CN107930153B - Energy-saving bubble gun - Google Patents

Abstract

The invention relates to an energy-saving bubble gun, comprising: the gun body comprises a gun body and a gun handle connected to the gun body; the liquid storage box is clamped in the gun body and used for storing bubble liquid; the rotating assembly is rotatably supported on the gun body and comprises a rotating shaft, a viscous liquid wheel and a wind wheel, wherein the viscous liquid wheel and the wind wheel are sequentially arranged on the rotating shaft along the axial direction of the rotating shaft, and the viscous liquid wheel is used for sticking bubble liquid and preforming the bubble liquid. This energy-conserving papaw rifle, can utilize open air natural wind to drive whole rotation assembly as power and rotate, make the mucus wheel that rotates in the assembly rotate the mucus, the fan rotates and provides power for the blowing of papaw expands, an axle is multi-purpose has been realized, concentrate on a whole driving system, and need not the operation of extra energy supply alright realization energy-conserving papaw rifle, the trouble that conventional electronic papaw rifle battery need often change and cause has been avoided, convenient to use and environmental protection. On the other hand, the energy-saving bubble gun has double functions of a windmill and bubble generation.

Description

Energy-saving bubble gun

Technical Field

The invention relates to the technical field of entertainment toys, in particular to an energy-saving bubble gun.

Background

An electric bubble gun is an entertainment toy for generating bubbles by using bubble liquid.

Conventional bubble guns exist, particularly self-powered electric bubble guns that use a battery as a power source to provide energy for the operation of the electric bubble gun. However, the use of batteries increases the weight of the electric bubble gun, and the use of batteries provides poor energy endurance, requiring frequent battery replacement, and a battery set can be played by the user only several times, or several hours, which is very inconvenient. And in the using process of the electric bubble gun, along with the gradual reduction of the consumed energy of the electric quantity of the battery, the generating effect of the electric bubble gun becomes worse and worse. The above conditions greatly affect the user experience.

Therefore, there is a need to design an energy-saving bubble gun capable of supplying energy continuously, which solves the problems in the prior art.

Disclosure of Invention

In view of the above, the present invention is directed to provide an energy saving bubble gun which can realize its own operation without additional energy supply, and avoid the trouble caused by frequent replacement of the battery of the conventional electric bubble gun, and is convenient and environment-friendly to use, so as to solve the problems in the prior art.

According to the present invention, there is provided an energy saving bubble gun, comprising:

the gun body comprises a gun body and a gun handle connected to the gun body;

the liquid storage box is clamped in the gun body and used for storing bubble liquid;

the rotating assembly is rotatably supported on the gun body and comprises a rotating shaft, a viscous liquid wheel and a wind wheel, the viscous liquid wheel and the wind wheel are sequentially arranged on the rotating shaft along the axial direction of the rotating shaft, and the viscous liquid wheel is used for sticking bubble liquid and performing preforming on the bubble liquid;

wherein, the pivot is passed gun body and rotatable support in on the gun body, the viscose wheel is located in the gun body, the lower part of viscose wheel soak in the stock solution box, the upper portion of viscose wheel exposes the roof of gun body, the wind wheel is located the outside of gun body, the wind wheel relies on wind-force to rotate the drive the viscose wheel rotates, the viscose wheel rotates the in-process and glues and get bubble liquid in the stock solution box and drive upper portion behind the preforming of bubble liquid, and the bubble liquid of preforming is blown and is drawn the inflation and generate the bubble.

Preferably, the rotating assembly further comprises a fan for providing wind power for bubble generation, and the fan is arranged on the rotating shaft and is positioned between the wind wheel and the viscous liquid wheel.

Preferably, the rotating shaft comprises a first cylindrical portion, a first prismatic portion, a second cylindrical portion, a second prismatic portion and a threaded portion which are sequentially arranged along the axial direction, a first shoulder portion is formed at the adjacent position of the first prismatic portion and the second cylindrical portion, a second shoulder portion is formed at the adjacent position of the second prismatic portion and the second cylindrical portion,

the first cylindrical portion and the second cylindrical portion are used for being supported on the gun body.

