CN111068347B - Continuous bubble machine - Google Patents

Abstract

The present invention relates to the field of entertainment equipment, and in particular to a continuous jetting bubble machine, which can generate bubbles for use in stage effects or for children to play with. The continuous jetting bubble machine is provided with a bubble liquid cavity, a bubble outlet, and a liquid guide channel to guide the bubble liquid flowing out of the bubble liquid cavity to the bubble outlet. The liquid guide channel is designed to guide the bubble liquid to the front and back of the bubble outlet, so that a liquid film can be formed on the front and back of the bubble outlet. The bubble machine not only improves the success rate of bubbling, but also improves the continuity of bubbling.

Description

Continuous jet type bubble machine

Technical Field

The invention relates to the field of entertainment tools, in particular to a continuous spraying type bubble machine which can generate bubbles for stage effect distribution or children to play.

Background

In the existing bubble machine capable of continuously discharging bubbles, a liquid wiping piece is generally arranged in front of a bubble outlet, and the liquid wiping piece rotates to enable the bubble outlet to form a new liquid film on one hand, and plays a role in cutting off blown bubbles on the other hand. In theory, the bubble machine can continuously discharge bubbles during continuous blowing, but in actual operation, the fact that the blown bubbles cannot form a liquid film in time after being scraped once the liquid wiping part rotates is found, and the blown bubbles cannot be continuous is caused.

Disclosure of Invention

The invention discloses a continuous ejection type bubble machine, which not only improves the success rate of bubble formation, but also improves the continuity of bubble formation.

In order to achieve the above purpose, the invention adopts the following technical scheme:

The continuous ejection type bubble machine is provided with a bubble liquid cavity and a bubble outlet, and is also provided with a liquid guide channel for guiding bubble liquid flowing out of the bubble liquid cavity to the bubble outlet, wherein the liquid guide channel is designed for guiding the bubble liquid to the front surface and the back surface of the bubble outlet so that a liquid film can be formed on the front surface and the back surface of the bubble outlet.

Further, the liquid guide channel comprises a main liquid channel, the upper end of the main liquid channel is connected with the bubble liquid cavity, and the lower end of the main liquid channel is connected with one surface of the bubble outlet.

The foam liquid guiding channel comprises an outer wall axial liquid guiding groove formed in the outer wall of the foam ring and/or an inner wall axial liquid guiding groove formed in the inner wall of the foam ring, and two ends of the axial liquid guiding groove are respectively communicated with two sides of the foam outlet, so that foam liquid can be guided from one side with higher foam outlet to the other side with lower foam outlet.

Further, the axial liquid guide groove is positioned on the upper semi-ring of the bubble outlet ring.

Further, the inner wall axial direction is a plurality of to the cistern quantity, surrounds the close-packed peripheral edge at the bubble mouth.

Further, the side of the bubble outlet connected with the lower end of the main liquid flow channel is a front side.

Further, a liquid smearing piece is arranged on the back surface of the foam outlet so as to smear foam liquid on the back surface of the foam outlet to form a liquid film.

Further, a fan and an air path are arranged, and air blown by the fan reaches the bubble outlet through the air path to continuously blow up a liquid film positioned at the bubble outlet so as to realize continuous bubble outlet.

Further, the bubble liquid outlet device comprises a lifting pump, wherein the bubble liquid cavity is positioned below the bubble outlet, and the main liquid runner is connected with the bubble liquid cavity through the lifting pump.

Further, a fan, a bubble blowing air path and an atomization air path are arranged, the rear ends of the bubble blowing air path and the atomization air path are connected with the fan, the front ends of the bubble blowing air path and the atomization air path are connected with the bubble outlet, the rear ends of the two air paths are connected with the same fan, and the air speed of the atomization air path is lower than that of the bubble blowing air path.

Further, the atomizing air path is narrower than the bubbling air path, and/or the atomizing air path is circuitous.

Further, an atomization module is arranged in the atomization air path.

Further, a mounting cavity for detachably mounting the atomizing module is provided in the atomizing air passage.

Further, the atomization module is included.

Further, a power supply contact is arranged in the mounting cavity, and a power taking contact aligned with the power supply contact in the mounting cavity is arranged on the atomizing module.

