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Homopolar generator

A homopolar generator, also known as a Faraday disk, is a direct current (DC) electrical generator that produces a steady voltage by rotating a conductive disk or cylinder in a uniform static magnetic field perpendicular to its plane of rotation, generating an electromotive force (EMF) between the center (axle) and the periphery (rim) of the disk through electromagnetic induction.^[1]^[2]^[3] This device operates without commutators or windings, relying on the Lorentz force acting on charge carriers in the conductor to separate positive and negative charges radially, resulting in a low-voltage, high-current output that remains constant at fixed rotational speed.^[2]^[4] The homopolar generator was first demonstrated by Michael Faraday in 1831 as part of his pioneering experiments on electromagnetic induction, where he rotated a copper disk between the poles of a permanent magnet and detected a voltage using a galvanometer connected via sliding contacts (brushes) at the axle and rim.^[3]^[5] Earlier related concepts appeared in Peter Barlow's 1822 invention of the Barlow wheel, a homopolar motor using a star-shaped wheel in mercury contact with a magnetic field, which Faraday adapted inversely for generation.^[1] Faraday's work, detailed in his Experimental Researches in Electricity (1832), established the foundational law that a moving conductor cutting magnetic field lines induces an EMF proportional to the rate of flux change, laying the groundwork for modern electrical generators despite the device's initial limitations in voltage output.^[3] In operation, the generator's EMF arises from the motional electromotive force, calculated as the line integral ∮ (v × B) · dl around a closed path, where v is the velocity of the conductor, B is the magnetic field, and dl is an element of the path; alternatively, it follows Faraday's flux rule as -dΦ_B/dt, the negative rate of change of magnetic flux through the circuit, though the two approaches reconcile via specific rules for moving circuits.^[3]^[2] The design's simplicity—no iron cores, armatures, or alternating current rectification—allows for robust construction capable of handling megampere currents, but it produces only a single polarity of DC, limiting voltage to values like a few volts unless scaled with multiple disks or high speeds, and practical implementations face challenges from brush wear and eddy current losses.^[4]^[2] Homopolar generators find niche applications in high-power pulsed systems due to their ability to deliver enormous currents briefly, such as in railguns, explosive flux compression, and electrothermal-chemical guns, with notable examples including the Australian National University's machine (two 40-tonne rotors storing 500 MJ at 900 rpm for megampere pulses) and University of Texas devices for welding and pulsed lasers.^[2]^[4] Ongoing research addresses contact issues through innovations like plasma brushes to enable cold cathode operation and reduce losses, enhancing feasibility for industrial pulsed power supplies.^[4] Despite rare everyday use compared to multipolar alternators, the homopolar generator remains a fundamental demonstration of electromagnetic principles and inspires advancements in compact, high-energy-density power sources.^[2]^[3]

History

The Faraday disc

In 1831, Michael Faraday invented the first homopolar generator, known as the Faraday disc, during his investigations into electromagnetic induction. This device consisted of a copper disc, approximately 12 inches in diameter and 1/5 inch thick, mounted on a brass axle and rotated between the poles of a permanent horseshoe magnet. The magnet provided an axial magnetic field perpendicular to the plane of the disc, while mercury cups or a bath served as sliding contacts: one at the center (axis) for the stationary connection and another at the amalgamated rim for the peripheral contact. Wires from these contacts connected to a galvanometer, allowing measurement of the induced current.^[6]^[7] When the disc was spun by hand or mechanical means, it cut through the stationary magnetic field lines, generating a radial electromotive force that drove a continuous direct current (DC) from the center to the edge—or vice versa, depending on the direction of rotation and magnet polarity—without the need for a commutator. Faraday's experiments, detailed in his diary entry of October 28, 1831, and later published, produced measurable deflections on the galvanometer needle, reaching up to 90 degrees or more with rapid rotation, confirming the production of steady-state electricity from mechanical motion. This demonstrated electromagnetic induction in a continuous rather than transient form, aligning with Faraday's emerging laws that a changing magnetic flux induces an electric current.^[6]^[8]^[7] The Faraday disc marked a pivotal shift in early electromagnetism, moving from alternating currents induced by oscillating magnets to unidirectional DC output suitable for practical circuits, though still conceptual at the time. However, the design faced key limitations: the single-turn equivalent structure yielded low voltage outputs, often requiring fast rotation for detectable results, and contact resistance at the mercury interfaces reduced efficiency despite the liquid metal's conductivity. These challenges highlighted the need for stronger fields and better materials in future iterations.^[6]^[8]

