FI77343B - Circuit arrangement. - Google Patents

Description

1 77343

switching System

The invention relates to a switching device according to the preamble of claim 1, which is intended to prevent the simultaneous use of terminals between a line network and terminals connected in parallel. The switching device according to the invention thus ensures that, during normal operation, only the switch-on of the parallel terminals which is first used is switched on to normal operation and the operation of the other parallel terminals is prevented.

The switching equipment is particularly well suited for applications of various signal lines, and especially of telephone technology, in which case the terminals are, for example, pu-15 helicopters.

Devices implemented with conventional telecommunication technology that prevent the listening of a parallel telephone are already known. However, the disadvantages of the known connections are their complexity, large size and the fact that the number of parallel devices is typically limited to a maximum of three for technical and practical reasons.

In addition, additional wiring is required between the devices to be connected, so installation is cumbersome and time consuming.

. U.S. Pat. Nos. 3,499,121 and 4,332,983 further disclose devices which use a diode bridge formed by four diodes, in which current is controlled through two diodes by directing a thyristor connecting the diodes to a conductor by means of a zener diode. However, the main disadvantage of these solutions is the resulting voltage drop, which limits the maximum available length of the conductor loop.

The object of the invention is therefore to provide a switching device of the type mentioned at the beginning, in which the above-mentioned disadvantages have been overcome. This is achieved in that the semiconductor switch is a bi-directional thyristor 2 77343 circuit, and that the sensor and control circuit consists of at least one diaco connected between at least one control electrode of the thyristor circuit and the second output terminal of the thyristor circuit.

The structure according to the invention achieves a simpler, more reliable, smaller and cheaper apparatus than the known solutions. In addition, the signal level is attenuated in the switching device according to the invention less than in the known devices according to the above-mentioned US publications 10.

The equipment is implemented in semiconductors and has no moving parts, so it is wear-free and silent. In theory, an unlimited number of terminals can be connected to one cable. In this case, the devices of each lead branch can be in-15 integrated into even one component.

The small size due to the electronic implementation makes it possible for the equipment to be placed, for example, inside the terminals or elsewhere in the wiring network in such a place that the enclosure can be omitted and no additional wiring and complicated connections are required.

The invention will now be described in more detail with reference to the examples according to the accompanying drawings, in which Fig. 1 shows the connection principle of the switching device between the line and the terminals. the structure of the switchgear, Fig. 5 shows a more detailed structural example of the switchgear corresponding to the general structure shown in Fig. 3, Fig. 6 shows an embodiment 35 according to the invention corresponding to the structure of Fig. 4, and Fig. 77343 Fig. 7 shows the embodiment of Fig. 6 at its simplest.

In Figure 1, n parallel terminals 1 ', 2', are connected to the wiring network JV. .., n '. Each branch of the wire-5 has a switching device 1 connected in series with the terminal between the corresponding terminal and the wiring network JV.

Figure 2 shows the general structure of each switching device 1. In connection with the figure, the operation of the switching device-10 is described in general in the case of a signal line such as a telephone network, i.e. in a case where the terminals are, for example, telephone machines or other subscriber devices. A semiconductor switch 2 is arranged in the second conductor of the terminals connected in parallel.

15 On the line side of the semiconductor switch 2, the switching device has a sensor 3 for detecting the voltage and / or current state on the line side of the line. On the terminal side of the semiconductor switch 2, the switching device 1 has a second sensor 4 for detecting the voltage and / or current state on the terminal side of the line. In addition, a third high-impedance sensor 5 is connected across the semiconductor switch 2 to detect the voltage across the semiconductor switch. Each sensor is connected to a control circuit 6, which controls a semiconductor switch 25 2 on the basis of the signals received from the sensors.

In a normal subscriber interface, the prevailing situation in the dormant state is that the line has a relatively high DC voltage level supplied at the exchange, which is detected by the sensor 3. The current through the sensors 3 and 4 is non-existent because the normal DC-30 current path through the terminal is cut off. Only a small amount of power required to maintain special operations is allowed. The semiconductor switch 2 can be dimensioned to provide the required maintenance current. Sensor 4 detects that the terminal is in a high-impedance state. Sensor 5 detects 35 that there is no or only a small voltage drop across the semiconductor switch. Based on the information provided by the sensors 3, 4 and 5, the control circuit 6 controls the semiconductor switch 2 to the closed state, which separates it from the terminal.

The interface alarm signal is a low frequency AC voltage over DC voltage. During the alarm, the detectors 5, 3, 4 and 5 detect the alternating current and direct it through the control circuit 6 to the conductive state of the semiconductor switch 2 during each half cycle of the alternating voltage component, whereby the alarm receiving circuit of the terminal operates normally. When the terminal is switched on or switched to the operating mode, a direct current path is formed through it, the voltage and current ratios and conversions caused by which the sensors 3, 4 and 5 detect and switch the semiconductor switch 2 to the conductive state during the connection.

When the terminal is now connected as described above, the voltage between the conductors has decreased so low that other terminals with a corresponding switching device 1 can no longer connect to the line when trying to receive a call, because the sensor 3 detects that the voltage on the line already corresponds to the operating situation. 20 via the control circuit 6 controls the semiconductor switch 2 to the conductive state. This prevents the parallel terminal from connecting to the current connection.

