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A combined cycle is characteristic of a power producing engine or plant that employs more than one thermodynamic cycle. Heat engines are only able to use a portion of the energy their fuel generates (usually less than 50%). The remaining heat from combustion is generally wasted. Combining two or more "cycles" such as the Brayton cycle and Rankine cycle results in improved overall efficiency.

In a combined cycle power plant (CCPP), or combined cycle gas turbine (CCGT) plant, a gas turbine generator generates electricity and the waste heat is used to make steam to generate additional electricity via a steam turbine; this last step enhances the efficiency of electricity generation. Most new gas power plants in North America and Europe are of this type. In a thermal power plant, high-temperature heat as input to the power plant, usually from burning of fuel, is converted to electricity as one of the outputs and low-temperature heat as another output. As a rule, in order to achieve high efficiency, the temperature difference between the input and output heat levels should be as high as possible (see Carnot efficiency). This is achieved by combining the Rankine (steam) and Brayton (gas) thermodynamic cycles. Such an arrangement used for marine propulsion is called Combined Gas (turbine) And Steam (turbine) (COGAS).

Contents 1 Design principle 1.1 Typical size of CCGT plants 1.2 Efficiency of CCGT plants 1.3 Supplementary firing and blade cooling 2 Fuel for combined cycle power plants 2.1 Configuration of CCGT plants 3 Integrated Gasification Combined Cycle (IGCC) 4 Automotive use 5 Aeromotive use 6 See also 7 References 8 External links

[edit] Design principle

In a thermal power station water is the working medium. High pressure steam requires strong, bulky components. High temperatures require expensive alloys made from nickel or cobalt, rather than inexpensive steel. These alloys limit practical steam temperatures to 655 °C while the lower temperature of a steam plant is fixed by the boiling point of water. With these limits, a steam plant has a fixed upper efficiency of 35 to 42%.

An open circuit gas turbine cycle has a compressor, a combustor and a turbine. For gas turbines the amount of metal that must withstand the high temperatures and pressures is small, and lower quantities of expensive materials can be used. In this type of cycle, the input temperature to the turbine (the firing temperature), is relatively high (900 to 1,400 °C). The output temperature of the flue gas is also high (450 to 650 °C). This is therefore high enough to provide heat for a second cycle which uses steam as the working fluid; (a Rankine cycle).

In a combined cycle power plant, the heat of the gas turbine's exhaust is used to generate steam by passing it through a heat recovery steam generator (HRSG) with a live steam temperature between 420 and 580 °C. The condenser of the Rankine cycle is usually cooled by water from a lake, river, sea or cooling towers. This temperature can be as low as 15 °C

[edit] Typical size of CCGT plants

For large scale power generation a typical set would be a 400 MW Gas Turbine coupled to a 200 MW Steam Turbine giving 600 MW. A typical power station might comprises between 2 and 6 such sets.

[edit] Efficiency of CCGT plants

By combining both gas and steam cycles, high input temperatures and low output temperatures can be achieved. The efficiency of the cycles add, because they are powered by the same fuel source. So, a combined cycle plant has a thermodynamic cycle that operates between the gas-turbine's high firing temperature and the waste heat temperature from the condensers of the steam cycle. This large range means that the Carnot efficiency of the cycle is high. The actual efficiency, while lower than this is still higher than that of either plant on its own.

The thermal efficiency of a combined cycle power plant is the net power output of the plant divided by the heating value of the fuel. If the plant produces only electricity, efficiencies of up to 60% can be achieved. In the case of combined heat and power generation, the Energy Utilisation Factor (overall efficiency) can increase to 85%.

[edit] Supplementary firing and blade cooling

The HRSG can be designed with supplementary firing of fuel after the gas turbine in order to increase the quantity or temperature of the steam generated. Without supplementary firing, the efficiency of the combined cycle power plant is higher, but supplementary firing lets the plant respond to fluctuations of electrical load. Supplementary burners are also called duct burners.

More fuel is sometimes added to the turbine's exhaust. This is possible because the turbine exhaust gas (flue gas) still contains some oxygen. Temperature limits at the gas turbine inlet force the turbine to use excess air, above the optimal stoichiometric ratio to burn the fuel. Often in gas turbine designs part of the compressed air flow bypasses the burner and is used to cool the turbine blades.

[edit] Fuel for combined cycle power plants

Combined cycle plants are usually powered by natural gas, although fuel oil, synthesis gas or other fuels can be used. The supplementary fuel may be natural gas, fuel oil, or coal. Integrated solar combined cycle power stations are currently under construction at Hassi R'mel, Algeria and Ain Beni Mathar, Morocco ^[1]. Next generation nuclear power plants are also on the drawing board which will take advantage of the higher temperature range made available by the Brayton top cycle, as well as the increase in thermal efficiency offered by a Rankine bottoming cycle.

