DE19944680C2 - Device for phase error detection - Google Patents

Description

The invention relates to a device for phase error detection, especially for earth fault detection.

In electrical energy systems, especially in lines or Line sections for the transmission of electrical energy are ground faults in the form not to be excluded from arcs, which lead to considerable damage, if this cannot be switched off quickly within a switchgear. It is therefore important that quick detection of such phase errors and a quick shutdown of the concerned facility or the relevant line section.

A device for phase error detection (phase loss detection) is known. Detector circuit) by monitoring the three phases of a three-phase Electric motor to protect this motor (EP 0 336 943 B1). The known device allows between a phase loss and another, temporary, from Ideally, to distinguish between different states of the phases and one Phase loss and in this case switch off the motor. The well-known Device has u. a. a device with which the tension of the electrical three-phase system and a measuring voltage is generated from it, that of the instantaneous voltage of the electrical three-phase system equivalent. The device further comprises a device for detecting the Peak voltage of the three-phase electrical system and to generate a corresponding peak voltage signal. Furthermore, a device is provided in which the peak voltage signal is compared to the instantaneous voltage and which generates a comparison signal. The comparison signal normally has one first polarity, in the event of a phase loss or a temporary deviation however, a second, opposite polarity, so that with the Comparison signal of the second, opposite polarity a possible phase loss or a temporary deviation is displayed. For differentiation in both cases, a further device is provided in both cases,  which then detects a phase loss when the comparison signal of the second polarity has an impulsive course.

The object of the invention is to demonstrate a device that is not only one enables early and very reliable detection of phase errors, but even immediately after the occurrence of a serious phase error (Earth fault) provides a signal (error signal) which can be switched off or disconnected the relevant facility or line section from the network can be used.

A device for phase error detection is used to solve this problem trained according to claim 1.

Developments of the invention are the subject of the dependent claims. The invention is explained in more detail below with reference to the figures using an exemplary embodiment.

Show it:

FIG. 1 is a simplified representation of a block or functional diagram of an embodiment of the inventive device for phase error detection in a three-phase line for transmitting electric power;

Fig. 2 the output of an input or measuring stage during normal operation;

FIGS. 3 and 4, the input and output of an integrator of the apparatus of Figure 1 during normal operation.

Fig. 5 and 6, the voltage waveform at the input of the input or measuring stage, namely at a ground fault occurs during a positive period (Fig. 5) or a ground fault occur during a negative period, in each case together with an output or error signal, inter alia, to operate disconnectors to switch off all phases;

FIGS. 7 and 8 representation like FIGS. 3 and 4 when a phase error occurs (earth fault);

Fig. 9 is the circuit of a possible embodiment of the input or measuring stage;

Fig. 10, the circuit of the input stage following stages of the apparatus of Fig. 1,

Figure 11 is a simplified representation of a medium-voltage switchgear, together with a plant protection system which includes the apparatus of Figure 1-10 as well as an arc detecting device..;

Fig. 12 in several simultaneous diagrams the earth fault current when an earth fault occurs, the output voltage of the device for detecting a phase error, the output voltage of an arc indicator of the arc detection device and a shutdown signal for actuating the circuit breaker of the cell in question.

In the figures 1-3 are the three conductors or phases of a line for the transmission of electrical energy, for example a medium-voltage switchgear. 4 generally designates the device for phase error detection or for earth fault detection, this device 4 actually serving not only for the pure detection or detection of a possible phase error or earth fault, but also simultaneously providing a signal (error signal 19 ) which, by controlling the corresponding circuit breaker, disconnects the line strand (conductor 1-3 ), which has the fault or earth fault, from the rest of the network.

In general, the device 4 for monitoring each phase 1-3 each has its own module 5 , which is accommodated, for example, on a card or an insert together with the modules for the other phases or conductors 1-3 in a common housing. This housing can then also accommodate further modules 5 for further lines or line sections.

In FIG. 1, for the sake of simplicity, only one module 5 for monitoring the conductor 3 is shown .

Each module 5 is associated with its own with single and measurement stage 6, which detects with its input the voltage at the respective conductor and provides a relative to the voltage of phase 3 reduced AC voltage signal at its output as a measurement signal 7, whose temporal profile of the time course of Voltage at phase 3 is proportional. In the embodiment shown in the figures, the input stage 6 is designed such that it delivers a measurement signal 7 generated by double-path rectification at its output.

