SE512721C2 - Rotary electric machine, machine comprising at least one rotating electric main machine and electric power plant comprising a rotating electric machine and method for magnetizing a rotating electric machine - Google Patents

Abstract

A rotary electric machine of alternating current type designed to be connnected directly to a distribution or transmission network comprises at least one electric winding. The winding comprises at least one electric conductor, a first layer with semiconducting properties surrounding the conductor, a solid insulating layer surrounding the first layer and a second layer with semiconducting properties surrounding the insulating layer. A brushless excitation system, switchable between positive and negative excitation, is also arranged for excitation of the machine. An electric power plant comprises such a rotary electric machine. In a method of exciting a rotary electric machine with both positive and negative excitation current direction, a two-way field over-voltage protection means (8, 10, 12, 14) or a two-way discharge circuit is connected temporarily across the field winding (4) of the machine.

Description

l lil Hi-im -... fl iamii thin 10 15 20 25 30 512 721 2 In the current situation, static feeders or brushless feeders with rotating diode rectifier bridges are used in rotating electrical machines. Frequent requirements for the excitation equipment are that it must be able to produce a peak voltage, and a peak current, which is 1.5 to 3 times as large as the corresponding quantities during rated load excitation for the machine in question for 10 - 30 seconds. Furthermore, the excitation equipment must be able to produce a field current corresponding to the rated load excitation current at 25% voltage on the stator socket of the machine. The magnetization system should preferably be "maintenance-free", i.e. a magnetization system without slip rings. Furthermore, response and response times in the event of network disturbances must be fast, ie. the excitation equipment must be able to generate both positive and negative field voltages. For synchronous compensators, it is added that the excitation system must be able to produce both positive and negative field current and the need for peak voltage factors greater than 3 times the rated load excitation voltage may occur.

With brushless feeders, the problems of soiling with carbon dust from brushes and slip rings are thus eliminated, while brushless feeders according to hitherto known technology show poorer control performance than static feeders.

The object of the present invention is thus to provide a rotating electric machine, which can be connected directly to the power grid and which is provided with a "maintenance-free" excitation system with improved control performance, and an electric power plant comprising such an electric machine, and to propose a method for magnetization of such a rotating electric machine.

Description of the object This object is achieved with a rotating electric machine of the kind initially stated with the features stated in claim 1, an electric power plant according to claim 17 and a method according to claim 18.

By providing the electric machine in question with a brushless, alternating magnetization system between positive and negative magnetization, it gets a "maintenance-free" system with fast response and turn-in times in the event of, for example, mains interference by the magnetization system producing both positive and negative field voltage . According to an advantageous embodiment of the machine according to the invention, the excitation system comprises two controllable, anti-parallel coupled device devices for supplying the field winding of the alternating current machine, a bidirectional field overvoltage protection or discharge circuit connection connected to the discharge circuit. or discharge circuit for controlling the converter device and field overvoltage protection in response to a control signal or discharge circuit for switching the magnetic current direction.

This is a simple design that does not require galvanically separated supply sources and current limiting reactances, nor separate short-circuiting devices for extinguishing and of conductive thyristors. The excitation system is also well suited for synchronous machines of the synchronous compensators type. In this invention, the possibilities of semiconductor technology for temporary polarity change are thus utilized in a simple manner, which facilitates rapid commutation of the field current from the converter bridge to the short-circuit circuit and vice versa if there is a need for a changed current direction in the machine's field circuit.

Brief Description of the Drawings In order to explain the invention in more detail, selected embodiments of the machine according to the invention will now be described in more detail, by way of example, with reference to the accompanying drawings, in which Figure 1 shows the insulated conductor used in the machine according to the invention. a diagram of the excitation system at the machine according to the invention, and Figure 3 af shows voltage and current courses during bridge changeover at the excitation system in fi g. 2.

