Autore	Singh Chandan Deep
Edizione	[1st ed.]
Pubbl/distr/stampa	Newark : , : John Wiley & Sons, Incorporated, , 2026
Descrizione fisica	1 online resource (227 pages)
Disciplina	658.4/08
Altri autori (Persone)	SinghTalwinder SinghDavinder
Soggetto topico	Manufacturing processes - Technological innovations Manufacturing processes - Environmental aspects
ISBN	1-394-19781-0 1-394-19782-9
Formato	Materiale a stampa
Livello bibliografico	Monografia
Lingua di pubblicazione	eng
Nota di contenuto	Cover -- Series Page -- Title Page -- Copyright Page -- Contents -- Preface -- Chapter 1 Green Energy Technologies -- 1.1 Introduction -- 1.2 Industrial Processes -- 1.3 Overview of Renewable Energy Technologies -- 1.4 Dedicated Energy Crops -- 1.5 Agricultural Crop Residue -- 1.6 Forestry Residues -- 1.7 Algae -- 1.8 Wood Processing Residues -- 1.9 Sorted Municipal Waste -- 1.10 Wet Waste -- 1.11 What is Solar PV? -- 1.12 Solar Photovoltaic Energy Conversion -- 1.13 What is Waste to Energy? -- 1.14 Where are Nanomaterials Found? -- References -- Chapter 2 Recent Advances in Green Energy Materials: A Review -- 2.1 Introduction -- 2.2 Solar Energy Materials -- 2.3 Wind Energy Materials -- 2.4 Hydroelectric Energy Materials -- 2.4.1 Turbines and Generators -- 2.4.2 Penstocks and Pipelines -- 2.4.3 Dams -- 2.4.4 Roller Compacted Concrete -- 2.4.5 Geosynthetics -- 2.4.6 Bamboo -- 2.4.7 Recycled Materials -- 2.4.8 Transmission Lines -- 2.5 Geothermal Energy Materials -- 2.5.1 Drill Bits and Casing -- 2.5.2 Heat Exchangers -- 2.5.3 Turbines and Generators -- 2.5.4 Piping -- 2.5.5 Sealing Materials -- 2.6 Biomass Energy Materials -- 2.6.1 Combustion Chambers -- 2.6.2 Boilers and Heat Exchangers -- 2.6.3 Gas Cleaning Systems -- 2.6.4 Storage Systems -- 2.6.5 Fuel Handling Systems -- 2.7 Conclusion -- References -- Chapter 3 Green Computing Technologies: Toward Sustainable Computing -- 3.1 Introduction -- 3.1.1 Definition of Green Computing -- 3.1.2 Energy Efficient Computing -- 3.1.3 Low Power Processors and Devices -- 3.1.4 Dynamic Voltage and Frequency Scaling -- 3.1.5 Energy-Efficient Memory Systems with Citation -- 3.1.6 Power Management Techniques -- 3.2 Virtualization and Cloud Computing -- 3.2.1 Virtualization Techniques for Energy Savings -- 3.2.2 Green Cloud Computing -- 3.2.3 Energy-Efficient Data Centers. 3.2.4 Cloud Computing and Carbon Footprint -- 3.2.5 Energy Harvesting and Energy-Neutral Computing -- 3.2.6 Hybrid Systems for Renewable Energy and Traditional Power Sources -- 3.3 Sustainable Computing Practices -- 3.3.1 Green Software Engineering Practices -- 3.3.2 Sustainable Data Management Practices -- 3.3.3 Sustainable Networking Practices -- 3.4 Green Computing in Industry and Society -- 3.4.1 Case Studies of Green Computing in Industry -- 3.4.2 Green Computing Initiatives by Governments and Non-Profits -- 3.4.3 The Role of Green Computing in Achieving Sustainable Development Goals -- 3.5 Challenges and Opportunities -- 3.5.1 Technological Challenges in Green Computing -- 3.5.2 Economic and Social Opportunities of Green Computing -- 3.5.3 Future Directions in Green Computing Research and Development -- 3.6 Conclusion -- References -- Chapter 4 Application of Machine Learning Techniques for Environmental Monitoring