WO2009012800A1 - Protective device and method for operating a protective device - Google Patents

Abstract

The invention relates, inter alia, to a protective device (40-47) for protecting an electrical conductor, hereinafter referred to as the dedicated conductor, associated with the protective device, of an energy supply system (20), having a primary protection function whereby in the event of a malfunction in the dedicated conductor it quickly produces a primary trigger signal in order to switch off the conductor, if prespecified primary protection triggering conditions are met. According to the invention, the protective device incorporates a communication unit (70) for communicating with directly or indirectly neighboring protective devices, as well as a control unit (72) connected to the communication unit, the control unit being so designed as to provide a back-up protection function using the transmitted current measuring values (11-14) of neighboring protective devices, under application of Kirchhoff's law, to check whether a malfunction has occurred within one or more secondary protection zones (50) defined by the neighboring protective devices, and the control unit can generate a back-up triggering signal in order to switch off the dedicated conductor if a malfunction has occurred within one of these secondary protection zones.

Description

description

Protective device and method for operating a protective device

The invention relates to a protective device with the features according to the preamble of claim 1.

Such protective devices are sold, for example, by Siemens AG under the product name SIPROTEC. These protective devices are used to protect a protective device associated with the electrical line, hereinafter called own line, a power supply system. They have a main protection function which, in the event of a fault on their own line, quickly generates a main trip signal for switching off the own line, if specified main protection tripping conditions are met. The previously known protection devices can also have a reserve protection function which is suitable for generating a reserve triggering signal for switching off one's own line delayed by a predetermined staggering time without fulfilling the actual main protection triggering conditions if predetermined reserve protection triggering conditions exist.

Under certain circumstances, the mentioned reserve protection function can cause the problem that by switching off a line of the energy supply system by a protective device in other neighboring protective devices tripping conditions are met, so that it in rare cases to a cascaded shutdown of lines through a variety of protection devices and a so-called "blackout" occurs, in which to a significant extent also parts of the

Power supply system are shut down, which are actually not affected by an error and actually should not have been shut down because the Protective devices specified in the main protection tripping conditions were not fulfilled.

Starting from a protective device of the type described, the invention has the object to provide a protective device in which a shutdown of fault-free sections of a power supply system is even better avoided than before in the event of a system failure.

This object is achieved by a protective device with the features of claim 1. Advantageous embodiments of the protective device according to the invention are specified in subclaims.

According to the invention, it is provided that the protective device has a communication device for communication with indirectly or immediately adjacent protective devices and a control device connected to the communication device, and that the control device for forming a reserve protection function - hereinafter referred to as "first" reserve protection function to distinguish from other reserve protection function - configured is that it can also check, based on the transmitted current readings of adjacent protection devices using the Kirchoffoff law, whether an error has occurred within one or more secondary protection zones defined by the adjacent protection devices and that it is a back-up trip signal - hereinafter differentiated from other back-up trip signals "first". Reserve trip signal - can be used to switch off the own line if an error has occurred within one of these secondary protection zones is.

A significant advantage of the protective device according to the invention is the fact that this is not only the own line and, in cooperation with neighboring protection devices, also cross-border zones - here referred to as secondary protection zones - by making use of the Kirchhoff law principle. For example, if the protection device detects that the sum of the currents within an associated secondary protection zone within which it is located is zero or approximately equal to zero and thus no fault has occurred in this secondary protection zone, the protection device may also switch off its own line in case of overload permanently or for a predetermined period of time distance, whereby the initially described cascaded automatic shutdown of not faulty sections of the power plant is avoided. If, on the other hand, it finds that it belongs to a secondary protection zone that actually has an error, then quickly disabling its own line can ensure that the error is effectively localized, even before other non-faulted sections the power supply system by staggered working reserve protection function of other protection devices are also affected and possibly the blackout problem described by cascaded shutdown occurs.

According to a preferred embodiment of the protective device is provided that the secondary protection zones, at least one of which is formed with at least one inner protection device which is completely contained within the secondary protection zone, and with at least one additional, electrically outside protective device, thereby electrically the at least one inner protection device around a closed outer shell of the secondary protection zone is defined by external protection devices. In this embodiment can be reliably for all internal protection devices Determine errors by applying the Kirchhoff rule to the closed outer shell. Preferably, the secondary protection zones are formed such that each protection device forms an internal protection device for at least one of the secondary protection zones.

According to a preferred embodiment of the protection device, it is provided that the first backup protection function operates with as little delay as possible, preferably faster than, just as fast or almost as fast as the main contactor function of the protection device and in particular faster than other backup protection function that delays according to a predetermined staggering time to react. In this embodiment, a delayed response of other staggered backup protection functions can be blocked permanently or for a predetermined period of time if the first backup protection function has not detected an error in its associated secondary protection zones.

The control device of the protective device preferably has an input device into which inputs can be fed for determining the assigned adjacent protective devices and for defining one or more secondary protection zones. In this embodiment, the user can be set individually how secondary protection zones should be procured and arranged in the energy supply system.

Alternatively or additionally, the control device of the protective device can have a zone-forming function, which can automatically determine one or more secondary protection zones on the basis of predetermined topology data of the energy supply system. Preferably, such a zoning function is designed such that an automatic formation of the secondary protection zones depending on the quality and / or the loading there is a communication connection to the neighboring protection devices.

