DE4200575A1 - AXIAL CYCLONE COMBUSTION REACTOR - Google Patents

Abstract

In an axial cyclone combustion chamber (1) for burning solid fuels in a rotary flow field with an essentially conical lower part (15) and a cylindrical upper part (13), an ash-removal opening (23) at the lower end of the lower part and a central waste-gas off-take opening in the top of the upper part, as well as at least one fuel supply and at least one air supply, it is envisaged, to simplify its construction, that at least one tangential air supply (8; 20a-20d; 36a-36b) is provided. <IMAGE>

Description

The invention relates to an axial cyclone Combustion reactor for burning solid fuels in a three-phase field with one essentially conical lower part and a cylindrical upper part, one Ash extraction opening at the lower end of the lower part and a central exhaust vent in the ceiling of the Upper part, and at least one fuel supply and at least one air supply.

Such an axial cyclone is known from DD 2 34 585 A3 Combustion reactor known in which both a carrier air Fuel mixture via a swirl generator and Combustion air axially into the via a swirl generator lower end of the conical lower part are inserted. The two swirl generators are complex components and, in particular, the swirl generator is subject to the fuel-air mixture into the combustion reactor is introduced, increased wear.

It is the object of the present invention, one To create a combustion reactor of the generic type, where no separate swirl generator is required.

This object is achieved in that at least one tangential air supply is provided.  

According to the invention, the rotary flow field is thus through the tangential air supply built.

Here is preferably at least one tangential Air supply on the cylindrical upper part and at least one tangential air supply at the bottom of the conical Lower part provided. In particular the air supply on cylindrical top part can be multi-stage axially and / or Air feeds arranged at a distance in the circumferential direction respectively.

Under certain circumstances, it is advisable to use a tangential one Air supply also at least one axial air supply, preferably in the form of a nozzle base for the supply of To provide fluidizing air.

DD 2 57 280 A1 describes the supply of fluidizing air at the lower end of the conical lower part by means of a frustoconical nozzle bottom known per se.

While with the DD 2 34 585 A3 the supply of fuel over the lower end of the cone, and at the DD 2 57 280 A1 the supply takes place via the cone itself, according to the present invention preferred that the Fuel is supplied to the cylindrical top and tangentially in a more preferred manner. Also the Fuel can be supplied in the axial and / or circumferential direction take place in several stages.

To be able to cool the conical lower part easily, it is preferably surrounded by an air box from which air in the conical lower part enters.

It is further preferred that one in the air box Distance from the outer surface of the conical lower part arranged double jacket is provided. The annulus of the Double jacket is forced through by the cooling air.  

It also seems appropriate if at least that cylindrical top is bricked up. In addition to Brick lining can be an external one or multilayer insulation may be provided. The insulation can by an insulating material and / or by a be built through forced-flow cooling jacket, the Cooling jacket with respect to the insulating material inside or can be arranged outside.

To improve combustion, it may be useful that the outlet opening in diameter compared to the Outlet opening extended afterburner with side Exhaust gas outlet is connected downstream.

The combustion chamber of the reactor is used to burn off the coarse grain up to a limit grain diameter of the cyclone flow. Further turbulence takes place in the afterburner further burning of the undersize and that from the combustion chamber escaping CO streaks.

The afterburner can be a separate assembly on the Be arranged reactor. However, it is also possible in the Reactor retraction of the cross section of the combustion chamber make so that the firebox itself through the Moving into a main and an afterburner is divided.

The invention is also directed to a method for Operation of an axial cyclone combustion reactor for Burn solid fuels in one Three-phase flow field, especially in one above described axial cyclone combustion reactor.

To improve the burnout behavior is according to the invention provided next to the fuel in the reactor to introduce granular inert material.  

This can be done separately or together with the fuel respectively. Particularly good results are achieved if the inert material has essentially the same properties as the fuel has, in particular the same specific Weight. It is also appropriate if the inert material in terms of its grain size range on the Fuel grain is matched. It appears special important when building fluidization air into the reactor a fluidized bed is introduced.

