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Advanced turbine

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Sarah Christy
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Advanced Turbine Periyanayaga Kristy.A, Ph.D. Research Scholar SRM Universtiy Chennai
Advanced Turbine • Turbine Definition: • A turbine is a rotary mechanical device that extracts energy from a fast moving flow of water, steam, gas, air, or other fluid and converts it into useful work. • A turbine is a turbo-machine with at least one moving part called a rotor assembly, which is a shaft or drum with blades attached. • Moving fluid acts on the blades so that they move and impart rotational energy to the rotor.
Advanced Turbine – Working Principle • The working principle is very much simple. • When the fluid strikes the blades of the turbine, the blades are displaced, which produces rotational energy. • When the turbine shaft is directly coupled to an electric gene- -rator mechanical energy is converted into electrical energy. • This electrical power is known as hydroelectric power.
Advanced Turbine Fuel Natural gas Frequency 60 Hz Gross Electrical output 187.7 MW* Gross Electrical efficiency 36.9 % Gross Heat rate 9251 Btu/kWh Turbine speed 3600 rpm Compressor pressure ratio 32:1 Exhaust gas flow 445 kg/s Exhaust gas temperature 612 °C NOx emissions (corr. to 15% O2,dry) < 25 vppm GT24 (ISO 2314 : 1989)
Advanced Turbine Fuel Natural gas Frequency 60 Hz Gross Electrical output 187.7 MW* Gross Electrical efficiency 36.9 % Gross Heat rate 9251 Btu/kWh Turbine speed 3600 rpm Compressor pressure ratio 32:1 Exhaust gas flow 445 kg/s Exhaust gas temperature 612 °C NOx emissions (corr. to 15% O2,dry) < 25 vppm 9756 kJ/kWh
Advanced Turbine - Types • Water Turbine : A) impulse turbine B) reaction turbine • Steam Turbine • Gas Turbine • Wind Turbine • Although the same principles apply to all turbines, their specific designs differ sufficiently to merit separate descriptions.
Advanced Turbine – Impulse turbine • In an impulse turbine, the fluid is forced to hit the turbine at high speed. Types of Impulse Turbines: I. Pelton Turbine II. Cross-flow Turbine
Advanced Turbine – Pelton turbine • It is a type of tangential flow impulse turbine used to generate electricity in the hydroelectric power plant. • The Pelton turbine was discovered by the American engineer L.A. Pelton The energy available at the inlet of the Pelton turbine is only kinetic energy. • The pressure at the inlet and outlet of the turbine is atmospheric pressure. • This type of turbine is used for high head. • Main Parts of Pelton Turbine • The various parts of the Pelton turbine are Nozzle and flow regulating arrangement (spear), Runner and Buckets, Casing and Breaking Jet
Advanced Turbine – Pelton turbine • Working principle of Pelton turbine is simple. • When a high speed water jet injected through a nozzle hits buckets of Pelton wheel; it induces an impulsive force. • This force makes the turbine rotate. The rotating shaft runs a generator and produces electricity. • In short, Pelton turbine transforms kinetic energy of water jet to rotational energy.
Advanced Turbine – Cross- Flow turbine • As with a water wheel, the water is admitted at the turbine's edge. After passing the runner, it leaves on the opposite side. • Going through the runner twice provides additional efficiency. • The cross-flow turbine is a low-speed machine that is well suited for locations with a low head but high flow.
Advanced Turbine – Reaction Turbine • In a reaction turbine, forces driving the rotor are achieved by the reaction of an accelerating water flow in the runner while the pressure drops. • In reaction turbines torque developed by reacting to the fluid's pressure. • The pressure of the fluid changes as it passes through the turbine rotor blades. • Kaplan Turbine • Francis Turbine • Kinetic Turbine Types of Reaction Turbines
Advanced Turbine – Kaplan Turbine • The Kaplan turbine is a water turbine which has adjustable blades and is used for low heads and high discharges. • The Kaplan turbine is an inward flow reaction turbine, which means that the working fluid changes pressure as it moves through the turbine and gives up its energy.
