EP2304316A2 - Burner unit and burner arrangement for powdered solid fuel - Google Patents

Abstract

The invention relates to a burner unit for solid powdered fuel (P), comprising a first tube (5, 5' ) for feeding the solid fuel (P) in a first feed direction and comprising a second tube (6) surrounding the first tube (5) for feeding combustion air (S). According to the invention, the burner unit is characterized in that a third tube (7) surrounding the first tube (5, 5') is provided for feeding an additional fuel (E). The invention further relates to a burner arrangement (A, A') comprising a burner unit of the type mentioned above and a method for burning powdered solid fuel and a furnace.

Description

 Burner unit and burner arrangement for dusty

solid fuel

The invention relates to a burner unit for Staubtorraigen solid fuel. Furthermore, the invention relates to a burner assembly for an oven, in particular for a ring-shaft furnace for burning limestone, and such a furnace.

Burner units of the type mentioned are known from the prior art. Among other things, they will be in

Shaft kilns, for example, used in ring shaft furnace for burning limestone. Here, the particular procedural challenge is to achieve the fullest possible implementation of the dusty fuel, for example petcoke dust _r in hot gases in order to use the energy content of the dusty solid fuel as completely as possible.

From DE 10 2006 035 174 Al a burner unit for dusty solid fuel, especially green

Petrolkoksstaub known, in which the injected via a lance m a combustion chamber dusty solid fuel after exiting the lance first encounters a arranged in extension of the lance Umlenkkorper, whereby it is deflected at about 180 ° in the opposite direction, which is so generated reverse flow mixed with tangentially injected into the combustion chamber secondary air. The resulting mixture is m in the direction of the output of the Transports combustion chamber, where it is implemented under optimal conditions completely m hot gases.

In this burner unit, however, there is regularly the problem that the m of the combustion chamber injected combustion air often not the required ignition temperature for the. can provide dusty solid fuel, so that the dust-like solid fuel does not ignite or incomplete. This precludes efficient operation of the burner unit.

Proceeding from this, the present invention seeks to provide a Burner unit of the type mentioned, which allows a stable and efficient Brennerbetrieo even with different operating conditions, especially different combustion air temperatures, and the use of different composite solid fuels, so that the injected dust-like solid fuel to ^ eder Time completely m hot gases is converted. Furthermore, a corresponding burner arrangement is to be specified.

The object is achieved with a burner unit for dust-shaped fuel Fesπbrennstoff having a first tube for demanding the solid fuel in a first Forderrichtung and surrounding the first tube second pipe to demand

Combustion air and a third tube surrounding the first tube to request an additional fuel unfasst.

The erfmdungsgemaße burner unit m in various respects over the known from the prior art burner units advantageous. Thus, on the one hand causes the emerging from the second tube surrounding the second tube Combustion air, that the dust-like solid fuel, which is initially encased in a cone or funnel shape of the combustion air, controlled in Brennraαm, in which the burner unit is installed, is guided and thus optimal in terms of stromungstechnischen aspects and under your aspect of a spatially uniform combustion Way spreads. The combustion air cone also makes it possible to directly control the length of the flame, so that it can be adapted to the spatial conditions in a furnace.

By means of the additional fuel, which is guided by a third, the first tube also surrounding tube, it is ensured that always enough thermal energy is available in the combustion chamber to the with a

Completely ignite Forderluftstrom transported through the first tube transported dusty solid fuel. The design principle of nested tubes also allows the simple upgrade of existing burner units for dusty solid fuels.

The additional fuel is therefore preferably an easily flammable gaseous auxiliary fuel, for example natural gas. Accordingly, the third tube is preferably designed for the delivery of a gaseous additional fuel.

According to a further embodiment of the invention, the third tube is arranged in the radial direction between the first and the second tube. This ensures that the combustion air flow emerging from the second and corresponding outer tube both from the first tube emerging dust-like solid fuel as well as the emerging from the third tube additional fuel cone or funnel-shaped wrapped.

