Series & Parallel Circuits Chapter 23 Physics Series & Parallel Circuits
Series Circuits - 1 ONE path for electrons to flow If one component goes out, they ALL go out The current is the same everywhere in the circuit The voltage & resistance change at each component The arrow symbols in the diagram are ammeters. They should ALL READ THE SAME. There is no where else for the flow of electrons to go and no reason for it to be different.
Series Circuits - 2 The voltage provided by the source (battery) is equal to the sum of the voltage drops across the resistors/lamps Vsource = VA + VB + … Add this equation to their card under a label that says SERIES CIRCUITS. This means that the first light bulbs in a circuit might get more voltage and thus be brighter than lighter light bulbs.
Series Circuits - 3 Equivalent Resistance – Total resistance in the whole circuit REq = RA + RB + … Current: I = Vsource / Req Voltage Dividers – drop the voltage to a desired amount by using up some of it Add these to the same location on the card
Series Circuits – Problem 1 (p 619 #1) Three 20 Ω resistors are connected in series across a 120 V generator. What is the equivalent resistance of the circuit? What is the current in the circuit? 60 Ω, 2 A
Series Circuits – Problem 2 (p 619 # 2 & 5) A 10 Ω, 15 Ω, and 5 Ω resistor are connected in a series circuit with a 90 V battery. What is the equivalent resistance of the circuit? What is the current in the circuit? What is the voltage drop (used up) across each of the 3 resistors? 30 Ω, 3 A, 30 V, 45 V, 15 V
Series Circuits – Problem 3 (p 619 # 4) A string of holiday lights has 10 bulbs with equal resistances connected in series. When the string of lights is connected to a 120 V outlet, the current through the bulbs is 0.06 A. What is the equivalent resistance of the circuit? What is the resistance of each bulb? 2000 Ω, 200 Ω
Parallel Circuits - 1 MANY paths for the electrons to flow Each “branch” is independent, so changing or removing one light doesn’t effect the others
Parallel Circuits - 2 The voltage everywhere is the same. The current through each branch is determined by its resistance. Equivalent Resistance: 1/REq = 1/RA + 1/RB + … Add this equation under Parallel Circuits Label on card.
Parallel Circuits – Problem 1 (p 625 Ex 3) Three resistors, 60.0 Ω, 30.0 Ω, and 20.0 Ω, are connected in parallel across a 90.0 V battery. Find the current through each branch of the circuit. Find the equivalent resistance of the circuit. Find the current through the battery. (Total current for entire circuit.) 1.50 A, 3.00 A, 4.50 A, 10.0 Ω, 9.00 A
Parallel Circuits – Problem 2 (p 626 # 15) Three 15.0 Ω resistors are connected in parallel and placed across a 30.0 V battery. What is the equivalent resistance for the circuit? What is the current through the entire circuit? What is the current through each branch of the circuit? 5.00 Ω, 6.00 A, 2.00 A
Safety Devices in Circuits - 1 Fuses Metal strip melts when the current becomes too high for the circuit Fuse is placed there because when it goes out, all the branches stop working. The fuse is in SERIES to the rest of the circuit.
Safety Devices in Circuits – 2 Circuit Breakers Reusable fuses When a circuit is ‘overloaded’ the breaker opens
Safety Devices in Circuits - 3 Ground-fault interrupter Detects small differences in current caused by an extra path and opens the current Extra path is usually water. These are in most kitchens and bathrooms Short Circuit Low resistance (too short of a path) in the circuit causes too much current Wires get hot and could start a fire Draw a circuit on the board. Show it shorted. Explain that this is the #1 problem with chaney kits.