DE835021C - Device for protecting contacts, which are preferably operated in rapid succession, especially in the case of Tirill regulators - Google Patents

Description

Device for the protection of preferably operated in rapid succession Contacts, in particular with .Tirill regulators The invention relates to a device to protect contacts that are preferably operated in rapid succession, in particular in Tirill regulators or the like for direct current circuits containing inductances which the inductance by a valve blocking in the operating current direction is bridged. To reduce the opening spark, switch to the switch contacts a capacitor in parallel. But not when the contacts are reclosed the discharge surge of the capacitor can damage the contacts, is after a earlier suggestion a switching choke for the contacts, preferably a pre-magnetized one Switching throttle with an approximately rectangular hysteresis loop switched in Reilte.

\ Venn also the switching throttle the contact damage when closing eliminated, it also has the disadvantageous effect of opening the contact to generate a very short but very high voltage peak, which causes the spark formation favored. The duration of this voltage spike is so short that it even with the usual Kafhodenstrahloszillographen even at the highest writing speed can not dissolve, but appears as a thin vertical line. Mostly is the voltage peak so high that it is the necessary, fairly high, at the contacts Exceeds the ignition voltage of the air. But once the spark is ignited, it can it continues to burn with a low operating voltage. Usually it exceeds after this voltage spike following contact voltage this burning voltage. The contact clamping is the sum of the inductor voltage and the voltage on the capacitor parallel path. There at the moment of contact opening the latter starts at zero, so is for the Spark formation, especially the behavior of the switching throttle, is decisive.

If you already have a switching choke with two windings with the contacts, one through which the current to be switched flows and one for premagnetization serving, so to speak a transformer used, so according to the invention those necessary to suppress sparks, avoid contact damage or the like Means at least partially instead of directly in the circuit to be switched in the circuit connected to it in a transformer, i.e. with premagnetized switching chokes in the pre-magnetization circuit. This gives you greater freedom of movement for the circuit, the dimensioning and selection of these means, because one z. B. already with regard to the voltage by using an appropriate gear ratio in the transformer is not tied to the circuit to be switched. So z. B. the invention can be used in such a way that from the throttle at the contact opening generated high voltage spike is suppressed without the conditions at, the contact closure are worsened. In the usual Circuit with bias is the bias current by means of a resistor set. By connecting a resistor, however, it is now closed at the moment of closing the current is a little higher than without an upstream resistor, and the voltage peak is also increased when opening. The increase in current when the contacts are closed is explained by the fact that at this moment the switching inductor has a counter voltage to the Operating voltage of the circuit to be switched induced. The former becomes transformative transferred to the bias winding. The result in the bias circuit the resulting additional voltage increases the bias current. The increase of the bias current is corresponding to the turns ratio of the two Switching inductor windings with an increase in current at the moment of contact closure tied together.

According to the invention, the one that is not in the circuit to be switched is now Winding of the switching inductor or the transformer is an ohmic resistor with a parallel capacitor and an inductivity with a parallel valve blocking in the operating current direction upstream, as shown in more detail with reference to the examples shown in the drawing is explained. 'Here the voltage of a direct current generator 1 is about the Tirill principle by continuously switching its excitation winding on and off 2 regulated by means of a switch 3. There is a @ in the direction of excitation winding 2 of the operating flow blocking valve g indicated by arrows P in parallel. To the Switch 3 is one winding 6 of a switching inductor 7 in front, both is a capacitor d connected in parallel with series resistor 3. The switching inductor 7 is made by a winding 8 premagnetized. It has an approximately rectangular hysteresis loop. The winding 8 is a resistor io with a parallel capacitor i i and an inductance 12 with upstream of the blocking parallel valve 13 in the direction of the operating flow.

