An air disinfection device includes: a housing that includes an inlet port for taking air therethrough and a disinfection chamber that has a shell in a shape of a truncated ellipsoid. The device also includes: a disinfection head that is disposed in the inlet port and includes a light source for generating disinfection light that disinfects the air in the disinfection chamber, where the light source is located substantially on a plane where a first focal point of the truncated ellipsoid is located. The disinfection head further includes a fan for taking the air through the inlet port to the disinfection chamber and a filter for filtering the air. The device further includes a power source electrically coupled to the disinfection head and configured to provide electrical power for the disinfection head.

An air disinfection device includes: a housing that includes an inlet port for taking air therethrough and a disinfection chamber that has a shell in a shape of a truncated ellipsoid. The device also includes: a disinfection head that is disposed in the inlet port and includes a light source for generating disinfection light that disinfects the air in the disinfection chamber, where the light source is located substantially on a plane where a first focal point of the truncated ellipsoid is located. The disinfection head further includes a fan for taking the air through the inlet port to the disinfection chamber and a filter for filtering the air. The device further includes a power source electrically coupled to the disinfection head and configured to provide electrical power for the disinfection head.

A dual-disinfecting germicidal lighting device includes a housing, an air-permeable porous carrier with at least two sides, a fan, two light sources, and two means of disinfection that are back-up means for each other. A first means of disinfection is an air-disinfection means and it includes the housing, the air-permeable porous carrier, the fan, and the first light source. The air-permeable porous carrier contains a photocatalyst material, and the first light source activates the photocatalyst material in air-permeable porous carrier. The housing, the air-permeable porous carrier, and the fan together form an air chamber. The fan forces the surrounding air through the air-permeable porous carrier. A second means of disinfection is an air-and-surface disinfection means that includes the second light source. The second light source is a germicidal light source that disinfects pathogens in the surrounding air or on a nearby surface through the shining of its light.

A dual-disinfecting germicidal lighting device includes a housing, an air-permeable porous carrier with at least two sides, a fan, two light sources, and two means of disinfection that are back-up means for each other. A first means of disinfection is an air-disinfection means and it includes the housing, the air-permeable porous carrier, the fan, and the first light source. The air-permeable porous carrier contains a photocatalyst material, and the first light source activates the photocatalyst material in air-permeable porous carrier. The housing, the air-permeable porous carrier, and the fan together form an air chamber. The fan forces the surrounding air through the air-permeable porous carrier. A second means of disinfection is an air-and-surface disinfection means that includes the second light source. The second light source is a germicidal light source that disinfects pathogens in the surrounding air or on a nearby surface through the shining of its light.

Some embodiments of the invention include a filter for a waste tank, the filter including a housing with a pair of end fittings; an inner tube positioned within the housing, the inner tube having perforated walls; and a negatively charged resin positioned between the housing and the inner tube. The first end fitting may be configured to attach to the tank's vent line, and the second end fitting may be configured to attach to external venting tubes such that fumes from the waste tank are configured to flow from the waste tank, through the inner tube of the filter, and away from the waste tank.

Some embodiments of the invention include a filter for a waste tank, the filter including a housing with a pair of end fittings; an inner tube positioned within the housing, the inner tube having perforated walls; and a negatively charged resin positioned between the housing and the inner tube. The first end fitting may be configured to attach to the tank's vent line, and the second end fitting may be configured to attach to external venting tubes such that fumes from the waste tank are configured to flow from the waste tank, through the inner tube of the filter, and away from the waste tank.

A wall- or surface-mounted light fixture with a housing containing one or more external visible light sources to illuminate the space where the light fixture is mounted, one or more UV emitters inside the housing to destroy bacteria and pathogens, and one or more fans inside the housing that recirculate the air in a space and subject the air to the UV radiation inside the housing, destroying bacteria and pathogens in the air passing though the housing.

Disclosed is a gas filtering apparatus positioned in a closed environment for reducing odor from gases using compost mass. The gas filtering apparatus includes a first compartment, a second compartment and a layer. The first compartment is having an inlet for receiving gases and a perforated top surface. The first compartment allows the gases to move upwards through the perforated top surface. The second compartment is positioned on top of the first compartment. The second compartment includes a top section with an opening and an open bottom section. The second compartment stores organic compost for treating the received gases from the perforated top surface of the first compartment. The treated gas is released in the atmosphere through the opening. The layer is configured to attach to the open bottom section of the second compartment. The layer is configured to hold the compost mass in the second compartment. Further, the layer is allows the gases to pass from the perforated top surface of the first compartment to the second compartment.

Disclosed is a gas filtering apparatus positioned in a closed environment for reducing odor from gases using compost mass. The gas filtering apparatus includes a first compartment, a second compartment and a layer. The first compartment is having an inlet for receiving gases and a perforated top surface. The first compartment allows the gases to move upwards through the perforated top surface. The second compartment is positioned on top of the first compartment. The second compartment includes a top section with an opening and an open bottom section. The second compartment stores organic compost for treating the received gases from the perforated top surface of the first compartment. The treated gas is released in the atmosphere through the opening. The layer is configured to attach to the open bottom section of the second compartment. The layer is configured to hold the compost mass in the second compartment. Further, the layer is allows the gases to pass from the perforated top surface of the first compartment to the second compartment.

An air purifier housing comprises an outer cover and a bottom bracket with a center cavity which is open downwards and insertion grooves, recessing openings stretching into the center cavity are formed in side walls of the insertion grooves, insertion rods are fixed on the outer cover, which is inserted into the insertion grooves through the insertion rods; installation grooves corresponding to the recessing openings are in the insertion rods; and a limiting structure is in the center cavity and comprises a driving part and inner container protrusions which correspond to the recessing openings, and the driving part connects with the inner container protrusions and drives them to reach a first position where the inner container protrusions stretch out of the insertion grooves to be inserted into the installation grooves of the insertion rods or to reach a second position where the inner container protrusions retreat into the center cavity.