Direct Current Circuits. Solutions of Home Work Problems

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Chapter 28 Direct Current Circuits. s of Home Work Problems 28.1 Problem 28.14 (In the text book) A 6.00-V battery supplies current to the circuit shown in Figure (28.14). When the doublethrow switch S is open, as shown in the figure, the current in the battery is 1.00 ma. When the switch is closed in position 1, the current in the battery is 1.20 ma. When the switch is closed in position 2, the current in the battery is 2.00 ma. Find the resistances R 1, R 2, and R 3. Figure 28.14:

2 CHAPTER 28. DIRECT CURRENT CIRCUITS. SOLUTIONS OF HOME WORK PROBLEMS When S is open R 1, R 2, R 3 are in series with the battery, so: R 1 + R 2 + R 3 = 6 = 6 kω (28.1) 10 3 When S is closed in position 1, the parallel combination of the two R 2 resitors is in series with R 1, R 2 and the battery, Thus: R 1 + R 2R 2 R 2 + R 2 + R 3 = R 1 + 1 2 R 2 + R 3 = 6 = 5 kω (28.2) 1.2 10 3 When S is closed in position 1, R 1 and R 2 are in series with the battery and R 3 is shorted. Thus: 6 R 1 + R 2 = = 3 kω (28.3) 2 10 3 Substituting for R 1 + R 2 from Equation (28.3) in Equation (28.1) we get: 3kΩ + R 3 = 6kΩ and R 3 = 3kΩ Now, subtracting Equation (28.2) from Equation (28.1) we get: 1 2 R 2 + R 3 = 5kΩ 3kΩ and R 2 = 2kΩ From Equation (28.3) we get R 1 = 1kΩ

28.2. PROBLEM 28.24 (IN THE TEXT BOOK) 3 28.2 Problem 28.24 (In the text book) Using Kirchhoffs rules, (a) find the current in each resistor in Figure (28.24). (b) Find the potential difference between points c and f. potential? Which point is at the higher Figure 28.24: We name the current I 1, I 2, and I 3 as shown in the Figure (28.14). Now going around loop abcf clockwise and applying Kirchhoff s voltage rule we get: 70.0 60.0 I 2 (3.00kΩ) I 1 (2.00kΩ) = 0 (28.4) Now, applying Kirchhoff s voltage rule to loop def c also clockwise, we get: 80.0 + I 2 (3.00kΩ) + 60.0 + I 3 (4.00kΩ) = 0 (28.5) Apply the current rule at c we get: I 2 = I 1 + I 3 (28.6)

4 CHAPTER 28. DIRECT CURRENT CIRCUITS. SOLUTIONS OF HOME WORK PROBLEMS (a) Substituting for I 2 from Equation (28.6) in Equation (28.4) ans solving the resulting three equations we get: I 1 = 0.385 ma I 2 = 2.69 ma I 3 = 3.08 ma (b) The potential difference between point c and point f staring from c to f is: V cf = V c V f = 60.0 + I 3 (3.00 kω) = 60 + 3.08 ma 3.00 kω = 69.2 V Point c is at higher potential than f.

28.3. PROBLEM 28.26 (IN THE TEXT BOOK) 5 28.3 Problem 28.26 (In the text book) In the circuit of Figure (28.26), determine the current in each resistor and the voltage across the 200-Ω resistor. Figure 28.26: We have four unknowns, so we need for equations. Naming the currents as shown in Figure (28.26), we find from applying the current rule at d and the voltage rule to loops abcd, dcfe and efgh clockwise we get: w + x + z = y 200w 40.0 + 80.0x = 0 80.0x + 40.0 + 360 20.0y = 0 +20.0y 360 80.0 + 70.0z = 0

6 CHAPTER 28. DIRECT CURRENT CIRCUITS. SOLUTIONS OF HOME WORK PROBLEMS eliminating y by substitution we get 2.5w + 0.500 = x 400 100x 20.0w 20.0z = 0 440 20.0w 20.0x 90.0z = 0 Eliminating x we get: 350 270w 20.0z = 0 440 70.0w 90.0z = 0 Eliminating z we get: z = 17.5 13.5w and 430 70.0w 1575 + 1215w = 0 and w becomes: and We can find x and y as: and w = 1145 1145 = 1.00 A z = 4.00 A x = 3.00 A y = 8.00 A The potential difference across the 200 Ω resistor is then: V = IR = wr = 1.00 A 200 Ω = 200 V

