EP1353125A1 - Apparatus and method for treating exhaust gases from solid fuel fire places - Google Patents

Abstract

To clean the exhaust gas and smoke from a solid fuel burner, e.g. a domestic wood fire and the like, a ceramic network is in the exhaust path for the smoke and gas to flow wholly through it. When the burning fuel temperature drops, and during initial firing, the hazardous matter in the emission is wholly or partially deposited on the ceramic material to be burned off. The ceramic netting is of a ceramic foam or in a ceramic textile net structure, or it can be of fireclay or cordierite or sintered silicon carbide ceramic, and can be fitted with an electrical heating system.

Description

Field of application of the invention

The invention relates to the field of combustion technology and relates to a Device and method for the treatment of exhaust gases from solid fuel fireplaces, for example for burning wood in the home can be used.

State of the art

Devices for burning solid fuels, such as wood, are increasingly being used. The emission of particles and aerosols and especially pollutant particles is a problem that has not yet been sufficiently solved.
The treatment of exhaust gas flows from solid fuel fireplaces with lower heat outputs through filters has hitherto hardly been practiced, since there is a risk of clogging of the filter material by soot, tar and ash, combined with the result that the exhaust gas is not removed and deflagrations under unfavorable conditions can arise. The reduction of particle emissions is attempted without the use of filters by means of an appropriate firing system, with the result that solid fuel fireplaces nevertheless have the highest particle emissions among the fireplaces according to statistical evaluations.
With regard to the post-combustion of combustion products formed, there are already solutions in which part of the exhaust gas is passed over a catalytic converter and the other part-flow as a bypass bypasses it. It is therefore not possible to influence the exhaust gas flow conducted through the bypass. However, the bypass enables sufficient exhaust gas to be removed from the combustion chamber so that no dangerous situations can arise. Regeneration of the soiled catalytic converter is not possible when installed. Post-combustion of carbon monoxide and hydrocarbons is generally attempted by installing ceramic components with catalytic properties (eg lining the walls of the combustion chamber with fireclay) in the fireplace. Here too, only a part of the exhaust gas flow comes into contact with the material, ie only a part of the flow can be catalytically afterburned.
The previously used possibilities in the design of fireplaces with low heat output, as they are required in modern residential construction due to the significantly improved thermal insulation properties of the structure, pose problems. Small fireboxes with low fuel requirements lead to high emissions. The same applies to conventional devices if they are operated in part-load operation due to the low heat requirement.

Furthermore, the use of open-cell foam ceramics in the Exhaust gas dedusting and aftertreatment known. DE 37 05 793 A1 is a Filter apparatus for flue gas cleaning with a dust filter made of open-pore Foam ceramic specified, which is optionally coated catalytically effective. Such filter apparatus are usually the as separate components Firing systems with large outputs downstream and are accordingly large and technically complex. DE 37 05 793 A1 describes a Pre-separation achieved by a cyclone or a separating nozzle and only that Residual dust content separated in the foam ceramic. The exhaust of the The combustion system is blown into the filter housing. The cleaning of the Filters are also achieved through technically complex measures, for example by a compressed gas flow in the opposite direction of flow.

DE 37 20 963 C2 describes an apparatus and a method for the separation of Ash from flue gas through the use of of foam ceramic filters described. This is the cleaning of liquid ash droplets from coal dust furnaces at temperatures between 1200-1700 ° C, whereby the Flue gas is led through the foam ceramic under pressure. The separation of the Ash particles and regeneration of the filter are done by dripping or draining the ashes from the filter. Such a system and the cleaning process is included Solid fuel fireplaces cannot be used for technical reasons, as neither necessary temperatures, the gas pressures are still available.

