DE2826048B2 - Arrangement for flue gas routing and flue gas extraction in a heating boiler - Google Patents

Description

The invention relates to an arrangement for flue gas guidance and flue gas extraction in a Heat core, with one of a heat transfer medium Surrounded combustion chamber and several flue gas passages also surrounded by the heat transport medium, which are designed as cooling surfaces each having a total cooling surface of different sizes and of which at least one has a passage control and the flue gases from the combustion chamber to a flue gas collecting chamber guide and with further, designed as cooling surfaces, flue gas flues that remove the flue gases the flue gas collection chamber to a flue gas chimney, as well as with an additional flue gas outlet the collecting chamber, in which the flue gas outlet can be controlled.

With conventional heat generators (steam generators or hot or warm water generators) it is known to use multi-pass generators, preferably designed in three-pass construction (roughly corresponding to the "Technical Guidelines for Steam Boilers" TRD, or "Steam Boiler Determinators", ed. of the V.d.T.Ü.V. Essen 1960, or DIN 4751, 4752 o.a.). In such known heat generators was by applied multi-pass construction a relatively good utilization of the heat released in the combustion chamber to achieve.

In a large number of technical processes, for example in thermochemical processes, in the heating of dryers in the wood or surface industry, for stenter frames in the textile industry, for dryers in the mineral industry, etc., it has proven necessary to use flue gases for direct or indirect heating to work in a temperature range between approx. 500 ⁰ C and 900 ⁰ C. The flue gases emerging from conventional heat generation systems were unsuitable for this purpose, as their temperature level (up to approx. 300 ^c C) was considerably too low. In these cases, it was necessary to use burner systems directly in such processes in which the high-temperature flue gases generated in the combustion chamber are then either mixed down to the desired temperatures with the supply of fresh air or in which only a partial flow of the flue gases generated is used. In both cases, a remarkably large proportion of the radiant heat generated in the combustion chamber and, in some cases, also the convection heat generated in the system were lost. The efficiency of such systems was not satisfactory.

In a known two-pass boiler (GB-PS 12 45 167), the flue gases exiting the combustion chamber are fed to the two gas flues cooled by the heat transfer medium via a reversing chamber. B. be derived to a chimney. The exit cross-sections of the one Rai: chgaszuges in the exhaust gas chamber can be closed completely or partially by means of a movable flap, which enables the mixed gas temperature within the exhaust gas chamber to be controlled in order to ensure that the gas temperature in the exhaust gas chamber is always raised above the dew point sufficient measure is guaranteed. The generation of flue gases in a range of 500 ° C to 900 ⁰ C is not, in this known arrangement is possible because the entering the exhaust chamber gas still having a temperature below the relevant temperature range temperature even at full opening of the only major by-pass cross-section . If one wanted to divert exhaust gases from the exhaust gas chamber of the known arrangement, then the exhaust gas fraction not diverted would be continued unused into the chimney, which is uneconomical. A sudden opening of the large bypass cross-section of the known arrangement (to raise the Ra ichgas temperature in the exhaust gas chamber) would also lead to the flue gas side pressure conditions would be changed in such a way that instability would have to occur. The known arrangement can therefore only function (as intended) when the mixed gas temperature is only to be controlled in the temperature range that is necessary to avoid the mixed gas temperature falling below the dew point.

In another known arrangement (GB-PS 1195 195) are those leaving the combustion chamber Flue gases divided into several partial flows, the partial flows via cooling sections with different strengths guided and by bringing together partial flows emerging from different cooling sections then a gas flow of a certain mixing temperature is generated, the mixing temperature here as well this gas flow is regulated so that the dew point in the exhaust chimney is always exceeded. In the known arrangement two flue gas turning chambers are provided, with between the first and the second turning chamber a bypass line of large cross-section parallel to the one between the two turning chambers arranged flue gas flues is provided, the outlet of which into the second turning chamber is adjustable. If undesired low temperatures occur on the exhaust side in the partial range that are necessary to achieve or falling below the dew point in the exhaust gas outlet chamber, then will first by appropriate control of the opening cross-section of the large bypass line between the first and the second turning chamber, a temperature increase in the latter by introducing hotter flue gases into it causes. Because when the bypass line is opened, the hot flue gases preferentially emerge from the first Reversing chamber via the bypass line into the second reversing chamber, as the flow resistance of this Line is considerably smaller than that of the other flue gas flue with many tubes of smaller cross-section. As a result of the temperature increase in the second turning chamber, the last flue gas pass occurs.

