DE645008C - Protective device in which a rectified network variable is fed to the control circuit of a polarized relay - Google Patents

Description

In order to achieve a delay in the response of a relay, one already has the Charging time of capacitors used. The response relays were in particular Glow relay used. With these there is only a single variable in the relay brought into effect. For the training of quotient relays, however, one has so far purely mechanical retarders are always used. For example, one has Balance beam relay that is activated when a certain ratio between Mains current and mains voltage should respond, a time dependency achieved in that a resistor has been connected in the circuit of one of the relay coils, which through special intermediate relay is constantly changing in size until the Response required value is reached.

However, such a device is relatively cumbersome. Further is their sensitivity not sufficiently large due to the use of numerous mechanical links.

The invention also looks for φ-her in quotient relays Provide electrically unchangeable resistances that automatically set the desired Bring about time dependency. For this purpose, the control circuit of a polarized relay in addition to the one network size, whose rms value changes over time due to electrical invariable resistances is, according to the invention, a second, possibly rectified network variable 'without Interposition of a time delay element is supplied in such a way that the one network variable the current, the other is proportional to the voltage and the response when a certain ratio is reached both takes place.

In Fig. Ι a time-impedance-dependent relay device according to the invention is shown. A current is denoted by ι and a voltage converter is denoted by 11, both of which work via rectifiers 8 and 18 on capacitors 9 and 19. As a result, these capacitors are charged to direct voltages which are proportional to the current / or the voltage U. Under normal operating conditions, the voltage across the capacitor 9 has the opposite sign to that across the capacitor 19, so that the difference between the two becomes effective. This difference is introduced into the lattice circle of the tube 3, that is between the lattice and the cathode. The coil of an actuating relay 5 and an anode current source 6, which simultaneously supplies the heating current via a resistor 20, are located in the anode circuit. If the difference between the rectified currents exceeds a certain value, the discharge continues

*) The patent seeker stated as the inventor:

Dr. Rolf Wideröe in Vinderen, Oslo.

Put the tube on and the coil 5 is energized. The resistors 21 and 22 in parallel with the capacitors are narrow and 19 serve to divert the charge from the capacitors so that the ' Capacitor voltages follow the values of the current / and the fast. '■

A resistor 25 connected in series with the rectifier ensures that the capacitor 9 is charged only gradually. At the start of the fault, the transformers 1 and 11 are switched on by response relays, not shown, which are dependent on the flow phenomena. The voltage across the capacitor 19 is then instantaneously adjusted to an amount which is proportional to the voltage of the line to be protected. The voltage across the capacitor 9, on the other hand, is at the moment of switch-on XuII and only rises gradually under the influence of the invariable resistor 25 in proportion to time. It has the opposite sign to the voltage on the capacitor 19, and only when both voltages are in equilibrium is the voltage XuIl on the grid, ie the voltage required for the start of the discharge process. The trigger condition is therefore Uj = U ₁₁ . But since Uj ~ a'J't, while U ₁ - is proportional to the short-circuit voltage, i.e. U ₁₁ = b U,

becomes a · J · f - b. U or I = - · -, -, ie

a J

the tripping time is directly proportional to the impedance.

An impedance relay, in which the change in one of the characteristic variables over time is caused by the effect of resonance and in which only one rectifier is required, is shown in Fig. 2. A resonance circuit, consisting of a choke coil 2Ü, a capacitor 9 and a resistor 21, which is matched to the Ereijuenz of the Xetzstromes, and whose individual determining pieces represent unchangeable resistances, which a temporal change in the electrical quantity influenced by them, is excluded from the auxiliary transformer 1 bring about. The mode of operation of the arrangement will be explained with reference to Fig. 2a. The voltage across the capacitor 19 runs in a straight line from the moment of the short circuit (t = o) and is proportional to the short circuit voltage. The voltage across resistor 21 follows a sinusoidal curve with increasing amplitude, the end value and envelope tangent of which is proportional to the short-circuit current. The oil switch is triggered when the resulting voltage XuIl appears on the grid of the tube 3 for the first time, i.e. after time t ', which for the same reasons, as already explained, is proportional to the ratio of short-circuit voltage to short-circuit current, i.e. the impedance . -The temporal change of the Xetz sizes. It can also be made in the voltage circuit instead of in the electric circuit.

