PL193529B1 - Regenerative post-combustion device - Google Patents

Abstract

The invention relates to a rotary distributor (5) that is provided with a through-opening (6) for waste gas and a through-opening (77) for clean gas on the upper side thereof. Said openings are offset against each other in an angle and are arranged at different radial distances from the axis of the post-combustion device (1). The lower partition wall (44) of the distribution chamber (6) is provided with a through-opening (80) for each segment and for the waste gas and a through-opening (81) for the clean gas. The through-opening (80) for waste gas is provided with the same radial distance from the axis of the post-combustion device (1) as the waste gas through-opening (76) of the rotary distributor (5). Accordingly, the through-opening (81) for clean gas is located in the lower partition wall (44) of the distribution chamber (6) at the same radial distance from the axis of the post-combustion device (1) as the clean gas through-opening (77) of the rotary distributor (5).

Description

Description of the invention

The present invention relates to a regenerative burn-up device.

Regenerative afterburner devices which, in the housing from top to bottom, include a combustion chamber, a heat exchange zone which is divided into a plurality of segments filled with heat exchanger material, a distribution zone which, like the heat exchange zone, is divided into segments connected in each case to a heat exchange zone segment , a rotary distributor which, according to its position, forms a connection between an inlet of the treated waste gas and the at least one first segment of the heat exchange zone, a connection between at least one second segment of the heat exchange zone and an outlet of the cleaned gas, and which for this purpose have at least one at the top an off-gas port and at least one clean gas port angularly offset therefrom are described, for example, in EP 0 719 984 A2 or EP 0 548 630 A1. They have a rotary divider, the upper through holes of which all have the shape of a piece of cake and extend radially. It is quite difficult for various gases to pass through such a rotary distributor, it being relatively large axially and the associated peripheral devices must also be taken into account. Generally, a drive unit cannot be mounted directly on such a distributor, but must be connected via a drive shaft. Moreover, the different temperature in the rotary distributor may cause its uneven expansion.

These problems are largely avoided in the case of a regenerative afterburner of the initially mentioned type described in US Pat. No. 4,280,416A. In this device, the various through holes on the top side of the rotary distributor differ not only in their angular position, but also in the radial distance from the axis of the after-burning device.

The waste gas port and the clean gas port in the rotary distributor are at different radial distances from the vertical axis of the afterburner, and the lower baffle of the distribution zone has in each segment a first waste gas port which is at the same radial distance from the axis of the afterburner such as the exhaust gas port of the rotary distributor, a second clean gas port which is at the same radial distance from the axis of the afterburner as the clean gas port of the rotary distributor.

The through holes at the top of the rotary distributor all connect through the same hole in the lower partition wall of the distribution zone with the corresponding segment of this zone, but connect through separate through holes in this partition, which, due to their radial distance from the axis of the afterburner are assigned to a special through-hole of the rotary distributor.

The rotary distributor in the device according to US 4,280,416 A is formed as a flat plate, the bottom side of which is adjacent to different radially spaced gas inlet and outlet channels, and the upper side is adjacent to a stationary plate which delimits the distribution zone from below. It is very difficult, especially due to the prevailing temperatures, to keep the rotary distributor unchanged. There are leaks and the rotary distributor is stuck. The concentric positioning of the gas supply and discharge channels is expensive and requires a lot of space.

The object of the invention is to design a regenerative afterburner device of the above-mentioned type so that the rotary distributor and the peripheral devices feeding the gas thereto have a simple structure and, in particular, take up little space in the axial direction, and that the rotary distributor is resistant to deformation.

