DE2125365C3 - Radiant burners for gaseous fuels - Google Patents

Description

45

The invention relates to a radiant burner for gaseous fuels with a fuel nozzle and a mixing tube, into which the fuel from the nozzle with simultaneous suction of main air is injected, with a mixing chamber connected to the mixing tube, a cylindrical outer one Element made of heat-resistant and heat-permeable material that attaches to its lower end the bottom wall of the mixing chamber is fixed with a cylindrical grid of metal wires that is arranged within the cylindrical outer member and coaxial therewith to an annular To form space that is in communication with the mixing chamber, with an annular cap that the upper end of the annular space closes, and with a base plate that the lower End of the cylindrical grid closes and is arranged above the bottom wall of the mixing chamber.

In US-PS 33 91 983 a radiant burner of this type is described in which within the cylindrical grid made of metal wires yet another cylindrical grid made of metal wires coaxially is arranged. Of these two grids, however, the inner cutter is not suitable for burning promote or support, so that the combustion of the fuel-air mixture exclusively at the Inner surface of the outer grid takes place.

Therefore, if an amount of fuel in excess of the capacity of the outer grille is fed to the radiant burner, incomplete combustion occurs, which is associated with the production of toxic carbon monoxide. This extremely adverse fact is due to the fact that the inner grid is heated only to a temperature of about 800 ⁰ C, but insufficient to cause complete combustion of the hindurcnströmenden through the inner grid and only partially combusted fuel gas streams.

From BE-PS 5 22 262 a radiant burner is already known in which a perforated Ceramic plate from which the fuel-air mixture emerges, several rods made of a heat-resistant material with low thermal conductivity are assigned. These rods are in a parallel to the ceramic plate Level arranged at mutual distance. It is provided that the rods from the on the surface The flames created by the ceramic plate can be heated to a red glow in order to radiate heat and thereby improving the combustion of the fuel-air mixture. A similarly designed radiation burner is also known from GB-PS 9 05 481.

In the case of the radiant burner of this known type, however, each rod is only part of its own The surface of the flat combustion zone formed by the ceramic plate faces the predominant The surface area of the rods therefore faces the environment, the temperature of which is of course is considerably below the temperature prevailing in the combustion zone. This condition However, this has the consequence that the rods are cooled more from the environment than they are heated up by the combustion zone.

In addition, in this arrangement, the bars are mutual only between adjacent bars Influence or a thermal interaction due to thermal radiation is possible.

The invention is based on the object of providing the radiant burner of the type mentioned at the beginning to the effect that complete combustion is achieved at a high temperature.

According to the invention, this object is achieved in that a plurality of rods within the cylindrical grid made of a heat-resistant material with low thermal conductivity with a mutual distance circular are arranged.

In the radiant burner according to the invention there is a thermal interaction not only between each of the rods and the cylindrical grid and between two adjacent rods, but also between each pair of diagonally opposite rods. So every single rod is thermally interrelated with the totality of the other rods. This has the advantageous result that the region surrounded by the rods central space of the burner is heated to a high temperature, which is generally at 900 ⁰ C. At this high temperature, the burned gas mixture rises in the central space of the burner, creating a strong upward draft to remove the fuel-air mixture.

m> i.ch for combustion from the mixing chamber through the Continuously sucking in the grid strongly into the central space. This creates turbulence, which the Affect gas flow in a beneficial way and cause the incompletely burned fuel comes into contact with the red-hot rods for complete combustion Radiant burner according to the invention is therefore universal for a large number of gaseous fuels suitable.

The radiant burner according to the invention acts as a high-temperature furnace, which has a small size emits very strong heat radiation with a wavelength of about 3 μ, so that it can be seen as heat and Drying device is ideal.

Appropriate materials for the rods are specified in the subclaims, for these Materials but no independent protection is sought, but only in connection with the Subject matter of claim 1 should be protected.

The invention is described below with reference to a preferred exemplary embodiment shown in the drawing explained in more detail. It shows

F i g. 1 is a perspective view of an inventive Radiant burner, cut open to better illustrate its internal structure is and

F i g. 2 shows a cross section along the line H-II in FIG. 1.

The in F i g. 1 has a fuel supply line 11 in which a valve 12 to adjust the fuel flow is provided The valve 12 is connected to a fuel nozzle 13, which extends into an air-fuel mixing tube 14. The end of the mixing tube 14 at which the nozzle 13 is connected to a device 16 for adjusting the main air flow into the mixing tube 14 Mistake. The latter opens at its other end in a mixing chamber 15, which is partially of a annular bottom wall 15a and a cylindrical wall 156 which extends at right angles from the outer peripheral edge of the bottom wall extends upward. An annular flange 17a is on the outer Peripheral surface of the cylindrical wall 15b is rigid attached to this to limit an upwardly open annular groove 17i> cooperate, in which an annular, heat-resistant seal 17 is arranged. A cylindrical hollow member 18 from heat-resistant and heat-permeable material, such as. 3. Quartz glass, is in the lower end Annular groove 17b added. The cylindrical hollow member 18 is at its other or upper end in a downwardly open annular groove 19a received by an outer peripheral edge portion of an annular upper element or a cap 19 is limited. An annular seal 17 'which the Seal 17 is similar, is between the top of the hollow member 18 and the bottom of the annular groove 19a inserted. A cylindrical grid 20 of metal wires is set within the cylindrical hollow member 18 in Distance 51 arranged from this. The cylindrical grid 20 is at the upper end on the inner one Fastened to the peripheral edge of the cap 19 and closed at its lower end by means of a base plate 21. In addition, a plurality of rods 23 made of a heat-resistant material are provided within the cylindrical grid 20 low thermal conductivity arranged at a mutual distance, with each rod 23 at the lower end is carried by a bracket 24 which extends from a cylindrical portion of the bottom plate 21 inward extends. The upper ends of the bars are supported by similar brackets 24 'extending from the inner Peripheral edge of the cap 19 extend inward and are attached to this.

