JP2005058743A - Ion generator built-in shoe cupboard - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an ion generator built-in shoe cupboard which can efficiently sterilize bacteria and sources of malodor such as microbes and molds in storage chambers in a box body by a minus ion effect and charcoal effect to keep shoes in a good condition. <P>SOLUTION: An inner air passage 8 is formed in a chamber which constitutes partition walls 16 and is separated from a shoe storage chamber in the box body 1 of this shoe cupboard. A fan device 4, an ion generator 5, and an inner air pipe 6 are constituted for inner air in the inner air flow passage 8. Inner air is taken in through a suction port of the fan and minus ionized air is discharged into the storing chambers via the inner air pipe 6 and circulated for sterilization in an air flow passage 30 formed in the box body 1. The storing chamber is tightly closed by setting a rubber packing 28 on a door, but dehumidification and humidity control is carried out because the box body has places using charcoal so as to keep footwear in a good condition. Various kinds of sensors 25 are electrically controlled by a controller 28 so as to achieve effective deodorization and sterilization. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

The present invention relates to a shoe box with a built-in ion generator having a negative ion effect and a charcoal effect.

As means for deodorizing and sterilizing the inside of a clog box, there is one that generates ozone using an ultraviolet lamp. In general, ozone is said to have an effect on the human body when it is at a high concentration, so depending on how it is used, it may harm the human body. Moreover, ozone may give an unpleasant sensation to humans because of the odor of ozone. In addition, since ultraviolet rays are radiated to generate ozone, it is considered that the deterioration of footwear material is accelerated by the leaked ultraviolet rays.

In addition, as another means of deodorizing and sterilizing footwear and shoe boxes, products that can be deodorized and sterilized by spraying chemicals with canned spray are generally sold. Because it is a chemical, it is considered to affect the human body. Also, leather footwear may become moldy if not sprayed regularly. Therefore, deodorization and sterilization using chemicals seems to be good in the short term, but in the long term, the effect cannot be expected so much when considering the maintenance of labor and storage conditions.

There is a clog box that removes odors with a deodorizing filter when the air inside the clog box is exhausted with a fan device, and discharges it outside the casing, but basically it sterilizes bacteria that are the source of the odor. I cannot expect the effect so much.

Therefore, the present invention is a means that is safe for the human body so that the material and color of footwear do not deteriorate even when used for a short and long term, and sterilizes bacteria floating and adhering to the footwear stored in the shoebox By doing so, it will be possible to eliminate odors and prevent mold. The present invention also provides an ion generator built-in clog box that can store and use sanitary footwear with electric control that enables sterilization of bacteria floating and adhering around the installed clog box. .

In addition, the door for putting in and out footwear and the shoebox housing are in close contact so that odors and bacteria from footwear do not leak from the storage room for storing the footwear in the shoebox. Etc. so that the treatment can be performed hygienically. And even if the door and the shoebox housing are in close contact with each other, the hygiene is achieved by electric control that allows dehumidification and humidity adjustment of the moisture of the human foot and other moisture attached to the footwear when the shoebox housing adheres to the footwear. A shoe box with a built-in ion generator that can store and use footwear.

As means for solving the above-mentioned problem, the invention according to claim 1 is characterized in that an air flow path is formed in the shoebox housing and an ion generator for generating negative ions in the shoebox housing, and the negative ions are provided. A fan device that flows, the air in the storage room that stores the footwear in the shoebox housing is sucked by the fan device, negative ions are generated by the ion generator in the air discharged from the outlet, and mixed with negative ions It is characterized in that the flowing air flows in a storage room for storing footwear by an air flow path.

The invention according to claim 2 comprises a separate chamber that forms a partition at a location in the shoebox housing different from the storage chamber in which the air flow path is formed in the shoebox housing and the footwear in the shoebox housing is stored, An internal airflow passage is formed in a separate room, and a partition wall of the separate room is an internal air intake port for taking in air in the storage room for storing footwear and an internal air that discharges air mixed with negative ions to the storage room for storing footwear. An air outlet with an air filter for removing dust and the like of a desorption structure at the at least one inside air inlet; a fan device for sucking and releasing air in a storage chamber for storing the footwear; and the fan device An ion generator that generates and mixes negative ions into the air discharged from the air outlet, and an internal air pipe that guides the air in which the negative ions are mixed to the internal air outlet. Ma By providing a wind direction plate for the flow of inside air that determines the release direction of air mixed with eggplant ions, an internal airflow path is formed in a separate chamber from the storage room for storing the footwear, and the footwear by the suction force of the fan of the fan device The air in the storage chamber that contains the dust is taken in from the inside air inlet, and the air discharged from the blower outlet of the fan device is mixed with negative ions generated by the ion generator. The air in which the negative ions are mixed is released from the internal air outlet through the internal air duct into the storage chamber for storing the footwear, and the air containing the negative ions is released by the internal air flow direction plate. The discharge direction is determined, and the storage room that stores the footwear flows through the air flow path and circulates between the separate room that forms the internal airflow passage and the storage room that stores the footwear. It is characterized.

According to a third aspect of the present invention, there is provided a separate chamber that constitutes a partition wall at a location within the shoebox housing different from the storage chamber for storing footwear in the shoebox housing, and an external airflow passage is formed in the separate chamber to provide a shoebox housing. An external air suction port with an air filter that removes dust and the like of desorption structure that takes in the air of outside air outside the clog box housing on the body, and an outside air outlet that discharges air mixed with negative ions to the outside of the clog box housing, A fan device that sucks and discharges outside air outside the shoebox housing, an ion generator that generates and mixes negative ions in the air discharged from the blower outlet of the fan device, and the negative ions are mixed By providing an outside air pipe that guides air to the outside air outlet, an outside air flow passage is formed in a separate chamber from the storage room for storing the footwear, and the outside air outside the shoebox housing is absorbed by the fan's suction force of the fan device. Air outside Intake of air from which dust is removed from the inlet, the negative ions generated by the ion generator are mixed into the air discharged from the blower outlet of the fan device, and the air containing the negative ions passes through the outer air pipe and blows into the outside air. It is characterized in that air in which negative ions are mixed is discharged from the exit to the outside of the shoebox housing.

According to a fourth aspect of the present invention, in the first, second, or third aspect, at least one storage chamber for storing footwear in the ion generator built-in clog box and the at least one storage chamber have an odor. Odor detection means for detecting, storage means for storing setting data corresponding to the detected odor, comparison means for comparing the odor detected by the odor detection means with the odor setting data stored in the storage means And controlling the operation of negative ion generation of the ion generator and rotation of the fan device based on the comparison result.

According to a fifth aspect of the present invention, in the first, second, or third aspect, at least one storage chamber that stores at least footwear in the shoe box with a built-in ion generator, and humidity in the at least one storage chamber. Humidity detection means to detect, storage means for storing setting data corresponding to the detected humidity, comparison means for comparing the humidity detected by the humidity detection means and the humidity setting data stored in the storage means And controlling the operation of the negative ion generation of the ion generator and the rotation of the fan device based on the comparison result.