Fig. 3 shows an example of such a circuit. In parallel with the capacitor 19 is a resistor 22 and a resistor 21 connected, which are alternately switched to the capacitor 19 by the contact lever 29 can be. In the event of a short circuit, the capacitor 19 instantly takes one the short-circuit voltage corresponding charge, then for example by the response relay of the contact lever 29 is moved into the position shown in dotted lines. Of the Current / through the resistor 21 runs ίο then according to the equation

R ^e ~ T

The voltage at the grid of the tube 3 becomes zero when the voltage drop / · R across the resistor 21 has become the opposite of the voltage drop Uj across the capacitor 9, that is to say

Uj

It follows:

e

Ur

t-.Tln-

The tripping characteristic of this relay is therefore time-dependent due to the resistors 19 and 21, which are not regulated in any way. This results in the Character shown in Fig. 3a, which has advantages for some types of power lines offers.

A reactance relay is shown in Fig. 4. The transformer 1 has two secondary windings 1 'and 1 ", each of which has a capacitor 9' via a rectifier 8 'or 8" 1) between 9 "charges. The transformer 11 operates on a resonant circuit, consisting of the capacitor 29, the choke coil 28 and the resistor 30. The geometric sum the alternating voltages on the secondary winding Γ of the transformer 1 and on the Choke coil 28 is rectified in the rectifier 18, the capacitor 19 takes a direct voltage corresponding to this geometric sum. In the grid circle the condensers 19, 9 'and 9 ″ are accordingly connected in series to the tube 3.

The mode of operation of the circuit will be explained using the xao vector diagram in Fig. 4 a. / and U mean the current resp.

the voltage of the line proportional secondary voltages of the transformers ι and ii; so the voltages on the secondary winding i 'of the transformer ι or on the secondary winding of the transformer 11. The phase angle existing between these voltages corresponds to the phase angle between short-circuit current and short-circuit voltage. The current / proportional

ίο The voltage is connected in series with the voltage drop across the choke coil 28, which in turn is phase-shifted by 90 ° with respect to the voltage U. The capacitor 19 is charged via the rectifier 18 to a direct voltage proportional to the geometric sum, that is to say to the vector V (path F ₁ -P ₃ in FIG. 4a). This DC voltage is connected to that of the capacitor 9 ', which the current / in to

is proportional to the protective line, so that the difference is effective as the resultant of these two capacitor voltages (path P _{2 -P 3} in Fig. 4a). As can be seen from the figure, this difference is approximate.

- U cos (go ° - φ) - L / sin 99.

In the practical cases, Cf will remain so small that this approximation is permissible. Because of the unchangeable resistance 25 ″ in the rectifier circuit, the voltage across the capacitor 9 ″ rises proportionally with time, without any regulation being required. When this voltage has become equal to the differential voltage of the capacitors 19 and 9 ', the discharge begins and the coil 5 is excited.

Fig. 4b shows the course of the grid stresses over time. The point at which the discharge begins is denoted by A = ο. Positive voltages are plotted upwards, negative voltages downwards. Uf is the positive voltage on capacitor 9 ″, which increases proportionally with time, U / is the likewise positive voltage on capacitor 9 'and Uy is the negative voltage on capacitor 19. The resultant of these three direct voltages acts on the grid of tube 3, as shown in Fig 4b is drawn in dotted lines. This resultant decreases as the voltage Uf increases; once it has become zero, the discharge begins.

A similar consideration, as it was carried out in the description of the impedance time relays, shows that the tripping time of the relay of the size - - τ - ^ ~ - ie the reactance

is proportional.

If the circuit in Fig. 4 is modified so that in series with the voltage 1 'des Transformer 1 the secondary voltage of the Transformer il is switched itself, so you get a relay whose tripping time of

of the size γ - * -, i.e. the resistance from

t /

hangs. Such relays are preferably used in cable networks with low reactance, while reactance-dependent relays in lines with strong inductance, for example used in overhead lines.

The characteristic of the discharge tube.3 must always be biased by a grid be corrected so that the onset of discharge takes place exactly when the difference between the capacitor voltages effective in the grid circuit has just become zero is.

