CN108926278B - High-efficiency foaming device - Google Patents

Abstract

The invention relates to the technical field of foaming devices, and discloses a high-efficiency foaming device which comprises a feeding mechanism for conveying cleaning objects, a water tank mechanism for conveying water and a stirring mechanism; the stirring mechanism comprises a stirring shell with an inner cavity and a stirring disc driven by a motor to rotate, the stirring disc separates the inner cavity to form a mixing cavity and a thinning cavity, the stirring disc is provided with a plurality of first overflow outlets which enable the mixing cavity to be communicated with the thinning cavity, the feeding mechanism is respectively communicated with the mixing cavity with the water tank mechanism, the stirring shell is provided with an air inlet and a foam outlet for air to enter the mixing cavity, and the cleaning matters, the water and the air are mixed to form mixed liquid; the foam outlet is arranged above the stirring plate, the mixed liquid is stirred by the stirring plate to form foam, and the foam moves upwards and is discharged through the foam outlet. Through the multiple stirring to the mixed solution to realize high-efficient foaming device's quick foaming and lasting bubble, and, the foam that forms is finer and smoother, more abundant, thereby reinforcing clean effect.

Description

High-efficiency foaming device

Technical Field

The invention relates to the technical field of foaming devices, in particular to a high-efficiency foaming device.

Background

Along with the development of economy, people pay more attention to the image of themselves while the social conditions are changed; foam personal care products such as shampoo, bath lotion, facial cleanser, hand cleanser, cleanser essence, toothpaste and the like become necessary cleaning consumer products for the masses every day.

At present, the product is required to be rubbed by hands to form foam, so that the use is realized, part of the product is wasted without foaming, the time and the labor are wasted, and the quick, automatic and effective cleaning and skin care cannot be realized; in addition, the nursing product is directly used, has high concentration and large stimulation, and is easy to cause skin injury.

In the prior art, foaming is realized by mixing cleansing milk, bath lotion, shampoo, cleaning skin care hair care products and the like with water through a foaming device; however, the existing foaming device still has a plurality of defects, the material selection is limited, the material supply is unstable, the rapid automatic foaming cannot be realized, the foaming stability is poor, and the foaming effect is not fine enough, so that the cleaning effect of the cleaning object is poor.

Disclosure of Invention

The invention aims to provide a high-efficiency foaming device and aims to solve the problem that the foaming effect of the foaming device in the prior art is poor.

The invention is realized in such a way that the high-efficiency foaming device comprises a feeding mechanism for conveying cleaning objects, a water tank mechanism for conveying water and a stirring mechanism; the stirring mechanism comprises a stirring shell with an inner cavity and a stirring disc driven by a motor to rotate, the stirring disc is used for separating the inner cavity to form a mixing cavity and a thinning cavity, the stirring disc is provided with a plurality of first overflow outlets which enable the mixing cavity to be communicated with the thinning cavity, the feeding mechanism is respectively communicated with the mixing cavity with the water tank mechanism, the stirring shell is provided with an air inlet and a foam outlet, air enters the mixing cavity, and cleaning matters, water and air are mixed to form mixed liquid; the foam outlet is arranged above the stirring disc, the mixed liquid is stirred by the stirring disc to form foam, and the foam moves upwards and is discharged through the foam outlet.

Further, the stirring mechanism comprises a stirring scraping wheel which is positioned above the stirring disc and synchronously rotates with the stirring disc, the foam outlet is positioned above the stirring scraping wheel, the refining cavity comprises an upper refining cavity and a lower refining cavity, the stirring scraping wheel is positioned in the upper refining cavity, the stirring scraping wheel is provided with a plurality of second overflow outlets which enable the lower refining cavity to be communicated with the upper refining cavity, and the mixed liquid sequentially passes through the mixing cavity, the lower refining cavity and the upper refining cavity to be stirred to form foam, and the foam moves upwards and is discharged through the foam outlet.

Further, the stirring scraping wheel is provided with a plurality of scraping hooks and a plurality of first thinning rods which are arranged in an upward extending mode, and the scraping hooks and the first thinning rods are respectively arranged at intervals in a circumferential surrounding mode.

Further, the top of the stirring shell is provided with a plurality of first guide rods which are arranged in a downward extending mode, the first guide rods are arranged at intervals in a circumferential surrounding mode, and the first guide rods are positioned in the upper thinning cavity; each first guide rod and each first refining rod are arranged in a staggered mode.

Further, the stirring plate is provided with a plurality of stirring rods which extend downwards and are embedded into the mixing cavity, the bottom of the stirring shell is provided with a plurality of second guide rods which extend upwards and are positioned in the mixing cavity, and each stirring rod and each second guide rod are arranged in a staggered mode.

Further, the stirring plate is provided with a plurality of second refining rods which extend upwards and are positioned in the lower refining cavity, and the first overflow is positioned between the second refining rods and the stirring rods.

Further, the efficient foaming device comprises an extraction mechanism, wherein the extraction mechanism comprises a plurality of cup air chambers, cup water chambers and an eccentric structure, and the eccentric structure drives the cup air chambers and the cup water chambers to work; the upper portion of the cup air chamber is communicated with the mixing cavity, the eccentric structure is fixed at the lower portion of the cup air chamber, the upper portion of the cup water chamber is communicated with the mixing cavity, and the eccentric structure is fixed at the lower portion of the cup water chamber.

Further, the eccentric structure comprises a driving shaft driven by a motor to do circular motion, an eccentric wheel fixedly connected with the driving shaft and synchronously rotating, and a leather cup plate which is fixed at the top of the eccentric wheel and has the same eccentric angle with the eccentric wheel, wherein the leather cup plate forms a plurality of mounting positions, and a plurality of leather cup air chambers and the leather cup water chambers are respectively and correspondingly fixed with the mounting positions; when the eccentric wheel rotates, the mounting position moves reciprocally; when the installation position moves upwards, the cup air chamber and the cup water chamber are in a compressed state, air and water are pumped into the mixing cavity, when the installation position moves downwards, the cup air chamber extracts air, and the cup water chamber extracts water.

