DE608789C - Device for the automatic starting of synchronous machines, especially synchronous motors - Google Patents

Description

Device for automatic starting of synchronous machines, - in particular Synchronous Motors The invention relates to. on starting devices for synchronous machines, especially for synchronous motors, in which the individual during the starting process control processes to be triggered are monitored by timing relays. The essential Features of the invention will be described in more detail below using an exemplary embodiment explained: The illustration shows a circuit diagram for a starting device with the a synchronous motor i, which can be connected to a three-phase network RST, automatically both from standstill after. Actuation of an anywhere Control switch as well as during operation or restarted can be if the motor for any reason, for example due to overload, has fallen out of step.

The motor r is connected to the network RST by a main switch 2. This is controlled by a switch 3, which is connected to any one in the Can be close to or remote from the engine control station and appropriate is designed as a push button switch. Another control switch is used for switching off ¢. The main switch is equipped with contacts 21 and 22, which are switched off States of the switch are open. The push-button switch becomes through the contacts 2 i 3 bridged and the excitation coil of switch 2 closed; held. The contacts 22 are in the circuit of a battery i i, which provides the DC excitation for the Excitation winding io of the synchronous motor i supplies. Instead of the battery i i can of course also other energy coils, for example; wise one from the synchronous motor self-propelled exciter. During the start is the Excitation winding io is not connected to battery ii, but via a starting resistor, 12 short-circuited, the current flowing in the field winding io during the asynchronous starting to: a certain, permissible for the excitation winding Limited value. A regulating resistor 13 is also located in the circuit of the battery i i. To switch on the excitation and to interrupt the parallel connection of the resistor 12 is a switch 5. This switch is equipped with contacts 51 and 52, of which the contacts 52 are closed when the switch 5 is switched off and contacts 5 1 are open. The excitation winding 5o of the switch 5 is connected to phases S and T of the three-phase network. Your circuit is through the Control switch 3 prepared.

To monitor the starting process of the synchronous motor i are used according to of the invention three timing relays 6, 7 and B. These timing relays can be arbitrary be trained. The setting of the time can either depend on the electrical determinants their excitation circuits or the dimensioning of damping and delay devices be made dependent. The timing relay 6, whose excitation coil 6o as well as the Excitation coil 5o of switch 5 is connected to phases S and T of the three-phase network, is equipped with .einer Dämpfungseinrichtimg 61 and closes its control contacts 62 and 63 a certain time after turning on the push button switch 3, This Timing relay 6 is used in a known manner to determine the time interval between switching on the primary winding of the synchronous motor and switching on the DC excitation or the disconnection of the starting, resistance to be measured as it is with the synchronous motor the prevailing operating conditions and the work machine to be driven request given special conditions. Instead of this timing relay 6 could also occur other known devices, which are used to start the starting process not only from the time, but also from others decisive for the starting process Operating parameters, for example the current in the primary or secondary winding or the frequency in the secondary circuit or other variables.

The further timing relays 7 and 8 provided according to the invention are, as can be seen from the drawing, each equipped with two excitation windings 71 and 72 or 81 and 82 . The two excitation windings 71 and 81 are connected to the direct current source ii via series resistors 73 and 83. The two excitation windings 71 and 81 are connected to the direct current source ii via series resistors 73 and 83. Both excitation windings can be short-circuited by control contacts, which in this case are connected to switch 5 (control contacts 53) and timing relay 6 (control contacts 63). These are time relays, which when switched on. their excitation windings attract their armature without delay and their relay contacts close or open, - while they drop with a certain time delay when short-circuiting or switching off the excitation windings due to the special electrical conditions given by the dimensioning of the excitation circuit. There is therefore a certain period of time between the closing of the control or auxiliary contacts 53 or 63 and the dropping out of the two timing relays 7 and 8. The above-mentioned additional exciter windings 72 and 82 have the main purpose of preventing the armature of the relay from sticking. In addition, however, the fall time of the two timing relays 7 and 8 can be set by appropriately dimensioning a resistor connected upstream of these additional exciter windings. The two springs 74 'and 84 also serve the same purpose.

A relay arrangement is located in the primary circuit of the synchronous motor i 9, which responds if the engine i falls out of step or if for other reasons the motor is overloaded. This purpose is used in the exemplary embodiment a relay 9o, which is connected to a current transformer 9 i of the primary phases of the motor i is connected. Contacts are parallel to the excitation winding of the relay 9o 75, by which the action of the protective device 9 are temporarily interrupted can. The relay go is equipped with control contacts 92, which are in the short circuit for the excitation winding 81 of the timing relay 8 lie.

As already mentioned, the starting device described does not serve only to start the synchronous motor i from a standstill; rather, it also has the purpose of bringing the motor back into synchronicity if it were out of any Reasons, for example due to overload, has fallen out of step. Hereinafter the mode of operation in the event that the motor has come to a standstill is described first left on. should be: First, the Erregerwickhuig is through the push button switch 3 23 of the switch 2 is connected to the phases S and T of the three-phase network. Of the Switch connects the primary winding of the motor to the mains and closes at the same time the auxiliary contacts 21 and 22. The contacts z, i serve as holding contacts for the excitation winding 23. Through the contacts 22, the excitation circuit of the excitation winding i o des Motor and its connection to the direct current source i i prepared. Those in the same Contacts 51 of the switch 5 lying in the circuit are initially still open. the Excitation winding io is via the contacts 52 of the switch 5 and via the starting resistor 12 shorted. The motor thus starts up as an asynchronous motor.

