WO2015072634A1

WO2015072634A1 - Device for sterilizing and drying shoes

Info

Publication number: WO2015072634A1
Application number: PCT/KR2014/003519
Authority: WO
Inventors: 전나영; 백형래
Original assignee: (주)아이디어스
Priority date: 2013-11-13
Filing date: 2014-04-22
Publication date: 2015-05-21
Also published as: KR101405048B1

Abstract

The present invention relates to a device for sterilizing and drying shoes, the device comprising: a body having a plurality of first blowing ducts formed such that sterilizing and drying air passes therethrough; drying units installed inside the plurality of first blowing ducts, respectively, each drying unit comprising a heater and a blowing fan installed adjacent to the heater to supply air to the heater; and a plurality of second blowing ducts rotatably fastened to the plurality of first blowing ducts so as to communicate with the plurality of first blowing ducts, wherein each of the plurality of second blowing ducts comprises a plurality of first air discharge portions for discharging wind, which has been supplied from the drying units, through upper surfaces towards bottom surfaces inside shoes and spacing members for spacing the bottom surfaces inside shoes from the upper surfaces such that sterilizing and drying air flows into the shoes through the first air discharge portions. Accordingly, the first air discharge portions are prevented from being closed by bottom surfaces inside shoes, thereby substantially improving shoe interior drying efficiency.

Description

Shoe Sterilization and Drying Equipment

The present invention relates to a shoe sterilization and drying apparatus, and more particularly, to a shoe sterilization and drying apparatus that is sterilized at the same time while drying the shoe as a whole by supplying the air throughout the shoe.

In general, washed shoes are allowed to dry naturally, such as by placing them at an angle in the sun or shade or hanging them on a drying rack.

However, such a drying method takes too much time to dry, and in the rainy season or winter, it is almost impossible to dry because of the rain and low temperature, rather there was a problem that mold and the like occurs inside the shoe.

In addition, since it is impossible to wash leather shoes such as shoes or boots, the inconvenience of having to dry the shoes often occurs. In addition, when left in the state of removing the moisture in the shoe, the hygiene state is very poor, such as a bad smell while breeding bacteria such as mold.

In order to improve such a conventional problem, Korean Laid-Open Patent Publication No. 2006-0016821 discloses a shoe drying apparatus including a machine room, a shoe drying room, a circulation fan, a heater tube, and the like.

However, in the case of ankle or high-heeled shoes, there was a problem in that the shoe drying room must be made large.

In addition, the drying air is not effectively provided inside the shoe takes a long time to dry, and unnecessarily a lot of dry air is supplied to the outside of the shoe to dry the inside of the shoe may cause deformation due to expansion and contraction, thereby There is a problem that the life is shortened.

The present invention has been devised to solve the above problems, it is possible to significantly increase the drying efficiency of the shoe by configuring the wind to be distributed and supplied throughout the inside of the shoe, so that it is dried while maintaining the original shape of the shoe as it is It is to provide a shoe sterilization and drying device that can prevent the deformation and life of the shoes that can occur during the drying process.

In addition, it provides a shoe sterilization and drying device that can effectively dry the interior of the shoe even if the shape of the foot surface is different depending on the height of the heel or the shoe shape is high, such as a shoe with a high ankle portion, such as boots. have.

Accordingly, an object of the present invention is to solve such a conventional problem, the body is formed with a plurality of first blowing duct through which sterilization and dry air passes; A drying unit having a heater and a blowing fan installed adjacent to the heater to supply air to the heater, the drying unit being installed inside the plurality of first blowing ducts; A plurality of second blowing ducts communicating with the plurality of first blowing ducts and rotatably fastened to the plurality of first blowing ducts; Each of the plurality of second air blowing ducts may include a plurality of first air exhaust parts through which wind supplied from the drying part is discharged to an upper surface of the second air blowing duct so as to face the bottom surface of the shoe, and the bottom surface of the shoe. And a second blowing duct having a separation member spaced apart from the separation member to allow the sterilization and drying air to flow into the shoe through the first air discharge unit.