Regenerative afterburner which comprises, in the housing from top to bottom, a combustion chamber, a heat exchange zone which is divided into a plurality of segments filled with heat exchanger material, a distribution zone which, like the heat exchange zone, is divided into segments connected to each exchange zone segment heat exchanger, a rotary distributor which, according to its position, forms a connection between the inlet of the treated waste gas and the at least one first segment of the heat exchange zone, the connection between the at least one second segment of the heat exchange zone and the outlet of the cleaned gas, and for this purpose at least one off-gas through-hole and at least one clean-gas through-hole angularly relative to it, the waste-gas through-hole and the clean gas through-hole in the rotary distributor are at different linear distances from the vertical axis of the device to baffle, and the lower baffle of the distribution zone has in each segment, a first exhaust gas passage that is at the same radial distance from the axis of the afterburner as the exhaust gas passage of the rotary distributor, a second clean gas passage that is in the same a radial distance from the axis of the afterburning device like the pure gas passage of the rotary distributor, it is characterized according to the invention that the rotary distributor has an upper limiting plate in which the exhaust gas passage and the clean gas passage and preferably the lower flushing air passage are formed. a restriction plate in which there is an opening communicating with the inlet of the treated waste gases, and a partition wall which connects the two restriction plates to each other and in the rotary distributor delimits at least partially the flow chamber of the treated waste gas.

In a regenerative afterburner, where the rotary distributor forms a connection according to its angular position between the purge air port and at least one third segment of the heat exchange zone, preferably the rotary distributor has at its top at least one purge air port angularly displaced with respect to the exhaust gas port and a clean gas port, the purge air port in the rotary distributor is at a radial distance from the axis of the afterburner, which differs from the waste gas port spacing and the clean gas port spacing, and the lower distribution zone baffle for each segment has a purge air port that has the same radial spacing from the axis of the afterburner as the purge air port in the rotary distributor.

Preferably, the clean gas passage in the upper restriction plate of the rotary distributor is connected via a radially outwardly open portion of the rotary distributor to an annular chamber which communicates with the clean gas outlet.

Preferably, the top restriction plate of the rotary distributor has a larger radius than the cylindrical wall of the rotary distributor which limits the flow chamber of the treated off-gas partially, and the clean gas passage on the upper restriction plate is located in a portion thereof radially beyond the wall.

Preferably, the rotary distributor has a hollow hub, the interior of which, near its lower end, connects to the purge air connection and, near its other end, it connects to the flow-through flushing air chamber in the rotary distributor, into which the passage of this air opens on the upper limiting plate of the rotary distributor. .

The rotary distributor according to the invention consists of components that are very easy to manufacture, which can be joined together without difficulty, e.g. by welding, in order to create different flow paths for different gases, but are nevertheless stable. The clean gas that flows through the clean gas port in the axial direction from the distribution zone downward need not entirely flow through the rotary distributor in the axial direction, but is deflected inside the rotary distributor radially outward. Connection components are therefore no longer required at the bottom of the rotary distributor for this flow. The pure gas flow zone is no longer present in such a rotary distributor, which allows for a significant reduction in manufacturing costs.

In almost all afterburner regenerative devices, also in the above-described European patents, not only the treated waste gas and clean gas pass through the rotary distributor, but also the scrubbing air. It cleans the segments through which the waste gas has previously passed before they are used for the flow of clean gas. Accordingly, the rotary distributors of such regenerative afterburner devices can also establish a connection between the scavenge air connection and the at least one third heat exchange zone segment according to their rotational position, and for this purpose have at least one scavenge air passage at the top which is angularly displaced with respect to the through-hole. off-gas and clean gas through-hole. Such regenerative afterburner devices configured in accordance with the invention have a scrubbing air passage in the rotary distributor at a radial distance from the axis of the afterburner, which differs from the exhaust gas passage spacing and the clean gas passage spacing, and a lower separation zone baffle for each of them. a segment having a purge air port that has the same radial spacing from the axis of the afterburner device as the purge air port of the rotary distributor.

PL 193 529 B1

The advantages of the device according to the invention, in which not only the angular position of the through holes of the rotary distributor is differentiated, but also their radial distance from the axis of the afterburner device, become particularly clear when three different gas streams flow through this distributor.

Finally, in the case of regenerative afterburning devices which operate with scavenge air passing through the distributor, it is finally advisable to configure the invention in such a way that the rotary distributor has a hollow hub, the interior of which joins the scavenge air connection near its lower end and in the vicinity of the other. end communicates to the purge air flow chamber in the rotary manifold, into which the purge air passage opens on the manifold upper restriction plate. In this way, the hollow distributor hub is used as a flow path for the purge air, which saves space in the device.

