1 Copyright 2006 OLI Systems, Inc. All Rights reserved The materials displayed here are provided to the lessees, selected individuals and agents of OLI.

Slides:

Advertisements

Similar presentations

Opening new doors with Chemistry THINK SIMULATION! 24 th Conference October 23-24, 2007 ESP and the OLI Engine Updates Robert Young.

Advertisements

Assumptions: Incompressible substance, B. Negligible heat transfer

Absorption and Stripping

Modelling & Simulation of Chemical Engineering Systems

Opening new doors with Chemistry THINK SIMULATION! Electrolyte Modeling Basics Process Simulation OLI Systems, Inc.

Lecture 5: Isothermal Flash Calculations 1 In the last lecture we: Described energy and entropy balances in flowing systems Defined availability and lost.

Heat Exchangers: Design Considerations

Refrigeration Cycles Chapter 11.

AP PHYSICS. p. 423 #59 A 1500W heat engine operates at 25% efficiency. The heat energy expelled at the low temperature is absorbed by a stream of water.

Chapter 15 CHEMICAL REACTIONS

Process Modeling using Aspen Plus

Pharmaceutical API Process Development and Design

Matching a Given Steam Turbine in THERMOFLEX Thermoflow Inc.

9 CHAPTER Vapor and Combined Power Cycles.

Chapter 1 VAPOR AND COMBINED POWER CYCLES

Nonisothermal case: adiabatic approach Prof. Dr. Marco Mazzotti - Institut für Verfahrenstechnik.

Michael Naas, Teddy Wescott, Andrew Gluck

Applications of API Process Simulation Pharmaceutical API Process Development and Design.

Cross-current cascade of ideal stages Prof. Dr. Marco Mazzotti - Institut für Verfahrenstechnik.

Development of Dynamic Models Illustrative Example: A Blending Process

Development of Dynamic Models Illustrative Example: A Blending Process

 For a non-ideal system, where the molar latent heat is no longer constant and where there is a substantial heat of mixing, the calculations become much.

ChE 201 Chemical Engineering Calculations I Fall 2005/2006 Course Description: System of units and dimensions. Stoichiometry. Ideal and non-ideal gases,

Vapor and Combined Power Cycles

Joshua Condon, Richard Graver, Joseph Saah, Shekhar Shah

Lec 23: Brayton cycle regeneration, Rankine cycle

Lecture 6: Bubble and Dew Point 1 Bubble Point and Dew Point Calculations In the last lecture we discussed: An isothermal flash separations The derivation.

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.

Chapter 3.1: Heat Exchanger Analysis Using LMTD method

THEORETICAL MODELS OF CHEMICAL PROCESSES

Controller Design Using CHEMCAD

Mass and Energy Balances – Stripping Section and Partial Reboiler

CHAPTER II PROCESS DYNAMICS AND MATHEMATICAL MODELING

The EpH module EpH calculates and plots isothermal EpH (Pourbaix) diagrams. EpH accesses only compound databases and treats the aqueous phase as an ideal.

University of Texas at AustinMichigan Technological University 1 Module 5: Process Integration of Heat and Mass Chapter 10 David R. Shonnard Department.

Chemical Engineering 3P04

Chemstations, Inc – Houston, TX – – Short Cut - Fenske-Underwood-Gilliland - Limited design, Rating Tower - Rigorous.

Lecture 1: Kinetics of Substrate Utilization and Product Formation

Chapter 4 Control Volume Analysis Using Energy. Learning Outcomes ►Distinguish between steady-state and transient analysis, ►Distinguishing between mass.

Introduction to Separation

© 2014 Carl Lund, all rights reserved A First Course on Kinetics and Reaction Engineering Class 23.

Energy and the Environment Fall 2013 Instructor: Xiaodong Chu ： Office Tel.:

Chapter 8: The Thermodynamics of Multicomponent Mixtures

© Copyright 2005 POSC Product Flow Model Overview.

The Production of Ethanol from Syngas

Copyright©2000 by Houghton Mifflin Company. All rights reserved. 1 Chapter 17 Honors Chemistry Thermochemistry.

Concentric Tube (double-pipe) Heat Exchangers

CHAPTER 15 CHEMICAL REACTIONS Lecture slides by Mehmet Kanoglu Copyright © The McGraw-Hill Education. Permission required for reproduction or display.

