CN105796038B

CN105796038B - Shoe washing machine

Info

Publication number: CN105796038B
Application number: CN201410844259.4A
Authority: CN
Inventors: 陈维会; 刘杰; 王佑喜; 才智; 杨丽梅; 林雪锋
Original assignee: Qingdao Haier Washing Machine Co Ltd
Current assignee: Qingdao Haier Washing Machine Co Ltd; Haier Smart Home Co Ltd
Priority date: 2014-12-30
Filing date: 2014-12-30
Publication date: 2020-04-28
Anticipated expiration: 2034-12-30
Also published as: CN105796038A

Abstract

The invention provides a shoe washing machine, which comprises a water containing barrel, an inner impeller and an outer impeller, wherein the inner impeller and the outer impeller are respectively arranged in the water containing barrel; the outer impeller and the inner impeller are opposite in direction of rotation in a washing state, a central hairbrush is arranged on the inner impeller, and a bucket wall hairbrush is arranged on the inner wall of the water containing bucket. The inside of a water containing barrel of the shoe washing machine is provided with an inner impeller and an outer impeller, the inner impeller is provided with a central hairbrush, and the inner wall of the water containing barrel is provided with a barrel wall hairbrush: when the shoes are washed, the two impellers rotate in opposite directions, the inner impeller drives the central hairbrush to rotate integrally, the outer impeller drives the shoes to rotate in opposite directions with the central hairbrush, so that the central hairbrush can rub the surfaces of the shoes to achieve washing, and meanwhile, the barrel wall hairbrush can rub the other side of the shoes to further improve the washing effect.

Description

Shoe washing machine

Technical Field

The invention relates to the technical field of shoe washing equipment, in particular to a shoe washing machine.

Background

As a common household appliance, the washing machine effectively meets the requirement of people on clothes washing in daily life, but no effective solution exists for washing shoes. If the existing shoe washing machine is used for directly washing shoes, the following disadvantages can be caused:

firstly, the shoes are washed by the traditional washing machine, because the washing machine mainly adopts a water flow stirring mode to wash clothes, and because of the structural characteristics of the shoes, the cleanliness of the shoes can not be ensured.

Secondly, because the washing machine consumes a large amount of water, under the condition that the quantity of the washed shoes is small, a large amount of water resources are wasted by adopting the washing machine for washing.

Finally, as the shoes contain more bacteria, some shoes even contain peculiar smell, cross contamination can be caused by washing clothes after the shoes are washed by the washing machine, the user experience is greatly reduced, and even the health of people can be influenced.

The invention relates to a device for washing shoes, in particular to a device for washing shoes, which is a device capable of simultaneously washing the inside and the outside of the shoes, such as the device with application number 201310667501.0 and is named as a method and a device for washing shoes. The shoe washing method comprises the following steps: water flow cleaning: horizontally and fixedly placing the shoes in the shoe cage, and fully cleaning all surfaces of the shoes by water flow; friction cleaning: the friction ball is added into the water, the water flow drives the friction ball to move, the friction ball collides with the shoe, and all surfaces of the shoe are washed. The invention provides a method and a device for washing shoes, wherein the shoes are fixed in a shoe cage, the shoe cage is horizontally fixed on a shoe rack, the shoe rack is fixed on the inner wall of a barrel body, water generates positive and negative rotating water flows under the action of a wave wheel, and the water flows drive friction balls and detergent to wash the surfaces of the shoe body. Because the surface of the friction ball is provided with a plurality of thorn-shaped bulges, when the friction ball collides with the surface of the shoe, the friction force is larger, so that the cleaning power is stronger, and the water flow can drive the friction ball to each part of the shoe, so that the whole shoe is cleaned under the repeated washing.

The invention discloses a method and a device for cleaning shoes by adding friction balls into water flow and driving the friction balls to clean the shoes through the water flow.

