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

Upon successful completion of the ICTQual Level 6 Diploma in Chemical Engineering 360 Credits – Three Years, learners will be able to:

Year 1: Foundation of Chemical Engineering

Introduction to Chemical Engineering

• Understand fundamental concepts and scope of chemical engineering.
• Explore roles and career pathways in chemical and process industries.
• Develop problem-solving skills for real-world engineering challenges.
• Gain familiarity with chemical engineering terminology and principles.
• Learn the integration of chemical processes and industrial applications.

Basic Thermodynamics

• Understand laws of thermodynamics and their applications in chemical processes.
• Analyze energy transformations in chemical systems.
• Apply thermodynamic principles to design and optimize processes.
• Develop analytical skills for energy efficiency and process evaluation.
• Use thermodynamics to solve practical engineering problems.

Mathematics for Chemical Engineers

• Apply advanced mathematics to model chemical engineering problems.
• Use calculus, algebra, and differential equations in process analysis.
• Develop quantitative skills for chemical process calculations.
• Support engineering decision-making with precise numerical analysis.
• Integrate mathematical modeling in design and simulation tasks.

Fluid Mechanics

• Analyze fluid properties, flow behavior, and pressure distribution.
• Understand principles of laminar and turbulent flow in pipelines.
• Apply fluid mechanics to process equipment and industrial systems.
• Develop skills in flow measurement and system design.
• Solve practical engineering problems related to liquids and gases.

Material and Energy Balances

• Perform mass and energy balance calculations for chemical processes.
• Understand conservation laws in process design and analysis.
• Apply balances to unit operations and reaction systems.
• Develop problem-solving skills for process optimization.
• Integrate calculations in real-world chemical engineering scenarios.

Introduction to Process Control

• Understand fundamentals of process control and automation.
• Learn basic instrumentation and control strategies.
• Apply control principles to maintain process stability and efficiency.
• Develop skills to troubleshoot and optimize process systems.
• Explore the integration of sensors and actuators in chemical plants.

Chemistry for Chemical Engineers

• Understand chemical reactions, bonding, and molecular structures.
• Apply chemistry concepts to industrial processes and material selection.
• Analyze reaction mechanisms and chemical behavior.
• Support process design with chemical knowledge.
• Gain foundational understanding for advanced engineering modules.

Introduction to Reaction Engineering

• Comprehend chemical reaction kinetics and reactor design principles.
• Analyze different types of reactors and their applications.
• Apply theoretical knowledge to optimize reaction performance.
• Develop problem-solving skills in reaction process design.
• Integrate reaction engineering principles in industrial scenarios.

Engineering Drawing and CAD

• Develop technical drawing skills for chemical engineering designs.
• Learn to create accurate 2D and 3D representations using CAD tools.
• Visualize process equipment and system layouts.
• Apply drawing skills in project design and documentation.
• Enhance communication through precise technical illustrations.

Professional Skills Development

• Build effective communication, teamwork, and leadership skills.
• Understand ethical, safety, and professional standards in engineering.
• Develop project planning and time management abilities.
• Gain workplace readiness for industrial and corporate environments.
• Prepare for professional growth and career advancement in engineering.

Heat and Mass Transfer Fundamentals

• Understand principles of conduction, convection, and radiation.
• Analyze mass transfer processes in chemical engineering systems.
• Apply heat and mass transfer knowledge in unit operations.
• Optimize energy and material usage in industrial processes.
• Solve engineering problems related to process efficiency.

Chemical Engineering Principles

• Integrate knowledge of unit operations, process design, and safety.
• Understand chemical plant operations and process optimization.
• Apply engineering principles to real-world industrial challenges.
• Develop analytical and critical thinking skills.
• Prepare for advanced modules in chemical process engineering.

Year 2: Advanced Chemical Engineering Concepts

Advanced Thermodynamics

• Apply thermodynamic principles to multi-component systems.
• Analyze chemical equilibria and phase behavior.
• Optimize processes for energy efficiency and cost-effectiveness.
• Solve complex thermodynamic problems in industrial applications.
• Integrate advanced theory with practical process design.

Heat Transfer

• Analyze heat exchange in chemical and industrial systems.
• Design and optimize heat exchangers and thermal equipment.
• Apply conduction, convection, and radiation principles to processes.
• Develop skills in thermal problem-solving and energy management.
• Support industrial operations with efficient heat transfer solutions.

Mass Transfer Operations

• Understand absorption, distillation, extraction, and drying processes.
• Design and analyze separation systems for chemical plants.
• Apply mass transfer principles to process optimization.
• Solve practical engineering challenges in material separation.
• Integrate lab and simulation studies for process efficiency.

Chemical Process Design

• Develop skills to design chemical reactors, plants, and systems.
• Apply process simulation and optimization techniques.
• Ensure designs meet safety, environmental, and efficiency standards.
• Integrate theoretical knowledge with practical applications.
• Prepare for project-based and industry-focused assignments.

Industrial Chemistry

• Understand chemical processes in industrial production.
• Analyze materials, reactions, and product formulation.
• Apply industrial chemistry principles in process optimization.
• Explore sustainable and efficient chemical manufacturing methods.
• Gain knowledge relevant to petrochemical, pharmaceutical, and specialty industries.

Process Systems Engineering

• Analyze and optimize integrated chemical process systems.
• Understand system interactions, control strategies, and process flow.
• Apply modeling techniques for industrial process performance.
• Develop problem-solving skills for complex process challenges.
• Integrate multiple unit operations into efficient systems.

