FI87540C - FOERFARANDE OCH ANORDNING FOER MATNING AV GAS TILL PARTIKELFILTER - Google Patents

Description

1 87540

Method and arrangement for supplying gas to a particulate filter

The invention relates to a method for supplying gas to a particulate filter comprising tubular filter elements, in which method the gas is led along the supply channel outside the filter elements of the particulate filter into the space between the filter elements.

The invention further relates to an arrangement for carrying out the method 10, which arrangement comprises a supply duct with at least one supply opening located in the middle of the space between the filter elements of the particulate filter and parallel to the filter elements for supplying gas to the outside of the filter elements.

Particulate filters are commonly used to purify various process gases from their particulate matter. In these, the gas is led inside the filter unit, from where it flows through the separate filter elements 20 to the outlet side, with the particles remaining on the surface of the filter element. DE 3709671 discloses a solution in which a gas is fed into a filter unit from the upper end of a pipe placed parallel to it inside the tubular filter elements so that the gas to be cleaned flows downwards from the upper end of the pipe along the filter elements. In this solution, the impurities accompanying the gas and remaining on the surface of the filter elements are not evenly distributed on the surfaces of the filter elements, but may form uniform deposits in places. Cleaning of such filter elements is generally accomplished by introducing momentarily pressurized air or gas into the element, which should expel the dust accumulated on the surface of the element from the surface and thus cause it to fall to the bottom of the filter unit. If local uniform deposits form on the surface 35 of the element, the air 2 87540 cannot remove these, but flows through the filter from the point where there are no deposits and thus the filter elements cannot be effectively cleaned.

The object of the present invention is to provide such a method and arrangement for soldering the gas to be cleaned into the cleaning chamber of the filter unit so as to avoid the above-mentioned disadvantages and to obtain both a filter that is more evenly filtered and a filter that can be cleaned more safely. The method according to the invention is characterized in that the gas to be purified is introduced into the space between the filter elements so that the gas flow from the supply duct to the filter elements is substantially constant along the length of the filter elements.

The arrangement according to the invention, in turn, is characterized in that the end of the supply duct is closed, that several supply openings are formed in the supply duct substantially symmetrically about its longitudinal axis and along the length of the filter elements. to keep the forward gas flow substantially constant along the length of the filter elements.

The essential idea of the invention is that the gas to be cleaned is conducted in a substantially uniform flow along the longitudinal elements of the filter unit, whereby dust accumulates evenly on the surface of the elements without forming local deposits which may be either a successive gap growing in the direction of flow or a gap extending in width in the direction of flow. There are several such rows of holes or slits in the supply pipe 35, so that also in the supply pipe I:

3 8 7 5 4 U

in the circumferential direction, the most even distribution possible for the incoming gas flow is obtained.

The invention is described in more detail in the accompanying drawings, in which Figure 1 shows a cross-section of an embodiment of the invention, Figure 2 shows a cross-section of the filter supply pipe of Figure 1 at point AA, Figure 3 shows a cross-section of another embodiment of the invention and Figure 4 shows a filter of Figure 3 cross section of the working tube at BB.

Fig. 1 shows a particulate filter with a filtration chamber 1 and a purified gas discharge chamber 2. The gas to be cleaned is fed to the filter chamber via a gas supply pipe 3 acting as a supply channel, which is closed at its ends length at regular intervals. The ceramic filters 20, the inner part 6 of which communicates with the outlet chamber 2, are attached at their upper end to the partition wall between the filter chamber 1 and the outlet chamber 2 in a manner known per se. The gas supply openings in the supply pipe 3 are located symmetrically with respect to the central axis of the supply pipe 3, whereby there may be a different number of them depending on the number of ceramic filter elements 5. The diameter of the holes 4 is smallest at the lower end of the filter elements 5, i.e. in the direction of gas inlet, and increases in the direction of advance of the supply pipe 3 so that the openings closest to the end of the supply pipe are 30 large. In this way, the pressure and flow of the gas can be adjusted outwards from the supply pipe so that the gas flows substantially evenly over the entire length of the filter element 5 into the filter element and through its surface. In this case, the dust particles contained in the gas accumulate evenly on the surface of the filter elements 5 35 without forming separate local 4 87540 deposits. The gases flowing from the inside of the filter elements 5 into the outlet chamber 2 leave the outlet chamber through the outlet duct 7 onwards.

