DE820172C - Differential protection device - Google Patents

Description

Differential protection device It is known that electrical machines, Apparatus and lines against internal faults with the help of differential protection to protect. This is based on the comparison of the current (s) flowing into the Protégé flows in with the current (s) flowing out of the protégé. In error-free operation these currents are in a certain constant Ratio, for example, they are the same for a generator. These currents are monitored with the help of current transformers. If a bug occurs in the protégé on, the ratio of the currents changes and it flows in via the relay Current. In these known differential protection devices, however, the disadvantage occurs on that the relay can also respond if an error is outside the protected area the differential protection device. This erroneous response can cause one Regulating transformer have their cause in the fact that the transformers of the differential protection when changing the transformation ratio of the regulating transformer not also in be changed according to their gear ratio, but, like it, in general it is customary to remain firmly set to a medium transmission ratio. Man can indeed set the differential relay so that the healthy operation over the residual current flowing through the relay does not trigger it. But kick If an external short circuit occurs, the current can be so large that the relay appeals to.

Another major cause of the incorrect response is in the inequality of the transducer characteristics. The converter would at all currents translate linearly or would it if it deviated from this linear translation always have the same characteristics, im error-free Condition of the protégé, no differential current occurs. In practice this results but, when the transducers come into the saturation area, differences in the translation, due to differences in the burden or the same with the same converters Burden due to the fact that the converters are saturated with currents of different magnitudes. through this can with large short-circuit currents caused by a fault outside of the protégé caused, large differential currents occur, which the relay to respond bring.

In order to avoid this inconvenience, it is known to use a so-called Use percentage relays, d. H. a relay in which the differential current in the releasing sense, while the through current acts in the blocking sense. This gives the protection a response characteristic (differential current at which the Relay responds, depending on the through current), at which the level of the The differential current required for the relay to respond with increasing through current increases, so the sensitivity of the differential protection device decreases. To the Avoidance of incorrect response of the differential protection in regulating transformers this percentage relay can be used well. Against this one must, to avoid the difference of the converter characteristics to avoid the response of the relay, the response characteristic of the protection lay very steeply, reducing the sensitivity of the protection at internal Failure suffers.

The subject of the invention is a differential protection device, which avoids this difficulty. According to the invention, the differential current and the through current is rectified and in the opposite sense to the relay brought into action, and a direct current source is provided which the This counteracts the flow of through current through the relay. To this end can for example, in the connecting line between the rectifier arrangement, which rectifies the through current, and insert a voltage into the relay, which counteracts the flow of the rectified through current through the relay, and in series with this voltage turn on a valve which prevents a current resulting from this voltage closes through the relay. One can also, for example, an auxiliary current from the auxiliary voltage source via the rectifier, which rectify the through current. One achieves that from Through current zero up to a certain value of the through current the response sensitivity of protection remains constant, but that of a certain level of through current from the sensitivity of the protection decreases. One becomes the dimensioning expediently like this meet that only with a through current that is equal to one to two times The nominal current is the rectified total current influences the sensitivity of protection wins. The rating depends on the through current is still to be expected if an error occurs in the protégé. The response characteristic thus remains, for example, up to a through current which is 1.5 times that of the rated current is constant and then increases. This can result in a faulty Response of the relay, caused by converter failure, can be prevented without that the sensitivity of the protection to be reduced in the event of internal faults needs.

In the drawing, two embodiments of the invention are for a three-phase system is shown.

In Fig. I with i the protégé, z. B. a regulating transformer, designated. The three current transformers on the input side have the reference number 2, the three current transformers on the output side have the reference number 3. The secondary sides of the two current transformer groups are connected in series. The difference of Currents in converters 2 and 3, i.e. the differential current or fault current, is passed through the transducer group 4 detected. The currents of the converter 4 are fed through a rectifier arrangement 7 rectified. There are four groups of rectifiers provided in order not to only the phase currents, but also. rectify an approximately occurring zero current. ' to the direct current side of the rectifier arrangement 7 is the coil 9 of a relay, z. B. the coil of a moving coil relay. It is also a rectifier arrangement 8 provided, which is fed by the through current. The one from the rectifier arrangement 8 supplied current acts on the relay coil 9 in the opposite sense as the current supplied by the rectifier group 7.