A sixth aspect of the present invention is the first, second, or third aspect, wherein at least one storage chamber for storing the footwear is stored in the shoe box with a built-in ion generator, and the at least one storage chamber has the footwear. Door opening / closing detection means for detecting the open / closed state of the door to be taken in and out, illumination means for illuminating the storage chamber when the door is open, and warning means for emitting a warning electronic sound when the door is open for a predetermined time; The storage means for storing the setting data corresponding to the detected opening / closing state of the door, and the door opening / closing state detected by the door opening / closing detection means are compared with the setting data of the door opening / closing state stored in the storage means. And controlling the generation of negative ions of the ion generator, the operation of the rotation of the fan device, the illumination for illuminating the storage room, and the warning sound based on the comparison result. There.

The invention according to claim 7 is the invention according to claim 1, claim 2, or claim 3, wherein at least one footwear is stored in the shoe box with a built-in ion generator, and whether or not there is a person outside the shoe box housing Human body detecting means for detecting the presence, storage means for storing setting data corresponding to the presence / absence state of the person to be detected, presence / absence state of the person detected by the human body detection means, and presence / absence of the person stored in the storage means Comparing means for comparing state setting data is provided, and the negative ion generation of the ion generator and the rotation operation of the fan device are controlled based on the comparison result.

According to an eighth aspect of the present invention, in the first, second, or third aspect, the ion generator built-in shoe box has at least one storage chamber and timer setting means for setting operation for a predetermined time or every predetermined time. And storage means for storing the setting data of the timer setting, and controlling the operation of the negative ion generation of the ion generator and the rotation of the fan device based on the stored setting data.

The invention described in claim 9 is the ion generator built-in type shoe box according to any one of claims 1 to 8, wherein negative ion generation of the ion generator and fan device are further provided in the shoe box housing. Simple display means for displaying the operation of rotation, display means for displaying the status of each control, display for setting of each control, display means for displaying the date and time, selection of each display, and control ON / OFF , Selection of ON / OFF of operation, and operation means for inputting each setting.

The invention according to claim 10 is the ion generator built-in type shoe box according to any one of claims 1 to 8, wherein charcoal is used as a material for the surface of the case of the ion generator built-in type shoe box. It is characterized in that it is configured on at least one surface or a part of the surface and has a structure for detaching from the housing.

The invention according to claim 11 is the ion generator built-in type shoe box according to any one of claims 1 to 8, wherein the door used when putting in and out footwear in the shoe box is closed. By providing a close contact means that tightly contacts the door and the housing body, air containing negative ions in the shoebox housing and odors and bacteria in the shoebox housing are not released from the gap between the door and the housing body. It is characterized by.

The invention according to claim 12 comprises an ion generator built-in type clog box comprising a separate chamber constituting a partition in a place in the clog box housing different from the storage chamber for storing footwear in the clog box housing, The inside air that contains negative ions that circulate through the storage room that stores the footwear in the shoebox housing and the outside air are taken in and the air that contains negative ions is released so as not to be confused with the outside air. It is characterized in that it has a structure of an internal airflow passage and an external airflow passage that constitute a partition wall, and a structure in a housing that partitions an electric device by a partition wall.

Bacteria attached to the footwear and bacteria attached to the footwear by circulating negative ions released from the ion generator through the shoe box through the odor source bacteria in the footwear. Can be used daily with sterilized and clean footwear.

Even if the bacteria that have been carried on the footwear are scattered around the entrance, etc., they are attached to the entrance by releasing negative ions released from the outside air ion generator around the entrance. The entrance can be used every day while the floating bacteria are sterilized and the hygienic condition around the entrance is well maintained.

By operating the ion generator and the fan device by electrical control, sanitary footwear and installation location can be used.

By using a material made of charcoal for the main body of the clog box, it is possible to dehumidify and adjust the humidity in the clog box, and by combining the ion generator and fan device, breeding of bacteria that like moisture The footwear can always be stored in an optimal environment. In addition, mold that tends to occur in footwear such as leather shoes can be prevented.

With the rubber packing attached to the door tightly sealed with the rubber packing attached to the door so that the door to put in and out the shoe box and the shoe box housing are in close contact, Because the air inside the shoebox housing does not leak outside the body, it is possible to deodorize and sterilize bacteria in the shoebox with bacteria that are attached to the footwear with high concentrations of negative ions and floating. This keeps the outside of the shoebox housing hygienic. And since the smell can be deodorized and bacteria can be sterilized inside and outside the clog box, the inside and outside of the clog box are kept hygienic.

A clog box is generally converted to a household appliance instead of a furniture category.

An embodiment of the present invention will be described with reference to FIGS. 1 to 5 of the drawings. FIG. 1 is an oblique perspective view seen from the front side of a shoe case with a built-in ion generator, FIG. 2 is a layout view seen from the top when the top panel of the shoe box with a built-in ion generator is removed, and FIG. Fig. 4 shows the arrangement of rubber packing on the right door when the right door of the clog box with built-in generator is opened, and Fig. 4 shows the air flow path of the inside air inside the clog box with the right side perspective view of the clog box with built-in ion generator. FIG. 5 and FIG. 5 are used to explain the ion generator built-in type shoe box as follows, using the air flow path diagram of the outside air outside the shoe box housing as seen from the left side perspective view of the ion generator built-in type shoe box.

First, the ion generator built-in shoe box of the present embodiment uses a material having a charcoal material effect for at least one of the side, bottom, back, front, and top of the casing. Configure the whole or part of the surface. Then, in consideration of the case where the material effect of charcoal shown below is lost, a function of a desorption structure that can be replaced or cleaned is provided so that it can be detached and attached. By this, the material effect of charcoal can be maintained for a long time by being able to clean. The material effect of this charcoal has the effects of dehumidification, humidity adjustment, sterilization, release of negative ions, deodorization of odors, absorption and desorption of harmful substances, etc. The means for negatively ionizing the box housing 1 and the storage chamber for storing the footwear in the shoebox housing is divided by a partition wall (partition wall) 16 above the storage chamber for storing the footwear in the shoebox housing. The partition 16 is provided with a suction port for taking in air in a storage room for storing the footwear in the shoebox housing, and an air filter that has an effect of removing dust and the like adhering to the footwear is provided in the suction port. Air filter inlet with air filter that can be removed and installed with a function of detachable structure that can be replaced or cleaned in consideration of the case where the effect is lost due to contamination with dust etc. 2 and the airflow A fan device intake port (for internal air) 3 that forms an air intake port of a fan device for taking in air coming from the filter-equipped internal air intake port 2 in another partition wall (partition wall) 16, and the fan device intake port ( A fan device (for inside air) 4 that sucks air from the inside (for inside air) 3 and discharges it to the outlet, and an ion generator (for inside air) 5 that mixes negative ions into the air discharged from the fan device (for inside air) 4 And an inner air tube 6 for guiding the air containing negative ions mixed into the storage room for storing the footwear in the shoebox housing by the ion generator (for indoor air) 5, and the inner air tube 6. An internal air outlet 7 for forming a blower outlet for releasing air mixed with negative ions into a storage room for storing footwear in the shoebox housing in a partition wall (partition wall) 16 above the storage room for storing footwear; From the inside air outlet 7 An air flow direction plate 29 for determining the discharge direction of air mixed with negative ions to be discharged and the air mixed with negative ions of the determined discharge direction flow in the storage chamber for storing footwear. The air flow path 30 formed in the clog box housing and the air containing negative ions from the gap of the door so that the air containing negative ions can flow stably and bacteria and bacteria in the storage chamber The rubber packing 28 is formed on the left and right doors so as not to leak the odor. A storage chamber for storing the footwear in a cylindrical shape in which an air flow passage 8 of air is formed in the storage chamber for storing the footwear in the shoebox housing from the inside air inlet 2 with the air filter to the inside air outlet 7. The air flows and circulates.

