WO2013007341A1 - Apparatus and method for introducing renewable fuels into the region of the radiation boiler wall of gasification reactors - Google Patents

Abstract

The invention relates to an apparatus for introducing renewable fuels into the region of the radiation boiler wall (9) of coal gasification reactors, which consist of a reaction chamber, with burners (6) arranged in the reaction chamber (2), and a cooling chamber (3), and the cooling chamber is provided with a radiation boiler wall (9) for cooling the liquid slag, wherein according to the invention the annular part of the cooling chamber in which the radiation boiler wall is arranged is provided with burners (11), which lead through the radiation boiler wall into the cooling chamber and through which a renewable fuel can be introduced into the cooling chamber. This apparatus allows renewable fuel to be introduced through a radiation boiler wall into the cooling chamber, which is located underneath the reaction chamber, and so the heat content of the hot synthesis gas can also be utilized in the cooling chamber for the secondary gasification of renewable fuel. The invention also relates to a method for introducing renewable fuel through the radiation boiler wall of the cooling chamber of a coal gasification reactor and to the use of the synthesis gas produced by the method.

Description

 Apparatus and method for introducing renewable fuels into the region of the radiation vessel wall of gasification reactors

The invention relates to a device for introducing renewable fuels in the region of the radiation boiler wall of gasification reactors, which consist of a reaction space with arranged in the reaction chamber burners and a cooling space, and the Abkühlraum equipped with a Strahlungskesselwand for cooling and solidifying the liquid slag is, according to the invention, the part of the cooling room, in which the radiation boiler wall is arranged, is equipped with burners which hindurchfüh- ren through the radiation boiler wall into the cooling space, through which a renewable fuel tangentially to the jacket vessel of the cooling space in the cooling space can be introduced. In this way, the heat of enthalpy of the hot synthesis gas can be better used in the cooling room for the gasification of renewable fuel. The invention also relates to a process for the introduction of renewable fuel through the radiation boiler wall tangential to the reactor wall in the cooling space of a coal gasification reactor and the use of the synthesis gas produced by the process.

Coal gasification reactors consist in most embodiments of a reaction chamber in which the actual coal gasification reaction is carried out, a cooling space in which the synthesis gas is cooled by mixing with a cooler foreign medium, and a slag collecting vessel, which is filled with water and in which cooled slag is introduced. The reaction space contains burners, with which a carbonaceous fuel is introduced in a mixture with an oxygen-containing gas, so that synthesis gas is produced in an entrainment gasification reaction. In most embodiments, the cooling space is arranged vertically outwardly leading directly below the reaction space, so that the synthesis gas containing liquefied slag and ash, first comes with the ash and slag in the cooling room. There, the hot synthesis gas is mixed with a cooler foreign medium, so that this cools and most of the ash and slag is deposited. The entire device is suspended in a pressure-tight jacketed vessel to allow for the high pressures and temperatures at which the reaction is carried out. The separated slag and the ash are transferred from the cooling space in the Schlackesammeigefäß, which is located below the Abkühlraumes. This contains water in most slag catching embodiments. There it is disposed of via a pressure lock from the reaction vessel. The synthesis gas is fed via a side nozzle for further treatment and use. The actual coal gasification reaction typically takes place at temperatures in excess of 1400 to 1500 ° C and at pressures of 0.5 to 8 MPa. After leaving the reaction chamber, the synthesis gas has a temperature of more than 1400 - 1500 ° C, after leaving the cooling space about 900 ° C, and after mixing with the cooler foreign medium still a temperature of 200 to 300 ° C. At this temperature, the synthesis gas from the jacket vessel is carried out with the reactor.

