UNIVERSITI PUTRA MALAYSIA NUMERICAL AND EXPERIMENTAL STUDIES OF HOMOGENEOUS CHARGE COMPRESSION IGNITION ENGINE PERFORMANCE MOHAMMAD IZADI NAJAFABADI FK 2014 55
NUMERICAL AND EXPERIMENTAL STUDIES OF HOMOGENEOUS CHARGE COMPRESSION IGNITION ENGINE PERFORMANCE By MOHAMMAD IZADI NAJAFABADI Thesis Submitted to the School of Graduate Studies,, in Fulfilment of the Requirements for the Degree of Master of Science February 2014
Abstract of thesis presented to the Senate of In fulfilment of the requirement for the degree of Master of Science Chairman: Faculty: NUMERICAL AND EXPERIMENTAL STUDIES OF HOMOGENEOUS CHARGE COMPRESSION IGNITION ENGINE PERFORMANCE By MOHAMMAD IZADI NAJAFABADI Nuraini Abdul Aziz, PhD Engineering February 2014 During the recent decade, an alternative combustion technology, known as Homogeneous Charge Compression Ignition (HCCI), has shown the potential to decrease both emissions and fuel consumption. In spite of its high fuel efficiency and low NO x emission compared to diesel and SI engines, HCCI combustion has some critical difficulties. The main difficulty of HCCI engine is the absence of any external control of ignition timing. Finding the effects of different parameters on the ignition timing is vital to be able to control HCCI engines. The focus of this study was to carry out a detailed numerical and experimental investigation into the factors affecting HCCI ignition timing in a 2-stroke gasoline engine. As the primary objective of this study, a Computational Fluid Dynamic (CFD) model was developed coupled to a semi-detailed chemical mechanism for the 2-stroke engine to investigate the effects of different variables such as intake temperature, air to fuel ratio, scavenging efficiency, and compression ratio on the ignition timing and emissions. As the second objective, effects of different simulation parameters such as turbulence model, grid density, and time step size were investigated to find the best method for simulation of considered engine. As the final objective, validation of numerical results was carried out using experimental study on the 2-stroke engine that was modified to operate in HCCI mode. Results confirmed that k-ε RNG model was the best turbulence model for simulation of this case study coupled to the time step size of 0.25 crank angle degree and the grid size of around 50,000 cells. Results also demonstrated that decreasing the intake temperature, equivalence ratio, residual gasses, and compression ratio can significantly retard the combustion timing and experimental results confirmed that this ignition retarding can considerably increase the engine power and torque. ii
Abstrak tesis dikemukakan kepada Senat sebagai memenuhi keperluan untuk Ijazah Master Sains KAJIAN BERANGKA DAN EKSPERIMEN UNTUK PRESTASI ENJIN PENCUCUHAN MAMPATAN SUAPAN HOMOGEN Pengerusi: Fakulti: Oleh MOHAMMAD IZADI NAJAFABADI Februari 2014 Nuraini Abdul Aziz, PhD Kejuruteraan Sepanjang dekad baru-baru ini, satu teknologi pembakaran dikenali sebagai pencucuhan mampat bercaj seragam (HCCI) telah menunjukkan potensi untuk mengurangkan gas pelepasan dan penggunaan bahan api. Walaupun ia mempunyai kecekapan bahan api yang tinggi dan pelepasan gas NOx yang rendah berbanding enjin diesel dan enjin palam pencucuhan, pembakaran secara HCCI mempunyai beberapa masalah kritikal. Masalah yang utama adalah ketiadaan kawalan luaran pemasaan penyalaan. Mencari kesan-kesan daripada parameter enjin yang berbeza terhadap pemasaan penyalaan adalah penting untuk membolehkan mengawal enjin HCCI. Fokus tesis ini adalah untuk menjalankan satu penyiasatan secara pengiraan terperinci dan eksperimen terhadap faktorfaktor yang mempengaruhi pemasaan penyalaan HCCI pada enjin gas dua lejang. Sebagai objektif utama kajian ini, satu