CN209847119U - Shoe-cleaning machine - Google Patents

Abstract

A shoe polisher comprises a rear wiping system (100) for wiping the rear of a shoe and a front wiping system (200) for wiping the front and/or sides of the shoe, the rear wiping system (100) and the front wiping system (200) being slidably arranged relative to each other. The utility model discloses a shoe-cleaning machine cleans system and preceding system of cleaning through setting up the back to make both slidable relatively, thereby realize that shoe-cleaning machine can be applicable to the work of cleaning of the shoes of different sizes. And the stable rotation of each brush is realized by innovating the transmission structure and the relative position of each brush. The utility model has the advantages of ingenious design and strong practicability.

Description

Shoe-cleaning machine

Technical Field

The utility model relates to a life service equipment field especially relates to a shoe-cleaning machine.

Background

Shoe-cleaning machines, also known as automatic shoe-cleaning machines, fully automatic shoe-cleaning machines, inductive shoe-cleaning machines. With the rapid development of society and the continuous improvement of living standard, people have higher and higher requirements on the appearance of clothes. The leather shoes are bright, not only reflect the spiritual appearance of people, but also reflect the quality maintenance of people. The shoe can not be wiped away when wearing the shoe. Therefore, the full-automatic shoe polisher for solving the service has wide market potential. With the pace of modern work and life, people have no time to waste on holding the shoe brush with hands and brushing the oil, and the manual shoe polishing is time-consuming and labor-consuming.

In the prior various shoe polishing machines, a brush or felt which is relatively fixed in position is mostly adopted to roll to polish shoes, such as patent ZL201620321800.8, however, shoes have various sizes, and the prior shoe polishing machines are difficult to be suitable for shoes with different sizes.

SUMMERY OF THE UTILITY MODEL

The utility model provides a to above-mentioned technical problem, a shoe-cleaning machine is proposed.

The utility model provides a technical scheme as follows:

the utility model provides a shoe polisher, which comprises a rear wiping system for wiping the rear part of a shoe and a front wiping system for wiping the front part of the shoe and/or the side part of the shoe, wherein the rear wiping system and the front wiping system can be arranged in a relatively sliding way;

the front wiping system comprises a rack, a first brush and a second brush which are respectively and rotatably arranged on the rack, wherein the first brush and the second brush are oppositely arranged and are used for cooperatively wiping two side parts of shoes;

the front wiping system also comprises a third brush which is rotatably arranged on the rack, is positioned above the first brush and the second brush and is used for wiping the top surface of the front part of the shoe;

the front wiping system also comprises a driving system which is arranged on the frame and is used for driving the first brush, the second brush and the third brush to synchronously rotate.

In the above shoe polisher of the present invention, the shoe polisher includes a base, the rear wiping system is fixedly installed on the base, and the front wiping system is slidably installed on the base.

In the shoe polisher of the present invention, the shoe polisher further comprises a slide rail disposed on the base and a slide block slidably disposed on the slide rail; the front wiping system is fixedly mounted on the slider.

In the above shoe polisher of the present invention, the shoe polisher further comprises a linear actuator for driving the front wiping system to slide on the slide rail.

In the shoe polisher of the present invention, the driving system comprises a first brush motor fixedly disposed on the frame and a driven shaft horizontally and rotatably disposed on the frame; the first brush, the second brush and the third brush are all horizontally arranged;

the output shaft of the first brush motor is in transmission connection with the driven shaft, and the driven shaft is in transmission connection with the first brush, the second brush and the third brush respectively.

In the above shoe polisher of the present invention, the frame comprises a bottom plate, a first side plate and a second side plate parallel to each other are formed on the bottom plate in a protruding manner, the first brush is horizontally and rotatably disposed on the first side plate, and the second brush is horizontally and rotatably disposed on the second side plate; the third brush is horizontally and rotatably arranged on the second side plate;

the driven shaft is respectively and rotatably arranged on the first side plate and the second side plate, and an output shaft of the first brush motor is in transmission connection with the driven shaft through a first belt; the driven shaft is in transmission connection with the second hairbrush and the third hairbrush through a second belt; the driven shaft is in transmission connection with the first hairbrush through a third belt.

