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Since March 2025
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Mechanical engineering is a broad field that covers various topics related to the design, analysis, and manufacturing of mechanical systems. Here’s a brief overview of the core subjects you would typically study during a mechanical engineering program at university:
Mathematics:
Calculus: For understanding changes in systems, modeling dynamic behavior, and analyzing forces and motions.
Linear Algebra: Used for solving systems of equations, matrix operations, and structural analysis.
Differential Equations: Essential for modeling physical systems that change over time (e.g., motion, heat, fluid flow).
Probability and Statistics: For analyzing data, reliability, and risks in engineering systems.
Physics:
Mechanics: Studying the forces and motion in solid bodies (statics and dynamics).
Thermodynamics: Understanding energy systems, heat transfer, and the conversion of energy between mechanical forms.
Fluid Mechanics: Focuses on the behavior of fluids (liquids and gases) in motion and at rest, which is essential for systems like pumps, engines, and turbines.
Material Science: Exploring the properties of materials and how they behave under various conditions (stress, temperature, etc.).
Statics and Dynamics:
Statics: Study of forces in equilibrium, such as the forces on structures or machines that are not moving.
Dynamics: Study of forces and motion in systems that are in motion, including vibrations, acceleration, and kinematics.
Strength of Materials:
Learning how materials respond to various forces, including stress, strain, bending, and torsion. This is essential for designing durable and safe structures and machines.
Manufacturing Processes:
Understanding different manufacturing techniques like casting, welding, machining, 3D printing, and material forming.
Concepts of production planning, quality control, and design for manufacturability.
Control Systems:
Study of systems that maintain desired outputs (e.g., in robotics or automated systems). This includes understanding feedback loops and stability.
Machine Design:
Focus on designing mechanical components (gears, shafts, bearings) to perform specific tasks reliably and efficiently.
Heat Transfer:
Studying how heat moves through materials and fluids, which is critical for applications like engines, HVAC systems, and electronics cooling.
Dynamics of Machinery:
The study of moving mechanical components, their vibrations, and how to design them to minimize failure and wear.
Computational Methods:
Learning how to use software tools (like CAD, FEM, and CFD) for designing, simulating, and analyzing mechanical systems.
Robotics and Automation:
Study of robotic systems, automation in manufacturing, and how to integrate mechanical components with electronic control systems.
Renewable Energy and Sustainability:
Topics related to sustainable engineering solutions, energy-efficient systems, and the use of renewable energy sources (wind, solar, etc.).
Mathematics:
Calculus: For understanding changes in systems, modeling dynamic behavior, and analyzing forces and motions.
Linear Algebra: Used for solving systems of equations, matrix operations, and structural analysis.
Differential Equations: Essential for modeling physical systems that change over time (e.g., motion, heat, fluid flow).
Probability and Statistics: For analyzing data, reliability, and risks in engineering systems.
Physics:
Mechanics: Studying the forces and motion in solid bodies (statics and dynamics).
Thermodynamics: Understanding energy systems, heat transfer, and the conversion of energy between mechanical forms.
Fluid Mechanics: Focuses on the behavior of fluids (liquids and gases) in motion and at rest, which is essential for systems like pumps, engines, and turbines.
Material Science: Exploring the properties of materials and how they behave under various conditions (stress, temperature, etc.).
Statics and Dynamics:
Statics: Study of forces in equilibrium, such as the forces on structures or machines that are not moving.
Dynamics: Study of forces and motion in systems that are in motion, including vibrations, acceleration, and kinematics.
Strength of Materials:
Learning how materials respond to various forces, including stress, strain, bending, and torsion. This is essential for designing durable and safe structures and machines.
Manufacturing Processes:
Understanding different manufacturing techniques like casting, welding, machining, 3D printing, and material forming.
Concepts of production planning, quality control, and design for manufacturability.
Control Systems:
Study of systems that maintain desired outputs (e.g., in robotics or automated systems). This includes understanding feedback loops and stability.
Machine Design:
Focus on designing mechanical components (gears, shafts, bearings) to perform specific tasks reliably and efficiently.
Heat Transfer:
Studying how heat moves through materials and fluids, which is critical for applications like engines, HVAC systems, and electronics cooling.
Dynamics of Machinery:
The study of moving mechanical components, their vibrations, and how to design them to minimize failure and wear.
Computational Methods:
Learning how to use software tools (like CAD, FEM, and CFD) for designing, simulating, and analyzing mechanical systems.
Robotics and Automation:
Study of robotic systems, automation in manufacturing, and how to integrate mechanical components with electronic control systems.
Renewable Energy and Sustainability:
Topics related to sustainable engineering solutions, energy-efficient systems, and the use of renewable energy sources (wind, solar, etc.).
Location
At student's location :
- Around Castleford, United Kingdom
Online from United Kingdom
About Me
I am a hardworking individual who always strives to do my best in all that I do. I am punctual, adaptable, and flexible.
