CN220588928U - Ejection sword - Google Patents

Abstract

The utility model discloses an ejection sword, which comprises a sword body, a rotating piece, a sword lattice, an ejection mechanism and a sword handle. The sword check connect in the sword body, set up trigger mechanism on the sword check, ejection mechanism set up in sword body and/or sword check. The sword handle is movably connected with the sword lattice, the sword handle is in transmission fit with the rotating piece so as to drive the rotating piece to rotate for energy storage, and the trigger mechanism can trigger the ejection mechanism to push the energy storage rotating piece out of the sword body. The ejection sword of the patent application stores energy for the rotating piece through the relative sword lattice of the sword handle, and the rotating piece is driven without arranging a sword sheath on the sword body, so that the modeling of the sword is more lifelike. The length of the sword handle is short, so that the length extension of the sword body when storing force is reduced, the weight of the whole sword body is greatly reduced, and the young children can easily hold and apply force, so that the audience range is enlarged. And the material consumption is reduced without arranging a scabbard, and the cost is reduced.

Description

Ejection sword

Technical Field

The utility model relates to the technical field of children toys, in particular to an ejection sword.

Background

The ejection sword in the prior art comprises a sword body, a sword lattice and a sword handle, wherein a sword sheath is slidably arranged on the sword body. The scabbard is matched with the top through the transmission mechanism in a transmission way, and the top can be driven to rotate by repeatedly pushing the scabbard. The sword body is provided with the sword sheath, so that the sword body is thick, poor in appearance and heavy in weight, and the shape of the sword is poor. Moreover, the length of the scabbard is longer, the whole weight of the sword is large, the smaller children are inconvenient to hold and apply force, and the use experience is poor.

In view of this, the present utility model has been made.

Disclosure of Invention

The utility model provides an ejection sword.

The application provides the following technical scheme:

an ejector sword, comprising:

a sword body and a rotating piece;

the sword lattice is connected to the sword body, and a trigger mechanism is arranged on the sword lattice;

the ejection mechanism is arranged on the sword body and/or the sword lattice;

the sword handle is movably connected to the sword lattice, the sword handle is in transmission fit with the rotating piece so as to drive the rotating piece to store energy in a rotating mode, and the trigger mechanism can trigger the ejection mechanism to push the energy-stored rotating piece out of the sword body.

Optionally, the sword comprises a driving gear, wherein the driving gear is arranged on the sword lattice;

the rotating piece is provided with a matched gear, and the matched gear can be meshed with the driving gear;

the gripper handle is in transmission connection with the driving gear, and the gripper handle translational motion can drive the driving gear to rotate.

Optionally, the tool comprises a rack, wherein one end of the rack is connected with the sword handle, and the rack is meshed with the driving gear;

the sword handle translates and drives the driving gear to rotate through the rack.

Optionally, a base is arranged on the sword grid, and the base is provided with a strip-shaped groove;

the driving gear is slidably connected to the strip-shaped groove;

when the sword handle translates to the first direction, the driving gear moves to the first end of the strip-shaped groove, and the driving gear is meshed with the matching gear;

when the sword handle translates to the second direction, the driving gear moves to the second end of the strip-shaped groove, and the driving gear is separated from the matching gear.

Optionally, the drive gear includes a first gear portion and a second gear portion;

the first gear part is arranged on one side of the second gear part along the thickness direction;

the first gear portion is larger in diameter than the second gear portion;

the second gear part is meshed with the rack, and the first gear part is used for being meshed with the matched gear.

Optionally, the sword lattice has an extension part, and the extension part extends to one side away from the sword body;

the sisal handle is slidably connected to the extension.

Optionally, the extension has a guide slot, and the sisal handle has a guide post;

the guide post runs through the guide slot.

Optionally, the ejection mechanism includes a slider and an elastic member;

the slider has a mounting portion for mounting the rotating member;

the ejection sword is in an upper boring state, in the upper boring state, the sliding piece moves to one side of the sword handle, and the elastic piece is in a compression state;

the trigger mechanism can release the sliding piece, so that the elastic piece is restored to deform, and pushes the sliding piece to move towards the side away from the sword handle, so that the rotating piece is separated from the sliding piece.

Optionally, the trigger mechanism comprises a trigger and a slider;

the trigger is in transmission connection with the sliding block;

in the upper boring state, the sliding piece is clamped to the sliding block;

the trigger can drive the slider to move away from the slider.

Optionally, the sliding direction of the slider is perpendicular to the sliding direction of the slider;

a spring is arranged between the sliding block and the sword grid;

the trigger is hinged to the sword lattice;

pressing the trigger can drive the sliding block to move towards one side of the spring so as to compress the spring.

