DE1590522B1 - Circuit arrangement for switching delay of relays - Google Patents

Description

The invention relates to a circuit arrangement for switching delay a relay by means of an additional inductance.

It is known to achieve switching delays in capacitive relays or to use inductive timers. Both types of timers have the Disadvantage that it influences the control current of the switching means to be switched exponentially. As a result, the switching threshold of the switching device is passed through flat, and the flatter the greater the delay time with a certain timing element shall be. Changes in the switching threshold, such as B. by the electrical and mechanical tolerances of the switching means are to be expected, therefore have a result in a relatively large spread of the switching delays.

The object of the invention is to provide a circuit arrangement to create switching delay by means of an additional inductance in which the switching threshold of the relay is traversed as steeply as possible, at which it is possible simple, reliable and easily manufactured components are used and in which, without additional switching elements, constant, from the tolerances of the relay allow independent delays when switching on and / or off.

This is achieved according to the invention in that on a core With an almost rectangular magnetization loop, two windings are applied are and that one of the two windings with a bridging this and the relay winding Rectifier is in the excitation current path of the relay, the other winding against it, Applied in the opposite direction to the first winding on the core, via an auxiliary closing contact of the relay is connected to voltage.

It is known that cores with such magnetizing loops need a voltage surge of a certain magnitude to move from one to the other saturation area to get. This saturation area change is referred to below as forward, backward or Called folding down. The turn-over time depends on the number of turns of the core winding, depends on the applied voltage and on the core constant. Since the core constant not or only insignificantly due to influences of temperature, air humidity and aging changes, delay times can also be very short for this reason Achieve scattering range.

With such an arrangement, a response delay can be achieved in an advantageous manner and a fall-out delay can be achieved. A similar one can also be used for the same purpose Solution can be used, in which the influence of the self-inductance of the Relay to which the delay times should at least be reduced. This solution is characterized according to the invention that on a core with an almost rectangular Magnetizing loop two core windings are applied to that one of these core windings in series with a first relay winding; and a control closing contact to the both poles of an operating DC voltage source is connected, that the other Core winding in a bridge branch one through an auxiliary closing contact of the relay Resistance bridge that can be connected to the two poles of the operating DC voltage source is arranged, in the diagonal branch of which is not connected to the operating DC voltage source the series connection of a first rectifier and a second relay winding and in the other branch of the bridge, which together with the second core winding containing bridge branch connected or connectable to the same operating voltage pole is, in addition, a second rectifier is arranged that relay windings and Core windings are polarized such that with the closing of the auxiliary make contact the second core winding is excited in the opposite direction to the first core winding and after Reopening of the control closing contact for the relay via its second winding the dropout delay period is maintained and that the rectifiers are poled in this way are that the voltage induced in the second core winding and that when switching off the first relay winding in the second relay winding induced voltage Generates electricity.

If only a drop-out delay of the relay is to be achieved, then proposed an advantageous solution, which is characterized in that on a core with an almost rectangular magnetization loop, two core windings are applied that one of these core windings with a series-connected Rectifier is parallel to the relay, which is in series with a resistor and a further rectifier by means of a control closing contact to the two Poles of an operating DC voltage source can be connected, and that the other core winding in the diagonal branch not connected to the operating DC voltage source, one to this Operating DC voltage source connectable resistance bridge is arranged, the one side of the bridge through a control closing contact and the other side of the bridge through an auxiliary closing contact of the relay to the same pole of the operating DC voltage source can be switched on in such a way that after the control closing contact is reopened a voltage holding the relay is induced in the first core winding.

If, on the other hand, only a response delay of the relay is to be achieved, so another advantageous solution is proposed, which is characterized is that on a core with an almost rectangular magnetizing loop two Windings are applied that one consisting of three resistors, over one Control make contact provided to a voltage source switchable voltage divider is that the control contact side tap of the voltage divider with the same direction Ends of the two core windings is connected, one of which is connected to the other end of the winding via the relay to the pole of the not switched by the control closing contact Voltage source and the other with the other end of the winding to the other tap of the voltage divider is connected that the control closing contact voltage divider side can be connected to the relay via an auxiliary closing contact of the relay and that both core windings are polarized and have such a turns ratio, that during the turn-over time which expires after the closing of the control closing contact of the core no significant current flows through the relay.