Further, the feeding mechanism comprises a charging barrel with a storage cavity, a piston body arranged in the charging barrel and a rotating shaft which rotates to enable the piston body to reciprocate, the piston body separates the storage cavity to form a first cavity and a second cavity, and the first cavity and the second cavity are not communicated with each other; a first communication port is formed at one end of the charging barrel, a second communication port is formed at the other end of the charging barrel, materials are added into the first cavity through the first communication port, and when the piston body moves towards the first communication port, the materials in the first cavity are discharged out through the first communication port and enter the mixing cavity; and when the piston body moves towards the direction of the second communication port, the material in the second cavity is discharged through the second communication port and enters the mixing cavity.

Further, the feeding mechanism comprises a magnetic induction switch, the magnetic induction switch is arranged at the lower part of the charging barrel and is positioned outside the charging barrel, the piston body is provided with a magnet, the magnet is driven to move downwards when the piston body moves downwards, and the magnetic induction switch is triggered by the magnet to feed back to a circuit, so that a warning that the material is used up is sent out; the bottom of the water tank mechanism is provided with a probe, the probe is connected with the circuit, and when the water level in the water tank is lower than the probe, the feedback information of the touch circuit shows that the water of the water tank mechanism is used up.

Compared with the prior art, when the efficient foaming device is used, cleaning matters enter the mixing cavity through the feeding mechanism, air enters the mixing cavity through the air inlet, the stirring disc is driven to rotate by the motor after the motor is started, the cleaning matters, water and air in the mixing cavity are cut and stirred, so that the cleaning matters, water and air are rapidly mixed and thinned to form foam, the foam enters the thinning cavity through the first overflow port, the foam enters the thinning cavity after being cut and stirred again through the first overflow port, and the foam formed after being cut and stirred again in the thinning cavity moves upwards and is discharged from the foam outlet; through the multiple stirring to the mixed solution to realize high-efficient foaming device's quick foaming and lasting bubble, and, the foam that forms is finer and smoother, more abundant, thereby reinforcing clean effect.

Drawings

FIG. 1 is an exploded schematic view of a high efficiency foaming device provided by an embodiment of the present invention;

FIG. 2 is a schematic cross-sectional view of a high efficiency foaming apparatus provided in an embodiment of the present invention;

fig. 3 is a schematic perspective view of a high-efficiency foaming device according to an embodiment of the present invention;

FIG. 4 is an exploded schematic view of a stirring mechanism of a high-efficiency bubbling device according to an embodiment of the present invention;

FIG. 5 is a schematic cross-sectional view of a stirring mechanism of a high-efficiency bubbling device according to an embodiment of the invention;

FIG. 6 is a schematic perspective view of a stirring plate of the high-efficiency bubbling device according to an embodiment of the invention;

Fig. 7 is a schematic perspective view of a stirring scraping wheel of the high-efficiency foaming device provided by the embodiment of the invention;

FIG. 8 is a schematic cross-sectional view of a stirring mechanism of a high-efficiency bubbling device according to an embodiment of the invention;

Fig. 9 is a schematic perspective view of a stirring mechanism of the high-efficiency bubbling device according to an embodiment of the invention;

FIG. 10 is a schematic partial perspective view of a stirring housing of a high-efficiency bubbling device according to an embodiment of the invention

FIG. 11 is a schematic perspective view of an extraction mechanism of a high-efficiency bubbling device according to an embodiment of the invention;

FIG. 12 is an exploded view of the extraction mechanism of the high efficiency foaming device provided by the embodiment of the invention;

FIG. 13 is a schematic perspective view of a power transmission mechanism of a high efficiency foaming device provided by an embodiment of the invention;

fig. 14 is a schematic perspective view of a feeding mechanism of the high-efficiency bubbling device according to an embodiment of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present invention more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

The same or similar reference numerals in the drawings of the present embodiment correspond to the same or similar components; in the description of the present invention, it should be understood that, if there is an azimuth or positional relationship indicated by terms such as "upper", "lower", "left", "right", etc., based on the azimuth or positional relationship shown in the drawings, it is only for convenience of describing the present invention and simplifying the description, but it is not indicated or implied that the apparatus or element referred to must have a specific azimuth, be constructed and operated in a specific azimuth, and thus terms describing the positional relationship in the drawings are merely illustrative and should not be construed as limitations of the present patent, and specific meanings of the terms described above may be understood by those skilled in the art according to specific circumstances.

The implementation of the present invention will be described in detail below with reference to specific embodiments.

Referring to fig. 1-14, a preferred embodiment of the present invention is provided.

The invention provides a high-efficiency foaming device which is used for solving the problem of poor foaming effect of the foaming device.

The high-efficiency foaming device comprises a feeding mechanism 300, a water tank mechanism 200 and a stirring mechanism 100; the feeding mechanism 300 is used for delivering cleaning objects, and the tank mechanism 200 is used for delivering water.

The stirring mechanism 100 comprises a stirring shell 120 and a stirring disc 110, wherein the stirring shell 120 is provided with an inner cavity, the stirring disc 110 is driven to rotate by a motor 410, the stirring disc 110 separates the inner cavity to form a mixing cavity 160 and a thinning cavity, the stirring disc 110 is provided with a plurality of first overflow outlets 115, and the first overflow outlets 115 enable the mixing cavity 160 to be communicated with the thinning cavity; the feeding mechanism and the water tank mechanism are respectively communicated with the mixing cavity 160, the stirring shell 120 is provided with an air inlet and a foam outlet 192, the air inlet is used for allowing air to enter the mixing cavity 160, and the cleaning matters, the water and the air are mixed to form mixed liquid; the foam outlet 192 is located above the stirring plate 110, and the mixed liquid is stirred by the stirring plate 110 to form foam, and the foam moves upwards and is discharged through the foam outlet 192.

