JP2013174249A - Gas turbine power generation system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To greatly reduce a corrosion amount of a component of a gas turbine even when a heavy oil fuel is used.SOLUTION: A gas turbine power generation system includes: a separation device (e.g. a pyrolysis device 30 or a distillation device 3 and the pyrolysis device 30) separating light oil from the heavy oil fuel; and a gas turbine 1 generating power by a generator 11 by rotationally driving a turbine 9 (or a post-stage side turbine 37) by a combustion gas generated by burning the mixed gas of the light oil from the separation device and compressed air compressed by a compressor 7 in a combustor 8. As a result, the corrosion amount of a component of the gas turbine can be greatly reduced even when the heavy oil fuel is used.

Description

  The present invention relates to a gas turbine power generation system. In particular, the present invention relates to a gas turbine power generation system using heavy oil fuel.

  This type of gas turbine power generation system is conventionally known (see, for example, Patent Document 1). Hereinafter, this conventional gas turbine power generation system will be described. This conventional gas turbine power generation system is a gas having a fuel reformer that produces reformed fuel using high-temperature and high-pressure water and heavy oil fuel, and a combustor that burns the reformed fuel produced by the fuel reformer. A turbine.

  Here, the heavy oil fuel is heavy oil which is a petroleum product obtained by mixing a crude oil atmospheric residue (residual oil) and a light oil fraction (light oil). And the said light oil does not contain a corrosive component (for example, vanadium (V), a vanadium compound, a sodium compound, a sulfur compound, etc.), or it is a trace amount even if it contains. However, the residual oil contains a corrosive component.

  For this reason, if the heavy oil fuel is used as it is, there is a possibility that parts of the gas turbine are corroded by the corrosive component. Therefore, as in the conventional gas turbine power generation system, it is necessary to reform heavy oil fuel to reduce the amount of corrosion of gas turbine components.

JP 2007-278152 A

  The problem to be solved by the present invention is that the amount of corrosion of gas turbine components can be greatly reduced even if heavy oil fuel is used.

  The present invention (invention according to claim 1) is a separation device for separating light oil from heavy oil fuel in a gas turbine power generation system, and the heavy oil fuel is distilled to contain light oil and corrosive components. Distillation device that separates heavy oil fuel into pyrolyzed oil, heavy oil fuel is pyrolyzed with high-temperature water to separate light oil and residual oil containing corrosive components, and heavy oil fuel is distilled The primary separation light oil is separated from the primary separation light oil and the residual oil containing corrosion components, and the primary separation light oil from the distillation device is pyrolyzed with high-temperature water to contain light oil and corrosion components. It was generated by combusting a mixture of light separation oil from the separation device and compressed air compressed by the compressor in the combustor, which is one of the pyrolysis devices that separate the residual oil into the residual oil. The turbine is rotated by combustion gas and the generator An exhaust gas recovery combustor as a residual oil combustor that burns residual oil from the separator, and an exhaust gas combustion as a residual oil combustor that burns residual oil from the separator It comprises any one of a regenerative heat exchanger using heat generated in the heat source as a heat source, and a reheating combustor as a residual oil combustor that burns residual oil from the separator.

  The present invention (invention according to claim 2) is a separator for separating light oil from heavy oil fuel in a gas turbine power generation system, wherein the heavy oil fuel is distilled to remove light oil and corrosive components. Equipment for separating oil into residual oil containing heavy oil, pyrolysis equipment for heavy oil fuel pyrolysis with high-temperature water and separating it into light oil and residual oil containing corrosive components, heavy oil fuel Is distilled into primary oils and residual oils containing corrosive components, and the primary oils from the distiller are pyrolyzed with high-temperature water to contain light oils and corrosive components. Combustion of a mixture of a separation device, which is any one of the thermal cracking devices that separate into the residual oil, and light oil from the separation device and compressed air compressed by the compressor, in a combustor The turbine is rotated by the generated combustion gas and generated. An exhaust gas heavy oil fuel heater that heats heavy oil fuel with exhaust gas, a steam heavy oil fuel heater that heats heavy oil fuel with steam, and a heavy oil fuel It is provided with any one of the light oil heavy oil fuel heater heated with light oil.

  Furthermore, the present invention (invention according to claim 3) is a separator for separating light oil from heavy oil fuel in a gas turbine power generation system, wherein the heavy oil fuel is distilled to light oil and corrosive components. Equipment for separating oil into residual oil containing heavy oil, pyrolysis equipment for heavy oil fuel pyrolysis with high-temperature water and separating it into light oil and residual oil containing corrosive components, heavy oil fuel Is distilled into primary oils and residual oils containing corrosive components, and the primary oils from the distiller are pyrolyzed with high-temperature water to contain light oils and corrosive components. Combustion of a mixture of a separation device, which is any one of the thermal cracking devices that separate into the residual oil, and light oil from the separation device and compressed air compressed by the compressor, in a combustor The turbine is driven to rotate by the generated combustion gas. An exhaust gas combustor that burns residual oil from the separator, a regenerative heat exchanger that uses heat generated in the exhaust gas combustor as a heat source, and regenerative heat exchange of heavy oil fuel An exhaust gas heavy oil fuel heater heated by exhaust gas on the downstream side or upstream side of the vessel.

  Furthermore, the present invention (invention according to claim 4) includes an exhaust heat recovery boiler, and a steam turbine that rotationally drives the steam from the exhaust heat recovery boiler to generate electric power with a generator. And

  The gas turbine power generation system of the present invention can greatly reduce the amount of corrosion of gas turbine components even when heavy oil fuel is used.

BRIEF DESCRIPTION OF THE DRAWINGS It is a block diagram which shows Embodiment 1 of the gas turbine power generation system concerning this invention. It is a block diagram which shows Embodiment 2 of the gas turbine power generation system concerning this invention. It is a block diagram which shows Embodiment 3 of the gas turbine power generation system concerning this invention. It is a block diagram which shows Embodiment 4 of the gas turbine power generation system concerning this invention. It is a block diagram which shows Embodiment 5 of the gas turbine power generation system concerning this invention. It is a block diagram which shows Embodiment 6 of the gas turbine power generation system concerning this invention. It is a block diagram which shows Embodiment 7 of the gas turbine power generation system concerning this invention. It is a block diagram which shows Embodiment 8 of the gas turbine power generation system concerning this invention. It is a block diagram which shows Embodiment 9 of the gas turbine power generation system concerning this invention. It is a block diagram which shows Embodiment 10 of the gas turbine power generation system concerning this invention. It is a block diagram which shows Embodiment 11 of the gas turbine power generation system concerning this invention. It is a block diagram which shows Embodiment 12 of the gas turbine power generation system concerning this invention. It is a block diagram which shows Embodiment 13 of the gas turbine power generation system concerning this invention. It is a block diagram which shows Embodiment 14 of the gas turbine power generation system concerning this invention. It is a block diagram which shows Embodiment 15 of the gas turbine power generation system concerning this invention. It is a block diagram which shows Embodiment 16 of the gas turbine power generation system concerning this invention.

  Hereinafter, 16 examples of embodiments of a gas turbine power generation system according to the present invention will be described in detail with reference to the accompanying drawings. In addition, this invention is not limited by this embodiment.

“Description of Embodiment 1”
FIG. 1 is a configuration diagram showing Embodiment 1 of a gas turbine power generation system according to the present invention. The gas turbine power generation system according to Embodiment 1 is a combined power generation system (combined cycle), which includes a gas turbine 1, an exhaust heat recovery boiler (waste heat recovery boiler, exhaust gas boiler) 2, and a distillation apparatus as a separation device. 3, a residual oil combustor 4, an exhaust gas heavy oil fuel heater 5, and a steam turbine 6.

  The gas turbine 1 includes a compressor 7, a combustor 8, and a turbine 9. The compressor 7 and the turbine 9 are connected via a turbine shaft 10. A generator 11 is connected to the turbine 9. An air (intake) line 12 for taking in air is connected to the inlet side of the compressor 7. On the other hand, an exhaust gas (exhaust) line 13 for discharging combustion gas is connected to the outlet side of the turbine 9. A compressed air line 14 for sending compressed air from the compressor 7 to the combustor 8 is connected between the outlet side of the compressor 7 and the inlet side of the combustor 8. A combustion gas line 15 is connected between the outlet side of the combustor 8 and the inlet side of the turbine 9 to send combustion gas from the combustor 8 to the turbine 9.

  A chimney 16 is connected to the exhaust gas line 13. The exhaust heat recovery boiler 2 is provided in the middle of the exhaust gas line 13 between the turbine 9 and the chimney 16. A water line 17 for supplying water is connected to the inlet side of the exhaust heat recovery boiler 2. On the other hand, a steam (steam) line 18 for discharging steam (steam) is connected to the outlet side of the exhaust heat recovery boiler 2.