Disclosure of Invention

In order to solve the technical problem, the invention provides a shoe washing machine, and aims to provide a shoe washing machine which is simple in structure and can carry out all-dimensional washing on the surfaces of shoes by adopting a brush. Specifically, the following technical scheme is adopted:

the shoe washing machine comprises a water containing barrel, an inner impeller and an outer impeller, wherein the inner impeller and the outer impeller are respectively arranged in the water containing barrel; the outer impeller and the inner impeller are opposite in direction of rotation in a washing state, a central hairbrush is arranged on the inner impeller, and a bucket wall hairbrush is arranged on the inner wall of the water containing bucket.

Furthermore, the outer impeller comprises an impeller body, a mounting opening is formed in the center of the impeller body, and the inner impeller is mounted in the mounting opening of the outer impeller and can rotate independently.

Furthermore, the impeller body is discoid, and the upper surface of impeller body sets up a plurality of stirring muscle and wash port.

Further, outer impeller on the detachable installation be used for placing the shoe rack of shoes, the shoe rack rotates with outer impeller is integrative: in a washing state, the shoe rack drives the shoes to rotate reversely with the central brush on the inner impeller to realize contact friction; under the dehydration state, the shoe rack drives the shoes and the central brush to rotate in the same direction and at the same speed so as to realize centrifugal dehydration.

Furthermore, the outer impeller is provided with a plurality of mounting holes for mounting the shoe rack, and the mounting holes are respectively distributed along the radial direction of the outer impeller so that the distance between the shoe rack and the central hairbrush can be adjusted.

Further, the central hairbrush is detachably arranged on the inner impeller: in a washing state, the central hairbrush is arranged on the inner impeller; in the dewatering state, the central hairbrush is detached from the inner impeller.

Furthermore, the central brush comprises a cylinder and central bristles, one end of the cylinder is mounted on the inner impeller through a sliding mechanism, and the sliding mechanism is sleeved on the cylinder and can be connected with or detached from the inner impeller in a sliding mode.

Furthermore, the sliding mechanism comprises a steel ball, a spring, a check ring and a sliding protective cover, the steel ball is arranged on the cylinder of the central hairbrush, the check ring is arranged on the cylinder and can block the steel ball, the spring is sleeved on the cylinder, and the sliding protective cover is sleeved on the spring and can slide relative to the cylinder; the cylinder is provided with a convex step used for abutting against one end of the spring, and the other end of the spring abuts against the sliding protective cover; the inner impeller is provided with a clamping groove matched with the sliding shield.

The water tub is provided with a water inlet, a water outlet and an inner impeller, the water inlet is provided with a water inlet hole, the water inlet hole is provided with a water inlet pipe, the water inlet pipe is provided with a water outlet pipe, the water inlet pipe is provided with a water inlet pipe, the water outlet pipe is provided with a water outlet pipe, the water inlet pipe is provided with a water inlet pipe, the water inlet pipe is provided with a water outlet pipe, the water inlet pipe is; the output shaft and the output shaft sleeve rotate in opposite directions in a washing state and rotate in the same speed and direction in a dehydration state.

Further, the driving device further comprises a driving motor, the driving motor is a direct-drive motor, one end of the output shaft and one end of the output shaft sleeve are respectively connected with the output end of the speed reduction clutch, and the input end of the speed reduction clutch is connected with the direct-drive motor through a transmission shaft: in a washing state, the power of the direct drive motor is distributed into two power with opposite rotation directions through the speed reduction clutch in a speed reduction way and is respectively transmitted to the output shaft sleeve and the output shaft, and then the outer impeller and the inner impeller are respectively driven to rotate reversely to realize washing; in a dehydration state, the power of the direct drive motor is distributed into two power with the same rotation direction and the same rotation speed through a speed reduction clutch to be respectively transmitted to an output shaft sleeve and an output shaft, and then an outer impeller and an inner impeller are respectively driven to rotate in the same speed and the same direction to realize dehydration;

or the driving motor is a double-rotor motor, one end of the output shaft and one end of the output shaft sleeve are respectively connected with two rotor output ends of the double-rotor motor, and washing and dewatering are realized by controlling the rotating speed and the rotating direction of two rotors of the double-rotor motor.

