The present invention is a transportable autonomous robotic merchandise dispensing drive thru wherein merchandise is loaded into said facility and dispensed to a customer through an ordering app downloaded on a mobile device or ordered at a facility site. Said drive thru facility is unmanned and completely computer and robotically operated utilizing no humans within said facility. Said facility is operated via computer processor and requires internet but no utility connections such as water, sewage, electric or gas. The current invention has a three part sanitizing system: interiorly, in each serving compartment and at each exterior touchscreen.

Identification and elimination of micro-organisms in the air, on surfaces and on objects that are stationary or in motion using artificial intelligence and machine learning algorithms.

Identification and elimination of micro-organisms in the air, on surfaces and on objects that are stationary or in motion using artificial intelligence and machine learning algorithms.

A method of sanitization includes determining a door of an enclosure is closed, the door separating a compartment within the enclosure from ambient air, and performing a sanitization process. The sanitization process includes determining an article has been placed into the compartment, initiating a treatment timer, introducing a sanitization agent into a volume of the compartment with a sanitization device, and determining the treatment timer has expired. A sanitization system includes an enclosure, a controller, and a sanitization device. The enclosure is configured to receive and secure one or more articles. The enclosure has a door separating a compartment within the enclosure from ambient air. The controller is configured to determine an article has been placed into the compartment, initiate a treatment timer, instruct the sanitization device to introduce a sanitization agent into a volume of the compartment, and determine the treatment timer has expired.

Various embodiments of the present invention relate to, among other things, systems for generating engineered water nanostructures (EWNS) comprising reactive oxygen species (ROS) and methods for inactivating at least one of viruses, bacteria, bacterial spores, and fungi in or on a wound of a subject in need thereof or on produce by applying EWNS to the wound or to the produce.

Various embodiments of the present invention relate to, among other things, systems for generating engineered water nanostructures (EWNS) comprising reactive oxygen species (ROS) and methods for inactivating at least one of viruses, bacteria, bacterial spores, and fungi in or on a wound of a subject in need thereof or on produce by applying EWNS to the wound or to the produce.

Decontamination device and method for sterilizing an inside of facility or an inside of a device installed in the facility in which cells, tissues, culture media, sterile reagents, microorganisms or the like are handled or cultured, including: dry fog generating machine, installed in decontamination area, for converting peracetic acid mixed solution containing low-concentration peracetic acid into dry fog and spraying the dry fog into the decontamination area; humidity sensor, installed in decontamination area, for measuring humidity in decontamination area; gas recovery machine, installed in the above decontamination area, for recovering gas in decontamination area; and control device for controlling spraying from dry fog generating machine and gas recovery operation by the gas recovery machine based on information from the above humidity sensor, a main control and monitoring device, installed outside the above decontamination area, for controlling the control devices of one or more of the above decontamination devices.

Decontamination device and method for sterilizing an inside of facility or an inside of a device installed in the facility in which cells, tissues, culture media, sterile reagents, microorganisms or the like are handled or cultured, including: dry fog generating machine, installed in decontamination area, for converting peracetic acid mixed solution containing low-concentration peracetic acid into dry fog and spraying the dry fog into the decontamination area; humidity sensor, installed in decontamination area, for measuring humidity in decontamination area; gas recovery machine, installed in the above decontamination area, for recovering gas in decontamination area; and control device for controlling spraying from dry fog generating machine and gas recovery operation by the gas recovery machine based on information from the above humidity sensor, a main control and monitoring device, installed outside the above decontamination area, for controlling the control devices of one or more of the above decontamination devices.

Disinfection devices are provided which include an enclosure comprising an interior cavity, a closable loading port for providing access to the interior cavity, a cold plasma generator, a fan, a nebulizer and optionally a heating element to heat the interior cavity. In some cases, the cold plasma generator, the fan, and the nebulizer are arranged in the disinfection device such that plasma species generated by the cold plasma generator are routed to an area to which droplets formed by the nebulizer are discharged and the interior cavity is exposed to a mixture of the droplets and the plasma species. In some additional or alternative cases, the disinfection device includes an electronic control system comprising a processor and a storage medium comprising program instructions executable by the processor for terminating operation of the cold plasma generator after a set time period subsequent to terminating operation of the nebulizer.

Disinfection devices are provided which include an enclosure comprising an interior cavity, a closable loading port for providing access to the interior cavity, a cold plasma generator, a fan, a nebulizer and optionally a heating element to heat the interior cavity. In some cases, the cold plasma generator, the fan, and the nebulizer are arranged in the disinfection device such that plasma species generated by the cold plasma generator are routed to an area to which droplets formed by the nebulizer are discharged and the interior cavity is exposed to a mixture of the droplets and the plasma species. In some additional or alternative cases, the disinfection device includes an electronic control system comprising a processor and a storage medium comprising program instructions executable by the processor for terminating operation of the cold plasma generator after a set time period subsequent to terminating operation of the nebulizer.