DD256925B5 - Circuit arrangement for monitoring the insulation state of circuits - Google Patents

Description

For this 1 page drawings

The invention relates to a circuit arrangement for monitoring the insulation state of insulated against a neutral potential operated AC or DC circuits, in particular isolated against ground operated WS or GS networks.

It is generally known to switch a voltmeter between earth and each live conductor in insulated catenary networks to control the state of insulation. With the same insulation resistance, the voltages are the same. By this method, only the resistance ratio can be determined. The insulation resistance can not be measured.

Most of the measuring principles for determining the insulation resistance of networks is based on the evaluation of the incoming current change.

From DE-OS 3 035 985 (G01R27 / 18) a circuit arrangement according to the bridge principle is known. Insulation errors are only detected if there is a sufficiently high bridge detuning. No statement about the absolute height of the detected ground fault is possible. Symmetrical isolation errors, d. H. in which both outer conductors or poles have the same but inadmissibly low insulation values against a neutral potential, are not detected. The sensitivity is also dependent on the tolerances of the main voltage.

From the ETZ volume 29, 1977, Issue 4, an arrangement according to the clock method is known. In this case, the network to be monitored is mutually connected to the ground potential via coupling resistors. The current through the coupling resistors is a measure of the insulation quality of the network. Symmetrical ground faults are not detected. The sensitivity depends on the tolerances of the main voltage. To achieve sufficient accuracy, the coupling resistances must be low-impedance.

Also known from ETZ volume 29, 1977, Issue 4 is a working according to the overlay method arrangement in which the network to be monitored is superimposed on a system-external measuring voltage. Thus, the responsiveness becomes independent of the main voltage. A dependence on the tolerances of the measuring voltage, however, persists. Insulation monitoring can also be performed when the main voltage is switched off. Symmetrical ground faults are not detected. The detectable insulation resistance results from the parallel connection of the insulation resistors all network points to ground.

From DE-OS 2 908 374 an arrangement for differential current detection is known. In this circuit, the currents of the forward and return conductors are compared. In case of ground faults, differences in the currents occur. Also, no symmetrical ground faults are detected.

The aim of the invention is to provide a circuit arrangement for monitoring the insulation state of circuits, which requires little effort, has a high reliability, detects all possible ground fault cases and degrades human hazards due to excessive contact or step voltages.

The invention has for its object to provide a circuit arrangement for monitoring the insulation resistance of isolated against a neutral potential operated AC or DC circuits, in particular insulated against ground operated WS-GS networks suggesting a clear detection of the nature and size of the insulation fault, which can also be used independently of the operating state of the network, has no dependence of the measured value of voltage tolerances, which allows fault location, selective shutdown and testing in branched networks and is suitable for use with a microcomputer.

According to the circuit arrangement according to the invention, the insulation resistance of AC or DC circuits operated in isolation against a neutral potential is monitored, each live conductor having a high-impedance voltage detection device against the neutral potential. According to the invention, a resistance is cyclically switched between the neutral potential and a live conductor or alternately between the neutral potential and the live conductors for higher accuracy requirements. The voltages between the live conductors and the neutral potential are measured with and without the connected resistor.

From these voltage ratios and the size of the connected resistor, the insulation resistance is determined according to the formulas which can be derived for a person skilled in the art and explained in more detail in the exemplary embodiment. The technical object is achieved with a circuit arrangement in which the neutral potential is connected to the first or the second conductor via a defined resistor and a switch. To the voltage detection device A / D converters are connected, whose outputs are connected to a computer. The calculator performs the calculation of the insulation resistance and controls the measuring process as well as the tripping circuit. If lower requirements are placed on the measurement accuracy, there is no switching of the defined resistance, but only a cyclic switching on / off.

In an embodiment of the invention, a filter for eliminating the harmonics is connected to eliminate the reactive current influence between voltage detection device and A / D converter.

In order to minimize the influence of the network capacitances on the measurement result, a corresponding clock frequency is selected, which can be determined by measurements.

If, in the absence of main voltage, the insulation resistance is to be measured, then an external test voltage is applied to the conductors.

