ICTQual Level 6 Diploma in Chemical Engineering 360 Credits –Three Years

This diploma provides learners with a structured journey from foundational knowledge to advanced specialization in chemical engineering. Across three years, learners will develop scientific expertise, technical skills, and professional competencies that prepare them to design sustainable processes, manage industrial systems, and contribute effectively to global engineering challenges.

Year 1: Foundation of Chemical Engineering

Introduction to Chemical Engineering

• Understand the fundamental concepts and scope of chemical engineering.
• Explore the role of chemical engineers in industry and society.
• Recognize the importance of chemical engineering in solving global challenges.
• Apply basic engineering principles to chemical processes.

Basic Thermodynamics

• Apply the laws of thermodynamics to chemical processes.
• Analyze energy balances in closed and open systems.
• Understand the relationship between heat, work, and energy in engineering contexts.
• Evaluate thermodynamic efficiency in industrial applications.

Mathematics for Chemical Engineers

• Solve mathematical problems using differential equations and linear algebra.
• Apply mathematical modeling to engineering systems.
• Use probability and statistics in analyzing chemical data.
• Develop quantitative reasoning for process optimization.

Fluid Mechanics

• Understand the behavior of fluids in engineering systems.
• Apply fluid mechanics principles to pipelines, pumps, and reactors.
• Analyze laminar and turbulent flow regimes.
• Solve real-world problems involving fluid transport.

Material and Energy Balances

• Apply material and energy balance equations to chemical processes.
• Solve problems involving multi-phase systems.
• Understand conservation laws in chemical engineering.
• Evaluate efficiency of industrial processes using balance principles.

Introduction to Process Control

• Understand basic concepts of process control.
• Apply control strategies to simple chemical processes.
• Explore feedback and feedforward control systems.
• Recognize the importance of stability in process operations.

Chemistry for Chemical Engineers

• Apply principles of general and organic chemistry to engineering.
• Understand chemical reactions and kinetics in industrial applications.
• Analyze reaction pathways and mechanisms.
• Evaluate chemical properties for process design.

Introduction to Reaction Engineering

• Understand the principles of chemical reaction engineering.
• Design and analyze simple chemical reactors.
• Apply kinetics to reactor performance.
• Evaluate efficiency of different reactor types.

Engineering Drawing and CAD

• Develop technical drawings using engineering standards.
• Utilize CAD software for process design and visualization.
• Apply drafting skills to chemical plant layouts.
• Communicate engineering concepts through visual representation.

Professional Skills Development

• Develop effective communication skills in technical contexts.
• Demonstrate teamwork and collaboration in projects.
• Apply leadership skills in group activities.
• Solve problems using structured approaches.

Heat and Mass Transfer Fundamentals

• Apply principles of heat and mass transfer to chemical processes.
• Solve problems involving conduction, convection, and diffusion.
• Analyze transfer mechanisms in industrial systems.
• Evaluate efficiency of heat and mass transfer operations.

Chemical Engineering Principles

• Understand conservation laws and reaction kinetics.
• Apply principles to solve engineering problems.
• Explore interdisciplinary applications of chemical engineering.
• Evaluate performance of chemical systems.

Year 2: Advanced Chemical Engineering Concepts

Advanced Thermodynamics

• Apply advanced thermodynamic principles to complex processes.
• Solve problems involving non-ideal mixtures and phase equilibria.
• Analyze thermodynamic cycles in industrial applications.
• Evaluate efficiency of advanced energy systems.

Heat Transfer

• Analyze and design heat exchange systems.
• Apply heat transfer principles to industrial processes.
• Evaluate performance of heat exchangers.
• Solve problems involving conduction, convection, and radiation.

Mass Transfer Operations

• Understand operations like distillation, absorption, and filtration.
• Apply mass transfer principles to industrial processes.
• Design separation systems for chemical industries.
• Evaluate efficiency of mass transfer operations.

Chemical Process Design

• Design chemical processes integrating material, energy, and safety.
• Develop process flow diagrams and select equipment.
• Apply optimization techniques to process design.
• Evaluate economic and environmental impacts of processes.