The output of the respective measuring stage 6 is connected to the associated input of the module 5 , this input being formed in the embodiment shown by an isolating stage 8 which brings about a complete galvanic isolation and essentially consists of an opto-coupler.

The output signal of the isolating stage 8 is fed to the input of an inverting trigger stage 9 , the output voltage of which is switched from a positive voltage value to zero by the leading edge of each pulse of the measuring signal 7 formed by a half-sine wave and then after a predetermined period of time and before the arrival of the edge of the next pulse of the measurement signal 7 controlled by a timing element in turn assumes the positive voltage value, so that the pulse voltage 10 shown in FIG. 3 is obtained at the output of the trigger stage 9 .

The output of the trigger stage 9 is connected to the input of an integrating stage 11 , in which each pulse of the pulse signal 10 is integrated, thereby generating a pulse signal 12 in which the amplitude of the pulses is a function of the width or the pulse duration of the pulses of the signal 10 , In the case of trouble-free operation, each pulse of the signal 10 corresponds to a pulse of the pulse signal 12 obtained by its integration.

The output signal of stage 11 is fed to a switching stage 13 , in which this output signal is compared with a switching threshold 14 . The latter is adjustable, in such a way that the amplitudes of the pulses of the signal 12 are well below the switching threshold 14 in normal, trouble-free operation.

FIGS. 5 and 6 show the timing of the input voltage at the input of the input or measuring stage 6, in the Fig. 5 a time course of 15 upon the occurrence of a ground fault in the positive phase of the AC voltage on the conductor 3. This earth fault is characterized by the sudden drop in voltage according to line 16 .

Fig. 6 shows the voltage waveform 17 at an occurring during the negative phase of the conductor 3 ground fault, which is characterized by the sudden voltage drop corresponding to the Line 18. Both errors lead to the fact that in the output or measurement signal 7 on a certain edge that still triggers the trigger stage 9 , for example the leading edge of the pulses of the measurement signal 7 after the earth fault occurs, the next edge triggering the trigger stage 9 remains and accordingly the output voltage 10 can no longer be set to zero at this trigger stage due to the missing edge, as shown at 10 'in FIG. 7. This has the consequence that after the occurrence of the earth fault, the pulses of the output signal 12 fail to appear and the amplitude of this output signal 12 rises above the switching threshold 14 , as is indicated in FIG. 8 by the curve 12 '. This also has the consequence that the switching stage 13 then supplies an error signal 19 which is represented in FIGS. 1, 5 and 6 by the voltage rising from zero to a positive voltage value. This error signal 19 then serves, among other things, to control an optical display 20 which shows the phase error on the conductor 3 . Furthermore, the error signal 19 present at the output 21 of the module 5 is also used to control the relay 23 via a driver or amplifier stage 22 . These are then used in the presence of the signal 19 motors of disconnectors, which disconnect all three conductors 1-3 of the line section on which the earth flow occurred, before this earth fault can lead to greater damage, for example by earth faults also the other phases or conductors etc.

Logic 24 is provided between output 21 and driver stage 22 . The latter, like the driver stage 22 and the relay 23, is provided together for the modules 5 of all conductors 1-3 of the line. For this purpose, the logic 24 has three inputs, to each of which an output 21 of a module 5 is connected. The logic 24 is designed in such a way that it then delivers an output signal which controls the relay 23 if at least one conductor 1-3 has a ground flow, ie at least one output 21 of a module the error signal 19 occurs, but no signal controlling the relay 23 then delivers when all conductors 1-3 are de -energized because the corresponding line section has been removed from the network, for example.

From the above description it follows that the trigger stage 9 in conjunction with the integration stage 11 act as a circuit which monitors the duration between two successive edges in the output signal 7 of the measuring stage 6 and supplies the error signal 19 when this duration has a predetermined threshold value exceeds, this threshold value being adjustable or preselectable, in the embodiment shown via the threshold voltage 14 . The circuit described above is characterized by a particularly simple structure with high operational reliability, especially in an environment that is loaded with high magnetic and electrical fields, but there is also the possibility of the length of time in which monitored edges or voltage levels in the measurement signal 7 follow one another to be monitored in a different way, for example by counting devices, an error signal 19 being generated when the time interval determined by a counting device between two monitored edges of the measuring signal 7 exceeds a predetermined threshold value.

