A burner for venting gas of a gas or oil well, the same comprises a venting gas tubing laid from the well up to a burning pit; a tubing for the supply of pilot gas laid parallel to the tubing of venting gas; a tubing of power lines from a control panel up to at least one electrode; a nozzle constituted by a tube that comprises a plurality of perforations that go through the wall of said tube, a plurality of air inlet tubes affixed to the wall of said tube; and a plurality of support spoilers affixed to the wall of said tube; where, the distal ends of the venting gas tubing, the tubing of supply of pilot gas and at the least one electrode, are located inside the nozzle; and where, the nozzle is installed inside the burning pit.

A burner for venting gas of a gas or oil well, the same comprises a venting gas tubing laid from the well up to a burning pit; a tubing for the supply of pilot gas laid parallel to the tubing of venting gas; a tubing of power lines from a control panel up to at least one electrode; a nozzle constituted by a tube that comprises a plurality of perforations that go through the wall of said tube, a plurality of air inlet tubes affixed to the wall of said tube; and a plurality of support spoilers affixed to the wall of said tube; where, the distal ends of the venting gas tubing, the tubing of supply of pilot gas and at the least one electrode, are located inside the nozzle; and where, the nozzle is installed inside the burning pit.

A flameless thermal oxidizer includes a container in which a ceramic matrix is contained, and a diptube having a passageway extending therethrough, the diptube positioned in and in communication with the ceramic matrix and in which a plurality of gaseous streams are present for combustion at the ceramic matrix, the plurality of gaseous streams including a vent stream and an oxygen stream. A related method is also provided.

A flameless thermal oxidizer (FTO) includes at least one baffle constructed and arranged in a reaction chamber of the FTO to coact with a diptube of the FTO to radially expand a resulting “bubble” or reaction envelope from the diptube outward into a porous matrix of the FTO. A related method is also provided.

A flameless thermal oxidizer (FTO) includes at least one baffle constructed and arranged in a reaction chamber of the FTO to coact with a diptube of the FTO to radially expand a resulting “bubble” or reaction envelope from the diptube outward into a porous matrix of the FTO. A related method is also provided.

A gas processing furnace according to the present invention includes: a heater body filled with an electric heating element; and a tubular gas passage passing through the heater body. The gas processing furnace includes: a block-like heater body extending in the up-down direction and filled with the electric heating element; gas passages passing through the heater body in the up-down direction, the gas passages being consecutively disposed or extended in the front-back direction, the gas passages being arranged so as to form a plurality of arrays parallel to each other in the right-left direction, in a plan view; and a headbox mounted at an upper end portion of the heater body and configured to allow the gas passages to communicate with each other via a communication space formed inside the headbox.

An apparatus for treating gaseous pollutant with plasma comprises a microwave source generating a microwave oscillation; a waveguide component coupled to the microwave source; and a resonant cavity coupled to the waveguide component, the microwave oscillation is substantially propagated toward a waveguide direction, the resonant cavity comprises a first chamber and a second chamber, the waveguide direction is substantially parallel to a reference axis defined in the first chamber, the first chamber has an inner wall surrounding the reference axis, the inner wall comprises a first inner wall obliquely inclined toward the reference axis and a second inner wall substantially parallel in respect to the reference axis relatively, an area of the first inner wall is larger than that of the second inner wall so that the first chamber has a tapered space, and the microwave oscillation interacts with an ignition gas in the second chamber to generate a torch.

A battery testing system includes: a test chamber; a battery test platform within the test chamber, the battery test platform being configured to accommodate a battery and to performing a test to the battery; and an ignition device configured to combust exhaust gases produced in the test chamber during the battery test while the exhaust gasses are in the battery testing system.

A battery testing system includes: a test chamber; a battery test platform within the test chamber, the battery test platform being configured to accommodate a battery and to performing a test to the battery; and an ignition device configured to combust exhaust gases produced in the test chamber during the battery test while the exhaust gasses are in the battery testing system.

A method of processing a mineral solid mixture, in particular road construction material, containing impurities with aromatic and/or aliphatic hydrocarbons, wherein the solid mixture is heated to a temperature below 570° C., wherein the solid mixture is heated in at least one heated rotating drum-like apparatus and is passed through at least one container and that the solid mixture is heated during or after the heating process, drum-like apparatus and is passed through at least one container, and in that the solid mixture is subjected to a negative pressure during heating or after heating, and in that the hydrocarbons are extracted from the heated solid mixture by the negative pressure and are rendered harmless by thermal combustion.