JP7017203B2 - Shoe cleaning equipment - Google Patents

Description

The present invention relates to a shoe washing device.

In the shoe washer disclosed in Patent Document 1 below, a rotation shaft extending up and down is rotatably provided at the center of the bottom of the inner tank arranged in the outer tank. A circular yok, a so-called pulsator, is integrally provided at the lower part of the rotating shaft. On the peripheral side surface of the rotating shaft, a main brush that projects laterally to near the inner surface of the inner tank is provided vertically, and an auxiliary brush that projects upward is provided on the yok. When the rotation shaft is inverted while the water is supplied to the inner tank and the shoe is inserted between the rotation shaft and the inner surface of the inner tank, the shoe is washed by being rubbed by the main brush and the auxiliary brush.

Jitsukaisho 62-120956

In a shoe cleaning device that cleans shoes using a cleaning liquid such as water as in Patent Document 1, improvement in water saving performance is required.

The present invention has been made under such a background, and an object of the present invention is to provide a shoe washing device capable of improving water saving performance.

The present invention is closed from the lower side by a first bottom surface portion that is recessed downward and has a recess having an outlet at the bottom, and a second bottom surface portion that extends laterally from the upper end of the recess, and stores shoes. A storage chamber, an injection port for injecting cleaning liquid onto shoes in the storage chamber, and a filter arranged at the outlet in the recess to capture foreign matter from the cleaning liquid flowing out of the storage chamber from the outlet. It is composed of a pump for sending the cleaning liquid that has passed through the filter and has flowed out of the storage chamber to at least the injection port, and a flat flat heater that is flat up and down. It is a shoe washing apparatus including a heater arranged at a distant position and a heater cover arranged in the recess and covering the heater from above.

Further, in the present invention, the second bottom surface portion is inclined so as to descend toward the recess, and the bottom of the recess is provided with an inclined surface portion descending toward the outlet, and the upper surface of the heater is provided. The portion is arranged so as to be substantially flush with the inclined surface portion, and the inlet of water supplied to the storage chamber is arranged in the recess at a position farther from the outlet than the heater. It is characterized by.

Further, the present invention is characterized in that the heater cover is formed with a plurality of through holes penetrating the heater cover up and down.

Further, the present invention is characterized in that the upper surface portion of the heater cover is arranged at substantially the same height as the second bottom surface portion.

According to the present invention, in the shoe washing device, the shoes in the storage room are washed by the washing liquid sprayed from the injection port. The cleaning liquid is repeatedly sprayed onto the shoes in the storage chamber by being pumped to the injection port after flowing out of the storage chamber from the outlet. As a result, shoes can be washed with a small amount of washing liquid, so that water saving performance can be improved.
In the shoe cleaning device, the filter captures foreign matter from the cleaning liquid flowing out of the storage chamber from the outlet, and the heater located at a position away from the outlet from the filter heats the cleaning liquid. Shoes can be effectively washed with a cleaning solution that has been heated to remove foreign matter.
The storage chamber is closed from the lower side by a first bottom surface portion that is recessed downward and has a recess having the outlet at the bottom, and a second bottom surface portion that extends laterally from the upper end of the recess, and the second bottom surface is formed. The portion is located higher than the bottom of the recess. A filter, a heater, and a heater cover covering the heater from above are arranged in the recess. Since the heater is formed of a flat heater and is flat in the vertical direction, the heater and the heater cover can be arranged so as not to protrude upward from the recess.
In the configuration in which the filter, the heater and the heater cover are arranged in the recess of the first bottom surface portion and the second bottom surface portion is raised in this way, the second bottom surface portion is at the same height position as the bottom of the recessed portion. Since the required amount of cleaning liquid can be reduced, water saving performance can be improved.

Further, according to the present invention, since the second bottom surface portion is inclined so as to descend toward the concave portion, foreign matter such as gravel removed from the shoe can be guided to the concave portion along the inclination of the second bottom surface portion. can. Since the bottom of the recess is provided with an inclined surface portion that descends toward the outlet, foreign matter in the recess can be guided to the outlet along the inclined surface portion and captured by a filter. In the recess, the heater and the inflow port are arranged so as to be close to the outflow port in this order, and the upper surface portion of the heater is arranged so as to be substantially flush with the inclined surface portion. In this case, the water flowing in from the inflow port at the time of supplying water for the cleaning liquid flows down on the inclined surface portion and passes through the upper surface portion of the heater at that time. As a result, in addition to the water supply, foreign matter on the inclined surface portion and foreign matter adhering to the upper surface portion of the heater can be placed on the water and guided to the outlet, and can be captured by the filter. Therefore, it is not necessary to add water only for removing foreign matter from the inclined surface portion or the upper surface portion of the heater, so that the water saving performance can be improved.

Further, according to the present invention, since a plurality of through holes are formed in the heater cover that covers the heater from above, the cleaning liquid can be poured from the through holes to the heater. As a result, the cleaning liquid can be effectively heated by the heater, and foreign matter adhering to the upper surface of the heater can be effectively removed by the force of the cleaning liquid flowing down from the through hole.

Further, according to the present invention, since the upper surface portion of the heater cover is arranged at substantially the same height as the second bottom surface portion, the upper surface portion and the second bottom surface portion of the heater cover can be cleaned together at the time of maintenance.

FIG. 1 is a plan view of a shoe washing device according to an embodiment of the present invention. FIG. 2 is a cross-sectional view taken along the line AA of FIG. FIG. 3 is a cross-sectional view taken along the line BB of FIG. FIG. 4 is a cross-sectional view taken along the line CC of FIG. FIG. 5A is a cross-sectional view taken along the line DD of FIG. FIG. 5B is a bottom view of the shoe washing device. FIG. 5C is a cross-sectional view taken along the line GG of FIG. 5B. FIG. 5D is a rear view of the shoe washing device.

Hereinafter, embodiments of the present invention will be specifically described with reference to the drawings. FIG. 1 is a plan view of a shoe washing device 1 according to an embodiment of the present invention. In the following, the vertical direction in FIG. 1 is referred to as the left-right direction X of the shoe cleaning device 1, the left-right direction in FIG. 1 is referred to as the front-back direction Y of the shoe cleaning device 1, and the direction orthogonal to the paper surface of FIG. 1 is referred to as the shoe cleaning device 1. It is called the vertical direction Z of. The left-right direction X includes a left side X1 corresponding to the upper side of FIG. 1 and a right side X2 corresponding to the lower side of FIG. The front-back direction Y includes a front side Y1 corresponding to the left side of FIG. 1 and a rear side Y2 corresponding to the right side of FIG. The vertical direction Z includes an upper side Z1 corresponding to the front side on the paper surface of FIG. 1 and a lower side Z2 corresponding to the back side on the paper surface of FIG. The left-right direction X and the front-back direction Y are included in the horizontal direction, more specifically in the horizontal direction, and the vertical direction Z is the same as the vertical direction, in other words, the height direction of the shoe cleaning device 1.

The shoe washing device 1 is incorporated in, for example, a hollow table (not shown) on which a washing machine for clothes is placed. The shoe washing device 1 includes a box-shaped frame 2 forming an outer shell thereof and a main body 3. The frame 2 includes, for example, a metal top plate 2A, a left side plate 2B, and a right side plate 2C, and is fixed to the above-mentioned base (not shown) by a fastening member such as a bolt. The top plate 2A is erected between the upper end edges of the left side plate 2B and the right side plate 2C. The frame 2 has an internal space 2D that is closed from the upper side Z1 by the top plate 2A and closed from both sides in the left-right direction X by the left side plate 2B and the right side plate 2C. The internal space 2D is opened to at least the front side Y1.