DE 102008012734 A1 describes a method and a device according to the prior art for the production of synthesis gas by a coal gasification reaction, wherein the synthesis gas generated is generated in a first, arranged in the top of the reactor reaction space, in the upper region of the starting materials are supplied , And on the side walls of liquid slag is deposited, which can run freely without the surface of this slag solidifies, and at the bottom there is an opening with a drip edge, from which both the recovered synthesis gas is withdrawn down as well as the liquid draining slag can drain off, and at the bottom of the opening adjoins a second space, which is designed as a cooling room, and the second space is bounded by a water film, with the bottom of the second room is followed by a third room in which by supplying water in the synthesis gas a cooling is made, and at the bottom of the third room connects a water bath, which is a slag collecting vessel, and below or laterally of the third space, but above the water bath, the generated and cooled synthesis gas is withdrawn from the pressure vessel. The second space below the reaction space is designed as a cooling room and contains a laterally delimiting water film to prevent deposits. Since the aim is to obtain a slag and ash-free as possible synthesis gas for further use, there are embodiments for coal gasification reactors in which the cooling space is equipped with a so-called radiation boiler wall. These act as cooling plates and are arranged on the lateral walls of the gasification reactor. This procedure simultaneously protects the reaction vessel. The effluent from the reaction space synthesis gas is this with a swirl, so that it flows with a twist in the cooling space and thereby comes into contact with the cooler radiant boiler walls. The slag solidifies and falls by gravity or by the flow of gas into the Schlackesammeigefäß. DE 102005041930 A1 describes a process for the gasification of solid fuels in the air stream with solid fuels with a free oxygen-containing oxidant by partial oxidation, wherein a fuel dust is fed to a pneumatic metering system, and the fuel dust passes through a bunker in at least one pressure lock , and charged with a condensate-free gas is fed to a metering, in the lower part of an inert gas is formed, so that a fluidized bed is formed, which passes through delivery pipes to the burner of a reactor, the reactor via a delivery pipe together with a free oxygen-containing oxidant in the reaction space with the cooling screen is subjected to a partial oxidation, wherein the ash of the fuel is melted and transferred together with the hot gasification gas via the discharge device in the quench of the quench cooler, and the quenched steam water saturated te raw gas for cleaning entrained fine dust is subjected to a crude gas scrubbing or mechanical dust separation. In the quench cooler, one or more nozzle rings are arranged, via which the required quench water is injected, wherein the nozzles terminate flush with an inner wear jacket, which is arranged annularly on the metal of the reactor pressure jacket for protecting the reactor pressure jacket.

[0008] DE 102005041931 A1 describes a process for the gasification of solid fuels in flowing stream with an oxidant containing free oxygen by partial oxidation, comprising the steps of pneumatic metering for combustible dust, gasification reaction in a reactor with cooled reactor space contour, partial quenching, cooling, Rohgaswäsche and partial condensation, wherein a fuel dust is fed to a pneumatic metering system, and wherein the fuel dust passes through a bunker in at least one pressure lock, and supplied with a condensate-free gas is fed to a metering, in the lower part of an inert gas is introduced, so that a fluidized bed is formed, which passes through delivery pipes to the burner of a reactor, and wherein the fed via a delivery pipe to the reactor fuel dust together with a free oxygen-containing oxidant in the reaction chamber with cooling screen of a partial oxidation is educated, and wherein the ash of the fuel is melted and transferred together with the hot combustion gas via the discharge device in the quench of the quench cooler and a Part quenching is subjected, and cooled the partially quenched crude gas in a waste heat boiler, and then subjected to a purification and further processing.

In one embodiment of the invention, the space of the quench cooler opens directly into a waste heat boiler, are arranged in the tubes for generating steam and in the lower part of an opening for the raw gas and slag removal with a water bath. In this way, the heat of the waste heat boiler can be used for the production of steam.

[0010] Many embodiments introduce the synthesis gas into a cooling space equipped with a radiation vessel wall, the radiation vessel wall consisting either of an inner wear jacket made of metal to protect the reactor pressure jacket, or of pipes through which water flows Steam generation is conducted. Both embodiments have the purpose not to direct the hot synthesis gas directly into the cooling space or against the radiation vessel wall of the jacket vessel, but to cool, so that the slag can solidify and is separated from the synthesis gas.

Sometimes it is also possible to perform the hot, slag-containing synthesis gas against cooling plates provided for this purpose, also called "bulkheads", said cooling plates run concentrically in the direction of the vertical geometric central axis of the cooling space and the entire reactor tapering - Cooling plates can also consist of tubes, which then run for better cooling, advantageously parallel to the gas flow direction.

In a typical embodiment of the invention, the synthesis gas is expediently already provided with a swirl in the reactor, so that it is not guided directly vertically into the cooling space, but already with a slight twist against the cooling plate in the cooling space. The reactor itself has a funnel-shaped outlet which causes an increase in the gas velocity, thus enhancing the guidance of the hot synthesis gas against the cooling plates. The actual wall around the cooling plates is often provided with pipes that protect the wall from the high temperatures of the synthesis gas. In the gas flow direction behind the cooling plates or bulkheads there are introduction nozzles for the foreign medium.

