KR20210158765A - Shoe management device - Google Patents

Abstract

The present invention relates to a shoe management device. More particularly, it includes: an accommodating part for forming an accommodating space for shoes; a first supply part that is located on the upper side of the accommodating part, comprises a conduit for guiding the movement of fluid, and is extended toward the accommodating space; and a second supply part that is located inside the first supply part and protrudes in the longitudinal direction of the first supply part to supply the fluid to the shoes.

Description

Shoe management device {SHOE MANAGEMENT DEVICE}

The present invention relates to a shoe care device capable of facilitating the drying of the inside of the shoe.

In general, shoes worn every day are sweaty due to long-term use, and various bacteria are propagated inside the shoes.

Also, when it rains, shoes get wet with rainwater, so moisture and bacteria inside the shoes can cause bad odors or health problems.

Washing or natural drying is used to remove moisture and germs from the inside of the shoes, but washing or drying the shoes is cumbersome and takes a long time, so it is difficult to wear clean shoes every day.

In order to solve this problem, the prior art (Korean Patent Application Laid-Open No. 10-2020-0031889) provides a circular arrangement mounted shoe drying device. The prior art is connected to the heater unit and is provided with an inlet for supplying hot air to the internal space, and an outlet for exhausting the internal air, and is rotatably installed on the floor or upper surface of the drying chamber and the hot air supplied through the inlet is divided. One end is connected to the distribution hole of the rotating duct unit and the rotating duct unit provided with a plurality of distribution holes to be transported, and protrudes at an upward inclination angle so that the shoe is inserted downward, and a plurality of injection holes are formed to spray hot air supplied through the distribution hole in all directions. It includes a holding pipe part.

However, since the prior art provides a structure in which the holding tube is always exposed to the outside, there is a problem in that the shoes interfere with the holding tube during the operation of storing or taking out the shoes inside the shoe care device.

In addition, the prior art has a problem in that the drying of the shoes is not made uniformly because the direction of the air flow supplied to the inside of the shoes is fixed.

In addition, the prior art has a problem in that it is not possible to dry shoes with a height higher than that of sneakers, such as boots, because only low-height shoes such as sneakers can be dried. Therefore, there is a need to improve it.

The background technology of the present invention is published in Korean Patent Application Laid-Open No. 10-2020-0031889 (published on March 25, 2020, title of invention: Circular Arrangement Mounting Shoe Drying Device).

SUMMARY OF THE INVENTION An object of the present invention is to provide a shoe care device capable of preventing the shoes from interfering with other parts during the operation of storing shoes in the shoe management device or taking the shoes out of the shoe management device.

It is also an object of the present invention to provide a shoe care device capable of controlling the direction of the air flow supplied to the inside of the shoe.

Another object of the present invention is to provide a shoe care device that can be commonly used for drying low-height shoes such as sports shoes and drying shoes with a height higher than sports shoes such as boots.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention not mentioned may be understood by the following description, and will be more clearly understood by the examples of the present invention. It will also be readily apparent that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the appended claims.

Technical feature of the shoe management device according to the present invention for solving the above problems is to prevent the phenomenon that the shoes interfere with other parts during the operation of storing the shoes in the shoe management device or taking the shoes out of the shoe management device. do it with

Specifically, since the first supply unit, the second supply unit, and the third supply unit are located inside the receiving unit before the drying of the shoes or after the drying of the shoes is made, the operation of storing or taking out the shoes is performed in the receiving unit. The phenomenon of interference with other parts is prevented, making it easier to manage shoes.

In addition, the present invention is technically characterized in that the drying of the shoes is made uniformly by adjusting the direction of the air flow supplied to the inside of the shoes.

Specifically, the fluid can be supplied to the inside of the shoe in a state where the second supply unit extends downwardly of the first supply unit, and the third supply unit extending downward of the second supply unit bends in contact with the inner sole of the shoe, so the front of the shoe By supplying the fluid to the shoes can be uniformly dried.

In addition, the present invention is technically characterized in that it is commonly used for drying shoes with a low height such as sneakers and for drying shoes with a height higher than sports shoes such as boots.

Specifically, the second supply unit is operated in consideration of the height of the shoe in a state in which the first supply unit is rotated downward. And the second supply part and the third supply part extend in the longitudinal direction of the first supply part. Therefore, the shoe management device can be commonly used for drying shoes with a low height such as sneakers and for drying shoes with a height higher than sneakers such as boots.

A shoe care device according to an embodiment of the present invention includes at least one of a case unit, a storage unit, a first supply unit, a second supply unit, a third supply unit, a rotation restraint unit, a height measurement unit, and a control unit.

A shoe management device according to an embodiment of the present invention includes a storage unit forming a storage space for accommodating shoes on the inside, and a conduit for guiding the movement of a fluid located on the upper side of the storage unit, and a storage space It includes a first supply part extending toward the inside of the second supply part located inside the first supply part and protruding in the longitudinal direction of the first supply part for supplying a fluid to the inside of the shoe.

In addition, the receiving unit includes a footrest in which foreign substances falling from the shoes are stored inside. In addition, the footrest unit includes a fixed footrest installed on the lower surface of the receiving unit and a folding footrest positioned above the fixed footrest to perform a folding or unfolding operation.

In addition, the second supply unit includes a pipe body located inside the rotating pipe unit and moving in a straight direction along the rotating pipe unit, a second driving unit connected to the first supply unit and generating rotating power, and power of the second driving unit. It is a tube shape having a screw bar that receives and rotates and an inner gear corresponding to the outer gear of the screw bar, and linear movement is made along the screw bar by the rotation of the screw bar, and the lower side located below the pipe body part or the pipe body part It includes a core member connected to the conduit portion.

In addition, the second supply unit further includes a stopper protrusion protruding to the outside of the pipe body. In addition, the first supply unit further includes a guide groove portion for forming a groove extending in a straight direction on the inner side of the rotary tube portion facing the tube body portion. In addition, the second supply unit, forming an acute angle with the inner window, descends obliquely toward the inner window.

Also, the present invention provides a third supply unit that is installed in succession to the second supply unit, is bent forward of the shoe in contact with the inner sole of the shoe, and converts the discharge direction of the fluid moving downward along the second supply unit to the front of the shoe. include more In addition, the third supply unit is located below the second supply unit, and connects the lower conduit portion that is in contact with the inner sole of the shoe and bends forward of the shoe and the lower conduit portion and the second supply unit, and a variable conduit whose shape is changed by external force includes wealth. In addition, the third supply unit is rotatably installed on the lower side of the lower conduit portion, and further includes a roller member rotating in contact with the inner window.

In the shoe care device according to the present invention, since the first supply unit, the second supply unit, and the third supply unit are located inside the receiving unit before drying of the shoes or after the drying of the shoes is made, the shoes are stored in the receiving unit. It is possible to improve the user's convenience by preventing the shoes from interfering with other parts during the action of putting them on or taking them out.

In addition, in the present invention, the fluid can be supplied to the inside of the shoe in a state where the second supply unit extends to the lower side of the first supply unit, and the third supply unit extended to the lower side of the second supply unit bends in contact with the inner sole of the shoe. By supplying the fluid to the front, the drying of the shoes can be done quickly and uniformly.

In addition, the present invention can reduce the installation cost of the shoe management device because the shoe management device can be used in common for drying shoes with a height lower than that of sports shoes, such as sneakers, and for drying shoes with a height higher than sports shoes, such as boots.

In addition, the present invention, since the footrest is provided on the lower side of the shoe, foreign substances falling from the shoe are stored in the footrest unit and do not fall on other shoes on the lower side of the shoe, so that contamination of other shoes can be prevented.

In addition, in the present invention, since the second supply unit extends to the lower side of the first supply unit to increase the air volume of the fluid supplied to the shoe, the time and cost required for drying the shoe can be reduced.

In addition, in the present invention, since the stopper projection is moved along the guide groove portion, the straight line movement of the pipe body portion can be made stably.

In addition, in the present invention, since the roller member rotates in contact with the sole of the shoe, the third supply unit can easily bend the inside of the shoe, thereby improving the operational reliability of the device.

Also, according to the present invention, even when the position of the lower conduit portion is changed, the shape of the variable conduit portion is changed to smoothly supply the fluid to the lower conduit portion, thereby improving the operational reliability of the device.

In addition, in the present invention, since the second supply unit descends obliquely toward the inner sole at an acute angle with the inner sole, the third supply unit bends while obliquely in contact with the inner sole, so that the operation reliability of the third supply unit can be improved. have.

In addition to the above-described effects, the specific effects of the present invention will be described together while describing specific details for carrying out the invention below.