The first blowing duct includes a hinge shaft; The second blowing duct further includes a hinge hole for receiving the hinge shaft; The second blowing duct may be fastened to a variable angle from the first blowing duct along the hinge axis.

Here, the second blowing duct is formed by fastening the upper plate forming the upper surface and the lower plate forming the lower surface; A semi-circular first hinge hole forming portion is formed on one side of the upper plate, and a semi-circular second hinge hole forming portion facing the first hinge hole forming portion is formed on one side of the lower plate, and the upper plate and the lower plate are fastened. As such, the first hinge hole forming part and the second hinge hole forming part may face each other to form the hinge hole.

In addition, one of the upper end of the first blowing duct and the lower end of the second blowing duct is formed with a locking projection, the other is formed with a locking groove corresponding to the locking projection, the second blowing duct is the first blowing duct It can be maintained at a variable angle state from.

On the other hand, the second blowing duct is a first upper surface member convexly disposed toward the outside of the second blowing duct, and the second upper surface member concavely disposed toward the inside of the second blowing duct is in the longitudinal direction The first air discharge part may be alternately disposed along the first upper surface member and the second upper surface member.

Here, it is preferable that both ends of at least one of the second upper surface members protrude upward.

The drying unit of the present invention further comprises a casing member for guiding the air supplied from the heater and the blowing fan to the first blowing duct and forming a limited space surrounding the outside of the blowing fan; A partition wall may be formed in the main body to allow each of the casing members to be seated therein, and the partition wall may form a chamber with the casing member to be seated therein.

In addition, the second blowing duct may further form a second air discharge portion formed on the lower end side of the second blowing duct.

The apparatus may further include an ultraviolet lamp formed to be exposed to the outside of the second blowing duct.

The apparatus may further include a temperature sensor installed inside the second air duct so as to be adjacent to the first air outlet or the second air outlet.

In addition, the main body may further include a control unit for controlling the operation of the drying unit and the operation of the ultraviolet lamp according to the temperature sensor.

According to the present invention according to the configuration as described above, the object of the present invention is to solve such a conventional problem, the drying efficiency of the shoe is remarkably improved by configuring the wind to be distributed and supplied throughout the inside of the shoe It is possible to increase, and to maintain the original shape of the shoe is dried, so that the shoe disinfection and drying apparatus that can prevent the deformation and life shortening of the shoes that can occur in the drying process is provided.

In addition, the shoe sterilization and drying apparatus is provided that can effectively dry the inside of the shoe even if the shape of the foot is different according to the height of the heel, or in the form of shoes, such as in the case of a shoe with a high ankle, such as boots. .

In addition, since the first air discharge portion is formed on the upper surface of the second ventilation duct from which the wind is discharged so as to be spaced apart from the bottom surface of the shoe, it is easy to discharge the wind, thereby improving drying efficiency and preventing malfunction.

1 is a perspective view of a shoe sterilization and drying apparatus of the present invention,

Figure 2 is an exploded perspective view of the shoe sterilization and drying apparatus of Figure 1,

3 is a perspective view of a part cut in the state of FIG.

Figure 4 is an explanatory view showing a part of the configuration of the shoe disinfection and drying apparatus of the present invention,

5 and 6 are cross-sectional views taken along line AA ′ of FIG. 1 for explaining angle adjustment of the second blowing duct according to an embodiment of the present invention.

7 is a view showing a connection structure of the first blowing duct and the second blowing duct according to an embodiment of the present invention,

8 is a reference diagram as a shoe sterilization and drying apparatus of the present invention,

9 is a view showing a second blowing duct in which a first air discharge unit is formed according to an embodiment of the present invention;

10 is a view showing a second blowing duct in which a second air discharge unit is formed according to an embodiment of the present invention;

FIG. 11 is a cross-sectional view taken along line BB ′ of FIG. 2.

