A movable curtain disinfection device according to an embodiment of the present invention includes frames installed on an upper portion of a support, spaced apart from each other to face each other, and configured to define a disinfection space for a curtain provided between the frames, rotary rollers provided so that a pair of rotary rollers thereof is mounted on an inner surface of each of the frames, the rotary rollers being configured to rotate so that the curtain passes through the disinfection space, rotary belts each configured to surround an outer portion of each of the pairs of rotary rollers, the rotary belts being configured to guide a movement of the curtain while rotating in conjunction with rotations of the rotary rollers, and disinfection modules disposed between the pairs of rotary rollers and configured to disinfect the curtain passing through the disinfection space.

The present invention discloses a UV sterilization fresh-keeping box, including an accommodating box and a UV sterilization device removably disposed on a top side of the accommodating box. The accommodating box includes a box body with a storage space, and a lid disposed on the box body. The lid has a light transmission part to allow UV light to pass through, and a first assembling part disposed on a peripheral side of the light transmission part. The UV sterilization device includes a case, a UV module disposed in the case, a control module electrically connected to the UV module, and a second assembling part disposed on a bottom side of the case. The UV sterilization device is mounted onto the lid by combining the second assembling part with the first assembling part. The UV module is controlled by the control module to emit UV light towards the light transmission part, so as to sterilize the storage space.

An apparatus and method for a mobile transport for delivering temperature-controlled contents includes a plurality of compartments coupled to a vehicle body where each compartment includes an interior space and a front panel defining a wall of the interior space. Each front panel is operable to open and reveal the interior space of its compartment in response to a predetermined condition. A temperature controller is configured to individually control a temperature setting within at least one of the plurality of compartments, and a germicidal controller is configured to provide a germicide to the interior space of each of the plurality of compartments. In operation, the mobile transport receives an order signal to pick up an item from a source, the order signal including the pickup location information, customer identification information, and delivery location information. After the item has been placed in the interior space of a compartment, the temperature controller sets the temperature setting for that compartment according to a type of the item. After arriving at the delivery location, the front panel of the compartment is opened in response to receiving an open request signal satisfying the predetermined condition, the open request signal including information relating to the customer identification information.

A display apparatus, including a display panel; a touch sensor provided on the display panel and configured to detect a user touch input; an ultraviolet (UV) light source provided on an edge portion of the display panel and configured to emit UV light to the display panel from the edge portion of the display panel; and a controller electrically connected to the display panel, the touch sensor, and the UV light source, wherein the controller is configured to, based on a determination that the user touch input is not detected, control the UV light source to emit the UV light toward the display panel.

A portable sanitization system may comprise: a portable device; a light source disposed in the portable device, the light source configured to emit a light having a wavelength between 414 and 474 nm; a light converter comprising a nonlinear crystal configured for frequency doubling; and a light guide extending from the light source to the light converter, the light converter disposed proximal a tip of the light guide.

Provided are methods and apparatus for environment-adaptive robotic disinfecting. In an example, provided is a method that can include (i) creating, from digital images, a map of a structure; (ii) identifying a location of a robot in the structure; (iii) segmenting, using a machine learning-based classifying algorithm trained based on object affordance information, the digital images to identify potentially contaminated surfaces within the structure; (iv) creating a map of potentially contaminated surfaces within the structure; (v) calculating a trajectory of movement of the robot to move the robot to a location of a potentially contaminated surface in the potentially contaminated surfaces; and (vi) moving the robot along the trajectory of movement to position a directional decontaminant source adjacent to the potentially contaminated surface. Other methods, systems, and computer-readable media are also disclosed.

The UVC sanitizing bag is a device intended to help with eliminating harmful bacteria and viruses from various solid products. In order to accomplish this, the device includes a bag base that ensures the bag can stay charged and hold various products. Further, the bag lid ensures the product placed within the device can be exposed to UVC lights from multiple directions. Additionally, the plurality of bag handles and bag pockets provide the user with additional functionality and storage. Further, a plurality of boards and shelves are designed to allow multiple storage levels which can be created within the UVC sanitizing bag and ensure the bag retains its overall shape. Thus, the device is a bag that can sanitize any solid product placed within, quickly and efficiently by utilizing UVC lights and ensures the safety of the user throughout the process.

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.

The present device provides a safe, effective means of mobile ultraviolet (UV) disinfection. A control board within the main body of the device receives data from sensors that may variously measure orientation and speed of the main body as it moves along various surfaces for disinfection. In response to such data, the control board may brighten, dim, or completely shut off UV light-emitting diodes (UVLEs), both to prevent over- and under-exposure of the materials being disinfected, and to prevent a user from unsafely using the device.

A vehicle door assembly comprising includes a vehicle door panel, a vehicle door handle operably connected to the door panel so as to enable operation of a door latch by the door handle, and at least one sanitizer dispensing mechanism having at least a first nozzle coupled to the vehicle door panel and structured to discharge a sanitizing material onto an exterior surface of the door handle.