Exergoeconomic Study of a Combined Flash-Binary Cycle at Dieng Unit 2 Geothermal Power Plant
Indonesia has vast potential of geothermal energy. In order to meet future electricity demands, PLN has plans to increase the provision of geothermal power plants. Past research has shown that a combined flash-binary cycle geothermal power plant is proven to increase the thermodynamic performanc...
Saved in:
| Main Author: | |
|---|---|
| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/43732 |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Indonesia has vast potential of geothermal energy. In order to meet future electricity
demands, PLN has plans to increase the provision of geothermal power plants. Past research
has shown that a combined flash-binary cycle geothermal power plant is proven to increase
the thermodynamic performance parameters for a given geothermal resource.
Exergoeconomics is a branch of engineering which combines thermodynamic aspects and
economic aspects in a single approach. Previous research has shown that the result from
exergoeconomic optimization is different than the result from thermodynamic optimization.
This study is done by first specifying the design variables of a geothermal combined
flash-binary cycle power plant, and then reviewing the thermodynamics and
thermoeconomics performance. The design variables chosen are the separator pressure and
the Organic Rankine Cycle (ORC) pump head. The performance parameters reviewed are the
exergy efficiency and the average levelized cost per unit of exergy of the product (electricity).
This study is done on Dieng Unit 2 Geothermal Power Plant, which is still in the feasibility
study phase, and used as the basis for well fluid properties and the recommended constraints.
Based on the simulation results, there is an optimal decision variable for both
performance parameters at 3150 kPa pump head and 2500 kPa separator pressure. On that
point, the exergy efficiency reaches 52,38%, and the electricity cost per unit exergy is
3,04x10
9 USD/J. Both performance parameters reach optimum values on the same point,
which shows that there is no difference between thermodynamic and exergoeconomic
optimization results. On the single-flash cycle simulation result, the performance parameters
reach optimal values at 1900 kPa separator pressure. The cost of electricity per unit exergy
is 4,27x109
USD/J and the exergy efficiency is 36%. It can be concluded that the use of the
flash-binary cycle will be good for both performance parameters.
|
|---|