According to a further embodiment of the invention, the free end of the third tube is set back relative to the free end of the first tube. Furthermore, the free end of the second tube is preferably arranged substantially at the height of the free end of the third tube. First, second and third pipe are thus inserted into one another, wherein the respective free ends of the second and third tube are stepped back relative to the first tube, so that the respectively exiting from the individual pipe ends combustion air or fuel / Forderluft-Strόmungen can expand, um - from a certain distance to

Exit point - to fill the entire combustion chamber cross section.

According to a further embodiment of the invention, the first tube is axially displaceable in the surrounding second tube and third tube. As a result, the optimal axial exit point for the dusty solid fuel can be defined from the point of view of flow engineering. If the first tube in continuous operation of the burner unit: shorten due to the strong thermal load, so the first tube can be adjusted accordingly due to the axial adjustability.

In order to achieve a complete and robust sealing of the thus axially displaceable first tube relative to the fixed structure, is another Design provided that the first tube is sealed by means of a stuffing box.

If the burner according to the invention is used, for example, for firing a ring-shaft furnace, it is to be ensured that the axial extent of the burner flame is limited so that a permanent loading of the inner cylinder of the annular shaft furnace, which would be associated with a long-term damage to the refractory material, is avoided. For this purpose, it is provided according to a further embodiment that the

Mixture of dust-like solid fuel and conveying air is supplied to the first tube via a Forderrohr, wherein the inner diameter of the first tube is smaller than or equal to the inner diameter of the delivery tube. As a result, a limitation of the axial flame expansion is achieved due to a limited mass flow and thus a limited pulse current.

The pulse Ström I _P is defined as follows:

with m: mass flow in kg / sec; BS: fuel; FL: exhaust air.

In order to achieve a complete combustion of the dusty solid fuel, it is ultimately necessary that the combustion air and the dust-like

Mix solid fuel from the first and second tubes completely. It is also crucial that the mixture formed from combustion air and dusty solid fuel is evenly distributed over the entire cross section of the combustion chamber. Furthermore, as already mentioned, the limitation of the flame length must be ensured in order to avoid damage to the refractory lining. For this purpose, according to a further embodiment of the invention, it is provided that a swirl body is arranged in the second tube near its mouth for generating a swirl flow in the combustion air emerging from the second tube.

By means of such a swirl body, a conically widening, strongly twisted air flow is achieved as a turbulent free jet, which limits the flame length by generating a negative pressure in the enclosed cone volume and also ensures a particularly gleichmaßige distribution with a high degree of mixing over the combustion chamber cross-section.

The twisting body in turn can take various forms. Preferably, it is annular, in particular as a vane ring with over the circumference of an annular

Base body distributed, to the symmetry axis of the body twisted vanes formed.

A further improved mixing between combustion air and pulverulent solid fuel can be achieved if a deflecting body for deflecting the solid fuel jet emerging from the first pipe is arranged in extension of the first pipe, as known in principle from the prior art. As a result, first a 180 ° deflection of the solid fuel jet is achieved immediately after exiting the first tube, which requires intensive mixing with the combustion air. However, the mechanical stability of the thermally heavily loaded in the operation of the burner deflecting body has been found in studies by the applicant as problematic. A further aspect of the present invention relates to a burner arrangement for an oven, in particular for a ring-shaft furnace for burning limestone, with a burner housing defining a combustion space and a burner unit according to one of claims 1 to 11.

For the advantages of this burner arrangement, the above applies in an analogous manner.

Preferably, the combustion chamber is formed substantially cylindrical, wherein the burner unit projects substantially coaxially into the combustion chamber.

According to a further particularly advantageous embodiment of the invention, the burner housing comprises a spiral housing into which a further combustion air duct tangentially opens. This makes it possible that further combustion air enters the burner housing with a combustion air that is significantly higher in comparison to the combustion air emerging from the second tube and due to the tangential flow

Entry and the special structural design of the spiral housing is strongly twisted. The correspondingly twisted from the volute casing into the combustion chamber combustion air can be intensively mixed with the emerging from the second tube combustion air and dusty solid fuel and with the exiting from a third tube additional fuel, so that a complete combustion of the dusty solid fuel even at substoichiometric Zufuhrung from the second tube exiting combustion air is ensured. For this purpose, the spiral housing is preferably arranged in the flow direction of the dust-like solid fuel in front of the combustion chamber. Furthermore, as far as the combustion air emerging from the second tube is twisted, the twist directions of the two air streams are preferably in the same direction, in order to achieve a particularly intensive mixing,

