A shoe treating apparatus including a sensor part including at least one sensor, a motor part configured to control tilting of at least one shelf, and a processor electrically connected to the sensor part and the motor part is provided. The processor may identify an approach of a user by using the at least one sensor, and may generate, based on the identified user approach, a control signal for adjusting a tilt speed of the at least one shelf. Also, the processor may transmit the generated control signal to the motor part to adjust the tilt speed of the at least one shelf. A method of operating a shoe treating apparatus is also provided.

A shoe treating apparatus includes an upper cabinet, a lower cabinet disposed below the upper cabinet, an electronic component part disposed below the lower cabinet, a sensor part, and a processor electrically connected to the electronic component part and the sensor part. The processor may identify at least one of a material, a type, and a condition of at least one shoe in the upper cabinet, and based on the identification, perform normal treatment on the at least one shoe in the upper cabinet through the electronic component part. The processor may identify at least one of a material, a type, and a condition of at least one shoe in the lower cabinet, and based on the identification, perform intensive treatment on the at least one shoe in the lower cabinet through the electronic component part. A method of operating the shoe treating apparatus is also provided.

A shoe management apparatus including a cabinet defining an inner space for storing shoes, an exhaust port disposed at a rear surface of the inner space and discharging air into the inner space, and a circulation filter disposed on an inner wall of the cabinet and for filtering air within the inner space of the cabinet, the circulation filter including an upper portion including a first opening and a lower portion including a second opening, the lower portion being disposed below the upper portion.

A shoe management apparatus including a receiving portion defining a receiving space for receiving a shoe therein, a first supply portion for guiding a fluid flow and extending towards the receiving space, and a second supply portion at least partially disposed inside the first supply portion and protruding in a longitudinal direction of the first supply portion to supply a fluid into the shoe.

A shoe management apparatus including a receiving portion defining a receiving space for receiving shoes therein, a first supply portion for guiding flow of a fluid towards the receiving portion, the first supply portion including a stationary duct disposed above the receiving space, a flexible duct connected to the stationary duct and able to rotate to change shape, a rotatable duct connected to the flexible duct and a first driver connected to the rotatable duct and for generating a rotational force to rotate the rotatable duct.

A cleaning, sanitizing or disinfecting scrubbing device includes a body, a non-thermal plasma generator and damp wipe. Generated plasma activates fluid in the wipe. The device may include spacer posts between the body and wipe and a conductive mesh between the body and wipe or embedded in the wipe. Another embodiment includes a reservoir for holding a water-based fluid, a fluid delivery element connected to the reservoir by a tube through which the fluid can flow and a non-thermal plasma generator. The non-thermal plasma generator activates the fluid. In one embodiment the scrubbing device is a mitt. In another embodiment the scrubbing device is a glove.

The present disclosure provides a device comprising: at least one opening, the at least one opening being configured receive an object; an inner cavity within the at least one opening, the inner cavity comprising: a light emitting diode (LED), a heat sink connecting the LED to a thermal reservoir, and an insulating layer arranged on the thermal reservoir, the insulating layer comprising an orifice arranged over the LED such that light from the LED passes through the orifice of the insulating layer; and a power source configured to power the LED.

A method for preparing a bactericidal film on fiber cloth, comprising cleansing a reel of fiber cloth; placing the reel of fiber cloth into a vacuum chamber; supplying a DC power and a mid-frequency power; introducing argon gas to increase the chamber pressure to 0.3 Pa; position sputtering targets in the following order: silicon target, silicon carbide target, silver target, silicon carbide target, silver target, silicon carbide target and silver target, and then sputtering the targets simultaneously; wherein the silicon targets act as a bonding layer between the bactericidal film and the substrate; stopping the silicon targets, the silicon carbide targets and the silver targets first, and then turning off the argon gas; injecting air into the chamber until the pressure in the chamber and the atmospheric pressure are balanced.

A self-disinfecting partition system is disclosed. The system includes a housing, and an attachment element configured to attach the housing to a surface. The system further includes one or more arms configured to deploy from a stored position an extended position. The system further includes a flexible screen coupled to the one or more arms configured to restrict a transmission of microbes. The system further includes a retraction assembly configured to retract the flexible screen into the housing. The system further includes an electromagnetic energy source disposed within the housing configured to emits disinfecting electromagnetic energy onto the flexible screen. A second self-disinfecting partition system is disclosed that includes a housing configured to fit around the headrest and/or seatback of a passenger seat. The system further includes an accordion-folded flexible screen coupled to the housing that deploys from the housing and disinfected via electromagnetic energy.

The disclosure relates to a mass decontamination system that utilizes dry heat.