Subsequent developments

Building on earlier concepts like Peter Barlow's 1822 homopolar motor (Barlow's wheel), which used a star-shaped wheel in mercury contact with a magnetic field, subsequent 19th-century refinements focused on adapting electromagnetic induction principles for more practical DC generation in homopolar configurations.^[1] Hungarian inventor Ányos Jedlik advanced homopolar concepts around 1859 by developing the "unipolar inductor," a commutator-free machine that generated smooth, uniform direct current through a rotating disc in a magnetic field.^[9] Jedlik's design emphasized the dynamo-electric principle without alternating currents, predating similar efforts by others and demonstrating the potential for continuous DC generation in a purely homopolar configuration.^[9] In the late 19th century, drum-type configurations, as patented by A.F. Delafield (US 278,516, 1883), emerged to address voltage limitations by extending the conductive path length within the magnetic field, enabling higher power outputs suitable for industrial applications.^[10]^[11] By the mid-20th century, particularly during and after World War II, these generators gained prominence in pulsed power systems, where their ability to store rotational energy in flywheels and deliver rapid high-current pulses proved valuable for military and research needs.^[12] Key patents and innovations further propelled the technology. In the 1960s, British electrical engineer Eric Laithwaite incorporated homopolar flux arrangements into oscillating synchronous linear machines, adapting the principles for motion in non-rotary formats and influencing transport applications.^[13] Post-2000 research has emphasized brushless designs to eliminate wear from traditional contacts, with developments like salient-pole brushless DC homopolar generators improving reliability and efficiency through optimized rotor structures.^[14] The transition to practical, high-performance devices involved material advancements to mitigate inherent low-voltage challenges. Enhanced conductors, such as copper alloys with reduced resistivity, combined with stronger magnetic fields from rare-earth permanent magnets and superconducting windings, have boosted output voltages and overall efficiency in modern iterations.^[12] These improvements, including ferrite magnets resistant to demagnetization, have made homopolar generators viable for demanding environments like propulsion systems.^[15]

Design and Operation

Disc-type generator

The disc-type homopolar generator, exemplified by the Faraday disc, features a rotating conductive disc typically constructed from copper or aluminum, mounted on a shaft and spun about its central axis within a uniform axial magnetic field produced by permanent magnets or electromagnets.^[16] Stationary brushes, such as liquid metal or carbon types, make sliding contact at the disc's inner axis and outer periphery to collect the generated current, forming the electrical terminals.^[16]^[4] In operation, the disc's rotation induces a radial motion of charge carriers in the presence of the axial magnetic field, resulting in charge separation via the Lorentz force and generating a direct current (DC) voltage between the brushes.^[4] The output voltage is proportional to the disc's radius, the rotational speed, and the strength of the magnetic field, producing a steady DC output without alternation.^[16] This configuration offers a simple mechanical design with no commutator required, yielding ripple-free DC output and compatibility with high rotational speeds, while liquid metal brushes minimize frictional losses.^[16] However, it is constrained by low output voltages, typically under 10 V due to the single radial current path, necessitating high currents for significant power delivery.^[4] Brush wear and eddy current losses further limit efficiency in prolonged use.^[4] Practical implementations include early laboratory demonstrations, such as Faraday's original 1831 experiment with a copper disc and horse-shoe magnet, and small-scale educational models using neodymium magnets for classroom voltage generation.^[16] Larger disc-type setups, like 10 kW systems employing mercury brushes, have been employed in research for pulsed power studies.^[16]