Skills
Languages:
• Arabic: Native
• English: Very Good
• French: Fair
Computer:
• SolidWorks
• AutoCAD
• Inventor
• MATLAB
• ADAMS
• CFD (ANSYS/Fluent)
Skills
Languages:
• Arabic: Native
• English: Very Good
• French: Fair
Computer:
• SolidWorks
• AutoCAD
• Inventor
• MATLAB
• ADAMS
• CFD (ANSYS/Fluent)
Education
Education
B.Sc. in Mechanical Engineering
Sebha University, Libya (1996-2001)
• General Grade: 69% with honours
• Project: On internal combustion engine
• Project Grade: Excellent
M.Sc. in Applied Engineering
University of Tripoli, Libya (2005-2008)
• General Grade: 3.14 out of 4
• Thesis Title: Modelling and Control of Front Wheel Steering Vehicle Dynamics
• Premaster Courses:
o Finite Element Method
o Modern Control Theory
o Theory of Shell
o Advanced Theory of Elasticity
o Advanced Theory of Plasticity
o Linear and Non-linear Vibration
o Acoustics and Noise Control
B.Sc. in Mechanical Engineering
Sebha University, Libya (1996-2001)
• General Grade: 69% with honours
• Project: On internal combustion engine
• Project Grade: Excellent
M.Sc. in Applied Engineering
University of Tripoli, Libya (2005-2008)
• General Grade: 3.14 out of 4
• Thesis Title: Modelling and Control of Front Wheel Steering Vehicle Dynamics
• Premaster Courses:
o Finite Element Method
o Modern Control Theory
o Theory of Shell
o Advanced Theory of Elasticity
o Advanced Theory of Plasticity
o Linear and Non-linear Vibration
o Acoustics and Noise Control
Experience / Qualifications
Sebha University, Libya 2
• Lecturer in Mechanical Engineering (2008-2012)
3- University of Huddersfield, UK
• PhD Researcher (2014-2018)
o Research on crosswind stability of ground vehicles using wind tunnel, CFD models, and multi-body dynamic techniques.
4- Further Education FE & Higher Education at Colleges
• Lecturer (Short Contract) (Feb 2019 – May 2019) at Darlington college
o Delivered lectures on Engineering fundamentals & principles, Engineering Design, and Pneumatic and Hydraulic systems.
•
• Work at Nissan on COVID time, then
Lecturer (Short Contract) (Feb 2021 – July 2021) at Gateshead college
o Delivered lectures on Engineering fundamentals & principles, Engineering Design, and Pneumatic and Hydraulic systems.
• Mechanical Engineering Lecturer (Feb 2022 – Present)
o Designed and delivered lectures for L2, T-level, BTEC(L3), HNC(L4) and up to L5 mechanical engineering students.
o Worked at New Durham College full academic year (2022-2023).
o Barnsley College(March 2024-July2024).
o Bury college (Sep2024-Present)
5- Nissan Company
• Mechanical Engineer (May 2019 – March 2021, June 2023 – October 2023)
o Worked in the Vehicle Quality Assurance Department.
Central Employment Agency / Adient Seating UK
• Production Department Worker (August 2021 – Feb 2022)
o Worked on the assembly line and performed inspection jobs.
• Lecturer in Mechanical Engineering (2008-2012)
3- University of Huddersfield, UK
• PhD Researcher (2014-2018)
o Research on crosswind stability of ground vehicles using wind tunnel, CFD models, and multi-body dynamic techniques.
4- Further Education FE & Higher Education at Colleges
• Lecturer (Short Contract) (Feb 2019 – May 2019) at Darlington college
o Delivered lectures on Engineering fundamentals & principles, Engineering Design, and Pneumatic and Hydraulic systems.
•
• Work at Nissan on COVID time, then
Lecturer (Short Contract) (Feb 2021 – July 2021) at Gateshead college
o Delivered lectures on Engineering fundamentals & principles, Engineering Design, and Pneumatic and Hydraulic systems.
• Mechanical Engineering Lecturer (Feb 2022 – Present)
o Designed and delivered lectures for L2, T-level, BTEC(L3), HNC(L4) and up to L5 mechanical engineering students.
o Worked at New Durham College full academic year (2022-2023).
o Barnsley College(March 2024-July2024).
o Bury college (Sep2024-Present)
5- Nissan Company
• Mechanical Engineer (May 2019 – March 2021, June 2023 – October 2023)
o Worked in the Vehicle Quality Assurance Department.
Central Employment Agency / Adient Seating UK
• Production Department Worker (August 2021 – Feb 2022)
o Worked on the assembly line and performed inspection jobs.