Advanced Turbine – Francis Turbine • The Francis turbine is a type of water turbine and are used for medium head(45-400 m) and medium discharge.(10-700 m^3/s) • The Francis turbine is a type of reaction turbine, a category of turbine in which the working fluid comes to the turbine under immense pressure and the energy is extracted by the turbine blades from the working fluid.
Advanced Turbine – Kinetic Turbines • Kinetic energy turbines, also called free-flow turbines, generate electricity from the kinetic energy present in flowing water. • The systems may operate in rivers, man-made channels, tidal waters, or ocean currents. • Kinetic systems utilize the water stream's natural pathway.
Advanced Turbine – Steam Turbine • A steam turbine is a device that extracts thermal energy from pressurized steam and uses it to do mechanical work on a rotating output shaft. • Steam turbines are used for the generation of electricity in thermal power plants, such as plants using coal fuel oil or nuclear fuel.
Advanced Turbine – Gas Turbine • A gas turbine, also called a combustion turbine, is a type of internal combustion engine. • Gas turbines are used to power aircraft, trains, ships, electrical generators or even tanks.
Advanced Turbine Developments in Gas Turbine Cycles 1. The wet compression (WC) cycle 2. The steam injected gas turbine (STIG) cycle 3. The integrated WC & STIG (SWC) cycle 4. Themo-chemical Recuperation cycles
Advanced Turbine Wet compression • One of the most effective ways to increase the gas turbine power output is to reduce the amount of work required for its compressor. • A gas turbine compressor consumes about 30 to 50% of work produced by the turbine.
Advanced Turbine Intake Air Inlet Duct Water InjectionCompressor Combustor Fuel Turbine G The wet compression (WC) cycle
Advanced Turbine The wet compression (WC) cycle • The wet compression cycle has the following benefits over the simple cycle. • Lower compressor work • Higher turbine work • Higher cycle efficiency
Advanced Turbine The steam injected gas turbine (STIG) cycle G Compressor Turbine Combustor Fuel Injection Steam Exhaust HRSG water pump Intake Air HRSG – Heat Recovery Steam Generator
Advanced Turbine The steam injected gas turbine (STIG) cycle • Steam injection into the combustion chamber of a gas turbine is one of the ways to achieve power augmentation and efficiency gain. • In a steam injected gas turbine (STIG), the heat of exhaust gasses of the gas turbine is used to produce steam in a heat recovery steam generator. • The steam is injected into the combustion chamber or before entering the combustion chamber (i.e. in the compressor discharge). • STIG cycle has higher cycle efficiency than the WC cycle. • STIG cycle gives higher net work out put than the WC cycle up to a pressure ratio of 7.
Advanced Turbine G Intake Air Water injection Inlet Duct Compressor Turbine Combustor Fuel Injection Steam Exhaust HRSG water pump The integrated WC & STIG (SWC) cycle HRSG – Heat Recovery Steam Generator
Advanced Turbine The integrated WC & STIG (SWC) cycle • It has the combined benefit of the advantage of higher efficiency of STIG cycle and higher net work output of WC cycle. • But its cycle efficiency is less than that of the STIG cycle owing to the need for higher heat input.
Advanced Turbine Comparison of typical parameters of simple, WC,STIG and SWC cycles. cycle Pressure ratio PR Evaporat ive rate, kg/k Net work output, MW Cycle efficienc y % Fuel mass flow rate, kg/sec Steam mass flow rate, kg/sec simple 11 0 151.13 31.28 11.04 0 WC 11 7.5e-4 232.75 35.35 15.04 0 STIG 11 0 215.65 39.63 12.43 54.49 SWC 11 7.5e-4 303.11 38.16 18.15 54.49
Advanced Turbine • There are many areas and challenges which can be explored further to this work. • They are: • Economic feasibility of these cycles need to be studied. • Compressor life reduction due to water injection. (because of the off design running conditions that prevail in reality). • The difficulties involved in designing a turbine to handle large mass flow rates of combustion gasses and steam. • The effect of steam injection in reducing Nitrogen Oxides (NOX) emissions
Advanced Turbine – Wind Turbine • A wind turbine is a device that converts kinetic energy from the wind into electrical power . • Conventional horizontal axis turbines can be divided into three components:. • Wind turbine used for charging batteries may be referred to as a wind charger.
