JP3702396B2 - Coal gasification combined power generation system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a combined coal gasification combined power generation apparatus having high efficiency and excellent environmental conservation.
[0002]
[Prior art]
FIG. 2 is a flowchart showing an example of the configuration of a conventional coal gasification combined power generation apparatus using a wet desulfurization facility and a sulfur recovery facility. The apparatus shown in the figure is an example described in “Sulfur recovery method and apparatus for coal gasification plant” (Japanese Patent Laid-Open No. Hei 6-293888) which is the invention of the present inventor.
In the air separation device 1, the air 2 sucked into the air compressor 3 is separated into nitrogen 7 and oxygen 6 in the rectification tower 5 through the heat exchanger 4. Using this oxygen 6 as a gasifying agent, coal 8 supplied from a coal hopper 9 is gasified in a coal gasification furnace 10 to generate a crude product gas 11 mainly composed of CO and H ₂ . The crude product gas 11 is cooled by a heat recovery boiler 12 and supplied to a de-H ₂ S tower 14 through a dust removing device 13. In the de-H ₂ S tower 14, sulfur compounds such as H ₂ S and COS in the crude product gas 11 are removed by the absorbing solution to below the allowable concentration of the gas turbine 16. The purified gas 15 is sent to the gas turbine 16 and is generated by the generator 20. The combustion exhaust gas from the gas turbine 16 is recovered by the exhaust heat recovery boiler 17 and then discharged from the chimney 18 to the atmosphere. The steam 31 obtained by the boiler 17 is sent to the steam turbine 19 together with the steam 31 obtained by the heat recovery boiler 12, and power is generated by the generator 20.
[0003]
The absorption liquid that has absorbed sulfur compounds such as H ₂ S and COS in the de-H ₂ S tower 14 is sent to the regeneration tower 21 and heated by low-pressure steam 37 of 10 atmospheres or less in order to prevent deterioration due to thermal decomposition of the absorption liquid. Thus, the absorbed H ₂ S and COS are desorbed and regenerated. This steam 37 uses the high-pressure steam 31 obtained in the heat recovery boiler 12 following the coal gasification furnace under reduced pressure. The concentration of the sulfur compound (H ₂ S, COS) in the regeneration exhaust gas 22 released from the upper part of the regeneration tower 21 is about 30 vol%.
[0004]
The regenerated exhaust gas 22 is guided to the incinerator 24, and the sulfur compound in the regenerated exhaust gas 22 is oxidized to sulfur dioxide by the air 23. In the incinerator 24, auxiliary fuel 32 such as oil and LPG is always burned in order to keep the flame stable. Since the combustion exhaust gas 25 generated in the incinerator 24 is a gas having a temperature of 500 to 1000 ° C. and contains several vol% of SO ₂ , the heat exchanger 26 performs heat recovery with the water vapor 31 a, and then the absorption tower 27. Led to. By contacting the limestone slurry 28 and the combustion exhaust gas 25 in the absorption tower 27, SO ₂ contained in the combustion exhaust gas 25 is absorbed until the SO ₂ content in the plant exhaust gas 44 at the outlet of the chimney 18 becomes equal to or lower than the environmental regulation value. Removed. Calcium sulfite 42 produced by the reaction of the limestone slurry 28 with SO ₂ is extracted from the lower part of the absorption tower 27. Next, it is led to the oxidation tower 41 and oxidized by the air 40 to become calcium sulfate 43. Calcium sulfate 43 is sent to thickener 29, and after dehydration, gypsum 30 is recovered.
[0005]
At the time of starting the gasifier, it is necessary to raise the temperature between the gasifier 10 and the dust removing device 13 to a temperature at which the moisture in the gas does not condense before charging the gasifier 10 with coal. Therefore, high-temperature combustion gas obtained by burning the auxiliary fuel 45 is passed from the gasification furnace 10 to the dust removing device 13. The gasifier start-up exhaust gas 35 generated by the combustion of the auxiliary fuel 45 is released from the chimney 18 into the atmosphere by operating the switching valves 33 and 34. As the auxiliary fuel 45, a liquid fuel having no phase change even when used in a gasification operation under a normal high pressure, that is, heavy oil, light oil or the like is usually used.
The
[Problems to be solved by the invention]
In the prior art described above, the following points have been problems.