The main body 3 includes a door 4 and a cleaning tank 5, and is slidably supported in the front-rear direction Y by a frame 2. The main body 3 in FIG. 1 is in the accommodation position, and in the main body 3 in the accommodation position, the cleaning tank 5 is accommodated in the internal space 2D of the frame 2. The door 4 is formed in a plate shape having a plate thickness direction corresponding to the front-rear direction Y, and is arranged on the front side Y1 of the frame 2. In the left-right direction X, the door 4 is larger than the frame 2, and both ends of the door 4 are arranged so as to project outward from the frame 2. An exhaust port 4A, a recess 4B, and an operation unit 4C are provided on the upper end surface of the door 4 in this order, for example, from the left side X1. The exhaust port 4A is in a state of communicating with the cleaning tank 5 via an exhaust duct (not shown) formed in the door 4, and the air in the cleaning tank 5 is introduced from the exhaust port 4A to the shoe cleaning device 1. It is discharged to the outside. The user can grab the door 4 by hooking his finger on the recess 4B and slide the main body 3 in the front-rear direction Y. The operation unit 4C is composed of, for example, a plurality of buttons and is operated by the user for the operation of the shoe washing device 1. The operation unit 4C may include, for example, a liquid crystal display unit.

FIG. 2 is a cross-sectional view taken along the line AA of FIG. FIG. 3 is a cross-sectional view taken along the line BB of FIG. With reference mainly to FIG. 2, the cleaning tank 5 is a resin or metal container that is one size smaller than the frame 2, is arranged on the rear side Y2 of the door 4, and is fixed to the door 4. The cleaning tank 5 integrally includes a front wall 6, a rear wall 7, a left wall 8, a right wall 9 (see FIG. 3), and a bottom wall 10. The front wall 6 and the rear wall 7 are formed in a plate shape having a plate thickness direction substantially coincided with the front-rear direction Y, and are arranged to face each other in the front-rear direction Y at intervals. The left wall 8 and the right wall 9 are formed in a plate shape having a plate thickness direction substantially coincided with the left-right direction X, and are arranged to face each other at intervals in the left-right direction X. The bottom wall 10 is formed in a plate shape having a plate thickness direction substantially coincided with the front-rear direction Y, is erected between the lower end edges of the front wall 6 and the rear wall 7, and is installed between the lower end edges of the left wall 8 and the right wall 9. It will be erected.

In the cleaning tank 5, the internal space sandwiched by the front wall 6 and the rear wall 7 from the front-rear direction Y, sandwiched by the left wall 8 and the right wall 9 from the left-right direction X, and blocked from the lower Z2 by the bottom wall 10. It is called the storage room 11. The upper surface portion of the bottom wall 10 is a bottom surface portion 12 that closes the storage chamber 11 from the lower side Z2. The storage chamber 11 is opened to the upper side Z1 via the doorway 13 bordered by the upper ends of the front wall 6, the rear wall 7, the left wall 8 and the right wall 9.

In connection with the doorway 13, the frame 2 is provided with a lid 14 that opens and closes the doorway 13. The lid 14 is formed in a plate shape having a size capable of closing the doorway 13, and is arranged directly below the top plate 2A of the frame 2. The lid 14 is movably supported by the frame 2 via a known elevating mechanism (not shown) using a cam or the like. As shown in FIG. 2, when the main body 3 is in the accommodation position, the lid 14 is lowered to seal the doorway 13. When the user grabs the door 4 and pulls it to the front side Y1, the main body 3 is pulled out to a drawer position (not shown) where the cleaning tank 5 is located on the front side Y1 of the frame 2. The elevating mechanism operates in conjunction with the main body 3 being pulled out from the accommodation position to the pull-out position, so that the lid 14 rises and separates from the doorway 13. As a result, in the washing tank 5 of the main body 3 at the drawer position, the doorway 13 is opened and exposed to the upper side Z1. The lid 14 is lowered by operating the elevating mechanism in conjunction with the return of the main body 3 from the drawer position to the accommodation position. As a result, when the main body 3 returns to the accommodation position, the doorway 13 is sealed by the lid 14.

The main body 3 includes a partition member 15, a holding portion 16, a filter unit 17, a heater 18, an injection mechanism 19, an injection port 20, a protection portion 21, a duct 22, a blower portion 23, and a water supply channel 24. And include. The partition member 15 is formed in a horizontally extending grid pattern, for example, by a wire rod made of resin or metal. The partition member 15 is arranged at a position biased toward Z2 below the center of the storage chamber 11 in the vertical direction Z, so that the storage chamber 11 is divided into an upper space 11A of Z1 above the partition member 15 and a partition member. It is partitioned into the lower space 11B of Z2 below 15. The upper space 11A has a size capable of accommodating a pair of shoes S to be washed by the shoe washing device 1 with a margin. The lower space 11B is smaller than the upper space 11A in the vertical direction Z. In FIG. 2, the low-cut type shoe S1 in which the shoe opening SH is close to the sole SZ as shown by the broken line, and the high-cut type shoe S2 in which the shoe opening SH is separated from the sole SZ as shown by the alternate long and short dash line. Two types of shoes S are shown together.

A pair of holding portions 16 are provided according to a pair of shoes S. The pair of holding portions 16 are arranged side by side in the left-right direction X in the upper space 11A. Each holding portion 16 integrally includes a root portion 16A, a tip portion 16B, and an intermediate portion 16C. The root portion 16A is fixed to the storage chamber 11, specifically, the rear wall 7 of the washing tank 5. The root portion 16A extends from the portion adjacent to the partition member 15 on the rear wall 7 from the upper side Z1 to the front side Y1 substantially horizontally. The tip portion 16B is arranged at a position higher than the root portion 16A, specifically, substantially in the center of the upper space 11A in the front-rear direction Y and the up-down direction Z, and extends substantially horizontally along the front-back direction Y. The intermediate portion 16C extends inclined from the tip portion 16B toward the root portion 16A toward the rear side Y2 and the lower side Z2, and connects the root portion 16A and the tip portion 16B. The holding portion 16 is formed in a frame shape by a wire rod.

In relation to the filter unit 17 and the heater 18, the bottom surface portion 12 of the storage chamber 11 has a first bottom surface portion 12A forming a substantially right half of the bottom surface portion 12 and a second bottom surface portion forming a substantially left half of the bottom surface portion 12. 12B is provided (see also FIG. 3). A recess 12C recessed to the lower side Z2 is formed in almost the entire area of the first bottom surface portion 12A. The second bottom surface portion 12B is configured to extend from the upper end of the recess 12C to the left side X1 and be inclined so as to descend toward the recess 12C (see FIG. 3). The inclination angle of the second bottom surface portion 12B with respect to the left-right direction X is, for example, about 5 degrees. The bottom 12D of the recess 12C is located lower than the second bottom surface portion 12B. At the front end of the bottom 12D, a concave outlet 12E recessed downward and a storage recess 12F recessed further downward Z2 from the lower end of the outlet 12E are formed. An opening 12G penetrating the bottom wall 10 is formed on the bottom surface or the side surface of the accommodating recess 12F (see also FIG. 5C described later). The opening 12G may be formed so as to straddle the bottom surface and the side surface of the accommodating recess 12F. The bottom 12D is provided with an inclined surface portion 12H arranged on the rear side Y2 of the outlet 12E. The inclined surface portion 12H extends from the lower end of the rear wall 7 of the cleaning tank 5 to the front side Y1 and gently descends toward the outlet 12E. The inclination angle of the inclined surface portion 12H with respect to the front-rear direction Y is, for example, about 5 degrees. The recess 12C, the outlet 12E and the accommodating recess 12F are part of the lower space 11B.

The filter unit 17 is arranged in the outlet 12E in the recess 12C of the first bottom surface portion 12A by being fitted in the accommodating recess 12F. The filter unit 17 is composed of a mesh or the like and has thin sheet-shaped filters 25 at the top and bottom. The filter 25 is arranged across the outlet 12E. As the heater 18, a flat flat heater having a built-in electric heater or the like and flattened up and down is used. The heater 18 is arranged in the recess 12C at a position farther from the outlet 12E to the rear side Y2 than the filter unit 17.

