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Clean Products and Processes II. 2. Overview. IntroductionMethodologyProblem FormulationSolution ApproachTools neededApplication examplesConclusions. Clean Products and Processes II. 3. Introduction-I: Definitions. Environmentally Benign ProcessAll environmental aspects have been considered.The process complies (AT LEAST) with all regulatory requirements.PollutionCausesSolvents, energy use, by-products in effluent streams.Prevention, Treatment
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1. Design of Environmentally Benign Processes: Integration of Solvent Design & Separation Process Synthesis Peter M. Harper, Martin Hostrup, Rafiqul Gani
CAPEC
Dept. of Chem. Eng., Tech. Univ. of Denmark
http://www.capec.kt.dtu.dk
2. Clean Products and Processes II 2 Overview Introduction
Methodology
Problem Formulation
Solution Approach
Tools needed
Application examples
Conclusions
3. Clean Products and Processes II 3 Introduction-I: Definitions Environmentally Benign Process
All environmental aspects have been considered.
The process complies (AT LEAST) with all regulatory requirements.
Pollution
Causes
Solvents, energy use, by-products in effluent streams.
Prevention, Treatment & Cure
4. Clean Products and Processes II 4 Introduction -II: Integration Objective: Develop a combined methodology in order to determine (interactively), optimal, environmentally benign processes
5. Clean Products and Processes II 5 Superstructure representation
6. Clean Products and Processes II 6 Methodology-I: Problem Formulation New process (pollution prevention)
Existing process (treatment/cure)
Variables are fixed
Problem more constrained (less degrees of freedom)
More difficult to solve
7. Clean Products and Processes II 7 Problem Formulation Steps 1. Analyse process, divide into reaction & separation blocks.
2. List separation techniques to be considered.
3. External mediums? Eliminate if none found.
4. Screen out infeasible separation techniques.
5. Binary mixture analysis: Azeotropes, miscibility, …
6. Generate solvent alternatives.
7. Multicomponent mixture analysis: Separation boundaries, etc.
8. Check separation stream for reactants. Recycle?
9. Formulate optimization problem in terms of superstructure, objective function, constraints, etc.
8. Clean Products and Processes II 8 Methodology-II: Solution Approach
9. Clean Products and Processes II 9 Sub-Problems: Process Design Conditions of operation
Temperature / Pressure
Separation unit (distillation column) design
Separation efficiency curves
Product specifications
Design parameters (feed location, reflux, …)
Reaction synthesis and optimization
Volume / Residence time
Temperature profile
Operational constraints
Separation boundaries
Solvent/material design (selection)
Energy consumption & waste
10. Clean Products and Processes II 10 Process Design: Separation techniques Need for (appropriate) thermodynamic models. Thermodynamic Model Selection
Need for Properties (Database/Property prediction)
11. Clean Products and Processes II 11 Sub-Problems: Solvent Design/Selection I Find compounds matching desired properties
Performs database search
Generates missing data
Based on properties controlling the search/design operation
Ability to identify novel compounds
Suitable for substitution problems
12. Clean Products and Processes II 12 Molecule Generation Multilevel Approach
All generation is rule-based (feasibility, method considerations).
Increasing complexity on the generated molecular descriptions.
Output from previous level is used as input for the next next level.
13. Clean Products and Processes II 13 Generation criteria/properties Group contribution
Correlation
EOS
UNIFAC
Rigorous phase calculations
Link to database
Calculation order optimised for speed
14. Clean Products and Processes II 14 Sub-Problems: Material Design/Selection Designing or selecting the most appropriate membrane material for a particular application.
Computer Aided Membrane Design still an emerging field.
Database approach combined with shortcut simulations:
Allows for realistic input data to be used in the selection process.
The choice of material can change the efficiency of a process by several orders of magnitude.
15. Clean Products and Processes II 15 Sub-Problems: Waste/Energy Aspects Local (process-wide) energy aspects can be addressed using the simulation engine.
Off-process energy requirements must be handled using LCA techniques - taking local conditions into account.
Waste/effluent minimisation can (in part) be handled using the simulator/optimiser.
Impact assessment tools must be used……...
16. Clean Products and Processes II 16 Methodology- III: Problem Solution Flexible & interactive solution of the problem
Rigorous models used in the NLP-step
Linear model generated for the MILP-step
Any sub-problem can also be solved independently
17. Clean Products and Processes II 17 Methodology - IV: Tools Needed Process Simulator (steady state, dynamic) & Modelling tool
Solvers (NLP, MINLP, AE, DAE, etc.)
Flowsheet generation tool (process synthesis)
CAMD (solvent selection/design)
Physical properties database (> 13000 compounds)
Environmental properties database
Materials database
Properties estimation tool (Pure component & mixture properties)
Impact Assessment tools
18. Clean Products and Processes II 18 Application Examples
19. Clean Products and Processes II 19 Example-I: Design criteria Compound type: Acyclic alkanes, ethers, esters, aldehydes, ketones and acids.
Pure component properties:
Tflash > 310 K, Tboil > 421 K ; Tmelt < 310 K
Mixture properties:
Sl < 0.01 ; m > 0.1 ; ? > 7 ; B > 1
Solvent must not form azeotrope with acetic acid
Liquid-liquid phase behaviour at 298 K
20. Clean Products and Processes II 20 Example-I: Results & performance 2332 Alternatives were found
Candidates sorted using m*? as ranking criteria
Structure analysis/matching to identify CAS-NO
21. Clean Products and Processes II 21 Example-I: Environmental Aspects D = Drug, S = Primary Irritant, T = Reproductive-Effector, M = Mutagen, C= Tumorigen
22. 22 Example-II: Integrated Problem
23. Clean Products and Processes II 23 Pressure dependence
24. Clean Products and Processes II 24 Pressure dependence
