Abstract
This article proposes a new rotor interturn short circuit (RISC) fault analysis model for the electromechanical property study in synchronous generators. The specific novelty of this model lies in two aspects: First, It considers that most generators exist static air-gap eccentricity (SAGE), so it analyzes the RISC fault under normal and SAGE, making the model more versatile, and second, it takes into account not only the short circuit degree, but also the short circuit position, consequently it is more universal. By feeding the number of short circuit turns (denotes the short circuit degree), the angle between the two slots, where the short circuit takes place (denotes the short circuit position) and the detailed parameters of the generator into the model, the developing tendency of the key magnetic flux density (MFD)-based parameters can be conveniently predicted. The advantages of the proposed model primarily lie in the universality and the calculation speed. It can quickly evaluate the generator operating conditions. The phase current and the electromagnetic torque are selected in this article as the representatives of the electrical parameter and the mechanical parameter, respectively. Two-dimensional finite element analysis and experimental studies validate the proposed model.
Highlights
ROTOR inter-turn short circuit (RISC) is a common electrical fault for both motors and generators
For the mechanical characteristic based methods, the electromagnetic torque (EMT) technique is simpler than the rotor vibration means since EMT can be calculated via stator voltages, currents, and rotor speeds [21]-[22]
Based on (17) the developing tendencies of Fd1 and Fd2 with 10% RISC due to varied short circuit positions are shown in Fig.5 (a)-(b), where the normal rotor magneto-motive force (MMF) is set as the reference
Summary
ROTOR inter-turn short circuit (RISC) is a common electrical fault for both motors and generators. It can be caused by many factors such as the mutual extrusion, insulation shift/distortion due to centrifugal forces, thermal deformation and local overheating of field windings, etc. For the mechanical characteristic based methods, the electromagnetic torque (EMT) technique is simpler than the rotor vibration means since EMT can be calculated via stator voltages, currents (power of the machine), and rotor speeds [21]-[22]. This paper proposes a novel hybrid model which takes into account the ubiquitous SAGE, and can manage the impact of the short circuit degrees, and the influence of the short circuit positions.
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