DE3218033A1 - Synchronous motor which is energised without sliprings - Google Patents

Abstract

In the case of a synchronous motor which is energised without sliprings via rotating energising rectifiers, a series circuit composed of two thyristors connected in the forward direction of the energising current is provided in parallel with the energising winding in order to provide protection against the rotor AC voltage which is induced during the asynchronous acceleration. These thyristors are triggered (turned on) as a function of voltage by a triggering device (14). The triggering device (14) has two unbalanced branches (21, 22). The first branch (21), which is connected to the control electrode of the thyristor connected to the negative terminal, has (after a diode (23)), one or more series circuits (25, 26, 27) composed of in each case one auxiliary thyristor (28) with a zener diode (29) in the control circuit, and has voltage-dependent resistors (30). The second branch (22), which is connected to the control electrode of the thyristor which is connected to the positive terminal of the energising winding, consists of a series circuit composed of a diode (24) and voltage-dependent resistors (34). The value of the response voltage of the voltage-dependent resistors (34) in the second branch (22) is less than the value of the response voltage of the voltage-dependent resistors (30) which are contained in the corresponding series circuit (25, 26, 27) in the first branch (21). <IMAGE>

Description

Synchronous motor excited without slip rings

The invention relates to a synchronous motor excited without slip rings, in which the rotating three-phase winding of the outer pole synchronous EI exciter machine feeds the excitation winding via a rotating rectifier, the excitation winding a series connection of two thyristors polarized in the forward direction of the excitation current is connected in parallel, the connecting line with a connection of the three-phase Winding of the outer pole synchronous exciter machine is connected, and in which between the positive pole of the excitation winding and the control electrodes of the thyristors depend on the voltage igniting ignition device is connected, which consists of two branches with auxiliary thyristor and series-connected diodes and resistors, as well as Zener diodes in the control circuit of the auxiliary thyristor, the diodes and the auxiliary thyristor also in the forward direction the field winding are polarized.

Such a synchronous motor excited without slip rings is from DE-PS 15 63 323 known. The series connection of the two thyristors serves as protection against that during the asynchronous self-start of the synchronous motor in the field winding Induced alternating voltage that drives an alternating current through the rotor circuit tries. The current during the voltage half-wave in the direction of flow of the valves of the Rectifier flows through the rectifier. The current in the opposite direction The voltage half-wave is short-circuited via the series connection of the thyristors, if their ignition device is ignited depending on the voltage, what happens at voltage values that otherwise the valves of the rectifier through would endanger the resulting overvoltage. This protection is also with eventual occurring correspondingly high interference voltages are effective.

The problem arises that the ignition energy of the alternating rotor voltage or the interference voltage must be taken. Change during asynchronous startup However, with the speed, the voltage and the frequency in the rotor circuit and thus also the conditions for the ignition device constantly.

In the known synchronous motor excited without slip rings Ignition device made up of two identical branches, each between the positive pole the excitation winding and the control electrode of the thyristors.

Each branch contains a series connection of one with the positive pole auxiliary thyristor connected to the excitation winding, a resistor and a diode, which leads to the control electrode of the thyristor. Between the control electrode of the auxiliary thyristor and the positive pole of the field winding also has one or more Zener diodes. With the choice of the Zener voltage of the Zener diodes, the voltage at the thyristors can be selected at the point of ignition. The response voltages of the zener diodes are like this selected high so that triggering of the thyristors is excluded in normal operation.

The known ignition device works as follows: When the im The voltage occurring in the rotor of the synchronous motor is the response voltage of the first Zener diode exceeds, this ignites its auxiliary thyristor and thus the first Rail circuit thyristor. D3 by the current of the auxiliary thyristor to the one in this Branch of the ignition device located resistance a voltage drop occurs, ignites now the second Zener diode and thus the second auxiliary thyristor and the second thyristor the series connection, so that the current generated by the induced voltage changes can close via the series connection. Due to the chronological sequence of the Ignition must be the resistance through which the ignition current of the first thyristor flows, be high in terms of performance to the power loss generated in it during of the ignition process.

The invention is based on the object of the ignition delay between reduce the two thyristors of the series connection and thus the ignition process to reduce power loss occurring in the resistor.

