EP1846151A1

EP1846151A1 - Method and device for the thermochemical conversion of a fuel

Info

Publication number: EP1846151A1
Application number: EP06706461A
Authority: EP
Inventors: Peter Quicker; Gerold Dimaczek; Frank Fojtik
Original assignee: APPLIKATIONS- und TECHNIKZENTRUM fur ENERGIEVERFAHRENS- UMWELT- und STROEMUNGSTECHNIK (ATZ-EVUS); Applikations- und Technikzentrum fur Energieverfahrens- Umwelt- und Stromungstechnik (atz-Evus); ATZ EVUS
Current assignee: Fraunhofer Gesellschaft zur Forderung der Angewandten Forschung eV
Priority date: 2005-02-09
Filing date: 2006-01-28
Publication date: 2007-10-24
Anticipated expiration: 2026-01-28
Also published as: US20080149011A1; CA2597520C; DE102005005796A1; JP2008530491A; EP1846151B1; WO2006084590A1; JP5007242B2; CA2597520A1

Abstract

The invention relates to a method for the thermochemical conversion of a fuel, comprising the following steps: a) provision of a fluidised-bed reactor with a central first combustion zone (1) and a second combustion zone (7) that is separated from the first by flow conduction means (2, 15), the first combustion zone (1) being provided with a supply opening (16) for supplying fuel and a unit (3), which lies opposite the supply opening (16) on the floor (B) of the fluidised bed reactor, for deviating a stream of fuel into the second combustion zone (7); b) feeding of fuel through the supply opening (16), so that a stream of fuel forms that is directed towards the floor (B); c) deviation of the stream of fuel on the floor (B) into the second combustion zone (7), so that the stream of fuel is guided in an essentially opposite direction; and d) additional deviation of the stream of fuel in the vicinity of the supply opening (16), causing the stream of fuel to be returned to the first combustion zone.

Description

description

Method and device for the thermochemical conversion of a fuel

The invention relates to a method and a device for the thermochemical conversion of a fuel. It relates in particular to the field of fluidized bed combustion, in which the fuel is burned in a fluidized bed formed by a circulating fluid.

From DE 39 24 723 C2, a fluidized bed reactor is known, in which the fuel is supplied via a projecting in the vicinity of the bottom of the reactor in the horizontal tube. The ash removal takes place through another horizontally extending

Pipe, which also opens in the vicinity of the soil in the reactor. The proposed method disadvantageously only a discontinuous process is possible. In particular, the process is not suitable for the combustion of ash-rich fuels.

US Pat. No. 5,858,033 describes a fluidized-bed reactor in which the fuel is supplied through a tube which opens laterally into the upper part of the reactor. At the bottom of the reactor, an annular nozzle arrangement is provided, with which a circulating fluid flow is generated. The ashes in the fluidized bed ash is removed via an annular gap surrounding the nozzle assembly at the bottom of the reactor. Similar fluidized-bed reactors are known from US Pat. No. 5,980,858 and US Pat. No. 5,922,090. The ash discharge takes place via a grate at the bottom of the fluidized bed reactor. In the known fluidized bed reactors, clogging of the nozzles and discharge of unburned fuel may occur. DE 199 37 524 A1, DE 198 43 613 C2, DE 198 06 318 A1 and DE 199 37 521 A1 describe processes for the combustion of waste products and waste materials from the paper industry. In this case, the energy generated in the fluidized-bed combustion is recovered from the exhaust gas via heat exchangers.

DE 197 14 593 A1, DE 199 03 510 C2, DE 35 17 987 C2, DE 690 00 323 T2 and DE 693 07 918 T3 describe fluidized-bed reactors in which the combustion takes place in a cylindrical reactor. Again, the heat recovery is usually carried out by means of switched into the exhaust gas flow heat exchanger.

DE 198 48 155 C1, DE 32 14 649 C3, DE 37 15 516 A1, DE 38 03 437 A1, DE 39 29 178 A1 and DE 696 18 819 T2 disclose fluidized bed reactors in which an inert material is used to produce the fluidized bed Reactor is supplied.

The fluidized bed reactors known from the prior art are usually designed for a high power range. In particular, they are not suitable for burning ash-rich solid fuels, for example biomass, in a small power range.

