DE1762195C - Circuit arrangement for triggering delayed switching processes in decentralized circuits by a central control circuit - Google Patents

Description

The invention relates to a circuit arrangement for triggering delayed switching operations in decentralized Circuits through a central control circuit.

Previously known solutions for achieving delays in the triggering of switching processes use individual delay elements in the form of capacitors. Such circuit arrangements however, if the effort is not to be too high, they are very imprecise. This is especially true for the recently widely used •• adjusted relays with single armature contacts, their The spread during deceleration is usually very large.

Other known solutions are based on the payment of centrally generated clock pulses individual counting members. This principle is also used in modern switching systems Memory-programmed central control, with de.r required delay times without great effort derived from one of the system clocks in connection with memory sections acting as counters can be.

In the conventional systems, however, realizing such solutions means one after all still considerable effort.

The object of the invention is therefore to provide a simpler, but nevertheless precisely working arrangement 7 To trigger delayed switching processes in decentralized circuits by a central control circuit to create that can be used in conventional systems.

This is achieved by the fact that the decentralized circuits in addition to the actual control circuit «Lied for triggering the delayed switching process have an auxiliary switching element that with the initiation of the delayed switching process a common starting circuit of the central delay switching element that can be influenced by this auxiliary switching element closed and thus switched on a timer that determines the delay time becomes that the further one for all auxiliary switching elements the decentralized circuits common control circuit for blocking the central delay switching element against further assignments is provided and that after the delay time has elapsed the control switching element that triggers the delayed switching operation via one for the control switching elements all decentralized circuits jointly provided control circuit is influenced and that thereupon this control switching element in addition to triggering the delayed stopping process central delay circuit unlocks again.

The execution of an arrangement according to the invention is in the usual relay technology with a Timing element, which can be constructed using any technique, to be implemented and without great effort can therefore easily be used in systems of conventional technology.

Instead of several individual timing elements, only a single timing element is used for a number of decentralized circuits required based on circuit principles known per se for central control devices connected to the assigned decentralized circuits via multiple lines is. This also has the advantage that several decentralized circuits can be used at the same time can be controlled as soon as several Requirements exist.

As already mentioned, the timer can be constructed using any technique. The mode of action of individual time step types can however force certain modifications and extensions, and although this is the case when the time step after its shutdown again takes a certain time until it has returned to its defined starting position is. This problem occurs, for example, with time levels in which charging or discharging processes of capacitors play a role on. It is then to be ensured that the delay time determining switching elements at the beginning of the delayed switching process always in a defined Condition are.

A first, simple solution provides a central delay device opposite the general solution has the special characteristics that the control circuit for blocking the central delay element the blocking after the triggering of the delayed switching process so is maintained for a long time until the timer has returned to its initial state.

The only decisive factor here is when the control circuit is used for the control switchgear of the decentralized circuits is activated. The time of release the entire central delay device, on the other hand, determines the sum of the delay time of the first time stage and the additional time, in which the block can still be maintained. This additional time will be at least as great as the necessary reset time for the timer must be selected. Mostly the required reset the time step, however, must be so small that this loss of time is of little consequence.

Otherwise, a further modified circuit arrangement offers a solution that is characterized by this is that two successively effective time stages are provided, the running time The second time stage is dimensioned in such a way that the first time stage returns to its off-state during this time achieved. The delay time is divided by the two time stages so that during the working time of one time step the other in it: n return to the initial state can. This means that the time after which the central delay circuit is free again for new requests is correct is practically the same as the required delay time t, which results in an optimum Timely dispatch of the requirements achieved is.

The invention will now be described on the basis of 3 exemplary embodiments explained in more detail with figures.

1 shows a circuit arrangement for response delay;

Fig. 2 shows a circuit arrangement for decay delay;

Fig. 3 shows a modified embodiment the circuit arrangement according to Fig. I.

In Fig. 1, only one of the several decentralized consumers connected in parallel to the central delay circuit is shown. When the contact «closes, the relay CV responds via the line A1, applies earth to the line A 2 via its contact cv 1 and also prepares the trip circuit with cv 2. The relay AN responds. brings his contact to the relay H and initiates the delay by triggering the timer Zl. The contact Λ separates the earth from the line A 1 and thus blocks the central circuit against reconnection. After the delay time has elapsed, the relay L connected downstream of the timer is energized, which switches earth to line Λ 3. The relay CW pulls through, maintains its level contact or and at the same time takes the request again from line A 2. After the relays / I / V, // and L have dropped out, the circuit can be closed again. Since several requests can occur during the time in which the relay // is active, the earth must be connected to line A 1 after the circuit has become free so that all requests are definitely met. The circuit works with timely use. Only in the event that further requests come in during the time in which the circuit is blocked against new allocation, they must wait a maximum of a delay time.

