Systems and methods are disclosed for cleaning and sterilizing fluids and other materials. In one implementation, one or more emitters are submerged within a fluid and emit electromagnetic waves having a variable frequency. The frequency of the electromagnetic waves is swept across a frequency range to neutralize bacteria, viruses, and other pathogens in the fluid. The emitters may be submerged within a fluid reservoir and/or within the interior of an enclosed fluidic path (e.g., a pipe). Solid materials may be sterilized by immersing the solid materials within the fluid of such a fluid reservoir. In another implementation, electromagnetic waves may be applied to one or more wires that are wrapped around an exterior wall of a pipe. The frequency of the electromagnetic waves may be varied across a frequency range, resulting in scale and other materials being cleaned from the interior wall of the pipe.

The present invention relates to a set of sterilizing electrodes, to a set of sterilizing electrodes, method of sterilizing and sterilization apparatus using same, comprising: a conductive body formed of electrically conductive material and having a facing surface and connected to power supply; an electrode catalyst layer stacked on the facing surface of the conductive body; and, an insulation cover formed of an insulating material, and is fixed to the conductive body with the electrode catalyst layer interposed between the conductive body, wherein through portions are provided to form a first region that is a exposed part of the electrode catalyst layer through the through portions at a plurality of positions, and wherein the remaining areas of the electrode catalyst layer other than the first region are covered by the insulation cover; thereby obtaining advantageous effects that it is easy to manufacture to replace and to recycle the electrode catalyst layer, and also sterilizing components can be uniformly and effectively generated.

An appliance disinfecting device with monitoring and safety interlock system that utilizes user detection and sensors to detect touch and can provide user feedback and decorative features. The device can include a UV transmissive material that provides disinfection of hard to reach surfaces or areas safely. The appliance disinfection device can include an automatic interlock to protect a user from UV exposure. The optics used for the UV disinfection allow the device to become a human interface. The device can be connected to the appliance control system which can be connected to a network and cloud interface.

An apparatus, system, and method for decontamination.

An apparatus, system, and method for decontamination.

The proposed technology relates to a system (8) for preventing microbiological growth in a conduit conveying a liquid. The system (8) comprises a multi-layered pipe (10) constituting said conduit and having an inner layer (12) that covers the complete inside (16) of the pipe (10) and is formed of an electrically conductive polymer material. A liquid in the pipe (10) is in direct contact with the inner layer (12). The system further has a first electrical connector (18) and a second electrical connector (19) connecting to the inner layer (12) from outside the pipe (10), wherein the first electric connector (18) and the second electric connector (19) are spaced apart along the pipe (10). The system further has an electric power source (20) operationally connected to the first electrical connector (18) and the second electrical connector (19) and configured for supplying an electric current to the inner layer (12).

The proposed technology relates to a system (8) for preventing microbiological growth in a conduit conveying a liquid. The system (8) comprises a multi-layered pipe (10) constituting said conduit and having an inner layer (12) that covers the complete inside (16) of the pipe (10) and is formed of an electrically conductive polymer material. A liquid in the pipe (10) is in direct contact with the inner layer (12). The system further has a first electrical connector (18) and a second electrical connector (19) connecting to the inner layer (12) from outside the pipe (10), wherein the first electric connector (18) and the second electric connector (19) are spaced apart along the pipe (10). The system further has an electric power source (20) operationally connected to the first electrical connector (18) and the second electrical connector (19) and configured for supplying an electric current to the inner layer (12).

Apparatus, system, and methods are provided for reducing infectious agents at a sterile site by preventing infectious agents from coming into contact with the sterile site. A barrier is produced for infectious agents that may come in proximity or otherwise communicate with the site. The apparatus is configured to create a void-free barrier in which infectious agents are reduced with minimal exposure of potentially harmful effects of the barrier to the sterile site, objects, or users of the apparatus.

Apparatus, system, and methods are provided for reducing infectious agents at a sterile site by preventing infectious agents from coming into contact with the sterile site. A barrier is produced for infectious agents that may come in proximity or otherwise communicate with the site. The apparatus is configured to create a void-free barrier in which infectious agents are reduced with minimal exposure of potentially harmful effects of the barrier to the sterile site, objects, or users of the apparatus.

Systems and methods for reducing pathogens near an implant are discussed. In some cases, the methods include reducing contaminants in a portion of a patient that has an implant and that is disposed interior to a closed surface of skin of the patient. The method can further include placing a conduit in the closed surface of skin and flowing an antimicrobial fluid into that portion of the patient to contact the antimicrobial fluid with a surface of the implant and tissue adjacent to the implant. In some cases, the antimicrobial fluid is then removed from the portion of the patient having the implant. As part of this method, biofilm near the implant can be mechanically, ultrasonically, electrically, chemically, enzymatically, or otherwise disrupted. Other implementations are described.