NO124900B - - Google Patents

Description

Coupling device with bistable function.

It is already known from German explanatory document no. 1,050,376

in connection with bistable semiconductor flip-flops as memory elements in control and regulation systems, to use a device that serves to prevent wrong commands after a loss of mains voltage, and where the flip-flop's two working current branches via a saturable transformer are connected together with opposite winding polarity and this transformer due to the hysteresis maintains an asymmetry corresponding to the respective rest position when the mains voltage fails and provides the original operating state after the voltage has returned.

However, there are application cases where it is not immediately permissible to include such non-linear resistors in the connection

ling devices with bistable function.

The task of the invention is to provide a coupling device which

has a bistable function, and where the aforementioned difficulties are avoided with the least possible switching equipment.

A special task for the invention is to design a switching device which has bistable function, and where the switching state is stored in such a way that the contained switching circuits with bistable function are advantageously usable for optional reconnection or blocking of alternating voltages.

More specifically, the invention thus relates to a switching device which has a bistable function, and which, after an interruption in the supply voltage by means of a transformer with magnetically hard core material and with a first and a second winding, is transferred to the switching state that existed when the supply voltage dropped out, and the characteristic of this switching device, according to the invention, consists primarily in the fact that the first winding is fed with a current that is independent of the switching state of the switching device, and that the second winding is arranged in a circuit which conducts or does not conduct current depending on the switching state of the switching device and is also designed as a control circuit, which other winding produces an ampere-turn figure which is opposite to the ampere-turn figure produced by the first winding and is thus much greater than this, e.g. by a factor of two,

that the transformer takes one or the other storage state depending on the switching state of the switching device. In particular, transistors or thyristors can be used as switching elements. With the help of these precautions, the advantage is achieved that with the switching device, using little switching equipment, a switching circuit is available which is free of non-linear resistors and has particularly favorable switching properties. Furthermore, the time at which the switching device after the connection of the mains is to be transferred to the position that existed before the mains voltage failed, can advantageously be chosen freely.

In accordance with a further development of the invention, the switching device is designed so that only one of the two transistors contained in the switching device is saturable, and that the other, which is particularly arranged for optional switching through or blocking of alternating voltages, can be controlled into the active area. The transistor which in the supply charge to its emitter is connected to the second winding is then suitably the saturable transistor. A coupling device designed in this way can be used with particular advantage in the selection

show through-connection and blocking of alternating voltages.

As a further elaboration of the invention, the switching device is designed so that the transistors are aV' of the opposite conductivity type, and that the base of the transistor which can be controlled into the active area, in particular via decoupling switching means, is connected to an input for an alternating voltage and further via a resistor is connected to a potential that blocks the transistor, as well as via a further resistor is connected to the collector of the saturable transistor, and that the emitter of the saturable transistor is connected to the reference potential across the second winding of the transformer, while its base is connected to the collector of the transistor that can be controlled into the active area. Such a switching device, which is particularly controllable via a control input connected to the saturable transistor's base, can be advantageously used in switching fields or feed-through fields similar to cross-bar distributors.

Furthermore, it is appropriate to connect the base of the - particularly saturable - transistor which is connected in its emitter supply line to the second winding, with the reference potential across a resistor.

As a further development of the invention, the positive feedback loop located between the collector of the saturable transistor and the base of the transistor which can be controlled to the active region contains a network with an integrating function.

In the case of a device with at least one group of switching devices where only a small number can be connected at the same time, it is further appropriate to design the switching device so that the winding on the transformer through which the current independent of the switching state flows is connected in series with the corresponding windings of the other coupling devices in the same group. This applies in particular to switching devices which are arranged to selectively block or pass through alternating voltages in a switching field and are assigned to one and the same output.

Finally, it is appropriate to take the current independent of the switching state of the switching device from a device for switching on the current with a time constant measured for safe testing of the transformer.

The invention will be explained in more detail by an embodiment shown in the drawing.

The drawing shows a switching device which has a bistable function and serves for the selective switching of alternating voltages in a switching field similar to a cross-bar distributor. However, the coupling device can also be used for other types of distributors or serve other purposes.

Of several asymmetric connecting elements resp. port connectors connected in front of the through-connection field output 15, the drawing only shows the connection element or the node £0, which is designed as a bistable flip-flop with complementary transistors.

The switching element 20 is a transistor stage in the collector-base connection which contains the transistor 10 and serves to selectively block or pass through alternating voltages. This transistor stage can also be connected in emitter-base connection and with the help of an amplifier at each output from the switching device be provided with a negative feedback.

