Principles, Tools and Industrial Examples
Buch, Englisch, 599 Seiten, Format (B × H): 178 mm x 246 mm, Gewicht: 1279 g
ISBN: 978-3-527-31552-9
Verlag: WILEY-VCH
Stellen Sie sich der Herausforderung, in der chemischen Industrie Prozesse zu entwerfen, die nicht nur hochmodern, sondern auch ökonomisch machbar und überdies nachhaltig konzipiert sind! In diesem Band zeigen Ihnen führende Experten aus Unternehmen der chemischen Industrie, wie Sie an diese Aufgabe herangehen müssen. Informationen aus erster Hand: Alle Anwendungen werden von den Entwicklern selbst beschrieben!
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Fachgebiete
- Geowissenschaften Umweltwissenschaften Nachhaltigkeit
- Technische Wissenschaften Verfahrenstechnik | Chemieingenieurwesen | Biotechnologie Verfahrenstechnik, Chemieingenieurwesen
- Geowissenschaften Umweltwissenschaften Umweltschutz, Umwelterhaltung
- Technische Wissenschaften Technik Allgemein Technische Zuverlässigkeit, Sicherheitstechnik
Weitere Infos & Material
FROM GREEN TO SUSTAINBABLE INDUSTRIAL CHEMISTRY
Principles of Green Chemistry, and of Sustainable Chemistry and Risk
Sustainable Chemical Production and REACH
International Chemicals Policy and Sustainability
Sustainable Chemistry and Inherently Safer Design
A Vision and Roadmap for Sustainability through Chemistry
METHODS AND TOOLS OF SUSTAINABLE INDUSTRIAL CHEMISTRY: CATALYSIS
Catalysis as Enabling Factor of Sustainable Chemical Production
Homogeneous Catalysis and the Role of Multi-Phase Operations
Bio- and Bio-Inspired Catalysts
Solid Acids and Bases
Redox Catalysis
Cascade and Domino Catalytic Reactions
Multicomponent Catalytic Reactions
Organocatalysis
METHODS AND TOOLS OF SUSTAINABLE INDUSTRIAL CHEMISTRY: PROCESS INTENSIFICATION
Alternative Sources and Forms of Energy for Process Intensification
Micro(structured) Reactors
MEMBRANE TECHNOLOGIES AT THE SERVICE OF SUSTAINABLE DEVLOPMENT THROUGH PROCESS INTENSIFICATION
From the Definitions to the Function: A Few Fundamental Ideas
The Need for More Integrated Views on Materials and Process Conditions
The Use of Hybrid Processes and New Operating Modes: The Key to Many Problems
Safe Management of Membrane Integration in Industrial Processes: A Huge Challenge
ACCOUNTING FOR CHEMICAL SUSTAINABILITY
Ecological Footprint
Ecological Indicators
Metrics for Environmental Analysis and Eco-Efficiency
Sustainability Accounting
E-Factor and Atom Economy
Energy Intensity
Environmental Impact Indicators
Sustainable Chemical Production Metrics
Life Cycle Tools
THE SYNTHESIS OF PROPENE OXIDE: A SUCCESSFUL EXAMPLE OF SUSTAINABLE INDUSTRIAL CHEMISTRY
Current Industrial Propene Oxide Production
The PO-Only Routes: Several Approaches for Sustainable Alternatives
THE SYNTHESIS OF ADIPIC ACID: ON THE WAY TO A MORE SUSTAINABLE PRODUCTION
The Adipic Acid Market
Current Technologies for AA Production
More Sustainable Alternatives for AA Production
Emerging and Developing Technologies for AA Production
An Overview: Several Possible Green Routes to AA, Some Sustainable, Others Not
ECOFINING: NEW PROCESS FOR GREEN DIESEL PRODUCTION FROM VEGETABLE OIL
From Vegetable Oil to Green Diesel
The UOP/Eni Ecfing Process
Life Cycle Assessment
A NEW PROCESS FOR THE PRODUCTION OF BIODIESEL BY TRANSESTERIFICATION OF VEGETABLE OILS WITH HETEROGENEOUS CATALYSIS
The Direct Use of Vegetable Oils
The Methyl Ester Derived from Vegetable Oils
The Homogeneous Process for the Production of Biodiesel
Improving the Transesterification Route: Esterfip H
Future Improvements fo the Process
HIGHLY SOUR GAS PROCESSING IN A MORE SUSTAINABLE WORLD
The Use of Activated MDEA for Acid Gas Removal
Process Performance Highlights
A Case Study on the Use of Activated MDEA for Very Sour Gas Treatment
Acid Gas Removal for Cycling and/or Disposal
Bulk H2S Removal for Disposal
SPREX Performance
Capital Cost and Energy Balance Comparison
