Enhanced Heat Transfer Mechanism of Nanofluid MQL Cooling Grinding

Enhanced Heat Transfer Mechanism of Nanofluid MQL Cooling Grinding

Changhe Li, Hafiz Muhammad Ali

Copyright: © 2020 |Pages: 441

ISBN13: 9781799815464|ISBN10: 1799815463|ISBN13 Softcover: 9781799815471|EISBN13: 9781799815488

DOI: 10.4018/978-1-7998-1546-4

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MLA

Li, Changhe, and Hafiz Muhammad Ali. Enhanced Heat Transfer Mechanism of Nanofluid MQL Cooling Grinding. IGI Global, 2020. https://doi.org/10.4018/978-1-7998-1546-4

APA

Li, C. & Ali, H. M. (2020). Enhanced Heat Transfer Mechanism of Nanofluid MQL Cooling Grinding. IGI Global. https://doi.org/10.4018/978-1-7998-1546-4

Chicago

Li, Changhe, and Hafiz Muhammad Ali. Enhanced Heat Transfer Mechanism of Nanofluid MQL Cooling Grinding. Hershey, PA: IGI Global, 2020. https://doi.org/10.4018/978-1-7998-1546-4

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In today’s modern world, the manufacturing industry is embracing an energy-efficient initiative and adopting green techniques. One aspect that has failed to adopt this scheme is flood grinding. Current flood grinding methods increase the treatment cost of grinding fluid and waste large quantities. In order to remain sustainable and efficient, in-depth research is necessary to study green grinding technologies that can ensure machining precision and surface quality of workpiece and reduce grinding fluid-induced environmental pollution.

Enhanced Heat Transfer Mechanism of Nanofluid MQL Cooling Grinding provides emerging research exploring the theoretical and practical aspects of nanofluid lubrication and its application within grinding flow and green manufacturing. Featuring coverage on a broad range of topics such as airflow distribution, morphology analysis, and lubrication performance, this book is ideally designed for mechanical professionals, engineers, manufacturers, researchers, scientists, academicians, and students seeking current research on clean and low-carbon precision machining methods.

Table of Contents

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Front Materials

Title Page

Copyright Page

Advances in Chemical and Materials Engineering (ACME) Book Series

Preface

Acknowledgment

Introduction

Chapters

Chapter 1

Introduction (pages 1-19)

This chapter introduces the application background and characteristics of five kinds of grinding processing methods, briefly describes the enhanced heat transfer mechanism and tribological properties of nanofluids, and points out...

Chapter 2

Enhanced Heat Transfer Mechanism of Nanofluids Minimum Lubrication Grinding (pages 20-42)

This chapter will discuss in detail the various aspects of nanofluids, form preparation of nanofluids, characterization and flow and energy transportation mechanisms of nanofluids. Preparation of nanofluids has been performed using...

Chapter 3

Machining Mechanism of Minimum Quantity Lubrication Grinding (pages 43-75)

To facilitate the analysis of experimental theory, this chapter studied the machining mechanism related to the grinding of NMQL and the three mechanisms of sliding, ploughing, and cutting of the abrasive grinding process. A...

Chapter 4

Heat Transfer Mechanism of Minimum Quantity Lubrication Grinding (pages 76-101)

Grinding temperature rise at the grinding interface has a great bearing on workpiece surface quality and service life of grinding wheel. In order to study influence degree of temperature on workpiece and analyze heat transfer at the...

Chapter 5

Finite Element Analysis of Grinding Temperature Field for NMQL in Nickel-Base Alloy Grinding (pages 102-131)

Temperature is not only an important parameter in machining, but also an important basis for process optimization. Accurate prediction and reasonable analysis of grinding temperature is of great and far-reaching significance to the...

Chapter 6

Experimental Research on Minimum Quantity Lubrication Surface Grinding With Different Cooling and Lubrication Conditions (pages 132-159)

Given the increasing attention to environmental and health problems caused by machining, the development of an environmentally friendly grinding fluid has become an urgent task. The cooling and lubricating properties of different...