When the efficient foaming device is used, cleaning matters enter the mixing cavity 160 through the feeding mechanism 300, air enters the mixing cavity 160 through the air inlet, the stirring disc 110 is driven to rotate by the motor 410 after the motor 410 is started, the cleaning matters, water and air in the mixing cavity 160 are cut and stirred, so that the cleaning matters, water and air are rapidly mixed and thinned to form foam, the foam enters the thinning cavity through the first overflow outlet 115, the foam enters the thinning cavity after being cut and stirred again through the first overflow outlet 115, and the foam formed after being cut and stirred again in the thinning cavity is upwards moved to be discharged from the foam outlet 192; through the multiple stirring to the mixed solution to realize high-efficient foaming device's quick foaming and lasting bubble, and, the foam that forms is finer and smoother, more abundant, thereby reinforcing clean effect.

The stirring mechanism 100 comprises a stirring scraping wheel 130, the stirring scraping wheel 130 is positioned above the stirring disc 110 and rotates synchronously with the stirring disc 110, a foam outlet 192 is positioned above the stirring scraping wheel 130, a refining cavity comprises an upper refining cavity 180 and a lower refining cavity 170, the stirring scraping wheel 130 is positioned in the upper refining cavity 180, the stirring scraping wheel 130 is provided with a plurality of second overflow outlets 118 which enable the lower refining cavity 170 to be communicated with the upper refining cavity 180, and after the mixed solution is stirred by the mixing cavity 160, the lower refining cavity 170 and the upper refining cavity 180 in sequence, foam is formed and upwards moves to be discharged through the foam outlet 192; in this way, under the action of the stirring disc 110 and the stirring scraping wheel 130, multiple stirring and cutting are performed on the mixed liquid, so that the formed foam is finer and more sufficient, and the cleaning effect is enhanced.

The first overflow 115 communicates the mixing chamber 160 with the lower refining chamber 170; the foam formed by the mixing chamber 160 is carried out through the first overflow 115 into the lower refining chamber 170 for subsequent refining of the foam.

Furthermore, the stirring scraper 130 is provided with a plurality of scraping hooks 131 and a first thinning rod 132, the first thinning rod 132 extends upwards, and the plurality of scraping hooks 131 and the plurality of first thinning rods 132 are respectively circumferentially arranged; along the top down, the lower parts of the scraping hooks 131 are arranged in an arc shape, and the scraping hooks 131 of the scraping hooks 131 are arranged longitudinally; in this way, the scraping hook 131 helps to enhance the stirring and cutting action on the mixed liquid, and also serves as a guide for the foam, facilitating the discharge of the foam from the foam outlet 192.

In addition, each of the first refining rods 132 further refines the foam entering the upper refining chamber 180, so that the formed foam is finer and the cleaning effect is better.

The stirring disk 110 is provided with a plurality of stirring rods which extend downwards and are embedded into the mixing cavity 160, the bottom of the stirring shell 120 is provided with a plurality of second guide rods 140 which extend upwards and are positioned in the mixing cavity 160, and each stirring rod and each second guide rod 140 are arranged in a staggered manner; under the combined action of the stirring rods and the second guide rods 140, the mixed liquid is subjected to multiple stirring and cutting, so that the rapid foaming of the foaming device is realized, and the formed foam is finer and more fully mixed, so that the cleaning effect is enhanced.

The stirring disk 110 has a plurality of second refining bars extending upwardly in the lower refining chamber 170, the second refining bars being above the stirring bars, the first overflow 115 being between the second refining bars and the stirring bars; under the combined action of a plurality of second refining rods, the foam is subjected to multiple stirring and cutting, so that the formed foam is finer and more fully mixed, and the cleaning effect is enhanced.

The top of the stirring shell is provided with a plurality of first guide rods 190 which extend downwards, the plurality of first guide rods 190 are circumferentially arranged at intervals, and the first guide rods 190 are positioned in the upper thinning cavity; each first guide rod 190 and each first refinement rod are arranged in a staggered manner; the formed foam is finer and more fully mixed, so that the cleaning effect is enhanced.

The top of the stirring shell is provided with a foam scraping strip 191, the foam scraping strip 191 extends and is arranged along the direction from the center to a foam outlet 192, and the foam scraping strip 191 has a guiding thickness along the direction away from the top of the stirring shell; in this way, foam is facilitated to be discharged from the foam outlet 192.

The stirring disk 110 has a plurality of second refining bars extending upwards in the lower refining chamber, the first overflow 115 being between the second refining bars and the stirring bars; when the foam stirring and cutting machine rotates, the stirring and cutting effects are also realized on the foam, and the formed foam is finer and more fully mixed, so that the cleaning effect is enhanced.

The mixed liquid is stirred by the stirring disk 110 to form foam, and the foam is collected and stirred by the stirring scraping wheel 130 after overflowing from the upper refining cavity 180 and is discharged from the foam outlet 192 under the action of extrusion centrifugal force.

The plurality of stirring rods comprise a plurality of inner stirring rods 114 and a plurality of outer stirring rods 113, and the plurality of inner stirring rods 114 and the plurality of outer stirring rods 113 are respectively arranged at annular intervals; the plurality of outer stirring rods 113 are arranged around the outer circumference of the plurality of inner stirring rods 114; under the action of the inner stirring rods 114 and the outer stirring rods 113, the mixed liquid in the mixing cavity 160 is subjected to multi-region stirring and cutting, so that the mixed liquid is mixed and stirred more fully, and the formed cleaning foam is finer and finer, thereby enhancing the cleaning effect.

The second guide bar 140 has an inward inner end face and an outward outer end face, and when the agitator disk 110 rotates, the inner agitator bar 114 is tangential to the inner end face of the second guide bar 140 and the outer agitator bar 113 is tangential to the outer end face of the second guide bar 140; the mixed liquid is ground under the combined action of the inner stirring rod 114, the outer stirring rod 113 and the second guide rod 140, so that the mixed liquid is mixed more fully; at the same time, the mixed liquid is prevented from adhering to the second guide rod 140, the inner stirring rod 114 and the outer stirring rod 113, and the foaming device is ensured to realize sufficient foaming.