Further, the cleaning device comprises a crank connecting rod structure and a driving mechanism, wherein the cleaning piece is connected with the connecting rod, and the driving mechanism drives the crank to rotate, so that the connecting rod and the cleaning piece are driven to swing back and forth.

The bubble machine has the advantages that the liquid guide channels in the bubble machine are designed to guide bubble liquid to the front surface and the back surface of the bubble outlet so that liquid films can be formed on the front surface and the back surface of the bubble outlet, so that bubbles can be formed only by forming the liquid films on any one surface of the front surface and the back surface of the bubble outlet, the success rate of foaming is improved, and the liquid films can be formed on the front surface and the back surface, and the liquid films can be formed on the back surface in time when the front surface is foamed, so that bubbles can be immediately formed on the back surface after the front surface is foamed, and the bubble outlet continuity is improved.

Drawings

FIG. 1 is a block diagram of a bubble machine;

FIG. 2 is a block diagram of the bubble machine with half of the gun body removed;

FIG. 3 is a block diagram of a bubble generating mechanism;

FIG. 4 is a block diagram within the housing;

FIG. 5 is a block diagram of an atomizing module;

FIG. 6 is a block diagram of the atomizing module with the housing removed;

FIG. 7 is a partial schematic view of an atomizing channel;

FIG. 8 is a schematic view of the bubble gun after the cap of the mounting cavity is removed and the upper cap is detached;

FIG. 9 is a block diagram of the bubble ring and the wiper;

Fig. 10 is a structural view of a crank.

Detailed Description

The invention is further described below with reference to specific embodiments and figures.

As shown in fig. 1, the continuous ejection type bubble machine is gun-shaped, and comprises a gun body 1, a bubble liquid bottle 2 with a bubble liquid cavity inside and a bubble forming mechanism 3 loaded in the gun body 1. As shown in fig. 2, a bubble liquid outlet 21 is arranged at the top of the bubble liquid bottle 2, the bubble liquid outlet 21 is connected with a water inlet pipe 323 (see fig. 9) on the bubble forming mechanism 3 through a pipeline (not shown), a lifting pump (not shown) for pumping out bubble water and conveying the bubble water to the water inlet pipe 323 is connected to the middle part of the pipeline, and the bubble liquid bottle 2 supplies bubble water for the bubble forming mechanism 3 when the lifting pump is started. A first power cavity 11 for placing three batteries is arranged in the handle of the gun body 1, and a lift pump is arranged at the rear part of the gun body 1 so that the batteries in the first power cavity 11 supply power for the lift pump. The bubble liquid bottle 2 and the lift pump are realized by adopting the prior art, and the specific structure and principle thereof are not repeated here.

As shown in fig. 3, the foaming mechanism 3 comprises a crank connecting rod structure 31, a foam outlet ring 32, a liquid wiping piece 33 and a shell 34, wherein the shell 34 encloses an atomization air path 35 (see fig. 4) and a foam blowing air path 36 (see fig. 4). As shown in fig. 4, a gear transmission assembly 37 is disposed at the back of the atomizing air path 35 and the bubbling air path 36 in the housing 34, a double-end motor 38 is fixed beside the gear transmission assembly 37, a first output shaft of the double-end motor 38 is connected with a fan blade assembly 39 to form a fan, the fan blade assembly 39 is located at the rear ends of the atomizing air path 35 and the bubbling air path 36, and when the double-end motor 38 drives the fan blade assembly 39 to rotate, wind generated by the fan blade assembly 39 enters the atomizing air path 35 and the bubbling air path 36 from the rear ends of the atomizing air path 35 and the bubbling air path 36 respectively. The bubble blowing air path 36 is a substantially straight air path, the atomization air path 35 first goes rightward, then goes forward through the atomization module 4 and turns leftward to be combined with the bubble blowing air path 36, namely, the atomization air path 35 is roundabout, and the atomization air path 35 is narrower than the bubble blowing air path 36, so that the air quantity entering the atomization air path 35 is smaller, and the air speed of the atomization air path 35 is lower than that of the bubble blowing air path 36. Because the atomizing air path 35 and the bubble blowing air path 36 share one fan, and through the structural design of the atomizing air path 35 and the bubble blowing air path 36, the number of fans is reduced and the volume of the bubble machine is saved under the condition of meeting the requirements of different wind speeds of the atomizing air path 35 and the bubble blowing air path 36. The front ends of the bubble blowing air passage 36 and the atomizing air passage 35 are converged, so that air generated by the fan blade assembly 39 is converged to reach the bubble outlet ring 32 after passing through the atomizing air passage 35 and the bubble blowing air passage 36 respectively (see fig. 3), smoke in the atomizing air passage 35 is brought to the bubble outlet ring 32, and then the air with the smoke continuously blows up a liquid film at the bubble outlet 321 to continuously form bubbles coated with the smoke, so that continuous bubble outlet is realized.