1 is a front perspective view of a shoe care device according to an embodiment of the present invention.
Figure 2 is a perspective view showing a state in which the rotary pipe section is folded upward according to an embodiment of the present invention.
3 is a perspective view illustrating a state in which the rotary pipe section is rotated downward according to an embodiment of the present invention.
4 is a perspective view illustrating a state in which the second supply part and the third supply part extend to the lower side of the lower pipe part according to an embodiment of the present invention.
5 is an exploded perspective view showing the main configuration of a shoe management device according to an embodiment of the present invention.
6 is a perspective view illustrating a state in which a second supply unit is connected to a rotary pipe part according to an embodiment of the present invention.
7 is an exploded perspective view of a rotary pipe unit and a second supply unit and a third supply unit according to an embodiment of the present invention.
8 is a perspective view illustrating a state in which a third conduit unit is installed in a bent shape according to an embodiment of the present invention.
9 is a perspective view illustrating an inner flow path of a shoe care device according to an embodiment of the present invention.
10 is a cross-sectional view illustrating a state in which the shoe care device according to an embodiment of the present invention is extended to the inside of the boot.
11 is a partially cut-away perspective view showing the main configuration of a shoe care device according to an embodiment of the present invention.
12 is a cross-sectional view showing the main configuration of a shoe care device according to an embodiment of the present invention.
13 is a cross-sectional view illustrating a state in which the second supply unit and the third supply unit are moved upward according to an embodiment of the present invention.
14 is a perspective view illustrating a state in which a screw bar and a core member are separated according to an embodiment of the present invention.
15 is a perspective view illustrating a state in which a screw bar and a core member are coupled according to an embodiment of the present invention.
16 is a perspective view illustrating a state in which the core member is moved upward along a screw bar according to an embodiment of the present invention.
17 is a perspective view illustrating a state in which a second driving part and a third driving part are extended from the rotating pipe part extending inside the receiving part according to an embodiment of the present invention.
18 is a cross-sectional view illustrating a state in which the third supply unit is bent in contact with the inner sole of the shoe according to an embodiment of the present invention.
19 is a perspective view illustrating an end of a third supply unit according to an embodiment of the present invention.
20 is a view illustrating a state in which the second supply unit extends downwardly to the lower side of the first supply unit according to an embodiment of the present invention.
21 is a view showing a state in which the third supply unit is in contact with the sole of the shoe according to an embodiment of the present invention.
22 is a view showing a state in which the third supply unit is bent forward of the shoe according to an embodiment of the present invention.
23 is a block diagram of a shoe management apparatus according to an embodiment of the present invention.

The above-described objects, features and advantages will be described below in detail with reference to the accompanying drawings, and accordingly, those of ordinary skill in the art to which the present invention pertains will be able to easily implement the technical idea of the present invention. In describing the present invention, if it is determined that a detailed description of a known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to indicate the same or similar components.

[Entire configuration of shoe management device]

1 is a front perspective view of a shoe care device 1 according to an embodiment of the present invention, and FIG. 9 is a perspective view showing an inner flow path portion 40 of the shoe care device 1 according to an embodiment of the present invention. and FIG. 10 is a cross-sectional view illustrating a state in which the shoe 300 management device according to an embodiment of the present invention is extended to the inside of the boot 320 .

1 and 9 and 10 , the shoe care device 1 according to an embodiment of the present invention may dry or sterilize the shoe 300 with steam, and the sole of the shoe 300 may be sterilized with steam. It may include various functions related to shoe 300 management, such as removing foreign substances attached to the shoe 300 .

The shoe care device 1 according to an embodiment of the present invention rotates with the case unit 10 , the receiving unit 50 , the first supply unit 90 , the second supply unit 180 , and the third supply unit 200 . It may include at least one of the restraint unit 220 , the height measurement unit 230 , and the control unit 240 .

[case part]

The case part 10 can be implemented with various modifications within the technical concept of having the electric chamber 20 for supplying a fluid for drying the shoes 300 . The case unit 10 according to an embodiment of the present invention includes at least one of the electric cabinet 20 , the water supply unit 30 , the water recovery unit 32 , the case body 34 , and the inner flow path unit 40 . may include

The electric compartment 20 constitutes a lower portion of the case portion 10 . A steam generator 24 and a main blower 22 are installed in the electric cabinet 20 . The steam generator 24 is a steam device that supplies steam for sterilization to the first supply unit 90 . The steam generator 24 generates steam by heating the supplied water. The steam generated from the steam generator 24 is supplied to the shoes 300 to shorten the time required for sterilization and deodorization of the shoes 300 .

The main blower 22 is connected to the steam generator 24 , and the steam generated from the steam generator 24 is fed to the first supply part 90 through the inner flow path part 40 provided inside the case part 10 . transmit A fan and a motor are installed inside the main blower 22 , and steam or air may be supplied to the first supply unit 90 through a passage provided inside the case unit 10 .

In addition, a water supply unit 30 for supplying water to the steam generator 24 is installed in the case unit 10 . The water supply unit 30 has a tank shape for storing water, and is detachably installed on the case body 34 .

And the water generated by the steam sprayed to the accommodating part 50 is collected by the water recovery part 32 . The water recovery unit 32 has a tank shape for storing the water collected by the receiving unit 50 , and is detachably installed on the case body 34 .

The inner flow passage 40 is a passage that connects the electric length chamber 20 and the first supply unit 90 , and the fluid passing through the electric length chamber 20 flows to the first supply unit 90 along the inner passage portion 40 . Move. The inner passage part 40 forms a passage inside the case body 34 forming the body of the case part 10 . An inner flow passage 40, which is a passage for moving air or steam, etc., is installed between the outer and inner surfaces of the case body 34 .

In the present invention, the fluid includes at least one of a gas including air and a liquid including water. When the shoes are dried, the fluid supplied to the first supply unit 90 is air. In addition, when the shoes 300 are washed or contaminated materials are removed, the fluid supplied to the first supply unit 90 may be steam or air including liquid.

Accordingly, the air supplied from the electric chamber 20 to the inner passage unit 40 may be supplied to the inside of the shoe 300 through the first supply unit 90 . Alternatively, the air supplied from the electric chamber 20 to the inner flow passage 40 is supplied to the inside of the shoe 300 through the first supply unit 90 , the second supply unit 180 , and the third supply unit 200 in sequence. do.

[storing department]

The accommodating part 50 is installed inside the case part 10 and forms a accommodating space 64 for accommodating the shoes 300 inside the accommodating part 50 . The accommodating part 50 has a box shape with an open front, and various modifications are possible within the technical idea for supporting the first supply part 90 . The accommodating part 50 according to an embodiment of the present invention may include at least one of an upper side surface 60 , a side surface 66 , a footrest part 70 , and a rear surface part 80 .

The upper surface 60 of the accommodating part 50 is located above the accommodating space 64 , and the first supply part 90 is installed. The upper surface 60 is installed in the horizontal direction or has a plate shape installed at an acute angle with the horizontal line. The upper surface 60 is provided with a moving hole 62, which is a hole through which the first supply unit 90 is moved. Two first supply units 90 according to an embodiment of the present invention are operated as a pair. Accordingly, the number of the long hole-shaped moving hole parts 62 provided on the upper side surface 60 is two.

The side surface 66 is located on both lower sides of the upper surface 60 and has a plate shape extending in the vertical direction. The upper side surface 60 and the side surface 66 are connected to each other, and are installed in a "C" shape that is opened toward the lower side.

The footrest part 70 is located on the lower side of the upper side surface 60, and various modifications can be made within the technical idea that foreign substances falling from the shoes 300 are stored inside. The footrest unit 70 according to an embodiment of the present invention is located on the upper side of the fixed footrest 73 and the fixed footrest 73 installed on the lower surface of the receiving unit 50, and performs a folding or unfolding operation. It may include a folding footrest (72).

A plurality of through-holes are formed on the upper side of the support foot plate 76 , and a space for storing foreign substances dropped from the shoe 300 is provided inside.

And the foldable footrest 72 is installed on the upper side of the support footrest 76. The shoes 300 with a low height such as the sports shoes 310 are placed on the upper side of the support foot 76 and the folding foot 72, respectively, and the drying of the shoe 300 and the cleaning of the shoe 300 can be performed.

The shoe 300, which has a higher height of the shoe 300 than the sneaker 310, such as the boot 320, put the boot 320 on the support foot 76 in the folded state of the folding foot 72 and use it. can The folding footrest 72 according to an embodiment of the present invention includes a fixed footrest 73 fixed to the inner side of the receiving unit 50 and a rotating footrest 74 that is rotatably installed on the fixed footrest 73 . do.

The fixed footrest 73 may be installed in a horizontal direction, and the rotating footrest 74 may be rotated and folded on the upper side of the fixed footrest 73 . In addition, the rotary footrest 74 may be installed side by side on the fixed footrest 73 by the unfolding operation. A plurality of through holes are formed in the upper side of the fixed footrest 73 and the rotating footrest 74 , and a space for storing foreign substances dropped from the shoe 300 is provided inside.