Age
Children (7-12 years old)
Teenagers (13-17 years old)
Adults (18-64 years old)
Seniors (65+ years old)
Student level
Beginner
Intermediate
Advanced
Duration
60 minutes
The class is taught in
Arabic
English
Availability of a typical week
(GMT -05:00)
New York
Online via webcam
At student's home
Mon
Tue
Wed
Thu
Fri
Sat
Sun
00-04
04-08
08-12
12-16
16-20
20-24
Mechanical engineering is a broad field that covers various topics related to the design, analysis, and manufacturing of mechanical systems. Here’s a brief overview of the core subjects you would typically study during a mechanical engineering program at university:
Mathematics:
Calculus: For understanding changes in systems, modeling dynamic behavior, and analyzing forces and motions.
Linear Algebra: Used for solving systems of equations, matrix operations, and structural analysis.
Differential Equations: Essential for modeling physical systems that change over time (e.g., motion, heat, fluid flow).
Probability and Statistics: For analyzing data, reliability, and risks in engineering systems.
Physics:
Mechanics: Studying the forces and motion in solid bodies (statics and dynamics).
Thermodynamics: Understanding energy systems, heat transfer, and the conversion of energy between mechanical forms.
Fluid Mechanics: Focuses on the behavior of fluids (liquids and gases) in motion and at rest, which is essential for systems like pumps, engines, and turbines.
Material Science: Exploring the properties of materials and how they behave under various conditions (stress, temperature, etc.).
Statics and Dynamics:
Statics: Study of forces in equilibrium, such as the forces on structures or machines that are not moving.
Dynamics: Study of forces and motion in systems that are in motion, including vibrations, acceleration, and kinematics.
Strength of Materials:
Learning how materials respond to various forces, including stress, strain, bending, and torsion. This is essential for designing durable and safe structures and machines.
Manufacturing Processes:
Understanding different manufacturing techniques like casting, welding, machining, 3D printing, and material forming.
Concepts of production planning, quality control, and design for manufacturability.
Control Systems:
Study of systems that maintain desired outputs (e.g., in robotics or automated systems). This includes understanding feedback loops and stability.
Machine Design:
Focus on designing mechanical components (gears, shafts, bearings) to perform specific tasks reliably and efficiently.
Heat Transfer:
Studying how heat moves through materials and fluids, which is critical for applications like engines, HVAC systems, and electronics cooling.
Dynamics of Machinery:
The study of moving mechanical components, their vibrations, and how to design them to minimize failure and wear.
Computational Methods:
Learning how to use software tools (like CAD, FEM, and CFD) for designing, simulating, and analyzing mechanical systems.
Robotics and Automation:
Study of robotic systems, automation in manufacturing, and how to integrate mechanical components with electronic control systems.
Renewable Energy and Sustainability:
Topics related to sustainable engineering solutions, energy-efficient systems, and the use of renewable energy sources (wind, solar, etc.).
Mathematics:
Calculus: For understanding changes in systems, modeling dynamic behavior, and analyzing forces and motions.
Linear Algebra: Used for solving systems of equations, matrix operations, and structural analysis.
Differential Equations: Essential for modeling physical systems that change over time (e.g., motion, heat, fluid flow).
Probability and Statistics: For analyzing data, reliability, and risks in engineering systems.
Physics:
Mechanics: Studying the forces and motion in solid bodies (statics and dynamics).
Thermodynamics: Understanding energy systems, heat transfer, and the conversion of energy between mechanical forms.
Fluid Mechanics: Focuses on the behavior of fluids (liquids and gases) in motion and at rest, which is essential for systems like pumps, engines, and turbines.
Material Science: Exploring the properties of materials and how they behave under various conditions (stress, temperature, etc.).
Statics and Dynamics:
Statics: Study of forces in equilibrium, such as the forces on structures or machines that are not moving.
Dynamics: Study of forces and motion in systems that are in motion, including vibrations, acceleration, and kinematics.
Strength of Materials:
Learning how materials respond to various forces, including stress, strain, bending, and torsion. This is essential for designing durable and safe structures and machines.
Manufacturing Processes:
Understanding different manufacturing techniques like casting, welding, machining, 3D printing, and material forming.
Concepts of production planning, quality control, and design for manufacturability.
Control Systems:
Study of systems that maintain desired outputs (e.g., in robotics or automated systems). This includes understanding feedback loops and stability.
Machine Design:
Focus on designing mechanical components (gears, shafts, bearings) to perform specific tasks reliably and efficiently.
Heat Transfer:
Studying how heat moves through materials and fluids, which is critical for applications like engines, HVAC systems, and electronics cooling.
Dynamics of Machinery:
The study of moving mechanical components, their vibrations, and how to design them to minimize failure and wear.
Computational Methods:
Learning how to use software tools (like CAD, FEM, and CFD) for designing, simulating, and analyzing mechanical systems.
Robotics and Automation:
Study of robotic systems, automation in manufacturing, and how to integrate mechanical components with electronic control systems.
Renewable Energy and Sustainability:
Topics related to sustainable engineering solutions, energy-efficient systems, and the use of renewable energy sources (wind, solar, etc.).
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