Preferably, the rotating assembly comprises an isolating cylinder and a nut, the mucus wheel is clamped on the first prism part, the isolating cylinder is sleeved on the second prism part, the nut is screwed on the threaded part,

the fan is clamped on the second prism part and extruded between the second shoulder part and the end face of the first end of the isolation cylinder, and the wind wheel is clamped on the second prism part and extruded between the end face of the second end of the isolation cylinder and the nut.

Preferably, the rotating shaft comprises a first cylindrical part, a prism part and a second cylindrical part which are sequentially arranged along the axial direction,

the second cylindrical part is provided with a sliding groove along the axial direction, the prism part is used for clamping the viscous liquid wheel, and the end face of the second cylindrical part is provided with an internal threaded hole.

Preferably, the fan is slidably disposed on the second cylindrical portion, and a bolt is disposed on the fan and is configured to be screwed into the sliding groove, so as to fix the fan.

Preferably, the wind wheel comprises a hub and a plurality of blades distributed on the peripheral wall of the hub, two end faces of the hub are respectively provided with an external thread rod and an internal thread cylinder, and the external thread rod is matched with the internal thread hole.

Preferably, the number of the wind wheel is multiple, the external thread rod is matched with the internal thread cylinder, so that the external thread rod can be screwed into the internal thread cylinder,

the wind wheels are connected with the internal thread cylinder in sequence through the respective external thread rods to form a wind wheel set.

Preferably, the mucoid wheel includes a wheel frame and a plurality of mucoid rings distributed on the outer circumference of the wheel frame.

Preferably, the mucus wheel further comprises a flywheel ring, and the flywheel ring is sleeved on the peripheral wall of the mucus rings.

The energy-saving bubble gun provided by the invention can utilize outdoor natural wind as power to drive the whole rotating assembly to rotate, so that the mucus wheel in the rotating assembly rotates mucus, the fan rotates to provide power for blowing, pulling and expanding of bubbles, one shaft is multipurpose, the whole power system is integrated into a whole, the operation of the energy-saving bubble gun can be realized without additional energy supply, the trouble caused by frequent replacement of a battery of the conventional electric bubble gun is avoided, and the energy-saving bubble gun is convenient to use and environment-friendly. On the other hand, the wind wheel has the windmill function while providing power, so that the energy-saving bubble gun has the double functions of the windmill and generating bubbles, and a user has better use experience.

Drawings

The above and other objects, features and advantages of the present invention will become more apparent from the following description of the embodiments of the present invention with reference to the accompanying drawings.

FIG. 1 shows a front view of an energy saving bubble gun according to a first embodiment of the present invention (with the gun body shown in transparency).

FIG. 2 shows a right side view of the energy saving bubble gun according to the first embodiment of the present invention (with the gun body shown in transparency).

FIG. 3 is a perspective view of the rotating assembly of the energy saving bubble gun according to the first embodiment of the present invention.

FIG. 4 shows a split-type structure diagram of the rotating assembly of the energy-saving bubble gun according to the first embodiment of the present invention.

Fig. 5 is a schematic view showing a split structure of a rotating shaft of the rotating assembly according to the first embodiment of the present invention.

Fig. 6 is a perspective view of a viscous fluid wheel of a rolling assembly according to a first embodiment of the present invention.

Fig. 7 shows a perspective view of a rotating assembly according to a second embodiment of the present invention.

Fig. 8 shows a split structure diagram of a rotating assembly according to a second embodiment of the present invention.

Fig. 9 is a perspective view illustrating a rotation shaft of a rotation assembly according to a second embodiment of the present invention.

In the figure: the bubble liquid 1000, the gun body 100, the gun body 11, the first chamber 111, the second chamber 112, the gun handle 12, the sight 13, the liquid storage box 200, the rotation assembly 300, the rotation shaft 31, the first cylindrical portion 311, the first prism portion 312, the second cylindrical portion 313, the sliding groove 3131, the second prism portion 314, the threaded portion 315, the internal threaded hole 316, the viscous liquid wheel 32, the wheel frame 321, the viscous liquid ring 322, the flywheel ring 323, the annular groove 3231, the wind wheel 33, the hub 331, the blade 332, the fan 34, the hub 341, the bolt 342, the isolation cylinder 35, and the nut 36.