During the outgoing selection signaling of the terminal equipped with the switching device 1, the sensors 3, 4 and 5 control the semiconductor switch 2 via the control circuit 6 either, for example so that the switch is conductive throughout the selection signaling or so that the switch 2 is guided rapidly for each selection pulse.

Depending on the application, the switching device 1 can be developed in such a way that the sensors 3 and 4 can be simplified or omitted altogether. In addition, when the control circuit 6 is connected to the sensors, the implementation principle according to the invention shown in Fig. 3 is achieved, in which the switching device 1a has a single sensor 5 'connected to the rin-35 of the semiconductor switch 2. No connection to another wire is required, making installation easier.

5 77343

The switching device 1a according to Fig. 3 can be further converted either by housing or by integrating it into one component Ib according to Fig. 4.

Fig. 5 shows a more detailed description of a switching device le according to the invention, which corresponds to the structure according to Fig. 3. The switching device has two similar blocks 7a and 7b, which are connected to each other side by side, whereby polarity independence is achieved. The functions of blocks 7a and 7b are the same, so only block 7a will be examined in more detail below. The semiconductor switch is a thyristor 2a, which is normally in the closed state if a holding current of a certain magnitude does not pass through it and the control electrode has no control voltage. The thyristor control electrode (gate) 8a is connected via a diac 5a to the anode of the thyristor 2a. In connection, the Diac acts as both a sensor and a control circuit. Above a certain voltage, the internal resistance of the diac decreases collapsingly, whereby it emits a generated voltage-voltage pulse to the thyristor control electrode 8a, causing the thyrist-20 to conduct the thorium. There is only a small voltage drop for the positive voltage between the cathode connected to the thyristor signal line and its control electrode, so the Diac 5a is able to sense the positive voltage across the switching device while handling the control pulse for the ty-25 resistor. The thyristor remains conductive if the external circuit maintains a sufficient holding current.

In the dormant state of the signal line, the thyristors are in the closed state and the direct current path through the terminal is cut off.

The AC voltage used as the alarm signals exceeds the switching voltage of the diaces 5a and 5b, and the diaces control the thyristors to conduct alternately at different half-cycles, causing the alarm receiving circuit of the terminal to operate.

When the terminal is switched on or off, a direct current path is formed through it 35 and the resting voltage on the line passes through the terminal to switch over the switch device 6 77343, whereby the Diac gives a voltage pulse to the thyristor, and the thyristor starts to conduct in either block 7a or 7b. The direct current flowing through the terminal keeps the thyristor conductive.

5 When the first connected terminal is in the operating state, the current through it is so large that it reduces the voltage acting on the line so low that other terminals correspondingly connected in parallel can no longer be connected to the line in the above-mentioned manner, but remain de-energized.

The switch of the switching device can also be a triac-type semiconductor Id according to Fig. 6, which alone can lead in both directions as well as the resistor-connected thyristors 2a and 2b described above.

The triac-type semiconductor Id of Fig. 6 is further integrated in the series of a Diac-type semiconductor, denoted by reference numeral 9, for the control electrode.

In Fig. 7, in the component 1f of Fig. 6, the integration is reduced so that the Diac branch is already connected inside the component to another position of the triac and the result is a 2-pole complete switching device.

The coupling principle according to Fig. 5 also contains only semiconductor elements and can thus be integrated into one 2-pole semiconductor component Ib as in Fig. 25 4.

The switching device 1 can also be implemented in such a way that it is dependent on polarity, whereby its structure can be simplified. The polarity dependence can then also be used as an additional function, for example to divide parallel actuators into different groups based on polarity.

Although the invention has been described above with reference to the examples according to the accompanying drawings, it is clear that the invention is not limited thereto, but can be modified within the scope of the inventive idea set forth above and in the appended claims, mainly depending on line signaling and voltage current behavior.

Claims (3)

7 77343 A switching apparatus for preventing the simultaneous use of terminals (l'-n ') connected in parallel to a line, the switching apparatus comprising a switching device (le; Id; lf) arranged in each parallel line branch, which is connected to the second conductor of the line branch in series with the terminal device, the switching device ( le; Id; lf) comprises a half-conductor switch (2a, 2b; Id; lf), the output terminals of which form the output terminals of the switching device, and a sensor and control circuit (5a, 5b; 9) connected to the semiconductor switch (2a, 2b; Id; lf) ), which controls the semiconductor switch on the basis of the current and / or voltage states of the wired network identified, characterized in that the semiconductor switch is a bidirectional thyristor circuit (2a, 2b; Id; lf), and that the sensor and control circuit (5a, 5b; 9) consists of at least one diackycell (5a, 5b; 9) connected between at least one control electrode of the thyristor circuit and the second output terminal 20 of the thyristor circuit. Switching device according to Claim 1, characterized in that the thyristor connection comprises two resistively connected thyristors (2a, 2b), each of which has a diac-type semiconductor (5a, 5b) connected to the control electrode (8a, 8b). Switching apparatus according to claim 1, characterized in that the thyristor connection comprises one triac-type semiconductor (Id), the sensor and control circuit consisting of a Diac-type semiconductor (9) connected between its control electrode and the other 30 targets.