DE-OS 196 27 028 specifies a flue gas filter system for wood-fired small furnaces, in which a regenerable filtering particle separator is installed in the exhaust air chimney of the furnace, which is combined with a subsequent additional device for chemical reduction of the gaseous pollutants by means of an oxidation catalyst. To ensure the function, an exhaust air blower is necessary, as well as two electrical heating devices, which are connected upstream of the filter and the catalytic converter. A complex, microprocessor-controlled control of the system with pressure transducers and thermocouples is necessary for operation. A ceramic fabric filter or fiber filter is specified as the filter material. The filter acts on particles as a cleaning process for the exhaust gas; cleaning takes place by burning off the soot particles as a result of switching on the additional electrical heater. The exhaust gas is cleaned continuously in the catalytic converter, which is heated by the second additional electrical heater to set its optimum operating temperature.
The proposed structure is technically complex and prone to failure: the separation of filter and catalyst requires two separate devices and for the operation of the cleaning system, the supply of electrical energy is both cyclical (for cleaning the particle filter) and continuously (for the functionality of the catalyst ) necessary. Functionality cannot be guaranteed without the complex control, regulation and monitoring technology of the system. An additional exhaust fan is also required.

State the nature of the invention

The object of the invention is to provide an apparatus and a method for Treatment of exhaust gases from solid fuel fireplaces, with which the Emission of pollutants over the entire performance range of a fireplace can be reduced.

The object is achieved by the invention specified in the claims. Further training is the subject of the subclaims.

In the inventive device for treating exhaust gases from Solid fuel fireplaces in which exhaust gas mass flows of up to 60 g / s occur A ceramic network is installed, which is in and / or above the combustion chamber is arranged so that a ratio of that separated from the ceramic network Volume of the solid fuel fireplace to the total internal volume of the Solid fuel fireplace from 0.5 to 0.95 is realized and still that Ceramic network from the exhaust gas flow completely or to a large extent is flowed through.

An open-cell foam ceramic or is advantageously used as the ceramic network ceramic network molded from textile structures (WO 99/28272).

Also advantageous is ceramic or cordierite or as ceramic material sintered silicon carbide ceramic is used.

Furthermore advantageously, the ceramic network is plate-shaped, the ceramic network each completely or at least in the combustion chamber predominantly of the further volume of the solid fuel fireplace in Separates in the direction of the exhaust gas flow. The filter plates are in the solid fuel fireplace arranged so that they have a larger area than that of the exhaust gas occupy the cross-sectional area of the combustion chamber, e.g. by Inclined arrangement, double or multiple inclined arrangement, or by Arrangement in the form of a multi-sided prism.

It is also advantageous to have the ceramic network in the form of one or more Hollow cylinders, hollow cones or truncated cones. It can too additional, known methods of filter surface enlargement are used, e.g. in which the filter surface is corrugated, folded, embossed, slotted, nubbed, etc.

The wall thickness of the filter plates have a constant thickness or have an advantageous embodiment also locally different thicknesses on or continuous changes in thickness. The beneficial change the filter thickness depends on the local flow situation of the filter and can be easily determined by experiment for the special fireplace.

It is also advantageous if the ratio of that of the ceramic network separated volume of solid fuel fireplace to the entire interior Volume of the solid fuel fireplace is 0.65 to 0.95.

It is also advantageous if the ceramic network has a density of 5 to 30% and still advantageously has from 7 to 15% of the pure density of the ceramic.

It is also advantageous if the ceramic network has a pressure loss of 20 20 Pa / cm at gas flow velocities ≤ 1 m / s and even more advantageous a pressure loss of ≤ 5 Pa / cm at gas flow velocities ≤ 1 m / s.

It is also advantageous if an open-cell foam ceramic with cell widths of 6 up to 60 ppi (pores per inch) or even more advantageously from 20 to 45 ppi is.

It is also advantageous if the cells of the open-cell foam ceramic are stretched are.

It is also advantageous if the ceramic network has a mesh size of 0.8 up to 15 mm or even more advantageously 1 to 10 mm.

It is also advantageous if the ceramic network in one, two or all three Different mesh sizes and / or depending on the direction Has mesh shapes.

It is particularly advantageous if the stitches are perpendicular to the Flow direction are greater than parallel to it, or even more advantageous if the mesh size perpendicular to the flow direction 5 to 10 mm and parallel for this purpose, be 1 to 2 mm.

Furthermore, it is advantageous if the ceramic webs of the ceramic network have a surface enlarged by micro- and / or macrostructuring.

