Advanced Chemical Reaction Engineering - Prof. Dr. Deniz Üner

Explore advanced concepts in chemical reaction engineering through a comprehensive lecture series. Delve into topics such as conservation laws, reactor design equations, energy balances, complex reactions, non-ideal reactors, chemical kinetics, surface reactions, and heterogeneous catalysis. Learn to analyze and optimize various reactor types, including batch, plug flow, and fluidized bed reactors. Develop skills in problem-solving, mathematical modeling, and process design for industrial applications. Gain insights into the theoretical foundations and practical applications of chemical reaction engineering, from fundamental principles to advanced reactor modeling techniques.

1.1 - Chemical Reaction Engineering.
1.2 - Conservation Laws.
1.3 - Structure of Problem and Its Solution.
1.4 - Time and Length Scales.
1.5 - Start Up of A Well Mixed Reactor.
1.6 - Unsteady State Reactor.
2.1- Setting up the problem through balance equations.
2.2 - Constant Volume, Constant Density Assumptions.
2.3 - Solving the Equations.
2.4 - Design Equations for a Batch Reactor and a Plug Flow Reactor.
2.5 - The Energy Balance.
2.6 - Stoichiometric Table.
2.7 - Energy Balance around a Chemical Reactor.
3.1- Energy Balance around a Batch Reactor.
3.2 - Energy Balances Examples.
3.3 - Example Solutions.
4.1 - BATCH REACTOR CONSTANT PRESSURE.
4.2 - ACCOUNTING FOR VOLUME CHANGE.
4.3 - ACCOUNTING FOR VOLUME CHANGE IN A BATCH REACTOR.
4.4 - PLUG FLOW REACTOR AND BATCH REACTOR ANALOGY.
4.5 - ENERGY BALANCE IN A MIXED FLOW REACTOR.
5 - MULTIPLE STEADY STATES IN CHEMICAL REACTORS.
6 - PROPERTY ESTIMATIONS.
7 - AVERAGE HEAT CAPACITIES.
8.1 - CRE FOR COMPLEX REACTIONS.
8.2 - DESIGN EQUATION FOR A BATCH REACTOR.
8.3 - PERFORMANCE INDICATORS.
8.4 - PERFORMANCE INDICATOR REACTION EXTENT.
8.5 - EXAMPLE: OPTIMUM SPACETIME IN A CSTR (MFR).
9.1 - LIMITS OF IDEAL REACTORS.
9.2 - NON-IDEAL REACTORS.
9.3 - NON-IDEAL REACTORS MICRO-MIXING VS MACRO-MIXING.
9.4 - NON-IDEAL REACTORS: AXIAL DISPERSION IN PFR.
10.1 - THEORY OF CHEMICAL KINETICS.
10.2 - SURFACE REACTIONS.
10.3 - THEORY OF CHEMICAL KINETICS HOMOGENEOUS REACTIONS.
11 - REACTIONS WITH AN INTERFACE.
13.2 - FLUIDIZED BED REACTOR DESIGN FOR HETEROGENEOUS CATALYZED REACTIONS MODELING.
1 - GENERAL INTRODUCTION TO CHEMICAL REACTION ENGINEERING.
2 - GENERAL MOLE BALANCE AND DESIGN EQUATIONS.
3 - TRANSIENT BEHAVIOR IN IDEAL REACTORS.
4 - REACTION HEATS AND HEAT CAPACITIES.
5 - THE ENERGY BALANCE.
6 - THE ENERGY BALANCE AROUND A BATCH REACTOR.
7 - VOLUME CHANGE DUE TO REACTION.
8 - MULTIPLE STEADY STATES IN CHEMICAL REACTORS.
9 - CRE FOR COMPLEX REACTIONS.
10 - CRE FOR COMPLEX REACTIONS EXAMPLE: OPTIMUM SPACE TIME IN A CSTR.
11 - LIMITS OF IDEAL REACTORS.
12 - NON IDEAL REACTORS.
13 - THEORY OF CHEMICAL KINETICS.
14 - REACTION RATES FOR COMPLEX HOMOGENEOUS REACTIONS.
15 - SURFACE REACTIONS.
16 - REACTIONS WITH AN INTERFACE.
17 - FIXED BED REACTOR DESIGN FOR SOLID CATALYZED REACTIONS.
18 - ADIABATIC REACTOR DESIGN FOR THERMODYNAMICALLY LIMITED REACTIONS.
19 - FLUIDIZED BED REACTOR DESIGN FOR HETEROGENEOUS CATALYZED REACTIONS.
20 - FLUIDIZED BED REACTOR MODELS.
A CRE PERSPECTIVE ON HUMAN METABOLISM.