The arrangement works as follows: When the switch is opened 3 suffer the ampere turns dir winding 6 of the switching inductor 7 as a result of the current interruption a jump. But is there a magnetic quadrupole that the switching reactor? represents always striving to get its total amp turns, otherwise it will generate Tensions on its windings that counteract the change in total ampere turns. At the moment the switch 3 is opened, the magnetic field strength remains in the iron of the choke 7, since the changes in the ampere turns in the winding 6 compensated by a corresponding change in the ampere turns in the winding 8 Nverden; because immediately after the switch 3 is opened, an equalizing current flows Via the capacitor i i and the valve 13. The previously approximately discharged the full operating voltage charged capacitor i i. The charge on the capacitor i i results from the fact that after reaching the steady state, it acts Concerning direct current, the voltage drops in inductors 8 and 12 are very small are compared to your voltage drop in the resistor io, so that about the full Operating voltage across the resistor io and consequently across your capacitor i i lies. When the switch 3 is opened, only a limited voltage jump can occur form in the bias circuit 8, io to 13, since the capacitor i i is not lets discharge suddenly and the valve 13 current-permeable immediately after opening the switch will. This small voltage jump corresponds to the sum of the voltages in the inductance 12 before the switch opening and on the valve 13 after the switch opening. The voltage at valve 13 is caused by the voltage drop in the valve current. if the voltage drop in valve 13 is neglected or during the opening period of switch 3 is assumed to be constant, the voltage on the winding increases 8 to the same extent as the capacitor voltage drops.

Is the steeply sloping branch of the hysteresis loop of the switching throttle 7 run through, so if this no longer generates a voltage, it returns to the inductive ität 12 lying voltage, which is equal to the voltage at valve 13, its sign around. The valve 13 blocks the passage of current in this direction, and the capacitor i i is charged again via the inductances 12 and 8.

As a result of the current interruption at switch 3, the excitation of the generator ceases i and with it his tension back. Once they reach a certain lower limit reached, the switch 3 is closed again. The premagnetized Choke 7 a delay in the discharge current surge of the capacitor 4, which is charged when the switch 3 is opened by swallowing the opening spark until switch 3 has been fully closed. During the closing process of the switch, the current passes through a relatively low current level. Within the running time of the current stage induces the switching inductor 7 a voltage because the Inductance 12 and the now blocking valve 13 a change in current in the Bias circuit opposes a resistance. The inductance 12 is generated at the same time a voltage which is the same as the choke voltage, but in the opposite direction. Conditional This voltage increases the current flowing through the inductance 12, with the The result is that the current level mentioned is not constant, but rather slightly increasing Electricity is passed through, but this can easily be accepted.

The advantage of the arrangement described is that the disadvantageous effect of the switching inductor 7, namely the voltage spike opening glue of the switch 3, is suppressed because d'ie special circuit in the bias circuit 8, io to 13 an abrupt change in the magnetic field strength of the switching inductor 7 impossible or, in other words, because the loss of ampere turns in winding 6 caused by opening switch 3 is compensated for by an increase in ampere turns in winding 8. The switching throttle does not have a very disruptive effect when the switch 3 is opened and is consistently favorable in terms of protecting the contacts when the switch 3 is closed.

The arrangement according to FIG. I with a capacitor it connected in parallel to the resistor io is best used only when the bias circuit s is preferably fed separately from a low-inductive and low-resistance voltage source (accumulator battery). Otherwise, when the contact 3 is opened, the associated sudden drop in the current in the voltage source and in the supply line will induce a voltage spike as a result of their inductances. The voltage equilibrium previously prevailing in the bias circuit is disturbed, and since the capacitor ii cannot suddenly discharge and the choke 12 is bridged by a valve 13 , the bias winding 8 of the switching choke 7 takes over this voltage peak. It is transmitted by means of a transformer to the main winding 6 of the switching reactor. But since the sum of the voltages on the switching throttle and on the parallel path 4, 5 is the same as that between the opening contacts 3 and the voltage on the parallel path rises steadily from zero without any peaks after the opening moment of the latter, the one generated by the switching throttle settles Voltage peak at the contacts 3.

According to the invention, this voltage spike can occur as a result be avoided that the capacitor i i not only the resistor io, but the voltage source is also bridged.

With the arrangement according to FIG. 2, no voltage jumps or voltage peaks can be generated on the preniagnosis winding 8 of the switching throttle when the contacts are opened and then during their remagnetization, since during this time the valve 13 is current-permeable and the capacitor voltage increases monotonically from zero. However, in this circuit too, an impermissible voltage may arise between the opening contacts 3. The ohmic voltage drop caused by the operating current in the main winding 6 of the switching inductor cannot be compensated by means of a transformer from the premagnetization side. Immediately after the power interruption in the main circuit, this ohmic voltage drop is applied to the contacts and, if it is sufficiently large, initiates a switch-off spark.