and Conservation: A Review -- 4.1 Introduction -- 4.1.1 Background of the Study -- 4.1.2 Machine Learning Techniques in Environmental Aspect -- 4.2 Machine Learning Techniques -- 4.3 Applications of Machine Learning in Environmental Aspect -- 4.3.1 Air Quality Monitoring and Prediction -- 4.3.2 Water Quality Monitoring and Prediction -- 4.3.3 Climate Change Analysis and Prediction -- 4.4 Natural Resource Management and Conservation -- 4.5 Biodiversity Conservation -- 4.6 Waste Management and Recycling -- 4.7 Challenges and Opportunities -- 4.8 Opportunities for the Advancement of Machine Learning in Environmental Aspect -- 4.9 Ethics, Transparency, and Fairness in Machine Learning for Environmental Aspect -- 4.10 Real-World Applications of Machine Learning in Environmental Aspect -- 4.11 Case Studies -- 4.12 Success Stories and Best Practices -- 4.13 Conclusion and Recommendations -- References -- Chapter 5 Green Engineering in IoT. 5.1 Introduction -- 5.2 IoT Data Types -- 5.2.1 IoT Data Value -- 5.3 What is Green IoT? -- 5.4 Benefits of Adopting Green IoT -- 5.4.1 Important Benefits of Adopting Green IoT are Highlighted Below -- 5.5 Green IoT Components -- 5.5.1 Green Wireless Sensor Network (WSN) -- 5.5.2 Green Machine to Machine (M2M) -- 5.5.3 Green Data Center (DC) -- 5.5.3.1 Ways to Achieve a Greener Data Center -- 5.5.4 Green Cloud Computing (CC) -- 5.5.4.1 Green Cloud Computing Objectives -- 5.5.4.2 Green Cloud Computing Benefits -- 5.5.5 Green Radio-Frequency Identification (RFID) -- 5.6 Recommendations for Raising Awareness and Future Research Directions -- References -- Chapter 6 Green Engineering in Product Development -- 6.1 Introduction and Meaning -- 6.2 Principles of Green Engineering -- 6.3 Benefits of Green Engineering -- 6.4 Promoting Green Engineering Through Green Chemistry -- 6.5 Sustainability and Green Engineering Innovations That Might Just Change the World -- 6.6 Conclusion -- References -- Chapter 7 Green Policies in Education: Fostering Environmental Stewardship and Sustainable Practices -- 7.1 Introduction -- 7.1.1 Importance and Relevance of Green Policies in the Education Sector -- 7.1.2 Objectives of the Research -- 7.1.3 Significance of the Study -- 7.2 Theoretical Framework -- 7.2.1 Place-Based Education -- 7.2.2 Addressing Environmental Challenges -- 7.3 Policy Development and Implementation -- 7.3.1 Policy Implementation -- 7.3.2 Case Studies of Successful Policy Implementation in Different Educational Settings -- 7.4 Curriculum Integration and Pedagogy -- 7.5 Infrastructure and Facilities -- 7.5.1 Waste Management and Recycling Initiatives in Educational Institutions -- 7.5.2 Case Studies Showcasing Exemplary Green Infrastructure Projects in Education -- 7.6 Student Engagement and Participation. 