The injection mechanism 19 includes a rotary nozzle 26, a side nozzle 27, a heel nozzle 28, and a pump 29. The rotary nozzle 26 has a tower nozzle 30 and a horizontal nozzle 31, and is arranged in the storage chamber 11. The tower nozzle 30 is arranged between the pair of holding portions 16 at substantially the center of the storage chamber 11 in a plan view. The tower nozzle 30 is a tubular hollow body whose upper end is closed, and is an upper Z1 that passes between the second bottom surface portion 12B of the storage chamber 11 and between the pair of holding portions 16 to the front of the entrance / exit 13 of the storage chamber 11. Extend to. Since the lower end portion of the tower nozzle 30 is supported by the bottom surface portion 12, the entire rotary nozzle 26 can rotate around the virtual vertical axis J passing through the center of the tower nozzle 30. With reference to FIG. 3, in the following, the circumferential direction around the vertical axis J is referred to as the circumferential direction T, and the radial direction centered on the vertical axis J is referred to as the radial direction R. Of the radial directions R, the side away from the vertical axis J is referred to as the radial outer side R1, and the side closer to the vertical axis J is referred to as the radial inner side R2. The horizontal nozzle 31 is a vertically flat hollow body protruding from the lower portion of the tower nozzle 30 to the radial outer side R1. A plurality of horizontal nozzles 31 exist and are arranged in the lower space 11B of the storage chamber 11 so as to be rotationally symmetric with respect to the vertical axis J. There are two horizontal nozzles 31 of this embodiment, and they are arranged side by side in a straight line with the tower nozzle 30 interposed therebetween.

There are a pair of side nozzles 27, and they are arranged in the cleaning tank 5 so as to sandwich the tower nozzle 30 and the pair of holding portions 16 from the left-right direction X. Each side nozzle 27 is a hollow body that is flat in the left-right direction X and long in the front-rear direction Y. Of the pair of side nozzles 27, the side nozzle 27L of the left side X1 is fixed to the right surface of the left wall 8 of the cleaning tank 5, and the side nozzle 27R of the right side X2 is fixed to the left surface of the right wall 9 of the cleaning tank 5. .. In the side view seen from the left-right direction X, the substantially front half of each side nozzle 27 overlaps the tip portion 16B and the middle portion 16C of each holding portion 16 (see FIG. 2).

FIG. 4 is a cross-sectional view taken along the line CC of FIG. A pair of heel nozzles 28 are provided side by side on the front surface of the rear wall 7 of the cleaning tank 5 at a position higher than the root portion 16A of each holding portion 16. The pair of heel nozzles 28 are at the same position as the pair of holding portions 16 one by one in the left-right direction X. Each heel nozzle 28 is a hollow body extending in the left-right direction X. Of the pair of heel nozzles 28, the left end of the heel nozzle 28L on the left side X1 is connected to the rear end of the side nozzle 27L, and the right end of the heel nozzle 28R on the right side X2 is connected to the rear end of the side nozzle 27R. Will be done. The internal space of the heel nozzle 28 and the internal space of the side nozzle 27 connected to the heel nozzle 28 are in a state of communication. The side nozzle 27 and the heel nozzle 28, which are on the same side in the left-right direction X, may be separate parts that exist separately and are combined, or are integrally formed as one L-shaped part in a plan view. You may.

FIG. 5A is a cross-sectional view taken along the line DD of FIG. FIG. 5B is a bottom view of the shoe washing device 1. FIG. 5C is a cross-sectional view taken along the line GG of FIG. 5B. FIG. 5D is a rear view of the shoe washing device 1. As the pump 29, a centrifugal pump or the like having a built-in rotating impeller (not shown) can be adopted. The pump 29 is fixed to the rear end of the bottom wall 10 of the cleaning tank 5. The pump 29 and the opening 12G of the storage recess 12F in the bottom surface portion 12 of the storage chamber 11 are in a state of being connected by a tubular first flow path 32 arranged in the lower Z2 of the bottom wall 10 (FIG. 2, FIG. 5B and FIG. 5C). The pump 29 and the lower end of the tower nozzle 30 of the rotary nozzle 26 are connected by a tubular second flow path 33 arranged in the lower Z2 of the bottom wall 10 (see FIGS. 3 and 5B).

The pump 29 and the rear end of each side nozzle 27 are connected by a tubular third flow path 34 and a fourth flow path 35 arranged on the rear side Y2 of the rear wall 7 of the cleaning tank 5. Specifically, the joint pipe 36 provided at the rear end of the side nozzle 27L and the pump 29 are connected by a third flow path 34, and the joint pipe 36 and the rear end of the side nozzle 27R are connected to the fourth flow. Connected by road 35 (see FIGS. 5A and 5D). The joint pipe 36 includes a circular tubular inlet pipe portion 36A extending vertically, a circular tubular first outlet pipe portion 36B (see FIG. 4) extending from the upper end of the inlet pipe portion 36A to the front side Y1, and the upper end of the inlet pipe portion 36A. It integrally has a circular tubular second outlet pipe portion 36C extending from the upper right side (upper left side in FIGS. 5A and 5D). The lower end of the inlet pipe portion 36A is connected to the upper end portion of the third flow path 34, the front end portion of the first outlet pipe portion 36B is connected to the rear end portion of the side nozzle 27L, and the upper end portion of the second outlet pipe portion 36C. Is connected to the left end of the fourth flow path 35 (the right end in FIGS. 5A and 5D). The first flow path 32 to the fourth flow path 35 and the joint pipe 36 are included in the injection mechanism 19.

One end of a tubular drainage channel 37 is connected to the pump 29. The pump 29 can suck in the water existing in the first flow path 32 and discharge it only to the second flow path 33 and the third flow path 34, or discharge it only to the drainage channel 37. The other end of the drainage channel 37 may join the drainage channel of a washing machine (not shown) arranged on the upper side Z1 of the shoe washing device 1.

With reference to FIGS. 2 to 4, the injection port 20 includes a tower nozzle 30 of the rotary nozzle 26, an injection port 20A provided in each horizontal nozzle 31, and a side injection port 20B provided in each side nozzle 27. Each heel includes a heel injection port 20C provided on the nozzle 28. The plurality of injection ports 20A are provided at the upper end portion 30A of the tower nozzle 30 and the upper surface portion of each horizontal nozzle 31. The plurality of injection ports 20A at the upper end portion 30A are arranged at different positions in, for example, the circumferential direction T and the vertical direction Z, and are in a state of communicating with the inside of the tower nozzle 30. With reference to FIG. 4, the plurality of injection ports 20A in each horizontal nozzle 31 are arranged side by side in a row along the radial direction R, and are in a state of communicating with the inside of the horizontal nozzle 31. At least a part of the injection ports 20A'located at the end of the radial outer side R1 in the plurality of injection ports 20A in the at least one horizontal nozzle 31 is in a state of facing one side in the circumferential direction T.

With reference to FIG. 2, a plurality of side injection ports 20B exist in each side nozzle 27. These side injection ports 20B are provided on the right surface portion of the side nozzle 27L and the left surface portion of the side nozzle 27R. The plurality of side injection ports 20B in each side nozzle 27 are arranged side by side in front, back, up and down so as to form two upper and lower rows extending in the front-rear direction Y, and are in a state of communicating with the inside of the side injection ports 20B. Of the upper and lower rows, the row L1 of the upper Z1 is composed of, for example, six side injection ports 20B arranged in front and back, and the row L2 of the lower Z2 is arranged in front and back in the lower Z2 at the rear of the row L1, for example 2. It is composed of two side injection ports 20B. Although the rows L1 and L2 are close to the horizontal direction, they are arranged so as to be inclined toward the front upper side. In each side nozzle 27, the portion where the rows L1 and the rows L2 are provided side by side is larger in the vertical direction Z than the portion where only the row L1 is arranged on the front side Y1 of this portion.

