DE3131948C2 - - Google Patents

Description

The invention relates to a natural gas burner for a jet network tube specified in the preamble of the claim Genus.

Such radiant heating pipes are used, for example, in rolls continuous furnaces for heat treatment of workpieces puts.

From DE-GM 71 46 234 a generic burner for radiant heating pipes is known, which should deliver a perfect fuel-air mixture even with partial outputs of approximately 10% of the nominal output. For this purpose, a series of primary air openings is formed downstream of the nozzle in the tube wall of the mixing tube, through which air flows from a surrounding annular space into the mixing tube, in the end section of which a primary air / gas mixture forms. The end of the mixing tube extends through a dividing wall forming a stabilizer plate, in which secondary air channels are arranged axially parallel to the central mixing tube. This burner leads to soot formation in the radiant heating tube due to the thermal decomposition of hydrocarbons at elevated temperatures and the locally low air ratio λ . The soot builds up on the inside surface of the radiant heating tube, thereby reducing heat exchange. There are also chemical reactions between the soot and the chromium-nickel materials of the radiant tube, which shortens their life.

Furthermore, in the SU magazine "Beam Object", No. 4, 1963, MOSCOW, S 68 to 70 Fig. 1b in the article "Test bench examination of radiant heating tubes for the continuous furnace of a galvanizing unit" by BN Anterman, among others, a gas burner shown, which contains a central gas supply tube, which coaxially opens into a mixing tube to form an annular gap for the primary air. One upstream end of this mixing tube is fixed in a separating plate and a nozzle-shaped mouthpiece sits at its downstream end. In the separating plate there are several secondary air openings arranged coaxially to the gas pipe, which create a flow connection between the air chamber on the flow side and the annular space delimited by the burner wall and the mixing tube. The ratio of the area F ₁ of the annular gap representing the primary air opening in the separating plate to the cross-sectional area F _{2 of} the annular secondary air duct is approximately 0.014, which means that in the mixing tube the primary air ratio is approximately 0.02 to 0.03 and the main air quantity as secondary air is fed. Actually, the combustible mixture is only formed at the nozzle-narrowed outlet of the mixing tube. Because of this air distribution, there are strong separations of soot during the combustion process, which deposits on the inner surfaces of the radiant heating tube and reduces its efficiency. Since the flow rate of the primary air-gas mixture at the nozzle-shaped mixing tube outlet is much greater than that of the secondary air, there is an uneven combustion over the length of the radiant tube and consequently uneven temperature distribution.

The object of the invention is to provide a burner for a jet to create heating tube of the type mentioned, in which Avoided soot and constant temperature distributions over the surface of the radiant tube be enough.

This object is achieved by the characterizing features of Claim resolved.

Due to the ratios of the flow cross-sections according to the invention, soot deposits are largely avoided and a uniform heat development is achieved over the length of the radiant tube. If these ratios are undershot, soot deposits occur due to an insufficient air ratio and if these ratios are exceeded, the temperature distribution over the radiant tube length is insufficient. The claimed length of the mixing tube ensures a complete mixing of the natural gas supplied with the primary air. In the burner according to the invention, the primary air-gas mixture and the secondary air flow at the burner outlet at approximately the same and low speeds so that they can mix intensively and slowly burn out when slowly flowing through the radiant tube. The stabilizer plate with the secondary air channels on the circumference and with the central nozzle ensures a reliable swirling of the streams and a reliable stabilization of the ignition without pulsation and tear at the dimensions F ₃ and F ₂ according to the invention.

The following is an embodiment of the invention explained in detail with reference to the drawing. It shows

Figure 1 is a partially sectioned side view of a radiant tube with a burner.

Fig. 2 is a longitudinal section of the burner; and

Fig. 3 shows the burner of FIG. 2 in cross section along line III-III.

The natural gas burner 1 shown is arranged in a housing 3 of a radiant heating tube 2 and consists of heat-resistant and scale-resistant steel. A mixing tube 4 is arranged in the axis aa of the burner part 5 of the radiant heating tube 2 and has 6 primary air holes 7 with a total area F ₁ in the tube wall 6 . The primary air holes 7 can be circular or have another shape and are in the immediate vicinity of a gas nozzle 8 which is arranged within the mixing tube 4 and is passed through the head 9 of the burner part 5 . The introduction of the gas nozzle 8 in the mixing tube 4 is secured by a seal 10 against air passage, which is also as a heat-resistant intermediate position in a different way, for. B. thread-shaped.