[edit] Configuration of CCGT plants

The combined-cycle system includes single-shaft and multi-shaft configurations. The single-shaft system consists of one gas turbine, one steam turbine, one generator and one Heat Recovery Steam Generator (HRSG), with the gas turbine and steam turbine coupled to the single generator in a tandem arrangement on a single shaft. The key advantage of this single-shaft arrangement is its operating simplicity with higher reliability than multi-shaft blocks. Further operational flexibility is provided with a steam turbine which can be disconnected, using a hydraulic clutch, for start up or for simple cycle operation of the gas turbine.

Multi-shaft systems have one or more gas turbine-generators and HRSGs that supply steam through a common header to a separate single steam turbine-generator. In terms of overall investment a multi-shaft system is about 5 % higher in costs.

Single- and multiple-pressure non-reheat steam cycles are applied to combined-cycle systems equipped with gas turbines having rating point exhaust gas temperatures of approximately 540 °C or less. Selection of a single- or multiple-pressure steam cycle for a specific application is determined by economic evaluation which considers plant installed cost, fuel cost and quality, plant duty cycle, and operating and maintenance cost.

Multiple-pressure reheat steam cycles are applied to combined-cycle systems with gas turbines having rating point exhaust gas temperatures of approximately 600 °C.

The most efficient power generation cycles are those with unfired HRSGs with modular pre-engineered components. These unfired steam cycles are also the lowest in cost. Supplementary-fired combined-cycle systems are provided for specific application.

The primary regions of interest for cogeneration combined-cycle systems are those with unfired and supplementary fired steam cycles. Theses systems provide a wide range of thermal energy to electric power ratio and represent the range of thermal energy capability and power generation covered by the product line for thermal energy and power systems.

[edit] Integrated Gasification Combined Cycle (IGCC)

An Integrated Gasification Combined Cycle, or IGCC, is a power plant using synthetic gas (syngas).

[edit] Automotive use

Combined cycles have traditionally only been used in large power plants. BMW, however, has proposed that automobiles use exhaust heat to drive steam turbines.^[2] It may be possible to use the pistons in a reciprocating engine for both combustion and steam expansion like in the Crower 6-stroke.^[3]

[edit] Aeromotive use

Some versions of the Wright R-3350 were produced as "Turbo-compound" engines. Three turbines driven by exhaust gases, known as "Power recovery turbines", provided nearly 600 hp at takeoff. These turbines added power to the engine crankshaft through bevel gears and fluid couplings.^[4]

[edit] See also

• Heat recovery steam generator
• Hydrogen-cooled turbogenerator
• Mercury vapour turbine

[edit] References

v • d • e Thermodynamic cycles Cycles normally with external combustion Gas cycles without phasechange - hot air engine cycles Bell Coleman cycle · Brayton/Joule cycle; (Externally heated) · Carnot cycle · Ericsson cycle · Ported constant volume cycle[1] · Stirling cycle · Pseudo Stirling cycle (same as Adiabatic Stirling cycle) · Stoddard cycle · Vuilleumier cycle Cycles with phasechange Kalina cycle · Rankine cycle (encompasses Organic Rankine Cycle) · Regenerative cycle · Two phased Stirling cycle[2] Cycles normally with internal combustion Atkinson cycle · Brayton/Joule cycle · Diesel cycle · Homogeneous Charge Compression Ignition · Lenoir cycle · Miller cycle · Otto cycle Cycle mixing Combined cycle · HEHC cycle · Mixed/Dual Cycle Not categorized Claude cycle [3] · Claude dual-pressure cycle  · Fickett-Jacobs cycle · Gifford-McMahon cycle [4] · Hirn cycle · Humphrey cycle · Siemens cycle · Hampson-Linde cycle · Linde dual-pressure cycle · Heylandt cycle · Kleemenko cycle

v • d • e Electricity generation Concepts Availability factor · Baseload · Black start · Capacity factor · Dark spread · Demand management · EROEI · Grid storage · Intermittency · Load following · Peak demand · Spark spread Sources Nonrenewable Coal · Natural gas · Petroleum · Nuclear · Oil shale Renewable Biomass · Geothermal · Hydro · Ocean · Solar · Wind Technology AC power · Cogeneration · Combined cycle · Cooling tower · Fossil fuel power plant · Induction generator · Micro CHP · Microgeneration · Pumped hydro · Rankine cycle · Virtual power plant Distribution Demand response · Distributed generation · Dynamic demand · Electricity distribution · Electrical grid · HVDC · Load control · Negawatts · Pylon · Smart grid · Super grid · TSO Policies Carbon offset · Ecotax · Energy subsidies · Feed-in Tariff · Net metering · Pigovian tax · Renewable Energy Certificates · Renewable energy payments · Renewable energy policy Categories: Electricity distribution · Electricity economics · Power station technology · Portals: Energy · Sustainable development

[edit] External links

• Hunstown: Ireland's most efficient power plant @ Siemens Power Generation website
• Natural Gas Combined-cycle Gas Turbine Power Plants Northwest Power Planning Council, New Resource Characterization for the Fifth Power Plan, August 2002
• Combined cycle solar power
• Combined cycle calculation