Macro structuring of the webs forming the ceramic network is achieved, for example, by using fiber-flocked foams or textiles or by subsequent flocking with ceramic fibers or by using textiles made of fluffy multifilament yarns.
The microstructuring can be achieved, for example, by forming micropores <1 μm in the webs of the ceramic or by etching the surface of the ceramic webs <1 μm or by applying a ceramic layer with a high specific surface.

It is also advantageous if the ceramic network is wholly or partly made consists of a catalytically active material.

It is particularly advantageous if the surface of the webs of the ceramic network completely or partially coated with a catalytically active material.

It is also advantageous if as a catalytically active material for the Ceramic network iron compounds, platinum or platinum compounds used are.

Another advantage of the invention is that the ceramic network in several layers, levels, segments in the plane as well as one above the other is constructed.

It is also advantageous if the ceramic network with regard to its material and / or its structure and / or its mesh and / or cell width is structured differently.

It is also advantageous if the ceramic network is within one layer is constructed differently in terms of its mesh size.

It is also advantageous if the ceramic network is located in the radiation area Flame from solid fuel fireplaces is located.

It is also advantageous if the ceramic network between the combustion chamber and Exhaust collector is arranged.

It is also advantageous if the ceramic network can be heated electrically.

It is also advantageous if the entire exhaust gas flow is passed through the filter is.

In the inventive method for the treatment of exhaust gases from Solid fuel fireplaces are switched on during the heating phase and during a lowering of the temperature caused by the fuel layer below the ignition temperatures of the pollutants the resulting pollutants in whole or in part on the Surface of a ceramic network deposited, which in and / or above the Firebox is arranged so that a ratio of that of the ceramic network separated volume of solid fuel fireplace to the entire interior Volume of the solid fuel fireplace from 0.5 to 0.95 is realized and after the heating phase or a temperature drop on the surface of the Ceramic network accumulated pollutants directly through the flame or by the radiation of the flame in the combustion chamber or by the hot exhaust gases be burned.

By burning the pollutants, such as soot and condensed hydrocarbons, cleaning in or on the ceramic network of the ceramic network.

Solid fuel fireplaces are fireplaces that are used to heat rooms and / or serve the hot water supply, are operated with solid fuels and together with the exhaust system form the combustion system. Individual and Be collective fireplaces. The definitions used here are part of the Firing regulations of the federal states and the Federal Immission Control Ordinance. European definition of these fireplaces applies: "Space heating systems solid (...) fuels burn for use in buildings "(decision of the European Commission, Official Journal EC L184 of July 17, 1999).

Solid fuel fireplaces are nationally and European standardized. You are as Building products in the Building Regulations List A Part 1 and 2 of the German Institute for Construction technology included.

Solid fuels are biogenic or fossil, solid fuels. To the biogenic solid Fuels include essentially lumpy or natural non-piece wood and pellets made of natural wood. Fossil solid Fuels are hard and brown coal coke as well as hard and brown coal briquettes. The fireplaces are connected to exhaust systems.

• Leistungsbereich bis 50 kW
• Abgastemperaturen bis 400 °C
• erforderliche Mindestabgasförderdrücke 8 bis 25 Pa
• Abgasmassenströme bis 60 g/s.

Fireplaces are essentially characterized by the following services:

• Power range up to 50 kW
• Exhaust gas temperatures up to 400 ° C
• required minimum exhaust gas delivery pressures 8 to 25 Pa
• Exhaust gas mass flows up to 60 g / s.

The use of ceramic networks as filter material for solid fuel fireplaces is advantageously carried out over the firebox. Installation can be in a frame in the form of plate-shaped filters, with several Layers of the ceramic network in the same or different mesh or Cell width can be arranged one above the other. This allows the filter to be used entire flow area of the exhaust gas can be effectively installed. Other Geometries for increasing the inflow area are possible.

The open-pore structure of the ceramic network used results in a filtration of the particles and aerosols (soot, condensed or gaseous hydrocarbons) that are deposited on the large surface of the ceramic network, without the limit values for device-specific maximum delivery pressures being exceeded when the exhaust gas flows away.
To clean the ceramic network from these deposits, the temperature of the ceramic network is increased above the ignition temperature of the deposited pollutants in the fireplace and / or in the exhaust gas stream or via the introduction of auxiliary energy, and thus the accumulated pollutants are burned off.

