No. | Title | Format | Download |
1 | Flyers MSc Manufacturing Engineering | [Download] | |
2 | Flyers M Eng Management | [Download] | |
3 | Brochure Tel & Information Eng | [Download] | |
4 | Flyers MSc Robotic Engineering | [Download] | |
5 | Flyers MSc Mechanical Engineering | [Download] | |
6 | Flyers MSc Aviation | [Download] | |
7 | Brochure Civil Eng | [Download] | |
8 | MSc FIE brochure | [Download] |
The Thermofluids (TFS) department is a branch of the School of Mechanical Engineering. The core discipline in TFS is the study on the principles of thermodynamics, heat transfer and fluid transport sciences. Branches in TFS covers the applied areas of combustion engines, thermal and hydro energy systems, HVAC, cooling systems, turbomachinery, tribology and energy sustainability. These areas are offered as courses at degree and postgraduate levels, as well as research topics at PhD level, with emphasis on developing strong capability in traditional and advanced numerical simulation tools to solve actual problems and develop new innovative solutions.
Academic members of TFS are globally recognized as top researchers in the fields of hydrogen fuel cell thermal management, electrolyzer modelling and technoeconomic, low pressure turbo-compounding of engines, thermoelectricity for industrial, waste heat energy recovery, as well as wind engineering for urban cities. The progressive shift from oil and gas towards renewable and clean energy requires TFS to adopt integrated engineering approaches to meet the growing demands for high performance, low pollution and cost-effective energy systems. New areas explored by TFS members include the formulation of nanofluid coolants, nano refrigerants and blended biomass fuels. International and industrial research collaborations are continuously undertaken holistically for projects ranging in scope from experimental characterization and modelling of processes to testing and technoeconomic evaluation of energy systems.
Mechatronics is an interdisciplinary field that combines elements of mechanical engineering, electronics, computer science, and control engineering to design and create intelligent systems and products. The Center of Studies, for Mechatronics is a dedicated administrative entity under School of Mechanical Engineering, UiTM that focuses on advancing the study and research of mechatronics. It plays a pivotal role in establishing and nurturing a thriving mechatronics center where students, school, and industry collaborators can explore, innovate, and develop cutting-edge solutions within the field of mechatronics.
The division collaborates with academic departments to design and update mechatronics programs that encompass the latest industry trends and technological advancements as well as to provide high-quality mechatronics education that equips students with the knowledge and skills needed for successful careers in the field. These programs cater to the diverse needs of students and industry professionals. The division also encourages and supports mechatronics research, both basic and applied, across a spectrum of areas such as robotics, automation, control systems, and IoT. It facilitates research projects, grant applications, and industry partnerships and advisors to ensure that the center’s activities are aligned with the demands of the job market and the development of practical, real-world solutions. On top of that, the division offer practical, hands-on experience through well-equipped laboratories and project-based learning. This can include robotics lab, automation facilities, and prototyping spaces where students can work on mechatronics projects.
In summary, mechatronics in modern engineering education is a forward-thinking and interdisciplinary approach that equips students with the skills and knowledge needed to design and develop intelligent systems, meet industry demands, and contribute to technological advancements. The division is dynamic, evolving with advances in technology and increasing integration of smart systems into our daily lives.
Machine design is a specialized area within mechanical engineering that focuses on the design and analysis of mechanical systems, machines, and components. It involves the creation of safe, efficient, and functional mechanical devices for various applications. Here are some specific details about machine design:
Design Process: The machine design process typically follows a structured approach, starting with defining the problem or project objectives and then proceeding through concept generation, analysis, and detailed design. The process also includes prototyping, testing, and final manufacturing.
Functional Requirements: Machine designers must understand the functional requirements of the system they are designing. This includes identifying the intended purpose, desired performance specifications, and operational constraints.
Material Selection: Selecting appropriate materials for the components is a critical aspect of machine design. Engineers consider factors like strength, weight, cost, and environmental considerations when choosing materials.
Mechanical Components: Machine design often involves selecting and designing various mechanical components, including gears, bearings, shafts, fasteners, couplings, and springs. These components must be chosen and designed to meet specific load, stress, and performance requirements.
Motion Control: Designers must determine the methods for controlling motion within the machine, whether it involves linear or rotary motion. This may include the use of cams, linkages, levers, and other mechanisms.
Kinematics and Dynamics: Machine designers analyze the kinematics (motion characteristics) and dynamics (forces and torques) of the machine to ensure that it operates safely and efficiently.
Strength and Stress Analysis: Stress analysis is a crucial part of machine design to ensure that components can withstand the loads and forces they will experience during operation. Finite element analysis (FEA) is often used for detailed stress analysis.
Safety Considerations: Ensuring the safety of the machine's users and operators is a top priority. Designers must incorporate safety features and mechanisms to prevent accidents and injuries.
Manufacturability: Designers must consider how the machine will be manufactured and assembled. This includes selecting manufacturing processes and techniques that are cost-effective and practical.
Cost Considerations: Machine design often involves cost constraints. Engineers need to balance performance, durability, and other factors with the available budget.
Design Documentation: Proper documentation of the design is essential. This includes detailed drawings, specifications, bills of materials, and assembly instructions to guide the manufacturing process.
Tolerance Analysis: Tolerances are essential in machine design to ensure that components fit and function correctly. Designers must specify appropriate tolerances for parts and assemblies.
Prototyping and Testing: Before final production, prototypes of the machine are often built and tested to validate the design and identify any potential issues or improvements.
Regulatory Compliance: Depending on the application, machines may need to meet specific regulatory and safety standards. Compliance with industry standards and regulations is a critical aspect of machine design.
Sustainability: Machine designers are increasingly considering the environmental impact of their designs, including material choices, energy efficiency, and end-of-life disposal.
Machine design is a dynamic and interdisciplinary field that requires a strong foundation in mechanical engineering principles, creativity, problem-solving skills, and a deep understanding of the specific requirements and constraints of the project. Successful machine designers create solutions that meet performance objectives while considering safety, reliability, and cost-effectiveness.