Chapter 7

Experimental Research on Grinding Temperature and Energy Ratio Coefficient in MQL Grinding Using Different Types of Vegetables Oils (pages 160-181)

Vegetable oil can be used as a base oil in minimal quantity of lubrication (MQL). This study compared the performances of MQL grinding by using castor oil, soybean oil, rapeseed oil, corn oil, sunflower oil, peanut oil, and palm oil...

Chapter 8

Experimental Research on Heat Transfer Performance in MQL Grinding With Different Nanofluids (pages 182-202)

An investigation into the effect of nanofluid minimum quantity lubrication (MQL) on the temperatures in surface grinding is presented and discussed. Six types of nanoparticles, namely molybdenum disulfide (MoS2), zirconium dioxide...

Chapter 9

Experimental Evaluation on the Effect of Nanofluids Physical Properties With Different Concentrations on Grinding Temperature (pages 203-225)

This chapter is proposed to solve the insufficient MQL cooling and heat transfer capability based on the heat transfer enhancement theory of solid. Adding nanoparticles into the base fluid can significantly elevate heat conductivity...

Chapter 10

Experimental Research on Grinding Temperature With Different Workpiece Materials (pages 226-248)

The results show that the nanofluids with a volume fraction of 2% have good comprehensive properties for lubrication. However, this study only concentrates on workpiece material—nickel base alloy. Based on literature analysis...

Chapter 11

Experimental Evaluation of the Lubrication Properties of the Wheel/Workpiece Interface in MQL Grinding Using Vegetable Oils (pages 249-274)

Given the increasing attention to environmental and health problems caused by machining, the development of an environmentally friendly grinding fluid has become an urgent task. In this study, seven typical vegetable oils (i.e....

Chapter 12

Experimental Study of Lubricating Property at Grinding Wheel/Workpiece Interface Under NMQL Grinding (pages 275-297)

Nanofluid is the suspension formed by lubricating oil and nanoparticles with particles sizes of 1~100 nm, and common nanoparticles include metal nanoparticles (Cu, Ag, etc.), oxide nanoparticles (Al2O3, SiO2, ZrO2, etc.), carbides...

Chapter 13

Comparative Study on Tribological Properties of Nanofluids in Friction-Wear Experiments and Grinding Processing (pages 298-316)

This chapter presents the lubricating properties of different vegetable-oil-based nanofluids through a comparative evaluation between frictional test and grinding experiment. The first experiment aimed to prejudge the lubricating...

Chapter 14

Experimental Evaluation on Tribological Performance of the Wheel/Workpiece Interface in NMQL Grinding With Different Concentrations of Al2o3 Nanofluids (pages 317-336)

As a result of the growing need for environmental protection and the increasing number of health problems faced by workers, traditional lubricants are gradually being replaced. Nanofluids, which contain nanoparticles in the proper...

Chapter 15

Optimization Design of Process Parameters for Different Workpiece Materials in NMQL Grinding With Different Vegetable Oils (pages 337-357)

This research shows with superior lubricating, heat-conducting properties, and proper market price, Al2O3 and MoS2 nanoparticles have broad application prospects as lubricant additives. This work has been researched, and most...

Chapter 16

Modeling and Simulation of Surface Topography in Single Abrasive Grain Grinding (pages 358-380)

This study establishes a kinematics model, elastic deformation model, and plastic accumulation model of a single grinding wheel, simulates the grain distribution on the surface of the common grinding wheel by using the grain...

Chapter 17

Modeling and Simulation of the Surface Topography Generation With Engineered Grinding Wheel (pages 381-403)

Precision grinding can obtain workpiece with high surface quality and high precision, but random distribution of abrasive grains on the grinding wheel surface poses a certain difficulty to improvement of machining precision and...

Chapter 18

Modeling and Simulation of the Surface Topography Generation With Ordinary Grinding Wheel (pages 404-438)

In order to simulate the surface grinding process of the common grinding wheel and evaluate the surface topography of the workpiece, the mathematical model of the common grinding wheel is established by using the abrasive vibration...

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