By adopting the technical scheme, the utility model has the following beneficial effects:

the ejection sword of the patent application stores energy for the rotating piece through the relative sword lattice of the sword handle, and the rotating piece is driven without arranging a sword sheath on the sword body, so that the modeling of the sword is more lifelike. The length of the sword handle is short, so that the length extension of the sword body when storing force is reduced, the weight of the whole sword body is greatly reduced, and the young children can easily hold and apply force, so that the audience range is enlarged. And the material consumption is reduced without arranging a scabbard, and the cost is reduced.

Specific embodiments of the present utility model will be described in further detail with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this application, illustrate embodiments of the utility model and together with the description serve to explain the utility model, without limitation to the utility model. It is evident that the drawings in the following description are only examples, from which other drawings can be obtained by a person skilled in the art without the inventive effort. In the drawings:

FIG. 1 is a schematic perspective view of a first modeling ejection sword according to an embodiment of the present application;

FIG. 2 is a schematic view of the internal structure of a first view angle of a first modeling ejection sword according to an embodiment of the present application;

FIG. 3 is a partial enlarged view of the internal structure of the first molded saber according to the embodiment of the present application, with the saber body removed;

FIG. 4 is a schematic view of the internal structure of a first view of a first modeling ejection sword according to an embodiment of the present application;

FIG. 5 is an enlarged view of a portion of FIG. 4;

FIG. 6 is a schematic perspective view of a second modeling ejection sword according to an embodiment of the present application;

FIG. 7 is a schematic perspective view of a third embodiment of an ejector sword according to the present utility model;

FIG. 8 is a schematic view of the top of FIG. 7 in a disengaged state;

fig. 9 is a schematic perspective view of a fourth modeling ejection sword according to an embodiment of the present application.

In the figure, a sword body 1, a sword grid 3, a trigger mechanism 31, a trigger 311, a slider 312, a base 32, a bar-shaped groove 33, an extension 34, a guide groove 35, an ejection mechanism 4, a slider 41, a mounting portion 411, an elastic member 42, a sword handle 5, a guide post 51, a driving gear 6, a first gear portion 61, a second gear portion 62, and a rack 7; a top 8;

it should be noted that these drawings and the written description are not intended to limit the scope of the inventive concept in any way, but to illustrate the inventive concept to those skilled in the art by referring to the specific embodiments.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions in the embodiments will be clearly and completely described with reference to the accompanying drawings in the embodiments of the present utility model, and the following embodiments are used to illustrate the present utility model, but are not intended to limit the scope of the present utility model.

In the description of the present utility model, it should be noted that the directions or positional relationships indicated by the terms "upper", "lower", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the apparatus or component referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted", "connected" and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

Referring to fig. 1 to 9, an embodiment of the present application provides an ejection sword, which includes a sword body 1, a rotating member, a sword grid 3, an ejection mechanism 4 and a sword handle 5. The sword grid 3 is connected to the sword body 1, a trigger mechanism 31 is arranged on the sword grid 3, and the ejection mechanism 4 is arranged on the sword body 1 and/or the sword grid 3. The sword handle 5 is movably connected to the sword grid 3, the sword handle 5 is in transmission fit with the rotating piece to drive the rotating piece to rotate for energy storage, and the triggering mechanism 31 can trigger the ejection mechanism 4 to push the energy storage rotating piece out of the sword body 1. When in use, the rapier handle 5 is pulled to store energy for the rotating member, the triggering mechanism 31 is pressed to a certain extent by the energy storage, the rotating member is pushed out by the rapier body 1 by the ejection mechanism 4, and the rotating member can continuously rotate for a period of time after leaving the rapier body 1. Wherein the rotating member (not shown in the figures) may be a spinning top of various forms.

According to the ejection sword, energy is stored for the rotating piece through the sword handle 5 relative to the sword lattice 3, and the rotating piece is driven without arranging a sword sheath on the sword body 1, so that the modeling of the sword is more vivid. The length of the sword handle 5 is short, so that the length extension in the moment of storing force is reduced, the weight of the whole sword body is greatly reduced, and the young children can easily hold and apply force, so that the audience range is enlarged. And the material consumption is reduced without arranging a scabbard, and the cost is reduced.