Since the footrest unit 70 is provided on the lower side of the shoe 300 , foreign substances falling from the shoe 300 are stored in the footrest unit 70 and do not fall to other shoes 300 located below the shoe 300 . Contamination of other shoes 300 can be prevented.

The rear portion 80 is installed on the rear side of the storage space 64 and has a plate shape extending in the vertical direction. In addition, the rear surface portion 80 may be installed in a shape to be in contact with or to face the inner flow passage portion 40 of the case portion 10 . In addition, the rear surface portion 80 may further include a ventilation hole portion 82 and a fan member 84 .

The ventilation hole 82 forms a slit-shaped air exhaust hole in the rear surface portion (80). Accordingly, a portion of the air moving to the first supply unit 90 through the inner flow passage 40 may move to the inside of the accommodation space 64 through the ventilation hole 82 .

And a fan member 84 for forcing the movement of air may be installed on the rear side of the vent hole 82, some of the air moving upward along the inner flow passage 40 by the operation of the fan member 84. moves to the inside of the accommodating part 50 through the ventilation hole part 82 .

The fan member 84 installed in the inner passage part 40 functions to forcibly blow air into the receiving part 50 through the ventilation hole part 82 . In addition, the fan member 84 forces the movement of the fluid so that the air or steam moving along the inner flow path part 40 can move to the inside of the accommodating part 50 .

[First supply unit]

Figure 2 is a perspective view showing a state in which the rotary pipe section 130 is folded upward according to an embodiment of the present invention, Figure 3 is a rotary pipe section 130 according to an embodiment of the present invention is rotated downward It is a perspective view showing a state, and FIG. 4 is a perspective view showing a state in which the second supply unit 180 and the third supply unit 200 are extended to the lower side of the lower conduit unit 202 according to an embodiment of the present invention, 5 is an exploded perspective view showing the main configuration of the shoe management device 1 according to an embodiment of the present invention.

2 to 5 , the first supply unit 90 is located above the receiving unit 50 , and a conduit for guiding the movement of the fluid is provided inside. In addition, the first supply unit 90 is provided with a pipe extending toward the inside of the receiving space 64 by various operation methods including rotation. The first supply unit 90 according to an embodiment of the present invention rotates a pipe for guiding the movement of the fluid, and directs the fluid supplied from the electric vehicle room 20 toward the inside of the accommodating unit 50 . guide

Only when the shoe 300 is placed on the inside of the receiving unit 50, the first supply unit 90 is operated to supply the fluid to the inside of the shoe 300 after the pipeline is moved to the inside of the receiving unit 50 have. And since the first supply unit 90 returns to the initial position after the drying of the shoes 300 placed in the receiving unit 50 is completed, the operation of taking out the shoes 300 from the receiving unit 50 can be easily performed. .

The first supply part 90 according to an embodiment of the present invention includes a fixed pipe part 100, a pipe bracket 110, a Yeonjin pipe part, a rotating pipe part 130, a first driving part 140, and a blowing part ( 150) and the heat exchange unit 160 may include at least one.

Before the shoe 300 is dried or after the shoe 300 is dried, since the first supply unit 90 is located inside the receiving unit 50 , the shoe 300 is placed in the receiving unit 50 . When storing or taking out the operation, it is possible to prevent the phenomenon that the shoe 300 interferes with other parts, thereby improving the user's convenience.

Since the first supply unit 90 is installed in a curved shape toward the inside of the receiving unit 50 by the rotation of the first supply unit 90, the air volume of the fluid supplied to the shoe 300 is increased to increase the flow rate of the shoe 300. The time and cost required for drying can be reduced.

[Fixed pipe part]

The fixed conduit unit 100 is located above the receiving unit 50 , and a conduit for guiding the movement of the fluid is provided inside. The fixed conduit part 100 is located above the receiving space 64, and movement is restricted. The fixed conduit unit 100 according to an embodiment of the present invention includes a first conduit unit 102 and a second conduit unit 106 .

The first conduit unit 102 is installed successively to the blower unit 150 and extends in the horizontal direction. And the second pipe section 106 is bent downward from the end of the first pipe section 102 is connected to the soft pipe section (120). In addition, the first conduit unit 102 includes an expanded conduit unit 104 in which the cross-sectional area of the inner conduit gradually increases in the direction from the second conduit unit 106 toward the blower 150 . A curved surface is formed on the inner side of the expansion pipe portion 104 . The expansion pipe part 104 may be formed in a fallopian tube shape, and is installed in a shape in which the cross-sectional area of the inner passage gradually increases toward the blower 150 .

Accordingly, the fluid passing through the blower 150 and flowing into the first conduit 102 passes through the expanded conduit 104 and gradually collects. Accordingly, the flow rate of the fluid moving to the soft pipe part 120 through the second pipe part 106 is increased. In addition, since the blower 150 is operated to increase the flow rate of the fluid supplied to the inside of the fixed pipe part 100 , the time required for drying the shoes 300 can be saved.

The fixed pipe part 100 is made in a "L" shape, and since the second pipe part 106 is curved along a curved shape, it passes through the first pipe part 102 and the second pipe part 106 in sequence. It is possible to reduce the increase in friction generated when the fluid is in contact with the inside of the fixed pipe part 100 .

[Cube Bracket]

The pipe bracket 110 supports the first pipe part 102 of the fixed pipe part 100 . The pipe bracket 110 may be fixed to at least one of the accommodating part 50 and the case part 10 . The pipe bracket 110 according to an embodiment of the present invention has a plate shape that has been erected, and supports the end of the first pipe section 102 . Accordingly, the pipe bracket 110 extends in the horizontal direction, and two first pipe parts 102 spaced apart in the horizontal direction are connected to the pipe bracket 110 . Also, the pipe bracket 110 may be positioned between the blower 150 and the fixed pipe part 100 .

[Soft pipe section]

6 is a perspective view illustrating a state in which the second supply unit 180 is connected to the rotation pipe unit 130 according to an embodiment of the present invention, and FIG. 7 is a rotation pipe unit 130 according to an embodiment of the present invention. and an exploded perspective view of the second supply unit 180 and the third supply unit 200 .

As shown in FIGS. 6 and 7 , the soft pipe part 120 is connected to the fixed pipe part 100 and can be deformed into various shapes within the technical idea that the shape is changed by the rotational operation. The soft conduit unit 120 according to the present invention has an upper side connected to the fixed conduit unit 100 and a lower side extending inside the rotating conduit unit 130 . Therefore, the connection pipe part guides the fluid received through the fixed pipe part 100 to the inside of the rotation pipe part 130 .

In addition, the soft pipe part 120 is a pipe having a plurality of bent shapes, and the fluid discharged to the inside of the rotary pipe part 130 through the soft pipe part 120 may move along a zigzag shape. The soft pipe part 120 according to an embodiment of the present invention is connected to the fixed pipe part 100 and has a first soft pipe 122 and a first soft pipe 122 that form a curved surface of a concave shape on one side. and a second soft tube 124 connected to and forming a curved surface of a convex shape on one side.

The first soft pipe 122 is connected to the lower end of the second pipe part 106, and forms a curved surface of a wave pattern shape toward the lower side. The second soft pipe 124 is connected to the lower end of the first soft pipe 122, and forms a curved surface of a wave pattern shape toward the lower side. The shapes of the first soft pipe 122 and the second soft pipe 124 are varied according to the position of the rotary pipe section 130 .

The cross-sectional areas of the inner passages of the first soft tube 122 and the second soft tube 124 are the same, and the fluid introduced into the first tube portion 102 through the expansion tube portion 104 is transferred to the second tube portion. It moves to the soft pipe part 120 through (106).

The soft pipe part 120 may be installed in a shape in which a curved surface is bent along a wave pattern shape, and may be deformed into various shapes, such as being formed in a spiral shape or bent in a twist shape. Therefore, the fluid supplied to the inside of the rotary pipe section 130 through the soft pipe section 120 can form a dynamic airflow.

Since the fluid supplied to the inside of the rotational pipe part 130 through the soft pipe part 120 moves in a zigzag shape, the shoes 300 can be dried uniformly.

The soft pipe part 120 may include silicon or rubber, and various materials may be used within the technical concept that the shape is deformed by an external force.

[Rotating pipe section]

The rotary pipe section 130 is connected to the soft pipe section 120 , and various modifications can be made within the technical idea located on the outside of the second supply section 180 . The rotary pipe section 130 receives the fluid supplied through the fixed pipe section 100 or the soft pipe section 120, and can be rotated or extended to the inside of the receiving space 64 by an operation moving in the longitudinal direction. have.

