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29. Sources of Magnetic Field

Ampere's Law (Calculus)

Physics

29. Sources of Magnetic Field

Ampere's Law (Calculus)

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5:47 minutes

Problem 74

Textbook Question

You want to get an idea of the magnitude of magnetic fields produced by overhead power lines. You estimate that a transmission wire is about 12 m above the ground. The local power company tells you that the lines operate at 145 kV and provide a maximum of 45 MW to the local area. Estimate the maximum magnetic field you might experience walking under one such power line, and compare to the Earth’s field. [For an ac current, values are rms, and the magnetic field will be changing.]

Verified step by step guidance

Determine the current in the transmission wire using the power and voltage provided. The formula for power is:

P = V I \cos θ

. Since the problem does not specify a power factor, assume it is 1 (pure resistive load). Rearrange the formula to find the current:

I = P / V

. Use the rms values for power (45 MW) and voltage (145 kV).

Calculate the magnetic field at a distance of 12 m from the wire using the Biot-Savart law for a long straight current-carrying wire. The formula is:

B = (μ

₀ I) / (2πr), where

μ

₀ is the permeability of free space (

4 π × 10

^-7 T·m/A),

I

is the current calculated in step 1, and

r

is the distance from the wire (12 m).

Since the current is alternating (AC), the magnetic field will also alternate. The value calculated in step 2 represents the maximum magnetic field, as it corresponds to the peak current. To find the rms magnetic field, divide the maximum magnetic field by

\sqrt{2}

Compare the calculated magnetic field to the Earth's magnetic field, which is approximately

5 × 10

^-5 T. Express the result as a ratio or percentage to provide a meaningful comparison.

Summarize the findings, noting that the magnetic field under the power line is likely to be much smaller than the Earth's magnetic field, especially when considering the rms value. Highlight the importance of understanding the context of AC fields and their time-varying nature.

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Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Magnetic Field Due to Current

A magnetic field is generated around a conductor when an electric current flows through it. The strength of this magnetic field can be calculated using Ampère's Law, which relates the magnetic field around a closed loop to the electric current passing through it. For overhead power lines, the magnetic field strength decreases with distance from the wire, and its direction is determined by the right-hand rule.

RMS Voltage and Current

RMS (Root Mean Square) values are used to express the effective voltage and current in alternating current (AC) systems. The RMS value provides a measure of the equivalent direct current (DC) that would deliver the same power to a load. In the context of power lines, knowing the RMS voltage helps in calculating the current and subsequently the magnetic field produced by the line.

Comparison with Earth's Magnetic Field

The Earth's magnetic field is approximately 25 to 65 µT (microteslas) and serves as a baseline for comparing other magnetic fields. When estimating the magnetic field from power lines, it is essential to compare the calculated value with the Earth's field to understand its significance. This comparison helps in assessing the potential impact of the power line's magnetic field on human health and the environment.

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Textbook Question

An infinitely wide flat sheet of charge flows out of the figure in FIGURE CP29.83. The current per unit width along the sheet (amps per meter) is given by the linear current density J_s. Find the magnetic field strength at distance d above or below the current sheet.

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Textbook Question

What is the line integral of $\vec{B} \cdot \vec{d s}$ between points i and f in FIGURE EX29.19?

118

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Textbook Question

The value of the line integral of $\vec{B} \cdot \vec{d s}$ around the closed path in FIGURE EX29.21 is 1.38 x 10^-5 T m. What are the direction (into or out of the figure) and magnitude of I₃?

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Textbook Question

(I) A 2.5-mm-diameter copper wire carries a 28-A dc current (uniform across its cross section). Determine the magnetic field: (a) at the surface of the wire; (b) inside the wire, 0.50 mm below the surface; (c) outside the wire 2.5 mm from the surface.

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Textbook Question

Suppose the current in the coaxial cable of Problem 34, Fig. 28–45, is not uniformly distributed, but instead the current density j varies linearly with distance from the center: j₁ = C₁R for the inner conductor and j₂ = C₂R for the outer conductor. Each conductor still carries the same total current I₀, in opposite directions. Determine the magnetic field in terms of I₀ in the same four regions of space as in Problem 34.

330

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Textbook Question

(II) A circular conducting ring of radius 𝑅 is connected to two exterior straight wires at two ends of a diameter (Fig. 28–47). The current I splits into unequal portions as shown (unequal resistance) while passing through the ring. What is $\vec{B}$ at the center of the ring?

356

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Textbook Question

Three long parallel wires are 3.5 cm from one another. (Looking along them, they are at three corners of an equilateral triangle.) The current in each wire is 9.50 A, but its direction in wire M is opposite to that in wires N and P (Fig. 28–57). Determine the magnetic force per unit length on each wire due to the other two.

225

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Textbook Question

(III) A coaxial cable consists of a solid inner conductor of radius R₁, surrounded by a concentric cylindrical tube of inner radius R₂ and outer radius R₃ (Fig. 28–45). The conductors carry equal and opposite currents I₀ distributed uniformly across their cross sections. Determine the magnetic field at a distance R from the axis for: (a) R < R₁; (b) R₁ < R < R₂; (c) R₂ < R < R₃; (d) R > R₃. (e) Let I₀ = 1.50 A, R₁ = 1.00 cm , R₂ = 2.00 cm , and R₃ = 2.50 cm Graph B from R = 0 to R = 3.00 cm.

324

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