Thursday, 5 September 2013

6.practical for Energy Conservation Technique for Diploma electrical engineering.

PRACTICAL -6

 AIM:- TO STUDY ABOUT USE OF COMBINED CYCLE POWER PLANT AND USE OF CO-GENERATION PLANT 

·        USE OF COMBINED CIRCLE POWER PLANT:

Power supply industry is highly capital intensive. Therefore, it is desirable to utilize it in optimum manner. There are two aims of the national economy.

(I)To create the maximum amount of generating capacity with the available    funds.
(ii)To generate power at the cheaper rate.

So, before investing huge amount in this industry, the most economic generating scheme should be selected to supply power at the lowest cost.
            The maximum steam temperature in a power plant not exceeds 6000C. However, the flame temperature in a boiler burning fossile fuels is about 16000C.as heat transferred from combustion gases to thermal irreversibility. So the use of gas turbine alone to drive the generator, would be uneconomical, however, the high exhaust temperature of the gas turbine can drive a steam turbine in the second stage. This is possible through combined cycle.
The production of electricity using two or more heat engines one by one as prime movers to operate electric generators called combined cycle power generation. First heat engine works at higher temperature. Part of heat from first discharge at lower temperature serves as the source for the next engine. The net result is a greater overall operating temperature range.
            The combined cycle concept combines two thermodynamic cycles.
(i)                Brayton cycle
(ii)             Rankine cycle

The Brayton cycle has the capability to operate at very high combustion temperature (say 12000C) and gives high efficiency at high temperature. The Rankine cycle will operate at low combustion temperature (say 5400C) and gives high efficiency at low temperature. If steam turbine or gas turbine operates independently, system efficiency will be lower. If both turbines operate in combined cycle, system efficiency will be of the order of 42-47%. The first installation of the combined cycle was commissioned in Germany in 1973.the system has a net output of approximately 35MW. In India, gas turbine can be used for power generation to exploit the vast reserves of natural gas.

First of all, air is compressed from atmosphere and given to combustion chamber. Fuel is burned by keeping air-fuel ratio constant. So inlet temperature ay Gas turbine is approximately 1200-13000 C. mechanical output is obtained by decompressing it in the gas turbine. This mechanical output is given to the electric generator-1 and electricity is produced by it. Outlet temperature of gas turbine is approximately 6000C. Gas from outlet is given to the HRSG (Heat Recovery Steam Generator). Steam is generated from HRSG with the help of super heater, evaporator, economizer etc and its temperature is about 5500C. Gas is exhausted to atmosphere from HRSG. Steam at lower temperature (approximately 5500C). Is given to steam turbine. Mechanical output is given to electrical generator-2 and electricity is produced by it. Steam from outlet of steam turbine is at approximately 400C to 800C. This steam is condensed in condenser and hot water is pumped to HRSG by feed water pump.
Combined cycle plants may of the following types.
(i)                Gas turbine-steam turbine plant
(ii)             MHD-steam plant
(iii)           Thermionic-system plant
(iv)           Thermoelectric-steam plan

v ADVANTAGES OF COMBINED CYCLE POWER GENERATION:
The following are the advantages of combined cycle power generation.
(1)  Higher efficiency
(2)  Low investment costs
(3)  Small amount
(4)  Great operating flexibility
(5)  Simplicity of operation
(6)  Low environmental impact
(7)  Small amount of water required

v USE OF CO-GENERATION PLANTS:
            Co-generation is a procedure for generating electric power and useful heat in a single installation. The useful heat may be in the form of steam, hot water or hot air. Thus, cogeneration is the simultaneous generation of electricity and steam (or heat) in a single power plant. In cogeneration system, mechanical work is converted into electrical energy in an electric generator and the discharge heat is utilized in an industrial process or in other ways. So the net result is an overall increase in the efficiency of fuel utilization.

v Many industries like chemicals, fertilizers, papers, textiles, sugar, food processing etc. require steam for heating and electric power for drives. Earlier, due to reliable electric power from government, these industries started generating only steam for process requirements. Now, electrical form state electricity boards are more expensive and lead to shortages, so cogeneration is being used extensively. It saves approximately 20% fuel and reduces the burden on electrically boards. Government is also encouraging.

(1)TYPES OF COGENERATION:

There are two board categories of co-generation.
v The bottoming cycle
v The topping cycle



v The bottoming cycle: Primary heat is used at high temperature directly for process requirements. Waste heat from process is used for electrical power generation. It is difficult to extract power economically in the bottoming cycle plants. It has low efficiency and therefore it is not widely used.

v The topping cycle: 

         First electricity is generated by steam turbine or gas turbine or diesel engine, and then exhaust steam or gas is used for process equipments. Process steam at low pressure and temperature is exhausted by two ways depending on process requirements.

(A)Extracted from turbine at an intermediate stage
(B) Taken at the turbine exhaust.


Therefore, topping cycle can provide true savings in primary energy. Also process applications require low pressure, low temperature. (Sometimes moderate temperature) steam. Such steam is easily produced in a topping cycle.

v Advantages of Co-generation:

The advantages of Co-generation applications for industrial use as

(I)Lower capital costs: The capital investment for co-generation is much lower than that of two separate systems for steam and electric power. Industries needing steam for their processes have to install boilers. To a kW of power from this steam is about ½ costly than the cost of installing and supplying a kW by a grid.

(ii)Energy efficiency: The energy efficiency can reach to 80% or even higher. This depends on the co-generation plant configuration and the utilization of heat. Energy is also saved in transportation of fuel.

(iii)Lower Gestation period: Co-generation plants can be commissioned in 1.5 years to 3 years. A central station may take more than 5 to 6 years. The shorter gestation period of cogeneration curtails the scope of time over-runs and reduces the cost of interest during constriction

(iv)Quality of supply: Since cogeneration uses simpler equipment which operates on lower temperatures and pressures, reliability of cogeneration is high. They reduce dependence of industries on the unreliable grid supply. Voltage of supply can also be much better controlled. Here, transmission and distribution losses are negligible.

(v)Reduction in Pollution levels: Cogeneration systems require 20% to 25% lesser fuel than for two separate systems for electricity and steam generation. Due to less usage of fuel, pollution levels will be lower.




v Constraints of Co-generation Plants:
(i)                Limitations faced by Industries: Due to lack of awareness, financial constrains, technology inadequacy, problems of coal etc., cogeneration capacity is not much accelerated of 8 to 10%. High T&D losses in the power system have been the subject of criticism particularly in concern with power shortages. The power shortages may lead to put up additional highly cost intensive generating capacity. Since power is backbone of development of any country. So the percentages of losses in T&S system are alarming.











LIST OF FIGURE.
Fig.1- combined cycle without reheat of exhaust gases.
Fig.2- Bottoming cycle.
Fig.3- Topping cycle.

Fig.4- Gas turbine plant with exhaust heat recovery system.



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