TECHNO ECONOMIC ANALYSIS OF COMBINED ORGANIC RANKINE CYCLE AND LNG REGASIFICATION SYSTEM FOR POWER PLANT GAS SUPPLY
Necessity for long term electricity development is being forced by PLN requirement to develop efficient investment plan, as stated in Indonesia’s Power Supply Business Plan (RUPTL) 2018. This thing is important to be done because investment decision in the electrical power supply industry benefit...
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| Format: | Theses |
| Language: | Indonesia |
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| Online Access: | https://digilib.itb.ac.id/gdl/view/37885 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Necessity for long term electricity development is being forced by PLN requirement
to develop efficient investment plan, as stated in Indonesia’s Power Supply Business
Plan (RUPTL) 2018. This thing is important to be done because investment decision
in the electrical power supply industry benefits, will be demanded in a long term
period. Lowest electricity cost will be acquired by minimizing net present value of
all electricity cost components consits of capital cost, fuel cost, operation and
maintenance cost. PLN is planning new power plants that will be operated using
LNG or gas fuel. In this study, the analysis will be conducted about design of LNG
regasification system by using organic rankine cycle that utilize sea water as the
heat source, therefore there will be a working cycle that utilize sea water as the
heat reservoir and LNG flow as cold reservoir. The research metode is by create,
calulate and simulate the thermodynamic cycle of combined organic rankine cycle
and LNG regasification system, also then calculate the capital cost and operation
cost of the system. The choice of organic fluid are propana, ethana, butana, R32
and R41. From the result can be known that the combined organic rankine cycle
and LNG regasification system with lowest cost over production ratio is the one
that utilize R41 as working fluid. Then followed by ethana, propana R32 and
butana. From the result also can be known that the ORC system with highest exergy
efficiency is the one that utilize R41 as working fluid. Then followed by the one that
utilize R32, propana, ethana and butana respectively. Combined LNG
regasification and ORC system with propane as working fluid can be an option,
when it is required to create a system with high power production and environement
friendly working fluid. From the study result, it is known that the combined LNG
regasification and ORC system with butane as working fluid, provide cheapest
capital cost and operatio cost, however also provide highest cost over power
production ratio. Therefore, system with butane as working fluid may be a better
option if its only required to create LNG regasification without additional power
cycle. |
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