The object of the present invention is to specify a method and a device with which fuels can be converted thermochemically in a simple and cost-effective manner even in a small power range.

This object is solved by the features of claims 1 and 18. Expedient embodiments emerge from the features of claims 2 to 17 and 19 to 34. According to the invention, a method for the thermochemical conversion of a fuel is provided with the following steps:

a) providing a fluidized bed reactor having a central first combustion zone and a second combustion zone separated therefrom by flow conduction, the first combustion zone having an opening for supplying fuel and a device for redirecting a fuel stream opposite the opening at the bottom of the reactor the second combustion zone is provided,

b) supplying fuel through the feed opening so that a fuel flow pointing to the ground is formed,

c) diverting the fuel stream at the bottom into the second combustion zone such that the fuel stream is directed in a substantially opposite direction, and

d) further redirecting the fuel stream near the feed opening such that the fuel stream is returned to the first combustion zone.

In the method proposed according to the invention, the combustion of the fuel takes place in a fluidized bed reactor which is subdivided into a first and a second combustion zone by means of a flow guide. This allows a positive guidance of the fuel stream and thus a particularly compact design of the fluidized bed reactor. The proposed method is particularly suitable for combustion of fuel in a small power range. In particular, the method is suitable for burning solid and ash-rich fuels, for example biomass. According to an advantageous embodiment, ashes occurring in the thermochemical reaction are removed through discharge openings provided on the bottom. For closing the discharge openings closure means may be provided. Furthermore, it has proven expedient to separate the discharge openings by a grate from the first and / or second combustion zone. This allows a continuous process management. For example, an ascending chamber can be provided between the grate and the discharge openings, which can be emptied discontinuously by opening the discharge openings. Of course, it is also possible to remove the resulting ash continuously through the discharge openings.

According to a further embodiment, it is provided that exhaust gas formed in the thermochemical reaction is led by at least one provided in the vicinity of the supply port exhaust port. This enables efficient process management with a small space requirement.

Advantageously, a cross-sectional area of the second combustion zone increases at least in sections from the bottom in the direction of the feed opening. In the area of the large cross-sectional area, the flow velocity is reduced. As a result, there forms when choosing a suitable

Flow rate of a fluidized bed in which large particles linger longer than small ones. Small particles, in particular fine particles of ash, are removed, whereas large particles still containing usable fuel are burned efficiently. Thus, a particularly efficient combustion of the fuel can be achieved.

The reactor according to the invention may be box-shaped. In this case, two second combustion zones are expediently provided which are adjacent to the first combustion zone are arranged. However, it may also be that the second combustion zone surrounds the first combustion zone. In this case, the first combustion zone is, for example, cylindrical.

According to a further embodiment, it is provided that the heat resulting from the thermochemical reaction is removed by a heat exchanger which at least partially surrounds the second combustion zone and / or is part of the flow control means provided between the first and second combustion zones. This allows a particularly effective utilization of the energy released during the thermochemical conversion.

The heat exchanger may be at least partially shielded from the first and / or second combustion zone by a refractory shield. The shield is suitably made of a refractory ceramic material. It may j e after design of the reactor, the shape of a plate, a cylinder, a truncated cone or the like. exhibit . In particular, the refractory shield may also be part of the flow guide.

The thermochemical reaction may be combustion or gasification. In particular, solid, but also liquid fuels can be converted.

According to a further embodiment, the device for deflecting the fuel stream on a roof or cone-like deflection. Furthermore, the means for redirecting the fuel stream may comprise nozzles for accelerating the fuel flow deflected by the deflection means in the direction of the second combustion zone. The nozzles may have a round, oval or slot-shaped opening. The fuel flow is expediently accelerated by a fluid supplied through the nozzles. The fluid can through the nozzles are ejected in a direction facing the ground. This assists the positive flow of fuel flow generated by the flow directing means from the first to the second combustion zone.

The fluid is expediently at least one gas selected from the following group: air, inert gas, flue gas or radiation-active gas. A radiation-active gas is understood as meaning a gas which enables heat transfer with a particularly high heat flux density. In particular, at high temperatures of more than 900 ⁰ C, a significant portion of the heat is transmitted by radiation. With a radiation-active gas, the heat transfer can be effectively carried out by means of radiation. The radiation-active gas preferably contains 40% by weight of a triatomic gas, for example one or more of the following gases: CO ₂ , NH ₃ , H ₂ O, SO ₂ or else CH ₄ . The radiation-active gas may also be mixed with air.

