DE3111107A1 - Circuit arrangement for measurement transmission of DC voltages - Google Patents

Abstract

The invention relates to a circuit arrangement for measurement transmission of DC voltages and/or direct currents from a live measurement-voltage source to a test set. In the case of such a circuit arrangement, the measurement-voltage transmitter and the test set are intended to be isolated from one another in potential terms. To this end, the invention provides that in each case one transmission device, which contains a voltage/frequency converter, a potential isolating device and a frequency/voltage converter, is arranged between the measurement-voltage source and the test set which is connected to reference potential. The circuit arrangement can be used, especially in the case of devices for removed power supply, for central indication of a plurality of measurements (readings). <IMAGE>

Description

Circuit arrangement for the transmission of measured values from direct

voltages The invention relates to a circuit arrangement for the transmission of measured values of direct voltages and / or direct currents, of at least a measuring voltage source leading to a voltage with respect to the reference potential to a measuring device, especially for measuring devices in devices for the remote power supply of intermediate amplifiers or regenerators of communication links.

With such circuit arrangements it can be for personal protection reasons and / or be expedient in terms of the structural design, measuring device and To separate the measured variable in terms of potential.

The object of the invention is to provide a circuit arrangement of the above to be designed in such a way that the measuring voltage transmitter and the measuring device are potential-wise are separated from each other.

According to the invention, the circuit arrangement for solving this Task designed in such a way that between the measuring voltage source and the reference potential lying measuring device Each one a voltage-frequency converter, a potential separation device and a transmission device containing a frequency-voltage converter is arranged is.

Through these measures there is the advantage that with potential more Separation of the measuring device from the measuring voltage transmitter with little circuit complexity can achieve a high measurement accuracy.

The potential separation device is expediently the measurement voltage source spatially assigned so that the transmission line is at low potential is located.

In a further embodiment of the invention, the circuit arrangement in the event that a common measuring device is provided for several measuring voltage sources is designed in such a way that a switching device connected upstream of the measuring device is arranged between the potential separation device and the measuring device. To this Several measured values, which have a high potential to earth or reference potential, can be recorded lead and / or high voltages lie between their potentials, of one and the same Measure the measuring device in a simple manner by switching. This is especially true advantageous if both the current and the partial voltages related to the center of symmetry of the output voltage are also measured should be, between which then a potential difference of half the value of the output voltage - in the case of a fault-free route - is pending. The switching device needs in advantageously not for the high voltages, but only for the low ones Voltages of the measured values to be designed.

In a further development of the invention, the switching device is between the potential separation devices and a common frequency-voltage converter arranged, with only a single frequency-voltage converter in an advantageous manner is needed.

On the other hand, the switching device is between the frequency / voltage converters and the measuring device, there is always a U / F converter for a specific F / U converter assigned, so that both can be compared with each other if necessary.

The output circuits are expediently the potential separation device and / or the frequency / voltage converter is single-pole connected to the reference potential. In this way, the converted measurands, which are on the potential-free Side of the optocoupler are to be combined with one pole.

Magnetic Serve transmitter or the like. It can prove to be particularly advantageous that the potential separation device is connected in particular as an emitter follower Optocoupler is formed. Because the opto-coupler does not transmit exact analog values there are no special requirements with regard to reinforcement, temporal Constancy or temperature curve set.

The voltage / frequency converters and the frequency / voltage converters are preferably selected to be in a frequency range below 100 kHz work, which ensures that when using a transformer or Optocoupler as a potential separation device, the frequencies to be transmitted are sufficient are far below the cut-off frequency of the potential separation device.

The invention is based on the exemplary embodiments shown in the figures explained in more detail.

1 shows a circuit arrangement for the transmission of measured values two DC voltages with a frequency-voltage converter for each measured value, FIG. 2 one Circuit arrangement for the transmission of measured values of two direct voltages with only one Frequency-voltage converter and FIG. 3 shows a device for remote power supply several measuring voltage sources lying at a relatively high potential.

