CN219231409U - Gyro toy sword - Google Patents

Abstract

The utility model relates to a gyroscopic toy sword, which comprises a sword body and a sword handle; the sword body is provided with a transmitting groove along the length direction of the sword body, the transmitting groove is internally provided with a transmitting mechanism, and the transmitting mechanism is provided with a clamping part which can be separated from and combined with the top; a driving mechanism capable of driving the gyroscope to rotate is arranged in the sword body; the sword handle is detachably arranged at one end of the sword body and is in transmission connection with the driving mechanism, and when the sword handle is detached from the sword body, the driving mechanism is driven to work so as to drive the top to rotate. The top toy sword disclosed by the utility model is ingenious in design, and the driving piece on the sword handle can drive the top to rotate and accelerate for a plurality of times, so that the top obtains larger rotation potential energy and then emits the rotation potential energy, and the playing method of the sword toy is combined, so that the interestingness and multiple playing properties of the toy are improved.

Description

Gyro toy sword

Technical Field

The utility model relates to the technical field of toys, in particular to a gyroscopic toy sword.

Background

Advances in technology have prompted the development of the child toy industry, and various types of child toys with different styles and functions not only bring a lot of fun to the life of children, but also are significant for early intelligence development.

The existing toy launcher mostly has the function of launching objects, and most of existing toy launchers adopt a rack direct acceleration mode to accelerate and rotate a top, specifically, the top is accelerated in a rotating mode by enabling an acceleration rack to penetrate through a driving gear of the top, and then the top after rotating energy storage is launched. However, due to the travel limitation of the acceleration rack, the acceleration obtained by the gyro is smaller, so that the rotation time of the emitted gyro is shorter, and the interestingness and entertainment of the gyro are not strong.

Disclosure of Invention

Based on the above, the utility model aims to overcome the defects of the prior art, and provides the gyroscopic toy sword which is ingenious in design, and the driving piece on the sword handle can drive the gyroscopic element to rotate and accelerate for a plurality of times, so that the gyroscopic element can obtain larger rotation potential energy and then be emitted, and the playing method of the sword toy is combined, so that the interestingness and multiple playing properties of the toy are improved.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

a top toy sword, which comprises a sword body and a sword handle; the sword body is provided with a transmitting groove along the length direction of the sword body, the transmitting groove is internally provided with a transmitting mechanism, and the transmitting mechanism is provided with a clamping part which can be separated from and combined with the top; a driving mechanism capable of driving the gyroscope to rotate is arranged in the sword body; the sword handle is detachably arranged at one end of the sword body and is in transmission connection with the driving mechanism, and when the sword handle is detached from the sword body, the driving mechanism is driven to work so as to drive the top to rotate.

As an embodiment, the sword handle comprises a driving piece for being in transmission connection with the driving mechanism, and the driving piece is telescopically arranged in the sword body; when the sword handle is pulled away from the sword body, the driving piece drives the driving mechanism to work and drives the top to rotate, and when the driving piece retracts into the sword body, the driving mechanism idles to prevent the top from reversely rotating.

As one embodiment, the driving mechanism comprises a driving gear, a sliding gear and an output gear, the driving piece is in driving connection with the driving gear, the driving gear is in meshed connection with the sliding gear, the sliding gear is slidably arranged in the sword body, and when the sword handle is pulled away from the sword body, the driving piece drives the driving gear to rotate so as to drive the driving gear to drive the sliding gear to be meshed with the output gear; when the driving piece retracts to the sword body, the driving piece drives the driving gear to reversely rotate so as to drive the driving gear to drive the sliding gear to be separated from the output gear.

As an embodiment, one or more first transmission gears may be disposed between the driving gear and the sliding gear, and one or more second transmission gears may be disposed between the sliding gear and the output gear.

As one embodiment, a first spring is arranged at one end of the driving piece far away from the sword handle, and the tail end of the first spring is arranged in the sword body; when the sword handle drives the driving piece to extend out of the sword body, the first spring is stretched by the driving piece.

As one implementation mode, the driving piece is a long strip-shaped tooth piece, and a movable groove for the long tooth piece to move is formed in the sword body; the tail end of the first spring is arranged at one end of the movable groove far away from the sisal handle.

