A multi-flame burner is disclosed with burner heads, which are set up to generate at least one burner flame directed along a respective flame axis when supplied with a fuel, wherein the flame axes of respectively adjacent burner heads are inclined relative to each other. A method for preheating a workpiece, in particular a pipe or large-diameter pipe, using a multi-flame burner is also disclosed.

The invention relates to a heat exchanger (1) comprising a shell (2) containing a heat exchange device (3) and delimiting a combustion chamber (30), said shell (2) being provided with an access opening and with a door (5) provided on its inner face with a burner (4).

It is remarkable in that said door (5) is mounted pivotally around a pivot (6) attached to the end of a slide (7), in that said shell (2) is provided on its exterior surface with axial guide means (8) of said slide (7) along a displacement axis X2-X2 which extends parallel to the longitudinal axis X-X of said shell (2), in that the pivot (6) extends along an axis Z-Z perpendicular to said displacement axis X2-X2, the travel of said slide (7) being greater than the length of the burner (4).

An ironing apparatus (100) comprises a rotating cylinder (11) and a burner assembly (2) comprising a main body (20) in which a passage (21) for a mixture of air and gas is defined. The main body comprises an outlet surface (22) in which a plurality of holes (220) are defined, through which the mixture of air and gas exits from the passage, wherein the passage is elongate-shaped, extends in a longitudinal direction inside said rotating cylinder and has a decreasing cross section along the longitudinal direction (x).

A gas-fired burner for a drying drum of an asphalt mixing plant, such that the burner preferably has a central primary air duct (6), which opens into a combustion zone (4) via a swirl body (2). The burner has gas supply openings (9) in the area of the circumferential boundaries of the swirl body (2) for supplying fuel gas to the primary air for firing the burner. It has been shown that a stable and well-developed flame can be produced over a very large load range with such burners according to the disclosure.

An oxygen generator with an oxygen-producing having a center bore, including: an impact-activated ignition mechanism, an end cover, a cylinder, a bell-shaped hood, a thermally insulating inner cylinder, an oxygen-producing column, a thermally insulating material, a support bowl, a gas purification material, a safety valve, an isolation net, an oxygen-discharging end cover and an oxygen-discharging joint. The cylinder is provided with the end cover at one end; the impact-activated ignition mechanism is fixed on the end cover; the oxygen-producing column is coaxially located with the cylinder, one end of the oxygen-producing column is connected to the impact-activated ignition mechanism, and the other end of the oxygen-producing column is connected to the support bowl; the support bowl is connected to the isolation net; the thermally insulating inner cylinder is arranged on the outside of the oxygen-producing column and the thermally insulating material.

A thermo-photovoltaic system including an infrared radiation emitter including a body including a first external surface and a second external surface, the first and second external surfaces being distinct, the first external surface facing a concentrator for receiving a concentrated solar radiation, the second external surface facing a thermo-photovoltaic cell, and the body further including at least one gas and/or liquid combustion chamber therein, and an igniter is provided for causing combustion in the combustion chamber.

A well test burner system has a plurality of burner nozzles supported by a support structure. Each burner nozzle has an air inlet, a well product inlet and an air/well product mixture outlet. At least one of the burner nozzles is supported to pivot relative to the support structure while the burner nozzle is operating to expel air/well product mixture.

A well test burner system includes a plurality of burner nozzles, each including an air valve and a well product valve movable between an open position, where air and a well product are allowed to circulate through the burner nozzle to discharge an air/well product mixture, and a closed position, where the air and the well product are prevented from circulating through the burner nozzle. One or more actuation devices are operatively coupled to the air valve and the well product valve to move the air valve and the well product valve between the open and closed positions.

A burner (1) comprises a front wall (2) with an exchanger opening (4) for the passage of a heat exchanger (14), a rear wall (5) with a fume discharge opening (7), a tubular side wall (8), a tubular diffuser wall (9) within the side wall (8), an annular distribution chamber (12) formed between the side wall (8), a combustion chamber (13) formed within the diffuser wall (9) and suitable for the insertion of the heat exchanger (14), wherein the rear wall (5) comprises a cooling interspace in flow communication with the gas supply line of the burner.

Systems and methods for hydroxyl driven combustion include introducing a first gas via at least a first orifice into a processing chamber having a substrate disposed on a substrate support. A second gas is introduced into the processing chamber via a plurality of second orifices. The plurality of first orifices and the plurality of second orifices are oriented in an alternating pattern such that each second orifice of the plurality of second orifices is at least partially surrounded by at least a first orifice of the plurality of first orifices. A radical is produced as a function of the first gas and the second gas while heating the chamber.