SE512822C2 - Electric system comprising at least one rotating electric machine and use of a rotating electric machine in an electrical plant - Google Patents

Abstract

An electric power plant comprises at least one rotating electric machine (G1), intended to be connected directly to a distribution or transmission network and comprising at least one electric winding. The winding comprises at least one electric conductor, a first layer with semiconducting properties surrounding the conductor, an insulating layer surrounding the first layer, and a second layer with semiconducting properties surrounding the insulating layer. Further, a brushless excitation system (1, 33, 34, 42, 44) is adapted to excite the electric machine.

Description

lO 15 20 25 30 512 822 2 similar to that of power transmission cables, the voltage of the machine may be increased to such levels that the machine can be directly connected to any power grid without intermediate transformer. The transformer can thus be excluded. Typical operating range for these machines is 30 - 800 kV.

The insulated conductor or high voltage cable used in the present This is described in more detail in PCT application SE 97/00874 and SE 97/00875. Further description of the insulated conductor or cable can be found in FCT applications SE 97/00901, SE 97/00902 and SE 97/00903.

According to a preferred embodiment of the invention, the isolated conductor is the cable or cable used in the installation so that the different layers in the beln adhere even when the cable is bent.

According to advantageous embodiments of the plant according to the invention the brushless magnetization system comprises a rotating part with a feeder, connected to rotating controllable semiconductor devices with associated control equipment for rectification of the obtained supply voltage for supplying the field winding of the machine and further, a communication unit is set up for wireless communication between a stationary regulator equipment and that included in the rotating part end control equipment. By using controllable semiconductor elements in this way improved regulatory properties are achieved by both positive and negative networking voltages can be achieved at the same time as the simple maintenance, which characterize brushless magnetization systems, are maintained. By magnetizing system can generate both positive and negative excitation voltage fast response and response times in the event of network disturbances.

According to other advantageous embodiments of the plant according to The feeder is made with double stator windings for feeding it as well the main electric machine as an auxiliary power machine. In this case, the stator windings are advantageously connected to their respective controllable semiconductor elements with their own control equipment. for individual control of the supply of the auxiliary power machine and the the main mask. Advantageously, the control equipment is arranged to generate control pulses to the controllable semiconductor elements on one, for variations in the supply the voltage to the main conductor elements self-compensating means. Flow changes necessary for voltage variations to adapt to the magnetization of the machine. lO 15 20 25 30 512 822 3 will therefore not affect the magnetization of a voltage regulator. machine for auxiliary power generation. By voltage regulation of the machine for auxiliary power generation, it is possible to keep the voltage at the auxiliary power rail and voltage increase to generate extra, temporary short-circuit power in case of error.

Brief description of the drawings To explain the invention in more detail now, as examples selected embodiments of the electrical system according to the invention to be described in more detail with reference to the accompanying drawings on which Figures 1 to 3 show diagrams of three different embodiments of the plant according to the excitement, Figure 4 shows an exemplary embodiment in more detail of the rotating part in the magnetization system in the embodiments according to fi g. 1 - 3, Fig. 5 illustrates a principle for reducing feed losses through demand adapted connection voltage to the controllable, rectifying semiconductor the elements in the form of a rotating thyristor bridge, Figure 6 illustrates a principle of self-compensating control pulse generation for control of the rectifying semiconductor elements, and Figure 7 shows in cross-sectional view the insulated conductor used in machines in the plant according to the invention.

Description of preferred embodiments Figure 1 shows a first embodiment of the electrical system according to the invention, including an electric machine G1 and an auxiliary power machine in the form of a permanent magnet generator G2. The machine G1 is magnetized with a mag- networking system comprising a rotating part 1 with a feeder G3, controllable rectifying semiconductor element in the form of a thyristor bridge 21 with control pulse generator 22, a bidirectional surge protector 24, and a rotating field winding 30 of the electric machine G1. Furthermore, the rotating part 1 contains a control device. equipment 23 for controlling the thyristor bridge 21 via the control pulse generator 22. The control equipment The connection 23 is also connected to current measuring means 25, 27 arranged on each ism 10 15 20 25 30 512 822 4 side of the thyristor bridge 21. An alter transformer 28 is connected between the supply the output side of the G3 and the control pulse generator 22 and the control equipment 23 for determine and turn the phase position for ignition of the thyristors in voltage matching purpose. Voltage variations can thus be compensated for by controlling the tyrist. the ignition.