This method has the disadvantage that the sensible heat of the synthesis gas leaving the reactor remains unused. The temperature of the synthesis gas when leaving the reactor is more than 1500 ° C, and is after cooling by supplying a cooling gaseous, vapor or liquid external medium 200 to 300 ° C. The heat of the synthesis gas is lost in this way unused. It would therefore be cheaper to use the heat of the synthesis gas, which is located between the reactor outlet and the radiation boiler wall, for a chemical process, it should be noted that a certain residence time in the cooling space is required for the course of this chemical reaction. It is therefore an object to provide a method which uses the enthalpy or sensible heat of the synthesis gas directly after the exit of the reactor for a subsequent process, ensures an increased residence time in the cooling space and still cooling the synthesis gas through a radiation boiler wall in the Cooling space and the supply of foreign media in the gas flow direction behind the radiation boiler wall allows.

The invention solves this problem by a device in which are arranged tangentially angled to the reactor wall burner in the cooling space, whereby the injected fuel undergoes a directed around the central axis of the cooling space swirl, so that increases the residence time of the injected substance in the cooling space becomes, and thus possible with the remaining heat of the synthesis gas synthesis chemical reactions. The burners can inject the renewable fuel angled with or against the gas flow direction. According to the invention, however, a tangential direction must be maintained, wherein the tangential direction refers to a tangential angle, which forms at a horizontal cross-section of the cooling space relative to the wall of the cooling space. The burners must be guided through the wall of the jacket vessel of the Abkühlraumes and the radiation boiler wall. This usually requires a high design effort, since the radiation boiler wall often contains pipes or thick-walled metal screens. A frequently used construction method for carrying out this burner arrangement is a "pipe-web-pipe" construction Preferably, a renewable raw material is tangentially injected into the cooling space as an additional fuel Renewable raw materials have the property of reacting with the synthesis gas without in the reaction a significant temperature increase the temperature. Due to the tangential injection of the renewable fuel, the residence time in the cooling space is increased, so that a reaction of the renewable fuel with the still hot synthesis gas is made possible. Frequently, the temperature of synthe- tegases is further reduced when adding renewable raw materials. The renewable fuels react with the components of the synthesis gas, consuming heat. The reaction produces additional synthesis gas.

By the device according to the invention, the efficiency of a coal gasification process can be significantly improved. Since renewable raw materials provide only a small amount of ash in a gasification process, the radiation boiler wall is subjected to considerably less ash and slag by the process according to the invention. Finally, the radiation boiler wall is exposed by the Nacheinleitung of renewable fuel a much lower heat load.

In particular, a device is claimed for introducing renewable fuels into the region of the radiation boiler wall of coal gasification reactors

 A reaction space which is suitable for the gasification of solid, carbon-containing fuels by reaction with an oxygen-containing or water vapor-containing and oxygen-containing gas, and which is equipped with burners,

 A second space, which is designed as a cooling space, and which is arranged in the gas flow direction below the reaction space, said cooling space is equipped with supply means for gaseous, vaporous and liquid cooling media, wherein

 At least part of the gas-flow-oriented expansion of the cooling space is equipped with an annular radiation wall arranged on the inner wall of the cooling space,

 and which is characterized in that

• the annular part of the cooling room, in which the radiation boiler wall is arranged, is equipped with burners, which pass through the radiation boiler wall into the cooling space, through which a renewable fuel in the cooling space can be introduced, and • The burners are arranged in the cooling space tangent to the reactor wall.

The increased design effort for the introduction depends on the nature of the radiation boiler wall. To carry out the invention, it is only necessary for at least one burner to be guided through the gas-tight radiation boiler wall in a media-tight manner. In one embodiment of the invention, tubes are arranged within the cooling space on the inner wall of the cooling space, wherein the tubes are flowed through in the gas flow direction by a cooling medium. The burners must then either be passed through the jacket vessel between the pipes or through the pipes into the cooling room. The design of the radiation boiler wall can sometimes vary considerably in the production of gasification reactors, so that the design effort of the burner assembly depends on the design of the radiation boiler wall.

In a further embodiment of the invention, the tubes cover the entire inner circumference of the cooling space over a certain length of the cooling space, wherein the tubes can be flowed through in the gas flow direction by a cooling medium. In this case, the burners must always be routed through pipes at a certain point. This can be done by pipe collars, but in an advantageous embodiment is carried out by a so-called "pipe-web-pipe" construction A typical embodiment for a "pipe-web-pipe" construction to reduce unwanted interruption of water flow through pipes in a burner assembly EP 0840053 B1 teaches.