Oil and Gas Technology Program Oil and Gas Technology Program PTRT 1317 Natural Gas Processing I Chapter 6A Intro to Refrigeration.

Unit Operations Laboratory Distillation Analysis Seminar Super Team 2005 Monday, December 5, :30 PM.

CHEM-2002 SIMULATION LAB SHEET-2 Example-1 Ammonia Recovery

ChemCAD Heat Exchangers

TOPIC:- VAPOUR CYCLES CREATED BY:

Chemical Engineering Explained

Aspen Separation Unit Operations

Concentric Tube (double-pipe) Heat Exchangers

9 CHAPTER Vapor and Combined Power Cycles.

Introducing OLI Flowsheet: ESP

Lecture Objectives: Finish with Electric Energy Generation

Introduction to Crude Oil Distillation

Introduction to Aspen Plus

Lecture Objectives: Start energy production systems - Sorption cooling.

Distillation Column – External Balance

1 INTERNATIONAL MARITIME COLLEGE OMAN PROCESS TECHNOLOGY & SYSTEMS (TPTS & PT-TPTS) PE (TPTS & PT-TPTS) (Chapter-3) Chapter - 3 Distillation Systems Textbook.

MASS TRANSFER II DISTILLATION.

12. Heat Exchangers Chemical engineering 170.

Nafa Tech Seminar Phoenix Arizona 2004

Minimum Boiling Point Azeotrope

Presentation transcript:

1 Copyright 2006 OLI Systems, Inc. All Rights reserved The materials displayed here are provided to the lessees, selected individuals and agents of OLI systems, Inc. The material may not be duplicated or otherwise provided to any entity without the expressed permission of OLI Systems, Inc.

2 Part 01

3 The ESP package consists of four main programs. These are: OLI Databook ESP/Process OLI/Toolkit CSP/Stability OLI Programs

4

5

6

7 Model Generation The generation of Chemistry models is an central theme throughout the OLI software. The following is an overview of the necessary steps required to generate a model:

8

9 Unit Operations Unit operations are the core to ESP/Process. The following diagrams illustrate some of the features of each block.

10 Unit Operations

11 Unit Operations Mixer

12 Unit Operations Mixer Up to 7 inlet streams 1 outlet stream Calculations Available Adiabatic Isothermal Bubble point Temperature or Pressure Dew point Temperature or Pressure Vapor rate or fraction

13 Unit Operations Separator

14 Unit Operations Separator Up to 7 inlet streams 4 phase separations may be determined Incomplete separations (entrainment) can be specified for all phases All “Mixer Block” calculations are supported.

15 Unit Operations Absorber

16 Unit Operations Absorber Types Aqueous (standard) Aqueous with Mass Transfer Non-Aqueous Stages Theoretical Maximum = 50 Stage efficiencies (Muphree) may be specified

17 Unit Operations Absorber Mass Transfer coefficients may be specified Maximum of 10 inlet streams Condenser and/or Reboiler may be added Condenser types Total Partial Decanter Pump-arounds

18 Unit Operations Absorber Heat Exchanges on a stage Side Draws Specifications and Controllers Block Reports Composition on a stage Temperature, Pressure, Flowrate, Heat Duty on a stage Scaling Tendencies on a stage

19 Unit Operations Neutralizer

20 Unit Operations Neutralizer Normally used to set a stream pH Reagent stream (pictured at top of block) flowrate is varied to match the Set Point pH. Adiabatic Up to 7 inlet streams (not including the reagent stream) 1 outlet stream Reagent stream can not be from elsewhere in the process.

21 Unit Operations Activated Sludge Bioreactor Simple configuration

22 Unit Operations Activated Sludge Bioreactor Simple configuration Requires bioreaction chemistry model Adiabatic or Isothermal Bioreaction constants are adjustable Block Reports Substrate Utilization Heat Duty (Isothermal) Nutrient Requirements Concentrations Design Warnings

23 Unit Operations Controller (Feed Back)

24 Unit Operations Controller (Feed Back) Determines specified value in target stream Computes the difference between the value and the Set Point Adjusts a block parameter based on the difference. The block is upstream of the controller Possible specified values Temperature Pressure pH Flowrate Composition

25 Unit Operations Manipulate

26 Unit Operations Manipulate Types Flow Component Adjusts the flow or composition by multiplying the flow by a factor: Flow inlet * Factor = Flow outlet The factor is frequently adjusted by a controller

27 Summary In this section we discussed: How a chemistry model is created mathematically The components of the software and the architecture The Unit operations and a brief description of each block.

