Predicting student academic performance in an engineering dynamics course: A comparison of four types of predictive mathematical models S Huang, N Fang Computers & Education 61, 133-145, 2013 | 466 | 2013 |
Slip-line modeling of machining with a rounded-edge tool—Part I: new model and theory N Fang Journal of the Mechanics and Physics of Solids 51 (4), 715-742, 2003 | 264 | 2003 |
A comparative study of the cutting forces in high speed machining of Ti–6Al–4V and Inconel 718 with a round cutting edge tool N Fang, Q Wu Journal of materials processing technology 209 (9), 4385-4389, 2009 | 200 | 2009 |
A universal slip-line model with non-unique solutions for machining with curled chip formation and a restricted contact tool N Fang, IS Jawahir, PLB Oxley International Journal of Mechanical Sciences 43 (2), 557-580, 2001 | 160 | 2001 |
The effects of chamfered and honed tool edge geometry in machining of three aluminum alloys N Fang, Q Wu International Journal of Machine Tools and Manufacture 45 (10), 1178-1187, 2005 | 145 | 2005 |
Slip-line modeling of machining with a rounded-edge tool—Part II: analysis of the size effect and the shear strain-rate N Fang Journal of the Mechanics and Physics of Solids 51 (4), 743-762, 2003 | 120 | 2003 |
Tool-chip friction in machining with a large negative rake angle tool N Fang Wear 258 (5-6), 890-897, 2005 | 112 | 2005 |
Student misconceptions about force and acceleration in physics and engineering mechanics education G Liu, N Fang International Journal of Engineering Education 32 (1), 19-29, 2016 | 102 | 2016 |
Analytical predictions and experimental validation of cutting force ratio, chip thickness, and chip back-flow angle in restricted contact machining using the universal slip … N Fang, IS Jawahir International Journal of Machine Tools and Manufacture 42 (6), 681-694, 2002 | 95 | 2002 |
Effect of tool edge wear on the cutting forces and vibrations in high-speed finish machining of Inconel 718: an experimental study and wavelet transform analysis N Fang, PS Pai, S Mosquea The International Journal of Advanced Manufacturing Technology 52, 65-77, 2011 | 94 | 2011 |
A new quantitative sensitivity analysis of the flow stress of 18 engineering materials in machining N Fang J. Eng. Mater. Technol. 127 (2), 192-196, 2005 | 93 | 2005 |
Slip-line modeling of built-up edge formation in machining N Fang, P Dewhurst International Journal of Mechanical Sciences 47 (7), 1079-1098, 2005 | 89 | 2005 |
An analytical predictive model and experimental validation for machining with grooved tools incorporating the effects of strains, strain-rates, and temperatures N Fang, IS Jawahir CIRP Annals 51 (1), 83-86, 2002 | 71 | 2002 |
Machining with tool–chip contact on the tool secondary rake face—Part I: a new slip-line model N Fang International journal of mechanical sciences 44 (11), 2337-2354, 2002 | 50 | 2002 |
Improving engineering students’ technical and professional skills through project-based active and collaborative learning N Fang The International journal of engineering education 28 (1), 26-36, 2012 | 48 | 2012 |
The effect of built-up edge on the cutting vibrations in machining 2024-T351 aluminum alloy N Fang, PS Pai, S Mosquea The International Journal of Advanced Manufacturing Technology 49, 63-71, 2010 | 47 | 2010 |
Spatial ability in learning engineering mechanics: Critical review O Ha, N Fang Journal of Professional Issues in Engineering Education and Practice 142 (2 …, 2016 | 41 | 2016 |
Theoretical and experimental investigations of finish machining with a rounded edge tool N Fang, G Fang Journal of materials processing technology 191 (1-3), 331-334, 2007 | 38 | 2007 |
Correlation between students’ motivated strategies for learning and academic achievement in an engineering dynamics course N Fang Global Journal of Engineering Education 16 (1), 6-12, 2014 | 36 | 2014 |
Interactive virtual and physical manipulatives for improving students’ spatial skills O Ha, N Fang Journal of Educational Computing Research 55 (8), 1088-1110, 2018 | 35 | 2018 |