One end of the inner stirring rod 114 is gradually reduced in thickness to form a first cutting end, and the first cutting end is pointed; thus, when the stirring plate 110 rotates, each inner stirring rod 114 synchronously rotates along with the stirring plate 110, and the first cutting end of each inner stirring rod 114 helps to enhance the stirring and cutting action on the cleaning foam, and meanwhile, the first cutting end plays a guiding effect on the cleaning foam, so that the cleaning foam is conveniently discharged.

One end of the external stirring rod 113 is gradually reduced in thickness to form a second cutting end, and the second cutting end is pointed; when the stirring plate 110 rotates, each external stirring rod 113 synchronously rotates along with the stirring plate 110, and the second cutting end of each external stirring rod 113 enhances the stirring and cutting action on the cleaning foam, and meanwhile, the second cutting end plays a guiding effect on the cleaning foam, so that the cleaning foam is conveniently discharged.

Along the direction away from the first cutting end, the thickness of one end of the second guide rod 140 is gradually reduced to form a third cutting end, and the third cutting end is pointed; the third cut end of each second guide bar 140 enhances the agitation cutting action on the cleaning foam.

In addition, the third cutting end is matched with the first cutting end, so that the mixed liquid is cut and stirred in multiple directions, and the stirring effect is improved.

The plurality of second refinement stems includes a plurality of inner stems 112 and a plurality of outer stems 111; the plurality of inner slim rods 112 and the plurality of outer slim rods 111 are respectively arranged in a ring shape at intervals; the plurality of outer slim rods 111 are arranged around the outer circumference of the plurality of inner slim rods 112; under the action of the inner thin rods 112 and the outer thin rods 111, the mixed liquid in the refining cavity is subjected to multi-region stirring and cutting, so that further refining is realized, and the formed cleaning foam is finer, so that the cleaning effect is enhanced.

The stirring disc 110 comprises a disc seat 116, a second stirring rod is positioned below the disc seat 116 and abuts against the disc seat 116, and a second thinning rod is positioned above the disc seat 116 and abuts against the disc seat 116; the first overflow port 115 is formed at the tray 116; thus, when the foam enters the refining cavity through the first overflow outlet 115, the first overflow outlet 115 also cuts and stirs the foam, so that the formed foam is finer, the foam is further refined in the refining cavity, and the foam is finer.

The adjacent outer thin rods 111 have first gaps, the tray seats 116 corresponding to the first gaps are formed with a plurality of first overflow outlets 115, second gaps are formed between the outer thin rods 111 and the inner thin rods 112, and the tray seats 116 corresponding to the second gaps are formed with a plurality of first overflow outlets 115; the foam after being cut and stirred by the mixing cavity 160 is ensured to enter the thinning cavity, and meanwhile, the plurality of first overflow outlets 115 enhance the cutting and stirring effects on the foam.

The stirring shell 120 is internally provided with a stirring scraping wheel 130 which rotates to realize stirring effect, the stirring scraping wheel 130 is positioned above the stirring disc 110, and the stirring scraping wheel 130 and the stirring disc 110 synchronously rotate; the stirring scraper 130 is provided with a plurality of scraping hooks 131, and the plurality of scraping hooks 131 are circumferentially arranged; along the top down, the lower part of the scraping hook 131 is arranged in an arc shape, and the upper part of the scraping hook 131 is arranged longitudinally; under the action of the plurality of scraping hooks 131, the foam refined by the refining cavity is further cut and stirred, so that the foam is finer and finer, and the cleaning effect of the foam is ensured; in addition, the stirring scraper 130 plays a guiding role, so that the foam is moved upward.

The foam outlet 192 is located above the stirring scraper 130 and directly above each scraper 131, so that the stirring scraper 130 guides the foam, and the foam is conveniently moved to the foam outlet 192 and discharged from the foam outlet 192.

The stirring scraping wheel 130 and the stirring disc 110 rotate coaxially and synchronously; this facilitates control of the agitator scrapers 130 and agitator discs 110.

The stirring disk 110 is provided with fixing posts 117, the fixing posts 117 penetrate through the disk seat 116, the upper parts of the fixing posts 117 extend to the upper part of the refining cavity, the stirring scraping wheel 130 is connected with the upper parts of the fixing posts 117, and the lower parts of the fixing posts 117 extend to the mixing cavity 160; the fixed post 117 is provided with a power shaft, the power shaft is connected with a power end of the motor 410, and the motor 410 drives the power shaft to rotate, so that the stirring disk 110 and the stirring scraping wheel 130 synchronously rotate.

The fixed posts 117 penetrate through the middle of the tray 116, and the fixed posts 117 are respectively positioned in the middle of the mixing cavity 160 and the refining cavity; thereby ensuring the smoothness of rotation of the stirring disk 110 and the stirring scraper 130.

The upper portion of the fixed post 117 is cylindrical, and is provided with a tangential plane, so that the relative fixing effect of the stirring disk 110 and the stirring scraper 130 is enhanced, and the synchronous rotation of the stirring disk 110 and the stirring scraper 130 is ensured.

The agitator housing 120 is formed with a liquid inlet for the cleaning material to enter the mixing chamber 160, thereby allowing the cleaning material to enter the mixing chamber 160.

The stirring housing 120 is formed with a boss 150 protruding upwards, and a plurality of communication cavities are formed on the outer surface of the boss 150, and the air inlet, the water inlet and the liquid inlet are respectively communicated with the communication cavities; thus, water, air and cleaning matters are convenient to intensively mix, and the three are convenient to mix, so that the mixed liquid formed by mixing the three is convenient to cut and stir.

