An integrated sterilization lamp module integrated in a vehicle, including: a sterilization lamp which is configured for emitting sterilization light rays to sterilize surfaces in the vehicle at which they arrive; an attachment device which is configured for attaching the integrated sterilization lamp module to the vehicle; and an automatic controller which is configured for controlling the sterilization lamp so that it can automatically perform a sterilization operation. The application also relates to a vehicle including the integrated sterilization lamp module.

A decontamination system, method, and sterilant kit for a device, such as a lumen device, is depicted. The decontamination system, in some embodiments, includes a device container, a wicking pad, and a sterilant fluid delivery device. The device container, such as a terminal package or a decontamination chamber, defines a device receiving area. The wicking pad is in fluid communication with the device receiving area. The sterilant fluid delivery device is in fluid communication with the wicking pad. The sterilant fluid delivery device is configured to wet the wicking pad with sterilant fluid. The wicking pad is configured to evaporate sterilant fluid into the device receiving area.

A sanitization device may include an ozone operating system configured to generate ozone, a sanitization compartment, a distribution line fluidly coupling the ozone operating system to the sanitization compartment, and an adaptor disposed within the sanitization compartment. The adaptor may be configured to couple to a mask and may be further configured to be fluidly coupled to the distribution line such that ozone passes through the adaptor and into the sanitization compartment.

A multifunctional light source assembly and a multifunctional desk lamp are disclosed. The multifunctional desk lamp includes a base assembly, a lamp head assembly, and a lamp arm assembly; one end of the lamp arm assembly is connected with the base assembly, and the other end is connected with and supports the lamp head assembly; the lamp head assembly is internally provided with the multifunctional light source assembly, the multifunctional light source assembly includes an illumination LED chip, a plant grow light LED chip and an ultraviolet LED chip. The illumination chip, the plant grow light chip and the ultraviolet chip are respectively connected to a controller, which respectively controls the three chips, through the on and off of currents, so that functions such as illumination for reading and writing, sterilization, plant growth assistance can be achieved.

A hybrid LED lighting device, in particular a recessed spotlight, with lighting and sanitizing functions, comprises: a support structure extending along a longitudinal axis; a central LED source, positioned along the axis and emitting white light; and a plurality of UV-C LED sources, emitting in the UV-C band and arranged spaced apart from one another about the axis and about the central LED source to form an LED ring.

The invention relates to a disinfection system for a motorized vehicle comprising at least one disinfectant light emitting device mounted in a vehicle cabin and arranged to emit disinfectant light rays towards internal surfaces of the vehicle cabin so as to sanitize them, first sensor means adapted to sense the presence of a human or an animal inside the vehicle cabin and providing a first sensing signal indicating no presence, and a controller operatively connected to the at least one disinfectant light emitting device and the first sensor means, the controller receiving the first sensing signal, wherein the controller is adapted to operate the at least one disinfectant light emitting device in response to the first sensing signal.

This application discloses an ultraviolet lamp tube comprising: an outer tube and an inner tube, each installed with an electrode, wherein the outer wall of the outer tube is coated with plated coatings A and B for filtering waves to enable emission of a single-wavelength light from the light source. This application also discloses an ultraviolet lamp tube comprising an inner tube and an outer tube each installed with an electrode, wherein the outer tube is coated with a plated coating A and a reflective coating to enable emission of a single-wavelengthe light with a high luminous efficiency. Through the method of plated coating, the UV lamps disclosed have achieved increased beam angle, improved light output power and luminous efficiency.

A modular disinfection vehicle. The disinfection component is designed into an independent extensible structure, where there is a light source module between the upper end and the lower end of the disinfection component, the upper end of the disinfection component is the first fixing part, the lower end of the disinfection component is the second fixing part, the upper end of the disinfection component is of a dismountable structure, so that the light source module can be replaced and maintained conveniently; when the quantity of the light source modules needs to be increased or decreased, only components and parts at the upper end or/and the lower end of the disinfection component need to be replaced, there is no need to significantly improve the overall structure of the disinfection vehicle, so that the quantity of light source modules of the disinfection vehicle can be increased or decreased conveniently.

A cryogenic fluid composition may include water (H20), and at least one salt. The ratio of water to the at least one salt is approximately between 1% and 6% salt with the remainder water. A cryogenic fluid production device may include a cylindrical housing, and a heat exchanger disposed within the cylindrical housing. The heat exchanger may include an inlet, a channel, and an outlet. A coolant may be conveyed through the inlet, the channel, and the outlet of the heat exchanger. The cryogenic fluid production device may further include an interior wall, and an auger disposed within the interior wall of the heat exchanger.

A system for activating an emitting module is provided. A computer device identifies (i) environment data relating to an environment, and (ii) user data relating to a user located within the environment, wherein the user is wearing a wearable computing device. The computing device predicts that the user will interact with a surface in the environment based, at least in part, on the environment data and the user data. The computing device selects at least one emitting module from a plurality of emitting modules on the wearable device based, at least in part, on a predicted proximity of the at least one emitting module to the surface. The computing device prompts the user to activate the at least one emitting module.