The shoe washing machine has water tub with two wavy wheels, including inner wavy wheel with central brush and outer wavy wheel with wall brush. When the shoes are washed, the two wave wheels rotate reversely, the inner wave wheel drives the central hairbrush to rotate integrally, the outer wave drives the shoes and the central hairbrush to rotate reversely, so that the central hairbrush can rub the surfaces of the shoes to achieve washing, and meanwhile, the barrel wall hairbrush can rub the other surface of the shoes to further improve the washing effect.

The shoe washing machine only comprises one water containing barrel, the structure is simpler, and two rotatable impellers are arranged in the water containing barrel, so that the washing effect of shoes can be further improved.

Specifically, the shoe washing machine of the present invention has the following advantages:

1. the shoe washing machine comprises the inner impeller and the outer impeller, and the inner impeller and the outer impeller rotate reversely under the washing state, so that shoes are driven by bidirectional power in the water containing barrel, and the washing effect is better.

2. The shoe rack is arranged on the outer impeller of the shoe washing machine, when in washing, shoes are placed on the shoe rack and kept in contact with the central hairbrush, and the contact friction of the central hairbrush on the shoes is realized under the action of the bidirectional rotation of the inner impeller and the outer impeller, so that the shoes have better washing effect under the friction action of the central hairbrush.

3. According to the shoe washing machine, when the shoes are dewatered, the shoes are firmly placed on the shoe rack, and the outer impeller drives the shoe rack to rotate at a high speed to realize centrifugal dewatering.

4. When the shoe washing machine disclosed by the invention is used for dewatering, shoes on the shoe rack need not to rub against the central brush, and the shoes are damaged when rotating at a high speed, and the shoe washing machine is realized by adopting the following two ways:

the distance between the shoe rack and the central hairbrush is adjustable, the shoe rack is arranged close to the central hairbrush to enable shoes to be in contact with the central hairbrush during washing, and the shoe rack is arranged far away from the central hairbrush to enable the shoes not to be in contact with the central hairbrush during dewatering;

in a second mode, in a washing state, the shoe rack and the central hairbrush rotate reversely to realize contact friction between the shoes and the central hairbrush, and in a dehydration state, the shoe rack and the central hairbrush rotate at the same speed and the same direction at high speed to realize centrifugal dehydration, so that relative operation between the shoes and the central hairbrush cannot occur.

The first mode has the advantages that no requirements are required on the rotation direction and the rotation speed of the central brush in the dehydration state; the second mode has the advantages of higher automation degree, no need of adjustment operation in the conversion process of the washing state and the dehydration state, and more convenience for users to use.

5. The shoe washing machine can wash and dewater shoes by only arranging one water containing barrel, and the existing washing device generally comprises an inner barrel and an outer barrel, wherein the inner barrel needs to rotate at high speed during dewatering, so that the shoe washing machine is simpler in structure.

In a word, the shoe washing machine has a simpler structure, the inner impeller and the outer impeller rotate in two directions, the washing effect is better, the shoe rack on the outer impeller drives shoes to rotate at a high speed to realize centrifugal dehydration, and the dehydration process is simpler and more convenient, so the shoe washing machine has good market popularization value.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a schematic block diagram of the structure of yet another embodiment of the present invention;

FIG. 3 is a schematic perspective view of the present invention;

FIG. 4 is a partial cross-sectional view of the present invention;

FIG. 5 is an exploded view of the assembly of the inner impeller, the outer impeller and the shoe rack of the present invention;

FIG. 6 is a perspective view of the center brush of the present invention;

FIG. 7 is a perspective view of another embodiment of a center brush according to the present invention;

FIG. 8 is a schematic view of the installation of the bucket wall brush of the present invention;

fig. 9 is an exploded view of the present invention.