  The distillation apparatus 3 is an apparatus for separating (distilling) light oil (in this example, gasified light oil) from heavy oil fuel. That is, the distillation apparatus 3 is an apparatus that separates (distills) heavy oil fuel into gasified light oil and residual oil. The gasified light oil contains no or even a corrosive component even if it is contained. A heavy oil fuel line 19 for supplying heavy oil fuel is connected to the inlet side of the distillation apparatus 3. Further, a gasified light oil line 20 for discharging gasified light oil is connected to the first outlet side of the distillation apparatus 3. In the middle of the gasified light oil line 20, a compressor 21 for compressing the gasified light oil is provided. Further, the second outlet side of the distillation apparatus 3 is connected to a residue oil line 22 for discharging a residue obtained by separating light oil from heavy oil fuel, that is, a residue oil containing a corrosive component.

  The residual oil combustor 4 burns the residual oil from the distillation apparatus 3. In this example, the residual oil combustor 4 is the exhaust heat recovery boiler 2 and has an integrated structure with the exhaust heat recovery boiler 2. That is, the residual oil combustor 4 is provided in the exhaust heat recovery boiler 2. The residual oil line 22 is connected to the inlet side of the residual oil combustor 4.

  The exhaust gas heavy oil fuel heater 5 preheats heavy oil fuel with exhaust gas. The exhaust gas heavy oil fuel heater 5 is provided in the middle of the heavy oil fuel line 19. In this example, the exhaust gas heavy oil fuel heater 5 is the exhaust heat recovery boiler 2 and has an integral structure with the exhaust heat recovery boiler 2. That is, the exhaust gas heavy oil fuel heater 5 is provided in the exhaust heat recovery boiler 2.

  The steam line 18 is connected to the inlet side of the steam turbine 6. A generator 23 is connected to the steam turbine 6.

  The gas turbine power generation system according to Embodiment 1 is configured as described above, and the operation thereof will be described below.

  The compressor 7 of the gas turbine 1 compresses the air sucked from the air line 12 to generate compressed air. This compressed air is sent from the compressor 7 to the combustor 8 via the compressed air line 14. On the other hand, the gasified light oil separated by the distillation apparatus 3 remains in a high-temperature gas state, passes through the gasified light oil line 20, and is compressed by the compressor 21 on the way to the combustor 8 from the distillation apparatus 3. Sent. The combustor 8 burns a mixture of compressed air and gasified light oil to generate combustion gas. This combustion gas is sent from the combustor 8 to the turbine 9 through the combustion gas line 15. With this combustion gas, the turbine 9 is rotationally driven to rotate the generator 11 to generate electric power.

  The combustion gas that rotationally drives the turbine 9 is sent as exhaust gas from the turbine 9 to the exhaust heat recovery boiler 2 via the exhaust gas line 13. The exhaust gas sent to the exhaust heat recovery boiler 2 exchanges heat with water supplied through the water line 17. The exhaust gas heat-exchanged with water is sent again to the chimney 16 from the exhaust heat recovery boiler 2 through the exhaust gas line 13 and discharged from the chimney 16 to the outside. The water exchanged with the exhaust gas by the exhaust heat recovery boiler 2 becomes steam. This steam is sent from the exhaust heat recovery boiler 2 to the steam turbine 6 through a steam line 18. With this steam, the steam turbine 6 is rotationally driven to rotate the generator 23 to generate power.

  The heavy oil fuel that is the raw material of the gasified light oil is sent to the exhaust gas heavy oil fuel heater 5 integrated with the exhaust heat recovery boiler 2 via the heavy oil fuel line 19. The heavy oil fuel sent to the exhaust gas heavy oil fuel heater 5 is preheated by the exhaust gas from the turbine 9. The heated heavy oil fuel is again sent to the distillation apparatus 3 from the exhaust gas heavy oil fuel heater 5 through the heavy oil fuel line 19. The distillation apparatus 3 separates gasified light oil from the heated heavy oil fuel.

  As described above, the gasified light oil separated from the heavy oil fuel in the distillation apparatus 3 is compressed by the compressor 21 through the gasified light oil line 20 and on the way, and sent from the distillation apparatus 3 to the combustor 8. The combustor 8 is mixed with compressed air and burned. On the other hand, the residual oil after the gasified light oil is separated from the heavy oil fuel in the distillation apparatus 3 passes from the distillation apparatus 3 to the residual oil combustor 4 integrated with the exhaust heat recovery boiler 2 via the residual oil line 22. It is sent and burned in the residual oil combustor 4.

  The gas turbine power generation system according to the first embodiment is configured and operated as described above, and the effects will be described below.

  In the gas turbine power generation system according to the first embodiment, gasified light oil is separated from heavy oil fuel by the distillation device 3 serving as a separation device. Therefore, the gasified light oil does not contain a corrosive component or Even if contained, the amount is extremely small, and the gasified light oil is used to drive the gas turbine 1 to generate electric power. For this reason, the gas turbine power generation system according to the first embodiment greatly reduces the amount of corrosion of the components of the gas turbine 1 (for example, stationary blades and turbine blades of moving blades) even when heavy oil fuel is used. can do.

  Further, the gas turbine power generation system according to the first embodiment is a distillation device 3 in which the separation device distills heavy oil fuel into gasified light oil and residual oil containing a corrosive component. Corrosive components in gasified light oil can be surely reduced. For this reason, the gas turbine power generation system according to the first embodiment can reliably significantly reduce the amount of corrosion of the components of the gas turbine 1.

  In particular, in the gas turbine power generation system according to the first embodiment, since the separation device is the distillation device 3, gasified light oil can be easily and efficiently separated from heavy oil fuel, and the gas turbine 1 The amount of corrosion of these parts can be further significantly reduced.

  Furthermore, in the gas turbine power generation system according to the first embodiment, the residual oil from the distillation flow device 3 as a separator is combusted in the residual heat combustor 4 integrated with the exhaust heat recovery boiler 2 provided in the exhaust gas line 13. Therefore, the efficiency of the exhaust heat recovery boiler 2 is improved. That is, since the viscosity of the residual oil decreases when heated, if it is atomized (for example, steam atomized), combustion in the exhaust heat recovery boiler 2 is possible, and the efficiency of the exhaust heat recovery boiler 2 is improved. Moreover, in the gas turbine power generation system according to the first embodiment, the residual oil from the distillation device 3 as a separation device is obtained by the residual oil combustor 4 that is integrated with the exhaust heat recovery boiler 2 that has a lower temperature than the turbine 9. Since combustion is performed, high-temperature corrosion does not occur in the components of the exhaust heat recovery boiler 2 and the residual oil combustor 4. For example, since the boiler tube has a lower temperature than the turbine 9, high temperature corrosion does not occur. In addition, in the gas turbine power generation system according to the first embodiment, the residual oil from the distillation device 3 as a separation device is not combusted in the combustor 8 of the gas turbine 1 and is integrated with the exhaust heat recovery boiler 2. Since combustion is performed in the combustor 4, corrosion does not occur in the components of the gas turbine 1.

  Here, the corrosive action due to the corrosive component occurs remarkably when the corrosive component is in a liquid phase (liquid), and hardly occurs when the corrosive component is in a gas phase (gas) state and a solid phase (solid) state. Or, if it happens, it is minor. For this reason, in the gas turbine power generation system according to the first embodiment, the residual oil from the distillation device 3 as the separation device is burned in the residual oil combustor 4 integrated with the exhaust heat recovery boiler 2, so that the residual oil is contained in the residual oil. Since the corrosive component contained in the gas phase is in a gas phase (gas), corrosion in the exhaust heat recovery boiler 2 and the residual oil combustor 4 can be prevented.

  Furthermore, in the gas turbine power generation system according to the first embodiment, the heavy oil fuel is heated by the exhaust gas with the exhaust gas heavy oil fuel heater 5 integrated with the exhaust heat recovery boiler 2, so that the distillation apparatus as a separation device The separation efficiency of gasified light oil from heavy oil fuel in 3 is improved.

  Furthermore, in the gas turbine power generation system according to Embodiment 1, the power generation efficiency is improved by the combined power generation system (combined cycle) of the gas turbine 1 and the steam turbine 6.

“Description of Embodiment 2”
FIG. 2 is a configuration diagram showing Embodiment 2 of the gas turbine power generation system according to the present invention (first modification of Embodiment 1). 2, the same reference numerals as those in FIG. 1 denote the same components.

  The difference between the gas turbine power generation system according to the second embodiment and the gas turbine power generation system according to the first embodiment is a heavy oil fuel heating apparatus. In other words, the heavy oil fuel heating device in the gas turbine power generation system according to the first embodiment is an exhaust gas heavy oil fuel heater 5 integrated with the exhaust heat recovery boiler 2, and the heavy oil fuel is converted into a turbine. 9 is preheated by the exhaust gas from No.9.

  On the other hand, the heavy oil fuel heating device in the gas turbine power generation system according to the second embodiment is a steam heavy oil fuel heater 24 that preheats the heavy oil fuel with the steam from the exhaust heat recovery boiler 2. The steam heavy oil fuel heater 24 is provided in the middle of the heavy oil fuel line 19 and in the middle of the branch steam line 25 branched from the steam line 18. The branch steam line 25 branches from the steam line 18 and is connected to the steam heavy oil fuel heater 24 via the exhaust heat recovery boiler 2 again, and the steam heavy oil fuel heater 24. To the condenser 26.