In the atomizing air path 35, there is provided a mounting chamber 351 (see fig. 8) for detachably mounting the atomizing module 4, the atomizing module 4 is mounted in the mounting chamber 351, the mounting chamber 351 is provided with a cover 352 (see fig. 8), and the cover 352 is fixed to the gun body 1 by screws. As shown in fig. 5, the atomizing module 4 includes a housing 41, an atomizing passage 42, and an atomizing liquid container 43 (see fig. 6), both of which atomizing passage 42 and atomizing liquid container 43 are enclosed by the housing 41, but both ends of the atomizing passage 42 are not shielded by the housing 41, so that wind energy flows from one end to the other end of the atomizing passage 42. As shown in fig. 6, the atomizing channel 42 is partially enclosed by an atomizing liquid container 43, the atomizing liquid container 43 is filled with an atomizing liquid, and two opposite through holes 421 (see fig. 7) are formed in the portion of the atomizing channel 42 located in the atomizing liquid container 43. The atomizing channel 42 is internally provided with liquid absorbing cotton (not shown), and two ends of the liquid absorbing cotton respectively penetrate through the two through holes 421 and extend into the atomized liquid container 43, so that atomized liquid can be absorbed by the liquid absorbing cotton and spread and transported towards the middle along the two ends of the liquid absorbing cotton, and the atomized liquid is supplied to the atomizing channel 42. After the two ends of the liquid suction cotton pass through the two through holes 421 respectively, the liquid suction cotton just fills the through holes 421, so that the atomized liquid in the atomized liquid container 43 can only enter the atomized channel 42 along the liquid suction cotton, and the problem that the atomized liquid possibly leaks from the two ends of the atomized channel 42 when entering the atomized channel 42 too much is avoided. A heating wire (not shown) serving as a heating device is wound on a part of the liquid absorbing cotton, which is located in the atomizing channel 42, a second power supply cavity 5 (see fig. 2) is arranged above the crank connecting rod structure 31 in the gun body 1, and a battery installed in the second power supply cavity 5 supplies power to the heating wire (the structure and principle of the battery are described in detail below). As shown in fig. 8, the gun body 1 includes an upper cover 12, and the upper cover 12 is fixed to the gun body 1 by screws. When the upper cover 12 is covered, the opening of the second power supply chamber 5 and the screwed portion of the cover 352 of the installation chamber 351 are covered by the upper cover 12. After the upper cover 12 is opened, the opening of the second power cavity 5 is exposed, and the user can replace the battery. In addition, the portion of the cover 352 of the installation cavity 351 locked by the screw is also exposed, and the user can remove the screw to open the cover 352 of the installation cavity 351 and replace the atomizing module 4. The installation cavity 351 is internally provided with a power supply contact 6 electrically connected with a battery in the second power supply cavity 5, the atomizing module 4 is provided with a power taking contact piece 44 (see fig. 5) aligned with the power supply contact 6 in the installation cavity 351, and the power taking contact piece 44 is electrically connected with the heating wire. when the atomizing module 4 is installed in the installation cavity 351, the battery in the second power supply cavity 5 supplies power to the heating wire through the power supply contact 6 and the power-taking electric shock, so that the heating wire can heat to atomize atomized liquid in the atomizing channel 42, and smog is formed. In this embodiment, the atomized liquid container 43 encapsulates the atomized liquid, the atomized liquid container 43 is provided with a liquid injection port 431 (see fig. 6), and the manufacturer fills the atomized liquid into the atomized liquid container 43 from the liquid injection port 431 and seals the liquid injection port 431. After the atomized liquid module is manufactured, the shell 41 blocks the liquid injection port 431, so that a user cannot add atomized liquid by himself, and safety is ensured. If the atomized liquid is used up, a user only needs to integrally replace the atomization module 4, the replaced atomization module 4 can be directly discarded, and if the manufacturer has a demand, the atomized liquid can be recycled for the manufacturer.

