DE6607713U - MULTI-STAGE REGENERATIVE AIR PREHEATER - Google Patents

Description

APPARATUS CONSTRUCTION. RÖTHEMÜHLE
Brandt & Kritzler

596Ί Rothemühle over. Pipe I3. January 197 ¹

Patent and utility model registration "Möhr stage regenerative air preheater"

The invention relates to regenerative air preheaters with a cylindrical housing and continuous radial secondary partitions in the entire regenerative chamber (USA patent 1820 199), in the outer annular spaces of which two or more separate heating surface stages are installed in a stationary manner and are located one behind the other in the axial direction and coaxially to this Annular spaces free of heating surfaces are provided around the stator core (British patent 5 ^ 0797) » ^v <> ⁿ which one serves to take or supply a partial gas flow (French patent 957953)» which alternate periodically, synchronously with the main diffusion of the heat exchanging Gases in the outer annular heating surface pins, through the rotating air connection hoods on the end faces of the cylindrical regenerative chamber. (DBP II56929)

- Such multi-stage regenerative air preheaters are used cleia purpose, the air preheating and the gas cooling in successive To undertake steps to this by introducing or removing different partial gas streams between the air preheater stages that are used for the changing £ lessell> e-fcx ± ei> Achieve favorable control of the air and gas inside the temperature.

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A regenerative air preheater is already known to use two separate stationary heating surface levels, which are in one behind the other in the axial direction ("USA Patent 1820 199). In this arrangement, the gases are supplied and discharged through a free ring roughness between the K ^ m the stationary regenerative chamber and the coaxial heating surface steps arranged in the outer annular space of the regenerative chamber.

On the other hand, a cixial space between heating surface steps axially one behind the other is known from the embodiments of the regenerative air preheaters according to the British patent $ kQ 797 and the French patent 957 953.This French patent also relates to regenerative air preheaters with stationary heat storage masses and also shows the gas extraction between the heating surface levels with rotating heat storage masses.

A partial gas supply between the air preheating stages can also be found in designs according to British patent 5 ^ O 79? (Figure 1, care flap 36),

Compared to the simple rotary slide mechanism known per se (USA Patent 1820 I99) for the supply and discharge of <ier gases ± n or from an inner annular space to be separated coaxially annularly arranged outer heating surface steps on the end faces of the cylindrical regeneration ■ fczLvkannei · is also a double rotary valve arrangement äekatrat (DBP 1156929).

Aios orders these for a 6 'and 6 "kick-off slide the neiden outer end faces of the, with the ring-shaped

Intermediate space (3) fi ⁿ the cylindrical regenerative chambers arranged heating surface stages (1 and 2), as well as a rotary valve (8) attached to the same ¥ elle, which in the free intermediate space (3) »causes a periodic partial gas flow withdrawal or supply synchronous with the main gas flow .

In this embodiment it is one of the heating surfaces Free, inner annular space is provided within the two heating surface levels, whereby the partial gas supply or removal, for example in or on a separate inner concentric channel (23) of the outer connecting slide 6 ", takes place.

Such a version of the regenerative air preheater with construction elements known per se and the combination of known connecting slides 6 ', 6 "with another Rotary valve (S) in the space between the The steps around the courtyard create an unnecessary complication of construction.

The disadvantage here is that the rotary valve 6 ', 6 " only one sector of the connection cross-section for the Delimit air flow. Such a one-sided structural design of the air hoods cannot be used in practice. It results in one-sided load moments for the air hood "shaft, which, due to the size of the construction, can practically not be compensated by counterweights. Farther a one-sided pressure load would occur as a result of the pressure differences between air and flue gas ducts. An equally significant disadvantage would be the asymmetrical thermal expansions that occur as a result of the one-sided Supply of the heat exchanging agents occur in the air heater became.

Our present application therefore sets itself the task of two-stage or multi-stage Regeneisfciv air preheaters to find a measure with stationary storage masses to constructively reduce partial gas flows of the heat exchanging means easy way to branch off or supply. Basically, a symmetrical feed or discharge should be used here the air on the outer regenerator inner surfaces are carried out by means of double hoods and the arrangement of a special Avoid \ * grounding the rotary valve in the space between the steps.

This object is achieved according to the present invention in such a way that one or both air hoods 5> 7 are designed at the same time as double rotary valve mechanisms, with outer sector-shaped connection cross-sections for the main flow in the channels (5b, 7 ^) and coaxial inner rotary valve parts (5c, ? c) for the supply or withdrawal of a partial gas flow to 1bz \\ ^r . from the inner, free of heating surfaces Statorringräumiän (12, 12b), which like the entire Re gene at ivkammer have continuous radial Sektortrenmiände (9), the upper and lower radial front edges sealingly against the inner rotary valve parts (5c, 7c).