The invention will be explained in more detail below using an exemplary embodiment. The accompanying drawings show

1: equivalent circuit for the first variant of the circuit arrangement according to the invention; FIG. 2: equivalent circuit for the second variant of the circuit arrangement according to the invention; FIG. 3: basic circuit of an arrangement for monitoring the insulation state

By means of the circuit arrangement according to the invention, the insulation state can be monitored by AC or DC circuits operated in isolation against a neutral potential, or the insulation resistance can be determined. Based on the behavior of the partial voltages, which adjust according to the size of the existing insulation resistance between the network points of the network to be monitored and the neutral potential, the proposed solution according to the invention allows a clear detection of any insulation faults in the network to be monitored. Depending on the requirement for the accuracy of the measured values determined, two variants are possible according to the circuit arrangement according to the invention. The first variant of FIG. 1 is suitable for low demands on the measurement accuracy and requires for their realization a low cost, while the second variant of FIG. 2 with correspondingly higher expenditure also allows a higher accuracy. In the first variant of the circuit arrangement according to the invention is in WS circuits an outer conductor a or b, in GS circles a pole a or b, cyclically via a defined resistance R _def via a switch S to the neutral potential, for. B. connected to ground potential. The due to the existing unknown isolation quality of the network to be monitored against this neutral potential adjusting partial voltages U ₁ ; U ₂ at the voltage detecting means for the state that the defined resistance R _{def is} not connected to the neutral potential, and the state in which the outer conductor a or Pol a is connected to the neutral potential via the defined resistance R _def are a measure for the size of the insulation resistances of all network points of the network to be monitored to the neutral potential. The formulas required for calculating the insulation resistances are derived from the equivalent circuit according to FIG. 1

 It means:

R ₁ insulation resistance of the outer conductor a or Pol a to the neutral potential

R ₂ insulation resistance from the outer conductor b or Pol b to the neutral potential

R _de , defined resistance, which is cyclically connected to the grid potential

Index 1 switch S open

Index 2 switch S closed

This results in the following calculation formulas

^U 2J_ 11

^R 2 = ^R 1 · у

According to the second variant of the circuit arrangement according to the invention, both outer conductors a are in WS circuits; b, when applied in DC circles, both poles a; b each have a defined resistance R _def alternating with the neutral potential, z. B. connected to ground potential. It is of course also possible to use only one common defined resistance R _def to be connected to the ground potential and alternately via switch S ₁ ; S ₂ , each with an outer conductor or pole a; b is connected. The resulting due to the unknown quality of insulation of the network to be monitored against the neutral potential partial voltages for the state that the outer conductor a or Pol a via the associated resistor R _{def is} connected to the neutral potential and the state that the outer conductor b or Pol b is connected via the associated defined resistance R _def with the neutral potential, are a measure of the size of the insulation resistance of all network points of the network to be monitored to the neutral potential. The formulas required for calculating the insulation resistance are derived from the equivalent circuit according to FIG. 2. It means:

R ₁ insulation resistance of the outer conductor a or Pol a to the neutral potential

R ₂ insulation resistance from the outer conductor b or Pol b to the neutral potential

R _def defined resistance, which is cyclically alternately connected to one or the other power potential

Index 1 Switch S1 closed, Switch S2 open Index 2 Switch S1 open, Switch S2 closed This results in the following calculation formulas

₁ _JJu

U ₂₁ U ₁

J-Q

Jn ₊ U ₁

U ₂₁ U ₂₁ U ₁₂

R ₁ =

U ₁₂ \ R _def F.

The processing of the measured values and the required intermediate results is carried out with electronic devices, preferably with an electronic computer.

When using the circuit arrangement according to the invention, it has to be weighed which of the two variants is most suitable for the respective purpose. Variant 2 has a higher technical accuracy to be realized compared to variant 1 with correspondingly higher effort.

The solution according to the invention can be realized by various circuit arrangements, both analog and digital and mixed circuits. The circuit arrangement according to the invention is described in more detail on an exemplary embodiment of isolated trolleybus systems operated in accordance with FIG. 3, wherein the first variant of the circuit arrangement according to the invention is realized. The realized monitoring arrangement consists of two main function groups, a potential part and an evaluation part located on auxiliary network potential with the computer 5 and the downstream switching elements. The transfer of measured value from the potential part to the computer 5 and the preparation of the measured values via an A / D converter, which must also realize the required potential separation. Basic elements of the potential part are the two high-impedance voltage detection devices 1; 2, which are realized by a voltage divider, which is connected between the two poles of the DC network and whose center is rigidly connected to the Erdpolpotential E and dependent on the required isolation quality (ohms / volts) of the network defined resistance 7, by means of via the computer 5 controlled switching element 8 according to the circuit arrangement according to the invention an additional connection of a respective pole 12; 13 realized with earth E.

