DE846878C - Resistance toggle relay - Google Patents

Description

Resistance toggle relay \ rlteiteil \\ 'i @ lerstaii @ lskiltl »-elais to <1e1- c; lci- chun t ~ p or "oh the l Aeichung ot y @ c_ L - c'i # 1 wiwin the vel <torial constants i, and c_ real or lutmltlex ropes k <iiiiien and 1 the line current and L have the line warning l so these relays not only have the property of determining ought a certain resistance below or above vain definite value (Meliwert) lies, but also a directional selectivity. L'tn the measured value ver: indern, (l. i.e. the value, i.e. what that Relay kilTt, it is known. the constant c_ to change. @ -ermin <if you learn this value, for example, so the measured value is increased, cüe directional Sensitivity of the relay for 1, error in the vicinity of the place of relay, and this is what matters : in, however, takes old. Now that such resistance kipl »-eIais in terms of their measured value in broad terms Limits need to be set, this has to be done Consequence, then with I? Setting on large readings only insufficient directional sensitivity for Error in the vicinity of the relay location is available. This will be explained in the following. Be it assumed that the relay according to the (equation ICt 3 114LI 11 C1 # 1 arlwitet. Such a relay is partially in Fig. I shown. 1? S is a 1) coil relay with two Moving coils i and 2 exerting opposing torques. The coil i is fed via a rectifier arrangement 3, the coil 2 via a rectifier arrangement 4. The rectifier arrangement 3 is excited via the winding 51 of a converter 5, and the rectifier arrangement 4 is excited via the winding 61 of a converter 6. The windings 5o and 6o of the converters 5 and 6 are connected in series and are excited by the current C @. The converter 5 also has a winding 52 which is excited by the voltage (i via a variable resistor 7 and an arrangement 8 for adjusting the phase position. The coil i thus develops a torque which is equal to ci # = 'c211 1, the coil 2 has a counteracting torque which is equal to c, j, the coil i acting in the blocking sense and the coil 2 in the releasing sense where the impedance vector to be measured and the level vector 3 at which the relay responds, is. The curve for the end point of the resistance in the RX diagram represents a circle that goes through the ordinate zero point and the center of which lies at the end of the vector 2o. This circle is shown in FIG. The effective resistance R is plotted as the ordinate and the reactance X = j c) L as the abscissa. The angle y between the positive direction of the ordinate axis and o is equal to the phase position of the vector If one assumes, for the sake of simplicity, that the vector of the resistance to be measured has the same phase position as 3 , then the relay speaks at a value at. The torque Md of the relay, based on the current i as a function of Z_, results in an isosceles triangle, which is shown in FIG. The course of this torque is readily obtained from the diagram in FIG. 4, in which the variables are shown which act on the relay. For errors in the immediate vicinity of the relay location, the voltage e is \ u11, i.e. the torque is also zero. The measured value of the relay is reached when the quantity (ci j - c2 e) is twice as large as c, The measured value is equal to Z = 2 Z .. The maximum torque occurs when Z = ZO is and is , equal to c1. The increase in torque with the distance to be measured, i.e. tg a, is therefore equal to c2.

If the measured value of the relay is increased, the factor must be four smaller. For example, does one bring about by changing the resistance? this factor to half of the previously considered value, then the measured value of the relay doubles. However, the maximum torque occurring in the relay remains constant. This means that the inclination angle α of the torque characteristic changes. The directional sensitivity of the relay drops by half. This is shown in FIG. 3 by the dashed triangle, in which the factor with which the voltage enters into the equilibrium condition of the relay is the same is. Since such relays have to be adjusted within wide limits in practice, this has the consequence that the directional sensitivity of the relay, if it is set to a large measured value, is insufficient. Directional sensitivity should always be understood here, as in the following, to be the increase in the torque curve (tg a) at the beginning of the route, because this is the only decisive factor because, in the event of errors in the vicinity of the relay location, the relay has to decide through its directional selectivity whether the There is a fault on one side or the other of the busbar.

In order to avoid these difficulties, a relay is used according to the invention in which a variable c3 - (! Is additionally used on the tripping side, so that (read relay according to the equation or the equation works and that the constants c2 and c3 are changed to different degrees to change the measured value. For example, one constant can remain the same when the measured value changes and only the other can be changed, or they are changed in such a way that the ratio of the two is not constant. For example, one can increase the constant c 1 and decrease the constant c 3, preferably in such a way that one is increased by the same amount as the other is decreased.

