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

Innovate, Optimize, and Lead in Process Engineering

ATTICS International is Directly Approved Centre of ICTQual AB

Course Overview

The ICTQual Level 6 Diploma in Chemical Engineering (360 Credits – Three Years) is a comprehensive qualification designed to develop advanced knowledge and practical skills required in modern chemical and process industries. This program provides in-depth training in chemical process design, thermodynamics, fluid mechanics, heat and mass transfer, industrial chemistry, process control, and safety management. By combining scientific principles with engineering applications, the diploma prepares learners to design, operate, and optimize industrial processes across a wide range of sectors.

Over the three-year duration, students gain industry-relevant competencies aligned with international standards and industrial requirements. Graduates develop the ability to improve production efficiency, ensure safety compliance, and implement environmentally responsible processes. This qualification supports career progression into roles such as chemical engineer, process engineer, production supervisor, quality control specialist, or plant operations technician, and also provides a pathway to higher education and professional advancement in the global chemical and process engineering sector.

Course Structure

This is a three-year diploma program designed to build comprehensive Chemical Engineering knowledge and practical skills.

Total Credits: 360
Total Study Units: 36
Credits per Year: 120
Units per Year: 12

Study Units

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

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

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

Learning Outcomes

Learning outcomes are clear statements that describe what a learner is expected to know, understand, and be able to do after completing a course or training program.

They define the specific skills, knowledge, and competencies students will gain and demonstrate upon successful completion.

Year 1: Foundation of Chemical Engineering

Introduction to Chemical Engineering

Understand the fundamental concepts and scope of chemical engineering.
Recognize the role of chemical engineers in industry and society.

Basic Thermodynamics

Apply the laws of thermodynamics to chemical processes.
Analyze energy balances in closed and open systems.

Mathematics for Chemical Engineers

Solve mathematical problems relevant to chemical engineering, including differential equations and linear algebra.
Apply mathematical modeling to engineering systems.

Fluid Mechanics

Understand the behavior of fluids in various engineering systems.
Apply principles of fluid mechanics to solve real-world problems in chemical engineering.

Material and Energy Balances

Apply material and energy balance equations to chemical processes.
Solve complex problems involving multi-phase systems.

Introduction to Process Control

Understand basic concepts of process control.
Apply control strategies to simple chemical processes.

Chemistry for Chemical Engineers

Apply principles of general and organic chemistry to chemical engineering.
Understand chemical reactions and their kinetics in industrial applications.

Introduction to Reaction Engineering

Understand the principles of chemical reaction engineering.
Design and analyze simple chemical reactors.

Engineering Drawing and CAD

Develop technical drawings using engineering drawing standards.
Utilize computer-aided design (CAD) software for process design and visualization.

Professional Skills Development

Develop effective communication and teamwork skills in a professional engineering context.
Demonstrate leadership and problem-solving abilities in group projects.

Heat and Mass Transfer Fundamentals

Apply the principles of heat and mass transfer to chemical processes.
Solve problems involving conduction, convection, and diffusion.

Chemical Engineering Principles

Apply these principles to solve engineering problems.
Understand key chemical engineering principles such as conservation laws and reaction kinetics.

Year 2: Advanced Chemical Engineering Concepts

Advanced Thermodynamics

Apply advanced thermodynamic principles to complex chemical processes.
Solve problems involving non-ideal mixtures and phase equilibria.

Heat Transfer

Analyze and design heat exchange systems.
Apply heat transfer principles to industrial processes.

Mass Transfer Operations

Understand mass transfer operations like distillation, absorption, and filtration.
Apply these operations to industrial processes.

Chemical Process Design

Design chemical processes from the ground up, integrating material, energy, and safety considerations.
Develop process flow diagrams and select appropriate equipment.

Industrial Chemistry

Apply chemical principles to industrial processes and products.
Analyze industrial chemical reactions and their economic implications.

Process Systems Engineering

Apply systems thinking to the design and optimization of chemical processes.
Utilize tools like process simulation and optimization software to enhance performance.

Fluid Dynamics and Flow Systems

Understand the behavior of fluids in both laminar and turbulent flow regimes.
Apply fluid dynamics to the design of pipelines, pumps, and other flow systems.

Reaction Engineering

Design and optimize chemical reactors for industrial-scale applications.
Analyze and solve complex reactor performance problems.

Environmental Engineering

Understand the environmental impact of chemical processes.
Develop strategies to minimize waste and pollution in chemical industries.

Process Control and Automation

Apply control theory to chemical process systems.
Implement automation strategies in industrial chemical processes.

Process Modeling and Simulation

Use modeling and simulation tools to predict the behavior of chemical processes.
Develop dynamic models for process analysis and optimization.

Engineering Materials

Select appropriate materials for specific engineering applications based on their properties.
Understand the properties and applications of materials used in chemical engineering.

Year 3: Specialization and Industry Application

Advanced Process Control

Apply advanced control strategies to optimize complex chemical processes.
Design and implement advanced control systems in industrial settings.

Process Safety and Risk Management

Understand the principles of process safety and risk assessment.
Develop strategies for preventing accidents and managing risks in chemical plants.