In addition to the above embodiment, as a simple means, a fan device (for inside air) 4 that sucks air into the shoe box housing 1 of the shoe box housing 1 and discharges it to the outlet, and the fan device (for inside air) 4. An ion generator (for inside air) 5 that mixes negative ions into the air discharged from the inside, and a shoebox case housing so that the air mixed with the negative ions flows in a storage chamber for storing footwear. It is also possible to configure the air flow path 30.

As a means to negatively ionize the outside air outside the clog box housing, that is, the air at the entrance where the clog box housing 1 is installed, it is placed on the storage room for storing footwear in the clog box housing 1 The partition part (partition wall) 16 partitions the processing part for negatively ionizing the inside air in the storage room for storing the footwear and the processing part for negative ionizing the outside air by the partition wall (partition wall) 16 to separate the inside air and the outside air. Each of the processing chambers for negative ionization is configured. As a result, the processing chamber for negatively ionizing the inside air in the storage room for storing the footwear and the processing chamber for negatively ionizing the outside air are separated so that the inside air and the outside air are not confused.

As a means for negatively ionizing the outside of the clog box housing, an air filter that has an effect of removing outside air dust is provided at the suction port by providing the clog box housing 1 with an intake port for taking in outside air outside the clog box housing. The air filter has an air filter inlet 9 with an air filter that can be removed and attached by providing a function of a detachable structure that can be replaced or cleaned in consideration of the case where the dirt effect is lost due to the dust or the like. A fan device inlet (for outside air) 10 that forms an air inlet of another fan (partition wall) 16 in the fan device for taking in air coming from the outside air inlet 9 with the air filter, and the fan A fan device (for outside air) 11 that sucks air from the device inlet (for outside air) 10 and discharges it to the air outlet, and negative ions are mixed into the air released from the fan device (for outside air) 11. An ion generator (for outside air) 12, an outside air tube 13 that guides air containing negative ions out of the clog box housing by the ion generator (for outside air) 12, and the outside air tube 13. An outside air outlet 14 is configured to discharge the air mixed with the introduced negative ions to the outside of the shoe casing. And it is made into the cylinder shape in which the external airflow path 15 of the air of external air is formed in a shoe rack housing from the external air inlet 9 with an air filter to the external air outlet 14. If both the inside air and outside air use a common fan device and ion generator, the product cost can be reduced.

As a means for controlling the operations of the fan device (for inside air) 4, the ion generator (for inside air) 5, the fan device (for outside air) 11 and the ion generator (for outside air) 12, A processing chamber for partitioning the upper part of the storage room for storing the footwear in the shoebox housing with a partition wall (partition wall) 16 and negatively ionizing the air inside the storage room for storing the footwear and the processing room for negatively ionizing the air from the outside The partition wall (partition wall) 16 for blocking the electromagnetic wave of the electric device is used so that the negative ion emission amount is not affected by the electromagnetic wave emitted from the power supply device 17 or the control device (microcomputer) 18. Configure the processing chamber. As a result, the ion generator can suppress the influence of electromagnetic waves and can stably emit negative ions. In addition, troubles due to moisture or the like of the electrical equipment in the housing can be prevented. If there is no influence of electromagnetic waves, moisture, etc., it is possible even without configuring the partition wall (partition wall) 16 in the processing chamber of the electrical equipment. In the processing chamber of the electric device, a power supply device 17 for supplying power to the electric device mounted in the present invention, an odor detection sensor device 22, a humidity detection sensor device 23, and an open / close SW sensor device 24 (SW is a switch) The situation can be determined from the data sent from the human body sensor device 25, the fan device (for inside air) 4, the ion generator (for inside air) 5, the fan device (for outside air) 11, and the ion generation. Control device (microcomputer) for controlling a device (for outside air) 12, a display device (panel) 19, a display device (lamp) 20, an operation device 21, an alarm buzzer 26, a lighting device 27, and a timer operation such as date and time. 18, a monitor display for displaying the status of each control, a display for selecting and setting control while viewing the display device with the operation device 21, a liquid crystal panel for displaying date and time, etc. LED operating status of display device (panel) 19 such as D panel, fan device (for inside air) 4, ion generator (for inside air) 5, fan device (for outside air) 11 and ion generator (for outside air) 12 A display device (lamp) 20 that displays simply by turning on or off, etc., an operation device 21 for inputting settings of each control, setting of date and time, starting and ending of control operation, and the like, and a built-in ion generator A human body detection sensor device 25 that detects the presence / absence of a person in front of a shoe shoe box and an alarm buzzer 26 that emits an electronic sound when the door for putting in / out footwear is opened by the open / close SW sensor device 24 are configured. The mounting position and the like can be adjusted according to the specifications such as the volume of the shoebox housing 1 and are not limited to this.

As other equipment related to means for controlling the operation of the fan device (for inside air) 4, the ion generator (for inside air) 5, the fan device (for outside air) 11, and the ion generator (for outside air) 12, In the storage room for storing the footwear of the housing 1, an odor detection sensor device 22 for detecting odors such as odors caused by bacteria such as bacteria in the storage room and a mold odor, and a humidity detection sensor device 23 for detecting humidity in the storage room. And an open / close SW sensor device 24 that detects the opening and closing of the door when the footwear is taken in and out of the storage room. In addition, the storage room for storing the footwear is configured with an illuminating device 27 for lighting the storage room based on the judgment of the control device (microcomputer) 18 based on the judgment of the control device (microcomputer) 18 in the open / close SW sensor device 24. The mounting position and the like can be adjusted according to the specifications such as the volume of the shoebox housing 1 and are not limited to this.

The oblique perspective view seen from the front side of the shoe box with a built-in ion generator in FIG. 1 constituting the above shows the arrangement of the respective parts. However, the inside air flow direction plate 29 is omitted in FIG. 1 because the drawing is difficult to understand. In addition to the above structure, a hinge is used as a door for taking in and out footwear, and a handle is used for opening the door. The storage room for storing footwear has three tiers, and the right end can hold a long boot or the like. The design of the first-stage storage room and the shoebox housing is not limited to the embodiments of the present invention because various specifications such as the place of use and the family structure are considered.

FIG. 2 is a layout view seen from the top when the top panel of the claw box with a built-in ion generator is removed, and shows the arrangement of partitions (partition walls) 16 on the storage chamber for storing footwear and components. A partition (partition wall) 16 partitions the upper part of the storage room for storing the footwear, and the partition (partition wall) 16 further negatively ionizes the inside air of the storage room for storing the footwear in the center and the left outside air. It is shown that the air is divided into a processing chamber for negative ionization and a processing chamber for the right electrical device. Thus, a partition (partition wall) 16 is provided above the storage chamber for storing the footwear in the shoebox housing, so that the processing chamber for negatively ionizing the inside air, the processing chamber for negatively ionizing the outside air, and the processing for negatively ionizing the inside air and the outside air are performed. It is divided into the processing chambers of the electrical equipment that controls. However, the partition wall (partition wall) 16 is provided with a hole or the like through which a cable wire for a power source, a signal or the like of an electric device used in the present invention is passed. The location of each processing chamber is not limited to this because it can be adapted to the specifications such as the volume of the clog box housing 1.