which leads to the chimney outlet, flue gases with a higher starting temperature, so that the flue gases emerging into the chimney chamber are correspondingly warmer and the desired temperature increase can thereby be achieved. However, if the said bypass line is fully opened (for example if the load is too low), the temperature in the chimney chamber is not raised sufficiently. da.iJi with the known arrangement the possibility can be taken of introducing hot exhaust gases directly from the first reversing chamber into the chimney outlet via a connecting line and thus ultimately ensuring the desired temperature increase, but in the known arrangement the control valves ^for the flue gas duct are opened , then occurs on the primary side e ^; ne such a strong change in the pressure behavior that the design data of the boiler (with regard to the furnace and convection heating surfaces, as well as its boiler resistance) are changed in such a way that the selected output variable changes in such a way that instability can occur in the operation of the chamber. When one or both valves are opened, there is a pressure loss which leads to the burner sucking in so much false air that the efficiency of the boiler can no longer be determined. By means of such measures it can be achieved that the dew point may not be undershot on the exhaust side. In the interest of economic use of such a boiler, however, would be the use of a

Your own small burner in the exhaust chimney to exceed the dew point is certainly even more economical. The deduction of flue gases to a desired mixing temperature within the main temperature range of about 500 ° C to about 900 ⁰ C to

A downstream consumer is not economically feasible with this known arrangement.

Based on this, the invention is based on the object of improving an arrangement of the type mentioned in such a way that, while maintaining the operation of the boiler as a heat generator, the possibility of simple removal of flue gases of any temperature within a temperature range of about 50O ⁰ C to approx. 900 ⁰ C for a downstream

4) Flue gas consumers with stable combustion conditions and great economic efficiency is possible.

According to the invention, this object is achieved with an arrangement for guiding and extracting flue gas of the aforementioned type solved in that all

so the flue gas passages emanating from the combustion chamber all over or exit cross-sections that can be partially switched on and off end in the collecting chamber, the flue gas consumer is connected to the additional flue gas outlet and the control of the flue gas outlet through the

ν, additional flue gas outlet essentially below The flue gas pressure in the collecting chamber is kept constant. The <\ norder according to the invention enables a mixed gas flow within a

w) Provide a temperature range of approx. 500 ⁰ C to approx. 900 ⁰ C with quick adjustability for the supply of a downstream flue gas consumer, whereby it is ensured that the desired smoke gas pressure corresponding to the design data of the burner is always maintained, thus the pressure conditions in the flue gas part of the system maintain the level required for continuous operation and thus independent of the needs of the downstream

Consumers always an economical, continuous operation of the boiler is ensured. At the same time will but also made sure that the not diverted to the downstream flue gas consumer Portions of the mixed gas flow can be used further to heat the boiler water, whereby there are no undesirable losses due to the discharge of excessively hot flue gases into the chimney. For the conventional heat generation of the boiler stands thus the full generated radiant heat and the The required convection heat is available, with smoke gases of the desired or required type at the same time Temperature within the specified temperature range can be continuously deducted for the downstream flue gas consumer, in comparison to conventional systems in which the smoke gases are generated at the required temperatures If a separate burner is also used for the downstream consumer, the Arrangement according to the invention through the combination of conventional heat generator and simultaneous Flue gas suppliers have greatly reduced overall emissions by eliminating a fireplace. At the same time will A particularly high level of economic efficiency is guaranteed, since the full flame emitted by the flame generated Radiant heat for conventional heat generation as well as for the required convection heat can be exploited. Even those not required for the downstream flue gas consumer Residual flue gas is still used to give off heat for the flue gas until it is introduced into the flue gas chimney Heat generation side of the boiler used. A particularly advantageous embodiment of the invention Arrangement is that to control the escape of smoke from the collection chamber through the additional flue gas outlet a throttle valve arranged in this and another, the introduction point of the Flue gases are provided in the discharge chimney upstream throttle valve, both throttle valves are coupled to one another so as to adjust in opposite directions to one another. This makes it easier and easier Way the total resistance on the exhaust gas side, which is necessary for the correct operation of the entire burner It is important to keep it in the desired area and to avoid that when connecting a larger flue gas consumer possibly an undesirable pressure collapse in the flue gas area entry.