Drum-type generator

The drum-type homopolar generator consists of a hollow cylindrical rotor, typically constructed from conductive materials such as aluminum alloy (e.g., 6061-T6) or copper, rotating about its central axis within a radial magnetic field generated by electromagnets or permanent magnets.^[17]^[18] The cylinder, often supported by an air-bearing system to minimize friction and handle high speeds, features thin walls (e.g., 0.32 cm thick) and dimensions scalable to needs, such as 25 cm diameter and 12.7 cm length in experimental models.^[17] Multiple axial brushes, arranged in clusters (e.g., eight groups of four copper-carbon brushes), contact the cylinder's length to extract current, with designs incorporating liquid metal contacts like mercury for high-current applications up to 12,000 A.^[17]^[18] This configuration evolved from disc designs to enable axial current flow, addressing limitations in voltage scaling for higher-power systems.^[18] In operation, the rotating cylinder in the radial magnetic field (e.g., 1.05–1.5 T) experiences a Lorentz force on charges directed along its axial length, inducing a voltage proportional to the field strength, cylinder length, and peripheral velocity (design target of 305 m/s), with tested speeds up to 3500 rpm.^[17] This axial emf generation simulates multiple effective turns along the drum's length, yielding higher voltages compared to single-path disc types, making it suitable for continuous high-power output with energy storage capacities like 40 kJ at 2500 A peak current.^[18] Key advantages include voltage scalability by extending the drum length, which increases output without proportionally raising rotational speeds, and reduced peripheral velocity requirements for equivalent performance, mitigating issues like centrifugal stresses in large-diameter rotors.^[18] Additionally, the design supports higher current capacities (3–4 times that of disc types with similar magnets) and improved field uniformity through integrated magnet-rotor construction, enhancing efficiency in compact setups.^[18] Limitations encompass more intricate brush arrangements, which can lead to voltage drops due to resistance and mechanical binding under high pressure, necessitating modifications like air-jet loading or copper strip replacements.^[17] At elevated RPM, dynamical instabilities and non-uniform fields may induce eddy currents and torque imbalances, while high currents generate heating that requires compensatory structures to maintain magnetic integrity.^[17]^[18] Historically, drum-type generators were employed in 20th-century pulsed power systems, such as the 1970s Argonne National Laboratory models for tokamak fusion reactor ohmic heating coils, delivering 40 kJ cycles for energy buffering.^[17] Modern adaptations include compact industrial prototypes, like a 300 kW superconducting drum-type generator tested in 1996 with 230–330 V output at 1300 RPM using solid brushes and cryogenic excitation for enhanced efficiency.^[19]

Physics

Fundamental principles

The homopolar generator exemplifies electromagnetic induction via the steady rotation of a conductor in a uniform static magnetic field, in contrast to traditional generators that depend on time-varying magnetic flux through coils to induce EMF.^[20] Rather than flux changes, the device generates motional EMF from the conductor's motion perpendicular to the field lines.^[3] This process requires relative motion between the conducting material and the magnetic field as a fundamental prerequisite for operation.^[20] At the core of this mechanism is the Lorentz force exerted on free charges within the conductor, given by F = q(v × B), where q is the charge, v is the velocity imparted by the rotation, and B is the magnetic field strength.^[3] This force drives positive charges radially outward (or inward, depending on the field direction), creating charge separation that establishes an opposing electric field until equilibrium is reached, with the net EMF sustaining a current if the circuit is closed.^[21] The unipolar nature of the generator stems from the unidirectional magnetic field and consistent rotational motion, yielding a constant-polarity DC output without alternation, unlike AC generators.^[20] Apparent paradoxes, such as the Faraday paradox questioning whether a rotating magnet drags its field lines (and thus affects induction), are resolved by recognizing that magnetic field lines remain stationary relative to the lab frame regardless of magnet rotation; induction occurs solely due to the conductor's motion through the field.^[3] Special relativity provides further insight into this resolution, as the field transformation in the rotating conductor's frame introduces an effective electric field component E' ≈ v × B (in the low-velocity limit), consistent with the observed EMF across reference frames.^[3] For instance, a rotating conducting disc in an axial magnetic field illustrates how this relative motion generates a radial potential difference from center to periphery.^[21]

