DE3705793A1 - Filter apparatus for gas purification - Google Patents

Abstract

A filter apparatus for gas purification comprises the combination of a dust filter, which is insensitive to heat and flying sparks, with a catalyst element in one module. The dust filter element used can be an open-pored expanded ceramic, which at the same time can have a catalytic coating. Dust filters which can also be used are filters, which are resistant to heat and flying sparks, having ceramic nonwoven fibre webs, nonwoven steel wire webs or packed bed filters or suitable centrifugal separators, e.g. a separation nozzle, which are arranged as a module with a catalyst in the form of a coated expanded ceramic.

Description

The invention relates to a filter apparatus for gas purification and / or detoxification of exhaust gases from ther mixing processes, e.g. B. furnaces, kilns, Melting furnaces, drying plants, whereby dust and / or gaseous pollutants from the exhaust gases should be removed.

For example, furnaces for wood waste or bark in large numbers for medium-sized companies Companies such as furniture factories, sawmills and Like., installed and naturally have a lot lower heat output than large power plants.

It is a known fact that the flue gas cleaning in relation to the entire furnace and boiler system becomes more complex, ever the incinerator is smaller. Example wise would be a flue gas washer, as in Coal power plants for flue gas desulfurization or is common at waste power plants, probably more expensive than the entire furnace and boiler with such a wood waste firing.

For example, with wood waste combustion also assign the dusts too fine to be used in electro filter to be deposited sufficiently. In addition, electrostatic precipitators are also ge nerell too expensive for all smaller furnaces plants or similar exhaust gas emitters.

For example, facilities for Dedusting, where the gas is cyclonic Housing tangential as in a cyclone separator is blown in. Coarser particles become  flung on the inside wall of the housing and finer Particles on a fabric filter, e.g. B. from one or more bag filters, inside the cyclone-like housing. Filter hose or filter bags with fabric or fiber However, tiles have the disadvantage that they are hot Exhaust gases that may also contain sparks be destroyed very quickly. In many cases is even the deposition in a temperature zone richly desirable in the fabric or fiber Do not use tiles made of glass fibers anymore are cash.

The catalytic conversion of gaseous pollutants requires a support material for a catalytic effective coating that is also as high as possible Endures temperatures, flying sparks and the like.

The object of the invention is to create a filter apparatus for gas cleaning, in which both the filter elements for dust separation as well as catalytic conversion elements gaseous pollutants high temperatures and Can withstand flying sparks.

The invention solves this problem, as in the Claims has been described.

The advantages of the invention result from the Fact that elements made of open-cell foam ceramics turned on even at very high temperatures can be placed and completely insensitive, for example against flying sparks. This is true both for dust filter elements with accordingly fine-pored fine ceramics as well as for catalytic coated elements, their pore structure  is generally much larger.

Even if for dust separation or dust pre-separation separating nozzles known per se before the others Foam ceramic elements are used, so it is possible to also use these separating nozzles ceramic materials for very high temperatures to manufacture. In the area of lower exhaust gas temperatures, such as behind wood waste burners but also metal separation nozzles completely insensitive against flying sparks.

Of course, sparks-insensitive and relatively temperature-resistant fabric filter made of high temperature-resistant stainless steel fiber tiles or made of pure quartz fibers in front of the cat layered foam ceramic elements to follow catalytic pollutant conversion be set.

It is particularly advantageous if the dust filter elements with the catalytically coated elements ten in an apparatus or a housing component are summarized. So far you needed practically always a dust filter unit in a separate one Housing, be it an electrostatic filter or fabric filter, and in a separate apparatus the catalyst for Um conversion of gaseous residual pollutants.

The figures show some examples of a fiction according filter apparatus for gas cleaning:

Fig. 1 shows an example of a filter apparatus with a single tubular body made of heat-resistant foam ceramic, which is also effective as a dust filter and with a corresponding coating as a catalyst. Fig. 2 shows an analog ges example, in which the actual filter body and possibly catalyst made of foam ceramic polygonal is composed of plate-shaped elements. Fig. 3 shows a filter apparatus in which a dust filter unit - candles in the example of multiple filters or filter bags consisting - is in a building or housing unit to be summarized - with a catalyst unit - in the example also with several filter candles.

