The ICTQual Level 6 Diploma in Chemical Engineering (360 Credits – Three Years) is an advanced qualification designed for learners who aspire to excel in one of the most critical and globally relevant fields of engineering. Whether you are a fresher aiming to establish a solid academic foundation or a professional seeking to enhance your technical expertise and progress in your career, this diploma offers a structured pathway to success.
Over a three-year period, this comprehensive programme equips learners with the knowledge and skills needed to understand and apply chemical engineering principles across industries such as energy, pharmaceuticals, food processing, manufacturing, and environmental management. With its 360-credit structure, the diploma balances theoretical concepts with practical application, ensuring learners can address complex engineering challenges with confidence and innovation.
Learners will gain expertise in areas including chemical process design, thermodynamics, reaction engineering, material science, fluid mechanics, environmental sustainability, and industrial safety. Beyond technical competence, the programme develops problem-solving ability, analytical thinking, and project management skills—qualities that are highly sought after by employers worldwide.
Completing this qualification opens doors to diverse career opportunities in production management, process engineering, quality control, research and development, and environmental protection. It also provides a strong academic platform for further study in specialised engineering disciplines.
With its industry relevance, international recognition, and career-focused outcomes, the ICTQual Level 6 Diploma in Chemical Engineering enables learners to achieve both professional growth and academic excellence, making it an ideal choice for those committed to shaping the future of chemical and process industries.
Inspire College of Technologies UK is Directly Approved Training Centre of ICTQual AB
The ICTQual Level 6 Diploma in Chemical Engineering (360 Credits – Three Years) is a comprehensive qualification designed to equip learners with advanced knowledge, technical expertise, and professional skills essential for thriving in the global chemical engineering industry. This structured three-year programme provides a total of 360 credits, offering an in-depth blend of theoretical learning and practical application that prepares learners to address real-world engineering challenges with confidence.
The curriculum covers a wide spectrum of core and specialised areas, including chemical process design, thermodynamics, fluid mechanics, reaction engineering, material science, environmental sustainability, and industrial safety. Each unit is designed to build progressively, enabling learners to develop a strong understanding of chemical engineering principles while applying innovative approaches to modern industry demands.
This diploma is ideally suited for freshers who want to establish a solid foundation in chemical engineering, as well as professionals already working in the field who wish to enhance their knowledge, strengthen their technical capabilities, and progress into advanced roles. Learners will also benefit from the development of transferable skills such as critical thinking, analytical problem-solving, and project management, which are vital for career growth across diverse engineering sectors.
Upon successful completion, learners will be prepared for career opportunities in industries such as energy, pharmaceuticals, food processing, manufacturing, water treatment, and environmental management. The programme also provides an excellent platform for those who wish to pursue higher-level academic or professional qualifications in specialised areas of chemical engineering.
With its international relevance, robust academic framework, and industry-focused outcomes, the ICTQual Level 6 Diploma in Chemical Engineering offers learners a valuable pathway to long-term professional success.
This qualification, the ICTQual Level 6 Diploma in Chemical Engineering 360 Credits – Three Years, consists of 36 mandatory units.
Year 1: Foundation of Chemical Engineering
- Introduction to Chemical Engineering
- Basic Thermodynamics
- Mathematics for Chemical Engineers
- Fluid Mechanics
- Material and Energy Balances
- Introduction to Process Control
- Chemistry for Chemical Engineers
- Introduction to Reaction Engineering
- Engineering Drawing and CAD
- Professional Skills Development
- Heat and Mass Transfer Fundamentals
- Chemical Engineering Principles
Year 2: Advanced Chemical Engineering Concepts
- Advanced Thermodynamics
- Heat Transfer
- Mass Transfer Operations
- Chemical Process Design
- Industrial Chemistry
- Process Systems Engineering
- Fluid Dynamics and Flow Systems
- Reaction Engineering
- Environmental Engineering
- Process Control and Automation
- Process Modeling and Simulation
- Engineering Materials
Year 3: Specialization and Industry Application
- Advanced Process Control
- Process Safety and Risk Management
- Chemical Plant Design
- Sustainable Chemical Engineering
- Separation Technology
- Computational Fluid Dynamics (CFD)
- Advanced Materials Science
- Process Optimization
- Industrial Placement / Internship
- Capstone Project
- Project Management for Chemical Engineers
- Biochemical Engineering
The ICTQual Level 6 Diploma in Chemical Engineering (360 Credits – Three Years) is designed for learners who are passionate about building a career in chemical engineering and want to develop advanced technical and professional skills. This qualification is suitable for a diverse group of learners, including freshers beginning their academic journey and professionals seeking to enhance their expertise and progress into senior roles across global industries.
