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Lesson Name: Torque on a Current Loop: Motors and Meters

Instructional Block

Torque on a Current Loop: Motors and Meters 

LEARNING OBJECTIVES

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

  • Describe how motors and meters work in terms of torque on a current loop.
  • Calculate the torque on a current-carrying loop in a magnetic field.
INTRODUCTION

Motors are the most common application of magnetic force on current-carrying wires. Motors have loops of wire in a magnetic field. When current is passed through the loops, the magnetic field exerts torque on the loops, which rotates a shaft. Electrical energy is converted to mechanical work in the process. (See Figure 1)

 

Diagram showing a current-carrying loop of width w and length l between the north and south poles of a magnet. The north pole is to the left and the south pole is to the right of the loop. The magnetic field B runs from the north pole across the loop to the south pole. The loop is shown at an instant, while rotating clockwise. The current runs up the left side of the loop, across the top, and down the right side. There is a force F oriented into the page on the left side of the loop and a force F oriented out of the page on the right side of the loop. The torque on the loop is clockwise as viewed from above.

Figure 1. Torque on a current loop. A current-carrying loop of wire attached to a vertically rotating shaft feels magnetic forces that produce a clockwise torque as viewed from above.

Let us examine the force on each segment of the loop in Figure 1 to find the torques produced about the axis of the vertical shaft. (This will lead to a useful equation for the torque on the loop.) We take the magnetic field to be uniform over the rectangular loop, which has width  and height \(l\). First, we note that the forces on the top and bottom segments are vertical and, therefore, parallel to the shaft, producing no torque. Those vertical forces are equal in magnitude and opposite in direction, so that they also produce no net force on the loop. Figure 2 shows views of the loop from above. Torque is defined as \(\tau = rF \sin \theta\), where \(F\) is the force, \(r\) is the distance from the pivot that the force is applied, and \(\theta\) is the angle between \(r\) and \(F\). As seen in Figure 2(a), right hand rule 1 gives the forces on the sides to be equal in magnitude and opposite in direction, so that the net force is again zero. However, each force produces a clockwise torque. Since \(r = w/2\), the torque on each vertical segment is \((w/2)F \sin \theta\), and the two add to give a total torque.

 

Diagram showing a current-carrying loop from the top, and four different times as it rotates in a magnetic field. The magnetic field oriented toward the right, perpendicular to the vertical dimension of the loop. In figure a, the top view of the loop is oriented at an angle to the magnetic field lines, which run left to right. The force on the loop is up on the lower left side where the current comes out of the page. The force is down on the upper right side where the loop goes into the page. The angle between the force and the loop is theta. Torque is clockwise and equals w over 2 times I l B sine theta. Figure b shows the top view of the loop parallel to the magnetic field lines. The force on the loop is up on the left side where I comes out of the page. The force on the loop is down on the right side where I goes into the page. The angle theta between the F and B is ninety degrees. Torque is clockwise and equals w over 2 I l B equals maximum torque. Figure c shows the top view of the loop oriented perpendicular to B. The force on the loop is up at the top, where I comes out of the page, and down at the bottom where I goes into the page. Theta equals 0 degrees. Torque equals zero since sine theta equals 0. In figure d the force is down on the lower left side of the loop where I goes in, and up on the upper right side of the loop where I comes out. The torque is counterclockwise. Torque is negative.

 

Figure 2. Top views of a current-carrying loop in a magnetic field. (a) The equation for torque is derived using this view. Note that the perpendicular to the loop makes an angle \(\theta\) with the field that is the same as the angle between \(w/2\) and \(\mathbf{F}\). (b) The maximum torque occurs when \(\theta\) is a right angle and \(\sin \theta = 1\). (c) Zero (minimum) torque occurs when \(\theta\) is zero and \(\sin \theta = 0\). (d) The torque reverses once the loop rotates past \(\theta = 0\).

