Given the spotlight on waste heat recovery (WHR) technologies for decarbonizing the shipping industry,
critically assessing waste heat from propulsion and auxiliary engines using actual data is crucial for accurately
predicting fuel and carbon savings. This paper addresses this by applying advanced data processing, considering
voyage characteristics, and developing methods for mapping waste heat from main engine (ME) and diesel
gensets (DGs) operations using long-term operational data from a Very Large Crude Carrier (VLCC) case
study. Two methods predict unrecorded air mass flows by implementing heat balance: one using measured
temperature values and the other estimating exhaust gas mass flow rates based on fuel oil consumption. Within
the main objectives of this study is to examine the impacts of employing the exhaust gases of both ME and
DGs to evaporate recuperative ORC working fluid on power output and vessel annual carbon savings, with
the formed diesel engines operational profiles serving as inputs. Simulations show a power output of 530 kW
using ME exhaust gases, increasing to 653 kW and 741 kW with DGs integration for R245fa and R1233zd(E)
as the selected ORC working fluids, respectively. The proposed solutions can reduce annual CO2 emissions by
4 % to 7 %.
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Given the spotlight on waste heat recovery (WHR) technologies for decarbonizing the shipping industry,
critically assessing waste heat from propulsion and auxiliary engines using actual data is crucial for accurately
predicting fuel and carbon savings. This paper addresses this by applying advanced data processing, considering
voyage characteristics, and developing methods for mapping waste heat from main engine (ME) and diesel
gensets (DGs) operations using long-term operational data from a...
»
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