7.6.1 Student-Led Initiatives and Organizations Promoting Environmental Awareness and Action -- 7.7 Collaboration and Partnerships -- 7.8 Monitoring, Evaluation, and Reporting -- 7.8.1 Importance of Monitoring and Evaluating the Implementation and Impact of Green Policies -- 7.8.2 Key Indicators and Evaluation Frameworks for Assessing Sustainability in Education -- 7.8.3 Reporting Mechanisms and Accountability in Relation to Green Policies -- 7.9 Challenges and Future Directions -- 7.9.1 Exploration of Potential Solutions and Strategies to Address These Challenges -- 7.9.2 Emerging Trends and Innovations in the Field of Green Policies in Education -- 7.9.3 Summary of the Main Findings and Insights From the Research -- 7.9.4 Contributions of the Study to the Field of Green Policies in Education -- 7.9.5 Implications for Policy, Practice, and Further Research -- 7.9.6 Further Research Implications -- 7.10 Conclusion -- References -- Chapter 8 Green Engineering in Automobile Sector -- 8.1 Introduction -- 8.2 Green Engineering in Automobile Design -- 8.2.1 Green Engineering in Automobile Manufacturing -- 8.2.2 Green Engineering in Automobile Operations -- 8.2.3 Green Engineering in Automobile End-of-Life -- 8.2.4 Case Studies -- 8.3 Conclusion -- References -- Chapter 9 Towards Sustainable Manufacturing: Integrating Digital Technologies on the Green Path -- 9.1 Introduction -- 9.1.1 Sustainable Manufacturing -- 9.1.2 Importance of Sustainable Manufacturing -- 9.1.3 Challenges to Achieving Sustainable Manufacturing -- 9.1.4 Digital Technologies for Sustainable Manufacturing -- 9.1.5 Advantages of Digital Technologies for Sustainable Manufacturing -- 9.2 Digital Technologies for Sustainable Manufacturing with Internet of Things (IoT) -- 9.3 Digital Technologies for Sustainable Manufacturing with Artificial Intelligence. 9.4 Digital Technologies for Sustainable Manufacturing with Digital Twins -- 9.5 Digital Technologies for Sustainable Manufacturing with Additive Manufacturing (3D Printing) -- 9.6 Digital Technologies for Sustainable Manufacturing with Augmented Reality (AR) -- 9.7 Green Path for Sustainable Manufacturing -- 9.8 Introduction to Green Manufacturing -- 9.8.1 Benefits of Green Manufacturing -- 9.8.2 Green Manufacturing Practices with Lean Manufacturing -- 9.8.3 Green Manufacturing Practices with Energy Efficiency -- 9.8.4 Green Manufacturing Practices with Waste Reduction and Recycling -- 9.8.5 Green Manufacturing Practices with Sustainable Supply Chain Management -- 9.8.6 Integration of Digital Technologies on the Green Path -- 9.8.7 Importance of Integrating Digital Technologies and Green Manufacturing Practices -- 9.8.8 Challenges to Integrating Digital Technologies and Green Manufacturing Practices -- 9.8.9 Case Studies of Successful Integration of Digital Technologies and Green Manufacturing Practices -- 9.9 Future Trends in Sustainable Manufacturing -- 9.10 Emerging Digital Technologies for Sustainable Manufacturing -- 9.11 New Trends in Green Manufacturing Practices -- 9.12 Future Directions for Sustainable Manufacturing -- 9.13 Conclusion -- 9.14 Future Scope -- References -- Chapter 10 Smart Manufacturing for a Sustainable Future: A Review -- 10.1 Introduction -- 10.1.1 Smart Manufacturing for a Green Future -- 10.1.2 Green Supply Chain Management -- 10.1.3 Waste Reduction -- 10.1.4 Renewable Energy Integration -- 10.1.5 Green Product Design -- 10.1.6 Circular Economy -- 10.1.7 Water Conservation -- 10.2 Smart Manufacturing for Green Future -- 10.2.1 Energy-Efficient Equipment and Machinery -- 10.2.2 Process Optimization -- 10.2.3 Energy Management Practices -- 10.2.4 Renewable Energy Sources -- 10.3 Green Supply Chain Management. 10.4 Waste Reduction.
