Disclosed herein are embodiments of combined cycle power plants having elevated exhaust pressure from a steam turbine. The elevated exhaust pressure from the steam turbine may result in an elevated condensate pressure and temperature. A cooling system removes sensible heat from the condensate. The e
Disclosed herein are embodiments of combined cycle power plants having elevated exhaust pressure from a steam turbine. The elevated exhaust pressure from the steam turbine may result in an elevated condensate pressure and temperature. A cooling system removes sensible heat from the condensate. The elevated condensate temperature results in a greater temperature difference between the condensate and the working medium in the cooling system. The amount of heat that is dissipated by the cooling system is proportionate to the heat transfer surface and the temperature difference between the condensate and the working medium. As a result of the greater temperature difference, a smaller cooling system configured to operate with a higher temperature condensate may be utilized in place of a larger cooling system configured to operate with lower temperature condensate. By reducing the size of the cooling system, the overall size of the combined cycle power plant may be reduced.
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1. A combined cycle power plant comprising: a combustion turbine comprising: a compressor configured to generate compressed air using ambient air,a combustor to combust a fuel in the compressed air to produce combustion air, anda gas turbine to expand the combustion air to produce mechanical energy
1. A combined cycle power plant comprising: a combustion turbine comprising: a compressor configured to generate compressed air using ambient air,a combustor to combust a fuel in the compressed air to produce combustion air, anda gas turbine to expand the combustion air to produce mechanical energy and exhaust gas;a heat recovery steam generator configured to receive the exhaust gas and transfer heat from the exhaust gas to water in order to generate a flow of steam;a condensing steam turbine configured to produce mechanical energy from the flow of steam, the condensing steam turbine comprising: an input to receive the steam from the heat recovery steam generator (HRSG); andan output to output exhaust steam at a pressure between eight PSIA and sixteen PSIA, wherein the exhaust steam is output at an above atmospheric pressure of approximately sixteen PSIA when operating at a high ambient temperature, and wherein the exhaust steam is output at a below atmospheric pressure of approximately twelve PSIA when operating at a lower ambient temperature;a condenser to receive the exhaust steam from the steam turbine and to condense the exhaust steam to form a condensate, wherein the condensate has a temperature above approximately 180 degrees Fahrenheit; anda dry cooling system coupled to the condenser and configured to cool the condensate in ambient temperatures between approximately 90 degrees Fahrenheit and 100 degrees Fahrenheit. 2. The combined cycle power plant of claim 1, wherein the steam from the HRSG has a temperature of approximately 1,000 degrees Fahrenheit. 3. The combined cycle power plant of claim 1, wherein the heat recovery steam generator further comprises a duct burner configured to add heat to the exhaust gas and increase its temperature. 4. The combined cycle power plant of claim 3, wherein the exhaust steam has a temperature above approximately 200 degrees Fahrenheit when the duct burner is operating at full capacity. 5. The combined cycle power plant of claim 3, wherein the output of the steam turbine is between twelve PSIA and sixteen PSIA when the duct burner is operating at full capacity. 6. The combined cycle power plant of claim 1, further comprising an electrical generator configured to convert the mechanical energy generated by the gas turbine to electrical energy. 7. The combined cycle power plant of claim 1, further comprising an electrical generator configured to convert the mechanical energy generated by the steam turbine to electrical energy. 8. The combined cycle power plant of claim 1, wherein the fuel comprises natural gas. 9. The combined cycle power plant of claim 1, wherein the fuel comprises distillate fuel. 10. The combined cycle power plant of claim 1, wherein the dry cooling system comprises a compact size configured to allow for rapid startup of the combined cycle power plant. 