A simultaneous afterburning of carbon monoxide still contained in the exhaust gas and hydrocarbons is also possible if the material of the Ceramic network consists of a catalytically active material or with a catalytically active material is coated.

The invention makes it possible to achieve a substantial reduction in emissions from solid fuel fireplaces. This is possible, in particular, by filtering the entire exhaust gas flow and afterburning still combustible components of the exhaust gas. As a result, a higher pollutant reduction can be achieved compared to influencing exhaust gas partial flows or catalytic combustion chamber cladding elements.
The effectiveness of the filtration and post-combustion is given over the entire performance range of the fireplace, ie especially at partial load.

For the implementation of the method according to the invention and for guarantee the functionality of the device according to the invention has been proven pointed out that it is not sufficient to place the filter in any place in the Built in fireplace, but that a certain relationship between the Volume of solid fuel fireplace separated by the filter, i.e. the Volume in which the combustion takes place before the flue gas passes the filter reached, and the total internal volume of the solid fuel fireplace must be observed. This ratio is 0.5 to 0.95, preferably 0.65 to 0.95. If the ratio is too low, <0.5, the combustion becomes unfavorable influenced, so that the resulting pollutants, especially CO and Hydrocarbons, too high due to insufficient combustion, so that the filter effectiveness is not sufficient to be compared to an improvement combustion in a fireplace without a filter. Is the relationship to large (> 0.9), the filter volume and thus the available filter inflow area is too small, which makes the filtration itself less effective and the pressure loss through the Filter rises, so that there is also insufficient combustion of the Fuels is coming.

A second parameter is from the above Reason for the size of the filter inflow area in the Reference to the volume of the fireplace. It will be as high as possible Filter inflow area sought, without the volume of the separated by the filter To reduce combustion chamber too much. In the simplest case, the filter becomes a surface have the horizontal cross section of the combustion chamber of the fireplace equivalent. A favorable enlargement results if the filter area is larger than this cross section is made, i.e. the quotient of the filter area and that of Flue gas flow area of the fireplace should be greater than / equal to 1, advantageously greater than or equal to 1.5. The simultaneous consideration of the above Volume ratio results if the above Volume ratio with the Area ratio is multiplied. This factor should be 0.5 or greater, advantageously greater than 1.5. If it is lower, the above-mentioned negative effects.

Way to perform the invention

The invention is explained in more detail using several exemplary embodiments.

example 1

In a wood-burning stove with a nominal heat output of 7 kW, an exhaust gas temperature of 230 ° C, the required minimum exhaust gas delivery pressure of 12 Pa and an exhaust gas mass flow of 9.7 g / s, a filter material is installed between the combustion chamber and the exhaust gas collector. The filter material consists of an open-cell foam ceramic made of cordierite with a cell width of 20 ppi with the dimensions 360 x 165 x 20 mm. Two of these plates are installed diagonally into the fireplace in a metal frame bracket, one of the short long sides of the panels touching and the other sides of the panels are attached to the walls of the fireplace. The arrangement of the two filter plates separates a wedge-shaped volume of 6 l in the fireplace. The combustion chamber of the stove has a volume of 55 l without a filter and a horizontal cross-section of 200 x 360 mm; the remaining volume below the filter, in which the combustion takes place, is still 49 l after installing the filter. The ratio of this volume to the volume of the entire interior of the fireplace is thus 0.89. The filter inflow area of the two filters is 1188 cm ² and is in a ratio of 1.65: 1 to the cross-sectional area of the fireplace that is flown by the exhaust gas. Multiplying the area ratio to the volume ratio mentioned above gives 1.47.

When the stove is operated, all of the exhaust gases are removed by the filter material Exhaust gas collector and existing pollutants such as soot, tar and Condensed hydrocarbons are on the surface of the filter material deposited. The filter material reaches due to the temperature of the exhaust gases and the radiation from the combustion chamber a temperature level, which for Afterburning of carbon monoxide and hydrocarbons leads. The Temperature in the filter continues to increase, so that a temperature above that Ignition temperature of the accumulated pollutants is reached and thus the accumulated pollutants are burned. So that the filter material is back cleaned and the surface free again.

