+353-1-416-8900REST OF WORLD
+44-20-3973-8888REST OF WORLD
1-917-300-0470EAST COAST U.S
1-800-526-8630U.S. (TOLL FREE)

Industrial Process Scale-up. Edition No. 2

  • ID: 4720965
  • Book
  • 142 Pages
  • Elsevier Science and Technology
1 of 4

Industrial Process Scale-up: A Practical Innovation Guide from Idea to Commercial Implementation, Second Edition helps industrial process innovators in research, development and commercial start-ups assess the risks of commercial-scale implementation, also providing them with practical guidelines and methods to reduce the risks to acceptable levels. In addition, the book can be used in cooperation with industrial R&D people and academic researchers to shape open innovation programs, and in education as a reference book. This updated edition has the latest literature and has been expanded with a scale-up of pharmaceutical processes and their history in both academia and the process industries.

  • Offers easily accessible, step-by-step and concise guidelines for industrial process scale-up
  • Explains each stage of the innovation funnel, from research, development, demonstration and commercial implementation for any process type and branch
  • Based on industrial experiences and practices that reduce the risks of commercial scale implementation of new processes to acceptable levels and reduce cost and time of process innovation

Please Note: This is an On Demand product, delivery may take up to 11 working days after payment has been received.

Note: Product cover images may vary from those shown
2 of 4

Dedication

Preface

Acknowledgements

1 Industrial Scale up Content and Context

1.1 Purpose and Set-up

1.2 Scale-up Definition Methodology and Risks

1.2.1 Scale-up Definition

1.2.2 Scale-up Methodology

1.2.3 Stage-gate Innovation Method

1.2.4 Scale-up and Design role

1.2.5. Scale-up Behavior and Risks

1.3 Process industry Systems

1.3.1 Value and Life Cycle Chains

1.3.2 Industrial Complexes

1.3.3 Processes

1.3.4 Unit Operations

1.3.5 Major Process Equipment

1.3.6 Dispersed System Level

1.3.7 Chemistry Level

1.4 Partners and Stakeholders for Innovation

2 Discovery Stage

2.1 Obtaining Process Ideas

2.1.1 Obtaining Ideas in General

2.1.2 Obtaining New Process Routes

2.2 Assessing Process Ideas

2.2.1 Assessing and Ranking many Ideas

2.2.2 Technology Readiness Level method

2.3 Process Design Sketch

2.3.1 Process Concept Design Essentials

2.3.2 Reference Case for Comparison

2.4 Proof of Principle

2.5 Discovery Stage-gate Evaluation

2.5.1 Discovery Stage-gate Purpose

2.5.2 Reporting Discovery Stage

2.6 Pitfalls Discovery Stage

3 Concept Stage

3.1 Detailed Assessment of Ideas

3.1.1 New Process Routes Assessments

3.1.2 Detailed Assessment Best Ideas

3.1.3 Co-operation with External Innovation Partners

3.2 Identifying Potential Showstoppers

3.3 Proof of Concept

3.4 Concept Design

3.4.1 Purpose Concept Design

3.4.2 Concept Design

3.4.3 Break-through Concept Design by Function Integration

3.4.4. Process Modelling and Simulation

3.4.5 Essential Property Determination

3.4.6 Concept Stage Reporting

3.5 Concept Stage-gate Evaluation

3.6 Pitfalls Concept Stage

4 Feasibility Stage

4.1 Purpose of Feasibility Stage

4.2 Process Equipment Scale-up

4.2.1 Introduction to Process Equipment Type Selection

4.2.2 Critical Performance Phenomena

4.2.2.1 Overview Critical Performance Phenomena

4.2.2.2 Feed Distribution

4.2.2.3 Residence time distribution

4.2.2.4 Mixing

4.2.2.5 Shear Rate Distribution

4.2.2.6 Mass transfer

4.2.2.7 Heat transfer

4.2.2.8 Impulse transfer

4.2.3 Process Equipment Scale-up Methods

4.2.3.1 Overview Process Equipment Scale-up Methods

4.2.3.2 Brute Force Scale-Up and Scale-Down

4.2.3.3 Model-Based Scale-Up

4.2.3.4 Empirical Scale-Up

4.2.3.5 Hybrid Model-Empirical Scale-up

4.2.3.6 Dimensionless numbers Scale-up

4.2.3.7 Direct Scale-Up

4.2.4 Scale-up Characteristics Process Equipment Tpes

4.2.5 Process Equipment Type Selection in View of Reliable Large Scale Performance