  The gas turbine power generation system according to the second embodiment is configured as described above, and the operation thereof will be described below. Since the gas turbine power generation system according to the second embodiment is different from the gas turbine power generation system according to the first embodiment in the heavy oil fuel heating device, the operation of the heavy oil fuel heating device will be described. The description of the operation of other devices is omitted.

  The heavy oil fuel that is the raw material of the gasified light oil is sent to the steam heavy oil fuel heater 24 via the heavy oil fuel line 19. The heavy oil fuel sent to the steam heavy oil fuel heater 24 is preheated by the steam from the exhaust heat recovery boiler 2. The heated heavy oil fuel is sent again from the vapor heavy oil fuel heater 24 to the distillation apparatus 3 through the heavy oil fuel line 19.

  On the other hand, a part of the steam sent from the exhaust heat recovery boiler 2 to the steam turbine 6 via the steam line 18 is sent again to the exhaust heat recovery boiler 2 via the branch steam line 25 branched from the steam line 18 and is discharged. It is overheated again by the heat recovery boiler 2. The steam superheated again by the exhaust heat recovery boiler 2 is sent from the exhaust heat recovery boiler 2 to the steam heavy oil fuel heater 24 via the branch steam line 25, and is then heavy by the steam heavy oil fuel heater 24. Heat the quality oil fuel in advance. The steam obtained by preheating the heavy oil fuel with the steam heavy oil fuel heater 24 is sent from the steam heavy oil fuel heater 24 to the condenser 26 via the branch steam line 25.

  Since the gas turbine power generation system according to the second embodiment is configured and operated as described above, substantially the same effects as those of the gas turbine power generation system according to the first embodiment can be achieved.

  In particular, the gas turbine power generation system according to the second embodiment uses a steam heavy oil fuel heater 24 that preheats heavy oil fuel with steam from the exhaust heat recovery boiler 2 as a heavy oil fuel heating device. Is. For this reason, even if heavy oil fuel leaks from the heavy oil fuel line 19 in the steam heavy oil fuel heater 24, there is no particular problem.

“Description of Embodiment 3”
FIG. 3 is a block diagram showing Embodiment 3 (second modification of Embodiment 1) of the gas turbine power generation system according to the present invention. 3, the same reference numerals as those in FIGS. 1 and 2 denote the same components.

  The difference between the gas turbine power generation system according to the third embodiment and the gas turbine power generation system according to the first embodiment is a heavy oil fuel heating apparatus. In other words, the heavy oil fuel heating device in the gas turbine power generation system according to the first embodiment is an exhaust gas heavy oil fuel heater 5 integrated with the exhaust heat recovery boiler 2, and the heavy oil fuel is converted into a turbine. 9 is preheated by the exhaust gas from No.9.

  On the other hand, the heavy oil fuel heating apparatus in the gas turbine power generation system according to Embodiment 3 is a gasified light heavy oil that heats the heavy oil fuel in advance with the light oil from the distillation apparatus 3, that is, the gasified light oil. This is a fuel heater 27. The gasified light oil heavy oil fuel heater 27 is provided in the middle of the heavy oil fuel line 19. A gasified light oil line 20 is connected between the distillation apparatus 3 and the gasified light oil heavy oil fuel heater 27. A light oil line 28 is connected between the gasified light oil heavy oil fuel heater 27 and the combustor 8. A pump 29 is provided in the middle of the light oil line 28.

  The gas turbine power generation system according to the third embodiment is configured as described above, and the operation thereof will be described below. Since the gas turbine power generation system according to the third embodiment is different from the gas turbine power generation system according to the first embodiment in the heavy oil fuel heating device, the operation of the heavy oil fuel heating device will be described. The description of the operation of other devices is omitted.

  The heavy oil fuel that is the raw material of the gasified light oil is sent to the gasified light oil heavy oil fuel heater 27 via the heavy oil fuel line 19. The heavy oil fuel sent to the gasified light oil heavy oil fuel heater 27 is preheated by the gasified light oil from the distillation apparatus 3. The heated heavy oil fuel is sent from the gasified light oil heavy oil fuel heater 27 to the distillation apparatus 3 through the heavy oil fuel line 19.

  On the other hand, the gasified light oil sent from the distillation apparatus 3 to the gasified light oil heavy oil fuel heater 27 via the gasified light oil line 20 is heavy in the gasified light oil heavy oil fuel heater 27. Preheat oil fuel. The gasified light oil obtained by heating the heavy oil fuel in advance with the gasified light oil heavy oil fuel heater 27 is condensed into light oil. The condensed light oil is sent from the gasified light oil heavy oil fuel heater 27 to the combustor 8 through the light oil line 28 and through the pump 29.

  Since the gas turbine power generation system according to the third embodiment is configured and operated as described above, substantially the same effects as those of the gas turbine power generation system according to the first embodiment can be achieved.

  In particular, the gas turbine power generation system according to Embodiment 3 is a gasified light oil heavy oil fuel heater that preheats heavy oil fuel with gasified light oil from the distillation device 3 as a heavy oil fuel heating device. 27 is used. Therefore, even if heavy oil fuel leaks from the heavy oil fuel line 19 in the gasified light oil heavy oil fuel heater 27, there is no particular problem.

“Description of Embodiment 4”
FIG. 4 is a configuration diagram showing Embodiment 4 (third modification of Embodiment 1) of the gas turbine power generation system according to the present invention. 4, the same reference numerals as those in FIGS. 1 to 3 denote the same components.

  The difference between the gas turbine power generation system according to the fourth embodiment and the gas turbine power generation system according to the first embodiment is a separation device that separates light oil from heavy oil fuel. That is, the separation device in the gas turbine power generation system according to the first embodiment is the distillation device 3.

  On the other hand, the separation device in the gas turbine power generation system according to the fourth embodiment is a thermal decomposition device 30. A heavy oil fuel line 19 is connected to the first inlet side of the thermal decomposition apparatus 30. A gasified light oil line 20 is connected to the outlet side of the thermal decomposition apparatus 30. Further, a branch steam line 25 is connected to the second inlet side of the thermal decomposition apparatus 30. The thermal decomposition apparatus 30 is an apparatus that separates (thermally decomposes) gasified light oil from heavy oil fuel. That is, the distillation apparatus 3 is an apparatus that separates (thermally decomposes) heavy oil fuel into gasified light oil and residual oil. The distillation apparatus 3 is an apparatus that thermally decomposes heavy oil fuel and reforms it into gasified light oil, carbon monoxide (CO) gas, hydrogen (H2) gas, or the like.

  The gas turbine power generation system according to Embodiment 4 is configured as described above, and the operation thereof will be described below. Since the gas turbine power generation system according to the fourth embodiment is different from the gas turbine power generation system according to the first embodiment in the separation device, the operation of the separation device will be described, and the operation of other devices will be described. Omitted.

  The heavy oil fuel that is the raw material for the gasified light oil is sent to the thermal cracking device 30 via the heavy oil fuel line 19. On the other hand, a part of the steam sent from the exhaust heat recovery boiler 2 to the steam turbine 6 via the steam line 18 is sent again to the exhaust heat recovery boiler 2 via the branch steam line 25 branched from the steam line 18. It is overheated again by the exhaust heat recovery boiler 2. The steam superheated again by the exhaust heat recovery boiler 2 is sent from the exhaust heat recovery boiler 2 to the thermal decomposition apparatus 30 via the branch steam line 25.

  In this thermal decomposition apparatus 30, heavy oil fuel is thermally decomposed by high-temperature water (steam) and contains gasified light oil, carbon monoxide (CO) gas, hydrogen (H2) gas, and the like, and corrosive components. Separated into residual oil. The gasified light oil, carbon monoxide (CO) gas, hydrogen (H2) gas, etc. separated in the pyrolyzer 30 are combusted from the pyrolyzer 30 through the gasified light oil line 20 and through the compressor 21. 8 is sent. On the other hand, the residual oil obtained by separating gasified light oil, carbon monoxide (CO) gas, hydrogen (H2) gas, and the like from the heavy oil fuel in the thermal cracking device 30 passes through the residual oil line 22 and is then used in the thermal cracking device. 30 to the residual oil combustor 4.

  Since the gas turbine power generation system according to the fourth embodiment is configured and operated as described above, substantially the same effects as the gas turbine power generation system according to the first embodiment can be achieved.

  In particular, the gas turbine power generation system according to Embodiment 4 uses gasified light oil, carbon monoxide (CO) gas, and hydrogen (H2) as a separation device by pyrolyzing heavy oil fuel with high-temperature water (steam). Since the thermal decomposition apparatus 30 which separates into gas etc. and the residual oil containing a corrosive component is used, the corrosive component in light oil can be reduced reliably.

  In addition, since the gas turbine power generation system according to the fourth embodiment uses the pyrolysis device 30 as a separation device, gas fueled light oil and carbon monoxide (CO) gas or hydrogen (H 2) ) Gas etc. can be separated easily and efficiently.