Fig. 4 shows an example in which a unit for dust separation with a separating nozzle and a further unit for catalytic gas conversion with coated elements made of ceramic foam is combined in one unit or housing unit.

In Fig. 1, the gas 2 is blown tangentially into the cyclone-like housing 1 . Particles contained in the exhaust gas 2 are discharged through the rotary valve 3 or an equivalent lock.

The tubular body 4 made of ceramic foam is arranged concentrically in the housing 1 . This is divided on the inside by radial walls 5 into several chambers 6 . In a cylindrical tubular body 4 - as shown - the chambers 6 have the cross section of circular segments, in a polygonal tubular body, the cross section is triangular. The tube body 4 is closed abge below by a plate 7 or by a corresponding disk made of foam ceramic. At the top, the tubular body 4 opens into a flap control apparatus 8 , in which closure flaps or valves (not shown) for the individual chambers 6 are installed with an automatic control system. At least one chamber 6 is closed by a flap or a valve and at the same time acted upon by a stream of compressed gas from the inside to the outside. The compressed gas is passed through the channel 9 into the control apparatus 8 . The circumferential section of the tubular body 4 assigned to the chamber 6 , which is acted upon by the compressed gas, is cleaned of the dust accumulated on the outside. All other chambers 6 are connected by the control apparatus 8 directly to the clean gas nozzle 10 through which the cleaned exhaust gas - for example via a suction fan in a chimney - is passed on. The apparatus according to FIG. 2 is practically analogous, except that instead of the tubular body 4 a - in this example polygon-shaped - outer tubular body 11 and the same inner tubular body 12 are arranged, the radial walls 5 only in the annular space between the two tubular bodies 11 and 12 form the chambers 6 . In this case, these chambers have a trapezoidal cross section. This arrangement of two or more tubular bodies arranged concentrically one inside the other increases the effective filter area considerably. All functions are analogous to the schematic representation and description of FIG. 1.

In Fig. 3, the exhaust gas 2 is blown into the crude gas chamber 13 in the housing 1. With a cylindrical housing 1 , this can be done tangentially, such as with a cyclone separator. Dust particles entrained in the exhaust gas 2 are discharged after their separation by a rotary valve 3 or an equivalent lock or screw.

Within the housing 1 in the raw gas space 13 , numerous rich candle or tubular filter elements 14 are arranged. These filter elements 14 can consist of extremely fine-pored foam ceramics, of sintered ceramics or of bag filters, preferably with heat-resistant fiber fleece or fiber fabric. For example, stainless steel fibers are suitable as heat-resistant fiber material, glass fibers, quartz fibers or other fibers made of heat-resistant ceramic material up to certain limits.

These filter elements 14 are closed from below by a plate 7 , this can also be a disk made of filter material, such as fine-pored foam ceramic or the like.

The filter elements 14 open at the top into the flap control apparatus 8 , which is designed as described in FIGS . 1 and 2. As in these FIGS. 1 and 2, the compressed gas (purge gas) is passed through the channel 9 into the control device 8 .

The dedusted gas then passes from the control apparatus 8 into the clean gas space 15 in the upper part of the housing 1 . In this clean gas space 15 , the catalyst elements 16 are arranged, which can have candle-shaped, tubular or pocket-like shapes. These catalyst elements 16 are preferably made of a coarse-pored foam ceramic which is coated with suitable metal oxides or metal compounds or also directly with pure metals. As a carrier material for the coating for the catalytic converter elements 16 , however, it is also possible to use fabrics or tiles made of high-temperature-resistant material, such as quartz fibers or stainless steel fibers.

The dedusted and catalytically detoxified flue gas then leaves the filter apparatus through the clean gas nozzle 10 .

In Fig. 4, the flue gas stream 2 in a known, so-called. "Separating nozzle" 17 in the dust-free gas stream 18 and the gas-dust concentrate 19 is divided. The dedusted gas 18 passes as in Fig. 3 in the clean gas space 15 with the catalyst elements 16 and leaves through the clean gas nozzle 10 the Fil apparatus.

The gas-dust concentrate 19 can, if this is technically possible in terms of combustion, be returned to the furnace so that the dust particles can agglomerate and be carried away with the ash.