In the exemplary embodiment, two are used to form the through current Current transformer groups 5 and 6 provided. The secondary sides of the transducers are in each Phase switched in parallel. The through current does not get through here a single transducer group recorded, but the sum of the incoming and outgoing Streams formed, which is advantageous when the converter groups 2 and 3 are in their Distinct characteristic. As mentioned earlier, the through current or the sum of the input and output currents is rectified by the rectifier group 8 and acts in the opposite sense as the current of the rectifier group 7 the relay coil 9 on. In the connection line between the rectifier arrangement 8 and the relay coil 9 is a resistor i i, over which one is only through a Plus and minus signs shown DC voltage source via a resistor 14 sends an auxiliary current and thereby a DC voltage across resistor i1 generated that the flowing of the rectified through current over the relay coil 9 or the converter group 7 counteracts this. In] series with this counter voltage or the resistor i i is a valve 12 which is switched so that the voltage at the resistor i i no current can drive the relay coil 9. Parallel a resistor io is applied to the direct current side of the rectifier arrangement 8 Its place also includes parallel resistors on the alternating current side of the rectifier arrangement 8th can be provided. As long as the io caused by the through current at the resistor Spanning is less than the sum of the voltage across the resistor i i and the voltage in the winding 9, the through current has no effect on the size of the to Response of the relay required differential current. The one to address the IZclais required differential current remains constant lins to this value. Exceeds but the voltage across the resistor io the sum of the voltages across the resistor i i and winding 9, the through current causes a reduction in responsiveness of protection, d. H. an increase in the differential current required for response, so (let the response characteristic of the protection increase from this value (inflection point in the characteristic). The influence of the through current depends on the size of the Resistances io and i i and the size of the passage resistance of the valve 12, z. B. a dry rectifier, dependent. As mentioned earlier, one becomes the counter tension Select the resistor 11 so that the kink in the characteristic curve for a through current, which is approximately equal to the 1.5faclien rated current, so from here onwards the to Response required differential current increases. The slope of the response characteristic to the right of the break point, by changing the size of the resistances io or ii or the resistance of the valve 12 can be changed.

In order to achieve that in regulating transformers, too below 1.5 times the nominal current, the response characteristic is somewhat, albeit less steeply than rises from a through current equal to the i, 5faclieti Neinistroni, a resistor 13 is also provided in the exemplary embodiment, which is parallel to the Series connection of the resistor ii and your valve i2 is connected.

fit of Fig. 2 is the size of the differential current required for response or fault current 7, t plotted as a function of the through current IL. plan sees that the current Jd initially remains constant with increasing through-current, in order to then]) rise steeply with a through-current equal to 1.5 times the nominal current, where, as mentioned, paints the steepness of the characteristic curve by choosing the sizes of the resistors can adjust. If the resistor 13 is still present, a characteristic is achieved which is shown in dashed lines in Fig. 2, in which the current ld below 1.5 times the N etitistronies also increases and the slope changes, when the through current is equal to 1.5 times the rated current.

As already mentioned, you can also use an auxiliary voltage instead of an auxiliary voltage Introduce auxiliary current, through the rectifier arrangement B. As long as the rectified Through current is smaller than this auxiliary current, it has no effect on the Response characteristic only when the through current outweighs the auxiliary current, the differential current required to respond to the relay increases. It is there expediently, the DC terminals of the rectifier arrangement 8 through a resistor to bridge and to connect the relay coil to a tap of this resistor; since the slope of the response characteristic is set by changing the tap can be.