In the processing chamber that negatively ionizes the air inside the storage room that stores the footwear in the center, the air inside the storage room that stores the footwear enters from the inside air inlet 2 with the air filter and enters from the inside air inlet 2 with the air filter. The fan device intake port 3 (for internal air) in which the air intake port of the fan device for taking in the air is formed in the partition wall (partition wall) 16, and air is sucked and blown from the fan device intake port (for internal air) 3. A fan device (for inside air) 4 discharged to the outlet, an ion generator (for inside air) 5 that mixes negative ions into the air discharged from the fan device (for inside air) 4, and the ion generator (for inside air) The inner air pipe 6 that guides the air containing negative ions into the storage chamber for storing the footwear in the shoe box housing and the negative ions introduced by the inner air pipe 6 are mixed. Processing chamber of negative ions the partition wall (partition wall) 16 formed by the inside air of the air inside air outlet 7 of releasing the storage room for accommodating a shoebox housing footwear care is constructed. The inner airflow passage 8 is formed in a bifurcated cylindrical shape. The internal airflow passage 8 is structured to prevent air from leaking so that air in which negative ions are stably mixed is discharged into the storage chamber for storing the footwear and flows, and an air flow path is formed in the shoebox housing. . If there is air leakage between the components, use packing or the like. Although the inner trachea 6 is bifurcated, the inner trachea 6 is not limited to the bifurcated type because it can be adapted to the specifications such as the volume of the shoebox housing 1.

The processing chamber that negatively ionizes the outside air on the left side is a fan device that takes in the outside air outside the clog box housing from the outside air inlet 9 with an air filter and takes in the air coming from the outside air inlet 9 with the air filter. A fan device suction port (for outside air) 10 that forms an air suction port in a partition wall (partition wall) 16, and a fan device (for outside air) that sucks air from the fan device suction port (for outside air) 10 and discharges it to the air outlet. ) 11, an ion generator (for outside air) 12 that mixes negative ions into the air discharged from the fan device (for outside air) 11, and negative ions are mixed by the ion generator (for outside air) 12. An outside air pipe 13 that guides air to be discharged out of the clog box housing, and air that is mixed with negative ions introduced by the outside air pipe 13 is placed outside the clog box housing from the outside air outlet 14. Processing chamber of negative ions the outside air of the air to emit is configured. The external airflow passage 15 is formed in an L-shaped cylinder. The external airflow passage 15 is structured to prevent air from leaking so that air in which negative ions are mixed can be stably discharged to the outside of the shoebox casing. If there is air leakage between the components, use packing or the like. Although the outside air tube 13 is a straight tube type, the outside air tube 13 is not limited to the straight tube type because it can be adapted to the specifications of the shoebox housing 1.

The processing chamber of the right electrical equipment includes a power supply device 17 that supplies power to the electrical equipment implemented in the present invention, an odor detection sensor device 22, a humidity detection sensor device 23, an open / close SW sensor device 24, and a human body detection sensor device. The situation can be determined from the data sent from 25, the fan device (for inside air) 4, the ion generator (for inside air) 5, the fan device (for outside air) 11, and the ion generator (for outside air) 12 A display device (panel) 19, a display device (lamp) 20, an operation device 21, an alarm buzzer 26, a lighting device 27, a control device (microcomputer) 18 that controls timer operations such as date and time, and an operation device 21 Display when inputting control selections and settings while looking at the display device, monitor display for displaying the status of each control, display of liquid crystal panel and LED panel for displaying date and time, etc. The operation status of the device (panel) 19, the fan device (for inside air) 4, the ion generator (for inside air) 5, the fan device (for outside air) 11, and the ion generator (for outside air) 12 is turned on or off. In front of a display device (lamp) 20 for simple display, an operation device 21 for inputting setting of each control, setting of date and time, start and end of control operation, etc., and an ion generator built-in shoe box A human body detection sensor device 25 that detects the presence / absence state of a person and an alarm buzzer 26 that emits an electronic sound when a door for putting in and out footwear is opened by the open / close SW sensor device 24 are configured.

The arrangement diagram of the rubber packing of the right door when the right door of the ion generator built-in clog box of FIG. 3 is opened shows the arrangement of the rubber packing 28 of the right door. A rubber packing 28 is formed inside the left and right doors, and a surface for the rubber packing 28 to be in close contact with the shoebox housing 1 is formed so that the air in the storage room for storing footwear does not leak by closing the door. To do. The rubber packing prevents the smell of footwear and the like stored therein from leaking the unpleasant odor that appears prominently when the temperature is high in summer and when the temperature is high and the humidity is high. Moreover, it is hygienic because bacteria are killed in the storage chamber so that they do not escape. The shoebox is hygienic because it is installed in a place where many people come and go, such as the entrance hall, so that it does not bother when there is a visitor. It is possible to use the rubber packing 28 that is currently used in refrigerators. In the case of the rubber packing used in the refrigerator, it is possible to make the portion of the shoebox housing 1 facing the rubber packing made of metal to which a magnetic material adheres.

The air flow path diagram of the inside air in the clog box housing viewed from the right side perspective view of the claw box with a built-in ion generator in FIG. 4 shows that the air in the storage chamber for storing the footwear in the clog box housing is the air intake with air filter An air flow path of the inside air in which negative ions sucked from the mouth 2 and discharged from the inside air outlet 7 are mixed is shown. The storage table for storing footwear so that the air in the clog box housing flows, except for the bottom storage table, the storage table has an air flow path through which air passes through the front side and the back side of the clog box case 1. Form. Then, the length and angle are adjusted so that air mixed with negative ions discharged from the inside air outlet 7 does not concentrate on one place of the storage table by the air flow plate 29 for flowing inside air so as to reach each storage table. Configure. Due to the formation of the air flow path in which the negative ions are mixed and the configuration of the air flow direction plate 29 for the internal air flow, the air mixed with the negative ions discharged from the internal air outlet 7 is blown to the footwear or the storage base. By deodorizing and sterilizing bacteria. Further, even if the bacteria are blown up by the blown air and are sucked through the inside air inlet 2 with the air filter, the bacteria are directly sterilized by the ion generator (for inside air) 5. Further, when the humidity of the storage room for storing the footwear is high, moisture is adsorbed by the flowing air inside the charcoal casing part that uses the source of moisture for the shoebox casing 1, and the absorbed moisture is Evaporate from the outside of the charcoal casing facing the outside air. In addition, the charcoal used in the shoe box with a built-in ion generator is mainly dehumidified and humidity-adjusted. By using a certain item, the air containing negative ions flows and circulates in the storage room for storing footwear, so that various effects are obtained and the product cost is reduced by eliminating the need for a dehumidifier. It is done. Moreover, when it is felt that the effect has weakened, the running cost can be suppressed by cleaning the portion of the shoebox housing 1 using the charcoal so that the original charcoal effect can be recovered. In addition, the running cost can be reduced by cleaning the inside air inlet 2 with the air filter so that the original effect of the air filter can be recovered, and the fan device (for inside air) 4 and the ion generator (for inside air) 5 can be reduced. It also protects electrical equipment.

