EP2931850A1

EP2931850A1 - Method for heating a high temperature winkler gasifier

Info

Publication number: EP2931850A1
Application number: EP13805306.1A
Authority: EP
Inventors: Domenico Pavone; Dobrin Toporov; Ralf Abraham
Original assignee: ThyssenKrupp Industrial Solutions AG
Current assignee: ThyssenKrupp Industrial Solutions AG
Priority date: 2012-12-12
Filing date: 2013-11-29
Publication date: 2015-10-21
Also published as: US20150322356A1; CA2894573A1; DE102012112182A1; CN104981535A; BR112015013735A2; AU2013357639A1; TW201433633A; WO2014090599A1; RU2015125173A

Abstract

The invention relates to a method for heating a high temperature Winkler gasifier when starting up the gasifier using at least one burner for heating, wherein a cyclone with a return line for returning particles deposited in the cyclone to the fluidized bed in the lower region of the gasifier is associated with the gasifier head. The method simplifies the heating of the high temperature Winkler gasifier (HTW) and is substantially independent of the overall size of the gasifier. This is achieved by using at least one burner installed in the head region of the gasifier and acting downwards into the gasifier interior, wherein a gas flow is generated in the reverse direction through the return line of the cyclone.

Description

Method for heating a high-temperature Winkler carburetor

The invention is directed to a method for heating a high-temperature Winkler carburetor when starting the carburetor with the use of at least one burner serving the heating, wherein the cyclone head associated with cyclone return line of the particles deposited in the cyclone in the fluidized bed in the lower region of the carburetor as well as on a suitably equipped high-temperature Winkler carburetor.

In order to operate such a carburetor, the system carburetor / cyclone / return line must first be heated. In this case, the refractory masonry is brought to the permissible temperature gradient corresponding operating temperature, wherein the introduced into the masonry heat storage is used to bring a fluidized bed material to the temperature necessary for the ignition process. From a system operated in practice, it is known to use for heating, for example, three identical gas burners with a power of 0.7 MW, which are mounted in the lower part of the carburetor for heating. It is necessary to mount the gas burner at standstill of the carburetor and dismantle after completion of the heating before the actual start of the carburetor again, the necessary carburetor nozzles must be closed before starting.

A particular disadvantage of this procedure is that the finished heated carburetor can not be ignited immediately, so that during the dismantling of the burner, for example, at least one hour lasting. ert, considerable heat losses occur. In addition, the people involved in the dismantling are exposed to a corresponding heat, so that protective equipment for the people are necessary.

As it is endeavored to operate plants with high capacity, for example to provide a throughput of 160 t / h hard coal, carburetor diameters of 3.5 to 4 m with a carburetor height of about 30 m are necessary. Such a carburetor would require at least four Aufheizbrenner, these theoretically necessary four Aufheizbrenner would have to be installed in the cone of the carburetor, but such a requirement is not enforceable in practice.

EP 0 500 517 A1 describes a method for starting up a plant for the production of pig iron, wherein there the plant parts are also preheated.

The object of the present invention is to provide a procedure which simplifies the heating of a high-temperature Winkler carburetor (HTW) and makes it substantially independent of the size of the carburettor.

With a method of the type described, this object is achieved according to the invention in that at least one installed in the head of the carburetor, is used in the carburetor interior downward burner, wherein a gas flow is generated by the return line of the cyclone in the reverse direction.

With this procedure, i. E. with the onset of a burner in the carburetor head and a reversal of the prevailing operating conditions flow conditions in the carburetor, an optimal heating of the carburetor is achieved with comparatively simple means, with assembly and disassembly of the burner is unnecessary only for the heating process. Embodiments of the method according to the invention will become apparent from the other dependent claims, it can be provided that the burner is operated stoichiometrically or substoichiometrically.

A further refinement is that, in the case of substoichiometric operation of the burner in the lower region of the carburettor, required combustion air is additionally injected through different nozzle planes.

This procedure makes use of the fact that different nozzle levels are provided anyway in the carburetors, which take over different functions during normal operation of the carburetor and can be used here for introducing necessary combustion air.

A further embodiment of the invention is that in the supply line from the gasifier to Abscheidezyklon a flap is operated temperature-controlled, d .h. In particular, during the starting process, the supply line to the separation cyclone can be closed to allow a corresponding backward flow.

In a further embodiment, it can be procedurally provided that when the required starting temperature of the carburetor is reached, the burner (s) provided in the head of the carburettor are reduced to a range of lower particle concentration.

It can also be provided that the burners are supplied with coolant for preventing particle melt phases, be it that the coolant is passed directly through the burner head or indirect cooling takes place.

To solve the problem mentioned above, the invention also provides a high-temperature Winkler carburetor with a cyclone or Zentrifugalab- separator, which is assigned to the carburettor head and with a solids return line from the cyclone into the lower region of the carburetor, which is characterized in that at least one burner acting in the carburetor head is provided in the carburetor head.

