The invention relates to a gasification reactor for the production of crude gas containing CO or H2, of the type indicated in the preamble of claim 1.
Such a gasification reactor is known, for example, from WO 2009/036985 A1 by the applicant, whereby a wealth of prior art is cited in this document, such as U.S. Pat. No. 4,474,584, for example, which particularly addresses the cooling of hot synthesis gas.
In particular, the invention concerns itself with problems that occur in such reactors, whereby the invention is not restricted to the gasification reactor that is specifically addressed here; it is also directed at apparatuses in which similar problems, described in greater detail below, can occur.
Such an apparatus must be suitable for allowing methods of pressure gasification/burning of finely distributed fuels, which includes the partial oxidation of the fuels coal dust, finely distributed biomass, oil, tars, or the like in a reactor. This also includes the separate or joint withdrawal of slag or fly ash, and generated synthesis gas or flue gas. Cooling of the reaction products (gas and slag/fly ash) must be made possible, for example by spray quenching, gas quenching, radiation quenching, convective heating surfaces, or the like, depending on the type of method used, whereby finally, attention also has to be directed toward discharge of the reaction products from the pressure container.
In the document WO 2009/036985 A1, as mentioned above, a spin flow is generated, in order to be able to completely react even coarser particles, and to protect critical regions of the heating surfaces from an overly high heat current density. This is brought about by means of a burner angle of 1 to 20° in the horizontal plane. The spin that is produced must be removed from the flow again after it leaves the reactor, so that the hot, sticky slag particles are not accelerated toward the unprotected heating surfaces that protect the pressure container, and cause caking or damage there.
Corresponding spin brakes are described, for example, in DE 10 2009 005 464.2.
It is the task of the present invention to create a solution with which a strand formation of the outflowing ash can be achieved, for one thing, and, for another, a further slag drip edge that ensures optimal slag outflow is made available.
This task is accomplished, according to the invention, in the case of a gasification reactor of the type indicated initially, in that the wall that carries the bulkheads makes a transition, below the bulkheads, into a cylinder wall that is reduced in diameter, by way of a step having a corrugated surface.
By means of the corrugated surface and low points underneath the bulkheads, the result is achieved that the slag can flow out of the corrugation valleys in strands, in targeted manner, and thus no closed slag film is formed.
In addition, it is provided that the cylinder wall, which is reduced in diameter, is enclosed by a further cylindrical wall, which is enlarged in diameter, which wall forms a second slag drip edge at its end, in the direction of gravity, whereby it is provided, in particular, that the further cylindrical wall is disposed to be adjustable in its vertical position, with reference to the first drip edge.
When “adjustability” is mentioned in this connection, this relates to an optical setting relative to the drip edge according to the given conditions, which are determined by operation. After optimization, no further adjustability is required, particularly not during operation of the reactor.
The invention also provides that the cylindrical second drip edge is enclosed by a further cylindrical wall that is enlarged in diameter, which wall encloses at least part of a gas transition region. In practice, this outer cylindrical wall delimits the transition region into the quench space or quench channel.
The invention furthermore also provides that at least one bulkhead of the spin brake is equipped with a device for measuring the heat flow density.
In a possible embodiment, the invention also provides that the second cylindrical wall and the further cylindrical wall are provided with a smooth, flat, corrosion-resistant surface, for example by means of using super-Ω pipes, whereby the bulkheads that reduce spin, the corrugated transition surface, and the cylinder wall that makes the first drip edge available are configured as a standard pipe/crosspiece/pipe wall with stud welding and tamping.
Further details, features and advantages of the invention are evident from the following description and the drawing. This shows, in:
The gasification reactor shown in
Following the transition region 8 is a quench chamber or quench channel 11, followed by a slag collection container 12 in a water bath 13.
As is evident from
The transition channel 7, including the configurations of the transition region between the wall 19 and the wall 18 that are used for strand formation of the slag, is enclosed by another cylindrical wall that stands in connection, in gas-tight manner, with the cylindrical wall 21 that encloses the transition chamber 8, by way of the wall disk 20 that is shown at a slant in
The special feature lies in the fact, for one thing, that the cylindrical wall 19 that encloses the transition channel 7 makes available the further, second drip edge, identified as 10. Also, according to the invention, the system of cylindrical wall 19 and wall disk 20 is adjustable in height, as indicated with the double arrow 22. The sealing regions or transition regions of the corresponding pipes, through which coolant flows, and which allow such adjustability, are indicated only schematically in
In
Of course, the exemplary embodiment of the invention that is described can be modified in many ways, without departing from the basic idea. For example, the corrugations 16 that are shown at an angle according to
Number | Date | Country | Kind |
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10 2009 034 870.0 | Jul 2009 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP10/04337 | 7/16/2010 | WO | 00 | 4/3/2012 |