In the embodiment of the shoe sterilization and drying apparatus of the present invention, the main body 5 having the first blowing duct 10 formed on both sides toward a top spaced apart by a predetermined distance; A drying unit (14) having a heater (12) and a blowing fan (13) installed adjacent to the heater (12) and installed in each of the first blowing ducts (10); A plurality of first air exhaust portion 17 through which the wind supplied from the drying unit 14 is discharged on the upper surface to face the bottom surface of the shoe, and the bottom surface of the shoe spaced apart from the upper surface It is preferable to include a second blower duct 20 having a spacer 25 to allow the first air outlet 17 to have an open state.

Hereinafter, with reference to the accompanying drawings will be described embodiments of the present invention;

According to the present invention, one side of the main body 5 accommodates a control device for controlling power, temperature, operating time and sterilization, the first blowing duct 10 vertically coupled to the main body 5, and the first A drying unit 4 accommodated in the one blowing duct 10 and blowing warm air to the second blowing duct;

The lower end is supported by the hinge shaft 16 formed horizontally on the upper end of the first blowing duct 10, the upper end of the angle is changed around the hinge shaft 16, the warm air supplied from the first blowing duct 10 A second blowing duct 20 having

air discharge portions

17 and 24 discharged to the outside, and a temperature sensing sensor installed inside the second blowing duct 20 adjacent to the

air discharge portions

17 and 24. (Not shown) and an ultraviolet lamp 50.

An embodiment of such a configuration will be described.

1 is a perspective view of a shoe sterilization and drying apparatus of the present invention, Figure 2 is an exploded perspective view of the shoe sterilization and drying apparatus of FIG. Referring to FIGS. 1 and 2, the shoe disinfection and drying apparatus according to the present invention includes a main body 5 in which a plurality of first blowing ducts 10 through which sterilization and drying air pass are formed.

And, the drying unit which is provided adjacent to the heater 12 and the blower fan 13 which supplies air to the heater 12, and is provided in each of the 1st blowing air duct 10 ( 14) and a plurality of second blowing ducts 20 in communication with the plurality of first blowing ducts 10 and rotatably fastened to the plurality of first blowing ducts 10.

Here, each of the second blower ducts 20 includes a plurality of first air outlets 17 through which the wind supplied from the drying unit 14 is discharged to the upper surface so as to face the bottom surface of the inside of the shoe, and the inside of the shoe. Spacer members 25 are spaced apart from the upper surface to allow sterilization and dry air to flow into the shoe through the first air outlet 17.

An operation according to such a configuration will be described in more detail by way of example.

If the operation setting button is operated after the power is supplied, the control unit operates the drying unit 14 according to a preset program, and the second blowing duct is configured to generate wind generated by the operation of the heater 12 and the blowing fan 13. Blow on (20). Therefore, the warm air is discharged to the outside through the

air discharge units

17 and 24 formed in the second blowing duct 20.

For example, the control unit may generate the warm air by operating the blower fan 13 and the heater 12 at the same time, or supply the room temperature wind by operating only the blower fan 13 independently. Accordingly, the blower fan 13 and the heater 12 are selectively operated by setting through the control unit.

The control unit may include a power supply and an operation setting button provided outside the main body 5, a blowing fan 13, a heater 12, and an ultraviolet lamp 50 provided at the side of the first blowing duct 10 and the second blowing duct 20. For example, a microprocessor mounted on a PCB connected to a temperature sensor (not shown) and disposed inside the main body is an example. The description of the PCB mounted to the electronic component and the components mounted on the PCB will be omitted, but the controller is not only controlled according to the user's operation setting, for example, the heater 12 or the second blowing duct 20 by the temperature sensor. It detects the temperature of the air discharged from the function to automatically control the operation of the heater 12 to a predetermined value.

FIG. 9 is a view illustrating a second air blowing duct in which a first air exhaust unit 17 is formed according to an embodiment of the present invention, and FIG. 10 is a second air exhaust unit 24 according to an embodiment of the present invention. 2 is a view showing a ventilation duct. Referring to FIG. 9 and FIG. 10, the wind supplied to the second blowing duct 20 may include the first air exhausting unit 17 and the second air exhausting unit 24 formed in the second blowing duct 20. Through the second blowing duct 20 is discharged to the outside.