If one leaves c2 unchanged and only changes the constant c3, for example according to the formula c = n c3, where n is a number between o and i, the equation according to which the relay works takes the following form: It is also assumed that (let and 'again o are in phase. Fig. 5 then shows the vector diagram of the quantities acting on the relay. The measured value of the relay is now inversely proportional to the difference c2 - ii c_, and the measured value is the same as is evident from the relay equation. It should be noted that Z here does not mean the absolute size of the vector up to the center of the response circle, but still (read ratio The maximum torque (which can occur when set to a certain \ lel.i @@ - ert, is calibrated if cl @t ^ c 'L - o. The maximum torque, related to the current r, is the same en (i + n). The maximum torque does not occur depending on the length of the distance to be measured 1) e1 of the arrangement selected here always 1) e1 of the value on. As a result, the course of the 1) i-elinioinents over the distance to be measured is no longer an isosceles triangle, but a tip isosceles triangle (Vig.6), and the directional sensitivity, i.e. tg a, is equal to c_, ( i + n). 1, for n = o one again obtains an isosceles triangle as in the arrangement according to FIG. 3 The directional sensitivity, i.e. tg x, on the other hand, does not decrease but increases. For the limit value n = i, the directional sensitivity is twice as great as for the value n = o. The measured value at ii = i is infinite, (.1i. ( The relay works as a pure direction relay, and its torque runs according to the form shown in FIG.

How nian can realize such a circuit is shown in Fig.; shown. There is again a Drelispuleiii-elais with two coils i and 2 provided by (those (never a coil of the rectifier: inordllulng 3, the other coil is excited by the (rectifier arrangement.f. As far as the "file with which you Vig. i, the same reference numerals are used. In contrast to the arrangement according to FIG This arrangement gives us a relay, (read on the equation appeals to. If the resistor 7 is adjusted, the factor 1i changes and thus the measured value of the relay.

You can also change the factor c_ to change the distance to be measured and leave the factor c.3 constant, for example your factor c. = =; I - c .; set, so (a13 (read the relay responds to the following equation: here 11 = i () is greater than i, whereas for 11 = i the @leLitvert becomes infinite. Under the previous assumption that the phase shift angle of the line coincides with the phase shift; angle of is (the larger rotating ionians appearing at the same distance s () (let al; o the direction "- ( 1. 11. 1g 2 = (ii + i) c., is. plan sees, (1a13 ztvar finitely decreasing) i the directional sensitivity (tg«) decreases, but not as strongly as 1) e1 der Arrangement according to FIG. I, (la for n = r, i.e. distance infinite, tg a = 2c3 and not like 1) e1 of the arrangement according to FIG. I equals Ntill.

One can also increase the factor c2 to enlarge the measuring range and reduce the factor c3, preferably in such a way that the factor c_ is increased by the same amount by which the factor c3 is reduced. For example, if you set c _ = (i + n) c4 and c3 = (1+; 1) c4, the relay responds to the following equation: Nian can also write this: where n is between o and i. Again with the assumption that 7 and 'are in phase the distance to which the relay responds is the same The maximum torque that occurs is the same In contrast to the arrangement according to the lig. 3 and 6 does not always occur at the same distance from the beginning of the route, but in a lintfertititig that is the same is. This results in (let tg 2 = 2c4. It is therefore independent of the setting of the measured value. The values of il are between o and i, but in the opposite sense for the arrangement according to FIG. 7, since with increasing; l. If; l has the value i, then the measured value has the smallest value, and an isosceles triangle is again obtained as the torque as a function of 7, as shown in solid line in FIG B. for; l = '/ =, (read the triangle in (read the triangle shown in dashed lines; fair; i = o niinint (read the torque the curve shown in dash-dotted lines. For n = o the measured value is infinite. As in Fig.8 shows, the directional sensitivity, i.e. the increase in torque for errors at the beginning of the route, remains constant.

How such a relay can be implemented is shown in FIGS. 9 and 10 shown. In the arrangement according to FIG. C), the coils i and 2 are again one Drelispulrelais and the rectifier arrangementell 3 and: I are provided. The converter 5 has four winding gels 50, 51, 52 and 53, the converter 6 also has four windings 6o, 61, 62 and 63. The winding 51 feeds the rectifier arrangement 3, the winding 6t the rectifier arrangement .4. The Wickhingen 5o and 6o are powered by the current _1 flowed through. The windings 52 and 62 are on the output side of the phase rotating Network 8, (read is excited by the voltage e. The windings 53 and 63 are via a changeable Resistor 7 also on the output side this phase-shifting network. By changing the resistance 7 is the Factor n changed, and the measured value setting of the relay takes place.

Another possibility is shown in FIG. A bridge circuit comprising the four resistors 20, 21, 22 and 23 is provided here. The windings 51 'and 61' of the converters 5 and 6 are also inserted into the bridge circuit, while the windings 51 and 61 again feed the rectifier arrangements 3 and 4. The current I is connected to two opposite points of the bridge, the other two opposite points of the bridge are connected to the voltage (! the other two diagonal points are connected to one another via resistors 26 and 27 of equal size. The connection point of resistors 24 and 25 and the connection point of resistors 26 and 27 are also connected to the output side of the phase-rotating network via a converter 28 and the adjustable resistor 7, see above <a13 Here, too, a relay is obtained that works according to the previously given equation: With this arrangement it is completely achieved that the current and voltage quantities supplied to the bridge do not influence one another.

