1 Optimization of LNG plants: Challenges and strategies Magnus G. Jacobsen Sigurd Skogestad ESCAPE-21, May 31, 2011 Porto Carras, Chalkidiki, Greece.

Slides:

Advertisements

Similar presentations

A series of heat exchangers with each stage using a different refrigerant. Tailored to take advantage of different thermodynamic properties of the refrigerants.

Advertisements

Heat Exchanger Network Retrofit

Introduction Process Simulation.

Dynamic modeling, optimization and control of a CO 2 stripper Marie Solvik Supervisors : Sigurd Skogestad and Marius Støre Govatsmark.

1 INTERACTION OF PROCESS DESIGN AND CONTROL Ref: Seider, Seader and Lewin (2004), Chapter 20.

Thermoflow, Inc. TOPS stands for Thermoflow’s Optimization System and is a general purpose optimizer for use with Thermoflow’s core programs. TOPS runs.

Control Structure Selection for a Methanol Plant using Hysys/Unisim

Operated by the Southeastern Universities Research Association for the U.S. Department of Energy Thomas Jefferson National Accelerator Facility Page 1.

CHAPTER 9 FLOWSHEET ANALYSIS FOR POLLUTION PREVENTION.

WinSim Inc. Advanced Engineering Software

Optimization of thermal processes2007/2008 Optimization of thermal processes Maciej Marek Czestochowa University of Technology Institute of Thermal Machinery.

Université de Lyon- CNRS-LAGEP, France Paper C-090 Model Predictive Control of the Primary Drying Stage of the Drying of Solutions.

PROCESS INTEGRATED DESIGN WITHIN A MODEL PREDICTIVE CONTROL FRAMEWORK Mario Francisco, Pastora Vega, Omar Pérez University of Salamanca – Spain University.

1 Single-cycle mixed-fluid LNG (PRICO) process Part I: Optimal design Sigurd Skogestad & Jørgen Bauck Jensen Quatar, January 2009.

Dynamic Steady State Continuous Discrete Deterministic Stochastic.

Supply Chain Design Problem Tuukka Puranen Postgraduate Seminar in Information Technology Wednesday, March 26, 2009.

Integration of Design & Control CHEN 4470 – Process Design Practice

1 Real-Time Optimization (RTO) In previous chapters we have emphasized control system performance for disturbance and set-point changes. Now we will be.

Introduction: What is LNG? When natural gas is cooled to a temperature of approximate (–160 C) at atmospheric pressure it condenses to a liquid,called.

Optimization of Linear Problems: Linear Programming (LP) © 2011 Daniel Kirschen and University of Washington 1.

1 M. Panahi ’Plantwide Control for Economically Optimal Operation of Chemical Plants’ Plantwide Control for Economically Optimal Operation of Chemical.

Introduction to API Process Simulation

Computer Assisted Process Design---HYSYS Bo Hu. Introduction HYSYS is only one process simulation program out of a number. Steady State Processes ASPEN.

1 Operation of heat pump cycles Jørgen Bauck Jensen & Sigurd Skogestad Department of Chemical Engineering Norwegian University of Science and Technology.

1 Single-cycle mixed-fluid LNG (PRICO) process Part II: Optimal operation Sigurd Skogestad & Jørgen Bauck Jensen Quatar, January 2009.

Optimal temperature control of rooms Siri Hofstad Trapnes Superviors: Sigurd Skogestad and Chriss Grimholt.

Ramprasad Yelchuru, MIQP formulations for optimal controlled variables selection in Self Optimizing Control, 1/16 MIQP formulation for optimal controlled.

CHAPTER II PROCESS DYNAMICS AND MATHEMATICAL MODELING

SINTEF Energy Research

GHGT-8 Self-Optimizing and Control Structure Design for a CO 2 Capturing Plant Mehdi Panahi, Mehdi Karimi, Sigurd Skogestad, Magne Hillestad, Hallvard.

1 Active constraint regions for optimal operation of a simple LNG process Magnus G. Jacobsen and Sigurd Skogestad Department of Chemical Engineering NTNU.

Optimal operation of distillation columns and link to control Distillation Course Berlin Summer Sigurd Skogestad. Part 3.

ERT 210/4 Process Control & Dynamics

1 Coordinator MPC for maximization of plant throughput Elvira Marie B. Aske* &, Stig Strand & and Sigurd Skogestad* * Department of Chemical Engineering,

1 Modelling, Operation and Control of an LNG Plant Jens Strandberg & Sigurd Skogestad Department of Chemical Engineering, Norwegian University of Science.

