EP2531302A2

EP2531302A2 - Device and method for producing a fine-grained fuel by drying and impact crushing

Info

Publication number: EP2531302A2
Application number: EP11705431A
Authority: EP
Inventors: Ralf Abraham; Stefan Hamel; Ralf Schäfer
Original assignee: ThyssenKrupp Uhde GmbH; Proactor Schutzrechtsverwaltungs GmbH
Current assignee: Proactor Schutzrechtsverwaltungs GmbH; ThyssenKrupp Industrial Solutions AG
Priority date: 2010-02-04
Filing date: 2011-01-26
Publication date: 2012-12-12
Anticipated expiration: 2031-01-26
Also published as: WO2011095295A3; CN102834179A; WO2011095295A2; RU2012135070A; AU2011212726B2; CA2786797A1; TW201134553A; MX2012009040A; US20130199424A1; DK2531302T3; UA105407C2; DE102010006916A1; EP2531302B1; ZA201204799B; PL2531302T3; ES2464277T3; KR20130009757A; AU2011212726A1

Abstract

The invention relates to a device and method for producing a fine-grained fuel, in particular from solid, paste-like or aqueous energy feed stocks, by drying and crushing, comprising an impact reactor having a rotor and impact elements, a labyrinth seal in the region of the rotor shaft of the impact reactor, a device for feeding hot drying gas through the labyrinth seal into the impact reactor and at least one further feed device for hot drying gas in the bottom region of the impact reactor, a feed device for solid or paste-like energy feed stocks in the top region of the impact reactor, at least one extractor device for a gas flow containing crushed and dried energy feedstock particles, and a device for separating and extracting crushed and dried energy feed stock particles from the gas flow extracted from the impact reactor.

Description

DEVICE AND METHOD FOR PRODUCTION OF A FINE-GRAIN FUEL BY DRYING AND DECAY CLEARING

The invention relates to the thermal and mechanical pretreatment substances which may be present in pasty or viscous form and are referred to hereinafter as solid or pasty energy resources, including, for example, biogenic and other highly reactive fuels, fossil fuels and residues count in one baffle reactor. As pasty all substances are understood here, in which solids and liquid fractions are mixed together, examples of which are sewage sludge and industrial residues, either on an aqueous basis or on the basis of solvents or energy-containing liquids, such as lubricants.

The expansion of the use of renewable energy sources and the recovery of waste and residues is sought worldwide, with an energetic or material use is targeted. As part of the energetic utilization of the above-mentioned starting materials, for example, the

Co-incineration in existing combustion plants or mono-incineration in specially designed and designed plants. In contrast, the material use is made possible by the thermal gasification. The synthesis gas thus produced is the feedstock for downstream chemical syntheses, such as for Fischer-Tropsch, methanol or ammonia synthesis.

Both in the case of the combustion technique as well as in the case of

Gasification technology will be as large as possible due to the specific costs

Plant capacities sought. This means that most of the flight flow procedures are used. Characteristics of the air flow method is that the fuels must be reduced to a pneumatically conveyable particle size in order to

To operate dust burner. Typical grain sizes are for hard coal e.g. in the range <100 microns.

For other fuels such as reactive biomass, this particle size may also be significantly larger depending on the process parameters, also is a

Reduction of the moisture content advantageous. In energy raw materials such as biomass, biogenic residues and waste due to the often tough and fibrous structure such pretreatments according to conventional prior art can be achieved only with high energy and equipment costs. For example, described in Kaltschmitt et al.: "Energy from biomass", ISBN 978-300-40-85094-6, 2009, pages 814 ff, the state of the art of biomass drying. In addition to the classic natural drying and

Ventilation methods are listed as technical drying devices, in which a promotion of the material to be dried, the rotary reversing dryer, belt dryer and rotary dryer. These mentioned devices have in common that no comminution of the particles takes place.

From the coal preparation and also from the Mineralstoffaufbereitung also a number of methods are known which can perform a drying and crushing simultaneously. These include, among others, roller mills, beater mills, ball mills. These Mahltrocknungsvorrichtungen are known, however, that a comminution of biomass due to the fibrous and tough structure is limited or not possible and after the present

Experience level by no means leads to a dusty product as it would be required. Instead, for example, Cutting mills or hammer mills are used. The former class of granulators require sharp cutting tools and correspondingly small gaps to allow a cutting operation. This means that an extremely high level of wear takes place and at the same time there is a high susceptibility to contaminants. Second class of hammer mills are characterized by a relatively high mechanical crushing effort.

The object of the invention is therefore to provide a device simpler apparatus and a more energy-efficient method available, with which the drying and crushing can be done in an apparatus, wherein the solid or pasty energy raw materials are pretreated so that they are for a

Flight gasification are operational without further measures.

