PRE-FEASIBILITY STUDY FOR THE OPTIMIZATION OF ENERGY CONSUMPTION AND CARBON DIOXIDE GAS EMISSIONS IN CONDENSATE STABILIZATION UNIT THROUGH THE APPLICATION OF HEAT PUMP SYSTEM INTEGRATED DISTILLATION TECHNOLOGY
The phenomenon of global warming originating from excessive carbon dioxide gas emissions has caused serious damage to important sectors of human life. Therefore, in line with the government's efforts to reduce the effects of prolonged global warming, this study evaluates measures that can in...
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| Format: | Theses |
| Language: | Indonesia |
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| Online Access: | https://digilib.itb.ac.id/gdl/view/68034 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The phenomenon of global warming originating from excessive carbon dioxide gas
emissions has caused serious damage to important sectors of human life. Therefore,
in line with the government's efforts to reduce the effects of prolonged global
warming, this study evaluates measures that can increase the greenery level in
crude oil field facilities. This study aims to conduct a pre-feasibility study of technoeconomics
by comparing the integrated heat pump distillation and multi-stage flash
vaporisation technologies for the application of a new condensate stabilization unit
(greenfield), so that utility consumption in the form of heating load and electrical
power and the amount of carbon dioxide gas emissions can be reduced
significantly. The base model applies multi-stage flash vaporisation technology,
with a heating load requirement of 2750 W and an electrical power demand of 2034
kW.
Simulation modeling for all models within the scope of this study was carried out
using the ASPEN HYSYS software in steady state conditions. Optimized models 1
and 2 are modifications of the base case model by applying the feed splitting stream
feature for heat utilization. Optimized model 3 is a modification of the base case
model by applying the feed splitting stream feature along with stabilizer column
and reboiler to replace the LP separator feed heater and LP separator. Optimized
models 4 and 5 are modifications of the base case model by applying mechanical
vapor recompression and heat integrated distillation column technologies. The
technical aspects that are evaluated are utility consumption in the form of heating
and electrical power loads, along with the amount of carbon dioxide gas emissions,
while the economic aspects that are evaluated are total investment costs, total
operating costs, and total annual costs. The evaluation related to the economic
aspect is carried out based on a minimum feasibility estimate of class V with an
accuracy of -30%/50%.
Optimization model 5 has the smallest total duty and carbon dioxide gas emissions
rate among all optimized models, approximately 4784 kW and 201 kg/h, with a
percentage saving of total duty and carbon dioxide gas emissions rate with respect
to the base model around 63.5% and 57.41%, respectively. However, optimized
model 4 has the lowest OPEX cost, around $517,231, because optimized model 4
has a smaller power requirement of about 65.8% compared to optimized model 5.
For a small difference in total duty, the electrical power requirement becomes the
determining factor of OPEX level, because the production cost of electric power
utility is more expensive than heating load utility. Therefore, optimized model 4 has
the smallest TAC among all optimized models, around $3,247,015, with a TAC
saving percentage with respect to the base case model of 31.25%.
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