John Wiley & Sons High Electrical Resistance Ceramics Cover HIGH ELECTRICAL RESISTANCE CREAMICS Pond and fly ash waste materials generated by thermal power sta.. Product #: 978-1-394-19993-8 Regular price: $167.29 $167.29 Auf Lager

High Electrical Resistance Ceramics

Thermal Power Plant Waste Resources

Panigrahi, Muktikanta / Ganguly, Ratan Indu / Dash, Radha Raman (Herausgeber)

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1. Auflage August 2023
240 Seiten, Hardcover
Wiley & Sons Ltd

ISBN: 978-1-394-19993-8
John Wiley & Sons

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HIGH ELECTRICAL RESISTANCE CREAMICS

Pond and fly ash waste materials generated by thermal power stations pollute the environment; this book demonstrates how the utilization of these materials minimizes environmental pollution and conserves land for cultivation.

This book highlights the preparation of ceramics using pond/fly ash. Since the mullite phase formed by heat treatment improves the properties of ceramics, current investigations will perhaps be the first attempt to develop ceramics using pond ash. The properties of components made with these developed ceramics are found to be comparable to those made with porcelain.

The extensively reviewed chapters of this book illustrate the current status of research on these materials. At the end of each of the 10 chapters, conclusions are drawn which will benefit researchers working in this area. Subjects discussed include:
* The fundamentals of thermal power plant wastes;
* Different production methods of ceramics and various characterization techniques;
* The preparation of ceramics from fly ash and fly ash/kaolin composite;
* The production of ceramics using pond ash;
* The preparation and characterization of geopolymer from pond ash and the preparation of pond ash composite;
* Production of ceramic matrix composite (CMC) using pond ash and pyrophyllite;
* The preparation of ceramics using pond ash and k-feldspar mixture.

Audience

The book will be used by civil engineers in the construction and ceramic industries as well as the industrial waste sector. Researchers in materials science, structural, civil and electrical engineering, environmental science, and ceramic engineering, will also have interest. Industries that have an interest include construction, electrical, and ceramic industries as well as pollution and waste sectors.

