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Transcript
AC-1
A transformer is attached to a battery and a resistor as shown. The voltage difference
across the resistor R is ...
V
N
2
N
1
R
iron core
A: V N2/N1
D: zero.
B: V N1/N2
C: V
E: not enough information to answer.
Answer: zero!! It's a trick question! Transformers only work with AC voltages. The
DC voltage V from the battery produces a DC current in the primary coil, but produces
no voltage of any kind in the secondary coil. Transformers work because of Faraday's
Law: the changing flux produced by the AC current in the primary coil produces an emf
in the secondary coil. If the flux is not changing, there is no emf.
AC-2
The primary coil of a transformer is connected to a battery, a resistor, and a switch. The
secondary coil is connected to an ammeter. When the switch is thrown closed, the
ammeter shows..
A: a zero current
B: a non-zero current for a brief instant
C: a steady non-zero current.
A
V
R
iron core
Answer: There is a non-zero current briefly as the switch is closed, but then, after a short
time, there is no current. As the switch is closed, the current in the primary changes from
zero to some non-zero value. While the current is changing, there is a changing B-field
and a changing flux which causes an emf in the secondary and a current flow in the
secondary. (The time period over which the current changes from zero to non-zero as the
switch is closed is L/R where L is the inductance of the primary coil and R is its
resistance.)
AC-3. A step-down transformer is attached to an AC voltage source and a resistor as
shown. How does the current in the resistor IR compare to the current in the drawn from
the AC source Iinput? (With AC circuits, we always use rms values of I and V.)
A) IR > Iin
B) IR < Iin
C) IR = Iin
Iin
IR
D) Depends on the value of Iin
Answer: IR > Iin. For a step-down
transformer, the voltage is stepped down. But power in = power out, so IPVP = ISVS, so
when the voltage is stepped down, the current must be stepped up.
AC-4.
A 600W hairdryer is attached to 120VAC circuit. What is the peak current through the
hairdryer (to within 5%)?
A: 10A
B: 7A
C: 5A
Answer: Power P = IV. This formula works fine with Pavg = Irms Vrms. So Irms =
Pavg/Vrms = 600W/120V = 5 A (rms current). The peak current is (2)1/2 larger than the
rms value. Peak current = (2)1/2 5A is about 7A.
AC-5.
An electrical engineer at a power plant wants to reduce the energy wasted during power
transmission from the plant to the city. The power output Po=IV of the plant is fixed at
100MW. The engineer decides to double voltage V. By what factor does the power lost
in the cable (Plost=I2Rcable) decrease? (Hint: if P=IV is fixed, when V goes up, I goes
down.)
A: No decrease
Rcable
VAC
B: factor of 2 decrease
I
C: factor of 4 decrease
Rcity
D: factor of 8 decrease
Answer: factor of 4 decrease. When V increases by 2, I decreases by 2 (since
P=IV=constant). When I decrease by 2, I2 decreases by a factor of 4, Plost=I2Rcable
decreases by 4.
The formula P = V2/R is not useful in this case. In the formula P=V2/R, V is the voltage
difference across the resistor R. But in this problem the voltage difference across Rcable
is not known.