In a further embodiment of the invention, an annular wall is located between the wall of the cooling space and the tubes as the radiation vessel wall. As a result, the mechanical load of the jacket vessel is kept low during the cooling of the slag-containing synthesis gas. In a further embodiment of the invention further tubes are arranged within the cooling space, which are flowed through in the gas flow direction by a cooling medium, and which are arranged by their parallel arrangement in concentric direction on the geometric center axis of the Abkühl- space. These tubes are preferably arranged in conjunction with the tubes, which surround the tubes over a certain length of the cooling space the entire inner circumference of the cooling space, wherein all tubes are flowed through in the gas flow direction of a cooling medium. The tapered to the geometric center axis of the cooling chamber tube arrangement causes improved cooling of the Synthesis gas and extended the residence time in the cooling room in addition. The concentric arrangement of these tubes is also referred to as "bulkheads." In a simple embodiment, these "bulkheads" can also be designed as plates. This arrangement typically does not protrude to the middle of the longitudinal axis of the cooling space, but only about one third of the cross section into the cooling space.

In one embodiment of the invention, the radiation boiler wall consists of a heat-resistant plate. The radiation vessel wall may also contain tubes contained in the radiation vessel wall in any arrangement. The radiation boiler wall may also consist entirely of tubes. The tubes serve to guide an indirectly cooling arbitrary medium. In this case, the burners for carrying out the invention have to be guided tightly against the cooling medium in the pipes and through the gas-tight radiation boiler wall ("pipe-web-pipe construction") .The pipes can also be used in the direction of the cooling space for carrying out the invention An embodiment of the prior art for a radiant wall containing tubes is DE 3809313 A1 In the practice of the present invention, at least one burner would be guided in a medium-tight manner through the annular walls and the refractory lining.

In a further embodiment of the invention is located around the concentric arrangement of the tubes another annular wall as a radiation boiler wall. This can also have on the side facing the reaction space further tubes for cooling, which can be traversed by a cooling medium. These tubes then run for better cooling, preferably around the geometric center axis of the reaction space.

[0026] Between the radiation vessel wall and the inner wall of the cooling chamber, a gap can also be arranged, through which gas can circulate. An example of such a radiation boiler wall is DE 102008012734 A1. For the practice of the present invention, burners for the renewable fuel are then passed through this gap and the inner wall. By way of example, the radiation vessel wall can also consist of a hollow-cylindrical convection bowl which concentrically surrounds the cooling space. An example of an embodiment with a cooling space, which consists of a hollow cylindrical Konvekti- onskessel for cooling, gives the EP 616022 B1. The convection boiler can also be divided several times, or in turn be equipped with cooling plates. It is also conceivable for carrying out the invention that behind in the gas flow direction the burner for the renewable raw material is a waterfall-like cooling device, as claimed for example in DE 102008012734 A1.

The burners which introduce the renewable raw material through the radiation boiler wall into the cooling space can be of any kind. These may be exemplified as burner lances. These can also be made as nozzles. The burners can also be arranged tangentially and concentrically. The burners may also be arranged to be in the gas flow direction in front of the reaction port of the reaction space so that they are in the "flow shadow" of the syngas stream during operation, thus better protecting the burners from slagging it is only necessary for at least one burner to be guided through the gas-tight radiation boiler wall in a media-tight manner, and that renewable fuel is guided or can be guided into at least part of the cooling space in the gas flow direction before the introduction of the cooling gaseous, vaporous or liquid foreign medium The reaction space and the cooling space can be provided for the construction of the device as a single component with the same diameter., The reaction space and the cooling space can also be two stacked pressure vessel with different diameters, the Du In this case, the diameter of the cooling space pressure vessel is greater than the diameter of the reaction space pressure vessel.

Also claimed is a method for the tangential injection of fuels into the cooling space of a gasification reactor. The fuel can be injected in the cooling space in or against the gas flow direction, but is injected in a horizontal sectional plane of the cooling space at a tangential angle to the reactor wall. This considerably increases the residence time in the reaction space.

For injection typically a renewable fuel is used. A renewable fuel is introduced concentrically tangentially into the cooling space through at least one burner through the radiation boiler wall, so that a further entrained flow gasification occurs, through which the temperature of the outflowing gas decreases and the enthalpy difference is used for additional gasification of renewable raw materials ("chemical quench"). This process is characterized by the tial injection of the fuel with the extension of the residence time allows or at least favors.