Advanced Turbine • A designed nano-turbine constructed by a single-wall carbon nanotube (CNT) and graphene sheets. • This nano-turbine can largely unidirectionally rotate as driven by a steady water flow. • The mechanism by which the nano-device works at nanoscale and the difference between the behavior of mechanical motion of a nano-device and its macroscopic analogue still largely remain elusive. • The averaged rotation rate of the nano-turbine shows linear relationship with the flow velocity through two orders of magnitude.
Advanced Turbine • Compared to the macroscopic counterpart, the rotation rate of nano-turbine is much slower. • Its efficiency of converting energy from fluid flow to the mechanical motion is only 6.4% of that of an ideal macroscopic counterpart. • As indicated by the distribution of flow velocity, the ‘‘effective’’ driving flow velocity is remarkably smaller than the bulk flow velocity and the ratio can be as low as 0.15. • The disruption of water flow, together with the water slippage at graphene surface and the dragging effect, should be related to the much slower rotation rate.
Advanced Turbine • The ratio of effective driving flow velocity decreases as the flow velocity increase, suggesting that the linear relationship between rotation rate and flow velocity may be more complicated. The water slippage and dragging, may get enhanced at the same time. • The top view (left) and side view (right) of the designed nano-turbine placed along the z-axis, visualized with VMD40. The two fixed pole carbon atoms are shown as the golden balls. The rotation of nano-turbine is driven by the water flow along the – z-direction. The 2-A° slab above the turbine blade is shown as the green region.
Applications • Almost all electrical power on earth is produced with a turbine of some type. • Very high efficiency turbines harness about 40% of the thermal energy with the rest exhausted as waste heat. • Most jet engines rely on turbines to supply mechanical work from their working fluid and fuel as do all nuclear ships and power plants.

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Advanced turbine

  • 1. Advanced Turbine Periyanayaga Kristy.A, Ph.D. Research Scholar SRM Universtiy Chennai
  • 2. Advanced Turbine • Turbine Definition: • A turbine is a rotary mechanical device that extracts energy from a fast moving flow of water, steam, gas, air, or other fluid and converts it into useful work. • A turbine is a turbo-machine with at least one moving part called a rotor assembly, which is a shaft or drum with blades attached. • Moving fluid acts on the blades so that they move and impart rotational energy to the rotor.
  • 3. Advanced Turbine – Working Principle • The working principle is very much simple. • When the fluid strikes the blades of the turbine, the blades are displaced, which produces rotational energy. • When the turbine shaft is directly coupled to an electric gene- -rator mechanical energy is converted into electrical energy. • This electrical power is known as hydroelectric power.
  • 4. Advanced Turbine Fuel Natural gas Frequency 60 Hz Gross Electrical output 187.7 MW* Gross Electrical efficiency 36.9 % Gross Heat rate 9251 Btu/kWh Turbine speed 3600 rpm Compressor pressure ratio 32:1 Exhaust gas flow 445 kg/s Exhaust gas temperature 612 °C NOx emissions (corr. to 15% O2,dry) < 25 vppm GT24 (ISO 2314 : 1989)
  • 5. Advanced Turbine Fuel Natural gas Frequency 60 Hz Gross Electrical output 187.7 MW* Gross Electrical efficiency 36.9 % Gross Heat rate 9251 Btu/kWh Turbine speed 3600 rpm Compressor pressure ratio 32:1 Exhaust gas flow 445 kg/s Exhaust gas temperature 612 °C NOx emissions (corr. to 15% O2,dry) < 25 vppm 9756 kJ/kWh
  • 6. Advanced Turbine - Types • Water Turbine : A) impulse turbine B) reaction turbine • Steam Turbine • Gas Turbine • Wind Turbine • Although the same principles apply to all turbines, their specific designs differ sufficiently to merit separate descriptions.