Part 2

29 Controllers/Recycles Consider the NEUTRAL1 process Mix 1Sep 1 Neut 1 pH 9

30 Controllers/Recycles Neutralizer Blocks may not be suitable if: –To control the pH you must adjust another upstream or downstream block. –The set point may be an impossible case –You need to control something other than pH

31 Looks like this may be a constant pH This may be an impossible pH

32 Solid NaHCO 3 is forming

33

34 You can control –pH –Temperature –Pressure –Flow –Concentration –Oxidation/Reduction Potential Controllers/Recycles

35 Controllers/Recycles Delete the neutralizer Mix 1Sep 1

36 Controllers/Recycles Insert the Manipulator Mix 1Sep 1 Manip

37 Controllers/Recycles Insert the new “Neutralizer” Mix Block Mix 1Sep 1 Manip Neut

38 Controllers/Recycles Add the controller Mix 1Sep 1 Manip Neut

39 Controllers/Recycles Adding the Recycle and additional blocks Mix 1Sep 1 Manip Neut Tear

Part 2

41 Controllers/Recycles Consider the NEUTRAL1 process Mix 1Sep 1 Neut 1 pH 9

42 Controllers/Recycles Neutralizer Blocks may not be suitable if: –To control the pH you must adjust another upstream or downstream block. –The set point may be an impossible case –You need to control something other than pH

43 Looks like this may be a constant pH This may be an impossible pH

44 Solid NaHCO 3 is forming

45

46 You can control –pH –Temperature –Pressure –Flow –Concentration –Oxidation/Reduction Potential Controllers/Recycles

47 Controllers/Recycles Delete the neutralizer Mix 1Sep 1

48 Controllers/Recycles Insert the Manipulator Mix 1Sep 1 Manip

49 Controllers/Recycles Insert the new “Neutralizer” Mix Block Mix 1Sep 1 Manip Neut

50 Controllers/Recycles Add the controller Mix 1Sep 1 Manip Neut

51 Controllers/Recycles Adding the Recycle and additional blocks Mix 1Sep 1 Manip Neut Tear

Part 2

53 Controllers/Recycles Consider the NEUTRAL1 process Mix 1Sep 1 Neut 1 pH 9

54 Controllers/Recycles Neutralizer Blocks may not be suitable if: –To control the pH you must adjust another upstream or downstream block. –The set point may be an impossible case –You need to control something other than pH

55 Looks like this may be a constant pH This may be an impossible pH

56 Solid NaHCO 3 is forming

57

58 You can control –pH –Temperature –Pressure –Flow –Concentration –Oxidation/Reduction Potential Controllers/Recycles

59 Controllers/Recycles Delete the neutralizer Mix 1Sep 1

60 Controllers/Recycles Insert the Manipulator Mix 1Sep 1 Manip

61 Controllers/Recycles Insert the new “Neutralizer” Mix Block Mix 1Sep 1 Manip Neut

62 Controllers/Recycles Add the controller Mix 1Sep 1 Manip Neut

63 Controllers/Recycles Adding the Recycle and additional blocks Mix 1Sep 1 Manip Neut Tear

Part 2

65 Controllers/Recycles Consider the NEUTRAL1 process Mix 1Sep 1 Neut 1 pH 9

66 Controllers/Recycles Neutralizer Blocks may not be suitable if: –To control the pH you must adjust another upstream or downstream block. –The set point may be an impossible case –You need to control something other than pH

67 Looks like this may be a constant pH This may be an impossible pH

68 Solid NaHCO 3 is forming

69

70 You can control –pH –Temperature –Pressure –Flow –Concentration –Oxidation/Reduction Potential Controllers/Recycles

71 Controllers/Recycles Delete the neutralizer Mix 1Sep 1

72 Controllers/Recycles Insert the Manipulator Mix 1Sep 1 Manip

73 Controllers/Recycles Insert the new “Neutralizer” Mix Block Mix 1Sep 1 Manip Neut

74 Controllers/Recycles Add the controller Mix 1Sep 1 Manip Neut

75 Controllers/Recycles Adding the Recycle and additional blocks Mix 1Sep 1 Manip Neut Tear