110/16/2015 Applied Physics Lecture 19 Electricity and Magnetism Induced voltages and induction Energy AC circuits and EM waves Resistors in an AC circuits
210/16/2015 Homework Assignment Due next class 19.7,11,33 20.1,7,9,24,28,37
310/16/2015 Inductor in a Circuit Inductance can be interpreted as a measure of opposition to the rate of change in the current Remember resistance R is a measure of opposition to the current Remember resistance R is a measure of opposition to the current As a circuit is completed, the current begins to increase, but the inductor produces an emf that opposes the increasing current Therefore, the current doesn’t change from 0 to its maximum instantaneously Therefore, the current doesn’t change from 0 to its maximum instantaneously Maximum current: Maximum current:
410/16/ Energy stored in a magnetic field The battery in any circuit that contains a coil has to do work to produce a current Similar to the capacitor, any coil (or inductor) would store potential energy Summary of the properties of circuit elements. ResistorCapacitorInductor units ohm, = V / A farad, F = C / Vhenry, H = V s / A symbolRCL relationV = I RQ = C V emf = -L ( I / t) power dissipated P = I V = I² R = V² / R 00 energy stored0PE C = C V² / 2PE L = L I² / 2
510/16/2015 Example: stored energy A 24V battery is connected in series with a resistor and an inductor, where R = 8.0 and L = 4.0H. Find the energy stored in the inductor when the current reaches its maximum value.
610/16/2015 A 24V battery is connected in series with a resistor and an inductor, where R = 8.0 and L = 4.0H. Find the energy stored in the inductor when the current reaches its maximum value. Given: V = 24 V R = 8.0 L = 4.0 H Find: PE L =? Recall that the energy stored in th inductor is The only thing that is unknown in the equation above is current. The maximum value for the current is Inserting this into the above expression for the energy gives
Chapter 21 Alternating Current Circuits and Electromagnetic Waves
810/16/2015 AC Circuit An AC circuit consists of a combination of circuit elements and an AC generator or source The output of an AC generator is sinusoidal and varies with time according to the following equation ΔV = ΔV max sin 2 ƒt ΔV = ΔV max sin 2 ƒt Δv is the instantaneous voltage ΔV max is the maximum voltage of the generator ƒ is the frequency at which the voltage changes, in Hz Same thing about the current (if only a resistor) Same thing about the current (if only a resistor) I = I max sin 2 ƒt I = I max sin 2 ƒt
910/16/2015 Resistor in an AC Circuit Consider a circuit consisting of an AC source and a resistor The graph shows the current through and the voltage across the resistor The current and the voltage reach their maximum values at the same time The current and the voltage are said to be in phase Voltage varies as ΔV = ΔV max sin 2 ƒt Same thing about the current I = I max sin 2 ƒt
1010/16/2015 More About Resistors in an AC Circuit The direction of the current has no effect on the behavior of the resistor The rate at which electrical energy is dissipated in the circuit is given by P = i 2 R = ( I max sin 2 ƒt) 2 R P = i 2 R = ( I max sin 2 ƒt) 2 R where i is the instantaneous current the heating effect produced by an AC current with a maximum value of I max is not the same as that of a DC current of the same value The maximum current occurs for a small amount of time Averaging the above formula over one cycle we get
1110/16/2015 rms Current and Voltage The rms current is the direct current that would dissipate the same amount of energy in a resistor as is actually dissipated by the AC current Alternating voltages can also be discussed in terms of rms values
1210/16/2015 Ohm’s Law in an AC Circuit rms values will be used when discussing AC currents and voltages AC ammeters and voltmeters are designed to read rms values AC ammeters and voltmeters are designed to read rms values Many of the equations will be in the same form as in DC circuits Many of the equations will be in the same form as in DC circuits Ohm’s Law for a resistor, R, in an AC circuit ΔV rms = I rms R ΔV rms = I rms R Also applies to the maximum values of v and i
1310/16/2015 Example: an AC circuit An ac voltage source has an output of V = 150 sin (377 t). Find (a) the rms voltage output, (b) the frequency of the source, and (c) the voltage at t = (1/120)s. (d) Find the maximum current in the circuit when the generator is connected to a 50.0W resistor.
1410/16/2015 Capacitors in an AC Circuit Consider a circuit containing a capacitor and an AC source The current starts out at a large value and charges the plates of the capacitor There is initially no resistance to hinder the flow of the current while the plates are not charged There is initially no resistance to hinder the flow of the current while the plates are not charged As the charge on the plates increases, the voltage across the plates increases and the current flowing in the circuit decreases
1510/16/2015 More About Capacitors in an AC Circuit The current reverses direction The voltage across the plates decreases as the plates lose the charge they had accumulated The voltage across the capacitor lags behind the current by 90°
1610/16/2015 Capacitive Reactance and Ohm’s Law The impeding effect of a capacitor on the current in an AC circuit is called the capacitive reactance and is given by When ƒ is in Hz and C is in F, X C will be in ohms When ƒ is in Hz and C is in F, X C will be in ohms Ohm’s Law for a capacitor in an AC circuit ΔV rms = I rms X C ΔV rms = I rms X C
1710/16/2015 Inductors in an AC Circuit Consider an AC circuit with a source and an inductor The current in the circuit is impeded by the back emf of the inductor The voltage across the inductor always leads the current by 90°
1810/16/2015 Inductive Reactance and Ohm’s Law The effective resistance of a coil in an AC circuit is called its inductive reactance and is given by X L = 2 ƒL X L = 2 ƒL When ƒ is in Hz and L is in H, X L will be in ohms Ohm’s Law for the inductor ΔV rms = I rms X L ΔV rms = I rms X L
1910/16/2015 Example: AC circuit with capacitors and inductors A 2.40mF capacitor is connected across an alternating voltage with an rms value of 9.00V. The rms current in the capacitor is 25.0mA. (a) What is the source frequency? (b) If the capacitor is replaced by an ideal coil with an inductance of 0.160H, what is the rms current in the coil?