An exemplary embodiment for this is shown in FIG. 3, namely here only the circuit shown on the DC side. In the arrangement according to FIG., 3 is the direct current source represented by a plus and a minus sign above a resistor 15 (the resistor 16 is to be thought away for now) to the DC terminals connected to the rectifier arrangement 8, which is bridged by a resistor io will. The relay coil 9 is connected to a tap of this resistor. As long as the rectified through current is smaller than the auxiliary current of the DC voltage source; which flows through the resistor 15 influences the total current the response characteristic does not. Only when the total current is greater than the auxiliary direct current, the differential current required to respond to the relay is increased, so that the Characteristic shown in Fig. 2 is achieved. Setting the slope the characteristic curve to the right of the inflection point is made by changing the tap at the resistance io. In the exemplary embodiment, similar to the arrangement according to Fig. I, another valve 12 inserted into the connection line to the relay coil, to prevent a current from the DC voltage source through this relay coil can flow. This valve could be omitted if the passage resistance the rectifier arrangement 8 would be zero.

In the exemplary embodiments, a relay is only one with one Coil provided. But you can also use a relay with two coils facing each other counteract, one of which flowed through by the rectified differential current is, while the other via the valve in the same way to the rectifier arrangement 8 is connected, as shown in FIGS. I and 3 for the coil 9.

If a relay with only one coil is used, the height of when the relay coil responds, the voltage has an influence on the position the break point of the characteristic. If you want to set the response value of the relay do without moving the break point, the response voltage of the relay must stay constant. For this purpose, the response value of the relay is not changed by changing the bias of the return spring of the relay is set, but by a variable Resistor 14 to relay coil 9, which is shown in FIGS.

In the arrangement according to FIG. 3, when the slope is changed, the response characteristic by changing the tap at the resistor io influences the position of the break point, if a relay with only a single coil is provided. To this influence to avoid, a resistor 16 is provided in the embodiment, its size is chosen so that the auxiliary current flowing through this DC voltage source at produces a voltage equal to the response voltage of the relay is. The steepness of the characteristic curve can then be changed by changing the tap change without shifting the position of the break point of the response characteristic.

Claims (6)

PATENT CLAIMS: i. Differential protection device in which the relay is influenced not only by the differential current but also by the through current, characterized in that the two currents act in a rectified manner in opposite directions on the relay and that a direct voltage source is provided which counteracts the flow of the through current to the relay. 2. Differential protection device according to claim i, characterized in that in the connecting line from the rectifier arrangement, which rectifies the through current, and a voltage is inserted into the relay, which counteracts the flow of through current across the relay, and that furthermore, a valve is switched on in this connecting line. 3. Differential protection device according to claim 2, characterized in that parallel to the direct current terminals the rectifier arrangement, which rectifies the through current, a resistor is switched. 4. Differential protection device according to claim 2, characterized in that that parallel to the series connection of the counter voltage and the valve, a resistor lies. 5. Differential protection device according to claim i, characterized in that that the direct current source is connected to the direct current terminals of the rectifier arrangement via a resistor is connected, which rectifies the through current. 6. Differential protection device according to claim 5, characterized in that in the connecting line from the rectifier arrangement, which rectifies the through current, and a valve is switched on to the relay. Differential protection device according to claim 5, characterized in that the direct current terminals the rectifier arrangement, which rectifies the through current, by a Resistance are bridged and the relay is connected to a tap of this resistance connected. B. Differential protection device according to claim 7, characterized in that that in series with the resistor connected to the terminals of the rectifier assembly another resistor is located and the relay is between the end point of this resistor and a tap of the first-mentioned resistor is located. G. Differential protection device according to claim 2 or 5, characterized in that the counter voltage or the auxiliary current is chosen so that a through current is equal to one to two times the nominal current the response characteristic of the protection shows a kink. ok Differential protection device according to claim i, characterized in that when using a relay with only an adjustable resistor connected in parallel to the relay with a single coil is. i i. Differential protection device according to claim i, characterized in that that the sum of the incoming and outgoing currents is rectified.