DE640917C - Arrangement for converting a direct voltage into an alternating voltage - Google Patents

Description

Various devices for the production of an alternating current have become known, at which discharge paths are used. Those of these institutions who work with high-vacuum discharge lines, however, have the disadvantage that they deal with the operational Let tensions transform only relatively small amounts of power.

Gas or vapor discharge paths with arc discharge have therefore already been used, however, these devices have the disadvantage that they do not cover a wide area Frequency range of the alternating current to be produced work equally well.

The invention avoids these two disadvantages; it becomes an arrangement for converting a direct voltage into an alternating voltage or an alternating voltage in such a lower frequency by means of a capacitor in conjunction with a choke coil and a grid-controlled vapor or gas discharge path Direction of current flow indicated, the grid circle of the discharge path being so dependent on the voltage on the capacitor dependent voltage receives that the capacitor is periodically charged and discharged again, and according to the invention ohmic resistances of such magnitude are provided in the discharge circuit or in the charging and discharging circuit of the capacitor, that the discharge or charge and discharge circuit are coordinated aperiodically. The alternating current consumer can be connected to any part of the charging or discharging circuit, for example to the Choke or the capacitor or to the ohmic resistances of the charging or discharging circuit or to a special one, Transformer inserted in the charge or discharge circuit.

Several embodiments of the invention are described below, wherein At the same time, some expedient arrangements for their further expansion are explained. The corresponding circuit arrangements are shown in Figs. 1 to 3 of the drawing shown. All exemplary embodiments relate to the production of a Alternating current from a direct current.

In Fig. 1, 10 are the ones for the direct current source, 11 the lines leading to the AC consumer. The discharge path is denoted by 12, the capacitor lying in series with it denoted by 13, the charging circuit for the capacitor runs over the discharge path 12. The discharge circuit for the capacitor consists of the choke coil 14 and the adjustable 6p

Resistance 15. The charging as well as the Discharge circles are adjusted aperiodically. A transformer 16 on its secondary side the alternating current consumer is connected, lies with its primary terminals at the end points of the choke coil 1,4. ^ A current limiting resistor 17 is connected upstream of the control grid of the discharge path 12.

To explain the mode of operation, it is initially assumed that the discharge may begin in the discharge path 12 when the control grid is at zero potential or at a positive potential with respect to the cathode. In addition, it should be noted for the operation of the device that in a gas or vapor discharge path, the discharge is extinguished as soon as the anode current has dropped to a certain small amount, which will be referred to below as the critical minimum current. It is also important that the control grid in such a discharge path, through which the discharge in progress cannot normally be influenced, is able to interrupt the discharge under special circumstances. This is possible when the anode current approaches the critical minimum amount and when a very high negative grid voltage is applied at the same time. By initiating the discharge in the discharge path 12, as already noted, the capacitor 13 is connected to the direct current source 10; it then quickly charges to its voltage, since the resistance of the charging circuit, which is only made up of the low arc resistance in the discharge path 12 is very small. The parallel current branch to the capacitor 13, which contains the resistor 15, the choke coil 14 and the primary winding of the transformer 16, has such a high total resistance and such a large inductance that the current generated in it during the charging process is below the critical minimum current of the discharge path remain. As soon as the voltage on the capacitor 13 approaches the voltage of the direct current source 10, the anode current in the discharge path 12 decreases, and since at the same time a high negative voltage, namely the voltage on the capacitor 13, is effective in the grid circuit, the discharge in the discharge path 12 is extinguished. The capacitor 13 now begins to discharge via the choke coil 14 and the resistor 15, the duration of this discharge process depending on the size of the elements of this circuit and increasing with an increase in the resistance values of these elements. The discharge of the capacitor 13 has an aperiodic profile. Accordingly, at the terminals of the choke coil 14, with each capacitor discharge, a direct current occurs, on the whole a pulsating light current, the alternating current component of which is fed through the transformer 16 to the alternating current consumer. The frequency of this alternating current can be set as desired by selecting the size of the resistor 15 accordingly. After the discharge process has ended, the voltage across the capacitor 13 has disappeared, so the control grid again has zero potential with respect to the cathode, and the discharge in the discharge path 12 starts again. The charging process of the capacitor 13 and the subsequent discharging process are now repeated in the manner described.

If a discharge path is used in the device described, in which the discharge starts with a negative potential of the grid compared to the cathode or with a positive grid potential, a grid bias voltage source of such size and voltage direction must be switched into the grid circuit that the discharge starts in the discharge path when the capacitor 13 is fully discharged. The transformer 16 used to supply the AC consumer does not need to be connected to the choke coil 14, it can also be connected to the capacitor 13 or to the resistor 15.

In the embodiment of the invention shown in Fig. 2, the capacitor is located 13 in contrast to the circuit according to Fig. Ι parallel to the discharge path 12. In Series with the capacitor 13 are the adjustable resistor 15 and the choke coil 14. The charging circuit closes over the 'choke coil 14 and the resistor 15, the Discharge circuit across the discharge path 12. The transformer 16 is shown in Fig. 2 for simplicity omitted for the sake of

