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Problemas del Laboratorio N°1 de Física II
1. Chapter 27. Current and Resistance Physics, 6th Edition
Chapter 27. Current and Resistance
Electric Current and Ohm’s Law
27-1. How many electrons pass a point every second in a wire carrying a current of 20 A?
How much time is needed to transport 40 C of charge past this point?
C 1e
Q = It = (20 C/s)(1 s); Q = 20 -19 ; Q = 1.25 x 1020 electrons/s
s 1.6 x 10 C
Q Q 40 C
I= ; t= = = 2.00 s ; t = 2.00 s
t I 20 A
27-2. If 600 C of charge pass a given point in 3 s, what is the electric current in amperes?
Q 600 C
I= = ; I = 20 A
t 3s
27-3. Find the current in amperes when 690 C of charge pass a given point in 2 min.
Q 690 C
I= = ; I = 5.75 A
t 120 s
27-4. If a current of 24 A exists for 50 s, how many coulombs of charge have passed through
the wire?
Q = It = (24 A)(50 s); Q = 1200 C
27-5. What is the potential drop across a 4-Ω resistor with a current of 8 A passing through it?
V = IR = (8 A)(4 Ω); V = 32.0 V
27-6. Find the resistance of a rheostat if the drop in potential is 48 V and the current is 4 A.
V 48 V
R= = ; R = 12.0 Ω
I 4A
119
2. Chapter 27. Current and Resistance Physics, 6th Edition
27-7. Determine the current through a 5-Ω resistor that has a 40-V drop in potential across it?
V 40 V
I= = ; I = 8.00 A
R 5Ω
27-8. A 2-A fuse is placed in a circuit with a battery having a terminal voltage of 12 V. What is
the minimum resistance for a circuit containing this fuse?
V 12 V
R= = ; R = 6.00 Ω
I 2A
7-9. What emf is required to pass 60 mA through a resistance of 20 kΩ? If this same emf is
applied to a resistance of 300 Ω, what will be the new current?
E = IR = 60 x 10-3 A)(20 x 103 Ω); E = 1200 V
E 1200 V
I= = ; I = 4.00 A
R 300 Ω
Electric Power and Heat Loss
27-10. A soldering iron draws 0.75 A at 120 V. How much energy will it use in 15 min?
P = IV = (0.75 A)(120 V); P = 90.0 W; t = 15 min = 900 s
Work
P= ; Energy = Pt = (90 W)(900 s) ; E = 81,000 J
t
27-11. An electric lamp has an 80-Ω filament connected to a 110-V direct-current line. What is
the current through the filament? What is the power loss in watts?
V 110 V
I= = ; I = 1.38 A
R 80 Ω
V 2 (110 V) 2
P= = ; P = 151 W
R 80 Ω
120
3. Chapter 27. Current and Resistance Physics, 6th Edition
27-12. Assume that the cost of energy in a home is 8 cents per kilowatt-hour. A family goes on
a 2-week vacation leaving a single 80-W light bulb burning. What is the cost?
E = Pt = (80 W)(2 wk)(7 day/wk)(24 h/day)(3600 s/h) = 26.9 kW h
E = (26.9 kW h)(0.08 c/kw h) = $2.15 (Rates vary)
27-13. A 120-V, direct-current generator delivers 2.4 kW to an electric furnace. What current is
supplied? What is the resistance?
P 2400W V 120 V
I= = ; I = 20 A; R= = ; R = 6.00 Ω
V 120 V I 20 A
27-14. A resistor develops heat at the rate of 250 W when the potential difference across its ends
is 120 V. What is its resistance?
V2 V 2 (120 V) 2
P= ; R= = R = 57.6 Ω
R P 250 W;
27-15. A 120-V motor draws a current of 4.0 A. How many joules of electrical energy is used in
one hour? How many kilowatt-hours?
P = VI = (120 V)(4.0 A) = 480 W
E
P= ; E = Pt = (480 W)(3600 s); E = 1.73 MJ
t
1 kW ⋅ h
E = 1.73 x 106 J 6 E = 0.480 kW h
3.60 x 10 J
27-16. A household hair dryer is rated at 2000 W and is designed to operate on a 120-V outlet.
What is the resistance of the device?
V2 V 2 (120 V) 2
P= ; R= = ; R = 7.20 Ω
R P 2000 W
121
4. Chapter 27. Current and Resistance Physics, 6th Edition
Resistivity
27-17. What length of copper wire 1/16 in. in diameter is required to construct a 20-Ω resistor at
200C? What length of nichrome wire is needed?