  In the gas turbine power generation system according to the fourth embodiment, the heavy oil fuel heating device, for example, the exhaust gas heavy oil fuel heater 5 of the first embodiment or the heavy steam fuel of the second embodiment. The oil fuel heater 24 or the gasified light oil heavy oil fuel heater 27 of the third embodiment may be provided.

“Description of Embodiment 5”
FIG. 5 is a configuration diagram showing Embodiment 5 (fourth modification of Embodiment 1) of the gas turbine power generation system according to the present invention. In FIG. 5, the same reference numerals as those in FIGS.

  The difference between the gas turbine power generation system according to the fifth embodiment and the gas turbine power generation system according to the first embodiment is a separation device that separates light oil from heavy oil fuel. That is, the separation device in the gas turbine power generation system according to the first embodiment is the distillation device 3.

  On the other hand, the separation apparatus in the gas turbine power generation system according to Embodiment 5 is composed of a primary distillation apparatus 3 and a secondary pyrolysis apparatus 30. That is, the separation apparatus in the gas turbine power generation system according to the fifth embodiment includes the thermal decomposition apparatus 30 in the middle of the gasified light oil line 20 of the gas turbine power generation system according to the first embodiment.

  A gasified light oil line 20 from the distillation apparatus 3 is connected to the first inlet side of the pyrolysis apparatus 30. A gasified light oil line 20 connected to the combustor 8 via the compressor 21 is connected to the first outlet side of the thermal decomposition apparatus 30. Further, a residual oil line 22 connected to the residual oil combustor 4 is connected to the second outlet side of the thermal decomposition apparatus 30. Furthermore, a branch steam line 31 from the exhaust gas recovery boiler 2 is connected to the second inlet side of the thermal decomposition apparatus 30.

  The gas turbine power generation system according to Embodiment 5 is configured as described above, and the operation thereof will be described below. Since the gas turbine power generation system according to the fifth embodiment is different from the gas turbine power generation system according to the first embodiment in the separation device, the operation of the separation device will be described, and the operation of other devices will be described. Omitted.

  The heavy oil fuel that is the raw material of the gasified light oil is sent to the exhaust gas heavy oil fuel heater 5 integrated with the exhaust heat recovery boiler 2 via the heavy oil fuel line 19. The heavy oil fuel sent to the exhaust gas heavy oil fuel heater 5 is preheated by the exhaust gas from the turbine 9. The heated heavy oil fuel is again sent to the distillation apparatus 3 from the exhaust gas heavy oil fuel heater 5 through the heavy oil fuel line 19. The distillation apparatus 3 primarily separates gasified light oil from the heated heavy oil fuel.

  The gasified light oil primarily separated from the heavy oil fuel in the distillation apparatus 3 is sent from the distillation apparatus 3 to the thermal cracking apparatus 30 via the gasified light oil line 20. Further, a part of the steam sent from the exhaust heat recovery boiler 2 to the steam turbine 6 through the steam line 18 passes through the branch steam line 31 branched from the exhaust heat recovery boiler 2 and then from the exhaust heat recovery boiler 2 to the thermal decomposition apparatus 30. Sent to. On the other hand, the remaining residual oil from which the first gasified light oil has been separated from the heavy oil fuel in the distillation apparatus 3 is sent from the distillation apparatus 3 to the residual oil combustor 4 via the residual oil line 22.

  In this pyrolysis apparatus 30, gasified light oil of primary separation is thermally decomposed by high-temperature water (steam) and contains gasified light oil, carbon monoxide (CO) gas, hydrogen (H2) gas, and the like, and corrosive components. And separated residual oil. The gasified light oil, carbon monoxide (CO) gas, hydrogen (H2) gas, etc. separated in the pyrolyzer 30 are combusted from the pyrolyzer 30 through the gasified light oil line 20 and through the compressor 21. 8 is sent. On the other hand, the residual oil obtained by separating the gasified light oil, carbon monoxide (CO) gas, hydrogen (H2) gas, etc. from the gasified light oil of the primary separation in the pyrolysis apparatus 30 passes through the residual oil line 22. It is sent from the thermal decomposition apparatus 30 to the residual oil combustor 4.

  Since the gas turbine power generation system according to the fifth embodiment is configured and operated as described above, substantially the same effects as the gas turbine power generation system according to the first embodiment can be achieved.

  In particular, in the gas turbine power generation system according to the fifth embodiment, as a separation device, a distillation device 3 for distilling heavy oil fuel into primary separated gasified light oil and residual oil containing corrosive components. And gasification light oil of the primary separation from the distillation apparatus 3 is pyrolyzed with high-temperature water and contains gasification light oil, carbon monoxide (CO) gas, hydrogen (H2) gas, and the like and corrosive components. Since it is comprised from the thermal decomposition apparatus 30 isolate | separated into residual oil, the corrosive component in the gasification light oil primary-separated from the heavy oil fuel can be reduced reliably.

  Further, in the gas turbine power generation system according to the fifth embodiment, since the separation device is composed of the distillation device 3 and the thermal decomposition device 30, the distillation device 3 converts gasified light oil from heavy oil fuel. Primary separation can be easily performed, and gasified light oil, carbon monoxide (CO) gas, hydrogen (H2) gas, etc. can be easily separated from the gasified light oil primarily separated by the thermal decomposition apparatus 30. Can do.

  Further, in the gas turbine power generation system according to the fifth embodiment, since the separation device is composed of the upstream distillation device 3 and the downstream pyrolysis device 30, the upstream distillation device 3 performs the heavy operation. Gasified light oil primarily separated from the fuel oil can be supplied to the thermal decomposition apparatus 30 on the downstream side. For this reason, in the gas turbine power generation system according to the fifth embodiment, the durability of the catalyst of the thermal decomposition apparatus 30 is improved as compared with a system that supplies heavy oil fuel to the thermal decomposition apparatus 30.

  In the gas turbine power generation system according to the fifth embodiment, the heavy oil fuel heating device uses the exhaust gas heavy oil fuel heater 5 of the first embodiment. Instead of the fuel heater 5, the steam heavy oil fuel heater 24 of the second embodiment or the gasified light oil heavy oil fuel heater 27 of the third embodiment may be used.

“Description of Embodiment 6”
FIG. 6 is a block diagram showing Embodiment 6 of the gas turbine power generation system according to the present invention. In FIG. 6, the same reference numerals as those in FIGS. 1 to 5 denote the same components.

  The difference between the gas turbine power generation system according to the sixth embodiment and the gas turbine power generation system according to the first embodiment is the structure of the residual oil combustor 4. That is, the residual oil combustor 4 in the gas turbine power generation system according to the first embodiment has an integrated structure with the exhaust heat recovery boiler 2, and the residual oil is integrated with the exhaust heat recovery boiler 2. It is made to burn with the residual oil combustor 4.

  On the other hand, the residual oil combustor 4 in the gas turbine power generation system according to the sixth embodiment is an exhaust gas combustor 32, and the residual oil is combusted by the exhaust gas combustor 32. The exhaust gas combustor 32 is provided in the middle of the exhaust gas line 13. A residual oil line 22 from the distillation apparatus 3 is connected to the exhaust gas combustor 32.

  The gas turbine power generation system according to Embodiment 6 includes a regenerative heat exchanger 33 that uses heat generated in the exhaust gas combustor 32 as a heat source. The regenerative heat exchanger 33 is provided in the middle of the exhaust gas line 13 and downstream of the exhaust gas combustor 32, that is, between the exhaust gas combustor 32 and the exhaust heat recovery boiler 2. The regenerative heat exchanger 33 is provided in the middle of the compressed air line 14 between the compressor 7 and the combustor 8 of the gas turbine 1.

  The exhaust gas heavy oil fuel heater 5 is provided integrally with the exhaust heat recovery boiler 2 on the downstream side of the regeneration heat exchanger 33.

  The gas turbine power generation system according to Embodiment 6 is configured as described above, and the operation thereof will be described below. Since the gas turbine power generation system according to the sixth embodiment is different from the gas turbine power generation system according to the first embodiment in the residual oil combustor 4, the exhaust gas combustor 32 and the regeneration as the residual oil combustor 4 are different. The operation of the heat exchanger 33 will be described, and description of the operation of other devices will be omitted.

  The heavy oil fuel is heated in advance by the exhaust gas heavy oil fuel heater 5 integrated with the exhaust heat recovery boiler 2 and sent to the distillation apparatus 3. The heavy oil fuel sent to the distillation apparatus 3 is separated into gasified light oil and residual oil by the distillation apparatus 3. The gasified light oil is sent to the combustor 8 through the gasified light oil line 20 and through the compressor 21.