With reference to FIG. 4, one heel injection port 20C is provided at the right end of the heel nozzle 28L and one at the left end of the heel nozzle 28R, but each heel nozzle 28 has a plurality of heel injection ports 20C. It may be provided. The heel injection port 20C is in a state of communicating with the inside of the heel nozzle 28. A positioning portion 38 is provided in the vicinity of the heel injection port 20C in each heel nozzle 28, for example, directly below the heel injection port 20C. That is, there are a pair of left and right positioning portions 38. Each positioning portion 38 has a plate thickness direction corresponding to the left-right direction X, and is formed in the shape of a triangular plate whose tip is rounded and becomes thinner in the vertical direction toward the front side Y1 (see FIG. 2). The rear end of the positioning portion 38 is fixed to the heel nozzle 28 or the rear wall 7 of the cleaning tank 5.

With reference to FIG. 2, the protective portion 21 is formed into a cylindrical shape by a wire rod. The protective portion 21 is placed on the partition member 15 and arranged in the upper space 11A of the storage chamber 11 and surrounds a part of the tower nozzle 30 of the rotary nozzle 26. Specifically, the protection portion 21 is arranged between the lower portion 30B of the Z2 below the upper end portion 30A provided with the injection port 20A in the tower nozzle 30 and each of the pair of holding portions 16. Surrounds and protects the lower portion 30B (see also FIG. 3). The protective portion 21 may be a member different from the partition member 15, or may be integrated with the partition member 15.

The duct 22 is formed in a tubular shape extending in the vertical direction Z, and is fixed to the rear wall 7 of the cleaning tank 5 from the rear side Y2. An outlet 22A is formed at the lower end of the duct 22. The outlet 22A is arranged in the lower part of the front surface portion of the rear wall 7, which is an example of the inner wall portion of the storage chamber 11, and is in a state of communicating with the lower space 11B in the storage chamber 11 from the rear side Y2.

The blower portion 23 is a so-called fan, which is arranged outside the cleaning tank 5 and is fixed to the upper end portion of the duct 22 from the upper side Z1. A suction port 23A is formed on the rear surface of the blower portion 23, and a discharge port 23B (see FIG. 5A) facing the internal space of the duct 22 from the upper side Z1 is formed on the lower surface of the blower portion 23.

The water supply channel 24 is a pipe extending from a faucet or other faucet (not shown), and is connected to a portion of Z2 below the portion of the duct 22 connected to the discharge port 23B of the blower portion 23 from the left side X1. (See FIG. 5A). The water supply channel 24 is not directly connected to the faucet (not shown), but branches from the water supply channel of the washing machine (not shown) arranged on the upper side Z1 of the shoe washing device 1 to the duct 22. It may be connected. A water supply valve 39 (see FIG. 5A) configured by a solenoid valve or the like is attached in the middle of the water supply channel 24. The water supply channel 24 and the drainage channel 37 described above are set to be longer to some extent in consideration of the fact that the main body 3 is slidable.

The main body 3 is provided with a control unit 40 (see FIG. 1) composed of a microcomputer or the like. The control unit 40 is electrically connected to each of the operation unit 4C, the heater 18, the blower unit 23, the pump 29, and the water supply valve 39 by wiring (not shown). Therefore, the control unit 40 can accept the operation of the operation unit 4C by the user, control the operation of the heater 18, the blower unit 23, and the pump 29, and control the opening and closing of the water supply valve 39.

Next, the washing operation of the shoe S by the shoe washing device 1 will be described. The washing operation includes a washing step of washing the shoes S with a washing liquid, a rinsing step of rinsing the shoes S with a washing liquid after the washing step, and a deliquesing step of removing water from the shoes S after the rinsing step. The cleaning liquid in the washing step is tap water in which the detergent is dissolved, and the cleaning liquid in the rinsing step is tap water containing no detergent component. In the washing step, bath water may be used instead of tap water.

Prior to the start of the washing operation, the user pulls out the main body 3 of the shoe washing device 1 to the drawer position (not shown) to open the doorway 13 of the washing tank 5, and puts a pair of shoes S from the doorway 13 into the storage room. It is stored in the upper space 11A of 11. At that time, the user inserts the tip portion 16B of each holding portion 16 into the internal space SN of the shoe S so as to face the toe ST side after inserting the tip portion 16B of each holding portion 16 into the shoe opening SH from the lower side Z2. As a result, in the upper space 11A, a pair of shoes S are lined up in the left-right direction X, and each shoe S is held by the holding portion 16 in an inverted posture that is substantially horizontal in the front-rear direction Y. In the shoe S in the inverted posture, the toe ST faces the front side Y1, the sole SZ faces the upper side Z1, and the upper portion SU covering the instep and the shoe opening SH face the lower side Z2. Further, when the shoe S is stored in the storage room 11, the user puts the detergent into the storage room 11. After that, the user returns the main body 3 to the accommodation position shown in FIGS. 2 to 4. This completes the preparation for the cleaning operation.

In the shoe washing device 1 for which the preparation for the washing operation is completed, the tower nozzle 30 of the rotating nozzle 26 is arranged between the pair of shoes S held in the inverted posture in the storage chamber 11. The upper end portion 30A of the tower nozzle 30 is arranged so as to project from the sole SZ of these shoes S to the upper side Z1. As a result, at least one of the plurality of injection ports 20A provided at the upper end portion 30A is arranged at a position higher than the sole SZ. Each horizontal nozzle 31 of the rotary nozzle 26 is arranged at a position lower than these shoes S, and the injection port 20A in each horizontal nozzle 31 faces the upper portion SU and the shoe opening SH of these shoes S from the lower side Z2. Placed in.

The pair of side nozzles 27 are arranged on both sides of the pair of shoes S in the storage chamber 11, that is, on both outer sides in the left-right direction X. The side injection ports 20B in the side nozzle 27L face the side portion SS of the left side X1 in the shoe S from the left side X1 in a state of being lined up substantially along the longitudinal direction of the shoe S of the left side X1. The side injection ports 20B in the side nozzle 27R face the side portion SS of the right side X2 in the right side X2 from the right side X2 in a state of being lined up substantially along the longitudinal direction of the shoe S in the right side X2. In the side view, the side injection port 20B of the row L1 of the upper side Z1 in each side nozzle 27 is arranged so as to overlap the portion closer to the sole SZ in the side portion SS. In particular, the front end side injection port 20B in the row L1 is arranged so as to overlap the portion closer to the toe ST in the side portion SS, and the rear end side injection port 20B in the row L1 is a portion closer to the heel portion SK in the side portion SS. It is placed on top of each other. The side injection port 20B of the row L2 of the lower side Z2 is arranged so as to overlap the portion of the side portion SS that is biased toward the discharge port SH side in the side view.

The pair of heel nozzles 28 are arranged on the rear side Y2 of the pair of shoes S. The heel injection port 20C in the heel nozzle 28L faces the heel portion SK of the shoe S on the left side X1 from the rear side Y2, and the heel injection port 20C in the heel nozzle 28R faces the heel portion SK of the shoe S on the right side X2 from the rear side Y2. Face. The front end of the positioning portion 38 of the left side X1 contacts the heel portion SK of the shoe S of the left side X1 from the rear side Y2, and the front end portion of the positioning portion 38 of the right side X2 contacts the heel portion SK of the shoe S of the right side X2. Contact from. As a result, the heel portion SK of the shoe S on the left side X1 is positioned by the positioning portion 38 so as to separate a constant gap 41 in the front-rear direction Y with respect to the heel injection port 20C on the left side X1. The heel portion SK of the shoe S on the right side X2 is also positioned by the positioning portion 38 so as to separate the gap 41 from the heel injection port 20C on the right side X2.