In this embodiment, the atomized liquid container 43 can be used for packaging the atomized liquid, and the housing 41 can be used for packaging the atomized liquid instead, so long as the housing 41 isolates the atomized liquid from the user, and no injection port capable of injecting the atomized liquid is arranged on the housing 41, so that the user cannot add the atomized liquid inwards by himself.

In this embodiment, two opposite through holes are formed in the portion of the atomizing channel 42 located in the atomized liquid container 43, but only one through hole 421 may be formed instead, and a portion of the liquid absorbent cotton extends into the atomized liquid container 43 through the through hole 421, and another portion is located in the atomized liquid channel 42, so long as the atomized liquid in the atomized liquid container 43 can spread into the atomized liquid channel 42 through the liquid absorbent cotton.

As shown in fig. 2, a bubble liquid recovery member 7 is connected to the front end of the housing 34. The bubble liquid recovery member 7 includes a front housing 71 and a rear housing 72, the front housing 71 and the rear housing 72 enclose a containing space, and the structure of the bubble liquid recovery member 7 for recovering bubble liquid is the prior art and is not described herein. The bubble outlet ring 32 and the liquid wiping member 33 are arranged in the accommodating space, as shown in fig. 9, a bubble outlet 321 is formed in the middle of the bubble outlet ring 32, a main liquid flow passage 322 is arranged above the front surface of the bubble outlet 321, the lower end of the main liquid flow passage 322 is connected with the front surface of the bubble outlet 321, the upper end of the main liquid flow passage 322 is connected with a water inlet pipe 323, the water inlet pipe 323 passes through the rear shell 72 and then is connected with a bubble liquid bottle 2 through a pipeline, and the bubble liquid in the bubble liquid bottle 2 is lifted and conveyed to the water inlet pipe 323 by the lifting pump. A gap is left between the front surface of the bubble ring 32 and the front housing 71, so that after the bubble liquid enters the main liquid flow channel 322 from the water inlet pipe 323, the bubble liquid can flow from top to bottom to the bubble outlet 321, and a front liquid film is formed on the front surface of the bubble outlet 321. The outer wall of the upper semi-ring of the bubble outlet ring 32 is provided with an outer wall axial liquid guiding groove 324, the inner wall of the bubble outlet ring 32 is provided with a plurality of inner wall axial liquid guiding grooves 325 which are distributed around the periphery of the bubble outlet 321, and two ends of each axial liquid guiding groove 324 and 325 are respectively communicated with two sides of the bubble outlet 321. The top of the bubble ring 32 is inclined rearward so that the front surface of the bubble outlet 321 is higher than the rear surface thereof, so that bubble liquid flowing down to the front surface from the lower end of the main liquid flow path 322 can flow to the rear surface through the outer wall axial liquid guide groove 324 and the inner wall axial liquid guide groove 325, whereby it can be seen that the main liquid flow path 322, the outer wall axial liquid guide groove 324 and the inner wall axial liquid guide groove 325 are used as liquid guide flow paths. The top of the liquid wiping part 33 is rotatably fixed on the back of the bubble outlet ring 32, the liquid wiping part 33 is connected with the transmission part 331, and the transmission part 331 drives the liquid wiping part 33 to swing under the drive of the crank connecting rod structure 31 (see fig. 3), so that the liquid wiping part 33 wipes bubble liquid on the back of the flow passage to form a back liquid film on the back of the bubble outlet 321. The bubble machine of the embodiment can form liquid films on the front surface and the back surface of the bubble outlet 321, and the front surface and the back surface are basically not mutually interfered when the liquid films are formed, so that bubbles can be formed only by forming the liquid films on any one surface of the front surface and the back surface of the bubble outlet 321, the success rate of bubble formation is improved, and the front surface and the back surface can form the liquid films in time when the front surface is foamed, so that bubbles can be immediately formed on the back surface after the front surface is foamed, and the bubble formation continuity is improved.

