DE20105136U1 - Exhaust gas cleaning device for cleaning exhaust gases - Google Patents

Description

Huss Maschinenfabrik GmbH & Co. KG, Stresemannstrasse 56, 28207 Bremen
Exhaust gas purification device for cleaning exhaust gases

The present invention relates to an exhaust gas purification device for purifying exhaust gases, comprising a housing with an inlet and an outlet, a filter arranged in the housing for purifying the exhaust gas, a preferably electrical heating device with a heating element arranged in the housing upstream of the filter.

Such exhaust gas purification devices are known to be used as soot filters for non-stationary diesel engines that are used to drive forklifts, construction machinery or the like. When the engine is running, the exhaust gas to be purified is introduced into the housing and flows through the ceramic filter, which can be a so-called monolytic filter, so that soot particles are retained in the inner cavities of the filter and settle there. After a while, such a large amount of soot particles have settled in the filter that it must be regenerated.

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For regeneration, the exhaust gas purification must be interrupted. With the help of the electric heating device, ambient air is heated up strongly using the highly heated heating element and fed to the filter so that the soot particles trapped in the filter are burned and the filter is completely regenerated. This requires relatively high electrical heating output to heat the air. The engine must be switched off during regeneration, so operation must be interrupted.

Although the known exhaust gas purification devices with heating devices for regenerating the filter achieve useful results, the aim is always to reduce the regeneration times and the required heating output of the heating device. In a known exhaust gas purification device, the air to be heated is introduced through a pipe socket and into the housing of the exhaust gas purification device, in which the heating element of the heating device is also arranged. The heat transfer from the heating element to the gas, more precisely air, can be improved.

The object of the present invention is to provide an exhaust gas purification device of the type mentioned at the outset, with which the regeneration times and the required heating power can be reduced and, in particular, the heat transfer can be improved.

The invention solves this problem in an exhaust gas purification device of the type mentioned at the outset by means of a gas distribution chamber arranged adjacent to the heating element, from which gas can be released through a plurality of outlets in the direction of the heating element.

The advantages of the invention essentially consist in the fact that a gas, preferably air, is passed through the gas distribution chamber with several outlets in order to regenerate the filter in several defined partial flows in the direction of the heating element, so that the flow of the gas is significantly more favorable, more precisely

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In other words, the heat transfer from the preferably electrically heated heating element to the gas for regenerating the filter is significantly improved. Practical tests have shown that the invention allows the regeneration times to be halved compared to conventional exhaust gas purification devices and the required power to be significantly reduced. The operating times of the engine whose exhaust gases are to be purified can thus be significantly increased.

The invention solves the problem according to a further aspect or is further developed in that the heating element essentially fills a chamber 20 of the housing 2 arranged between the inlet 10 of the housing 2 and the filter 18. Because the chamber of the housing accommodating the heating element is adapted to the geometric dimensions of the heating element in such a way that the heating element essentially fills this section, on the one hand the size can be reduced, on the other hand vibrations of the heating element that occur in the prior art can be reduced and energy losses that arise from relatively large housings can be reduced.

In a preferred development of the invention, it is proposed that the gas distribution chamber has a partition wall with a plurality of outlet bores and an inlet opening opposite the partition wall, so that the plurality of outlets are formed in a simple manner. The partition wall is preferably designed as a perforated plate with a plurality of circular bores.

The heat transfer can be further improved or heat losses reduced by using a reflector to limit the section of the housing that accommodates the heating element. The reflector is preferably designed as a circular ring-shaped sheet, the perforated sheet is flush with the reflector and the outer diameter of the heating element is larger than the diameter of the perforated sheet. Radiant heat emitted by the heating element is thus effectively reflected.