  • 7. Advanced Turbine – Impulse turbine • In an impulse turbine, the fluid is forced to hit the turbine at high speed. Types of Impulse Turbines: I. Pelton Turbine II. Cross-flow Turbine
  • 8. Advanced Turbine – Pelton turbine • It is a type of tangential flow impulse turbine used to generate electricity in the hydroelectric power plant. • The Pelton turbine was discovered by the American engineer L.A. Pelton The energy available at the inlet of the Pelton turbine is only kinetic energy. • The pressure at the inlet and outlet of the turbine is atmospheric pressure. • This type of turbine is used for high head. • Main Parts of Pelton Turbine • The various parts of the Pelton turbine are Nozzle and flow regulating arrangement (spear), Runner and Buckets, Casing and Breaking Jet
  • 9. Advanced Turbine – Pelton turbine • Working principle of Pelton turbine is simple. • When a high speed water jet injected through a nozzle hits buckets of Pelton wheel; it induces an impulsive force. • This force makes the turbine rotate. The rotating shaft runs a generator and produces electricity. • In short, Pelton turbine transforms kinetic energy of water jet to rotational energy.
  • 10. Advanced Turbine – Cross- Flow turbine • As with a water wheel, the water is admitted at the turbine's edge. After passing the runner, it leaves on the opposite side. • Going through the runner twice provides additional efficiency. • The cross-flow turbine is a low-speed machine that is well suited for locations with a low head but high flow.
  • 11. Advanced Turbine – Reaction Turbine • In a reaction turbine, forces driving the rotor are achieved by the reaction of an accelerating water flow in the runner while the pressure drops. • In reaction turbines torque developed by reacting to the fluid's pressure. • The pressure of the fluid changes as it passes through the turbine rotor blades. • Kaplan Turbine • Francis Turbine • Kinetic Turbine Types of Reaction Turbines
  • 12. Advanced Turbine – Kaplan Turbine • The Kaplan turbine is a water turbine which has adjustable blades and is used for low heads and high discharges. • The Kaplan turbine is an inward flow reaction turbine, which means that the working fluid changes pressure as it moves through the turbine and gives up its energy.
  • 13. Advanced Turbine – Francis Turbine • The Francis turbine is a type of water turbine and are used for medium head(45-400 m) and medium discharge.(10-700 m^3/s) • The Francis turbine is a type of reaction turbine, a category of turbine in which the working fluid comes to the turbine under immense pressure and the energy is extracted by the turbine blades from the working fluid.
  • 14. Advanced Turbine – Kinetic Turbines • Kinetic energy turbines, also called free-flow turbines, generate electricity from the kinetic energy present in flowing water. • The systems may operate in rivers, man-made channels, tidal waters, or ocean currents. • Kinetic systems utilize the water stream's natural pathway.
  • 15. Advanced Turbine – Steam Turbine • A steam turbine is a device that extracts thermal energy from pressurized steam and uses it to do mechanical work on a rotating output shaft. • Steam turbines are used for the generation of electricity in thermal power plants, such as plants using coal fuel oil or nuclear fuel.
  • 16. Advanced Turbine – Gas Turbine • A gas turbine, also called a combustion turbine, is a type of internal combustion engine. • Gas turbines are used to power aircraft, trains, ships, electrical generators or even tanks.
  • 17. Advanced Turbine Developments in Gas Turbine Cycles 1. The wet compression (WC) cycle 2. The steam injected gas turbine (STIG) cycle 3. The integrated WC & STIG (SWC) cycle 4. Themo-chemical Recuperation cycles
  • 18. Advanced Turbine Wet compression • One of the most effective ways to increase the gas turbine power output is to reduce the amount of work required for its compressor. • A gas turbine compressor consumes about 30 to 50% of work produced by the turbine.
