Learning Objectives

Learning Objectives

By the end of this section, you will be able to do the following:

  • Calculate the emf induced in a generator
  • Calculate the peak emf that can be induced in a particular generator system

The information presented in this section supports the following AP® learning objectives and science practices:

  • 4.E.2.1 The student is able to construct an explanation of the function of a simple electromagnetic device in which an induced emf is produced by a changing magnetic flux through an area defined by a current loop (i.e., a simple microphone or generator) or of the effect on behavior of a device in which an induced emf is produced by a constant magnetic field through a changing area. (SP.6.4)

Electric generators induce an emf by rotating a coil in a magnetic field, as briefly discussed in Induced Emf and Magnetic Flux. We will now explore generators in more detail. Consider the following example.

Example 6.3 Calculating the Emf Induced in a Generator Coil

The generator coil shown in Figure 6.20 is rotated through one-fourth of a revolution (from θ=0º to θ=90º) θ=0º to θ=90º) in 15.0 ms. The 200-turn circular coil has a 5.00 cm radius and is in a uniform 1.25 T magnetic field. What is the average emf induced?

The figure shows a schematic diagram of an electric generator. It consists of a rotating rectangular coil placed between the two poles of a permanent magnet shown as two rectangular blocks curved on side facing the coil. The magnetic field B is shown pointing from the North to the South Pole. The two ends of this coil are connected to the two small rings. The two conducting carbon brushes are kept pressed separately on both the rings. The coil is attached to an axle with a handle at the other end. Outer e
Figure 6.20 When this generator coil is rotated through one-fourth of a revolution, the magnetic flux Φ Φ changes from its maximum to zero, inducing an emf.

Strategy

We use Faraday’s law of induction to find the average emf induced over a time Δt. Δt.

6.11 emf=NΔΦΔtemf=NΔΦΔt size 12{"emf"= - N { {ΔΦ} over {Δt} } } {}

We know that N=200N=200 size 12{N="200"} {} and Δt=15.0 ms, Δt=15.0 ms, and so we must determine the change in flux ΔΦΔΦ size 12{ΔΦ} {} to find emf.

Solution

Since the area of the loop and the magnetic field strength are constant, we see that

6.12 ΔΦ=Δ(BAcosθ)=ABΔ(cosθ).ΔΦ=Δ(BAcosθ)=ABΔ(cosθ). size 12{ΔΦ=Δ \( ital "BA""cos"θ \) = ital "AB"Δ \( "cos"θ \) } {}

Now, Δ(cosθ)=1.0,Δ(cosθ)=1.0, size 12{Δ \( "cos"θ \) = - 1 "." 0} {} since it was given that θ θ goes from to 90º. 90º. Thus, ΔΦ=AB,ΔΦ=AB, size 12{ΔΦ= - ital "AB"} {} and

6.13 emf=NABΔt.emf=NABΔt. size 12{"emf"=N { { ital "AB"} over {Δt} } } {}

The area of the loop is A=π r 2 =(3.14. . .) (0.0500 m) 2 =7.85 ×  10 3   m 2 . A=π r 2 =(3.14. . .) (0.0500 m) 2 =7.85 ×  10 3   m 2 . Entering this value gives

6.14 emf=200 (7.85 ×  10 3 m 2 )(1.25T) 15.0 ×  10 3 s =131V. emf=200 (7.85 ×  10 3 m 2 )(1.25T) 15.0 ×  10 3 s =131V.

Discussion

This is a practical average value, similar to the 120 V used in household power.

The emf calculated in Example 6.3 is the average over one-fourth of a revolution. What is the emf at any given instant? It varies with the angle between the magnetic field and perpendicular to the coil. We can get an expression for emf as a function of time by considering the motional emf on a rotating rectangular coil of width ww size 12{w} {} and height size 12{l} {} in a uniform magnetic field, as illustrated in Figure 6.21.

