A UV emission interface cell including a sensor arranged to detect an object along an axis extending from the sensor, at least one UV light emitter arranged to emit UV light toward the object, and an activator circuit arranged to activate the at least one UV light emitter in response to the sensor detecting that the object is aligned along the axis extending from the sensor.

A system and method include an ultraviolet (UV) lamp including one or more UV light emitters coupled to electrodes. The UV light emitters are configured to emit UV light within an environment. A power source is coupled to the UV lamp. The power source is configured to supply power to the UV lamp. A pressure sensor is configured to detect an ambient air pressure within the environment. A temperature sensor is configured to detect an ambient air temperature within the environment. A control unit is configured to analyze air pressure data regarding the ambient air pressure and air temperature data regarding the ambient air temperature in relation to a breakdown voltage for the UV lamp. The control unit is further configured to modify at least one aspect of the UV lamp in response to the ambient air pressure and the ambient air temperature reaching a breakdown threshold that is less than the breakdown voltage.

Implementations of the disclosed subject matter provide a device of a mobile robot may include a motor to drive a drive system to move the mobile robot in an area, and a light source to output ultraviolet light. The device may include at least one first sensor to determine at least one of an orientation of the mobile robot, a location of the mobile robot, and/or when the light source is within a predetermined distance of an object in the area. The device may include a controller, communicatively coupled to the drive system, the light source, and the at least one first sensor to control the drive system so as to stop or move the mobile robot before the light source is within the predetermined distance of the object based on at least a signal received from the at least one first sensor.

A standalone UV-C sanitizing apparatus and method is provided that is operable to sanitize and disinfect a user's hands or protective gloves. The apparatus includes a housing with light emitting diodes (LEDs) positioned to emit ultraviolet (UV-C) light connected to a circuit board which are individually connected to a power source. The apparatus is configured so that when the user positions the hands or gloves under the housing, the UV-C light is emitted for a predetermined period of time based on the distance to the hands and the power output of the LEDs. The UV-C light is emitted at a wavelength suitable to kill, destroy, or reduce growth of microorganisms/germs. The housing can be configured with a sensor to detect motion under the housing and include a limiter hand guard.

Provided herein are methods and systems for verifying a path in a monitored space, comprising transmitting a device identification (ID) of the mobile wireless device while the mobile wireless device moves through a monitored space, receiving one or more location certificates transmitted, in response to reception of the device ID, by one or more wireless transceivers deployed at a predefined location in the monitored space and having a limited transmission range, each location certificate comprising at least the device ID and a transceiver ID of the respective wireless transceiver, storing the one or more location certificates, and transmitting the one or more location certificates to one or more verification units configured to verify a path of the mobile wireless device in the monitored space estimated according to the predefined location of the one or more wireless transceivers identified by the transceiver ID extracted from the one or more location certificates.

This disclosure relates to storage bin for a door of a motor vehicle. In an example, a door, which provides a boundary between a passenger compartment of the motor vehicle and an exterior of the motor vehicle, includes a storage bin configured such that an item in the storage bin is accessible both from the passenger compartment and from the exterior.

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.

A decontamination system includes a housing having at least one inner surface defining a chamber. An irradiation system supplies ultraviolet germicidal irradiation (UVGI) to the chamber at a level effective to at least one of inactivate SARS-CoV-2 or inactivate at least 90% single-stranded RNA viruses present on an object positioned in the chamber in less than about 2 minutes.

A shopping cart washing assembly includes a tunnel that is positionable in a location which employs shopping carts wherein the tunnel is configured to have the shopping carts moved through the tunnel. A plurality of lower spray nozzles and a plurality of upper spray nozzles is each integrated into the tunnel to spray a liquid for washing shopping carts. A first drive unit and a second drive unit is each movably integrated into the tunnel. A plurality of grappling units each extends between the first drive unit and the second drive unit. Each of the grapping units engages a handle of a respective shopping cart to transport the respective shopping cart through the tunnel.