DE1148915B - Remote counting and telemetry equipment - Google Patents

Description

Remote counting and telemetry equipment For the remote transmission of measured quantities the pulse frequency method is often used. This is done on the sending side the measured variable is converted into a pulse train that is sent to the receiver via a signal line is directed. Arrangements are known in which directly from the measured variable an impulse contact is actuated, so that for the impulse transmission to the receiver only one signal line is required. However, pulse generators with electronic Components used must be used to supply power to the electronic components Voltage sources are provided.

If, for example, the reading of a three-phase electricity meter is to be transmitted through a long-distance line can be transmitted as a voltage source for the electronic components of the pulse generator, one phase of the three-phase network can be used. On the receiving side However, there is no control over whether the remote metering device comes to a standstill the counter, the status of which is to be transferred, really stands still or maybe only the phase that is used as the voltage source for the electronic pulse generator has failed is used and the counter continues to run. For remote counting or telemetry systems In addition, in most cases it will be necessary to check the voltage source directly at the pulse generator is difficult, while on the receiving side, where the Devices are almost constantly monitored, a control in most cases is possible.

It is already a remote metering and telemetry device with an electronic one Pulse generator has been proposed in which the necessary to power the pulse generator Voltage source is arranged on the receiver side and the supply of the pulse generator takes place via the signal line. To display the measured value, the am Measurement location changed in its amplitude by the transmitter and on the receiving side evaluated direct current generated by the voltage source arranged on the receiving side used. At the measuring point, a voltage divider is connected to the signal line, the consists of an ohmic and a non-linear resistor. The almost constant The voltage drop across the non-linear resistor is used to supply the measured variable influenced pulse generator. A contact is controlled by the pulse generator, which controls the ohmic Resistance bridged in rhythm with the pulse frequency.

In addition to electronic pulse generators, there are numerous mechanical ones Pulse generator known, which are equipped with an electric booster motor. This amplifier rotor provides the mechanical work for closing the impulse contact, while the measured variable controls the impulse contact with almost no power. With these Pulse generators equipped with amplifier motors act in relation to the voltage supply the amplifier motor has the same difficulties as with the electronic pulse generator, however, they cannot be fixed in the same way.

It is the object of the invention to provide an arrangement in the advantageous power supply of the pulse generator from the receiving side can also be used when using amplifier motors for the pulse generator can.

According to the invention this is achieved in that the booster motor fed via the long-distance line supplied with alternating current from the receiving end and the amplifier motor on the encoder side is parallel to that of the measured variable controlled impulse contact.

Parallel connection of motors and contact arrangements in an energy network are known, but the conditions are hereby actuating the contact not changed in the network. In the device according to the invention, the relationships are different, because here impulses are given via a signal line. On the signal line changes in the current and voltage ratios are caused by the impulse contact caused, so that this line cannot be compared with a power line.

In the arrangement according to the invention is expediently in the transmission A mechanical energy storage device between the amplifier motor and the impulse contact available, which can be charged by the booster motor and when the Booster motor able to open this contact again by the impulse contact.

For pulse generators with rectifiers in series with the pulse generator contact are arranged, a capacitor is provided in series with the motor, which together with the motor inductance a matched to the frequency of the AC voltage source Series resonance circle forms.

The principle of the invention is based on two exemplary embodiments with reference to the drawing explained. Fig. 1 shows a basic circuit diagram for AC control of the receiving relay, while Fig.2 shows a circuit for direct current control of the relay.

The receiving relay 2 (Fig. 1) is from the voltage source 1 via the long-distance line 3 and the impulse contact 4 are fed on the encoder side. Will the impulse contact controlled by the measured variable is closed for a short time, so speaks the receiving device 2 to the current pulse. On the donor side it says Periods between the impulses when the impulse contact is open to the Impulse contact cycles make the full voltage of voltage source 1 available. Of the Booster motor 5, which is connected here, must, however, be much larger Represent the resistance as the receiving device 2, because only then is it ensured that when the impulse contact 4 is open, the receiving device 2 does not respond and the booster motor 5 is at sufficient voltage.

So that the motor 5 does not have a closed impulse contact 4 for always stops, is an energy storage device, not shown, in the form of a spring or a flywheel is provided, the time before the contact movement of the motor 5 is charged forth and takes over the reopening of the contact 4.

In the embodiment of FIG. 2, a polarized receiving relay is used 7 is used, which responds only to direct current pulses of both polarities. The receiving relay is from the AC voltage source 6 via the trunk line 8, the rectifier 10 and the pulse change contact 9 fed.

With this circuit, there is always only one half-wave voltage on the encoder side available, namely the reverse voltage at the rectifiers 10. This half-wave voltage the AC motor 11 is connected via a capacitor 12. Advantageous the ballast capacitor 12 is dimensioned so that it is one with the motor inductance Series resonance circuit that is matched to the frequency of the AC voltage source 6 is. With this arrangement, an alternating current with low harmonics is forced in the motor. This alternating current for supplying the motor 11 can be seen on the receiving end polarized receiving relay 7 with the aid of the capacitor 13 in a known manner pass by.

Claims (3)

PATENT CLAIMS: 1. Remote counting and Femmeßeinrichtung with a pulse generator at the measuring location that requires an amplifier motor to generate impulses by actuating the contacts and by influencing the voltage source arranged on the receiving side the current supplied via the long-distance line causes the impulses to be generated, characterized in that that the amplifier motor (5) on the receiving side with alternating current supplied long-distance line (3) is fed and the amplifier motor (5) on the encoder side parallel to the pulse contact (4) controlled by the measured variable. 2. Arrangement according to claim 1, characterized in that in the gearbox between the booster motor (5) and impulse contact (4) mechanical energy storage are available, which from Booster motor (5) are charged and when the booster motor is bridged (5) to be able to open this contact (4) again through the impulse contact (4). 3. Arrangement according to claim 1 for pulse generators, in which rectifier in series with the impulse contact are arranged, characterized in that in series with the amplifier motor (5) a capacitor (12) is provided, which together with the Motor inductance is matched to the frequency of the AC voltage source (6) Series resonance circle results. Publications considered: German patent specification No. 971533.