It is also claimed a method for introducing renewable fuels in the region of the radiation boiler wall of coal gasification reactors, wherein

• the finely ground, carbonaceous fuel in admixture with oxygen or an oxygen-enriched gas, from the outside in the horizontal direction concentrically or downwardly injected from above into a refractory reaction space, so that the fuel reacts in a flow-gasification in the reaction space to synthesis gas, and

The synthesis gas obtained is under a pressure of 0.5 to 8 MPa and is carried out in an upward or downward direction from the reaction space, and

 The synthesis gas thus obtained is passed, after execution, into a second reaction space which is designed as a cooling space and in which the supplied gas is mixed for cooling with a cooler gaseous, vaporous or liquid foreign medium,

 and which is characterized in that

 • between the reaction space and the point of introduction of the foreign medium through the radiation boiler wall through at least one

Burner a renewable fuel is introduced concentrically into the cooling space, so that a further entrained flow gasification, through which the temperature of the effluent gas decreases and the enthalpy difference is used for additional gasification of renewable resources, and

• The renewable fuel is injected in tangential angled direction to the wall of the cooling space in the cooling space, so that the renewable fuel receives a swirl when injected into the raw gas stream from the reaction space. As a renewable fuel all biological materials can be used, which are suitable for the production of synthesis gas with an oxygen-containing gas as the reaction gas. These can be chopped, crushed, finely ground energy plants, straw, grasses, cereals, biological waste, marine plants or livestock manure. The renewable resources may be subjected to pre-treatment prior to gasification, wherein the pre-treatment steps include, by way of example, drying, carbonization, milling or a combination of these steps. The renewable fuel is then introduced to the gasification in admixture with a vapor or oxygen-containing gas, water vapor, or an oxygen-containing gas and water vapor in the cooling space. As fuel for the burners in the cooling room, the renewable fuels can also be used mixed with carbonaceous or fossil fuels. The addition of renewable raw materials in an entrainment gasification is known in principle. EP 1027407 B1 describes a method for producing fuel gas, synthesis gas and reducing gas from renewable and fossil fuels by burning the fuels in a burner with gaseous oxygen or oxygen-containing gases. DE 102009011174 A1, which was not yet disclosed at the time of the present application, describes a method for utilizing the enthalpy of a synthesis gas by additional gasification of renewable fuels within a second burner level, which extends over a partial area of the entire height of the reaction space.

DE 102010008384.4, not yet disclosed at the time of the present application, describes a method in which a biological fuel is introduced concentrically into the cooling space through additional openings in the cooling space, which are arranged within the cooling space, so that a further reaction with the synthesis gas is carried out, whereby the temperature of the synthesis gas is further lowered. This application introduces the fuel directly into the cooling room and gives no indication of a complex construction for the tangential introduction of a renewable fuel through a radiation boiler wall.

The temperature of the synthesis gas is at exit from the reaction chamber typically 1400 to 1500 ° C, after initiation of the renewable fuel about 1200 to 1300 ° C and after leaving the cooling chamber about 900 ° C. The temperature of approx. 900 ° C when leaving the cooling room is confirmed by measured values, the other values are estimated values.

The burners can be arranged arbitrarily in the cooling space. The renewable fuel has only by tangentially arranged burner tangentially in be introduced into the cylindrical cooling space, so that the flow of air in the cooling space receives a twist, which increases the residence time of the fuel in the cooling space. Since the burners have to be guided through the blast furnace wall in a media-tight manner, they are typically equipped with sealing collars in the area of the blast furnace wall. However, the seal can be made arbitrarily and the type of seal can be performed arbitrarily.

The sensible heat of the synthesis gas can be used to generate steam. This can also be a high-pressure steam. For this purpose, a foreign medium is used, which absorbs the heat from the cooling space by indirect cooling in the cooling plate or pipes in the radiation boiler wall. This heat can be used in a downstream waste heat boiler to generate steam or high pressure steam. The radiation vessel wall and the bulkheads can also be cleaned by knockers or sootblowers or both for carrying out the invention.

Also claimed is the use of the synthesis gas produced by said process. This can be used as an example for generating electricity in a power plant. This can also be used to generate electricity in a power plant with deposition of carbon dioxide from the combustion gas. An example of this is the IGCC technology (IGCC: Integrated Gasification Combined Cycle) Finally, it is also possible to use the synthesis gas produced according to the invention for the production of synthetic fuels or of synthetic natural gas, and also any use of the synthesis gas according to the invention for the production of chemicals ("polygeneration") is possible.

The invention has the advantage of utilizing the enthalpy of a hot synthesis gas from a coal gasification also in a cooling space equipped with a radiation boiler wall. This can significantly improve the economy of a coal gasification process. Since renewable fuels provide only a small amount of ash in a gasification process, the radiation boiler wall is subjected to considerably less ash and slag by the process according to the invention. Finally, the post-introduction of renewable fuel exposes the radiation boiler wall to a much lower heat load.

The invention will be explained in more detail with reference to two drawings, wherein the invention is not limited to these embodiments. 1 shows a coal gasification reactor with the gasification according to the invention, in which the radiant would be made of a water or cooling medium-carrying tube, which is equipped with an overlying cooling plate. FIG. 2 shows a coal gasification reactor with the gasification according to the invention in which the radiation boiler wall consists of a cooling plate which is equipped with tubes which guide the cooling medium and are arranged circularly around the cooling space.