The object mentioned at the outset is achieved by a process for firing dust-like solid fuel xn of a burner arrangement, in particular a burner arrangement according to one of claims 12 to 15, characterized

- That the dust-like solid fuel is blown in a first Forderrichtung means of a Forderluftstroms from a first tube of a burner unit in a combustion chamber,

- That combustion air is blown from a second tube surrounding the first tube in the combustion chamber and

- That an additional fuel from a first tube also surrounding the third tube is blown into the combustion chamber.

For the advantages of the inventive method again the above applies accordingly.

As auxiliary fuel, a gaseous auxiliary fuel, in particular natural gas, is preferably used. This is highly flammable and capable of providing the thermal energy necessary for complete combustion, particularly of high solids fumed solid fuels. As dust-like solid fuels are preferably Kohlestaαbe used. Particularly preferred is the use of petroleum coke dust or brown coal dust. Brown coal dust is characterized by a comparatively low

Zundtemperatur of about 45O ⁰ C, so that the use of an additional fuel in stationary operation of the burner unit is often no longer necessary because the required ignition temperatures are already provided by the Verbrennungsluftstrora. Petroleum coke dust, on the other hand, has one

Ignition temperature of about 700 ⁰ C, so that here the use of the additional fuel is necessary to bridge the temperature difference between the temperature of the combustion air and the ignition temperature of the petroleum coke dust.

In the context of the method, it is thus possible to switch off the introduction of the additional fuel as soon as in the combustion chamber sufficient thermal energy is permanently available, which is a complete combustion of the dust

Solid fuel also without additional fuel for the purpose of raising the temperature level in the combustion chamber ensures.

According to a further embodiment of the erfindαngsgemaßen method is the exit velocity of the Forderluft for the dust-like solid fuel v _FL <about 15 m / sec. As a result, the pulse current of the Forderluft / fuel mixture is limited upwards. By this limitation of the pulse current, in turn, the length of the flame can be limited and thus damage to the refractory lining of the furnace fired by the firing unit can be avoided. In the following, the invention will be explained in more detail with reference to a drawing illustrating an exemplary embodiment. Show it:

FIG. 1 shows a burner arrangement known from the prior art, FIG.

Fig. 2 shows an improved burner assembly in particular for a ring shaft furnace for burning limestone and

Fig. 3 shows the burner assembly of FIG. 2 in a modified embodiment and

4 a ring shaft furnace for burning limestone with burner arrangements according to FIG. 2.

In Fig. 1 a known from the prior art burner assembly is shown. The burner assembly comprises a burner housing 100 with a rotationally symmetrical combustion chamber 200, which initially widens conically in the transport direction of the fuel or in the propagation direction of the flame and then conically rejuvenated dusenformig conical up to the burner output. By means of a central tube 300 disposed coaxially with the combustion chamber 200, dust-like solid fuel is pneumatically, i. in a so-called. Primarluftstrom, required and exits at the free end 300 a of the central tube 300 from this.

The arranged over a tangential to the combustion chamber 200

Zufuhrung 500 in the Brennraurα 200 at its closed end injected secondary combustion air is in Combustion chamber 200 twisted, as indicated by the spiral line S. An intensive mixing of the dusty solid fuel with the twisted secondary air is achieved in that the dust-like solid fuel at exnem arranged in extension of the central tube 300

Stromungsumlenker 400 is deflected by about 180 ° from its original Strόmungsrichtuπg. This return flow thus mixes with the twisted secondary air, so that a dust mass enriched with air flows through the combustion chamber 200 in the direction of its output and passes into the burner flame B. In addition to the secondary combustion air 600 tertiary combustion air is still stepped through several tangentially arranged nozzles introduced into the combustion chamber 200 to support the swirl flow in the combustion chamber 200.

In this construction, which is known from the prior art, it happens again and again that in particular at too low a temperature of the supplied combustion air into the combustion chamber 200 injected dusty solid fuels with high

Ignite ignition temperature or not completely, so that the total combustion is inefficient.