The subject of the invention is explained in more detail in the embodiment in which Fig. 1 shows a vertical axial section of the lower part of the afterburner regenerative device, Fig. 2 - a section along the line II-II in Fig. 1, and Fig. 3 shows a view from the top of the rotary distributor of the afterburner of Fig. 1.

The regenerative burn-up device is generally designated in FIG. 1 by the reference numeral 1. Its basic structure and principle of operation - unless otherwise stated - are known. In the lower part of the afterburner 1, which is only partially shown in FIG. 1, there is an inlet 3 of the treated exhaust air, which is supplied through an essentially horizontal inlet conduit 4. The inlet conduit 4 is closed at its end radially internal to the housing 2 of the after-burning device and there is an opening 50 facing upwards. Above this opening 50 is an opening 52 of the annular subplate 51, so that exhaust air can flow upward through the two openings 50, 52. The outer edge of the subplate 51 is connected via a cylindrical wall 53 of the housing to a horizontally extending baffle 44 which closes the distribution zone 6 from below.

In the area girded by the wall 53 of the housing, closed at the bottom by a subplate 51 and at the top by a partition 44, there is a rotary distributor 5, which can be rotated continuously or stepwise around the axis of the housing 2 by means of a drive device 54. The rotary distributor 5 has a lower, annular a stop plate 55 and an upper circular stop plate 56, the latter having a diameter greater than the former. A cylindrical wall 57 leads from the periphery of the lower stop plate 55 to the upper stop plate 56, thus defining a chamber 58 inside the divider 5. It is delimited radially inward by a further downward tapering annular partition 59 and a hollow hub 60 of the rotary distributor 5.

The chamber 61, delimited by a partition 59 and a hollow hub 60, communicates through a window 62 in the upper side of the hub 60 with its interior, which in turn communicates through a similar window 63 in the lower part of the hub 60 with an inlet zone 64 which is connected by a horizontal pipe 65 to a purge air connection 66.

The lower stop plate 55 of the rotary distributor 5 has large openings 67 so that the chamber 58 in the rotary distributor 5 can communicate in all rotational positions with the inlet conduit 4 through the opening 52 of the adapter plate 51.

The periphery of the lower limiting plate 55 of the rotary distributor 5 is connected by a spring ring 68 to a rigid pressure ring 69, at the bottom of which one or more gaskets 70 are inserted. The gaskets 70 are pressed by a spring ring 68 against the upper surface of the subplate 51. In this way, the plate of the ring is pressed against the plate. of the spring 68 compensates for the uneven axial expansion, with known afterburning devices a special compensator is used for this.

An annular chamber 72 is formed between the housing wall 53 and the cylindrical wall 57 of the rotary distributor 5, which is connected by a horizontal conduit 73 to the clean gas outlet 74. This gas is sucked off this outlet 74 by means of a blower not shown.

As can be seen in Fig. 3, the upper limit plate 56 of the rotary distributor 5 is schematically divided into 11 pie-shaped sectors with each sector being within an angle of approximately 32.7 °. In one of these sectors, near the center of the containment plate 56, there is a first through hole 75 which is shaped as an annular segment and passes purge air as explained below. The sector next to the sector having the port 75 has no through holes, but is joined by three sectors that have a second through hole 76 in the form of an annular segment. The through-opening 76 serves, as will be explained later, to pass the treated off-gas. The radially inner contour arc of through hole 76 has a larger radius than the radially outer contour arc of through hole 75.

A sector having a through-opening 76 is again adjacent to the upper bounding plate 56 of the rotary distributor 5 which has no through-holes. This sector is followed in a clockwise direction by four sectors through which a third through hole 77 extends in the form of an annular segment which conducts clean air, as also explained below. The inner contour arc of through hole 77 again extends at a greater distance from the center of the upper bounding plate 56 of the rotary distributor 5 than the radially outer contour arc of through hole 76. Between the last sector which has through hole 77 and the sector containing the through hole 76 in a clockwise direction. scavenge air port 75 is again provided with a through hole sector of upper limit plate 56.