FIG. 1 shows a coal gasification reactor (1) according to the invention, equipped with a reaction space (2) for the gasification of carbonaceous fossil fuel, a cooling space (3) with radiation boiler walls (4), and a slag collecting vessel (5) serving as water bath (5a). is kind. The reaction chamber (2) is equipped with burners (6) through which the carbonaceous fossil fuel (6a) is introduced into the reaction space (2) in admixture with an oxygen-containing fuel, and is suspended in a pressure-tight jacket vessel (2) via suspension devices (2a). 7) hung. In the gasification reaction, synthesis gas (8) is formed, which receives a twist (8a) when using tangential burners. At the bottom of the reaction space (2) there is an execution nozzle (2b) for the effluent synthesis gas (8b), which passes via this into the cooling space (3). The execution socket (2b) is equipped with a collar-shaped opening. The jacket vessel (7) is equipped at the level of the cooling space (3) with a radiation boiler wall (4), which consists of a heat-resistant plate (4) arranged annularly around the inner wall (7) of the cooling space (3). Between the wall of the shell vessel (7) and the radiation vessel wall are tubes (9), which lead an indirectly cooling cooling medium and in the gas flow direction parallel to the wall of the shell vessel (7). On the inside of the radiation boiler wall (4) are also pipes (10), which lead an indirectly cooling cooling medium, wherein the tubes (10) annularly about the axis of the cooling space (3). The cooling medium-carrying tubes (10) on the inside of the radiation boiler wall (4) are equipped with feed nozzles (10a) and nozzles (10b). In the gas flow direction in front of the radiation boiler wall (4) burners (11) for renewable fuel (11a) are arranged according to the invention pass through the radiation boiler wall (4) and introduced via a renewable fuel (11a) in the cooling space (3) and gasified. This causes a gasification and the temperature of the synthesis gas decreases. Solidified slag settles on the radiation boiler wall (4). This passes through the action of gravity into the slag collecting vessel (5) arranged below, which is filled with water (5a), or is entrained by the gas flow. The effluent synthesis gas (8b) then passes into the cooling region in the gas flow direction behind the radiation vessel wall (4), in which supply nozzles (12) for a cooling gaseous, vaporous or liquid foreign medium (12a) are arranged. are net. The supplied foreign medium (12a) further cools the synthesis gas in the cooling space (8c) before this (13) leaves the cooling space (3) in the lateral direction via an outlet connection (14). The slag (15) is periodically carried out via locks (16) and an outlet nozzle (17) from the reactor (1). FIG. 1 also shows the sectional plane AA whose cross-section is shown in FIG.

FIG. FIG. 2 shows the cross-section of a gasification reactor whose plane is shown in FIG. 1 was designated A-A. The jacket vessel of the cooling space, the interior of the reaction space (2), the synthesis nozzle (2b), the radiation boiler wall (4), the tubes on the inner wall of the jacket vessel (9) and the cooling tubes (10), can be seen. which are arranged annularly on the radiation boiler wall (4) on the side of the cooling space (3). The tubes (9) on the inner wall of the jacket vessel (7) are equipped with cooling tubes (9a, "bulkheads") tapering concentrically in the direction of the geometric central axis of the cooling space (3) in order to improve the cooling. arranged in a tangential direction to the jacket vessel (7), so that the synthesis gas receives a twist (8c).

[0043] List of Reference Numerals

 1 coal gasification reactor

 2 reaction space

 2a Suspension devices for reaction space

 2b execution socket for synthesis gas

 3 cooling room

 4 radiation boiler wall

 4a cooling plate

 5 slag collecting vessel

 5a water bath

 6 burners for carbonaceous, fossil fuel

 6a Carbonaceous fossil fuel

 7 Pressure-tight jacket

 8 synthesis gas

 8a synthesis gas with spin

 8b effluent synthesis gas

 8c synthesis gas in the cooling room with swirl

 Tubes for cooling medium on the inner wall of the jacket vessel

 a Supply nozzle for cooling medium

b Delivery socket for cooling medium Coolant-carrying pipes

a Supply nozzle for cooling medium

b Delivery socket for cooling medium

 burner

a Renewable fuel

 Engineered synthesis gas

a Cooling gaseous, vaporous or liquid foreign medium outlet nozzle

 slag

 smuggle

 execution socket

 Pipes of the radiation boiler wall

a Supply nozzle for the pipes of the radiation boiler wall

Claims

claims

1. gasification reactor (1) with a device (11) for introducing renewable fuels (1 1 a) in the region of the radiation boiler wall (9) of gasification reactors (1) comprising