In the circuit arrangement according to FIG. 1, an arrangement A is the contains a plurality of measurement voltage sources 70 and 80, via the connecting line C. out an arrangement, the measuring instrument 93 with a series resistor as a measuring device 92 contains. The measuring voltage sources 70 and 80 are each through a resistor formed at which a DC voltage drops. The resistances are in particular - which is not shown in detail in the figure - at such a high potential that A direct connection of the measuring device 93 is not permitted for reasons of personal protection is.

To the measuring voltage source 70 or 80, which is used when measuring a direct current can be a shelf, is one with its own auxiliary voltage UH1 or UH2 supplied voltage / frequency converter 71 or 81 connected. The voltage / frequency converter 71, 81 each emits a rectangular pulse train at its output.

The pulse repetition frequency depends on the measured DC voltage value applied to the input away. Such voltage / frequency converters, designed as integrated circuits, are commercially available and are called Voltage wo Frequency Converters or V / F converters or U / F converter. One of those Voltage / frequency converter generates a frequency proportional to the input voltage at its output. Suitable are in particular voltage / frequency converters with input voltages of about 0 to approx. 5 V work, have TTL level at the output and their output frequencies lie in the range from 0 to approx. 100 kHz.

There is an optocoupler at the output of the voltage / frequency converter 72 or 82 connected. The transistor contained in the optocoupler 72, 82 is each connected as an emitter follower and spatially assigned to the measurement voltage source.

The resistor 73 or 83 located in the emitter circuit is in each case over the connection line C to the input of the frequency / voltage converter 74 or 84 led.

The frequency / voltage converters give a frequency at their output proportional output voltage and are commercially available as integrated circuits, especially as a so-called frequency to voltage converter.

The frequency / voltage converters 74 and 84 are spatial to the measuring device 93 assigned or together with this in one and the same structural unit, the arrangement B, housed. With the help of the switch 91 this can be done by a measuring instrument formed measuring device either to the frequency / voltage converter 74 or to the frequency / voltage converter 84 connect. The resistors 73 and 83, the frequency / voltage converters 74 and 84 and the measuring device 93 are unipolar at reference potential. Lie in arrangement B. the frequency / voltage converters 74 and 84 on the supply voltage + UH. Also the Collectors of the optocoupling learn 72, 82 contained transistors are each led to the supply voltage + UH3 of arrangement B.

If necessary, different or separate supply voltages can be used Use.

The DC voltage to be measured is sent to the input of the voltage / frequency converter given. Its output frequency is transmitted to the frequency / voltage converter via the optocoupler transfer. The output of the frequency / voltage converter now supplies one of the DC voltage values proportional voltage. Both voltages are in terms of potential via the optocoupler separated from each other.

The arrangement shown in Fig. 1 is suitable for applications in where DC voltages or DC currents that are at high potential are measured should be. The meter does not accept the high potential as it is not direct is connected to the quantity to be measured.

The circuit arrangement according to FIG. 2 is correct with regard to the arrangement A and the connecting line C correspond to that of FIG. It differs in the Arrangement B 'only a single frequency / voltage converter is provided. The switch 91 'applies the input of the frequency / voltage converter 94 optionally to that of the optocoupler 72 or to the wire of the connecting line C coming from the optocoupler 82. The measuring device 93 is directly on via the series resistor 92. the frequency / voltage converter 94 connected.

If necessary, the frequency / voltage converter 94 can have additional measurement voltage sources be assigned.

The circuit arrangement is advantageously required in the arrangement B 'only a single frequency / voltage converter.

Fig. 3 shows a device: for remote supply or

Remote power supply of repeaters on cable runs, at which two or more remote feed devices are used in the feeding point and the current and voltage values given by each device to a central Place to be measured. To route between the potential of the cable leading Output circuit of the devices and a receiving central measuring point a high-voltage-proof The type of measured value transmission explained with reference to FIG. 1 can create separation find particularly advantageous application.

The power sources 10 and contained in the remote feed devices 1 and 2 20 are connected in series. At the outer connections of the series circuit the inner conductors a and b of the coaxial cables 3 and 4. The inner conductors a and b are on Connected to each other at the end of the remote feed line and form the remote feed circuit 5.