Another advantageous embodiment of the arrangement according to the invention is that for partial or complete switching on or off of the flue gas passages emanating from the combustion chamber one in the Rauchgassammeikammer arranged flap is provided, through which the inlet openings each Flue gas in the collecting chamber can be fully or partially closed. This flap can be like this be arranged that with it the escape of smoke gases from the individual cooling surfaces, depending on Position of the flap, completely closed or opened continuously, with a suitable Arrangement of the flap with the opening of a flue gas a simultaneous corresponding Closing the other connected and thereby a continuous mixing together at any one Mixing ratio is easily possible Advantageously, the switching on and off takes place from Combustion chamber outgoing flue gas depending on a presettable flue gas temperature in the collection chamber automatically.

It is also advantageous if, in an arrangement according to the invention, the flue gas collecting chamber is designed as a reversing chamber for the flue gases, which is completely surrounded ^{by the heat transport medium of the heat r) kesseis and is arranged at one end of the boiler.}

A further preferred embodiment of the arrangement according to the invention is that each

ίο the flue gas passages from a large number of closely spaced, individual tubes arranged parallel to one another each have the same cross-section, whereby a simple construction is made possible by the use of inexpensive commercially available tubes. Depending on the purpose However, it can also prove to be advantageous, instead of tubes, cooling surfaces of other geometrical shapes Design to use and instead of a large number of individual, side by side individual cooling surfaces to use a single large cooling surface.

In the invention, the flue gas temperature and the flue gas pressure are where the mixing the gases are regulated so that the temperature according to the needs of the downstream flue gas consumer and the flue gas pressure can be set according to the required quantities of this consumer. It is advisable to switch the temperature control upstream or overrule the pressure control. The flue gas quantities required by the downstream flue gas consumer are after the merging the cooled flue gases arriving from the various cooling sections are extracted; she thus no longer enter the last cooling section (to the exhaust gas chimney) and can no longer heat there hand over. When this consumer is switched off, however, the full flue gas flow takes place as in the case a conventional multi-pass heat generator, so that then all the available energy for the Heat generation (steam generation, hot water generation, etc.) is available.

With a further arrangement for flue gas routing and flue gas extraction with a heating boiler one combustion chamber surrounded by the heat transport medium and several, also with the heat transport medium Flue gas flues surrounded by flushing to solve the same task are the flue gases from the combustion chamber can be fed to a flue gas collection chamber as well as through flue gas flues designed as cooling surfaces can be fed to an exhaust chimney, with an additional smoke gas outlet on the collecting chamber is provided in which the flue gas outlet is controllable. When the heating boiler is designed as a once-through boiler According to the invention, the flue gas collecting chamber is arranged in this way at the end of the combustion chamber that part of the smoke gases generated enter them directly after leaving the flame area without cooling and without Flow around heating surfaces can be initiated and a device is also provided via the exhaust gases can be introduced from the chimney into the collecting chamber, with gas flows in the collecting chamber for both a control is provided and connected to the collecting chamber of the flue gas consumer is

In this arrangement according to the invention, a part of the there is already behind the flame area Existing flue gases without further cooling (or only slightly cooled by the environment) immediately into the Passed collecting chamber and there with the admixture of much cooler exhaust gases from the exhaust chimney to the

desired mixing temperature brought; then the mixed flue gas is completely connected to the downstream Consumer derived. The remaining flue gases are countercurrent to the cooling coils (with Heat transport medium) passed and after Ab- ■> cooling initiated in the exhaust chimney.

The arrangements according to the invention allow in a surprisingly simple manner with high economic efficiency the use of boilers for conventional heat generation as well as for providing ι ο development of exhaust gases at any desired temperature within a temperature range of approx. 500 ° C to approx. 900 ° C, with both downstream flue gas consumers switched on and off quickly and easily can be, as well as a desired is Change of the flue gas temperature for these consumers quickly, without major changes and functionally reliable can be done.

In the following, the invention is explained in more detail by way of example with reference to the drawing. It shows

F i g. 1 shows a basic illustration of an arrangement according to the invention;

F i g. 2 shows a cross section through the (principle) illustration a heating boiler from an arrangement according to the invention;

F i g. 3 shows a further basic illustration of an inventive Arrangement for training as a once-through boiler.