1. In order to prevent moisture in the generated coal gas 11 from condensing between the coal gasifier 10 and the dust removing device 13, the temperature is raised using the heat of the combustion gas combusted in the auxiliary fuel 45 when the gasifier is started. To do. At this time, since the liquid fuel combusted as the auxiliary fuel 45 usually contains a sulfur content, the combustion exhaust gas 35 contains SO ₂ . Since the absorption liquid of the wet desulfurization facility can also absorb SO ₂ , desulfurization can be performed by passing the combustion gas through the de-H ₂ S tower 14. In that case, the absorbed SO ₂ is desorbed and the absorption liquid. Is difficult to regenerate, and the problem is that the absorption performance of H ₂ S, which is the original application, decreases due to the absorption of SO ₂ . For this reason, in the conventional apparatus, the combustion exhaust gas 35 at the time of start-up is discharged from the chimney 18 to the atmosphere by bypassing the de-H ₂ S tower 14.
Therefore, desulfurization of the start-up exhaust gas 35 is not performed, and it cannot be said that environmental conservation at the time of start-up of the apparatus is preferable. In addition, when a high-sulfur fuel is used as the auxiliary fuel 45 at the start-up, there is a possibility that the environmental regulation value cannot be satisfied at the start-up. Depending on the properties of the fuel, SO in the exhaust gas at the start-up of the gasifier _A separate device for removing ₂ is required.
[0007]
2. The absorption liquid heating steam 37 in the absorption liquid regeneration tower 21 is preferably less than the boiling point of the absorption liquid to avoid thermal decomposition of the absorption liquid, and is preferably as low a temperature as possible, usually about 200 ° C. Should. In the conventional apparatus, a part of the high-pressure steam 31 generated in the heat recovery boiler 12 is decompressed and used as the low-pressure steam necessary for regenerating the absorption liquid of the wet desulfurization facility. -The efficiency of power generation in the bin 19 was reduced.
[0008]
An object of the present invention is to solve the above-mentioned problems in the prior art, and to provide a highly efficient coal gasification combined power generation apparatus having excellent environmental conservation and high efficiency.
[0009]
[Means for Solving the Problems]
The purpose is to gasify coal in a coal gasification furnace with oxygen or a gasifying agent containing oxygen as a main component, and to degas the H ₂ S-containing exhaust gas generated in the incinerator when the gas is desulfurized with a wet desulfurization facility. In a combined gasification combined cycle power plant that recovers sulfur in the coal as gypsum by reacting the combustion gas generated by the combustion with limestone, the exhaust gas generated at the start of the coal gasification furnace to the incinerator This is achieved by a combined coal gasification combined cycle power generation system characterized in that it has introduction means for guiding.
[0010]
The above object is also to incinerate the H ₂ S-containing exhaust gas generated when coal is gasified in a coal gasification furnace with oxygen or a gasifying agent containing oxygen as a main component and the gas is desulfurized with a wet desulfurization facility. In a combined gasification combined cycle power plant that recovers sulfur in the coal as gypsum by reacting the combustion gas generated by the combustion with limestone, the exhaust gas generated at the start of the coal gasification furnace This is achieved by a combined coal gasification combined power generation system characterized in that the sulfur content in the exhaust gas is also recovered as gypsum.
By guiding the combustion exhaust gas at the start of the gasification furnace to the incinerator by bypassing the de-H ₂ S tower, SO _{2 in} the exhaust gas at the start can be removed, and environmental conservation is maintained.
[0011]
The above object is also to incinerate the H ₂ S-containing exhaust gas generated when coal is gasified in a coal gasification furnace with oxygen or a gasifying agent containing oxygen as a main component and the gas is desulfurized with a wet desulfurization facility. In a combined gasification combined cycle power plant that recovers sulfur in coal as gypsum by reacting the combustion gas generated by the combustion with limestone, the desulfurization using the exhaust heat of the incinerator A regeneration steam generating means for generating water vapor as a regeneration heat source of the absorption liquid regeneration tower of the facility, and means for sending the steam generated by the regeneration steam generation means to the heat source section of the absorption liquid regeneration tower are provided. This is achieved by the combined coal gasification combined power generation system.
[0012]
The above object is also to incinerate the H ₂ S-containing exhaust gas generated when coal is gasified in a coal gasification furnace with oxygen or a gasifying agent containing oxygen as a main component and the gas is desulfurized with a wet desulfurization facility. In the combined gasification combined cycle power plant that recovers sulfur in the coal as gypsum by reacting the combustion gas generated by the combustion with limestone, and absorbing it by using the exhaust heat of the high temperature exhaust gas from the incinerator This is achieved by a combined coal gasification combined cycle power generation apparatus characterized in that steam serving as a regeneration heat source for a liquid regeneration tower is obtained and the steam is used as a heat source for regeneration of an absorbing liquid in the wet desulfurization facility.