The function of the circuit arrangement for achieving a fall-out delay according to FIG. 2 corresponds largely that of the circuit arrangement

ίο Generation of the response delay. The instantaneous switch-on process is initiated by the contact /, which brings the relay CV. The relay CV brings the relay CW with its contact cvl. In addition, it separates the starting circuit with its contact er 2 and prepares the blocking circuit with its contact cv3. The relay CW maintains itself through its contact oi>2; and also closes a hold circuit for the relay CV with its contact cw 1. During the following work phases, the

21-. both relays CV and CW energized. The shutdown process is initiated by closing contact ei. This removes the earth from the CV relay, causing CV to drop. By opening the contact ot'2, earth comes to the line A 2; the relay ON responds. The contact on brings the relay H and initiates the delay. By closing the contact /; earth is placed on line A 1, which prevents the central delay circuit from being reassigned to the drop-out delay, since closing a second contact of a second decentralized device would not cause the CK-Rclais of the corresponding decentralized device to drop. After the delay time has elapsed, relay L responds, opens contact 1 in the trip circuit, causing relay CIF to drop out. By opening the contacts or 1 undov2, the blocking circuit, the starting circuit, the timer and the trip circuit return to their original position and are ready for a new fall-off delay process. For requests that come in during the time in which the circuit is blocked against re-assignment, waiting times up to a delay time must also be added.

In the exemplary embodiments of FIGS. 1 and 2, it is necessary for proper functioning that when the delayed switching process is initiated by the starting circuit, the time stages are in a defined initial state A certain period of time is required until this state is reached again after a working position; If the next request were to be received by the central delay device before the initial state was reached, the delay time would be too short. A simple solution to prevent this consists, for example, in The arrangements according to Fig. 1 and Fig. 2 include letting the relay speak without delay, but letting it drop with a delay so that the time stage has resumed its initial state before it drops his contact Ii the blocking of the central facility for the necessary time to upright. However, this increases the waiting time for pending new cleanings.

Should this N ': u · h part vcrmiivliMi im-r / iiMi, ι .. ·, ..

the above-mentioned loss of time must be eliminated by using two time stages. In Fig. 3, a corresponding embodiment based on FIG. 1 is shown. The function is identical to the function of the arrangement according to FIG. 1 until the relay AN responds. The relay AN IUU located in the starting circuit not only controls the timer with its contact at 1, but also takes over the blocking of the central delay circuit through a second contact at 2. After the delay time of the time stage Zl has elapsed, the relay LA is energized and thus started through the contact al the time stage Z2. At the same time, the relay H is switched on, which maintains itself via its own contact / il and switches off the timer Zl via a break contact / i2. At the same time it takes over the blocking of the central delay circuit with its contact / i 3. During the delay time of the time stage Z 2, the time stage Z1 can return to its initial state. After the second delay time has elapsed, relay LD responds and, with its contact Lb, releases the delayed switching process. Relay CW picks up , AN drops out and then also / 7 and LIi. Since the relay AN drops out before the relay //, / i3 had to take over the blocking of the central unit in order to guarantee the correct functioning. Immediately after this blocking is lifted, new requests can be processed

ίο be. The time stage Z 2 can be used during the following Work line of the timer Zl resume their initial state.

The circuit arrangements shown can generally be used for central delay devices, whether they are intended for the pull-in or drop-out delay, use them. Special uses arise mainly for circuit arrangements for bridging dialing pulses, for the generation of Meldezählimpulscn and for

ao charge pulse detection.

1 sheet of drawings

Claims (3)

Patent claims: 1. Circuit arrangement for triggering delayed switching processes in decentralized circuits by a central control circuit, characterized in that the decentralized circuits in addition to the actual control switching element for triggering the delayed Switching operation have an auxiliary switching element that is to be triggered with the initiation of the delayed Switching process a common starting circuit that can be influenced by this auxiliary switching element of the central delay switching element closed and thus the delay time determining time step is switched on, that furthermore one for all auxiliary switching elements the J central circuits common control circuit for blocking the central delay switching element against further assignments is provided and that after the delay time has elapsed the control switching element triggering the delayed switching operation via a for the Control switching elements of all decentralized circuits jointly provided control circuit is influenced, and that this control switching element then, in addition to triggering the delayed switching process, the central delay switching frciswitches again. 2. Circuit arrangement ι according to claim 1, with a time stage, div. A certain period of time required to return to its defined starting position after it has been switched off, characterized in that the control circuit for blocking the central delay element, the blocking after triggering of the delayed switching process is maintained until the time stage is defined Has reached the initial state. 3. Circuit arrangement according to claim 2, characterized in that to form the total delay time, two successively effective time stages are provided, wherein the running time of the second time stage is dimensioned so that the first time stage during this returns to its original state and vice versa.