 protrudes toward the inside of the mounting groove 41, and the limiting portion 62 protrudes and abuts against the outer side surface of the prism 14, so that the degree of freedom of outward movement of the prism 14 is limited, and the clamping assembly realizes clamping of the gyroscope.

In this embodiment, in order to further improve the safety of the launching device and prevent other objects except the top from being placed in the top launching device to be launched, the abutting portion 52 extends downwards to form the clamping portion 55, and the side wall of the launching channel 21 is provided with the bayonet 23. Under the state of not installing the top, joint portion 55 supports with bayonet 23 and pushes up, and the slide can't realize popping out under no matter what kind of state, if and only after the top is installed in mounting groove 41, prismatic 14 applys a thrust to joint portion 55 to make joint portion 55 and bayonet 23 dislocation, under this condition, the slide just can be popped out to reinforcing top emitter's security.

Referring to fig. 9 to 10, the trigger ejection mechanism includes a trigger button 71 which is vertically reciprocable, a latch member 72 which is vertically reciprocable and is vertically aligned with the trigger button 71, and a striking spring 60 which drives the carriage to eject in the striking direction, the latch member 72 being provided with a hook portion 73 which hooks the carriage. The trigger ejection mechanism further includes a first return spring 74 urging upward movement of the trigger button 71 and a second return spring 75 urging upward movement of the latch hook member 72.

In this embodiment, the trigger button 71 of the trigger ejection mechanism is elastically connected to the head 101 of the toy man 100, when in use, an external force presses the head 101 of the toy man 100 downward, so as to drive the trigger button 71 to move downward, the downward movement of the trigger button 71 abuts against the latch hook 72, the latch hook 72 moves downward, after the downward movement of the latch hook 72, the hook 73 of the latch hook 72 releases the locking of the slider, the compressed launching spring 60 drives the slider to eject outward, the elastic force provided by the launching spring 60 is greater than the retaining force of the retaining component on the spinning top, so that by using inertia, when the slider ejects and abuts against the launching base 2, the spinning top is separated from the retaining of the retaining component by its own inertia, and thus the spinning top is ejected.

In this embodiment, referring to fig. 11 and 12, the launching base 2 is further provided with a flip 91 covering the launching channel 21, one end of the flip 91 is hinged to the launching base 2 through a torsion spring 93, and the torsion spring 93 drives the flip 91 to flip in the opening direction. The trigger ejection mechanism further comprises an L-shaped lock rod 92 which is installed in the launching seat 2 and can slide, a first inclined surface is arranged at the end part of the transverse section of the L-shaped lock rod 92, a second inclined surface which is complementary to the first inclined surface is formed on the bottom surface of the trigger button 71, the end part of the longitudinal section of the L-shaped lock rod 92 penetrates out of the launching seat 2, and a stop block 94 which is clamped with the end part of the longitudinal section of the L-shaped lock rod 92 is formed on the inner side surface of the flip cover 91. When the fire door is fired, the trigger button 71 drives the L-shaped lock lever 92 to slide, the L-shaped lock lever 92 is released from the block 94, and the torsion spring 93 drives the flip cover 91 to turn over by its own elasticity, thereby opening the flip cover 91.

When the gyro launching device of the embodiment is used, a gyro is installed in the launching seat 2, after the gyro enters the launching channel 21, the gyro can enter the installation groove 41 of the sliding seat, the clamping component in the installation groove 41 limits and clamps the gyro, after the gyro is installed in the installation groove 41, the output gear 33 of the energy storage component can be meshed with the gyro, then the handle 31 is rotated by external force, the handle 31 drives the output gear 33 to rotate through the driving gear 32, so that the gyro rotates in an accelerated manner and stores energy, after the energy storage is completed, the ejection mechanism is triggered by the external force, and the ejection mechanism can relieve the limitation of the clamping component on the gyro and eject the gyro. Compared with the prior art, the top emitter of this embodiment adopts hand formula to carry out the energy storage, utilizes the transmission power between the gear, need not to set up clockwork spring device, and its structure is simpler, has got rid of the long banding clockwork spring in the past, and it is more convenient to carry, and the operation is more swift and convenient, has improved the security of operation, and gear drive is more wear-resisting, and life is longer.

Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present invention, and not for limiting the protection scope of the present invention, although the present invention is described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions can be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention.