28.4. PROBLEM 28.36 (IN THE TEXT BOOK) 7 28.4 Problem 28.36 (In the text book) In the circuit of Figure (28.36), the switch S has been open for a long time. suddenly closed. Determine the time constant It is then (a) before the switch is closed and (b) after the switch is closed. (c) Let the switch be closed at t = 0. Determine the current in the switch as a function of time. Figure 28.36: (a) While the switch is open, the battery charges the capacitor. The current used to charge the battery is determined by the two resistors in series with the battery. So, the time constant τ open is: τ open = RC = (50.0 kω + 100 kω) 10µF = 1.5 s (b) When the switch is closed, the capacitor discharges through 100 kω resistor, so the time constant τ closed is: τ closed = 100 kω 10 µf = 1.0 s (c) The current through the closed switch will produced by the battery I b and while the capacitor is discharging a current I c, the total current trough the switch is then: I = I b + I c = V b R + I e t/τ closed = 10 50.0 10 3 + I e t/1.00 = 200 µa + I e t/1.00

8 CHAPTER 28. DIRECT CURRENT CIRCUITS. SOLUTIONS OF HOME WORK PROBLEMS To find I we notice that once the capacitor is fully charged, there will be no current flowing in the circuit an no potential differences on the two resistors. This means that potential difference across the capacitor is the same as that across the battery i.e. 10 V. Once the switch is closed the initial current due to the discharge of the capacitor is determined by the initial potential difference across the capacitor and the resistor through which the discharge takes place. So, and the total current becomes: I = 10.0 V 100 kω = 100 µa I = 200 + 100e t/1.00 µa A long time after the switch is closed the capacitor is fully discharged and the current in the switch will be mainly from the battery.

28.5. PROBLEM 28.42 (IN THE TEXT BOOK) 9 28.5 Problem 28.42 (In the text book) A typical galvanometer, which requires a current of 1.50 ma for full-scale deflection and has a resistance of 75.0 Ω, may be used to measure currents of much greater values. To enable an operator to measure large currents without damage to the galvanometer, a relatively small shunt resistor is wired in parallel with the galvanometer, as suggested in Figure (28.27). Most of the current then goes through the shunt resistor. Calculate the value of the shunt resistor that allows the galvanometer to be used to measure a current of 1.00 A at full-scale deflection. (Suggestion: use Kirchhoffs rules.) Figure 28.27: Applying Kirchhoff s loop rule we get: I g 75 Ω + (I I g )R p = 0

10 CHAPTER 28. DIRECT CURRENT CIRCUITS. SOLUTIONS OF HOME WORK PROBLEMS The Galvanometer requires 1.5 ma for full deflection, to use it to give full deflection for 1 A we then set I g = 1.5 ma and I = 1 A in the above equation, and R p becomes: R p = 75 I g I I g = 75 1.5 10 3 = 0.113 Ω 1 1.5 10 3

28.6. PROBLEM 28.50 (IN THE TEXT BOOK) 11 28.6 Problem 28.50 (In the text book) Aluminum wiring has sometimes been used instead of copper for economy. According to the National Electrical Code, the maximum allowable current for 12-gauge copper wire with rubber insulation is 20 A. What should be the maximum allowable current in a 12-gauge aluminum wire if the power per unit length delivered to the resistance in the aluminum wire is the same as that delivered in the copper wire? Since the power is the same in both wires, then: I 2 AlR Al = I 2 CuR Cu or I Al = RCu ρcu I Cu = I Cu = R Al ρ Al 1.70 20.0 = 15.5 A 2.82

12 CHAPTER 28. DIRECT CURRENT CIRCUITS. SOLUTIONS OF HOME WORK PROBLEMS 28.7 Problem 28.68 (In the text book) Switch S has been closed for a long time, and the electric circuit shown in Figure (28.68) carries a constant current. Take C 1 = 3.00 µf, C 2 = 6.00 µf, R 1 = 4.00 kω, and R 2 = 7.00 kω. The power delivered to R 2 is 2.40 W. (a) Find the charge on C 1. (b) Now the switch is opened. After many milliseconds, by how much has the charge on C 2 changed? Figure 28.68: (a) With the switch closed, current exists in the circuit as shown in the top part of Figure (28.68). The capacitors carry no current. For R 2 we have P 2.40 P = I 2 R 2 then I = = = 18.5 ma R 2 7000 The potential difference across R 1 and C 1 is V 1 = IR 1 = 1.85 10 2 4000 = 74.1 V

28.7. PROBLEM 28.68 (IN THE TEXT BOOK) 13 The charge on C 1 is Figure 28.69: Q = C 1 V = 3.00 10 6 74.1 = 222 µc The potential difference across R 2 and C 2 is: The charge on C 2 is: The battery emf is: or V 2 = IR 2 = 1.85 10 2 7000 = 130 V Q = C 2 V = 6.00 10 6 130 = 778 µc V = V 1 + V 2 = 74.1 + 130 = 204 V V = IR eq = I(R 1 + R 2 ) = 1.85 10 2 (4000 + 7000) = 204 V (b) In equilibrium after the switch has been opened, no current exists. The potential difference across each resistor is zero. The full 204 V appears across both capacitors. The new charge C 2 is: Q = C 2 V = 6.00 10 6 204 = 1222 µf and the change is 1222 778 = 444 µf

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