FIG. 2 shows an improved burner arrangement A compared to FIG. 1. This can be used for example in a ring-shaft furnace for burning limestone, but is not limited to this use. The burner assembly A comprises a housing 1 which encloses a presently cylindrical combustion chamber 2. In the direction of propagation of the flow in front of the combustion chamber 2, a volute 3 is arranged, via soft combustion air or a mixture of so-called. Propellant and rückgefuhrtem Umwalzgas (a partial flow of the kiln exhaust gases, see Fig. 4) can be introduced tangentially with very high volume flow into the combustion chamber 2. On the side facing away from the combustion chamber 2 side of Schneckengehauses 3 of the burner block 4 is arranged with conically widening inner cross-section, in which the Brenneremheii described below is arranged substantially coaxially.

The burner unit comprises a first tube 5 for the demand of dusty solid fuel, in this case petroleum coke dust P, in a Forderluftstrom. This is fed to the first tube 5 via a conveyor tube 5b. In the present case, the inner diameter of the first tube 5 and that of the conveyor tube 5b are identical. This ensures that the mass flow of the solid fuel / Forderiuft mixture proportional to the pulse flow of solid fuel / Forderiuft mixture through the first tube 5 is not too large, so that the length of the flame forming in the combustion chamber 2 is limited.

In the present case, the first tube 5 is designed to be axially displaceable, so that the optimal axial exit point for the dust-like solid fuel can be determined from the point of view of flow engineering. Furthermore, the free end of the pipe can be nachgefuhrx in a possible burn-off of the tip due to ongoing high thermal stress during operation of the burner unit. For sealing the first tube 5 with respect to the other construction, a stuffing box 5a is provided.

Coaxially to the first tube 5, a second tube 6 is arranged, in which the first tube 5 is received. The second tube 6 serves to promote secondary combustion air S in the combustion chamber 2, which can be supplied to the second tube 6 via a radial line 6a. In the annular volume formed between the second tube 6 and the first tube 5, finally, a third tube 7 is received, which serves to promote an additional fuel, in this case natural gas E. This is in turn fed to the third tube via a radial line 7a. In the present case, the third tube 7 has a conical section 7b at its free end.

As can be seen from FIG. 2, the free end of the third tube 7 and that of the second tube 6 are set back relative to that of the first tube 5. One behind the other are the free ends of the second and third tubes 6, 7 in

Essentially arranged at the same height .. This allows the emerging from the pipe ends each air or fuel / conveying air flows conically divergent along the longitudinal axis of the combustion chamber 2 propagate.

The second tube 6 also has, near its free end, a swirl body 8, which in the present case is annularly designed as a vane ring with guide vanes which are distributed over the circumference of an annular base body and rotated with respect to the axis of symmetry of the base body. As a result, a twisted secondary air flow is generated, as will be explained below.

The operation of the burner assembly A according to FIG. 2 is the following: In the first tube 5, a mixture of the dust-like solid fuel (petcoke dust P) and a transport air flow (so-called primary air) is introduced via the Forderrohr 5b and required by the first tube 5 in the combustion chamber 2, wherein the solid fuel jet in the region of the burner block 4 from the first tube 5 exits. The exit velocity αer Forderluft for dust-based solid fuel amounts to preferably <about 15 m / sec, in order to limit the momentum flow of the fuel-air mixture against the background of a limitation of the flame length total.

From the annular channel formed between the outer surface of the first tube 5 and the inner surface of the third tube 7 of the introduced via the line 7a into the third tube 7 additional gas-fuel (natural gas E) exits in a likewise divergent flow and envelops the solid fuel jet in a cone. The exiting from the free end of the second tube 6 secondary combustion air S is strongly twisted by the twist body 8 and also widens conically, where they are the natural gas and

Solid fuel flow E _Λ P enveloped. The introduced via the second tube 6 into the combustion chamber 2 secondary combustion air S due to their comparatively low flow rate allows only a substoichiometric combustion. A complete combustion of the dusty