The tripping characteristic of the relay described is, at least as long as it is linear Part of the voltage curve of the capacitor 9 is worked in a straight line. In some cases however, certain deviations from this straightness are desirable, as already mentioned in Fig. 3. These requirements can expediently be met in that transformers 1 and 11 have a constriction in the iron path (series saturation) or a magnetic shunt to the secondary winding (Parallel saturation). Similar effects can also be caused by voltage-dependent Resistances can be achieved.

The response relays can be used appropriately to control the timing relay ' to protect against interference from leakage currents and the like in the idle state. Some of those The facilities are shown in Fig. 5. The capacitors 9 and 19 are in the idle state the timing relay bridged by normally closed contacts 31 and 32 of the response relay; the The grid of the discharge tube 3 receives a negative potential in the idle state (blocking potential) opposite the glow wire through the normally closed contact 33 of the response relay. The anode circuit of the tube 3 is at rest opened by normally open contact 34 of the primary relay.

If no DC voltage is available in the relay station, the tube 3 can also be replaced by a polarized relay and another rectifier. the Corresponding circuit is shown in Fig. 6 using the example of the impedance time relay. In the rectifier circuit of the current / a resistor 25 is switched on, which increases the time of the current in the capacitor 9 is influenced. The voltage across the capacitor 9 increases from the moment it is switched on

the curve Uj = Cj (1 - e —ψ- J an. U is the voltage across the capacitor 9, / which is to be

waking current, c a constant, e the base of the natural logarithms, t the time and T the time constant of the circle i, 25, 8, 9. The first part of this curve can be viewed with a close approximation as straight and is in this area through the equation

Vj = a Jt

shown, in which α means another variable that depends on the circuit constants. The voltage across the capacitor 9 accordingly rises in a straight line as a function of λόπ time. As long as the voltage on the capacitor 19 is higher than that on the capacitor 9, the rectifier 35 blocks the flow of current through the relay 3 (1. If, on the other hand, the voltage on the capacitor 9 is higher, the relay 36 is energized and closes the circuit of the trip coil For this case, particularly sensitive relays, e.g. polarized relays, are used according to the moving coil principle in order not to overload the current transformer or to have to work with capacitors 9 and 19 that are too large.

To make the time relay, mainly its dry rectifiers and capacitors, even against strong temperature fluctuations insensitive that \ ^r er \ vendung is appropriate from temperaturabhUngigen Korrektionswiderständen. This makes the relay particularly suitable for unattended or open-air stations. To eliminate the influence of current fluctuations, voltage-dependent Yor resistors can also advantageously be used in the heating circuit of the tube.

Claims (5)

Patent claims: i. Protection device in which a rectified network variable is fed to the control circuit of a polarized relay, the rms value of which is changed over time by electrical invariable resistors (25, 21) until it reaches the response value of the relay, characterized in that a second, possibly rectified network variable (U ) is fed to the control circuit without the interposition of a time delay element, in such a way that one network variable is proportional to the current and the other to the voltage and the response occurs when a correct ratio of both is reached. 2. Protection device according to claim 1, characterized in that the one Network size, the effective value of which is to be changed over time, acts on a resonance circuit (28,9,21) in such a way that it only gradually reaches its final value. 3. Protection device according to claim 1 and 2 for reactance-dependent protection devices, characterized in that in the control circuit of the polarized relay a direct voltage proportional to the vector sum of mains current and mains voltage (P ₁ -P ₃ ) and this counteracted by a direct voltage proportional to the mains current (P ₁ -Pt) is inserted (Fig. 4 and 4a). 4. Protection device according to claim 1 to 3, characterized in that for Achieving a linear release characteristic of one of the ratio of voltage the time-delaying resistors for the protection device that is dependent on the current or a similar resistance function (21) are effective in the circuit that is proportional to the mains current Voltage is excited to achieve a logarithmic release characteristic on the other hand, in the circuit that is proportional to one of the mains voltage Voltage is excited (Fig. 1, 2 or 3). 5. Protection device according to claim 1 to 4, characterized in that as polarized relay a gas or vapor-filled discharge tube is used, whose grid current and voltage are fed to the network to be monitored. 1 sheet of drawings