MULTIPERIOD DESIGN OF AZEOTROPIC SEPARATION SYSTEMS Kenneth H. Tyner and Arthur W. Westerberg.

1 Chapter 8 Nonlinear Programming with Constraints.

A Framework for Distributed Model Predictive Control

Business Analytics with Nonlinear Programming

Optimization of Process Flowsheets S,S&L Chapter 24 T&S Chapter 12 Terry A. Ring CHEN 5253.

1 Chapter 7 Linear Programming. 2 Linear Programming (LP) Problems Both objective function and constraints are linear. Solutions are highly structured.

1 Single-cycle mixed-fluid LNG (PRICO) process Part II: Optimal operation Sigurd Skogestad & Jørgen Bauck Jensen Qatar, January 2009.

1 Self-Optimizing Control HDA case study S. Skogestad, May 2006 Thanks to Antonio Araújo.

1 Active constraint regions for optimal operation of chemical processes Magnus Glosli Jacobsen PhD defense presentation November 18th, 2011.

Basic skill for ASPEN plus Liang Yu Department of Biological Systems Engineering Washington State University

Held by Faragostaran Co. Presented to Gas refinery plants of Asalouyeh, Iran By: Ali Akbar Eftekhari.

1 Single-cycle mixed-fluid LNG (PRICO) process Part I: Optimal design Sigurd Skogestad & Jørgen Bauck Jensen Qatar, January 2009.

1 Active constraint regions for economically optimal operation of distillation columns Sigurd Skogestad and Magnus G. Jacobsen Department of Chemical Engineering.

1 Using Self-Optimizing Control on the Statoil Mongstad HEN Daniel Greiner Edvardsen May 27, 2010 NTNU Confidential.

1 Ref: Seider et al, Product and process design principles, 2 nd ed., Chapter 4, Wiley, 2004.

1 Self-optimizing control From key performance indicators to control of biological systems Sigurd Skogestad Department of Chemical Engineering Norwegian.

1 Optimal operation of energy storage in buildings: The use of hot water system Emma Johansson Supervisors: Sigurd Skogestad and Vinicius de Oliveira.

1 Unconstrained degrees of freedom: C. Optimal measurement combination (Alstad, 2002) Basis: Want optimal value of c independent of disturbances ) – 

Economic Plantwide Control using

1 Control of maldistribution of flow in parallell heat exchangers Magnus G. Jacobsen, Sigurd Skogestad Nordic Process Controi workshop, Porsgrunn

Better together... we deliver MODELLING, CONTROL AND OPTIMISATION OF A DUAL CIRCUIT INDUCED DRAFT COOLING WATER SYSTEM February 2016 C.J. Muller Sasol;

Structural & Multidisciplinary Optimization Group Deciding How Conservative A Designer Should Be: Simulating Future Tests and Redesign Nathaniel Price.

1 Self-optimizing control From key performance indicators to control of biological systems Sigurd Skogestad Department of Chemical Engineering Norwegian.

MULTIPERIOD DESIGN OF AZEOTROPIC SEPARATION SYSTEMS Kenneth H. Tyner and Arthur W. Westerberg.

Coordinator MPC with focus on maximizing throughput

Bounded Nonlinear Optimization to Fit a Model of Acoustic Foams

by Lars Erik Øi and Vladyslav Shchuchenko

Dynamic modelling of a Hex with phase change

Economic Plantwide Control:

Stian Aaltvedt Supervisors: Sigurd Skogestad Johannes Jäschke

Ramprasad Yelchuru Sigurd Skogestad Henrik Manum

Optimization of Process Flowsheets

An ODDISAY System: Process Design Optimization by Using MCD Algorithm

Operation and Control of Divided Wall (Petlyuk) Column

The Design of LNG liquefaction Plant & Control Strategy development.