Reference numbers in the drawings illustrate: 1-water containing barrel 2-central hairbrush 3-shoe rack 4-barrel wall hairbrush 5-inner impeller 6-outer impeller 7-water outlet 8-sliding mechanism 9-speed reduction clutch 10-input shaft 11-input shaft sleeve 12-direct drive motor 13-shell 14-input shaft sleeve 15-input shaft 16-birotor motor 17-water containing barrel mounting port 201-cylinder 202-central bristle 203-convex step 401-buckle 402-barrel wall bristle 501-inner impeller body 502-inner impeller mounting portion 601-outer impeller body 602-stirring rib 603-mounting port 604-mounting hole 605-water discharge hole 802-steel ball 802-spring 803-retaining ring 804-sliding shield.

Detailed Description

The shoe washing machine of the present invention will be described in detail with reference to the accompanying drawings:

as shown in fig. 1, 2, 3 and 4, the shoe washing machine of the present invention comprises a water tub 1, and an inner pulsator 5 and an outer pulsator 6 respectively disposed inside the water tub 1, wherein the inner pulsator 5 is rotatably disposed at a central position of a bottom of the water tub 1, and the outer pulsator 6 is rotatably disposed at an outer periphery of the inner pulsator 5; the direction of rotation of the outer impeller 6 and the direction of rotation of the inner impeller 5 in the washing state are opposite, the central hairbrush 2 is arranged on the inner impeller 5, and the bucket wall hairbrush 4 is arranged on the inner wall of the water containing bucket 1.

The inside of a water containing barrel 1 of the shoe washing machine is provided with an inner impeller 5 and an outer impeller 6, the inner impeller 5 is provided with a central brush 2, and the inner wall of the water containing barrel 1 is provided with a barrel wall brush 4. When the washing state, interior impeller 5 and outer impeller 6 antiport, interior impeller 5 drives 2 integrative rotations of central brush, and outer impeller drives shoes and 2 antiport of central brush, and central brush 2 can rub the realization washing to the surface of shoes like this, and simultaneously, bucket wall brush 4 can rub the another side of shoes and further improve the washing effect.

As shown in fig. 5, the outer impeller 6 includes an impeller body 601, a through mounting hole 603 is formed in the center of the impeller body 601, the inner impeller 5 is mounted in the mounting hole 603 of the outer impeller 6 and can rotate independently, and the edge of the inner impeller 5 is tightly fitted with the mounting hole 603 of the outer impeller 6.

The inner impeller 5 of the invention is arranged at the central position of the outer impeller 6, so that the central brush 2 arranged on the inner impeller 5 can be contacted with the shoes on the peripheral outer impeller 6, and the central brush 2 can simultaneously wash a plurality of pairs of shoes in a washing state.

The edge of the inner impeller 5 is tightly matched with the mounting opening 603 of the outer impeller 6, so that a small gap is formed between the inner impeller 5 and the outer impeller 6, and the phenomenon that shoes are clamped and damaged in the washing process can be avoided, and the shoe washing machine is damaged more seriously.

Specifically, the pulsator body 601 of the present invention is disposed in a disc shape, the edge of the pulsator body 601 is closely fitted with the inner wall of the water tub 1, and the upper surface of the pulsator body 601 is provided with a plurality of agitating ribs 602 and water discharge holes 605.

The edge of the impeller body 601 of the invention is tightly matched with the inner wall of the water containing barrel 1, thus avoiding the phenomenon of shoe clamping damage in the washing process, and more serious damage to the shoe washing machine. The plurality of stirring ribs 602 are arranged on the upper surface of the impeller body 601, so that shoes in the water containing barrel 1 are stirred by the stirring ribs 602 on the outer impeller 6 in the washing process to roll, so that different parts of the shoes have friction with the central brush 2 and the barrel wall brush 4, the shoes are washed in all directions, and a better washing effect is achieved.