4.2.6 Historic Case of Process Equipment Type Selection Shell Gas-To-Liquid Development

4.3 Process Scale-up by Design

4.3.1 Purpose Commercial Scale Design in Feasibility Stage

4.3.2 Design Choices in View of Development Cost.

4.3.3 Design Base

4.3.4 Purchasing a Complete Process Technology

4.4 Risk Assessment for Decision Mini-Pant

4.4.1 Mini-plant Choice

4.4.2. Mini-plant Cost Estimate

4.5 Decision on Integrated Down-Scaled pilot plant

4.5.1 Pilot Plant Purposes

4.5.2 Decision on having a Pilot Plant

4.5.3 Industry Project Statistics of not having a Pilot Plant.

4.5.4 Value of Information Approach for Development Plan Decisions

4.5.5 Pilot Plant design

4.5.6 Pilot Plant Cost Estimate

4.6 Decision and Design of Cold-Flow Test Units

4.7 Feasibility Stage Study Pharmaceuticals Agrochemicals and Fine Chemicals

4.7.1 Pharmaceuticals Feasibility Stage

4.7.2 Agrochemicals Feasibility Stage

4.7.3 Fine chemicals Feasibility stage: Unit Operations Choices in View of Scale-up

4.8 Planning for Concurrent Development and Commercial Scale Design

4.9 Feasibility Stage-gate Evaluation

4.10 Pitfalls Feasibility Stage

5 Development Stage

5.1 Mini-Plant Engineering, Procurement, Construction and Testing

5.2 Pilot Plant Engineering, Procurement, Construction and Testing

5.3 Cold-Flow Plant Engineering, Procurement, Construction and Testing

5.4 Front End Engineering Design (FEED)

5.5 Development Stage-Gate Reporting and Evaluation

5.6 Pitfalls Development Stage

6 Scale-up from Existing Pilot Plant

6.1 Scale-up from Existing Pilot Plant to Existing Commercial Scale Process

6.1.1 Scale-up Continuous Process from Existing Pilot Plant to Existing Process

6.1.2 Scale-up for Batch Process from Pilot Plant to Existing Commercial Scale Process

6.2 Scale-up from Existing Pilot Plant to New Process

7 Implementation Stage

7.1 Introduction to Implementation Stage

7.2 Rationale Demonstration Scale Decision

7.3 Engineering Design, Procurement and Construction

7.3.1 Contractor selection

7.3.2 Detailed Design

7.3.3 Procurement, Construction and Commissioning

7.4 Start-Up Commercial Processes

7.4.1 Start-Up Time Prediction

7.4.1.1 Start-up time Merrow Industry Correlation

7.4.1.2 Critical Success Factors Reducing Start-up time

7.4.1.3 Fulfilling critical success factors

7.4.1.4 Start-up time and Critical Success Factors Shell GTL Case

7.5 Pitfalls Implementation Stage

8 Industrial Scale-Up Cases

8.1 Liquid- Liquid Extractive Reaction by Taguchi model-based product quality control

8.2 Start-up Bulk Chemical Product Conventional Process

8.3 Start-up Conventional Process in South Korea

8.4 Purchasing Novel Process

8.5 Polymerization Process

8.6 Wastewater Novel Design and Implementation

8.7 Carilon Engineering Polymer: New Product, Process, Market and Strategy Change

8.8 Purchasing a Commercially Proven Rotating Filter

8.9 Fermentation Scale-up

8.10 Fine chemicals Discovery stage

8.11 Summary of Learning points from Industrial Cases

References

Index

Note: Product cover images may vary from those shown
3 of 4

Loading
LOADING...

4 of 4
Harmsen, Jan
Jan Harmsen is currently the Director of Harmsen Consultancy B.V., Leonardo da Vinci Chair Sustainable Chemical Technology at the University of Groningen, and Chairman of the Dutch Process Technology Association (NPT). From 1996 to 2010 he was the Principal Process Developer, Shell Technology Center Amsterdam. Recently he pubished the books:

Jan Harmsen, Industrial Process Scale-up: A practical innovation guide from idea to commercial implementation, Elsevier, (2013), ISBN 9780444627261.

Gerald Jonker and Jan Harmsen, Engineering for Sustainability. A practical guide for sustainable design, Elsevier, (2012), ISBN 9780444538468.

Note: Product cover images may vary from those shown
5 of 4
Note: Product cover images may vary from those shown
Order Online - visit: https://www.researchandmarkets.com/reports/4720965
Adroll
adroll