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

The future progression of the ICTQual Level 6 Diploma in Chemical Engineering 360 Credits – Three Years can lead learners towards several pathways, depending on their career goals and aspirations in the field of law and related sectors. Here are some potential avenues of progression:

Year 1: Foundations of Chemical Engineering

1. Introduction to Chemical Engineering
   • Understand the role and scope of chemical engineering in industry.
   • Recognize the fundamental principles of chemical processes and engineering practice.
2. Basic Thermodynamics
   • Comprehend the laws of thermodynamics and their applications to chemical engineering.
   • Solve problems involving energy balances and thermodynamic cycles relevant to chemical processes.
3. Mathematics for Chemical Engineers
   • Apply mathematical methods, such as calculus and differential equations, to solve engineering problems.
   • Use numerical methods for process modeling and simulation.
4. Fluid Mechanics
   • Understand the principles of fluid behavior, flow dynamics, and how fluids interact in chemical processes.
   • Analyze and solve fluid flow problems using relevant equations and techniques.
5. Material and Energy Balances
   • Conduct material and energy balance calculations for simple and complex chemical systems.
   • Apply conservation principles to solve engineering problems in chemical processes.
6. Introduction to Process Control
   • Understand the basic principles of process control systems and their applications.
   • Apply control theory to maintain stability and performance in chemical processes.
7. Chemistry for Chemical Engineers
   • Understand the fundamentals of chemistry, including reaction mechanisms, stoichiometry, and chemical equilibrium.
   • Apply chemical principles to solve engineering problems in the chemical process industries.
8. Introduction to Reaction Engineering
   • Study the kinetics of chemical reactions and understand the design of chemical reactors.
   • Analyze simple reaction systems and calculate reaction rates.
9. Engineering Drawing and CAD
   • Develop skills in engineering drawing techniques and computer-aided design (CAD) tools.
   • Create accurate technical drawings and models of chemical engineering systems.
10. Professional Skills Development

• Build skills in communication, teamwork, and problem-solving essential for chemical engineers.
• Develop an understanding of professional and ethical responsibilities in engineering practice.

11. Heat and Mass Transfer Fundamentals

• Understand the principles of heat and mass transfer in chemical processes.
• Apply these principles to solve real-world engineering problems such as heat exchangers and distillation columns.

12. Chemical Engineering Principles

• Integrate fundamental chemical engineering principles to analyze and design chemical processes.
• Apply concepts such as stoichiometry, thermodynamics, and transport phenomena in process analysis.

Year 2: Advanced Chemical Engineering Concepts

1. Advanced Thermodynamics
   • Apply advanced thermodynamic cycles and processes to complex chemical systems.
   • Analyze phase equilibria, chemical reaction equilibria, and non-ideal systems.
2. Heat Transfer
   • Understand advanced heat transfer methods, including conduction, convection, and radiation.
   • Design heat transfer equipment and optimize heat exchangers.
3. Mass Transfer Operations
   • Master mass transfer processes such as distillation, absorption, and filtration.
   • Analyze and design separation equipment based on mass transfer principles.
4. Chemical Process Design
   • Apply chemical engineering principles to the design of chemical processes and systems.
   • Design process flowsheets, select materials, and optimize the performance of chemical processes.
5. Industrial Chemistry
   • Understand the application of chemical principles in industrial settings, focusing on the production of chemicals, polymers, and pharmaceuticals.
   • Apply industrial chemistry techniques to scale-up laboratory processes for commercial production.
6. Process Systems Engineering
   • Apply systems engineering techniques to model, design, and optimize large-scale chemical processes.
   • Use process simulation software to optimize system performance and efficiency.
7. Fluid Dynamics and Flow Systems
   • Study advanced fluid dynamics, including turbulent and laminar flows, and apply this knowledge to chemical processing.
   • Design and analyze piping systems, pumps, and flow meters.
8. Reaction Engineering
   • Study more complex chemical reaction systems, including heterogeneous reactions and catalytic processes.
   • Apply reaction engineering principles to design and optimize reactors for industrial processes.
9. Environmental Engineering
   • Understand the impact of chemical processes on the environment and develop sustainable solutions to reduce pollution.
   • Design processes that minimize waste, conserve energy, and comply with environmental regulations.
10. Process Control and Automation

• Master advanced process control techniques, including PID control, supervisory control, and automation systems.
• Design and implement automated control systems to enhance the performance of chemical plants.

11. Process Modeling and Simulation

• Use process modeling and simulation software to predict system behavior under different operating conditions.
• Develop dynamic models of chemical processes for optimization and troubleshooting.

12. Engineering Materials

• Study materials used in chemical engineering applications, including metals, polymers, and ceramics.
• Analyze the properties and behavior of materials in various chemical processes.

Year 3: Specialization and Industry Application

1. Advanced Process Control
   • Master advanced control strategies for complex chemical systems, including multi-loop control and advanced process diagnostics.
   • Design control strategies that optimize plant efficiency, safety, and reliability.
2. Process Safety and Risk Management
   • Understand the principles of process safety management, hazard analysis, and risk assessment.
   • Develop strategies to mitigate safety risks and ensure compliance with industry standards.
3. Chemical Plant Design
   • Apply engineering principles to design a complete chemical plant, including process flow design, equipment selection, and site planning.
   • Conduct economic feasibility studies and consider environmental impacts in plant design.
4. Sustainable Chemical Engineering
   • Understand the role of chemical engineering in promoting sustainability, including renewable energy, waste minimization, and resource efficiency.
   • Develop sustainable processes that reduce environmental footprints and improve energy efficiency.
5. Separation Technology
   • Study advanced separation processes such as membrane filtration, centrifugation, and adsorption.
   • Design and optimize separation systems to enhance product yield and purity.
6. Computational Fluid Dynamics (CFD)
   • Master CFD techniques to model fluid flow, heat transfer, and mass transfer in complex chemical systems.
   • Apply CFD simulations to optimize the design and operation of chemical engineering systems.
7. Advanced Materials Science
   • Study the properties of advanced materials used in chemical engineering, including nanomaterials, composites, and biomaterials.
   • Analyze the performance and selection of materials for specific chemical engineering applications.
8. Process Optimization
   • Use optimization techniques to improve the efficiency and performance of chemical processes.
   • Apply mathematical modeling, statistical analysis, and simulation to optimize production processes.
9. Industrial Placement / Internship
   • Gain practical experience in the chemical engineering field by working on real-world projects in industry.
   • Apply theoretical knowledge to solve practical problems and develop industry-specific skills.
10. Capstone Project

• Undertake a comprehensive research project that integrates all aspects of chemical engineering.
• Develop a solution to a real-world problem, demonstrating your ability to innovate and apply engineering principles effectively.

11. Project Management for Chemical Engineers

• Develop project management skills essential for chemical engineering projects, including planning, budgeting, scheduling, and team coordination.
• Learn to manage resources, risks, and deadlines in large-scale engineering projects.

12. Biochemical Engineering

• Study the application of chemical engineering principles in the biotechnology and pharmaceutical industries.
• Design processes for the production of biological products, including pharmaceuticals, biofuels, and enzymes.