한국해양대학교

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A Study on the Combustion and Emission Characteristics of Dual-Fuel Marine Engines Using Various Alternative Fuels

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dc.contributor.advisor 최재혁 -
dc.contributor.author Pham Van Chien -
dc.date.accessioned 2022-06-23T08:57:44Z -
dc.date.available 2022-06-23T08:57:44Z -
dc.date.created 20220308093445 -
dc.date.issued 2022 -
dc.identifier.uri http://repository.kmou.ac.kr/handle/2014.oak/12846 -
dc.identifier.uri http://kmou.dcollection.net/common/orgView/200000603133 -
dc.description.abstract The shipping industry is being responsible for a significant proportion of climate change and global warming problems due to exhaust gas emissions from marine engines. As a result, the International Maritime Organization (IMO) emission regulations, as well as the local emission regulations, are becoming increasingly strict to protect human health and the environment. In another aspect, due to fossil fuels are being depleted resulting in the fuel price is being increased, there are urgent needs to undertake research and develop feasible alternative fuels to substitute for petroleum-based fuels aiming to meet the increasing global energy demand, thereby reducing the reliance on fossil-derived fuels, as well as minimum environmental and economic impacts. This thesis presents studies on the effects of various viable alternative fuels on the combustion and emission characteristics of four-stroke and two-stroke heavy-duty dual-fuel (DF) marine engines. The computational fluid dynamic (CFD) approach together with the support of computer simulation software (AVL FIRE and ANSYS FLUENT) were used to conduct three-dimensional (3D) simulations of the combustion and emission formations occurring inside the engine cylinder in both diesel and DF mode to analyze the in-cylinder pressure, temperature, performance and emission characteristics of the engine. The effectiveness of various viable alternative fuels, such as methane (CH4), ethane (C2H6), propane (C3H8), butane (C4H10), dimethyl ether (DME), and H2+CH4 mixture, when being employed as the primary fuel in the DF mode of the engines has been analyzed and evaluated in terms of engine performance and emission formation. The numerical simulation results were then compared and showed a good agreement with the experimental results reported in the engine’s shop test technical data. The results showed significant benefits in both economic and environmental aspects of using gaseous fuels as the primary fuel in DF engines instead of diesel only in diesel engines. In particular, the researched fuels reduced exhaust gas emissions while keeping the engine power almost unchanged, even increasing the engine power in some operating modes. This thesis has also studied the effects of some operating factors that affect the combustion and emission characteristics of the engine, such as the start of injection (SOI) timing and scavenging air temperature (SAT), aiming to find a way to further increase engine power and emission performance. The study results showed that in-cylinder peak pressure and temperatures were reduced as the SOI angle reduced in both diesel and DF modes, resulting in a reduction in NO emission, however, there also were reductions in the engine power. Analyzing the effects of the SAT cooling method on the combustion and emission characteristics of the engine showed that this method not only enhanced the engine performance but also reduced exhaust gas emissions. The studies in this thesis have successfully analyzed the benefits of using various viable alternative fuels as primary fuels for heavy-duty DF marine engines, as well as the effectiveness of the SOI angle adjustment and SAT cooling methods in reducing exhaust gas emissions and keeping or enhancing engine performance of the engines to meet the emission regulations of IMO without using any emission after-treatment devices that were very rare to be found in previous studies. -
dc.description.tableofcontents Chapter 1 INTRODUCTION 1 1.1 Introduction 1 1.2 Aims and Methodology 3 1.2.1 Aims of the Research 3 1.2.2 Methodology 3 1.3 Structure of the Thesis 4 Chapter 2 BACKGROUND AND LITERATURE REVIEW 5 2.1 Dual-Fuel Engine Concept 5 2.2 Merits of Operating on Gaseous Fuels 8 2.3 Combustion Process and Emission Formations in Dual-Fuel Engines 11 2.3.1 Combustion Process of Dual-Fuel Engines 11 2.3.2 Emission Formations in Dual-Fuel Engines 14 2.4 Comparison of Dual-Fuel Engines and Diesel Engines 17 2.4.1 Diesel engines 17 2.4.2 Dual-Fuel engines 18 2.5 Modelling the Combustion of Dual-Fuel Engines 19 Chapter 3 Theoretical Analysis 23 3.1 Combustion Basis Knowledge 23 3.2 Conservation Laws in Combustions 25 3.2.1 General Species Transport Equation 25 3.2.2 Mass Conservation Equation 25 