[0013]
The exhaust gas temperature at the incinerator outlet varies depending on the composition of coal and the operating conditions of the wet gas purification equipment (de-H ₂ S tower, regeneration tower, etc.), but is usually about 500 to 1000 ° C. Since the lower the temperature of the exhaust gas entering the absorption tower, the higher the desulfurization effect and the more economical, the exhaust gas at the outlet of the incinerator is recovered and cooled by the regeneration steam generating means. The temperature of the steam generated by the exhaust heat recovery can be arbitrarily selected. Therefore, the steam temperature generated by the regeneration steam generating means is set as the regeneration heat source temperature of the absorption liquid regeneration tower. Usually, the temperature is in the range of 150 ° C. to 250 ° C., particularly about 200 ° C., and the steam is used as a heat source for heating and regenerating the absorbing liquid in the absorbing liquid regeneration tower, thereby partially reducing the pressure of the high-pressure steam necessary for power generation, etc. An economical steam system can be constructed without taking the above measures.
[0014]
The above object is also achieved by a combined coal gasification combined cycle power generation apparatus that combines the above characteristics.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Next, the present invention will be described by way of specific examples. FIG. 1 is a flowchart showing an example of the configuration of a combined coal gasification combined power generation system using a wet desulfurization facility and a sulfur recovery facility. Coal 9 is gasified in a coal gasification furnace 10 using oxygen 6 separated from air 2 in the air separation device 1 as a gasifying agent, and a crude product gas 11 mainly composed of CO and H ₂ is generated. . The crude product gas 11 is cooled by a heat recovery boiler 12 and supplied to a de-H ₂ S tower 14 through a dust removing device 13. In the de-H ₂ S tower 14, sulfur compounds such as H ₂ S and COS in the crude product gas 11 are removed by the absorbing solution to below the allowable concentration of the gas turbine 16. The purified gas 15 is sent to the gas turbine 16 to generate power, and the combustion exhaust gas from the gas turbine 16 is cooled by the exhaust heat recovery boiler 17 and simultaneously collects the high-pressure steam 31 from the chimney 18. Released into the atmosphere. The steam obtained here is sent to the steam turbine 19 together with the steam 31 obtained by the heat recovery boiler 12 to generate power.
[0016]
The absorption liquid that has absorbed sulfur compounds such as H ₂ S and COS in the de-H ₂ S tower 14 is sent to the regeneration tower 21 and heated by the regeneration steam 37 to desorb the absorbed H ₂ S and COS. Played. The regenerated exhaust gas 22 is guided to the incinerator 24, and the sulfur compound in the regenerated exhaust gas 22 is oxidized to sulfur dioxide by the air 23. In the incinerator 24, auxiliary fuel 32 such as oil and LPG is always burned in order to keep the flame stable. The combustion exhaust gas 25 generated in the incinerator 24 is a gas having a temperature of 500 to 1000 ° C. and contains several vol% of SO ₂ , so that it is 150 to 250 ° C. (5 After generating and cooling water vapor (atmospheric pressure to 40 atmospheric pressure), it is guided to the absorption tower 27. In the absorption tower 27, by contacting the limestone slurry 28 and the combustion exhaust gas 25, the SO ₂ contained in the combustion exhaust gas 25 is absorbed and removed until the SO ₂ content in the plant exhaust gas 44 at the outlet of the chimney 18 becomes the environmental regulation value or less. Is done. From the lower part of the absorption tower 27, calcium sulfite 42 produced by the reaction of the limestone slurry 28 with SO ₂ is extracted and then led to the oxidation tower 41 where it is oxidized by the air 40 to become calcium sulfate 43. . The calcium sulfate 43 is sent to the thickener 29, and after dehydration, the gypsum 30 is recovered.
[0017]
At the start of the gasification furnace, heavy oil or light oil of the auxiliary fuel 45 is burned with air or oxygen in the coal gasification furnace 10 to obtain a high-temperature combustion gas, and the temperature rise between the coal gasification furnace 10 and the dust removing device 13 is increased. Boost the voltage. The combustion exhaust gas 35 at this time passes through the incinerator 24 by operating the switching valves 33 and 34 to bypass the de-H ₂ S tower 14. In the incinerator 24, the auxiliary fuel 32 is burned with air. The combustion exhaust gas 25 containing SO ₂ at the outlet of the incinerator is cooled by a heat exchanger 26 and then led to an absorption tower 27 that performs desulfurization with limestone. Thereby, it is possible to remove SO _{2 in} the exhaust gas 35 at the time of startup. In addition, after the temperature rise between the coal gasifier 10 and the dedusting device 13 is completed, the sulfur content in the exhaust gas changes from SO ₂ to H ₂ S at the start of coal input to the gasifier 10. In this case, since H ₂ S is oxidized to SO ₂ in the incinerator 24, the sulfur content in the exhaust gas is desulfurized even when the gasifier fuel is switched, and the environmental conservation is maintained. The SO ₂ in the combustion exhaust gas 25 reacts with the limestone slurry in the absorption tower 27, and the gypsum 30 is recovered.