11. A combined cycle power plant comprising: a combustion turbine comprising: a compressor configured to generate compressed air in ambient temperatures between approximately 90 degrees Fahrenheit and 100 degrees Fahrenheit,a combustor to combust a fuel in the compressed air to produce combustion air, anda gas turbine to expand the combustion air to produce mechanical energy and exhaust gas;a heat recovery steam generator configured to receive the exhaust gas and transfer heat from the exhaust gas to water in order to generate a flow of steam;a condensing steam turbine configured to produce mechanical energy from the steam, the condensing steam turbine comprising: an input configured to receive the steam from the heat recovery steam generator;an output to output exhaust steam at a pressure between eight PSIA and sixteen PSIA when the gas turbine operates at full capacity, wherein the exhaust steam is output at an above atmospheric pressure of approximately sixteen PSIA when operating at a high ambient temperature, and wherein the exhaust steam is output at a below atmospheric pressure of approximately twelve PSIA when operating at a lower ambient temperature;a condenser to receive the exhaust steam from the steam turbine and to condense the exhaust steam to form a condensate; andan air cooled system coupled to the condenser and configured to cool the condensate. 12. The combined cycle power plant of claim 11, wherein the condensate has a temperature above approximately 180 degrees Fahrenheit. 13. The combined cycle power plant of claim 11, wherein the steam from the HRSG has a temperature of approximately 1,000 degrees Fahrenheit. 14. The combined cycle power plant of claim 11, wherein the heat recovery steam generator further comprises a duct burner configured to add heat to the exhaust gas and increase its temperature. 15. The combined cycle power plant of claim 14, wherein the exhaust steam has a temperature above approximately 200 degrees Fahrenheit when the duct burner is in operation. 16. The combined cycle power plant of claim 14, wherein the output of the steam turbine is between twelve PSIA and sixteen PSIA when the duct burner is operating at full capacity. 17. A method of operating a combined cycle power plant having a combustion turbine, a heat recovery steam generator, and a condensing steam turbine system, the method comprising the steps of: operating said combustion turbine system to generate compressed air, to combust a fuel and a flow of exhaust gas, and to produce mechanical energy;directing the flow of exhaust gas through the heat recovery steam generator to transfer heat from the exhaust gas to water in order to produce a flow of steam;directing the flow of steam to the condensing steam turbine to generate mechanical energy from the flow of steam;exhausting an exhaust steam from the condensing steam turbine at a pressure between eight PSIA and sixteen PSIA, wherein the exhaust steam is output at an above atmospheric pressure of approximately sixteen PSIA when operating at a high ambient temperature, and wherein the exhaust steam is output at a below atmospheric pressure of approximately twelve PSIA when operating at a lower ambient temperature;directing the exhaust steam to a condenser, wherein the exhaust steam has a temperature above approximately 180 degrees Fahrenheit; anddissipating excess heat from the condenser using a dry cooling system. 18. The method of claim 17, wherein the flow of steam to the condensing steam turbine has a temperature of approximately 1000 degrees Fahrenheit. 19. The method of claim 17, further comprising: adding heat to the exhaust gas using a duct burner disposed within the heat recovery steam generator. 20. The method of claim 19, wherein the exhaust steam has a temperature above approximately 200 degrees Fahrenheit when the duct burner is operating at full capacity. 21. The method of claim 19, wherein the output of the steam turbine is between twelve PSIA and sixteen PSIA when the duct burner is operating at full capacity. 22. The method of claim 17, further comprising: converting the mechanical energy generated by the gas turbine to electrical energy. 23. The method of claim 17, further comprising: converting the mechanical energy generated by the steam turbine to electrical energy.
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이 특허에 인용된 특허 (13)
Briesch Michael S. (Orlando FL) Costanzo Michael A. (Akron OH), Combined combustion and steam turbine power plant.
Bds Jnos (Budapest HUX) Papp Istvn (Budapest HUX) Ageiev Georgy S. (Moscow SUX) Diakov Anatoly F. (Moscow SUX) Santurian Hermes R. (Yerevan SUX) Trushin Sergei G. (Moscow SUX), Cooling system for condensing the exhaust steam of steam turbine plants, particularly of power plants.
Fisher Uriyel (Haifa ILX) Sinai Joseph (Ramat Gan ILX) Gilon Yoel (Jerusalem ILX), Gas turbine system and method using temperature control of the exhaust gas entering the heat recovery cycle by mixing wi.
Robert Sean Talley ; John Raymond Hawley ; Bruce Lockheart Morrison, Optimized steam turbine peaking cycles utilizing steam bypass and related process.
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