3.2.3 Momentum Conservation Equation 26 3.2.4 Energy Conservation Equation 26 3.3 Combustion Models 27 3.3.1 Non-Premixed Combustion 27 3.3.2 Premixed Combustion 29 3.3.3 Partially Premixed Combustion 32 3.3.4 Extended Coherent Flame Model (ECFM) 33 3.3.5 Probability Density Function (PDF) Approach 33 3.4 Turbulence Models 35 3.4.1 Overview 35 3.4.2 The Standard k-ε model 37 3.4.3 The k-ζ model 38 3.5 Pollutant Formation Models 39 3.5.1 The NOx emission 39 3.5.2 The Kinetic Soot Model 41 3.5.3 The Moss-Brookes Model 42 3.6 Fuel Spraying Models 44 3.6.1 Fuel Droplet Motion Theory 44 3.6.2 Fuel Breakup Models 46 3.7 Heat Transfer 49 3.7.1 Modeling Conductive and Convective Heat Transfer 50 3.7.2 Modeling Radiation 51 Chapter 4 COMPUTATIONAL FLUID DYNAMICS APPROACH AND CFD CODE 53 4.1 Computational Fluid Dynamics (CFD) Approach 53 4.2 CFD Codes and Simulation Software 54 4.2.1 ANSYS FLUENT Code 55 4.2.2 AVL FIRE Code 56 Chapter 5 SIMULATION OF THE COMBUSTION AND EMISSION CHARACTERISTICS OF A FOUR-STROKE NATURAL GAS/DIESEL DUAL-FUEL MARINE ENGINE 58 5.1 Introduction 58 5.2 Simulated Engine and CFD Models 60 5.2.1 Simulated Engine Specifications 60 5.2.2 Three-Dimensional CFD Simulation Models 62 5.2.3 Computational Domain and Initial Conditions 65 5.2.4 Simulation Conditions 68 5.2.5 Mesh Independence Analysis 69 5.2.6 CFD Models Validation 72 5.3 Simulation Results 73 5.3.1 In-cylinder Fluid Flow Turbulence 73 5.3.2 In-cylinder Pressure 74 5.3.3 In-cylinder Temperature and NO Emission 77 5.3.4 Soot Formation 80 5.3.5 Carbon Monoxide (CO) and Carbon Dioxide (CO2) Emissions 83 5.3.6 In-cylinder Temperature Contours 85 5.3.7 Effects of Injection Timing on Combustion and Emission Formations 88 5.4 Conclusions 93 Chapter 6 SIMULATION OF THE COMBUSTION AND EMISSION CHARACTERISTICS OF A FOUR-STROKE DUAL-FUEL MARINE ENGINE USING VARIOUS ALTERNATIVE FUELS 95 6.1 Introduction 95 6.2 Numerical Setup 101 6.2.1 Engine Specifications and Fuel Properties 101 6.2.2 CFD Simulation Models 103 6.2.3 Computational Mesh, Boundary and Initial Conditions 105 6.2.4 Simulation Conditions 106 6.2.5 Mesh Independence Analysis 108 6.2.6 CFD Simulation Model Validation 110 6.3 Simulation Results 112 6.3.1 In-Cylinder Fluid Flow Turbulence 112 6.3.2 In-Cylinder Pressure 114 6.3.3 In-Cylinder Temperature and NO Emission 117 6.3.4 Soot Formation 121 6.3.5 Carbon Dioxide (CO2) Emissions 124 6.3.6 Ignition Delay 126 6.3.7 Effects of Injection Timing on Combustion and NO Emission 128 6.4 Conclusions 135 Chapter 7 SIMULATION OF THE COMBUSTION AND EMISSION CHARACTERISTICS OF A TWO-STROKE DUAL-FUEL MARINE ENGINE USING HYDROGEN AND METHANE MIXTURES 137 7.1 Introduction 137 7.2 Computational Fluid Dynamic (CFD) Analysis 142 7.2.1 Engine Specifications and Fuel Properties 142 7.2.2 CFD Models 146 7.2.3 Computational Mesh, Boundary and Initial Conditions 147 7.2.4 Simulation Conditions 151 7.2.5 CFD Model Validations 153 7.3 Simulation Results 154 7.3.1 In-Cylinder Fluid Flow Turbulence 154 7.3.2 In-Cylinder Pressure and IMEP 157 7.3.3 In-Cylinder Temperature and NO emission 159 7.3.4 Soot Formation 165 7.3.5 Carbon dioxide (CO2) Emission 168 7.3.6 Heat Loss 170 7.3.7 Effects of Scavenging Air Temperature on Combustion and Emissions.171 7.4 Conclusions 186 Chapter 8 CONCLUSIONS 188 8.1 Simulation of the Combustion and Emission Characteristics of a Four-Stroke Natural gas/Diesel Dual-Fuel Marine Engine 188 8.2 Simulation of the Combustion and Emission Characteristics of a Four-Stroke Dual-Fuel Marine Engine Using Various Alternative Fuels 190 8.3 Simulation of the Combustion and Emission Characteristics of a Two-Stroke Dual-Fuel Marine Engine Using Hydrogen and Methane Mixtures 191 -
dc.language eng -
dc.publisher 한국해양대학교 대학원 -
dc.rights 한국해양대학교 논문은 저작권에 의해 보호받습니다. -
dc.title A Study on the Combustion and Emission Characteristics of Dual-Fuel Marine Engines Using Various Alternative Fuels -
dc.title.alternative 다양한 대체 연료를 사용하는 이중 연료 선박 엔진의 연소 및 배출 특성에 관한 연구 -
dc.type Dissertation -
dc.date.awarded 2022. 2 -
dc.embargo.liftdate 2022-03-08 -
dc.contributor.department 대학원 기관시스템공학과 -
dc.contributor.affiliation 한국해양대학교 대학원 기관시스템공학과 -
dc.description.degree Doctor -
dc.identifier.bibliographicCitation [1]Pham Van Chien, “A Study on the Combustion and Emission Characteristics of Dual-Fuel Marine Engines Using Various Alternative Fuels,” 한국해양대학교 대학원, 2022. -
dc.subject.keyword Methane (CH4); Ethane (C2H6) -
dc.subject.keyword Propane (C3H8) -
dc.subject.keyword Butane (C4H10) -
dc.subject.keyword Dimethyl Ether (DME); Hydrogen (H2); Start of Injection (SOI); Scavenging Air Temperature (SAT); Dual-fuel (DF) engine; Combustion; Emission; Computational Fluid Dynamics (CFD). -
dc.contributor.specialty 동력기계. 재료공학전공 -
dc.identifier.holdings 000000001979▲200000002763▲200000603133▲ -
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