BIOETBE: A NEW COMPONENT FOR GASOLINE
High Quality Oxygenated as Gasoline Components
ETBE Technology
OLEFIN/PARAFFIN ALKYLATION: EVOLUTION OF A "GREEN" TECHNOLOGY
Liquid Acid Catalysts
Zeolite Catalysts
AlkyClean Alkylation Process: A True Solid Acid Catalyst (SAC) Process
TOWARDS THE DIRECT OXIDATION OF BENEZENE TO PHENOL
The Cumene Process
The Solutia Process
Direct Oxidation of Benzene to Phenol with Hydrogen Peroxide
Perspectives
THE FRIEDEL-CRAFTS ACYLATION OF AROMATIC ETHERS USING ZEOLITES
Literature Background
Acylation of Anisole by Acetic Anhydride
Acylation of Veratrole by Acetic Anhydride over HY Zeolite
Deactivation of the Catalysts
Benzoylation of Phenol Ether
GREEN SUSTAINABLE CHEMISTRY IN THE PRODUCTION OF NICOTINATES
Requirements for Green Processes
Significance of Niacin
Green Principles in the Manufacture of Niacin
Green Principles in LONZA's Niacinamide Process (5000 mtpa)
INTRODUCING GREEN METRICS EARLY IN PROCESS DEVELOPMENT. COMPARATIVE ASSESSMENT OF ALTERNATIVE INDUSTRIAL ROUTES TO ELLIOTT'S ALCOHOL, A KEY INTERMEDIATE IN THE PRODUCTION OF RESMETHRINS
Elliott's Alcohol
An Alternative Synthesis of Elliott's Alcohol
Comparative Synthesis of Elliott's Alcohol
Driving the "Green" Improvement
BASELL SPHERIZONE TECHNOLOGY
Technology Evolution
The Spherizone Technology
Technology Comparison
Environmental Considerations
Preface XV
List of Contributors XIX
1 From Green to Sustainable Industrial Chemistry 1
Gabriele Centi and Siglinda Perathoner
1.1 Introduction 1
1.2 Principles of Green Chemistry, Sustainable Chemistry and Risk 11
1.3 Sustainable Chemical Production and REACH 36
1.4 International Chemicals Policy and Sustainability 43
1.5 Sustainable Chemistry and Inherently Safer Design 47
1.6 A Vision and Roadmap for Sustainability Through Chemistry 56
1.7 Conclusions 69
2 Methods and Tools of Sustainable Industrial Chemistry: Catalysis 73
Gabriele Centi and Siglinda Perathoner
2.1 Introduction 73
2.2 Catalysis as Enabling Factor of Sustainable Chemical Production 74
2.3 Homogeneous Catalysis and the Role of Multiphase Operations 77
2.4 Bio- and Bioinspired-Catalysts 103
2.5 Solid Acids and Bases 120
2.6 Redox Catalysis 158
2.7 Cascade and Domino Catalytic Reactions 184
2.8 Multicomponent Catalytic Reactions 186
2.9 Organocatalysis 187
2.10 Conclusions 188
3 Methods and Tools of Sustainable Industrial Chemistry: Process Intensification 199
Gabriele Centi and Siglinda Perathoner
3.1 Introduction 199
3.2 Alternative Sources and Forms of Energy for Process Intensification 230
3.3 Micro(structured)-Reactors 243
4 Membrane Technologies at the Service of Sustainable Development Through Process Intensification 257
Gilbert M. Rios, Marie-Pierre Belleville, Delphine Paolucci-Jeanjean, and José Sanchez
4.1 Introduction 257
4.2 From Definitions to Function: A Few Fundamental Ideas 258
4.3 The Need for More Integrated Views on Materials and Process Conditions 262
4.4 Use of Hybrid Processes and New Operating Modes: The Key to Many Problems 267
4.5 Safe Management of Membrane Integration in Industrial Processes: A Huge Challenge 273
4.6 Conclusions 276
5 Accounting for Chemical Sustainability 279
Gabriele Centi and Siglinda Perathoner
5.1 Introduction 279
5.2 Ecological Footprint 281
5.3 Ecological Indicators 283
5.4 Metrics for Environmental Analysis and Eco-Efficiency 283
5.5 Sustainability Accounting 292
5.6 E-Factor and Atom Economy 296
5.7 Energy Intensity 304
5.8 Environmental Impact Indicators 305
5.9 Sustainable Chemical Production Metrics 306
5.10 Life Cycle Tools 310
5.11 Conclusions 315
6 Synthesis of Propene Oxide: A Successful Example of Sustainable Industrial Chemistry 319
Fabrizio Cavani and Anne M. Gaffney
6.1 Introduction: Current Industrial Propene Oxide Production 319
6.2 PO-only Routes: Several Approaches for Sustainable Alternatives 323
6.3 Conclusions 358