The measured values U ₁₁ ; U ₂₁ or U ₁₂ ; U ₂₂ are tapped in a known manner and in the A / D converters 3; 4 converted into isolated digital signals that form the input variables of the computer 5. By the configuration of the computer 5, the determination of the resulting insulation resistance R ₁₁ ; R ₁₂ based on the existing relationship between voltage and insulation resistance in real-time operation. When falling below the permissible values for the insulation resistances, a signal is issued in the case of single ground fault and disconnection of the catenary network by means of a tripping circuit 6 in the case of double earth faults. Thereafter, the fault location and, if necessary, permanent shutdown of the faulty network takes place with circuits known measures. In networks whose network sections can be switched independently of one another, it is expedient to determine the faulty network section by means of an invention and to selectively disconnect it from the network in the event of danger.

In the case of a missing main voltage, a test for insulation faults can be carried out by implementing the supply of the network to be monitored by an external test voltage source.

The influence of the network capacity on the test result is minimized by the fact that the clock frequency / _r is chosen so that transients do not distort the measurement result in voltage drops or when reconnecting the voltage.

The influence of capacitive and inductive reactive currents on the isolation between the network to be monitored and the neutral potential due to network harmonics on the test result is minimized by the fact that after the voltage detection devices 1; 2 filter elements or filters 10, 11 are connected, which only the relevant frequency range of the measured value to the A / D converter 3; Let 4 happen.

The invention finds application in AC or DC circuits operated in isolation against a neutral potential for monitoring insulation faults or potential carryovers. Neutral potential should be understood as meaning all those points in the vicinity of the circuit to be monitored which, owing to constructive (insulation) or electrical measures, do not make an electrically conductive connection to at least one point of the circuit

to have monitoring circuit. The invention is particularly suitable for use in isolated against ground powered WS or DC networks whose network points can be spatially separated from each other and switched independently, but are galvanically connected together to detect ground faults.

Special application examples can trolleybuses, electric power supply systems for technological systems whose equipment z. B. electrolysis, drive machines from o. G. Nets be fed or to be monitored cables and lines.

The invention has made a significant contribution to increasing the reliability by all dangerous insulation faults are detected and therefore targeted measures can be taken to ensure the required personal safety and to maintain the availability of the facilities as far as possible. Threats to humans or livestock are reduced.

With the application of the invention, it is possible for the first time to detect faulty network sections and to selectively switch them off, since fault type and fault location can be determined locally by applying state-of-the-art circuit measures within the network to be monitored in conjunction with the solution proposed according to the invention. The invention enables a clear detection of the nature and size of the insulation fault. Thus it can be distinguished between single and double closure, high or low impedance and symmetric or asymmetric. The detection of insulation faults is independent of the operating state of the network, since the possibility of testing with a separate auxiliary voltage. The measured values are independent of voltage tolerances of the main voltage or auxiliary voltage. The invention is particularly suitable for networks in which monitoring and control by means of microcomputers takes place.

Claims (5)

1. Circuit arrangement for monitoring the insulation state of isolated against a neutral potential operated AC or DC circuits, each live conductor has a high-impedance voltage detection device against a neutral potential, characterized in that time-limited, defined changes in the insulation resistance of one or more live conductors against a neutral potential of the circuits to be monitored are brought about by additional resistance circuitry in order to be able to determine the original insulation resistance of the circuits from the voltage conditions which then arise within the circuits to be monitored in comparison with the original voltage conditions and in conjunction with the selected resistance circuits. 2. A circuit arrangement according to claim 1, characterized in that via a resistor (7) and a switch (8), the neutral potential (E) with the first conductor (12) or the second conductor (13) is connected to the voltage detection device ( 1; 2) A / D converters (3; 4) are connected, the outputs of which are connected to a computer (5) which controls the measuring operation and is connected to a triggering switch (6). 3. A circuit arrangement according to claim 2, characterized in that for eliminating a reactive current influence between voltage detection means (1; 2) and A / D converter (3; 4), a filter (10; 11) is connected. 4. Circuit arrangement according to claim 2, characterized in that the influence of the network capacitances on the measurement result by selecting the clock frequency (/ _T ) is minimized. 5. Circuit arrangement according to claim 2 to 4, characterized in that in the absence of the main voltage to the conductor (12; 13) an external test voltage (9) is connected.