Specifically, the efficient foaming device comprises an extraction mechanism 500, wherein the extraction mechanism 500 comprises a plurality of cup air chambers 530, a cup water chamber 540 and an eccentric wheel 510 structure, and the eccentric wheel structure drives the plurality of cup air chambers 530 and the cup water chamber 540 to work; the upper part of the cup air chamber 530 is communicated with the mixing cavity 160, the lower part of the cup air chamber 530 is fixed with an eccentric structure, the upper part of the cup water chamber 540 is communicated with the mixing cavity 160, and the lower part of the cup water chamber 540 is fixed with an eccentric structure; under the action of the eccentric structure, each cup air chamber 530 and the cup water chamber 540 sequentially work, thereby realizing continuous air and water supply.

The eccentric structure comprises a driving shaft 450, an eccentric wheel 510 and a cup tray 520, wherein the driving shaft 450 is driven by a motor 410 to do circular motion, the eccentric wheel 510 is fixedly connected with the driving shaft 450, the eccentric wheel 510 and the driving shaft 450 synchronously rotate, the cup tray 520 is fixed on the top of the eccentric wheel 510, the eccentric angles of the cup tray 520 and the eccentric wheel 510 are consistent, the cup tray 520 forms a plurality of mounting positions 521, and a plurality of cup air chambers 530 and cup water chambers 540 respectively correspond to the fixed mounting positions 521; as the eccentric 510 rotates, the mounting location 521 reciprocates; when the mounting position 521 moves upwards, the cup air chamber 530 and the cup water chamber 540 are in a compressed state, air and water are pumped into the mixing cavity 160, and when the mounting position 521 moves downwards, the cup air chamber 530 pumps air and the cup water chamber 540 pumps water; thus, each cup air chamber 530 and the cup water chamber 540 sequentially operate, and continuous supply of air and water is realized.

Furthermore, the upper part of the driving shaft 450 extends upwards to be connected with the stirring mechanism 100, so as to drive the stirring disk 110 to synchronously rotate; the driving force of the motor 410 is transmitted to the agitator disk 110 through the driving shaft 450, and the rotation of the agitator disk 110 is achieved.

The cup water chamber 540 is communicated with the water tank mechanism 200, so that water in the water tank mechanism 200 is convenient to enter the mixing cavity 160 under the action of the cup water chamber 540, and is mixed with cleaning matters and air.

The cup air chambers 530 and 540 are arranged in a staggered manner; the cup air chambers 530 and 540 operate sequentially to continuously supply air and water.

The eccentric 510 includes a connection post 511 arranged in an inclined manner, the connection post 511 penetrates and fixes the cup plate 520, and each mounting position 521 is arranged in an annular interval along the circumference of the connection post 511; because the connecting posts 511 are obliquely arranged, when the eccentric wheel 510 rotates, the plurality of angles of the connecting posts 511 are switched, the cup plates 520 are vertically reciprocated along the longitudinal direction, and the mounting positions 521 are vertically reciprocated along the longitudinal direction.

The eccentric wheel 510 comprises a supporting plate 512, the supporting plate 512 is connected with the lower part of the connecting column 511, the supporting plate 512 is obliquely arranged, and the leather cup plate 520 is abutted against the supporting plate 512; thereby enhancing the installation stability of the cup tray 520.

The lower end of the cup water chamber 540 extends downwards to form a first column, and the first column penetrates through the mounting position 521; the first column body has a first limiting block 542, and the first limiting block 542 clamps the mounting position 521 with the lower end of the cup water chamber 540; under the action of the first limiting block 542, the connection stability between the lower end of the cup water chamber 540 and the mounting position 521 is ensured; thus, the mounting location 521 compresses or expands the cup chamber 540 as it reciprocates up and down.

After the leather cup water chamber 540 is installed, the first column body is removed, the whole occupied area is reduced, and meanwhile, under the action of the first column body, the leather cup water chamber 540 is convenient to install.

The lower end of the cup air chamber 530 extends downwards to form a second column, and the second column penetrates through the mounting position 521; the second cylinder is provided with a second limiting block 532, and the second limiting block 532 clamps the mounting position 521 with the lower end of the cup air chamber 530; under the action of the second limiting block 532, the connection stability between the lower end of the cup air chamber 530 and the mounting position 521 is ensured; thus, the mounting location 521 compresses or expands the cup air chamber 530 as it reciprocates up and down.

After the cup air chamber 530 is installed, the second cylinder is removed, the whole occupied area is reduced, and meanwhile, under the action of the second cylinder, the cup air chamber 530 is conveniently installed.

The extracting structure is connected with a stirring mechanism 100, the stirring mechanism 100 is provided with a plurality of air inlets and water inlets, and the air inlets are correspondingly arranged and communicated with the upper ends of the leather cup air chambers 530; the water inlet is correspondingly arranged and communicated with the upper end of the leather cup water chamber 540; thus, the water is provided for the stirring mechanism 100 through the cup water chamber 540, the air is provided for the stirring mechanism 100 through the cup water chamber 530, the mixing of the water, the air and the cleaning matters is realized, the water and the air are not needed to be added temporarily and manually, and the use of the foaming device is facilitated.

Furthermore, the air inlet and the water inlet are respectively provided with a one-way valve 550; thereby avoiding the backflow of water and air and ensuring the normal use of the foaming device.

The extraction structure comprises a plurality of positioning columns, the positioning columns are arranged in an extending mode along the direction deviating from the air inlet, adjacent mounting positions 521 form positioning gaps for embedding the positioning columns, and when the positioning columns are embedded into the positioning gaps, two sides of the positioning columns respectively abut against the adjacent mounting positions 521; under the action of the plurality of positioning posts, the installation stability of the cup tray 520 is enhanced, and the shaking of the cup tray 520 when the cup tray 520 rotates is reduced.

The stirring mechanism 100 comprises a stirring shell 120 with an inner cavity and an opening at the lower end and a base, wherein the base seals the opening at the lower end of the stirring shell 120; the air inlet and the water inlet are respectively formed at the base, and when the cup water chamber 540 is in a compressed state, water is conveyed into the inner cavity, and when the cup water chamber 530 is in a compressed state, gas is conveyed into the inner cavity; the water and air of the foaming device are supplied, and under the action of the eccentric wheel 510, the cup air chambers 530 and 540 work continuously in sequence, so that continuous supply is realized.