model Dinamik Bendalir Komputeran (CFD) dibangunkan dan ditambah kepada satu mekanisma kimia separa terperinci untuk enjin dua lejang bagi menyiasat kesan-kesan pembolehubah lain seperti pengambilan suhu, nisbah udara untuk bahan api, kecekapan menghapussisa dan nisbah mampatan pada masa penyalaan dan pelepasan. Sebagai objektif kedua, kesan-kesan berbeza parameter simulasi model pergolakan, grid ketumpatan dan saiz masa langkah disiasat untuk mencari kaedah terbaik untuk simulasi enjin tersebut. Sebagai objektif terakhir, pengesahan keputusan daripada model pengiraan dijalankan menggunakan kajian eksperimen terhadap enjin dua lejang yang diubah untuk beroperasi dalam mod HCCI. Keputusan mengesahkan yang model k-ε RNG merupakan model pergolakan terbaik untuk simulasi kajian ini dengan saiz masa langkah sebanyak 0.25 darjah sudut engkol dan saiz grid sebanyak 50,000 sel. Keputusan juga menunjukkan bahawa pengurangan suhu pengambilan, nisbah setara, sisa gas dan nisbah mampatan boleh melengahkan masa penyalaan dengan ketara dan keputusan eksperimen mengesahkan yang pelengahan masa penyalaan ini boleh meningkatkan kuasa dan tork enjin. iii
ACKNOWLEDGEMENTS First of all, I would like to thank my dear spouse, Fahimeh, for her love, warmheartedness and support she has demonstrated during the past two years it has taken me to finalize this thesis. Furthermore I would also like to thank my parents for their countless affection and support. I am grateful for the endless sacrifices they made for me. I would like to thank Dr. Nuraini Abdul Aziz who has supported me throughout my thesis with her valuable guidance and knowledge. I could not have imagined having a better supervisor for my Master study. Also special thanks to my supervisory committee member, Associate Professor Ir. Dr. Nor Mariah Adam, for her encouragement and helpful advice. The author also acknowledges the support of under Research University Grants (RUGS), Project No. 05-05-10-1076RU and Ministry of Higher Education under Exploratory Research Grants Scheme (ERGS), Project Code: ERGS/1/2012/TK01/UPM/02/5 for this research. iv
I certify that a Thesis Examination Committee has met on 3 February 2014 to conduct the final examination of Mohammad Izadi Najafabadi on his thesis entitled "Numerical And Experimental Studies Of Homogeneous Charge Compression Ignition Engine Performance" in accordance with the Universities and University Colleges Act 1971 and the Constitution of the [P.U.(A) 106] 15 March 1998. The Committee recommends that the student be awarded the Master of Science. Members of the Thesis Examination Committee were as follows: Mohd Sapuan b. Salit, PhD Professor Ir. Faculty of Engineering (Chairman) Kamarul Arifin Ahmad, PhD Associate Professor Faculty of Engineering (Internal Examiner) Nur Ismarrubie bt. Zahari, PhD Senior Lecturer Faculty of Engineering (Internal Examiner) Md. Mustafizur Rahman, PhD Associate Professor Universiti Malaysia Pahang Malaysia (External Examiner) NORITAH OMAR, PhD Associate Professor and Deputy Dean School of Graduate Studies Date: 17 February 2014 v
This thesis was submitted to the Senate of and has been accepted as fulfillment on the requirement for the degree of Master of Science. The members of the supervisory committee were as follows: Nuraini Abdul Aziz, PhD Senior Lecturer Faculty of Engineering (Chairman) Nor Mariah Adam, PhD, PE Associate Professor Faculty of Engineering (Member) BUJANG BIN KIM HUAT, PhD Professor and Dean School of Graduate Studies Date: vi