The rotating part 1 of the magnetization system further comprises feed 26 for the electronic devices of the rotating part 1.

A bi-directional surge protector 24 serves as surge protector for the field winding 30 and diverts induced currents in the event of a fault. Surge voltage the cover 24 comprises a current-limiting resistor 34, which enables further operation with activated surge protection 24. Activated protection 24 is restored through temporary character change of the field voltage.

The control equipment 23 is further connected to a rotating communication device. wireless communication unit 29 with a stationary communication device unit 34, which in turn is connected to a controller equipment 33 for controlling the power stage formed by the thyristor bridge 21 and the control pulse generator 22 the controller equipment 33 via the control equipment 23. In this way, the magnetization of the skin G1 from the stationary regulator equipment 33 through regulation of the degree of equipment of the pier's 21 thyristors. j Other monitoring and control functions can also be performed from it stationary regulator equipment 33.

The signal transmission between the stationary and rotary communication the units 34, 29 can be made by means of frequency modulated infrared light. Each the unit 34, 29 is then provided with at least one transmitting and one receiving part, including a number of LEDs. The number of LEDs and the location of the rotating part 1 is such that no blind spots can occur between the transmitters and receiving units.

Alternatively, the communication between the stationary and rotary the communication units 34, 29 take place by capacitive or inductive means or by radio connection.

The rotary feeder G3 is of the synchronous machine type with a rotating stator winding, which is magnetized with a smaller static feeder, comprising current-rich 10 15 20 25 30 512 822 5 42 for feeding the stationary field winding 44. The static feeder is taken from the auxiliary power generator G2 and the excitation is controlled from the regulator equipment. 33 by controlling the supply voltage of the converter bridge 42. Food- voltage to the thyristor bridge 21, which in turn supplies the field winding 30, can thus be regulated by changing the magnetic fl fate in it rotary feeder G3.

The auxiliary power generator G2 further supplies a rail 36 for auxiliary power distribution. via an equipment 35 for voltage and possibly frequency adjustment.

The output voltage of the machine G1 is fed back to the regulator via a connection 46. equipment 33 for automatic adjustment of the rectifying semiconductor devices 21's connection voltage to current operating conditions.

By such demand-adapted control of the connection of the thyristor bridge 21 voltage, the losses in the rotary feeder G3 are reduced. When transient currents, you can increase the field voltage. Tranquility stability thus means low peak voltage factor and transient stability means high peak voltage factor.

The peak voltage factor can be som denied as the ratio between the maximum possible field voltage and the field voltage at rated load and hot field winding. Compare the writing of 5 gur 5 below.

Wd quiet operating conditions thus increase or decrease the voltage of the feeder G3. proportional to the setpoint input to the controller equipment 33. At transient stability and voltage regulation (the controller may alternatively be field current regulator) the supply voltage is increased to a maximum value until calm stability has been restored. Return to current voltage level for calm operation stability can then take place either momentarily or via a ramp function with enchanted rate of change. The control pulse generator 22, with the function of compensating at the ignition times of the thyristors 21 at voltage variations, the field current is maintained constant during the transition process.

Via a connection 48, the mains voltage can be returned to the regulator equipment. a 33 for use in phasing in machine G1.

Figure 2 shows an alternative embodiment, in which the auxiliary power generator G2 is a synchronous machine and the rotating part 1 comprises a feeder G3 in shape of a permanent magnet generator with double stator windings for magnetization 10 15 20 25 30 512 822 6 of the machine G1 and the auxiliary power generator G2 via each, in the rotating part 1 input thyristor bridge. Thus, in this embodiment, it comprises rotating part 1 and a unit 51 of a power stage, surge protection and control equipment for feeding the field winding 30 of the machine G1, and similar devices, re- presented by block 52 in Figure 2, for supplying the auxiliary power generator G2.

In the same way as the control equipment 23 for the magnetization of the main machine G1 is connected to a stationary controller equipment 53 via communication devices 29, 34 for wireless communication as described in connection with fi g. 1, is corresponding control equipment for the auxiliary power generator G2 magnetization connected to the controller equipment 53 via similar communication units 54, 57. In this embodiment, the regulator equipment 53 comprises two voltage regulators 58, 59 for constant maintenance of both the machine G1 and the auxiliary power generator G2 by magnetization control.