The rotary pipe section 130 according to an embodiment of the present invention is connected to the soft pipe section 120 and moves to the inside of the receiving space 64 by a rotating operation. The rotation pipe unit 130 is rotated by the operation of the first driving unit 140 , and when there is no shoe 300 inside the storage space 64 , it rotates upward of the storage space 64 . Accordingly, the rotary pipe section 130 is positioned inside the fixed housing section 170 through the moving hole section 62 provided on the upper side surface 60 .

And when the fluid is supplied to the inside of the shoe 300 , the rotation pipe 130 is rotated by the operation of the first driving unit 140 . The rotation pipe 130 is rotated inside the receiving unit 50 through the moving hole 62 and supplies the fluid toward the inside of the shoe 300 .

The rotary pipe unit 130 is rotatably installed in the fixed housing unit 170 , and rotates in the first mode in which the fixed housing unit 170 rotates inwardly by the rotating operation, and rotates in the receiving space 64 . is operated in the second mode.

When the first supply unit 90 does not operate, since the storage of the first supply unit 90 inside the fixed housing unit 170 is stably made, durability of parts can be improved.

The rotating conduit unit 130 is rotatably installed inside the fixed housing unit 170 , and one side forms an open conduit.

The rotary pipe section 130 according to an embodiment of the present invention forms the body of the rotary pipe section 130, and the rotary pipe body 132 is formed in a rectangular tube shape, and the length of the rotary pipe body 132 is It includes a guide groove portion 136 for forming a groove on the inner side of the rotation pipe body 132 along the direction.

The rotary pipe body 132 has one side and the other open, respectively, and the soft pipe part 120 is inserted into one side of the rotary pipe body 132 to supply a fluid to the inside of the rotary pipe body 132 .

In addition, hinge protrusions 134 are provided on both sides of the rotary pipe body 132 . The hinge protrusion 134 protruding to the outside of the rotary pipe body 132 is inserted into a groove provided on the inside of the fixed housing 170 and is rotatably installed. Hinge protrusions 134 are installed on both sides of the rotary pipe section 130 protruding upward of the upper side surface 60 , and these hinge protrusions 134 are fixed housing portions 170 fixed to the upper side of the upper side surface 60 . ) is rotatably installed.

A guide groove part 136 extends along the longitudinal direction of the rotation pipe part 130 . Two guide grooves 136 are installed in parallel to form a pair, and are installed at positions facing each other. And the stopper protrusion 184 provided in the second supply unit 180, which will be described later, is guided to linear movement along the guide groove portion 136 . And since the end of the guide groove portion 136 is provided with a locking protrusion, the stopper projection 184 is caught on the end of the guide groove portion 136 and is prevented from being separated to the outside of the rotation pipe portion 130 . Since the stopper protrusion 184 is moved along the guide groove portion 136 , the straight line movement of the pipe body portion 182 can be made stably.

[1st drive unit]

The first driving unit 140 is connected to the rotary pipe unit 130 , and various types of driving devices may be used within the technical idea of supplying rotational power to rotate the rotating pipe unit 130 . The first driving unit 140 according to an embodiment of the present invention includes a motor bracket 142 fixed to the accommodating unit 50 or fixed housing unit 170, and a rotation pipe part fixed to the motor bracket 142 ( It is shaft-connected to the center of rotation of 130 and includes a driving motor 144 for rotating the rotary pipe section 130 .

The driving motor 144 may be directly connected to the rotation center of the rotation pipe unit 130 , and the power of the driving motor 144 is moved to the transmission to increase the torque and then be connected to the rotation center of the rotation pipe unit 130 . may be

The motor bracket 142 is fixed to the upper surface 60 of the receiving unit 50 , and the driving motor 144 supported by the motor bracket 142 is installed in a shape that penetrates the side surface of the fixed housing unit 170 . do. And since the output shaft of the drive motor 144 is connected to the hinge protrusion 134 of the rotary pipe section 130, the rotary pipe section 130 including the hinge protrusion 134 by the operation of the drive motor 144 rotates. do.

The driving motor 144 may use a servo motor or a step motor, and may be operated by a control signal of the controller 240 to rotate the rotation pipe unit 130 at a set angle.

[Blower]

The blower 150 is installed successively to the fixed conduit unit 100 , and various modifications are possible within the technical idea of blowing air into the fixed conduit unit 100 . The blower 150 according to an embodiment of the present invention includes a rotating fan, and is located at the entrance of the fixed conduit unit 100 .

The blower 150 is installed at a position facing the expansion pipe part 104 . The blower 150 installed between the expansion pipe part 104 and the inner flow path part 40 increases the flow rate of air moving from the inner flow path part 40 toward the expansion pipe part 104 . The operation and rotation speed of the blower 150 are controlled by the controller 240 .

[Heat Exchanger]

The heat exchange unit 160 is installed in succession to the blower unit 150 , and various types of heat exchange devices may be used within the technical concept of exchanging heat with the fluid flowing into the blower unit 150 . The heat exchange unit 160 according to an embodiment of the present invention performs heat exchange with a fluid using the Peltier effect. The heat exchange unit 160 includes a Peltier element 162 , a first heat exchange plate 164 and a second heat exchange plate 166 .

The Peltier element 162 may be used as a temperature controller such as a cooler or a warmer by using a phenomenon in which the junction is cooled when an electric current is passed after joining two different types of metal. The Peltier element 162 is formed in a plate shape, and the temperature is varied by power supply. In order to supply a fluid having a temperature higher than room temperature to the inside of the shoe 300 , the first heat exchange plate 164 facing the inlet of the fixed pipe part 100 is heated. And, when the room temperature is a high temperature of 30° C. or higher, such as in summer, the first heat exchange plate 164 may be cooled to lower the temperature of the dried shoes 300 .

The first heat exchange plate 164 is connected to one side of the Peltier element 162 and exchanges heat with the fluid flowing into the blower 150 . The first heat exchange plate 164 according to an embodiment of the present invention is provided with a plate shape in contact with the Peltier element 162, and a plurality of heat exchange plates are installed on the side facing the fixed pipe part 100 to exchange heat with the fluid. area is increased

Therefore, since the area in contact with the first heat exchange plate 164 of the fluid passing through the first heat exchange plate 164 to the fixed pipe part 100 is increased, the heat exchange efficiency of the heat exchange part 160 can be improved.

The second heat exchange plate 166 is connected to the other side of the Peltier element 162, and exchanges heat with the fluid. The second heat exchange plate 166 according to an embodiment of the present invention is provided with a plate shape in contact with the Peltier element 162, and a plurality of heat exchange plates are installed in a direction opposite to the first heat exchange plate 164 to exchange heat with the fluid. area is increased.

Accordingly, since the area in which the fluid passing through the periphery of the second heat exchange plate 166 comes into contact with the second heat exchange plate 166 is increased, the heat exchange efficiency of the heat exchange unit 160 can be improved.

In addition, during the drying operation of the shoe 300 , the heat exchange unit 160 is operated to adjust the temperature of the fluid supplied to the shoe 300 , so the time required for drying the shoe 300 can be reduced.

[Fixed housing part]

As shown in FIG. 5 , the fixed housing 170 is fixed to the accommodating part 50 , and the rotating pipe part 130 and the second supply part 180 rotated upward of the accommodating part 50 are located. An inner space 175 is provided. The fixed housing part 170 surrounds the soft pipe part 120 and is fixed to the accommodating part 50 . In addition, the fixed housing unit 170 is installed in an open shape at the lower side, and has an inner space 175 in which the rotating conduit unit 130 rotated to the upper side of the receiving unit 50 is located.

The inner space 175 of the fixed housing 170 communicates with the moving hole 62 of the upper surface 60 . Accordingly, the second supply unit 180 and the third supply unit 200 that rotate together with the rotation pipe unit 130 may be located in the inner space 175 of the fixed housing unit 170 .

With the installation of the fixed housing unit 170 , it is possible to block the leakage of the fluid moving upward of the receiving unit 50 through the moving hole 62 of the receiving unit 50 . In addition, it is possible to prevent a phenomenon in which foreign substances on the inside of the case part 10 fall into the storage space 64 through the moving hole 62 .

[Second supply unit]

8 is a perspective view illustrating a state in which a third conduit unit is installed in a bent shape according to an embodiment of the present invention, and FIG. It is a partially cut-away perspective view, and FIG. 12 is a cross-sectional view showing the main configuration of the shoe care device 1 according to an embodiment of the present invention.

As shown in FIGS. 8, 11 and 12 , the second supply unit 180 is located inside the first supply unit 90 , and protrudes downward of the first supply unit 90 to the inner side of the shoe 300 . Various modifications are possible within the technical idea of supplying fluid with The second supply unit 180 is connected to the first supply unit 90 , and extends downward from the first supply unit 90 rotated toward the inside of the receiving unit 50 .

