A gas treatment includes: a gas scrubber chamber operable to receive an effluent gas stream originating from a manufacturing process tool to be scrubbed therewithin to provide a scrubbed gas stream; and an electrostatic precipitation chamber operable to receive the scrubbed gas stream to be treated therewithin to provide a treated gas stream, one of the gas scrubber chamber and the electrostatic precipitation chamber defining a first chamber and another of the gas scrubber chamber and the electrostatic precipitation chamber defining a second chamber, the first chamber being configured to surround the second chamber. In this way, the first chamber and the second chamber can share the same volume.

The utility model provides an air purifier. The air purifier comprises a positive ion generation module, a first airflow filter screen and a second airflow filter screen, wherein the positive ion generation module is mounted between the first airflow filter screen and the second airflow filter screen. The beneficial effects of the air purifier of the utility model are that particles as small as 0.3 microns in air can be filtered out, completely-silent operation can be achieved in a sleeping environment, three operation modes can be selected, a large purification system can be executed with the minimum size, and positive ions are generated to replace negative ions.

According to an example aspect of the present invention, there is provided a device for separating materials in the form of particles and/or drops from a gas flow, especially particles and/or drops the diameter of which varies from one nanometer to a few dozen nanometers, the device comprising an inlet for incoming air to be purified, a collection chamber, an outlet for the purified air, a voltage source with actuators, an fastening column to which ion yield tips have been coupled, the device is configured to direct high tension to the ion yield tips providing ion beams from the ion yield tips to the collection surface, the collection surface conducting electricity is electrically insulated from the outer wall of the collection chamber by an electrical insulation, and the device is configured to direct voltage of opposite sign to the ion yield tips than the voltage directed to the collection surface, wherein ion yield tips are arranged directly on a surface of the fastening column having a length, wherein the ion yield tips protrude from the surface of the fastening column into a cavity of the collection chamber.

An improved electrode for use in an electrostatic precipitator is disclosed. The electrode comprises a generally rod-shaped conductive central portion, to which are attached a plurality of conductive disc-shaped elements. Each disc-shaped element has a number of sharp points spaced around its circumference and a plurality of openings near its center. The central portion of the central portion passes through the centers of each of the plurality of disc-shaped elements such that the disc-shaped elements are located parallel to one another along the central portion, and may be equally spaced along the central portion. The disc-shaped elements are conical or convex in shape, and oriented with their rims raised above their centers so that any water that collects on them runs out through the openings and down the central portion of the electrode. This greatly reduces or eliminates arcing between the electrode and a collector in the electrostatic precipitator.

A system and method of treating air. Bipolar ionization is delivered to an airflow within a conduit from a tubeless ion generator. The ionized airflow may be delivered to a conditioned airspace by an HVAC system. In alternate applications, the airflow delivers ionized combustion air to an engine. The invention also includes a mounting assembly for positioning one or more ion generators into an airflow.

An air cleaning device for separating airborne particles from a flow of air is provided. The air cleaning device comprises a separating unit and an ionizing unit arranged to charge airborne particles present in the flow of air and transmit at least a major part of the charged particles towards the separating unit. The ionizing unit comprises at least one collector electrode and at least one emitter electrode. The separating unit is arranged to attract at least some of the charged particles so as to separate them from the flow of air. Further, the at least one collector electrode is shaped so as to conduct at least a portion of the flow of air and has a spherically curved inner surface and the emitter electrode is centered with respect to the spherically curved inner surface of the collector electrode.

The present application relates to a purification unit, a purification device and a using method, belonging to the technical field of air purification, the purification unit includes a frame, an electrostatic dust removal zone located inside the frame, the electrostatic dust removal zone is located inside the frame, a support plate located on an outer side of the frame, wherein an insulation member is connected between the support plate and the frame; and a conductive assembly connected to a high-voltage end of the electrostatic dust removal zone and the support plate. A grounding end of the electrostatic dust removal zone is connected to the frame.

A negative ionization cell for negatively ionizing fine, ultrafine or nanoparticles present in an air flow defined by fumes, vehicle exhaust gases or indoor environments is disclosed. The cell has a body defining an ionizing part having first and second portions which are elongated, preferably plate-like, and facing each other. The first portion has a negative voltage to generate a potential difference with the second portion. The first and second portions also define a passage for the air flow and the first portion supports a plurality of elongated and sharp-pointed bodies projecting into the passage for the air flow and orthogonally to the air flow. The elongated and sharp-pointed bodies generate an electron flow, directed toward the second portion due to the potential difference and intercept the solid particles in the air flow to negatively charge them. An air purifier including the negative ionization cell is also disclosed.

A dust collection system, a dust collection method, and a dust collector, can enhance dust-collecting efficiency while reducing the volume of the dust collector as a whole. A dust collector is provided with a casing having an inlet into which gas is introduced; a discharge electrode to which voltage is applied, the discharge electrode being disposed inside the casing and having a spike called discharge spike and mounting frames for supporting the discharge spike; and a collecting electrode having a planar member, disposed inside the casing facing the discharge electrode, the mounting frames being inclined with relation to the gas flow at the inlet. Two mounting frames are connected to each other on the downstream side of the gas flow, and are arranged so that, between the two mounting frames, the upstream side of the gas flow is wider than the downstream side of the gas flow.

A flux recovery device recovers a vaporized flux being generated at a time of soldering an electronic circuit board on which electronic components are placed. The flux recovery device includes a first pipe, a dust collector, and a current controller. The first pipe causes gas including the vaporized flux to pass to the flux recovery device. The dust collector solidifies the vaporized flux passed through the first pipe and collects dust, by a plasma discharge. The current controller performs a constant current control of the plasma discharge.