Example one

As shown in fig. 1, 2, 4 and 5, the shoe washing machine of the present embodiment includes a tub 1, and an inner pulsator 5 and an outer pulsator 6 respectively disposed inside the tub 1, the inner pulsator 5 being rotatably disposed at a bottom center position of the tub 1, the outer pulsator 6 being rotatably disposed at an outer periphery of the inner pulsator 5; the direction of rotation of the outer impeller 6 and the direction of rotation of the inner impeller 5 in the washing state are opposite, the central hairbrush 2 is arranged on the inner impeller 5, and the bucket wall hairbrush 4 is arranged on the inner wall of the water containing bucket 1.

In order to further improve the washing effect of the shoe washing machine on shoes, the shoe rack 3 for placing the shoes is detachably arranged on the outer impeller 6, the shoe rack 3 and the outer impeller 6 rotate integrally, the shoe rack 3 is mainly used for supporting the shoes to be placed, so that the shoes are better rubbed by the central hairbrush 2 and the barrel wall hairbrush 4 in a washing state, and the washing effect is improved.

The shoe rack 3 of the present invention is also used to implement a shoe dehydration process, specifically, the following two ways can be adopted:

in the first mode, the distance between the shoe rack and the central brush 2 is adjustable, the shoe rack 3 is arranged close to the central brush 2 to enable the shoes to be in contact with the central brush 2 during washing, and the shoe rack is arranged far from the central brush 2 to enable the shoes not to be in contact with the central brush 2 during dewatering.

The mode has the advantages that no requirement is made on the steering and rotating speed of the central brush 2 in the dehydration state, and the driving device for driving the inner impeller 5 and the outer impeller 6 to move is simpler.

How to realize that the distance between the shoe rack and the central brush 2 is adjustable is a key point of a first realization mode, and the following two modes can be specifically adopted:

(1) as shown in fig. 5, the outer pulsator 6 is provided with a plurality of mounting holes 604 for mounting the shoe rack 3, and the mounting holes 604 are respectively distributed along the radial direction of the outer pulsator 6 so that the distance between the shoe rack 3 and the central brush 2 is adjustable.

In addition, the mounting holes 604 are distributed along the circumferential direction of the outer impeller 6, so that the shoe racks 3 are arranged around the central brush 2, a plurality of shoes can be washed at one time, and the washing efficiency is improved.

(2) As shown in fig. 9, the central brush 2 is detachably mounted on the inner pulsator 5: in a washing state, the central hairbrush 2 is arranged on the inner impeller 5; in the dewatering state, the central brush 2 is detached from the inner impeller 5.

In a second mode, in a washing state, the shoe rack 3 drives the shoes to rotate reversely with the central brush 2 on the inner impeller 5 to realize contact friction; in the dehydration state, the shoe rack 3 drives the shoes to rotate with the central brush 2 in the same direction and at the same speed to realize centrifugal dehydration.

The method has the advantages of higher automation degree, no need of adjustment operation in the conversion process of the washing state and the dehydration state, and more convenient use for users.

Example two

The shoe washing machine of the embodiment comprises a water barrel 1, an inner impeller 5 and an outer impeller 6 which are respectively arranged inside the water barrel 1, wherein the inner impeller 5 is rotatably arranged at the central position of the bottom of the water barrel 1, and the outer impeller 6 is rotatably arranged at the periphery of the inner impeller 5; the direction of rotation of the outer impeller 6 and the direction of rotation of the inner impeller 5 in the washing state are opposite, the central hairbrush 2 is arranged on the inner impeller 5, and the bucket wall hairbrush 4 is arranged on the inner wall of the water containing bucket 1.

As shown in fig. 8, the central brush 2 of the present embodiment is detachably mounted on the inner pulsator 5, and the detachable mounting method mainly has the following advantages:

(1) in a washing state, the central hairbrush 2 is arranged on the inner impeller 5; in the dewatering state, the central brush 2 is detached from the inner impeller 5.

Therefore, the central hairbrush is detached during dehydration, and the central hairbrush 5 is prevented from being damaged by high-speed rotation in the dehydration process.

(2) When the unexpected article of washing except shoes, for example shoe-pad, socks or rag etc. can dismantle central brush 2, realize the washing through the stirring of interior impeller 5, outer impeller 6, prevent that central brush 2 from causing wearing and tearing to shoe-pad, socks or rag etc..