FIG. 5 is a left side perspective view of the clog box with a built-in ion generator. FIG. 5 shows the air flow path of the outside air outside the clog box case. An air flow path of the outside air in which negative ions discharged from the air outlet 14 are mixed is shown. At the entrance or the like where the present invention is installed, the bacteria that are present when the entrance is opened and the bacteria that are attached to the footwear are sterilized by air mixed with negative ions. In addition, the outside air inlet 9 with the air filter can be cleaned to reduce the running cost by using the air filter that can restore the original effect of the air filter, and the fan device (for outside air) 11 and the ion generator (for outside air) 12 can be reduced. It also protects electrical equipment.

Next, the control of the present invention will be described with reference to FIGS. FIG. 6 is a control block diagram of an ion generator built-in shoe box, FIG. 7 is an operation flowchart with the ion generator built-in shoe box, and FIG. 8 is an ion generator built-in shoe box humidity detection sensor. FIG. 9 is an operation flowchart diagram of the ion generator built-in type clog box opening / closing SW sensor device, and FIG. 10 is an operation flowchart diagram of the ion generator built-in type clog box human body detection sensor device. The control of the ion generator built-in shoe box will be described below.

First, the control will be described with reference to a control block diagram of the ion generator built-in clog box of FIG. A clog box case 1 with a built-in ion generator type clog box has a control unit including a CPU of an arithmetic processing unit, ROM and RAM of a storage unit, a determination unit for determining a state, a power input / output unit for signals, and the like. A control device (microcomputer) 18 is provided, and the fan device (for indoor air) 4 shown below provided in the shoe cabinet 1 and the rotational speed of the fan device (for indoor air) 5 and the amount of negative ions generated by the ion generator (for indoor air) 5 and the fan The rotation speed of the device (for outside air) 11, the amount of negative ions generated by the ion generator (for outside air) 12, the display on the screen of the liquid crystal panel or LED panel of the display device (panel) 19, and the LED of the display device (lamp) 20 Etc., the input function of the operating device 21, the transmission of the electronic sound of the alarm buzzer 26, and the lighting of the light bulb or LED of the lighting device 27 are controlled. The date and time control and the control of the electrical equipment using the timer use the timer function of the control device (microcomputer) 18.

The control data of the present invention includes an odor detection sensor device that detects odors caused by bacteria such as bacteria and fungi when attached to footwear in a storage room for storing footwear in the shoebox housing 1 22 and a humidity detection sensor device 23 for detecting the humidity of the storage room for storing the footwear, an open / close SW sensor device 24 (SW is an abbreviation of a switch) for detecting the open / closed state of the door of the storage room for storing the footwear, and the presence / absence state of a person A human body detection sensor device 25 is provided, and input data such as settings of the operation device 21 is used together with these data.

If the power supply 17 of the present invention is turned on, the switch of the operation device 21 can be input, and the setting input of the operation device 21 is selected and input while viewing the screen of the display device (panel) 19. . The selection input for controlling the operation of the fan device and the ion generator for inside air and outside air is arbitrarily selected from the odor detection sensor device 22, the humidity detection sensor device 23, the open / close SW sensor device 24, and the human body detection sensor device 25. Enter. When the operation time is specified and controlled using the timer function of the control device (microcomputer) 18, for example, when it is desired to specify the operation time only at night, the start time is 6:00 pm and the end time is 6 am the next day. It is possible to save energy by allowing the user to arbitrarily select a setting for controlling the operation by specifying the time, such as setting to 0:00. These settings selection inputs may be duplicated.

If the odor detection sensor device 22 is selected and input, settings such as the type of odor to control operation and the strength of the odor can be selected and input, or if the humidity detection sensor device 23 is selected and input. It is possible to select and input the setting of the humidity level for controlling the operation, or if the opening / closing SW sensor device 24 is selected and input, the setting of the length of time for controlling the operation can be selected and input. If the human body detection sensor device 25 is selected and input, the user can manually operate so that the setting of the length of time for controlling the operation when the presence of a person is detected can be selected and input. You can select the control. In addition, for a person who is weak in operation, the user can control driving by an automatic operation so that an automatic setting capable of suppressing the odor and bacterial growth caused by bacteria such as bacteria and fungi can be selected. In addition to the selection screen for controlling the operation, the display panel (panel) 19 displays a monitor display for displaying each control state, a date and time, and can be used for a clock or the like. This eliminates the need for another watch at the installed entrance and the like, and is an accessory. The date and time of the clock are set by the input of the operation device 21 and controlled by the control device 18 (microcomputer).

When the input of the setting data of the odor detection sensor device 22, the humidity detection sensor device 23, the open / close SW sensor device 24, and the human body detection sensor device 25 is completed, the control device (microcomputer) 18 is ready and enters standby. These setting data are stored in the storage unit of the control device (microcomputer) 18. From the next time, the operation can be controlled with the setting data stored in the storage unit.

When the start switch for controlling the operation of the operation device 21 is turned ON, the rotational speed of the fan device (for inside air) 4, the negative ion generation amount of the ion generator (for inside air) 5, and the fan device (for outside air) The operation of controlling the rotation speed of 11, the amount of negative ions generated by the ion generator (for outside air) 12, and the lighting of the LEDs of the display device (lamp) 20 is started. If the operation end switch for controlling the operation of the controller device 21 is turned off, the operation for controlling the operation is completed.

When the odor detection sensor device 22 detects the odor of the storage room for storing the footwear, the control unit detects the odor generated by factors such as bacteria and mold in the data sent from the odor detection sensor device 22. If it is determined that the strength is equal to or greater than the set value, the fan device (for inside air) 4 is rotated and the ion generator (for inside air) 5 generates negative ions, and the display device (lamp) 20 is turned on. Lights up and displays the operation. If the odor intensity becomes lower than the set value during operation, the operations of the fan device (for inside air) 4 and the ion generator (for inside air) 5 are stopped and the display device (lamp) 20 is turned off. Automatic control according to odor intensity.

When the humidity detection sensor device 23 detects the humidity of the storage room for storing the footwear, if the control unit determines that the humidity is equal to or higher than the set value in the data sent from the humidity detection sensor device 23 The rotation of the fan device (for inside air) 4 and the operation of generating negative ions of the ion generator (for inside air) 5 are executed and the display device (lamp) 20 is turned on to display the operation. If the humidity becomes lower than the set value during operation, the operations of the fan device (for inside air) 4 and the ion generator (for inside air) 5 are stopped and the display device (lamp) 20 is turned off. Automatic control according to humidity level.