The details of the radiant burner 10 are explained below. The fuel supply line 11 is connected to the input side of a valve housing 12b which receives a valve plug 12a. the One end of the fuel nozzle 13 is connected to the outlet side of the valve housing 12b and with its other end facing the inlet 14a of the mixing tube 14.

The device 16 for adjusting the main air flow has a stationary plate 16a and one opposite this rotatable plate 16b. The stationary plate 16a is provided with an arcuate opening 16c, and the rotatable plate 16b is provided with a similar opening (not shown) so that this Openings can be brought more or less to coincide by rotating the plate 16b, around the Adjust the main air flow in the mixing tube 14 according to the respective type of fuel and thereby a to achieve complete combustion. A slot 16d is provided in the stationary plate 16a as a sliding guide arranged in which a pin 16a connected to the rotatable plate 16b engages.

The mixing tube 14 consists of a converging inlet 14a and a diverging mixing section 14b. The mixing portion 14b is at its upper end with the inner peripheral edge of the annular Bottom wall 15a of the mixing chamber 15 connected.

The mixing tube 14 can have the following dimensions, for example:

The diameter D of the inlet 14a is 60 mm,

the diameter d of the constriction is 20 mm,

the diameter θ of the upper end of the mixing portion 14b is 30 mm and

the length / of the mixing section 14b is 140 mm.

These dimensions are suitable for a case in which the radiant burner 10 with a nozzle of 2.7 mm diameter is operated with town gas of 4500 kcal / m ³ under a pressure of 40 to 100 mm water column. In this case, the burner has a heat output of 3000 kcal / h, the fuel gas is supplied under a pressure of 70 mm water column and the air passage opening 16c is set so that it has an area of 0.78 to 5.85 cm ² .

The cylindrical grid 20 consists of wires made of heat-resistant metal, such as. B. iron-chromium or nickel-chromium, which have a diameter in the range from 0.15 to 0.55 mm. The grid 20 can have twenty to fifty wires over a length of 25.4 mm in the axial and radial directions. The The grid 20 is arranged at a distance S1 within the outer cylindrical element 18.

Within the cylindrical grid 20, a plurality of rods 23 are spaced apart from one another S3 arranged in a circle, the spacing of the rods 23 from the grid S 2.

In a preferred embodiment, the rods 23 are made of sintered porous material, whose main component is "clay". In addition to

the α-alumina may contain the sintered material CaO, MgO, SKh .

For example, a burner that should generate a heat output of 300 kcal / h can be constructed with the following widths:

Wire for the grid 20 0.25 mm diameter Mesh size of the Grid 20 40 mesh Length of the grid 20 90 mm Diameter of the Grid 20 72 mm Diameter of the rods 23 6 mm Spacer 10 mm Distance 5 2 2 mm Distance S3 20 mm

Next, the operation of the radiation burner is described, when the valve 12 is open, so the fuel gas is passed through the nozzle 13 into the mixing tube 14, whereby it sucks air through the opening 16c into the mixing tube fourteenth The fuel gas-air mixture thus formed is passed into the mixing chamber 15. The mixture is fed evenly to the grid 20 and exits through the meshes of the same into the central interior space. When the mixture is ignited, the combustion takes place on the inner surface of the grille to heat it to red heat. The combustion is such that the flames protrude radially inward from the grid 20 against the rods 23, whereby these are heated. Since the rods 23 have poor thermal conductivity, they facilitate complete combustion of the incompletely burned fuel in their vicinity once they have been heated by the flames. As the fuel is completely burned, the sticks are heated even further to red heat. In this way there is a thermal influence between the red-hot cylindrical grid 20 and the red-hot rods 23, so that their surfaces are kept at a considerably increased temperature and the inside of the radiant burner is heated to a considerably increased temperature.

ϊο For this reason, the grille generates an infrared beam len which emerge into the environment through the outer cylindrical element made of glass.

The completely burned gas mixture can escape from the top of the radiant burner.

1 sheet of drawings

Claims (6)

Patent claims: 1. Radiant burner for gaseous fuels with a fuel nozzle and a mixing tube into which the fuel is injected from the nozzle with simultaneous suction of main air, with a mixing chamber connected to the mixing tube, a cylindrical outer element made of heat-resistant and heat-permeable material, which is attached at its lower end to the bottom wall of the mixing chamber, with a cylindrical grid of metal wires, which is arranged within the cylindrical outer member and coaxially to this to form an annular space which is in communication with the mixing chamber, with a annular cap which closes the upper end of the annular space, and with a base plate which closes the lower end of the cylindrical grid and is arranged above the bottom wall of the mixing chamber, characterized in that a plurality of rods (23) within the cylindrical grid (20) from a heat-resistant n material with low thermal conductivity are arranged in a circle at a mutual distance. 2. Radiant burner according to claim 1, characterized in that the rods (23) made of sintered Material. 3. Radiant burner according to claim 2, characterized in that the main component of the sintered material is α-alumina 4. Radiant burner according to claim 1, characterized in that the rods (23) made of ceramic Material. 5. Radiant burner according to claim 1, characterized in that the rods (23) made of glass exist. 6. Radiant burner according to claim 1, characterized in that the rods (23) made of metal exist.