As an implementation mode, the launching mechanism comprises an ejection piece and a touch pressing piece, the ejection piece is matched and clamped with the touch pressing piece, the ejection piece is arranged in the launching groove in an ejection mode, the touch pressing piece is arranged in the sword body in a telescopic mode, and one end, far away from the ejection piece, of the touch pressing piece extends out of the sword body.

As one embodiment, the launching mechanism further comprises an ejection spring and a second spring, and the ejection member is slidably arranged in the launching groove through the ejection spring; the touch piece is arranged in the sword body in a telescopic way through the second spring; the pressing piece is pressed to drive the pressing piece to be released from the ejection piece, and the ejection spring drives the ejection piece to rapidly slide in the emission groove.

As one implementation mode, the ejection piece is a U-shaped piece with one end open, and one end of the opening of the ejection piece faces to the opening direction of the emission groove; the inner side wall of the ejection piece is provided with an elastic clamping block, and the clamping part is formed between the elastic clamping block and the inner side wall of the ejection piece.

As an implementation mode, one end of the ejection piece, which faces the opening of the emission groove, is provided with a limiting notch, the side wall of the limiting notch is provided with a movable clamping block in a telescopic manner, and a clamping part is formed between the movable clamping block and the inner side wall of the limiting notch.

Compared with the prior art, the utility model has the beneficial effects that: according to the top toy sword, through the detachable matching design between the sword handle and the sword body, the driving piece of the sword handle is arranged in the sword body in a telescopic manner, and the driving piece can drive the driving mechanism to work when the sword handle is pulled away, so that the top in the transmitting mechanism is driven to rotate, and when the sword handle is retracted into the sword body, the driving piece drives the driving mechanism to idle, so that the driving mechanism is prevented from driving the top to rotate in opposite phase; therefore, the effect of accelerating and storing energy for the top can be achieved by pulling the sword handle for many times, so that the top in the clamping part obtains larger rotation potential energy, and finally the top after energy storage is launched out from the launching groove of the sword body through the launching mechanism. Therefore, the gyroscopic toy sword combines two playing methods of the sword toy and the gyroscopic toy, thereby increasing the fun and the multiple playing of the toy.

For a better understanding and implementation, the present utility model is described in detail below with reference to the drawings.

Drawings

FIG. 1 is a schematic diagram of the construction of a gyroscopic toy sword according to the present utility model;

FIG. 2 is a schematic view of the outer structure of the body and handle of the gyroscopic toy sword of the present utility model;

FIG. 3 is a schematic view of the internal structure of the body and handle of the gyroscopic toy sword of the present utility model;

FIG. 4 is a schematic view of another internal structure of the body and handle of the gyroscopic toy sword of the present utility model;

FIG. 5 is a schematic diagram of the launching mechanism of the gyroscopic toy sword of the present utility model;

FIG. 6 is another schematic structural view of the launching mechanism of the gyroscopic toy sword of the present utility model;

FIG. 7 is a schematic diagram of the drive mechanism of the gyroscopic toy sword of the present utility model;

fig. 8 is a schematic diagram of the connection of the driving member and the driving mechanism of the gyroscopic toy sword of the present utility model.

Detailed Description

For further illustration of the various embodiments, the utility model is provided with the accompanying drawings. The accompanying drawings, which are incorporated in and constitute a part of this disclosure, illustrate embodiments and together with the description, serve to explain the principles of the embodiments. With reference to these matters, one of ordinary skill in the art will understand other possible implementations and advantages of the present utility model.

In the description of the present utility model, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "left", "right", "top", "bottom", "inner", "outer", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus are not to be construed as limiting the present utility model.

The embodiment provides a gyroscopic toy sword, which comprises a sword body 10 and a sword handle 20; in this embodiment, the sword body 10 is provided with a transmitting slot 11 along its length direction for the top 30 to be transmitted, the transmitting slot 11 is provided with a transmitting mechanism 40, and the transmitting mechanism 40 is provided with a clamping part 41 which can be separated from and combined with the top 30; in addition, the sword body 10 of this embodiment is further provided with a driving mechanism 50 that can drive the top 30 to rotate. The handle 20 is detachably disposed at one end of the body 10, and the handle 20 is in transmission connection with the driving mechanism 50, so that the driving mechanism 50 can be driven to work when the handle 20 is detached from the body 10, and the top 30 clamped in the clamping portion 41 of the launching mechanism 40 is driven to store energy in a rotating manner.