The permanent magnet generator G3 comprises a stationary permanent magnetic rotor 60, supplemented by some winding turns 61, which are fed via converter 62 from the auxiliary power generator G2 for controlled fl fate changes.

With such a permanent magnet rotor 60 fi there is always a field even at zero voltage.

The control pulse generation for the thyristor bridges is based on a principle for self-compensation for variations in the supply voltage of the thyristor bridges. Flow changes necessary for voltage variations to adapt to machine The magnetization requirement of the G1 will thus not affect the magnetization of the voltage-regulated auxiliary power generator G2. Voltage control of the auxiliary power generator G2 is made possible by the the gulator equipment53 includes the voltage regulator 58, which enables either constant voltage holding on the auxiliary power rail 36, ALT. 2, or voltage increase for temporary generation of additional short-circuit power in the event of a fault, ALT 1. Auxiliary the voltage of the power generator G2 is thereby increased by increasing its magnetization.

In the embodiment shown in Figure 2, the auxiliary power generator G2 is a crown machine, as mentioned above, of smaller size than machine G1. Also effective step 52 for feeding the field to the auxiliary power generator G2 is smaller than the corresponding power step 51 for feeding the machine's G1 field. 10 15 20 25 30 512 822 7 Other parts of the embodiment in fl g. 2 are identical to the corresponding parts in the embodiment shown in Figure 1 and is therefore not described in more detail.

Figure 3 shows another embodiment of the plant according to ningen. This embodiment differs from the embodiment shown in Figure 2 that the feeder G3 is of the type asynchronous machine with double rotor windings for magnetization of the machine G1 and the auxiliary power generator G2.

The G3 reverse rotation asynchronous machine works as one rotating transformer and also enables magnetization at standstill.

In addition to the above-described change of the feeder G3 is consistent this embodiment with that shown in Figure 2 and is therefore not described further here.

Figure 4 shows in more detail an embodiment of the rotating part 1 in the embodiments according to the preceding urer gures. The rotating part 1 comprises thus a part 71 for magnetizing and protecting the machine G1. Part 71 contains comprises a thyristor bridge 81 with control pulse generator 82, as described above, connected one to the output of a selector 83, which is arranged to select the smallest of an input signal in the form of a control signal from the controller equipment 93 (not shown), received over the wireless communication units 93, 94, and a signal from a regulated tower unit 85. This control unit 85 is arranged to receive one as input signals setpoint or limit value signal from the communication unit 93 and a signal representing the field current measured with the current measuring device 95 l field, for manual control or limitation of the field current.

A current measuring unit 86 is further connected to the communication unit 93 and to the current transformers 87 for measuring the alternating currents therefrom rotary feeder G3, in this case of permanent magnet generator type, and supply of corresponding measurement signals lr, ls, lt to the communication unit 93.

With the current measuring devices 95 resp. 86, 87 the current is measured at both as the AC voltage side and the differential current are used as a criterion for positioning of the surge protector 84, the reset taking place by means of a temporary negative excitation voltage.

A voltage measuring unit 89 is arranged with an alternator transformer 88, as described above, measure the voltage at the output of the rotary feeder G3 and output corresponding signals Ur, Us, Out to the communication unit 93. The of 10 15 20 25 30 512 822 the voltage signal sensed by the transformer 88 is also applied to the control pulse generator 82, where it is compared with the signal from the selector 83 to control the thyristor bridge 81 in the calming of this.

A further voltage measuring unit 70 is arranged to measure the field voltage. and give the corresponding measurement signal Off-field to the communication unit 93 for transmission to the stationary communication unit 94 and the controller equipment.

There is also a bi-directional surge protector 84 for the machine's G1 field winding 64 as previously described.

A unit 71 for detecting earth faults in the field winding 64 is further provided as well as a sensor 72 for measuring the temperature of the field winding 64.

Figure 4 further shows the permanent magnet rotor 60 of the feeder G3 with comm. plating winding 61, as described in connection with Figure 2, and feedback connection 46 from the machine G1 to the controller equipment and connection 48 to supply mains voltage measured with the controller equipment, as described in conclusion to 1 gur 1.