It is also best to combat the adverse effects the switching throttle to generate voltage peaks at the moment of opening, not from the cables of the pre-magnetization circuit, but rather in the main circuit, because the iron of the switching inductor at this moment through the over its main winding flowing and disconnected operating current is saturated and consequently the switching inductor allows only a small transformational transmission.

The circuit shown in FIG. 3 is therefore used to maintain the magnetic field strength of the switching inductor immediately after the moment the contacts 3 open. In this circuit, immediately after the contacts have opened, the main winding 6, valve 13, capacitor ii circuit takes over the full operating current, and the current in this circuit only decreases when this capacitor ii is charged. In this way, the ohmic voltage drop in the main winding 6 of the switching inductor only gradually decreases. The switching inductor 7 induces according to the charging of the capacitor i i. This means that the contact voltage cannot suffer any jumps when the contacts are opened and then during the remagnetization of the switch actuators.

However, in the circuit according to FIG. 3, an additional choke 14 is required which has the task of discharging the capacitor ii after the magnetization of the switching di-ossel7 has been reversed. With little difference in its mode of operation, the throttle 14 can be switched so that it bridges not the valve 13, but the capacitor ii. If the demands on the circuit are not so high, the choke can be replaced by a resistor. In order to achieve greater freedom in the dimensioning of the switching throttle damping circuit, consisting of a valve 13, capacitor iz and throttle 14, the main winding 6 of the switching throttle 7 is implemented in the economy circuit and the damping circuit according to FIG. 4 or 5 is connected.

In the exemplary embodiment, only part of the was used to protect the contact serving means in the transformer-coupled with the operating circuit Circuit the winding 8 relocated. Of course, other means can also be included in this group to protect the contact, if necessary with the help of tertiary or quaternary circuits, which act in such a way that in each case those occurring at the switch Currents and voltages are canceled out by induced counter currents or voltages.

The particular advantage of the invention is that (leave one for the Switching, dimensioning and selection of the means to protect the contact greater freedom of movement than if one were to put these funds into the operating circuit as before have to switch on myself.

Claims (6)

PATENT CLAIMS: i. Device for the protection of contacts, preferably operated in rapid succession, in particular in the case of Tirill regulators, with a switching throttle connected upstream of the contacts, characterized in that at least some of the means used for contact protection (in particular 1o to 13) are transformed into the transformer (by d'ie Switching throttle 7) is switched on with the operating circuit (2, 6, 3) coupled circuit (8, to to 13) . 2. Device according to claim i with pre-magnetized switching throttle, characterized in that the bias winding (8) of the switching throttle (7) has a resistor (to) Parallel capacitor (ii) and an inductance (i2) with in the operating current direction (Arrows P) blocking parallel valve (t3) are connected upstream. 3. Apparatus according to claim i and 2, characterized gekennzeichtict that the VormagnetIsierungskreis (8, to 1) is 13 in Fi, g. i), preferably separately, is connected to a low induction and w-id-low SI) aiititiligs (luelle (battery)). 4. Device according to claim 1, characterized in that in series with the pre-magnetization winding (8 in F], 2) a resistor (io) and a throttle (12) that are parallel to this winding (8), a capacitor (i i) and a valve (i3) are old-closed and the connection between capacitor (ii) and X "elltil (l3) with this winding (8) opposite I? Li (le of the choke (i2) is short-circuited. @. A device for suppressing the spinning precursors according to claim i, characterized in that with the bias winding (8 in Fig. 3) of the switching throttle (7) an oil switch (io) and an indicative resistance (i2) lie in series and parallel to the main winding (6) of the switching throttle (7) are connected by a throttle (t4) or a resistor bridged valve (13) and a capacitor (ii). 6. Provision according to. = \ Tisl) rttcli i and s, characterized in that the throttle (1d in Fig..l and 5), (read valve (i3) and the capacitor (i i) containing parallel circuit in economy circuit an extension (Fig. 4) or a, -. lnzapfung (Fig.;) of the Hattl) development (6) of the Switching throttle (7) is connected.