Now, each vertical segment has a length \(l\) that is perpendicular to \(B\), so that the force on each is \(F = IlB\). Entering \(F\) into the expression for torque yields

If we have a multiple loop of \(N\) turns, we get \(N\) times the torque of one loop. Finally, note that the area of the loop is \(A = wl\); the expression for the torque becomes

This is the torque on a current-carrying loop in a uniform magnetic field. This equation can be shown to be valid for a loop of any shape. The loop carries a current \(I\), has \(N\) turns, each of area \(A\), and the perpendicular to the loop makes an angle \(\theta\) with the field \(B\). The net force on the loop is zero.

EXAMPLE

CALCULATING TORQUE ON A CURRENT-CARRYING LOOP IN A STRONG MAGNETIC FIELD

Find the maximum torque on a 100-turn square loop of a wire of 10.0 cm on a side that carries 15.0 A of current in a 2.00-T field.

Strategy

Torque on the loop can be found using \(\tau = NIAB \sin \theta\). Maximum torque occurs when \(\theta = 90^\circ\) and \(\sin \theta =1\).

Solution

For \(\sin \theta =1\), the maximum torque is

Entering known values yields

\(= 20.0 \thinspace \mathrm{N \cdot m}.\)

Discussion

This torque is large enough to be useful in a motor.


 

The torque found in the preceding example is the maximum. As the coil rotates, the torque decreases to zero at \(\theta = 0\). The torque then reverses its direction once the coil rotates past \(\theta = 0\). (See Figure 2(d).) This means that, unless we do something, the coil will oscillate back and forth about equilibrium at \(\theta = 0\). To get the coil to continue rotating in the same direction, we can reverse the current as it passes through \(\theta = 0\) with automatic switches called brushes. (See Figure 3.)

 

The diagram shows a current-carrying loop between the north and south poles of a magnet at two different times. The north pole is to the left and the south pole is to the right. The magnetic field runs from the north pole to the right to the south pole. Figure a shows the current running through the loop. It runs up on the left side, and down on the right side. The force on the left side is into the page. The force on the right side is out of the page. The torque is clockwise when viewed from above. Figure b shows the loop when it is oriented perpendicular to the magnet. In both diagrams, the bottom of each side of the loop is connected to a half-cylinder that is next to a rectangular brush that is then connected to the rest of the circuit.

 

Figure 3. (a) As the angular momentum of the coil carries it through \(\theta = 0\), the brushes reverse the current to keep the torque clockwise. (b) The coil will rotate continuously in the clockwise direction, with the current reversing each half revolution to maintain the clockwise torque.

Meters, such as those in analog fuel gauges on a car, are another common application of magnetic torque on a current-carrying loop. Figure 4 shows that a meter is very similar in construction to a motor. The meter in the figure has its magnets shaped to limit the effect of \(\theta\) by making \(B\) perpendicular to the loop over a large angular range. Thus the torque is proportional to \(l\) and not \(\theta\). A linear spring exerts a counter-torque that balances the current-produced torque. This makes the needle deflection proportional to \(I\). If an exact proportionality cannot be achieved, the gauge reading can be calibrated. To produce a galvanometer for use in analog voltmeters and ammeters that have a low resistance and respond to small currents, we use a large loop area \(A\), high magnetic field \(B\), and low-resistance coils.

 

Diagram of a meter showing a current-carrying loop between two poles of a magnet. The torque on the magnet is clockwise. The top of the loop is connected to a spring and to a pointer that points to a scale as the loop rotates.

Figure 4. Meters are very similar to motors but only rotate through a part of a revolution. The magnetic poles of this meter are shaped to keep the component of \(B\) perpendicular to the loop constant, so that the torque does not depend on \(\theta\) and the deflection against the return spring is proportional only to the current \(I\).
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Free Response

Discuss the similarity of the actions of a galvanometer and a motor. Explain your answer.

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Check All That Apply

Which of the following factors affect the magnetic field strength of a coil? Choose 3 correct options.




Answer Rubric % Of Choosen
The straightness of the wire. In-Correct 0 %
The number of loops in the coil. Correct 0 %
The type of core material. Correct 0 %
The current in the coil. Correct 0 %


Numeric + Units

Calculate the magnetic field strength needed on a 200-turn square loop 20.0 cm on a side to create a maximum torque of \(300\; N\cdot m\) if the loop is carrying 25.0 A.