Solid fuel P and the additional gaseous fuel E is achieved in that on the Spiralgehause 3 more preheated combustion air or a mixture of preheated combustion air and recirculating exhaust gas (so-called injection air 1} tangential and high

Volumetric flow is introduced into the combustion chamber 2. Due to the geometric design of the Spiralgehauses 3 and the tangential introduction, this air flow is also strongly twisted, as indicated by the spiral line D. With increasing distance from the burner unit then the swirled injection air I, the emerging from the second tube 6 preferably co-twisted secondary combustion air S, the emerging from the third tube 1 natural gas stream E and exiting from the first tube 5 dusty solid fuel P for not shown open end of the combustion chamber towards intensively mixed and completely converted to hot gases.

The burner arrangement A 'modified with respect to the burner arrangement A from Fig. 2 differs from the former in that the first pipe 5 "has, in extension of its free end, a deflection body 9 for deflecting the solid fuel jet P emerging from the first pipe a further improved mixing between solid fuel P, additional gaseous fuel (natural gas E) and secondary combustion air S. However, the mechanical stability of the deflecting body 9 has proved to be problematic if the thermal load continues.

The integration of a burner arrangement A according to FIG. 2 or a burner arrangement A 'according to FIG. 3 into a ring-shaft furnace for burning limestone is shown in FIG. 4 shown.

The annular shaft furnace of Fig. 4 is of the type

"Beckenbach" is constructed and shall be briefly described below for the purposes of basic understanding. The oven has a cylindrical outer shell, which is divided into a top shaft 20 and a main shaft 10. The inner shaft wall of the main shaft 10 is formed by a lower inner cylinder 30, which is the

Oberschachtes 20 by an upper inner cylinder 40. In the combustion zone BZ a plurality of burner assemblies A of the type described in connection with FIG. 2 are arranged in a lower burner level, of which m is the present sectional view visible. The Brennereinhej th the upper burner level can also be formed in the inventive manner.

During operation of the annular shaft kiln, the granular material G (limestone) to be fired is placed in the annular shaft kiln and, owing to gravity, first moves through the preheating zone VZ, where it is heated in countercurrent by exhaust gases rising from the combustion zone BZ. As soon as the firing material G has passed the upper inner cylinder 40, it enters the combustion zone BZ and is burned there in countercurrent and below the lower burner level with the burner arrangements A in DC. Subsequently, the now fired Good G * enters the Kuhlzone KZ, where it is again cooled in countercurrent. Finally, the product G * is discharged from the annular shaft furnace.

As can be seen in FIG. 4, m of the preheating zone VZ of the upper shaft 20 flows into an exhaust part τ: rom in the upper inner cylinder 40 and from there into a recuperator unit 70, where it heats a three-air flow path. This feeds to the burner assemblies A connected, so-called injectors 50 together with a partial exhaust gas stream, which in turn flows via the lower inner cylinder 30 and a loop in the injectors 50.

The injection air provided by the injectors 50 often does not have those for the ignition of the

Petrolkoksstaubes required as dusty solid fuel temperature of about 700 ⁰ C. The additional thermal energy required for complete burning of the petroleum coke dust is now provided in an advantageous manner by the additional gaseous auxiliary fuel (in the present case natural gas) introduced into the combustion chamber 2 in the burner arrangement A or A ', so that the petroleum coke dust is guaranteed at all times is fully converted into hot gases, which ensure efficient operation of the annular shaft furnace.

Another advantage of the presented burner concept is that existing burners can be easily converted in such a way that they also allow the use of an additional fuel such as natural gas.

Claims

claims

1. Brennereinneit for dusty solid fuel (P) with a first tube (5, 5 ') for demanding the solid fuel (P) m a first Forderrxchtung and with the first tube (5) surrounding the second tube (6) for combustion air ( S) and with a first tube (5, 5 ') surrounding the third tube (7) for claiming an additional fuel (E).

2. Burner unit according to claim 1, characterized in that the third tube (7) for the demand of a gaseous additional fuel, in particular natural gas (E), is formed.

3. Burner unit according to claim 1 or 2, characterized in that the third tube (7) in the radial direction between the first and the third tube (7). second tube (5, 5 ', 6) is arranged.