Further, the fluid may contain at least one additive selected from the following group: lime, ammonia, urea, limestone. Such additives contribute to the lowest possible pollutant combustion of fuels.

Conveniently, a device for preheating the fluid is also provided. Thus, the combustion temperature can be adjusted and / or controlled.

According to another aspect of the invention, there is provided apparatus for thermochemically reacting a solid fuel having a fluidized bed reactor having a central first combustion zone and a second combustion zone separated therefrom by flow directing means, the first combustion zone having a supply port for supplying fuel and one opposite the supply port provided at the bottom of the reactor Means is provided for diverting a fuel stream into the second combustion zone, such that a fuel flow pointing from the supply opening to the ground is deflected into the second combustion zone, guided in a substantially opposite direction and in turn deflected in the vicinity of the feed opening and into the first combustion zone is led back.

The proposed device is compact and allows efficient thermochemical conversion of fuels even in a small power range. Because of the advantageous embodiments of the device, reference is made to the above statements. The described features are suitable mutatis mutandis as development of the device.

An embodiment of the invention will be explained in more detail with reference to the single drawing.

In the fluidized bed reactor shown in the single figure, a first combustion zone 1 is bounded laterally by plates 2 made of a refractory material, for example alumina, magnesia, zirconia or the like. , are made. At the bottom B of the fluidized bed reactor, a deflection device 3 is provided. The deflection device 3 has a roof-shaped or saddle-like design, with the roof surfaces or saddle flanks falling away from the center of the fluidized-bed reactor towards its sides in the direction of the bottom B. The deflection device 3 can be made of a temperature-resistant metal or also of a refractory ceramic material. Below the deflection device 3 is a

Fluid supply device 4 is provided, which has a feed tube 5 and nozzles 6. The nozzles 6 are arranged such that a fluid passed through is guided obliquely in the direction of a section of the bottom B which is located approximately below a second combustion zone 7. The nozzles 6 are bounded by the preferably made of a metal deflecting device 3. During operation of the fluidized bed reactor, the deflection device 3 heats up. As a result, it also preheats a fluid passed through the nozzles 6. Instead of the feed tube 5, a feed chute or feed channels may also be provided in the feed device 4, which are arranged in particular in such a way that a further preheating of the fluid is thereby effectively achieved. The second combustion zone 7 is arranged adjacent to the first combustion zone 1. The fluid may in particular be a gas, for example air, inert gas or a radiation-active gas. The nozzles 6 expediently open in the region of the lower end of the deflection device 3. Nozzle openings designated by the reference numeral 8 can be slit-like, oval or round.

Approximately below the second combustion zone 7 are ash collection zones 9, which are covered with 10 gratings. In the area of the ash collecting zones 9, discharge openings 11 for discharging ash are also provided. The discharge openings 11 are expediently located below flaps 12. By opening the flaps 12, the interior of the fluidized bed reactor for maintenance and cleaning purposes in a simple manner accessible. Instead of the flaps 12, of course, other closure means can be provided, which allow a recurring access to the interior of the fluidized bed reactor.

A parallel to the bottom B extending cross-sectional area of the second combustion zone 7 increases up to a designated by the reference numeral 13 Nebenwirbelschichtzone.

The walls of the second combustion zone 7 are provided with an outer heat exchanger 14 and an inner heat exchanger 15. The inner heat exchanger 15 acts as well as the plate 2 as Flow guide and separates the first combustion zone 2 of the second combustion zone. 7

Opposite the deflection device 3, a supply opening 16 for supplying fuel and two exhaust openings 17 for discharging exhaust gas are provided in an upper area of the fluidized-bed reactor. Between the exhaust gas openings 17 and the plates 2 there is a gap or passage 18, which allows a passage of a fuel stream coming from the second combustion zone 7 into the first combustion zone 1.