The invention solves the problem by means of a device for producing a fine-grained fuel, in particular from solid, pasty or aqueous energy by drying and comminution, comprising

A baffle reactor with a rotor and baffle elements,

A labyrinth seal in the area of the rotor shaft of the impact reactor,

• a hot-drying gas supply device through the

Labyrinth seal through into the impact reactor,

At least one further hot gas feed device in the bottom area of the impact reactor, • a feeding device for solid or pasty energy raw materials in

Head area of the impact reactor,

• at least one extraction device for a gas stream containing comminuted and dried energy raw material particles, and a separation and extraction device for crushed and dried

Energy raw material particles from the withdrawn from the impingement reactor gas stream.

The invention is characterized in that narrow columns and cutting

Elements are not required, whereby the crushing process has little effect on the wear of the material.

In embodiments of the device it is provided that different fractions of different grain sizes can be withdrawn from the impingement reactor by using as a take-off device for crushed and dried

Energierohstoffpartikel Abweiseradsichter or side screens or both are provided. By different design and mesh sizes can be deposited in this way different grain fractions.

Further embodiments of the device relate to

Hot-drying gas supply device in the bottom area of the impact reactor, wherein large amounts of drying gas are to be introduced. For this purpose, distributed over the circumference holes are provided. Furthermore, it can be provided that the holes are made inclined in the radial direction and that the bores are aligned tangentially to the direction of rotation of the baffle elements. In this case, the outlet direction of the holes can be aligned with or against the direction of rotation of the rotor of the Praiireaktors. The procedurally more favorable solution depends on the interaction of the properties of the material to be comminuted and the

geometric configurations of the rotor and the baffles and the operation of the rotor, so e.g. the speed and the resulting influence on the local flow processes, from.

Alternatively, hot drying gas can be added in the bottom region of the baffle reactor by distributed over the circumference slit-shaped openings. In this case, the slots may also have a radial inclination. The slots can also be formed by overlapping mounting of floor panels.

In a further embodiment of the device is a

Circuit circuit provided with a gas circuit, having in addition

• at least one additional firing,

At least one pressure-increasing device in the recycle gas stream, • at least one diluent gas addition device in the

Recycle gas stream,

• at least one device for coupling the flue gas from the

Additional firing obtained waste heat in the recycle gas stream.

The object of the invention is also achieved by a method for producing a fine-grained fuel from solid, pasty or aqueous energy raw materials by drying and impact crushing using a

Impingement reactor with a rotor and baffles, in which

• the energy resources of the impact reactor in the head area of the impact reactor

be fed

Hot drying gas is supplied both in the bottom area of the impact reactor and via a labyrinth seal in the area of the rotor shaft of the impact reactor,

The energy raw materials in the impact reactor are comminuted and dried, and comminuted and dried energy raw material particles in a mixture containing them

Gas stream are guided out of the impingement reactor in a particle separator.

Further embodiments of the method according to the invention are caused by the fact that the promotion of solid or pasty energy resources in a conventional manner can be associated with great effort when the raw materials tend to stick. In further embodiments, it is therefore provided that at least a portion of the drying gas is fed together with the energy raw materials through its supply device into the reactor, in this case it is important to ensure that the drying gas is introduced into the supply device sufficiently cool. By the introduction of the drying gas is a drying of the outer surface of the energy resources, especially in the case of solid

Energierohstoffe causes what leads to improved conveyability and significantly reduces the tendency to stick. The passage of the drying gas can be carried out both in countercurrent and in direct current.

In one embodiment of the method it is provided that the

Feeding device is heated indirectly. Due to the drying effect, the drying gas cools during passage through the feeder. The heating counteracts this cooling. For heating, the hot drying gas can be used, which itself cools and then passed through the feeder. About a screw conveyor, which is open to the impact reactor, the

Drying gas can be introduced freely into the baffle reactor. It is advantageous in this case if the energy raw materials and the drying gas are passed in co-current through the screw conveyor. With a rotary valve, which connects the silo with the screw conveyor, a backflow into the silo can be prevented.

All types of feed for drying gas can also be used additively. It is thus possible to introduce drying gas both via the labyrinth seal, as well as the feed device for energy resources, as well as holes and slots in the bottom region of the impact reactor in the baffle reactor and thus process technology to respond to a variety of raw materials, which is an advantage of the invention.

A suitable impact reactor is described for example in DE 196 00 482 A1. This apparatus is surprisingly capable of producing biomass, e.g. Straw or green waste, in the same way as the one described there

To treat plastic fractions. To improve the mode of action, devices as described in the application DE 10 2005 055 620 A1 can also be usefully used.

The fact that in the present invention, the drying and comminution take place simultaneously, there are synergy effects, of which both processes receive benefits. By the simultaneous treatment in the invention takes place after entry of the coarse particles, a rapid superficial drying and by the further particle heating takes place, from outside to inside, a drying also from the particle exterior to the particle interior instead. While in prior art processes the particle size is maintained during drying (e.g.