Copper: ρ = 1.78 x 10-8 Ω m ; nichrome: ρ = 100 x 10-8 Ω m
1
16 ft = 0.0625 in. = 62.5 mil; A = (62.5 mil) 2 = 3906 cmil
ρl RA (20 Ω)(3906 cmil)
R= ; l= = ; l = 7510 ft
A ρ 10.4 Ω ⋅ cmil/ft
ρl RA (20 Ω)(3906 cmil)
R= ; l= = ; l = 130 ft
A ρ 600 Ω ⋅ cmil/ft
27-18. A 3.0-m length of copper wire (ρ = 1.78 x 10-8 Ω m) at 200C has a cross section of 4
mm2.What is the electrical resistance of this wire? [ A = 4 mm2 = 4 x 10-6 m2 ]
ρ l (1.72 x 10-8Ω ⋅ m)(3.0 m)
R= = ; R =12.9 mΩ
A 4.00 x 10-6 m 2
27-19. Find the resistance of 40 m of tungsten (ρ = 5.5 x 10-8 Ω m) wire having a diameter of 0.8
mm at 200C?
π D 2 π (0.0008 m) 2
A= = ; A = 5.03 x 10-7 m2
4 4
ρ l (5.5 x 10-8Ω ⋅ m)(40.0 m)
R= = ; R = 4.37 Ω
A 5.03 x 10-7 m 2
27-20. A certain wire has a diameter of 3 mm and a length of 150 m. It has a resistance of
3.00 Ω at 200C. What is the resistivity? [ A = πD2/4 = 7.07 x 10-7 m2. ]
ρl RA (3 Ω)(7.07 x 10-7 m 2 )
R= ; ρ= = ; ρ = 1.41 x 10-8 Ω m
A l 150 m
122
5. Chapter 27. Current and Resistance Physics, 6th Edition
27-21. What is the resistance of 200 ft of iron (ρ = 9.5 x 10-8 Ω m) wire with a diameter of 0.002
in. at 200C? (ρ = 9.5 x 10-8 Ω m). [ 200 ft = 61.0 m; 0.002 in. = 5.08 x 10-5 m ]
π D 2 π (5.08 x 10-5 m) 2
A= = ; A = 2.03 x 10-9 m2
4 4
ρ l (9.5 x 10-8Ω ⋅ m)(61.0 m)
R= = ; R = 2860 Ω
A 5.08 x 10-5 m 2
*27-22. A nichrome wire (ρ = 100 x 10-8 Ω m) has a length of 40 m at 200C What is the diameter
if the total resistance is 5 Ω?
ρl ρ l (100 x 10-8Ω ⋅ m)(40 m)
R= ; A= = ; A = 8 x 10-6 m2
A R 5.00 Ω
π D2 4A 2(8 x 10-6 m 2 )
A= ; D= = ; D = 2.26 mm
4 π π
*27-23. A 115-V source of emf is attached to a heating element which is a coil of nichrome wire
(ρ = 100 x 10-8 Ω m ) of cross section 1.20 mm2 What must be the length of the wire if
the resistive power loss is to be 800 W? [A = 1.20 mm2 = 1.20 x 10-6 m2 ]
V2 V 2 (115 V) 2
P= ; R= = = 16.5 Ω ; R = 16.5 Ω
R P 800 W
ρl RA (16.5 Ω)(1.20 x 10-6 m 2 )
R= ; l= = ; l = 19.8 m
A ρ 100 x 10-8 Ω ⋅ m
Temperature Coefficient of Resistance
27-24. The resistance of a length of wire (α = 0.0065/C0) is 4.00 Ω at 200C. What is the
resistance at 800C? [ ∆t = 800C – 200C = 60 C0 ]
∆R = α Ro ∆t = (0.0065 / C0 )(4 Ω)(60 C0 ) = 1.56 Ω ; R = 4.00 Ω + 1.56 Ω = 5.56 Ω
123
6. Chapter 27. Current and Resistance Physics, 6th Edition
27-25. If the resistance of a conductor is 100 Ω at 200C, and 116 Ω at 600C, what is its
temperature coefficient of resistivity? [ ∆t = 600C – 200C = 40 C0 ]
∆R 116 Ω - 100 Ω
α= = ; α = 0.00400 /C0
R0 ∆t (100 Ω)(40 C0 )
27-26. A length of copper (α = 0.0043/C0) wire has a resistance of 8 Ω at 200C. What is the
resistance at 900C? At - 300C?