Preface ix

1 Fundamentals of Thermal Power Plant Wastes-as Ceramic Backbone 1

1.1 Introduction 1

1.2 Thermal Power Plant Wastes 2

1.3 Generation of Thermal Power Plant Ashes 2

1.4 Nature and Composition of Thermal Power Plant Ashes 5

1.5 Characteristics of Thermal Power Plant Ashes 10

1.6 Causes of Resistance in Insulator 14

1.7 Resistance Measurement 15

1.8 Different Methods for Resistivity Measurement 15

1.9 Resistance Temperature Detector (RTDs) 19

1.9.1 Benefit of RTD 19

1.10 Platinum Resistance Thermometer (PRTs) 19

1.11 Thermal Power Plant Wastes (i.e., Coal Ash) Management 20

1.12 Literatures Survey on Thermal Power Plant Wastes-Based Ceramics 20

1.13 Conclusions 24

Acknowledgements 25

References 25

2 Ceramic Production Methods and Basic Characterization Techniques 35

2.1 Introduction 35

2.2 Characterization Techniques 41

2.2.1 X-Ray Diffraction (XRD) Technique 41

2.2.2 Fourier Transformation Infra-Red (FTIR) Spectroscopy 42

2.2.3 Scanning Electron Microscopy (SEM) 42

2.2.4 Electrical Characterizations 43

2.2.4.1 Electrical Resistivity Measurement by Two Probe (at Room Temperature) 43

2.3 Conclusions 44

Acknowledgements 45

References 45

3 High Resistance Sintered Fly Ash (FA) Ceramics 51

3.1 Introduction 52

3.2 Experimental Details 53

3.2.1 Materials and Chemicals 53

3.2.2 Materials Preparation 54

3.2.3 Physical Characterizations 55

3.2.4 Results and Discussion 56

3.3 Conclusions 61

Acknowledgements 61

References 61

4 High Resistance Sintered Fly Ash/Kaolin (FA/CC) Ceramics 65

4.1 Introduction 66

4.2 Experimental Section 66

4.2.1 Materials and Method 66

4.3 Preparation of Test Samples 67

4.3.1 Preparation of Sintered FA/CC Composite 67

4.4 Characterization Techniques 68

4.5 Results and Discussion 69

4.6 Conclusions 75

Acknowledgements 75

References 75

5 High Resistance Pond Ash Geopolymer Ceramics 79

5.1 Introduction 80

5.2 Experimental Details 83

5.2.1 Materials and Chemicals 83

5.3 Test Methods 85

5.4 Results and Discussion 86

5.5 Conclusions 92

Acknowledgements 92

References 92

6 High Resistance Sintered Pond Ash Ceramics 97

6.1 Introduction 98

6.2 Experimental Details 99

6.2.1 Materials and Chemicals 99

6.2.2 Materials Preparation 99

6.2.3 Test Methods 101

6.2.4 Results and Discussion 102

6.3 Conclusions 108

Acknowledgements 109

References 109

7 High Resistance Sintered Pond Ash/Kaolin (PA/CC) Ceramics 115

7.1 Introduction 115

7.2 Experimental Details 118

7.2.1 Materials and Chemicals 118

7.2.2 PA/Kaolin Composite Preparation 118

7.2.3 Test Methods 121

7.3 Results and Discussion 122

7.4 Conclusions 130

Acknowledgements 131

References 131

8 High Resistance Sintered Pond Ash/Pyrophyllite (PA/PY) Ceramics 137

8.1 Introduction 137

8.2 Experimental Section 140

8.2.1 Materials and Chemicals 140

8.3 Preparation of PA/PY Composite Materials 140

8.4 Test Methods 143

8.5 Results and Discussion 144

8.6 Conclusions 152

Acknowledgements 152

References 153

9 High Resistance Sintered Pond Ash/k-Feldspar (PA/k-FD) Ceramics 159

9.1 Introduction 160

9.2 Experimental Details 162

9.2.1 Materials and Chemicals 162

9.3 Preparation of PA/FD Sintered Materials 162

9.4 Test Methods 165

9.5 Results and Discussion 166

9.6 Conclusions 174

Acknowledgements 175

References 175

10 Applications, Challenges and Opportunities of Industrial Waste Resources Ceramics 181

10.1 Introduction 182

10.2 Different Ways of Utilization of Waste 183

10.2.1 Porous Insulation Refractory 183

10.2.2 Dense Refractory 183

10.2.3 Ceramic Tiles 184

10.3 Glass 187

10.4 Glass-Ceramic (GC) 188

10.5 Mullite 188

10.6 Wollastonite 188

10.7 Cordierite 189

10.8 Silicon Carbide 189

10.9 Silicon Nitride 190

10.10 Ceramic Membranes 190

10.11 Challenges 190

10.12 Opportunity 191

10.13 Conclusions 191

Acknowledgments 192

References 193

Index 199
Muktikanta Panigrahi, PhD, completed his doctorate in materials science, Indian Institute of Technology, Kharagpur. He is an assistant professor in the Department of Materials Science, Maharaja Sriram Chandra Bhanja Deo University, Odisha, India. He has completed a project on Geopolymer sponsored by the Ministry of Mines, Govt. of India. He has innovations/discoveries in the area of Geopolymer/MMCs/Ceramics/Polymers and is skilled in the field of basification of industrial wastes, organic semiconductors, biodegradable polymers, and gas sensors.

Ratan Indu Ganguly, PhD, completed his doctorate in materials science, Indian Institute of Technology, Kharagpur. He has 50 years of experience in academic teaching. He has completed an industry-sponsored project for the development of floor and wall tiles from industrial waste such as fly ash. He is now supporting a research project which relates to the development of geopolymer from pond ash.

Radha Raman Dash, PhD, completed his doctorate in materials science, Indian Institute of Technology, Kharagpur. He spent decades at the CSIR-National Metallurgical Laboratory (NML), Jamshedpur as Senior Scientist. He now is Dean of research & development, Gandhi Institute of Engg. & Technology, University, Gunupur, Orissa. He has 10 inventions/discoveries and his research interests are in foundry, composite materials, corrosion, ceramic matrix composites, fractal images, and advanced materials.

M. Panigrahi, Indian Institute of Technology, Kharagpur; R. I. Ganguly, Indian Institute of Technology, Kharagpur; R. R. Dash, Indian Institute of Technology, Kharagpur