Fig. 9 shows a possible embodiment for the input or measuring stage. 6 This stage is connected to the respective conductor, for example to conductor 3 and to a reference potential, for example to a neutral conductor, via the primary side of a transformer 25 . In the secondary circuit of the transformer 25 there is a bridge rectifier 25 ', the output voltage of which is available as an output voltage 7 via a voltage divider 25 "with diodes which limit the voltage.

Fig. 10 shows an example of the circuit for the separation stage 8, the trigger stage 9, the integration stage 11 and the comparator 13 of a module 5. Also shown are the common logic 24 and common driver stage 22 for all modules 5 for controlling the relays 23, which are not shown in FIG. 10.

As shown in FIG. 10, the integrating stage 11 essentially consists of an RC element which is formed by the resistor 26 and the capacitor 27 . The diode 28 is used in parallel with the resistor 26 for faster discharge of the capacitor 27 in the zero phase of the output signal 10 .

The switching stage 13 is formed by a trigger 29 . The voltage present at the input can be set using a potentiometer 30 . The switching threshold 14 is set with the potentiometer, at which the output signal 12 causes the error signal 19 .

The logic stage 24 consists, for example, of the circuit shown in FIG. 10 from the logic AND circuit 31 with negated output, the AND circuit 32 and the two OR circuits 33 and 34 , the output of the AND circuit 32 being the output the logic level 24 forms. An output 21 is respectively connected to a module 5 to the three inputs of the AND circuit 31 and the three outputs 21 are are so linked via the OR circuits 33 and 34, that at the output of the OR circuit 34, the logic value "1 "is present, the error signal 19 is present at least at one output 21 , while the AND circuit 31 has the logic value" 0 "at the output if the error signal 19 is present at all three outputs 21 at the same time. At the output of the AND circuit 32 , a signal which drives the relays 23 via the driver stage 22 is only present if an earth fault occurs on one or more conductors 1-3 , but the voltage on conductors 1-3 does not already occur beforehand was missing because the corresponding line section was disconnected from the network.

In order to ensure that the device 4 functions properly even in the event of a power failure, it is operated with battery backup. By setting the switching threshold 14 accordingly, it is achieved that only serious phase errors and not voltage fluctuations or drops caused by fluctuations in the load trigger the error signal 19 .

As FIG. 10 also shows, the driver stage 22 is equipped with an attenuator or delay element, namely consisting of a capacitor to prevent the relay 23 from "fluttering" when the voltages on the conductors 1-3 drop briefly.

Fig. 11 shows a gas-insulated medium-voltage switchgear 40 or a cell of such switchgear, namely the ease of illustration, because of the single-pole cell. The switchgear assembly 40 consists in a known manner of three chambers or sections, namely first of all the section 41 which forms the cable outlet and to which the underground cables leading, for example, to an overhead line are connected. The circuit breaker 43 for the phase shown is located in a second section 42 . In a third section 44 , a changeover switch 45 is provided, with which this phase is optionally possible by connecting to one of the two busbars 46 or 47 .

In FIG. 11, the device 4 is once again added to the phase error detection, which is connected to the busbar 47 via the input and measuring stage 6, which corresponds to the conductor 3 in FIG. 1. The output of the device 4, which is formed by a relay 23 , is combined with the output of an arc detection device 49, which is also formed by a relay 48 , in the form of a logic AND function such that when an output signal 19 indicating a phase error is present at the output of the device 4 , ie the relay 23 is activated and at the same time a signal registering an arc is present at the output of the arc detection device 49 , ie the relay 48 is activated, the circuit breaker 43 is opened.

The device 49 has, inter alia, three light detectors 50 , one of which is provided in each section 41 , 42 and 44 . Light guides 51 lead from the light detectors 50 to an optical input of the device 49 . The transmitting through the light conductor 41, light pulses are converted in the device 49 to electrical signals and evaluated, so that an output signal of the device 49 always is present when at least an arc occurs in a portion 41, 42, 44th

With the system formed by the two devices 4 and 49 , reliable protection of the medium-voltage switchgear 40 against internal earth faults occurring in this system and resulting short-circuits between the phases is possible.