Accordingly, since the second supply unit 180 increases the length of the flow path for supplying the fluid, the fluid received through the first supply unit 90 can be easily supplied to the inside of the shoe 300 . The second supply unit 180 is connected to the first supply unit 90 , and extends toward the inside of the shoe 300 from the first supply unit 90 rotated toward the inside of the receiving unit 50 . Accordingly, the fluid supplied to the rotation pipe 130 of the first supply unit 90 is moved toward the shoe 300 through the second supply unit 180 .

Since the second supply unit 180 extends downward of the first supply unit 90 to increase the air volume of the fluid supplied to the shoe 300 , the time and cost required for drying the shoe 300 can be reduced.

The second supply unit 180 according to an embodiment of the present invention includes at least one of the pipe body portion 182, the stopper protrusion 184, the second driving unit 186, the screw bar 190, and the core member 196. may contain one.

[pipe body part]

The pipe body part 182 is located inside the rotary pipe part 130 and moves in a straight direction along the rotary pipe part 130 to extend the length of the pipe for guiding the fluid. The conduit body portion 182 according to an embodiment of the present invention is located inside the rotary conduit unit 130, and has a rectangular tube shape with both sides open.

The conduit body 182 according to an embodiment of the present invention is a conduit extending in a linear direction, and a rectangular passage is provided inside.

Since the pipe body part 182 moves in a straight direction along the inside of the rotary pipe part 130 , a section guiding the movement of the fluid discharged to the lower side of the rotary pipe part 130 may be extended. And the stopper protrusion 184 in the shape of a protrusion protruding to the outside of the conduit body 182 is caught by the guide groove 136 provided inside the rotary conduit 130 to guide movement in a straight direction. The stopper protrusion 184 protrudes from both sides of the conduit body portion 182 and is rotatably inserted into the fixed housing portion 170 .

The second supply unit 180 includes a stopper protrusion 184 protruding to the outside of the pipe body portion 182 . The first supply part 90 includes a guide groove part 136 that forms a groove extending in a straight direction on the inner side of the rotary pipe part 130 facing the pipe body part 182 . Accordingly, the stopper protrusion 184 is guided in a straight line along the guide groove portion 136 .

The second driving unit 186 is connected to the first supply unit 90 and generates rotational power, so that at least one of the second supply unit 180 and the third supply unit 200 is moved in the longitudinal direction of the first supply unit 90 . Various types of driving devices can be used within the technical idea of moving. The second driving unit 186 according to an embodiment of the present invention uses a motor that receives electric energy and generates rotational power.

The second driving unit 186 is fixed to the inner side of the rotation pipe unit 130 , and a screw bar 190 is connected to an output shaft of the second driving unit 186 . The screw bar 190 rotates by receiving power from the second driving unit 186 . When the rotary pipe section 130 is rotated downward, the rotary pipe section 130 is installed in a vertical direction or an acute angle with a vertical line and inclined.

The second supply unit 180 according to an embodiment of the present invention forms an acute angle with the inner sole 302 of the shoe 300 and descends obliquely toward the inner sole 302 . Accordingly, the second supply unit 180 or the second supply unit 180 and the third supply unit 200 pass sequentially, and the air flow supplied to the inside of the shoe 300 comes into contact with the inner sole 302 and moves toward the inside of the shoe 300 . Since the movement is inclined, the time and cost required for drying the shoes 300 can be reduced.

The second supply unit 180 descends obliquely toward the inner sole 302 at an acute angle with the inner sole 302, so that the third supply unit 200 bends while obliquely in contact with the inner sole 302. Operation reliability of the third supply unit 200 may be improved.

In addition, the third supply unit 200 is connected to the lower side of the second supply unit 180, and the third supply unit 200 is obliquely in contact with the inner sole 302, and the bending operation of the third supply unit 200 can be easily induced. Therefore, the movement of the fluid supplied to the inside of the shoe 300 can be made more easily.

13 is a cross-sectional view illustrating a state in which the second supply unit 180 and the third supply unit 200 are moved upward according to an embodiment of the present invention, and FIG. 14 is a screw bar according to an embodiment of the present invention. 190) is a perspective view showing a state in which the core member 196 is separated, and FIG. 15 is a perspective view showing a state in which the screw bar 190 and the core member 196 are coupled according to an embodiment of the present invention, 16 is a perspective view illustrating a state in which the core member 196 is moved upward along the screw bar 190 according to an embodiment of the present invention.

13 to 16 , the second driving unit 186 is fixed to the rotary pipe section 130 , and the screw bar 190 extends downward along the rotary pipe section 130 . The screw bar 190 has a rod shape extending in the longitudinal direction of the rotary pipe section 130 , and a gear having a male thread shape is provided on the outside of the screw bar 190 .

The screw bar 190 is located inside the rotating pipe part 130 and the pipe body part 182 and rotates in the forward or reverse direction by the operation of the second driving part 186 .

The core member 196 is connected to the outside of the screw bar 190 , and various modifications are possible within the technical idea in which the screw bar 190 is moved in the longitudinal direction along the screw bar 190 by rotation of the screw bar 190 .

The core member 196 according to an embodiment of the present invention has a tube shape in which an inner gear corresponding to the outer gear of the screw bar 190 is provided. In addition, the core member 196 is linearly moved along the screw bar 190 by the rotation of the screw bar 190 , and the lower pipe part located below the pipe body part 182 or the pipe body part 182 . 202 is connected.

The core member 196 may be directly connected to the pipe body part 182 or the lower pipe part 202, and if necessary, to be connected to the pipe body part 182 or the lower pipe part 202 through a separate member. may be

The core member 196 according to an embodiment of the present invention has a soft tube shape, and the screw bar 190 is inserted and connected to the inside of the core member 196 on the outside of the screw bar 190 . A gear having a female thread shape connected to the selected gear is provided.

The fixed support part 197 is connected to the core member 196 and the pipe body part 182, respectively. Accordingly, the conduit body portion 182 , the fixed support portion 197 , and the core member 196 are located inside the rotating conduit unit 130 , and are moved along the longitudinal direction of the rotating conduit unit 130 .

The fixed support 197 is connected to the upper portion of the core member 196 and is installed to surround the outside of the core member 196 . In addition, since the protrusion protruding from the fixed support 197 is fixed to the inside of the conduit body 182, the fixed support 197, the core member 196, and the conduit body 182 move together.

[3rd supply unit]

The third supply unit 200 is installed successively to the second supply unit 180 , is in contact with the inner sole 302 of the shoe 300 , and is bent forward of the shoe 300 . The third supply unit 200 is capable of various modifications within the technical idea of converting the discharge direction of the fluid moving downward along the second supply unit 180 toward the front of the shoe 300 .

The third supply unit 200 moves together with the conduit body 182 by the operation of the second driving unit 186, is in contact with the inner sole 302 of the shoe 300, and is a conduit that bends to the inside of the shoe 300. can be formed In addition, when the third supply unit 200 is spaced apart from the shoe 300 , the shape is transformed from the bent pipe to a straight pipe again.

Since the third supply unit 200 is in contact with the inner sole of the shoe 300 and is bent toward the front of the shoe 300 , the time and cost required for drying the shoe 300 can be reduced.

The third supply unit 200 according to an embodiment of the present invention may include at least one of a lower conduit unit 202 , a variable conduit unit 208 , a roller member 209 , and a sterilization unit 212 . .

[Lower conduit part]

17 is a perspective view showing a state in which the second driving part 186 and the third driving part are extended from the rotating pipe part 130 extending inward of the receiving part 50 according to an embodiment of the present invention, FIG. 18 is a cross-sectional view showing a state in which the third supply unit 200 according to an embodiment of the present invention is bent while in contact with the inner sole 302 of the shoe 300, and FIG. 19 is a third supply unit ( 200) is a perspective view showing the end.

17 to 19 , the lower conduit portion 202 is located below the second supply unit 180 , is in contact with the inner sole 302 of the shoe 300 , and is bent forward of the shoe 300 . it is a conduit The lower pipe part 202 of the third supply part 200 is located inside the rotation pipe part 130 of the first supply part 90 together with the pipe body part 182 of the second supply part 180 .

The lower conduit portion 202 is formed in a rectangular tube shape, and both sides of the lower conduit portion 202 have an open shape. And the lower conduit portion 202 descends toward the inner sole 302 at an acute angle with the inner sole 302 of the shoe 300 . When the lower conduit portion 202 descends perpendicularly to the inner window 302 , the fluid discharged from the lower conduit portion 202 comes in contact with the inner window 302 and then moves to the upper side of the inner window 302 again. . Therefore, when the rotation pipe 130 is rotated toward the shoe 300 , the virtual line extending from the rotation pipe part 130 forms an acute angle with the horizontal line. In addition, the imaginary lines extending from the second supply unit 180 and the third supply unit 200 protruding downward of the rotary pipe unit 130 also form an acute angle with the horizontal line.