  On the other hand, the residual oil is sent from the distillation apparatus 3 to the exhaust gas combustor 32 as the residual oil combustor 4 through the residual oil line 22 and burned in the exhaust gas combustor 32. Further, the exhaust gas sent from the turbine 9 to the exhaust gas combustor 32 is heated by the exhaust gas combustor 32. The exhaust gas sent from the turbine 9 is heated. The exhaust gas heated by the exhaust gas combustor 32 is directly sent to the regenerative heat exchanger 33 through the exhaust gas line 13, and the regenerated heat exchanger 33 exchanges heat with the compressed air in the compressed air line 14 to convert the compressed air. Heat. The exhaust gas heat-exchanged with the compressed air in the regenerative heat exchanger 33 is sent to the exhaust heat recovery boiler 2 through the exhaust gas line 13, and the heavy oil fuel in the heavy oil fuel line 19 is sent to the exhaust heat recovery boiler 2. Heat and exchange heat with water in the water line 17. The exhaust gas that heats the heavy oil fuel and exchanges heat with water in the exhaust heat recovery boiler 2 is sent to the chimney 16 through the exhaust gas line 13 and discharged from the chimney 16 to the outside.

  Since the gas turbine power generation system according to the sixth embodiment is configured and operated as described above, substantially the same effects as those of the gas turbine power generation system according to the first embodiment can be achieved.

  In particular, in the gas turbine power generation system according to the sixth embodiment, the residual oil from the distillation apparatus 3 is burned in the exhaust gas combustor 32 as the residual oil combustor 4 provided in the exhaust gas line 13 and is generated in the exhaust gas combustor 32. Since the generated heat is used as a heat source for the regenerative heat exchanger 33 provided in the compressed air line 14, the heat efficiency (turbine efficiency) of the heat cycle is improved. In addition, the gas turbine power generation system according to Embodiment 6 has a lower temperature than the turbine 9 and burns residual oil from the distillation apparatus 3 in the exhaust gas combustor 32 that is different from the high-temperature and high-pressure environment inside the turbine 9. In addition, since the heat of the exhaust gas combustor 32 is used as the heat source of the regenerative heat exchanger 33, high-temperature corrosion does not occur in the exhaust gas combustor 32 parts and the regenerative heat exchanger 33 parts, or even if hot corrosion occurs. Trace amount. Moreover, in the gas turbine power generation system according to the sixth embodiment, the residual oil from the distillation apparatus 3 is burned in the exhaust gas combustor 32 without being burned in the combustor 8 of the gas turbine 1. Corrosion does not occur.

  In the gas turbine power generation system according to the sixth embodiment, the residual oil from the distillation apparatus 3 is burned in the exhaust gas combustor 32 as the residual oil combustor 4 provided in the exhaust gas line 13. In almost the same manner as in such a gas turbine power generation system, the corrosive component contained in the residual oil is in a gas phase (gas), so that corrosion in the exhaust gas combustor 32 can be prevented.

  Further, in the gas turbine power generation system according to Embodiment 6, the exhaust gas heavy oil fuel heater 5 is provided on the downstream side of the regenerative heat exchanger 33, so that the heat generated in the exhaust gas combustor 32 is used as a heat source for regenerative heat exchange. It can be supplied directly to the vessel 33. For this reason, in the gas turbine power generation system according to the sixth embodiment, the exhaust gas inflow side temperature (about 600 ° to about 800 °) of the regeneration heat exchanger 33 is high. The difference (thermal step) between the temperature on the side (about 600 ° to about 800 °) and the temperature on the outflow side (about 400 ° to about 450 °) can be increased, and the thermal efficiency of the heat cycle (turbine efficiency) ) Is further improved.

“Description of Embodiment 7”
FIG. 7 is a block diagram showing Embodiment 7 (first modification of Embodiment 6) of the gas turbine power generation system according to the present invention. In FIG. 7, the same reference numerals as those in FIGS. 1 to 6 denote the same components.

  The difference between the gas turbine power generation system according to the seventh embodiment and the gas turbine power generation system according to the sixth embodiment is an arrangement location of the exhaust gas heavy oil fuel heater 5. That is, the exhaust gas heavy oil fuel heater 5 in the gas turbine power generation system according to the sixth embodiment is provided downstream of the regeneration heat exchanger 33 and integrated with the exhaust heat recovery boiler 2. .

  On the other hand, the exhaust gas heavy oil fuel heater 5 in the gas turbine power generation system according to the seventh embodiment is provided integrally with the exhaust gas combustor 32 on the upstream side of the regenerative heat exchanger 33.

  The gas turbine power generation system according to Embodiment 7 is configured as described above, and the operation thereof will be described below. The gas turbine power generation system according to the seventh embodiment is different from the gas turbine power generation system according to the sixth embodiment only in the location where the exhaust gas heavy oil fuel heater 5 is disposed. Similarly to the operation of the gas turbine power generation system according to 6, the operation of the exhaust gas combustor 32 and the regenerative heat exchanger 33 as the residual oil combustor 4 will be described, and the description of the operation of other devices will be omitted.

  The heavy oil fuel is heated in advance by the exhaust gas heavy oil fuel heater 5 integrated with the exhaust gas combustor 32 and sent to the distillation apparatus 3. The heavy oil fuel sent to the distillation apparatus 3 is separated into gasified light oil and residual oil by the distillation apparatus 3. The gasified light oil is sent to the combustor 8 through the gasified light oil line 20 and through the compressor 21.

  On the other hand, the residual oil is burned in the exhaust gas combustor 32 as the residual oil combustor 4 through the residual oil line 22. Further, the exhaust gas sent from the turbine 9 to the exhaust gas combustor 32 is heated by the residual oil combustor 4 that is integrated with the exhaust gas combustor 32. The exhaust gas heated by the residual oil combustor 4 integrated with the exhaust gas combustor 32 is heat-exchanged with the heavy oil fuel by the exhaust gas heavy oil fuel heater 5 integrated with the exhaust gas combustor 32, and the heavy oil. Heat the fuel. The exhaust gas heat-exchanged with the heavy oil fuel in the exhaust gas heavy oil fuel heater 5 integrated with the exhaust gas combustor 32 is sent to the regenerative heat exchanger 33 through the exhaust gas line 13, and in this regenerative heat exchanger 33. Heat is exchanged with the compressed air in the compressed air line 14 to heat the compressed air. The exhaust gas that has heated the compressed air by the regenerative heat exchanger 33 is sent to the exhaust heat recovery boiler 2 through the exhaust gas line 13, and exchanges heat with the water in the water line 17 in the exhaust heat recovery boiler 2. The exhaust gas heat-exchanged with water in the exhaust heat recovery boiler 2 is sent to the chimney 16 through the exhaust gas line 13 and is discharged from the chimney 16 to the outside.

  Since the gas turbine power generation system according to the seventh embodiment is configured and operated as described above, substantially the same effects as those of the gas turbine power generation system according to the sixth embodiment can be achieved.

  In particular, in the gas turbine power generation system according to the seventh embodiment, the exhaust gas heavy oil fuel heater 5 is provided on the upstream side of the regeneration heat exchanger 33 and integrally with the exhaust gas combustor 32. Therefore, the regeneration heat exchanger 33 is provided. The temperature on the inflow side of the exhaust gas is lower than that in the gas turbine power generation system according to the sixth embodiment. For this reason, in the gas turbine power generation system according to the seventh embodiment, the thermal step is reduced, but the thermal durability of the regenerative heat exchanger 33 is improved.

“Description of Embodiment 8”
FIG. 8 is a configuration diagram showing an eighth embodiment (second modified example of the sixth embodiment) of the gas turbine power generation system according to the present invention. 8, the same reference numerals as those in FIGS. 1 to 7 denote the same components.

  The gas turbine power generation system according to the eighth embodiment corresponds to the gas turbine power generation system according to the second embodiment which is a first modification of the first embodiment. That is, the difference between the gas turbine power generation system according to the eighth embodiment and the gas turbine power generation system according to the sixth and seventh embodiments is a heavy oil fuel heating apparatus. That is, the heavy oil fuel heating device in the gas turbine power generation system according to the sixth and seventh embodiments is the exhaust gas heavy oil fuel heater 5 integrated with the exhaust heat recovery boiler 2 or the exhaust gas combustor 32. The heavy oil fuel is preheated by the exhaust gas from the turbine 9.

  On the other hand, the heavy oil fuel heating apparatus in the gas turbine power generation system according to the eighth embodiment is a steam heavy oil fuel heater 24 that preheats the heavy oil fuel with the steam from the exhaust heat recovery boiler 2. The steam heavy oil fuel heater 24 is provided in the middle of the heavy oil fuel line 19 and in the middle of the branch steam line 25 branched from the exhaust heat recovery boiler 2. The branch steam line 25 branches from the exhaust heat recovery boiler 2, is connected to the steam heavy oil fuel heater 24 via the exhaust gas combustor 32, and the steam heavy oil fuel heater 24. To the condenser 26. As a result, the steam superheated by the exhaust heat recovery boiler 2 is sent to the exhaust gas combustor 32 through the branch steam line 25 and further heated by the exhaust gas combustor 32, and again passes through the branch steam line 25. Then, it is sent to the steam heavy oil fuel heater 24.

  Since the gas turbine power generation system according to the eighth embodiment is configured as described above, it is possible to achieve substantially the same operational effects as those of the gas turbine power generation systems according to the second, sixth, and seventh embodiments.