The transistor 10, which is an NPN transistor, emits, depending on the switching state of the flip-flop stage, the alternating voltage which is supplied to its base via the input transformer 11, via the diode 12 amplified to the output 15. In a switching field, especially in the form of a cross-bar distributor, there remains the input transformer 11 controlled further nodes in the same way. On the other hand, in such a connection field, there are quickly several junctions to the output 15 because the emitter of the amplifying transistors is connected to a common working resistance 14, which is arranged between the operating voltage and the output 14.

Both the alternating voltage applied to the input transformer 11 and a control DC voltage are fed to the base of the transistor 10,

so the alternating voltage is added to the direct voltage. Furthermore, the input transformer 11 is galvanically separated from the base of the transistor 10. The secondary winding of the input transformer 11 is on the one hand connected to the DC voltage -19 V and on the other hand via the diode 12 connected to the base of the transistor 10 as well as to other connecting elements connected to it same entrance, but is not shown in more detail.

The control voltage that controls the transistor 10 to the blocking or conducting state is formed in the voltage divider 16, which contains the resistors 7 > 9 °S 19» Furthermore, the base of the transistor 10 is connected via the series-connected resistors 7 and 9 to the collector of the transistor 5 and across the resistor 13 connected to the operating voltage. The emitter of the transistor 5 is connected to ground across the winding 22 of the transformer 2.

The base of the transistor 5 is connected to the flip-flop control input 6, with the collector of the transistor 10 and, across the resistor 3"

with soil.

A further winding 21 on the transformer 2 is constantly connected to the supply voltage across the resistor 4« Resistors 9 and 13 are shunted with the capacitor 8.

The diode 12 has such polarity that it also blocks when transistor 5 is blocked. The voltage divider 16 is dimensioned so that the diode 12 at conducting transistor 5 likewise conducts.

Input signal et is fed into the diode 12. When the transistor

5 is controlled, current flows across the diode 12, and you get a voltage of e.g. -18.3 V at the base of the transistor 10 and correspondingly a voltage of e.g. -19 V at the emitter.

If, on the other hand, the transistor 5 is blocked, then the base of the transistor 10 is connected to the operating voltage of e.g. -24 V across the resistors 7 > 9 °g the winding 22, and the diode 12 and the base-emitter circuit of the transistor 10 blocked, e.g. with 5 V.

This connection is particularly advantageous as the series connection of the blocking capacity of the diode 12 and the capacity of the blocked base-emitter section of the transistor 10 is decisive for the blocking function. In addition, the input resistance of a blocked switching element becomes very large. The direct current which passes across the resistor 13 through the diode 12 can be chosen to be sufficiently large with a view to a large jingle margin.

On the other hand, it is also possible to control the transistors so that the blocking potential is supplied to the transistor's base via a secondary winding on an input transformer and a resistor connected in series with it, at the same time that this secondary winding is common to all transistor stages that are connected to the relevant input.

Based on the connection arrangement shown in the drawing, it is also possible to arrange a capacitor instead of the diode 12, and the input transformer 11 is then omitted.

The node 20 consists of a bistable flip-flop which is made up of complementary transistors, of which the transistor 5 in the through-connected state is controlled to saturation, while the transistor 10 remains in amplifier operation, resp. in the active area, and passes through the input signal, which may in particular be a carrier frequency signal.

When the node is blocked, the winding is 22 on the transformer

.2 stromlos, and the storage core. respectively the transformer 2 is magnetized with the direct current J across the winding 21 to position 0. When the node is connected through, the storage core 2 is magnetized with the direct current 2 J to position 1 across the winding 22, assuming that

number of turns for the windings 21 and 22. At different numbers of turns, the ratio between the currents changes accordingly.

If a storage core that is in position 0 is magnetized in the direction towards position 0, short disturbing impulses occur on the winding 22, which can be kept small by suitable selection of the time constants for the remagnetization. An RC link increases the security that these disturbing impulses cannot switch through the tilt step.

Depending on the connection state of the port connection, the storage core 2 is magnetized in a different direction, namely so that when the port connection was connected through for a loss of power supply, when the network is switched on by means of the reconnection of the core, a pulse occurs which engages the port connection again.

The tipping step must be dimensioned so that, in the event of a power supply failure, only at low current supply voltages do the connected nodes tip over to a blocked state so that the magnetization state remains maintained. When reconnecting the network, all nodes are initially blocked. Thus, all the storage cores above the respective winding 21 are magnetized to position 0. On the winding 22, pulses occur which, if the core is already magnetized to position 0, are shorter and normally also smaller than if the core was previously magnetized to position 1. These pulses controls the transistor 5 *il conducting state, but only the long pulses can over the RC link with the resistor 7 °g the capacitor 8 also control the transistor 10 to this state and thus switch the flip-flop stage. When the flipped stage is connected through, it immediately re-magnetizes the storage core 2 to position 1, whereby the original state is again reached.