In one possible embodiment, the ejector sword further comprises a drive gear 6, said drive gear 6 being arranged to said sword grid 3. The rotating member has a mating gear which can mesh with the drive gear 6. The gripper handle 5 is in transmission connection with the driving gear 6, and translational movement of the gripper handle 5 can drive the driving gear 6 to rotate. The pulling sword handle 5 can drive the driving gear 6 to drive the matched gear to rotate, so that the rotating piece can store energy in a rotating way. The sword handle 5 adopts a translation mode to drive the driving gear 6, so that the operation is more handy and easy to learn, the young children can learn easily, and the audience range is enlarged.

In a possible embodiment, the ejection sword further comprises a rack 7, one end of the rack 7 is connected to the sword handle 5, the rack 7 is meshed with the driving gear 6, and the sword handle 5 translates to drive the driving gear 6 to rotate through the rack 7. The translational motion can be converted into a rotary motion through the cooperation of the rack 7 and the driving gear 6, so that the rotary piece is driven to rotate for energy storage. The structure of the rack 7 and the gear is stable in transmission, and the energy storage effect of the rotating piece after the rapier handle 5 is translated is guaranteed.

In one possible embodiment, a base 32 is provided on the sword grid 3, the base 32 has a slot 33, and the driving gear 6 is slidably connected to the slot 33. Upon translation of the sword handle 5 in a first direction, the drive gear 6 moves to the first end of the bar-shaped groove 33, the drive gear 6 and the mating gear mesh. Upon translation of the sword handle 5 in the second direction, the drive gear 6 moves to the second end of the bar-shaped groove 33, and the drive gear 6 and the mating gear are separated. The rotatable member may be driven to rotate as the handle 5 translates in the first direction, but to ensure energy storage before firing of the rotatable member, it may be desirable to move the handle 5 multiple times in the first direction, thus requiring multiple translations of the handle 5 in the first and second directions at intervals. In order to ensure the energy storage effect of the rotating member, the rotating member can not be applied with a counter-rotating acting force to release force when the sisal handle 5 translates in the second direction, so that the strip-shaped groove 33 is arranged, and the rack 7 can drive the rotating member to move towards the driving gear 6 when the sisal handle 5 translates in the first direction, so that the driving gear 6 is meshed with the matched gear, and the rotating member stores energy; when the sword handle 5 translates to the second direction, the rack 7 can drive the rotating piece to move away from the driving gear 6, so that the driving gear 6 is separated from the matched gear, and the energy of the rotating piece is kept.

In one possible embodiment, the drive gear 6 comprises a first gear portion 61 and a second gear portion 62. The first gear portion 61 is provided on one side of the second gear portion 62 in the thickness direction, and the first gear portion 61 has a larger diameter than the second gear portion 62. The second gear portion 62 is engaged with the rack gear 7, and the first gear portion 61 is engaged with the mating gear. The first gear portion 61 and the second gear portion 62 are coaxially connected, the rack 7 translates to drive the first gear and the second gear to rotate together at the same angular velocity, but because the diameter of the first gear portion 61 is larger than that of the second gear portion 62, the linear velocity of the second gear portion 62 is larger than that of the first gear portion 61, so that the sword handle 5 drives the rack 7 to translate for a shorter distance to generate a larger rotation angle, the movement distance of the sword handle 5 can be reduced in the energy storage process of the rotating piece, and the sword handle is more convenient for infants with shorter arms to play.

In one possible embodiment, the sword grid 3 has an extension 34, the extension 34 extending to the side facing away from the sword body 1, and the sword handle 5 is slidably connected to the extension 34. Because the handle 5 needs to slide for a long time, it is vulnerable. The arrangement of the extension 34 increases the strength of the sword handle 5, ensuring the durability of the toy.

In one possible embodiment, the extension 34 has a guide slot 35 and the shank 5 has a guide post 51, the guide post 51 being disposed through the guide slot 35. The guide post 51 and the guide groove 35 are matched to limit the translation of the sisal handle 5 along the guide groove 35, so that the translation stability of the sisal handle 5 is ensured, the meshing stability of the rack 7 and the driving gear 6 is ensured, and the energy storage effect of the rotating member is ensured.

In one possible embodiment, the ejection mechanism 4 comprises a slider 41 and an elastic member 42. The slider 41 has a mounting portion 411 for mounting a rotating member. The ejector sword has an upper boring state in which the slider 41 moves toward the side of the sword handle 5 and the elastic member 42 is in a compressed state. The trigger mechanism 31 can release the sliding piece 41, so that the elastic piece 42 recovers deformation, and pushes the sliding piece 41 to move towards the side away from the sword handle 5, so that the rotating piece is separated from the sliding piece 41. The rotating member is stabilized at the ejection mechanism 4 in the loaded state, and is ensured to be meshed with the driving gear 6 when the sisal handle 5 translates towards the rotating member. When the rotating member is stored to a certain extent, the trigger mechanism 31 is pressed, and the sliding member 41 pushes against the rotating member to be emitted.