Chemical Plant Design

Design and optimize large-scale chemical plants, considering economic, environmental, and safety factors.
Develop detailed engineering designs for chemical plant operations.

Sustainable Chemical Engineering

Apply sustainable engineering principles to reduce the environmental impact of chemical processes.
Develop strategies for improving energy efficiency and waste reduction in chemical industries.

Separation Technology

Understand and apply separation technologies such as filtration, distillation, and membrane processes.
Design separation processes for specific industrial applications.

Computational Fluid Dynamics (CFD)

Apply CFD tools to model and simulate fluid flow in complex chemical systems.
Use CFD for optimization and design of chemical processes.

Advanced Materials Science

Understand the properties and applications of advanced materials in chemical engineering.
Design and select materials for innovative engineering solutions.

Process Optimization

Apply optimization techniques to improve the efficiency and cost-effectiveness of chemical processes.
Use data-driven methods to optimize process performance.

Industrial Placement / Internship

Gain practical experience in the chemical engineering industry.
Apply academic knowledge to solve real-world engineering problems in a professional setting.

Capstone Project

Apply knowledge and skills gained throughout the program to a comprehensive, real-world chemical engineering project.
Demonstrate problem-solving, research, and design abilities in a professional context.

Project Management for Chemical Engineers

Develop project management skills specific to chemical engineering projects.
Plan, execute, and evaluate projects, managing resources, time, and budgets.

Biochemical Engineering

Design and optimize systems for the production of bio-based products and energy.
Apply chemical engineering principles to biological and biochemical processes.

Certification Route

This qualification offers two flexible pathways for certification.

Route 1: New Learners (No Experience)

Enrollment & Training
Learners must enroll with an ICTQual Approved Training Centre and complete all required study units. Training includes both theoretical instruction and practical activities.

Assessment
Learners are required to complete and submit assignments based on the course learning outcomes. These assessments evaluate understanding and the ability to apply chemical engineering concepts in practical situations.

Certification
After successfully completing all assignments and assessments, learners will be awarded the ICTQual Level 6 Diploma in Chemical Engineering (360 Credits – Three Years).

Route 2: Experienced & Competent Candidates

Eligibility
Candidates must have a minimum of 6 years of verified experience in chemical engineering or a related technical field relevant to the qualification.

Competence Assessment
The ICTQual Approved Training Centre will assess the candidate’s existing knowledge and skills to ensure they meet the course learning outcomes.

Evidence Submission
Candidates must submit documented proof of work experience, including job roles, responsibilities, and tasks demonstrating competence in required areas.

Knowledge Verification
Centres will confirm familiarity with all learning outcomes. If gaps are identified, a skills gap assessment or additional learning may be required.

Certification
Upon successful verification of competence and experience, candidates will be awarded the ICTQual Level 6 Diploma in Chemical Engineering (360 Credits – Three Years) without completing the full training program.

Certification Benefits

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

International Recognition – A globally respected qualification that enhances professional credibility and employability.
British Council Verifiable – Confirms authenticity and strengthens international acceptance.
MOFA & Embassy Attestable – Suitable for overseas employment and official documentation requirements.
Supports Iqama & Work Visa Approval – Helps meet employment and residency requirements in Gulf countries.
High-Demand Career Opportunities – Opens doors to roles in chemical processing, oil & gas, petrochemicals, pharmaceuticals, manufacturing, and energy sectors.
Industry-Relevant Skills – Develops expertise in process design, production efficiency, safety management, and industrial operations.
Career Advancement – Supports progression into supervisory, technical, and plant management roles.
Pathway to Higher Education – Enables further studies and specialization in chemical and process engineering.
Focus on Safety & Sustainability – Promotes environmentally responsible processes and industrial safety compliance.
Professional Recognition – Demonstrates competence in chemical engineering and commitment to industry best practices.

This certification strengthens global career prospects while supporting professional growth and industrial excellence.

Course Details

Duration: 4 to 36 Months

Mode: Online and incampus

Assessments: Assignments and work based

Get in Touch

Name

Email*

WhatsApp *

Select Your Course of Intrest*

Please enable JavaScript in your browser to submit the form.kadence-form-2575_9d9a44-1d .kadence-blocks-form-field.kb-submit-field { display: none; }

+92-333-0106324

engineering@atticsintl.com

Course Eligibility

Learners should meet the following entry requirements:

A Level 5 qualification or relevant diploma in chemical engineering, chemistry, or a related technical field is recommended.
Relevant work experience in chemical, manufacturing, or technical fields (preferred but not mandatory).
Ability to communicate in English (reading and speaking)

Course Fee

150k PKR / 450G BP / 600 USD

FAQs

Yes, the diploma is suitable for new learners and also offers a competency-based route for experienced professionals.

Yes, the qualification is internationally recognized and British Council verifiable, enhancing global acceptance.

Yes, it is MOFA and Embassy attestable, making it suitable for international job and legal documentation requirements.

Yes, it supports employment opportunities and documentation requirements such as Iqama and work visa approvals.

Graduates can work as chemical engineers, process engineers, production supervisors, quality control specialists, or plant operations technicians.

Yes, candidates with at least 6 years of relevant experience may qualify through a competency assessment route.