In the shoe polisher of the utility model, two second brushes are arranged; the projections of the third brush axial direction, the driven shaft axial direction and the two second brush axial directions on the second side plate are four vertexes of a concave quadrilateral.

In the shoe polisher of the present invention, the rear polishing system comprises a fourth brush and a second brush motor fixedly disposed on the base for driving the fourth brush to rotate;

the base is provided with a step, the fourth brush is rotatably arranged on the step, and an output shaft of the second brush motor is connected with a shaft of the fourth brush through a coupler.

In the above shoe polisher of the present invention, the shoe polisher further comprises a shoe polish supply system for supplying shoe polish to the third brush.

In the above shoe polisher of the present invention, the shoe polish supply system comprises an oil can disposed on the base for storing shoe polish and an oil pump for pumping the shoe polish in the oil can and spraying the shoe polish on the third brush;

the shoe polisher also includes a foot pedal disposed on the base and between the first brush and the second brush.

The utility model discloses a shoe-cleaning machine cleans system and preceding system of cleaning through setting up the back to make both slidable relatively, thereby realize that shoe-cleaning machine can be applicable to the work of cleaning of the shoes of different sizes. And the stable rotation of each brush is realized by innovating the transmission structure and the relative position of each brush. The utility model has the advantages of ingenious design and strong practicability.

Drawings

The invention will be further explained with reference to the drawings and examples, wherein:

FIG. 1 is a schematic view showing a structure of a shoe polisher according to a preferred embodiment of the present invention;

FIG. 2 is a reference view illustrating a state of use of the shoe polisher shown in FIG. 1;

FIG. 3 is a schematic view showing the construction of a base of the shoe polisher shown in FIG. 1;

FIG. 4 illustrates a schematic connection diagram of the front wiping system and the linear actuator of the shoe polisher shown in FIG. 1;

FIG. 5 is a schematic view showing the construction of a front wiping system of the shoe polisher shown in FIG. 1;

FIG. 6 is a schematic view of the rear wiping system of the shoe polisher shown in FIG. 1;

fig. 7 is a schematic view illustrating the construction of a shoe polish supply system of the shoe polisher shown in fig. 1.

Detailed Description

The utility model discloses the technical problem that will solve is: shoes have various sizes, and the existing shoe polisher is difficult to be suitable for shoes with different sizes. The utility model discloses the technical thinking that just this technical problem provided is: a shoe polisher is constructed in such a manner that a structure of a front part of a shoe and a structure of a rear part of the shoe are designed to be relatively slidable, thereby enabling the shoe polisher to be adapted to the polishing work of shoes of different sizes.

In order to make the technical purpose, technical solution and technical effects of the present invention more clear so as to facilitate those skilled in the art to understand and implement the present invention, the present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

As shown in fig. 1 and 2, fig. 1 is a schematic view showing a structure of a shoe polisher according to a preferred embodiment of the present invention; fig. 2 is a reference view illustrating a state in which the shoe polisher shown in fig. 1 is used. The shoe polisher comprises a rear wiping system 100 for wiping the rear of a shoe and a front wiping system 200 for wiping the front and/or sides of the shoe, the rear wiping system 100 and the front wiping system 200 being slidably arranged relative to each other. Therefore, the relative position between the rear wiping system and the front wiping system can be adjusted according to the size of the shoes, so that the shoe polisher can be suitable for wiping shoes with different sizes.

