List the factors that affect the heat produced in a current-carrying conductor. An electric cable consists of a single strand of insulated copper wire. The wire is of uniform cross-sectional area and is designed to carry a current of 20 A. To preserve the insulation, the maximum rate at which heat may be produced in the wire is 2.7 W per metre length. Calculate (i) the maximum resistance per metre of the wire. (ii) the minimum diameter of the wire. (resistivity of copper = 1.7 × 10⁻⁸ Ω m)

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List the factors that affect the heat produced in a current-carrying conductor - Leaving Cert Physics - Question c - 2011

Question c

List the factors that affect the heat produced in a current-carrying conductor. An electric cable consists of a single strand of insulated copper wire. The wire is ... show full transcript

Worked Solution & Example Answer:List the factors that affect the heat produced in a current-carrying conductor - Leaving Cert Physics - Question c - 2011

Step 1

List the factors that affect the heat produced in a current-carrying conductor.

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Answer

The heat produced in a current-carrying conductor is affected by:

Resistance (R): Higher resistance results in more heat dissipation due to the I²R losses.
Current (I): Increased current through the conductor increases the heat produced, as heat is proportional to the square of the current.
Material: Different materials have different resistivities, affecting heat production.
Length of the Wire: The longer the conductor, the higher the resistance, which leads to more heat generation.
Cross-sectional Area: A larger cross-sectional area reduces resistance, hence decreases heat production, while a smaller area increases heat.
Temperature: As the temperature increases, the resistivity of the conductor usually increases, leading to more heat generation.
Condition of the Conductor: Degradation, corrosion, or other physical conditions can affect the resistance and hence the heat produced.

Step 2

Calculate the maximum resistance per metre of the wire.

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Answer

To find the maximum resistance per metre (R) of the wire, we can use the formula for power:

$P = I^2 R$

Given:

Power (P) = 2.7 W
Current (I) = 20 A

Rearranging for R gives us:

$R = \frac{P}{I^2}$

Substituting values:

$R = \frac{2.7}{20^2} = \frac{2.7}{400} = 0.00675 \; \Omega$

Step 3

Calculate the minimum diameter of the wire.

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Answer

Using the formula for resistivity:

$\rho = R \frac{A}{L}$

where

$\rho$ = resistivity of copper = $1.7 \times 10^{-8} \; \Omega m$
$A$ = cross-sectional area
$L$ = length (1 m in this case)

The area A can be expressed as:

$A = \frac{\pi d^2}{4}$

Substituting this into the resistivity equation:

$\rho = R \frac{\pi d^2/4}{1}$

Rearranging gives:

$d^2 = \frac{4\rho}{\pi R}$

Substituting in the known values:

$d^2 = \frac{4 \times (1.7 \times 10^{-8})}{\pi \times 0.00675}$

Calculating:

$d^2 \approx 8.017 \times 10^{-7}$

Taking the square root yields:

$d \approx 0.9 \times 10^{-4} \text{m} = 0.0009 m = 1.8 mm$

List the factors that affect the heat produced in a current-carrying conductor - Leaving Cert Physics - Question c - 2011

Worked Solution & Example Answer:List the factors that affect the heat produced in a current-carrying conductor - Leaving Cert Physics - Question c - 2011

List the factors that affect the heat produced in a current-carrying conductor.

Calculate the maximum resistance per metre of the wire.

Calculate the minimum diameter of the wire.

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