1. The orientation giving the maximum magnetic flux would be 90 degrees or perpendicular to the magnetic field because that gives the maximum amount of magnetic field lines able to pass through the area of the coil. The greater density of field lines gives a greater magnetic field. The orientation that would give a magnetic flux of zero is the plane of the coil to be parallel to the magnetic field, making no lines pass through the coil and thus no flux.
in the same direction as the field
Non-uniform magnetic field and a phase shift of 120 electrical degrees will occur.
The 3-phase currents in the 3 coils of an induction motor will produce a steady rotating magnetic field.
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A uniform magnetic field has constant strength and direction throughout the region. A non-uniform magnetic field varies in strength or direction in different parts of the region. Uniform magnetic fields are simpler to work with mathematically, while non-uniform magnetic fields can lead to more complex behaviors in magnetic materials.
1.maximum torque is experienced 2.torque is uniform for all positions of coil
A uniform magnetic field has the same strength and direction at all points in space. In contrast, a non-uniform magnetic field is one where the strength and/or direction varies from point to point. Uniform magnetic fields are often created in laboratory settings, while non-uniform magnetic fields can occur naturally or in more complex magnetic systems.
A magnet is produced at the atomic level, the atoms that make up magnetic material have a "valence" electron configuration that causes the atom to have a positive and negative pole, these when are placed next to atoms of the same orientation will cause a uniform magnetic field and also the domains line up to make the magnetic field
A uniform magnetic field is a field where the magnetic field strength and direction are consistent throughout the region. This means that the magnetic field lines are parallel and evenly spaced, creating a uniform magnetic force on objects placed within the field. Uniform magnetic fields are often used in scientific experiments and applications due to their predictable behavior.
A uniform magnetic field is a magnetic field that has the same strength and direction at all points in a given region of space. It has constant magnetic flux density and does not vary in magnitude or direction within the specified area. Uniform magnetic fields are often used in scientific experiments and applications to provide consistent and predictable conditions for studying magnetic effects.
If a magnetic needle is placed in a non-uniform magnetic field, it will experience a torque that will tend to align the needle with the field lines. The direction in which the needle aligns will depend on the variation in the magnetic field strength. In regions of stronger field, the needle will align differently compared to regions of weaker field.
Uniform magnetic field is represented by parallel and evenly spaced magnetic field lines that run either from north to south or south to north, without any convergence or divergence.
A uniform magnetic field can be produced using a solenoid by ensuring the solenoid has a tightly wound coil of wire with a constant current flowing through it. The magnetic field inside the solenoid will be parallel and uniform along the central axis of the solenoid. Placing a ferromagnetic core inside the solenoid can help enhance and concentrate the magnetic field.
A uniform magnetic field has the same strength and direction at all points in the space, while a non-uniform magnetic field varies in strength and/or direction. The strength of a magnetic field can be calculated using the formula B = μ0 * I / (2 * π * r), where B is the magnetic field strength, μ0 is the permeability of free space, I is the current, and r is the distance from the current.
A uniform magnetic field can be represented by field lines that are parallel and evenly spaced. Mathematically, it is represented by a vector field where the magnetic field strength (B) is constant in both magnitude and direction throughout the region of interest.
The induced EMF in a coil rotating in a uniform magnetic field depends on the strength of the magnetic field, the number of turns in the coil, the area of the coil, the speed of rotation, and the angle between the magnetic field and the plane of the coil.