DE618581C - Circuit arrangement for level monitoring of several channels or lines, especially for high-frequency connections - Google Patents

Description

GERMAN EMPIRE

ISSUED ON SEPTEMBER 12, 1935

REICH PATENT OFFICE

PATENT LETTERING

CLASS 21 a ⁴ GROUP

Siemens & Halske Akt.-Ges. in Berlin-Siemensstadt *)

Patented in the German Empire on May 5, 1931

Devices for level monitoring, d. H. Facilities that display level deviations, in order to initiate their adjustment, or automatically the adjustment make yourself, mean for the systems a not inconsiderable increase in Costs. This is particularly noticeable when there are a large number of communication lines or channels, as in the case of multiple high frequency telephony, are to be monitored individually.

It is already known orzusehen a measuring circuit for several lines \ ^r and this in cyclic sequence by a contact device, eg. B. by a collector-like device to switch to the individual lines. In the latter case, contact is not guaranteed with sufficient certainty with regard to the measurements to be made, or the contact resistances do not remain sufficiently constant, so that difficulties arise. If, instead of a collector, a relay is used as the contact means, the contacting is better, but disadvantages are in turn linked to the fact that, particularly with regard to the long switching times, a larger number of relays and thus extensive circuits are required.

According to the invention, there is a significant technical advance in terms of simplicity the circuit for level monitoring of several channels or lines by means of a common device achieved that the switching of the level monitoring device through the mediation of a Relaxation oscillation takes place, the time constant of which determines the switchover time. at Such an arrangement allows for relatively long switching times in the simplest way Manufacture way, especially if you have gas discharge tubes, such as. B. glow tubes, used as tilting devices, the response of which depends on the charging circuit of a capacitor. In this case are apart from the discharge tube only simple resistances and capacitances as elements required for the timer.

The signal currents can be used as a measure of the level for alarming or control purposes themselves or special control currents can be used.

As in high-frequency telephony not only in wireless transmission, but also in the case of transmission via lines (overhead lines, cable or power lines) level fluctuations The establishment is particularly frequent and of great strength

*} The patent seeker stated as the inventor:

Dipl.-Ing. Karl Scherer in Berlin-Siemensstadt.

according to the invention for the high frequency telephony equipment particularly important. Hereinafter the invention is then described particularly in application to such devices. In order to maintain the low-frequency residual attenuation of the HF telephone device, a constant high frequency level required at the rectifier grid. Due to the weather in high-frequency telephony over lines caused fluctuations in the Power attenuation must therefore be compensated for by appropriate gain control at the receivers and intermediate amplifiers will. This regulation can be carried out automatically or by the operating personnel will. In the latter case, an alarm is recommended that is triggered if the carrier frequency level deviates by more as + 0.2 Neper of the setpoint comes into function, since it has been shown that level fluctuations of 0.2 Neper with regard to the residual attenuation. In principle, it would be possible to activate this alarm using a relay combination, .that is triggered by the changes in the anode direct current of the tube rectifier in the receivers of the HF telephony equipment. However, these changes are . Frequently too low (approx. 0.3 mA) for a factory-made relay to be operationally reliable to operate. However, if a high-power tube in a directional amplifier circuit is used for demodulation, the anode direct current is, for example, at normal level of the carrier current 3 mA and its deviations with fluctuations of + 0.2 Neper about + 1 mA. These currents are sufficient to operate a relay and thus to trigger a signal. However, from the point of view of the recipient, it is usually not desirable to have one Use a receiving modulator with a higher power than for receiving directly necessary. If level control devices are installed in high-frequency devices, which already exist or are installed, a redesign is undesirable be. Then you will prefer to use a separate one for level control Rectifiers and, if necessary, preamplifiers to which the high-frequency currents, ζ. B. · from the amplifier or rectifier transformers of the receiver branched off, fed. This arrangement has the advantage of being an existing one at all times High-frequency device to be switchable.

On level control circuits for high frequency telephony In general, the following conditions must be met.

The signal should not respond to short, jerky fluctuations like them possibly due to atmospheric disturbances or short-term strong modulation of the modulator (volume peaks) can occur. This condition must also be met if the level is still within the permissible limits, the deviation of the normal value, however, has almost reached the limit value of 0.2 Neper. Furthermore, may the connection of the circuit does not cause any significant loss in gain of the receiving amplifier, even if the connecting lines are up to 15 m long. Combination streams are also not allowed arise or the crosstalk attenuation between the individual devices is reduced will.

In the following, an exemplary embodiment of the level monitoring system is shown on the basis of the figure executed according to the invention, which satisfies these conditions, namely for the case of level monitoring of three Channels of a carrier stream telephony connection.

In the figure at the top left potentiometers W ₁ , W ₂ and W _{3 are} shown, which are to be connected to the carrier current channels, preferably to the high-frequency ^{intermediate transmitters of the receiver or the S 0} post-transmitters of the intermediate amplifiers. This can be done in that the transformers mentioned receive a third winding. The windings are then advantageously designed with low resistance in order to avoid a possible reduction in the transformer input resistance and an associated disruption of the other functions of the transformer (e.g. amplification).