If the control unit detects that the door is open in the data sent from the open / close SW sensor device 24 when the open / close SW sensor device 24 detects the open / closed state of the door of the storage room for storing the footwear. For example, the lighting device 27 is turned on to brighten the storage room. If it is determined that the alarm is open for longer than the set time, an electronic sound of the alarm buzzer 26 is sounded as a forgetting to close alarm to notify the user. In addition, when the rotation of the fan device (for inside air) 4 and the operation of generating negative ions of the ion generator (for inside air) 5 are being executed, the operation is automatically stopped at the same time as it is determined that the door is opened. To do. When it is determined that the door is closed, the lighting device 27 is turned off, and when the electronic alarm buzzer is sounding, the electronic alarm buzzer is stopped. Then, the control of the rotational speed of the fan device (for inside air) 4 and the amount of negative ions generated by the ion generator (for inside air) 5 is executed again. In addition, the operation of the rotational speed of the fan device (for inside air) 4 and the amount of negative ions generated by the ion generator (for inside air) 5 is set in conjunction with the opening / closing state of the door for storing footwear from open to closed. If the control is performed for the predetermined time, the data sent from the opening / closing SW sensor device 24 by the control unit is set if it is determined that the door has been changed from the open state to the closed state. Within a predetermined time, the fan device (for inside air) 4 is rotated and the ion generator (for inside air) 5 is operated to generate negative ions, and the display device (lamp) 20 is turned on to display the operation. When the predetermined time has passed, the operations of the fan device (for inside air) 4 and the ion generator (for inside air) 5 are stopped, and the display device (lamp) 20 is turned off.

When the human body detection sensor device 25 detects the presence / absence state of a person and the person crosses or stops in front of the sensor, the control unit uses the ion generator in the data sent from the human body detection sensor device 25 If it is determined that a person has crossed or stopped in front of the built-in shoe rack, the fan device (for outside air) 11 rotates and the ion generator (for outside air) 12 generates negative ions. In addition, the display device (lamp) 20 is turned on and displayed. For example, if the timer setting time is set to 20 minutes, the operation of the fan device (for outside air) 11 and the ion generator (for outside air) 12 is stopped 20 minutes after the presence of a person is not detected, and the display device (lamp) ) Turn off 20.

Next, the control will be described in detail with reference to operation flowcharts of the odor detection sensor device 22, the humidity detection sensor device 23, the open / close SW sensor device 24, and the human body detection sensor device 25 described above.

FIG. 7 is a flowchart of the operation of the odor detection sensor device of the shoe box with a built-in ion generator. When the power is turned on, initial setting (S101) of the system such as setting of each sensor of the control device (microcomputer) 18 and setting of input / output ports is executed. When the control device (microcomputer) 18 is turned on, the setting data for operation control can be changed. When the input start switch for controlling the operation of the operation device 21 is turned ON (S102), the open / close state of the door of the storage chamber for storing the footwear of the open / close SW sensor device 24 is determined (S103). If it is determined that the door is open, the process waits. If it is determined that the door is closed, it is determined whether the function of the odor detection sensor device 22 in the storage room for storing the footwear is set to ON (S104). If it is set to OFF, the control of the odor detection sensor device 22 does not function. If it is set to ON, the operation of the function of the odor detection sensor device 22 is started (S105), and odor data is transmitted to the control unit. Then, a determination is made as to whether or not the odor intensity is greater than or equal to a set value for each odor data sent (S106). If it is determined that the odor intensity is greater than or equal to the set value based on the odor data, a display device (lamp) that indicates that the fan device (for inside air) 4 and the ion generator (for inside air) 5 are operating. ) 20 is turned on (S107), and the operations of the fan device (for inside air) 4 (S108) and the ion generator (for inside air) 5 (S109) are started.

Then, the open / close SW sensor device 24 determines whether or not the open / closed state of the door continues to be kept closed (S110). If it is determined that the door is in the closed state, it is determined for each odor data whether the intensity of the odor is equal to or less than a set value (S111). While it is determined that the door is in the closed state, it is continued to determine whether the value has become equal to or less than the set value for each odor data. If the odor intensity of the data is equal to or less than the set value, the operation of the ion generator (for inside air) 5 (S112) and the fan device (for inside air) 4 (S113) is terminated and the display device (lamp) ) 20 is turned off (S114), and the process returns to the point where the open / close state (S103) of the door of the storage chamber for storing the footwear of the open / close SW sensor device 24 is determined.

In addition, during the determination of whether or not the odor intensity has become equal to or less than the set value for each odor data (S111), it is determined whether or not the door is being kept closed by the open / close SW sensor device 24 (S110). If it is determined that is in an open state, the operation of the ion generator (for inside air) 5 (S112) and the fan device (for inside air) 4 (S113) is forcibly terminated and the display device (lamp) 20 is turned off. Then (S114), the process returns to the point where the open / close state of the door of the storage chamber (S103) for storing the footwear of the open / close SW sensor device 24 is determined.

FIG. 8 is an operation flowchart diagram of the humidity detection sensor device of the shoe box with a built-in ion generator. When the power is turned on, initial setting (S201) of the system such as setting of each sensor of the control device (microcomputer) 18 and setting of input / output ports is executed. When the control device (microcomputer) 18 is turned on, the setting data for operation control can be changed. If the input start switch for controlling the operation of the operation device 21 is turned ON (S202), the open / close state of the door of the storage chamber for storing the footwear of the open / close SW sensor device 24 is determined (S203). If it is determined that the door is open, the process waits. If it is determined that the door is in a closed state, it is determined whether the function of the humidity detection sensor device 23 in the storage room for storing the footwear is set to ON (S204). If it is set to OFF, the control of the humidity detection sensor device 23 does not function. If it is set to ON, the operation of the function of the humidity detection sensor device 23 is started (S205), and humidity data is transmitted to the control unit. Then, it is determined whether the humidity level is equal to or higher than a set value for each humidity data sent (S206). If it is determined that the humidity level of the data is equal to or higher than a set value, the display device (lamp) 20 displays that the fan device (for indoor air) 4 and the ion generator (for indoor air) 5 are operating. Is turned on (S207), and the operations of the fan device (for inside air) 4 (S208) and the ion generator (for inside air) 5 (S209) are started.

Then, the open / close SW sensor device 24 determines whether or not the open / closed state of the door continues to be kept closed (S210). Then, if it is determined that the door is in the closed state, it is determined whether the humidity data has become a set value or less for each humidity data (S211). While it is determined that the door is in the closed state, it is continued to determine whether or not the humidity is below the set value for each humidity data. When the humidity level of the data is equal to or lower than the set value, the operation of the ion generator (for indoor air) 5 (S212) and the fan device (for indoor air) 4 (S213) is terminated and the display device (lamp) ) 20 is turned off (S214), and the process returns to a position where the open / close state of the door of the storage chamber for storing the footwear of the open / close SW sensor device 24 is determined (S203).

Further, during the determination of whether the humidity level has become equal to or lower than the set value for each humidity data (S211), it is determined whether or not the door is being kept closed by the open / close SW sensor device 24 (S210). Is determined to be open, the operations of the ion generator (for indoor air) 5 (S212) and the fan device (for indoor air) 4 (S213) are forcibly terminated and the display device (lamp) 20 is turned off. (S214), and the process returns to the determination of the open / closed state (S203) of the door of the storage chamber for storing the footwear of the open / close SW sensor device 24.