The figure shows a schematic diagram of an electric generator with a single rectangular coil. The rotating rectangular coil is placed between the two poles of a permanent magnet shown as two rectangular blocks curved on side facing the coil. The magnetic field B is shown pointing from the North to the South Pole. The North Pole is on the left and the South Pole is to the right and hence the direction of field is from left to right. The angular velocity of the coil is given as omega. The velocity vector v
Figure 6.21 A generator with a single rectangular coil rotated at constant angular velocity in a uniform magnetic field produces an emf that varies sinusoidally in time. Note the generator is similar to a motor, except the shaft is rotated to produce a current rather than the other way around.

Charges in the wires of the loop experience the magnetic force, because they are moving in a magnetic field. Charges in the vertical wires experience forces parallel to the wire, causing currents. But those in the top and bottom segments feel a force perpendicular to the wire, which does not cause a current. We can thus find the induced emf by considering only the side wires. Motional emf is given to be emf=Bv, emf=Bv, where the velocity v is perpendicular to the magnetic field B.B.size 12{B} {} Here the velocity is at an angle θθ size 12{θ} {} with B, B, so that its component perpendicular to BB size 12{B} {} is vsin θvsin θ size 12{v"sin"θ} {} (see Figure 6.21). Thus, in this case, the emf induced on each side is emf=Bℓvsinθ,emf=Bℓvsinθ, size 12{"emf"=Bℓv"sin"θ} {} and they are in the same direction. The total emf around the loop is then

6.15 emf=2Bℓvsinθ.emf=2Bℓvsinθ. size 12{"emf"=2Bℓv"sin"θ} {}

This expression is valid, but it does not give emf as a function of time. To find the time dependence of emf, we assume the coil rotates at a constant angular velocity ω.ω. size 12{ω} {} The angle θθ size 12{θ} {} is related to angular velocity by θ=ωt,θ=ωt, size 12{θ=ωt} {} so that

6.16 emf=2Bℓvsinωt.emf=2Bℓvsinωt. size 12{"emf"=Bℓv"sin"ωt} {}

Now, linear velocity v v is related to angular velocity ω ω by v=rω. v=rω. Here r=w/2 r=w/2 , so that v=(w/2)ω , v=(w/2)ω , and

6.17 emf=2Bℓw2ωsinωt=(w)sinωt.emf=2Bℓw2ωsinωt=(w)sinωt. size 12{"emf"=2Bℓ { {w} over {2} } ω"sin"ωt= \( ℓw \) Bω"sin"ωt} {}

Noting that the area of the loop is A=w,A=w, size 12{A=ℓw} {} and allowing for NN size 12{N} {} loops, we find that

6.18 emf = NAB ω sin ωt emf = NAB ω sin ωt size 12{"emf"= ital "NAB"ω"sin"ωt} {}

is the emf induced in a generator coil of NN size 12{N} {} turns and area AA size 12{A} {} rotating at a constant angular velocity ω ω in a uniform magnetic field B. B. This can also be expressed as

6.19 emf=emf0sinωt,emf=emf0sinωt, size 12{"emf"="emf" rSub { size 8{0} } "sin"ωt} {}

where

6.20 emf 0 = NAB ω emf 0 = NAB ω size 12{"emf" rSub { size 8{0} } = ital "NAB"ω} {}

is the maximum (peak) emf. Note that the frequency of the oscillation is f=ω/2π, f=ω/2π, and the period is T=1/f=2π/ω. T=1/f=2π/ω. Figure 6.22 shows a graph of emf as a function of time, and it now seems reasonable that AC voltage is sinusoidal.

The first part of the figure shows a schematic diagram of a single coil electric generator. It consists of a rotating rectangular loop placed between the two poles of a permanent magnet shown as two rectangular blocks curved on side facing the loop. The magnetic field B is shown pointing from the North to the South Pole. The two ends of this loop are connected to the two small rings. The two conducting carbon brushes are kept pressed separately on both the rings. The loop is rotated in the field with an a
Figure 6.22 The emf of a generator is sent to a light bulb with the system of rings and brushes shown. The graph gives the emf of the generator as a function of time. emf0emf0 size 12{"emf" rSub { size 8{0} } } {} is the peak emf. The period is T=1/f=2π/ω, T=1/f=2π/ω, where ff size 12{f} {} is the frequency. Note that the script E stands for emf.