Therefore, in a state in which the second supply unit 180 and the third supply unit 200 are located inside the first supply unit 90 , the fluid discharged to the lower side of the first supply unit 90 is the inner sole 302 of the shoe 300 . It is obliquely collided with and can easily move forward of the shoe 300 .

Alternatively, in a state in which the second supply unit 180 and the third supply unit 200 extend downward of the first supply unit 90 , the roller member 209 provided in the third supply unit 200 is installed on the inner sole of the shoe 300 . Since it moves while being in contact with 302 , the shape of the third supply unit 200 may be deformed into a curved shape. The fluid may be supplied to the front of the shoe 300 through the third supply unit 200 deformed into a curved shape.

[Variable Pipeline]

The variable conduit unit 208 connects the lower conduit unit 202 and the second supply unit 180, and various modifications are possible within the technical idea that the shape is changed by an external force. The variable pipe part 208 according to an embodiment of the present invention is made of a corrugated pipe having elasticity, and is deformed in shape to be bent by an external force. In addition, the variable pipe part 208 is deformed into a straight pipe shape in a state in which the external force is removed.

Even when the position of the lower conduit unit 202 is changed, the shape of the variable conduit unit 208 is changed to smoothly supply the fluid to the lower conduit unit 202 , thereby improving the operational reliability of the device.

[Roller member]

The roller member 209 is rotatably installed on the lower side of the lower conduit part 202, and rotates in contact with the inner sole 302 of the shoe 300, so as to induce a bending operation of the third supply unit 200 and the third supply unit ( 200) to reduce the frictional force.

The roller member 209 is rotatably installed on the roller bracket 204 protruding from the lower pipe part 202 toward the rear window of the shoe 300 . A roller bracket 204 is installed on the side of the lower conduit 202 facing the rear surface 80 of the receiving part 50 , and the roller member 209 is rotatably installed on the roller bracket 204 .

Since the roller member 209 rotates in contact with the sole of the shoe 300 , the third supply unit 200 bends the inside of the shoe 300 easily, thereby improving the operation reliability of the device.

[Sterilization Department]

The sterilization unit 212 is installed on the lower side of the lower conduit portion 202, and irradiates a light for sterilization toward the inside of the shoe 300. The sterilization unit 212 may use an LED that generates UVC ultraviolet rays, and in addition, various types of light sources may be used as the sterilization unit 212 to irradiate the sterilization light.

The sterilization unit 212 is installed on the lower side of the third supply unit 200, and sterilizes the inside of the shoe 300 by irradiating light. Also, the sterilization unit 212 is operated under the control of the control unit 240 .

Since the sterilization unit 212 is operated to sterilize the shoe 300 with the sterilizing light, it is possible to block the transmission of pathogens through the shoe 300 .

[Rotation restraint part]

The rotation constraint 220 restricts the rotation of the core member 196, and allows for linear movement of the core member 196 along the lower conduit 202. Various modifications can be made within the technical idea. The rotation restraint unit 220 according to an embodiment of the present invention may include a rotation restraint protrusion 222 and a rotation restraint groove portion 224 .

The rotation restraining protrusion 222 can be deformed into various shapes within the technical idea of connecting the core member 196 to the lower conduit portion 202 . The core member 196 is connected to the inner side of the lower conduit portion 202 through the rotation restraining protrusion 222 . The rotation restraining protrusion 222 is located outside the lower portion of the core member 196 , is fixed to the core member 196 , and is installed to be movable in the longitudinal direction of the lower conduit portion 202 together with the core member 196 .

The rotation constraining protrusion 222 positioned inside the lower conduit portion 202 is inserted into the rotation constraining groove 224 formed inside the lower conduit portion 202 . Since the rotation restriction protrusion 222 is inserted into the rotation restriction groove portion 224, the rotation of the core member 196 is restricted, and the linear movement of the core member 196 along the longitudinal direction of the lower conduit portion 202 is allowed. .

The rotation restraining projection 222 is installed in a ring shape surrounding the lower side of the core member 196, and the projection provided on the rotation restraining projection 222 is a rotation restraining groove portion 224 provided on the inner side of the lower conduit portion 202. is inserted into

The rotation constraint groove portion 224 has a groove shape formed on the inner side of the lower conduit portion 202 along the longitudinal direction of the lower conduit portion 202 . Since the rotation restriction protrusion 222 is inserted into the rotation restriction groove portion 224 to allow sliding movement, when the lower conduit portion 202 located at the lower side of the rotation tube portion 130 is installed in a bent shape, the core member ( 196) is connected to the rotation restraint projection 222 is moved along the rotation restraint groove (224).

The length of the rotation constraint groove 224 is set in consideration of the length at which the rotation constraint protrusion 222 slides when the lower conduit portion 202 moves in a bent shape.

[Height measurement part]

23 is a block diagram of a shoe management device 1 according to an embodiment of the present invention.

As shown in FIGS. 1 and 23 , the height measuring unit 230 is installed inside the receiving unit 50 , and measuring the height of the shoes 300 accommodated in the receiving unit 50 , the control unit 240 . It is possible to implement various modifications within the technical idea of delivering measured values to In the height measuring unit 230 according to an embodiment of the present invention, a plurality of measuring sensors 232 are installed in the vertical direction along the side surface 66 of the receiving unit 50 .

The control unit 240 may receive the measurement value of the height measurement unit 230 and operate only the first supply unit 90 . Alternatively, the control unit 240 may receive the measurement value of the height measurement unit 230 and sequentially operate the first supply unit 90 and the second supply unit 180 .

In the present invention, by installing the folding footrest 72 and the height measuring unit 230, the drying of the low-height shoes 300, such as the sneakers 310, and the height of the sneakers 310, such as the boots 320, are Since the shoe management device 1 can be used in common for drying the high shoes 300 , the installation cost of the shoe management device 1 can be reduced.

[Sequential operation of the first supply unit, the second supply unit, and the third supply unit]

Hereinafter, an operating state of the shoe care device 1 according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

20 is a view illustrating a state in which the second supply unit 180 is extended downward of the first supply unit 90 according to an embodiment of the present invention, and FIG. 21 is a third supply unit according to an embodiment of the present invention. 200 is a view showing a state in contact with the sole of the shoe 300, and FIG. 22 is a view showing a state in which the third supply unit 200 according to an embodiment of the present invention is bent forward of the shoe 300 It is a drawing.

As shown in FIGS. 3 and 20 to 22 , in the state where the shoe 300 is not in the receiving unit 50 , the rotation pipe 130 is rotated upward and the fixed housing located at the upper side of the upper surface 60 . It is located in the inner space 175 of the part 170 . Therefore, in the operation of the user placing the shoe 300 in the receiving unit 50 , the phenomenon that the shoe 300 collides with the rotation pipe unit 130 can be prevented.

3 , when the shoe 300 is placed in the receiving unit 50 , the measurement sensor 232 of the height measuring unit 230 detects the shoe 300 and sends a signal to the control unit 240 . . In addition, since a plurality of measurement sensors 232 are installed in the height measurement unit 230 in the vertical direction, the height measurement unit 230 measures the height of the shoe 300 and transmits the measurement value to the control unit 240 .

The control unit 240 determines whether to operate only the first driving unit 140 or the first driving unit 140 and the second driving unit 186 based on the measured height of the shoe 300 , the first It is determined whether to operate the driving unit 140 , the second driving unit 186 , and the third driving unit.

When the control unit 240 operates the first driving unit 140 , the rotary pipe unit 130 rotates by the power of the first driving unit 140 . The rotation pipe section 130 located inside the fixed housing unit 170 is rotated to the lower side of the upper side surface 60 to stop at a position where the fluid can be supplied toward the inside of the shoe 300 .

And, in order to protrude the pipe body part 182 to the lower side of the rotary pipe part 130 , the controller 240 operates the second driving part 186 . The screw bar 190 rotates by the operation of the second driving unit 186 , and the core member 196 geared to the outside of the screw bar 190 moves downward along the screw bar 190 .

The core member 196 has a hollow screw thread engaged with the screw thread provided on the outside of the screw bar 190 , and is connected by a fixing support part 197 to restrict rotation. The core member 196 is fixed to the inside of the pipeline body 182 through the fixing support 197, and since the pipeline body 182 is located inside the rotating pipe 130, the pipeline body 182 of rotation is constrained.

The lower movement of the core member 196 moves the pipe body 182 to the lower side, and the lower pipe part 202 located below the pipe body 182 also rotates the core member through the constraint 220 as a medium. (196) is connected to the lower side. Accordingly, as the core member 196 moves downward, the pipe body part 182 and the lower pipe part 202 move downward.