And, as shown in FIG. 9, the second blower duct 20 includes a plurality of first air discharge units 17 and shoes in which wind supplied from the drying unit 14 is discharged toward the bottom surface of the shoe. A spacer 25 is formed to space the bottom surface from the upper surface of the second blowing duct 20 so that the first air discharge unit 17 is in an open state. As shown in FIG. The blowing duct 20 has a second air discharge portion 24 formed on the lower end side of the second blowing duct 20.

Although not shown, the UV lamp 50, the first air outlet 17 and the second air outlet in a state where the shoe is inserted and mounted in the second air duct 20 while the upper surface is turned upside down. The inside of the shoe is sterilized and dried by 24.

In this case, the shoes may be hung by varying the angle around the hinge shaft 16 formed in the first blowing duct 10 according to the shoe size and the type of shoes.

Then, when the shoe drying is completed by detecting the set time or a separate humidity sensor to stop the power supply to the drying unit 14 and sterilize the inside of the shoe using an infrared lamp 50 to sterilize as needed do.

In more detail with respect to the first air exhaust unit 17, the upper surface of the second blowing duct 20 is the first air exhaust through the first upper surface member 28 and the second upper surface member 27 It consists of forming 17.

The first upper surface member 28 is formed such that a circumferential surface having a predetermined width is formed so that the outer circumference faces outward toward the outer surface of the second blowing duct 20, that is, the upper portion of the second blowing duct 20. Thus, the upper surface of the second blowing duct 20 has a convex shape of approximately '∩' shape.

The second upper surface member 27 is formed such that a circumferential surface having a predetermined width is formed such that an outer circumference thereof faces inward toward the inside of the second blowing duct 20, and thus an upper portion of the second blowing duct 20 is formed. It has a concave state in the shape of approximately '' in the plane.

The first upper surface member 28 and the second upper surface as the first upper surface member 28 and the second upper surface member 27 are alternately disposed in the transverse direction along the longitudinal direction of the second blowing duct 20. The first air outlet 17 is formed between the members 27.

Here, the first upper surface member 28 and the second upper surface member 27 is an example that is formed when the injection molding the upper plate 22 forming the upper surface of the second blowing duct 20, but not limited thereto. no.

1 and 9, in the present invention, the spacer 25 is formed to protrude upward at both ends of at least one second upper surface member 27.

The spacer 25 formed on both sides of the second upper surface member 27 has a second air blowing duct having a first air discharge unit 17 formed on the bottom surface of the shoe together with the convex first upper surface member 28. It is supported in a state spaced apart from the upper surface of the 20) to enable a smooth discharge of air.

Meanwhile, as shown in FIG. 10, the second air discharge part 24 is formed in a plurality of long holes to be inwardly communicated with the second blower duct 20 on the lower end side of the second blower duct 20. The second air discharge unit 24 allows the wind to be discharged toward the upper side of the approximately front heel of the mounted shoe, and the second air duct 20 having a predetermined size is provided by the gravity of the shoe itself. Since 24 is naturally spaced apart from the upper surface of the mounted shoe, unlike the first air outlet 17, a configuration for opening the second air outlet 24 is unnecessary.

According to the second air discharge part 24, it is possible to dry up to the deep part of the shoe mounted on the second blowing duct 20.

On the other hand, in the present invention, the ultraviolet lamp 50 is formed to be exposed to the outside of the second blowing duct 20, as shown in FIG. For example, the ultraviolet lamp 50 is installed at the end of the second blower duct 20 to sterilize and disinfect the inside of the shoe through the ultraviolet lamp 50 to function together with drying to prevent the growth of microorganisms in the interior. Keep your shoes in good condition.

The ultraviolet lamp 50, through the control unit to sterilize the inside of the shoe when the operation time of the drying unit 14 set from the control unit is completed, or when the drying of the shoe is completed by a separate humidity sensor (not shown). It operates in the set state.

Next, a configuration in which the second blowing duct 20 connected to the hinge shaft 16 of the first blowing duct 10 is changed to maintain the angle at the variable angle is described.

