DE1270156B - Device for controlling the excitation current of electrical machines - Google Patents

Description

Device for controlling the excitation current of electrical machines The invention relates to a device for controlling the excitation current of electrical machines, in particular of generators, in their excitation circuit an electronic switch controlled by the voltage of the electrical machine is provided by periodically switching the excitation voltage off and on Temporal mean value of the excitation current in the sense of regulating the machine voltage influenced and is additionally controlled by a current monitoring element.

It is already a safety device against sudden overloads of the armature circuit of electrical machines known, which a the excitation current monitoring element and for which the excitation voltage is exceeded a specified maximum excitation current is completely switched off and the machine is taken out of service. A new start-up is activated by switching on again of the excitation circuit made by hand.

To achieve asynchronous operation of a synchronous machine in A fast de-energization has already been used in an interconnected network and in asynchronous Generator operation switched a resistor in the excitation circuit to the excitation to reduce. It is also known for the rapid de-energization of self-excited generators short-circuit the generator winding in whole or in part.

These known devices work with switching devices that require maintenance.

In the case of multi-phase synchronous generators, a device has become known which is equipped with contactless elements and which protects the field winding the excitation derived from the generator current and the mains voltage Size is influenced in the sense of a limitation. As a control device, however, a Magnetic amplifier arrangement is used, the accommodation is often difficult, because such an arrangement takes up a relatively large amount of space.

For contactless control of the excitation current of a shunt generator It is also known, depending on the generator voltage taken, into the excitation circuit an electronic switch controlled by the voltage of the electrical machine to arrange. This switch influences the periodic switching off and on of the Excitation voltage is the mean value of the excitation current over time in the sense of a regulation the generator voltage. A current flow in the field winding through a parallel to this arranged zero diode allows. Is in the output circuit of the generator a current monitoring element that acts on the electronic switch in the sense of a Limitation of the load current acts.

In the excitation circuit of electrical machines, the excitation current flowed through parts are dimensioned so that they also have the greatest occurring value can lead this current without damage. Now this value can be used on a case-by-case basis, e.g. B. when the machine is cold, considerably above the maximum value required for operation lie. As a rule, the operationally required maximum excitation current must also be available when the machine is very warm. This results from the quotient of the excitation voltage and warm resistance of the excitation circuit. Is the cold resistance of the excitation circuit considerably lower, this results in a certain excitation voltage when the machine is cold a correspondingly higher current, which, even if it only flows for a short time Electricity to be taken into account is a considerable increase in space requirements and price of the exciter accessories. This is particularly the case with generators Cases that are equipped with two-position controllers, d. H. with controllers where z. B. an electronic switch by periodically switching the excitation voltage off and on controls the mean value of the excitation current over time in terms of voltage regulation.

As long as the generator voltage falls below the control tolerance by more than the setpoint, the switch remains closed according to the control principle. This State - full loading of the excitation circuit with undervoltage of the generator - is used without special precautions with every excitement process, z. B. when starting up, run through and occurs even when the machine is oversaturated (underspeed). Both leads to an overcurrent in the excitation circuit when the winding is cold.

As some parts of the excitation circuit, especially electronic switches of regulators, as a result of their small heating time constant already can be destroyed by brief overloads, they must overcurrent for them be measured. This results in, based on the operational excitation current, under Under certain circumstances, a significant oversizing of the switching means used. So can z. B. the excitation winding of a fully utilized generator of a certain insulation class reach a temperature of 180 ° C. At this temperature the winding must at given excitation voltage still has the largest excitation current required for operation take up. If such a machine is started at very low temperatures, so the excitation winding z. B. at -40 ° C only 47% of the given at 180 ° C Resistance value. The winding would therefore be more than double that provided Record excitation current.

It was suggested that this temperature dependency of the excitation circuit resistance, z. B. by connecting resistors, preferably with negative temperature coefficients to reduce or abolish completely, but such measures inevitably require one considerable increase in the total excitation output, including deterioration the efficiency an enlargement and price increase, - the exciter accessories.

The invention is based on the object of a device of the initially described type with simple and reliable means to build through the at the same time an oversizing of the switching means used is avoided can be. The solution according to the invention is that the current monitoring element is controlled by the excitation current and is designed so that the im. Excitation circuit lying circuit elements only for the maximum excitation current at operating temperature Machine need to be sized. Through the current monitoring element, at exceeding a specified maximum excitation current for the duration of the overcurrent the excitation voltage is directly or indirectly reduced or switched off and initiates reconnection after the current has fallen below the limit value. In this way, the excitation current is limited when a certain value is reached, so that the switching elements located in the excitation circuit, in particular the electronic Voltage regulator switch, not for when the field winding is cold the start of the machine must be designed to flow high current, but dimensioned only for the much smaller excitation current when the winding is at operating temperature need to become. This makes it possible to use smaller components than the known one Control device for generators with an electronic switch in the excitation circuit.

The device according to the invention results in a current that with time fluctuations - the frequency of the same depends on the magnetic Time constants of the excitation circuit - in an arbitrarily narrowly dimensioned, to the Response value bound interval runs, i. H. the maximum permissible current practically can be made equal. The maximum allowable current is a little practical greater than the highest excitation current required for operation. In order to an operation is achieved in which the working areas of the invention Device on the one hand and a voltage regulator on the other hand do not overlap. So it can be an already existing electronic switch of a voltage regulator can also be made usable for the excitation current limitation according to the invention.