At the other end of the mixing pipe 4 is located at a distance e from the primary air holes 7 a stabilizer lisator plate 11, a plurality of angularly spaced secondary air ducts are provided with a total ₂ F 12 at the periphery thereof. In the central region of the stabilizer plate 11 there is a central nozzle 13 with a diameter d and the cross-sectional area F ₃ for the passage of the primary air / gas mixture. The shape of the channels 12 can be any. In the example in question, the channels 12 are rectangular.

An ignition device for igniting the mixture is accommodated in an axially parallel tube 14 . The Stabilisa gate plate 11 has an opening in which one end of the tube 14 is fixed with the igniter. At the other end of the tube 14 is fixed in the head 9 of the burner part 5 .

The head 9 of the burner part 5 is connected through a nozzle 15 to a - not shown - recuperator for air preheating, which is housed in the recuperative branch 16 of the radiant tube. The air enters the recuperator through a nozzle 17 .

You choose the outer diameter of the stabilizer plate 11 so that between its outer edge and the inner surface of the housing 3 remains as small as possible, resulting from the assembly conditions gap. The cross-sectional area of this gap is calculated when calculating the cross-sectional area F _{2 of} the secondary air.

The burner works as follows:

The air is fed from the recuperator through the nozzle 15 to the mixing tube 4 divided into two streams. The primary air flows through the holes 7 in the mixing tube 4 and the secondary air passes through the channels 12 in the stabilizer gate plate 11 in the working space of the housing 3 of the heating tube 2nd

All natural gas flows through the gas nozzle 8 into the interior of the mixing tube 4 , where it mixes with the primary air and flows as a mixture from the mixing tube 4 through the center nozzle 13 into the working space of the housing 3 . Due to its length, the mixing tube 4 ensures good mixing of the fuel gas with the primary air.

The amounts of primary air and secondary air are determined by the total area F _{1 of} the primary air holes 7 and F _{2 of} the channels 12 . The area F _{1 is determined} so that the mixture formed in the mixing tube 4 is incombustible.

When it is burned with the smallest possible air ratio λ , no soot should arise. The size of the areas F ₂ and F ₃ is chosen so that the flow rates of the primary air-gas mixture and the secondary air are the same and small in amount, so that a uniform burnout takes place over the length of the radiant tube.

The selected size of the stabilizer plate, which is approximately the same as the cross section of the burner part 5 , ensures a good swirling of the primary air-gas mixture with the secondary air behind the plate 11 and consequently a stable ignition.

The burner design described has the advantage of a simple training, a high level of economy Combustion of natural gas throughout the Re without excreting soot gel area of thermal stress, a long shelf life the radiant heating tube and one uniform temperature distribution over its surface and reliable ignition stabilization.

Claims (1)

Natural gas burner for a radiant heating tube with a mixing tube ( 4 ), in the center of which a gas nozzle ( 8 ) and in the wall in the immediate vicinity of the gas nozzle ( 8 ) primary air holes ( 7 ) are provided, and with a stabilizer plate ( 11 ) which has secondary air ducts ( 12 ) on its outer circumference and a central opening at the free end of the mixing tube ( 4 ), characterized in that
that the diameter (d) of the central opening in the stabilizer plate ( 11 ) designed as a central nozzle ( 13 ) for the gas-primary air mixture is at least 10 times smaller than the distance ( 1 ) between the primary air holes ( 7 ) and the stabilizer plate ( 11 ) is
that the ratio of the area (F ₃ ) of the center nozzle ( 13 ) to the total area (F ₁ ) of all primary air holes ( 7 ) is approximately 0.8 to 1.0 and
that the ratio of the area (F ₃ ) of the center nozzle to the total area (F ₂ ) of all secondary air channels ( 12 ) of the stabilizer plate ( 11 ) is approximately 0.6 to 0.8.