The invention is explained in more detail using several exemplary embodiments. It shows F i g. 1 and 6 circuit arrangements to achieve response and dropout delays a relay, F i g. 5 shows a circuit arrangement for achieving Dropout delays of a relay, FIG. 7 shows a circuit arrangement for achieving this of response delays of a relay, F i g. 2, 3 and 4 a simplified equivalent circuit diagram, a magnetization loop of the core material used and the current flow in the relay, all three representations referring to the F i g. 1 refer.

In FIG. 1, a control contact s connected to the positive pole of a voltage source, a first core winding W l, a relay A and a resistor R 1 are connected in series to the voltage source, with a rectifier G 1 connected in parallel to the series circuit of the first core winding W 1 and relay A is. In a further circuit, a second core winding W 2 and a resistor R 2 are in series. This circuit can be closed by a normally open contact a of relay A connected to the positive pole of the voltage source. Both windings W 1, W 2 are applied to a core, not shown, which has an almost rectangular magnetization loop, such as that shown in FIG. 3 is shown. The points at one end of the core windings W 1, W 2 indicate the beginning of these windings, based on the same flow direction. The point on the core winding W 1 is set to the positive, the point on the core winding W 2 to the negative pole of the voltage source.

It is assumed that the core is in the negative remanence point and the control contact is open, so that no current IA flows through the relay A (points 1 in FIGS. 3 and 4). If the control contact s is now closed, a very specific time, the flip time, is required to bring the core from the state of negative saturation to the state of positive saturation. During this turn-over time, the core winding W1 forms a high-ohmic resistance, so that only a lower relay current flows (section to to t1 in FIG. 4). When positive saturation is reached, the upper right corner of the magnetization loop, the core winding W 1 forms a low-ohmic resistance, so that the relay current 1A rises steeply, the steeper the less rounded the corner of the magnetization loop. This also causes the response value lan of relay A to pass through steeply. The resistor R 1 limits the relay current (point 2 in FIGS. 3 and 4).

The relay A responds. After the closing of the contact a flows a current through the core winding W2, which the field strength in the core around a certain Amount decreased. This amount (Section 2 to 3, Fig. 3) must be at least as follows be large so that the core can just be folded back (section 1 to 5, Fig. 3).

If the control contact s is opened again, the excitation of the core winding W 1 by the voltage source does not occur. The path 3 to 4 of the magnetization loop is traversed in a very short time, and the relay current 1`1 decreases (t 2 in FIG. 4). During the fallback time in which the magnetization loop is passed from point 4 to the lower left corner, however, a voltage is induced in the core winding W 1, which drives a current through the relay A and the rectifier G 1 of such magnitude that it is still over the drop value lab of relay A (section t2 to t3 in Fig. 4). When the negative saturation is reached, the core windings are decoupled. The relay current 1A decreases rapidly (t3, Fig. 4). Relay A thus drops out. After contact a is opened, the core again assumes the state of negative remanence (point 1, FIG. 3).

The conditions after reopening the control contact s are in the simplified equivalent circuit diagram in FIG. 2 shown. In series with the The voltage source is the resistor R2 and the ohmic resistor RW 2 of the core winding W2, the switching resistance RK, which is to be regarded as the equivalent resistance for the magnetization losses and the low inductance L2 of the core winding W 2. The series connection of the flap resistor RK and inductance L2 is a series circuit in parallel, which consists of the translated Resistors Rw r ', G 1', A 'of the ohmic resistance of the core winding W l, des Rectifier G1 and relay A consists. During the turn-over time, the turn-over resistance is RK in comparison to the relay resistance A 'relatively large, so that through the relay A holding current can flow. When saturation is reached, the flip resistance increases RK shows the value zero. As a result, the inductance L2 is also negligibly small is, the relay resistor A 'is practically short-circuited, whereby the relay A drops out.

