DE102004006824A1 - Pore burner with silicon carbide pore body - Google Patents

Abstract

A pore burner (10) for burning a fuel-air mixture to produce a hot flue gas (22), comprising a housing (12) in which a pore material (16) made of porous, high-temperature-resistant silicon carbide (SiC) is provided for combustion, is characterized in that the pore body comprises siliconized carbon fabric, which has an orderly, regular structure. The fabric (16) made of silicon carbide can have a shape that deviates from a flat surface, for example a wave shape, and a plurality of fabric pieces (28, 30) can be stacked on top of one another.

Description

technical area

The The invention relates to a pore burner for burning a fuel-air mixture for generation one is called Flue gas containing a housing, in which a pore material made of porous, high temperature resistant silicon carbide (SiC) for combustion is provided.

On such pore burner is used, for example, to a steam superheater with a hot one To apply flue gas flow. The steam generated in the steam superheater has high temperatures and is under high pressure. The one in the steam stored energy can then be in the form of mechanical or electrical Energy can be used, e.g. B. by relaxation in one Expansion machine for driving a generator. The hotter the Steam and the higher the pressure, the better the efficiency of such machines. Accordingly, it is necessary that the flue gas flow if possible has high temperatures. Typical temperatures are in the range between 850 ° C and 1400 ° C.

The Differentiate pore burners for generating a hot flue gas stream in particular from a pure radiation burner, where only the radiant heat the burner is used and the flue gas produced as a by-product via a Chimney or an exhaust pipe is withdrawn. Such radiant burners are artificial, for example Open fire or radiant burner for drying paintwork. Radiant heat can also a pore burner can be used, the main part of the transferred to the steam generator However, energy comes from the flue gas.

From the DE 199 39 951 C2 a pore burner for burning a fuel / oxidant mixture is known. The pore burner is filled with spherical fillers. The size of the resulting pores is determined by the size of the packing. The known pore burner is designed so that an excessively high temperature in the reaction space is avoided by an additional cooling gas.

From the DE 195 27 583 C2 a pore burner is known which contains porous material which has spatially connected cavities which are formed by a packing made of heat-resistant wire, foil or sheet material. A defined flame zone forms in these cavities. The material is not suitable for high temperatures.

Pore burners are also known which are filled with a ceramic which has a large number of cavities, e.g. B. from the US 5,890,886 , Other foam ceramics, metal foams or sponges are also known, e.g. B. from the DE 196 21 638 A1 , These foams or sponges have the disadvantage that they are expensive to manufacture. They are also very sensitive to mechanical and thermal loads. They tear or burst under excessive load, which leads to reduced performance and increased pollutant emissions.

From the DE 198 47 042 A1 a highly porous burner mat is known which consists of metallic or ceramic fibers which are welded together in irregular structures. The mat is provided with holes through which the gas flows. Areas of different flow velocities are created, through which an irregular flame carpet is created which lifts off the surface of the mat.

It is the object of the invention to provide a pore burner, the one even combustion has and its pore structure directly in the manufacturing process can be influenced.

According to the Task solved by that the pore body Siliconized carbon fabric, which has an orderly, regular structure having. The invention is based on the knowledge that the Have the properties of a pore burner influenced if the Pore structure can be produced in a targeted manner. A weaving of the hard and brittle Silicon carbide material is not possible. By siliconizing one suitably shaped carbon fabric, however, it is possible to to create appropriately designed tissue structure from SiC. The Silicated tissue is inexpensive produced. It holds mechanical and thermal loads very well. The mesh size and flat The shape of the fabric is just as customizable as its size and outline, so that when using such materials as pore bodies for pore burners an optimization of the burner properties is possible.

In In one embodiment of the invention, the fabric made of silicon carbide one of a flat surface deviating form. Then a plurality of pieces of tissue can be stacked be layered. This way, no additional Spacers or the like a three-dimensional arrangement created with which the pore burner can be filled.

The fabric can be wavy his. However, other shapes are also possible, such as a profile that is sawtooth-shaped or box-shaped. In order to obtain a small pore size, on the one hand the tissue parameters can be kept small and on the other hand the waveform can be composed of a large number of small waves.

The Tissue can be made completely Silicated fibers exist. For However, for some applications it may also be useful for the tissue is partially silicided, and contains a core of pure carbon.

In a particularly preferred embodiment of the invention the ordered Structures are designed so that zones differ Develop porosity. The porous body of the burner in two or more zones of different pore sizes his. The inlet-side part of the porous body then has a smaller one Pore size than that outlet-side pores on. In this configuration, the flame forms in the large-pored Zone while in the fine-pored zone, a mixture and preheating of the fuel-air mixture occur. this leads to too low pollutant content in the flue gas during combustion the usual Fuels such as natural gas, gasoline or the like. The pore size can be determined by the selected ones Tissue and its arrangement, such as. B. stacking, be designed particularly well.

In an alternative embodiment of the invention is the fine-pored Part from conventional Porous materials are made, while the large-pored part is made of siliconized carbon fabric. The material of the fine-pored Part is preferably poorly conductive, so that heat transfer from the combustion zone into the premix zone is avoided. To this Wise one will kick back leaning against the flames.