Drum dryer or belt dryer for biomass), here takes place simultaneously a crushing by the baffle effect. It will be in contact with the

Impingement elements preferably the already partially dried outer

Particle layers knocked off. The remaining, not yet completely dried particle core is thereby exposed again and is back to full

Heat transfer while reduced size exposed.

By the continuous comminution and simultaneous heating, the total drying time is significantly reduced. By the invention, on the one hand, the expenditure on equipment of the usual treatment chain is significantly reduced and at the same time the required specific time requirement is also reduced. The invention will be explained in more detail with reference to an example in Fig. 1 and Fig. 2. FIG. 1 shows the device within a circulatory operation, and FIG. 2 shows a detailed detail in the area of the rotor shaft of the impingement reactor. From the storage tank 1, the biomass 2 on the

Rotary valve 3 and the screw conveyor 4 promoted in the baffle reactor 5. There it is crushed by means of the rotor 7. In the bottom area of the impact reactor 5, drying gas 8a is transferred via a labyrinth seal and drying gas 8b

Bottom openings supplied. The comminuted and dried particles 11 are withdrawn via a separator 6, which is preferably a motor-operated rotary separator, with the gas stream 9 from the impingement reactor 5 and into the particle separator 10, shown here as a filtering separator. Another withdrawal takes place through the side outlet 6a, wherein the withdrawn gas 9a also for

Particle separator 10 is passed.

It is advantageous that the size of the exiting with the gas stream 9 particles can be adjusted by the use of the classifier 6. It may also be advantageous to dispense with the motor-driven rotary separator and to use screens or perforated plates, by which the particle size of the solids contained in the gas stream 9 can be influenced.

Depending on the desired use of the pretreated fuel, the target particle size of the dried particles 11 is defined by various requirements of the gasification or incineration plant. These are e.g. Requirements for the interaction of reactivity and particle size, on the transport properties or further, may be advantageous for different Einsatzsof a different particle size or particle size distribution. Therefore, they are different

Pre-separation methods such as sifters or sieves make sense. Depending on the desired particle size, a mass separator or a cyclone separator may be used sensibly as a particle separator 10.

In the particle separator 10, the dried particles 11

separated and discharged by means of the rotary valve 12 in the storage tank 13. The cleaning of the Partikelabscheiders 10 is preferably done by means of nitrogen 14. Depending on the integration of the present invention in more

Verfarhensschritte can also be a cleaning with other inert gases or with carbon dioxide, air or with oxygen-depleted air.

The recycle gas 15, which is obtained from the Partikelabscheider 0, is clean and contains only small amounts of dust and can the chimney 16th be discharged. A partial flow 17 is previously branched off, and mixed by means of the blower 18 with hot gas, which is obtained from the burner 19 from air 20 and fuel gas 21. The resulting drying gas 22 is with

Dilution gas 23 added to the impact reactor 5 is returned.

There it is divided as the drying gas 8a via a labyrinth seal and drying gas 8b via bottom openings as described above as in the

Passed bottom region of the baffle reactor 5 and also as a drying gas 8c in the screw conveyor 4, through which it also passes into the baffle reactor 5. The

Screw conveyor 4 is via a heating medium with Heizmittelzulauf 24 and

Heating medium return 25 indirectly heated.

Furthermore, in Fig. 2 is a fragmentary detail view of

Baffle reactor 5 shown in the region of the rotor shaft 34, via which the rotor 7 is driven by a motor not shown in detail. As the illustration of Fig. 2 can be taken here, located at the front end of the

Rotor shaft 34 has a rotor receptacle 35, in the underside of a circumferential recess or groove 36 is introduced, for example, has a rectangular cross-section. In the circumferential recess 36 extends from below a circumferential projection 37, which is preferably arranged on the bottom plate 38 of the baffle reactor 5. The projection 37 has a width which is smaller than the width of the recess 36, and does not extend completely with its top to the bottom of the recess, so that between the outer surface of the projection 37 and the inner surface of the recess 36, a labyrinth seal 33rd with a

Labyrinthgang 33a formed through which the full amount of the drying gas (8a + 8b) or a subset (6a) or other gas is introduced into the interior of the impingement reactor 5. For example, the labyrinth passage may have a width in the range of 2mm to 20mm. According to a not shown

Embodiment of the invention, the labyrinth seal 33 viewed in the radial direction to improve the sealing effect also have two or more projections 37 which extend into corresponding recesses 36, which are adapted in shape to the shape of the projections.

