ELECTRIC POWER GENERATION
Unit 2 Lecture 4
Continuation on various classifications of gas turbine power plant:
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 (e.g. hot exhaust fumes) from combustion is generally wasted. Combining two or more "cycles" such as the Brayton cycle and Rankine cycle results in improved overall efficiency. It can also work with the Otto, diesel, and Crower cycles which may allow it to be suited to automotive use. Aside from the Rankine cycle, the Stirling cycle could also be used to re-use waste heat in automotive or aeronautical applications, for the simple reason that there is less weight (water) to carry and that stirling engines or turbines can be made to operate with low temperature differences.
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).
Open Cycle Gas Turbine Power Plant
In this type of plant the atmospheric air is charged into the combustor through a compressor and the exhaust of the turbine also discharge to the atmosphere.
In actual operation the processes along 2-3 and 4-1 are never isentropic and the degree or irreversibility of these processes and the mechanical efficiencies of the machine components greatly reduce the ideal value of thermal efficiencies of the cycle.
If the air entering the combustor is preheated by the heat of exhaust gases escaping from the turbine, some heat can be recovered resulting into an increase in the efficiency of the cycle improved. Such heating of combustion air is known as regeneration and the heat exchanger transferring heat from gas to air is called regenerator.
Since most of the output of turbine is consumed by the compressor, the actual efficiency of the cycle greatly depends upon an efficient working of the compressor. To attain higher compression ratios, it is necessary to use multi-stage compression with inter-cooling.
In actual practice, all these modifications, viz. regeneration, reheating and inter-cooling are combined in a simple modified cycle and a substantial gain in the overall plant efficiency is attained.
Closed Cycle Gas Turbine Power Plant
In this type of power plant, the mass of air is constant or another suitable gas used as working medium, circulates through the cycle over and over again.
A closed-cycle gas turbine is a turbine that uses a gas (e.g. air, nitrogen, helium, argon, etc.) for the working fluid as part of a closed thermodynamic system. Heat is supplied from an external source. Such recirculating turbines follow the Brayton cycle.
In the closed cycle, quantity of air is constant, or another suitable gas used as working medium, circulates through the cycle over and over again. Combustion products do not come in contact with the working fluid and, thus, remain closed.
A development in the basic gas turbine cycle is the use of the closed cycle which permits a great deal of flexibility in the use of fuels. Moreover, working medium of the plant could by any suitable substance other than air which would give higher efficiency. An arrangement of closed gas turbine cycle is shown in Figure. In this cycle, working fluid is compressed through the requisite pressure ratio in the compressor, and fed into the heater, where it is heater up to the temperature of turbine itself. The fluid is then expanded in the turbine and the exhaust is cooled to the original temperature in the pre-cooler. It then re-enter the compressor to begin the next cycle. Thus, the same working fluid circulates through the working parts of the system. The heater burns any suitable fuel and provides the heat for heating the working fluid. In fact, this combustor is akin to an ordinary boiler furnace, working at the atmosphere pressure and discharging the gaseous products to the atmosphere. There is, thus, a great deal of flexibility in respect of furnace design and use of fuel, allowing low cost fuel to be used.