Vehicle comprising a plurality of walls defining a housing and a sanitization system for said housing comprising diffuser means, a source of sanitizing fluid, ventilation means and an electronic unit, this being configured to allow the passage of the sanitizing fluid from the source to the diffuser means, the diffuser means nebulizing this fluid inside said housing, the electronic unit being configured to activate the ventilation means to allow the airing of said housing following the nebulization of the sanitizing fluid inside the housing.

An ozone treatment device includes an ozone destruct module and an ozone generator mounted within a housing. The ozone destruct module and the ozone generator are mounted between corresponding air inlets and air outlets formed in the housing. The ozone treatment device also includes a controller mounted to the housing. The controller is configured to generate ozone with the ozone generator for a first time period and to automatically destruct ozone with the ozone destruct module for a second time period following the first time period. In certain implementations the treatment device includes an input device for receiving an operator input. In such cases the controller can determine the first and second time periods based on the operator input.

An ozone treatment device includes an ozone destruct module and an ozone generator mounted within a housing. The ozone destruct module and the ozone generator are mounted between corresponding air inlets and air outlets formed in the housing. The ozone treatment device also includes a controller mounted to the housing. The controller is configured to generate ozone with the ozone generator for a first time period and to automatically destruct ozone with the ozone destruct module for a second time period following the first time period. In certain implementations the treatment device includes an input device for receiving an operator input. In such cases the controller can determine the first and second time periods based on the operator input.

A dosing station comprises a receiving area for receiving a module and a sampling system for acquiring water from the module, analyzing the water and determining a refill recipe based on one or more parameters of the water. The dosing station includes a nutrient dispenser arranged to dispense at least one nutrient into the module according to the refill recipe. The recipe can be based on the type of plants in the module, the age of the plant and/or the physical condition of the plants. The dosing station can change refill recipes for each module within an agricultural facility based on one or more parameters to optimize the nutrient supply for all plants within the agricultural facility.

A dosing station comprises a receiving area for receiving a module and a sampling system for acquiring water from the module, analyzing the water and determining a refill recipe based on one or more parameters of the water. The dosing station includes a nutrient dispenser arranged to dispense at least one nutrient into the module according to the refill recipe. The recipe can be based on the type of plants in the module, the age of the plant and/or the physical condition of the plants. The dosing station can change refill recipes for each module within an agricultural facility based on one or more parameters to optimize the nutrient supply for all plants within the agricultural facility.

The present disclosure relates to a plasma treatment apparatus and a method using the same, and more particularly, to a plasma treatment apparatus for applying, to a target object, such as a biomaterial, characteristics (e.g., removal of organic materials, crosslinking reaction, etching reaction, structural change by surface chemical reaction, sterilization effect, wettability, adhesiveness, bondability, color compatibility, surface reinforcement, modification of surface heat resistance, sterilization, removal of harmful proteins/bacteria, etc.) according to plasma treatment, and a method using the plasma treatment apparatus.

The present disclosure relates to a plasma treatment apparatus and a method using the same, and more particularly, to a plasma treatment apparatus for applying, to a target object, such as a biomaterial, characteristics (e.g., removal of organic materials, crosslinking reaction, etching reaction, structural change by surface chemical reaction, sterilization effect, wettability, adhesiveness, bondability, color compatibility, surface reinforcement, modification of surface heat resistance, sterilization, removal of harmful proteins/bacteria, etc.) according to plasma treatment, and a method using the plasma treatment apparatus.

An active oxygen supply apparatus includes a casing, a plurality of plasma generating devices provided in an inside of the casing and configured to generate an induced flow containing ozone, an ultraviolet light source provided in the inside of the casing and configured to irradiate the induced flow containing the ozone with ultraviolet light, and a shielding plate provided in the inside of the casing and configured to shield the ultraviolet light irradiated to an outside of the casing through an opening portion of the casing. An active oxygen generated by irradiating the induced flow containing the ozone with the ultraviolet light from the ultraviolet light source supplies to the outside of the casing through the opening portion of the casing.

An active oxygen supply apparatus includes a casing, a plurality of plasma generating devices provided in an inside of the casing and configured to generate an induced flow containing ozone, an ultraviolet light source provided in the inside of the casing and configured to irradiate the induced flow containing the ozone with ultraviolet light, and a shielding plate provided in the inside of the casing and configured to shield the ultraviolet light irradiated to an outside of the casing through an opening portion of the casing. An active oxygen generated by irradiating the induced flow containing the ozone with the ultraviolet light from the ultraviolet light source supplies to the outside of the casing through the opening portion of the casing.

A medical device inspection system may include a base, a medical device holder on the base, a fiber scope holder on the base, a moveable roller moveably attached to the base such that it is free to rotate around an axis and move from a first position to a second position along the base, and a feeder coupled with the base for feeding a flexible portion of the fiber scope into a lumen of the medical device. During use, the flexible portion of the fiber scope may extend from the handle, around the moveable roller, and through the feeder to enter an opening in the lumen of the medical device.