The stirring mechanism 100 comprises a stirring disc 110 for realizing stirring and cutting, a motor 410 is connected with a transmission shaft, and the transmission shaft respectively penetrates through an eccentric wheel 510 and the stirring disc 110 to realize synchronous rotation of the eccentric wheel 510, a cup plate 520 and the stirring disc 110; control of the eccentric 510, the cup 520, and the agitator 110 is facilitated, and normal use of the frothing device is ensured.

The eccentric wheel 510 is connected with the cup 520 through a ball bearing 590, so that the eccentric wheel 510 and the cup 520 are relatively fixed and synchronously rotate.

The connecting post 511 of the eccentric 510 penetrates the ball bearing 590, and the cup plate 520 forms a connecting port surrounding the ball bearing 590; the eccentric 510 and the cup plate 520 are relatively fixed.

The outer wall of the ball bearing 590 is fixed with the cup plate 520, and the inner wall is fixed with the eccentric 510; the fixation of the eccentric 510 and the cup plate 520 is realized.

The extracting structure comprises a pump housing 560, the upper part of the cup air chamber 530 and the upper part of the cup water chamber 540 are respectively arranged on the pump housing 560, the upper part of the cup air chamber 530 forms a first top opening, the upper part of the cup water chamber 540 forms a second top opening, the air inlet is communicated with the first top opening, and the water inlet is communicated with the second top opening; thereby enabling water of the water tank mechanism 200 to enter the cup chamber 540 and external air to enter the cup chamber 530.

A cover plate 580 is arranged above the pump housing 560, the cover plate 580 is provided with a plurality of through openings 581, and the through openings 581 are arranged in one-to-one correspondence with the first top opening and the second top opening; the through-hole 581 communicates with the mixing chamber 160, and air and water enter the mixing chamber 160 through the through-hole 581.

The check valve 550 is provided at the through-hole 581 to prevent air from flowing backward and water from flowing backward, thereby ensuring the normal operation of the pumping structure.

Specifically, the feeding mechanism 300 includes a barrel 310, a piston body 360 and a rotating shaft 320, the barrel 310 has a storage cavity, the piston body 360 is disposed in the barrel 310, the rotating shaft 320 rotates to make the piston body 360 reciprocate, the piston body 360 separates the storage cavity to form a first cavity 311 and a second cavity 312, and the first cavity 311 is not communicated with the second cavity 312; a first communication port 420 is formed at one end of the cylinder 310, a second communication port is formed at the other end of the cylinder 310, and when the piston body 360 moves toward the first communication port 420, the material of the first chamber 311 is discharged out of the first chamber 311 through the first communication port 420; when the piston body 360 moves toward the second communication port, the material of the second chamber 312 is discharged out of the second chamber 312 through the second communication port.

In this way, the piston body 360 performs extrusion of the material, facilitating the discharge of the material; and, first chamber 311 and second chamber 312 do not influence each other, realize discharging the material while, add the material in another chamber, be convenient for operation, save time.

When one end of the feeding shell is abutted against the stirring mechanism 100, the first cavity 311 is communicated with the stirring mechanism 100 through the first communication port 420; when the other end of the feeding shell is abutted against the stirring mechanism 100, the second cavity 312 is communicated with the stirring mechanism 100 through the second communication port; the piston body 360 is located between the first communication port 420 and the second communication port; it is achieved that the first chamber 311 is fed with material while the second chamber 312 is fed with material, or that the second chamber 312 is fed with material while the first chamber 311 is fed with material, thereby facilitating the feeding and feeding of material.

The high-efficiency foaming device comprises a power transmission mechanism 400, wherein the power transmission mechanism 400 comprises a transmission shell 470 and a plurality of transmission gears 440, the transmission gears 440 are meshed with each other in sequence, and the motor 410 drives each transmission gear 440 to rotate synchronously; the transmission housing 470 has a plurality of fixing grooves 430, and the water tank mechanism 200, the stirring mechanism 100, and the feeding mechanism 300 are arranged in one-to-one docking with the respective fixing grooves 430; the lower part of the driving shaft 450 extends downwards to engage with one transmission gear 440, and the lower part of the rotating shaft 320 extends downwards to be connected with the other transmission gear 440; the motor 410 is used for driving all the mechanisms simultaneously, so that the cost is saved, and all the mechanisms are convenient to control; in addition, each transmission gear 440 plays a role in multi-layer speed change, and precise control over each mechanism is realized.

In addition, the material in the first cavity 311 is extruded through the piston body 360, the material enters the mixing cavity 160 through the first communication port 420, and the material is added through the second communication port to enter the second cavity 312; when the other end of the material cylinder 310 is abutted against the fixing groove 430, the material in the second cavity 312 is extruded through the piston body 360, the material enters the mixing cavity 160 through the second communication port, and the material is added through the first communication port 420 and enters the first cavity 311; thereby facilitating the addition of cleaning substances and the entry of cleaning substances into the mixing chamber 160.

And, need not stop the foaming device work after, just add the material, simultaneously, avoid the material to use up, add the material loaded down with trivial details.

Meanwhile, when the first cavity 311 is in a discharging state, the cleaning objects in the second cavity 312 exert a pressurizing effect on the piston body 360, so that the cleaning objects can be discharged from the first cavity 311 conveniently; when the second chamber 312 is in the discharging state, the cleaning object in the first chamber 311 pressurizes the piston body 360, so that the second chamber 312 discharges the cleaning object.

The water tank mechanism 200, the stirring mechanism 100 and the feeding mechanism 300 are respectively abutted against the fixed groove 430 of the transmission housing 470; the water tank mechanism 200, the stirring mechanism 100 and the feeding mechanism 300 are integrated, and the stirring mechanism 100 is respectively communicated with the water tank mechanism 200 and the feeding mechanism 300, so that water and cleaning matters enter the mixing cavity 160 of the stirring mechanism 100.