Further, the bucket wall brush 4 is detachably mounted on the inner wall of the water containing bucket 1, specifically, the bucket wall brush 4 is connected in a buckling connection mode, the bucket wall brush 4 comprises a buckle 401 and bucket wall bristles 402, and the inner wall of the water containing bucket 1 is provided with a water containing bucket mounting port 17 for mounting the bucket wall brush 4.

The bucket wall brush 4 adopts the same installation mode as the thread scrap filter on the washing machine, when insoles, socks or rags and the like need to be washed, the bucket wall brush 4 is also detached, and if the conditions exist, the thread scrap filter can be installed.

Therefore, the central brush 3 and the barrel wall brush 4 of the shoe washing machine are detachably mounted, so that the washing function of the shoe washing machine is expanded, more articles except shoes can be washed, and the shoe washing machine is better in practicability.

Specifically, as shown in fig. 8, the central brush 2 of the present embodiment includes a column 201 and a central brush 202, one end of the column 201 is mounted on the inner pulsator 5 through a sliding mechanism 8, and the sliding mechanism 8 is sleeved on the column 201 and can be slidably connected to/detached from the inner pulsator 5.

The sliding mechanism 8 described in this embodiment includes a steel ball 801, a spring 802, a retainer 803, and a sliding shroud 804, the steel ball 801 is disposed on the column 201 of the central brush 2, the retainer 803 is disposed on the column 201 and can block the steel ball 801, the spring 802 is sleeved on the column 201, and the sliding shroud 804 is sleeved on the spring 802 and can slide relative to the column 201; the cylinder 201 is provided with a convex step 203 used for abutting against one end of a spring 802, and the other end of the spring 802 abuts against a sliding shield 804; the inner wave wheel 5 is provided with a clamping groove 503 matched with the sliding shield 804.

The sliding mechanism 8 of the embodiment has simple structure and convenient installation, and is greatly convenient for a user to install/dismantle the central brush 2.

EXAMPLE III

The central brush 2 of this embodiment includes a post 201 and a central brush 202, as shown in fig. 6, the central brush 202 is spirally disposed on the post 201, so that the central brush 202 is disposed to better contact with the upper of the shoe on the shoe rack 3, and the washing effect of the central brush 202 is improved. As shown in FIG. 7, the central bristles 202 are arranged in a large-size manner, so that the central bristles 202 are better contacted with the upper of the shoe, and the washing effect of the central bristles 202 is improved.

Example four

As shown in fig. 1, the shoe washing machine of the present embodiment comprises a water tub 1, and an inner pulsator 5 and an outer pulsator 6 respectively disposed inside the water tub 1, wherein the inner pulsator 5 is rotatably disposed at a central position of a bottom of the water tub 1, and the outer pulsator 6 is rotatably disposed at an outer periphery of the inner pulsator 5; the outer impeller 6 and the inner impeller 5 are opposite in rotation direction in the washing state, and the outer impeller 6 and the inner impeller 5 rotate in the same speed and the same direction in the dehydration state; the inner impeller 5 is provided with a central brush 2, and the inner wall of the water containing barrel 1 is provided with a barrel wall brush 4.

In order to realize the rotation mode of the outer impeller 6 and the inner impeller 5, the shoe washing machine of the embodiment comprises a driving device, the driving device is arranged outside the bottom wall of the water containing barrel 1, the driving device comprises an output shaft 15 and an output shaft sleeve 14 sleeved on the output shaft 15, the output shaft 15 and the output shaft sleeve 14 penetrate through the bottom wall of the water containing barrel 1 and are sealed with the water containing barrel, the output shaft 15 is connected with the inner impeller 5, and the output shaft sleeve 14 is connected with the outer impeller 6; the output shaft 15 and the output shaft sleeve 14 rotate in opposite directions in a washing state and rotate in the same speed and direction in a dehydration state.