In Fig. 1, a basic representation of a heating boiler 1 is shown, which is filled with a heat transport medium 2 (water, steam or another suitable medium). on the right) a burner 4 is shown schematically on one side, which receives the air required for combustion via a fan 5 and the required fuel via a line 6. The hot flue gases generated within the combustion chamber 3 flow along the combustion chamber, are diverted to the other end thereof (see FIG. W Pfeildarstcllung) and occur in counter-current in two flue gas drafts 7 and 8 which g in F i. 1 are only shown in principle and the representation is not intended to say anything about a suitable design of these flue gas ducts. The flue gas flues themselves are represented by a large number of smaller or larger pipes running parallel to one another (see Fig. 2) and should be designed in such a way that the total cooling surface of a flue gas flue is different from that of every other flue gas flue emanating from combustion chamber 3 This means that the proportion of flue gases that enter the cooling section or the flue 7 is cooled to a different extent than the proportion of the flue gases that enter another flue (such as flue 8) as shown in FIG. 1 can be removed, in turn completely surrounded by the heat transport medium 2 over its full length the smoke gases can be formed. Via a throttle valve 12 arranged in the flue gas collection chamber 9, the individual volume flows of the cooled flue gases emerging from the various flue gas flues can be controlled so that the desired mixed temperature can be set within the flue gas collection chamber 9. From the flue gas collection chamber 9, part of the combined flue gases with the new mixed temperature exits via an additional flue gas outlet 15, which can be closed or opened via a throttle valve 13, to a consumer 16, while the remainder of the flue gases from the flue gas collection chamber 9 into a last Flue gas flue 10 (last cooling section) enters and is introduced from this via a throttle valve 14 into an exhaust gas chimney 11. The throttle valves 13 and 14 are coupled to one another in such a way that a desired flue gas pressure is always maintained in the flue gas collecting chamber 9 so that the pressure conditions in the flue gas part of the system maintain the level required for continuous operation.

From the boiler 1 (in Fig. 1: above shown) the heated heat transport medium 2 via a transport line 23 to a consumer 24 and fed back from this via a transport line 25 back into the heating boiler 1. In the Rttuchgassammelkammer 9 is also a device 18 attached over the in the mixing area of the Collection chamber, if necessary, further, additional cooling gas can be introduced, which - in the case of the one shown in FIG. 1 Example shown - directly to the exhaust chimney 11 over a line 17 is removed.

To control the throttle valves 13 and 14 and thus to regulate the pressure level on the exhaust gas side a pressure control device 19 is also provided, which immediately generates a corresponding pressure control device in the event of control deviations Adjustment of the throttle valves 13 and 14 causes.

From the flue gas collection chamber 9 via the additional flue gas outlet 15 to the flue gas consumer 16 are conducted flue gases are then also the exhaust chimney 11 after they have been used fed.

In Fig. 2 shows a basic sectional view of a heating boiler of the type according to FIG. 1, from which the The position and arrangement of the individual flue gas ducts is clearly visible:

Within the heating boiler 1, the combustion chamber 3 is enclosed by a flame tube 26. Below this Flame tube, a first flue gas 7 can be seen, which consists of a large number of individual ones close to one another arranged pipes 20 of the same, relatively small cross-section exists below the flue gas flue 7 the second flue gas duct 8 can then be seen, which in turn consists of a large number of individual tubes 21 which are arranged close to one another, but a considerably larger diameter than the tubes 20 of the flue gas 7 have. The flue gas 10 leading from the collecting chamber 9 (Fig. 1) to the exhaust chimney 11 (Fi g. 1) leads to the representation after F i g. 2 from a plurality of tubes 22 of relatively small diameter, which in turn are arranged close together are. Instead of the flue gas flues shown, however, even more flue gas flues within the given space be provided, for example between the flues 7 and 8 with pipe diameters that between which the tubes 20 and 21 lie. The position of the pipes can also be designed differently, for example in such a way that that the flame tube 26 is not arranged above, but laterally in the boiler 1 and the various Flue gas flues are also provided on the side next to it.

Since the figures are only intended to convey the principle of representation, it was not generally accepted

and to specifically represent devices known to every person skilled in the art, such as control and regulating devices for the fuel supply line 6 or the like; it goes without saying. even that such devices must always be provided for the proper functioning of the system and can be used in any conventional form.
The illustration according to FIG. 3 shows a further embodiment for an arrangement which is designed here as a forced through-flow boiler. In this arrangement, rows of pipe guides T and - with an even greater distance from the flame - pipe guides 8 'are arranged around the area of the flame, preferably helically, with essentially the same distance from the flame, through which the heat transport medium is continuously pumping. The released radiation energy as well as the convection energy are here transferred to the heat transport medium flowing in the pipe guides 7 'and 8'. As shown by arrow lines, the flue gases are initially deflected axially after passing through the combustion path, then guided along the pipe guides T and then, after a renewed axial deflection, i.e. again in countercurrent, guided along the pipe guides 8 'to finally enter an exhaust gas chimney 11' to enter.