The bending axes the waves of a piece of fabric can lie in one plane and the tissue pieces are arranged one above the other in such a way that the projections the wave normal to such a plane defined by the axes of curvature run perpendicular to each other. The wave normals preferably form then in each case an angle of approximately 45 ° to the direction of flow of the flue gas. A wave normal is the vertical on a wave front. It lies in the through the axes of curvature defined level. In this embodiment of the invention Pore structure formed from stacked wavy SiC mats. The individual levels are at an angle of approximately 90 ° to each other twisted arranged. This arrangement is for the combustion behavior of the burner particularly cheap. The structure flowed through in this way is called a static mixer. The fuel and the combustion air are mixed together in such a way that the fuel is particularly low in pollutants and complete is burned.

Preferably is the housing of the burner with an insulating layer. So an unwanted one convective heat transfer through the housing avoided in the periphery of the burner.

alternative can the housing wall from a cooling medium flows through be either discharged into the environment separately or with the hot flue gas is mixed in the outlet area of the burner.

refinements the invention are the subject of the dependent claims. One embodiment is explained in more detail below with reference to the accompanying drawings.

Short description of the drawings

1 is a schematic representation of a pore burner

2 shows a section of a wave-shaped piece of tissue made of silicon carbide

3 is section through a schematically shown pore burner

4 is a section along the line AA in 3 and shows the outlet of a pore burner

description of the embodiment

In 1 is schematically a pore burner 10 shown. The pore burner consists of a housing 12 , into which a fuel gas-air mixture is introduced. The direction of flow of the inflowing gas is through the arrows 14 shown. In the case 12 are a variety of fabric pieces 16 layered on top of each other. In a first zone 18 the pores are smaller and in a second zone 20 the pores are bigger. The porous material of the first zone 18 is not shown. In the second zone there is an oxidation in the pores without real flame formation. This creates hot flue gas, which in 1 by arrows 22 is represented. The flue gas is used to heat a steam generator. It is possible to place the steam generator within the radiation field of the pore burner 10 to be arranged so that not only the heat transferred by the flue gas is used, but also the radiant heat.

The tissue pieces 16 are in 2 presented again in detail. They consist of an essentially rectangular, net-like fabric. A variety of these pieces of tissue 16 is layered on top of each other. Every piece of tissue 16 is wavy around an axis of curvature 37 bent. The fabric pieces are stacked on top of each other so that the mountains 24 and valleys 26 the curvatures are alternately 90 degrees apart. This is in 3 seen. For example, the piece of fabric lies 30 offset by 90 degrees on the piece of fabric 28 on. The pore burner is completely with the tissue pieces 16 refilled. This creates a pore structure that allows particularly good, even flame development. The fuel / air mixture creates the porous body parallel to the planes of the individual tissue layers and in the direction of the bisector 34 the angle of rotation between the shaft normals 35 and the wave normal 39 flows through the layers.

In the present case, the pore burner has 10 a rectangular cross-section and is therefore also available with rectangular fabric pieces 16 filled. Has the pore burner 10 a differently shaped cross-section, the shape of the fabric pieces is of course adapted accordingly.

Furthermore, the housing 12 a coolant flows through the pore burner. In this case, the cooling air is separated into a cooling duct 38 ( 4 ) of the housing 12 fed and is at the outlet 40 mixed with the flue gas.

By the size of the mesh 32 , the radii of curvature of the wave valleys and mountains and the number of curvatures per piece of tissue can influence the pore size. In the present exemplary embodiment, the pore size is in the zone 18 ( 1 ) smaller and in zone 20 greater.

The fabric pieces consist of silicon carbide. Silicon carbide is a carbide Ceramic material and as such not woven. For the production Such a fabric is therefore a carbon fabric, which is brought into the appropriate shape and then siliconized. Suitable for silicating different processes. In the liquid siliciding process molten Silicon a porous Carbon fiber reinforced carbon (C / C) substrate infiltrates and reacts directly with the carbon of the matrix to SiC. The procedure is known and described for example on the Internet at http://www.fz-juelich.de/iwv/iwv1/index.php?index=8 and therefore does not need closer are explained.

The siliconized tissue pieces 16 are stiff after this process and can be inserted into the burner without any further change in shape. The material is resistant to high temperatures. The manufacturing process for flat SiC structures is inexpensive compared to sponge-like ceramic bodies, and the mechanical and thermal resilience is significantly higher than that of ceramic sponges.

Claims (8)

Pore burner ( 10 ) to burn a fuel-air mixture to produce a hot flue gas ( 22 ) containing a housing ( 12 ) in which a pore material ( 16 ) made of porous, high-temperature-resistant silicon carbide (SiC) for combustion, characterized in that the pore body comprises siliconized carbon fabric which has an orderly, regular structure. Pore burner ( 10 ) according to claim 1, characterized in that the fabric ( 16 ) made of silicon carbide has a shape deviating from a flat surface and a plurality of fabric pieces ( 28 . 30 ) are layered on top of each other. Pore burner ( 10 ) according to claim 2, characterized in that the fabric ( 16 ) is wavy. Pore burner ( 10 ) according to one of the preceding claims, characterized in that the fabric ( 16 ) consists of completely siliconized fibers. Pore burner ( 10 ) according to one of claims 1 to 3, characterized in that the fabric is partially silicided and contains a core of pure carbon. Pore burner ( 10 ) according to one of the preceding claims, characterized in that the ordered structures are designed such that zones of different porosity are formed. Pore burner ( 10 ) according to one of claims 3 to 6, characterized in that the axes of curvature of the waves of a piece of fabric lie in one plane and the pieces of fabric are arranged one above the other in such a way that the projections of the wave normals on such a plane defined by the axes of curvature are perpendicular to one another. Pore burner according to claim 7, characterized in that the Wave standards each have an angle of approximately 45 ° to the direction of flow of the flue gas form.