5 and 6 are cross-sectional views taken along line AA ′ of FIG. 1 for explaining angle adjustment of the second blowing duct according to an embodiment of the present invention. 5 shows a state in which the second blowing duct 20 stands up at the end of the first blowing duct, and FIG. 6 shows a state in which the second blowing duct 20 is laid down at the end of the first blowing duct.

7 is a view illustrating a connection structure between a first blowing duct and a second blowing duct according to an exemplary embodiment of the present invention. 5 to 7, in the present invention, the second blowing duct 20 is provided so as to change an angle from the first blowing duct 10.

As shown in FIG. 7, the locking projection 21 is formed by injection molding on the lower rear surface of the first blowing duct 10, and the upper side of the second blowing duct 20 is also formed on the locking projection 21 by injection molding. The locking groove 11 is formed to be locked.

As a result, the locking projections 21 and the locking grooves 11 corresponding to the locking projections 21 are formed on one of the upper ends of the first blowing duct 10 and the lower end of the second blowing duct 20. When the second blower duct 20 is erected vertically, the catching jaw 11 and the catching protrusion 21 are engaged with each other so that the second blower duct 20 is maintained vertically.

On the contrary, as shown in FIG. 6, when the second blowing duct 20 is changed, the locking projection 21 of the second blowing duct 20 is released from the locking groove 11 of the first blowing duct 10. The angle is variable.

More specifically, the first blowing duct 10 has a hinge axis 16 in the horizontal direction formed on the end side facing the second blowing duct 20, and the hinge shaft ( A hinge hole 26 is formed to accommodate 16, and the hinge shaft 16 of the first blower duct 10 is accommodated in the hinge hole 26 of the second blower duct 20 so that the hinge shaft 16 is received. By rotating along, the angle of the second blowing duct 20 is variably fastened.

Figure 4 is an explanatory view showing a part of the configuration of the shoe disinfection and drying apparatus of the present invention. As shown in FIGS. 4 and 7, the second blower duct 20 is injection molded into the upper plate 22 and the lower plate 23 to form a semi-circular first hinge hole at one end of the inner side of the upper plate 22. The lower plate 23 forms a semi-circular second hinge hole forming portion 25 facing the first hinge hole forming portion 25 at an inner side end portion of the lower plate 23. The first hinge hole forming portion 24 and the second hinge hole forming portion 25 wrap the hinge shaft 16 on the hinge shaft 16 of the blower duct 10 and then use the process unit to form the upper plate 22. ) And the lower plate 23 is a fixed configuration so as not to be separated.

More specifically, the second blowing duct 20 may include an upper plate 22 forming an upper surface of the second blowing duct 20, and a lower plate 23 forming a lower surface of the second blowing duct 20. The fastening is formed, the end of the upper plate 22 and the lower plate 23 which is fastened to the side of the first blowing duct 10 has a joint structure of the joint shape to enable angle adjustment.

A semi-circular first hinge hole forming portion 24 is formed at one end of the upper plate 22 constituting the joint structure of the joint shape, and a semi-circle facing the first hinge hole forming portion 24 at one end of the lower plate 23. The first hinge hole forming part 24 and the second hinge hole forming part 25 face each other as the second hinge hole forming part 25 having a shape is fastened and the upper plate 22 and the lower plate 23 are fastened to each other. A hinge hole 26 is formed to enclose and accommodate the hinge shaft 16.

In addition, the upper plate 22 and the lower plate 23 are fixed by fastening pins such as screws in the overlapping state, and the upper plate 22 and the lower plate 23 are fixed so as not to be separated from each other.

As described above, the semi-circular first hinge hole forming portion 24 is formed on the upper plate 22, and the semi-circular second hinge hole forming portion 25 is formed on the lower plate 23, and is formed in the first blowing duct 10. By enclosing the hinge shaft 16, when the second blower duct 20 is connected to the first blower duct 10, the variable structure of the fastening and joint shape is achieved, thereby reducing the parts.