∆R = (0.0043 / C0 )(8 Ω)(70 C0 ) = 2.41 Ω ; R = 8.00 Ω + 2.41 Ω = 10.41 Ω
∆R = (0.0043 / C0 )(8 Ω)(-300 C − 200 C) = −1.72 Ω ; R = 8.00 Ω - 1.72 Ω = 6.28 Ω
*27-27. The copper windings (α = 0.0043/C0) of a motor experience a 20 percent increase in
resistance over their value at 200C. What is the operating temperature?
∆R ∆R 0.2
= 0.2; ∆t = = = 46.5 C0 ; t = 200C + 46.5 C0 = 66.5 0C
R R0α 0.0043 / C 0
*27-28. The resistivity of copper at 200C is 1.78 x 10-8 Ω m. What change in temperature will
produce a 25 percent increase in resistivity?
Challenge Problems
27-29. A water turbine delivers 2000 kW to an electric generator which is 80 percent efficient
and has an output terminal voltage of 1200 V. What current is delivered and what is the
electrical resistance? [ Pout = (0.80)(2000 kW) = 1600 kW ]
P 1600 x 103 W
P = VI ; I= = ; I = 1330 A
V 1200 V
V 1200 V
R= = ; R = 0.900 Ω
I 1300 A
124
7. Chapter 27. Current and Resistance Physics, 6th Edition
27-30. A 110-V radiant heater draws a current of 6.0 A. How much heat energy in joules is
delivered in one hour?
E
P= = VI ; E = VIt = (110 V)(6 A)(3600 s); E = 2.38 MJ
t
27-31. A power line has a total resistance of 4 kΩ. What is the power loss through the wire if the
current is reduced to 6.0 mA?
P = I 2 R = (0.006 A) 2 (4000 Ω); P =144 mW
27-32. A certain wire has a resistivity of 2 x 10-8 Ω m at 200C. If its length is 200 m and its cross
section is 4 mm2, what will be its electrical resistance at 1000C. Assume that α = 0.005/C0
for this material. [ ∆t = 1000C – 200C = 80 C0 ]
ρ l (2 x 10-8Ω ⋅ m)(200 m)
R0 = = -6 2
; R0 = 1.00 Ω at 200C
A 4 x 10 m
R = R0 + α R0 ∆t = 1.00 Ω + (0.005 / C0 )(1 Ω)(80 C0 ); R = 1.40 Ω
27-33. Determine the resistivity of a wire made of an unknown alloy if its diameter is 0.007 in.
and 100 ft of the wire is found to have a resistance of 4.0 Ω. [ D = 0.007 in. = 7 mil ]
ρl RA
A = (7 mil)2 = 49 cmil; R= ; ρ=
A l
RA (4 Ω)(49 cmil)
∆= = ; ρ = 1.96 Ω cmil/ft
l 100 ft
27-34. The resistivity of a certain wire is 1.72 x 10-8 Ω m at 200C. A 6-V battery is connected to
a 20-m coil of this wire having a diameter of 0.8 mm. What is the current in the wire?
π D 2 π (0.0008 m) 2 ρl
A= = = 5.03 x 10-7 m 2 ; R=
4 4 A
125
8. Chapter 27. Current and Resistance Physics, 6th Edition
ρ l (1.72 x 10-8Ω ⋅ m)(20 m)
27-34. (Cont.) R= = ; R = 0.684 Ω
A 5.03 x 10-7 m 2
V 6.00 V
I= = ; I = 8.77 A
R 0.684 Ω
27-35. A certain resistor is used as a thermometer. Its resistance at 200C is 26.00 Ω, and its
resistance at 400C is 26.20 Ω. What is the temperature coefficient of resistance for this
material?
∆R (26.20 Ω - 26.00 Ω)
α= = ; α = 3.85 x 10-4/C0
R0 ∆t (26.00 Ω)(400 C - 200 C)
*27-36. What length of copper wire at 200C has the same resistance as 200 m of iron wire at
200C? Assume the same cross section for each wire. [ Product RA doesn’t change. ]
ρl ρ1l1
R= ; RA = ρ l ; ρ1R1 = ρ2l2; l2 =
A ρ2
ρ1l1 (9.5 x10−8 Ω ⋅ m)(200 m)
l2 = = ; l2 = 1100 m
ρ2 1.72 x 10-8Ω ⋅ m
*27-37. The power loss in a certain wire at 200C is 400 W. If α = 0.0036/C0, by what percentage
will the power loss increase when the operating temperature is 680C?