It is particularly well-suited for learners who:
- Aspire to establish a strong foundation in chemical process design, reaction engineering, and material science.
- Are professionals working in sectors such as energy, pharmaceuticals, manufacturing, food processing, or environmental management who wish to upgrade their skills.
- Want to gain internationally relevant knowledge in sustainability, industrial safety, and advanced chemical engineering practices.
- Seek to improve their problem-solving, analytical, and project management abilities to take on leadership responsibilities.
- Are motivated to pursue further academic study in specialised fields of chemical or process engineering.
Whether learners are just starting out or aiming to advance their career, this three-year, 360-credit diploma offers a comprehensive route to success. The programme’s industry-focused outcomes ensure that graduates are equipped with the technical competence, innovative thinking, and professional skills needed to make a significant impact in the chemical engineering sector worldwide.
Here are the learning outcomes for each study unit:
Year 1: Foundation of Chemical Engineering
- Introduction to Chemical Engineering
- Understand the scope and importance of chemical engineering in industry
- Identify key principles, processes, and applications of chemical engineering
- Recognise career pathways and opportunities in the chemical engineering sector
- Basic Thermodynamics
- Apply the laws of thermodynamics to chemical processes
- Analyse energy transformations in engineering systems
- Evaluate the role of thermodynamics in industrial operations
- Mathematics for Chemical Engineers
- Apply mathematical tools to solve engineering problems
- Use calculus, algebra, and differential equations in process analysis
- Develop quantitative reasoning for chemical process optimisation
- Fluid Mechanics
- Understand the behaviour of fluids in chemical processes
- Apply fluid flow principles to pipes, pumps, and reactors
- Analyse industrial fluid dynamics for process efficiency
- Material and Energy Balances
- Apply conservation principles to chemical systems
- Perform mass and energy balance calculations in processes
- Evaluate efficiency in chemical plant operations
- Introduction to Process Control
- Understand basic concepts of control systems in engineering
- Apply feedback and control mechanisms to simple processes
- Recognise the role of process control in plant safety and efficiency
- Chemistry for Chemical Engineers
- Apply chemical principles to industrial processes
- Understand reactions, bonding, and material properties
- Relate chemical theory to engineering applications
- Introduction to Reaction Engineering
- Understand fundamentals of chemical reaction kinetics
- Apply rate laws and reactor design principles
- Analyse reaction mechanisms in industrial contexts
- Engineering Drawing and CAD
- Develop skills in technical drawing and computer-aided design
- Apply CAD tools to create chemical engineering diagrams
- Interpret engineering schematics for plant operations
- Professional Skills Development
- Develop effective communication and teamwork skills
- Apply critical thinking and problem-solving in engineering tasks
- Demonstrate professional ethics and workplace readiness
- Heat and Mass Transfer Fundamentals
- Understand the principles of heat and mass transfer
- Apply transfer concepts to exchangers, absorbers, and diffusers
- Analyse industrial operations involving heat and mass flow
- Chemical Engineering Principles
- Integrate core chemical engineering concepts into practice
- Apply scientific and engineering methods to process analysis
- Evaluate the role of chemical engineering in modern industry
Year 2: Advanced Chemical Engineering Concepts
- Advanced Thermodynamics
- Apply advanced thermodynamic principles to industrial systems
- Analyse phase equilibria and thermodynamic properties
- Evaluate thermodynamic cycles in chemical processes
- Heat Transfer
- Understand mechanisms of conduction, convection, and radiation
- Apply heat transfer principles to exchangers and reactors
- Analyse industrial heating and cooling systems
- Mass Transfer Operations
- Apply mass transfer principles to absorption, distillation, and extraction
- Analyse diffusion and separation processes in chemical plants
- Evaluate efficiency in large-scale mass transfer operations
- Chemical Process Design
- Understand the principles of process design in chemical engineering
- Apply design methods to create efficient chemical processes
- Evaluate plant layout, equipment selection, and process flows
- Industrial Chemistry
- Understand large-scale chemical production methods
- Analyse the application of chemistry in manufacturing industries
- Evaluate industrial chemical processes for efficiency and safety
- Process Systems Engineering
- Apply systems thinking to chemical process integration
- Analyse process flowsheets and system optimisation
- Evaluate the performance of complex chemical processes
- Fluid Dynamics and Flow Systems
- Understand advanced fluid flow behaviour in industrial contexts
- Apply principles to design pumps, compressors, and piping systems
- Analyse pressure losses and flow rates in process equipment
- Reaction Engineering
- Apply advanced kinetics to reactor design and optimisation
- Analyse catalytic and non-catalytic reaction systems
- Evaluate industrial reactor performance and scale-up challenges
