Internal Resistance and Resistivity in DC Circuits AP Physics C.

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Presentation transcript:

Internal Resistance and Resistivity in DC Circuits AP Physics C

Internal Resistance All components in a circuit off some type of resistance regardless of how large or small it is. Batteries especially have what is called an internal resistance, r. Within the schematic it will be represented as a resistor symbol next to a battery symbol and between 2 points that represent the positive and negative terminals of the battery. Many times they are labeled with letters. Since the battery is in effect a resistor, there is a voltage drop across it. Therefore there is only a certain amount of voltage that actually goes pout to the circuit. That voltage is called the TERMINAL VOLTAGE, V T.

Internal Resistance To solve situations involving internal resistance we must use Kirchhoff's Voltage Law. Going around the circuit counterclockwise. We define the maximum voltage that the battery can produce the EMF. Some of the voltage will DROP across the battery. The rest will drop ACROSS the external circuit. This is called the terminal voltage. When KVL is re-arranged algebraically it looks like the slope of a line!

Internal Resistance is the SLOPE!  V T (V) I (A) r I max There are many graphical applications as the equation above looks like the slope intercept form of a line. The terminal voltage is plotted on the Y-axis, the current is plotted on the X-axis, the internal resistance is the SLOPE, the EMF is the Y-intercept.

Example Suppose we have a car battery with an emf = 13.8 V, under a resistive load of 20 ,the voltage sags to 11.8 V. a) What is the battery's resistance? 0.58 A The car’s battery is in series with the load so the current is the SAME throughout the circuit  b) What is the rate at which energy is dissipated in the battery? 1.16 W

Resistivity All wires in a circuit also contribute to the overall resistance in a circuit. Even though the value is often small and negligible, it is often important to determine the value for the resistance of a wire if it is thick or long. This being said, the resistance is dependant on the geometry of the material The resistance of the wire is DIRECTLY proportional to the length and inversely proportional to the area. The constant of proportionality is then defined as the RESISTIVITY, which is based on material type.

Example Calculate the resistance of a one meter length of 24 SWG Nichrome wire  As you can see, using significant amounts of wire can greatly influence the voltage drops, current, and power produced in circuits.