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Unformatted text preview: CHAPTER 28 ELECTRIC CIRCUITS ActivPhysics can help with these problems: Section 12, “DC Circuits” Section 281: Circuits and Symbols Problem 1. Sketch a circuit diagram for a circuit that includes a resistor R 1 connected to the positive terminal of a battery, a pair of parallel resistors R R 2 3 and connected to the lowervoltage end of R 1 , then returned to the battery’s negative terminal, and a capacitor across R 2 . Solution A literal reading of the circuit specifications results in connections like those in sketch (a). Because the connecting wires are assumed to have no resistance (a real wire is represented by a separate resistor), a topologically equivalent circuit diagram is shown in sketch (b). Problem 1 Solution (a). Problem 1 Solution (b). Problem 2. A circuit consists of two batteries, a resistor, and a capacitor, all in series. Sketch this circuit. Does the description allow any flexibility in how you draw the circuit? Solution In a series circuit, the same current must flow through all elements. One possibility is shown. The order of elements and the polarity of the battery connections are not specified. Problem 2 Solution. 660 CHAPTER 28 Problem 3. Resistors R 1 and R 2 are connected in series, and this series combination is in parallel with R 3 . This parallel combination is connected across a battery whose internal resistance is R int . Draw a diagram representing this circuit. Solution The circuit has three parallel branches: one with R 1 and R 2 in series; one with just R 3 ; and one with the battery (an ideal emf in series with the internal resistance). Problem 3 Solution. Section 282: Electromotive Force Problem 4. What is the emf of a battery that delivers 27 J of energy as it moves 3.0 C between its terminals? Solution From the definition of emf (as work per unit charge), E = = = W q = = 27 3 9 J C V. Problem 5. A 1.5V battery stores 4.5 kJ of energy. How long can it light a flashlight bulb that draws 0.60 A? Solution The average power, supplied by the battery to the bulb, multiplied by the time equals the energy capacity of the battery. For an ideal battery, P E = I , therefore E It = 4 5 . , kJ or t = = × = 4 5 1 5 0 60 5 10 1 39 3 . ( . )( . ) . kJ V A s h. = Problem 6. If you accidentally leave your car headlights (current drain 5 A) on for an hour, how much of the 12V battery’s chemical energy is used up? Solution The power delivered by an emf is E I , so (if the voltage and current remain constant) the energy converted is E It = = ( )( )( ) . 12 5 3600 216 V A s kJ Problem 7. A battery stores 50 W h ⋅ of chemical energy. If it uses up this energy moving 3 0 10 4 . × C through a circuit, what is its voltage? CHAPTER 28 661 Solution The emf is the energy (work done going through the source from the negative to the positive terminal) per unit charge: E = ⋅ × = ( )( ) ( ) . 50 3600 3 10 6 4 W h s/h C V = (This is the average emf; the actual emf may vary with time.) Section 283: Simple Circuits: Series and Parallel Resistors...
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This note was uploaded on 10/19/2010 for the course PHY 78647 taught by Professor Miller during the Spring '09 term at Albany College of Pharmacy and Health Sciences.
 Spring '09
 Miller
 Physics

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