Mathematical formulation

The induced electromotive force (EMF) in a homopolar generator arises from the motional EMF due to the motion of charges in a magnetic field and is expressed in vector form as \varepsilon = \int (\mathbf{v} \times \mathbf{B}) \cdot d\mathbf{l}, where \mathbf{v} is the velocity of the conductor, \mathbf{B} is the magnetic field, and the integral is taken along the path of the circuit from one terminal to the other.^[20] This formulation assumes a uniform magnetic field \mathbf{B} perpendicular to the plane of rotation and a velocity \mathbf{v} perpendicular to both \mathbf{B} and the radial direction d\mathbf{l}.^[20] For a disc-type homopolar generator, consider a conducting disc of radius r rotating with angular velocity \omega in a uniform axial magnetic field B. The tangential velocity at radius \rho (where $0 \leq \rho \leq r) is v = \omega \rho, directed azimuthally. The Lorentz force on charges induces a radial electric field, with |\mathbf{v} \times \mathbf{B}| = \omega \rho B. Integrating along the radial path from the center to the edge yields the EMF:

\varepsilon = \int_0^r (\omega \rho B) \, d\rho = \frac{1}{2} \omega B r^2.

This derivation holds under the assumptions of uniform B across the disc and negligible self-inductance or relativistic effects.^[20]^[22] The electrical power output is P = \varepsilon I, where I is the current drawn by the external load, limited by the total circuit resistance R_\text{total} such that I = \varepsilon / R_\text{total}.^[23] The internal resistance of the disc contributes significantly and is approximated as R_\text{disc} = \frac{\rho}{2\pi t} \ln(r_\text{outer}/r_\text{inner}), where \rho is the resistivity and t is the disc thickness; for a full disc from center to edge (r_\text{inner} \to 0), this diverges, necessitating brushes or slip rings offset from the center.^[23] The mechanical torque required to maintain rotation is T = P / \omega, balancing the electrical power extracted (ideally, neglecting losses).^[20]^[23] Efficiency is reduced by losses, including ohmic heating in the disc and leads, contact resistance at brushes (which increases with velocity due to sliding effects), and eddy currents induced in the rotating conductor, approximated as F_\text{eddy} \propto \omega^{1.19} for opposing torque.^[20]^[23] Scaling laws show that voltage \varepsilon scales as \omega B r^2, while current capacity scales with disc thickness t and inversely with \rho, enabling high-power designs at the cost of increased mechanical torque.^[23] As a numerical example, for a disc of radius r = [1](/page/1) m rotating at 1000 RPM (\omega = 1000 \times 2\pi / 60 \approx 104.7 rad/s) in a uniform B = [1](/page/1) T field, the induced EMF is \varepsilon = \frac{1}{2} \times 104.7 \times 1 \times 1^2 \approx [52](/page/52) V.^[20]