Detailed Description

Various embodiments of the present invention will be described in more detail below with reference to the accompanying drawings. Like elements in the various figures are denoted by the same or similar reference numerals. For purposes of clarity, the various features in the drawings are not necessarily drawn to scale.

The first embodiment:

as shown in fig. 1 to 6, the energy saving bubble gun of the present invention includes a gun body 100, a liquid storage case 200 and a rotation assembly 300. The gun body 100 includes a gun body 11 and a gun handle 12 attached to the gun body 11. The liquid storage box 200 is clamped in the gun body 11 and is used for storing the bubble liquid 1000. The rotating assembly 300 is rotatably supported on the gun body 100 and comprises a rotating shaft 31, a viscous liquid wheel 32 and a wind wheel 33, wherein the viscous liquid wheel 32 and the wind wheel 33 are sequentially arranged on the rotating shaft 31 along the axial direction of the rotating shaft 31, and the viscous liquid wheel 32 is used for adhering the bubble liquid 1000 and preforming the bubble liquid 1000.

The rotating shaft 31 penetrates through the gun body 11 and is rotatably supported on the gun body 11, the viscous liquid wheel 32 is arranged in the gun body 11, the lower portion of the viscous liquid wheel 32 is soaked in the liquid storage box 200, the upper portion of the viscous liquid wheel 32 is exposed out of the top wall of the gun body 11, the wind wheel 33 is located outside the gun body 11, the wind wheel 33 rotates by means of wind power to drive the viscous liquid wheel 32 to rotate, the viscous liquid wheel 32 is used for sticking the bubble liquid 1000 in the liquid storage box 200 in the rotating process and driving the bubble liquid 1000 to the upper portion after being preformed, and the preformed bubble liquid 1000 is blown and expanded to generate bubbles.

Specifically, the bottom wall of the gun body 11 is provided with a first chamber 111 extending towards the top wall direction for accommodating the liquid storage box 200. A triangular first protrusion is arranged on the inner wall of the first cavity 111, a triangular second protrusion is arranged on the outer wall of the liquid storage box 200, the second protrusion is matched with the first protrusion, and the second protrusion is made of soft sealing materials, such as rubber. The first protrusion and the second protrusion are matched for use and are used for clamping the liquid storage box 200. Further, the top end surface of the liquid storage box 200 is provided with a sealing material, which may be specifically selected from rubber. After the liquid storage box 200 is clamped in the first chamber 111, the top end surface of the liquid storage box 200 is simultaneously pressed on the top wall of the first chamber 111 to seal the liquid storage box 200 and prevent the bubble liquid 1000 in the liquid storage box 200 from flowing out.

The gun body 11 is further provided with a second chamber 112 for accommodating the mucus wheel 32, and the second chamber 112 penetrates from the top wall of the gun body 100 to the first chamber 111. The second chamber 112 is arcuate along opposite inner walls of the length of the frame 11 to generally match the outer dimensions of the freewheel ring 323, and the second chamber 112 is approximately the same thickness as the viscous fluid wheel 32 to provide a side wall seal.

In this embodiment, the first chamber 111 and the second chamber 112 are provided slightly offset to the side away from the wind wheel 33 in the thickness direction of the gun body 11, so as to form an overall force balance.

When the viscous liquid wheel 32 drives the bubble liquid 1000 to rotate to the outside of the gun body 11, the preformed bubble liquid 1000 can be blown and expanded into bubbles by the natural wind from the outside.