However, it can also be followed by a dust filter device according to FIGS. 1, 2 or 3 (lower half of FIG. 3) for the gas-dust concentrate 19 , this dust filter apparatus being able to be made smaller because of the significantly lower gas volume. In an arrangement according to FIG. 3, 17 adjacent to the housing 1 of the filter apparatus are angeord net, the separating nozzle and the gas-dust concentrate 19 is a directed un indirectly in the Rohgasstutzen for the raw gas 2, while the clean gas 18 unmittbar into the clean gas space 15 in 3 is eingelei tet upper part of FIG.. In this case, for example, a structural unit or even a housing unit can also be implemented.

The invention is not limited to the Darge presented examples. For larger flue gas throughputs, the filter elements 14 and the catalyst elements 16 can, for example, each be accommodated in larger, possibly rectangular housings, as is also common in known bag filter systems. The combination with a cylindrical housing with tangential raw gas inlet, as with a cyclone separator, is only expedient and advantageous in relatively small systems. The separating nozzle 17 can of course also be designed as a circular, concentric separating nozzle, as is generally known and customary. Such separating nozzles can also be made of highly heat-resistant stainless steel alloys or can be made of ceramic material at even higher temperatures. As dust collectors or dust pre-separators, they are completely insensitive to higher temperatures and in particular to flying sparks.

Claims (11)

1. Filter apparatus for gas cleaning, preferably for flue gas cleaning with a dust filter in the raw gas space of the filter housing, characterized in that elements made of an open-pore foam ceramic are arranged as a dust filter in the filter apparatus, which are optionally coated with metals, metal oxides or other metal compounds. 2. Filter apparatus according to claim 1, characterized records that several filter elements from open porous foam ceramic connected in parallel Flue gas flow are arranged, each of which because part or all of these elements appropriately controlled flaps, valves or Like. Separated from the flue gas stream and by a compressed gas flow in reverse flow direction cleaned from the adhering dust becomes. 3. Filter apparatus according to claim 1, characterized records that in a housing like a Cyclone separator a tubular Filterele ment made of foam ceramic instead of the so-called Dip tube is arranged, which from below through a plate or a foam ceramic plate or ceramic foam disc is completed. 4. Filter apparatus according to claim 1, characterized in that a cylindrical or polygonal tubular body ( 4 ) made of foam ceramic is arranged as a filter element, which is divided on the inside by radial walls ( 5 ) into chambers ( 6 ) by the cross section of a segment of a circle or triangle. 5. Filter apparatus according to claim 1, characterized in that two or more tubular bodies ( 11 , 12 ) circular or polygon-like cross-section are arranged concentrically one inside the other, the spaces through ra diale walls ( 5 ) in chambers ( 6 ) with example, as a filter element trapezoidal cross section are divided. 6. Filter apparatus according to claim 1, characterized in that the chambers ( 6 ) are provided with a flap pen control apparatus ( 8 ) for the clean gas connector ( 10 ), each of which closes at least one chamber ( 6 ) for the clean gas connector ( 10 ), while at the same time a gas is blown with a pressure surge through a compressed gas line ( 9 ) into this closed chamber ( 6 ). 7. Filter apparatus according to claim 1, characterized records that a heat or sparks permanent dust filter element with a Kataly sator element made of coated, open-pore Foam ceramic in one unit or in one Housing is summarized. 8. Filter apparatus according to claim 7, characterized in that the dust filter element ( 14 ) made of filter cartridges or filter bags with heat filter material, for example felts, fabrics or tiles made of glass fibers, quartz fibers or stainless steel fibers is arranged. 9. Filter apparatus according to claim 7, characterized records that as a dust filter element a bulk layered filter with a packed bed of heat resistant granules is arranged. 10. Filter apparatus according to claim 9, characterized records that the individual grains of the bulk well-granules or part of the same kataly are effectively coated. 11. Filter apparatus according to claim 9, characterized records that the elements for dust removal dung from parts, for example tubular Filter candles or plate-shaped filter bags, from a fine-pored foam ceramic or from fine-pored sintered ceramic materials, exist while in the same construction unit or arranged in the same housing Catalyst elements from a coarse pore Foam ceramic with appropriate coating consist.