DE3009215A1 - Multi-cyclone dust extractor for flue gases - uses heat exchangers in common raw and clean gas chambers - Google Patents

Abstract

A multicyclone dust extraction plant for flue gases has a common crude gas inlet chamber for all cyclones. Heat exchanges are arranged in these chambers for the passage of a heat transfer medium to cool the gases before a blower takes them to a chimney. This prevents damage to the chimney lining by excessively high temps. and utilises the otherwise wasted heat energy of the flue gases. Specifically a bank of six cyclones receives the flue gases from the dust laden gas chamber. The clean gas leaves through the central tube and passes through a common clean gas chamber before the blower with the motor drive takes it to the chimney through pipe. Both chambers contain tubular heat exchangers with fins on their tubes and with flap valves so that they can be by-passed.

Description

Multi-cyclone dedusting device for flue gases

The invention relates to a multi-cyclone dedusting device for Flue gases, with several cyclone cells, which are connected to a common raw gas chamber and to a common clean gas chamber are connected.

With the known cyclone dust extractors, the flue gas (raw gas) is in a housing set in rapid rotation. The solids contained in the flue gas are pushed by the centrifugal force against the wall of the jacket pipe, where they are after sink down. A dip tube protrudes from above into the interior of the cyclone housing, through which the clean gas is discharged.

Multi-cyclone dedusting devices are used to dedust larger amounts of flue gas used, in which several cyclone cells to a common raw gas chamber and to a common clean gas chamber are connected. The usage several relatively smaller cyclone cells has compared to using a large cyclone the advantage that a greater degree of separation is achieved. From a certain one In terms of size, the degree of separation with the larger size of the cyclone always applies gets smaller. Axial cyclones are used for multi-cyclone systems, in which the After entering the cyclone housing, raw gas is initially moved in the axial direction and is then swirled by special guide vanes and thus in rotation is moved. Such axial cyclones can be packed close together can be combined to form a multi-cyclone system by placing the Raw gas chamber is arranged.

The immersion tubes of the cyclone cells lead through the raw gas chamber into the clean gas chamber arranged above the raw gas chamber. One on the clean gas chamber The attached exhaust fan sucks in the clean gas from the immersion pipes and conveys it it in the chimney.

The flue gas temperature must be within a certain temperature range move. Tar deposits form below a certain minimum temperature in the deduster or

arise in the chimney and above an upper limit temperature Destruction of the chimney. If the temperature is too high, In addition, the components that come into contact with the gas must have a corresponding one Maintain temperature resistance, which causes higher costs.

It must also be taken into account that the flue gases are valuable thermal energy carry with you, which is lost unused.

The object of the invention is to provide a multi-cyclone dedusting device to create, with which an effective cooling of the gas before it is introduced into the chimney and utilization of the thermal energy contained in the gas can.

To solve this problem, the invention provides that in the The raw gas chamber and / or a heat exchanger is arranged in the clean gas chamber, whose pipe system is traversed by a heat transfer medium.

In this way, an effective use of the in the flue gas or thermal energy still contained in the clean gas is possible. At the same time the temperature can of the clean gas entering the chimney within a desired temperature range being held.

If a heat exchanger is present in the raw gas chamber, flows through the raw gas coming from the boiler in its entirety this heat exchanger to then to be evenly distributed over the individual cyclone cells. Since the Raw gas chamber is assigned to all cyclone cells of the multi cyclone in common they have a correspondingly large volume in which the heat exchanger without difficulty can be accommodated. Dust deposits that form on the heat exchanger, are burned free again due to the high temperature of the raw gas and into the Cyclone cells flushed.

While when using relatively small individual cyclones the installation of heat exchangers would lead to a considerable increase in the size of the devices and it would also be very expensive if there is a heat exchanger in the raw gas chamber or the clean gas chamber of a multi cyclone without difficulties in economical and Can be used in a technically sensible way, since only one (or two) heat exchanger is required.

If there is a heat exchanger each in the raw gas chamber and in the clean gas chamber is arranged, the line systems this heat exchanger expediently be connected in series. The heat transfer medium, e.g. Water first flows through the heat exchanger in which the lower temperature level prevails, so the heat exchanger of the clean gas chamber, and then arrives in the heat exchanger of the raw gas chamber, in which there is a higher temperature level. In this way, the heat transfer medium is heated in two stages. The heat exchangers can also depending on the respective temperature of the Flue gases are switched. So it would make sense if the flue gas temperature is high to connect the pipe systems of both heat exchangers in series, with less Flue gas temperature only to switch on the heat exchanger of the raw gas chamber and at Only switch on the heat exchanger of the clean gas chamber at an even lower temperature. There is also a parallel connection of the line systems of the two heat exchangers possible.