Further, the rotating assembly 300 further comprises a fan 34 for providing wind power for bubble generation, wherein the fan 34 is disposed on the rotating shaft 31 and located between the wind wheel 33 and the viscous liquid wheel 32. The wind wheel 33 and the fan 34 are opposite in wind-receiving surface, in this example, the wind-receiving surface of the wind wheel 33 faces the side far away from the gun handle 12, and the wind-receiving surface of the fan 34 faces the side close to the gun handle 12. The wind receiving area of the wind wheel 33 is larger than that of the fan 34, and the wind receiving area of the wind wheel 33 is 2-6 times, for example 4 times, larger than that of the fan 34. Thus, the fan 34 can provide a large wind force to promote the generation of bubbles, and the situation that the bubbles cannot be generated or the generation effect is poor due to insufficient wind force of external natural wind can be avoided.

The rotating shaft 31 includes a first cylindrical portion 311, a first prism portion 312, a second cylindrical portion 313, a second prism portion 314, and a threaded portion 315, which are sequentially arranged along an axial direction, where a first shoulder portion is formed at a position adjacent to the first prism portion 312 and the second cylindrical portion 313, and a second shoulder portion is formed at a position adjacent to the second prism portion 314 and the second cylindrical portion 313. The first cylindrical portion 311 and the second cylindrical portion 313 are used for being supported on the gun body 100.

The rotating assembly 300 comprises an isolating cylinder 35 and a nut 36, the viscous liquid wheel 32 is clamped on the first prism portion 312, the isolating cylinder 35 is sleeved on the second prism portion 314, and the nut 36 is screwed on the thread portion 315. The fan 34 is clamped on the second prism portion 314 and is pressed between the second shoulder portion and the end surface of the first end of the isolation cylinder 35, and the wind wheel 33 is clamped on the second prism portion 314 and is pressed between the end surface of the second end of the isolation cylinder 35 and the nut 36. The fan 34 includes a hub 341 and a plurality of fan blades distributed on the hub 341.

The mucus wheel 32 includes a wheel frame 321 and a plurality of mucus rings 322, and the plurality of mucus rings 322 are distributed on the outer circumference of the wheel frame 321. The inner peripheral wall of the mucus ring 322 is provided with mucus teeth for sticking and temporarily storing the bubble liquid 1000, and increasing the adhesion to the bubble liquid 1000. The axial direction of the viscous ring 322 is parallel to the axial direction of the rotary shaft 31. At least one viscous ring 322 of viscous liquid wheel 32 is completely exposed from the top wall of gun body 11, and in this embodiment, three viscous rings 322 are simultaneously and completely exposed from the top wall of gun body 11.

The wind wheel 33 includes a hub 331 and a plurality of blades 332 distributed on an outer circumferential wall of the hub 331.

Further, the viscous liquid wheel 32 further includes a flywheel ring 323, and the flywheel ring 323 is sleeved on the outer peripheral wall of the viscous liquid rings 322, so that the viscous liquid rings 322 are distributed between the external flywheel ring 323 and the internal wheel carrier 321. In this embodiment, the flywheel ring 323 is made of rubber, on the one hand, the flywheel ring 323 is used to store kinetic energy when the rotating assembly 300 rotates, and on the other hand, to form a sidewall seal with the inner wall of the second chamber 112.

Further, the wind wheel 33 has annular grooves 3231 formed on opposite sides thereof for storing a portion of the bubble liquid 1000, so as to form a boundary wall lubrication with the inner wall of the second chamber 112 during rotation, thereby facilitating the rotation of the viscous liquid wheel 32.

In this embodiment, a sight 13 is rotatably provided on the top wall of the gun body 11 near the gun handle 12, and the sight 13 can be swung back and forth perpendicular to a rotation shaft 31 on the top wall of the gun body 11 to adjust the viewing angle. The sight 13 has an amplification effect, can observe the generation process of bubbles and the gorgeous changing color, and can provide better use experience.

In this embodiment, the shaft 31, the fan 34 and the wind wheel 33 may be made of a lightweight environment-friendly plastic material so as to reduce the overall mass of the rotating assembly 300.