Applications

Conventional and industrial uses

Homopolar generators found early applications in the 20th century through designs like the Forbes dynamo, which provided stable direct current (DC) output for various electrical equipment, including early welding systems, owing to their ability to produce low-voltage, high-current power without mechanical commutators.^[24] In industrial welding, homopolar generators power pulse resistance welding processes for thick metals, delivering rapid, high-energy pulses that create strong joints with minimal heat-affected zones and reduced distortion. This is particularly useful for applications involving large cross-sections, such as welding bridge flanges from high-performance steel or circumferential seams in pipelines, where welds on 1-inch-thick components can be completed in seconds, significantly shortening production times compared to traditional methods.^[25]^[26] In aviation, their high-speed, high-magnetic-field designs enable lightweight power generation for aircraft, improving overall system reliability in demanding operational conditions.^[27] In educational and laboratory settings, simple disc-type homopolar generators are widely used as teaching tools to illustrate Faraday's law of electromagnetic induction, often constructed from basic components like a rotating metal disc, magnets, and brushes to demonstrate continuous DC generation.^[28]^[29] A key advantage of homopolar generators in these conventional and industrial contexts is their high reliability in harsh environments, stemming from a robust, simple mechanical structure that eliminates commutators and associated sparking or wear, making them suitable for continuous operation under vibration or impact.^[30]^[31]^[32]

Pulsed power and advanced systems

Homopolar generators serve as critical pulsed power supplies in high-energy applications, including railguns, electromagnetic launchers, and plasma experiments, where they deliver transient currents up to 200 kA to support fusion research and high-pressure simulations.^[33]^[34]^[35] These systems leverage the generator's ability to store rotational energy in flywheels and release it rapidly through inductors, enabling multi-megajoule pulses for projectile acceleration and plasma confinement without the need for explosive flux compression.^[36]^[37] Drum-type configurations enhance scalability for such transient loads by increasing rotor surface area for higher current handling.^[38] Superconducting variants of homopolar generators employ high-temperature superconductors like REBCO to generate magnetic fields exceeding 10 T, achieving efficiencies over 97% in high-speed operations up to 10,000 rpm.^[39] Post-2020 ARPA-E-funded projects have advanced electron-transfer brushless designs, which eliminate mechanical contacts for 99% efficiency and 5-10 times higher power density, targeting aviation propulsion systems for hybrid-electric aircraft.^[27]^[40] These innovations support megawatt-scale outputs in compact forms, with prototypes demonstrating 5.5 MW at reduced weight for aerospace integration.^[41] As of 2024, research has advanced megawatt-class superconducting homopolar inductor machines specifically for aerospace applications, enhancing power density for propulsion systems.^[42] Conceptual designs as of October 2025 explore superconducting hydroelectric homopolar generators for high-power demands in aluminum smelters and large-scale hydrogen electrolyzers, supporting renewable energy integration.^[43] In industrial pulsed applications, homopolar generators enable large-scale resistance welding and metal forming by delivering megajoule pulses in seconds, a capability pioneered through 1950s developments in stored-energy systems.^[26]^[44]^[45] Homopolar pulse resistance welding (HPRW) heats thick sections without filler material, producing solid-state joints for pipelines and heavy structures, with pulses up to 5 MJ from upgraded systems.^[38]^[46] Recent advancements from 2020 to 2025 have focused on efficiency gains in homopolar motors and generators, such as integrating ferrite magnets into synchronous designs to boost output by 20-30% for passenger electric vehicles while reducing weight.^[47] These improvements facilitate renewable energy integration, particularly in wind power systems where high-efficiency homopolar machines enhance grid stability and emissions reduction.^[27] High-speed superconducting prototypes, including 30 kW units at 10,200 rpm, signal growing market potential for aerospace and EV applications, with global homopolar generator demand projected to expand due to their reliability in heavy-duty environments.^[48]^[49] Key challenges in these pulsed systems include optimizing flywheel energy storage for rapid discharge without structural failure and managing thermal buildup from high currents, which can degrade superconductors or bearings during megajoule pulses.^[50]^[51] Advanced cooling and material reinforcements address these issues, enabling sustained operation in demanding scenarios like fusion pulses or electromagnetic forming.^[52]