In addition, the hinge shaft 16 of the first blower duct 10, which has not been described above, is formed during the injection molding process of the first blower duct 10.

On the other hand, in the present invention, one of the upper end of the first blowing duct 10 and the lower end of the second blowing duct 20 is formed with a locking projection, the other is formed with a locking groove 13 corresponding to the locking projection. Thus, the second blowing duct 20 is formed to be maintained in a variable angle state from the first blowing duct 10.

As shown in FIGS. 5 to 7, when the second blowing duct 20 stands in the vertical direction, the catching protrusion is accommodated in the catching groove 13 to maintain the standing state, and conversely, the second blowing air in the standing state. When a force is applied to lay the duct 20, the locking projection is separated from the locking groove 13 of the first blowing duct 10 and the angle is variable.

In the exemplary embodiment of the present invention, the locking protrusion is formed at the lower end of the second blowing duct 20, and the locking groove 13 is formed at the upper end of the first blowing duct 10, but the positional change is possible.

According to such a configuration, when the second blower duct 20 is erected vertically, the catching protrusion is caught in the catching groove 13 so that the second blower duct 20 is maintained vertically. Since the angle is variable in the state in which the second blowing duct 20 is coupled to the first blowing duct 10, the second blowing duct 20 can be laid down as shown in FIG. In addition, as shown in FIG. 5, the second blower duct 20 can stand in a vertical state to easily mount shoes of a kind such as boots that cover the upper end of the ankle, even shoes having various sizes and shapes. Sterilization and drying are possible.

FIG. 11 is a cross-sectional view taken along line BB ′ of FIG. 2. Referring to FIG. 3 and FIG. 11 together, the drying unit 14 according to the embodiment of the present invention includes a heater 12, a blowing fan 13, and a casing member 33.

The casing member 33 guides the air supplied from the blowing fan 13 to the first blowing duct 10, and forms a limited space surrounding the outside of the blowing fan 13. In addition, a heater 12 is accommodated in the upper end side of the casing member 33, and a blower fan 13 that blows heat radiated from the heater 12 upward is mounted at the lower end side.

In addition, the discharge hole 34 of the casing member 33 through which the wind is discharged is narrowly formed, and a part of the wind blown from the blower fan 13 is vortexed toward the heater 12 to heat exchange again in the heater 12 being heated. It is formed to lose.

The reason for the secondary heat exchange as described above is that the wind of the blowing fan is weak in this application. The weak wind has not been heat-exchanged with the entire heater 12 being heated, and has been found to be discharged through the discharge port 14 'through experiments.

That is, when the wind of the blower fan 13 is not strong enough, the wind having a weak intensity is discharged without sufficient heat exchange with the entire heater 12 being heated so that the heater 12 is heated to an appropriate temperature or more. A problem arises.

For reference, when the wind supplied by the blower fan 13 does not exchange heat smoothly with the heater 12 being heated and the heater 12 is heated, the periphery of the material inside the main body 5 including the casing member 33. It causes the problem of deformation of the material.

Of course, when the heater 12 is heated, a bimetal switch that cuts off the power supply may be mounted on the heater 12, but the bimetal switch is a safety device, and there is a limit in controlling the operating power of the heater 12 at all times.

According to this problem, the discharge port 34 is designed to be narrow so that the wind supplied through the blower fan 13 is vortexed. The vortexed wind increases the time to stay in the casing member 33 so that the heat exchanges with the heater 12 sufficiently.

In this case, improving the performance of the blower fan 13 may be one method for the heat exchange problem, but as the blower fan 13 becomes larger, it is generally more efficient because the secondary problem of noise and power consumption can be solved. .

On the other hand, the partition wall 19 is formed in the main body 5 so that the casing member 33 may be seated inside. Referring again to FIG. 2, the partition walls 19 are respectively formed upwardly to have a predetermined height on the bottom member 14 of the main body 5 in correspondence with the positions of the drying sections 14 on both sides. Each partition wall 19 allows the casing member 33 to be seated so that the blower fan 13 and the heater 12 can be stably operated.