Figure 5 shows a diagram illustrating a principle solution for reducing supply losses through demand adjustment of the connection voltage to the rotary spirit thyristor bridge. U fl l0 denotes the field voltage at unloaded machine, U fl / 1 field voltage at rated load on the machine, Ufc maximum field voltage during quiet operation (quiet operating stability), Umm, maximum field voltage during transient operation (transient ), the connection voltage of the Uac thyristor bridge and Udc denote the current field voltage. ning = 1.35. Uac. cos a.

In the case of transient disturbances, the maximum field voltage Utopp is thus increased. at t1, as well as the peak voltage factor, as they finiered above. This way you get improved efficiency of the rotary feeder at stationary conditions.

Figure 6 illustrates in more detail the principle of self-compensating control pulse installation for the thyristor bridge at the plant according to the invention.

From the anslter transformer 88, the control pulse generator 82 is supplied with the phase voltages UR, US, UT, cf. 4 gur 4 and the upper curve in fi gur 6. An internal auxiliary voltage U + R, which is phase shifted 60 electrical degrees from the phase voltage UR, is generated. RE- The output signal UC of the yellowator 83, 85 in Fig. 4 is applied to the control pulse generator 82 and compared to a 10 15 20 25 512 822 comparator with the auxiliary voltage U + R and when the signal UC is equal to the auxiliary voltage the U + R and US are greater than UR, the ignition signal is given to the current thyristor in the S-phase in bridge 81 in 4 gur 4, marked in the lower part of fl gur 6, whereupon the thyristor intervals follow.

The ignition timing is thus partly controlled by the changes in the control signal UC, partly by changes in the signal level for the internal auxiliary voltage U + R.

To enable direct connection of the electrical machine and even the auxiliary power machine, as discussed earlier, the machines have windings comprising an isolated conductor of i fi g. 7 shown strokes. I fi g. 7, a cross-section is thus shown. sectional view of an insulated conductor 11 comprising a number of strands 35 with circular cross section of, for example, copper (Cu). These strands 35 are arranged in the middle of the insulated conductor 11. A first semiconductor is arranged around the strands 35 layer 13. An insulating layer is arranged around the first semiconducting layer 13 37 e.g. PEX insulation. A second semiconductor device is arranged around the insulating layer 37. The insulated conductor has a diameter in the range 20 - 250 mm and a wire area in the range 80 - 3000 mmz.

A number of modifications of the embodiments described above are self-explanatory. case possible. Thus, one can e.g. transform the phase mode of the converter closing voltage to the stationary side, which enables a stationary device control pulse generator and transmission of the starting time of the ignition pulses to the rotating one the part by wireless means, as described above. Furthermore, for example, the voltage of the rotating supply part is transformed into the rotating one the part using ring transformer. According to additional possible options can current, voltage and temperature measurement are realized using optical fi berteknik.

In the case of the insulated conductor or cable 11, the three layers 13,37,15 are so that they adhere to each other even when the cable is bent. This property is maintained the cable during its service life.

Claims (32)