Description of a Preferred Embodiment Figure 1 shows a cross-sectional view of insulated conductor 11 intended for use in the windings of the machine of the present invention. The insulated conductor 11 comprises a number of strands 35 with a circular cross section of, for example, copper (Cu). These strands 35 are arranged in the middle of the insulated conductor 11. Around ... ¿i. The strands 35 are arranged a first semiconducting layer 13. An insulating layer 37, Lex, is arranged around the first semiconducting layer 13. PEX insulation. Arranged around the insulation layer 37 is a second semiconducting layer 15. The insulated conductor has a diameter in the range 20 - 250 mm and a conduit area in the range eo - sooo mm? The three layers 13, 37, 15 of the insulated conductor or cable are designed so that they adhere to each other even when the cable is bent, and this property is retained by the insulated conductor or cable 11 during its service life.

Figure 2 shows a diagram of the excitation system in the machine according to the invention. The field winding 4 of the machine, which may be stationary or rotating, is connected to two antiparallal coupled converter bridges 1, 2. Above the field winding 4 is further a bi-directional overvoltage protection, comprising two antiparallel-connected thyristors 8, 10 with associated ignition circuits 12, 14.

The converter bridges 1,2 are fed from a supply source, at 16 and are controlled from a switching logic 18 via control pulse amplifiers 20, 22. A control pulse generator 28 for the converter bridges 1,2 designed as thyristor bridges is likewise arranged to deliver control pulses to the pulse amplifiers 20, 22. Measuring devices 24, 26 are further arranged to measure the currents IFB1 and IFB2, respectively, from the converter bridges 1 and 2, respectively, and to transmit the measurement results to the switching logic 18 for control purposes. The connection of the overvoltage protection thyristors 8, 10 is also controlled from the switching logic 18 via the ignition circuits 12, 14. The overvoltage protection is connected to a current limiting resistor R. In the system with field switches, this resistor R serves as a discharge resistor.

The procedure for switching from bridge 1 to bridge 2 is as follows. In the initial position, bridge 1 is assumed to be conductive, which means a positive current direction lF through the field winding 4, cf. fi g. 3a and b. The control signal Us ”see fi figure 2, to the control pulse generator 28 and the switching logic 18 becomes negative, which means downgrading and thus polarity change of the bridge 1, cf. fi g 3a. The time interval for the tuning down, tz -t1 according to fi gur 3b, from maximum positive peak voltage to maximum negative peak voltage is approximately equal to 8.3 ms at a frequency of 50 Hz and 6-pulse 2-way bridge. At the time ta, when the current IFS is still greater than 0, an ignition pulse is given to the discharge control resistor 10 and a blocking signal to the bridge 1. Due to the freewheel action in the event of negative control, an instantaneous transmission of the supply current IFB is effected to the surge protection circuit and the bridge 1 become de-energized. When a signal for an electroless bridge 1 from the measuring device 24 is initiated, both the unblocking of the bridge 2 and the blocking of the ignition circuit 14 for the thyristor 10 are initiated.

The time interval L, - ts according to fi gur 3, ie. the time from blocking the bridge 1 until the bridge 2 is switched on is approximately equal to 5 ms, see fi figure 3. Figure 3 shows that the current IF in the field circuit 4 is maintained during this changeover interval due to the inductance of the field winding 4. As can be seen from 3d gur 3d and e, the controlled bridge 2 now drives an IR current, see fi g. 3f, through the thyristor 10 and the current limiting resistor R and partly a current IF through the field winding 4 of the synchronous machine. At time ts the field current IF has changed polarity and the discharge thyristor 10 is extinguished by temporarily lowering the bridge 2, i.e. temporary polarity change to drive a current in the reverse direction of the short-circuit circuit or overvoltage protection.

By appropriate selection of current levels for generating blocking and detection signals, the time interval for switching on the double-directional field surge protection 8, 10, 12, 14 or bi-directional thyristor discharge circuit serving as auxiliary circuit becomes short-lived.

Switching from negative current direction to positive current direction in the case of a positive control signal takes place in a corresponding manner by temporarily connecting the thyristor 8 to the overvoltage protection.

Above, an exemplary embodiment of the rotating electric machine according to the invention has been described, but a number of modifications are of course conceivable within the scope of the invention. Thus, the described principle can be used for both stationary and rotating thyristor bridges for magnetizing synchronous machines or feeding motors for drive systems. Furthermore, temporary or pulsed downgrading can be used to restore an activated overvoltage protection. An overvoltage signal then gives a signal in the first stage for alarms and reset of the protection.