To solve this problem is a synchronous motor excited without slip rings of the type described at the outset, the ignition device according to the invention is designed in such a way that that the two branches of the ignition device are asymmetrical, that the one with the control electrode of the thyristor connected to the negative pole of the exciter winding one or more series circuits of one auxiliary thyristor each after a diode and voltage-dependent resistors and with the control electrode of the a thyristor connected to the positive pole of the exciter winding Series connection of a diode with voltage-dependent resistors and that the value the response voltage of the voltage-dependent resistors in the second branch is lower than the value of the response voltage in the corresponding series connection of the voltage-dependent resistances contained in the first branch.

Such an asymmetrically constructed ignition device Has the advantage that the use of voltage-dependent resistors in both branches upon ignition of the auxiliary thyristor in the first branch through response of the Zener diode in its control branch, after which the full voltage is only applied to the voltage-dependent Resistances this branch lies, through the shift of the working point of the voltage-dependent Resistances according to their characteristic immediately in the first branch a substantial higher current flows through the control electrode to the first thyristor of the series circuit ignites. Then there are the cathodes of the two thyristors in the series connection at about the same potential, which means that now also the voltage-dependent Resistors of the second branch are connected to the entire voltage and immediately the Supply ignition current for the second thyristor of the BeXhenschaltung, so that this also is ignited. Due to the high response speed of the voltage-dependent resistors the ignition delay of the second thyristor is reduced very far compared to the first, what for the first branch of the ignition device, the one until the ignition of the second thyristor conducts the grid current of the first thyristor, which means rapid discharge.

In addition, the asymmetrical ignition device has the advantage of that they have small tensions, which because of their low energy content do not have the ability have to ignite the thyristors in the series circuit, because then the corresponding circuit via the Zener diodes or the auxiliary thyristor and the voltage-dependent resistors of the first branch closes.

The ignition level of the first branch of the ignition device is adjustable and determined by the voltage-dependent resistors and the Zener diodes. It it is recommended to use several TReXh circuits of auxiliary thyristors and voltage-dependent Resistances in the first branch between these and at corresponding Place the second branch between the voltage-dependent resistors taps to be provided. By appropriately connecting these taps of each branch with one another the ignition level can then be adjusted in a simple manner.

In the following the invention is still based on the in FIGS. 1 and 2 Ausfühungs shown in the drawing, for example, explained in more detail. Fig. 1 shows a circuit diagram of the synchronous motor excited without slip rings, FIG. 2 shows a Circuit diagram of an ignition device designed according to the invention.

The synchronous motor 1 excited without slip rings receives the for its excitation necessary direct current via rotating field rectifier 2, which his field winding 3 dine. The exciter rectifier 2 are in turn via the rotating, three-phase Alternating current winding 4 of the external pole synchronous exciter 5 with alternating current fed. The excitation winding 6 of the external pole synchronous excitation machine 5 is in their Stand arranged.

The synchronous motor 1 is activated by connecting its stator winding 7 switched to the network, not shown, and runs up asynchronously until he has the Synchronism achieved and falls into step. As protection during asynchronous self-start of the synchronous motor 1 is parallel to the rotating field rectifiers 2 and the excitation winding 3 is a series connection of two in the forward direction of the excitation current polarized thyristors 8, 9 are provided, the connecting line 10 via the line 11 with a connection 13 of the three-phase winding 4 of the external pole synchronous excitation machine 5 is connected. The ignition of the two as protection for the excitation rectifier 2 thyristors 8 serving during the asynchronous start-up of synchronous motor 1, 9 takes place with the aid of the ignition device 14, which is connected on the one hand via the connection 15 with the positive pole of the excitation winding 3 and on the other hand via the connection 16 with the control electrode 17 of the thyristor 8 and via the connection 18 to the control electrode 19 of the thyristor 9 is connected.

The ignition device 14 is divided behind one after the connection 15 lying, in the forward direction of the excitation current polarized diode 20 in two, asymmetrical built branches 21, 22, of which the first branch 21 for triggering the thyristor 8 and the second branch 22 is used to ignite the thyristor 9 of the series circuit. Behind the diode 20 are again in both branches 21, 22 in the forward direction of the excitation current polarized diodes 23, 24. However, this circuit can also be used to that effect change so that instead of one diode 20 two parallel diodes are used, so that the branches 21, 22 already share immediately behind the connection 15.

The first branch 21 consists of three series connections 25, 26, 27 with in each case one auxiliary thyristor 28 polarized in the forward direction of the excitation current, in the control circuit of which there is a Zener diode 29, and two connected in series voltage-dependent resistors 30. Between the series circuits 25, 26, 27 are Taps 31, 32 provided, and another tap 33 between the last Series circuit 27 and the connection 16. The second branch 22 of the ignition device 14 has between the diode 24 and the terminal 18 only series-connected voltage-dependent Resistors 34, each in groups of two successive voltage-dependent Resistors 34 are combined and between which taps 35, 36 and still a tap 37 located in front of the connection 18 are provided.