Fig. 2 shows a cross-section of the supply pipe 5 according to Fig. 1 at the point A-A marked in Fig. 1. Figure 2 shows how the gas supply openings 4 are located symmetrically with respect to the central axis of the supply pipe 3, whereby gas flows evenly from all openings in the directions of the openings and thus on the surface of the different filter elements 5 substantially evenly.

Fig. 3 shows a filter corresponding to the structure of Fig. 1 in other respects, the corresponding parts of which are numbered in the same way. However, it has gas supply grooves 14 formed in the supply pipe, which expand in the flow direction of the gas 15 so that the groove is narrowest at the lower end of the filter elements 5 and widens evenly at the upper end of the filter elements, i.e. in the gas flow direction. In this case, the wall parts of the supply pipe which form in the form of strips are supported on each other by annular support elements 15a which keep them immovable relative to one another. In this case too, the upper end of the supply pipe 3 is closed so that the gas does not flow out of it, but comes out through the flow openings 14. As in the case according to Fig. 1, in this case too the flow openings can be arranged in the desired number so that a gas flow is evenly distributed around the supply pipe 3 with respect to the filter elements 5. Instead of separate support rings 15, in this solution the wall strips of the supply pipe can also be fastened to each other by fasteners or welds running across the supply openings 14 30, the existence of which in itself in no way substantially affects the uniformity of the gas flow.

Fig. 4 shows a cross-section of the filter supply pipe 3 of Fig. 3 from B-B. Also in this case 35, the gas supply grooves 14 are formed symmetrically with respect to the axis of the supply pipe 3 in order to obtain the gas flow as evenly as possible around the supply pipe and thus with respect to the filter elements 5.

Claims (5)

Method for supplying gas to a particulate filter with tubular filter elements (5), in which the process gas is conducted along a supply channel (3) to the outside of the filter element (5) of the particle filter to the space between the filter elements (5), characterized in hence, the gas to be purified is directed into the space between the filter elements (5) such that the gas flow from the supply channel (3) to the filter elements (5) is substantially constant in the axis of the filter elements (5) along the length of the filter elements. 2. A method according to claim 1, characterized in that the gas to be purified is supplied to the space between the filter elements (5) substantially along the supply channel (3) in the middle of the space and that openings (4) are formed in the supply channel (3) with cross sections growing in the gas. flow direction forward to accommodate the free-flowing gas stream (3) from the gas stream substantially constant at the length of the portion of the channel (3) which includes the openings (4). Apparatus for realizing the method according to claim 1, which includes a supply channel (3) located substantially in the space between the filter element (5) of the particle filter and parallel to the filter elements (5) and provided with at least one supply opening. (4) for supplying gas to the outside of the filter elements (5), characterized in that the end of the supply channel (3) is closed, that a plurality of supply openings (4) are formed substantially symmetrically around the longitudinal axis of the filter element and the filter elements (3). (5) length to direct the gas out of the supply channel (3) in its transverse direction and the cross-section of the openings (4) grow in the forward flow direction of the gas in order to keep the gas flow directed towards the filter elements (5) substantially constant on the length of the filter elements (5). li 9 87540 4. Apparatus according to claim 3, characterized in that in the supply channel (3), rows of apertures forming successive openings (4) which are substantially synunetic in relation to the supply channel (3) are formed in its axial direction. periphery. 5. Apparatus according to claim 3, characterized in that a plurality of openings (4) are formed in the supply duct (3) which are substantially uniform in length of the filter elements (5) and whose cross-section becomes wider in the direction of flow of the gas. .