Booster (electric power)

A booster was a motor-generator (MG) set used for voltage regulation in direct current (DC) electrical power circuits. The development of alternating current and solid-state devices has rendered it obsolete. Boosters were made in various configurations to suit different applications.

Line booster

In the days of direct current mains, voltage drop along the line was a problem so line boosters were used to correct it. Suppose that the mains voltage was 110 V. Houses near the power station would receive 110 volts but those remote from the power station might receive only 100 V so a line booster would be inserted at an appropriate point to "boost" the voltage. It consisted of a motor, connected in parallel with the mains, driving a generator, in series with the mains. The motor ran at the depleted mains voltage of 100 V and the generator added another 10 V to restore the voltage to 110 V. This was an inefficient system and was made obsolete by the development of alternating current mains, which allowed for high-voltage distribution and voltage regulation by transformers.

Milking booster

Again in the days of direct current mains, power stations often had large lead-acid batteries for load balancing. These supplemented the steam-powered generators during peak periods and were re-charged off-peak. Sometimes one cell in the battery would become "sick" (faulty, reduced capacity) and a "milking booster" would be used to give it an additional charge and restore it to health. The milking booster was so-called because it "milked" the healthy cells in the battery to give an extra charge to the faulty one. The motor side of the booster was connected across the whole battery but the generator side was connected only across the faulty cell. During discharge periods the booster supplemented the output of the faulty cell.^[1]

Reversible booster

Before solid-state technology became available, reversible boosters were sometimes used for speed control in DC electric locomotives. To avoid confusion, it should be explained that it is the electrical output of the booster that is reversible, not the direction of rotation.

The motor of the MG set was connected in parallel with the supply, usually at 600 volts, and was mechanically coupled, via a shaft with a heavy flywheel, to the generator. The generator was connected in series with the supply and the traction motors, and its output could be varied between +600 volts, through zero, to -600 volts by adjusting switches and resistors in the field circuit. This allowed the generator voltage to either oppose, or supplement, the line voltage. The net output voltage could therefore be varied smoothly between zero and 1,200 volts as follows:

Generator producing maximum opposing voltage, net output zero volts
Generator producing zero volts, net output 600 volts
Generator producing maximum supplementary voltage, net output 1,200 volts

To match the 1,200 volt output, the locomotive would have three 400 volt traction motors connected in series.^[2] Later locomotives had two 600 volt motors in series.

When the locomotive was working at full power, half the energy came through the MG set and the other half came directly from the supply. This meant that the power rating of the MG set needed to be only half the rating of the traction motors. Thus there was a saving in weight and cost compared to the Ward Leonard system, in which the MG set had to be equal in power rating to the traction motors.

If the power supply to the locomotive was interrupted (e.g. because of a gap in the third rail at a junction) the flywheel would power the MG set for a short period to bridge the gap. During this period, the motor of the MG set would temporarily run as a generator. It was this system that was used in the design of British Rail classes 70, 71 and 74 (Class 73 does not utilise booster equipment).

Metadyne

Some types of London Underground stock (e.g. London Underground O Stock) were fitted with Metadynes.^[3] These were four-brush electrical machines which differed from the reversible boosters described above.

References

↑ Elliott, T. C., Electric Accumulator Manual, George Newnes Ltd, London, 1948, page 29
↑ Cooper, B. K., Electric Trains and Locomotives, Leonard Hill Ltd, London, 1954, pp 35–38
↑ Cooper, B. K., Electric Trains and Locomotives, Leonard Hill Ltd, London, 1954, page 38

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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