Astrophysical unipolar inductors

Planetary dynamos

Planetary dynamos exemplify natural unipolar inductors on a grand scale, where the rotation of conductive fluid layers within a planet interacts with its intrinsic magnetic field to generate electric currents. In Earth's case, the convective motion and rotation of the molten iron-nickel outer core, which is electrically conductive, operate akin to a homopolar generator, inducing currents that sustain the geomagnetic field and contribute to auroral phenomena through field-aligned currents flowing into the ionosphere. This process relies on the basic Lorentz force analogy, where charged particles in the rotating core experience a force perpendicular to both the velocity and the magnetic field, driving the inductive currents. For gas giants like Jupiter, the rapid rotation of their deep metallic hydrogen layers, combined with strong internal magnetic fields generated by convective dynamos, produces immense induced electromotive forces. Estimates suggest voltages on the order of 10^8 V across Jupiter's equatorial diameter due to this rotational unipolar induction, powering vast current systems that maintain the planet's powerful magnetosphere. Recent Juno mission data as of 2024 indicate mysterious waves propagating in Jupiter's deep interior, potentially modulating the dynamo action and induced EMFs.^[53] Similar mechanisms operate in other gas giants, such as Saturn, where the dynamo arises from helical convection in the interior, amplified by the planet's swift spin, leading to field strengths that dwarf those of terrestrial planets.^[54] Interactions with the solar wind further highlight planetary magnetospheres as dynamic homopolar setups, where the co-rotation of the ionosphere with the planet induces currents across the magnetic field lines stretched by external plasma flows. In Jupiter's magnetosphere, for instance, the rotating ionosphere acts as the conducting disk, coupling with the solar wind to drive azimuthal currents that enforce co-rotation of the magnetospheric plasma out to significant distances.^[55] This unipolar configuration results in energy transfer from the planet's rotation to the magnetosphere, sustaining plasma dynamics against solar wind drag. Observational evidence from spacecraft missions supports these models, particularly Voyager 1's detection of intense field-aligned currents, approximately 5 \times 10^6 A, associated with Io's interaction but indicative of broader Jovian current systems driven by unipolar induction.^[56] Theoretical frameworks further incorporate ohmic dissipation, where resistive heating in the conductive regions balances the inductive energy input, as modeled in numerical simulations of planetary interiors that reveal dissipation rates comparable to viscous losses in sustaining the dynamo.^[57] Unlike artificial homopolar generators, planetary dynamos operate at vastly larger scales—spanning thousands of kilometers—with self-sustaining feedback from thermal convection in the fluid core or metallic layers, which continuously regenerates the seed magnetic field against ohmic decay, a process absent in engineered devices reliant on external power.^[58] This convective drive ensures long-term stability over geological timescales, distinguishing natural systems by their integration of rotation, conduction, and buoyancy.

