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Current, Voltage and resistance Objective: to recap GCSE circuits To know the circuit laws for current, voltage and resistance. Starter: table to fill out
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Current The net flow of charged particles In a metal this is due to electrons, when the circuit is not complete then the electrons just drift around and there is no net flow.
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Current The net flow of charged particles When a potential difference is applied the electrons start to drift in the positive to neagtive direction. This causes a net movement not a rapid flow. Annoyingly conventional current is positive to negative.
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Representing current direction
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Current
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How does current behave in series and parallel circuits? Set up some circuits and fill out the sheet (15mins) Current is the same everywhere in a series circuit Current splits up at each junction/branch in a parallel circuit
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Voltage Voltage, also known as potential difference, is a measure of the energy provided to the charge carriers. It can be defined as the amount of work done per unit charge. V (V) = W (J) Q (C) Voltage is measured as a difference in potential between two points. Thus a voltmeter must be connected in parallel and used to measure the difference in potential across a device. If a cell supplies 23 coulombs of charge with 776 J of energy, what is its voltage? 776 23 V = = 33.7 V
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How does voltage(P.D) behave in series and parallel circuits? Set up the circuits and record your answers on the sheet Voltage (P.D) is divided amongst the components in a series circuit Voltage (P.D) is the same across each branch in a parallel circuit
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Resistance Resistance is a measure of the opposition a material exerts against the flow of electrons. R (Ω) = V (V) I (A)I (A) The resistance of a material can be calculated from the current and voltage passing through it. 9.7 V 3.2 A Calculate the resistance in this simple circuit. R = 9.7 3.2 = 3.0 Ω
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How does resistance behave in series and parallel circuits?
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Equivalent resistance When designing or analysing circuits, complex combinations of resistors are common. To perform calculations, for example to find a suitable fuse to protect the circuit, it is easier to use a value for the total resistance of the circuit, R T. R1R1 R2R2 R3R3 R4R4 R5R5 R6R6 R7R7 RTRT R T can be called the equivalent resistance because it is the single resistor that is equivalent to the complex combination.
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Resistors in series To work out the equivalent resistance of resistors in series, the resistor values can just be added together: In general for a number of resistors, n: R T = R 1 + R 2 + … + R n 10 Ω20 Ω15 Ω equivalent resistance = 10 + 20 + 15 = 45 Ω
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Resistors in parallel To work out the equivalent resistance for resistors in parallel, a more complex equation must be applied: For example: 10 Ω 20 Ω 15 Ω 1 RTRT =++…+ 1 R1R1 1 R2R2 1 RnRn = 1 RTRT 1 10 1 20 1 15 ++ 1 RTRT = 60 6 + 3 + 4 1 RTRT = 13 60 =RTRT 13 = 4.62 ΩΩ
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Resistor combinations
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