DE3903936A1 - Reactor for allothermal coal gasification - Google Patents

Abstract

The invention relates to a reactor for allothermal coal gasification, with a pyrolysis zone and at least one gasification zone which follows this zone and in which exchange tubes are arranged in a suspended manner in parallel successive planes, which tubes debouch into common manifolds and distribution lines. The object of the invention is to dispense, entirely or in part, with a multiplicity of supply and discharge pipes passing through the reactor top, and with the associated sealing problems of the gas plenum above the banks of tubes in the individual reactor zones, and to facilitate the replacement of the meander- or hairpin-shaped exchange tubes of the banks of tubes of the reactor zones, another object being to provide for the possibility of blanking off individual tubes in a simple manner. To this end it is provided that there extends, across the pyrolysis zone(s) and the gasifier zone(s) (I, II, III) for all exchanger tubes (16-19), at least one common manifold (12) which has at least one heating gas inlet and a heating gas outlet (23, 24) and whose cross-section is subdivided into longitudinal chambers (A-K; R-U). <IMAGE>

Description

The invention relates to a reactor for allothermic Coal gasification with the characteristics of the generic term of Claim 1.

Such reactors are known, for. B. by the DE-OS 24 23 951, 29 10 437 and 36 35 215. With these as well as other known reactors is their interior into a pyrolysis zone and usually two gasification zones assigned. Protrude into each of these zones Reactor ceiling one or more heating gas supply and -discharge pipes that run in parallel to the longitudinal axis of the Reactor-running header and distributor pipes open, where meandering or hairpin-shaped heat exchanger tubes hang. This results in a large number of lines passing through the reactor ceiling; the multitude of the feed and discharge pipes to the collecting and Distribution pipes conditional in the event of removal of the Pipe register in the zones mentioned a diverse  Cut the supply and discharge pipes push through the reactor ceiling. The so-called blind setting single meandering or hairpin-shaped Heat exchanger tubes are not possible.

The object of the invention is therefore a reactor to create a generic concept in which, on the one hand, those Large number of feed lines passing through the reactor ceiling and drain pipes and the related Sealing problems in the gas collection space above the Pipe register reduced in the individual reactor zones is, on the other hand, the replacement of the meandering or hairpin - shaped exchanger tubes of the tube register Reactor zones is made easier, as is blind setting individual pipes in a very simple manner should be able to.

To achieve this object, the invention provides one Generic reactor the features of the main claim in front. The features of the subclaims serve Improvement and further development of the characteristics of the Main claim. -

The reactor of the invention has the advantage that the Reactor ceiling no openings for heating gas supply and Has heating gas discharge pipes and in so far the  Sealing problems of the reactor ceiling compared to known ones Embodiments are omitted. - Is the exchange of Pipe register required in the zones, so it only needs opening the top of the cylindrical reactor and the axial pulling out of the tube register with the Collecting and distribution pipes from the reactor. The The pipe register is inserted in the same way Wise.

Another advantage of the reactor according to the invention consists in the fact that the collection and manifolds an interior inspection as well as a advantageous connection and detachment of the ends of the meandering and allow hairpin-shaped heat exchanger tubes. The Welding and loosening of these ends will not affected by neighboring pipes, rather it can Welding and loosening the pipe ends on the inside of the Collecting and distribution pipes using the full cross section of the respective longitudinal chamber made will. The same applies to blind setting Heat exchanger tubes on their in the collection and Manifold ends. -

The arrangement and training of the meandering or Hairpin shaped heat exchanger tubes can be used in conventional Way with respect to the vertical longitudinal median plane of the  Reactor be of such a kind that on each side of the Longitudinal central plane of the reactor, a common collection and manifold with meandering or hairpin-shaped heat exchanger tubes is arranged.

In the drawing, embodiments of the shown reactor according to the invention, namely shows

Fig. 1 shows a longitudinal section through the reactor,

Fig. 2 shows the connection of a meandering or hairpin-shaped heat exchanger tube with the inside of the longitudinal chamber of a collection and distribution pipe,

Fig. 3 shows a cross section through the reactor with the partition of the collecting and distributing pipes in the longitudinal chambers,

Fig. 4-6 is a cross section along the lines IV-IV, VV and VI-VI of Fig. 1 through the interior of a collection and distribution pipe,

Fig. 7 shows a schematic representation of the hot gas, through the successive longitudinal chambers of a collection and distribution pipe according to a first embodiment of

Fig. 8 shows the division of the heating gas pipe according to a second embodiment and

Fig. 9 is a schematic longitudinal section through the collection and distribution pipe according to the first embodiment shown in FIGS. 4-6.

The cylindrical reactor R has the jacket 1 , which reveals an upper side 2 and an underside 3 and which has a detachable end cover 4 . -

The interior J of the reactor is divided in the longitudinal direction into the pyrolysis zone I and the gasification zones II, III. Through the underside of the pyrolysis zone and the two gasification zones, steam feed lines 6 , 7 , 8 protrude to manifolds 9 of zones I to III. Coal dust supply pipes 10 are arranged on both sides of the steam feed lines 6 of the pyrolysis zone I.