At the. Closing the contacts 22 through the main switch 2 will be the both timing relays 7 and 8 switched on. Both relays pull without delay their Anchor. The relay 7 thereby closes the contacts 75 and sets the protective device 9 of the engine i ineffective. The relay 8: opens the contacts 85, which are in the excitation circuit of switch 5 lie.

After a time dependent on the setting of the timing relay 6 has elapsed, approximately after the synchronous motor i has started to 90% of its synchronous speed, this timing relay closes its contacts 62 and 63. The excitation circuit of the switch 5 for switching on the DC excitation is through the contacts 62 of the synchronous machine. The switch cannot yet respond because the contacts 85 of the timing relay 8, which are in the same circuit, are still open. The excitation winding 81 of the at) time relay 8 is short-circuited by the contacts 63, and this relay begins to drop out. After a further delay time, the excitation circuit of switch 5 is completely closed, and this switch closes contacts 51 and opens contacts 52. As a result, the excitation winding io of motor i is connected to direct current and the short-circuit circuit of resistor 12 is interrupted.

When the switch 5 is switched on, its control contacts are also activated 53 is closed, and the excitation winding 71 of the timing relay 7 is short-circuited as a result. This relay also starts to drop out and opens after a certain time contacts 75; through which the excitation winding of the monitoring relay 9o short-circuited was. After it has dropped, the starting process is completely finished.

The overcurrent protection devices are therefore in place during the entire starting process or: other devices that protect the motor against falling out of step, except Effect established, and not only up to the moment when the direct current excitation the synchronous machine has been switched on after the two timing relays 6 and 8 have expired, but a certain time beyond that, which is dependent on the timing relay 7. It is achieved that deviations in the engine speed from synchronism and the short-term overloading of the motor caused by this does not lead to its shutdown lead, but that only a certain time depending on the timing relay 7 later the protective devices against falling out of the way are put into the normal operating state will. Against short circuits and others not related to the starting process In the event of industrial accidents, the engine must of course be specially protected, so that the switch 2 switched off without delay in such cases and thereby the whole starting process is interrupted.

It is known that the operating states which lead to exiting of a synchronous motor cause usually only occur for a short time, and it It would therefore also be advisable to always have a synchronous motor completely connected to the network to be disconnected if such short-term malfunctions occur. Through the invention a means is therefore given, with which the synchronous motor falls out of step first brought back to the starting condition and after a certain time again : is switched to DC excitation. Now set this time so that it is slightly longer than the duration of brief malfunctions, the motor, continue to run undisturbed after the DC excitation has been switched on again.

The mode of operation of the starting device according to the invention is as follows in this case: During operation, the switch 5 and the timing relay 6 are closed. The two. In contrast, timing relays 7 and 8 have dropped out because contacts 53 of switch 5 and contacts 63 of timing relay 6 short-circuit the two excitation windings 7 and 81. The contacts 75 lying parallel to the excitation winding 9o of the protective device 9 are open. If a malfunction now occurs, the relay 9o attracts its armature and opens the contacts 92. the short circuit of the excitation winding 81 of the timing relay 8 is canceled, and this closes its armature without delay and opens the contacts 85. This has the consequence; that the switch 5 is switched off, and that the direct current source is thereby separated from the excitation winding io and this is short-circuited via the starting resistor 12. At the same time, the short circuit of the timing relay 7 is canceled by opening the contacts 53 of the switch 5, and this relay also attracts its armature without delay.

The effects which occur when the engine was started from standstill from the moment in which the time relay 6 has expired therefore occur. The motor is now brought back to synchronism, and after a certain time, which depends on the timing relay 8, the direct current excitation is switched on again. After a further period of time, which of the. Time relay 7 depends, the protective device 9o is finally brought into effect again. Also in this case, both during ied time section before switching and after. Switching on the DC excitation rendered the overcurrent protection device 9 of the motor ineffective.

Claims (7)

PATENT CLAIM i. Device for the automatic events of synchronous machines, especially synchronous motors, with disgusting DC excitation after a certain time-switching time relay, characterized in that the switch-on (Start of running) of the timing relay (8), depending Moderately about the restarter after the 'falling out of step', of one the same. second time relay (6) switched on when the motor is switched on or by one the synchronism over the monitoring device (9) is dependent, and that the time for letting it go again after falling out of step is shorter than the time for that Starting from a standstill. 2. Device according to claim i, characterized in that that the timing relay (8), which is decisive for switching on the DC excitation, is approximately is set to the time required for restarting after falling out of step necessary is. 3. Device according to claim i, characterized in that the the Synchronism monitoring device (9) during a certain time after Switching on the DC excitation, expediently with the help of another time relay (7), is ineffective. q .. Device - according to claim i to 3, characterized characterized in that the time relays (8, 7) are equipped with an additional excitation, which acts in the sense of a detachment of the anchor. 5. Device according to claim i and 3, characterized in that the time relay (7), which the device for monitoring of the synchronism is ineffective, depending on the starting point standstill or restarting after falling out of step, either is switched on immediately when switching on the primary winding of the synchronous motor, or immediately after the monitoring device (9) has initiated the restarter Has. 6. Device according to claim i and 2, characterized in that the excitation of the timing relay (8), which causes the activation of the DC excitation, from the device monitoring the start-up, for example a time relay (6), or from the device monitoring the synchronism (9) is short-circuited at the moment of exiting the step, so that the time relay (8) drops out after a certain time. 7. Device according to claim 3, characterized in that the excitation the timing relay (7), which the device for monitoring the synchronism (9) is ineffective when the one that switches on the DC excitation responds Switch (5) is short-circuited.