Flemings Left Hand Rule

The Engineering Mindset

5 Nov 202202:51

Summary

TLDRThis video explains Fleming's Left-Hand Rule, which helps determine the direction of force in electromagnetic fields. Viewers learn to visualize their left hand in a specific position to denote conventional current, the magnetic field, and the resulting force. The tutorial includes worked examples to clarify how changes in current direction affect the force on a wire and how coils behave under these conditions. The engaging content is supplemented with resources for further learning, encouraging viewers to deepen their understanding of electromagnetic principles.

Takeaways

😀 Fleming's left-hand rule helps determine the direction of force in electromagnetic interactions.
🔋 The rule is based on conventional current, which flows from positive to negative, rather than electron flow.
🖐️ To use Fleming's left-hand rule, extend your left hand with your palm facing you: thumb for force, first finger for magnetic field, and second finger for current direction.
➡️ The second finger indicates the direction of conventional current, while the first finger shows the magnetic field direction from north to south.
👍 The thumb points in the direction of the force acting on the wire due to the magnetic field.
📄 A PDF guide with examples is available in the video description for better understanding.
📊 In an example, if the conventional current moves towards you and the magnetic field goes left to right, the force will move upwards.
🔄 When the current direction reverses, the hand positioning must also change to reflect the new direction of the force.
🌀 A coil can be analyzed as two halves, with each half experiencing opposite forces, leading to rotation.
📺 The video encourages continued learning with more resources available on various social media platforms.

Q & A

What is Fleming's left-hand rule used for?
-Fleming's left-hand rule is used to determine the direction of force acting on a current-carrying conductor in a magnetic field.
What does conventional current refer to?
-Conventional current refers to the flow of positive charge, moving from the positive terminal to the negative terminal of a power source.
How do you position your left hand to apply Fleming's left-hand rule?
-Extend your left hand flat with your palm facing you. Your thumb represents force, your first finger represents the magnetic field direction, and your second finger represents the direction of conventional current.
If the conventional current is flowing towards you, how do you position your fingers?
-You point your second finger towards you, your first finger in the direction of the magnetic field, and your thumb will then point upwards, indicating the direction of force.
What happens when the conventional current is reversed?
-If the conventional current is flowing away from you, you flip your hand so that your second finger points away from you, resulting in your thumb pointing downwards, indicating the force on the wire moves downwards.
How does wrapping the wire into a coil affect the forces acting on it?
-When the wire is wrapped into a coil, each half experiences different forces; the left half will have a downward force while the right half will have an upward force, causing the coil to rotate.
What is the significance of the first finger in Fleming's left-hand rule?
-The first finger represents the direction of the magnetic field, which flows from the north pole to the south pole.
Can you describe the movement of a wire in a magnetic field using Fleming's left-hand rule?
-Using the left-hand rule, the direction of the force on the wire is determined by the orientation of your fingers based on the directions of the magnetic field and conventional current.
What educational resources are available to help with understanding Fleming's left-hand rule?
-The video provides links to a PDF guide that includes worked examples to help learners better understand Fleming's left-hand rule.
Why is it important to distinguish between conventional current and electron flow?
-It is important to distinguish between conventional current and electron flow because conventional current is based on historical conventions of charge flow, while electron flow is the actual movement of electrons, which is in the opposite direction.