Abstract
Emission control devices such as selective catalytic reduction (SCR), exhaust gas recirculation (EGR), and scrubbers were installed in the compression ignition (CI) engine, and flow analysis of intake air and exhaust gas was required to predict the performance of the CI engine and emission control devices. In order to analyze such gas flow, it was inefficient to comprehensively analyze the engine’s cylinder and intake/exhaust systems because it takes a lot of computation time. Therefore, there is a need for a method that can quickly calculate the gas flow of the CI engine in order to shorten the development process of emission control devices. It can be efficient and quickly calculated if only the parts that require detailed observation among the intake/exhaust gas flow of the CI engine are analyzed in a 3D approach and the rest are analyzed in a 1D approach. In this study, an algorithm for gas flow analysis was developed by coupling 1D and 3D in the valve systems and comparing with experimental results for validation. Analyzing the intake/exhaust gas flow of the CI engine in a 3D approach took about 7 days for computation, but using the developed 1D–3D coupling algorithm, it could be computed within 30 min. Compared with the experimental results, the exhaust pipe pressure occurred an error within 1.80%, confirming the accuracy and it was possible to observe the detailed flow by showing the contour results for the part analyzed in the 3D zone. As a result, it was possible to accurately and quickly calculate the gas flow of the CI engine using the 1D–3D coupling algorithm applied to the valve system, and it was expected that it can be used to shorten the process for analyzing emission control devices, including predicting the performance of the CI engine.
Highlights
Environmental pollutants emitted from compression ignition (CI) engines used for propulsion and electricity generation of ships were regulated according to the regulations of the International Maritime Organization (IMO) and regulations on SOx and NOx are gradually being strengthened
In order to quickly and accurately calculate the gas flow of the CI engine, the 1D–3D coupling algorithm that could be applied to the valve system was developed
The results of the gas flow analysis using this algorithm were verified by comparing them with the experimental results, as summarized below: (1) An algorithm for coupling 1D and 3D for valve systems was developed by applying the calculation using the method of characteristics (MOC) to a commercial computational fluid dynamics (CFD) code; (2) In the case of analyzing the gas flow using the 1D–3D coupling algorithm, it could be computed within 30 min
Summary
Environmental pollutants emitted from compression ignition (CI) engines used for propulsion and electricity generation of ships were regulated according to the regulations of the International Maritime Organization (IMO) and regulations on SOx and NOx are gradually being strengthened. Zhu et al performed simulation analysis on the high-pressure SCR system in a marine diesel using the commercial CFD code Ansys Fluent and analyzed the characteristics of vaporizer/mixers [15] These advanced studies are focused on analyzing the emission control device, and if the engine specifications change, the characteristics will change. The 3D approach CFD has the disadvantage that it takes a long time to compute, so it is not suitable for analyzing the intake/exhaust gas flow by applying the emission control devices installed in the CI engine. Marine CI engines are designed in consideration of the pulsating flow of intake/exhaust gas, and when the emission control device is installed in the existing engine, it is necessary to analyze pulsating flow to predict their performance. Where A is the non-dimensional speed of sound, U is the non-dimensional velocity, and the gas flow of the intake/exhaust system of the CI engine is analyzed using λ and β, which are characteristics
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