In order to keep the supply requirement low, it is appropriate to connect the windings 21 on the storage terminals in series at all nodes which are connected to one and the same output from the connection field, and connect them to the supply voltage via a resistor assigned to the output.

In order for the device to function safely even when the network is switched on stealthily, it is appropriate to arrange a device which either only when a certain network voltage is reached, switches the network on with a defined time constant or, after switching on the network, adds the windings 21 of the storage cores to voltage with a delay and /or with defined time constant.

In the case of symmetrical switching of alternating voltages, the switching device contains an additional transistor that can be controlled into the active area, while the transistors controllable to the active area that are of the same wire type each have an at least partially separate base voltage divider.

The connection points of the switching device can be controlled point-wise, particularly via coin-side gates, as the control pulses are applied on the basis of one of the transistors contained in the bistable flip-flop stage.

On the other hand, it is also possible to control the switching device's switching points coordinately with coincident pulses so that at all times all switching points for a line are triggered with a first control pulse and all switching points for a column are triggered with a second control pulse. One control pulse is then suitably supplied to the emitter and the other supplied to the base of one and the same transistor, which is contained in the bistable flip-flop stage. In this connection, it has proved particularly appropriate to use such coordinate-wise control of the amplifying transistor 10, that the output line advantageously also serves as a control line.

Furthermore, the potential conditions at the switching elements can be selected so that a transfer of one of the switching elements assigned to one and the same output to the conductive state can only take place when no switching element has yet been connected to the output in question. With such a design of the coupling device, a coupling element which is already conductive must be switched off before a new through-connection can take place. This switching off is carried out in groups or individually.

Claims (9)

1. Switching device which has a bistable function, and which, after an interruption in the supply voltage by means of a transformer with magnetic hard core material and with a first and a second winding, is transferred to the switching state that existed before the supply voltage failed, characterized by the fact that the first winding ( 21) is fed with a current that is independent of the switching state of the switching device (20), and that the second winding (22) is arranged in a circuit that carries or does not pass current depending on the switching state of the switching device and is also designed as a control circuit, which other winding ( 22) produces an ampere-turn figure which is opposite to the ampere-turn figure produced by the first winding (21) and is thus much greater than this, e.g. with a factor of two, that the transformer takes one or the other storage state depending on the switching state of the switching device (20). 2. Switching device as set forth in claim 1, characterized in that only one (5) of two transistors (5, 10) contained in the switching device is saturable, and that the other transistor (10), which may in particular be arranged for optional through-connection or blocking of alternating voltages, is controllable to the active area. 3. Switching device as set forth in claim 2, characterized in that the transistor (5) which is connected to the second winding (22) in its emitter supply line is made up of the saturable transistor (5). 4. Switching device as set forth in claim 2 or 3> characterized in that the transistors (5, 10) are of mutually opposite conductance type, and that the basis of the transistor (10) which can be controlled to the active region, in particular above a'v Switching means (diode 12) are connected to an input for an alternating voltage and further across a resistor (13) with a potential that blocks the transistor (10), as well as across a further resistor (the resistors 7 and 9) ma<i the saturable transistor's (5) collector, and that the emitter of the saturable transistor is connected to the reference potential across the second winding (22) of the transformer (2) and this transistor's base is connected to the collector of the transistor (10) which can be controlled to the active area. 5. Switching device as stated in one of the claims 2 - 4 > characterized in that the basis of the - particularly saturable - transistor H5) which is connected in its emitter supply line to the second winding (22), is connected to the reference potential (ground) above a resistor (3). 6. Switching device as stated in one of the claims 2 - 5"characterized in that the positive feedback loop which lies between the collector of the saturable transistor (5) and the base of the transistor (10) which can be controlled to the active region, contains a network of integrative function. 7. Switching device as stated in one of claims 2-6, characterized in that the winding on the transformer that is flowed through by the current independent of the switching state (J), in a device that has at least one group of switching devices of which only a limited number can be switched through at the same time , are connected in series with the corresponding windings of the other connecting devices in the same group. 8. Switching device as specified in one of the preceding claims, characterized in that the current (J) independent of the switching state of the switching device (20) is taken from a device for connecting the current (J) with a time constant dimensioned for safe testing of the transformer. 9. Switching device as set forth in one of claims 2-8, characterized in that the switching device, by symmetrically connecting alternating voltages, contains a further transistor that can be controlled to the active area, and that each of the transistors that can be controlled to the active area are of the same wire type , has at least partial base voltage components.