A continuous error signal after a number of reset attempts generates a trip signal. In addition, the insertion and use of extinguishing semiconductor devices can shorten the time interval for switching between positive and negative magnetization or vice versa. The introduction of extinguishing semiconductor elements in the bidirectional overvoltage protection means that temporary character reversal of the field voltage is not required to extinguish an activated and conductive semiconductor element.

Claims (18)

10 15 20 25 30 512 721 7 PATENT REQUIREMENTS Rotary electric machine of the AC type, intended to be directly connected to a distribution or transmission network and comprising at least one electrical winding, characterized in that the winding comprises at least one electrical conductor, a conductor enclosing the first layer with semiconducting properties, a the the first layer enclosing a solid insulating layer and a second layer enclosing the insulating layer with semiconducting properties and that a brushless, alternating magnetization system between positive and negative magnetization is arranged for the magnetization of the machine. Machine according to claim 1, characterized in that the potential of the first layer is substantially equal to the potential of the conductor. Machine according to claim 1 or 2, characterized in that the second layer is arranged to form substantially an equipotential surface, surrounding the conductor. Machine according to claim 3, characterized in that the second layer is connected to a predetermined potential. Machine according to claim 4, characterized in that said predetermined potential is ground potential. Machine according to one of the preceding claims, characterized in that at least two adjacent layers of the machine winding have substantially equal coefficients of thermal expansion. Machine according to one of the preceding claims, characterized in that the conductor comprises a number of strands, at least some of which are in electrical contact with each other. . Illli il-illil iuii .... 10 15 20 25 30 512 721 8 Machine according to any one of the preceding claims, characterized in that each of said three layers is fixedly connected to adjacent layers along substantially the entire abutment surface. Machine according to one of the preceding claims, characterized in that the layers are arranged to adhere to one another even when the insulated conductor or cable is bent. 10. A machine comprising at least one rotating main electrical type of the alternating current type, intended to be directly connected to a distribution or transmission network and comprising a magnetic core and at least one electrical winding, characterized in that the winding is formed by a cable comprising one or more current conductors, each conductor has a number of strands, an inner semiconducting layer arranged around each conductor, an insulating layer of solid insulating material arranged around said inner semiconducting layer, and an outer semiconducting layer, arranged around the insulating layer, and a brushless, between positive and negative magnetization interchangeable magnetization system is set up for the magnetization of the machine. Machine according to claim 10, characterized in that said cable comprises a metal shield or sheath. Machine according to one of the preceding claims, characterized in that the excitation system comprises two controllable anti-parallel converter devices (12) for supplying the field winding (4) of the alternating current machine, a bidirectional field overvoltage protection (8, 10, 12, 14) or discharge circuit the field winding and control equipment (18,28) connected to the converter device and field overvoltage protection or discharge circuit in order to control the converter device and field overvoltage protection or discharge circuit for switching the magnetic current direction in response to a control signal. 13. A machine according to claim 12, characterized in that for switching the magnetic current direction from the excitation system, the control equipment is arranged to change the polarity of the inverters, the control equipment controlling the overvoltage protection to be temporarily switched on when switching from one to the other current direction. . Machine according to claim 12 or 13, characterized in that the overvoltage protection or discharge circuit comprises a bidirectional thyristor discharge circuit (8, 10). Machine according to one of Claims 12 to 14, characterized in that activated overvoltage protection or discharge circuit can be reset by controlling conductive converter devices (1, 2) to a temporary or pulse-shaped polarity change. Machine according to one of Claims 12 to 14, characterized in that activated overvoltage protection or discharge circuit can be reset by extinguishing semiconductor elements. Electric power plant, characterized in that it comprises a rotating electric machine according to any one of claims 1 - 16. Method for magnetizing a rotating electric machine according to one of Claims 1 to 16 with both positive and negative magnetizing current direction, characterized in that a bidirectional overvoltage protection (8, 10, 12, 14) or a bidirectional discharge circuit is temporarily connected across the field of the machine. winding (4) when switching between the excitation current directions_