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Helmholtz coil

 
Sci-Tech Dictionary: Helmholtz coils
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(′helm′hōlts ′köilz)

(electromagnetism) A pair of flat, circular coils having equal numbers of turns and equal diameters, arranged with a common axis, and connected in series; used to obtain a magnetic field more nearly uniform than that of a single coil.

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Sci-Tech Encyclopedia: Helmholtz coils
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A pair of flat circular coils with equal numbers of turns and equal diameters, arranged with a common axis, and connected in series to have a common current. The purpose of the arrangement is to obtain a magnetic field that is more nearly uniform than that of a single coil without the use of a long solenoid. The optimum arrangement is that in which the distance between the two coils is equal to the radius of one of the coils. See also Solenoid (electricity).

Wikipedia: Helmholtz coil
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A Helmholtz coil
Helmholtz coil schematic drawing

The term Helmholtz coils refers to a device for producing a region of nearly uniform magnetic field. It is named in honor of the German physicist Hermann von Helmholtz.

Contents

Description

A Helmholtz pair consists of two identical circular magnetic coils that are placed symmetrically one on each side of the experimental area along a common axis, and separated by a distance h equal to the radius R of the coil. Each coil carries an equal electrical current flowing in the same direction.

Setting h = R, which is what defines a Helmholtz pair, minimizes the nonuniformity of the field at the center of the coils, in the sense of setting d2B / dx2 = 0, but leaves about 6% variation in field strength between the center and the planes of the coils. A slightly larger value of h reduces the difference in field between the center and the planes of the coils, at the expense of worsening the field's uniformity in the region near the center, as measured by d2B / dx2.[1]

In some applications, a Helmholtz coil is used to cancel out Earth's magnetic field, producing a region with a magnetic field intensity much closer to zero.[2]

Mathematics

Magnetic field vector in a plane bisecting the current loops. Note the field is approximately uniform in between the coil pair. (In this picture the coils are placed one above the other: the axis is vertical)
Magnetic field induction along the axis crossing the center of coils; z=0 is the point in the middle of distance between coils.
Contours showing the magnitude of the magnetic field near the coil pair. Inside the central 'octopus' the field is within 1% of its central value B0. The five contours are for field magnitudes of .5B0, .8B0, .9B0, 0.95B0, and .99B0 .

The calculation of the exact magnetic field at any point in space has mathematical complexities and involves the study of Bessel functions. Things are simpler along the axis of the coil-pair, and it is convenient to think about the Taylor series expansion of the field strength as a function of x, the distance from the central point of the coil-pair along the axis. By symmetry the odd order terms in the expansion are zero. By separating the coils so that x = 0 is an inflection point for each coil separately we can guarantee that the order x2 term is also zero, and hence the leading non-uniform term is of order x4. One can easily show that the inflection point for a simple coil is R / 2 from the coil center along the axis; hence the location of each coil at x=\pm R/2

A simple calculation gives the correct value of the field at the center point. If the radius is R, the number of turns in each coil is n and the current flowing through the coils is I, then the magnetic flux density, B at the midpoint between the coils will be given by

B = {\left ( \frac{4}{5} \right )}^{3/2} \frac{\mu_0 n I}{R}

μ0 is the permeability constant (1.26 \times 10^{-6} \text{ T}\cdot\text{m/A}), and R is in meters.

Derivation

Start with the formula for the on-axis field due to a single wire loop [1] (which is itself derived from the Biot-Savart law [2]):

B = \frac{\mu_0 I R^2}{2(R^2+x^2)^{3/2}}
Where:
\mu_0\; = the permeability constant = 4\pi \times 10^{-7} \text{ T}\cdot\text{m/A} = 1.26 \times 10^{-6} \text{ T}\cdot\text{m/A}
I\; = coil current, in amperes
R\; = coil radius, in meters
x\; = coil distance, on axis, to point, in meters

However the coil consists of a number of wire loops, the total current in the coil is given by

nI\; = total current
Where:
n\; = number of wire loops in one coil

Adding this to the formula:

B = \frac{\mu_0 n I R^2}{2(R^2+x^2)^{3/2}}

In a Helmholtz coil, a point halfway between the two loops has an x value equal to R/2, so let's perform that substitution:

B = \frac{\mu_0 n I R^2}{2(R^2+(R/2)^2)^{3/2}}

There are also two coils instead of one, so let's multiply the formula by 2, then simplify the formula:

B = \frac{2\mu_0 n I R^2}{2(R^2+(R/2)^2)^{3/2}}
B = {\left ( \frac{4}{5} \right )}^{3/2} \frac{\mu_0 n I}{R}

See also

References

  1. ^ Electromagnetism
  2. ^ "Earth Field Magnetometer: Helmholtz coil" by Richard Wotiz 2004

External links


This entry is from Wikipedia, the leading user-contributed encyclopedia. It may not have been reviewed by professional editors (see full disclaimer)

 
 

 

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