Meanwhile, the fluid is supplied to the first supply unit 90 through the inner passage unit 40 provided in the case unit 10 . The fluid moving through the inner flow passage 40 may be air that does not contain steam or air that includes steam.

In the case of air that does not contain steam, the air that has passed through the main blower 22 of the electric vehicle room 20 is supplied. The air discharged from the main blower 22 moves upward through the inner flow path part 40 provided inside the case part 10 .

Some of the air moving through the inner flow passage part 40 is supplied to the inside of the receiving part 50 through the ventilation hole part 82 of the rear part 80 to dry the shoes 300 . Due to the operation of the fan member 84 installed on the rear side of the rear surface portion 80 , the operation of supplying some of the air moving upward along the inner flow path portion 40 to the ventilation hole portion 82 can be made easier.

The air moved to the first supply unit 90 through the inner flow passage 40 may be supplied to the inside of the shoe 300 to dry the shoe 300 .

On the other hand, when air containing steam is supplied to the inner flow passage 40 , the steam generated by the steam generator 24 is moved to the inner passage 40 together with the air discharged from the main blower 22 , and then the receiving unit Move to the upper side where (50) is located.

The air moved to the first supply unit 90 through the inner flow passage 40 is supplied to the inside of the shoe 300 to sterilize the shoe 300 or remove the smell of the shoe 300 for various purposes. can be used

The air supplied through the inner flow passage 40 passes through the heat exchange unit 160 , and after being heated or cooled to a set temperature, moves to the inside of the fixed tube portion 100 through the blower 150 . And the air moved to the inside of the rotary pipe part 130 through the soft pipe part 120 connected to the fixed pipe part 100 forms a wave-shaped airflow by the shape of the soft pipe part 120, and the rotating pipe part Move to the lower side of (130).

The air moved to the lower side of the lower conduit 202 passes through the conduit body 182, the variable conduit 208, and the lower conduit 202 in turn, and is supplied to the inside of the shoe 300 to provide the shoe 300. dry the inside of

Meanwhile, the air supplied to the inside of the receiving unit 50 through the ventilation hole 82 of the receiving unit 50 dries the outside of the shoe 300 .

At this time, the conduit body 182 extends to the lower side of the rotary conduit 130, and the variable conduit 208 and the lower conduit 202 are sequentially connected to the lower side of the conduit body 182 and extend in a straight direction. installed in a tubular shape. Accordingly, the air discharged through the first supply unit 90 , the second supply unit 180 , and the third supply unit 200 forms an airflow in a straight direction toward the inside of the shoe 300 .

And when the control unit 240 operates the second driving unit 186 to further move the pipe body 182 downward, the roller member 209 located below the third supply unit 200 causes the inner sole of the shoe 300 to move. In contact with the 302, the third supply unit 200 forms a curved conduit.

The third supply unit 200 descends obliquely toward the inner sole 302 of the shoe 300 , and the lower conduit 202 centered on the variable conduit 208 while the roller member 209 is in contact with the inner sole 302 . ) is rotated by a predetermined angle. The length of the variable conduit 208 is increased by the rotation of the lower conduit portion 202 , and the rotation restraining protrusion 222 is moved along the rotation restraining groove 224 .

The core member 196 functions to elevate the second supply unit 180 and the third supply unit 200 and to maintain the shape of the third supply unit 200 installed in a curved shape.

Accordingly, the air moved to the conduit body 182 of the second supply unit 180 through the first supply unit 90 passes through the variable conduit unit 208 and the lower conduit unit 202 in turn, and the inner side of the shoe 300 is supplied to dry the shoes 300 .

Since the third supply unit 200 forms a conduit in a bent state, it is possible to uniformly and quickly dry the inside of the shoe 300 .

In addition, various modifications such as steam or a deodorant may be included in the air supplied to the inside of the shoe 300 . And the sterilization unit 212 installed in the lower conduit portion 202 is operated to sterilize the bacteria on the inside of the shoe 300 .

[Only the first supply unit operates]

The shoe 300 management device according to the present invention may install only the first supply unit 90 without installing the second supply unit 180 and the third supply unit 200 .

When the shoe 300 is placed in the receiving unit 50 , the measurement sensor 232 of the height measuring unit 230 detects the shoe 300 and sends a signal to the control unit 240 . In addition, since a plurality of measurement sensors 232 are installed in the height measurement unit 230 in the vertical direction, the height measurement unit 230 measures the height of the shoe 300 and transmits the measurement value to the control unit 240 .

The control unit 240 operates the first driving unit 140 based on the measured height of the shoe 300 . Accordingly, the rotation pipe unit 130 rotates by the power of the first driving unit 140 . The rotation pipe section 130 located inside the fixed housing section 170 is rotated inside the receiving section 50 to stop at a position where air can be supplied toward the inside of the shoe 300 .

And the air supplied through the inner flow passage 40 is supplied to the inside of the shoe 300 through the rotation tube portion 130 . When the first supply unit 90 is not used, the rotary pipe unit 130 is rotated upward of the receiving unit 50, and only when the first supply unit 90 is used, the rotating pipe unit 130 rotates to the receiving unit ( 50) extends inward.

In addition, since a conduit for supplying air toward the inside of the shoe 300 is additionally installed compared to the method of simply supplying air in the direction in which the shoe 300 is placed in the receiving unit 50, the air supplied to the inside of the shoe 300 is additionally installed. The amount is increased, thereby significantly reducing the time and cost required for drying the shoes 300 and managing the shoes 300 .

[Only the second supply unit operates]

The shoe 300 management device according to the present invention can be installed in a fixed type that maintains the rotation pipe section 130 provided in the first supply section 90 is extended toward the inside of the receiving section 50 without being rotated. have.

In addition, the second supply unit 180 is installed inside the rotary pipe section 130 installed in a fixed type, so that the elevating operation can be performed.

When the shoe 300 is placed in the receiving unit 50 , the measurement sensor 232 of the height measuring unit 230 detects the shoe 300 and sends a signal to the control unit 240 . In addition, since a plurality of measurement sensors 232 are installed in the height measurement unit 230 in the vertical direction, the height measurement unit 230 measures the height of the shoe 300 and transmits the measurement value to the control unit 240 .

The control unit 240 operates the second driving unit 186 based on the measured height of the shoe 300 . The control unit 240 operates the second driving unit 186 to move the conduit body 182 to the lower side of the rotary conduit unit 130 .

Accordingly, the air moved to the conduit body 182 of the second supply unit 180 through the first supply unit 90 is supplied to the inside of the shoe 300 to dry the shoe 300 .

The conduit for supplying air toward the inner side of the shoe 300 is extended by the operation of extending the second supply unit 180 to the lower side of the rotary conduit unit 130 . The amount of air supplied to the inside of the shoe 300 is increased by the operation of the second supply unit 180 , and the time and cost required for drying the shoe 300 and managing the shoe 300 are significantly reduced. .

[Only the 2nd and 3rd supply units operate]

The shoe 300 management device according to the present invention can be installed in a fixed type that maintains the rotation pipe section 130 provided in the first supply section 90 is extended toward the inside of the receiving section 50 without being rotated. have.

In addition, the second supply unit 180 and the third supply unit 200 are installed inside the rotating conduit unit 130 installed in a fixed type, so that the elevating operation can be performed.

When the shoe 300 is placed in the receiving unit 50 , the measurement sensor 232 of the height measuring unit 230 detects the shoe 300 and sends a signal to the control unit 240 . In addition, since a plurality of measurement sensors 232 are installed in the height measurement unit 230 in the vertical direction, the height measurement unit 230 measures the height of the shoe 300 and transmits the measurement value to the control unit 240 .

In order to protrude the pipe body part 182 to the lower side of the rotary pipe part 130 , the controller 240 operates the second driving part 186 . The screw bar 190 rotates by the operation of the second driving unit 186 , and the core member 196 geared to the outside of the screw bar 190 moves downward along the screw bar 190 .

The core member 196 has a hollow screw thread engaged with the screw thread provided on the outside of the screw bar 190 , and is connected by a fixing support part 197 to restrict rotation. The core member 196 is fixed to the inside of the pipeline body 182 through the fixing support 197, and since the pipeline body 182 is located inside the rotating pipe 130, the pipeline body 182 of rotation is constrained.

The lower movement of the core member 196 moves the pipe body 182 to the lower side, and the lower pipe part 202 located below the pipe body 182 also rotates the core member through the constraint 220 as a medium. (196) is connected to the lower side. Accordingly, as the core member 196 moves downward, the pipe body part 182 and the lower pipe part 202 move downward.