To enable a heat exchanger to be switched on and off is expediently the path of the gas through the heat exchanger with activation a bypass channel can be blocked. When the heat exchanger is switched off, means So this is that the hot gas makes its way through the bypass channel, and not through the Heat exchanger through, takes.

In an advantageous development of the invention it is provided that the Heat exchanger only part of the volume of the raw gas chamber or the clean gas chamber occupies and is bounded by an impermeable wall that is attached to two at a distance from each other is open. The bypass channel is here through the volume of the respective chamber not occupied by the heat exchanger is formed.

In the known multi-cyclone dedusting devices exist Cyclone cells from axial cyclones, in which the gas does not swirl until inside the cyclone housing receives. A higher degree of dedusting can be achieved with tangential cyclones, at where the raw gas is fed into the cyclone housing via a helical inlet and is already in rotation when it enters. Such Tangential cyclones are not without their helical inlets, however to summarize further to a multicyclone. In particular, the raw gas chamber and the clean gas chamber cannot be arranged directly above the cyclone cells.

According to an advantageous development of the invention, it is now provided that the raw gas chamber and the clean gas chamber are combined into a separate assembly are and on their side walls openings for the connection of the raw gas inlets or of the clean gas lines of the cyclone cells.

The connection openings of the raw gas chamber and the clean gas chamber Assemblies are therefore on the side walls, so that the flue gas from the raw gas chamber can flow horizontally into the respective cyclone cell. The arrangement of the cyclone cells thus takes place in a star shape around the two chambers and at least one heat exchanger containing assembly around.

The cyclone cells are preferably tangential cyclones with a plan view Helical raw gas inlets and two tangential cyclones each are arranged side by side with crude gas inlets that are curved in opposite directions. By this paired arrangement of complementary daily cyclones is achieved, that the connection openings of the raw gas chamber can be relatively close to one another, so that the raw gas chamber is small and space-saving can be.

To adapt to different cyclone heights as well as to different lice Installation conditions is preferably the assembly containing the chambers on height-adjustable Supports placed.

In the following, an embodiment of the invention is referred to explained in more detail on the figures.

The figures show: FIG. 1 a side view of the multicyclone dedusting device, Figure 2 shows a horizontal section along the line II-II of Figure 1, Figure 3 a Vertical section through the chambers containing the heat exchangers at a slightly modified embodiment, Figure 4 along a section through the raw gas chamber the line IV-IV of Figure 3 and Figure 5 along a section through the clean gas chamber the line V-V of Figure 3.

The illustrated dedusting device has six cyclone cells 10, of which only one is shown in FIG. 1.

Each cyclone cell consists of a cylindrical cyclone housing 11, under which a dust container 12 is arranged. At the top of the cyclone housing 11 is the in plan view helical inlet 13, through which the raw gas flows tangentially into the cyclone jacket 11. The clean gas leaves the cyclone cell 11 through the dip tube 14, which passes through the helical inlet 13 leads out of the cyclone housing 11 and via a pipe or a flexible one Hose 15 is connected to the clean gas chamber 16. The clean gas chamber 16 is cylindrical formed and arranged directly on the top wall of the raw gas chamber 17.

The raw gas chamber 17 is square in plan, with three sides of the square rectangular lugs 17 'are attached. The fourth side wall has a nozzle 19 which is connected to the flue gas pipe 18, through which the of The flue gas coming from the boiler is fed to the raw gas chamber 17. The side walls of the raw gas chamber 17, i.e. the walls of the lugs 17 ', have openings for connection of the cyclone inlets 13. In the embodiment shown in FIG a cyclone inlet connected to each opening.

However, the connections do not all have to be used. You can go with Closures may be provided that are manual or electromechanical, hydraulic or can be pneumatically shut off and opened.

The flue gas flows through the line 18 into the raw gas chamber 17 from where it is distributed to the inlets 13 of the cyclone cells 10. In the cyclone cells the solid particles are separated out by centrifugal forces and placed in the dust containers 12 collected. The clean gas leaves the cyclone cells 10 through the immersion tube 14 and reaches the clean gas chamber 16 via lines 15. The clean gas chamber 16 instructs its cylindrical outer wall numerous connecting pieces 20 for each line 15 on. The lower end of the clean gas chamber 16 is through the top of the raw gas chamber 17 closed, while the upper end face of the clean gas chamber 16 with a fan 21 is connected, which is driven by the motor 22 and with an outlet line 23 leading to the chimney. The fan 21 thus has an axial inlet and a radial outlet.