The feeding mechanism 300 comprises a first cover body for covering the first communication port 420, the first cover body is provided with a first communication column 370 which is hollow, and when the first cover body covers the first communication port 420, one end of the first communication column 370 is communicated with the first cavity 311; when one end of the feeding shell is abutted against the stirring mechanism 100, the other end of the first communication column 370 is communicated with the stirring mechanism 100; the material in the first cavity 311 is conveyed to the stirring mechanism 100 through the first communication column 370, so that the subsequent processing of the material is facilitated.

One end of the first communicating column 370 is in a shape of big end down, which facilitates the material in the first cavity 311 to be transported to the stirring mechanism 100.

The feeding mechanism 300 comprises a second cover body for covering the second communication port, the second cover body is provided with a second hollow communication column 340, and when the second cover body covers the second communication port, one end of the second communication column 340 is communicated with the second cavity 312; when one end of the feeding shell is abutted against the stirring mechanism 100, the other end of the second communication column 340 is communicated with the stirring mechanism 100; the material in the second cavity 312 is conveyed to the stirring mechanism 100 through the second communication column 340, so that subsequent processing of the material is facilitated.

One end of the second communicating column 340 is in a shape of big end down, which facilitates the material in the second chamber 312 to be transported to the stirring mechanism 100.

One end of the feeding shell is hinged with a cover lock body 350, one end of the cover lock body 350 is hinged with the feeding shell, the other end of the cover lock body 350 is movably arranged, one end of the feeding shell is provided with a fixed groove 430 for relatively fixing the other end of the cover lock body 350, and the cover lock body 350 is provided with a lock groove; when the other end of the cover lock body 350 is inserted into the fixing groove 430, the first communication post 370 is inserted into the locking groove; under the action of the cover lock body 350, the cover stability of the first cover body for covering the first communication port 420 is reinforced, so that the first cover body is prevented from being separated from the first communication port 420 by mistake.

The other end of the cover lock body 350 moves laterally, and when the cover lock body 350 is movably arranged, the cover lock body 350 loses the reinforcement effect on the first cover body, so that the first cover body is conveniently pulled out, and the material is conveniently added into the first cavity 311.

The other end of the feeding shell is hinged with the cover lock body 350, so that the cover stability of the second cover body for covering the second communication port is reinforced, and the second cover body is prevented from being separated from the second communication port by mistake.

The other end of the cover lock 350 moves laterally and, in a movable arrangement, the cover lock 350 loses reinforcement against the second closure, thereby facilitating removal of the second closure and facilitating insertion of additional material into the second cavity 312.

The cover lock body 350 has a recess groove recessed inward, and the cover lock body 350 is conveniently controlled by the recess groove, so that the other end of the cover lock body 350 is fixed or possibly released from the fixing groove 430.

The outer surface of the rotating shaft 320 is formed with threads, the rotating shaft 320 penetrates through the piston body 360, and the rotating shaft 320 rotates to realize reciprocating movement of the piston body 360; under the action of the screw thread, when the rotating shaft 320 rotates, the piston body 360 moves reciprocally, and the structure is simple and the operation is convenient.

The feeding shell and the piston body 360 are respectively arranged in a circular shape, the feeding shell is provided with a first tangent plane, the piston body 360 is provided with a second tangent plane, and the second tangent plane is overlapped with the first tangent plane; the advantage of this arrangement is that when the shaft 320 rotates, the piston body 360 is prevented from rotating with the shaft 320, the wedging property of the piston body 360 and the feeding housing is ensured, the mutual non-conduction of the first cavity 311 and the second cavity 312 is ensured, and simultaneously, the extrusion effect of the piston body 360 on the first cavity 311 or the second cavity 312 is ensured.

The feeding shell is provided with a magnetic induction switch 330, and the piston body 360 is provided with a magnet 361; when the piston body 360 moves close to the magnetic induction switch 330, the connection circuit of the magnetic induction switch 330 is turned on; thereby realizing the detection of the storage amount of the materials in the first cavity 311 or the second cavity 312 and avoiding the shortage of the materials.

The magnetic induction switch is arranged at the lower part of the charging barrel and is positioned at the outer part of the charging barrel, when the piston body moves downwards to drive the magnet to move downwards, the magnet touches the magnetic induction switch to feed back to the circuit, and a warning that the materials are used up is sent out; the bottom of the water tank mechanism is provided with a probe which is connected with the circuit, and when the water level in the water tank is lower than the probe, the feedback information of the touch circuit shows that the water in the water tank mechanism is used up; the problem that the foaming device is damaged due to insufficient water of the water tank mechanism and insufficient materials in the charging barrel is avoided.

The two ends of the rotating shaft 320 extend to the outside of the two ends of the feeding shell respectively to form a connecting part 321, and when the feeding shell is abutted to the stirring mechanism 100, the power of the motor 410 is transmitted to the connecting part 321; thereby enabling the motor 410 to power the shaft 320.

The feeding mechanism 300 includes a plurality of sequentially engaged transmission gears 440, and the motor 410 engages one of the transmission gears 440; the other transmission gear 440 is formed with a docking slot 450, and the connection portion 321 is embedded in the docking slot 450; the stability of the rotation shaft 320 is ensured, and the motor 410 is convenient to transmit power to the rotation shaft 320.

The abutting groove 450 is internally provided with a clamping piece 460, and when the connecting part 321 is embedded into the abutting groove 450, the connecting part 321 is clamped by the clamping piece 460; under the action of the clamping piece 460, the connection stability between the online machine and the butt joint groove 450 is enhanced, and the use of the foaming device is ensured.

The clamping piece 460 is hollow, one end of the clamping piece 460 is provided with an opening, after the connecting part 321 is inserted into the butt joint groove 450, the clamping piece 460 is embedded into the clamping piece, and the opening is in an expanded state, so that the connecting part 321 is clamped, and the connecting part 321 is fixed.

The water tank mechanism 200 comprises a water barrel 210, a water outlet 220 is formed at the bottom of the water barrel 210, the water outlet 220 is communicated with the mixing cavity 160, and a water filling port is formed at the top of the water barrel 210, so that the addition of water is realized.