It is sometimes desirable to reduce or prevent the influence of the relay's self-inductance on the delay times. To reduce this influence, it is advisable to use relays with low self-inductance, e.g. B. low-resistance relays to be used. If this route is not feasible, a circuit arrangement according to FIG. 6 can be used. There are again a first core winding W 1 and a first winding AI of a relay A in series with a voltage source in the control circuit. Another circuit contains a resistor bridge R 7, RS, R9, W2, in which one branch of the bridge is formed by a second core winding W 2 and the diagonal branch by a second winding A II of the relay A. The resistance bridge can be connected to a voltage source through a contact a of relay A. A rectifier G 5 or G6 is connected in series with the second winding A II or the resistor R 9.

After closing the control contact s, the core is folded over the core winding W 1. The voltage induced in the second core winding W 2 when it is folded forward blocks the rectifiers G 5, G6 so that no current can flow in the second circuit. After the folding process, relay A responds. As soon as the contact a is closed, the core receives a slight counter-excitation via the core winding W2. As a result of the low resistance of this winding, the rectifier G 5 remains blocked and only the rectifier G 6 becomes conductive. If the control contact s now opens, the core winding W 2 offers a high resistance, so that the rectifier G 5 becomes conductive and a holding current flows through the winding A II.

This holding current is suddenly switched off when core saturation is reached, because then the core winding W 2 again represents a very low resistance and the rectifier G 5 is blocked again. The one when switching off the winding A II voltage generated at it can only change with its reverse voltage of the rectifier Exceeding G5 Partly have an insignificant effect on the drop-out delay.

If the relay is not to be delayed on, but rather delayed on, a circuit arrangement according to FIG. 5 appropriate. In Fig. 5, a control contact s, a rectifier G 3, a relay A and a resistor R 3 are arranged in series with a voltage source in the control circuit, the relay A being a series circuit of a rectifier G 2 polarized against the direction of the control current and a first core winding W. 1 is connected in parallel. A second core winding W 2 is located in the diagonal branch of a resistor bridge G4, R4, R5, R6 that can be connected to a voltage source, one side of which can be switched by the control contact s and the other side of the bridge by a contact a of the relay A to the positive pole of the voltage source. The rectifiers G 3, G 4 are used to decouple the two circuits; these rectifiers can also be saved if a further contact of the control contact is used.

If the control contact s is closed, the relay A speaks immediately at. At the same time, the core is folded over the core winding W 2. A stream Cannot flow through the core winding W 1 at this moment because the rectifier G2 both by the voltage induced in the core winding W 1 and by the Voltage source is blocked. As soon as the contact closes, the excitement decreases the core winding W 2 by a certain amount. After reopening the control contact The folding back process takes place via the core winding W 2 by changing the direction of the current. A voltage is generated in the core winding W 1, which is transmitted via the relay A and the rectifier G2 drives a current until core saturation is reached.

If the relay is not to be drop-out delayed, but only to be delayed on, a circuit arrangement according to FIG. 7 can be used. A voltage divider consisting of three resistors R 16, R 14, R 15 is provided there, which can be switched to a voltage source with a control contact s. The tap of the voltage divider on the control contact side is connected to the ends of two core windings W l, W in the same direction. The other end of the core winding W is connected to the negative pole of the voltage source via a rectifier G 8 and a relay A, while the other end of the core winding WI is connected to the further tap of the voltage divider. Furthermore, the control contact s on the voltage divider side can be connected to the connection point between the core winding W and the rectifier G8 via a contact a of the relay. After the control contact is closed, the core is folded over the core winding WI. During the pre-folding time, a voltage is generated in the core winding W which is opposite to that of the voltage source. If both voltages are chosen to be equal, the rectifier G 8 can be saved without a current flowing through the relay A during the pre-folding time. If the voltage induced in the core winding W is selected to be greater, the rectifier G 8 is blocked and a current flow through the relay A likewise ceases. Only when the core is saturated is no voltage induced in the core winding W, so that the rectifier G 8 becomes conductive and the relay A can respond. By closing the contact a , the polarity of the core winding W is reversed and the core is thus folded back. The excitation of the core winding W must of course exceed the excitation of the core winding W 1 accordingly.