 A reaction space (2) which is suitable for the gasification of solid, carbon-containing fuels (6a) by reaction with an oxygen-containing or water vapor and oxygen-containing gas, and which is equipped with burners (6),

 A second space (3) which is designed as a cooling space (3) and which is arranged in the gas flow direction (8b) below the reaction space (2), said cooling space (3) having feed means (12) for gaseous, vaporous and liquid Cooling media (12a) is equipped, wherein

 At least part of the gas flow-directed (8b) extension of the cooling space (3) is equipped with an annular radiation boiler wall (9) arranged on the inner wall of the cooling space (3), characterized in that

 • the annular part of the cooling space (3), in which the radiation boiler wall (9) is arranged, is equipped with burners (1 1) which pass through the radiation boiler wall (9) into the cooling space (3), through which a renewable fuel (1 1 a) in the cooling space (3) can be introduced, and

 • the burner (1 1) in the cooling space (3) tangentially to the reactor wall (7) are arranged.

2. gasification reactor (1) with a device (11) for introducing renewable fuels (1 1 a) in the region of the radiation boiler wall (9) of gasification reactors (1) according to claim 1, characterized in that within the cooling space (3) the inner wall (7) of the cooling space (3) tubes (9) are arranged, wherein the tubes (9) in the gas flow direction (8b) of a cooling medium (9a, 9b) are flowed through.

3. gasification reactor (1) with a device (11) for introducing renewable fuels (11 a) in the region of the radiation boiler wall (9) of gasification reactors (1) according to one of claims 1 or 2, characterized in that the tubes (9) on the inner wall (7) of the cooling space (3) covering the entire inner circumference of the cooling space (3) over a certain length, wherein the tubes (9) in the gas flow direction (8b) of a cooling medium (9a, 9b) are flowed through.

4. Gasification reactor (1) with a device (1 1) for introducing renewable fuels (11 a) in the region of the radiation boiler wall (9) of gasification reactors (1) according to one of claims 2 or 3, characterized in that between the Wall (7) of the Abkühlraumes (3) and the tubes (9) has an annular wall (4) as a radiation boiler wall (4).

5. Gasification reactor (1) with a device (11) for introducing renewable fuels (1 1a) into the region of the radiation boiler wall (9) of gasification reactors (1) according to one of claims 1 to 4, characterized in that within the cooling space ( 3) further tubes (10) are arranged, which in the gas flow direction (8b) of a cooling medium (10a, 10b) can be flowed through, and which are arranged by their parallel arrangement in the concentric direction on the geometric center axis of the cooling space (3).

6. gasification reactor (1) with a device (11) for introducing renewable fuels (1 1a) in the region of the radiation boiler wall (9) of gasification reactors (1) according to claim 5, characterized in that the concentric arrangement of the tubes ( 10) a further annular wall (4) is located as a radiation boiler wall.

7. Gasification reactor (1) with a device (1 1) for introducing renewable fuels (1 1a) in the region of the radiation boiler wall (9) of gasification reactors (1) according to one of claims 1 to 6, characterized in that the further annular Wall (4) consists of a heat-resistant plate (4).

8. gasification reactor (1) with a device (1 1) for introducing renewable fuels (1 1a) in the region of the radiation boiler wall (9) of gasification reactors (1) according to one of claims 1 to 6, characterized in that the further annular wall (4) contains tubes (10) which carry an indirectly cooling medium (10a, 10b) in the interior.

9. gasification reactor (1) with a device (11) for introducing renewable fuels (11 a) in the region of the radiation boiler wall (9) of Verga sungsreaktoren (1) according to claim 8, characterized in that on the

Reaction space side (3) of the further annular wall (4) extend annularly around the geometric center axis of the reaction space (3) tubes (10), which by a cooling medium (10 a, 10 b) can be flowed through.

10. Gasification reactor (1) with a device (11) for introducing renewable fuels (11 a) in the region of the radiation vessel wall (9) of gasification reactors (1) according to one of claims 1 to 6, characterized in that the further annular wall (4) consists of a hollow cylindrical boiler which surrounds the cooling space (3) concentrically.

11. Gasification reactor (1) with a device (11) for introducing regrowable fuels (1 1a) in the region of the radiation boiler wall (9) of gasification reactors (1) according to one of claims 1 to 10, characterized in that the burners (11) are burner lances.

12. Gasification reactor (1) with a device (11) for introducing renewable fuels (1 1a) in the region of the radiation boiler wall (9) of Verga sungsreaktoren (1) according to one of claims 1 to 10, characterized in that the burner (11) are designed as nozzles.