FIG. 9 is a flowchart of the operation of the open / close SW sensor device of the ion generator built-in clog box. When the power is turned on, initial setting (S301) of the system such as setting of each sensor of the control device (microcomputer) 18 and setting of input / output ports is executed. When the control device (microcomputer) 18 is turned on, the setting data for operation control can be changed. Then, the operation of the function of the open / close SW sensor device 24 is started (S302), and the open / close state of the storage chamber door for storing the footwear is transmitted to the control unit as data. The door opening / closing data is also used for the odor detection sensor device 22 and the humidity detection sensor device 23. Then, the open / close SW sensor device 24 determines the open / closed state (S303) of the door of the storage chamber for storing the footwear. If it is determined that the open / closed state of the door is closed, the process waits. If it is determined that the open / closed state of the door is open, the lighting device 27 that illuminates the storage room is turned on (S304).

Then, if the door open / close state is open, the timer operation is started, and if the door open / close state is determined to be over the set time due to forgetting to close the door or the like (S305), The alarm buzzer 26 starts its operation and emits an electronic sound (S306) to notify the user. If it is determined that the door is closed within the set time (S307), the alarm buzzer 26 does not start and the lighting device 27 is turned off (S308). If the alarm buzzer 26 is sounding, the operation of the alarm buzzer 26 is stopped (S309). If the input start switch for controlling the operation of the operation device 21 is ON (S310), the setting is determined to indicate that the door of the open / close SW sensor device 24 is closed (S307). Then, the function of starting the operation of the fan device (for inside air) 4, the ion generator (for inside air) 5, and the display device (lamp) 20 is determined ON / OFF (S311). When the input start switch for controlling the operation of the operation device 21 is OFF (S310) or when the setting of the function for starting the operation in conjunction with the operation is OFF (S311), the open / close SW sensor device 24 It is determined whether the door is open (S303).

When the input start switch for controlling the operation of the operation device 21 is ON (S310) and the setting is determined that the door of the open / close SW sensor device 24 is closed (S307), the fan device is linked. If the function for starting the operation of (for inside air) 4, ion generator (for inside air) 5, and display device (lamp) 20 has been set to ON (S311), the operation of the set timer starts ( In step S312, in conjunction with the timer operation, the fan device (for inside air) 4 and the ion generator (for inside air) 5 are turned on (S 313) to display that the fan device (for inside air) 5 is in operation (S 313), and the fan The operation of the device (for inside air) 4 (S314) and the ion generator (for inside air) 5 (S315) is started.

Then, it is determined by the open / close SW sensor device 24 whether the open / closed state of the door continues to be kept closed (S316). Then, it is displayed that the fan device (for inside air) 4 and the ion generator (for inside air) 5 are operating during the timer set time while it is determined that the door is kept closed. The operation of the lighting (S313) of the display device (lamp) 20, the fan device (for indoor air) 4 (S314), and the ion generator (for indoor air) 5 (S315) is continued. If it is determined that the timer set time has ended (S317), the timer operation is ended (S318), the ion generator (for indoor air) 4 (S319) and the fan device (for indoor air) 5 (S320). The display device (lamp) 20 is turned off (S321), and the process returns to the position where the open / close state of the door of the open / close SW sensor device 24 is determined (S303).

In addition, during the timer set time operation, if it is determined that the door is kept closed (S316) by the open / close SW sensor device 24 (S316), the timer operation is forcibly terminated (S318). Then, the operation of the ion generator (for inside air) 5 (S319) and the fan device (for inside air) 4 (S320) is forcibly terminated, the display device (lamp) 20 is turned off (S321), and the open / close SW The process returns to the position where the door open / close state of the sensor device 24 is determined (S303).

FIG. 10 is a flowchart showing the operation of the human body detecting sensor device of the shoe box with a built-in ion generator. When the power is turned on, initial setting (S401) of the system such as setting of each sensor of the control device (microcomputer) and setting of input / output ports is executed. When the control device (microcomputer) 18 is turned on, the setting data for operation control can be changed. If the input start switch for controlling the operation of the operation device 21 is turned ON (S402), it is determined whether the function of the human body detection sensor device 25 is set to ON (S403). If it is set to OFF, the control of the human body detection sensor device 25 does not function. If it is set to ON, the operation of the function of the human body detection sensor device 25 is started (S404), and data on the presence / absence state of the human body is transmitted to the control unit. Then, the presence / absence of a human body is determined for each data of the presence / absence state of the human body (S405). If it is determined that the presence / absence data of the human body is present, the set timer operation is started (S406), and the fan device (for outside air) 11 and the ion generator are linked with the timer operation. The display device (lamp) 20 for indicating that the (for outside air) 12 is operating is turned on (S407), and the fan device (for outside air) 11 (S408) and the ion generator (for outside air) 12 (S409). The operation starts.

When the timer is in operation, the fan device (for outside air) 11 and the ion generator (for outside air) 12 are turned on (S407) and the fan device (for outside air) is displayed. 11 (S408) and the operation of the ion generator (for outside air) 12 (S409) are continued. If it is determined that the timer set time has ended (S410), the timer operation ends (S411), the ion generator (for outside air) 12 (S412) and the fan device (for outside air) 11 (S413). And the display device (lamp) 20 is turned off (S414), and the process returns to the point where it is determined whether the function of the human body detection sensor device 25 is set to ON (S403).

It is the see-through | perspective perspective view seen from the front side of the shoe box with a built-in ion generator of this invention. It is the arrangement | positioning figure seen from the upper surface at the time of removing the upper surface panel of the shoe box with a built-in ion generator of this invention. It is a rubber packing arrangement view of the right door when the right door of the shoe box with a built-in ion generator of the present invention is opened. It is the air flow path | route figure of the inside air in the clog box housing | casing seen with the right side perspective view of the claw box with a built-in ion generator of this invention. It is the air flow path | route figure of the external air outside the shoe claw box housing | casing seen with the left side perspective view of the shoe box with a built-in ion generator of this invention. It is a control block diagram of the claw box with a built-in ion generator of the present invention. It is an operation | movement flowchart figure with the odor detection sensor apparatus of the shoe box with a built-in ion generator of this invention. It is an operation | movement flowchart figure with the humidity detection sensor apparatus of the shoe box with a built-in ion generator of this invention. It is an operation | movement flowchart figure with the opening / closing SW sensor apparatus of the shoe box with a built-in ion generator of this invention. It is an operation | movement flowchart figure with the human body detection sensor apparatus of the shoe box with a built-in ion generator of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Shoe box housing, 2 ... Inside air inlet with air filter, 3 ... Fan device inlet (for inside air), 4 ... Fan device (for inside air), 5 ... Ion generator (for inside air), 6 ... Inside trachea , 7 ... Inside air outlet, 8 ... Inside air passage, 9 ... Outside air inlet with air filter, 10 ... Fan device inlet (for outside air), 11 ... Fan device (for outside air), 12 ... Ion generator (for outside air) ), 13 ... Outside air pipe, 14 ... Outside air outlet, 15 ... Outside air passage, 16 ... Partition wall (partition wall), 17 ... Power supply device, 18 ... Control device (microcomputer), 19 ... Display device (panel), 20 DESCRIPTION OF SYMBOLS ... Display device (lamp), 21 ... Operation device, 22 ... Odor detection sensor device, 23 ... Humidity detection sensor device, 24 ... Opening / closing SW sensor device, 25 ... Human body detection sensor device, 26 ... Alarm buzzer, 27 ... Illumination device, 28 ... rubber packing, 29 ... shy Motion for a wind direction plate, 30 ... air flow path