After the preparation for the washing operation is completed, the user operates the operation unit 4C (see FIG. 1) to instruct the shoe washing device 1 to start the washing operation. Then, the control unit 40 starts the washing process, and first opens the water supply valve 39 to supply water to the storage chamber 11. As a result, the water from the faucet (not shown) flows into the duct 22 through the water supply channel 24 due to the water pressure, flows down from the outlet 22A to the storage chamber 11, and collects in the lower space 11B of the storage chamber 11. Such a duct 22 also serves as at least a part of the water supply channel 24. Further, tap water flowing into the lower space 11B from the outlet 22A of the duct 22 reaches the pump 29 through the outlet 12E, the opening 12G, and the first flow path 32 (thick solid arrows in FIGS. 5B and 5C). (See), the control unit 40 stops the pump 29 so that at least the water in the first flow path 32 does not flow into the drainage channel 37. Therefore, the water level in the lower space 11B rises according to the water supply.

When the water surface W in the lower space 11B rises to a predetermined water level lower than the horizontal nozzle 31 of the rotary nozzle 26, the control unit 40 closes the water supply valve 39 and stops the water supply. As described above, since the detergent is charged into the storage chamber 11 in advance, the cleaning liquid produced by dissolving the detergent in water collects in the lower space 11B. A part of the cleaning liquid in the lower space 11B also spreads to the first flow path 32. A detergent storage room (not shown) connected to the water supply channel 24 is provided in the shoe washing device 1, and the detergent stored in the detergent storage room is put into the storage room 11 on tap water at the time of water supply. May be done.

Next, the control unit 40 sucks the cleaning liquid in the lower space 11B of the storage chamber 11 from the first flow path 32 while maintaining the state in which the first flow path 32 and the drainage channel 37 are continuously shut off in the pump 29. The pump 29 is driven so as to be discharged to the second flow path 33 and the third flow path 34. Then, the cleaning liquid discharged from the first flow path 32 to the second flow path 33 (see the arrow of the thick one-dot chain line in FIG. 5B) flows into the tower nozzle 30 of the rotary nozzle 26 and flows into the tower nozzle 30. As it rises, it also spreads within each horizontal nozzle 31.

Then, among the plurality of injection ports 20A lined up in a row in each horizontal nozzle 31, the cleaning liquid is injected from the above-mentioned injection port 20A'(see FIG. 4) toward one side in the circumferential direction T. As a result, each horizontal nozzle 31 receives a thrust in the circumferential direction T, so that the entire rotary nozzle 26 rotates around the vertical axis J. The injection port 20A'for generating the thrust for rotating the rotary nozzle 26 does not have to be one injection port 20A located at the end of the radial outer side R1 in the horizontal nozzle 31, and the other injection port 20A may be used. There may be. During the rotation of the rotary nozzle 26, the left and right holding portions 16 holding the shoes S are arranged at substantially equal intervals from the tower nozzle 30 in the left-right direction X, so that each shoe S is a rotating tower nozzle 30. It is arranged away from the tower nozzle 30 so as not to come into contact with the tower nozzle 30 (see FIG. 3).

In each horizontal nozzle 31 of the rotating nozzle 26 during rotation, the cleaning liquid is discharged from the injection port 20A other than the injection port 20A', as shown by the thick solid arrow, the upper portion SU and the shoes of each shoe S in the upper space 11A. It is ejected from the lower Z2 toward the mouth SH. Further, the cleaning liquid that has risen in the tower nozzle 30 of the rotating rotary nozzle 26 is discharged from each injection port 20A at the upper end portion 30A of the tower nozzle 30 to the sole SZ or the side of each shoe S, as shown by the thick broken line arrow. It is ejected from the upper side Z1 toward the portion SS.

Further, the cleaning liquid flowing into the third flow path 34 from the first flow path 32 (see the thick broken line arrow in FIGS. 5B and 5D) is the inlet pipe portion 36A and the first outlet pipe portion 36B of the joint pipe 36 (FIG. 5B and FIG. 5D). 4 and the inside of the heel nozzle 28L as well as the side nozzle 27L via (see FIG. 5D). The cleaning liquid flowing through the third flow path 34 flows into the fourth flow path 35 (see FIG. 5A) via the inlet pipe portion 36A and the second outlet pipe portion 36C of the joint pipe 36, and then enters the side nozzle 27R. As it spreads, it spreads inside the heel nozzle 28R.

Then, referring to FIG. 4, in the side nozzle 27L, the cleaning liquid is sprayed from the side injection port 20B to the side portion SS of the left side X1 in the shoe S of the left side X1 as indicated by the arrow of the thick one-dot chain line. .. In the heel nozzle 28L, the cleaning liquid is sprayed from the heel injection port 20C to the heel portion SK of the shoe S on the left side X1 as shown by the thick broken line arrow in FIG. In the side nozzle 27R, the cleaning liquid is sprayed from the side injection port 20B to the side portion SS of the right side X2 in the shoe S of the right side X2 as indicated by the arrow of the thick one-dot chain line. In the heel nozzle 28R, the cleaning liquid is sprayed from the heel injection port 20C to the heel portion SK of the shoe S on the right side X2 as indicated by the thick broken line arrow.

The cleaning liquid that has flowed through the third flow path 34 and has flowed into the inlet pipe portion 36A of the joint pipe 36 turns at a substantially right angle in the first outlet pipe portion 36B and flows into the side nozzle 27L, but flows into the side nozzle 27L. In the pipe portion 36C, the pipe portion 36C flows through the third flow path 34 and flows into the side nozzle 27R with almost no change in direction. In this case, the momentum of the cleaning liquid flowing into the side nozzle 27L may be weaker than the momentum of the cleaning liquid flowing into the side nozzle 27R.

Therefore, the inner diameter of the first outlet pipe portion 36B is set to be larger than the inner diameter of the second outlet pipe portion 36C. Further, the internal space of the first outlet pipe portion 36B is directly connected to the internal space of the side nozzle 27L from the rear side Y2, and these internal spaces are along the longitudinal direction of the side nozzle 27 and overlap each other when viewed from the front-rear direction Y. Therefore, the hydraulic resistance in these internal spaces can be reduced. As a result, the flow rate of the cleaning liquid in the first outlet pipe portion 36B is increased, and the cleaning liquid in the first outlet pipe portion 36B is supplied to the front end portion in the side nozzle 27L without weakening the momentum as shown by the solid line arrow in FIG. It can be distributed. Therefore, the cleaning liquid having substantially the same momentum is sprayed onto the left and right shoes S from the side injection ports 20B of the left and right side nozzles 27.

The shoes S on which the cleaning liquid is sprayed at a high pressure are cleaned by removing stains such as mud and gravel by the force of the cleaning liquid or by chemically decomposing the stains by the cleaning liquid. In particular, the cleaning liquid sprayed from each injection port 20A of the horizontal nozzle 31 of the rotating rotary nozzle 26 is in every corner of the outer surface portion of the front side of each shoe S in the inverted posture, that is, the toe ST, the upper portion SU, and the shoe opening. It is evenly sprayed on each of SH and heel part SK. As a result, even for various shoes S having different shapes of the front portion, not only the entire surface portion of the shoe S but also the cleaning liquid that has entered the internal space SN from the shoe opening SH causes the internal space SN, that is, the shoe S. The entire area inside can also be washed.

Further, each side injection port 20B of the pair of side nozzles 27 injects the cleaning liquid onto the side portion SS of each shoe S from the left-right direction X, and the heel injection port 20C of the pair of heel nozzles 28 is the heel portion of each shoe S. The cleaning liquid is sprayed onto the SK from the rear side Y2. As a result, on the outer surface portion on the front side of the shoe S, the side portion SS and the heel portion SK are cleaned by the cleaning liquid, and the cleaning liquid flowing down the side portion SS and the heel portion SK to the upper portion SU causes the upper portion SU and the shoe opening. SH is also washed.