Record Nr.	UNINA-9911020262603321

Autore	Zhu Frank Xin X
Pubbl/distr/stampa	Hoboken, New Jersey : , : John Wiley and Sons, Incorporation, , 2014
Descrizione fisica	1 online resource (xvii, 513 p.) : ill
Disciplina	658.5
Soggetto topico	Production engineering Manufacturing processes - Cost control Manufacturing processes - Environmental aspects Energy conservation
ISBN	1-118-78250-X 1-118-78254-2 1-118-78253-4
Classificazione	TEC009010
Formato	Materiale a stampa
Livello bibliografico	Monografia
Lingua di pubblicazione	eng
Nota di contenuto	Machine generated contents note: Dedications Preface Part 1: Basic concepts and theory Chapter 1: Overview of this book 1.1 Introduction 1.2 Who is the book written for 1.3 Five ways to improve energy efficiency 1.4 Four key elements for continuous improvements 1.5 Promoting improvement ideas in the organization Chapter 2: Theory of Energy Intensity 2.1 Introduction 2.2 Definition of energy intensity for a process 2.3 The concept of fuel equivalent for steam and power 2.4 Energy intensity for a total site 2.5 Concluding remarks 2.6 Nomenclature 2.7 References Chapter 3: Energy benchmarking 3.1 Introduction 3.2 Data extraction from historian 3.3 Convert all energy usage to fuel equivalent 3.4 Energy balance 3.5 Fuel equivalent for steam and power 3.6 Energy performance index method for energy benchmarking 3.7 Concluding remarks 3.8 Nomenclature 3.9 References Chapter 4: Key indicators and targets 4.1 Introduction 4.2 Key indicators represent operation opportunities 4.3 Define key indicators 4.4 Set up targets for key indicators 4.5 Economic evaluation for key indicators 4.6 Application 1: Implementing key indicators into an "Energy Dashboard" 4.7 Application 2: Implementing key indicators to controllers 4.8 It is worth the effort 4.9 Nomenclature 4.10 References Part 2: Energy system assessment methods Chapter 5: Fired heater assessment 5.1 Introduction 5.2 Fired heater design for high reliability 5.3 Fired heater operation for high reliability 5.4 Efficient fired heater operation 5.5 Fired heater revamp 5.6 Nomenclature 5.7 References Chapter 6: Heat exchanger performance assessment 6.1 Introduction 6.2 Basic concepts and calculations 6.3 Understand Performance criterion - U values 6.4 Understand pressure drop 6.5 Heat exchanger rating assessment 6.6 Improving heat exchanger performance 6.7 Appendix: TEMA Types of Heat Exchangers 6.8 Nomenclature 6.9 References Chapter 7: Heat exchanger fouling assessment 7.1 Introduction 7.2 Fouling mechanisms 7.3 Fouling mitigation 7.4 Fouling mitigation for crude preheat in oil refining 7.5 Fouling resistance calculations 7.6 A cost-based model for clean cycle optimization 7.7 Revised cost-based model for clean cycle optimization 7.8 A practical method for clean cycle optimization 7.9 Putting all together - A practical example of fouling mitigation 7.10 Nomenclature 7.11 References Chapter 8: Energy loss assessment 8.1 Introduction 8.2 Energy loss audit 8.3 Energy loss audit results 8.4 Energy loss evaluation 8.5 Brainstorming 8.6 Energy audit report 8.7 Nomenclature 8.8 References Chapter 9: Process heat recovery opportunity assessment 9.1 Introduction 9.2 Data extraction 9.3 Composite curves 9.4 Basic concepts 9.5 Energy targeting 9.6 Pinch golden rules 9.7 Cost targeting: determine optimal ΔTmin 9.8 Case study 9.9 Be aware of sub-optimal 9.10 Integrated cost targeting and process design 9.11 Challenges for applying the systematic design approach 9.12 Nomenclature 9.13 References Chapter 10: Heat recovery modification assessment 10.1 Introduction 10.2 Network pinch - the bottleneck of existing heat recovery system 10.3 Identification of modifications 10.4 Automated network pinch retrofit approach 10.5 Case studies for applying the network pinch approach 10.6 References Chapter 11: Process integration opportunity assessment 11.1 Introduction 11.2 Definition of process integration 11.3 Plus and minus (+/-) principle 11.4 Grand composite curves 11.5 Appropriate placement principle for process changes 11.6 Examples of process changes 11.7 References Part 3: Process system assessment and optimization Chapter 12: Distillation operating window 12.1 Introduction 12.2 What is distillation 12.3 Distillation efficiency 