From the potentiometers W ₁ , W ₂ , W ₃ , the modulated carrier stream arrives via two relay contacts, which switch the individual channels, to the pre-transformer VU of the amplifier tube VR and from there, amplified via the intermediate transformer ZU, to the grid of a strongly negatively biased rectifier tube Gi ?,

The controllers W ₁ , W ₂ , W ₃ are set so that at a normal carrier frequency level the anode direct current of the Gi? Tube (indicated by an instrument /) is 3 mA, while the quiescent current may be about 0.3 mA. This anode current flows through one winding of the differential relay D ₁ and, at its normal value, compensates for the field of the constant current flowing in the second winding. If the high-frequency level deviates from its nominal value by more than 0.2 neper, a current difference of more than ι mA occurs in the relay windings, and relay D ₁ responds. But since the drop-off current of the relay is smaller

as the response current, the armature might not drop again after a brief level deviation, and the alarm would respond, even if the level deviation is still within the permissible limits of + 0.2 Neper. In order to avoid this, a relay B is switched on by the normally open contact d _t , the contact e "of which switches the windings of D _{1 in} parallel so that the same currents flow and the armature drops again, whereby E becomes de-energized again and e" the parallel connection again picks up. If the level deviation still persists, D ₁ responds again, and the same process is repeated until the level is again within its permissible limits. The relay B is delayed by a copper sleeve so that the armature of D ₁ always returns to the rest position during the oscillations.

The relay B causes a control _{lamp L 4} to light up through the contact e ^l , which also indicates brief level fluctuations, and on the other hand it switches on the thermal contact T , which only lasts longer after some time via the relay F by means of a signal lamp L ₅ and a clock reports persistent excesses of the permissible limits, which require readjustment by the recipient. The delay is about 10 seconds.

Since the armature of E oscillates while the level monitoring device responds, the contact ^ _{1 is designed} so that it remains closed at all times, so that e ^{1 is} closed first and only then takes e ¹¹ with it and closes. As a result of the delay of E , e ^{1 is} not opened, since the relay D ₁ responds again immediately after the interruption of e ″ , whereby E picks up again.

This ensures that the winding of the thermal contact T receives a constant current and its response time is independent of the size of the level change. Instead of signaling the presence of a level deviation through the lamp L ₅ or the alarm clock W and causing the monitoring staff to regulate, the regulation can automatically z. B. done by shifting the grid potential of one or more tubes or shifting a damping circuit in the high-frequency telephony channel. Of course, automatic control and signaling can also be carried out at the same time.

The whole level monitoring device described so far is now replaced by an additional Switching in the same time periods, e.g. B. from 20 + 25 seconds, continuously below three channels switched automatically. The cyclic changeover takes place as follows Way (see illustration).

The capacitor K ₁ is charged via a high-ohm resistor R ₁ from the anode battery (220 V) common to the tubes VR and GR. Since the time constant R ₁ , K _{1 is} large (about 10 seconds), the voltage rises only slowly after switching on and only reaches the ignition value of the glow lamps G ₁ , G ₂ after about 20 seconds. When the lamps are ignited, a current flows through the resistor R ₂ and the grid battery to earth and causes _{a voltage drop in .R 2} which is opposite to the grid bias of the tube VR. As a result, the anode direct current of the tube increases, and the differential relay D ₂ responds and closes the contact d ₂ . When the heating battery is applied, a current HB, a ^vl , W, c ^VI , A ₂ , earth flows. The ^ -relay responds, opens at a ^VI , but remains through the contact al ·. The contact a "is therefore closed when d includes ₂ and K ₁ can be discharged through the coil B _1. When the tube VR bodice its normal bias assumes drops D ₂ again. Due to the discharge current surge speaks B., adheres via b ^l , A switches off through b " ¹ , so that A drops out again and opens a ¹¹ , and through b ¹¹ prepares the path for the following surge of discharge. After a further 25 seconds, the glow lamps ignite, D ₂ responds again, the discharge current flows through C ₁ , C responds, persists through c ¹ , switches B _{2 off} through c ^m , so that B falls off and b " opens, and the The following current surge is passed through c " via A ₁ . The relays A, B and C respond one after the other in a continuous cycle. The rhythm of the process can be set as desired by choosing the time constant K ₁ · R ₁ (when using paper capacitors, the switching time is limited to about 1.5 minutes by the insulation resistance).

So that the charge of the capacitor K ₁ can flow as quickly as possible and no periodic discharges occur due to the inductance of the windings A ₁ , B ₁ and C ₁ , the relays A, B and C are damped by copper sleeves. The closing time of the contact d ₂ must be long enough so that the entire charge can flow away and the A, B and C relays respond reliably. The actually extremely short closing time of the contact d ₂ is extended by the capacitor K ₂ . Its effect is that after the glow lamps have been extinguished, the displacement ^{voltage in the grid circle can only slowly decay, so that the anode current increase in the i r} i? Tube does not immediately decrease. The switchover of the pre-transmitter VU among the three high-frequency telephony devices is done by

Normally open contacts a ' ^v , b ^lv , c ^{lv of} the relays ^, B and C. Since, due to the delay in relays A, B and C , two relays always picked up for a moment during switching, the normally closed contacts a ^v , b ^v , c ^v prevent couplings and thus crosstalk and interference tones from occurring when two high-frequency telephony devices are switched on at the same time.