Further, referring to FIG. 2, after being sprayed from each injection port 20A of the horizontal nozzle 31, the tip of the cleaning liquid that hits the lid 14 which is the ceiling of the storage chamber 11 and drops is the sole SZ, that is, the outer surface of the back side of the shoe S. There is a part. Further, each injection port 20A at the upper end portion of the tower nozzle 30 of the rotary nozzle 26 rotates integrally with the tower nozzle 30, so that the cleaning liquid can be injected from the upper side Z1 over a wide range in the sole SZ of each shoe S. With these cleaning liquids, the entire area of the sole SZ can be effectively cleaned.

As described above, even if the shoes S are not rubbed with a brush or the like, the cleaning power equivalent to that when the shoes S are rubbed with a brush or the like with the high-pressure cleaning liquid sprayed from each injection port 20 to the shoes S in the storage chamber 11 The entire inside and outside of the shoe S can be washed evenly so as not to cause damage while maintaining the above. Therefore, the cleaning power can be improved so that the shoes S are not damaged.

In particular, the plurality of side injection ports 20B arranged vertically in each side nozzle 27 ensure that the cleaning liquid is applied to the side portion SS of the shoes S regardless of the above-mentioned low-cut type shoes S1 and high-cut type shoes S2. Can be sprayed. Therefore, it is possible to improve the detergency so as not to cause damage to any of the shoes S having different positions of the shoes S.

In addition to the side injection port 20B injecting the cleaning liquid onto the side portion SS of the shoe S, the heel injection port 20C injects the cleaning liquid into the heel portion SK of the shoe S, so that the entire outer surface portion of the shoe S is washed more evenly. can. Further, the positioning portion 38 positions the heel portion SK with respect to the heel injection port 20C. As a result, the positional relationship between the heel injection port 20C and the heel injection port 20C is such that the above-mentioned constant gap 41 is secured regardless of the shoes S having different shapes of the heel portion SK. The positional relationship is optimal for spraying the cleaning liquid onto the heel SK. As a result, the heel injection port 20C can effectively inject the cleaning liquid onto the heel portion SK of the shoe S in the storage chamber 11, so that the cleaning power can be further improved.

Since the holding portion 16 inserted into the internal space SN of the shoe S has a frame shape having a large number of gaps, the cleaning liquid from each injection port 20A of the horizontal nozzle 31 toward the shoe opening SH obstructs the flow by the holding portion 16. It can smoothly flow into the internal space SN from the shoe opening SH, and after the inflow, it can smoothly flow out from the shoe opening SH to the outside of the shoe S. If the entire shoe S is tilted so that the sole SZ shifts from the toe ST side toward the heel SK side toward the lower Z2 as in the low-cut type shoe S1, the cleaning liquid in the internal space SN is removed. It can be more smoothly discharged from the shoe opening SH to the outside of the shoe S.

Further, in the washing step, the control unit 40 may turn on the heater 18 to heat the washing liquid in the lower space 11B. In this case, the cleaning power can be enhanced by the warm cleaning liquid sprayed on the shoes S from each injection port 20, so that the shoes S can be cleaned more effectively.

Further, a partition member 15 is provided between the shoe S and the horizontal nozzle 31 of the rotary nozzle 26 in the storage chamber 11. As a result, the shoe S that has suddenly fallen off the holding portion 16 and the shoelace (not shown) of the shoe S come into contact with the horizontal nozzle 31 to rotate the rotary nozzle 26 and inject each of the horizontal nozzle 31. It is possible to prevent the injection of the cleaning liquid from the mouth 20 from being obstructed. Further, since the partition member 15 has a grid pattern, the cleaning liquid sprayed from each injection port 20 can surely reach the shoes S by passing through the grid of the partition member 15. Therefore, even if the partition member 15 is present, the shoes S can be reliably cleaned by the cleaning liquid ejected from each injection port 20 of the horizontal nozzle 31.

The detergent used in the cleaning liquid is preferably a low-foaming detergent dedicated to shoe cleaning, which contains a surfactant which is a soap component in a proportion of 10% by mass or less, which is less than half of the usual amount. In this case, it is possible to suppress abnormal foaming of the cleaning liquid, prevent clogging of each injection port 20 due to the foam of the cleaning liquid, and prevent a decrease in the rotation speed of the rotary nozzle 26 due to the resistance of the foam.

In the washing step, the cleaning liquid spilled from the shoes S after being sprayed from each injection port 20 into the shoes S in the upper space 11A of the storage chamber 11 or the shoes S sprayed from each injection port 20 into the upper space 11A. The cleaning liquid that has not been applied falls through the grid of the partition member 15 into the lower space 11B and collects on the bottom surface portion 12. In the washing process, the pump 29 is continuously driven. Therefore, the cleaning liquid in the lower space 11B flows into the first flow path 32 via the outlet 12E and the opening 12G in the bottom surface portion 12, and flows into the second flow path 33, the third flow path 34, and the fourth flow path 35. Is injected into the upper space 11A from each injection port 20 of the rotary nozzle 26, the side nozzle 27, and the heel nozzle 28. As a result, the cleaning liquid circulates between the upper space 11A and the lower space 11B. Therefore, even with a small amount of cleaning liquid, the shoes S can be washed by circulating and repeatedly using them, so that the water saving performance can be improved.

Foreign matter such as gravel removed from the shoes S by spraying the cleaning liquid gets on the cleaning liquid that is about to flow out of the storage chamber 11 from the outlet 12E. As the cleaning liquid passes through the outlet 12E, the filter 25 in the filter unit 17 captures foreign matter from the cleaning liquid. As a result, it is possible to prevent a problem that the foreign matter circulates together with the cleaning liquid and clogs the pump 29 and the injection port 20. The shoe washing device 1 may further include a second sheet-shaped filter 42, which is made of a mesh having a finer mesh than the filter 25. The second filter 42 is arranged, for example, directly under the filter 25 on the way until the cleaning liquid that has passed through the filter 25 reaches the opening 12G. The second filter 42 captures fine foreign matter contained in the cleaning liquid that has passed through the filter 25. The cleaning liquid that has passed through the filter 25 and the second filter 42 and has flowed out of the storage chamber 11 is sent to each injection port 20 by the pump 29 and is ejected from each injection port 20 into the storage chamber 11. It circulates as described above.

After continuing the circulation of the cleaning liquid for a predetermined time, the control unit 40 switches the operation of the pump 29 so that the cleaning liquid of the first flow path 32 flows into the drainage channel 37. As a result, the cleaning liquid in the lower space 11B is forcibly discharged to the outside of the machine through the first flow path 32 and the drainage channel 37. After such drainage, the control unit 40 stops the pump 29. This completes the washing process. A drain valve (not shown) that is controlled to open and close by the control unit 40 and opens at the time of drainage may be provided in the middle of the drainage channel 37.

When the washing process is completed, the control unit 40 starts the rinsing process, executes water supply again, and collects tap water in the lower space 11B. When the water surface W in the lower space 11B reaches a predetermined water level lower than the horizontal nozzle 31 of the rotary nozzle 26 by water supply, the control unit 40 drives the pump 29 to use tap water as rinsing water and lower the upper space 11A. Circulate with space 11B. As a result, the rinse water from the injection ports 20 of the rotary nozzle 26, the side nozzle 27, and the heel nozzle 28 is sprayed onto the shoes S in the upper space 11A at high pressure, so that the shoes S are rinsed by the rinse water. At this time, the control unit 40 may turn on the heater 18 to heat the rinse water in the lower space 11B. In this case, the shoes S can be effectively rinsed by spraying the shoes S with warm rinsing water from each injection port 20.

