· Magnetic fields and forces are extremely useful. The fields can allow energy storage, or transmit forces.
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· Magnetic fields have direction. As a result we must pay special attention to directions, and vector calculations.
· Magnetic fields pass through space.
· resistivity of materials decreases with temperature
· Amperes Circuit Law
· Flux density can be calculated for low H values. As the value climbs the relationship becomes non-linear.
· Permeability,
· Permeability is approximately linear for smaller electric fields, but with larger magnetic fields the materials saturate and the value of B reaches a maximum value.
Figure 23.1 Saturation for a mild steel (approximately)
Figure 23.2 Magnetization curves (Sen, 1989)
· Flux density about a wire
· Flux and flux density,
· When a material is used out of the saturation region the permeabilities may be written as reluctances,
· Electric circuit analogy
· Example,
· Faraday's law,
· Field energy,
· Force can be derived from the energy,
· The basic property of induction is that it will (in the presence of a magnetic field) convert a changing current flowing in a conductor to a force or convert a force to a current flow from a change in the current or the path.
Figure 23.3 The current and force relationship
· We will also experience an induced current caused by a conductor moving in a magnetic field. This is also called emf (Electro-Motive Force)
Figure 23.4 Electromagnetically induced voltage
· Hysteresis
· These systems are very common, take for example a DC motor. The simplest motor has a square conductor loop rotating in a magnetic field. By applying voltage the wires push back against the magnetic field.
Figure 23.5 A motor winding in a magnetic field
Figure 23.6 Calculation of the motor torque
Figure 23.7 Calculation of the motor torque (continued)
· As can be seen in the previous equation, as the loop is rotated a voltage will be generated (a generator), or a given voltage will cause the loop to rotate (motor).
· In this arrangement we have to change the polarity on the coil every 180 deg of rotation. If we didn't do this the loop the torque on the loop would reverse for half the motion. The result would be that the motor would swing back and forth, but not rotate fully. To make the torque push consistently in the same direction we need to reverse the applied voltage for half the cycle. The device that does this is called a commutator. It is basically a split ring with brushes.
· Real motors also have more than a single winding (loop of wire). To add this into the equation we only need to multiply by the number of loops in the winding.
· As with most devices the motor is coupled. This means that one change, say in torque/force will change the velocity and hence the voltage. But a change in voltage will also change the current in the windings, and hence the force, etc.
· Consider a motor that is braked with a constant friction load of Tf.
Figure 23.8 Calculation of the motor torque (continued)
· We still need to relate the voltage and current on the motor. The equivalent circuit for a motor shows the related components.
Figure 23.9 Calculation of the motor torque (continued)
· Practice problem,
Figure 23.10 Drill problem: Electromotive force
· Consider a motor with a separately excited magnetic field (instead of a permanent magnet there is a coil that needs a voltage to create a magnetic field). The model is similar to the previous motor models, but the second coil makes the model highly nonlinear.
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