“Description of Embodiment 9”
FIG. 9 is a configuration diagram showing Embodiment 9 (third modification of Embodiment 6) of the gas turbine power generation system according to the present invention. 9, the same reference numerals as those in FIGS. 1 to 8 denote the same components.

  The gas turbine power generation system according to the ninth embodiment corresponds to the gas turbine power generation system according to the third embodiment which is the second modification of the first embodiment. That is, the difference between the gas turbine power generation system according to the ninth embodiment and the gas turbine power generation system according to the sixth and seventh embodiments is a heavy oil fuel heating apparatus. That is, the heavy oil fuel heating device in the gas turbine power generation system according to the sixth and seventh embodiments is the exhaust gas heavy oil fuel heater 5 integrated with the exhaust heat recovery boiler 2 or the exhaust gas combustor 32. The heavy oil fuel is preheated by the exhaust gas from the turbine 9.

  On the other hand, the heavy oil fuel heating apparatus in the gas turbine power generation system according to Embodiment 9 is a gasified light oil heavy oil that preheats heavy oil fuel with light oil from the distillation device 3, that is, gasified light oil. This is a fuel heater 27. The gasified light oil heavy oil fuel heater 27 is provided in the middle of the heavy oil fuel line 19. A gasified light oil line 20 is connected between the distillation apparatus 3 and the gasified light oil heavy oil fuel heater 27. A light oil line 28 is connected between the gasified light oil heavy oil fuel heater 27 and the combustor 8. A pump 29 is provided in the middle of the light oil line 28.

  Since the gas turbine power generation system according to the ninth embodiment is configured as described above, it is possible to achieve substantially the same operational effects as the gas turbine power generation systems according to the third, sixth, and seventh embodiments.

“Description of Embodiment 10”
FIG. 10 is a configuration diagram showing Embodiment 10 (fourth modification of Embodiment 6) of the gas turbine power generation system according to the present invention. 10, the same reference numerals as those in FIGS. 1 to 9 denote the same components.

  The gas turbine power generation system according to the tenth embodiment corresponds to the gas turbine power generation system according to the fourth embodiment which is the third modification of the first embodiment. That is, the difference between the gas turbine power generation system according to the tenth embodiment and the gas turbine power generation system according to the sixth and seventh embodiments is a separation device that separates light oil from heavy oil fuel. That is, the separation device in the gas turbine power generation system according to the sixth and seventh embodiments is the distillation device 3.

  On the other hand, the separation device in the gas turbine power generation system according to the tenth embodiment is a thermal decomposition device 30. A heavy oil fuel line 19 is connected to the first inlet side of the thermal decomposition apparatus 30. A gasified light oil line 20 is connected to the first outlet side of the thermal decomposition apparatus 30. Further, a branch steam line 25 is connected to the second inlet side of the thermal decomposition apparatus 30. Furthermore, a residual oil line 22 is connected to the second outlet side of the thermal decomposition apparatus 30. The branch line 25 does not pass through the exhaust heat recovery boiler 2 but passes through the exhaust gas combustor 32 as in the eighth embodiment.

  Since the gas turbine power generation system according to the tenth embodiment is configured as described above, it is possible to achieve substantially the same operational effects as those of the gas turbine power generation systems according to the fourth, sixth, and seventh embodiments.

  In the gas turbine power generation system according to the tenth embodiment, the heavy oil fuel heating device, for example, the exhaust gas heavy oil fuel heater 5 of the first, sixth, and seventh embodiments or the second embodiment. , 8 steam heavy oil fuel heater 24 or gasified light oil heavy oil fuel heater 27 of Embodiments 3 and 9 may be provided.

“Description of Embodiment 11”
FIG. 11: is a block diagram which shows Embodiment 11 (5th modification of the said Embodiment 6) of the gas turbine power generation system concerning this invention. 11, the same reference numerals as those in FIGS. 1 to 10 denote the same components.

  The gas turbine power generation system according to the eleventh embodiment corresponds to the gas turbine power generation system according to the fifth embodiment which is the fourth modification of the first embodiment. That is, the difference between the gas turbine power generation system according to the eleventh embodiment and the gas turbine power generation system according to the sixth and seventh embodiments is a separation device that separates light oil from heavy oil fuel. That is, the separation device in the gas turbine power generation system according to the sixth and seventh embodiments is the distillation device 3.

  On the other hand, the separation device in the gas turbine power generation system according to Embodiment 11 is composed of a primary distillation device 3 and a secondary pyrolysis device 30. That is, the separator in the gas turbine power generation system according to the eleventh embodiment is the one in which the thermal decomposition apparatus 30 is provided in the middle of the gasified light oil line 20 of the gas turbine power generation system according to the eighth embodiment.

  A gasified light oil line 20 from the distillation apparatus 3 is connected to the first inlet side of the pyrolysis apparatus 30. A gasified light oil line 20 connected to the combustor 8 via the compressor 21 is connected to the first outlet side of the thermal decomposition apparatus 30. Further, a residue oil line 22 connected to the residue oil combustor 4 integrated with the exhaust gas combustor 32 is connected to the second outlet side of the thermal decomposition apparatus 30. Furthermore, a branch steam line 31 from the exhaust gas recovery boiler 2 is connected to the second inlet side of the thermal decomposition apparatus 30. The branch steam line 31 passes through the exhaust gas combustor 32.

  Further, the heavy oil fuel heating device in the gas turbine power generation system according to the fifth embodiment is an exhaust gas heavy oil fuel heater 5 integrated with the exhaust heat recovery boiler 2, and the heavy oil fuel is converted into a turbine. 9 is preheated by the exhaust gas from No.9.

  On the other hand, the heavy oil fuel heating apparatus in the gas turbine power generation system according to the eleventh embodiment is configured so that the heavy oil fuel is vaporized from the exhaust heat recovery boiler 2 and vapor that has passed through the exhaust gas combustor 32 in advance. It is the steam heavy oil fuel heater 24 to heat. The steam heavy oil fuel heater 24 is further branched from a branch steam line (first branch steam line) 31 branched from the exhaust heat recovery boiler 2 in the middle of the heavy oil fuel line 19. Is provided in the middle of the branched steam line (second branched steam line) 34. The branch steam line (second branch steam line) 34 branches from the exhaust heat recovery boiler 2 and is connected to the thermal decomposition apparatus 30 via the exhaust gas combustor 32 (first branch steam). The steam heavy oil fuel heater 24 is further branched from the line 31, and is connected to the steam heavy oil fuel heater 24 from the steam heavy oil fuel heater 24.

  Since the gas turbine power generation system according to the eleventh embodiment is configured as described above, it is possible to achieve substantially the same operational effects as those of the gas turbine power generation systems according to the fifth, sixth, seventh, and eighth embodiments.

  In the gas turbine power generation system according to the eleventh embodiment, the heavy oil fuel heating device uses the vapor heavy oil fuel heater 24 according to the second and eighth embodiments. Instead of the refined oil fuel heater 24, the exhaust gas heavy oil fuel heater 5 of the first, sixth and seventh embodiments, or the gasified light oil heavy oil fuel heater 27 of the third and ninth embodiments. May be provided.

“Description of Embodiment 12”
FIG. 12 is a block diagram showing Embodiment 12 of the gas turbine power generation system according to the present invention. 12, the same reference numerals as those in FIGS. 1 to 11 denote the same components.

  The difference between the gas turbine power generation system according to the twelfth embodiment and the gas turbine power generation system according to the first embodiment is the structure of the residual oil combustor 4. That is, the residual oil combustor 4 in the gas turbine power generation system according to the first embodiment has an integrated structure with the exhaust heat recovery boiler 2, and the residual oil is integrated with the exhaust heat recovery boiler 2. It is made to burn with the residual oil combustor 4.

  On the other hand, the residual oil combustor 4 in the gas turbine power generation system according to the twelfth embodiment is a reheating combustor 35 that burns residual oil in the reheating combustor 35. The reheating combustor 35 is provided in the middle of the combustion gas line 15 between the front-stage turbine 36 and the rear-stage turbine 37 of the gas turbine 1. A combustion gas line 15 from the preceding turbine 36 is connected to the first inlet side of the reheating combustor 35. A combustion gas line 15 to the rear stage turbine 37 is connected to the outlet side of the reheating combustor 35. Further, a residual oil line 22 from the distillation apparatus 3 is connected to the second inlet side of the reheating combustor 35.

  The turbine 36 on the front stage side and the turbine 37 on the rear stage side of the gas turbine 1 are the number of turbine blade stages of the gas turbine (a single stage turbine blade is constituted by one stage stationary blade and one stage moving blade). For example, when there are four turbine blades, the first and second stages are the turbines 36 on the front stage, and the third and fourth stages are the turbines 37 on the rear stage.

  The gas turbine power generation system according to the twelfth embodiment is configured as described above, and the operation thereof will be described below. The gas turbine power generation system according to the twelfth embodiment is different from the gas turbine power generation system according to the first embodiment in the residual oil combustor 4. Therefore, the reheat combustor 35 as the residual oil combustor 4. The description of the operation of the other devices will be omitted.

