A laundry treatment appliance includes a cabinet, a door to selectively open and close the cabinet, a tub mounted within the cabinet, a drum rotatably mounted within the tub, an air circulation duct provided in the cabinet and having a first end connected to an air outlet of the tub and a second end connected to an air inlet of the tub, and a filter provided within the air circulation duct. The filter defines a cool air end having a perimeter thereof attached to an interior wall of the circulation duct and a warm air end having a perimeter thereof spaced apart from the interior wall of the circulation duct, and the second end is positioned below the first end in a vertical direction.

A laundry treatment appliance includes a cabinet, a door to selectively open and close the cabinet, a tub mounted within the cabinet, a drum rotatably mounted within the tub, an air circulation duct provided in the cabinet and having a first end connected to an air outlet of the tub and a second end connected to an air inlet of the tub, and a filter provided within the air circulation duct. The filter defines a cool air end having a perimeter thereof attached to an interior wall of the circulation duct and a warm air end having a perimeter thereof spaced apart from the interior wall of the circulation duct, and the second end is positioned below the first end in a vertical direction.

A support grid assembly for use in a vessel. The support grid assembly includes panels each including a first wall including a media-supporting screen and a second wall to be supported by the vessel wall inner surface. A manifold is coupled to the panels and is in hydraulic communication with vessel outlet. The manifold and the panels permit fluid to flow through the screen in each panel, through the panels, into the manifold, and through the manifold to the outlet of the vessel, as well as in the reverse direction. At least a portion of the first wall may slope downward toward the manifold, and at least a portion of the second wall may form a bottom surface that is curved to substantially conform to a curvature of the vessel wall inner surface. The panels may be arranged in a circular configuration extending radially from the manifold.

A support grid assembly for use in a vessel. The support grid assembly includes panels each including a first wall including a media-supporting screen and a second wall to be supported by the vessel wall inner surface. A manifold is coupled to the panels and is in hydraulic communication with vessel outlet. The manifold and the panels permit fluid to flow through the screen in each panel, through the panels, into the manifold, and through the manifold to the outlet of the vessel, as well as in the reverse direction. At least a portion of the first wall may slope downward toward the manifold, and at least a portion of the second wall may form a bottom surface that is curved to substantially conform to a curvature of the vessel wall inner surface. The panels may be arranged in a circular configuration extending radially from the manifold.

A vehicle exhaust system including an exhaust pipe section, a selective catalytic reduction (SCR) catalyst, and a burner assembly, connected to the exhaust pipe section at a position upstream of the selective catalytic reduction (SCR) catalyst, for pre-heating the exhaust system prior to engine start-up. The burner assembly includes a burner with a combustion chamber and a connecting tube that extends between the burner and the exhaust pipe section. A metallic mesh filter element is located inside the connecting tube and/or a catalytic washcoat is disposed on an inner surface of the connecting tube to reduce emissions of the burner assembly at start-up. The catalytic washcoat comprises a mixture of a support material and a catalyst material that chemically reacts with emissions generated by the burner to reduce the amount of burner produced emissions released from the exhaust system during pre-heating.

A vehicle exhaust system including an exhaust pipe section, a selective catalytic reduction (SCR) catalyst, and a burner assembly, connected to the exhaust pipe section at a position upstream of the selective catalytic reduction (SCR) catalyst, for pre-heating the exhaust system prior to engine start-up. The burner assembly includes a burner with a combustion chamber and a connecting tube that extends between the burner and the exhaust pipe section. A metallic mesh filter element is located inside the connecting tube and/or a catalytic washcoat is disposed on an inner surface of the connecting tube to reduce emissions of the burner assembly at start-up. The catalytic washcoat comprises a mixture of a support material and a catalyst material that chemically reacts with emissions generated by the burner to reduce the amount of burner produced emissions released from the exhaust system during pre-heating.

A retainer secures an airbag inflator to a base plate of an apparatus for helping to protect an occupant of a vehicle. The retainer includes a base wall and a sidewall that extends from the base wall and is configured to encircle a discharge portion of the inflator from which the inflation fluid is discharged. The retainer also includes a filter liner secured to the retainer sidewall, wherein the sidewall and filter liner are configured so that inflation fluid discharged from the discharge portion is directed into the filter liner.

A retainer secures an airbag inflator to a base plate of an apparatus for helping to protect an occupant of a vehicle. The retainer includes a base wall and a sidewall that extends from the base wall and is configured to encircle a discharge portion of the inflator from which the inflation fluid is discharged. The retainer also includes a filter liner secured to the retainer sidewall, wherein the sidewall and filter liner are configured so that inflation fluid discharged from the discharge portion is directed into the filter liner.

A macro electrically active mask includes two conductive layers separated by at least one filtering and insulating layer. The conductive layers are connected to each other by a power source. The power source includes an oscillator and a high voltage transformer. The power source generates a periodic voltage with a fundamental frequency and multiple harmonic frequencies. The power source is connected between the two conductive layers and the periodic voltage generates a periodic electric field between the two conductive layers. The fundamental frequency, the duty cycle, and the amplitude of the periodic voltage are configured to inactivate the microorganism that pass through the electric field.

Disclosed are a capture device for purifying air, a purification device, and an air purifier. The capture device for purifying air includes: a housing and a capture assembly. The housing is provided with an air inlet and an air outlet, wherein a cavity, in communication with the air inlet and the air outlet, is defined inside the housing; and the capture assembly is arranged in the cavity, and is located between the air inlet and the air outlet. The capture assembly includes a first rotating disk, a second rotating disk and a cylinder, wherein both the first rotating disk and the second rotating disk are rotatable and rotate in opposite directions; and the cylinder is disposed between the first rotating disk and the second rotating disk.