Further, in the present embodiment, as shown in fig. 1, the shoe polisher includes a base 300, the rear wiping system 100 is fixedly installed on the base 300, and the front wiping system 200 is relatively slidably disposed on the base 300. In this way, a relatively slidable arrangement of the rear wiping system 100 and the front wiping system 200 is achieved. It is understood that in other embodiments, the front wiping system 200 can be fixedly mounted on the base 300 and the rear wiping system 100 can be slidably disposed on the base 300, and thus the aforementioned objects can be achieved. Here, the base 300 may be a plate, a block, a profile plate, or an integrally formed or detachable combination structure of the plate and/or the block and/or the profile plate, etc.

Further, in the present embodiment, as shown in fig. 3, fig. 3 shows a schematic structural view of a base 300 of the shoe polisher shown in fig. 1. The shoe polisher further comprises a slide rail 310 disposed on the base 300 and a slider 320 slidably disposed on the slide rail 310; the front wiping system 200 is fixedly mounted on the slider 320, thereby achieving a relative sliding arrangement of the front wiping system 200 and the base 300. Here, the slide rail 310 may be provided in one or more pieces. As shown in fig. 3, in the present embodiment, there are two slide rails 310, and the two slide rails 310 are arranged in parallel, and each slide rail 310 is provided with two sliders 320; the two sliders 320 on each slide rail 310 are arranged at intervals, so that the four sliders 320 correspond to four corners of the front wiping system 200 respectively, and the front wiping system 200 is fixedly connected with the four sliders 320 respectively, so that the front wiping system 200 can slide on the slide rail 310 smoothly. It is understood that in other embodiments, the number of the sliders 320 on each sliding rail 310 may be 1, or may be more than two.

Further, as shown in fig. 4, fig. 4 shows a schematic connection diagram of the front wiping system 200 and the linear actuator 400 of the shoe polisher shown in fig. 1. The shoe polisher further includes a linear actuator 400 for driving the front wiping system 200 to slide on the slide rail 310. The driving motor 410 of the linear actuator 400 is fixedly installed on the base 300, and the push rod 420 of the linear actuator 400 is fixedly connected to the front wiping system 200.

Further, as shown in fig. 4 and 5, fig. 5 shows a schematic view of the front wiping system 200 of the shoe polisher shown in fig. 1. The front wiping system 200 includes a frame 210, and a first brush 214 and a second brush 215 rotatably disposed on the frame 210, respectively, wherein the first brush 214 and the second brush 215 are disposed opposite to each other for cooperatively wiping two sides of a shoe. Specifically, in the present embodiment, the frame 210 includes a bottom plate 211, a first side plate 212 and a second side plate 213 protruding from the bottom plate 211 and parallel to each other, a first brush 214 horizontally and rotatably disposed on the first side plate 212, and a second brush 215 horizontally and rotatably disposed on the second side plate 213. Meanwhile, the bottom plate 211 is fixedly connected with the slider 320, wherein the bottom plate 211 is fixedly connected with the slider 320 through screws or pins or adhesive glue; the push rod 420 of the linear actuator 400 may be fixedly connected to the bottom plate 211 or the first side plate 212 or the second side plate 213 for the purpose of pushing the front wiping system 200. In addition, the first side plate 212 and the second side plate 213 may not be arranged in parallel, and the first brush 214 and the second brush 215 may be arranged horizontally by axially arranging the limiting holes for limiting the first brush 214 and the second brush 215 in a horizontal direction; all designs that can horizontally arrange the first and second brushes 214 and 215 are within the scope of the present application.

Further, as shown in fig. 4 and 5, the front wiping system 200 further includes a third brush 216 horizontally rotatably disposed on the frame 210 above the first and second brushes 214 and 215 for wiping the top surface of the front portion of the shoe. Specifically, in the present embodiment, the third brush 216 is rotatably provided on the second side plate 213.