As shown in fig. 3, the crank link structure 31 includes a link 311 and a crank 312. A pair of pushing members 81 and 82 are fixed to the front end of the link 311 with a gap, and a transmission member 331 on the bubble ring 32 is inserted into the gap after passing through the rear housing 72. As shown in fig. 10, an insert 3121 is provided at the edge of the crank 312, a rotation shaft 3122 is provided in the middle of the lower surface of the crank 312, the rotation shaft 3122 passes through the housing 41 and is connected with a tail transmission wheel 372 (see fig. 4) in the gear assembly 37, a head transmission wheel 371 (see fig. 4) in the gear assembly 37 is engaged with a screw 9 provided on the second output shaft of the double-headed motor 38, the gear assembly 37 is of the prior art, and the engagement relationship between the gears is not described herein. After the double-headed motor 38 is started, the crank 312 can be driven to rotate by the gear transmission assembly 37, so that the double-headed motor 38 and the gear transmission assembly 37 can be used as a driving mechanism. As shown in fig. 3, the rear end of the link 311 is provided with a moving through groove 3111, and a plug 3121 on the edge of the crank 312 is inserted into the moving through groove 3111, the top of the housing 41 is provided with a rotation fulcrum 45, and the middle of the link 311 is rotatably fixed on the rotation fulcrum 45. When the crank 312 rotates, the insert 3121 pushes the rear end of the link 311 to swing, and the middle of the link 311 rotates about the rotation pivot 45, thereby causing the front end of the link 311 to swing back and forth. The pair of pushing members 81 and 82 swings back along with the front end of the connecting rod 311 to push the driving member 331 to rotate back and forth together with the wiper member 33, thereby realizing the back and forth swinging of the wiper member 33. The position of the connecting rod 311 between the moving through groove 3111 and the middle part is provided with a limit groove 3112 parallel to the back and forth swinging direction so as to limit the back and forth swinging distance of the end part of the connecting rod 311, thereby limiting the back and forth swinging angle of the liquid wiping piece 33, and ensuring that the back and forth swinging of the liquid wiping piece 33 just meets the requirement of forming a liquid film by coating bubble liquid on the bubble outlet 321. The foam machine can realize the swinging of the liquid wiping part 33 without controlling the rotation by a control program, thereby not only reducing the software development cost, but also correspondingly reducing the volume of the foam outlet 321.

In this embodiment, the outer wall axial liquid guiding groove 324 is formed on the outer wall of the upper half ring of the bubble ring 32, the inner wall of the bubble ring 32 is provided with a plurality of inner wall axial liquid guiding grooves 325 which are circumferentially and densely distributed around the bubble outlet 321, two ends of each axial liquid guiding groove 324 and 325 are respectively connected with two sides of the bubble outlet 321, and the top of the bubble ring 32 is inclined backwards, so that bubble liquid flowing down to the front from the lower end of the main liquid flow channel 322 can flow to the back through the outer wall axial liquid guiding groove 324 and the inner wall axial liquid guiding groove 325, and then the bubble liquid flowing to the back is smeared through swinging of the liquid smearing piece 33 arranged on the back of the bubble outlet 321, thereby forming a back liquid film on the back of the bubble outlet 321. In a non-preferred case, the outer wall axial liquid guiding groove 324 and the inner wall axial liquid guiding groove 325 may be changed to have another main liquid flow channel which is the same as the main liquid flow channel 322 on the back surface of the bubble ring, the upper end of the main liquid flow channel on the back surface is also connected with the water inlet pipe 323, and the lower end of the main liquid flow channel is connected with the back surface of the bubble outlet 321, so that after the bubble liquid enters the main liquid flow channel on the back surface from the water inlet pipe 323, the bubble liquid can flow to the bubble outlet 321 from top to bottom, and a back liquid film is formed on the back surface of the bubble outlet 321. In this case, the wiper 33, the crank link structure 31 and the gear transmission assembly 37 can be omitted, which has the advantage of a more simplified structure. However, the premise of forming a back liquid film by utilizing the back main liquid channel to flow downwards to the bubble outlet is that the main liquid channel needs to be above the bubble outlet. The user may hold the foam machine obliquely when using the foam machine, so that the main liquid guide channel is not located above the foam outlet, and at this time, there is a risk that a liquid film cannot be formed at the foam outlet, so that the foam machine cannot continuously foam.

