A method reduces microbiological contamination in a closed chamber (6), formed by at least two interconnected components (1, 4), by introducing a germicidal medium in liquid form into the chamber (6). The chamber (6) is formed by and between a cap (4) and a head (2) of a filled container.

A mattress cleaning system receives a mattress in a tank of wash liquid so that the mattress is fully submerged. A pressure applicator, for example a mechanical structure or a jetted flow of wash fluid, applies a cyclical compressive force to the sleeping surface of the mattress while the mattress is fully submerged so as to cause flushing of the wash liquid outwardly of the mattress through at least the sleeping surface of the mattress. When using a barrier to isolate one of the surfaces of the mattress on a first side of the barrier from remaining surfaces of the mattress on a second side of the barrier, use of a blower to create an air pressure differential between opposing sides of the barrier causes migration of the wash liquid through the mattress from the isolated surface of the mattress to the remaining surfaces for drying the mattress.

What is presented and described is a method for avoiding the microbial attack of a cleaning apparatus (X2), in particular a cleaning apparatus (X2) for a metering system, wherein the cleaning apparatus (X2) has at least one mechanical cleaning element (X29) with at least one cleaning surface (X31), wherein the method is characterized in that the at least one cleaning surface (X31) of the at least one mechanical cleaning element (X29) is exposed, at least temporarily, to an oxidizing agent. The present invention further relates to a method for cleaning a metering system, in particular for a dispersion, especially a paint-metering system, to a cleaning apparatus, and to a metering system.

An air scrubber system including a system for creating an oxidation reduction potential (ORP) in water is disclosed. The system includes a pipe assembly for in-line mixing. The pipe assembly includes a first flow path for water to flow through. The first flow path includes one or more ozone intake ports that are fluidically coupled to one or more ozone output ports of an ozone supply unit. The pipe assembly further includes a second flow path fluidically coupled in parallel with the first flow path. The second flow path includes a control valve that selectively permits a portion of the water to flow through the second flow path to produce a negative pressure in the first flow path so that ozone is drawn into the first flow path through the one or more ozone intake ports and mixed into the water flowing through the first flow path.

A disinfection apparatus for drainage piping of sanitary equipment includes a cleansing tank, a toilet bowl, and a drainage pipe connected to the toilet bowl. When the sanitary equipment is used, a fixed amount of cleansing water is supplied to the toilet bowl from the cleansing tank, and the cleansing water after cleansing the toilet bowl is drained from the drainage pipe. A sensor senses a supply of water to the cleansing tank. A chemical liquid pump supplies a fixed amount of chemical liquid from a chemical liquid tank to the cleansing tank. A control unit is configured to operate the chemical liquid pump by means of a water supply sensing signal from the sensor to supply a fixed amount of chlorine dioxide to the cleansing tank, thereby maintaining the concentration of chlorine dioxide in the cleansing water within the cleansing tank at a fixed concentration.

The disclosed robot enables the efficient transportation of objects scattered over a wide area. The disclosed robot may include: a main body having one or more support; a moving mechanism for moving the main body; and a manipulator installed on one support, among the one or more support, thereby having the one support as a rotating shaft so as to be rotatable by 360° or higher

Dispenser (10), for the dispensing of drinking water and/or other beverages, comprising: —a cabinet (100); —a user interface (112); —a dispensing compartment (113) having a support surface (1130) for a container (9) to be filled; —at least one nozzle (114) for the dispensing of drinking water and/or other beverages, positioned over said support surface (1130); a washing compartment (1) for said container (9), said washing compartment (1) comprising: —a washing device for dispensing one or more washing fluids inside said container (9), —a drain (60) for draining one or more washing fluids outside said washing compartment (1), wherein said washing compartment (1) for said container (9) comprises: a basket (11) adapted to contain said container (9) to be washed in an upside down setup, said basket (11) being movable between: —a first operating position, wherein said basket (11) is completely inserted inside said washing compartment (1) to enable to wash the container (9) contained therein, —and a second operating position, wherein said basket (11) projects, at least partially, from said washing compartment (1) to enable to insert said container (9) to be washed and pull it out once the washing operations are concluded, said washing device being adapted to provide, alternatively, water and water plus ozone when said basket (11) is located in said first operating position.

A turf decontamination system includes a mobile device coupled to a host vehicle, an application system coupled to the mobile device, and a number of nozzles. The decontamination system includes a liquid and an ozone generator operative to create gaseous ozone. Each nozzle is configured to receive and combine the gaseous ozone and the liquid to create an ozone-liquid mixture. The ozone-liquid mixture is provided from an outlet according to a desired spray pattern to decontaminate the turf or surface beneath the system.

A system for disinfecting an enclosed area with an atomized disinfectant fluid may include a plurality of fogging devices each including a portable housing, an atomizing disinfectant generator carried by the portable housing, a wireless transceiver carried by the portable housing, and a processor carried by the portable housing and coupled to the atomizing disinfectant generator and the wireless transceiver. The processor may be configured to communicate within a wireless communications network to initiate a treatment cycle on a coordinated schedule with the other fogging devices, and cause the atomizing disinfectant generator to dispense atomized disinfectant fluid into the enclosed area along with the other fogging devices based upon the coordinated schedule. The system may also include at least one fan configured to wirelessly communicate within the wireless communications network and operate to circulate air based upon the coordinated schedule.

A system and method for creating an oxidation reduction potential (ORP) in water and for reducing the surface tension of the water for the pathogenic cleansing and/or degreasing of hard surfaces and equipment. The hard surfaces to be cleansed and/or degreased may be plastic, glass, ceramic, porcelain and stainless steel. The equipment to be cleansed and/or degreased may be food service equipment such as ovens, ranges, fryers, grills, steam cookers, refrigerators, coolers, holding cabinets, cold food tables, work tables, beverage dispensing equipment, beer dispensers, shelving, food displays, dish washing equipment and grease traps.