The air port 75 of the top restriction plate 56 of the rotary manifold 5 connects to the chamber 61 bordered by the baffle 59 of the rotary manifold 5. The port 76 in the upper restriction plate 56 connects to the chamber 58 of the rotary manifold 5. Finally, the passage 77 of the clean gas of the upper restriction plate 56 is located in that part which projects radially beyond the cylindrical wall 57 of the rotary distributor 5 and communicates with the annular space 72 between this cylindrical wall 57 and the housing wall 53 and thus the clean gas outlet 74.

As can be seen in Fig. 2, the distribution zone 6 located above the rotary distributor 5 is divided by partitions 49 into 11 segments, which also have an angle of approximately 32.7 [deg.]. The baffles 49 extend radially from the inner stub 78 to the housing wall 2. The baffle 44 which closes the distribution zone 6 at the bottom has, in each of the sectors that are associated with a segment of the distribution zone 6, three through-holes 79, 80, 81 at different radial distances. :

The through hole 79 closest to the center of the partition 44 is limited radially on the inside by a pipe stub 78 and has a radially outward contour arc whose radius is equal to the radius of the outer arc of the scouring air opening 75 in the upper boundary plate 56 of the rotary distributor 5.

Located radially outside this inner through hole 79 of the partition 44, the next opening 80 of each sector has a radially inner contour arc whose radius corresponds to the radius of the inner contour arc of the opening 76 of the rotary distributor 5 and whose radially outer contour arc has the same radius as the outer contour arc of this opening. through 76.

Finally, the radially outer through hole 81 in each sector of the partition 44 of the distribution zone 6 radially covers the same area as the through hole 77 in the upper stop plate 56 of the rotary distributor 5.

In the part of the afterburner 1, not shown in Fig. 1, above the distribution zone 6 there is a known heat exchange zone, which, like the distribution zone 6, is divided into 11 segments that connect to 11 segments of the distribution zone 6 through through-openings in a partition located between the distribution zone and the heat exchange zone. Finally, above the heat exchange zone there is a combustion chamber in which generally one burner is arranged.

The above-described thermal afterburner operates as follows:

The exhaust gases to be treated are introduced into the annular chamber 58 of the rotary distributor 5 through the inlet 3 and the inlet line 4 and through the opening 50 in the inlet line 4, the hole 52 in the connecting plate 51 and the lower openings 67 in the rotary distributor 5. From the chamber 58, the treated waste gas passes through the through hole 76 in the upper stop plate 56 of the rotary distributor 5 to certain segments of the distribution zone 6, namely through through holes 80 in those sectors of the partition 44 which just meet the through hole 76 of the distributor 5.

The waste gases then pass through the respective segments of the heat exchange zone above the distribution zone 6 and are thereby heated in a known manner to almost the ignition temperature of the pollutants contained in these gases. The combustion of these pollutants takes place in the combustion chamber above the heat exchange zone. Hot exhaust gas freed from pollutants (called

In this case, they pass again downstream through defined segments of the heat exchange zone, where they meet the heat exchanger material preheated by the ascending exhaust gas and cool down in the process. From the heat exchange zone, they enter the corresponding segments of the distribution zone 6. These are those segments whose radially outer through holes 81 connect with the through hole 77 in the rotary distributor 5. From there, clean gases flow into the annular chamber 72 between the rotating distributor 5 and the wall. 53 of the housing and from there exit via line 73 and outlet 74 for pure gas.

At the same time, clean air is introduced into the inlet zone 64 through the purge air connection 66 and the line 65, which may be a part of the clean air produced. This clean flush air continues through the window 63 into the hollow hub 60 of the distributor 5, through the window 62 in the upper part of the hub 60 into the flow chamber 61 of the rotary distributor 5 and hence through the port 75 in the upper stop plate 56 of the rotary distributor 5 and a radially inner through-hole 79 of the adjoining segment of the distribution zone 6 upward to the segment of the heat exchange zone. Here, the purge air flushes into the combustion chamber the residual waste gas that remained in this segment with the previous flow of the waste gas, and in this chamber these are burned up. leftover.

