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Seit März 2025
Lehrer seit März 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.).
Ort
Beim Schüler zu Hause :
- In der Umgebung von Castleford, Vereinigtes Königreich
Online aus Vereinigtes Königreich
Über mich
محترف مجتهد ومتفانٍ يتمتع بخلفية قوية في الهندسة الميكانيكية والتعليم والصناعة. دقيق، متكيف، ومتحفز للغاية لتحقيق التميز في جميع المهام.
مقيم أكاديمي، مراجع أبحاث، وعضو فريق تطوير المناهج لجامعة سبها (عن بُعد).
مقيم أكاديمي، مراجع أبحاث، وعضو فريق تطوير المناهج لجامعة سبها (عن بُعد).
Bildung
دكتوراه في الهندسة الميكانيكيةجامعة هدرسفيلد، المملكة المتحدة (2014-2018)
ماجستير في الهندسة التطبيقيةجامعة طرابلس، ليبيا (2005-2008)
شركة نيسان (مايو 2019 – مارس 2021، يونيو 2023 – أكتوبر 2023)
مهندس ميكانيكي في قسم ضمان جودة المركبات.
ماجستير في الهندسة التطبيقيةجامعة طرابلس، ليبيا (2005-2008)
شركة نيسان (مايو 2019 – مارس 2021، يونيو 2023 – أكتوبر 2023)
مهندس ميكانيكي في قسم ضمان جودة المركبات.
Erfahrung / Qualifikationen
التدريس والمحاضرات
محاضر في الهندسة الميكانيكية (فبراير 2022 – حتى الآن)
تدريس طلاب L2، T-Level، BTEC (L3)، HNC (L4)، و L5 في الهندسة الميكانيكية.
المؤسسات: كلية دورهام الجديدة (2022-2023)، كلية بارنسلي (مارس 2024-يوليو 2024)، كلية بوري (سبتمبر 2024-حتى الآن)
محاضر في التعليم الإضافي والعالي (عقود قصيرة)
كلية دارلينجتون (فبراير 2019 – مايو 2019)
كلية جيتسهيد (فبراير 2021 – يوليو 2021)
تقديم محاضرات حول مبادئ الهندسة، التصميم، الأنظمة الهوائية والهيدروليكية.
المدارس الثانوية (أكتوبر 2023 – حتى الآن)
مدرس احتياطي ومراقب امتحانات لمواد العلوم، الرياضيات، والتكنولوجيا (تصميم هندسي).
محاضر في الهندسة الميكانيكية (فبراير 2022 – حتى الآن)
تدريس طلاب L2، T-Level، BTEC (L3)، HNC (L4)، و L5 في الهندسة الميكانيكية.
المؤسسات: كلية دورهام الجديدة (2022-2023)، كلية بارنسلي (مارس 2024-يوليو 2024)، كلية بوري (سبتمبر 2024-حتى الآن)
محاضر في التعليم الإضافي والعالي (عقود قصيرة)
كلية دارلينجتون (فبراير 2019 – مايو 2019)
كلية جيتسهيد (فبراير 2021 – يوليو 2021)
تقديم محاضرات حول مبادئ الهندسة، التصميم، الأنظمة الهوائية والهيدروليكية.
المدارس الثانوية (أكتوبر 2023 – حتى الآن)
مدرس احتياطي ومراقب امتحانات لمواد العلوم، الرياضيات، والتكنولوجيا (تصميم هندسي).
Alter
Kinder (7-12 Jahre alt)
Jugendliche (13-17 Jahre alt)
Erwachsene (18-64 Jahre alt)
Seniorinnen und Senioren (65+ Jahre alt)
Unterrichtsniveau
Anfänger
Mittel
Fortgeschritten
Dauer
60 Minuten
Unterrichtet in
Arabisch
Englisch
Fachkenntnisse
Verfügbarkeit einer typischen Woche
(GMT -05:00)
New York
Online via Webcam
Beim Schüler zu Hause
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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