The lamps L ₁ , L ₂ and L ₃ indicate which channel is being monitored. For manual adjustment, the automatic switchover can be canceled and the monitoring circuit can be connected to a specific channel. This is done by switching the switch U ₁ , U ₂ or U ₃ from operation to locking. ' The relevant winding A ₂ , B ₂ or C _{2 is connected} to HB by U ₁ '(U ₂ ' or U ₃ ') and the corresponding windings of the other relays are switched off by U ₁ "(UJ ¹ or U ₃ ") , so that only A or only B or C responds. When a high-frequency telephony device is switched off, the level arm is prevented from responding in that the current in the differential relay D ₁ is brought to its normal value of 3 mA by switching on the resistor R _5. To do this, the relevant switch U ₁ , U ₂ or U _{3 is set} to the "OFF" position. R _s is then connected to ground via U ₁ " ¹ and a ^v " or U ₂ ¹ " and b ^v " or U ₂ '" and c ^v ".

To adjust the gain, the level of the channel to be monitored is brought to its setpoint. The monitoring circuit is then set by the corresponding switch on the channel and a current of 3 mA is _set in the instrument 7 with the aid of the controller W ₁ or W ₂ or W s. The other controllers are set in the same way.

The number of jointly supervised ¹ channels is not limited to three. You can z. B. can be expanded to six without difficulty, as z. B, for intermediate exchanges with three high-frequency telephony calls and for end exchanges with six calls or with three calls and monitoring of the transmission level is required. If three channels are monitored together, the individual channels can be monitored with pauses of around 1 minute. With six channels, if the same equipment is used, the pause is 2 minutes. In view of the relatively slow changes in the line attenuation and the small response values (+ 0.2 neper), these pauses are irrelevant for operational safety, especially since major disturbances, such as line breaks and failure of operating voltages, are either signaled in a different way or all channels are common disturb, so be displayed immediately.

So the same types of apparatus sets can be used if the number of Use channels that have great manufacturing value.

Only in the case of an extraordinary expansion could the case arise that the breaks are closed get long. Then, however, the shorter pause time can be passed through in a simple manner Achieve change in the time constant of the tilting oscillation control.

Claims (10)

Patent claims: 1. Circuit arrangement for level monitoring of several channels or lines, especially for high frequency connections, with a common monitoring device is switched one after the other to the individual channels, characterized in that the switching of the Level monitoring device takes place through the intermediary of a relaxation circuit, the time constant of which determines the switching times certainly. 2. Circuit arrangement according to claim i, characterized in that the relaxation oscillation circuit · the sequence of switching operations in a relay chain regulates, the relays of which are assigned to the individual channels and for the connection of the level monitoring device are provided with the channels. 3. Circuit arrangement according to claim i, characterized in that as Tilting organ in the tilting vibration switch too device gas discharge tubes, in particular glow tubes, are provided. 4. Circuit arrangement according to claim i, characterized in that in the level monitoring device in the anode circuit of a rectifier tube a relay, in particular a DifEerentialrelais (D ₁ ), for actuating the level monitoring and in the anode circuit of a preamplifier tube a relay, in particular a differential relay (D ₂ ), for Triggering of the switching device is. 5. Circuit arrangement according to claim 3 and 4, characterized in that the Loose oscillation circuit on the grid circle of the preamplifier tube of the level monitoring device acts in such a way that the relay circuit located in the anode circuit of the preamplifier in certain Is switched on at intervals. 6. Circuit arrangement according to claim 3 and 5, characterized in that the Relaxation circuit consisting of a series circuit of resistor and capacitor, to which a voltage is applied, and consists of the glow tube or tubes that are charged by the capacitor are ignited and during the ignition by discharging the capacitor a current impulse through the resistor in the grid circuit cause. 7. Circuit arrangement according to claim 6, characterized in that the Resistance in the grid circuit of the preamplifier is a capacitor in parallel to change the grid bias hold out for a long time. 8. Circuit arrangement according to Claim 4 or the following, characterized in that the relay (D ₂ ) in the anode circuit of the preamplifier tube (VR) provides a path for the discharge of the capacitor (K ₁ ) which determines the breakover oscillations via further relays (A, B ₁ C) prepared, which in turn are excited cyclically alternately by the discharge that each of the other relays (A ₁ B ₁ C) prepares the discharge path via the neighboring relay for the next discharge when energized. 9. Circuit arrangement according to claim ι and following, characterized in that signals (z. B. lamps L ₁ , L ₂ , Lg) are arranged which are switched on by the relay (A, B ₁ C) of the chain circuit excited in a cyclic sequence and mark the channel under control. 10. Circuit arrangement according to claim i, characterized in that im Input of the level monitoring circuit for the channels or lines to be monitored Appropriate potentiometer arrangements are assigned to the response value of the relay, which causes the level control or the signaling, with the normal level in agreement to be able to bring. ' 1 sheet of drawings