It is also possible to design the regenerative afterburner according to the invention in which the scrubbing air flows in the opposite direction: it is then sucked off through the scrubbing air connection 66.

The closed sectors in the upper limiting plate 56 of the rotary distributor 5 ensure that none of the through holes 79, 80, 81 in the lower partition 44 of the distribution zone 6 can connect simultaneously with the two through holes 75, 76, 77 of the rotary distributor. 5, which would create a gas bypass flow and degrade the cleaning performance.

Claims (5)

1. Regenerative afterburner, which comprises, in the housing from top to bottom, a combustion chamber, a heat exchange zone which is divided into a plurality of segments filled with heat exchanger material, a distribution zone which, like the heat exchange zone, is divided into segments connected to a segment in each case. heat exchange zone, a rotary distributor which, according to its position, forms a connection between the inlet of the treated waste gas and the at least one first segment of the heat exchange zone, the connection between at least one second segment of the heat exchange zone and the outlet of the cleaned gas, and which for this purpose is provided at the top at least one off-gas port and at least one clean gas port angularly offset therefrom, the off-gas port and the clean gas port in the rotary distributor at different radial distances from the vertical axis of the afterburner, and The lower baffle of the distribution zone has, in each segment, a first exhaust gas passage which is at the same radial distance from the axis of the afterburner as the exhaust gas passage of the rotary distributor, a second clean gas passage which is at the same radial distance from axis of the afterburner device as the pure gas passage of the rotary distributor, characterized in that the rotary distributor (5) has an upper limiting plate (56) in which the exhaust gas passage (76) and the pure gas passage (77) and preferably the hole are formed the purge air passage (75), the lower containment plate (55) in which there is an opening (67) communicating with the inlet (3) of the flue gas to be treated, and a partition wall (57) that connects both these limiting plates (55) to each other. , 56) and in the rotary distributor (5), at least partially restricting the flow chamber (50) of the off-gas to be treated. 2. The regenerative burn-up device according to claim 1. The rotary distributor as claimed in claim 1, wherein the rotary distributor forms a connection according to its angular position between the purge air port and at least one third segment of the heat exchange zone, characterized in that the rotary distributor (5) has at its top at least one purge air passage (75) displaced angularly with respect to the exhaust gas port (76) and the clean gas port (77), the purge air port (75) of the rotary distributor (5) being at a radial distance from the axis of the afterburner (1) that differs from The distance of the flue gas passage opening (76) and the distance of the clean gas passage (77), and the lower partition (44) of the distribution zone (6) for each segment has a purge air passage (79) that has the same spacing radial from the axis of the afterburner (1) like the flushing air through hole (75) in the rotary distributor (5). 3. The regenerative burn-up device according to claim 1. A clean gas through-hole (77) in the upper restriction plate (56) of the rotary distributor (5) is connected via a radially outwardly open part of the rotary distributor (5) with an annular chamber (72) which communicates with the outlet (74) clean gas. 4. The regenerative burn-up device according to claim 1. The rotary distributor (5) as claimed in claim 3, characterized in that the upper limit plate (56) of the rotary distributor (5) has a larger radius than the cylindrical wall (57) of the rotary distributor (5) that delimits a partially flowing chamber (58) of the waste gas to be treated, and the passage (77) the clean gas on the upper restriction plate (56) is in its portion that extends radially beyond the wall (57). 5. The regenerative burn-up device according to claim 1. The rotary distributor (5) as claimed in claim 2, 3 or 4, characterized in that the rotary distributor (5) has a hollow hub (60), the interior of which connects to the purge air connection (66) near its lower end and communicates with the flow chamber (66) near its other end ( 61) of scrubbing air in the rotary distributor (5) into which the passage (75) of this air opens on the upper restriction plate (56) of the rotary distributor (5).