DE1140273B - Dependent overcurrent protection, especially for semiconductor rectifiers - Google Patents

Description

Dependent overcurrent protection, especially for semiconductor rectifiers The invention relates to a dependent overcurrent protection with as far as possible controllable characteristic. Such protection is usually made dependent on the current and should with small overcurrents with a long time, with large overcurrents with smaller Trigger time.

Such protection systems have been known for a long time. The desired current dependency is so far obtained by various means. You can use thermal elements which are heated up faster or slower by the current. One can also use magnetic relays with special attenuators, which work stronger or weaker depending on the tightening force. With all of these relays the influence on the characteristic is limited.

It is true that the characteristic curve can be changed using thermal storage elements, but one generally does not achieve very short times with thermal relays, which are necessary for high overcurrents. In the case of magnetic relays, on the other hand, is in the case of low overcurrents, the tripping time is often not high enough.

Relays that are dependent on electron tubes are already available manufactured. With these, the voltage is controlled via a delay element (RC element) brought up to the grid of a tube. The duration depends on the level of tension different sizes until the tube responds. This voltage can also come from electricity can be derived by dividing the current through a resistor into a current proportional Voltage is converted. You can also use different ones within a half-wave Achieve times for a tube to respond because the half-wave at high voltages reaches a certain response value more quickly than with lower voltages. These However, all measures are not suitable for long at the same time with smaller tensions and to achieve very short times for higher voltages.

The requirements for such protective relays have grown more rapidly today. In the case of semiconductor rectifiers, for example, when there are high overcurrents, the times extremely short, while light overloads are often still acceptable.

The common requirement for long times with small overcurrents and very short times with very large overcurrents could be achieved with the previous versions not be obtained, in particular it was not possible with simple means, such as variable resistances to influence the characteristics of the relays.

Counting tubes have already become known for time measurement, which have several counting cathodes that are ignited in quick succession and whose ignition time is determined by the frequency sequence of pulses. Such counter tubes can be tackled decadically by igniting the last cathode a new tube is ignited, which then expires ten times longer. These Counting tubes have specially adapted cathode resistances, these are for everyone Ignition cathodes of the same size.

According to the invention, a dependent overcurrent protection is now used at least one counter tube with several cathodes, which by the frequency of a pulsating DC voltage are ignited one after the other, and, using of current transformers that are loaded by a resistor in which a Forms current proportional voltage, and with a relay device that a Actuation triggers, suggested that on the cathode resistors in the order the counting cathodes each have different tapping points and that their Potentials different according to a prescribed curve and with the potential in the converter resistance are compared by the relay device, such that triggers from a certain current intensity to the relay device.

This enables a current-dependent measurement, since the current level is different depending on the position of the counter tube. If you use two one behind the other Counting tubes, so the second tube counts down with ten times the time and thereby flattens the Characteristic curve for long overload times.

Figs. 1 and 2 describe examples of the arrangements. Fig. 3 shows the characteristic curve achieved with these arrangements. In Fig. 1 are 1 and 2 labeled two counting tubes. The overcurrent comes from a converter (not shown) Acquired via the resistor 3 as a voltage. In the case of alternating current, this voltage must still to be rectified.

The tripping devices, three of which are drawn, are marked with 4, 5 and 6. Here, for example, the triggering device 4 on a Short circuiter, 5 act on a circuit breaker and 6 on the control. With very high currents, the triggering device 4 must be actuated, with as much as possible short time. In the case of medium overcurrents, it is sufficient to use a switch, for example turn off the DC switch in rectifier systems, with only low Overcurrent, a shutdown is not required, it is only required by the control the stream getting downsized. 7 is the actuation device for the counting tubes, there an alternating voltage is generated by rectification in pulses of 100 Hz, the second counter tube then counts with a frequency of 10 Hz, since it only counts after each cycle the first counter tube is switched. Further counting tubes can still be connected which in turn count with the tenth part, i.e. with 1 Hz. The cathode resistors 9 to 34 for the counting cathode are shown as voltage dividers. You own Tapping points, which are connected to a triggering device via diodes 35 to 47 are. In addition, relays 48 and 49 are also provided, their meaning in the description the mode of operation is explained in more detail.