When the energy-saving bubble gun in this embodiment is used, the bubble liquid 1000 is injected into the liquid storage box 200 and is clamped into the first chamber 111. The energy-saving bubble gun is held outdoors, wherein the wind wheel 33 faces to one side of the wind direction, and the wind wheel 33 rotates under the action of the wind force, so as to drive the fan 34 and the viscous liquid wheel 32 to rotate. The viscous liquid wheel 32 picks up the bubble liquid 1000 in the liquid storage box 200 during rotation, the preformed bubble liquid 1000 is driven to the upper part, and the preformed bubble liquid 1000 is blown and pulled by the wind of the fan 34 to generate bubbles.

Energy-conserving papaw rifle in this embodiment, can utilize open air natural wind to drive whole rotation assembly 300 as power and rotate, make the mucus wheel 32 rotation mucus in the rotation assembly 300, fan 34 rotates and provides power for the blowing of papaw expands, realized a multi-purpose, concentrate on a whole driving system, and need not extra energy supply alright realize the operation of energy-conserving papaw rifle, avoided the electronic papaw rifle battery of conventional needs often to be changed and the trouble that causes, high durability and convenient to use and environmental protection. On the other hand, the wind wheel 33 has a windmill function while providing power, so that the energy-saving bubble gun has dual functions of a windmill and generating bubbles, and a user has better use experience.

Second embodiment:

as shown in fig. 7 to 9, the energy saving bubble gun in this embodiment is different from the first embodiment in that:

the rotating shaft 31 includes a first cylindrical portion 311, a first prism portion 312, and a second cylindrical portion 313, which are sequentially arranged along the axial direction. The second cylindrical portion 313 has a sliding groove 3131 formed along the axial direction, the first prism portion 312 is used for clamping the viscous liquid wheel 32, and an end surface of the second cylindrical portion 313 has an internal threaded hole 316.

The wind wheel 33 comprises a hub 331 and a plurality of blades 332 distributed on the outer peripheral wall of the hub 331, two end faces of the hub 331 are respectively provided with an external threaded rod and an internal threaded cylinder, the external threaded rod is matched with the internal threaded hole 316, and the wind wheel 33 can be screwed into the internal threaded hole 316 of the rotating shaft 31 through the external threaded rod. The number of the wind wheels 33 can be one or more, and the external thread rods are matched with the internal thread cylinders at the same time, so that the external thread rods of the wind wheels 33 can be screwed into the internal thread cylinders of the adjacent wind wheels 33. The wind wheels 33 are sequentially connected with the internal thread cylinders of the adjacent wind wheels 33 through the respective external thread rods to form a wind wheel set. The specific number of the wind wheels 33 in the wind wheel 33 can be set according to the needs, for example, when the wind power is insufficient outdoors or when the bubbles need to be generated rapidly, the number of the wind wheels 33 can be set to be more, for example, two, three, four or five.

The fan 34 is slidably disposed on the second cylindrical portion 313, and a bolt 342 is disposed on a hub 341 of the fan 34 along a radial direction, and the bolt 342 is configured to be screwed into the sliding groove 3131, so as to fix the fan 34. When it is necessary to adjust the position of the fan 34 on the rotating shaft 31, for example, the bubble generation effect is not good (for example, the expansion effect is not obvious), or the generation speed is not good, the bolt 342 is firstly loosened to adjust the fan 34 back and forth until the desired effect is achieved, and then the bolt 342 is tightened to achieve the axial fixation of the fan 34.

When the energy-saving bubble gun in this embodiment is used, the bubble liquid 1000 is injected into the liquid storage box 200 and is clamped into the first chamber 111. The energy-saving bubble gun is held outdoors, wherein the wind wheel 33 faces to one side of the wind direction, and the wind wheel 33 rotates under the action of the wind force, so as to drive the fan 34 and the viscous liquid wheel 32 to rotate. Meanwhile, the number of the wind wheels 33 in the wind wheel set is set according to the requirement, and the position of the fan 34 on the rotating shaft 31 is adjusted until the ideal bubble generating effect is achieved. The viscous liquid wheel 32 picks up the bubble liquid 1000 in the liquid storage box 200 during rotation, the preformed bubble liquid 1000 is driven to the upper part, and the preformed bubble liquid 1000 is blown and pulled by the wind of the fan 34 to generate bubbles.