- Environmental Engineering
- Understand environmental challenges in chemical industries
- Apply pollution control and waste treatment methods
- Evaluate sustainable solutions for industrial processes
- Process Control and Automation
- Understand advanced automation systems in chemical plants
- Apply control strategies to maintain process stability
- Evaluate modern automation technologies for efficiency and safety
- Process Modeling and Simulation
- Develop skills in using simulation software for process analysis
- Apply modelling techniques to optimise plant operations
- Evaluate digital process design for accuracy and reliability
- Engineering Materials
- Understand the properties and applications of engineering materials
- Apply material selection principles to chemical equipment design
- Evaluate durability, corrosion resistance, and performance of materials
Year 3: Specialisation and Industry Application
- Advanced Process Control
- Apply advanced control strategies to complex processes
- Analyse dynamic behaviour in large-scale plants
- Evaluate the role of automation in process safety and efficiency
- Process Safety and Risk Management
- Understand principles of risk analysis and hazard assessment
- Apply safety strategies to prevent accidents in chemical plants
- Evaluate safety management systems and compliance requirements
- Chemical Plant Design
- Apply design principles to complete chemical plant projects
- Analyse equipment sizing, plant layout, and process integration
- Evaluate design alternatives for cost, safety, and efficiency
- Sustainable Chemical Engineering
- Understand sustainability challenges in chemical processes
- Apply green technologies to reduce environmental impact
- Evaluate long-term strategies for sustainable production
- Separation Technology
- Understand separation methods including filtration, distillation, and membranes
- Apply separation technologies in industrial applications
- Evaluate performance and efficiency of separation units
- Computational Fluid Dynamics (CFD)
- Understand CFD principles in chemical engineering
- Apply simulation tools to model fluid flow and heat transfer
- Evaluate CFD analysis for process optimisation and design
- Advanced Materials Science
- Understand advanced material properties for chemical engineering applications
- Apply materials science to high-performance equipment and processes
- Evaluate new material technologies for innovation in industry
- Process Optimization
- Apply optimisation techniques to improve plant efficiency
- Analyse cost, quality, and performance trade-offs in processes
- Evaluate optimisation tools for sustainable operations
- Industrial Placement / Internship
- Gain hands-on experience in real-world chemical engineering environments
- Apply theoretical knowledge to industrial practices
- Develop professional skills and industry connections
- Capstone Project
- Integrate knowledge from across the diploma into a major project
- Apply research, design, and analysis to solve complex engineering problems
- Demonstrate innovation, teamwork, and project execution skills
- Project Management for Chemical Engineers
- Understand project planning, budgeting, and scheduling in engineering projects
- Apply project management tools to chemical industry tasks
- Evaluate project outcomes using performance benchmarks
- Biochemical Engineering
- Understand biochemical processes in industrial applications
- Apply principles of fermentation, enzyme technology, and bio-processing
- Evaluate the role of biochemical engineering in pharmaceuticals and biotechnology
Learners enrolling in the ICTQual Level 6 Diploma in Chemical Engineering (360 Credits – Three Years) will follow a structured pathway designed to ensure progressive academic development, practical skills enhancement, and professional readiness for the global chemical engineering industry.
The qualification is delivered across three years, with a total of 36 mandatory units that collectively amount to 360 credits. Each academic year focuses on specific learning outcomes—beginning with fundamental principles of chemical engineering, moving into advanced concepts, and culminating in specialised applications and industry-focused projects.
Assessment throughout the programme is based on a combination of assignments, projects, case studies, simulations, and practical applications. This ensures that learners not only acquire theoretical knowledge but also demonstrate competence in applying engineering principles to real-world challenges. The inclusion of an Industrial Placement / Internship and a Capstone Project in the final year further strengthens practical understanding and industry engagement.
To be awarded the diploma, learners must successfully complete all mandatory units and meet the assessment criteria across the three-year programme. On successful completion, learners will be formally certified with the ICTQual Level 6 Diploma in Chemical Engineering, a qualification that is internationally recognised and highly valued by employers in sectors such as energy, pharmaceuticals, food processing, water treatment, manufacturing, and environmental management.
This certification route provides learners with both academic progression opportunities and professional advancement, making it an ideal foundation for higher-level studies or career development in the chemical and process engineering sectors.