Is correct? Answer (midpoint) Rounding Margin Answer Range Units Wrong Answer Feedback
Correct 1.55 0.1 [1.45,1.65]

\(T\)

\(\tau=NIAB\;\;\Rightarrow\;\; B=\frac{\tau}{NIA}\)

\(B=\frac{300\;N\cdot m}{(200)(25.0\; A)(0.200\; m)^2}\)

Answer: 1.50 T


Numeric + Units

Find the current through a loop needed to create a maximum torque of \(9.00\; N\cdot m\). The loop has 50 square turns that are 15.0 cm on a side and is in a uniform 0.800-T magnetic field.

Is correct? Answer (midpoint) Rounding Margin Answer Range Units Wrong Answer Feedback
Correct 10 0 [10,10]

\(A\)

\(\tau= NIAB\;\; \Rightarrow\;\; I=\frac{\tau}{NAB}\)

\(I=\frac{9.00\;N}{(50)(0.150\;m)^2(0.800\;T)}\)

Answer: 10.0 A


Numeric + Units

What is the maximum torque on a 150-turn square loop of wire 18.0 cm on a side that carries a 50.0-A current in a 1.60-T field?

Is correct? Answer (midpoint) Rounding Margin Answer Range Units Wrong Answer Feedback
Correct 395 10 [385,405]

\(N \cdot m\)

The maximum torque occurs when \(sin \phi= 1\), so the maximum torque is:

 

\(\tau_{max}=NIABsin\phi \)

\(\tau_{max}=(150)(50.0\;A)(0.180\;m)^2(1.60\; T)(1)\)

Answer: 388.8 \(N \cdot m\)

Numeric + Units

 

What is the torque when \(\theta\) is 10.9°?

Is correct? Answer (midpoint) Rounding Margin Answer Range Units Wrong Answer Feedback
Correct 74.5 1 [73.5,75.5]

\(N \cdot m\)

\(\tau=NIABsin\phi\)

Now set \(\phi=19.9^\circ\), so

 

\(\tau=(150)(50.0\;A)(0.180\; m)^2(1.60\; T)(sin(10.9^{\circ})\)

Answer: 73.52 \(N\cdot m\)



Numeric + Units

At what angle \(\theta\) is the torque on a current loop 90.0% of the maximum?

Is correct? Answer (midpoint) Rounding Margin Answer Range Units Wrong Answer Feedback
Correct 64.5 1 [63.5,65.5]

\(^\circ\)

\(\theta=sin^{-1}(0.90)\)

Answer: 64.1580°

Numeric + Units

At what angle \(\theta\) is the torque on a current loop 50.0% of the maximum?

Is correct? Answer (midpoint) Rounding Margin Answer Range Units Wrong Answer Feedback
Correct 30 0 [30,30]

\(^\circ\)

\(\theta= sin^{-1}(0.50)\)

Answer: 30.0°


Numeric + Units

At what angle \(\theta\) is the torque on a current loop 10.0% of the maximum?

Is correct? Answer (midpoint) Rounding Margin Answer Range Units Wrong Answer Feedback
Correct 5.75 0.1 [5.65,5.85]

\(^\circ\)

\(\theta= sin^{-1}(0.10)\)

Answer: 5.7391°



Numeric + Units

A proton has a magnetic field due to its spin on its axis. The field is similar to that created by a circular current loop \(0.650\times10^{-15}\;m\) in radius with a current of \(1.05\times10^4\;A\) (no kidding). Find the maximum torque on a proton in a 2.50-T field. (This is a significant torque on a small particle.)

Is correct? Answer (midpoint) Rounding Margin Answer Range Units Wrong Answer Feedback
Correct 3.55e-26 1.0E-27 [3.45E-26,3.65E-26]

\(N \cdot m\)

\(\tau=IAB\)

\(\tau=(1.05\times10^4\;A)(\pi)(0.650\times10^{-15}\;m)^2(2.50\; T)\)

Answer: 3.48E-26 \(N\cdot m\)


Instructional Block

Magnetic Fields Produced by Currents: Ampere’s Law

LEARNING OBJECTIVES

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

  • Calculate current that produces a magnetic field.
  • Use the right-hand rule 2 to determine the direction of current or the direction of magnetic field loops.