∆R
∆R = α R0 ∆t ; = (0.0036 / C0 )(680 C - 200 C) = 0.173
R
Since P = I2R, the power loss increases by same percentage: 17.3 %
126
9. Chapter 27. Current and Resistance Physics, 6th Edition
Critical Thinking Problems
27-38. A 150-Ω resistor at 200C is rated at 2.0 W maximum power. What is the maximum
voltage that can be applied across the resistor with exceeding the maximum allowable
power? What is the current at this voltage?
V2
P= ; V = PR = (2.00 W)(150 Ω); V = 17.3 V
R
27-39. The current in a home is alternating current, but the same formulas apply. Suppose a fan
motor operating a home cooling system is rated at 10 A for a 120-V line. How much
energy is required to operate the fan for a 24-h period? At a cost of 9 cents per kilowatt-
hour, what is the cost of operating this fan continuously for 30 days?
P = VI = (110 V)((10 A) = 1100 W; E = Pt = (1100 W)(24 h) = 26.4 kW h
E = (26.4 kW h)(3600 s/h)(1000 W/kW); E = 95.0 MJ
kW ⋅ h $0.08
Cost = 26.4 (30 days); Cost = $53.36
day kW ⋅ h
*27-40. The power consumed in an electrical wire (α= 0.004/C0) is 40 W at 200C. If all other
factors are held constant, what is the power consumption when (a) the length is doubled,
(b) the diameter is doubled, (c) the resistivity is doubled, and (d) the absolute
temperature is doubled? (Power loss is proportional to resistance R)
ρl 1
R= ; P ∝ l; P ∝ ; P ∝ ∆R ∝ ∆T
A A
(a) Double length and double power loss; Loss = 2(40 W) = 80 W
(b) doubling diameter gives 4A0 and one-fourth power loss: Loss = ¼(40 W) = 10 W
(c) Doubling resistivity doubles resistance, and also doubles power loss: Loss = 80 W
127
10. Chapter 27. Current and Resistance Physics, 6th Edition
*27-40. (Cont.) (d) T = (200 + 2730) = 293 K; ∆T = 2T – T = T; ∆T = 293 K = 293 C0
If absolute temperature doubles, the new resistance is given by:
R
R = R0 (1 + α∆T ); = 1 + (0.004 / C0 )(293 C0 ) = 2.172;
R0
P R
= = 2.172; Loss = 2.172(40 W); Loss = 86.9 W
P0 R 0
This of course presumes that resistivity remains linear, which is not likely.
*27-41. What must be the diameter of an aluminum wire if it is to have the same resistance as an
equal length of copper wire of diameter 2.0 mm? What length of nichrome wire is
needed to have the same resistance as 2 m of iron wire of the same cross section?
ρl R ρ ρc ρa π D2 ρc ρa
R= ; = = const.; = ; A= ; 2
=
A l A Ac Aa 4 ( Dc ) ( Dc ) 2
ρ a Dc2 ρc 1.72 x 10-8Ω ⋅ m
Da =
2
; Da = Dc = (2 mm) ; Da = 1.57 mm
ρc ρa 2.80 x 10-8Ω ⋅ m
ρl ρi li
R= ; RA = ρ l = const.; ρ nln = ρi li ; ln =
A ρn
ρi li (1.72 x 10-8Ω ⋅ m)
ln = = ; ln = 1.72 cm
ρn (100 x 10-8Ω ⋅ m)
*27-42. An iron wire (α = 0.0065/C0) has a resistance of 6.00 Ω at 200C and a copper wire (α =
0.0043/C0) has a resistance of 5.40 Ω at 200C. At what temperature will the two wires
have the same resistance? [ Conditions: αiRoi∆ti - αcR0c∆tc = 6 Ω −5.4 Ω = -0.60.Ω. ]
−0.600 Ω −0.600 Ω
∆t = = ; ∆t = -38.0 C0
α i Roi − α c Roc (0.0065 / C )(6.0 Ω) - (0.0043 / C0 )(5.4 Ω)
0
∆t = tf – 200 = -38.0 C0; tf = -18.00C
128