SU54421A1 - Device for counting electrical impulses - Google Patents

Description

The proposed device relates to an electric pulse counter based on the use of several thyratrons, switched on so that when the counting current is applied to their grids, they are alternately unlocked, and each time after the arrival of a number of pulses equal to the number of thyratrons, the electromagnetic counter triggered from thyratrons. Such a counter was described by Winn-Wil mms (WinnWilliams, Proceedings of the Royal Society, Ser. A., Vol, 132, No. 819). The disadvantage of this counter is that a separate grid battery is included in the grid circuit of each thyratron and, thus, the total number of power sources reaches a high value.

The proposed device has the advantage over this counter that it only uses one battery to supply a blocking bias to the nets of all thyratrons. According to the invention, the thyratron nets are connected through resistances to correspondingly selected points of the potentiometers connected to the grid battery.

FIG. 1 of the accompanying drawing is a diagram of a meter according to the invention; in fig. Figure 2 shows the use of this device for controlling grids of a multi-anode converter feeding a synchronous communication motor.

FIG. 1, T ... Ta denotes thyratrons, RK resistances in their anode circuits, r, g, are potentiometers to which thyratron nets are connected through resistance Gs. Co - capacitances, which serve to enrich the thyratron during the ignition of the next, Cs - capacitances, transmit control voltages to the nets of the thyratrons, K-key to apply the voltage Uynp to the nets of thyratrons, R - resistance to discharge capacitors Q, BA - anode battery and BS-grid battery.

The operation of the device is as follows. Normally, at each instant of time, one of the tiratrons is unlocked. Its anode current, the pass through the resistance RK, increases the grid potential of the next thyratron, which is thus prepared for ignition. This happens when the next current pulse counts. At the same time, due to the presence of Cc tipping capacitors, the previous thyratron is locked. As the pulses arrive, cyclic ignition of the thyratrons occurs. An electromagnetic counter (not shown in the diagram) is included in the anode circuit of one of their thyratrons, which registers the number of the last series of n pulses each.

The use of the described device for controlling a synchronous motor is shown in FIG. 2, where Φ:. . . FB mean the stator windings of a synchronous motor, the rotor of which is not shown. Tc is a multiphase thyratron with a liquid or hot cathode, powered from a UzLo DC network. The thyratron Tc is controlled by a thyratron device of the type described above, shown in FIG. 2 with the same designations and with the addition of only the RC contacts, which serve to change the order of ignition of thyratrons and are actuated by the PP relay. On the left in FIG. Figure 2 shows a circuit rectifying and amplifying the incoming pulses, as well as allowing the reversal of the direction of rotation of the controlled engine. It consists of Tff and G tiratrons with resistances / ". Gs and Ha, capacitors Co and Cn and BS batteries, and TPi and TPg thyratrons, with resistances I, R and R, rectifiers 1, 5o, BZ and B, BS batteries, capacitor Co and PP.

With a successive transition of an arc in a T thyratron from one horn to another, the phase stator windings F ;, F.,. . . Fe will alternately receive power from the BA power network. Accordingly, the magnetic field of the stator will move, which will carry along an excited rotor. However, with such a scheme, it is not possible to obtain a rotating magnetic field necessary for continuous one-way rotation of the rotor. The direction of movement of the magnetic field of the stator will correspond to the initial rotation of the rotor only within 180 electrical degrees. In order to use the circuit in FIG. 2 it was possible to obtain a rotating magnetic field, it was necessary to equip the used synchronous motor with an additional device that every 180 electric degrees changed the direction of the magnetic zero of the rotor or stator. The latter is more convenient, since each phase winding of the stator is F-, F. . . F is a fairly long time without current. This time is useful for switching the ends of the stator phase windings. A device that does this can be made in the form of a collector that switches the ends of each phase winding through 180 electrical degrees.

A device of such a switch is not of fundamental interest and is therefore omitted in FIG. 2, but its presence is mandatory.

The circuit in FIG. 2 is given for the case of the use of a Tc thyratron with a liquid cathode. Such thyratrons usually have an ignition characteristic that lies in the positive region of the grid potentials. Therefore, at zero on the grid, all the rosatiratron Tc are locked. The horn nets of the thyratron Tc are controlled by the counting thyratron device described above.

In turn, the thyratron counting device is controlled by a thyratron T and an auxiliary thyratron T, connected according to a circuit with a tipping capacitor Co. In the presence of pulses of any polarity, thanks to the action of rectifiers B, B2, B, B, the thyratron T, c is unlocked, and the thyratron TN goes out. In the interval, the thyratron T is ignited, and the thyratron Tk goes out. Ignition of the thyratron TN causes the appearance of a pulse on the resistance Gk (of the thyratron TAG) acting on the counting device. At each subsequent interval, the corresponding thyratron counter is turned on, unlocking the corresponding horn of the thyratron TC. Arc arc horn

The Tc thyratron is also produced with the help of " tipping containers Co.

As already shown, the unlocking of each horn of the Tc thyratron corresponds to the new stable position of the rotor of a synchronous motor. With a six-phase winding of the stator, there will be twelve stable positions per revolution of the rotor.

To change the direction of rotation of a synchronous motor, a device was used consisting of rPj, TP tiragrons, PP relay and its contact system KP. The direction of rotation depends on the polarity of the pulses coming from the communication channel. With pulses of one polarity, the locking for the TPj thyratron is compensated. It is unlocked, and the GRZ thyratron is extinguished. The relay is left without current. The contact system of the PP relay comes to the position indicated in FIG. 2. The synchronous motor rotor will rotate clockwise. When the polarity of the pulses is changed, the locking for the thyratron of the GG-Relay PP is activated, the switches KP are moved to the right of the contacts 1 to the contacts 2, the rotor of the engine changes the direction of rotation.

As can be seen from the description, the proposed device is suitable for both synchronous angle transmission and synchronous rotation transmission. Moreover, the number of host engines operating from one date

Chica, not limited. Another valuable advantage of the proposed device is that synchronous communication can be carried out via a two-wire line or via radio.

The subject matter of the invention.

A device for counting electrical pulses, made in the form of a system of several thyratrons, connected in such a way that when applying the counting pulses to the grids, the ignition and extinction of each of the thyratrons, one of which includes an electromagnetic counter, occurs alternately, so that the counters trigger each time after the passage of a number of pulses corresponding to the number of thyratrons, characterized in that, in order to use to create a blocking voltage on the grids, all thyratrons one common current source is applied a number of parallel connected potentiometers / i, Gg, for respectively selected points which are connected in series with the grid thyratrons resistances Gs.

2. The use of the device according to claim 1 for controlling the grids of the multi-anode ion converter in a synchronous communication system with synchronous motors at alternating current of variable frequency.

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