According to a further development of the invention, it is proposed that the heating element is designed as a multi-layer spiral and can be heated electrically, that the gas distribution chamber is fed with gas by means of a coaxially arranged pipe, that a connection space for electrical connections is provided adjacent to the gas distribution chamber, which is electrically insulated, and that an insulation space filled with a heat insulator is arranged adjacent to the electrical connection space. The insulation space filled with a heat insulator, preferably so-called soapstone, ensures thermal insulation and at the same time moisture protection, so that moisture from the outside does not penetrate into the electrical connection space.

A preferred development of the invention provides that the spiral is supported by support elements attached to the perforated plate, so that the spiral can be easily attached and vibrations are largely avoided.

Furthermore, it is preferred that the housing is substantially cylindrical, the inlet of the housing is arranged on a peripheral surface of the cylindrical housing and the outlet is arranged on an end face of the cylindrical housing.

The invention is described below using an embodiment with reference to the accompanying drawings.

Figure 1 shows an exhaust gas purification device according to the invention in a sectional view;

Figure 2 shows the device according to Figure 1 in a side view;

Figure 3 shows an electrical heating device for an exhaust gas purification device according to Fig. 1 and

Figure 4 is a side view of the heating device according to Fig. 3.

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The exhaust gas purification device 1 shown in Fig. 1 is used to purify exhaust gases from internal combustion engines such as diesel engines for vehicles, in particular forklifts. The device 1 has a housing 2 made of sheet metal, which is arranged essentially rotationally symmetrically to the central axis 3 and which is divided into several adjacent modules or sections 4, 6, 8 fastened to one another. The housing has an inlet 10 for introducing exhaust gas to be purified and which contains particles, which is formed by a radially projecting pipe socket 12, and an outlet 14 for discharging the purified exhaust gas, which is formed by a pipe socket 16 arranged concentrically to the central axis 3.

Between the inlet 10 and the outlet 14 there is arranged a monolithic, cylindrical soot particle filter 18 for filtering out soot particles contained in the exhaust gas, which has a plurality of internal channels in which the soot particles are retained. The inlet 10 communicates with an expansion chamber 20 arranged in the housing 2, which is arranged between the inlet 10 and the filter 18 and is part of the housing section 4. During normal operation of the device 1, exhaust gas to be cleaned flows through the inlet 10 into the chamber 20, through the filter 18 and then through a space 22 accommodated in the section 8 of the housing 2 and out of the device 1 through the outlet 14. Particles are retained in the filter 18 until the particle filling level of the filter 18 has increased to such an extent that the flow resistance is so high that the operation of the engine is adversely affected. Then, a regeneration of the filter 18 of the device 1 is carried out.

An electric heating device 24 is used to heat gas, in this case ambient air, to regenerate the filter 18. The heated gas flows into the filter 18 in a manner to be described below and ensures that the soot particles that have accumulated in the filter 18 are burned. To introduce the gas to be heated, a pipe socket 26 connected to a fan (not shown) is integrated into the heating device 24. As can also be seen from Figure 3, the heating device 24 has a cylindrical, metallic housing 28.

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which is delimited by a sheet 30 and divided into several sub-chambers by partitions 32, 34. The pipe socket 26 opens into a gas distribution chamber 36 according to the invention, into which gas, here ambient air, can be introduced. The gas distribution chamber is delimited by a partition 38 arranged opposite the partition 34, which is designed as a perforated sheet. An inlet opening 39 is formed in the partition 34, so that gas can flow through the pipe socket 26 into the gas distribution chamber 36. A plurality of outlets 40 in the form of circular through-holes are formed in the partition 38. Gas can flow out of the gas distribution chamber 36 through the outlets 40 and into the expansion chamber 20, specifically in the direction of an electrically heatable heating element 42 of the heating device 24, so that gas flowing out of the gas distribution chamber 36 through the outlets 40 flows in the direction of the heating element 42 and is heated up strongly there. The heated gas then flows in the direction of the filter 18 and ensures regeneration of the filter 18.