Example 2

In a wood chip boiler with a nominal heat output of 30 kW, exhaust gas temperature of 190 ° C, required minimum exhaust gas delivery pressure of 25 Pa, exhaust gas mass flow of 33 g / s and a combustion chamber volume of 165 l, a plate-shaped ceramic network is created between the combustion chamber and the heat exchanger Frame is fixed, built in. The ceramic network is made by molding a textile spacer fabric. The ceramic consists of sintered silicon carbide.
First there is a textile knitted spacer fabric, in which rhombohedral lattice meshes with edge lengths of 6 mm are arranged on the top and bottom with vertically oriented wales, which are spaced apart by approx. 2 mm and the top and bottom with a spacing connect by 4 mm. These are knitted from polyester monofilament yarn from dtex 277.
Then there is a textile spacer fabric, in which rhombohedral lattice meshes with edge lengths of 3 mm are arranged on the top and bottom with vertically oriented wales, which are spaced apart by about 0.5 mm and the top and bottom with connect at a distance of 2 mm. These are knitted from polyester monofilament yarn from dtex 56, with the upper side being velorized.
Four layers of the spacer fabric with the coarser meshes and one layer of the spacer fabric with the finer meshes are stacked on top of one another and arranged so that the rhombohedral meshes are perpendicular to the direction of flow. These layers are converted to ceramic network plates with the dimensions 250 x 300 x 18 mm using known methods. The ceramic network maintains the same structuring as the textile spacer fabrics. Four of these plates are installed next to each other in a metal frame, resulting in a filter area of 500 x 600 mm (3000 cm ² ). The frame with the 4 filter plates is installed vertically in the fireplace with a distance of 150 mm from the rear wall. The surface of the plates with the finer meshes faces the heat exchanger and a volume of 45 l is separated. The remaining volume in front of the filter is 120 l; whereby the ratio to the total volume of the fireplace (165 l) is then 0.73.
The filter area is equal to the cross-sectional area of the fireplace that is flown by the exhaust gas, resulting in a quotient of 1 and the factor from this quotient with the volume ratio is also 0.73.
By positioning the plates in the boiler, the resulting exhaust gas is completely passed through the ceramic network.
The ceramic network causes a pressure drop of 10 Pa / cm, measured at a flow rate of 1 m / s.
When the wood chip boiler is operated, all the exhaust gases are led through the filter material to the exhaust gas collector and pollutants still present, such as soot, tar and condensed hydrocarbons, are separated on the surface of the filter material. Due to the temperature of the exhaust gases and the radiation from the combustion chamber, the filter material reaches a temperature level which leads to the afterburning of carbon monoxide and hydrocarbons. The temperature in the filter continues to increase, so that a temperature above the ignition temperature of the accumulated pollutants is reached and thus the accumulated pollutants are burned. The filter material is cleaned again and the surface is free again.

Claims (36)

