PAG 03.3 - Determining Internal Resistance and Maximum Power of a Cell Flashcards

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1
Q

What is a source’s internal resistance?

A

A source’s internal resistance is the resistance of the materials inside the source. It is equal to the lost volts per unit current in the source.

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2
Q

What is the emf of a power source?

A

A power supply’s emf is the work done by the source per unit charge. It is equal to the potential difference across the source when no current flows.

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3
Q

State the equation used to calculate a battery’s emf from its current, load resistance and internal resistance.

A

𝜺 = I (R + r)

R: Load Resistance
r: Internal Resistance

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4
Q

What is meant by the phrase ‘lost volts’?

A

The lost volts of a battery is the difference between the battery’s emf and its terminal potential difference.

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5
Q

How do you calculate a battery’s emf from its terminal potential difference, current and internal resistance?

A

𝜺 = V + Ir

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6
Q

Demonstrate how the equation of a V-I graph, for a source with internal resistance ‘r’ can be obtained.

A

𝜺 = I (R + r) V = I R
𝜺 = V + Ir
V = 𝜺 - Ir
V = -rI + 𝜺
Which is in the form y = mx + c

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7
Q

How can you find the internal resistance of a battery from a graph of V against I?

A

V = - rI + 𝜺
y = mx + c
The internal resistance is the gradient of the graph.

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8
Q

How can you find the emf of a battery from a graph of V against I?

A

V = - rI + 𝜺
y = mx + c
The emf is the y-intercept of the graph.

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9
Q

Why should the battery be disconnected between readings?

A

The temperature of the circuit should remain constant throughout this experiment, so as not to affect the resistance. Disconnecting the battery when not needed will reduce heating.

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10
Q

Why should you avoid using a rechargeable battery/cell when carrying out this experiment?

A

Rechargeable power sources have a very low internal resistance which would be hard to measure with this experiment.

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11
Q

Why should a new cell/battery be used when carrying out this experiment?

A

Run-down cells and batteries have internal resistances that may fluctuate throughout the experiment. Using a new source will result in a more constant value.

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12
Q

What safety precautions should be taken when carrying out this experiment?

A

If connected for long periods of time, the battery and circuitry can become hot. Avoid touching bare metal contacts and disconnect the battery when not taking readings.

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13
Q

What device could be used to check your value for the cell’s internal resistance?

A

An Ohmmeter

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14
Q

Suggest why your value for the cell’s emf may be slightly different to the true value.

A

Ideal voltmeters are assumed to have an infinite resistance. In reality, a small current may still flow through the voltmeter, resulting in there being a pd across the internal resistance.

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