The axial cyclone combustion reactor according to the invention is intended now based on the attached figures in different Embodiments are explained in more detail. Show it

Fig. 1 a reactor having a tangential supply of secondary air, and multi-stage tangential supply of fuel,

Fig. 2 shows a multi-stage tangential supply of primary air and a multi-stage tangential supply of secondary air in the cylindrical region, wherein the conical lower part is surrounded by an air box and

Fig. 3 shows a combustion reactor with tangential supply of primary air to the cone, a cooling jacket for the cone and a multi-stage supply of secondary air, and an afterburning chamber arranged on the ceiling of the combustion reactor.

In the combustion reactor 1 according to FIG. 1, both the conical lower part 2 and the cylindrical upper part 3 are delimited by a cylindrical lining. Under "brick lining" in the description and in the claims, both a brick made up of individual building blocks, a cast brick lining or a ceramic lining of the reactor interior, e.g. B. understood in the form of a sputtered membrane wall. Fuel is introduced into the reactor via tangential and inclined fuel feeds 4 a, 4 b and 4 c. About 2 to the cone opening towards lines 5 a and 5 b primary air is blown into the cone. 2 The cone 2 is connected at its lower end to an ash extraction line 6 . Sifter air can be blown into the ash line 6 via line 7 . The grain fraction, which can be drawn off via line 6 , is determined by the classifier air. Secondary air is fed tangentially to the cylindrical upper part 3 via a line 8 . Ignition gas can be introduced into the line 6 via a valve 9 , which gas is ignited via an electrical igniter 10 . The outlet 3 a assigned to the upper part 3 opens towards an angled exhaust duct 11 . The primary air inlets 5 a and 5 b are also arranged so that the primary air enters the cone 2 tangentially.

The angled guide of the channel 11 is of a reduced remaining twist in the outlet opening 3, so that takes place in the subsequent non-illustrated discharge pipe to transport the flyash mitabgezogenen substantially without swirl. Such an angled line also essentially prevents backflows into the reactor.

In the embodiment shown in FIG. 2, the reactor 12 is provided in its cylindrical upper part 13 with a lining 14 made of two layers 14 a and 14 b, while an air box 16 is assigned to the conical lower part 15 . The conical lower part 15 consists of a first cone 15 a adjoining the upper part 13 , a cylindrical intermediate section 15 b and a further cone 15 c. Such an arrangement is also considered to be essentially conical in the description and in the claims. The air box 16 is provided with a connecting piece 17 into which cooling air flows. This cooling air enters the interior of the reactor through tangentially aligned openings 18 in the cone section 15 a. Further, the cylindrical portion 15 are a plurality of b the air box 16 passes through primary air connection piece 19 a and b associated with 19 from which primary air entering tangentially into the interior of the reactor.

The supply of secondary air takes place via air feeds 20 a to 20 f arranged at a distance in the axial and in the circumferential direction. The fuel is introduced at 21 . Furthermore, an external cooling jacket 22 is supplied with cooling air, to which cooling air is supplied via connector 22 a and cooling air is drawn off from connector 22 b.

Here too, the coarse ash discharge 23 following the lower cone section 15 c is provided with a classifier air connection 24 .

In the reactor 25 shown in FIG. 3, the cylindrical upper part 26 is in turn provided with a lining 27 and the conical lower part 28 is arranged in an air box 29 , to which primary air is supplied via a connecting piece 30 , which is supplied via an air supply 31 into a straight cylindrical one Section 28 a of the conical lower part can enter tangentially. The purely conical section 28 b is provided with a spaced double jacket 28 b '. In the space between the conical section 28 b and double jacket 28 'occurs through a through the air box 29 through connection 32 cooling air, which also enters the air box at the lower end of the double jacket through an annular gap 33 .

The lines 30 and 32 are acted upon in a regulated and separate manner so that the temperature of the air introduced into the cone 28 can be regulated.

The lower end of the cylindrical section 28 a is assigned a nozzle base 34 through which air from the air box 29 axially enters the conical lower part 28 as fluidizing air. The withdrawal of ashes the nozzle floor by releasing and b to the cylindrical portion 28 opening toward the exhaust pipe 35 is provided.

