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Transcript
Electrical and Electronic Principles P1 Calculation and use of Ohm’s law, for this circuit the applied voltage will be 12 volts. Find: The total resistance RT The total current IT The current through R3 The voltage across R5 The total power dissipated Related formulae R = V/I I = V/R V =I x R Power in Watts = I2 x R = V x I = V2/R To find RT Use Product/Sum to find resistances in parallel. Warning, this technique only works with 2 resistors at a time. The product simply means to multiply the values of the resistors. Therefore the product of R1 x R2: R1 x R2 = 220 X 100 = 22,000 We now take the sum of R1 and R2 and divide it into the product to find the parallel resistance of R1 and R2 together. Hence 22,000/R1 + R2 = 22,000/320 = 68.75 Ω To help you understand the process we now redraw the circuit: You should be able to see that R1 and R2 have been replaced by a single resistance of 68.75Ω which multisim has labeled R2 We now carry out exactly the same procedure with R2 and R3. When this is complete all of the 3 original resistances will be replaced by a single resistance. (R2 x R3)/(R2 + R3) (68.75 x 47)/(68.75 + 47) = 27.91 Ω And we redraw the circuit again Now do the same for R4 and R5 and redraw the circuit: So RT = R1 + R2 = 36.7Ω You can check this with the results of the simulation. You will see that it is completely correct. To find IT Using the triangle or the related formulae, finding the total current flowing through the circuit is easy enough. I = V/R = 12/36.7 IT = 0.326 Amps or 326 mA Although we could find the current through R3 at this stage, it is much easier to find the voltage dropped across each of the parallel branches first. From the formulae shown above we note that: V=IxR We have just worked out the total current flowing into the circuit, so the voltage drop across both banks is given by: Vbank 1 = 0.326 x 27.9 = 9.122 volts Vbank 2 = 0.326 x 8.8 = 2.86 volts If we have worked it out correctly then Kirchoff’s law tells us that the sum of voltage drops in the external circuit must = the applied voltage ( 12 volts) Sum of external volt drops = 9.122 + 2.86 = 11.99 volts That’s close enough for me Now we have worked out two different things here. First you now know the voltage drop across R5. VR5 = 2.86 volts = Vbank 2 Second you now know the volt drop across R3 = 9.122 volts = Vbank 1 Now applying Ohms law we can find the current flowing through R3 IR3 = 9.122/47 IR3 = 0.194 Amps Finally you can work out the total power consumed by the circuit in 3 different ways. P = I2 x R = 0.3262 x 36.7 = 3.9 watts
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