FIG. 12 shows in diagram a) the current of a single-phase earth fault that occurred at time T0. Diagrams b) and c) show that the error signal 19 and also an output signal from the device 49 are present after a short period of time after the phase error (single-phase) earth fault, so that according to the diagram d) within a period of time significantly less than 100 milliseconds after the occurrence of the earth fault, the circuit breaker 43 is opened at least in this phase and the earth fault is thus deleted.

Diagrams e), f) and g) show the current of the three phases for the assumed case that the protection system formed by devices 4 and 49 is not present and the faulty phase is therefore not switched off early. After about 250 milliseconds, the earth fault rotating around the faulty conductor forms a short circuit between two phases, which is indicated by the alternating current in diagrams f) and g). A short time later, this short circuit includes the third phase. This then results in high currents, which release considerable energy and can lead to complete destruction of the switchgear.

With the system described, internal, ie. H. in the switchgear occurring earth faults are detected and an automatic shutdown of at least the faulty phase is reached before there is a two- or three-pole short circuit.

The system has been described above for medium voltage switchgear. The The system can also be used for high-voltage switchgear. Farther the system is also used in single-phase, encapsulated gas-insulated switchgear usable advantageously.

The advantages of the system described above can be summarized as follows:

• - With three-pole gas-insulated switchgear in extinguished networks
  The system has, as stated above, a great advantage which can be switched off in less than 100 milliseconds, ie the single-phase fault (whether earth fault or short circuit) can be switched off before it becomes a two- or three-phase fault.
• - With single-pole gas-insulated switchgear in extinguished networks
  The arcing fault is limited to an earth fault arc. This earth leakage arc is precisely recorded with the system. In connection with the device 4 , the earth fault arc can then be specifically activated or deactivated.
• - With three-pole air-insulated switchgear
  In such systems in particular, it is necessary to switch off faults very quickly, since the single-pole earth fault leads to a two- or three-pole short circuit within 150-200 ms. The rapid shutdown significantly reduces the risk to operating personnel and the destruction of the switchgear.

The invention has been described above using exemplary embodiments. It understands is aware that numerous other changes and modifications are possible.  

LIST OF REFERENCE NUMBERS

1

.

2

.

3

ladder

4

device

5

module

6

measuring stage

7

Output signal of the measuring stage

8th

separation stage

9

trigger level

10

Output signal of the trigger stage

11

integration level

12

integrated output signal

13

comparison stage

14

switching threshold

15

Input signal at the measuring stage

16

Voltage drop due to earth fault

17

Input signal at the input stage

18

Voltage drop due to earth fault

19

error signal

20

display

21

output

22

driver stage

23

relay

24

logic stage

25

exchangers

25

'Rectifier

25

"Voltage divider

26

resistance

27

capacitor

28

diode

29

trigger

30

potentiometer

31

.

32

logical AND circuit

33

.

34

logical OR circuit

35

Time delay element

40

switch arrangement

41

Section or chamber

42

Section or chamber

43

breakers

44

chamber

45

switch

46

.

47

bus

48

relay

49

Arc detection device

50

light detector

51

optical fiber

Claims (19)