The water outlet 220 is communicated with the cup water chamber 540, and the cup water chamber 540 pumps water in the water barrel 210 and transmits the water to the mixing cavity 160 for use by the foaming device.

The bottom of the water drum 210 is provided with a water quantity detecting needle 230, the water quantity detecting needle 230 is immersed in water, once the water quantity detecting needle 230 has an exposed part, the water quantity is proved to be at the bottom, and then an alarm is given, so that the influence of insufficient water quantity on the foaming effect is avoided.

Another embodiment of extraction mechanism 500:

the external bracket is communicated with the mixing cavity, and the communicating structure can adopt the structure of a feeding mechanism to change the materials in the charging barrel into water; the cup water chamber 540 is changed into a cup air chamber 530; ensuring a sufficient air supply.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims (5)

1. The efficient foaming device is characterized by comprising a feeding mechanism for conveying cleaning objects, a water tank mechanism for conveying water and a stirring mechanism; the stirring mechanism comprises a stirring shell with an inner cavity and a stirring disc driven by a motor to rotate, the stirring disc is used for separating the inner cavity to form a mixing cavity and a thinning cavity, the stirring disc is provided with a plurality of first overflow outlets which enable the mixing cavity to be communicated with the thinning cavity, the feeding mechanism is respectively communicated with the mixing cavity with the water tank mechanism, the stirring shell is provided with an air inlet and a foam outlet, air enters the mixing cavity, and cleaning matters, water and air are mixed to form mixed liquid; the foam outlet is positioned above the stirring disc, the mixed liquid is stirred by the stirring disc to form foam, and the foam moves upwards and is discharged through the foam outlet;

The stirring mechanism comprises a stirring scraping wheel which is positioned above the stirring disc and synchronously rotates with the stirring disc, the foam outlet is positioned above the stirring scraping wheel, the refining cavity comprises an upper refining cavity and a lower refining cavity, the stirring scraping wheel is positioned in the upper refining cavity, the stirring scraping wheel is provided with a plurality of second overflow outlets which enable the lower refining cavity to be communicated with the upper refining cavity, and after being stirred by the mixing cavity, the lower refining cavity and the upper refining cavity in sequence, foam is formed, and the foam moves upwards and is discharged through the foam outlet;

The stirring scraping wheel is provided with a plurality of scraping hooks and a plurality of first thinning rods which are arranged in an upward extending mode, and the scraping hooks and the first thinning rods are respectively arranged at intervals in a circumferential surrounding mode; the lower parts of the scraping hooks are arranged in an arc shape from top to bottom;

The top of the stirring shell is provided with a plurality of first guide rods which are arranged in a downward extending mode, the first guide rods are positioned in the upper refining cavity, and the plurality of first guide rods are circumferentially arranged at intervals; each first guide rod and each first refinement rod are arranged in a dislocation manner;

the stirring disc is provided with a plurality of stirring rods which extend downwards and are embedded into the mixing cavity, the bottom of the stirring shell is provided with a plurality of second guide rods which extend upwards and are positioned in the mixing cavity, and each stirring rod and each second guide rod are arranged in a staggered manner;

The stirring disk is provided with a plurality of second refining rods which extend upwards and are positioned in the lower refining cavity, and the first overflow is positioned between the second refining rods and the stirring rods.

2. The high-efficiency foaming device of claim 1, wherein the high-efficiency foaming device comprises an extraction mechanism, the extraction mechanism comprises a plurality of cup air chambers, a cup water chamber and an eccentric structure, and the eccentric structure drives the plurality of cup air chambers and the cup water chamber to work; the upper portion of the cup air chamber is communicated with the mixing cavity, the eccentric structure is fixed at the lower portion of the cup air chamber, the upper portion of the cup water chamber is communicated with the mixing cavity, and the eccentric structure is fixed at the lower portion of the cup water chamber.

3. The efficient foaming device according to claim 2, wherein the eccentric structure comprises a driving shaft driven by a motor to do circular motion, an eccentric wheel fixedly connected with the driving shaft and synchronously rotating, and a cup plate which is fixed on the top of the eccentric wheel and has an eccentric angle consistent with the eccentric wheel, wherein the cup plate forms a plurality of mounting positions, and a plurality of cup air chambers and cup water chambers are respectively and correspondingly fixed on the mounting positions; when the eccentric wheel rotates, the mounting position moves reciprocally; when the installation position moves upwards, the cup air chamber and the cup water chamber are in a compressed state, air and water are pumped into the mixing cavity, when the installation position moves downwards, the cup air chamber extracts air, and the cup water chamber extracts water.

4. The high-efficiency foaming device of claim 3, wherein the feeding mechanism comprises a material cylinder with a storage cavity, a piston body arranged in the material cylinder and a rotating shaft which rotates to enable the piston body to reciprocate, the piston body separates the storage cavity to form a first cavity and a second cavity, and the first cavity and the second cavity are not communicated with each other; a first communication port is formed at one end of the charging barrel, a second communication port is formed at the other end of the charging barrel, materials are added into the first cavity through the first communication port, and when the piston body moves towards the first communication port, the materials in the first cavity are discharged out through the first communication port and enter the mixing cavity; and when the piston body moves towards the direction of the second communication port, the material in the second cavity is discharged through the second communication port and enters the mixing cavity.

5. The efficient foaming device according to claim 4, wherein the feeding mechanism comprises a magnetic induction switch, the magnetic induction switch is arranged at the lower part of the charging barrel and is positioned outside the charging barrel, the piston body is provided with a magnet, the magnet is driven to move downwards when the piston body moves downwards, and the magnetic induction switch is triggered by the magnet to feed back to a circuit, so that an alarm that the material is used up is sent out; the bottom of the water tank mechanism is provided with a probe, the probe is connected with the circuit, and when the water level in the water tank mechanism is lower than the probe, the feedback information of the touch circuit shows that the water in the water tank mechanism is used up.