Course ID: CH375 Type: Face-to-Face CourseLanguage: English Skill Level: Intermediate Duration: 4 days CEUs: 3.00 PDHs: 30.00 Share This Post: Source: RAPID - RAPID Manufacturing Institute for Process Intensification Join Dr. Brian Paul and Dr. Goran Jovanovic in this 4-day course for professional engineers interested in advancing MCPI in the chemical industry, specifically through the use of "number-up" plant designs. After taking this course you will be able to: Use a newly developed characteristic time-scale analysis tool to identify, design and develop PI components for an MCPI application. Engage additive manufacturing and micromanufacturing equipment used to build PI components. Control the cost of producing innovative PI component designs with component suppliers. Consider how to overcome barriers in the deployment of MCPI plants through Engineering, Procurement and Construction firms. Develop a business rationale for the design and scale-up of an MCPI plant. Describe the global trends driving modular manufacturing as well as the key challenges in deploying modular technologies Instructor(s): Goran Jovanovic Dr. Jovanovic received his B.Sc. degree in chemical engineering from Belgrade University (Belgrade, Serbia). He was awarded the Fulbright Grant for graduate study in the US where he received his M.Sc. and the Ph.D. degree in chemical engineering. Dr. Jovanovic taught chemical engineering at Belgrade University from 1980 to 1991. In 1991 he moved back to the US at Oregon State University (OSU) where he is Professor at the School of Chemical, Biological and Environmental Engineering (CBEE). Dr. Jovanovic served in the leadership of the ATAMI institute, and he is the lead Principal...Read more Brian Paul Brian K. Paul is the Tom and Carmen West Faculty Scholar and a Professor of Manufacturing Engineering at Oregon State University (OSU) where he conducts research in manufacturing process design, materials joining and hybrid additive manufacturing. Professor Paul has authored more than 100 refereed publications, received twelve U.S. patents (six licensed), and helped 15 companies advance microchannel and nanotechnology toward the marketplace, four formed from work with his graduate students. In 2013, Professor Paul was invited to serve as the Assistant Director of Technology...Read more Pricing No public sessions of this course are scheduled at this time. If you are interested in receiving updates related to this course please fill out the Course Inquiry Form. Teams (10 or more) Minimize cost and maximize learning with Train-A-Team. Learn more Horizontal TabsOutline Day One Theme: Designing for Process Intensification 7:45 - 8:00 Registration 8:00 – 8:30 Welcome 8:30 – 9:45 The Change in Paradigm: Chemical Technologies Go 2D 9:45 – 10:00 Morning Break 10:00 – 11:30 Time Scale Analysis & Characteristic Times 11:30 – 1:00 Lunch Break 1:00 – 2:30 Introduction to GTL Bioprocesses 2:30 – 3:15 Class Exercise: Four Tenants of PI 3:15 – 3:30 Afternoon Break 3:30 – 4:00 Class Exercise: Suggested PI Improvements 4:00 - 5:00 Lab Stations (Bio-Lamina-Plate Reactor, Mutliphase Microchannel Separator, BHD Reactor, Corona Reactor) 5:00-5:30 Wrap-Up Day Two Theme: Designing for Process Intensification 8:30 – 9:45 BLP Reactor Analysis 9:45 – 10:00 Morning Break 10:00 – 11:00 Lamina Plate Separation 11:00 – Noon Lab Visit: L-P Separation Demonstration Noon – 1:00 Lunch Break 1:00 – 2:00 Solid Catalyzed Reaction Processes 2:00 – 3:15 Class Exercise: Characteristic Times for Innovation Opportunities 3:15 – 3:30 Afternoon Break 3:30 – 4:00 Microfluidics 4:00 – 5:00 Lab Visit: Demonstration of Microfluidics Testing 5:00 - 5:30 Wrap-Up Day Three Theme: Implementing Novel PI Components 8:00 – 9:15 Challenges with Implementing PI, Process Selection & Shaping Processes 9:15 - 9:30 Morning Break 9:30 – 11:00 Lab Demonstration: Binder Jetting, Electrically-Assissted Embossing, Hot-Embossing, Characterizing Shape 11:00 – 11:15 Morning Break 11:15 - 12:00 Bonding Processes 12:00 - 1:00 Lunch Break 1:00 - 2:30 Lab Demonstration: Diffusion Bonding and Brazing, Laser Welding & Laser Powder Bed Fusion (LPBF) 2:30 - 2:45 Afternoon Break 2:45 – 3:15 Machine Tool Selection, Process Step Analysis 3:15 - 3:45 Class Exercise: Develop a Phase Separator Design Based on Manufacturing Constraints 3:45 - 5:00 Requirements, Exploring Design and Manufacturing Innovations, Engaging with Suppliers 5:00 - 5:30 Wrap-Up Day Four Theme: Implementing Modular Chemical Process Intensification 8:00 - 9:30 Introduction to Modular Offsite Construction, When to Choose Modular vs. Conventional Processing, How Chemical PI Advances Modular Offsite Construction 9:30 - 9:45 Morning Break 9:45 - 10:45 Show & Tell: Sizing of Plants: Discuss Specification of EPC Flow Sheet and Real-Time Modular Assembly of Components 10:45 - 11:00 Morning Break 11:00 - Noon Understanding MCPI Noon - 1:00 Lunch Break 1:00 - 2:45 Barriers to MCPI, Understanding Total Cost of Ownership, Forecasting and Net Present Value of Chemical Plants 2:45 - 3:00 Afternoon Break 3:00 - 4:00 Class Exercise: Make a Business Case for MCPI 4:00 - 4:30 Wrap-Up 4:30 - 5:30 Workshop Feedback Download Course Outline (PDF) What You'll Learn Use a newly developed characteristic time-scale analysis tool to identify, design and develop PI components for an MCPI application. Engage additive manufacturing and micromanufacturing equipment used to build PI components. Control the cost of producing innovative PI component designs with component suppliers. Consider how to overcome barriers in the deployment of MCPI plants through Engineering, Procurement and Construction firms. Develop a business rationale for the design and scale-up of an MCPI plant. Describe the global trends driving modular manufacturing as well as the key challenges in deploying modular technologies Who Should Attend Engineers working in the following industries Refining Chemicals Pharmaceuticals Pulp & Paper Accommodation Instructions: Corporate rates available courtesy of Oregon State University. Reserve through the links above to make your reservation using the corporate codes.