Claims (12)

An air flow path is formed in the shoebox housing, and the shoe generator housing includes an ion generator that generates negative ions and a fan device that flows the negative ions, and stores footwear in the shoebox housing. The air in the storage chamber is sucked by the fan device, negative ions are generated by the ion generator in the air discharged from the outlet, and the air mixed with the negative ions flows through the storage chamber storing the footwear by the air flow path. An ion generator built-in clog box characterized by that. An air flow path is formed in the clog box housing, and a separate chamber constituting a partition is provided at a location in the clog box housing different from the storage chamber for storing footwear in the clog box housing, and an internal airflow passage is formed in the separate chamber. The partition wall of the separate room has an inside air inlet for taking in air from the inside of the storage room for storing the footwear, an inside air outlet for discharging air mixed with negative ions to the storage room for storing the footwear, and the at least one The inside air suction port has an air filter inside air suction port for removing dust and the like having a desorption structure, a fan device for sucking and releasing the air in the storage chamber for storing the footwear, and the air discharged from the air outlet of the fan device An ion generator that generates and mixes negative ions, and an internal air pipe that guides air containing the negative ions to the internal air outlet, and further, negative ions are mixed into the internal air outlet. A storage chamber for storing footwear by the suction force of the fan of the fan device by forming an internal airflow passage in a separate chamber from the storage chamber for storing footwear by providing a wind direction plate for air flow that determines the direction in which air is discharged The air from which the dust is removed from the air intake port is mixed with the negative ions generated by the ion generator into the air discharged from the blower outlet of the fan device, and the air containing the negative ions is the internal air duct The air containing negative ions is discharged from the internal air outlet to the storage room for storing the footwear, and the discharge direction of the air mixed with the discharged negative ions is determined by the internal air flow direction plate. Ion generation characterized by flowing through a storage chamber storing footwear by an air flow path and circulating between a separate chamber forming an internal airflow passage and a storage chamber storing footwear Built-in cupboard. It has a separate room that forms a partition at a location inside the clog box housing that is different from the storage room that stores the footwear in the clog box housing, and an external airflow passage is formed in the separate room, and the clog box housing is outside the clog box housing. An outside air inlet with an air filter that removes dust and the like of a desorption structure that takes in outside air, an outside air outlet that discharges air containing negative ions to the outside of the shoe cabinet, and the outside air outside the shoe cabinet A fan device that sucks and discharges air, an ion generator that generates and mixes negative ions in the air discharged from the air outlet of the fan device, and guides the air in which the negative ions are mixed to the outside air outlet. By providing an external air pipe, an external airflow passage is formed in a separate chamber from the storage room for storing footwear, and the air from the outside of the shoebox housing is dusted from the external air suction port by the suction force of the fan of the fan device. Remove The negative ions generated by the ion generator are mixed in the air discharged from the blower outlet of the fan device, and the air mixed with the negative ions passes through the outside air pipe from the outside air outlet to the outside of the shoebox housing. Claw box with built-in ion generator, characterized in that air containing negative ions is released. In claim 1 or claim 2 or claim 3, at least one storage chamber for storing footwear in an ion generator built-in shoe box, the odor detection means for detecting odor in the at least one storage chamber, A storage means for storing setting data corresponding to the odor to be detected; and a comparison means for comparing the odor detected by the odor detection means with the odor setting data stored in the storage means. An ion generator built-in clog box characterized by controlling the negative ion generation of the ion generator and the rotation of the fan device based on the above. In Claim 1 or Claim 2 or Claim 3, at least one storage room for storing footwear in an ion generator built-in shoe box, humidity detection means for detecting humidity in the at least one storage room, A storage means for storing setting data corresponding to the humidity to be detected; and a comparison means for comparing the humidity detected by the humidity detection means with the setting data for the humidity stored in the storage means. An ion generator built-in clog box characterized by controlling the negative ion generation of the ion generator and the rotation of the fan device based on the above. The detection apparatus according to claim 1, 2 or 3, wherein at least one storage room for storing footwear is stored in the shoe box with a built-in ion generator, and an open / closed state of a door through which the footwear is taken in and out is stored in the at least one storage room. Door opening / closing detection means, lighting means for illuminating the storage room when the door is open, warning means for emitting a warning electronic sound when the door is open for a predetermined time, and opening / closing state of the door to be detected Storage means for storing setting data corresponding to the above, and a comparison means for comparing the setting data of the door open / close state stored in the storage means and the door open / close state detected by the door open / close detection means, Based on the comparison result, the negative ion generation of the ion generator, the rotation operation of the fan device, the illumination to illuminate the storage room and the electronic sound of the warning are controlled. Box. In claim 1 or claim 2 or claim 3, at least one storage chamber for storing footwear in an ion generator built-in shoe shoe box, and a human body detecting means for detecting the presence or absence of a person outside the shoe shoe box housing, The storage means for storing the setting data corresponding to the presence / absence state of the person to be detected, and the comparison for comparing the setting data of the presence / absence state of the person detected by the human body detection means and the presence / absence state of the person stored in the storage means Means for controlling the generation of negative ions of the ion generator and the rotation of the fan device based on the comparison result. 4. The ion generator built-in type shoe box according to claim 1, or at least one storage room, timer setting means for setting operation for a predetermined time or every predetermined time, and setting data for the timer setting And an ion generator built-in shoe box that controls the generation of negative ions of the ion generator and the rotation of the fan device based on the stored setting data. The ion generator built-in clog box according to any one of claims 1 to 8, further comprising: a simple display for displaying the negative ion generation of the ion generator and the rotation operation of the fan device on the clog box housing. Display means, each control status display, each control setting display, date and time display, each display selection, control ON / OFF selection, and operation ON / OFF An ion generator built-in clog box comprising an operation means capable of selecting and inputting each setting. The ion generator built-in clog box according to any one of claims 1 to 8, wherein at least one surface using a charcoal material on the surface of the housing of the ion generator built-in clog box or A clog box with a built-in ion generator, comprising a part of the surface and a structure for detaching from a housing. The ion generator built-in type clog box according to any one of claims 1 to 8, wherein the door and the casing body are brought into close contact with each other when the door used for putting in and out the shoes in the clog box is closed. Built-in ion generator that has negative contact in the clog box housing and odors and bacteria in the clog box housing are not released from the gap between the door and the housing body. Mold clog box. The ion generator built-in clog box has a separate chamber that forms a partition at a location in the clog box housing that is different from the storage chamber that stores the footwear in the clog box housing, and further the footwear in the clog box housing is placed in the separate chamber. Inner airflow path that configures the partition so that the air of the inside air that contains negative ions circulating in the storage room to store and the outside air is taken in and the air that contains negative ions is released to the outside of the clog box housing An ion generator built-in shoe box, characterized in that it has a structure of an external air flow passage and a structure in a casing that partitions an electric device by a partition wall.

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