In the upper section of the reactor interior, on both sides of the vertical longitudinal center plane L of the reactor R ( FIG. 3), a collection and distribution pipe 12 extends from the end 13 of the reactor to the end 14 of the gasification zone III, the meaning and design of which is described below. - As a result of the similar symmetrical design of the collecting and distribution pipes 12 on both sides of the level L, it is sufficient to show and describe a pipe 12 and the meandering exchanger pipes 16 to 19 attached to it. These exchanger tubes are arranged in pairs (pair 16 , 17 as an outer pair of tubes, the pair 18 , 19 as an inner pair of tubes) ( Fig. 3). In the example shown, eight exchanger tubes form a tube plane perpendicular to the longitudinal axis of the reactor, a plurality of such tube planes forming a tube register X, Y, Z of each of the zones II-IIII. The tube registers X and Y of the pyrolysis zone I and the first gasification zone II are separated from one another by a partition 5 . The ash discharge 15 is provided below the gas outlet 15 a .

The ends 16 a - 19 a of the exchanger tubes 16-19 protrude slightly, as shown in FIG. 2, into one of the longitudinal chambers of the header and distributor tubes 12, which are described in more detail below. Here, the edge region 16 b - 19 b of the exchanger tubes is connected by a weld 20 to the inside 21 of the corresponding longitudinal chamber of the distributor or header tube 12 . The pipes 16-19 are connected and disconnected from the inside of the longitudinal chambers of the pipe 12 , and the opening 22 of the pipes 16-19 can also be blinded from this inside of the longitudinal chamber of the pipe 12 . The two mutually parallel collecting and distribution pipes 12 have two common heating gas supply lines 23 and a likewise common discharge line 24 . ( Fig. 1-3).

The collecting and distribution pipes 12 are divided into sections 25 , 26 and 27 , which correspond to the pipe registers X , Y , Z , section 25 being assigned to the pyrolysis zone I, section 26 to the first gasification zone II and third section 27 to the gasification zone III is. These sections have different cross-sectional subdivisions with the same internal and external cross-sections. The two collecting and distributing pipes 12 are such that it is sufficient to respectively 25 on both sides of the center plane L in this division is equal to one of these tubes and the portions - 27 describe a first embodiment.

The section 25 shown in Fig. 4 of the collecting and distributing tube 12 has two symmetrically to the longitudinal center plane M of the tube 12 are arranged similar to the longitudinal chambers A. An interior space extends between these elliptical chambers and is divided into a longitudinal chamber B , a further chamber C and finally a chamber D. The section 26 of the collecting and distributor pipes 12 at the level of the gasification zone II shown in FIG. 5 has the two longitudinal chambers E which are likewise arranged elliptically and preferably equal to the longitudinal chambers A and which are arranged laterally to the longitudinal center plane M of the pipe. In this case, however, in section 26 the space between the two longitudinal chambers E is divided by two longitudinal chambers G and F. - Finally, the section 27 of the collecting and distribution pipes 12 in the gasification zone III shown in FIG. 6 is only divided into a lateral longitudinal chamber H on both sides of the vertical central plane M , while the space between the longitudinal chambers H forms a single central longitudinal chamber K.

In order to supply fresh heating gas to the individual sections of the collecting and distribution pipes, or to remove cooled heating gas from these sections, guide orifices or plates 30, 31 are provided at the transitions between sections 25 , 26 and 27 , through which the heating gas follows described guide in the manifolds and manifolds, although only two common heating gas supply lines 23 and a common heating gas discharge line 24 is provided. In Fig. 7 is the scheme of the heating gas to the first embodiment in the individual sections 25, 26 that is shown, 27 at the level of the zones II IIII, in the arrayed in these zones registers X, Y, Z. The two chambers A of the collection and distribution pipes 12 give their gas into the heat exchanger pipes 16-19 of the register X , the heating gas being collected in the longitudinal chamber B. The chambers C and D are supplied with fresh heating gas from the feed lines 23 , at the end of the longitudinal chamber C this fresh heating gas is transferred (symbolically via line 100 ) to the longitudinal chamber F.

From the longitudinal chamber F , the heating gas enters the chambers E in the register Y via the heat exchanger tubes 16-19 .

Fresh heating gas is also introduced into the longitudinal chamber D and is transferred to the longitudinal chamber G at the end of the longitudinal chamber D , which is symbolically represented by the dashed line 101 . At the end of the longitudinal chamber G of the collecting and distribution pipes 12 of the register Y , this fresh heating gas enters the middle longitudinal chamber K of the last register Z (line 102 ) and from there via the collecting pipes 16-19 of the gasification zone III to the two lateral longitudinal chambers H led. The derived heating gas is conducted from the chambers H to the rear end (the end facing the reactor end 13 ) of the longitudinal chambers E of the register Y , which is symbolized by the line 103 . From the front end of these chambers E , the heating gas cooled in the gasifier zones 2 and 3 reaches the longitudinal chambers A of the register X of the pyrolysis zone I, which is symbolized by the line 104 . Heating gas is withdrawn via the line 24 from the chambers A.