7 Synthesis of Adipic Acid: On the Way to More Sustainable Production 367
Fabrizio Cavani and Stefano Alini
7.1 Introduction: The Adipic Acid Market 367
7.2 Current Technologies for AA Production 368
7.3 Alternatives for AA Production 385
7.4 Emerging and Developing Technologies for AA Production 402
7.5 An Overview: Several Possible Green Routes to AA, Some Sustainable, Others Not 413
8 Ecofining: New Process for Green Diesel Production from Vegetable Oil 427
Franco Baldiraghi, Marco Di Stanislao, Giovanni Faraci, Carlo Perego, Terry Marker, Chris Gosling, Peter Kokayeff, Tom Kalnes, and Rich Marinangeli
8.1 Introduction 427
8.2 From Vegetable Oil to Green Diesel 428
8.3 UOP/Eni Ecofining Process 434
8.4 Life Cycle Assessment 435
8.5 Conclusion 437
9 A New Process for the Production of Biodiesel by Transesterification of Vegetable Oils with Heterogeneous Catalysis 439
Edouard Freund
9.1 Introduction 439
9.2 Direct Use of Vegetable Oils 441
9.3 Methyl Ester Derived from Vegetable Oils 441
9.4 Homogeneous Process for the Production of Biodiesel 442
9.5 Improving the Transesterification Route: Esterfip-H 445
9.6 Future Improvements of the Process 447
9.7 Conclusion 448
10 Highly Sour Gas Processing in a More Sustainable World 449
François Lallemand and Ari Minkkinen
10.1 Introduction 449
10.2 Use of Activated MDEA for Acid Gas Removal 451
10.3 Process Performance Highlights 454
10.4 Case Study of the Use of Activated MDEA for Treatment of Very Sour Gas 454
10.5 Acid Gas Removal for Cycling and/or Disposal 456
10.6 Bulk H2S Removal for Disposal 458
10.7 SPREX Performance 459
10.8 Capital Cost and Energy Balance Comparison 460
10.9 Conclusions 461
11 BioETBE: A New Component for Gasoline 463
Marco Di Girolamo and Domenico Sanfilippo
11.1 Introduction 463
11.2 High Quality Oxygenated as Gasoline Components 463
11.3 ETBE Technology 466
12 Olefin/Paraffin Alkylation: Evolution of a "Green" Technology 475
Anne M. Gaffney and Philip J. Angevine
12.1 Introduction 475
12.2 Liquid Acid Catalysts 476
12.3 Zeolite Catalysts 484
12.4 AlkyClean Alkylation Process: A True Solid Acid Catalyst (SAC) Process 488
12.5 Conclusion 504
13 Towards the Direct Oxidation of Benzene to Phenol 507
Marco Ricci, Daniele Bianchi, and Rossella Bortolo
13.1 Introduction 507
13.2 Cumene Process 508
13.3 Solutia Process 514
13.4 Direct Oxidation of Benzene to Phenol with Hydrogen Peroxide 516
13.5 Perspectives 525
13.6 Conclusions 525
14 Friedel-Crafts Acylation of Aromatic Ethers Using Zeolites 529
Roland Jacquot and Philippe Marion
14.1 Introduction 529
14.2 Literature Background 530
14.3 Acylation of Anisole by Acetic Anhydride 530
14.3.1 Industrial Processes 531
14.4 Acylation of Veratrole by Acetic Anhydride Over HY Zeolite 533
14.5 Deactivation of the Catalysts 534
14.6 Benzoylation of Phenol Ether 536
14.7 Concluding Remarks 539
15 Green Sustainable Chemistry in the Production of Nicotinates 541
Roderick Chuck
15.1 Requirements for Green Processes 541
15.2 Significance of Niacin 542
15.3 Green Principles in the Manufacture of Niacin 542
15.4 Green Principles in Lonza's Niacinamide Process (5000 mtpa) 548
16 Introducing Green Metrics Early in Process Development. Comparative Assessment of Alternative Industrial Routes to Elliott's Alcohol, A Key Intermediate in the Production of Resmethrins 551
Paolo Righi, Goffredo Rosini, and Valerio Borzatta
16.1 Introduction 551
16.2 Elliott's Alcohol 552
16.3 An Alternative Synthesis of Elliott's Alcohol 554
16.4 Comparative Assessment of the Two Alternative Routes to Elliott's Alcohol 555
16.5 Driving the "Green" Improvement 561
16.6 Conclusions 561
17 Basell Spherizone Technology 563
Maurizio Dorini and Gabriele Mei
17.1 Introduction 563
17.2 Technology Evolution 563
17.3 Spherizone Technology 567
17.4 Technology Comparison 575
17.5 Environmental Considerations 576
References 578
Index 579