In order to prevent the top 30 from reversing, the driving mechanism 50 of the present embodiment is a clutch driving structure, when the handle 20 is pulled away from the body 10, the handle 20 drives the driving mechanism 50 to work and simultaneously drives the top 30 in the clamping portion 41 to rotate, and when the handle 20 is retracted into the body 10, the handle 20 only drives the input end of the driving mechanism 50 to work reversely, at this time, the output end of the driving mechanism 50 is separated from the input end of the driving mechanism 50, so that the input end of the driving mechanism 50 is separated from the output end thereof to generate an idle phenomenon, and therefore, when the handle 20 is retracted into the body 10, the output end of the driving mechanism 50 cannot operate the top 30.

Therefore, the gyro toy sword of this embodiment, through the cooperation of the sword handle 20 and the driving mechanism 50, utilizes the clutch driving theory of the driving mechanism 50 to pull the sword handle 20 for multiple times, so as to achieve the effect of accelerating and storing energy for the gyro 30 multiple times, further make the gyro 30 in the clamping portion 41 obtain larger rotation potential energy, and finally, the stored gyro 30 is launched out from the launching groove 11 of the sword body 10 through the launching mechanism 40.

In the present embodiment, the emission groove 11 is provided on one side of the body 10, and an end of the emission groove 11 remote from the grip 20 penetrates the tip portion of the body 10, thereby enabling the top 30 to be emitted from the tip along the emission groove 11.

In some preferred embodiments, the handle 20 includes a drive member 21 for driving connection with the drive mechanism 50, the drive member 21 being telescopically disposed in the body 10. Thus, when the handle 20 is pulled away from the body 10, the driving member 21 fixedly connected with the handle 20 drives the driving mechanism 50 to work so as to drive the top 30 to rotate; when the driving member 21 is retracted into the sword body 10, the driving member 21 drives the input end of the driving mechanism 50 to idle, thereby preventing the spinning top 30 from rotating reversely.

In the present embodiment, the end of the driving member 21 away from the sword handle 20 is provided with a first spring 22, and the end of the first spring 22 is disposed in the sword body 10; when the gripper 20 drives the driving piece 21 to extend out of the gripper body 10, the first spring 22 is stretched by the driving piece 21. Therefore, when the gripper handle 20 drives the driving piece 21 to draw away from the gripper body 10, the driving piece 21 drives the driving mechanism 50 to work and simultaneously stretches the first spring 22; therefore, when the handle 20 is released, the driving member 21 can be quickly retracted into the sword body 10 under the action of the elastic force of the first spring 22, and the handle 20 is abutted against the end face of the sword body 10 again, so that the resetting operation of the driving member 21 is faster and the playing method is more novel.

The driving member 21 may be, but not limited to, a long toothed member in a long shape, and a movable slot for the long toothed member to stretch is provided in the sword body 10; thus, the end of the first spring 22 can be disposed at the end of the movable slot remote from the shank 20.

The driving mechanism 50 of the present embodiment includes a driving gear 51, a sliding gear 52 and an output gear 53, where the driving member 21 is engaged with the driving gear 51, the driving gear 51 is engaged with the sliding gear 52, the sliding gear 52 is slidably disposed in the sword body 10, and when the sword handle 20 is pulled away from the sword body 10, the driving member 21 can drive the driving gear 51 to rotate so as to drive the driving gear 51 to drive the sliding gear 52 to slide into engagement with the output gear 53; when the driving member 21 retracts into the sword body 10, the driving member 21 drives the driving gear 51 to rotate reversely and drives the driving gear 51 to drive the sliding gear 52 to slide to be separated from the output gear 53, at this time, the sliding gear 52 is idle, so that the sliding gear 52 is ensured not to generate power to the output gear 53.

In order to better install the above gear structure, in this embodiment, the sword body 10 is further provided with a driving box 54, the driving gear 51, the sliding gear 52 and the output gear 53 are rotatably disposed on the driving box 54, and a part of the output gear 53 extends out of the driving box 54 and is engaged with the top 30 in the clamping portion 41, and the driving member 21 may pass through the driving box 54 and be engaged with the driving gear 51. The driving box 54 is provided with a pair of opposite arc-shaped sliding grooves 55, and two ends of the rotating shaft of the sliding gear 52 are respectively slidably arranged in the pair of arc-shaped sliding grooves 55. Thus, when the driving member 21 is withdrawn from the sword body 10, the driving gear 51 pushes the sliding gear 52 to slide to the end of the arc chute 55 close to the output gear 53 and is engaged with the output gear 53, and when the driving member 21 is retracted into the sword body 10, the driving gear 51 pushes the sliding gear 52 to slide to the end of the arc chute 55 far from the output gear 53 and is separated from the output gear 53.

