SU304890A1 - DEVICE FOR CONTROLLING ROTATING RECTIFIER - Google Patents

Description

The invention relates to electrical engineering.

The device is intended for use in brushless excitation systems of synchronous machines with rotating controlled semiconductor rectifier.

Incontactless devices for controlling a rotating rectifier, made in the form of an electric machine with mutually perpendicular excitation windings on the stator and the main winding on the rotor are known. With regard to large electric machines, they are of considerable size due to the need to use control pulse shaping units, the number of which is equal to the number of control valves.

To improve the shape of the control signal and reduce the size of the device, T-shaped poles have been installed on the rotor of the proposed electrical panel, the number of which is equal to or a multiple of the number of phases of the exciter.

To increase the control accuracy, the rotor can be enclosed in a cylindrical electrically non-magnetic screen, and in order to increase the strength of the device, tides are made at the rotor poles connected by insulating studs with pressure flanges fixed at the rotor ends.

FIG. 1 and 2 show the structure of a rotating control device.

respectively in transverse and longitudinal sections.

The stator of the device has a core /, which it is advisable to perform in order to improve speed) i not pole to improve the quality of angle control. In the slots of the core, the excitation windings 2 and 5 are electrically mutually perpendicular to each other, which, in order to improve the quality of the angle control

it is advisable to perform sinus. The number of pairs of poles of each winding is equal to the number of pairs of poles of the exciter.

The rotor has a laminated core 4, on which T-shaped poles with

the maximum possible width of the pole shoe 5 and the minimum possible technological and mechanical conditions are the core width 6. The number of poles of the rotor is equal to or a multiple of the number of phases of the driver. On the roiaria of the rotor are the coils 7, and the whole rotor is enclosed in a cylindrical e. Electroconductive non-magnetic shield 8. The core package is clamped between the flanges of a nonmagnetic material. The flanges have tides .9, tides at the poles of the rotor. The tides of the flanges and the package are fastened with W studs from isolates of the material. The rotor bag with flanges is closed by covers 11 of insulating material, in which conclusions 12 from the rotor coils 7 are mounted. The entire rotor structure is assembled on sleeve 13 and wall bolts 14. When the windings 2 and 5 are flown around by constant currents, the resultant is created, and magnetized, and the force sinusoidally distributed along the air gap, and an emf is induced in the rotor windings. a peaked shape determined by the core size of the pole shoe. In the pole bantmak, a considerable part of the flux created by the stator windings is collected, and in the thin kerpa the saturation quickly begins. Induced eddy currents in an electrically conductive screen of the rotor shield the rotor from zeros of toothed harmonics. This eliminates interference and increases the control angle of the control pulse. 4 Subject of the invention 1. A device for controlling a rotating rectifier of a brushless excitation system of electric synchronous mains, made in the form of an electric machine with mutually perpendicular excitation windings on the stator and with the main winding on the rotor, connected to the control value of the control of the rotating terminal, the exciter was different, the driver had a different pattern. that, in order to improve the shape of the control signal and reduce the overall dimensions of the device, T-shaped poles are installed on the rotor, the number of which is equal to or multiple of the phase tel. 2. The device according to claim 1, characterized in that, in order to improve the leveling accuracy, the rotor is enclosed in a cylindrical electronically conductive non-magnetic screen. 3. Device by n. 1, distinguished by the fact that, for the purpose of mechanical damage, the terminals of the rotor are made attached to the ends of the rotor, which are insulated with pressure flanges fixed to the ends of the rotor by means of insulation.