The heating element 42 is, as can also be seen from Fig. 2, designed as a multi-layer spiral which contains an electrical resistance heater and has a substantially cylindrical cross-section. The spiral is supported by support elements 44, 46, 48, 50. The support element 44, designed as a cylindrical rod, is attached to the partition wall 38 by welding, and the rod-shaped support elements 46, 48, 50 protrude radially - with respect to the central axis 3 - from the support element 44 and are attached to it. The support elements 46, 48, 50 ensure that the heating element 42 is stabilized and prevent vibrations. The heating element 42 is arranged immediately adjacent to the gas distribution space 36 and takes up a large portion of the chamber 20 and essentially fills this section of the housing.

An electrical connection space 52 filled with electrical insulation material accommodates the electrical connections 54 for supplying electrical energy to the heating element 42 and is arranged adjacent to the gas distribution chamber 36. A heat and moisture insulating thermal insulator

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in the form of so-called soapstone is arranged in an insulation space 56 of the housing 28 adjacent to the connection space 52.

As can be seen from Fig. 1, a reflector 50 in the form of a circular ring-shaped sheet is provided in alignment with the partition wall 38 and arranged in a plane therewith adjacent to the chamber 20 in order to reflect heat radiation from the space 20, in particular from the heating element 42, so that heat losses can be kept low and effective heating of the gas can be achieved. The reflector 54 can also have a coating made of a particularly highly reflective material. An insulating material 56 is arranged between the housing of the heating device 24 and the section 4 of the housing 2 of the device 1 in order to ensure thermal insulation. A tubular sleeve 58 can accommodate a thermocouple in the chamber 20 by means of a temperature sensor (not shown).

Claims (9)

1. Exhaust gas purification device for cleaning exhaust gases with
a housing ( 2 ) with an inlet ( 10 ) and an outlet ( 14 ),
a filter ( 18 ) arranged in the housing ( 2 ) for cleaning the exhaust gas,
a preferably electrical heating device with a heating element arranged in the housing upstream of the filter,
characterized by a gas distribution chamber ( 36 ) arranged adjacent to the heating element, from which gas can be released through a plurality of outlets in the direction of the heating element. 2. Device according to claim 1 or the preamble of claim 1, characterized in that the heating element substantially fills a chamber ( 20 ) of the housing ( 2 ) arranged between the inlet ( 10 ) of the housing ( 2 ) and the filter ( 18 ). 3. Device according to claim 1 or 2, characterized in that the gas distribution space ( 36 ) has a partition wall ( 38 ) having a plurality of outlet bores ( 40 ) and an inlet opening opposite the partition wall ( 38 ). 4. Device according to claim 3, characterized in that the partition wall is designed as a perforated plate. 5. Device according to claim 4, characterized in that a reflector delimits the portion of the housing receiving the heating element. 6. Device according to claim 5, characterized in that the reflector ( 54 ) is designed as a circular ring-shaped sheet, the perforated sheet is aligned with the reflector ( 54 ) and the outer diameter of the heating element ( 42 ) is larger than the diameter of the perforated sheet. 7. Device according to one of the preceding claims, characterized in that the heating element is designed as a multi-layer spiral and can be heated electrically: that the gas distribution chamber is fed with gas by means of a coaxially arranged pipe, that adjacent to the gas distribution chamber ( 36 ) there is provided a connection space ( 52 ) for electrical connections ( 54 ), which is electrically insulated, and that adjacent to the electrical connection space ( 52 ) there is arranged an insulation space ( 56 ) filled with a heat insulator. 8. Device according to one of the preceding claims, characterized in that the spiral is supported by support elements ( 44 ) fastened to the perforated plate. 9. Device according to at least one of the preceding claims, characterized in that the housing ( 2 ) is substantially cylindrical, the inlet ( 10 ) of the housing ( 2 ) is arranged on a peripheral surface of the cylindrical housing ( 2 ) and the outlet ( 14 ) is arranged on an end face of the cylindrical housing ( 2 ).