The fact that the peak emf, emf0=NABω,emf0=NABω, size 12{"emf" rSub { size 8{0} } = ital "NAB"ω} {} makes good sense. The greater the number of coils, the larger their area, and the stronger the field, the greater the output voltage. It is interesting that the faster the generator is spun (greater ω ) ω), the greater the emf. This is noticeable on bicycle generators—at least the cheaper varieties. One of the authors as a juvenile found it amusing to ride his bicycle fast enough to burn out his lights, until he had to ride home lightless one dark night.

Figure 6.23 shows a scheme by which a generator can be made to produce pulsed DC. More elaborate arrangements of multiple coils and split rings can produce smoother DC, although electronic rather than mechanical means are usually used to make ripple-free DC.

The first part of the figure shows a schematic diagram of a single coil D C electric generator. It consists of a rotating rectangular loop placed between the two poles of a permanent magnet shown as two rectangular blocks curved on side facing the loop. The magnetic field B is shown pointing from the North to the South Pole. The two ends of this loop are connected to the two sides of a split ring. The two conducting carbon brushes are kept pressed separately on both sides of the split rings. The loop is r
Figure 6.23 Split rings, called commutators, produce a pulsed DC emf output in this configuration.

Example 6.4 Calculating the Maximum Emf of a Generator

Calculate the maximum emf, emf0, of the generator that was the subject of Example 6.3.

Strategy

Once ω, ω, the angular velocity, is determined, emf0=NABωemf0=NABω size 12{"emf" rSub { size 8{0} } = ital "NAB"ω} {} can be used to find em f 0 . em f 0 . All other quantities are known.

Solution

Angular velocity is defined to be the change in angle per unit time.

6.21 ω= Δθ Δt ω= Δθ Δt

One-fourth of a revolution is π/2π/2 size 12{l} {} radians, and the time is 0.0150 s; thus,

6.22 ω =  π/2 rad 0.0150 s . ω =  π/2 rad 0.0150 s .

104.7 rad/s is exactly 1,000 rpm. We substitute this value for ωω size 12{ω} {} and the information from the previous example into em f 0 =NABω, em f 0 =NABω, yielding

6.23 emf0 = NABω = 200(7.85×103m2)(1.25T)(104.7rad/s) = 206V. emf0 = NABω = 200(7.85×103m2)(1.25T)(104.7rad/s) = 206V.alignl { stack { size 12{"emf" rSub { size 8{0} } = ital "NAB"ω} {} # " "="200" \( 7 "." "85" times "10" rSup { size 8{ - 3} } " m" rSup { size 8{2} } \) \( 1 "." "25"" T" \) \( "104" "." 7" rad/s" \) {} # " "="206"" V" {} } } {}

Discussion

The maximum emf is greater than the average emf of 131 V found in the previous example, as it should be.

In real life, electric generators look a lot different than the figures in this section, but the principles are the same. The source of mechanical energy that turns the coil can be falling water (hydropower), steam produced by the burning of fossil fuels, or the kinetic energy of wind. Figure 6.24 shows a cutaway view of a steam turbine; steam moves over the blades connected to the shaft, which rotates the coil within the generator.

Photograph of a steam turbine connected to a generator.
Figure 6.24 Steam turbine/generator. The steam produced by burning coal impacts the turbine blades, turning the shaft that is connected to the generator. (Nabonaco, Wikimedia Commons)

Generators illustrated in this section look very much like the motors illustrated previously. This is not coincidental. In fact, a motor becomes a generator when its shaft rotates. Certain early automobiles used their starter motor as a generator. In Back Emf, we shall further explore the action of a motor as a generator.