In addition, the partition wall 19 is the casing member 33 is seated and forms a chamber inside the main body 5, when the blower fan 13 operates, the operation of the blower fan 13 is respectively installed on both sides Do not interfere with the flow of air. Accordingly, the intake hole 18 formed in the side member 15 of the main body 5 enables smooth intake, which is effective for sterilization and drying of shoes.

Although some embodiments of the invention have been shown and described, it will be apparent to those skilled in the art that modifications may be made to the embodiment without departing from the spirit or spirit of the invention. . It is intended that the scope of the invention be defined by the claims appended hereto and their equivalents.

The present invention can be used as a device for managing shoes in organizations or companies that need to dry and sterilize shoes.

Claims

A body having a plurality of first blowing ducts through which sterilization and dry air pass;

A drying unit having a heater and a blowing fan installed adjacent to the heater to supply air to the heater, the drying unit being installed inside the plurality of first blowing ducts;

A plurality of second blowing ducts communicating with the plurality of first blowing ducts and rotatably fastened to the plurality of first blowing ducts;

Each of the plurality of second blowing ducts,

A plurality of first air exhaust parts through which the wind supplied from the drying part is discharged to an upper surface of the shoe so as to face the bottom surface of the shoe, and the bottom surface of the shoe is spaced apart from the upper surface by the first air exhaust part; Shoe disinfection and drying apparatus, characterized in that it comprises a second blowing duct having a spacer for allowing the sterilization and drying air to flow into the shoe.
The method of claim 1,

The first blowing duct includes a hinge axis;

The second blowing duct further includes a hinge hole for receiving the hinge shaft;

Shoe disinfection and drying apparatus, characterized in that the second blowing duct is fastened along the hinge axis in a variable angle from the first blowing duct.
The method of claim 2,

The second blowing duct is

An upper plate forming the upper surface and a lower plate forming the lower surface are fastened;

A semi-circular first hinge hole forming portion is formed on one side of the upper plate, and a semi-circular second hinge hole forming portion facing the first hinge hole forming portion is formed on one side of the lower plate, and the upper plate and the lower plate are fastened. Shoe disinfection and drying apparatus, characterized in that forming the hinge hole facing the first hinge hole forming portion and the second hinge hole forming portion.
The method of claim 2,

At least one of an upper end of the first blowing duct and a lower end of the second blowing duct is formed with a locking projection, and the other is formed with a locking groove corresponding to the locking protrusion, so that the second blowing duct is variable from the first blowing duct. Footwear sterilization and drying apparatus, characterized in that maintained in the angled state.
The method of claim 1,

The second blowing duct is

A first upper surface member convexly disposed toward the outside of the second blowing duct;

The second upper surface member which is concavely disposed toward the inside of the second blowing duct is alternately disposed along the longitudinal direction, characterized in that the first air discharge portion is formed between the first upper surface member and the second upper surface member. Shoe sterilization and drying equipment.
The method of claim 5,

Both ends of at least one of the second upper surface member is a shoe sterilization and drying apparatus, characterized in that formed to protrude toward the top.
The method of claim 1,

The drying unit further includes a casing member for guiding the air supplied from the heater and the blowing fan to the first blowing duct and forming a limited space surrounding the outside of the blowing fan;

A partition wall is formed in the main body so that each of the casing members is seated therein, and the partition wall forms a chamber and the casing member to be seated.
The method of claim 1,

The second blowing duct is

Shoe disinfection and drying apparatus further comprises a second air discharge portion formed on the lower end side of the second blowing duct.
The method according to any one of claims 1 to 8,

Footwear sterilization and drying apparatus further comprises an ultraviolet lamp formed to be exposed to the outside of the second blowing duct.
The method of claim 9,

Shoe disinfection and drying apparatus further comprises a temperature sensor installed inside the second blowing duct to be adjacent to the first air discharge hole or the second air discharge hole.
The method of claim 10,

The main body

Shoe disinfection and drying apparatus further comprises a control unit for controlling the operation of the drying unit and the operation of the ultraviolet lamp according to the temperature sensor.