 

INTRODUCTION

How much current is needed to produce a significant magnetic field, perhaps as strong as the Earth’s field? Surveyors will tell you that overhead electric power lines create magnetic fields that interfere with their compass readings. Indeed, when Oersted discovered in 1820 that a current in a wire affected a compass needle, he was not dealing with extremely large currents. How does the shape of wires carrying current affect the shape of the magnetic field created? We noted earlier that a current loop created a magnetic field similar to that of a bar magnet, but what about a straight wire or a toroid (doughnut)? How is the direction of a current-created field related to the direction of the current? Answers to these questions are explored in this section, together with a brief discussion of the law governing the fields created by currents.

MAGNETIC FIELD CREATED BY A LONG STRAIGHT CURRENT-CARRYING WIRE: RIGHT HAND RULE 2

Magnetic fields have both direction and magnitude. As noted before, one way to explore the direction of a magnetic field is with compasses, as shown for a long straight current-carrying wire in Figure 1. Hall probes can determine the magnitude of the field. The field around a long straight wire is found to be in circular loops. The right hand rule 2 (RHR-2) emerges from this exploration and is valid for any current segment—point the thumb in the direction of the current, and the fingers curl in the direction of the magnetic field loops created by it.

 

Figure a shows a vertically oriented wire with current I running from bottom to top. Magnetic field lines circle the wire counter-clockwise as view from the top. Figure b illustrates the right hand rule 2. The thumb points up with current I. The fingers curl around counterclockwise as viewed from the top.

 

Figure 1. (a) Compasses placed near a long straight current-carrying wire indicate that field lines form circular loops centered on the wire. (b) Right hand rule 2 states that, if the right hand thumb points in the direction of the current, the fingers curl in the direction of the field. This rule is consistent with the field mapped for the long straight wire and is valid for any current segment.
MAKING CONNECTIONS: NOTATION

For a wire oriented perpendicular to the page, if the current in the wire is directed out of the page, the right-hand rule tells us that the magnetic field lines will be oriented in a counterclockwise direction around the wire. If the current in the wire is directed into the page, the magnetic field lines will be oriented in a clockwise direction around the wire. We use  to indicate that the direction of the current in the wire is out of the page, and  for the direction into the page.

The diagram on the left shows a small circle with a dot in the center. There are three progressively larger circles on the outside of the small circle with arrows pointing in the counter-clockwise direction representing magnetic fields. The diagram on the right has a small circle with an x in the middle. The three progressively larger circles have arrows pointing in the clockwise direction.
Figure 2. Two parallel wires have currents pointing into or out of the page as shown. The direction of the magnetic field in the vicinity of the two wires is shown.

 

The magnetic field strength (magnitude) produced by a long straight current-carrying wire is found by experiment to be

 

where \(l\) is the current, \(r\) is the shortest distance to the wire, and the constant \(\mu _{0} = 4 \pi \times 10^{-7} \thinspace \mathrm{T \cdot m/A}\) is the permeability of free space is one of the basic constants in nature. We will see later that \(\mu _{0}\) is related to the speed of light.) Since the wire is very long, the magnitude of the field depends only on distance from the wire \(r\), not on position along the wire.

EXAMPLE #1

CALCULATING CURRENT THAT PRODUCES A MAGNETIC FIELD

Find the current in a long straight wire that would produce a magnetic field twice the strength of the Earth’s at a distance of 5.0 cm from the wire.

Strategy

The Earth’s field is about \(5.0 \times 10^{-5} \mathrm{T}\), and so here \(B\) due to the wire is taken to be \(1.0 \times 10^{-4} \mathrm{T}\). The equation \(B = \frac{\mu _{0}I}{2 \pi r}\) can be used to find \(I\), since all other quantities are known.