Stellar and cosmic examples

In stellar contexts, the Sun serves as a prominent example of a unipolar inductor, where its rotation in its own magnetic field generates large-scale induction currents estimated at 1.5 × 10⁹ A flowing from the polar regions. These currents produce azimuthal magnetic fields through the Lorentz force (J × B), which accelerates coronal plasma radially outward, contributing to the formation of the slow solar wind observed at speeds around 200–400 km/s near 1 AU during solar minimum. This mechanism overcomes solar gravity without requiring additional coronal heating, explaining the uniform, cool nature of the wind in low-latitude regions (0°–70° polar angle).^[59] Binary star systems provide another key stellar illustration, particularly close binaries consisting of a strongly magnetized white dwarf primary and a non-magnetic secondary, such as another white dwarf. The slight asynchronism between the primary's spin and the orbital motion induces an electromotive force, driving a current loop between the stars and enabling electric spin-orbit coupling that extracts rotational energy from the primary. This process can power observable phenomena like enhanced accretion or radio emissions, with the induced voltage scaling as V ≈ (B R² Ω)/c, where B is the primary's surface field (typically 10⁶–10⁹ G), R its radius, and Ω the angular velocity difference. Similar dynamics occur in neutron star-white dwarf or neutron star-neutron star binaries, where unipolar induction facilitates magnetic braking and gravitational wave-driven evolution.^[60]^[61] Pulsars, rapidly rotating magnetized neutron stars, exemplify unipolar induction on compact scales, with their magnetospheres functioning as electrical circuits powered by the rotation. The electromotive potential across the polar cap, approximated as V_{pc} \simeq B_0 R_0 (\Omega R_0 / c)^2 (with B_0 \sim 10^{12} G, R_0 \sim 10 km, and \Omega \sim 10^4 rad/s for millisecond pulsars), drives charge separation and currents near the Goldreich-Julian density, n_{GJ} \approx \Omega B / (2\pi e c). This setup creates parallel electric fields (E_\parallel) in dissipative regions, accelerating particles to relativistic energies and producing high-energy radiation such as gamma rays and pair cascades observed in pulsar wind nebulae.^[62] On cosmic scales, rotating galaxies can act as unipolar inductors, with the magnetized galactic disk generating large-scale currents analogous to the solar heliospheric circuit. The rotation induces an electromotive force that powers filamentary structures and double radio sources, where the galaxy's differential rotation in interstellar magnetic fields (B \sim 10^{-6} G) drives currents up to 10^{18} A, potentially explaining extended radio lobes and jets in active galactic nuclei. Hannes Alfvén proposed this model to unify electric currents across scales, from stellar to galactic, emphasizing the role of plasma circuits in cosmic energy transport. Black holes also manifest unipolar induction, particularly non-rotating (Schwarzschild) black holes moving through an ambient magnetic field, which induces surface charges and currents on the event horizon. This generates bipolar electromagnetic jets comprising counter-aligned current flows (totaling four streams), with power output comparable to gravitational wave emission during mergers, estimated at P_{EM} \sim (B^2 r_h^2 v)/c for horizon radius r_h and velocity v. In Kerr black holes with accretion disks, unipolar induction extracts rotational energy via frame-dragging, powering relativistic jets observed in quasars and gamma-ray bursts, where the induced EMF couples the disk's differential rotation to the hole's spin.^[63]^[64]