  The heavy oil fuel is heated in advance by the exhaust gas heavy oil fuel heater 5 integrated with the exhaust heat recovery boiler 2 and sent to the distillation apparatus 3. The heavy oil fuel sent to the distillation apparatus 3 is separated into gasified light oil and residual oil by the distillation apparatus 3. The gasified light oil is sent to the combustor (first combustor) 8 through the gasified light oil line 20 and through the compressor 21. The gasified light oil sent to the combustor 8 is mixed with compressed air and burned. The combustion gas generated by the combustor 8 is sent from the combustor 8 to the turbine 36 on the front stage through the combustion gas line 15. With this combustion gas, the front-stage turbine 36 is rotated together with the later-stage turbine 37 described later to rotate the generator 11 to generate power.

  On the other hand, the residual oil is sent from the distillation apparatus 3 to the reheating combustor (second combustor) 35 as the residual oil combustor 4 through the residual oil line 22 and burned in the reheating combustor 35. . Further, the combustion gas whose pressure and temperature are reduced by rotating the turbine 36 at the front stage is sent to the reheating combustor 35 through the combustion gas line 15 and is heated again by the reheating combustor 35. . The combustion gas heated again by the reheating combustor 35 and having a high temperature is sent to the turbine 37 on the rear stage side through the combustion gas line 15. With this combustion gas, the turbine 37 on the rear stage together with the turbine 36 on the front stage rotates to drive the generator 11 to generate power.

  The combustion gas that rotationally drives the rear-stage turbine 37 is sent as exhaust gas from the rear-stage turbine 37 to the exhaust heat recovery boiler 2 through the exhaust gas line 13. The exhaust gas sent to the exhaust heat recovery boiler 2 heats the heavy oil fuel in the heavy oil fuel line 19 and exchanges heat with the water in the water line 17 in the exhaust heat recovery boiler 2. The exhaust gas that heats the heavy oil fuel and exchanges heat with water in the exhaust heat recovery boiler 2 is sent to the chimney 16 through the exhaust gas line 13 and discharged from the chimney 16 to the outside.

  Since the gas turbine power generation system according to the twelfth embodiment is configured and operated as described above, substantially the same effects as the gas turbine power generation system according to the first embodiment can be achieved.

  In particular, in the gas turbine power generation system according to the twelfth embodiment, the residual oil from the distillation apparatus 3 as a separator is provided in the combustion gas line 15 between the front-stage turbine 36 and the rear-stage turbine 37. Since combustion is performed by the reheat combustor (second combustor) 35 as the combustor 4, the turbine efficiency is improved. Moreover, the gas turbine power generation system according to the twelfth embodiment is lower in temperature and pressure than the combustor (first combustor) 8 of the gas turbine 1 to which the compressed air line 14 is connected. The residual oil from the distillation apparatus 3 is burned in the reheating combustor 35 different from the high temperature / high pressure environment of the combustor 8. For this reason, in the gas turbine power generation system according to the twelfth embodiment, even if a corrosive component is contained in the combustion gas supplied from the reheating combustor 35 to the turbine 37 on the rear stage side, the combustion of the gas turbine 1 is performed. Compared to the case where a corrosive component is contained in the combustion gas supplied from the vessel 8 to the front-stage turbine 36, the amount of corrosion of the rear-stage turbine 37 (for example, turbine blades) is small.

  In general, the gas turbine has a structure in which the turbine blades are not cooled in the region where the temperature of the combustion gas is about 800 ° or less. For this reason, if the temperature of the combustion gas in the region of the turbine 37 on the rear stage side of the gas turbine 1 is about 800 ° C. or less, the turbine blades of the turbine 37 on the rear stage side form an uncooled structure. As a result, in the gas turbine power generation system according to the twelfth embodiment, even if a corrosive component is contained in the combustion gas supplied to the turbine 37 on the rear stage side, the corrosive component in a gas phase state in the combustion gas is not present. Condensation does not become strong due to condensation on the surface of the turbine blade of the turbine 37 on the rear stage side. Moreover, since the pressure in the region of the turbine 37 on the rear stage side is lower than the pressure in the region of the front turbine 36, the dew point temperature of the corrosive component in the region of the rear turbine 37 is higher than that of the corrosive component in the region of the front turbine 36. The temperature is lower than the dew point temperature, which makes it difficult for the corrosive components in the gas phase to condense in the region of the turbine 37 on the rear stage side.

  Further, in the gas turbine power generation system according to the twelfth embodiment, since the residual oil is burned in the combustion gas from the upstream (the front-stage turbine 36) in the reheating combustor 35, the residual oil is simply removed in the simple combustor. Compared with the case of burning, the concentration of the corrosive component is lowered.

  If the dew point of the corrosive component is reached in the region of the turbine 37 on the rear stage side, an additive may be added to the residual oil to increase the dew point of the corrosive component.

“Description of Embodiment 13”
FIG. 13: is a block diagram which shows Embodiment 13 (1st modification of the said Embodiment 12) of the gas turbine power generation system concerning this invention. 13, the same reference numerals as those in FIGS. 1 to 12 denote the same components.

  The gas turbine power generation system according to the thirteenth embodiment is the gas turbine power generation system according to the second embodiment, which is the first modification of the first embodiment, and the second modification of the sixth embodiment. This corresponds to the gas turbine power generation system according to the eighth embodiment. That is, the difference between the gas turbine power generation system according to the thirteenth embodiment and the gas turbine power generation system according to the twelfth embodiment is a heavy oil fuel heating apparatus. In other words, the heavy oil fuel heating device in the gas turbine power generation system according to the twelfth embodiment is the exhaust gas heavy oil fuel heater 5 integrated with the exhaust heat recovery boiler 2, and the heavy oil fuel is converted into the turbine. 9 is preheated by the exhaust gas from No.9.

  On the other hand, the heavy oil fuel heating apparatus in the gas turbine power generation system according to the thirteenth embodiment is a steam heavy oil fuel heater 24 that preheats heavy oil fuel with steam from the exhaust heat recovery boiler 2. The steam heavy oil fuel heater 24 is provided in the middle of the heavy oil fuel line 19 and in the middle of the branch steam line 25 branched from the steam line 18. The branch steam line 25 branches from the steam line 18 and is connected to the steam heavy oil fuel heater 24 via the exhaust heat recovery boiler 2, and from the steam heavy oil fuel heater 24. It is connected to the condenser 26.

  Since the gas turbine power generation system according to the thirteenth embodiment is configured as described above, it is possible to achieve substantially the same operational effects as the gas turbine power generation systems according to the second, eighth, and twelfth embodiments.

“Description of Embodiment 14”
FIG. 14 is a block diagram showing Embodiment 14 (second modification of Embodiment 12) of the gas turbine power generation system according to the present invention. 14, the same reference numerals as those in FIGS. 1 to 13 denote the same components.

  The gas turbine power generation system according to the fourteenth embodiment is the gas turbine power generation system according to the third embodiment, which is the second modification of the first embodiment, and the third modification of the sixth embodiment. This corresponds to the gas turbine power generation system according to the ninth embodiment. That is, the difference between the gas turbine power generation system according to the fourteenth embodiment and the gas turbine power generation system according to the twelfth embodiment is a heavy oil fuel heating apparatus. In other words, the heavy oil fuel heating device in the gas turbine power generation system according to the twelfth embodiment is the exhaust gas heavy oil fuel heater 5 integrated with the exhaust heat recovery boiler 2, and the heavy oil fuel is converted into the turbine. 9 is preheated by the exhaust gas from No.9.

  On the other hand, the heavy oil fuel heating device in the gas turbine power generation system according to the fourteenth embodiment is a gasified light heavy oil that preheats heavy oil fuel with light oil from the distillation device 3, that is, gasified light oil. This is a fuel heater 27. The gasified light oil heavy oil fuel heater 27 is provided in the middle of the heavy oil fuel line 19. A gasified light oil line 20 is connected between the distillation apparatus 3 and the gasified light oil heavy oil fuel heater 27. A light oil line 28 is connected between the gasified light oil heavy oil fuel heater 27 and the combustor 8. A pump 29 is provided in the middle of the light oil line 28.

  Since the gas turbine power generation system according to the fourteenth embodiment is configured as described above, it is possible to achieve substantially the same operational effects as the gas turbine power generation systems according to the third, ninth, and twelfth embodiments.

“Description of Embodiment 15”
FIG. 15 is a configuration diagram showing Embodiment 15 (third modification of Embodiment 12) of the gas turbine power generation system according to the present invention. 15, the same reference numerals as those in FIGS. 1 to 14 denote the same components.

  The gas turbine power generation system according to the fifteenth embodiment is the gas turbine power generation system according to the fourth embodiment, which is the third modification of the first embodiment, and the fourth modification of the sixth embodiment. This corresponds to the gas turbine power generation system according to the tenth embodiment. That is, the difference between the gas turbine power generation system according to the fifteenth embodiment and the gas turbine power generation system according to the twelfth embodiment is a separation device that separates light oil from heavy oil fuel. That is, the separation device in the gas turbine power generation system according to the twelfth embodiment is the distillation device 3.