Solution

Solving for \(I\) and entering known values gives

\(= 25 \thinspace \mathrm{A}.\)

Discussion

So a moderately large current produces a significant magnetic field at a distance of 5.0 cm from a long straight wire. Note that the answer is stated to only two digits, since the Earth’s field is specified to only two digits in this example.

AMPERE'S LAW AND OTHERS

The magnetic field of a long straight wire has more implications than you might at first suspect. Each segment of current produces a magnetic field like that of a long straight wire, and the total field of any shape current is the vector sum of the fields due to each segment. The formal statement of the direction and magnitude of the field due to each segment is called the Biot-Savart law. Integral calculus is needed to sum the field for an arbitrary shape current. This results in a more complete law, called Ampere’s law, which relates magnetic field and current in a general way. Ampere’s law in turn is a part of Maxwell’s equations, which give a complete theory of all electromagnetic phenomena. Considerations of how Maxwell’s equations appear to different observers led to the modern theory of relativity, and the realization that electric and magnetic fields are different manifestations of the same thing. Most of this is beyond the scope of this text in both mathematical level, requiring calculus, and in the amount of space that can be devoted to it. But for the interested student, and particularly for those who continue in physics, engineering, or similar pursuits, delving into these matters further will reveal descriptions of nature that are elegant as well as profound. In this text, we shall keep the general features in mind, such as RHR-2 and the rules for magnetic field lines listed in Magnetic Fields and Magnetic Field Lines, while concentrating on the fields created in certain important situations.

MAKING CONNECTIONS: RELATIVITY

Hearing all we do about Einstein, we sometimes get the impression that he invented relativity out of nothing. On the contrary, one of Einstein’s motivations was to solve difficulties in knowing how different observers see magnetic and electric fields.

MAGNETIC FIELD PRODUCED BY A CURRENT-CARRYING CIRCULAR LOOP

The magnetic field near a current-carrying loop of wire is shown in Figure 3. Both the direction and the magnitude of the magnetic field produced by a current-carrying loop are complex. RHR-2 can be used to give the direction of the field near the loop, but mapping with compasses and the rules about field lines given in Magnetic Fields and Magnetic Field Lines are needed for more detail. There is a simple formula for the magnetic field strength at the center of a circular loop. It is

where \(R\) is the radius of the loop. This equation is very similar to that for a straight wire, but it is valid only at the center of a circular loop of wire. The similarity of the equations does indicate that similar field strength can be obtained at the center of a loop. One way to get a larger field is to have \(N\) loops; then, the field is \(B = N_{\mu_{0}} I /(2R)\). Note that the larger the loop, the smaller the field at its center, because the current is farther away.

 

Figure a illustrates use of the right hand rule 2 to determine the direction of the magnetic field around a current-carrying loop. The right hand thumb points in the direction of I while the fingers curl around in the direction of B. Figure b shows the magnetic field lines circling the wire, as viewed from the side.

Figure 3. (a) RHR-2 gives the direction of the magnetic field inside and outside a current-carrying loop. (b) More detailed mapping with compasses or with a Hall probe completes the picture. The field is similar to that of a bar magnet.
MAGNETIC FIELD PRODUCED BY A CURRENT-CARRYING SOLENOID

A solenoid is a long coil of wire (with many turns or loops, as opposed to a flat loop). Because of its shape, the field inside a solenoid can be very uniform, and also very strong. The field just outside the coils is nearly zero. Figure 4 shows how the field looks and how its direction is given by RHR-2.

 

A diagram of a solenoid. The current runs up from the battery on the left side and spirals around with the solenoid wire such that the current runs upward in the front sections of the solenoid and then down the back. An illustration of the right hand rule 2 shows the thumb pointing up in the direction of the current and the fingers curling around in the direction of the magnetic field. A length wise cutaway of the solenoid shows magnetic field lines densely packed and running from the south pole to the north pole, through the solenoid. Lines outside the solenoid are spaced much farther apart and run from the north pole out around the solenoid to the south pole.

Figure 4. (a) Because of its shape, the field inside a solenoid of length \(l\) is remarkably uniform in magnitude and direction, as indicated by the straight and uniformly spaced field lines. The field outside the coils is nearly zero. (b) This cutaway shows the magnetic field generated by the current in the solenoid.