The outlet can be swiveled in the horizontal plane so that its position can be adapted to the respective installation conditions of the outlet pipe 23 can.

The assembly consisting of chambers 16 and 17 rests on supports 24, which can be adjusted in height.

A heat exchanger 27 is arranged in the interior of the raw gas chamber 17, which consists of numerous parallel tubes 28 sharing a common inlet chamber 29 and a common outlet chamber 30. The inlet chamber 29 is at one Inlet connection 31 and the outlet chamber 30 are connected to an outlet connection 32. The tubes 28 are made of highly thermally conductive metal and are used to enlarge the The heat exchange surface is provided with fins 33. The heat exchanger 27 is through vertical side walls 34 limited. The walls 34 are spaced from the Side walls of the raw gas chamber 17. There is also a free space above of the heat exchanger 27.

As FIG. 3 shows, a line 35 leads from the flue gas line 18 to an opening 36, which is located below the heat exchanger 27 in the bottom wall the raw gas chamber 17 is located. An adjustable flap 37 allows the flue gas either through the opening 38 in the side wall of the raw gas chamber or through the Opening 36 in the bottom wall of the raw gas chamber are passed. Will the gas through the side opening 38 then passed through the wall 34 of the tubes of the heat exchanger kept away, so that it is over the Heat exchanger 27 away and laterally past this into the inlets 13 of the various cyclone cells 10 flows.

On the other hand, if the flap 37 is in a position in which the Flue gas is passed into the bottom opening 36, then the hot flue gas flows the tubes 28 of the heat exchanger 27 along to the water in the tubes to warm up.

The clean gas chamber 16, which is shown in Fig. 5 in horizontal section is, as FIG. 3 shows, is above the raw gas chamber 17. The clean gas chamber 16 also contains a heat exchanger 26. This has numerous tubes 37 on, which are also provided with fins 33 to improve the heat exchange are. The tubes 37 are horizontal in the present case and are of a cylinder 38 surrounded, which is arranged coaxially inside the clean gas chamber 16 and one Distance from the wall. The tubes 37 rest on a base plate 39, the one Distance from the bottom plate 40 of the clean gas chamber 16 has. The one between the plates 39 and 40 formed channel can be opened or closed by a flap 41 optionally. If the flap 41 closes the channel, that which has been introduced into the inlet connection 20 flows Clean gas through an opening 41 in the base plate 39 between the pipes 37 of the heat exchanger 26 and leaves the heat exchanger 26 through an opening 42 in the side wall. From there, the clean gas flows into the chimney.

The two heat exchangers 26 and 27 are made of water, for example flows through them and their circles can be one behind the other, so that the water gradually heated first in the clean gas chamber 16 and then in the raw gas chamber 17 will. Depending on the temperature of the clean gas chamber 16 leaving clean gas, the flaps 37 and 41 can be controlled.

Claims (7)

A n p r ü c h e 1. Multi-cyclone dedusting device for flue gases, with several cyclone lines connected to a common raw gas chamber and to a common one Clean gas chambers are closed, that is not indicated a heat exchanger in the raw gas chamber (17) and / or in the clean gas chamber (16) (27,26) is arranged, the line system of a heat transfer medium is flowed through. 2. Multi-cyclone dedusting device according to claim 1, characterized in that that in the raw gas chamber (17) and in the clean gas chamber (16) arranged heat exchangers (27,26) the line systems of these heat exchangers are connected in series. 3. Multi-cyclone dedusting device according to claim 1 or 2, characterized characterized in that the path of the gas through the heat exchanger (26,27) is switched on a bypass channel can be blocked. 4. Multi-cyclone dedusting device according to one of claims 1 to 3, characterized in that the heat exchanger (27,26) only part of the Volume of the raw gas chamber (17) or the clean gas chamber (16) occupies and through a impermeable wall (34; 38,39) is limited to two at a distance from each other lying places is open. 5. Multi-cyclone dedusting device according to one of claims 1 up to 4, characterized in that the raw gas chamber (17) and the clean gas chamber (16) to a separate Assembly (16,17) are summarized and on their side walls have openings for the connection of the raw gas inlets (13) or the clean gas outlets (15) of the cyclone cells (10). 6. Multi-cyclone dedusting device according to claim 5, characterized in that that the cyclone cells (10) as tangential cyclones with helical in plan view Raw gas inlets (13) are formed and that two tangential cyclones with each oppositely curved raw gas inlets (13) are arranged next to one another. 7. Multi-cyclone dedusting device according to claim 5 or 6, characterized characterized in that the assembly (16, 17) rests on height-adjustable supports (24).