DE1537858C - Circuit arrangement for achieving defined switching times for shutdown processes in telecommunications, in particular remote intercom systems - Google Patents

Description

In telecommunications, especially telephone systems, magnetic relays are used with a large number of Contacts are used that allow a number of switching operations corresponding to the number of contacts to be triggered depending on the excitation state of the relay. When closing or opening the excitation circuit for such a relay the current rise or fall takes place according to a known e-function, which, after an infinitely long time, is asymptotically determined by the operating voltage and resistance of the Excitation circuit specific maximum value or when opening the excitation circuit the current value Approaching zero. The relay speaks after a much shorter time, namely when it is reached of the response current, and also falls after a much shorter time, namely when the value falls below the threshold of the holding current. It is now known, through special switching measures, the response or the To influence the fall time of a relay in one direction or the other.

When using relays in which all contacts are actuated by a common armature, the individual switching processes controlled by the relay contacts are generally triggered at the same time, regardless of whether the response or fall time is due to special switching measures of the relay is delayed or not.

If, on the other hand, one uses relays with individual armature contacts - what are meant are relays in which the individual Contacts are operated by an individual armature or their contacts the armature form themselves - so there is a simultaneous closing or opening, especially with delayed relays of contacts not given. The response and fall times of the individual armature contacts vary in such a way that that the proper functioning can be significantly disturbed. The causes of these dispersions in the pick-up and drop-out times for relays with single armature contacts are once in this Relay own construction and on the other hand in the difficulty of using magnetic sheets in the smallest Unit of volume to produce completely the same electrical and magnetic values. With the relays With individual armature contacts, the magnetic circuit runs separately over the individual contacts individually assigned armature, of which, for example, four from a common excitation coil be enclosed. It is impossible with economic means to separate the individual magnetic circuits to train in their magnetic and electrical values completely the same. The slightest inconsistency of the magnetic sheets, different air gaps, different spring forces, different Moving masses of the armature are, although the individual deviations move within very narrow tolerances, Causes which in their entirety lead to inconsistent magnetic circles and thus to scattering in lead to the pick-up and drop-out times of the individual armature contacts.

The resulting spread for the fall and rise times is increased by the following Appearance: B. from an armature of an energized relay, the resistance increases in it magnetic circuit considerably, which increases the flux in the remaining, still closed armature circuits Consequence. , The further consequence is that the remaining closed anchors only at lower values of the Open the waste stream. With the low steepness of the current curve in its asymptotically approaching zero In some cases, this results in considerable time differences. The same applies to tightening of the relay.

To avoid these difficulties, it is already known that the delayed. Relay with a to couple an instantaneous auxiliary relay as a slave relay, the contacts of which are then actuated almost simultaneously will. Often, however, the starting relay that triggers the delay is also shaded with a delay. For example, at higher voltages it may be necessary to use a capacitor for spark quenching parallel to the relay, which inevitably leads to a delay. On the other hand certain time conditions can be set for the switching processes initiated by the starter relay, which require a delay circuit. Due to the delayed start relay, the point in time can be to which the contact triggering the delay process opens, spread considerably and the Functional processes are disturbed as a result. This could be done by inserting a further Auxiliary relays analogous to the known solution can be avoided, but the consequence would be even greater Effort and a confusing circuit structure. .

The purpose of the invention is now to provide a circuit arrangement with as little effort as possible create that, despite variations in the fall times of the individual armatures of delayed-switched relays with Single armature contacts allow the simultaneous triggering of switching processes controlled by these contacts allows an approximately precisely defined point in time, even when the starter relay to Control of the delayed switched relay itself a delayed switched relay with single armature contacts is.

Another purpose of the arrangement is to set the switching point in time by means of a simple control circuit to be able to change over a relatively large control range.

This is achieved by triggering the working relay from several contacts on the control relay depends on the fact that these control contacts are in one of the working relays associated with resistors and a capacitor existing delay network with several discharge circuits or Charging circuits lie in such a way that the time constants of the individual discharging or charging circuits are dimensioned are that regardless of the chronological order with which the individual control contacts become effective, the switching function to be triggered by the working relay after a specified one has expired Period of time is initiated.

By using several control contacts instead of the usual single control contact can considerably reduce the release delay caused by the scattering of the individual contacts will. The remaining release delay is calculated by dimensioning the discharge or charging circuits largely compensated. With two available control contacts this can be done by having a control contact directly controlling the working relay, while the other is to switch the discharge or Charging circuits for the capacitor causes. If more than two control contacts are available, they can be used in pairs or in larger numbers.

number can be connected in parallel or in series, which further limits the original spread will. Depending on the design and purpose of the circuit, either the first or the last opening is then Contact determining the subsequent timing.

This principle can also be applied to the contacts of the working relay by e.g. connected in parallel and only thereby determines the last opening d, en fall time; then Experience has shown that the spread of the fall time of the last contact is very small.

The time constants of the delay circuits are variable within certain limits Resistances adjustable, whereby the drop-out point can be regulated. This control range is particularly very large because the full voltage on the capacitor during the working phase of the relay located.

The invention is now based on the in the drawing illustrated embodiments explained in more detail. In detail shows

F i g. 1 shows a circuit arrangement in which the drop-out delay by discharging a capacitor is effected.

2 and 3 show the current curve at relay B. the circuit arrangement according to FIG. 1 if the order in which the Control contacts and

F i g. 4 shows a circuit arrangement in which the drop-out delay by charging a capacitor is effected.