10 15 20 25 30 512 822 10 PATENT REQUIREMENTS Electrical installation, comprising at least one rotating electrical machine, intended to be connected directly 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 self-conducting and an insulating layer enclosing the first layer, and a second layer having semiconducting properties enclosing the insulating layer, and a brushless magnetization system is provided to magnetize the electrical machine. Plant according to claim 1, characterized in that the potential on the first layer is substantially equal to the potential on the conductor. Plant according to claim 1 or 2, characterized in that the second layer is arranged to form substantially an equipotential surface, surrounding the conductor. Plant according to Claim 3, characterized in that the second layer is connected to a predetermined potential. Plant according to claim 4, characterized in that said predetermined potential is earth potential. Plant according to one of the preceding claims, characterized in that at least two adjacent layers of the winding of the mesh have substantially equal coefficients of thermal expansion. Plant 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 one another. 10 l5 20 25 30 512 822 Plant 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. Plant according to any one of the preceding claims, characterized in that said layers are arranged to adhere to each other even when the insulated conductor or cable is bent. Electrical system comprising at least one electrical machine of the AC 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 conductive conductor, each conductor having a plurality of strands, an inner semiconductor layer disposed around each conductor, an insulating layer of solid insulating material disposed around said inner semiconducting layer, and an outer semiconducting layer disposed around the insulating layer. , and that a brushless magnetization system is arranged to magnetize the electric machine. Plant according to claim 10, characterized in that said cable comprises a metal shield or sheath. Plant according to one of the preceding claims, characterized in that the brushless excitation system comprises a rotating part with a feeder, connected to controllable semiconductor elements with associated control equipment for rectifying the obtained supply voltage for supplying the field winding of the machine. Plant according to Claim 12, characterized in that a communication unit is arranged for wireless communication between a stationary regulator equipment and the control equipment included in the rotating part. Plant according to Claim 12 or 13, characterized in that the feeder is of the synchronous machine type with a rotating stator winding. 10 15 20 25 30 512 822 12 Plant according to Claim 12 or 13, characterized in that the feeder comprises a permanent magnet generator, in which stationary permanent magnets are supplemented by winding turns for controlled fl fate changes. Plant according to Claim 12 or 13, characterized in that the feeder comprises an asynchronous machine with three rotating windings and the reverse direction of rotation. Plant according to one of Claims 12 to 16, comprising a machine for auxiliary power generation, characterized in that the feeder is designed with double stator windings for feeding both the electric machine or the main machine and the auxiliary power machine. Plant according to Claim 17, characterized in that the stator windings are connected to separate controllable semiconductor elements, each with its own control equipment for individual control of the supply of the auxiliary power machine and the electrical machine. A system according to claim 17 or 18, characterized in that the control equipment is arranged to generate control pulses to the controllable semiconductor elements in a self-compensating manner for variations in the supply voltage to the semiconductor elements. Plant according to one of Claims 12 to 19, characterized in that the controllable semiconductor elements are arranged to form a thyristor bridge. System according to one of Claims 12 to 20, characterized in that an trlter-transformer is arranged to determine the phase position for ignition of the controllable semiconductor elements for voltage adaptation. 10 15 20 25 30 512 822 13 System according to one of Claims 13 to 21, characterized in that the communication unit comprises stationary transmitters and / or receivers in connection with the controller equipment and receivers and / or transmitters on the rotating part in connection with the control equipment for communication therebetween with frequency modulated infrared. light. Plant according to one of Claims 17 to 22, characterized in that the auxiliary power machine is arranged to feed the stationary field winding of the rotary feeder via a converter. Plant according to one of Claims 17 to 23, characterized in that the output voltage of the auxiliary power machine is connected via a regulator to the controllable semiconductor elements of the auxiliary power machine in order to regulate the voltage by excitation control. Plant according to one of Claims 13 to 24, characterized in that the stationary part and the rotating part of the communication unit are arranged for wireless communication by capacitive or inductive means or by radio connection or optical connection. Plant according to one of the preceding claims, characterized in that a unit is arranged to detect earth faults in the supply of the field winding of the electrical machine. Plant according to one of the preceding claims, characterized in that sensors are arranged to measure the temperature in the field winding of the electrical machine. System according to one of Claims 12 to 27, characterized in that surge protection controlled from the control equipment is connected across the field winding of the electrical machine. 10 15 20 512 822 14 Installation according to Claim 28, characterized in that current measuring means are arranged on the alternating and direct current sides of the controllable semiconductor elements and in that the overvoltage protection is arranged to be reset in response to the difference between these currents fulfilling a predetermined condition. Plant according to one of Claims 13 to 29, characterized in that the output voltage of the electrical machine is fed back to the regulator equipment for adapting the connection voltage to the current operating conditions. Plant according to any one of claims 17 to 30, characterized in that the auxiliary power machine comprises at least one electrical winding with at least one electrical conductor, a conductor enclosing, first layer with semiconducting properties, a first layer enclosing, insulating layer and an insulating layer enclosing those, other layers with semiconducting properties. Use of a rotary electrical machine in an electrical installation according to any one of the preceding claims, which machine is intended to be connected directly to a distribution or transmission network and comprises at least one electrical winding, which winding comprises at least one electrical conductor, a conductor enclosing first layer with semiconducting properties, a first layer enclosing insulating layer, and an insulating layer enclosing, second layer having semiconducting properties, and a brushless magnetization system for magnetizing the electric machine.