A burner assembly includes a burner box that defines an enclosure that has a burner plate opening. A mixing tube is in fluid communication with the burner box through a mixing tube opening that extends through the burner box. A baffle creates an enclosure that at least partially separates the mixing tube opening from the burner plate opening.

A burner that is useful for providing a melting flame whose axis can be altered during operation, and for providing a supersonic jet of oxidant that can penetrate through the surface of the molten material, has a unique combination of features including a specially contoured flame collar at its open discharge end.

A burner that is useful for providing a melting flame whose axis can be altered during operation, and for providing a supersonic jet of oxidant that can penetrate through the surface of the molten material, has a unique combination of features including a specially contoured flame collar at its open discharge end.

Disclosed are an infrared burner and a warmer. The infrared burner includes a cover, a chassis, a mounting bracket, a ceramic plate, a hollow air column and a strengthening net. The chassis is defined with a through hole. A bottom of the mounting bracket is mounted on the chassis and a top of the mounting bracket is mounted on the cover. The ceramic plate is defined with air holes and provided on the mounting bracket. The ceramic plate is enclosed with the mounting bracket. The chassis and the cover to form a combustion space. The hollow air column is defined with air holes and passes through the through hole to extend into the combustion space. A bottom of the strengthening net is connected with the chassis and a top of the strengthening net is connected with the cover, and the strengthening net is provided outside the ceramic plate.

Disclosed are an infrared burner and a warmer. The infrared burner includes a cover, a chassis, a mounting bracket, a ceramic plate, a hollow air column and a strengthening net. The chassis is defined with a through hole. A bottom of the mounting bracket is mounted on the chassis and a top of the mounting bracket is mounted on the cover. The ceramic plate is defined with air holes and provided on the mounting bracket. The ceramic plate is enclosed with the mounting bracket. The chassis and the cover to form a combustion space. The hollow air column is defined with air holes and passes through the through hole to extend into the combustion space. A bottom of the strengthening net is connected with the chassis and a top of the strengthening net is connected with the cover, and the strengthening net is provided outside the ceramic plate.

A method of heating an optical fiber, the method including flowing gas from a common gas channel into one or more gas outlets of a burner, the common gas channel encircling an aperture of the burner. The method further including igniting the gas to form a flame and heating the fiber with the flame as the fiber passes through the aperture. The one or more gas outlets opening into the aperture such that each gas outlet has a gas outlet bore terminating at an inward-facing wall of the burner that defines the aperture. And the gas outlet bore being oriented at an angle .sub.1 defined between the gas outlet bore and the inward-facing wall of the burner, downstream of the gas outlet bore, that is greater than or equal to 10 degrees and less than or equal to 70 degrees.

A method of heating an optical fiber, the method including flowing gas from a common gas channel into one or more gas outlets of a burner, the common gas channel encircling an aperture of the burner. The method further including igniting the gas to form a flame and heating the fiber with the flame as the fiber passes through the aperture. The one or more gas outlets opening into the aperture such that each gas outlet has a gas outlet bore terminating at an inward-facing wall of the burner that defines the aperture. And the gas outlet bore being oriented at an angle .sub.1 defined between the gas outlet bore and the inward-facing wall of the burner, downstream of the gas outlet bore, that is greater than or equal to 10 degrees and less than or equal to 70 degrees.

A method for flame straightening is disclosed, wherein acetylene with oxygen is combusted by means of a burner to yield a flame, and the flame is directed onto a workpiece so as to heat the workpiece, wherein an electric field is applied between the burner and the non-melting workpiece which is electrically conductive, or the electric field is applied between the burner and a non-melting electrode arranged on the non-melting workpiece side to reduce NOx emission.

A method for flame straightening is disclosed, wherein acetylene with oxygen is combusted by means of a burner to yield a flame, and the flame is directed onto a workpiece so as to heat the workpiece, wherein an electric field is applied between the burner and the non-melting workpiece which is electrically conductive, or the electric field is applied between the burner and a non-melting electrode arranged on the non-melting workpiece side to reduce NOx emission.

An infrared temperature equalizing device and a grill thereof having a first vertical plate, a first folded plate, a second vertical plate, and a second folded plate. The first folded plate is connected with the second folded plate to form a cover. The first vertical plate and the second vertical plate form a wall. The wall and the cover form a heat aggregation chamber for hot air aggregation and circulation, which has a closed top and a bottom opening with a longitudinal depth. The temperature equalizing device achieves heat aggregation, temperature rising, and temperature equalizing. Through infrared and convection heating, the grill can heat food evenly and roast the food quickly.