A disinfecting apparatus includes a pipe configured to allow disinfecting light to penetrate therein to disinfect powder, liquid, or other substances. In some examples, the pipe has a window with a disinfecting light coupled to the exterior of the pipe and positioned to shine disinfecting light through the window so as to expose the substances passing therethrough. Because the disinfecting light is external to the pipe, repair and replacement of the disinfecting light is quickly and easily performed. Additionally, the disinfecting light may be retrofitted to current pipes.

A disinfecting apparatus includes a pipe configured to allow disinfecting light to penetrate therein to disinfect powder, liquid, or other substances. In some examples, the pipe has a window with a disinfecting light coupled to the exterior of the pipe and positioned to shine disinfecting light through the window so as to expose the substances passing therethrough. Because the disinfecting light is external to the pipe, repair and replacement of the disinfecting light is quickly and easily performed. Additionally, the disinfecting light may be retrofitted to current pipes.

A solution for disinfecting an area using ultraviolet radiation is provided. The solution can include an enclosure including at least one ultraviolet transparent window and a set of ultraviolet radiation sources located adjacent to the at least one ultraviolet transparent window. The set of ultraviolet radiation sources can be configured to generate ultraviolet radiation directed through the at least one ultraviolet transparent window. An input unit can be located on the enclosure and configured to generate an electrical signal in response to pressure applied to the enclosure. A control unit can be configured to manage the ultraviolet radiation by monitoring the electrical signal generated by the input unit and controlling, based on the monitoring, the ultraviolet radiation generated by the set of ultraviolet radiation sources.

A solution for disinfecting an area using ultraviolet radiation is provided. The solution can include an enclosure including at least one ultraviolet transparent window and a set of ultraviolet radiation sources located adjacent to the at least one ultraviolet transparent window. The set of ultraviolet radiation sources can be configured to generate ultraviolet radiation directed through the at least one ultraviolet transparent window. An input unit can be located on the enclosure and configured to generate an electrical signal in response to pressure applied to the enclosure. A control unit can be configured to manage the ultraviolet radiation by monitoring the electrical signal generated by the input unit and controlling, based on the monitoring, the ultraviolet radiation generated by the set of ultraviolet radiation sources.

Devices, methods, and systems for disinfection with light are disclosed. In some examples, a lighting source is operable to provide light at wavelength range of about 380 nm - 420 nm with an irradiance and/or dosage sufficient for disinfection. One or more sensors and a control system may be used to control operation of the lighting source, such as by adjusting the lighting source in response to various inputs.

Methods and systems for reducing acrylamide concentration in heat-processed products, and products produced by such methods and systems are provided. The baked products may be sprayed with a riboflavin solution and then irradiated with a UV light source to initiate monomer reactions of acrylamide and reduce the concentration of the acrylamide in the baked product. In addition, riboflavin may be dissolved in heat-processed products, followed by irradiation of the riboflavin-containing heat-processed products with a UV light source to initiate monomer reactions of acrylamide and reduce the concentration of the acrylamide in the baked product.

Methods and systems for reducing acrylamide concentration in heat-processed products, and products produced by such methods and systems are provided. The baked products may be sprayed with a riboflavin solution and then irradiated with a UV light source to initiate monomer reactions of acrylamide and reduce the concentration of the acrylamide in the baked product. In addition, riboflavin may be dissolved in heat-processed products, followed by irradiation of the riboflavin-containing heat-processed products with a UV light source to initiate monomer reactions of acrylamide and reduce the concentration of the acrylamide in the baked product.

Provided herein are portable ultraviolet (UV) devices, systems, and methods of use and manufacturing same. Methods of use include methods for UV disinfection and sterilization, more specifically, methods for UV disinfection and sterilization of a container, a room, a space or a defined environment. The portable UV devices, systems and methods are particularly useful for the UV disinfection and sterilization of a container, a room, a space or defined environment used in various industries. Provided are also portable UV devices, systems, and methods for inhibiting the growth of one or more species of microorganisms present in a container, a room, a space or a defined environment, preferably for inhibiting the growth of one or more species of microorganisms present on an interior surface of a container, a room, a space or a defined environment.

Provided herein are portable ultraviolet (UV) devices, systems, and methods of use and manufacturing same. Methods of use include methods for UV disinfection and sterilization, more specifically, methods for UV disinfection and sterilization of a container, a room, a space or a defined environment. The portable UV devices, systems and methods are particularly useful for the UV disinfection and sterilization of a container, a room, a space or defined environment used in various industries. Provided are also portable UV devices, systems, and methods for inhibiting the growth of one or more species of microorganisms present in a container, a room, a space or a defined environment, preferably for inhibiting the growth of one or more species of microorganisms present on an interior surface of a container, a room, a space or a defined environment.

Provided herein are portable ultraviolet (UV) devices, systems, and methods of use and manufacturing same. Methods of use include methods for UV disinfection and sterilization, more specifically, methods for UV disinfection and sterilization of a container, a room, a space or a defined environment. The portable UV devices, systems and methods are particularly useful for the UV disinfection and sterilization of a container, a room, a space or defined environment used in the food, beverage and dairy industry and in the process of fermentation for an alcoholic beverage. Provided are also portable UV devices, systems, and methods for inhibiting the growth of one or more species of microorganisms present in a container, a room, a space or a defined environment, preferably for inhibiting the growth of one or more species of microorganisms present on an interior surface of a container, a room, a space or a defined environment.