Claims

1. A gyroscopic transmitter device, comprising:

the launching seat is provided with a launching channel for mounting the gyroscope;

the energy storage assembly comprises a gear set arranged in the launching seat and a handle positioned on the outer side of the launching seat, the handle can rotate relative to the launching seat, the gear set comprises a driving gear and an output gear, the handle is fixedly connected with the driving gear, the driving gear is in transmission engagement with the output gear, the output gear is rotatably arranged in the launching seat and protrudes into the launching channel, and the output gear is used for rotating the gyroscope;

the gyroscope locking mechanism comprises a sliding seat capable of sliding along the emission channel, the sliding seat is provided with a mounting groove for embedding a gyroscope, and the wall of the mounting groove is provided with a clamping component for locking the gyroscope;

the trigger ejection mechanism comprises a trigger button capable of reciprocating in the vertical direction, a locking hook piece capable of reciprocating in the vertical direction and aligned with the trigger button in the vertical direction, and an ejection spring for driving the sliding seat to eject towards the ejection direction, wherein the locking hook piece is provided with a hook part for hooking the sliding seat.

2. The gyroscopic transmitter of claim 1, further comprising: the clamping component comprises an elastic positioning piece which is rotatably installed in the sliding seat, the elastic positioning piece extends out of a first elastic arm towards the mounting groove, the end part of the first elastic arm is provided with a butting part which extends into the mounting groove, and the butting part is provided with a guide arc surface and a positioning surface which is connected with the guide arc surface.

3. The gyroscopic transmitter of claim 2, further comprising: the abutting part extends downwards to form a clamping part, and a bayonet is arranged on the side wall of the transmitting channel;

and under the state that the spinning top is not installed, the clamping part is abutted against the bayonet.

4. The gyroscopic transmitter of claim 2, further comprising: the clamping component also comprises an elastic limiting piece which is rotatably arranged in the sliding seat, the elastic limiting piece extends out of a second elastic arm towards the mounting groove, and a limiting part which extends into the mounting groove is formed at the end part of the second elastic arm;

and in the state of installing the top, the limiting part props against the outward side surface of the top.

5. The gyroscopic transmitter unit of claim 4, further comprising: elastic positioning element and elasticity locating part are located respectively the left and right sides in the slide, elastic positioning element dorsad the side of first elastic arm is formed with the protrusion the first guide bump in the slide outside, the elasticity locating part dorsad the side of second elastic arm is formed with the protrusion the second guide bump in the slide outside.

6. The gyroscopic transmitter unit of claim 5, further comprising: the bottom surface of the launching channel is provided with a guide groove for mounting the sliding seat, and the groove width of the guide groove is gradually increased along the launching direction of the gyroscope; in an assembling state, the first guide salient point and the second guide salient point respectively abut against the groove wall of the guide groove.

7. The gyroscopic transmitter of claim 1, further comprising: the gear set further comprises a plurality of auxiliary gears which are sequentially in meshing transmission, the driving gear is in meshing transmission with one of the auxiliary gears, and the output gear is in meshing transmission with one of the auxiliary gears.

8. The gyroscopic transmitter of claim 1, further comprising: the triggering ejection mechanism further comprises a first return spring for driving the triggering button to move upwards and a second return spring for driving the locking hook piece to move upwards

9. The gyroscopic transmitter of claim 1, further comprising: the transmission seat is further provided with a turnover cover for covering the transmission channel, one end of the turnover cover is hinged to the transmission seat through a torsional spring, and the torsional spring drives the turnover cover to turn towards the opening direction.

10. The gyroscopic transmitter of claim 9, further comprising: the trigger ejection mechanism further comprises an L-shaped locking rod which is installed in the launching seat and can slide, a first inclined plane is arranged at the end part of the transverse section of the L-shaped locking rod, a second inclined plane which is complementary with the first inclined plane is formed on the bottom surface of the trigger button, the end part of the longitudinal section of the L-shaped locking rod penetrates out of the launching seat, and a stop block which is clamped with the end part of the longitudinal section of the L-shaped locking rod is formed on the inner side surface of the flip cover;

when the trigger button is used for transmitting, the trigger button drives the L-shaped lock rod to slide inwards, and the L-shaped lock rod is connected with the stop block in a clamped mode.