Device for the treatment of exhaust gases from solid fuel fireplaces, in the Exhaust gas mass flows of up to 60 g / s occur, and in the case of a ceramic network is installed, which is arranged in and / or above the firebox, that a ratio of the volume of the Solid fuel fireplace to the total internal volume of the Solid fuel fireplace from 0.5 to 0.95 is realized and still that Ceramic network from the exhaust gas flow completely or to a large extent is flowed through. Apparatus according to claim 1, in which an open-celled ceramic network Foam ceramic or a ceramic network molded from textile structures is used. Apparatus according to claim 2, in which chamotte or as the ceramic material Cordierite or sintered silicon carbide ceramic is used. The device of claim 1, wherein the ceramic network is plate-shaped is formed, the ceramic network completely the firebox or at least to a large extent from the further volume of the Solid fuel fireplace separated in the direction of the exhaust gas flow. The apparatus of claim 1, wherein the filter plates in the solid fuel fireplace are arranged so that they are inclined, double or multiple oblique arrangement, or by arrangement in the form of a multi-sided Prisms a larger area than the cross-sectional area flowed by the exhaust gas of the fireplace. The device of claim 1, wherein the ceramic network is in the form of an or several hollow cylinders, hollow cones or truncated cones. Device according to claim 1, in which the filter surface is corrugated, folded, embossed, slotted, nubbed. The device of claim 1, wherein the wall thickness of the ceramic network a constant thickness, locally different thicknesses or continuously changes in thickness. The apparatus of claim 1, wherein the ratio of that of Ceramic network separated volume of the solid fuel fireplace to the total internal volume of the solid fuel fireplace is 0.65 to 0.95. The device of claim 1, wherein the ceramic network has a density of 5 to 30% of the pure density of the ceramic. The device of claim 10, wherein the ceramic network has a density of 7 up to 15% of the pure density of the ceramic. The device of claim 1, wherein the ceramic network has a pressure drop of ≤ 20 Pa / cm at gas flow velocities ≤ 1 m / s. The apparatus of claim 12, wherein the ceramic network has a pressure drop of ≤ 5 Pa / cm at gas flow velocities ≤ 1 m / s. Apparatus according to claim 1, wherein an open-cell foam ceramic with Cell widths from 6 to 60 ppi are used. Apparatus according to claim 14, wherein an open-cell foam ceramic with Cell widths from 20 to 45 ppi are used. The device of claim 1, wherein the cells of the open cell foam ceramic are stretched. The device of claim 1, wherein the ceramic network is a mesh size from 0.8 to 15 mm. Apparatus according to claim 17, wherein the ceramic network mesh sizes 1 up to 10 mm. Apparatus according to claim 1, wherein the ceramic network in one, two or Different mesh sizes in all three spatial directions depending on the direction and / or has mesh shapes. Apparatus according to claim 19, wherein the stitches are perpendicular to the Flow direction are larger than parallel to it. Apparatus according to claim 20, wherein the mesh size is perpendicular to Flow direction 5 to 10 mm and parallel to it 1 to 2 mm. Apparatus according to claim 1, wherein the ceramic webs of the Ceramic network an enlarged by micro and / or macro structuring Have surface. The apparatus of claim 22, wherein the macrostructuring of the Bridges forming ceramic network by using fiber-flocked Foams or textiles or by subsequent flocking with ceramic fibers or by using textiles from fluffy Multifilament yarn is reached. The apparatus of claim 22, wherein the microstructuring is through formation of micropores <1 µm in the webs of the ceramic or by etching the Surface of the ceramic bars <1µm or by applying a ceramic Layer with a high specific surface is reached. The device of claim 1, wherein the ceramic network is wholly or partially consists of a catalytically active material. Apparatus according to claim 1, wherein the surface of the webs of the Ceramic network entirely or partially with a catalytically active material are coated. Apparatus according to claim 25 and / or 26, in which acts as a catalytic Material for the ceramic network iron compounds, platinum or Platinum compounds are used. Apparatus according to claim 1, wherein the ceramic network in several Layers, levels, segments in the plane as well as on top of each other. Apparatus according to claim 1, wherein the ceramic network in terms of its Materials and / or its structure and / or its mesh and / or cell width is structured differently. The apparatus of claim 29, wherein the ceramic network is within one Layer is constructed differently with regard to its mesh size. Apparatus according to claim 1, wherein the ceramic network in the Radiation area of the flame from solid fuel fireplaces is located. Apparatus according to claim 1, wherein the ceramic network between the firebox and exhaust manifold is arranged. The device of claim 1, wherein the ceramic network is electrically heated is. The device of claim 1, wherein the total exhaust gas flow through the filter is led. Process for the treatment of exhaust gases from solid fuel fireplaces during the heating up phase and during a fuel load Lowering the temperature below the ignition temperatures of the pollutants the resulting pollutants in whole or in part on the surface of a Ceramic network are deposited, which in and / or above the Firebox is arranged so that a ratio of that from Ceramic network separated volume of the solid fuel fireplace to the total internal volume of the solid fuel fireplace from 0.5 to 0.95 is realized and after the heating phase or a temperature reduction pollutants deposited on the surface of the ceramic network immediately by the flame or by the radiation of the flame in the combustion chamber or be burned by the hot exhaust gases. 36. The method of claim 35, wherein by burning the pollutants in Form of soot and condensed hydrocarbons in or on the Ceramic network the cleaning of the ceramic network is carried out.