The trigger mechanism 31 may be a key trigger mechanism, and the trigger mechanism 31 may also be a trigger mechanism, taking the trigger mechanism as an example: the triggering mechanism 31 comprises a trigger 311 and a slide 312, wherein the trigger 311 and the slide 312 are in transmission connection. In the upper boring state, the sliding piece 41 is clamped with the sliding block 312, so that the stable loading state is ensured, the rotating piece is maintained at the position capable of storing energy, the stable energy storage process is ensured, and the energy storage effect is good. The trigger 311 can drive the slider 312 to move away from the slider 41, and the slider 312 pushes the rotating member to separate from the sword body 1 under the action of the elastic member 42 after separating from the slider 41.

In one possible embodiment, the sliding direction of the slider 312 is perpendicular to the sliding direction of the slider 41, and a spring is provided between the slider 312 and the sword grid 3. The trigger 311 is hinged to the sword 3, and pressing the trigger 311 can drive the slider 312 to move to the side of the spring to compress the spring. The spring can store energy after being compressed, and when released, the slider 312 is pushed by the elastic force to push the rotating piece to separate from the sword body 1.

The foregoing description is only illustrative of the preferred embodiment of the present utility model, and is not to be construed as limiting the utility model, but is to be construed as limiting the utility model to any simple modification, equivalent variation and variation of the above embodiments according to the technical matter of the present utility model without departing from the scope of the utility model.

Claims (10)

1. An ejector sword, comprising:

a sword body and a rotating piece;

the sword lattice is connected to the sword body, and a trigger mechanism is arranged on the sword lattice;

the ejection mechanism is arranged on the sword body and/or the sword lattice;

the sword handle is movably connected to the sword lattice, the sword handle is in transmission fit with the rotating piece so as to drive the rotating piece to store energy in a rotating mode, and the trigger mechanism can trigger the ejection mechanism to push the energy-stored rotating piece out of the sword body.

2. The ejector sword according to claim 1, comprising a drive gear disposed on the sword lattice;

the rotating piece is provided with a matched gear, and the matched gear can be meshed with the driving gear;

the gripper handle is in transmission connection with the driving gear, and the gripper handle translational motion can drive the driving gear to rotate.

3. The saber of claim 2 including a rack, said rack being connected to said saber at one end, said rack being meshed with said drive gear;

the sword handle translates and drives the driving gear to rotate through the rack.

4. The ejection sword according to claim 3, wherein a base is provided on the sword lattice, the base having a bar-shaped groove;

the driving gear is slidably connected to the strip-shaped groove;

when the sword handle translates to the first direction, the driving gear moves to the first end of the strip-shaped groove, and the driving gear is meshed with the matching gear;

when the sword handle translates to the second direction, the driving gear moves to the second end of the strip-shaped groove, and the driving gear is separated from the matching gear.

5. The saber of claim 4 wherein the drive gear includes a first gear portion and a second gear portion;

the first gear part is arranged on one side of the second gear part along the thickness direction;

the first gear portion is larger in diameter than the second gear portion;

the second gear part is meshed with the rack, and the first gear part is used for being meshed with the matched gear.

6. The ejector sword according to claim 1, wherein the sword lattice has an extension that extends to a side facing away from the sword body;

the sisal handle is slidably connected to the extension.

7. The ejector sword according to claim 6, wherein the extension has a guide slot and the handle has a guide post;

the guide post runs through the guide slot.

8. The ejector sword of claim 1, wherein the ejector mechanism comprises a slider and a resilient member;

the slider has a mounting portion for mounting the rotating member;

the ejection sword is in an upper boring state, in the upper boring state, the sliding piece moves to one side of the sword handle, and the elastic piece is in a compression state;

the trigger mechanism can release the sliding piece, so that the elastic piece is restored to deform, and pushes the sliding piece to move towards the side away from the sword handle, so that the rotating piece is separated from the sliding piece.

9. The saber of claim 8 wherein the trigger mechanism includes a trigger and a slider;

the trigger is in transmission connection with the sliding block;

in the upper boring state, the sliding piece is clamped to the sliding block;

the trigger can drive the slider to move away from the slider.

10. The ejector sword of claim 9, wherein the sliding direction of the slider is perpendicular to the sliding direction of the slider;

a spring is arranged between the sliding block and the sword grid;

the trigger is hinged to the sword lattice;

pressing the trigger can drive the sliding block to move towards one side of the spring so as to compress the spring.