As stated above, it is expedient to functionally separate the cyclone from the carburator head during startup. For this purpose, the invention provides that a shut-off or throttle valve is provided in the connecting line between the carburetor head and the cyclone.

In the not previously published application of the applicant DE

10 2012 004 590 solutions are shown that describe the flow in the connecting line between the carburettor head and the cyclone.

In an embodiment, it is provided that for positioning of the burner during the carburetor operation in areas of lower particle concentrations of the burner or the burner is axially movable or are. Appropriately, it can also be the case that coolants for preventing particle melt phases can be conducted through the burner.

The invention is not limited to a particular type of fuel. The burner (s) required for start-up may be operable with gaseous, liquid or solid fuels, such as natural gas, oil or corresponding carbonaceous powdered material, to name just a few examples.

The invention is explained in more detail below with reference to the drawings, for example. This shows in the single figure a schematic representation of a high-temperature Winkler carburetor in section.

The generally designated 1 high-temperature carburetor is shown in simplified form in the single figure in section. The carburetor body made of refractory Masonry, designated 2, has in the lower conical region 2a on the necessary for the fluidized bed training facilities. In the head region 2b a cyclone 3 is positioned, which is provided in operation via a controllable by a flap 4 supply 5, wherein the separated solid particles are fed back via a return line 6 of the lower fluidized bed in the region 2a of the carburetor.

For starting according to the invention, the high-temperature Winkler carburetor with at least one in the head, designated 2b, heating burner 7, this burner 7 via corresponding, not shown devices according to double arrow 8 is retracted into the carburetor and at least during normal operation as far as can be pulled out, that the burner nozzle is not subject to any contamination or additives. When starting the hot combustion products are guided through the reactor according to the arrows 9. After reaching the necessary starting temperature, the gas flow is formed substantially opposite, which takes place when starting and opening the high temperature flap 4.

In order to allow additional influence of the fluidized bed and the reaction in the gasifier, air inlet nozzles are provided in the conical region 2a and in the transition region of the fluidized bed, these nozzles are designated 10.

In the head area, the arrow 11 indicates the fuel supply and the arrow 12 indicates the air supply.

Of course, the described embodiment of the invention is still to be modified in many ways, without departing from the spirit. Thus, as already indicated above, more than one burner can be provided, the removal or retraction of the burner can possibly also be done horizontally instead of vertically u. like. more. List of reference numbers:

1 high temperature Winkler carburetor

2 masonry

2a lower conical area

2b head area

3 cyclone

4 flap

5 feed line

6 return line

7 head heating torch

8 double-headed arrow

9 arrow

10 nozzles

11 arrow

12 arrow

Claims

claims:

1. A method for heating a high temperature Winkler carburetor when starting the carburetor with the use of at least one burner serving the heating, wherein the carburetor head is associated with a cyclone return line of the cyclone deposited particles in the fluidized bed in the lower region of the carburetor,

characterized,

in that at least one burner installed in the head region of the carburettor and operating downward in the carburetor interior is used, a gas flow being generated in the reverse direction through the return line of the cyclone

2. The method according to claim 1,

characterized,

that the burner is operated stoichiometrically or substoichiometrically.

3. The method according to claim 2,

characterized,

that at substoichiometric operation of the burner in the lower part of the carburetor combustion air required is additionally injected through different nozzle levels.

4. The method according to any one of the preceding claims,

characterized,

that in the supply line from the carburetor to Abscheidezyklon a flap Tempe raturgeregelt operated.

5. The method according to any one of the preceding claims,

characterized,

that when the required starting temperature of the carburettor is reached, the burner or burner provided in the head of the carburetor is returned to a region of lower particle concentration.

6. The method according to any one of the preceding claims,

characterized,

that the burners are supplied with coolant for preventing particle melting phases.

7. High-temperature Winkler carburettor (1) with a cyclone (3) or centrifugal separator associated with the carburettor head (2b) and with a solids return line (6) from the cyclone (3) to the lower part (2a) of the carburetor,

characterized,

in that at least one burner (7) acting in the carburetor head (7) is provided in the carburettor head (2b).

8. high-temperature Winkler carburetor according to claim 7,

characterized,

a shut-off or throttle flap (4) is provided in the connecting line (5) between the carburettor head (2b) and the cyclone (3).

9. high temperature Winkler carburettor according to claim 7 or 8,

characterized,

that for positioning the burner (7) during the carburetor operation in areas of lower particle concentrations of the burner or the burner is axially movable or are (arrow 8).

10. High-temperature Winkler carburettor according to claim 7 or one of the following,

characterized,

in that coolant for preventing particle melting phases can be conducted through the burner (7).