However, some of the flue gases generated are not passed through the pipe guides T and 8 ', where the flue gases are continuously cooled until they enter the chimney W , but rather introduced directly at the end of the combustion chamber via a channel 31 into a flue gas collecting chamber 9' . A connecting line 30 from the flue gas chimney 11 'to the flue gas collecting chamber 9' allows the considerably cooled flue gases to be mixed with the hotter flue gases in the flue gas collecting chamber so that flue gases of a desired temperature in a range of approx. 500 "C to approx. 900 ° C are available. In this case (which is not shown in the figures) both the flue gas flow through the duct 31 and the volume flow from the flue gas chimney 11 'via the line 30 of the flue gas collection chamber 9' feedable exhaust gases are controllable in each case in order to be able to easily set the desired temperature of the smoke gases to be withdrawn for the downstream smoke gas consumer.

For this purpose 3 sheets of drawings

Claims (7)

Patent claims: 1. Arrangement for flue gas routing and flue gas extraction in a heating boiler, with a combustion chamber surrounded by a heat transport medium and several flue gas flues also surrounded by the heat transport medium, which are designed as cooling surfaces each of different sizes and of which at least one has a passage control and which the flue gases from the combustion chamber lead to a flue gas collecting chamber and with further flue gas flues designed as cooling surfaces, which feed the flue gases from the flue gas collecting chamber to a flue gas chimney, as well as with an additional flue gas outlet on the collecting chamber, in which the flue gas outlet is controllable, characterized in that all flue gas flues emanating from the combustion chamber (3) (7, 8) end via fully or partially switched on and off Austriltsquerschnitle in the collecting chamber (9), a flue gas consumer (16) is connected to the additional flue gas outlet (15) and the control of the flue gas outlet through the additional union flue gas outlet (15) takes place essentially while keeping the flue gas pressure constant in the collecting chamber (9). 2. Arrangement according to claim 1, characterized in that for controlling the flue gas outlet from the collecting chamber (9) through the additional flue gas outlet (15) arranged in this one Throttle valve (13) and another upstream of the inlet section of the flue gases into the discharge chimney (11) Throttle valve (14) are provided, the two throttle valves (13, 14) facing each other in opposite directions are coupled to one another in an adjusting manner. 3. Arrangement according to claim 1 or 2, characterized in that in part or in whole Switching on or off the flue gas flues (7, 8) emanating from the combustion chamber (3) one in the Flap (12) arranged in the flue gas collection chamber (9) is provided through which the inlet openings each flue gas flue (7, 8) in the collecting chamber (9) can be completely or partially closed. 4. Arrangement according to one of claims 1 to 3, characterized in that the switching on and off of the flue gas flues (7, 8) emanating from the combustion chamber (3) as a function of a presettable one Flue gas temperature in the collecting chamber (9) takes place automatically. 5. Arrangement according to one of claims 1 to 4, characterized in that the flue gas collecting chamber (9) as completely washed around by the heat transport medium (2) of the heating boiler (1), on one End of the heating boiler (1) arranged reversing chamber (9) is formed for the flue gases. 6. Arrangement according to one of claims 1 to 5, characterized in that each of the flue gas passes (7; 8; 10) from a plurality of closely spaced, parallel to each other arranged individual tubes (20,21,22) each has the same cross section. 7. Arrangement for flue gas routing and flue gas extraction in a heating boiler with a Combustion chamber surrounded by the heat transport medium and several, also by the heat transport medium flushed flue gas flues, the flue gases from the combustion chamber of a flue gas collecting chamber can be fed to an Abeaskamin through a smoke puddle designed as a cooling surface can be supplied, as well as with an additional flue gas outlet on the collection chamber, in which the Flue gas outlet is controllable, characterized in that when the heating boiler is designed as Forced flow boiler the flue gas collecting chamber (9 ') at the end of the combustion chamber (3) in this way it is arranged that part of the smoke gases generated enter them directly after leaving the flame area can be introduced uncooled and without flow around heating surfaces (7 ', 8'), and that a device (30) is provided via the exhaust gases from the chimney (1Γ) can be introduced into the collecting chamber (9 '), for both gas flows in the collecting chamber (9') a control is provided and connected to the collecting chamber (9 ') of the flue gas consumer (16) is.