4. The burner unit according to claim 1, wherein the free end of the third tube is set back relative to the free end of the first tube.

5. Burner unit according to one of claims 1 to 4, characterized in that the free end of the second tube (6) is arranged substantially at the height of the free end of the third tube (7).

6. Burner unit according to one of claims 1 to 5, d a d u r c h e c e n e c e s e s, e s the first tube in the surrounding second tube (6) and third tube (7) formed axially displaceable xst.

7. Burner unit according to claim 6, characterized in that the first tube (5, 5 ') is sealed by means of a stuffing box.

8. Brennereinheat nacn Ansprucne 1 to 7, characterized in that the dusty solid fuel to the first tube (5) but a Forderrohr (5a, 5a ^τ ) is supplied, wherein the inner diameter of the first tube (5) is less than or equal to the inner diameter of Forced tube (5a _r 5a ') is.

9. burner unit according to one of claims 1 to 8, d a d u c h e c e n e c e s in the second tube (6) near its mouth a Verdallkorper (8) for generating a swirling flow in the second pipe (6) exiting combustion air (S) is arranged.

10. Burner unit according to claim 9, characterized in that the swirler (8) has an annular shape, in particular as a vane ring with distributed over the circumference of an annular basic body, to the axis of symmetry of

Grundkorpers verdrenten vanes, is formed.

11. Burner unit according to one of claims 1 to 10, characterized in that in extension of the first tube (5 _f 5 ') a Umlenkkorper (9) for Urrtlenkung of from the first tube (5, 5') exiting solid fuel jet (P) is arranged ,

12. Brenneranordnαng (A, A '} for a furnace, in particular for a ring shaft furnace for burning limestone, with a combustion chamber (2) defining burner housing (1) and a burner unit according to one of claims 1 to 11.

13. Burner arrangement (A, A ') according to claim 12, characterized in that the combustion chamber (2) is substantially cylindrical, wherein the burner unit protrudes substantially coaxially into the combustion chamber.

14. Burner assembly (A, A ') according to claim 12 or 13, d a d u r c h e c e n e z e c h e e s t, s a the burner housing (1) comprises a spiral housing (3) into which a combustion air line (I) tangentially.

15. Burner arrangement (A, A ') according to claim 14, characterized in that the spiral housing (3) in the flow direction of the dusty fuel Fesubrennstoffes (P) in front of the combustion chamber (2) is arranged.

16. Method for burning dust formx solid fuel

(P) m of a burner arrangement, in particular a burner arrangement (A, A ') according to one of claims 12 to 15,

- wherein the staubformige solid fuel is blown (P) m a first Ford construction by means of a Forderluftstroms of a first tube (5, 5 ') a burner unit in a combustion chamber (2), - the combustion air (S) from a first tube [S ₁ 5 ') surrounding the second tube (6) m the combustion chamber (2) is blown and

- An additional fuel (E) from a first tube (5, 5 ') also surrounding the third tube (7) is blown into the combustion chamber (2).

17. A process as claimed in claim 16, wherein said petroleum coke dust or lignite dust is used as a dust-like solid fuel (P).

18. A process according to claim 16 or 17, wherein the additional fuel is a gaseous auxiliary fuel, in particular natural gas (E).

19. The method according to any one of claims 16 to 18, characterized in that the exit velocity of the Forderluft for the dusty solid fuel v _FL <ca. 15 m / sec amounts.

20. The method according to any one of claims 16 to 19 b, d a d u c h e c e n e c e s, wherein the combustion air (S) is supplied substoichiometrically.

21. Method according to one of claims 16 to 20, characterized in that additional combustion air (I) is injected tangentially into the combustion space (2) via a spiral housing (3).

22. Method according to claims 20 and 21, wherein the quantity of additionally injected combustion air (I) is dimensioned in such a way that the solid fuel (P) which forms a solid dust burns completely.

23. The method according to claim 16, wherein the supply of the additional fuel (E) is switched off as soon as sufficient thermal energy is available in the combustion chamber (2).

24. Oven, in particular ring shaft furnace for burning

Limestone, with at least one burner arrangement (A, A ') according to one of Claims 12 to 15.