F i g. 1 shows a schematic representation of a circuit example of the invention and FIG. 2 the course of speed, voltage and excitation current of a self-excited generator with and without a device according to the invention.

According to FIG. 1, the three-phase generator 1 works via the rectifier 3 to a direct current network. The rectifier 3 is also used in switching mode working transistor 4 fed the excitation winding 2 of the generator. For voltage regulation the switching transistor 4 is controlled by a device that monitors the generator voltage U. 5, e.g. B. a pulse width modulator, controlled and thereby switches the excitation voltage periodically to the field winding 2 in such a way that the time average of the in its flowing current IE has the value required in each case for voltage maintenance. A parallel-connected in train to the excitation voltage of the winding 2 in the blocking direction electrical valve 6 (so-called zero anode) allows this winding to be when transistor 4 is blocked, i.e. when the excitation voltage is briefly switched off, Can carry electricity. -The electric valve 6 can also be replaced by another passive one The voltage regulator consisting of parts 4, 5 and 6 must be replaced supplemented by a current monitoring element 7 which monitors the current IE. From the element 7 emanate control signals that are transmitted to the control electrodes of transistor 4 act that this when reaching an upper limit value of the excitation current IE locks. The excitation voltage is then switched off from the excitation winding 2 and the excitation current IE flows decaying over time via the electric valve 6. The Transistor 4 opens again when the excitation current 1E has fallen below the limit value is. The control of the transistor 4 can. either - as in FIG. 1 schematically shown - directly by the monitoring element 7 or indirectly, for. B. via the voltage monitoring element 5 provided for the voltage regulation take place. In this case, the output signals of element 7 act on the device 5; and this controls the transistor 4.

The element 7 monitoring the excitation current is advantageously designed as a trigger amplifier with a response threshold. Instead of the Ipp amplifier, use can also be made of a current transformer or a shunt resistor, the resulting voltage being able to be switched to the base of the transistor 4 via a threshold value diode or the like.

If the voltage reduction according to the invention is not to be extended to zero, this is shown in FIG. 1 can be achieved, for example, by a resistor 8, which - shown in dashed lines - is connected in parallel with the switching transistor 4 , so that this transistor acts as a bypass switch.

The F i g. 2 is based on the assumption of a self-excited generator provided with a two-point voltage regulator, which is run up from standstill with constant acceleration up to operating speed n3. If the start-up is carried out with the machine at operating temperature, it takes place at time t. (Speed n2) Self-excitation, the voltage U reaches its setpoint and the excitation current the value IE 2. From then on the voltage regulator comes into action and lowers the excitation current with increasing speed so that the generator voltage practically maintains the value Usora. After run-up, full load occurs at time t4, which means that an excitation current 1E 4 (a little less than 1E 2) is required and controlled by the voltage regulator. The switching operation of the controller results in the indicated ripple of 1E.

If the machine is started up when the machine is cold, self-excitation begins at a lower speed. Achieved without the device according to the invention, as shown in FIG. 2 drawn in dashed lines, the voltage the value Usorl and the excitation current the value IL, 1> IE2 already at time t1 (speed n1), whereupon the voltage regulator takes up its activity and IE decreases as required with increasing speed. In this case, the switching transistor of the controller must be dimensioned for the peak value IE 1, which is not required for operational purposes.

If, on the other hand, a device according to the invention for limiting the excitation current is provided and set to the limit value 1E 2, the self-excitation begins at the same time as before when the excitation winding is cold, but the excitation current remains limited to the mean value IE 2 from time t, * on, the generator voltage U therefore does not reach its setpoint until time t2, that is to say at the same speed n2 as in the warm state, and the voltage regulator only begins its activity from then on. From ti * to t2, the excitation current runs in time with the connection and disconnection or periodic reduction of the excitation voltage caused by the monitoring device 7 (FIG. 1). This self-clocked switching frequency is, as in FIG. 2 indicated, mostly an order of magnitude lower than that of the voltage regulator. The excitation current peak reaching up to IE 1 with the disadvantages explained is now avoided.

Claims (4)

Claims: 1. Device for controlling the excitation current of electrical machines, in particular generators, in their excitation circuit an electronic switch controlled by the voltage of the electrical machine is provided by periodically switching the excitation voltage off and on Temporal mean value of the excitation current in the sense of regulating the machine voltage influenced and additionally controlled by a current monitoring element, thereby characterized in that the current monitoring element (7) is controlled by the excitation current is and is designed so that the circuit elements lying in the excitation circuit only dimensioned for the maximum excitation current when the machine is at operating temperature need to be. 2. Device according to claim 1, characterized in that the current monitoring element (7) the electronic switch (4) directly or via the voltage monitoring element (5) controls. 3. Device according to claim 1 or 2, characterized in that the current monitoring element (7) contains a voltage threshold value diode. 4. Establishment according to claim 1 or 2, characterized in that the current monitoring element (7) contains a trigger amplifier with a response threshold. Considered publications: German Patent No. 762,986; German interpretation L22116 VIIIb / 21d2 (announced on 23 B. 1956); Swiss Patent No. 87 294; French patent specification No. 1198 885; U.S. Patent No. 3,007,105.