[0018]
The combustion exhaust gas 25 discharged from the incinerator 24 is heat-exchanged by the heat exchanger 26 as described above, and the incineration heat is recovered, and the steam 37 is generated by the recovery. Here, 36 is boiler water, 38 is a boiler water circulation pump, and 39 is a steam drum. The temperature of the steam 37 is set to approximately 200 ° C., and the heat energy generated in the incinerator 24 is used as a heat source for absorbing and heating the absorbing liquid in the regeneration tower 21. This eliminates the need to take measures such as partially depressurizing the high-pressure steam 31 required for power generation.
[0019]
Other specific examples of the present invention include a system that uses air instead of oxygen as a gasification agent for coal, a system that uses a fuel cell instead of a gas turbine, and the like.
[0020]
【The invention's effect】
According to the present invention, the amount of sulfur oxide generated when the gasification furnace is started to the atmosphere is greatly reduced without passing through the desulfurization apparatus, and the environmental conservation is excellent without impairing the coal gas desulfurization capability. Realize the device. Furthermore, the energy loss of the high-pressure steam recovered in the system can be reduced, and higher power generation efficiency can be obtained, and an economical coal gasification combined power generation apparatus can be provided.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a combined coal gasification combined power generation apparatus according to the present invention.
FIG. 2 is a configuration diagram of a conventional coal gasification combined power generation device.
[Explanation of symbols]
1 air separation unit 8 coal 10 gasifier 11 crude gas 12 heat recovery boiler 14 de H ₂ S tower 21 regenerator 22 regeneration exhaust gas 24 incinerator 25 flue gas 26 heat exchanger 27 absorbing tower 29 thickener -
31 High-pressure steam 37 Low-pressure steam 39 Steam drum 41 Oxidation tower 45 Start-up fuel

Claims (5)

Coal is gasified in a coal gasification furnace with oxygen or a gasifying agent containing oxygen as a main component, and the H ₂ S-containing exhaust gas generated when the gas is desulfurized with a wet desulfurization facility is incinerated in an incinerator. In a coal gasification combined cycle power generation system that recovers sulfur content in coal as gypsum by reacting combustion gas generated by combustion with limestone, introducing means for introducing exhaust gas generated at the start of the coal gasification furnace to the incinerator A coal gasification combined cycle power generation system comprising: Coal is gasified in a coal gasification furnace with oxygen or a gasifying agent containing oxygen as a main component, and the H ₂ S-containing exhaust gas generated when the gas is desulfurized with a wet desulfurization facility is incinerated in an incinerator. In a combined coal gasification combined power generation system that recovers sulfur in coal as gypsum by reacting combustion gas generated by combustion with limestone, the exhaust gas generated at the start of the coal gasification furnace is led to the incinerator, and the exhaust gas Coal gasification combined cycle power generation system that collects sulfur content in gypsum. Coal is gasified in a coal gasification furnace with oxygen or a gasifying agent containing oxygen as a main component, and the H ₂ S-containing exhaust gas generated when the gas is desulfurized with a wet desulfurization facility is incinerated in an incinerator. In a coal gasification combined power generation system that recovers sulfur content in coal as gypsum by reacting combustion gas generated by combustion with limestone, regeneration of the absorption liquid of the desulfurization facility using exhaust heat of the exhaust gas from the incinerator Coal gasification comprising: a regeneration steam generating means for generating water vapor as a regeneration heat source for the tower; and a means for sending the steam generated by the regeneration steam generation means to the heat source section of the absorption liquid regeneration tower Combined power generator. Coal is gasified in a coal gasification furnace with oxygen or a gasifying agent containing oxygen as a main component, and the H ₂ S-containing exhaust gas generated when the gas is desulfurized with a wet desulfurization facility is incinerated in an incinerator. In a coal gasification combined cycle power generation system that recovers sulfur content in coal as gypsum by reacting combustion gas generated by combustion with limestone, the regeneration heat source of the absorption liquid regeneration tower using the exhaust heat of the exhaust gas from the incinerator A coal gasification combined power generation apparatus characterized by using the steam as a heat source for regenerating an absorbent in the wet desulfurization facility. A coal gasification combined cycle power generation device having the features of claim 1 or 2 and claim 3 or 4.

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