It can not only electromechanical switching means, such as relays, but electronic switching means are also delayed in a similar manner, these electronic switching means can be composed of several components, how it z. B. is the case with flip-flops.

Claims (6)

Claims: 1. Circuit arrangement for switching delay of a relay by means of an additional, a magnetizable core having inductance, characterized in that two windings (W1, W2) are applied to a core with an almost rectangular magnetizing loop and that one of the two windings (W1) with a this and the relay winding (A) bridging rectifier (G1) is in the excitation current path of the relay, the other winding (W2), on the other hand, applied in the opposite direction to the first winding (W1) on the core, via an auxiliary closing contact (a) of the relay (A) Voltage is (Fig. 1). 2. Circuit arrangement for the switching delay of a relay by means of an additional inductance having a magnetizable core, characterized in that two core windings (W1, W2) are applied to a core with an almost rectangular magnetizing loop, that one of these core windings is in series with a first relay winding (AI) and a control closing contact (s) is connected to the two poles of an operating DC voltage source that the other core winding (W2) in a bridge branch of a resistor bridge (R 7, R 8, R 9) is arranged, in the diagonal branch of which is not connected to the operating DC voltage source, the series connection of a first rectifier (G 5) and a second relay winding (A 1I) is located, and in its bridge branch, which, together with the bridge branch containing the second core winding, is connected to the same operating voltage voltage source pole is connected or connectable, in addition a second rectifier (G 6) is arranged that relay windings and core windings are polarized in such a way that when the auxiliary closing contact is closed, the second core winding is excited in the opposite direction to the first core winding and after the control closing contact (s) is reopened the Relay via its second winding (A 1I) is held for the drop-out delay period and that the rectifiers are polarized in such a way that the voltage induced in the second core winding (W2) and the voltage induced in the second relay winding (A II) when the first relay winding (AI) is switched off ) induced voltage does not generate any current (F i g. 6). 3. Circuit arrangement for switching delay a relay by means of an additional, one magnetizable core having inductance, characterized in that on a core with an almost rectangular magnetization loop, two core windings (1Il 1, W2) are applied that one of these core windings with one in series connected rectifier (G2) is parallel to the relay (A), which is in series with a resistor (R 3) and a further rectifier (G 3) by means of a Control closing contact (s) to the two poles of an operating DC voltage source can be connected, and that the other core winding (W2) is not connected to the operating DC voltage source lying diagonal branch can be connected to this operating DC voltage source Resistance bridge (G 4, R 4, R 5, R 6) is arranged, one bridge side of which through a control make contact (s) and the other side of the bridge through an auxiliary make contact (a) the relay can be switched to the same pole of the operating DC voltage source, in such a way that after the control closing contact is reopened the relay sustaining voltage is induced in the first core winding (FIG. 5). 4. Circuit arrangement for the switching delay of a relay by means of an additional, magnetizable one Core having inductance, characterized in that on a core with almost rectangular magnetization loop two windings (W1, W) are applied, that one consisting of three resistors (R 16, R 14, R 15) via a control closing contact (S) a voltage divider switchable to a voltage source is provided that the Control contact side tap of the voltage divider with the same ends of the two core windings is connected, one of which is connected to the other end of the winding the relay to the pole of the voltage source that is not switched by the control closing contact and the other end of the winding to the other tap of the voltage divider is connected that the control closing contact voltage divider side via a Auxiliary closing contact of the relay can be connected to the relay and that both core windings are polarized and have such a turns ratio that during the turn-over time of the core after the closing of the control closing contact no significant current flows through the relays (Fig. 7). 5. Circuit arrangement according to claim 4, characterized in that a rectifier (G 8) is in series. 6. Circuit arrangement according to one of claims 1 to 5, characterized characterized in that relays with lower self-inductance are used.