Energy-conserving papaw rifle in this embodiment can utilize open air natural wind to drive whole rotation assembly 300 and rotate as power for mucus wheel 32 in the rotation assembly 300 rotates mucus, fan 34 rotates and provides power for the blowing of papaw expands, realized a multi-purpose, say that whole driving system concentrates on a whole, and need not extra energy supply alright realize the operation of energy-conserving papaw rifle, avoided the electronic papaw rifle battery of conventional needs often to be changed and the trouble that causes, high durability and convenient to use and environmental protection. On the other hand, the wind wheel 33 has a windmill function while providing power, so that the energy-saving bubble gun has dual functions of windmill and generating bubbles.

The energy-saving bubble gun in this embodiment has a power system adjustment function relative to the energy-saving bubble gun in the first embodiment, so that the user experience is better.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

Finally, it should be noted that: it should be understood that the above examples are only for clearly illustrating the present invention and are not intended to limit the embodiments. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. And obvious variations or modifications of the invention may be made without departing from the scope of the invention.

Claims (3)

1. An energy saving bubble gun, comprising:

the gun body comprises a gun body and a gun handle connected to the gun body;

the liquid storage box is clamped in the gun body and used for storing bubble liquid;

the rotating assembly is rotatably supported on the gun body and comprises a rotating shaft, a viscous liquid wheel and a wind wheel, the viscous liquid wheel and the wind wheel are sequentially arranged on the rotating shaft along the axial direction of the rotating shaft, and the viscous liquid wheel is used for sticking bubble liquid and performing preforming on the bubble liquid;

the rotating assembly further comprises a fan for providing wind power for bubble generation, and the fan is arranged on the rotating shaft and is positioned between the wind wheel and the viscous liquid wheel;

the wind wheel and the fan are opposite in wind receiving surface, the wind receiving surface of the wind wheel faces to one side far away from the gun handle, the wind receiving surface of the fan faces to one side close to the gun handle, the wind receiving area of the wind wheel is larger than that of the fan, and the wind receiving area of the wind wheel is 2-6 times of that of the fan;

the rotating shaft penetrates through the gun body and is rotatably supported on the gun body, the viscous liquid wheel is arranged in the gun body, the lower part of the viscous liquid wheel is soaked in the liquid storage box, the upper part of the viscous liquid wheel is exposed out of the top wall of the gun body, the wind wheel is positioned outside the gun body and is driven to rotate by wind power, bubble liquid in the liquid storage box is adhered and driven to the upper part after being preformed in the rotating process of the viscous liquid wheel, and the preformed bubble liquid is blown, pulled and expanded to generate bubbles;

the rotating shaft comprises a first cylindrical part, a prism part and a second cylindrical part which are sequentially arranged along the axial direction, wherein the prism part is used for clamping the viscous liquid wheel, and an internal threaded hole is formed in the end face of the second cylindrical part;

the wind wheel comprises a hub and a plurality of blades distributed on the peripheral wall of the hub, an external thread rod and an internal thread cylinder are respectively arranged on two end faces of the hub, and the external thread rod is matched with the internal thread hole;

the wind wheels are multiple in number, the external thread rods are matched with the internal thread cylinders, so that the external thread rods can be screwed in the internal thread cylinders, and the wind wheels are sequentially connected with the internal thread cylinders through the respective external thread rods to form wind wheel sets;

the fan is arranged on the second cylindrical portion in a sliding mode, a sliding groove is formed in the second cylindrical portion in the axial direction, the fan is arranged on the second cylindrical portion in a sliding mode, and a bolt is arranged on the fan and used for being screwed into the sliding groove in a screwing mode, so that the fan is fixed.

2. The energy saving bubble gun of claim 1, wherein the mucoid wheel comprises a wheel frame and a plurality of mucoid rings distributed on the outer circumference of the wheel frame.

3. The energy saving bubble gun of claim 2, wherein the viscous liquid wheel further comprises a flywheel ring, the flywheel ring being fitted around the outer peripheral wall of the plurality of viscous liquid rings.

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