Provided are a mist generator and a washing machine. The mist generator can provide mist having small enough particles. The mist generator includes: a housing having a discharge part; a mist generation unit having a mist spraying nozzle for spraying a mist and causing the mist sprayed from the mist spraying nozzle to collide in the housing to generate a mist with particles smaller than those of the sprayed mist; and a discharging unit for generating an airflow toward the discharging opening in the housing, so that in case of nonuse of a blowing fan, the mist with smaller particles generated by the mist generation unit is discharged from the discharging opening along with the airflow.

A mobile vehicle that is self-contained and equipped to wash firefighter gear at the firefighter's station. The vehicle would be on a dispatched network and be activated after an incident, and for scheduled cleanings on a regular basis; the vehicle having the required equipment to clean all contaminated gear by use of a sonic cleaner, extractors, and dryers. The process includes monitoring the life of the gear and decontaminating the gear in accordance with the gear manufacturer's recommendations. Gear that has been cleaned is reassembled, wrapped, sealed and placed back into a fireman's station, giving the firefighter the assurance that their firefighting gear was cleaned, sanitized, and serviced per the manufacturer's recommendations.

A laundry washing appliance includes a drum that is rotationally operable within a tub. A sanitization mechanism delivers ozone into a processing space defined within the drum for sanitizing laundry within the drum. An ozone generator of the sanitization mechanism generates ozone gas wherein the sanitization mechanism includes an injection device that injects the ozone into the drum during a specific rotational operation of the drum.

A water ozonation system (18) that receives source water (16) from a water source (14) and converts it to ozonated water (20) for use in a washing machine (12) includes a system body (30), an ozone generator (38), a sensor assembly (21), and a controller (46). The system body (30) receives the source water (16) from the water source (14). The ozone generator (38) is configured to generate ozone. The ozone generator (38) is coupled the system body (30). The sensor assembly (21) is also coupled to the system body (30). The sensor assembly (21) is configured to sense at least one ambient environmental condition and generate at least one electronic data signal based on the sensed at least one ambient environmental condition. The controller (46) receives the at least one electronic data signal from the sensor assembly (21) and regulates a level of ozone that is generated by the ozone generator (38) based at least in part on the at least one electronic data signal.

The subject disclosure relates to a clothing washing system, an apparatus for generating nano microbubble ionic water, and a method of washing clothes. The clothing washing system includes an adjustment unit, an electrolysis unit, a first fluid circulation unit, a nano microbubble generation unit, a second fluid circulation unit, and a cleaning unit. The electrolysis unit is in fluid communication with the adjustment unit. The first fluid circulation unit is connected to the adjustment unit and the electrolysis unit. The nano microbubble generation unit is in fluid communication with the adjustment unit. The second fluid circulation unit is connected to the adjustment unit and the nano microbubble generation unit. The cleaning unit is in fluid communication with the adjustment unit.

A washing machine having a washed laundry/garment treatment system. The washing machine comprises a rotatable drum, a soap/laundry dispenser, a water supply flow valve, an ozone generator and a control panel for controlling operation of the rotatable drum, the soap/laundry dispenser, the water supply flow valve, and the ozone generator. The laundry/garment treatment system comprises a source of an additive/treating composition to be added a washing machine without any laundry/garments contained therein, and the source of the additive/treating composition is connected to the washing machine to supply a quantity of additive/treating composition thereto for mixing with water and formation of a treatment mixture. A circulating pump is connected to the washing machine for pumping the treatment mixture into a treatment holding tank. A mixture feed valve controls the flow of treatment mixture from the treatment holding tank back into the washing machine for treating the laundry/garments, following washing thereof.

An ozone and/or hydroxyl laundry system that injects ozone and/or hydroxyls into the chemical injection system in order to allow the system to inject ozone and/or hydroxyls as other cleaning chemicals are injected into the washer. This allows ozone and/or hydroxyls to be injected through the wash cycle rather than just during the initial fill phase and additional avoids the expense and maintenance of adding ozone and/or hydroxyls recirculation plumping to an ozone and/or hydroxyls laundry system. Accordingly, ozone and/or hydroxyl levels may be maintained at superior levels throughout the wash cycle.

Methods for processing denim are provided. An initial fabric is abraded by passing the initial fabric through an abrader at a first predetermined speed, thereby obtaining a pre-washed fabric with an abraded texture. The abrader comprises one or more sanding boards, where each respective sanding board has a respective diamond surface that contacts the initial fabric while spinning about a respective axis at the respective center of the respective sanding board during the abrading. The pre-washed fabric is then washed with an ozone composition, thereby obtaining an ozone washed fabric.

An ozone production method and system for producing ozone which comprises a plurality of washing machines, an ozone generator for generating ozone, and an ozone supply conduit for supplying ozone from the ozone generator to the washing machines. Each washing machine has a respective venturi, located between a water source and an inlet to the washing machine. The venturi is connected to the ozone supply conduit so that, as water flows through the respective venturi, such water flow creates a negative pressure within the ozone supply conduit. At least one sensor is located so as to detect the negative pressure created within the ozone supply conduit. The at least one sensor is connected to a control box, coupled to the ozone generator, which controls ozone production of the ozone generator depending upon the negative pressure generated within the ozone supply conduit.

An ozone and/or hydroxyl laundry system that injects ozone and/or hydroxyls into the chemical injection system in order to allow the system to inject ozone and/or hydroxyls as other cleaning chemicals are injected into the washer. This allows ozone and/or hydroxyls to be injected through the wash cycle rather than just during the initial fill phase and additional avoids the expense and maintenance of adding ozone and/or hydroxyls recirculation plumping to an ozone and/or hydroxyls laundry system. Accordingly, ozone and/or hydroxyl levels may be maintained at superior levels throughout the wash cycle.