The cylindrical section 26 is supplied tangentially via secondary air feeds 36 a and 36 b, while fuel is fed via line 37 . In the upper part of the reactor, a closable passage 38 is provided for a pilot burner which can be pushed into and retractable from the reactor space and is not shown in FIG. 3. Such a passage 38 is also provided in FIG. 2.

The outlet opening 39 is followed by an afterburning chamber 40 of larger diameter, possibly insulated according to the dash-dotted line, from which the exhaust gas is drawn off through a side exhaust pipe 41 . The afterburning chamber 40 extends the residence time of the fuel grains in the system and also at least partially removes the swirl from the flow.

As in the embodiment according to FIG. 2, the lining 27 can be constructed in several layers. The material for creating the cone can be high temperature resistant steel in all embodiments. In the embodiment according to FIG. 2, the cooling air used for cooling can under certain circumstances also be used as preheated primary and / or secondary air.

In addition to the fuel, inert material can be used for stabilization combustion and continuous cleaning all three embodiments are used. The Inert material should be essentially the same  Have properties like the fuel, e.g. B. specific weight, bulk density and / or grain.

Claims (15)

1. Axial cyclone combustion reactor for burning solid fuels in a three-phase flow field with an essentially conical lower part and a cylindrical upper part, an ash extraction opening at the lower end of the lower part and a central exhaust gas opening in the ceiling of the upper part, and at least one fuel supply and at least one air supply, characterized in that at least one tangential air supply ( 8 ; 20 a- 20 d; 36 a- 36 b) is provided. 2. Reactor according to claim 1, characterized in that at least one tangential air supply ( 8 ; 20 a- 20 d; 36 a- 36 b) on the cylindrical upper part ( 3 ; 13 ; 26 ) and at least one tangential air supply ( 5 a, 5 b; 19 a; 19 b; 31 ) is provided at the lower end of the conical lower part ( 2 ; 15 ; 28 ). 3. Reactor according to claim 1 or 2, characterized in that the air supply to the cylindrical upper part takes place in several stages via axially and / or circumferentially spaced air supplies ( 20 a- 20 f; 36 a- 36 b). 4. Reactor according to at least one of claims 1 to 3, characterized in that in addition to a tangential air supply at least one axial air supply ( 34 ), preferably in the form of a nozzle base for the supply of fluidizing air, is provided. 5. Reactor according to at least one of claims 1 to 4, characterized in that the fuel supply ( 4 a- 4 c; 21; 37 ) takes place in the cylindrical upper part ( 3 ; 13 ; 26 ). 6. Reactor according to at least one of claims 1 to 5, characterized in that the Fuel is supplied tangentially. 7. Reactor according to at least one of claims 1 to 6, characterized in that the Multi-stage fuel supply in axial and / or Circumferential direction. 8. Reactor according to at least one of claims 1 to 7, characterized in that the conical lower part ( 15 ; 28 ) is surrounded by an air box ( 16 ; 29 ) from which air enters the conical lower part. 9. Reactor according to at least one of claims 1 to 8, characterized in that in the air box ( 29 ) at a distance from the outer surface of the conical lower part ( 28 ) arranged double jacket ( 28 b ') is provided. 10. Reactor according to at least one of claims 1 to 9, characterized in that at least the cylindrical upper part ( 3 ; 13 ; 26 ) is bricked up. 11. Reactor according to at least one of claims 1 to 10, characterized in that  in addition to the brick lining an external one or multilayer insulation is provided. 12. Reactor according to at least one of claims 1 to 11, characterized in that the reactor has a forced-flow cooling jacket ( 22 ). 13. Reactor according to at least one of claims 1 to 12, characterized in that the outlet opening ( 39 ) is followed by an afterburner chamber ( 40 ) with a lateral flue gas outlet ( 41 ) which is enlarged in diameter compared to the outlet opening. 14. Method for operating an axial cyclone Combustion reactor for burning solid Fuels in a three-phase field, in particular in an axial cyclone combustion reactor at least one of claims 1 to 13, characterized characterized that in addition to the Fuel in the reactor is a granular inert material is introduced. 15. The method according to claim 14, characterized characterized in that inert material in essentially the same properties as the Has fuel.