The outer conductors 32, 42 of the coaxial cables 3, 4 are at the connection c merged.

The remote feed devices 1 and 2 each contain one of two resistors existing voltage dividers 63, 64 and 65, 66. The two voltage dividers are connected in parallel to each other. The center taps are at connection c or center of symmetry of the output voltages, which can be grounded. The cons-end 63 and 65 are on the inner conductor a, the resistors 64 and 66 on the inner conductor b led.

The resistors 63 and 65 are each connected to tension Among other things, which the inner conductor a leads against the connection c. At resistors 64 and 66 is the voltage Ub that the inner conductor b with respect to the connection c or earth has. The total voltage U1 delivered by the remote power supply unit 1 is present the source 10. The total voltage U2, which the remote power supply unit 2 emits, is present the source 20.

The remote feed current flows from the source 10 via the Fenis feed loop 5, the current measuring resistor 62, the current source 20, the current measuring resistor 61 for Power source 10 back. The voltage U, 7 ′ across the resistor 62 is applied to the resistor 61 the voltage UI2.

Sources 10 and 20 and resistors 61 to 66 lead, respectively a voltage that is to be displayed for monitoring purposes.

There are high voltages between the potentials of the measured values, e.g. between point C and UI2 about 600 V.

These measured values are to be sent to a central display device with which Help yourself to display all measured variables or the relevant measured variable let bring, be transmitted. To achieve this ra, it suffices in more advantageous Way, the sources 10, 20 and to the resistors 61 to 66, in the same way as the resistors 70 and 80 in Fig. 1 of 2 with a voltage / frequency converter and to be provided to the downstream facilities. The arrangement B contains as many voltage / frequency converters as in remote power supply units 1 and 2 measuring voltage sources available. If necessary, further remote feed devices can be connected to the central Display device be performed.

Instead of the switch 91, which allows for the Measuring instrument Control elements can be used to select a desired measured variable in each case to select the measurement voltage sources after remote power supply and MeB-large. In In this case, the device B expediently contains in addition to the instrument a first group of buttons with one button per remote power supply and a second Group of keys with one key for each measuring voltage source of a remote power supply unit.

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Claims (8)

Patent claims ½;) Circuit arrangement for the transmission of measured values DC voltages and / or DC currents, of at least one with respect to reference potential Voltage SUhrenden measuring voltage source to a measuring device, in particular for measuring devices in devices for the remote power supply of repeaters or regenerators of message transmission routes, which are not indicated, that between the measuring voltage source (70, 80) and the reference potential Measuring device (93) each with a voltage-frequency converter (71, 81), a potential separation device and a transmission device including a frequency-to-voltage converter (74, 84) is arranged. 2. Circuit arrangement according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the potential separation device of the measuring voltage source (70, 80) is spatially assigned. 3. Circuit arrangement according to claim 1 or 2, d a -d u r c h g e k 0 n n z e i c h n e t that for the case that for several measurement voltage sources (70, 80) a common measuring device (93) is provided, one upstream of the measuring device (93) Switching device (91) between the potential separation stages and the measuring device (93) is arranged. 4. Circuit arrangement according to claim 3, d a d u r c h g e k e n n z e i c h n e t that the switching device (91) between the potential separation devices and a common frequency-voltage converter is arranged. 5. Circuit arrangement according to claim 3, d a -d u r c h g e k e n n notices that the switching device (91) between the frequency / voltage converters (74, 84) and the measuring device (93) is arranged. 6. Circuit arrangement according to one of claims 3 to 5, d a d u r c h e k e n n n n z e i c h n e t that the output circuits of the potential separation device and / or the frequency / voltage converter (74, 84) unipolar to the reference potential are led. 7. Circuit arrangement according to one of claims 1 to 6, d a d u r c h g e k e n n n z e i c h n e t that the potential separation device is is formed in particular as an emitter follower connected optocoupler (72, 82). 8. Circuit arrangement according to one of claims 1 to 7, d a d u r c h g e k e n n n n e i c h n e t that the voltage / frequency converters (71, 81) and the frequency / voltage converters (74, 84) operate in a frequency range below 100 kHz.