Declaration by graduate student I hereby confirm that: this thesis is my original work; quotation, illustration and citations have been duly referenced; this thesis has not been submitted previously or concurrently for any other degree at any other institutions; intellectual property from the thesis and copyright of thesis are fully-owned by University Putra Malaysia, as according to the University Putra Malaysia (Research) Rules 2012; written permission must be obtained from supervisor and the office of Deputy Vice-Chancellor (Research and Innovation) before thesis is published (in the form of written, printed or in electronic form) including books, journals, modules, proceedings, popular writings, seminar papers, manuscripts, posters, reports, lecture notes, learning modules or any other materials as stated in the (Research) Rules 2012; there is no plagiarism or data falsification/fabrication in the thesis, and scholarly integrity is upheld as according to the University Putra Malaysia (Graduate studies) Rule 2003 (Revision 2012-2013) and University Putra Malaysia (Research) Rules 2012. The thesis has undergone plagiarism detection software. Signature: Date: 20 March 2014 Name and Matric No.: MOHAMMAD IZADI NAJAFABADI, GS31644 vii
Declaration by Members of Supervisory Committee This is to confirm that: the research conducted and the writing of this thesis was under our supervision; supervision responsibilities as started in the university Putra Malaysia (Graduate Studies) Rules 20003 (Revision 2012-2013) are adhered to. Signature: Signature: Name of Name of Chairman of Member of Supervisory Supervisory Committee: Nuraini Abdul Aziz, PhD Committee: Nor Mariah Adam, PhD viii
TABLE OF CONTENTS Page ABSTRACT... ii ABSTRAK... iii ACKNOWLEDGEMENTS... iv APPROVAL v DECLARATION vii LIST OF TABLES... xi LIST OF FIGURES... xii LIST OF ABBREVIATIONS... xvi CHAPTER... 1 1. INTRODUCTION... 1 1.1 Background of the Study... 1 1.1.1 HCCI Concept... 1 1.1.2 Gasoline HCCI Combustion Engines... 2 1.1.3 2-Sroke HCCI Combustion Engine... 4 1.1.4 HCCI Challenges and Proposed Solutions... 5 1.2 Significance of Study... 7 1.3 Problem Statement... 7 1.4 Research Scope... 8 1.5 Objectives... 8 1.6 Thesis Organization... 9 2. LITERATURE REVIEW... 10 2.1 HCCI/CAI Engine... 10 2.1.1 2-Stroke HCCI Engine... 10 2.1.2 4-Stroke HCCI Engine... 14 2.2 Control of HCCI Combustion... 15 2.2.1 Mixture Dilution for HCCI Control... 15 2.2.1 Changing Fuel Properties for HCCI Control... 19 2.2.2 Fast Thermal Management for HCCI Control... 20 2.2.3 Direct Injection for HCCI Control... 22 2.3 HCCI Modeling... 23 2.3.1 Single-zone Thermo-kinetic Model... 24 2.3.2 Multi-zone Models... 24 2.3.3 Full Integration of CFD and Chemical Kinetics Codes... 26 3. MATERIALS AND METHODS... 27 3.1 Introduction... 27 3.2 Numerical Method... 28 ix
3.2.1 Geometry and Grid Generation... 29 3.2.2 Governing Equations and Solver Algorithm... 34 3.2.3 Wall Function... 36 3.2.4 Chemical Reactions... 37 3.2.5 Dynamic Mesh... 42 3.2.6 Boundary and Initial Conditions... 44 3.3 Experimental Method... 45 4. RESULTS AND DISCUSSION... 50 4.1 Introduction... 50 4.2 Validation of Numerical Method... 50 4.2.1 Validation Based on the Experimental Data of the 2-stroke Engine... 50 4.2.2 Validation Based on the Dec Experimental Data... 52 4.3 Numerical Results... 56 4.3.1 Grid Size Independence... 57 4.3.2 Time Step Size Independence... 61 4.3.3 Effect of Different Turbulence models... 65 4.3.4 Effect of Intake Temperature on Ignition Timing and Emissions... 67 4.3.5 Effect of Equivalence Ratio on Ignition Timing and Emissions... 71 4.3.6 Effect of Scavenging Factor on Ignition Timing and Emissions... 75 4.3.7 Effect of Compression Ratio on Ignition Timing and Emissions... 81 4.4 Experimental Results... 85 5. CONCLUSIONS AND RECOMMENDATIONS... 88 5.1 Introduction... 88 5.2 Findings... 88 5.3 Recommendations and Future Works... 90 REFERENCES... 91 APPENDIX A... 101 BIODATA OF STUDENT... 106 LIST OF PUBLICATIONS... 107 PERMISSIONS... 108 x