50 is a switch which indicates that the entire device is being started target. The tripping devices 4 to 6 consist of the transistors 51 to 53 and the relays 54 to 56.

The mode of operation of the arrangement is as follows: If an overcurrent occurs on, the switch 50 is closed by an excitation device (not shown), this is anode voltage across the DC bus P to the anodes 57 and 58 of the counting tubes 1 and 2 are placed. A pulse frequency passes through the pulse device 7 of, for example, 100 Hz to the auxiliary cathode 59 of the tube 1. First, the burns Counting cathode 0 of each tube. The 0-cathode can through the capacitors 61 and 62 ignite immediately, this gives the relays 48 and 49, which are usually through Inertia electronic members are replaced, tension and close their Contact, thereby connecting the bus 63 to the diode 65 and the bus 64 with the diode 66.

Furthermore, the overcurrent creates a certain voltage U, an the emitter side of the transistors 51 to 53. This voltage is determined by the level of the Overcurrent determined. The voltage U i is applied to the bus 63. This will determined by the voltage divider on the counting cathodes. As long as U, less than Uz, a base current flows through the transistor 51, and the relay 54 remains attracted, then it does not yet trigger; only when U2 is less than Uo does the relay drop 54 and actuates, for example, a short-circuiter.

The counter tube is now in a cycle of i / loo s from the cathode 0 to- -IX forwarded, thereby successively the voltage dividers 10, 23 and 11, 24 etc. switched on. The sum of the resistances of the voltage dividers is equal to but the tapping points between the two partial resistors are arranged so that the voltage U., decreases with each counting pulse; if now during this time If U2 is smaller than U, the relay 54 can drop out and the short-circuiter is actuated but the voltage U2 at the ignition cathode IV is even greater as U., the following occurs: In the case of ignition cathode IV, the tapping point is between the voltage divider 13, 26 given to the bus 64 via the diode 39. These The bus is connected to transistor 52 via diode 66. The voltage at transistor 51 is kept constant from this point on by the additional Voltage dividers 67, 68; but now the voltage U3 changes at the base of the Transistor 52 in the pulse train from the ignition cathode IV to IX.

This voltage divider is also effective when the switch 50 has not closed or if the associated high voltage system is switched off; even then the relay 54 is prevented from dropping out; the same goes for the voltage divider 71, 72 and 75, 76.

If during this time the voltage has become less than U., then would turn off the relay 55 and operate any switch, this is not the one If so, the other counter tube 2 is now switched over. this happens in that the ignition cathode IX of the tube 1 via a resistor to the auxiliary cathode 60 of the tube 2 is connected, so that the tube 2 begins to count, namely counts it every time a pulse reaches the auxiliary cathode 60, that is, when the tube 1 has counted.

Since the switch of the relay 49 is closed, the voltage at the base of the transistor 52 is further reduced in accordance with the rhythm of the counter tube 2. Has This is ignited by the ignition cathode II of the tube 2, then connects the manifold 69 to the voltage U6, the tapping points of the voltage dividers from 18.31 to 21.34 with the base of the transistor 53 through the diodes 44 to 47 and 70th

A control device is now operated by the relay 56 set if the voltage U. has become less than U in the meantime. The transistor 52 remains unchanged during this time, since now the voltage divider 71, 72 is via the diode 73 at its base.

Fig. 2 shows a slightly different arrangement. The cathode resistance is but otherwise switched in the same way. The cathode resistances are one behind the other, and the tapping points are connected to the individual ignition cathodes. This will the voltage at the base of transistor 51 is also gradually decreased. In this arrangement, however, only one diode 35 is required, which for the interconnected Ignition cathodes works together.