After continuing such circulation of the rinse water for a predetermined time, the control unit 40 switches the operation of the pump 29 so that the water in the first flow path 32 flows into the drainage channel 37. As a result, the rinse water in the lower space 11B is discharged to the outside of the machine through the first flow path 32 and the drainage channel 37. After that, the control unit 40 stops the pump 29. This completes the rinsing process, that is, the entire cleaning process.

After the cleaning step, the control unit 40 starts the liquid removal step by driving the blower unit 23. As a result, the air outside the machine is taken into the duct 22 through the suction port 23A and the discharge port 23B of the blower unit 23. The air taken into the duct 22 becomes wind and heads toward the outlet 22A, and is sent from the outlet 22A into the storage chamber 11. Such a duct 22 also serves as at least a part of the air passage for sending wind to the outlet 22A, and in this embodiment, the entire air passage.

The air sent into the storage chamber 11 is exposed to the outer surface of each shoe S in the upper space 11A in a high-pressure state pressurized by the blower 23, or the inside space SN of the shoe S from the shoe opening SH. Moisture such as a cleaning liquid is exuded from the shoe S by flowing into the shoe S. The exuded water spills from the shoe S. Therefore, by exposing each shoe S to the air from the duct 22, the washed shoe S can be effectively deliquesed. The air sent into the storage chamber 11 is finally discharged to the outside of the machine through the exhaust port 4A (see FIG. 1) of the door 4 of the main body 3. In the liquid removal step, the control unit 40 may turn on the heater 18 to generate hot air in the storage chamber 11. In this case, the shoes S can be more effectively deliquescented by hot air.

When a predetermined time has elapsed from the start of driving the blower unit 23, the control unit 40 stops the blower unit 23 and ends the liquid removal process. As a result, the washing operation is completed. The control unit 40 may drive the pump 29 at the end of the liquid removal process to discharge the water spilled from the shoes S during the liquid removal process to the outside of the machine. After the washing operation is completed, the user pulls out the main body 3 to the drawer position (not shown) to open the doorway 13 of the washing tank 5, and takes out the shoes S in the storage chamber 11 from the doorway 13.

As described above, in the shoe washing device 1, when the shoes S are first stored in the storage chamber 11 and held in the holding portion 16, then a series of steps is performed without moving the shoes S in the storage chamber 11. Cleaning operation can be carried out. Further, in the shoe washing device 1, since the shoe S in the storage chamber 11 is held in the inverted posture by the holding portion 16, the height dimension of the storage chamber 11 is increased as compared with the case where the shoe S is held in the vertical posture. Since it can be kept small, the entire shoe washing device 1 can be made compact.

Next, details of the filter unit 17 and the heater 18 housed in the recess 12C of the first bottom surface portion 12A of the storage chamber 11 will be described. With reference to FIG. 2, the filter unit 17 has, for example, a resin holder 75 and a filter cover 76 in addition to the filter 25 described above. The holder 75 is formed in a shape of a frame that is long in the left-right direction X and thin in the up-down direction Z, and the filter 25 is arranged in the inner space thereof. The filter unit 17 in the recess 12C is positioned in the vertical direction Z by mounting the outer edge portion of the holder 75 on the step portion 12I at the boundary between the outlet 12E of the recess 12C and the accommodating recess 12F (see also FIG. 3). .. The front portion of the boundary 12J between the first bottom surface portion 12A and the second bottom surface portion 12B projects convexly toward the left side X1 in a plan view and surrounds the left end portion of the filter unit 17 (see FIG. 4). As a result, the filter unit 17 in the recess 12C is positioned in the left-right direction X and the front-back direction Y.

The filter cover 76 is formed in a substantially rectangular plate shape that is substantially the same as the holder 75 or one size smaller than the holder 75 in a plan view. In the filter cover 76, a plurality of through holes 76C penetrating the filter cover 76 vertically are arranged, for example, evenly arranged in a matrix (see FIG. 4). The filter cover 76 is arranged directly above the filter 25 with a predetermined gap V in a posture substantially parallel to the filter 25, and covers almost the entire area of the filter 25 from the upper side Z1. As a result, the foreign matter captured by the filter 25 and existing in the gap V on the filter 25 is blindfolded by the filter cover 76. Therefore, it is difficult for foreign matter on the filter 25 to enter the user's field of view to access the storage chamber 11 for taking out the shoes S or the like. Therefore, it is possible to improve the appearance of foreign matter removed from the shoe S. The filter cover 76 is rotatably supported up and down by the holder 75. The filter unit 17 is removable from the storage chamber 11. When the filter unit 17 is removed from the storage chamber 11 and the user opens the filter cover 76 by rotating the filter cover 76 from the closed position shown in FIG. 2 to the upper Z1, the filter 25 is exposed to the upper Z1. .. As a result, the user can easily remove the foreign matter on the filter 25 and maintain the filter 25.

The upper surface portion of the filter cover 76 in the closed position is arranged substantially flush with each other at a substantially same height position as the second bottom surface portion 12B (see FIG. 3). As a result, since there is no large unevenness between the second bottom surface portion 12B and the filter cover 76, workability can be improved when cleaning the bottom surface portion 12.

As described above, the heater 18 configured by the flat heater is formed in a disk shape having a circular contour in a plan view (see FIG. 4), and in the recess 12C, in the middle of the inclined surface portion 12H of the bottom 12D of the recess 12C. Placed in. The rear portion of the boundary 12J between the first bottom surface portion 12A and the second bottom surface portion 12B is formed by bulging in an arc shape to the left side X1 according to the disk shape of the heater 18 in a plan view (see FIG. 4).

A recess 12K recessed to the lower side Z2 is formed in the middle of the inclined surface portion 12H in the front-rear direction Y, and the heater 18 is housed in the recess 12K. The heater 18 in the recess 12K is connected to the second bottom surface portion 12B via the packing 51. Since the gap around the heater 18 in the recess 12K is closed by the packing 51, the cleaning liquid in the storage chamber 11 is prevented from leaking to the bottom of the recess 12K through the gap. The packing 51 is a heat insulating packing. Therefore, since the space between the heater 18 and the second bottom surface portion 12B around the heater 18 is insulated by the packing 51, when the second bottom surface portion 12B is made of resin, the second bottom surface portion 12B heats the heater 18. Is prevented from melting. The upper surface portion 18A of the heater 18 is exposed from the recess 12K to the bottom 12D. Since the heater 18 in the recess 12K is arranged so as to be slightly inclined with respect to the horizontal direction so as to shift toward the upper side Z1 toward the rear side Y2, the upper surface portion 18A of the heater 18 has a substantially surface with the surrounding inclined surface portion 12H. Arranged to be one. The upper surface portion 18A may be arranged at a position slightly higher than the inclined surface portion 12H.

In connection with the heater 18, the shoe cleaning device 1 further includes a heater cover 52. The heater cover 52 is formed in a plate shape having a plate thickness direction corresponding to the vertical direction Z. The heater cover 52 has a size that substantially coincides with the region of Y2 on the rear side of the filter unit 17 in the recess 12C in a plan view (see FIG. 4), and is arranged in the recess 12C to provide the inclined surface portion 12H and the heater 18. Cover from the upper Z1. The upper surface portion 52A of the heater cover 52 is arranged at substantially the same height position as the second bottom surface portion 12B so as to be substantially flush with each other (see FIG. 3). Similar to the upper surface portion of the filter cover 76, if the upper surface portion 52A of the heater cover 52 is arranged substantially flush with the second bottom surface portion 12B, the entire bottom surface portion 12 becomes substantially flat and is simply configured. Therefore, at the time of maintenance, the upper surface portion 52A, the second bottom surface portion 12B, and the filter cover 76 of the heater cover 52 can be cleaned together. Further, as in the case of the filter cover 76, since there is no large unevenness between the second bottom surface portion 12B and the heater cover 52, workability can be improved when cleaning the bottom surface portion 12.