The function of the fluidized-bed reactor is as follows: Fuel supplied by the feed opening 16, for example biomass, is guided in the direction of the deflection device 3 in the first combustion zone 1 and is burnt. The directed in the direction of the deflector 3 Brennstoffström is split by means of the deflection device 3 into two partial streams and deflected in the direction of the second combustion zone 7. To maintain the flow, for example, air is blown through the feed tube 5, which exits at the nozzle openings 8 and accelerates the partial flows, so that they are directed in ent opposite direction in the second combustion zones 7 upwards. As a result of the cross-sectional enlargement provided in the second combustion zones 7, the flow velocity decreases. In the sub-fluidized bed zones 13 coarser, not yet completely burned fuel particles are separated from the fine material until they have reached a certain fineness as a result of the combustion. Finer ash particles, however, are immediately transported further and withdrawn through the exhaust ports 17 the circulating fuel flow.

The resulting in the combustion in the combustion zones 1, 7 heat is decoupled by means of the heat exchangers 14, 15 and can elsewhere for power generation, heating or the like. be used. The supplied through the feed tube 5 fluid, such as air, can be preheated by means provided in the bottom B and / or in the deflection device 3 along the nozzle 6 fluid channels. This makes it possible to set or control the combustion temperature.

Coarse ash particles are collected in the ash collecting zones 9 and discharged via the discharge openings 11, preferably continuously.

The present invention is not limited to the described embodiment. To carry out the process according to the invention, differently designed eddy current reactors are also suitable. For example, the first combustion zone 1 can also be cylindrical and the second combustion zone 7 can be designed as an annular gap surrounding the first combustion zone 1. - Similarly, the exhaust port 17 may be designed as an annular gap which surrounds the feed opening 16. The deflecting device 3 may be designed conical or dome-like in a cylindrical embodiment. The arrangement of the nozzles 6 is chosen so that an optimal circulation of the fuel through the first 1 and the second combustion zone 7 is ensured. Depending on the geometry of the second combustion zone 7, a speed of the circulating fuel stream is to be set such that mist vortex layer zones 13 are expediently formed there.

LIST OF REFERENCE NUMBERS

1 first combustion zone

2 plate

3 deflection device

4 Pluidzuführvorrichtung

5 feed tube

6 nozzle

7 second combustion zone

8 nozzle opening

9 ash collection zone

10 rust

11 discharge opening

12 flap

13 sub-fluidized bed zone

14 outer heat exchangers

15 internal heat exchangers

16 feed opening

17 exhaust port

18 gap

B floor

Claims

claims

1. A process for the thermochemical conversion of a fuel with the following steps:

a) providing a fluidized bed reactor having a central first combustion zone (1) and a second combustion zone (7) separated therefrom by flow control means (2, 15), the first combustion zone (1) having a feed opening (16) for feeding Fuel and an opposite of the feed opening (16) provided on the bottom (B) of the fluidized bed reactor means (3) for deflecting a fuel stream in the second combustion zone (7) is provided,

b) supplying fuel through the feed opening (16) so that a fuel stream facing the bottom (B) is formed,

c) diverting the fuel stream at the bottom (B) into the second combustion zone (7) such that the fuel stream is directed in a substantially opposite direction, and

d) further redirecting the fuel stream in the vicinity of the feed opening (16), so that the Brennstoffström is returned to the first combustion zone.

2. The method of claim 1, wherein in the thermochemical reaction resulting ash by at the bottom (B) provided discharge openings (11) is discharged.

3. The method according to any one of the preceding claims, wherein closure means for closing the discharge openings (11) are provided.

4. The method according to any one of the preceding claims, wherein the discharge openings (11) by a grate (10) of the first (1) and / or second combustion zone (7) are separated.

5. The method according to any one of the preceding claims, wherein exhaust gas formed in the thermochemical reaction by at least one in the vicinity of the feed opening (16) provided exhaust port (17) is discharged.

6. The method according to any one of the preceding claims, wherein a cross-sectional area of the second combustion zone (7) at least partially increases from the bottom (B) in the direction of the feed opening (16).

7. The method according to any one of the preceding claims, wherein the second combustion zone (7) surrounds the first combustion zone (1).

8. The method according to any one of the preceding claims, wherein the resulting in the thermochemical reaction heat is removed through a heat exchanger (14, 15) which at least partially surrounds the second combustion zone (7) and / or part of the between the first (1) and second combustion zone (7) provided Strömungsleitmittels is.