12.4 Definition of feasible operating window 12.5 Understanding operating window 12.6 Typical capacity limits 12.7 Effects of design parameters 12.8 Design check list 12.9 Example calculations for developing operating window 12.10 Concluding remarks 12.11 Nomenclature 12.12 References Chapter 13: Distillation system assessment 13.1 Introduction 13.2 Define a base case 13.3 Calcu7lations for missing and incomplete data 13.4 Building process simulation 13.5 Heat and material balance assessment 13.6 Tower efficiency assessment 13.7 Operating profile assessment 13.8 Tower rating assessment 13.9 Heat integration assessment for column design 13.10 Guidelines for reuse of an existing tower 13.11 Nomenclature 13.12 References Chapter 14: Distillation system optimization 14.1 Introduction 14.2 Tower optimization basics 14.3 Energy optimization for distillation system 14.4 Overall process optimization 14.5 Concluding remarks 14.6 References Part 4: Utility system assessment and optimization Chapter 15: Modeling of steam and power system 15.1 Introduction 15.2 Boiler 15.3 Deaerator 15.4 Steam turbine 15.5 Gas turbine 15.6 Letdown valve 15.7 Steam desuperheater 15.8 Steam flush drum 15.9 Steam trap 15.10 Steam distribution losses 15.11 Nomenclature 15.12 References Chapter 16: Establishing steam balances 16.1 Introduction 16.2 Guidelines for generating steam balance 16.3 A working example for generating steam balance 16.4 A practical example for generating steam balance 16.5 Verify steam balance 16.6 Concluding remarks 16.7 Nomenclature 16.8 References Chapter 17: Determining steam pricing 17.1 Introduction 17.2 The cost of steam generation from boiler 17.3 Enthalpy-based steam pricing 17.4 Work-based steam pricing 17.5 Fuel equivalent-based steam pricing 17.6 Cost-based steam pricing 17.7 Comparison of different steam pricing methods 17.8 Marginal steam pricing 17.9 Effects of condensate recovery on steam cost 17.10 Concluding remarks 17.11 Nomenclature 17.12 References Chapter 18: Benchmarking steam and power system 18.1 Introduction 18.2 Benchmark steam cost - minimize generation cost 18.3 Benchmark steam and condensate losses 18.4 Benchmark process steam usage and energy cost allocation 18.5 Benchmark steam system operation 18.6 Benchmark steam system efficiency 18.7 Nomenclature 18.8 References Chapter 19: Steam and power management and optimization 19.1 Introduction 19.2 Optimizing steam header pressure 19.3 Optimizing steam equipment loadings 19.4 Optimizing onsite power generation versus import 19.5 Minimizing steam letdowns and venting 19.6 Optimizing steam system configuration 19.7 Developing steam system optimization model 19.8 Nomenclature 19.9 References Part 5: Retrofit project evaluation and implementation Chapter 20: Determine true benefits from OSBL 20.1 Introduction 20.2 Energy improvement options under evaluation 20.3 A method for evaluating energy improvement options in OSBL 20.4 Feasibility assessment and make decision for implementation Chapter 21: Determine true benefits from operation variations 21.1 Introduction 21.2 Collect online data for the whole operation cycle 21.3 Normal distribution and Monte Carlo simulation 21.4 Basic statistic summary for normal distribution 21.5 Nomenclature 21.6 References Chapter 22: Feasibility Assessment 22.1 Introduction 22.2 Scope and stages of feasibility assessment 22.3 Feasibility assessment methodology 22.4 Get the project basis and data right in the very beginning 22.5 Get the project economics right 22.6 Don't forget OSBL costs 22.7 Squeeze capacity out of design margin 22.8 Identify and relax plant constraints 22.9 Interactions of process conditions, yields ad equipment 22.10 Don't get misled by false balances 22.11 Prepare for fuel gas long 22.12 Two revamp cases for shifting bottlenecks 22.13 Concluding remarks 22.14 Nomenclature 22.15 References Chapter 23: Create optimization culture with measurable results 23.1 Introduction 23.2 Site wide energy optimization strategy 23.3 Case study of the site wide energy optimization strategy 23.4 Establishing energy management system 23.5 Energy operation management 23.6 Energy project management 23.7 An overall work process from idea discovery to implementation 23.8 References .