Since the heater 18 is composed of a flat heater as described above, the heater 18 has a thickness of about several cm and is flat in the vertical direction. In this case, since the heater 18 itself can be made thinner than when the sheathed heater is used, the heater 18 and the heater cover 52 can be arranged so as not to protrude from the recess 12C to the upper side Z1. As a result, it is possible to secure a large height dimension of the upper space 11A in which the shoes S are actually arranged in the storage chamber 11. A plurality of through holes 52B that vertically penetrate the heater cover 52 are formed in the heater cover 52, and these through holes 52B are regularly arranged in a staggered or matrix-like arrangement pattern on the upper surface portion 52A. (See FIG. 4).

The shoe washing device 1 further includes a guide member 53 arranged in the storage chamber 11. The guide member 53 integrally has a plate-shaped facing portion 53A and an extending portion 53B. The facing portion 53A is inclined so as to extend from the portion bordering the upper end of the outlet 22A to the front side Y1 in the rear wall 7 of the cleaning tank 5 and descend. The facing portion 53A faces the outlet 22A from the front side Y1, the lower end of the facing portion 53A is arranged directly above the heater 18 in the recess 12C, and the right end of the facing portion 53A is connected to the right wall 9 of the cleaning tank 5. (See also Figure 4). The extending portion 53B has a plate thickness direction corresponding to the left-right direction X, and is formed in a substantially triangular shape in a side view. The extending portion 53B extends from the left end of the facing portion 53A to the rear side Y2, and is connected to a portion of the rear wall 7 bordering the left end of the outlet 22A. The extension portion 53B is formed with, for example, a substantially triangular intake port 53C that penetrates the extension portion 53B in the left-right direction X. The air taken into the duct 22 from the outside of the machine in the liquid removing step flows out between the outlet 22A and the facing portion 53A, and then is sent into the storage chamber 11 from the intake port 53C.

At the lower end of the guide member 53, an inflow port 53D bordered by the lower ends of the facing portion 53A and the extending portion 53B, the rear wall 7 and the right wall 9 is formed. The inflow port 53D is arranged in the recess 12C at a position farther from the outlet 12E to the rear side Y2 than the heater 18, specifically at the rear end portion of the recess 12C, and at least one of the upper surface portion 18A and the inclined surface portion 12H of the heater 18. Face the club from directly above. The heater cover 52 is arranged so as to avoid the lower end portion of the guide member 53 (see FIG. 4). The water that has flowed into the duct 22 through the water supply channel 24 at the time of water supply, after flowing out from the outlet 22A, collides with the facing portion 53A and is guided downward, flows down from the inflow port 53D into the recess 12C, and is supplied into the storage chamber 11. Will be done. Water first collects in the recess 12C to fill the recess 12C, and then collects on the second bottom surface portion 12B.

In the configuration in which the filter 25, the heater 18, and the heater cover 52 are arranged in the recess 12C of the first bottom surface portion 12A and the second bottom surface portion 12B is raised (see also FIG. 3), the second bottom surface portion 12B is Compared with the case where the recess 12C is located at the same height as the bottom 12D, the required amount of the cleaning liquid in the cleaning operation can be reduced, so that the water saving performance can be improved. Further, by raising the bottom of the second bottom surface portion 12B, a space P is secured directly under the second bottom surface portion 12B. Therefore, in order to arrange the first flow path 32, the second flow path 33, and the like in this space P. Can be effectively used for (see Fig. 3).

Further, as described above, since the second bottom surface portion 12B is inclined so as to descend toward the recess 12C, foreign matter such as mud and gravel removed from the shoe S is inclined along the inclination of the second bottom surface portion 12B. It can be guided to the recess 12C (see FIG. 3). Since the bottom 12D of the recess 12C is provided with an inclined surface portion 12H that descends toward the outlet 12E, foreign matter in the recess 12C can be guided to the outlet 12E along the inclined surface portion 12H and captured by the filter 25. .. In the recess 12C, the heater 18 and the inlet 53D are arranged in this order so as to be closer to the outlet 12E. The water supplied from the inflow port 53D for the cleaning liquid flows down on the inclined surface portion 12H, and at that time, passes through the upper surface portion 18A of the heater 18. As a result, in addition to the water supply, foreign matter on the inclined surface portion 12H and foreign matter adhering to the upper surface portion 18A can be placed on the water and guided to the lower outlet 12E, and can be captured by the filter 25 at the outlet 12E. Therefore, it is not necessary to add water only for removing foreign matter on the inclined surface portion 12H or from the heater 18, so that the water saving performance can be improved. Further, according to the above, the foreign matter can be positively collected at the outlet 12E and captured by the filter 25 without being left accumulated on the bottom surface portion 12 or the heater 18.

Further, since a plurality of through holes 52B (see FIG. 4) are formed in the heater cover 52 that covers the heater 18 from the upper side Z1, the cleaning liquid can be poured from the through holes 52B into the heater 18. As a result, the cleaning liquid can be effectively heated by the heater 18, and foreign matter adhering to the heater 18 can be effectively removed by the force of the cleaning liquid flowing down from the through hole 52B.

The present invention is not limited to the embodiments described above, and various modifications can be made within the scope of the claims.

For example, in the above-described embodiment, the shoe washing device 1 is used by being incorporated in a washing machine stand (not shown), but may be incorporated in the washing machine itself, and in these cases, the shoe washing device 1 is used. The control unit 40 of 1 may execute the washing operation by receiving an instruction from the control unit of the washing machine. Of course, the shoe washing device 1 may exist independently without being incorporated in the washing machine stand or the washing machine. In that case, the frame 2 may be omitted and the main body 3 may not be slidable. ..

Further, in the above-described embodiment, the substantially right half of the bottom surface portion 12 is the first bottom surface portion 12A, and the substantially left half of the bottom surface portion 12 is the second bottom surface portion 12B. 2 The left and right positions of the bottom surface portion 12B may be reversed. Further, the substantially front half of the bottom surface portion 12 is one of the first bottom surface portion 12A and the second bottom surface portion 12B, and the substantially rear half of the bottom surface portion 12 is the other of the first bottom surface portion 12A and the second bottom surface portion 12B. There can be a configuration.

1 Shoe cleaning device 11 Storage room 12A 1st bottom surface 12B 2nd bottom surface 12C Recess 12D Bottom 12E Outlet 12H Inclined surface 18 Heater 18A Top surface 20 Injection port 25 Filter 29 Pump 52 Heater cover 52A Top surface 52B Through hole 53D Flow Entrance S Shoes Z1 Upper side Z2 Lower side

Claims (3)

A storage chamber that is closed from the lower side by a first bottom surface portion that is recessed downward and has a recess having an outlet at the bottom and a second bottom surface portion that extends laterally from the upper end of the recess, and stores shoes. ,
An injection port that injects cleaning liquid onto the shoes in the storage room,
A filter that is arranged at the outlet in the recess and captures foreign matter from the cleaning liquid that flows out of the storage chamber from the outlet.
A pump for sending the cleaning liquid that has passed through the filter and has flowed out of the storage chamber to at least the injection port.
A heater composed of vertically flat flat heaters and arranged in the recess at a position farther from the outlet than the filter, and a heater.
Including a heater cover arranged in the recess and covering the heater from above.
The second bottom surface portion is inclined so as to descend toward the recess, and the second bottom surface portion is inclined.
The bottom of the recess is provided with an inclined surface portion that descends toward the outlet.
The upper surface portion of the heater is arranged so as to be substantially flush with the inclined surface portion.
A shoe washing device in which an inlet of water supplied to the storage chamber is arranged in the recess at a position farther from the outlet than the heater . The shoe cleaning device according to claim 1 , wherein a plurality of through holes penetrating the heater cover up and down are formed in the heater cover. The shoe washing device according to claim 1 or 2 , wherein the upper surface portion of the heater cover is arranged at substantially the same height as the second bottom surface portion.

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