DE1256714B - Bistable clock circuit as a counter stage for relay chains for dual counting and storage of unipolar pulses with a high pulse repetition frequency - Google Patents

Description

Bistable clock circuit as a counting stage for relay chains to the dual Counting and storing of unipolar pulses of high pulse repetition frequency The invention relates to a bistable clock circuit as a counting stage for relay chains to the dual Counting and storing of unipolar pulses of high pulse repetition frequency. By interconnecting several of these clock circuits can be easily formed relay chains, with which any number of unipolar pulses are counted and stored is so that with a relay chain of n counting levels 2 "- 1 pulses are counted and stored can be.

A known bistable clock circuit has three relays, one of which two have two windings each. While these two relays have the "yes-no characteristic" determine, the third relay is used to output or display the respective switching status. A normally closed contact of the other relay is connected in series with the first winding. the second windings of the first two relays are controlled by a changeover contact of the The output relay is alternately short-circuited, which is self-acting when actuated holds.

Although this clock circuit can store unipolar pulses, it can only with an unreasonable effort. When connecting several of these Counting steps to a relay chain can also only achieve a low counting speed because at least two relays are switched to store a pulse have to.

In another known clock circuit with only two relays per stage, their windings A and B are connected in series via a normally open contact a. Furthermore, there are two changeover contacts b parallel to the windings of the two relays A and B , the center springs of which can be connected to one another via a pulse contact.

With this clock circuit, the windings are temporarily short-circuited. This makes the clock circuit very sluggish and can generate a maximum of two to three pulses record per second.

From the German patent specification 1157 688 a clock circuit with a relay is known in which two capacitors in combination with resistors can be switched on in the excitation circuit of the relay to be switched via a switching contact controlled by the relay.

The charging current of the two capacitors causes the response of the relay. In the rest position of the changeover contact, the charging current is the a capacitor with its parallel resistance effective and in the switched Position of the response current of the other lying in series with its series resistor Capacitor. The activated 2 relays hold themselves via a holding contact. When the impulse ends, the one provided with the parallel resistor discharges Capacitor. The discharge current of the second capacitor provided with the series resistor is kept away from the relay by a diode polarized against the direction of the discharge current.

In this known clock circuit, the response of the relay caused by the charging current of two successive capacitors.

The relay dropping out is achieved by placing the relay with a Resistance is connected in series, a charged capacitor is connected in parallel which produces such a large voltage drop in the resistor that the relay falls off. However, this parallel connection of relay and capacitor the time constant of the falling relay adversely affected, so that only relatively low pulse repetition frequencies can be achieved. Occurring voltage differences have an unfavorable effect on this clock circuit, since the voltage is in the capacitor charge is received in a square manner.

However, this disadvantage cannot be achieved by any magnification of the mentioned capacitor can be compensated without the switch-on function of the Endanger relay.

This capacitor also takes over the first phase of switching on and can, if it is not fully charged, the relay immediately after switching make it fall off again.

This makes the clock circuit critical and leads in the sizing the switching means and in the application to difficulties.

Despite the increased cost of switching means, this clock circuit can only with a further increase in switching means (relays) to build relay chains be applied. A bistable clock circuit is also known as a counting stage for relay chains for dual counting and storage of unipolar pulses, in which only a single relay per counting stage and a rechargeable capacitor are arranged which is charged or reloaded via a changeover contact of the relay and the relay alternately responds or drops out via a pulse contact brings.

With this clock circuit, the switchover contact belonging to the relay is activated together with the other switching elements and a resistor combination in one Switching position of the relay and the capacitor selected while the changeover contact in the other switch position the relay disconnects from the voltage. The condenser is charged via resistors from a direct current source when the changeover contact is in rest position, d. H. the relay coil is de-energized. Then becomes the impulse contact closed, the capacitor discharges through the only winding of the relay, this is turned on, picks up and at the same time switches its switchover contact and holds itself on its working side. When the impulse contact is subsequently opened the capacitor is switched to - as a result of the relay holding current - at a holding resistor falling voltage reloaded.

This known clock circuit allows pulse counting with a small number of switching means, which, however, are selected with particular care and must be coordinated. There is a special match between the relay to be used and the resistor combination with regard to the to to make the processing pulse repetition rate because the charging or reloading time of the capacitor plays an essential role. So the capacitor must be proportionate be designed to be large in order to quickly achieve a sufficient in the limited charging voltage to be able to store a large charge. Has a resistance of the resistance combination namely in the activated state of the relay the function of the holding resistor, and the voltage dropping on it is used to recharge the capacitor.

Since this voltage is only a partial voltage, the capacitor must still have a considerable size. As a result, the loading and reloading time will turn relatively long. The holding resistance cannot be chosen arbitrarily small, otherwise if the pulse contact is still closed and the relay has already dropped out, the Residual current becomes too large and can cause the relay to respond. The resistance combination must therefore be dimensioned with a very high resistance, so that in this case the relay at most Receives fault current.

It is well known that these high-value resistances influence the processable Pulse repetition frequency is disadvantageous again.

If, on the other hand, the resistances are made smaller, this is a prerequisite for safe dual counting with a higher pulse repetition frequency with this clock circuit, that the pulse contact only closes very briefly. This is especially for the construction of a relay chain with such clock circuits is necessary because then yes, each relay has a pulse contact designed as a wiping contact to control the must have the following counting level. On the other hand, if you only use a normal one Impulse contact, the resistor combination and the relay would take too long too large a current is flowing, which makes the clock circuit unsafe.

