Circle diagram

Constant air-gap induction motor equivalent circuit

First conceived by A. Heyland in 1894 and B.A. Behrend in 1895, the circle diagram is the graphical representation of the performance of the electrical machine^[1]^[2]^[3] drawn in terms of the locus of the machine's input voltage and current.^[4] The circle diagram can be drawn for alternators, synchronous motors, transformers, induction motors. The Heyland diagram is an approximate representation of circle diagram applied to induction motors, which assumes that stator input voltage, rotor resistance and rotor reactance are constant and stator resistance and core loss are zero.^[3]^[5]^[6] Another common circle diagram form is as described in the two constant air-gap induction motor images shown here,^[7]^[8] where,

R_s, X_s: Stator resistance and leakage reactance
R_r^', X_r^', s: Rotor resistance and leakage reactance referred to the stator and rotor slip
R_c, X_m, : Core and mechanical losses, magnetization reactance
V_s, Impressed stator voltage
I₀ = OO^', I_BL = OA, I₁ =OV: No load current, blocked rotor current, operating current
Φ₀, Φ_BL : No load angle, blocked rotor angle
P_max, s_Pmax, PF_max, T_max, s_Tmax: Maximum output power & related slip, maximum power factor, maximum torque & related slip
η₁, s₁, PF₁, Φ₁,: Efficiency, slip, power factor, PF angle at operating current
AB: Represents rotor power input, which divided by synchronous speed equals starting torque.

The circle diagram is drawn using the data obtained from no load and either short circuit or, in case of machines, blocked rotor tests by fitting a half-circle in points O^' and A.

Beyond the error inherent in the constant air-gap assumption, the circle diagram introduces errors due to rotor reactance and rotor resistance variations caused by magnetic saturation and rotor frequency over the range from no-load to operating speed.

Constant air-gap induction motor circle diagram

References

↑ Behrend, B.A. (1921). The Induction Motor and Other Alternating Current Motors, their Theory and Principles of Design. McGraw-Hill. p. ix. Retrieved 4 January 2013.
↑ Heyland, A. (1894). "A Graphical Method for the Prediction of Power Transformers and Polyphase Motors)" (PDF). ETZ. pp. 561–564. Retrieved 4 January 2013.
1 2 Terman, Frederick Emmons; Freedman, Cecil Louis; Lenzen, Theodore Louis; Rogers, Kenneth Alfred (Jan 1930). "The General Circle Diagram of Electrical Machinery". 49. American Institute of Electrical Engineers, Transactions of the.
↑ S.K.Bhattacharya. Electrical Machines (2008 ed.). Tata McGraw-Hill Education. p. 359. ISBN 0-07-066921-X.
↑ Heyland, Alexander (1906). A Graphical Treatment of the Induction Motor. G.H. Rowe, R.E. Hellmund (trans.). McGraw Publishing Company. Retrieved 10 January 2013.
↑ Phase to Phase BV (2006). "The Asynchronous Motor Model" (PDF). pp. 5–6. Retrieved 10 January 2013.
↑ Alger, Philip L.; et al. (1949). "'Induction Machines' subsec. of sec. 7 - Alternating-Current Generators and Motors". In A.E. Knowlton (Ed.). Standard Handbook for Electrical Engineers (8th ed.). McGraw-Hill. pp. 710–711.
↑ Fernandez, Francis M. "Construction of Circle Diagram" (PDF). College of Engineering Trivandrum. Retrieved 10 January 2013.

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)

This article is issued from Wikipedia - version of the 10/28/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.

Circle diagram

See also

References