Further, as shown in fig. 4 and 5, in the present embodiment, the front wiping system 200 further includes a driving system 220 mounted on the frame 210 for driving the first brush 214, the second brush 215 and the third brush 216 to rotate synchronously. Specifically, in the present embodiment, the driving system 220 includes a first brush motor 221 fixedly disposed on the frame 210 and a driven shaft 222 horizontally rotatably disposed on the frame 210; the output shaft of the first brush motor 221 is in transmission connection with the driven shaft 222, and the driven shaft 222 is in transmission connection with the first brush 214, the second brush 215 and the third brush 216 respectively. In this way, synchronous movement of the first brush 214, the second brush 215, and the third brush 216 is achieved. Specifically, in the present embodiment, the first brush motor 221 is fixedly installed on the bottom plate 211, the driven shafts 222 are respectively and rotatably disposed on the first side plate 212 and the second side plate 213, and the output shaft of the first brush motor 221 is in transmission connection with the driven shafts 222 through the first belt 223; the driven shaft 222 is in transmission connection with the second brush 215 and the third brush 216 through a second belt 224; the driven shaft 222 is in transmission connection with the first brush 214 through a third belt (not shown). Here, in order to make the sliding between the driven shaft 222 and the first and second side plates 212 and 213, respectively, bearings are provided between the driven shaft 222 and the first side plate 212, and between the driven shaft 222 and the second side plate 213. Further, in the present embodiment, two first brushes 214 and two second brushes 215 are provided. The projections of the third brush 216, the driven shaft 222, and the two second brushes 215 on the second side plate 213 in the axial direction are four vertexes of a concave quadrilateral. In this way, the transmission between the driven shaft 222, the third brush 216, and the two second brushes 215 can be more smooth. Based on the same principle, the projections of the axial direction of the driven shaft 222 and the axial direction of the two first brushes 214 on the first side plate 212 are three vertexes of a triangle, so that the transmission of the axial direction of the driven shaft 222 and the axial direction of the two first brushes 214 is more stable.

Further, as shown in fig. 6, fig. 6 shows a schematic view of the rear wiping system 100 of the shoe polisher shown in fig. 1. The rear wiping system 100 includes a fourth brush 110 and a second brush motor 120 fixedly disposed on the base 300 for driving the fourth brush 110 to rotate. In this embodiment, a step 330 is formed on the base 300, the fourth brush 110 is rotatably disposed on the step 330, and an output shaft of the second brush motor 120 is connected to a shaft of the fourth brush 110 through a coupling (not shown) to drive the fourth brush 110 to rotate. In the present embodiment, there are two fourth brushes 110.

Further, as shown in fig. 7, fig. 7 is a schematic view illustrating a structure of the shoe polish supplying system 500 of the shoe polisher shown in fig. 1. The shoe polisher further includes a shoe polish supply system 500 for supplying shoe polish to the third brush 216; the shoe polish supplying system 500 includes an oil container 510 provided on the base 300 for storing the shoe polish, and an oil pump 520 for pumping the shoe polish in the oil container 510 and spraying it on the third brush 216. It is understood that in other embodiments, the shoe polish supply system 500 may also use a drip to drip the shoe polish onto the third brush 216.

Further, as shown in fig. 1 and 2, the shoe polisher further includes a foot pedal 600 disposed on the base 300 and between the first and second brushes 214 and 215. The foot pedal 600 also serves as a starting means for the driving motor 410, the first brush motor 221, and the second brush motor 120 of the linear actuator 400. Specifically, the foot pedal 600 may be activated by a mechanical activation (e.g., a circuit breaker) or an electronic activation (e.g., a force sensor) to activate the drive motor 410, the first brush motor 221, and the second brush motor 120. When the shoe is supported on the foot rest 600, each motor can be operated to drive each corresponding driven member to effect wiping of each side of the shoe.

The utility model discloses a shoe-cleaning machine cleans system and preceding system of cleaning through setting up the back to make both slidable relatively, thereby realize that shoe-cleaning machine can be applicable to the work of cleaning of the shoes of different sizes. And the stable rotation of each brush is realized by innovating the transmission structure and the relative position of each brush. The utility model has the advantages of ingenious design and strong practicability.