Accordingly, the air moved to the second supply unit 180 and the third supply unit 200 through the first supply unit 90 is supplied to the inside of the shoe 300 to dry the shoe 300 .

Since the conduit for supplying air toward the inside of the shoe 300 is extended by the operation of extending the second supply unit 180 and the third supply unit 200 to the lower side of the rotation pipe unit 130, the shoe 300 is inside. The amount of supplied air is increased, thereby significantly reducing the time and cost required for drying the shoes 300 and managing the shoes 300 .

And when the control unit 240 operates the second driving unit 186 to further move the pipe body 182 downward, the roller member 209 located below the third supply unit 200 causes the inner sole of the shoe 300 to move. In contact with the 302, the third supply unit 200 forms a curved conduit.

The third supply unit 200 descends obliquely toward the inner sole 302 of the shoe 300 , and the lower conduit 202 centered on the variable conduit 208 while the roller member 209 is in contact with the inner sole 302 . ) is rotated by a predetermined angle. The length of the variable conduit 208 is increased by the rotation of the lower conduit portion 202 , and the rotation restraining protrusion 222 is moved along the rotation restraining groove 224 .

The core member 196 functions to elevate the second supply unit 180 and the third supply unit 200 and to maintain the shape of the third supply unit 200 installed in a curved shape.

Accordingly, the air moved to the conduit body 182 of the second supply unit 180 through the first supply unit 90 passes through the variable conduit unit 208 and the lower conduit unit 202 in turn, and the inner side of the shoe 300 is supplied to dry the shoes 300 .

Since the third supply unit 200 forms a conduit in a bent state, it is possible to uniformly and quickly dry the inside of the shoe 300 .

As described above, the present invention has been described with reference to the illustrated drawings, but the present invention is not limited by the embodiments and drawings disclosed in this specification, and various methods can be obtained by those skilled in the art within the scope of the technical spirit of the present invention. It is obvious that variations can be made. In addition, although the effects according to the configuration of the present invention have not been explicitly described and described while describing the embodiments of the present invention, it is natural that the effects predictable by the configuration should also be recognized.

1: Shoe management device
10: case part
20: electric cabinet 22: main blower 24: steam generator 30: water supply 32: water recovery part 34: case body 40: inner flow passage part
50: storage unit
60: Upper side 62: Moving hole 64: Storage space 66: Side surface 70: Footrest 72: Folding foot 73: Fixed foot 74: Rotating foot 76: Support foot 80: Back side 82: Ventilation hole 84: Fan member
90: first supply unit
100: fixed conduit unit 102: first conduit unit 104: expanded conduit unit 106: second conduit unit
110: pipe bracket 120: soft pipe section 122: first soft pipe 124: second soft pipe
130: rotary pipe section 132: rotary pipe body 134: hinge projection 136: guide groove 140: first driving section 142: motor bracket 144: drive motor 150: blower unit
160: heat exchange unit 162: Peltier element 164: first heat exchange plate 166: second heat exchange plate
170: fixed housing portion 175: inner space
180: second supply unit
182: pipe body part 184: stopper projection 186: second driving part 190: screw bar 196: core member 197: fixed support part
200: third supply unit
202: lower pipe section 204: roller bracket 208: variable pipe section 209: roller member 212: sterilization section
220: rotation restraint portion 222: rotation restraint projection 224: rotation restraint groove portion
230: height measuring unit 232: measuring sensor
240: control unit
300: shoes 302: insoles 310: sneakers 320: boots

Claims (21)

a storage unit forming a storage space for accommodating shoes inside;
a first supply part located above the accommodating part, having a conduit for guiding the movement of the fluid provided therein, and extending toward the accommodating space; and
A shoe care device comprising a; located inside the first supply unit, the second supply unit protruding in the longitudinal direction of the first supply unit to supply the fluid to the shoe.
According to claim 1,
The fluid is a shoe care device comprising at least one of a gas containing air and a liquid containing water.
According to claim 1,
The receiving unit may include: an upper surface on which the first supply unit is installed;
a side surface located on both lower sides of the upper surface and extending in the vertical direction; and
Shoe management device comprising a; located on the lower side of the upper side, the footrest for storing foreign substances falling from the shoe inside.
4. The method of claim 3,
The footrest unit, a fixed footrest installed on the lower surface of the receiving unit; and
Shoe management device comprising a; is located on the upper side of the fixed footrest, and performs a folding or unfolding operation.
4. The method of claim 3,
a plurality of height measurement units installed in the vertical direction along the side surface and measuring the height of the shoes; and
Shoe management device further comprising a; control unit for receiving the measurement value of the height measurement unit to control the operation of the second supply unit.
According to claim 1,
The first supply unit may include: a fixed conduit unit located above the storage space and constrained to move; and
Shoe care device comprising a; receiving the fluid supplied through the fixed pipe, the rotation pipe extending into the storage space.
7. The method of claim 6,
The second supply unit may include: a conduit body located inside the rotating conduit unit and moving in a linear direction along the rotating conduit unit;
a second driving unit connected to the first supply unit and generating rotational power;
a screw bar rotating by receiving power from the second driving unit; and
A tube shape having an inner gear corresponding to the outer gear of the screw bar, linear movement is made along the screw bar by rotation of the screw bar, and the lower conduit is located below the conduit body or the conduit body. A shoe care device comprising a; core member connected to the unit.
8. The method of claim 7,
The second supply unit further includes a stopper protrusion protruding to the outside of the pipe body part;
The first supply unit may further include a guide groove portion for forming a groove extending in a straight direction on the inner side of the rotary tube portion facing the tube body portion,
The stopper projection is a shoe management device that is guided in a straight line movement along the guide groove.
According to claim 1,
A third supply unit that is installed in succession to the second supply unit, is in contact with the inner sole of the shoe, is bent forward of the shoe, and converts the discharge direction of the fluid moving downward along the second supply unit to the front of the shoe; Further comprising a shoe care device.
10. The method of claim 9,
The third supply unit, located below the second supply unit, in contact with the inner sole of the shoe, the lower conduit portion bent forward of the shoe; and
A shoe care device comprising a; a variable conduit that connects the lower conduit portion and the second supply unit, the shape of which is changed by an external force.
11. The method of claim 10,
The variable pipe section is made of a corrugated pipe having elasticity, and the shoe care device is deformed in shape to be bent by an external force.
11. The method of claim 10,
The lower conduit part forms an acute angle with the inner sole and descends toward the inner sole.
11. The method of claim 10,
The third supply unit, a roller member that is rotatably installed on the lower side of the lower conduit portion, and rotates in contact with the inner sole; shoe care device further comprising a.
14. The method of claim 13,
The roller member is a shoe care device that is rotatably installed on the roller bracket that protrudes from the lower conduit toward the rear window of the shoe.
a case unit having an electrical chamber for supplying a fluid for drying shoes;
a accommodating part forming a accommodating space for accommodating shoes inside the case part;
a first supply part located above the accommodating part, having a conduit for guiding the movement of the fluid provided therein, and extending toward the inside of the accommodating space;
a second supply unit located inside the first supply unit and protruding in the longitudinal direction of the first supply unit to supply a fluid to the shoe; and
A third supply unit that is installed in succession to the second supply unit, is in contact with the inner sole of the shoe, is bent forward of the shoe, and converts the discharge direction of the fluid moving downward along the second supply unit to the front of the shoe; A shoe care device comprising.
16. The method of claim 15,
The case unit may further include an inner flow path connecting the electrical equipment chamber and the first supply unit.
The fluid supplied from the electric chamber to the inner flow path is supplied to the shoes through the first supply unit, the second supply unit, and the third supply unit sequentially.
16. The method of claim 15,
The second supply unit may include: a pipe body located inside the rotation pipe part provided in the first supply part and moving in a straight direction along the rotation pipe part;
a second driving unit connected to the first supply unit and generating rotational power;
a screw bar rotating by receiving power from the second driving unit; and
A tube shape having an inner gear corresponding to the outer gear of the screw bar, linear movement is made along the screw bar by rotation of the screw bar, and the lower conduit is located below the conduit body or the conduit body. A shoe care device comprising a; core member connected to the unit.
18. The method of claim 17,
The core member is in the shape of a soft tube, and the screw bar is inserted into and connected to a shoe care device.
18. The method of claim 17,
The shoe care device further comprising a; rotation constraint for restricting the rotation of the core member and allowing the linear movement of the core member along the lower conduit section.
16. The method of claim 15,
The third supply unit, located below the second supply unit, in contact with the inner sole of the shoe, the lower conduit portion bent forward of the shoe; and
A shoe care device comprising a; a variable conduit that connects the lower conduit portion and the second supply unit, the shape of which is changed by an external force.
16. The method of claim 15,
The second supply unit, forming an acute angle with the inner sole, a shoe management device for descending obliquely toward the inner sole.

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