The response values of the voltage-dependent resistors 30 of the first Branch 21 and that of the voltage-dependent resistors 34 of the second branch 22 of the ignition device 14 are selected so that in each case the sum of the response values of the voltage-dependent resistors 30 of a series circuit 25, 26, 27 are higher than the sum of the response values of the corresponding assigned voltage-dependent Resistors 34 in the second branch 22. The taps 31, 32, 33 of the first branch and the corresponding taps 35, 36, 37 of the second branch 22 can total or in part, but in each case in the same way connected to one another to a To get setting of the ignition level.

The ignition device 14 acts as follows: During the asynchronous Acceleration of the synchronous motor 1 in the field winding 3 induced alternating voltage tries to drive a current through the rotor circuit of synchronous motor 1. Of the Current during the voltage half-wave in the forward direction of the valves of the exciter rectifier 2 flows via the exciter rectifier 2. In the other half-wave of the rotor alternating voltage, which corresponds to the forward direction of the diodes 20, 23, 24 and also that of the auxiliary cathyristors 28, a small current initially flows with the increase in the voltage half-wave Via the Zener diodes 29 in the first branch 21 of the ignition device 14 Voltage half-wave the range of the set ignition level, which is determined by the voltage-dependent Resistors 30 and the Zener diodes 29 in the first branch 21 is determined, so increases the current immediately so far until the auxiliary thyristors 28 are ignited. In the same At the moment, the entire voltage is only applied to the varistors 30 of first branch 21, which immediately changes according to its characteristic curve by shifting its Working point lead the higher current and thus via the control electrode 17 the Ignite thyristor 8. Then the cathodes of both thyristors 8, 9 are on approximately the same potential, means that now also the voltage-dependent resistances 34 of the second branch 22 are connected to the entire voltage and immediately the ignition current for the thyristor 9, so that this is also ignited. By the high The response speed of the voltage-dependent resistors 30, 34 is the ignition delay very much reduced between the ignition of the thyristor 8 to the ignition of the thyristor 9, so that the current-carrying time of the first branch 21 of the ignition device 14 is very is short.

Through the connecting line 11 between the connection 10 between two thyristors 8 and 9 and the terminal 13 of a phase of the alternating current winding 4, the thyristors 8, 9 after each start-up when the synchronous motor starts 1 finally deleted, so that the arrangement can be used again for the next start-up of is ready for operation again. This also prevents the subsequent operational Excitation current flows through the series connection of the thyristors 8, 9.

2 claims 2 figures

Claims (2)

Claims slip ring-less excited synchronous motor in which the rotating three-phase winding of the external pole synchronous exciter machine via a rotating rectifier feeds the field winding, the field winding a series connection of two thyristors polarized in the forward direction of the excitation current is connected in parallel, the connecting line with a connection of the three-phase Winding of the outer pole Synchlr-on ~ exciter machine is connected and in which between the positive pole of the excitation winding and the control electrodes of the thyristors depend on the voltage igniting ignition device is connected, which consists of two branches with auxiliary thyristor and series-connected diodes and resistors, as well as Zener diodes in the control circuit of the auxiliary thyristor, the diodes and the auxiliary thyristor also in the forward direction of the excitation winding are polarized, that is, that the two branches (21,22) of the ignition device (14) are asymmetrical that the one with the control electrode (17) of the thyristor located on the negative pole of the excitation winding (3) (8) connected first branch (21) after a diode (23) one or more series connections (25,26,27) each of an auxiliary thyristor (28) and voltage-dependent resistors (30) and with the control electrode (19) of the thyristor connected to the positive pole (9) connected second branch (22) a series connection of a diode (24) with voltage-dependent Resistors (34) and that the value of the response voltage of the voltage-dependent Resistors (34) in the second branch (22) lower than the value of the response voltage that contained in the corresponding series connection (25,26,27) of the first branch (21) voltage-dependent resistors (30) is. 2. slip ring-less excited synchronous motor according to claim 1, d a d u r c h g e k e n n n n z e i c h n e t that with several series connections (25,26,27) of auxiliary thyristors (28) and voltage-dependent resistors (30) in the first branch (21) between these and at corresponding points of the second branch (22) between the voltage-dependent resistors (34) taps (31,32,33; 35,36,37) are provided are.