The inner rotary valve parts (5c "? C) are provided to those for the supply or removal of a partial gas croine serving inner stator annulus spaces (12, 12b) each completely to be closed off from the main gas supply.

For this purpose, it is proposed that the air supply and air extraction for air flows connected in parallel to be carried out under the same pressure conditions, which results in a Simplification of the construction with stationary heating surfaces and

rotating air duct connections results because additional Seals for the separate air duct routing almost completely can be saved.

Fig. 1 and 2 show an example and schematically a possible Realization of the two-stage regenerative air preheater design according to the present invention.

In Fig. 1 in elevation on the left side is a section AO through the air duct and on the right is a section QB represented by the gas channels.

The plan in Fig, 2 shows a fine cross-section through the Connection frame of the upper rotatable air connection hood (7 $ along the elevation line CD.

According to Fig. 1, the heating gases of the fixed regenerator chamber (1) from above through the permanently connected heating gas inlet channel (2) and leave the chamber through the lower hot gas outlet duct (3) · The cold one Air enters from the bottom left through the air inlet duct (1) axially into the lower rotatable air connection hood (5), flows through the separately superimposed heating surfaces (6 a) and (6 b) partly into the outer annular chamber (7b) and partly in the inner coaxial one for the extraction of intermediate air Chamber (7 a) of the upper rotatable air connection hood (7) From there the higher heated main air flow is continued, to the right into the air outlet manifold (8 b) and the mill air flows from the inner chamber (7 a) of the upper air connection hood in the air extraction manifold leading to leftB (8 a).

The space between the

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Heating surface levels (6 a) and (6 b) is like the entire regenerative chamber by. Radial walls (9) divided, but has iceine ridge walls (TO).

Around the cylindrical inner ring wall (It) of the regenerative chamber additional annular spaces (12 a) and i (12 b) are arranged, which are divided equally by radial walls are.

Only the upper annular space (12 b), while the lower annulus (12 a) completely from dor Air and gas routing completed int.

The upper Luftanschiußhaubö (7) has a rotary valve part (7 c) which covers the annular space (12 b).

The lower air connection hood (5) is used for common Cold air duct and is completely closed off from the inner annular spaces (11) and (12 a).

Main air and mill air have the same pressure, so that sealing the two air currents is not difficult is.

If necessary, the mill air is blown by a pressure-increasing fan brought to the necessary pressure behind the air heater.

Control flaps (I3) can be arranged in the mill air duct, to achieve fine regulation of the mill air by adding main air »

6G07713 15.Λ.71

The arrangement of the Ringräxane (12 a) and (12 b) is enlarged the type of air heater is generally negligible or insignificant, because the cylindrical inner ring wall of the regenerative chamber (11) must be chosen to be relatively large to create favorable flow conditions. It it follows from this that with this version of the two-stage air heater, the sealing system compared to the normal design is practically unchanged. This is a great advantage compared to the construction with rotating heating surfaces and stationary connection channels.

Fig. 3 and h show by way of example and schematically a modified embodiment of the air preheater according to the present invention with mill air extraction and additional hot gas bypass,

The elevation shows the same section as in Fig. 1, while in the plan on the left in Fig. H a cross-section through CD through the upper air connection hood (7) and on the right a section along line EP through the lower air connection hood (5) will.

As can be seen, in this embodiment, the lower rotatable air connection hood (5) is also divided into two coaxial chambers (5a) and (5b). The cold air flows similarly to the one described above from the left through the air inlet manifold (k) and the outer annular chamber (5b) of the air connection hood (5) through the separately superimposed heating surface steps (6a) and (6b), partly into the outer annular chamber (7b) and partly into the inner coaxial chamber (7a) of the upper air connection

hood (7) · From there the main air flow is to the right into the outlet elbow (8 b) and the mill air to the left into the air extraction elbow (8a).

The annular space (12) around the stator core (11) is just like the Zv, * ischenraum between the heating surface stages (6 a) and (6 b) divided by radial walls (9), while coaxial ring walls (1O) are missing. The upper air connection hood (7) has a core part (7 c) which closes the annular space on the Rruchgasseite and has the lower air connection hood (5) a similar annular core part (5c), which is called the one introduced through the flue gas bypass elbow (14) Partial gas flow closes off against the air side of the annular space (12). It can therefore only after this partial gas flow right into the sectors acted on by the gases the annular space (12) between the heating surface steps (6 b) and (6a) enter.