Presentation transcript:

1 Optimization of LNG plants: Challenges and strategies Magnus G. Jacobsen Sigurd Skogestad ESCAPE-21, May 31, 2011 Porto Carras, Chalkidiki, Greece

2 Outline Design vs Operation Challenges in simulation and optimization Example process: C3-MR Reliability and accuracy study Conclusions Jacobsen, Skogestad – Optimization of LNG plants: Challenges and strategies

3 Design vs operation Design: Select –Process equipment –Nominal operating conditions Operation: –Process equipment is given –Run the process at an economical optimum –Satisfy quality and safety constraints Jacobsen, Skogestad – Optimization of LNG plants: Challenges and strategies

4 Optimization objective Minimize the cost J –x : internal process variables, –u : inputs (degrees of freedom) –d: are disturbances Low energy price: Maximize production rate, given the available energy High energy price: Minimize energy consumption, producing the contracted amount Jacobsen, Skogestad – Optimization of LNG plants: Challenges and strategies

5 Earlier work on LNG optimization Increasing capacity through equipment improvements Process design modifications Optimal design of a process –Both continuous methods (SQP), gradient-free and mixed-integer methods have been used Optimal operation of a given process –Few papers overall –Very few using continuous methods, only one using it on the world’s most used liquefaction process! Jacobsen, Skogestad – Optimization of LNG plants: Challenges and strategies

6 Potential challenges Precise optimization requires good models. Commercial modelling software (Aspen, Unisim etc) does not have good steady-state models for LNG heat exchangers. Strong correlation between process variables Discontinuities in constraint functions Jacobsen, Skogestad – Optimization of LNG plants: Challenges and strategies

7 Example process: C3-MR Most widely used process for liquefaction of natural gas Uses propane (C3) for precooling down to -40°C Uses a mixed refrigerant for liquefaction in a spiral- wound heat exchanger Three or four pressure levels in precooling Jacobsen, Skogestad – Optimization of LNG plants: Challenges and strategies

8 PrecoolingLiquefaction

9 Unisim model, precooling part Jacobsen, Skogestad – Optimization of LNG plants: Challenges and strategies

10 Degrees of freedom, liquefaction part 6 degrees of freedom in liquefaction part –Mixed refrigerant flowrate (F MR ) –Refrigerant pressures (P h,MR, P l,MR ) –Refrigerant composition (x MR ), 3 mole fractions

11 Unisim model, liquefaction part Jacobsen, Skogestad – Optimization of LNG plants: Challenges and strategies LNG

12 Solving of heat exchanger model

13 Jacobsen, Skogestad – Optimization of LNG plants: Challenges and strategies

14 Model formulations 1.Specify temperatures in the MCHE submodel We must add heat exchanger area specifications as equality constraints in optimization 2.Specify heat exchanger UA values, include recycle convergence in optimization problem (infeasible- path optimization) [1] 3.Specify heat exchanger UA values, and let the simulator solve recycles [1] See t.e. Biegler, L., Hughes, R., Infeasible path optimization with sequential modular simulators. AIChE journal 28 (6), 994–1002. Jacobsen, Skogestad – Optimization of LNG plants: Challenges and strategies

15 Model solution reliability study Focus on liquefaction part Unisim used for flowsheet calculations Matlab for optimization & equation solving Reliability of Unisim model itself –How frequently will the simulation program fail to return aconverged flowsheet? Overall accuracy –How accurately can we solve the liquefaction model with the three different formulations mentioned earlier? Jacobsen, Skogestad – Optimization of LNG plants: Challenges and strategies

16 Results: Unisim reliability For each model formulation, Unisim model called 300 times –Temperatures specified: No failures (the Unisim model converged at every call) –Areas specified: Recycles inactive: 11 failures (4%) Recycles active: 177 failures (59%) Shows that the Unisim solver –easily solves for temperature, –less easily for HX area –recycle convergence is not robust Jacobsen, Skogestad – Optimization of LNG plants: Challenges and strategies

17 Results: Heat exchangers solved by MATLAB Solve UA(T) = UA specified to a relative error of using different MATLAB solvers 150 runs with different values for process inputs u –fsolve.m: 103 failures (69%) –fmincon, active-set algorithm: 128 failures (85%) –fmincon, interior-point algorithm: 86 failures (57%) Jacobsen, Skogestad – Optimization of LNG plants: Challenges and strategies

18 Results: Recycles solved in MATLAB Converge recycle stream temperatures to a tolerance of 0.1°C (relative error ) 150 runs varying the values of u –fsolve.m: 29 failures (19%) –fmincon, active-set algorithm: 138 failures (92%) –fmincon, interior-point algorithm: 132 failures (88%) Jacobsen, Skogestad – Optimization of LNG plants: Challenges and strategies

19 Conclusions Model Formulation II most reliable for simulation –For optimization, formulation I works best Matlab’s standard equation solver fsolve is more likely to converge recycles than the internal recycle solver in Unisim Further work on the formulation of the optimization problem is needed Jacobsen, Skogestad – Optimization of LNG plants: Challenges and strategies