DE4200575C2 - Axial cyclone combustion reactor and method for operating an 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 combustion of solid fuels in a three-phase field with an in essential conical lower part and a cylindrical upper part, one Ash extraction opening at the lower end of the lower part and a central one Exhaust vent in the top cover, as well as at least one Fuel supply and at least one air supply.

DD 2 57 280 A1 is a generic axial cyclone Combustion reactor known in the construction of the rotary flow field Combustion air axially into the lower end of the swirl generator conical lower part is introduced. The swirl generator presents a complicated one Component. Cooling of the conical lower part is not provided. At the lower end, fluidization air is additionally supplied by means of a frustoconical nozzle bottom and the fuel is the cylindrical top fed.

An axial cyclone combustion reactor is known from DD 2 34 585 A3, at which also the carrier air-fuel mixture also via a Swirl generator is fed to the lower end of the conical lower part.

DE 36 36 071 A1 describes a device for the combustion of inert coal dust is known, in which coal dust in a muffle is introduced, into which pre-twisted air is also introduced. For Twisting of the preheated combustion air is a separate one Swirl device provided.  

From Patents Abstracts of Japan, M-113, February 20, 1982 Vol. 61No. 29 - Air Heating furnace is known an arrangement for heating air in which for heating air over itself to the inside of the top of a External burners opening fuel and axial cyclones Combustion air can be supplied. Due to the cyclone arrangement ash removed from the combustion as a result of the cyclone effect and the dust-free smoke gases with the supplied warming be mixed.

DE 38 39 381 A1 describes an arrangement with a vertically rotating one Fluidized bed combustion known in a weakly conical Lower part of a large number of circular cascades Primary air nozzles are provided, which extend radially onto a central discharge shaft are aligned. Primary air in the tangential direction is generated via nozzles admitted. For the discharge of ash that is on the rusty floor air lances for applying short bursts of air required.

From DE 12 18 649 B, a melting chamber furnace is operational associated burners known to be tangential to one around the Combustion chamber center line imaginary circle are aligned so that on Form flames leading downwards in a helical path. A Air cooling of the conical lower part is not provided.

A pyrolysis or smoldering arrangement is known from DE 35 03 603 A1, where in the lower conical part of the reactor a pyrolysis and Smoldering chamber is provided. The conical part of the reactor is through cooled walls limited, but not by those supplied to the pyrolysis Air cooled.

It is the object of the present invention to provide an axial To create a combustion reactor of the generic type, in which none separate swirl generator for the construction of the three-phase field is required and in which cooling of the lower part is simple of the combustion reactor is reached.  

This object is achieved in that at least one tangential Air supply on the cylindrical upper part and at least one tangential Air supply is provided at the lower end of the conical lower part that the conical lower part is surrounded by an air box from which air into the conical lower part occurs, and that in the air box at a distance from the Flow through the outer surface of the conical lower part Double jacket is provided.

Due to the tangential air supply to the cylindrical top and bottom The end of the conical lower part is without a special swirl device desired three-phase flow field established. The feed at the bottom of the Conical lower part ensures that there is a rotating particle cloud mainly trained in the conical area.

Because a rotating particle cloud of higher density is predominantly conical Area and there is expected to be a higher heat generation due to the double jacket through which the supplied air flows cleverly achieved good cooling of the conical lower part. By the cooling, the air supplied to the combustion is preheated at the same time.

The air supply to the cylindrical upper part is preferably carried out in several stages Air supplies arranged axially and / or circumferentially at a distance. It is also appropriate that in addition to a tangential air supply at least one axial air supply, preferably in the form of a Nozzle bottom for the supply of fluidizing air is provided.

The fuel supply is preferably also tangential and can in axial and / or circumferential direction take place in several stages.

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

In order to improve the combustion, it may be appropriate that the Outlet opening one in diameter opposite the outlet opening extended afterburner with a side exhaust outlet.

The combustion chamber of the reactor is used to burn the coarse grain up to a limit grain diameter of the cyclone flow. In the afterburner further turbulence causes the undersize and the strands of CO emerging from the combustion chamber.

The afterburner can be a separate assembly on the reactor be arranged. However, it is also possible to draw into the reactor of the combustion chamber cross section so that the combustion chamber itself through the feed is divided into a main and an afterburner.