The ratios are similar for 1 relays that work with quadratic values. The usual finite directional selectivity relay works according to the equation If one assumes for the sake of simplicity that the values c1 and c_ are real, then the equation results for the working curve of the lndl) factor of the resistance vector to be measured In the RX diagram (see Fig. Ii), this represents a circle whose center point on the real axis is = @ 1); t v @@ m zero point is. If one further assumes that the resistance to be eroded is also only real, ie only contains effective resistance, therein is (read 1) rehmoinent proportional (2 ci c_ -c_ = R) R. The torque becomes zero for and for The last one, NFe t, is the reading of the relay. The maximum of the torque lies in the middle of the distance to be measured and is proportional to c19, i.e. independent of c ,. If you now reduce the size in order to increase the measured value, c., The torque remains constant and lies in the middle of the distance to be measured. Torque curves as shown in FIG. 12 are thus obtained. As the figure shows, the directional sensitivity decreases as the measured value increases. How such a relay can be designed, for example, is shown in FIG. 13. 1? S is a `Vaagebalkenrelais. The coils 30 and 31 act on one armature and the coil 34 acts on the other armature. The S1) valves 3o and 34 are excited by the current 3, the coil 3 i via a variable resistor 7 v011 on the output side of the phase-rotating network 8, which is connected to the voltage e on the input side. By changing the resistor 7, the variable c2 is changed and, as already mentioned, the directional sensitivity decreases as the measured value increases.

In a corresponding manner, as described earlier for the moving coil relay, an improvement can also be achieved here after further development of the invention by using a relay which is influenced on both sides by both the current and the voltage, i.e. according to the equation is working. Here, too, you can change the constants c_ and c3 for setting the measured value of the relay to different degrees, for example leave one constant and change the other, or you can change both in such a way that their ratio is not constant is. For example, if one sets c, = (i -I- n) c4 and c3 = (i-ri) c, 1, the equation for the relay is obtained and inan, can adjust the measuring range by changing n. Assuming that c, and c, 4 are real and the resistance to be eroded is also real, the measured value of the relay is equal. An increase in n means a decrease des i \ Ießl> event and vice versa, where again the values of ii between o and i come into question. There. 1lalimum <nasty 1) rehrnonients lies in the middle of the route and is proportional so that the maximum torque increases with less than one measured value and thus the sensitivity of the relay, tinaliliiiiigi (, before the setting of the measured value, remains the same ; i = o the course of the 1) reliinoinents strong and for; i = 'I = the course of the 1) relinloments is shown in dashed lines. As the figure shows, the angle of inclination remains constant at the beginning of the distance, although the measuring range has increased to twice the value.

FIG. 15 shows how such a relay can be designed. A balance arm relay is again provided. Three coils 30, 31 and 32 act on one armature and three coils 34, 35 and 36 act on the other. The coils 30 and 34 are in turn traversed by the current. The coils 31 and 35 are connected to the output side of the phase-rotating network 8, the coils 32 and 36 are also connected to the output side of the phase-rotating network via a resistor 7. By changing the resistance 7, the fit factor is reduced. liei (Icii: \ usfüliruiigslieislüeleii, the work with rectifiers was used as a relay that has two NleOspulen. plan can instead use a relay with only one \ lel.isl> ule ver @@ cu (len, which depends on the difference of ( The (lleicllstl-i) lne supplied to both rectifiers 3 and 4 is excited. The course (les Drehin (nuemts is then a different. Ws shown in Figs. 3, b and 8) , but remains the same \ t ic in the figures mentioned.

In the previous exemplary embodiments, the change in the .Me value was made by changing the voltage vectors acting on the relay. However, the constants c = and c.! change so that the angular position is changed, whereby in turn (the measure of the change is different, in that one factor remains constant, for example, and only the other I # act (ir is reduced in its angular position Factors c_ and c3 both in size and in their angular position ämleni and again to different degrees, lieisl> ielst @ -eise (len leave one constant and the other alone: change.

It should be pointed out that iuwh (larauf that (las I> hare-turning network can. if the voltage is in its natural phase relation to the measurement `vcr @@ - em (Ict will.

Claims (2)

PA1'E \ TA \ Sf'Itl`CüE: i. Resistance signaling relay for the protection of cables with quality selectivity @ it, (read states that oll iIci- l.eitumgswi (lerstalid falls below or exceeds a certain value (Metwert) characterized by the fact that under additional consideration of a (size c3 - e on the AuAiise side (read lZelais according to the equality; or the equation operates, where L is the line voltage, _1 is the line current and c1, c., and c3 are vector constants, and that the constants c_tnid c 3 are changed to different degrees to change the Nfiwert of the relay. 2. Resistance measuring relay according to claim r, characterized in that one of these factors remains constant in order to change the distance to be measured, while only the other is veined. 3. \\ 'i <lerstam <lsmeßrelais according to claim 1, characterized in that (let the one factor increased, the other is reduced the same amount is increased by which (l (° r other (c3)) is reduced. Resistance measuring relay according to claim t or one of the following, characterized by a relay, on (read the difference between two equal (quantities, one of which acts the rectified geometric difference from a current and voltage vector, the other is the rectified geometric sum of a current and voltage vector. Cited publications: Manfred Schleicher "The modern selective protection technology and the methods for fault location in 1-hole-tensioned areas", `` succumbed to Jul. Springer , Berlin, 1 () 3 (), p. 1 18 to p. 12o.