FIG. 9 shows a cross section through the tube registers of zones I, II, II, from which the supply of the fresh heating gas from the lines 23 into the longitudinal chambers C and D and the removal of the cooled heating gas via the line 24 is illustrated.

In the second embodiment according to FIG. 8, the collecting and distribution pipes 12 are sealed off from one another at the level of the dividing wall 5 , ie at the end of the pyrolysis zone and the register X , so that the register X is assigned a heating gas supply and discharge, while at the rear end 14 of the reactor an inlet and outlet line for the registers Y and Z of the gasification zones II and III is provided. The register X is fed into the longitudinal chamber Q fresh heating gas, which is passed via the heat exchanger tubes 16 , 17 and 18 , 19 to the longitudinal chamber P , where it is drawn off via the line 24 .

Line F in FIG. 8 symbolizes the separation between the two named pipe sections of the pipes 12 in the pyrolysis zone I and the two gasification zones II, II. Here, the fresh heating gas at the end 14 of the reactor becomes the register Z (ie the rear of the two registers) Y and Z ) fed to the chamber R , from where it reaches the chambers S via the heat exchanger tubes 16-19 .

At the same time, fresh gas is also introduced at the rear end of the longitudinal chamber T , which fresh gas is introduced into the central longitudinal chamber U of the register Y at the front end of this chamber (cf. line 110 ). From this longitudinal chamber, the heating gas passes via the pipes 16 , 17 and 18 , 19 into the lateral longitudinal chambers V , from which it is transferred to the outlet longitudinal chamber S (see line 111 ), into which the cooled heating gas from the longitudinal chamber R also passes and from where the discharge takes place via the discharge line 24 from the chambers S.

The heating gas supply lines 23 as well as the heating gas discharge line 24 are arranged in the embodiment according to FIG. 1 at the end 12 a of the collecting and distribution pipes 12 which protrude from the detachable end cover 4 . If this is opened, the entire pipe register with the lines 12 can be pulled axially out of the reactor after removal of the partition 5 . - The lines 12 are based on bearings, not shown, which allow the axial displacement of the pipes.

Claims (10)

1. Reactor for allothermic coal gasification with a pyrolysis zone and at least one gasification zone following this zone, in which exchanger tubes are suspended in parallel, successive levels, which open into common collecting and distribution lines, characterized in that the pyrolysis and the gasification zone or zones (I, II, III) for all exchanger tubes ( 16-19 ) extends at least one common collector and distributor tube ( 12 ) with at least one heating gas supply and discharge line ( 23, 24 ), the cross section of which in longitudinal chambers (AK ; RU) is divided. 2. Reactor according to claim 1, characterized in that the longitudinal chambers (AK; RU) in the successive zones (I, II, III) have different cross sections. 3. Reactor according to claim 1 and 2, in which the heating gas is supplied at one end of the reactor, characterized in that the longitudinal chamber ( B ) forming the section of the heating gas manifold with the longitudinal chamber ( A ) forming the distributor line of the first pipe section in the pyrolysis zone (I) is connected, into which the heating gas flowing back from the gasification zones (II) and (III) is introduced. 4. Reactor according to claim 1 and one of claims 2 or 3, with a pyrolysis zone and two gasification zones, characterized in that the cross section of the common collecting and distribution pipe in the pyrolysis zone (I) has two feed chambers ( C , D ) to the following distribution chambers ( F , K ) and a distribution chamber ( A ) and a collecting chamber ( B ) for the exchanger tubes ( 16-19 ) of the pyrolysis zone (I). 5. Reactor according to claim 1 and 2 with two ends at both ends of the longitudinal chambers, characterized in that the longitudinal chambers ( P , Q ) at the end of the pyrolysis zone (I) and the longitudinal chambers ( U , V ) at the beginning of the gasification zone (II) from each other are separated. 6. Reactor according to claim 2 to 5, characterized in that the longitudinal and the manifolds ( 12 ) representing the longitudinal chambers of the lateral or upper (A, E, H, P, S, V) and the lower or middle (B , F, K, Q, R, U) form section of the cross section of the tubes ( 12 ). 7. Reactor according to claim 6, characterized in that the feed lines to the longitudinal chambers of the gasification zone or zones (II, III) representing longitudinal chambers ( D , C , G , T ) are arranged in the upper section of the collecting and distribution pipes ( 12 ). 8. Reactor according to claim 1 and one of claims 2 to 7, characterized in that the ends of the exchanger tubes ( 16-19 ) in the inner wall of the successive longitudinal chambers ( A , B , E , F , H , K , P , Q , R , S , U , V) are attached, from which or into which the heating gas exits or enters in different flow directions. 9. Reactor according to claim 1 and one of claims 2 to 8, characterized in that the collecting and distribution pipes ( 12 ) protrude from a releasable end cover ( 4 ) and there the Heizgaszuführungs- ( 23 ) and -ausleitungen ( 24 ) in the Pipes ( 12 ) open out. 10. Reactor according to one or more of claims 1-9, characterized in that at least the cross section of the longitudinal chambers ( A , B , E , F , H , K , P , Q , R , S , U , V ) for an inspection and is dimensioned for work on the ends of at least the exchanger tubes ( 16-19 ).