TH35611A - Low exhaust loop coil burner - Google Patents

Abstract

The DC60 burner (10) is provided with a central fuel outlet (18) and a number of oxygen outlets (22) that have been shaped and positioned for the formation of convergence, rotation of current. Of oxygen, which cuts with any fuel This oxygen / fuel inter-action results in two areas of combustion and its effects. Which helps in complete combustion Or completely significant Of unwanted waste gas components The burner (10) is equipped with a central fuel outlet (18) and a large amount of oxygen outlet (22) that has been shaped and positioned to induce convergence, rotation of the Oxygen, which cuts off any fuel This oxygen / fuel inter-action results in two areas of combustion and its effects. Which helps in complete combustion Or completely significant Of unwanted waste gas components

Claims (2)

1.Oxygen-fueled burner with an outer tube (12) consisting of one inlet terminal, (12a), second exit-end (12b) to release the combustion flame along the axis. Long X fuel feed path (14,18, 20) for conduction of fuel stream into inlet (12a) and oil to outlet (12b) oxygen feed path (22, 24, 26) for conduction of oxygen. enter To the inlet port (12a) and to take it to the exit (12b) where the fuel feed path (14, 18, 20) is significantly incorporated with the central exit (18), which has an inner surface as Exposed cone (20) through which the fuel passes over while the fuel is released from it. And the oxygen supply path (22, 24, 26) consists of a number of oxygen exits (22) spaced in the circumference. Fuel feed path (14,18, 20) and inward radius angle In to the output end (12b) and is twisted relative to the X axis resulting in a whirling The conical convergence of oxygen Which intersects the fuel flow in the area of the origin one of the Related With unique characteristics The oxygen supply outlet (22) is angled inside according to The radial radius with an alpha angle of 5 to 10 degrees is related to the X axis 2. Oxygen-fueled burner according to claim 1, in which the oxygen-feed outlet (22) is twisted at a theta angle of 20 to 30 degrees relative to X-axis 3. Oxygen-fuel burner according to claim 1 or claim 2, in which the fuel-feed path lifts at an angle (formula) between 30 and 40 degrees relative to the X-axis 4. Oxygen-fuel burner according to the proposition. Right 3 where the angle (formula) is between 30 and 35 degrees 5. One of the right oxygen-fuel burners according to claim 1 to 4 This includes paths (36, 38 40) to vary the axial position of the fuel and oxygen outlet (18, 22) as a result of altering the burner emission pattern. 6. Oxygen-fuel-based burner Any 1 to 5 claim The fuel and oxygen outlet (18, 22) is located in the burner block (16) and the burner block (16) can be moved along the X axis as a result of varying the vertical position. The axes of the fuel and oxygen exit (18, 22) relate to the second exit destination (12b) of the burner 7. Oxygen-fuel burner according to claim 6, where at least one central fuel exit (18) and innermost. The surface surrounding the expander cone (20) forms a single component that is removable attached to the burner block (16). 8. Burner according to one of the previous claims. It also consists of a path (50) for air emission from the terminal in the direction of the emission of a combustion flame. 9. Burner according to claim 8, in which the air emission path consists of a number of airways. One (50) that has been spaced along the perimeter. Oxygen outlet (22) 1 0. Burner according to claim 9, in which the airway (52) is angled inward, radially touching the X-axis 1. 1. Burners according to claim 9 or claim 10, which on the air (52) have been twisted. Relative to the X 1 axis 2. The burner according to claim 11, which the airway (52) has been twisted around the X axis in the same direction as the oxygen outlet.