Barlow's wheel

An 1842 diagram of Barlow's wheel

Barlow's wheel was an early demonstration of a homopolar motor, designed and built by English mathematician and physicist, Peter Barlow in 1822.^[1] An electric current passes through the hub of the wheel to a mercury contact on the rim; this is contained in a small trough through which the rim passes. Due to health and safety considerations brine is sometimes used today in place of mercury. The interaction of the current with the magnetic field of a U-magnet causes the wheel to rotate. The presence of serrations on the wheel is unnecessary and the apparatus will work with a round metal disk, usually made of copper.^[2]

"The points of the wheel, R, dip into mercury contained in a groove hollowed in the stand. A more rapid revolution will be obtained if a small electro-magnet be substituted for a steel magnet, as is shown in the cut. The electro-magnet is fixed to the stand, and included in the circuit with the spur-wheel, so that the current flows through them in succession. Hence the direction of the rotation will not be changed by reversing that of the current; since the polarity of the electromagnet will also be reversed."

(Excerpt taken from the 1842 edition of the Manual of Magnetism, page 94)^[3]

How The Wheel Moves

Action of a magnet on current and how rotational motion is produced due to this can be shown by Barlow's wheel experiment. The apparatus consists of a star shaped copper wheel capable of rotating freely in a vertical plane about a horizontal axis. The point of each spoke of the star just dips into a pool of mercury kept in a small groove on the wodden base of the apparatus. The pool of mercury is kept in between the two opposite poles of a strong magnet. The wheel rotates with its plane being perpendicular to the direction of the magnetic field and during its rotation only one point of the star dips into the pool of mercury at a time. When the axis of the wheel and the mercury are connected to electric cell, the circuit is completed through the axis of the wheel (when a point dips in the mercury) and the mercury. On passing current through the circuit the wheel will begin to rotate due to the action of the magnet on the current. The direction of rotation of the wheel can be determined by applying Fleming's left hand rule. While rotating and when a spoke of the wheel just leaves the mercury the circuit breaks but due to inertia of motion the wheel continues its motion and brings the next spoke in contact with the mercury thereby restoring the electrical contact. In this way rotation of the wheel continues. On reversing the direction of the current or that of the magnetic field the wheel rotates in the opposite direction. The speed of rotation depends upon the strength of the magnetic field and the strength of the current. Here mechanical energy is obtained from electrical energy.

References

↑ on Peter Barlow in the Encyclopedia of geomagnetism and paleomagnetism By David Gubbins, Emilio Herrero-Bervera ISBN 1-4020-3992-1, ISBN 978-1-4020-3992-8 (pp 44)
↑ 巴洛輪(Barlows wheel). YouTube. 5 June 2009.
↑ "Full text of "Davis's Manual of Magnetism: Including Also Electro-magnetism, Magneto-electricity, and Thermo ..."". archive.org.

External links

Wikimedia Commons has media related to Barlow's wheel.

Barlow's wheel designed by Eckling 1840 (German page)
Barlow's Wheel - Interactive Java Tutorial National High Magnetic Field Laboratory
5H40.50 BARLOW'S WHEEL

Electric motors

AC - Alternating current DC - Direct current PM - Permanent magnet SC - Self-commutated

Fundamental types	AC motor DC motor

DC motors	Homopolar Electrically-excited field or PM field brushed DC Unipolar

AC SC mechanical commutator	Repulsion Universal

AC SC electronic commutator	Brushless DC (BLDC) Switched reluctance (SRM)

AC asynchronous (induction (IM))	Shaded-pole (single-phase) Dahlander pole changing motor Squirrel-cage rotor (SCIM) Wound-rotor (WRIM) Linear induction

AC synchronous (SM)	Hysteresis Interior / Surface PM (IPMSM / SPMSM) Reluctance (SyRM) Wound-rotor (WRSM)

Special magnetic machines	Doubly-fed Linear Servomotor Stepper Traction

Non-magnetic	Electrostatic Piezoelectric Ultrasonic

Enclosure Type	Hermetic TEFC

Components and accessories	Armature Braking chopper Brush Commutator DC injection braking Field coil Rotor Slip ring Stator Winding

Motor controllers	AC/AC converter Amplidyne Adjustable-speed drive (ASD) Cycloconverter Direct torque control (DTC) Metadyne Motor controller Motor soft starter Motor starter (engine) Power inverter Thyristor drive Variable-frequency drive (VFD) Vector control Voltage controller Ward Leonard control

History, education, recreational use	Timeline of the electric motor Ball bearing motor Barlow's wheel Lynch motor Mendocino motor Mouse mill motor

Experimental, futuristic	Coilgun Railgun Superconducting machine

Related topics	Blocked-rotor test Circle diagram Closed-loop control Electromagnetism Open-circuit test Open-loop controller Power-to-weight ratio Torque and speed of a DC motor Two-phase system

People	Arago Baily Barlow Botto Cook Davenport Davidson Dolivo-Dobrovolsky Faraday Ferraris Froment Gramme Henry Jacobi Jedlik Lenz Maxwell Ørsted Park Pixii Saxton Siemens Sprague Steinmetz Stimpson Sturgeon Tesla

See also	Alternator Electric generator Inchworm motor

SI electromagnetism units	C - Capacitance (F) Q - Charge (C) G, B, Y - Conductance, susceptance, admittance (S) κ, γ, σ - Conductivity (S/m) I - Current (A) D - Electric displacement field (C/m²) E - Electric field (V/m) Φ_E - Electric flux (V·m) χ_e - Electric susceptibility U, ΔV, Δφ; E - Emf (V) L, M - Inductance (H) H - Magnetic field (A/m) strength Φ - Magnetic flux (Wb) B - Magnetic flux density (T) χ - Magnetic susceptibility μ - Permeability (H/m) ε - Permittivity (F/m) P - Power (W) R, X, Z - Resistance, reactance, impedance (Ω) ρ - Resistivity (Ω·m)

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