Lectures related to Batch to Continuous: Reactor Types and Process Optimization

Crystallization in COBRs

Explores the use of COBRs for crystallization processes, comparing batch and continuous reactors, and discussing nucleation mechanisms and growth kinetics.

Chemical Reaction Engineering: Conversion and Reactor Sizing

Explores the algorithm for solving chemical reaction engineering problems, focusing on conversion and reactor sizing.

Chemical reaction engineering: reactor design

Explores the Chemical Reaction Engineering algorithm applied to isothermal reactor design, with examples on SO2 oxidation and N2O4 decomposition.

Multiplying media: Analytical Solutions and Non-leakage Probability

Covers media containing fuel, analytical solutions, and non-leakage probability for thermal and fast neutrons.

Chemical Reaction Engineering: Reactor Design

Explores chemical kinetics, reactor design, and critical thinking in chemical reaction engineering.

Batch vs Continuous Reactors

Compares batch and continuous reactors, focusing on advantages, limitations, and high pressure processing for implementing continuous processing.

Isothermal Reactor Design: Mole Balances

Covers mole balances, reactor volume determination, membrane reactors, semibatch systems, and reversible reactions.

Chemical Reaction Engineering: Algorithm and Stoichiometry

Explores the Chemical Reaction Engineering algorithm in batch reactors and CSTRs, focusing on stoichiometry and rate laws.

Conversion and Reactor Sizing

Explores conversion, reactor sizing, and series reactors with practical examples.

Miniaturization: Impact on Chemical Reactions and Mixing

Covers miniaturization in chemical engineering, focusing on mixing effects on reactions and process efficiency.

Chemical reaction engineering: reactor design

Focuses on isothermal reactor design, covering mole balances, rate laws, stoichiometry, and pressure drop effects.

Reactor Technology: Reactivity Variations and Control

Explores reactivity variations in reactor technology, covering short-term, medium-term, and long-term effects, means of control, and consequences.

Chemical Reaction Engineering: Algorithmic Approach

Explores problem-solving algorithms for chemical reactor design and analysis, emphasizing the CRE approach and various reactor configurations.

Chemical reaction engineering

Explores chemical reaction engineering fundamentals, reactor design, and variable flow rates.

Chemical Reaction Engineering

Covers the analytical derivation of various design models and reactor sizing.

Nuclear Reactor Criticality Analysis

Covers the formalism and criticality analysis of nuclear reactors, focusing on mathematical equations and reactor stability.

Chemical Reaction Engineering: Isothermal Reactor Design

Covers the design of isothermal reactors for chemical reactions, focusing on stoichiometry, rate laws, and concentration as a function of conversion.

Heterogeneous Reactions: Kinetics and Reactors

Covers the analysis of heterogeneous reactions, focusing on kinetics and reactor types.

Chemical Reaction Engineering

Focuses on chemical kinetics, reactor design, and problem-solving skills with interactive modules for active participation.

Nuclear Reactors: Concepts and Analysis

Explores nuclear reactor physics, covering basic principles, specific reactor types, accidents like Chernobyl, and advanced technologies.