9. The method according to any one of the preceding claims, wherein the heat exchanger (14, 15) relative to the first (1) and / or second combustion zone (7) is at least partially shielded by a refractory shield (2).

10. The method according to any one of the preceding claims, wherein the thermochemical reaction is a combustion or gasification.

11. The method according to any one of the preceding claims, wherein the means (3) for deflecting the fuel flow comprises a roof or cone-like deflection means.

12. The method according to any one of the preceding claims, wherein the means (3) for deflecting the fuel flow nozzles (6) for accelerating the deflected by means of the deflecting fuel flow in the direction of the second combustion zone (7).

13. The method according to any one of the preceding claims, wherein the Brennstoffström is accelerated by a through the nozzles (6) supplied fluid.

14. The method according to any one of the preceding claims, wherein the fluid is ejected through the nozzles (6) in a direction to the bottom (B) direction.

15. The method according to any one of the preceding claims, wherein the fluid is at least one selected from the following group gas: air, inert gas, flue gas or radiation-active gas.

16. The method according to any one of the preceding claims, wherein the fluid contains at least one selected from the following group: lime, ammonia, urea, limestone.

17. The method according to any one of the preceding claims, wherein means for preheating the fluid is provided.

18. An apparatus for thermochemical conversion of a solid fuel with a fluidized bed reactor having a central first combustion zone (1) and one of them by Strömungsleit- medium (2, 15) separated second combustion zone (7), wherein the first combustion zone (7) with a feed opening (16) for supplying fuel and an opposite of the feed opening (IS) at the bottom (B) of the fluidized bed reactor provided means (3) for deflecting a fuel stream in the second firing zone (7) is provided in that a fuel flow pointing from the feed opening (16) to the bottom (B) is deflected into the second combustion zone (7), guided in a substantially opposite direction and deflected again in the vicinity of the feed opening (16) and into the first combustion zone ( 1) is returned.

19. The apparatus of claim 18, wherein at the bottom (B) discharge openings (11) are provided for discharging accumulating in the thermochemical reaction ashes.

20. The apparatus of claim 18 or 19, wherein closure means for closing the discharge openings (11) are provided.

21. Device according to one of claims 18 to 20, wherein the discharge openings (11) by a grate (10) of the first (1) and / or second combustion zone (7) are separated.

22. Device according to one of claims 18 to 21, wherein in the vicinity of the feed opening (16) at least one exhaust port

(17) is provided for discharging formed in the thermochemical conversion exhaust gas.

23. Device according to one of claims 18 to 22, wherein a cross-sectional area of the second combustion zone (7) at least partially increases from the bottom (B) in the direction of the feed opening (16).

24. Device according to one of claims 18 to 23, wherein the second combustion zone (7) surrounds the first combustion zone (1).

25. Device according to one of claims 18 to 24, wherein a heat exchanger (14, 15) is provided for discharging the resulting heat in the thermochemical reaction, which at least partially surrounds the second combustion zone (7) and / or part of the between the is first (1) and second combustion zone (7) provided Strömungsleitmittels.

26. Device according to one of claims 18 to 25, wherein the heat exchanger (14, 15) relative to the first (1) and / or second combustion zone (7) is at least partially shielded by a refractory shield (2).

27. Device according to one of claims 18 to 26, wherein the thermochemical reaction is a combustion or gasification.

28. Device according to one of claims 18 to 27, wherein the means (3) for deflecting the fuel stream comprises a roof or cone-like deflection means.

29. Device according to one of claims 18 to 28, wherein the means (3) for deflecting the fuel stream nozzles

(6) for accelerating the fuel flow deflected by the deflection means in the direction of the second combustion zone (7).

30. Device according to one of claims 18 to 29, wherein the Brennstoffström is accelerated by a through the nozzles (6) supplied fluid.

31. Device according to one of claims 18 to 30, wherein the nozzles (6) are arranged so that their ejection direction to the bottom (B) has.

32. Device according to one of claims 18 to 31, wherein the fluid is at least one selected from the following group gas: air, inert gas, flue gas or radiation-active gas.

33. Device according to one of claims 18 to 32, wherein the fluid contains at least one selected from the following group: lime, ammonia, urea, limestone.

34. Device according to one of claims 18 to 33, wherein means for preheating the fluid is provided.