|
In AC electrical power systems, a synchroscope is a device that indicates the degree to which two systems (generators or power networks) are synchronized with each other.〔Terrell Croft, Wilford Summers (ed.), ''American Electricians' Handbook Eleventh Edition'', Mc Graw Hill, 1987 ISBN 0-07-013932-6 pp. 7-46 - 7-48〕 For two electrical systems to be synchronized, both systems must operate at the same frequency, and the phase angle between the systems must be zero (and two polyphase systems must have the same phase sequence). Synchroscopes measure and display the frequency difference and phase angle between two power systems. Only when these two quantities are zero is it safe to connect the two systems together. Connecting two unsynchronized AC power systems together is likely to cause high currents to flow, which will severely damage any equipment not protected by fuses or circuit breakers. ==Operating principles== The simplest aid to synchronizing a generator to another system uses lamps wired between similar phases of the two systems; when the lamps stay dark, the voltage and frequency of the two systems are the same and the generator may be connected. However, the accuracy of this approach is low since it is difficult to discern slight phase differences, and the lamps do not show the relative speeds of the two systems. Synchroscopes are instruments that show the relative frequency (speed) difference and the phase angle between the machine to be synchronized and the system voltage. Since most synchroscopes are connected only to a single phase of the two systems, they cannot assure that the phase sequence is correct. When generators are newly connected to a power system, or temporary connections are used, other means are required to assure both systems have the same phase sequence. Synchroscopes are electrodynamic instruments, which rely on the interaction of magnetic fields to rotate a pointer. In most types, unlike voltmeters and wattmeters, there is no restoring spring torque for the magnetically produced torques to overcome; the pointer system is free to rotate continually. Synchroscopes have a damping vane to smooth out vibration of the moving system. A polarized-vane synchroscope has a field winding with a phase-shifting network arranged to produce a rotating magnetic field. The field windings are connected to the "incoming" machine. A single-phase polarizing winding is connected to the "running" system. It is mounted perpendicular to the field winding and produces a magnetic flux that passes through the moving vanes. The moving vanes turn a shaft that carries a pointer moving over a scale. If the frequency of the source connected to the polarizing winding is different from the source connected to the field winding, the pointer rotates continually at a speed proportional to the difference in system frequencies (the beat frequency). The scale is marked to show the direction of rotation corresponding to the "incoming" machine running faster than the "running" system. When the frequencies match, the moving vanes will rotate to a position corresponding to the phase difference between the two sources. The incoming machine can then be adjusted in speed so that the two systems are in phase agreement. In the moving iron instrument, an iron vane is mounted on a shaft along with the pointer. The field winding is a three-phase winding, with the phases connected to both the running and incoming sources through a phase-shifting "impedor" network containing resistors, capacitors, and inductors. In this instrument, conceptually the field winding produces two rotating magnetic fields due to the running and incoming sources. The iron vane moves in response to the resultant sum of the two fields. The cross-coil synchroscope somewhat resembles a wound-field induction motor. A two-phase rotor winding is connected to the incoming machine source by a phase-shifting network through brushes and slip rings. The stationary field winding is connected to the incoming source. 〔 In a Weston pattern synchroscope, the moving element is not free to rotate continuously and oscillates back and forth slowly as the two sources are brought into synchronism. The moving pointer is illuminated by a pilot lamp connected to a three-winding transformer fed by both sources. The pointer is only illuminated at the in-phase condition, thereby distinguishing between in-phase and 180-degree out of phase conditions. All these instruments use single-phase connections to the running and incoming systems to simplify the wiring. For most systems, synchroscopes are connected through voltage transformers to reduce the machine voltage to around 120 volts to operate the instruments. Synchroscopes operate only over a limited range of frequencies, a few per cent above and below the system nominal frequency. Cross-coil type instruments draw a relatively large amount of power from the systems and are intended for only brief operation. The moving-iron and polarized-vane instruments put less burden on the system and can operate for a longer time without overheating. 〔 General Electric ''Electric Instruments Construction and Operating Principles'', General Electric Meter and Instrument Department, West Lynn, Mass. 1949, chapter 7 〕 Electronic digital systems can measure and display the phase angle difference directly. The display may be a ring of discrete LEDs arranged to simulate the effect of a pointer moving over a scale, with a different color of LED to indicate the "in phase" condition. These instruments may also have a relay contact for use by external control circuits, to indicate synchronism. 抄文引用元・出典: フリー百科事典『 ウィキペディア(Wikipedia)』 ■ウィキペディアで「Synchroscope」の詳細全文を読む スポンサード リンク
|