In addition, one or more first transmission gears 56 may be disposed between the driving gear 51 and the sliding gear 52 in the present embodiment, and one or more second transmission gears may be disposed between the sliding gear 52 and the output gear 53 in the same manner.

In order to drive the top 30 better, in the present embodiment, a driven gear is fixedly sleeved on the rotation shaft of the top 30, and a movable sleeve is rotatably sleeved on the rotation shaft of the top 30, whereby the top 30 can be disposed in the holding portion 41 of the launching mechanism 40 through its movable sleeve, and the top 30 is engaged and connected with the output gear 53 through its driven gear. In this way, when the output gear 53 drives the driven gear of the top 30 to rotate, the movable sleeve of the top 30 is fixed in the clamping portion 41, and the rotating shaft of the top 30 and the top 30 body can perform rotation energy storage.

In some preferred embodiments, the launching mechanism 40 includes an ejector 42 and a contact piece 43, the ejector 42 is engaged with the contact piece 43 in a matching manner, the ejector 42 is arranged in the launching slot 11 in a ejectable manner, the contact piece 43 is arranged in the sword body 10 in a telescopic manner, and one end of the contact piece 43 away from the ejector 42 protrudes out of the sword body 10.

Further, the launching mechanism 40 of the present embodiment further includes a launch spring 44 and a second spring 45, and the ejector 42 is slidably disposed in the launching groove 11 by the launch spring 44; the contact piece 43 is telescopically arranged in the sword body 10 through a second spring 45; in this way, pressing the contact element 43 can drive the contact element 43 and the ejection element 42 to release the card, and then drive the ejection element 42 to slide in the ejection slot 11 rapidly through the ejection spring 44.

The ejector 42 of the present embodiment may be, but is not limited to, a U-shaped member having one end opened, in which embodiment, the open end of the ejector 42 faces the opening direction of the launching groove 11; in addition, an elastic block is provided on the inner side wall of the ejector 42, and the clamping portion 41 is formed between the elastic block and the inner side wall of the ejector 42. In this way, the movable sleeve of the top 30 is movably clamped in the clamping portion 41 formed between the elastic clamping block and the inner side wall of the ejector 42, and when the ejector 42 slides forward rapidly, the top 30 can break the limit of the elastic clamping block by using huge inertia force of itself and launch along the launching groove 11.

In the ejector 42 of the present embodiment, a limiting notch is disposed at one end of the ejector 42 facing the opening of the launching slot 11, a movable clamping block 46 is telescopically disposed on a side wall of the limiting notch, and a clamping portion 41 is formed between the movable clamping block 46 and an inner side wall of the limiting notch. The movable clamping block 46 can be telescopically arranged in the side wall of the limit notch by adopting a spring structure, so that the movable clamping block 46 can be pushed and inserted into the clamping part 41 for fixation when the top 30 is inserted into the limit notch; when the ejector 42 is ejected forward, the top 30 can break the limit of the movable block 46 by using the huge inertia force and is launched along the launching groove 11.

Compared with the prior art, the utility model has the beneficial effects that: according to the gyro toy sword, through the detachable matching design between the sword handle 20 and the sword body 10, the driving piece 21 of the sword handle 20 is arranged in the sword body 10 in a telescopic manner, and when the sword handle 20 is pulled away, the driving piece 21 can drive the driving mechanism 50 to work so as to drive the gyro 30 in the launching mechanism 40 to rotate, and when the sword handle 20 is retracted into the sword body 10, the driving piece 21 drives the driving mechanism 50 to idle so as to prevent the driving mechanism 50 from driving the gyro 30 to rotate in opposite phase; therefore, the effect of accelerating and accumulating energy on the top 30 can be achieved by pulling the rapier handle 20 for multiple times, so that the top 30 in the clamping part 41 obtains larger rotation potential energy, and finally the top 30 after accumulating energy is launched out of the launching groove 11 of the rapier body 10 through the launching mechanism 40. Therefore, the gyroscopic toy sword combines two playing methods of the sword toy and the gyroscopic toy 30, thereby increasing the interestingness and the multiple playing of the toy.