In Fig. 1 it is assumed that two Anlaßkoritakte are al and al actuated by a delayed-connected starter relay A single anchor contacts. As a result, the order in which the two contacts drop is indeterminate. Before one of the two contacts drops, the capacitor C is fully charged to the voltage U if the relay A is excited for a long time, the capacitor current i _c = 0. The current _{i B} through the relay B is through

can take place in such a way that the decrease value is almost always reached at the same point in time t ^ , regardless of how great the time difference t ₂ -t _x is. When the drop value is reached, relay B drops out at time ί _ώ , which means that contacts fei to 64 open.

Now consider the case that contact al opens first. The voltage U _c on the capacitor C before opening was again equal to the battery voltage U, after opening al it goes against

Uc = U- _o * '

When al is opened , a jump in current occurs at capacitor C, which is added to the steady-state current i _BS . Then i _B goes back to an exponential function and with a time constant

¹ B ~~ ¹ BSt -

R _B + Rl

definitely. As a first case, let us now assume that contact a 1 drops out at time i. Then the capacitor C will be with a time constant

45 against the value i _{BS <} . If the contact α 1 also drops, i _B makes a jump downwards.

The current value to which this jump leads is determined by the instantaneous capacitor voltage and the resistors R _v and R _B. The individual resistances of the discharge circuits are dimensioned so that this jump in current almost leads back to the e-curve, which is determined by the time constant T ₂ and the condition that the current i _B = i _ah must be at time t ^. The course of i _B as a function of time is for this case in FIG. 3 shown. From FIGS. 2 and 3 it can be seen that the time t _ab remains approximately constant over a wide range regardless of the sequence of fall and the difference between the individual fall times of the contacts.

A principle of the arrangement according to FIG. 1 corresponding circuit is shown in FIG. 4 shown. Their mode of operation is as follows: In the working state, when the contacts al, al are closed, the capacitor C is discharged. A current flows through B, its magnitude

= (Rv + Rl

R _B ) C

⁵ °

discharged after an e-function. In addition, at time T _{1, there is} a downward jump in current, since the discharge circuit formed is more highly resistive than the starting circuit. '

After a certain time, the sequential changeover contact al drops out at time t ₂ . This discharges the capacitor C with the smaller time constant

if the first starting contact al opens, then the capacitor C charges through the resistors Ry, Rl, Rl and R _B. if contact al then opens, C continues to charge via R _B and R _v . At the point in time t _ab , the contacts b \ to fe4 connected in parallel open, whereby the contacts of the relay D, which is switched without delay, drop out immediately. Conversely, if al as the first contact opens, the capacitor C will be with a time constant

^Rl ' ^R

T ₂ =

R _B ) C

after a steeper e-curve. Due to the different time constants, a sudden change in current occurs in the discharge circuit at time t _2; the course of the current i _B during the disconnection process is shown in FIG. 2 shown for two different times t ₂ . It can be seen from this figure that if the discharge circuits are correctly dimensioned, the current is charged; the voltage of the capacitor goes towards a value determined by the voltage divider formed by the resistors Rl and R _0. When a 1 opens, the capacitor C is again fully charged to the battery voltage via the resistors R _B and Rv. Here, too, the charging circuits are dimensioned in such a way that constant fall times result.

Against the scattering of the contacts 61 to 64 of the relay B is shown in FIG. 1 and 4 a simple method is used: Several contacts of a delayed relay are switched in parallel, so that only the last contact that opened is decisive for the switching process during the switch-off process. Experience has shown that the spread of the switching time of the last falling contact Sr is very small. You can also select the first opening contact as the one that determines the switching time, then the contacts must be connected in series for the switch-off process.

Due to the variable resistance Rv , the time tab can be changed within a certain control range. The size of the resistance depends essentially on the electrical values (dropout AW value) of the relay and the voltage with which the circuit is operated.

The fact that the capacitor C is always fully charged to the battery voltage also has a particularly favorable effect for a large control range. The protective resistor Kl, which together with R _{B represents} a voltage divider for C in the idle state, is namely switched ineffective when the starting contacts for the discharge circuit or charge circuit are closed

If the control range is to be increased, are to connect the circuit arrangements shown in series in several stages.

Claims (4)

Patent claims: 1. Circuit arrangement for achieving defined switching times fiif shutdown processes in telecommunications, especially telephone systems, in which a similar drop-out delayed working relay is controlled by a delayed relay with individual armature contacts, characterized in that the release of the working relay (B) from several contacts (z. B. al and α2) of the control relay is dependent on the fact that these control contacts are in a delay network associated with the working relay, consisting of resistors and a capacitor, with several discharge circuits or charge circuits and that the time constants of the individual discharge or charge circuits are dimensioned in this way are that regardless of the time sequence with which the individual control junction become effective, the switching function to be triggered by the working relay is initiated after a predetermined period of time has elapsed. 2. Circuit arrangement according to claim 1, characterized in that the triggering of the working relay (B ) of two contacts {al and al) of the control relay is dependent, one of which (al) in a known manner of the direct control of the relay (B ) is used, while the other (α2) switches the discharge or charge * circuit for the capacitor (C). 3. Circuit arrangement according to claim 1, characterized in that several contacts of the Control relays are each connected in parallel or in series. 4. Circuit arrangement according to claim 1, characterized in that the contacts of the Working relays are connected in parallel and / or in series. For this purpose A sheet of drawings