An engine and a double-swirl mixing device thereof are provided. The double-swirl mixing device includes a mixing tube configured to mix exhaust gas with urea, a tapered mixer including a tapered tube having an outlet end extending into the mixing tube, and a plurality of tapered swirl plates which are arranged along a circumferential direction on a side wall of the tapered tube, and a fan-type blade arranged at the outlet end of the tapered tube, and a diameter of an inlet end of the tapered tube is smaller than a diameter of the outlet end of the tapered tube.

A cartridge for a fragrance dispensing device includes a hollow body having an inlet and an outlet, and an accumulator for odorant composition in the hollow body. The cartridge further includes a closer for the inlet and outlet. Also disclosed is a device for dispensing fragrances, having a housing including: at least two receptacles, each removably receiving a cartridge, each receptacle including an air inlet and exhaust, connected respectively to the inlet and outlet of a cartridge and also act on the closer of a cartridge in the receptacle to move them in the open position, a generator of air flow through the receptacles between the inlet and exhaust, and a control unit controlling the air flow generator and the inlet and exhaust and ensures an independent or simultaneous dispensing of the compositions in the cartridges in variable proportions and closure of the cartridges when the apparatus is stopped.

A cartridge for a fragrance dispensing device includes a hollow body having an inlet and an outlet, and an accumulator for odorant composition in the hollow body. The cartridge further includes a closer for the inlet and outlet. Also disclosed is a device for dispensing fragrances, having a housing including: at least two receptacles, each removably receiving a cartridge, each receptacle including an air inlet and exhaust, connected respectively to the inlet and outlet of a cartridge and also act on the closer of a cartridge in the receptacle to move them in the open position, a generator of air flow through the receptacles between the inlet and exhaust, and a control unit controlling the air flow generator and the inlet and exhaust and ensures an independent or simultaneous dispensing of the compositions in the cartridges in variable proportions and closure of the cartridges when the apparatus is stopped.

An airborne particulate suppression system is disclosed as it may be implemented for cleaning diesel particulate filter (DPF) devices. In an example, the airborne particulate suppression system includes a containment area having an air inlet to receive air containing soot and an air outlet to exhaust air cleaned of the soot. The airborne particulate suppression system includes a supply basin for a scrubbing agent. The airborne particulate suppression system also includes a coil having a plurality of spray nozzles to spray the scrubbing agent into the containment area. A pump provides the scrubbing agent to the coil at a pumping rate configured to spray the scrubbing agent from the plurality of spray nozzles and onto the air with soot to clean the air of the soot.

An air conditioner includes a flow path through which air to be humidified flows, an agitating plate group, and a spray nozzle. The agitating plate group is configured by arranging agitating plates in parallel at intervals over an entire cross-section of the flow path. Each of the agitating plates has a plate width adjusted to cause a vortex downstream. The spray nozzle is disposed immediately downstream of the agitating plate group, and sprays water particles in a direction perpendicular to a flow direction of the flow path. The plate width of each of the agitating plates is adjusted to satisfy a range of a Reynolds number causing a Karman vortex within a range of used wind speeds. The air conditioner provides high humidification efficiency and high saturation efficiency.

A particulate matter collecting apparatus includes a duct, a water sprayer, a micro-channel forming unit, and an impactor. A gas-liquid mixed fluid is formed by spraying water to air flowing along the inside of the duct using the water sprayer. The gas-liquid mixed fluid collides with a collision plate of the impactor after passing through a plurality of micro-channels provided in the micro-channel forming unit. Particulate matter in air is collected by droplets or a liquid film formed on the plurality of micro-channels and the collision plate. Water flowing down from the plurality of micro-channels is discharged through a first water outlet.

The present invention provides an exhaust gas purification system. In the exhaust gas purification system, a shower nozzle 20 disperses liquid toward exhaust gas 11 from an upper portion of the exhaust gas 11. The dispersed liquid is mixed with the exhaust gas 11 and thereafter, the liquid accumulates in a tank 30, and odor and oil content are dissolved by action of microorganism included in the liquid in the tank 30. The shower nozzle 20 is connected to an opening 24 horizontally provided in a nozzle pipe 23 connected to a liquid-supply pipe conduit 22. The exhaust gas purification system includes a nozzle 20N directed to a downward dispersing direction of the liquid. The nozzle 20N is placed in the nozzle pipe 23 such that a lower end 20L of the nozzle 20N is located higher than a bottom 25 of an inner wall of a pipe conduit of the nozzle pipe 23. According to this, exhaust gas including odor and oil content is purified.

An apparatus for performing chemosensory disorder testing includes an application for installation on a mobile computing device. The application includes a set of instructions to receive a scanning signal from a scanner communicating with the mobile computing device, the scanning signal including a unique identifier. The application next identifies a predetermined scent responsive to the scanning signal. The application generates multiple choice display for display on a display screen associated with the mobile computing device, the multiple-choice display includes an indication associated with the identified predetermined scent and at least one indication associated with another scent. The application receives a test response input from the display screen responsive to an input from a test subject attempting to detect the predetermined scent.

An atmospheric water generation system comprises water vapor consolidation systems configured to increase the relative humidity of a controlled air stream prior to condensing water from the controlled air stream. The water vapor consolidation system comprises a fluid-desiccant flow system configured to decrease the temperature of the desiccant to encourage water vapor to be absorbed by the desiccant from an atmospheric air flow. The desiccant flow is then heated to encourage water vapor evaporation from the desiccant flow into a controlled air stream that circulates within the system. The humidity of the controlled air stream is thereby increased above the relative humidity of the atmospheric air to facilitate condensation of the water vapor into usable liquid water.

The contacting device for countercurrent contacting of fluid streams and having a first pair of intersecting grids of spaced-apart and parallel deflector blades and a second pair of intersecting grids of spaced-apart and parallel deflector blades. The deflector blades in each one of the grids are interleaved with the deflector blades in the paired intersecting grid and may have uncut side portions that join them together along a transverse strip where the deflector blades cross each other or adjacent opposed ends of the deflector blades and cut side portions that extend from the uncut side portions to the ends of the deflector blades. At least some of the deflector blades have directional tabs and associated openings to allow portions of the fluid streams to pass through the deflector blades to facilitate mixing of the fluid streams.