The above examples illustrate only a few embodiments of the present utility model, which are described in greater detail and are not to be construed as limiting the scope of the inventive gyroscopic toy sword. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the utility model, which are all within the scope of the utility model.

Claims (10)

1. A gyroscopic toy sword, which is characterized in that:

comprises a sword body and a sword handle; the sword body is provided with a transmitting groove along the length direction of the sword body, the transmitting groove is internally provided with a transmitting mechanism, and the transmitting mechanism is provided with a clamping part which can be separated from and combined with the top; a driving mechanism capable of driving the gyroscope to rotate is arranged in the sword body; the sword handle is detachably arranged at one end of the sword body and is in transmission connection with the driving mechanism, and when the sword handle is detached from the sword body, the driving mechanism is driven to work so as to drive the top to rotate.

2. The gyroscopic toy sword according to claim 1, wherein:

the sword handle comprises a driving piece which is used for being in transmission connection with the driving mechanism, and the driving piece is telescopically arranged in the sword body; when the sword handle is pulled away from the sword body, the driving piece drives the driving mechanism to work and drives the top to rotate, and when the driving piece retracts into the sword body, the driving mechanism idles to prevent the top from reversely rotating.

3. The gyroscopic toy sword according to claim 2, wherein:

the driving mechanism comprises a driving gear, a sliding gear and an output gear, the driving piece is in driving connection with the driving gear, the driving gear is in meshed connection with the sliding gear, the sliding gear is slidably arranged in the sword body, and when the sword handle is pulled away from the sword body, the driving piece drives the driving gear to rotate so as to drive the driving gear to drive the sliding gear to be meshed with the output gear; when the driving piece retracts to the sword body, the driving piece drives the driving gear to reversely rotate so as to drive the driving gear to drive the sliding gear to be separated from the output gear.

4. A gyroscopic toy sword according to claim 3, wherein:

one or more first transmission gears can be arranged between the driving gear and the sliding gear, and one or more second transmission gears can be arranged between the sliding gear and the output gear.

5. The gyroscopic toy sword according to claim 2, wherein:

a first spring is arranged at one end of the driving piece, which is far away from the sword handle, and the tail end of the first spring is arranged in the sword body; when the sword handle drives the driving piece to extend out of the sword body, the first spring is stretched by the driving piece.

6. The gyroscopic toy sword according to claim 5, wherein:

the driving piece is a long strip-shaped tooth piece, and a movable groove for the long tooth piece to move is formed in the sword body; the tail end of the first spring is arranged at one end of the movable groove far away from the sisal handle.

7. The gyroscopic toy sword according to claim 1, wherein:

the shooting mechanism comprises a shooting piece and a touch pressing piece, the shooting piece is clamped with the touch pressing piece in a matched mode, the shooting piece is arranged in the shooting groove in a shooting mode, the touch pressing piece is arranged in the sword body in a telescopic mode, and one end, away from the shooting piece, of the touch pressing piece extends out of the sword body.

8. The gyroscopic toy sword according to claim 7, wherein:

the launching mechanism further comprises an ejection spring and a second spring, and the ejection piece is slidably arranged in the launching groove through the ejection spring; the touch piece is arranged in the sword body in a telescopic way through the second spring; the pressing piece is pressed to drive the pressing piece to be released from the ejection piece, and the ejection spring drives the ejection piece to rapidly slide in the emission groove.

9. The gyroscopic toy sword according to claim 7, wherein:

the ejection piece is a U-shaped piece with one end open, and one end of the opening of the ejection piece faces to the opening direction of the emission groove; the inner side wall of the ejection piece is provided with an elastic clamping block, and the clamping part is formed between the elastic clamping block and the inner side wall of the ejection piece.

10. The gyroscopic toy sword according to claim 7, wherein:

the ejector is provided with a limiting notch towards one end of the opening of the transmitting groove, the side wall of the limiting notch is provided with a movable clamping block in a telescopic mode, and a clamping part is formed between the movable clamping block and the inner side wall of the limiting notch.

Images