Record Nr.	UNINA-9910140189903321

Pubbl/distr/stampa	[Place of publication not identified], : John Wiley & Sons, 2007
Disciplina	670.28/6
Collana	Wiley series in environmentally conscious engineering Environmentally conscious manufacturing
Soggetto topico	Manufacturing processes - Environmental aspects Mechanical Engineering Engineering & Applied Sciences Industrial & Management Engineering
ISBN	0-470-16819-6 1-60119-640-7
Classificazione	43.35
Formato	Materiale a stampa
Livello bibliografico	Monografia
Lingua di pubblicazione	eng
Nota di contenuto	Environmentally benign manufacturing / William E. Biles -- Design for the environment / Jack Jeswiet -- Organization, management, and improvement of manufacturing systems / Keith M. Gardiner -- Manufacturing systems evaluation / Walter W. Olson -- Prevention of metalworking pollution : environmentally conscious manufacturing at the machine tool / Steven J. Skerlos -- Metal finishing and electroplating / Timothy C. Lindsey -- Air quality in manufacturing / John W. Sutherland, Donna J. Michalek, and Julio L. Rivera -- Environmentally conscious electronics manufacturing / Richard Ciocci -- Disassembly for end-of-life electromechanical products / Hong C. Zhang ... [et al.] -- Industrial energy efficiency / Bhaskaran Gopalakrishnan ... [et al.] -- Industrial environmental compliance regulations / Thomas J. Blewett and Jack Annis.
Record Nr.	UNINA-9910144584403321

Pubbl/distr/stampa	Pfaffikon, Switzerland : , : Trans Tech Publications Ltd, , 2014
Descrizione fisica	1 online resource (103 p.)
Disciplina	658.408
Collana	Applied Mechanics and Materials
Soggetto topico	Production management - Environmental aspects Manufacturing processes - Environmental aspects
Soggetto genere / forma	Electronic books.
ISBN	3-03826-667-1
Formato	Materiale a stampa
Livello bibliografico	Monografia
Lingua di pubblicazione	eng
Nota di contenuto	Green Factory Bavaria Colloquium 2014; Preface; Table of Contents; Chapter 1: Sustainable Manufacturing Strategies; Life Cycle Assessment Tool in the Early Stage of Development; Contribution for the Life Cycle Oriented Evaluation of Costs and Resource Efficiency of Production Machines in Procurement; E\|Benchmark - Approaches and Methods for Assessing the Energy Efficiency of the Industrial Automated Product Manufacturing; Identification of Energy Consumption and Energy Saving Potentials of Electric Drive Systems; Energy Concepts for Manufacturing Companies; Chapter 2: Energy Measuring Systems Energy Controlling - Analysis and Evaluation of Energy Measuring Equipment for the Purpose of Energy Transparency in Production Plants Development of an Adjustable Measuring System for Electrical Consumptions in Production; Identifying Energy Efficiency Potentials by Applying Flexible Measuring Systems; Energy Planning of Manufacturing Systems with Methods-Energy Measurement (MEM) and Multi-Domain Simulation Approach; Estimating Machine Power Consumptions through Aggregated Measurements and Machine Data Acquisition; Chapter 3: Energy Efficient Process Technologies Methodology to Increase Energy Efficiency in Discrete Manufacturing Energy Efficient Manufacturing of Lightweight Products Illustrated by a Structural Optimization of an Automatic Knife Cutting System; Basic Investigation on Melting Operations in the Die Casting Industry to Increase Manufacturing Efficiency and Process Reliability; Influence of Temperature and Wavelength on Optical Behavior of Copper Alloys; Energy Efficiency Investigation on High-Pressure Convection Reflow Soldering in Electronics Production; Keywords Index; Authors Index
Record Nr.	UNINA-9910460065603321