It will be understood that modifications and variations can be made by persons skilled in the art in light of the above teachings and all such modifications and variations are considered to be within the scope of the invention as defined by the following claims.

Claims (7)

1. A shoe polisher characterized by comprising a rear wiping system (100) for wiping the rear of a shoe, a front wiping system (200) for wiping the front of a shoe and/or the sides of a shoe, and a base (300) on which the rear wiping system (100) and the front wiping system (200) are mounted, the rear wiping system (100) being fixedly mounted on the base (300), the front wiping system (200) being relatively slidably disposed on the base (300);

the base (300) comprises a slide rail (310) and a slide block (320) which is arranged on the slide rail (310) in a sliding way;

the front wiping system (200) is fixedly arranged on the sliding block (320); the shoe polisher further comprises a linear driver (400) for driving the front wiping system (200) to slide on the slide rail (310);

the front wiping system (200) comprises a rack (210), a first brush (214) and a second brush (215) which are respectively and rotatably arranged on the rack (210), wherein the first brush (214) and the second brush (215) are oppositely arranged and are used for cooperatively wiping two side parts of shoes;

the front wiping system (200) further comprises a third brush (216) rotatably arranged on the frame (210) and positioned above the first brush (214) and the second brush (215) and used for wiping the top surface of the front part of the shoe;

the front wiping system (200) also comprises a driving system (220) which is arranged on the frame (210) and is used for driving the first brush (214), the second brush (215) and the third brush (216) to synchronously rotate; the driving system (220) comprises a first brush motor (221) fixedly arranged on the rack (210) and a driven shaft (222) horizontally and rotatably arranged on the rack (210); an output shaft of the first brush motor (221) is in transmission connection with a driven shaft (222), and the driven shaft (222) is in transmission connection with the first brush (214), the second brush (215) and the third brush (216) respectively.

2. The shoe polisher according to claim 1, wherein the first brush (214), the second brush (215), and the third brush (216) are horizontally disposed.

3. The shoe polisher according to claim 2, wherein the frame (210) comprises a bottom plate (211), the bottom plate (211) has a first side plate (212) and a second side plate (213) protruding therefrom, the first brush (214) is horizontally rotatably disposed on the first side plate (212), and the second brush (215) is horizontally rotatably disposed on the second side plate (213); the third brush (216) is horizontally and rotatably arranged on the second side plate (213);

the driven shaft (222) is respectively and rotatably arranged on the first side plate (212) and the second side plate (213), and an output shaft of the first brush motor (221) is in transmission connection with the driven shaft (222) through a first belt (223); the driven shaft (222) is in transmission connection with the second brush (215) and the third brush (216) through a second belt (224); the driven shaft (222) is in transmission connection with the first brush (214) through a third belt.

4. A shoe polisher according to claim 3 wherein there are two second brushes (215); the projections of the axial direction of the third brush (216), the axial direction of the driven shaft (222) and the axial direction of the two second brushes (215) on the second side plate (213) are four vertexes of a concave quadrilateral.

5. The shoe polisher according to claim 1, wherein the rear wiping system (100) comprises a fourth brush (110) and a second brush motor (120) fixedly disposed on the base (300) for driving the fourth brush (110) to rotate;

a step (330) is formed on the base (300), the fourth brush (110) is rotatably arranged on the step (330), and an output shaft of the second brush motor (120) is connected with a shaft of the fourth brush (110) through a shaft coupling.

6. A shoe polisher according to claim 3 further comprising a shoe polish supply system (500) for supplying shoe polish to the third brush (216).

7. The shoe polisher according to claim 6, wherein the shoe polish supply system (500) comprises an oil pot (510) provided on the base (300) for storing the shoe polish and an oil pump (520) for sucking the shoe polish in the oil pot (510) and spraying it on the third brush (216);

the shoe polisher further includes a foot pedal (600) disposed on the base (300) and between the first brush (214) and the second brush (215).