Fluid Dynamics and Flow Systems

• Apply advanced fluid dynamics in chemical process design.
• Analyze multiphase flow, turbulence, and pressure drop.
• Design pumps, pipelines, and industrial flow systems.
• Solve practical engineering problems using simulations and calculations.
• Ensure safe and efficient process operations.

Reaction Engineering

• Design and analyze chemical reactors for industrial applications.
• Study kinetics, thermodynamics, and reactor efficiency.
• Optimize reaction conditions for yield, safety, and sustainability.
• Apply computational tools to simulate chemical reactions.
• Integrate reaction engineering in process design projects.

Environmental Engineering

• Analyze environmental impact of chemical processes.
• Apply pollution control, waste management, and sustainability strategies.
• Ensure compliance with environmental regulations and standards.
• Develop sustainable process solutions in industrial operations.
• Promote green engineering practices and eco-friendly design.

Process Control and Automation

• Implement advanced control strategies for chemical processes.
• Use sensors, actuators, and automation tools for process optimization.
• Develop skills in SCADA, PLC, and process monitoring systems.
• Troubleshoot and maintain automated industrial processes.
• Integrate control solutions for safe and efficient plant operations.

Process Modeling and Simulation

• Build computational models of chemical processes.
• Simulate unit operations, reaction kinetics, and system behavior.
• Optimize process performance using simulation results.
• Develop predictive tools for industrial applications.
• Apply modeling techniques in research, design, and industrial projects.

Engineering Materials

• Study properties and applications of metals, polymers, and composites.
• Select materials for chemical process equipment and safety.
• Analyze material behavior under chemical and thermal stresses.
• Integrate materials knowledge in process optimization and design.
• Promote durability, efficiency, and sustainability in chemical systems.

Year 3: Specialization and Industry Application

Advanced Process Control

• Implement advanced strategies for controlling complex chemical processes.
• Optimize production, safety, and energy efficiency.
• Apply predictive and adaptive control methods in industry.
• Troubleshoot and improve control system performance.
• Integrate automation tools with process design.

Process Safety and Risk Management

• Identify hazards and assess risks in chemical plants.
• Implement safety protocols and emergency response procedures.
• Ensure compliance with global safety standards and regulations.
• Analyze case studies to develop safety awareness and decision-making.
• Promote a culture of safety in industrial environments.

Chemical Plant Design

• Design comprehensive chemical production facilities.
• Integrate unit operations, utilities, and safety systems.
• Apply process simulation, optimization, and cost analysis.
• Develop practical skills in plant layout and equipment selection.
• Ensure designs meet environmental and regulatory requirements.

Sustainable Chemical Engineering

• Implement sustainable practices in chemical process design.
• Reduce environmental impact through waste management and energy efficiency.
• Integrate renewable energy and green technologies into processes.
• Develop solutions for sustainable industrial operations.
• Promote ethical and responsible engineering practices.

Separation Technology

• Design and analyze separation processes including distillation, absorption, and extraction.
• Apply theoretical knowledge to optimize industrial separation systems.
• Develop skills in process simulation and laboratory validation.
• Ensure efficiency and cost-effectiveness of separation units.
• Integrate separation technologies into overall process design.

Computational Fluid Dynamics (CFD)

• Apply CFD techniques to simulate fluid flow and heat transfer.
• Optimize process equipment and piping systems using computational models.
• Analyze multiphase flow, turbulence, and reaction systems.
• Solve complex engineering challenges using CFD tools.
• Support design and troubleshooting of industrial processes.

Advanced Materials Science

• Study cutting-edge materials for chemical and process engineering.
• Analyze materials for corrosion resistance, strength, and durability.
• Apply knowledge to design high-performance chemical process equipment.
• Evaluate materials for environmental and operational sustainability.
• Integrate material innovation in industrial applications.

Process Optimization

• Optimize chemical processes for efficiency, cost, and safety.
• Apply lean engineering and continuous improvement principles.
• Use analytical and computational tools for decision-making.
• Develop strategies to maximize production and minimize waste.
• Integrate optimization techniques in real-world industrial operations.

Industrial Placement / Internship

• Gain hands-on experience in chemical and process engineering industries.
• Apply theoretical knowledge in practical, real-world scenarios.
• Develop professional, technical, and workplace skills.
• Build industry networks and career development opportunities.
• Integrate academic learning with industrial practice.

Capstone Project

• Conduct an independent research or design project in chemical engineering.
• Integrate knowledge from all previous modules into a practical solution.
• Develop project management, analytical, and presentation skills.
• Demonstrate innovation and problem-solving in a professional context.
• Prepare a comprehensive report showcasing technical expertise.

Project Management for Chemical Engineers

• Apply project planning, scheduling, and resource management techniques.
• Use project management tools for chemical engineering projects.
• Ensure projects are completed on time, within budget, and to quality standards.
• Develop leadership and teamwork skills in industrial projects.
• Integrate management principles with technical problem-solving.

Biochemical Engineering

• Understand biochemical processes and their industrial applications.
• Apply bioprocess design principles in fermentation, bio-reaction, and downstream processing.
• Integrate chemical and biological engineering techniques.
• Develop skills for pharmaceutical, food, and biotech industries.
• Solve practical engineering challenges in biochemical process systems.