  • 19. Advanced Turbine Intake Air Inlet Duct Water InjectionCompressor Combustor Fuel Turbine G The wet compression (WC) cycle
  • 20. Advanced Turbine The wet compression (WC) cycle • The wet compression cycle has the following benefits over the simple cycle. • Lower compressor work • Higher turbine work • Higher cycle efficiency
  • 21. Advanced Turbine The steam injected gas turbine (STIG) cycle G Compressor Turbine Combustor Fuel Injection Steam Exhaust HRSG water pump Intake Air HRSG – Heat Recovery Steam Generator
  • 22. Advanced Turbine The steam injected gas turbine (STIG) cycle • Steam injection into the combustion chamber of a gas turbine is one of the ways to achieve power augmentation and efficiency gain. • In a steam injected gas turbine (STIG), the heat of exhaust gasses of the gas turbine is used to produce steam in a heat recovery steam generator. • The steam is injected into the combustion chamber or before entering the combustion chamber (i.e. in the compressor discharge). • STIG cycle has higher cycle efficiency than the WC cycle. • STIG cycle gives higher net work out put than the WC cycle up to a pressure ratio of 7.
  • 23. Advanced Turbine G Intake Air Water injection Inlet Duct Compressor Turbine Combustor Fuel Injection Steam Exhaust HRSG water pump The integrated WC & STIG (SWC) cycle HRSG – Heat Recovery Steam Generator
  • 24. Advanced Turbine The integrated WC & STIG (SWC) cycle • It has the combined benefit of the advantage of higher efficiency of STIG cycle and higher net work output of WC cycle. • But its cycle efficiency is less than that of the STIG cycle owing to the need for higher heat input.
  • 25. Advanced Turbine Comparison of typical parameters of simple, WC,STIG and SWC cycles. cycle Pressure ratio PR Evaporat ive rate, kg/k Net work output, MW Cycle efficienc y % Fuel mass flow rate, kg/sec Steam mass flow rate, kg/sec simple 11 0 151.13 31.28 11.04 0 WC 11 7.5e-4 232.75 35.35 15.04 0 STIG 11 0 215.65 39.63 12.43 54.49 SWC 11 7.5e-4 303.11 38.16 18.15 54.49
  • 26. Advanced Turbine • There are many areas and challenges which can be explored further to this work. • They are: • Economic feasibility of these cycles need to be studied. • Compressor life reduction due to water injection. (because of the off design running conditions that prevail in reality). • The difficulties involved in designing a turbine to handle large mass flow rates of combustion gasses and steam. • The effect of steam injection in reducing Nitrogen Oxides (NOX) emissions
  • 27. Advanced Turbine – Wind Turbine • A wind turbine is a device that converts kinetic energy from the wind into electrical power . • Conventional horizontal axis turbines can be divided into three components:. • Wind turbine used for charging batteries may be referred to as a wind charger.
  • 28. Advanced Turbine • A designed nano-turbine constructed by a single-wall carbon nanotube (CNT) and graphene sheets. • This nano-turbine can largely unidirectionally rotate as driven by a steady water flow. • The mechanism by which the nano-device works at nanoscale and the difference between the behavior of mechanical motion of a nano-device and its macroscopic analogue still largely remain elusive. • The averaged rotation rate of the nano-turbine shows linear relationship with the flow velocity through two orders of magnitude.
  • 29. Advanced Turbine • Compared to the macroscopic counterpart, the rotation rate of nano-turbine is much slower. • Its efficiency of converting energy from fluid flow to the mechanical motion is only 6.4% of that of an ideal macroscopic counterpart. • As indicated by the distribution of flow velocity, the ‘‘effective’’ driving flow velocity is remarkably smaller than the bulk flow velocity and the ratio can be as low as 0.15. • The disruption of water flow, together with the water slippage at graphene surface and the dragging effect, should be related to the much slower rotation rate.
  • 30. Advanced Turbine • The ratio of effective driving flow velocity decreases as the flow velocity increase, suggesting that the linear relationship between rotation rate and flow velocity may be more complicated. The water slippage and dragging, may get enhanced at the same time. • The top view (left) and side view (right) of the designed nano-turbine placed along the z-axis, visualized with VMD40. The two fixed pole carbon atoms are shown as the golden balls. The rotation of nano-turbine is driven by the water flow along the – z-direction. The 2-A° slab above the turbine blade is shown as the green region.
  • 31. Applications • Almost all electrical power on earth is produced with a turbine of some type. • Very high efficiency turbines harness about 40% of the thermal energy with the rest exhausted as waste heat. • Most jet engines rely on turbines to supply mechanical work from their working fluid and fuel as do all nuclear ships and power plants.