1. Device for phase error detection on at least one conductor or at least one phase of a device or line for the transmission of electrical energy, by monitoring the AC voltage on this phase or on this conductor, characterized by detection and evaluation means ( 9 , 11 , 13 ), with which at least a section that recurs periodically in the course of the AC voltage or a measurement signal corresponding to this AC voltage in the case of trouble-free operation is generated and an error signal ( 19 ) indicating a phase error is generated when a monitor in the measurement signal after the last arrival Section no further section occurs within a predetermined monitoring time interval. 2. Device according to claim 1, characterized in that of the detection and evaluation means each have a predetermined edge of the positive and / or negative half wave of the AC voltage, for example the temporal leading edge is detected. 3. Apparatus according to claim 1 or 2, characterized in that each of the detection and evaluation means ( 9 , 11 , 13 ) a predetermined edge of both the positive and the negative half-wave of the AC voltage on the at least one conductor ( 1- 3 ) is detected. 4. Device according to one of the preceding claims, characterized in that the predetermined monitoring time interval is approximately equal to half the period of the AC voltage on the at least one conductor ( 1-3 ). 5. Device according to one of the preceding claims, characterized in that detection and evaluation means ( 9 , 11 , 13 ) are part of a monitoring module ( 5 ) assigned to the respective phase. 6. Device according to one of the preceding claims, characterized by detection and evaluation means for generating a first output signal ( 12 ) corresponding to the duration of the monitored period and for generating the error signal ( 19 ) if one is preferred for the first output signal ( 12 ) adjustable switching threshold ( 14 ) is exceeded. 7. Device according to one of the preceding claims, characterized in that the detection and evaluation means ( 9 , 11 ) as the first output signal ( 12 ) deliver a pulse signal in which the amplitude of the pulses is proportional to the time period in which two monitored sections in the measurement signal follow one another. 8. Apparatus according to claim 6 or 7, characterized in that the first output signal is compared in a further stage ( 13 ) with the preferably adjustable switching shaft ( 14 ). 9. Device according to one of the preceding claims, characterized in that the detection and evaluation means have a stage, preferably a trigger stage ( 9 ), which provides a second output signal ( 10 ), each of which arrives at the arrival of a monitored section from a first State is set to a second state and automatically assumes the first state again before the arrival of a following section, wherein if the monitored section is absent, the second output signal ( 10 ) is not set from the first state to the second state, and that Means are provided which detect the duration of the first state and generate the error signal ( 19 ) when this duration exceeds a predetermined or adjustable threshold. 10. The device according to claim 9, characterized in that the first and second Condition are different voltage values. 11. The device according to claim 9 or 10, characterized in that for generating a first output voltage forming the first output signal ( 12 ) a second output signal ( 10 ) forming the second output voltage of an integrating stage ( 11 ) is supplied, which has the first output signal at its output ( 12 ) runs as a pulse-shaped first output voltage, in which the amplitudes of the pulses are proportional to the duration of the first state of the second output signal ( 10 ). 12. Device according to one of the preceding claims, characterized by a further stage ( 13 ) which supplies the error signal ( 19 ) when the amplitudes of the pulses of the first output signal ( 12 ) exceed the switching threshold ( 14 ). 13. Device according to one of the preceding claims, characterized in that an input or measuring stage ( 6 ), at whose input the AC voltage of the at least one conductor ( 1 , 3 ) or a voltage proportional thereto, a full-wave rectifier for Generation of the measurement signal in the form of a pulse-shaped measurement voltage, the pulse repetition frequency is equal to twice the frequency of the AC voltage on the at least one conductor ( 1-3 ). 14. Device according to one of the preceding claims, characterized in that the measuring stage ( 6 ) has means for voltage reduction ( 25 ') and for voltage limitation ( 25 "). 15. Device according to one of the preceding claims, characterized by an optical and / or acoustic display controlled by the error signal ( 19 ). 16. Device according to one of the preceding claims, characterized in that at least one steep element of at least one isolating switch for switching off the at least one monitored conductor ( 1-3 ) can be actuated by the error signal ( 19 ). 17. Device according to one of claims 5 to 16, characterized in that a monitoring module ( 5 ) is provided for the simultaneous monitoring of several conductors or phases for each phase or for each conductor, and that the outputs providing the error signal ( 19 ) ( 21 ) control these modules via a logic ( 24 ) actuating elements for isolating switches of all conductors, in such a way that when a phase error occurs on one conductor ( 1-3 ) the isolating switches of all conductors are actuated to switch off these conductors from the mains become. 18. Device according to one of claims 5 to 17, characterized in that the output ( 21 ) of the at least one monitoring module ( 5 ) controls at least one switching element, for example relays for actuating a disconnector. 19. Switchgear protection system characterized by a device according to one of the preceding claims and by an arc detection device ( 49 ) which has at least one light sensor ( 50 ) monitoring a switchgear assembly ( 40 ) and, when an arc occurs in the switchgear assembly ( 40 ), an output signal registering this arc provides, as well as means generating a signal causing the switching device ( 40 ) to be switched off or at least one circuit breaker ( 43 ) to open if both the error signal ( 19 ) indicating the phase error and the output signal registering an arc are present in the signal from the Devices monitored part of the switchgear.