3 now shows the characteristic curve obtained with this device of the relay. The time in ms is plotted on the abscissa and the Overcurrent 1 ". The required characteristic is the solid line 74, this is indicated by the arrangement in a stepped curve, the steps of which are the individual cathodes corresponds, simulated. When the protection is started, the ignition cathode 0 enters Task; if the current is greater than the value I., the relay 54 already responds. To the ignition of the ignition cathode I, the arrangement can already respond when the current 11 is tall. In the example, this takes place in 20 ms. The ignition cathode ignites after 30 ms II and the current at which the relay arrangement would respond only needs to be greater than 12. This continues until the ignition cathode IX has ignited, until therefore the tube 1 is decisive for the characteristic. Now the tube works 2, which ignites with the tenth part of the pulse frequency. The distances between the ignitions are 100 ms per count.

In the example shown, the relay device would take 10 to 40 ms 4, from 40 to 200 ms the relay device 5 and then the relay device 6 in Activity to be set. Depending on the location of the tapping points in the voltage dividers 9, 22 etc. the current level is now determined. You can here to set the characteristic as you like to be able to adjust, make the individual voltage dividers variable (potentiometer).

The advantage of the arrangement is that it is an overcurrent protection device to obtain which has any number of flat characteristics and their characteristics can be adjusted with easy means, and in which it is possible to have different To use tripping devices that are operated at different times.

Claims (12)

PATENT CLAIMS: 1. Dependent overcurrent protection, especially for semiconductor rectifiers, using at least one counting tube with multiple cathodes, which through the frequency of a pulsating DC voltage can be ignited one after the other, with Cathode resistors, and using current transformers through a resistor are loaded, in which a current-proportional voltage develops, and with a relay device which triggers an actuation, characterized in that that at the cathode resistors in the order of the counting cathodes each different Tapping points are provided, the potentials of which follow a prescribed curve different and with the potential in the converter resistance through the relay device be compared in such a way that of a certain current intensity to the relay device triggers. 2. Dependent overcurrent protection according to claim 1, characterized in that that the cathode resistors are designed as a voltage divider and together with connected to the resistor connected to the current transformer and d'ass the tapping points the voltage divider resistors are connected to the relay device, the on the other hand is also connected to the current transformer resistance, and that the Voltage divider resistors have the same overall values, the partial resistances but different values according to the required characteristic of the overcurrent protection to have. 3. dependent overcurrent protection according to claim 1, characterized in that the cathode resistors are connected in series and their connection points are connected to the cathodes in such a way that in the order of the switching cathodes gradually smaller resistances are applied to the cathodes. 4. Dependent overcurrent protection according to claim 1, characterized in that the relay device is a transistor is formed, at the base of which the cathode voltage is supplied via diodes, and that a relay is provided which is in the collector circuit of the transistor. 5. dependent overcurrent protection according to claim 2 and 4, characterized in that the tapping points of the voltage divider each via a diode with a common bus are connected, which in turn are connected to the base of the transistor via a diode is. 6. dependent overcurrent protection according to claim 1, characterized in that counter tubes connected in series are arranged in decadic form. 7. Dependent overcurrent protection according to claim 1, characterized in that several relay devices are provided are and that up to an arbitrarily selectable number of counts the first relay device and after a further number of counts the next relay device is switched on is. B. Dependent overcurrent protection according to Claim 7, characterized in that the different relay devices cause different actuations. 9. Dependent Overcurrent protection according to Claims 5 and 6, characterized in that the common Bus line is each assigned to a relay device. 10. Dependent overcurrent protection according to claim 1, characterized in that the relay devices are de-energized Counting tubes are switched in such a way that they cannot be triggered. 11. Dependent Overcurrent protection according to Claim 1, characterized in that the relay device consists of a transistor circuit, the transistor being current-permeable in the idle state is. 12. Dependent overcurrent protection according to claims 10 and 11, characterized in that in the switched-off state the transistor is fed via a voltage divider especially connected to a constant direct voltage, in such a way that the transistor is continuously current-permeable. Considered publications: German Patent No. 1070 280.