The above description is merely of a preferred embodiment of the present invention, the present invention is not limited to the above embodiment, and minor structural modifications may exist in the implementation process, and if various modifications or variations of the present invention do not depart from the spirit and scope of the present invention and fall within the scope of the appended claims and the equivalent technology, the present invention is also intended to include such modifications and variations.

Claims (12)

1. A continuous jet bubble machine, provided with a bubble liquid chamber, a bubble outlet, and a liquid guide channel to guide the bubble liquid flowing out of the bubble liquid chamber to the bubble outlet, characterized in that the liquid guide channel is designed to guide the bubble liquid to the front and back sides of the bubble outlet, so that a liquid film can be formed on the front and back sides of the bubble outlet; the liquid guide channel includes a main liquid guide channel, the upper end of which is connected to the bubble liquid chamber, and the lower end is connected to one side of the bubble outlet; including a bubble outlet ring forming the bubble outlet, and the bubble outlet is connected to the lower end of the main liquid guide channel. The other side is higher than the other side; the liquid guide channel includes The invention comprises an outer wall axial liquid guide groove provided on the outer wall of the bubble outlet ring and an inner wall axial liquid guide groove provided on the inner wall of the bubble outlet ring, the two ends of the outer wall axial liquid guide groove are respectively connected to the two sides of the bubble outlet so as to guide the bubble liquid from the higher side of the bubble outlet to the lower side thereof, and the two ends of the inner wall axial liquid guide groove are respectively connected to the two sides of the bubble outlet so as to guide the bubble liquid from the higher side of the bubble outlet to the lower side thereof; the outer wall axial liquid guide groove is located in the upper half of the bubble outlet ring; there are a plurality of inner wall axial liquid guide grooves which are densely distributed around the bubble outlet. 2. The continuous jet bubble machine according to claim 1 is characterized in that the side of the bubble outlet connected to the lower end of the main liquid flow channel is the front side. 3. The continuous jet bubble machine according to claim 2 is characterized in that a liquid smearing member is provided on the back of the bubble outlet to smear bubble liquid on the back of the bubble outlet to form a liquid film. 4. The continuous jet bubble machine according to claim 1 is characterized in that a fan and an air path are provided, and the wind blown by the fan reaches the bubble outlet through the air path to continuously blow up the liquid film located at the bubble outlet to achieve continuous bubble production. 5. The continuous jet bubble machine according to claim 1 is characterized in that it includes a lifting pump, the bubble liquid chamber is located below the bubble outlet, and the main liquid flow channel is connected to the bubble liquid chamber through the lifting pump. 6. The continuous jet bubble machine according to claim 3 or 5 is characterized in that it is provided with a fan, a bubble blowing air path and an atomizing air path, the bubble blowing air path and the atomizing air path have rear ends connected to the fan and front ends connected to the bubble outlet, the bubble blowing air path and the atomizing air path have rear ends connected to the same fan, and the air path structure is arranged so that the wind speed of the atomizing air path is lower than that of the bubble blowing air path. 7. The continuous jet bubble machine according to claim 6, characterized in that the atomizing air path is narrower than the bubble blowing air path, and/or the atomizing air path is circuitous. 8. The continuous jet bubble machine according to claim 6, characterized in that an atomization module is provided in the atomization air path. 9. The continuous jet bubble machine according to claim 6, characterized in that a mounting cavity for detachably mounting the atomizing module is provided in the atomizing air passage. 10. The continuous jet bubble machine according to claim 9, characterized in that it comprises the atomization module. 11. The continuous jet bubble machine according to claim 10, characterized in that a power supply contact is provided in the installation cavity, and a power contact piece aligned with the power supply contact in the installation cavity is provided on the atomization module. 12. The continuous jet bubble machine according to claim 3, characterized in that it comprises a crank-connecting rod structure and a driving mechanism, wherein the liquid spreading member is connected to the connecting rod, and the driving mechanism drives the crank to rotate, thereby driving the connecting rod and the liquid spreading member to swing back and forth.