Enhanced heat transfer mechanism of nanofluid MQL cooling grinding

""This book examines the distribution of airflow field in the grinding zone in nanofluid minimum quantity lubrication cooling grinding; tribological performance in grinding wheel/work piece interface; thermodynamic mechanism in grinding wheel/work piece interface; and surface integrity eva...

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Bibliographic Details
Main Authors Li, Changhe, 1966- (Author), Ali, Hafiz Muhammad, 1981- (Author)
Format Electronic eBook
LanguageEnglish
Published Hershey, PA : IGI Global, [2020]
SeriesAdvances in chemical and materials engineering (ACME) book series.
Subjects
Grinding wheels.
Lubrication and lubricants.
Nanofluids.
elektronické knihy
electronic books
Online AccessFull text
ISBN9781799815488
179981548X
9781799815464
9781799815471
9781799815495
1799815498
Physical Description1 online resource (xvii, 441 pages)

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Table of Contents:
  • Chapter 1. Introduction
  • Chapter 2. Enhanced heat transfer mechanism of nanofluids minimum lubrication grinding
  • Chapter 3. Machining mechanism of minimum quantity lubrication grinding
  • Chapter 4. Heat transfer mechanism of minimum quantity lubrication grinding
  • Chapter 5. Finite element analysis of grinding temperature field for NMQL in nickel-base alloy grinding
  • Chapter 6. Experimental research on minimum quantity lubrication surface grinding with different cooling and lubrication conditions
  • Chapter 7. Experimental research on grinding temperature and energy ratio coefficient in MQL grinding using different types of vegetables oils
  • Chapter 8. Experimental research on heat transfer performance in MQL grinding with different nanofluids
  • Chapter 9. Experimental evaluation on the effect of nanofluids physical properties with different concentrations on grinding temperature
  • Chapter 10. Experimental research on grinding temperature with different workpiece materials
  • Chapter 11. Experimental evaluation of the lubrication properties of the wheel/workpiece interface in MQL grinding using vegetable oils
  • Chapter 12. Experimental study of lubricating property at grinding wheel/workpiece interface under NMQL grinding
  • Chapter 13. Comparative study on tribological properties of nanofluids in friction-wear experiments and grinding processing
  • Chapter 14. Experimental evaluation on tribological performance of the wheel/workpiece interface in NMQL grinding with different concentrations of Al2o3 nanofluids
  • Chapter 15. Optimization design of process parameters for different workpiece materials in NMQL grinding with different vegetable oils
  • Chapter 16. Modeling and simulation of surface topography in single abrasive grain grinding
  • Chapter 17. Modeling and simulation of the surface topography generation with engineered grinding wheel
  • Chapter 18. Modeling and simulation of the surface topography generation with ordinary grinding wheel.

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