The invention is based on the object of a bistable clock circuit as a counting stage of the type mentioned to create that with less effort on simple and conventional switching means, counting and storing of unipolar ones Pulses with a higher pulse repetition frequency are guaranteed with full utilization of the Switching speed of the relay, with mechanical stresses and voltage fluctuations do not cause any disturbance.

This is essentially achieved in that the pulse contact is designed as a changeover contact, via which it is not connected to the relay Side of the capacitor is connected to the center spring of the relay's changeover contact and can be connected directly to a special charging or recharging current source. The relay, on the other hand, switches with its holding contact via the holding resistor to a special holding power source.

The capacitor is preferably in an AC branch and that Relay connected in a DC circuit. When a relay chain is formed Another changeover contact of each relay as a pulse contact of the respective assigned downstream counting level.

The invention is based on the embodiments shown in the drawings explained.

F i g. 1 shows a counting stage; F i g. 2 shows a relay chain according to of the invention, and FIG. 3 is a relay diagram of this relay chain. The in F i g. 1, the switching state shown is a capacitor 1 via a diode 2 so charged that the negative pole is on the contact side.

If a pulse contact 5 is actuated by the first pulse, the capacitor 1 is discharged via a relay 6 , so that it is triggered and thus holds itself via its contact 61 and a resistor 4. By switching the relay 6, a changeover contact 62 has also been switched from the diode 2 to a diode 3. When the pulse contact 5 is switched back from the position 51 to the starting position, the capacitor 1 is charged via the diode 3 with the opposite polarity.

When the pulse contact 5 is switched again, the capacitor discharges 1 again via relay 6.

However, since the discharge current of the capacitor 1 is opposite to the holding current of the relay 6 in this case, the relay 6 is thrown off. The current through the relay 6 becomes approximately zero when the discharge current of the capacitor 1 is the same as the holding current of the relay 6.

The pulse contact 5 can now be switched back to the starting position and thereby charge the capacitor 1 again negatively with start-up polarity. Thus, when the pulse contact 5 is pressed for the third time, the relay is activated again. The pulse contact 5 can be actuated by a relay or by a limit switch will. If the switching means relay, resistor and capacitor are designed accordingly the pulse repetition frequency can be up to 15 Hz.

F i g. 2 shows an interconnection of three of the counting stages just described to form a relay chain in which only one further changeover contact 63 or 73 is assigned to each relay 6 or 7 as a pulse contact of the respective downstream counting stage.

In Fig. 3 is the switching sequence of the relay chain according to FIG. 2: The capacitor 1 is charged via the diode 2 and the contacts 62 and 5 with start-up polarity. The capacitor 1 discharges through the pulse contact 5, which closes the working side 51 with the first pulse, so that the relay 6 picks up. In this case, its holding contact 61 closes, and the relay 6 is held at minus via the holding resistor 4. The changeover contact 62 switches from diode 2 to diode 3.

The changeover contact 63, which acts as a pulse contact in the second counting stage is switched, its capacitor 9 switches via the changeover contact 72 to the negative diode 2, via which it is charged with start-up polarity. By the return of the pulse contact 5 to the initial position is the capacitor 1 has been charged via the diode 3 with the opposite dropping polarity. At the second impulse, when the impulse contract 5 is switched again, the capacitor becomes 1 again discharged via the relay 6, which consequently drops out for the first time. Included the holding contact 61 opens, the changeover contact 62 switches from the diode 3 to Diode 2 back. The pulse contact 63 switches this with its rest side 64 Relay 7 to the capacitor 9, so that the relay 7 by discharging the capacitor 9 is started for the first time and with his holding contact 71 over his Holding resistor 10 holds itself. The changeover contact 72 switches from the diode 2 to diode 3.

The further switching sequence takes place as in FIG. 3 shown.

The extension of this relay chain to n bistable counting stages can take place according to the requirements, without a load on the first counting stage entry.

The main advantage is that when. Interconnect of the counting stages no switching problems occur.

Claims (3)

Claims: 1. Bistable clock circuit as a counting stage for relay chains for dual counting and storage of unipolar pulses, which by means of a pulse contact that switches on and off once with each pulse, turn on or off a single relay with a single winding, the beginning of which with a - over the rest side of a changeover contact of the relay charged with a certain (starting) polarity - capacitor is connected in parallel to one pole of a direct current source, at the other pole of which the relay triggered by the capacitor discharge current as a result of the closing pulse contact is connected to the end of the winding via its holding contact which was switched on via the switched-on pulse contact to the capacitor, which in the following pulse pause as a result of the back-switching pulse contact via the working side of the changeover contact of the relay held in series with a holding resistor in a holding circuit with opposite The (discarding) polarity is charged, characterized in that the pulse contact is designed as a changeover contact (5), via the side (53) of which is not connected to the relay, the capacitor (1) with the central spring of the changeover contact (62) of the relay (6 ) and can be connected directly to a special charging or recharging current source (-, 2, 3), whereas the relay (6) with its holding contact (61) connects to a special holding current source (-) via the holding resistor (4) turns on. 2. Clock circuit according to claim 1, characterized in that the capacitor in an alternating current branch and the relay acted upon by this in a direct current circuit are switched. 3. Clock circuit according to claim 1, characterized in that when it is used as a counting stage in a relay chain, a further changeover contact (63, 73, ...) is assigned to each relay as a pulse contact of the respective downstream counting stage. Considered publications: German Patent Nos. 825 856, 1107 436, 1157 688; German Auslegeschriften Nos. 1001722, 1018 922, 1089 811; Journal "Elektronik", 1958, issue 6, pp. 171/172.