Abstract
This paper presents a comparison of the conventional dual pressure steam Rankine cycle process and the organic Rankine cycle process for marine engine waste heat recovery. The comparison was based on a container vessel, and results are presented for a high-sulfur (3 wt %) and low-sulfur (0.5 wt %) fuel case. The processes were compared based on their off-design performance for diesel engine loads in the range between 25% and 100%. The fluids considered in the organic Rankine cycle process were MM(hexamethyldisiloxane), toluene, n-pentane, i-pentane and c-pentane. The results of the comparison indicate that the net power output of the steam Rankine cycle process is higher at high engine loads, while the performance of the organic Rankine cycle units is higher at lower loads. Preliminary turbine design considerations suggest that higher turbine efficiencies can be obtained for the ORC unit turbines compared to the steam turbines. When the efficiency of the c-pentane turbine was allowed to be 10% points larger than the steam turbine efficiency, the organic Rankine cycle unit reaches higher net power outputs than the steam Rankine cycle unit at all engine loads for the low-sulfur fuel case. The net power production from the waste heat recovery units is generally higher for the low-sulfur fuel case. The steam Rankine cycle unit produces 18% more power at design compared to the high-sulfur fuel case, while the organic Rankine cycle unit using MM produces 33% more power.
Highlights
IntroductionShipping is environmentally friendly and cost-effective compared to other means of transport, the shipping industry is responsible for large amounts of emissions of CO2 , SOx (sulfur oxides) and NOx (nitrogen oxides)
The majority of goods transported world-wide are carried by sea
The waste heat recovery (WHR) system designs resulting from the design optimizations are listed in Table 4 for the high-sulfur fuel case
Summary
Shipping is environmentally friendly and cost-effective compared to other means of transport, the shipping industry is responsible for large amounts of emissions of CO2 , SOx (sulfur oxides) and NOx (nitrogen oxides). Such emissions result from the combustion of fossil fuels like heavy fuel oil (HFO) in the machinery system of the ship. The propeller shaft is coupled directly to a slow speed two-stroke diesel engine, which delivers the required propulsion power. Electricity demands for pumps, fans, lighting, cooling, etc., are typically supplied by four stroke auxiliary engines or alternatively by a shaft generator mounted on the propeller shaft. Heat from the jacket cooling water is typically used in the fresh
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