The invention is also directed to a method for operating a Axial cyclone combustion reactor for burning solid fuels in a three-phase flow field, in particular one described above Axial cyclone combustion reactor.

To improve the burnout behavior, the invention provides to introduce a granular inert material in addition to the fuel in the reactor.

This can be done separately or together with the fuel. Especially good results are obtained when the inert material is essentially has the same properties as the fuel, in particular the same specific weight. It is also useful if the inert material matched to the fuel grain with regard to its grain size range is. This appears particularly important when fluidizing air into the reactor is introduced to build up a fluidized bed.

An embodiment of the axial cyclone Combustion reactor with tangential air supply from primary air to Cone, a cooling jacket for the cone and a multi-stage supply of Secondary air, as well as one on the ceiling of the combustion reactor arranged afterburning chamber is now to be based on the attached figure in an embodiment are explained in more detail.  

The reactor 25 shown in the figure has a cylindrical upper part 26 with a lining 27 and a conical lower part 28 . Under "lining" is in the description and in the claims both a built of individual building blocks, a cast lining or a ceramic lining of the interior of the reactor, for. B. understood in the form of a powdered membrane wall. The lining 27 can be constructed in several layers. The conical lower part 28 is arranged in an air box 29 , which is supplied with primary air via a connecting piece 30 , which can enter tangentially via an air supply 31 into a straight cylindrical section 28 a of the conical lower part. 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 b '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 action of the lines 30 and 32 is regulated and separated, so that the temperature of the air introduced into the cone 28 can be regulated.

A nozzle base 34 is assigned to the lower end of the cyclindrical section 28 a, 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 supplied 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 the figure.

The outlet opening 39 of the upper part 26 of the reactor is followed by an afterburning chamber 40 of larger diameter, optionally isolated according to the dash-dotted line in the figure, 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. The material for creating the cone can be high temperature resistant steel in all embodiments.

An external cooling jacket to which cooling air is applied can be assigned to the cylindrical upper part 26 , to which cooling air is supplied via a connecting piece and from which cooling air is drawn off via a connecting piece. The cooling air used to cool the cylindrical upper part can, under certain circumstances, also be used as preheated primary and / or secondary air. In addition to the fuel, inert material can be used to stabilize the combustion and for continuous cleaning. The inert material should have essentially the same properties as the fuel, e.g. B. specific weight, bulk density and / or grain.

Claims (12)

1. Axial cyclone combustion reactor for burning solid fuels in a rotary flow field with a substantially 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 ( 36 a- 36 b) is provided on the cylindrical upper part ( 26 ) and at least one tangential air supply ( 31 ) on the lower end of the conical lower part ( 28 ), that the conical lower part ( 28 ) by one Air box ( 29 ) is surrounded, from which air enters the conical lower part and that in the air box ( 29 ) at a distance from the outer surface of the conical lower part ( 28 ) arranged through-flow double jacket ( 28 b ') is provided. 2. Reactor according to claim 1, characterized in that the air supply to the cylindrical upper part takes place in several stages via axially and / or circumferentially spaced air supplies ( 36 a- 36 b). 3. Reactor according to claim 1 or 2, 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. 4. Reactor according to at least one of claims 1 to 3, characterized in that the fuel supply ( 37 ) takes place in the cylindrical upper part ( 26 ). 5. Reactor according to at least one of claims 1 to 4, characterized in that the fuel supply takes place tangentially. 6. Reactor according to at least one of claims 1 to 5, characterized in that the fuel supply takes place in several stages in the axial and / or circumferential direction. 7. Reactor according to at least one of claims 1 to 6, characterized in that at least the cylindrical upper part ( 26 ) is bricked up. 8. Reactor according to at least one of claims 1 to 7, characterized in that in addition to the lining an external single or multi-layer insulation is provided. 9. Reactor according to at least one of claims 1 to 8, characterized in that the reactor has forced-flow cooling jacket. 10. Reactor according to at least one of claims 1 to 9, 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 with respect to the outlet opening. 11. Method for operating an axial cyclone combustion reactor for Burning solid fuels in a three-phase field, especially in an axial cyclone combustion reactor after at least one of claims 1 to 10, characterized in that in addition to the fuel in the A granular inert material is introduced into the reactor.   12. The method according to claim 11, characterized in that the inert material has essentially the same properties as the Has fuel.