13. Gasification reactor (1) with a device (11) for introducing renewable fuels (1 1a) into the region of the radiation vessel wall (9) of gasification reactors (1) according to one of claims 1 to 12, characterized in that 11) or burner lances are arranged so that they are in

Gas flow direction (8b) in front of the nozzle (2b) of the reaction space (2) are located so that they are in operation in the flow shadow of the synthesis gas stream.

14. Gasification reactor (1) with a device (11) for introducing regrowable fuels (11a) into the region of the radiation vessel wall (9) of gasification reactors (1) according to one of claims 1 to 13, characterized net, that the reaction space (2) and the cooling space (3) consists of two superimposed pressure vessels with different diameters, wherein the diameter of the cooling space pressure vessel (3) is greater than the diameter of the reaction space pressure vessel (2).

15. A method for introducing renewable fuels (11 a) in the region of the radiation boiler wall (9) of gasification reactors (1), wherein

A finely ground, carbonaceous fuel (6a) mixed with oxygen or an oxygen-enriched gas is injected from the outside in a horizontal direction concentrically or downwardly from above into a refractory reaction space (2), so that the fuel (6a) in an entrainment gasification ( 8a) in the reaction space (2) to synthesis gas (8b), and

 The resulting synthesis gas (8b) is under a pressure of 0.5 to 8 MPa and is carried out in an upward or downward direction from the reaction space (2), and

 The synthesis gas (8b) thus obtained is passed after execution into a second reaction space (3) which is designed as a cooling space (3) and in which the supplied gas (8b) is cooled by a cooler gaseous, vaporous or liquid external medium ( 12a), characterized in that

 • between the reaction chamber (2) and the discharge point (12) for the foreign medium (12a) through the radiation boiler wall (9) via at least one burner (11) a renewable fuel (11a) is introduced concentrically into the cooling space (3), so that a further entrained flow gasification (8c) is formed, through which the temperature of the outflowing gas (8b) decreases and the enthalpy difference is used for additional gasification of renewable raw materials (11a), and

• the renewable fuel (11a) in a tangential angled direction to the wall (7) of the cooling space (3) is injected into the cooling space (3), so that the renewable fuel (11a) when injected into the raw gas stream (8b) from the reaction space ( 2) receives a twist (8c).

16. A method for introducing renewable fuels (11a) in the region of the radiation boiler wall (9) of gasification reactors (1) according to claim 15, characterized in that as renewable fuel (11a) chopped shredded, finely ground energy plants, wood in any form , Straw, grasses, cereals, biological waste, marine plants or livestock manure.

17. A method for introducing renewable fuels (11a) into the region of the radiation boiler wall (9) of gasification reactors (1) according to one of claims 15 or 16, characterized in that the renewable fuels (11a) are subjected to a pretreatment before the gasification, wherein the pretreatment steps comprise drying, carbonization, milling or a combination of these steps.

18. A method for introducing renewable fuels (11a) in the region of the radiation boiler wall (9) of gasification reactors (1) according to any one of claims 15 to 17, characterized in that the renewable fuel (11a) in admixture with an oxygen-containing gas , Steam, or an oxygen-containing gas and water vapor is introduced into the cooling space.

19. A method for introducing renewable fuels (11a) in the region of the radiation boiler wall (9) of gasification reactors (1) according to any one of claims 15 to 18, characterized in that as fuel (11a) for the

Burners (11) in the cooling room (3) renewable fuels are used in a mixture with carbonaceous fuels.

20. A method for introducing renewable fuels (11a) into the region of the radiation vessel wall (9) of gasification reactors (1) according to any one of claims 15 to 19, characterized in that the heat of the synthesis gas (8b), which is a foreign medium ( 9a, 10a) in the radiation vessel wall (9, 10) is used for the generation of steam (9b, 10b) or high-pressure steam (9b, 10b).

21. Use of a method for introducing renewable fuels (1 1a) into the region of the radiation vessel wall (9) of gasification reactors (1) according to one of claims 15 to 20, characterized in that the herge represented synthesis gas (13) is used to generate electricity in a power plant.

22. Use of a method for introducing renewable fuels (11a) in the region of the radiation boiler wall (9) of gasification reactors (1) according to one of claims 15 to 21, characterized in that the synthesis gas produced (13) for generating electricity in one Power plant with deposition of carbon dioxide from the combustion gas is used.

23. Use of a method for introducing renewable fuels (11a) into the region of the radiation boiler wall (9) of gasification reactors (1) according to one of claims 15 to 22, characterized in that the synthesis gas produced (13) for the production of synthetic fuels or of synthetic natural gas is used.