The supply of the drying gas 8a via the labyrinth seal 33 is preferably carried out by one or more below the bottom plate 38 in the

Waveguide 39 arranged holes 40 therethrough along the indicated by the arrows 8a supply path. This first extends in the direction of the rotor shaft 34, ie the center of rotation of the rotor 7, then substantially parallel to the rotor shaft or axis of rotation of the rotor 7 in the upward direction and then above the Bottom plate 38 again in the opposite direction through the labyrinth passage 33a through radially outward from the center of rotation of the baffle reactor 5 away, resulting in a particularly efficient sealing and distribution of the drying gas inside the reactor. This can be further improved by the use of one or more, the labyrinth passage 33a fluidly downstream Schleuderleisten 41.

The supply of the further drying gas 8b is carried out by one or more located in the bottom plate 38 openings 42. These openings 42 can be performed as a plurality of holes over the circumference or as one or more slots. It is also conceivable to provide oblique bores in order to impart to the gas 8b, as it flows into the impingement reactor 5, a flow direction advantageous in terms of process technology.

LIST OF REFERENCE NUMBERS

1 storage tank

2 biomass

3 rotary valve

4 screw conveyor

5 impact reactor

6 classifiers

6a side outlet

7 rotor

8 8, 8a, 8b, 8c hot recycle gas / drying gas

9 gas flow through sifter

9a gas flow through side outlet

10 particle separators

11 dried particles

12 rotary valve

13 storage tank

14 backwash gas

15 dedusted gas

16 exhaust

17 cycle gas

18 blowers

19 burners

20 air

21 fuel gas

22 gas

23 diluent gas

24 heating medium for screw

25 heating medium return

33 labyrinth seal

33a labyrinthine passage

35 Rotor mount

34 rotor shaft

36 deepening

37 advantage

38 base plate

39 wave guide

40 hole

41 skating strip

42 opening

M engine

Claims

claims

1. Apparatus for producing a fine-grained fuel, in particular from solid, pasty or aqueous energy by drying and comminution, comprising

A baffle reactor with a rotor and baffle elements,

A labyrinth seal in the area of the rotor shaft of the impact reactor,

A hot-drying gas supply device through the labyrinth seal into the impact reactor,

• at least one further hot gas feed device in the

Bottom area of the impact reactor,

A feed device for solid or pasty energy raw materials in the head region of the impact reactor,

• at least one extractor for shredded and dried

Energy raw material containing gas stream, and

• a separation and extraction device for shredded and dried

Energierohstoff particle from the withdrawn from the impingement reactor gas stream.

2. Apparatus according to claim 1, characterized in that Abweiseradsichter be provided as a take-off device for crushed and dried energy commodity particles.

3. A device according to claim 1, characterized in that are provided as a take-off device for shredded and dried energy raw material side screens.

4. Apparatus according to claim 1, characterized in that as

Hot-dry gas supply means are provided in the bottom area of the impingement reactor with holes distributed over the circumference.

5. Apparatus according to claim 4, characterized in that the bores are performed inclined in the radial direction.

6. Apparatus according to claim 5, characterized in that the bores

are aligned tangentially to the direction of rotation of the baffles.

7. Apparatus according to claim 1, characterized in that as

Hot-dry gas supply means are provided in the bottom area of the impingement reactor over the periphery distributed slot-shaped openings.

8. Apparatus according to claim 7, characterized in that the slots a

have radial inclination.

9. Device according to one of claims 7 or 8, characterized in that the slots are formed by overlapping mounting of floor panels.

10. Device according to one of claims 1 to 9, characterized by a

Circulation circuit with a gas circulation, having in addition

• at least one additional firing,

At least one pressure-increasing device in the recycle gas stream,

At least one diluent gas addition device into the recycle gas stream,

• at least one device for coupling the flue gas from the

Additional firing obtained waste heat in the recycle gas stream.

11. A process for producing a fine-grained fuel from solid, pasty or aqueous energy raw materials by drying and impact crushing using a baffle reactor with a rotor and baffles according to claim 1, wherein

The energy raw materials are supplied to the impact reactor in the head region of the impact reactor,

• the energy resources in the impact reactor are crushed and dried, and

• comminuted and dried energy raw material particles in a containing them

Gas stream are guided out of the impingement reactor in a particle separator.

12. The method according to claim 11, characterized in that at least a portion of the drying gas together with the energy raw materials by the

Feeder is guided into the reactor.

13. The method according to claim 12, characterized in that the

Supply device for the energy resources is heated indirectly in the reactor. Method according to one of claims 11 to 13, characterized in that a circulation operation is provided, wherein

At least one additional firing, wherein the energy of the flue gas obtained is used directly or indirectly for heating the cycle gas stream,

Adding to the cycle gas stream a diluent gas, which may be an inert gas such as nitrogen or carbon dioxide, or may be a gas with reduced oxygen content, or may be air, or a mixture of said gases.

• the pressure loss in the recycle gas flow is compensated, and

• the heated circulation stream is returned to the baffle reactor.