Further, the driving device further comprises a driving motor, the driving motor is a direct-drive motor 12, one end of the output shaft 15 and one end of the output shaft sleeve 14 are respectively connected with the output end of the speed reduction clutch 9, and the input end of the speed reduction clutch 9 is connected with the direct-drive motor 12 through a transmission shaft: in a washing state, the power of the direct drive motor 12 is distributed into two power with opposite rotation directions through the speed reduction clutch 9 in a speed reduction way, and the two power are respectively transmitted to the output shaft sleeve 14 and the output shaft 15, so that the outer impeller 6 and the inner impeller 5 are respectively driven to rotate reversely to realize washing; in a dehydration state, the power of the direct drive motor 12 is distributed into two power with the same rotation speed and the same steering direction through the speed reduction clutch 9 and is respectively transmitted to the output shaft sleeve 14 and the output shaft 15, and then the outer impeller 6 and the inner impeller 5 are respectively driven to rotate in the same direction and the same speed to realize dehydration.

The direct drive motor 12 of the present embodiment is connected to the input end of the speed reduction clutch 9 through the input shaft 10 and the input shaft sleeve 11, the driving device of the present invention is disposed outside the bottom wall of the tub 1 and in the housing 13, and the housing 13 is connected to the tub 1.

In the embodiment, the existing direct drive motor 12 is adopted to realize bidirectional power output through the speed reduction clutch device 9, and the speed reduction clutch device 9 can distribute the rotating speeds of the output shaft 15 and the output shaft sleeve 14, so that the shoe washing machine is more suitable for the washing and dehydration states of the shoe washing machine and is easier to realize.

EXAMPLE five

As shown in fig. 2, the present embodiment is different from the fourth embodiment in that: the driving motor is a double-rotor motor 16, one end of the output shaft 15 and one end of the output shaft sleeve 14 are respectively connected with two rotor output ends of the double-rotor motor 16, and washing and dewatering are achieved by controlling the rotating speed and the rotating direction of two rotors of the double-rotor motor 16.

The dual-rotor motor 16 of this embodiment has two rotors, each of the two rotors has two output ends, the output shaft 15 and the output shaft sleeve 14 are respectively connected to the output ends of the two rotors, and the rotation speed of the two rotors can be controlled, so as to control the rotation speed and the rotation direction of the output shaft 15 and the output shaft sleeve 14.

The shoe washing machine of the embodiment has simpler structure and more convenient installation.

EXAMPLE six

The present embodiment is different from the fourth embodiment in that: the driving motor is a belt pulley motor, the belt pulley motor is connected with a belt pulley through a belt, the belt pulley is connected with the input shaft, and the input shaft sleeve is sleeved on the input shaft.

In the embodiment, the belt pulley motor is used as the driving motor, and the power of the belt pulley motor is respectively output to the output shaft and the output shaft sleeve through the conventional speed reduction clutch, so that the power output requirement of the shoe washing machine is met, therefore, the shoe washing machine greatly reduces the manufacturing cost and has wide market popularization value. Although the present invention has been described with reference to a preferred embodiment, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims

1. The shoe washing machine is characterized by comprising a water containing barrel (1), an inner impeller (5) and an outer impeller (6) which are respectively arranged in the water containing barrel (1), wherein the inner impeller (5) is rotatably arranged at the central position of the bottom of the water containing barrel (1), and the outer impeller (6) is rotatably arranged at the periphery of the inner impeller (5); the outer impeller (6) and the inner impeller (5) are opposite in rotation direction in a washing state, a central brush (2) is arranged on the inner impeller (5), and a bucket wall brush (4) is arranged on the inner wall of the water bucket (1);

outer impeller (6) on the detachable installation be used for placing shoe rack (3) of shoes, shoe rack (3) and outer impeller (6) an organic whole rotate: in a washing state, the shoe rack (3) drives the shoes to rotate reversely with the central brush (2) on the inner impeller (5) to realize contact friction; in a dehydration state, the shoe rack (3) drives the shoes and the central brush (2) to rotate in the same direction and at the same speed to realize centrifugal dehydration;

the outer impeller (6) is provided with a plurality of mounting holes (604) for mounting the shoe rack (3), and the mounting holes (604) are respectively distributed along the radial direction of the outer impeller (6) to enable the distance between the shoe rack (3) and the central brush (2) to be adjustable.