  On the other hand, the separation device in the gas turbine power generation system according to the fifteenth embodiment is a thermal decomposition device 30. A heavy oil fuel line 19 is connected to the first inlet side of the thermal decomposition apparatus 30. A gasified light oil line 20 is connected to the outlet side of the thermal decomposition apparatus 30. Further, a branch steam line 25 is connected to the second inlet side of the thermal decomposition apparatus 30. The branch line 25 passes through the exhaust heat recovery boiler 2 as in the thirteenth embodiment.

  Since the gas turbine power generation system according to the fifteenth embodiment is configured as described above, it is possible to achieve substantially the same operational effects as the gas turbine power generation systems according to the fourth, tenth and twelfth embodiments.

  In the gas turbine power generation system according to the fifteenth embodiment, the heavy oil fuel heating device, for example, the exhaust gas heavy oil fuel heater 5 of the first, sixth, seventh, and twelfth embodiments, or the implementation described above. The steam heavy oil fuel heater 24 according to Embodiments 2, 8, and 13 or the gasified light oil heavy oil fuel heater 27 according to Embodiments 3, 9, and 14 may be provided.

“Description of Embodiment 16”
FIG. 16: is a block diagram which shows Embodiment 16 (The 4th modification of the said Embodiment 12) of the gas turbine power generation system concerning this invention. 16, the same reference numerals as those in FIGS. 1 to 15 denote the same components.

  The gas turbine power generation system according to the sixteenth embodiment is the gas turbine power generation system according to the fifth embodiment, which is the fourth modification of the first embodiment, and the fifth modification of the sixth embodiment. This corresponds to the gas turbine power generation system according to the eleventh embodiment. That is, the difference between the gas turbine power generation system according to the sixteenth embodiment and the gas turbine power generation system according to the twelfth embodiment is a separation device that separates light oil from heavy oil fuel. That is, the separation device in the gas turbine power generation system according to the twelfth embodiment is the distillation device 3.

  On the other hand, the separation apparatus in the gas turbine power generation system according to Embodiment 16 is composed of a primary distillation apparatus 3 and a secondary pyrolysis apparatus 30. That is, the separation apparatus in the gas turbine power generation system according to the sixteenth embodiment is such that the thermal decomposition apparatus 30 is provided in the middle of the gasified light oil line 20 of the gas turbine power generation system according to the twelfth embodiment.

  A gasified light oil line 20 from the distillation apparatus 3 is connected to the first inlet side of the pyrolysis apparatus 30. A gasified light oil line 20 connected to the combustor 8 via the compressor 21 is connected to the first outlet side of the thermal decomposition apparatus 30. Further, a residual oil line 22 connected to the reheating combustor 35 is connected to the second outlet side of the thermal decomposition apparatus 30. Furthermore, a branch steam line 31 from the exhaust gas recovery boiler 2 is connected to the second inlet side of the thermal decomposition apparatus 30.

  Further, the heavy oil fuel heating device in the gas turbine power generation system according to the sixteenth embodiment is the same as the heavy oil fuel heating device in the gas turbine power generation system according to the fifth embodiment, and the exhaust heat recovery boiler 2. And an exhaust gas heavy oil fuel heater 5 having an integral structure, in which the heavy oil fuel is preheated by the exhaust gas from the turbine 9.

  Since the gas turbine power generation system according to the sixteenth embodiment is configured as described above, it is possible to achieve substantially the same operational effects as the gas turbine power generation systems according to the fifth, eleventh, and twelfth embodiments.

  In the gas turbine power generation system according to the sixteenth embodiment, the heavy oil fuel heating device uses the exhaust gas heavy oil fuel heater 5 of the first, sixth, and seventh embodiments. Instead of the exhaust gas heavy oil fuel heater 5, the steam heavy oil fuel heater 24 of the second and eighth embodiments, or the gasified light oil heavy oil fuel heater 27 of the third and ninth embodiments. May be provided.

"Description of examples other than Embodiments 1 to 16"
In the first to 16th embodiments, the gas turbine 1 and the steam turbine 6 drive and rotate the separate generators 11 and 23, respectively. However, in the present invention, the gas turbine 1 And the steam turbine may drive and rotate the same generator to generate power.

  The gas turbine power generation system according to the present invention is useful as a gas turbine power generation system using heavy oil fuel.

1 Gas turbine 2 Waste heat recovery boiler 3 Distillation device (separation device)
4 Residual oil combustor 5 Exhaust gas heavy oil fuel heater 6 Steam turbine 7 Compressor 8 Combustor 9 Turbine 10 Turbine shaft 11 Generator 12 Air line 13 Exhaust gas line 14 Compressed air line 15 Combustion gas line 16 Chimney 17 Water line 18 Steam line (steam line)
19 Heavy Oil Fuel Line 20 Gasified Light Oil Line 21 Compressor 22 Residual Oil Line 23 Generator 24 Steam Heavy Oil Fuel Heater 25 Branch Steam Line 26 Condenser 27 Gasified Light Oil Heavy Oil Fuel Heater 28 Light Oil line 29 Pump 30 Pyrolysis device (separation device)
31 Branch steam line (first branch steam line)
32 Exhaust gas combustor 33 Regenerative heat exchanger 34 Branch steam line (second branch steam line)
35 Reheating Combustor 36 Front Stage Turbine 37 Rear Stage Turbine

Claims (4)

In the gas turbine power generation system,
A separation device for separating light oil from heavy oil fuel, the distillation device for distilling the heavy oil fuel into the light oil and residual oil containing a corrosive component, and the heavy oil fuel Pyrolysis apparatus that thermally decomposes the oil into high-temperature water and separates it into the residual oil containing the light oil and the corrosive component, the heavy oil fuel is distilled to contain the primary separated light oil and the corrosive component A pyrolysis apparatus that separates the light oil of the primary separation from the distillation apparatus into high-temperature water and separates the light oil and the residual oil containing a corrosive component; A separation device that is any one of
A gas turbine that generates electric power by a generator by rotationally driving a turbine with combustion gas generated by burning a mixture of the light oil from the separator and compressed air compressed by a compressor in a combustor;
With
Exhaust heat recovery boiler as a residual oil combustor that combusts the residual oil from the separator, an exhaust gas combustor as a residual oil combustor that combusts the residual oil from the separator, and the exhaust gas combustor Any one of a regenerative heat exchanger using heat as a heat source and a reheat combustor as a residual oil combustor that burns the residual oil from the separation device;
A gas turbine power generation system characterized by that. In the gas turbine power generation system,
A separation device for separating light oil from heavy oil fuel, the distillation device for distilling the heavy oil fuel into the light oil and residual oil containing a corrosive component, and the heavy oil fuel Pyrolysis apparatus that thermally decomposes the oil into high-temperature water and separates it into the residual oil containing the light oil and the corrosive component, the heavy oil fuel is distilled to contain the primary separated light oil and the corrosive component A pyrolysis apparatus that separates the light oil of the primary separation from the distillation apparatus into high-temperature water and separates the light oil and the residual oil containing a corrosive component; A separation device that is any one of
A gas turbine that generates electric power by a generator by rotationally driving a turbine with combustion gas generated by burning a mixture of the light oil from the separator and compressed air compressed by a compressor in a combustor;
With
Exhaust gas heavy oil fuel heater for heating the heavy oil fuel with exhaust gas, Steam heavy oil fuel heater for heating the heavy oil fuel with steam, Light oil for heating the heavy oil fuel with the light oil Comprising one of the heavy oil fuel heaters,
A gas turbine power generation system characterized by that. In the gas turbine power generation system,
A separation device for separating light oil from heavy oil fuel, the distillation device for distilling the heavy oil fuel into the light oil and residual oil containing a corrosive component, and the heavy oil fuel Pyrolysis apparatus that thermally decomposes the oil into high-temperature water and separates it into the residual oil containing the light oil and the corrosive component, the heavy oil fuel is distilled to contain the primary separated light oil and the corrosive component A pyrolysis apparatus that separates the light oil of the primary separation from the distillation apparatus into high-temperature water and separates the light oil and the residual oil containing a corrosive component; A separation device that is any one of
A gas turbine that generates electric power by a generator by rotationally driving a turbine with combustion gas generated by burning a mixture of the light oil from the separator and compressed air compressed by a compressor in a combustor;
With
An exhaust gas combustor that burns the residual oil from the separator, a regenerative heat exchanger that uses heat generated in the exhaust gas combustor as a heat source, and the heavy oil fuel downstream or upstream of the regenerative heat exchanger An exhaust gas heavy oil fuel heater heated by exhaust gas on the side,
A gas turbine power generation system characterized by that. An exhaust heat recovery boiler;
A steam turbine that rotationally drives the steam from the exhaust heat recovery boiler to generate power with a generator;
The gas turbine power generation system according to any one of claims 1 to 3, further comprising:

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