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homopolar generator
### Definition and Context of Homopolar Generator
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Homopolar generators for electric guns | Semantic Scholar
Low voltage homopolar generators combined with magnetic energy storage inductors were used to power several early experimental railguns.
[40]
[PDF] RAILGUN ENERGY STORES AND SYSTEMS
The single, pulsed homopolar generator-inductor- railgun system is well understood. It offers the means of imparting energies of multi-MJ to projectiles.
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[PDF] Five-Megajoule Homopolar Upgrade - DTIC
The machine proved very reliable and useful in a variety of applications, notably pulsed resistance welding, and was modified in 1978 to improve its ...Missing: 1950s discoveries
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High‐Efficiency Superconducting Homopolar dc Generators
Two designs for homopolar superconducting dc generators will be discussed and their performances reported on; both use permanent magnet and iron rotors. The ...
[43]
Dual Coil Superconducting AC Homopolar Machine for Turbo ...
May 7, 2025 · This homopolar generator has dual REBCO superconductor field coils, a mass-optimized rotor, and a rated power of 5.5 MW with 97.6% efficiency ...
[44]
High Speed Superconducting Machine for Aircraft Turbogenerator ...
Jul 27, 2024 · This paper presents design concepts for a high-speed homopolar generator using stationary superconducting REBCO excitation windings. The ...
[45]
Superconducting AC Homopolar Machines for High-Speed ... - MDPI
This paper presents a novel high-speed alternating current (AC) homopolar motor/generator design using stationary ReBCO excitation windings.
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[PDF] 19800024348.pdf - NASA Technical Reports Server (NTRS)
One of these machines, the 5 MJ homopolar generator, was designed and built in 1974 to explore further the electrical characteristics of this type machine when ...Missing: 1910s | Show results with:1910s
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https://www.mdpi.com/2076-3417/13/6/3990
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OTC 7814 Homopolar Pulse Welding for Offshore Deep ... - OnePetro
Homopolar pulse welding is properly classified as a resistance- ... homopolar pulse weld may be utilized to heat treat the weld and HAZ. ... 3, March 1950, pp. 211- ...
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Analysis of Performance Improvement of Passenger Car ... - MDPI
The purpose of the study is to increase the performance and reduce the weight and dimensions of synchronous homopolar generators for passenger cars operated on ...
[50]
Development of a 30-kW Class High-Speed Superconducting ...
Aug 8, 2025 · In this article, a 30-kW 10 200-r/min superconduct- ing homopolar generator prototype is designed to meet the high speed requirement of electric ...
[51]
Global and U.S. Homopolar Generators Market Report, Published
Oct 22, 2025 · https://www.qyresearch.com/reports/5184273/homopolar-generators. Core market data: Global market size: USD 408 million. CAGR (2024-2030): 5.1%
[52]
[PDF] An Integrated Flywheel Energy Storage System with a Homopolar ...
All three of these motor types, PM, SR, and homopolar inductor, share the advantage of high efficiency, however PM rotors tend to be more temperature ...Missing: limitations | Show results with:limitations
[53]
[PDF] Challenges and Solutions for the Use of Flywheel Energy Storage in ...
As most flywheels operate in a vacuum enclosure, thermal management of the rotor bearings is challenging. The ALPS flywheel for example relies solely on ...
[54]
Critical Review of Flywheel Energy Storage System - MDPI
This review presents a detailed summary of the latest technologies used in flywheel energy storage systems (FESS).
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Dynamo Action in the Steeply Decaying Conductivity Region of ...
Feb 24, 2019 · The analysis of our numerical simulations confirms that dynamo action in the SDCR is dominated by Ohmic dissipation. The magnetic field dynamics ...Missing: unipolar | Show results with:unipolar
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A model of Io's local electric field for a combined Alfvénic and ...
Jan 20, 2004 · This perturbation electric field maps into the ionosphere of Jupiter for the unipolar inductor model. Due to the dipole magnetic field ...
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Magnetic Field Studies at Jupiter by Voyager 1: Preliminary Results
We report on the analysis and interpretation of magnetic field perturbations associated with intense electrical currents (approximately 5 x 106 amperes) flowing ...
[58]
Scale separated low viscosity dynamos and dissipation within the ...
Aug 22, 2018 · In this dynamo dissipation is almost exclusively Ohmic, as in the Earth, with convection inside the so-called tangent cylinder playing a ...Force Balance · Dissipation · Governing Equations And...<|control11|><|separator|>
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Ohmic Dissipation - an overview | ScienceDirect Topics
Ohmic dissipation refers to the power dissipated in a core due to ohmic heating, which is critical for determining the operational capacity of a dynamo, ...
[60]
On the Causes of the Slow Solar Wind: 1. The Solar Unipolar ...
Jun 9, 2021 · In this paper, we suggest that the solar unipolar induction plays an important role in generating the solar wind. The solar unipolar induction ...Missing: inductor | Show results with:inductor
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An electrically powered binary star? - Oxford Academic
For a white dwarf atmosphere with Te∼105 K, the conductivity σ∼1013–1014 esu. Since the conductivities of the atmospheres of white dwarfs are similar to each ...
[62]
Astrophysical unipolar inductors powered by GW emission
The Unipolar Inductor Model (UIM from here on) has been originally proposed (Goldreich & Lynden-Bell 1969) for the. Jupiter-Io system to explain the origin of ...
[63]
None
### Summary: Pulsars as Unipolar Inductors and Particle Acceleration
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[1101.0639] Schwarzschild black holes as unipolar inductors - arXiv
Jan 4, 2011 · As a result, the black hole will generate bipolar electromagnetic jets each consisting of two counter-aligned current flows (four current flows ...
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Black hole electrodynamics: How does unipolar induction work in ...
This paper focuses on elucidating the basic underlying electrodynamic processes of extracting a Kerr hole's rotational energy through its own magnetosphere, as ...