2. The shoe washing machine according to claim 1, characterized in that the outer impeller (6) comprises an impeller body (601), a mounting opening (603) is formed in the center of the impeller body (601), and the inner impeller (5) is mounted in the mounting opening (603) of the outer impeller (6) and can rotate independently.

3. The shoe washing machine according to claim 2, wherein the pulsator body (601) is disposed in a disk shape, and a plurality of agitating ribs (602) and water discharge holes (605) are provided on an upper surface of the pulsator body (601).

4. The shoe washing machine according to claim 1, characterized in that the central brush (2) is removably mounted on the inner pulsator (5): in a washing state, the central hairbrush (2) is arranged on the inner impeller (5); in the dewatering state, the central hairbrush (2) is detached from the inner impeller (5).

5. The shoe washing machine according to claim 4, characterized in that the central brush (2) comprises a cylinder (201) and central bristles (202), one end of the cylinder (201) is mounted on the inner pulsator (5) through a sliding mechanism (8), and the sliding mechanism (8) is sleeved on the cylinder (201) and can be connected/detached with the inner pulsator (5) in a sliding manner.

6. The shoe washing machine according to claim 5, characterized in that the sliding mechanism (8) comprises a steel ball (801), a spring (802), a retainer ring (803) and a sliding shield (804), the steel ball (801) is arranged on the cylinder (201) of the central brush (2), the retainer ring (803) is arranged on the cylinder (201) and can block the steel ball (801), the spring (802) is sleeved on the cylinder (201), and the sliding shield (804) is sleeved on the spring (802) and can slide relative to the cylinder (201); the cylinder (201) is provided with a convex step (203) used for abutting against one end of the spring (802), and the other end of the spring (802) abuts against the sliding shield (804); the inner impeller (5) is provided with a clamping groove (503) which is used for being matched with the sliding shield (804).

7. The shoe washing machine according to claim 1, further comprising a driving device disposed outside the bottom wall of the water tub (1), the driving device comprising an output shaft (15) and an output shaft sleeve (14) fitted over the output shaft (15), the output shaft (15) and the output shaft sleeve (14) penetrating through and sealing with the bottom wall of the water tub (1), the output shaft (15) being connected to the inner pulsator (5), the output shaft sleeve (14) being connected to the outer pulsator (6); the output shaft (15) and the output shaft sleeve (14) rotate in opposite directions in a washing state and rotate in the same speed and direction in a dehydration state.

8. The shoe washing machine according to claim 7, characterized in that the driving device further comprises a driving motor, the driving motor is a direct drive motor (12), one end of the output shaft (15) and one end of the output shaft sleeve (14) are respectively connected with the output end of the speed reduction clutch (9), the input end of the speed reduction clutch (9) is connected with the direct drive motor (12) through a transmission shaft: in a washing state, the power of the direct drive motor (12) is distributed into two power with opposite rotation directions through a speed reduction clutch (9) in a speed reduction way and is respectively transmitted to an output shaft sleeve (14) and an output shaft (15), and then the outer impeller (6) and the inner impeller (5) are respectively driven to rotate reversely to realize washing; in a dehydration state, the power of the direct drive motor (12) is distributed into two power with the same rotation direction and the same rotation speed through a speed reduction clutch (9) and is respectively transmitted to an output shaft sleeve (14) and an output shaft (15), and then the outer impeller (6) and the inner impeller (5) are respectively driven to rotate in the same speed and the same direction to realize dehydration;

or the driving motor is a double-rotor motor (16), one end of the output shaft (15) and one end of the output shaft sleeve (14) are respectively connected with two rotor output ends of the double-rotor motor (16), and washing and dewatering are realized by controlling the rotating speed and the rotating direction of two rotors of the double-rotor motor (16).