With regard to the initiation of the discharge in the discharge path, this applies on the basis of the Fig. I Said. The charging of the capacitor 13 goes through the choke coil 14 and the resistance 15 slowly in front of you. When the capacitor is the voltage of the DC power source assumed, the voltage drop across resistor 15, and disappears the control grid of the discharge path 12 comes to zero potential compared to the Cathode. The discharge therefore begins, and the capacitor 13 is over the Discharge path 12 discharged quickly. The deletion of the discharge will take place as soon as

the anode current approaches the critical minimum amount, because then at the same time the control grid is practically at the Potentia.l of the negative pole of the direct current source, i.e. at a high negative potential with respect to the cathode. After the capacitor has been discharged, charging takes place again in the manner described. Fig. 3 shows another embodiment applied to the remote transmission of an alternating current measurement. This can be the voltage of an alternating current network as well as the alternating current flowing in a line. In the former case, the auxiliary transformer 28 of Fig. 3 is a voltage converter that is connected to the voltage to be measured via the lines 27, in the latter case the transformer 28 is a current converter whose primary winding is to be connected to the AC line to be monitored. On the secondary side of the transformer 28, two electrical valves 29, for example dry rectifiers, are provided in such a way that a direct voltage is applied to the lines 10, the magnitude of which is proportional to the alternating current measured variable to be monitored. If it is a question of the remote transmission of a direct current measured quantity, the transformer 28 and the rectifier 29 are to be omitted. In this case, if the level of a direct voltage is to be transmitted remotely, the lines 10 are to be connected to the voltage to be measured directly or via a voltage divider, and if the transmission of a direct current is to be connected to a resistor that is derived from the relevant direct current is traversed. In Fig. 3, .S "means the transmitter station, E the receiver station of the telemetry system. The transmitter side> S contains a capacitor 13 with a charging and discharging circuit and a discharge path 12 and the discharge circuit, consisting of the discharge path 12, the primary winding 21 of the transformer 22 and the resistor 34, are aperiodically damped The grid bias voltage is set so that the discharge in the discharge path 12 ignites at a certain anode voltage. The charge of the capacitor 13 and therefore also the frequency of the discharge oscillations is then directly proportional to the voltage on the lines 10 .

The circuit arrangement on the receiving side B essentially corresponds to that shown in FIG. In the discharge circuit for the capacitor 13, a DC measuring instrument 32, the resistor 15 and the choke 14 are switched on and in the grid circuit of the discharge path 12 the secondary winding of a transformer 31, whose primary winding is connected via the trunk line 33 to the secondary winding of the transformer 22 of the transmitting station 5 * is, and the bias battery 30. The charging circuit (12, 13) is again damped aperiodically. The capacitor is charged from the direct current network 10.

The mode of operation of the receiving device is that described on the basis of Fig. 1 similar, however, the discharge of the capacitor is caused by the transmission line 33 incoming voltage surges controlled. Namely, the bias battery 30 gives the grid of the discharge gap 12 a negative bias of such magnitude that after the capacitor has discharged 13 a charge of the same can only take place if previously by a grid voltage pulse the discharge in the discharge path 12 from the transformer 31 has been initiated. If the voltage surges originating from the transformer 31 have a time interval that is greater than the discharge time of the capacitor, the capacitor 13 is the receiving station for de-energized for a certain time within two impulses. Is the time between two On the other hand, current surges are shorter than the discharge time, so the capacitor is recharged 13 of the receiving station via the discharge path 12 already takes place before the Capacitor is completely discharged. The direct current of the discharge circuit in the instrument 32 is generated increases and decreases accordingly with the frequency of the remotely transmitted Current surges, which in turn is proportional to the measured variable to be remotely reported.

The invention not only enables the conversion of direct current into alternating current, but also the conversion of alternating current into such lower freno quenz. It also allows remote measurement of the in a simple and clear manner Operating parameters of direct and alternating current networks.

Claims (1)

Patent claims: i. Arrangement for converting a direct voltage into an alternating voltage or an alternating voltage in such a lower frequency by means of a capacitor, a choke coil and a grid-controlled steam or gas vent charge stretch of unambiguous direction of current flow, wherein the grid circle of the discharge path is a function of the voltage across the capacitor Voltage receives that the capacitor is periodically charged and discharged wildly, characterized in that in the discharge circuit or in the charging and discharging circuit of the capacitor Ohmic ίο resistors are provided which bring about an aperiodic coordination of the discharge circuit or the charging and discharging circuit and that the generated alternating voltage is taken from any active or reactive resistance of the charging or discharging circuit or from a transformer connected to one of these circuits.
2. Arrangement according to claim i, characterized in that the elements of the charging and / or discharging circuit, preferably the ohmic resistance of these circuits or the grid bias of the discharge tube, are chosen such that the charging and discharging process with the consideration the frequency of the alternating current to be produced plays the required speed. 3. Arrangement according to claim 1 and 2, characterized in that the capacitor (13) is in series with the discharge path (12) and charged via this becomes (Fig. 1). 4. Arrangement according to claim 1 and 2, characterized in that the capacitor (13) parallel to the discharge path (12) and discharges through the same (Fig. 2). 5. Arrangement according to claim 1 to 4, characterized in that in the grid circle the discharge path (12) is where the capacitor voltage is located (Fig. 1). 6. Arrangement according to claim 1 to 4, characterized in that in the Lattice circle of the discharge path (12) on part of the charging or discharging circle occurring voltage is (Fig. 2). 7. Arrangement according to claim 1 or the following, characterized in that in the grid circle one of a battery (23) and one connected to this battery Voltage divider (24) resulting grid bias is effective, a terminal (25) of the Battery (23) is adjustable (Fig. 3). 8. Arrangement according to claim 1 to 7 for the remote transmission of measured variables, characterized in that on the transmitting side one is proportional to a measured variable DC voltage is used to charge a capacitor (13) and at a voltage pulse is transmitted to the receiving station for each of its discharge surges will wear (Fig. 3) and that a capacitor arranged on the receiving side is charged in time with the remotely transmitted voltage pulses, with his A DC current measuring instrument (32) is switched on for the charging or discharging circuit, the direct current component of the charging device proportional to the measured variable to be displayed Indicates discharge current. For this purpose ι sheet of drawings