The magnetic field inside of a current-carrying solenoid is very uniform in direction and magnitude. Only near the ends does it begin to weaken and change direction. The field outside has similar complexities to flat loops and bar magnets, but the magnetic field strength inside a solenoid is simply

 

where \(n\) is the number of loops per unit length of the solenoid , with \(N\) being the number of loops and \(l\) the length). Note that \(B\) is the field strength anywhere in the uniform region of the interior and not just at the center. Large uniform fields spread over a large volume are possible with solenoids, as Example #2 implies.

EXAMPLE #2

CALCULATING FIELD STRENGTH INSIDE A SOLENOID

What is the field inside a 2.00-m-long solenoid that has 2000 loops and carries a 1600-A current?

Strategy

To find the field strength inside a solenoid, we use \(B = \mu _{0}nI\). First, we note the number of loops per unit length is

Solution

Substituting known values gives

\(= 2.01 \thinspace \mathrm{T}.\)

Discussion

This is a large field strength that could be established over a large-diameter solenoid, such as in medical uses of magnetic resonance imaging (MRI). The very large current is an indication that the fields of this strength are not easily achieved, however. Such a large current through 1000 loops squeezed into a meter’s length would produce significant heating. Higher currents can be achieved by using superconducting wires, although this is expensive. There is an upper limit to the current, since the superconducting state is disrupted by very large magnetic fields.

APPLYING THE SCIENCE PRACTICES: CHARGED PARTICLE IN A MAGNETIC FIELD

Visit here and start the simulation applet “Particle in a Magnetic Field (2D)” in order to explore the magnetic force that acts on a charged particle in a magnetic field. Experiment with the simulation to see how it works and what parameters you can change; then construct a plan to methodically investigate how magnetic fields affect charged particles. Some questions you may want to answer as part of your experiment are:

  • Are the paths of charged particles in magnetic fields always similar in two dimensions? Why or why not?
  • How would the path of a neutral particle in the magnetic field compare to the path of a charged particle?
  • How would the path of a positive particle differ from the path of a negative particle in a magnetic field?
  • What quantities dictate the properties of the particle’s path?
  • If you were attempting to measure the mass of a charged particle moving through a magnetic field, what would you need to measure about its path? Would you need to see it moving at many different velocities or through different field strengths, or would one trial be sufficient if your measurements were correct?
  • Would doubling the charge change the path through the field? Predict an answer to this question, and then test your hypothesis.
  • Would doubling the velocity change the path through the field? Predict an answer to this question, and then test your hypothesis.
  • Would doubling the magnetic field strength change the path through the field? Predict an answer to this question, and then test your hypothesis.
  • Would increasing the mass change the path? Predict an answer to this question, and then test your hypothesis.

There are interesting variations of the flat coil and solenoid. For example, the toroidal coil used to confine the reactive particles in tokamaks is much like a solenoid bent into a circle. The field inside a toroid is very strong but circular. Charged particles travel in circles, following the field lines, and collide with one another, perhaps inducing fusion. But the charged particles do not cross field lines and escape the toroid. A whole range of coil shapes are used to produce all sorts of magnetic field shapes. Adding ferromagnetic materials produces greater field strengths and can have a significant effect on the shape of the field. Ferromagnetic materials tend to trap magnetic fields (the field lines bend into the ferromagnetic material, leaving weaker fields outside it) and are used as shields for devices that are adversely affected by magnetic fields, including the Earth’s magnetic field.

PHET EXPLORATIONS: GENERATOR

Generate electricity with a bar magnet! Discover the physics behind the phenomena by exploring magnets and how you can use them to make a bulb light.

 

Click here to view the simulation page

 

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Ungraded

Make a drawing in your notebook and use RHR-2 to find the direction of the magnetic field of a current loop in a motor (such as in the figure below). Then show that the direction of the torque on the loop is the same as produced by like poles repelling and unlike poles attracting.

 

Figure 1. Torque on a current loop. A current-carrying loop of wire attached to a vertically rotating shaft feels magnetic forces that produce a clockwise torque as viewed from above.

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