Industrial Chemistry

• Apply chemical principles to industrial processes.
• Analyze industrial reactions and their economic implications.
• Explore large-scale production of chemicals.
• Evaluate sustainability of industrial chemistry practices.

Process Systems Engineering

• Apply systems thinking to chemical process design.
• Use simulation and optimization software.
• Analyze system performance for efficiency.
• Integrate multiple processes into cohesive systems.

Fluid Dynamics and Flow Systems

• Understand fluid behavior in laminar and turbulent regimes.
• Apply fluid dynamics to pipelines, pumps, and reactors.
• Solve flow problems in industrial systems.
• Evaluate efficiency of fluid transport systems.

Reaction Engineering

• Design and optimize industrial-scale reactors.
• Apply kinetics to reactor performance.
• Solve complex reactor problems.
• Evaluate efficiency of different reactor designs.

Environmental Engineering

• Understand environmental impacts of chemical processes.
• Develop strategies to minimize waste and pollution.
• Apply sustainability principles to chemical industries.
• Evaluate compliance with environmental standards.

Process Control and Automation

• Apply control theory to chemical processes.
• Implement automation strategies in industry.
• Analyze system stability and performance.
• Evaluate benefits of automation in chemical plants.

Process Modeling and Simulation

• Use modeling tools to predict process behavior.
• Develop dynamic models for analysis.
• Apply simulation to optimize processes.
• Evaluate accuracy of models in real-world applications.

Engineering Materials

• Understand properties of materials used in chemical engineering.
• Select materials for specific applications.
• Analyze material performance under different conditions.
• Apply advanced materials to innovative solutions.

Year 3: Specialization and Industry Application

Advanced Process Control

• Apply advanced control strategies to optimize processes.
• Design and implement control systems in industry.
• Analyze performance of complex control systems.
• Evaluate benefits of advanced automation.

Process Safety and Risk Management

• Understand principles of process safety.
• Develop strategies to prevent accidents.
• Apply risk assessment models in chemical plants.
• Evaluate effectiveness of safety measures.

Chemical Plant Design

• Design and optimize large-scale chemical plants.
• Develop detailed engineering designs.
• Apply economic, environmental, and safety considerations.
• Evaluate plant performance and sustainability.

Sustainable Chemical Engineering

• Apply sustainable principles to reduce environmental impact.
• Develop strategies for energy efficiency.
• Implement waste reduction practices.
• Evaluate long-term sustainability of chemical processes.

Separation Technology

• Understand separation technologies like distillation and membranes.
• Design separation processes for industry.
• Apply principles to optimize separation systems.
• Evaluate efficiency of separation technologies.

Computational Fluid Dynamics (CFD)

• Apply CFD tools to model fluid flow.
• Simulate complex chemical systems.
• Use CFD for optimization and design.
• Evaluate accuracy of CFD models.

Advanced Materials Science

• Understand properties of advanced materials.
• Design materials for innovative solutions.
• Apply materials to chemical engineering applications.
• Evaluate performance of advanced materials.

Process Optimization

• Apply optimization techniques to improve efficiency.
• Use data-driven methods for process improvement.
• Analyze cost-effectiveness of processes.
• Evaluate performance of optimized systems.

Industrial Placement / Internship

• Gain hands-on experience in industry.
• Apply academic knowledge to real-world problems.
• Develop professional skills in workplace settings.
• Evaluate learning outcomes from practical experience.

Capstone Project

• Apply knowledge to a comprehensive project.
• Demonstrate problem-solving and design skills.
• Conduct research on real-world challenges.
• Present findings professionally.

Project Management for Chemical Engineers

• Develop project management skills for engineering projects.
• Plan, execute, and evaluate projects.
• Manage resources, time, and budgets effectively.
• Apply leadership in project contexts.

Biochemical Engineering

• Apply chemical engineering principles to biological processes.
• Design systems for bio-based products and energy.
• Optimize biochemical production systems.
• Evaluate sustainability of biochemical engineering applications.