This partial bypassing of the hot flue gases is used during the start-up period of the boiler to increase the temperature of the cold end.

There are control dampers in the flue gas duct above the air heater (15) arranged, if necessary during the bypass the smoke gases can be completely closed. The flue gas extraction then takes place above these flaps, so that only flue gas in the zone between the heating surface areas (6 a) and (6b) is introduced and as a result of this elimination the heating surface level (6b) a significant increase dex * Exhaust gas temperature can be reached.

It is also advantageous in the hot air duct butterfly valves

pen (16) to be arranged in this way also, the Heizfläclienstufe (6 b) to be completely bypassed with air.

The gradual diversion of the gas and air flows in one Air preheater according to the present invention can operate in the boiler in various ways are used to connect in parallel To pressurize heat exchanger; for example In the embodiment according to Fig. 3, the partial gas flow that is used to bypass the heating surface stage (6b) is branched off, passed through an economizer and then fed to the heating surface stage 6 a.

The "advantages achieved with the inventive solution are above all a simpler supply or removal of a partial gas flow through the annular space around the air hood. Furthermore, the separation of the heat exchanging means and the partial gas flows within the rotating air hoods at the two outer regenerator end faces and thus the savings of a special rotary valve opposite the Kon- 's tr * uk: t ± oii nacli DBP ΐ 156929 * H ± ex "feei. ^ eardes also unnecessary sealing lengths in the connection cross-sections for the withdrawn or supplied partial gas flows saved.

Claims (6)

ι * * ι m Pat.6l3 / 49 / Et / B Jan. 13, 1971 New claims 1.) Regenerative air pre-wormers with cylindrical housing (l) and continuous radial sector partition walls (9) in the entire regenerative chamber (l), two in the outer annular spaces or several separate heating surface steps (6a, 6b) stationary are built-in and lie one behind the other in the cvxial direction and coaxially with this, annular spaces free of heating surfaces (l2 a and Ϊ2 b) are provided around the stator core (ll), one of which (12 b) is used to remove or supply a partial gas stream, which is periodically alternating, synchronously with the H atapt flow of the heat exchanging gases in the outer annular heating surface steps (6a and 6b) the rotating air connection hoods (5 * 7) takes place on the end faces of the cylindrical regenerative chamber, characterized in that that one of the air hoods (7) is designed as a double rotary valve mechanism with outer sector-shaped Connection cross-sections for the main flow in the Channel cross-sections (7 b) and a coaxial inner rotary valve part (7 c) for removing a Teilgasstromäs from the inner stator annulus (12 b), free of heating surfaces, which, like the entire regenerative karamer, is continuous has radial sector partitions, the upper radial front edges of which seal against the inner rotary valve parts (7 c) issue. 2.) Regenerative air preheater according to claim 1, characterized in that that the under part {l ?. a) free from hot surfaces. inner stator annulus completely from the air and gas supply is completed. 3 ·) Regenerative air preheater with cylindrical housing (l) and continuous radial sector partition walls in the entire regenerative chamber in the outer annular spaces two or several separate heating surface stages (6a and 6b) stationary are installed and lie one behind the other in the axial direction and coaxially with this an annular space free of heating surfaces (12) is provided around the stator core space (II) for removal and supplying a partial gas flow, which alternate periodically, synchronously with the main flow of the heat-exchanging Gases in the outer annular heating surface steps (6a and 6 b) through the rotating air connection hoods (5i 7) takes place at the end faces of the cylindrical regenerative chamber, characterized in that the air hoods (5 and 7) are both designed as double rotary slide mechanisms with outer sector-shaped connection cross-sections for the heat-exchanging gases and each a coaxial inner rotary valve part (5 c, 7 c) for the supply or withdrawal of a partial gas flow to or from the inner heating surfaces free, stator annulus (12), as well as the entire Regenerative chamber has continuous radial sector partition walls (9), the upper and lower radial end edges sealing against the inner rotary valve parts (5 c and 7 c) are present. 4.) Regenerative air heater according to claim 3, characterized in that that the inner rotary valve part (5c) of the lower Air connection hood (5) the annular space (12) within the of the Sectors acted upon by air flow are covered in a sealing manner. ' ■■ * l ■. 5) Device for simultaneous air preheating for mill air and combustion air in an air preheater according to one or more of the preceding claims, characterized ^ that in »Mühleialuftkanal control flaps (13) are arranged are to achieve a fine regulation of the mill air by adding main air. 6.) Device according to claim 5 »characterized in that the Mill air, if necessary, by arranging a pressure-increasing fan behind the air heater to the required level Pressure is brought.