Particularly preferably, the protective device also has a second reserve protection function which differs from the first reserve protection function and which is suitable for generating a second reserve triggering signal for switching off the dedicated line in the event of an overload situation on the own line without fulfilling the predetermined main protection triggering conditions by a predetermined staggering time. if predetermined overload tripping conditions are met. Preferably, the control device will activate the second backup protection function if there is no communication connection to the protection devices of the secondary protection zones and no current measured values are received; in a corresponding manner, it will preferably deactivate the second reserve protection function if there is a communication connection to the protection devices of the secondary protection zones and their current measured values are received.

Also, the controller may operate the first backup protection function and the second backup protection function in parallel and during the staging time of the second backup function using the transmitted current readings of the protection devices of the secondary protection zones using the Kirchoffoff law check whether an error has occurred within the associated secondary protection zones, and generating the second Permanently or temporarily block the reserve trip signal if it detects that an error has not occurred within any of its associated secondary protection zones.

In order to ensure that all protection devices can operate autonomously, it is considered advantageous if the protection devices each have a time synchronization device which has a allows time-synchronous measurement of the current measured values in comparison to the neighboring protection devices. The control device is preferably connected to the time synchronization device and capable of receiving the current measured values of its own line in a time-synchronized manner relative to those of the neighboring protective devices.

The control device is preferably suitable for generating pointer measured variables as current measured values, for example according to the IEEE standard C37.118.

For example, the control device is also suitable for sending its pointer measurement values with the communication device to the neighboring protection devices, in particular via a wired or wireless telephone or data connection, for example via Ethernet or Internet.

It is also considered advantageous if the control device is suitable for phase-selectively measuring the current measured values of electrical phase conductors of its own line and for forming phase-selective current measured values.

As an independent invention, a method for operating a protective device is also considered. According to the invention it is provided in this regard that a secondary protection zone with at least one inner protection device which is completely contained within the secondary protection zone, and at least one additional electrically external protection device is formed, whereby electrically around the at least one inner protection device around a closed outer shell of the secondary protection zone external protection devices is defined, and that the secondary protection zone formed in this way is entered into the control device of the protective device. With regard to the advantages of the method according to the invention Reference is made to the above statements in connection with the protective device according to the invention.

The invention also relates to an arrangement with a plurality of protective devices, as described above, for protecting a power supply system, wherein the protective devices form at least two secondary protection zones to be monitored.

In such an arrangement, at least one of the protective devices preferably belongs to at least two, preferably otherwise non-overlapping, secondary protection zones.

In addition, the invention relates to a method for protecting a predetermined electrical line of a power supply system, with a main protection function of a protective device in the event of a fault on the given line promptly a main trigger signal for switching off the predetermined line is generated, if predetermined Hauptschutzauslösebedingungen are met ,

According to the invention, with regard to such a method, it is provided that with communication devices current readings of directly or indirectly adjacent other protective devices are transmitted to a central device with which, using the Kirchoffoff law, it is checked whether an error has occurred within one or more secondary protection zones defined by the adjacent protective devices, and generating a first reserve trip signal for turning off the predetermined line if such a fault exists. For example, the control device of the protective device assigned to the specified line is used as the central device in this method.

Alternatively, a centrally arranged monitoring device can be used as the central device, which communicates with the protective device assigned to the predetermined line in a communication connection.

For example, the definition of the secondary protection zones takes place in the centrally arranged monitoring device. With regard to this variant, it is considered advantageous if the definition of the secondary protection zones is staggered and begins with large secondary protection zones for gross fault location and continues successively with decreasing secondary protection zones until the fault location by determining a smaller, preferably the smallest possible , Secondary protection zone has been identified with fault behavior.

The invention will be explained in more detail with reference to embodiments; thereby show exemplarily:

1 shows a section of a power supply system with unclaimed protective devices for general explanation,

FIG. 2 shows a section of a power supply system which is equipped with exemplary embodiments of protection devices according to the invention, an embodiment variant of the method according to the invention being explained by way of example with reference to this energy supply system, Figure 3 shows an embodiment of a protective device for the arrangement according to the figure 2 and

Figure 4 shows a portion of a power supply system, which is equipped with another embodiment of protection devices according to the invention, namely those that cooperate with a central unit, which is explained by way of example, another variant of the inventive method with reference to this energy supply system.

For the sake of clarity, the same reference numbers are always used in the figures for identical or comparable components.

FIG. 1 shows a section 10 of a power supply system 20; the section 10 is defined by the terminals A, B, C and D as an example. Within the section 10 protection devices 10, 11, 12, 13, 14, 15, 16 and 17 are present, each of which is assigned a separate line for protection purposes.

In the following, it is assumed by way of example that the protective devices of the power supply system each have a main protection function which, in the event of a fault on the own line, promptly generates a main trip signal for switching off the own line, if predetermined main protection tripping conditions are met.

In addition, it is assumed by way of example that the protective devices additionally each have a reserve protection function which is suitable in the event of an overload situation on the own line without fulfillment of the prescribed Main protection trip conditions delayed by a predetermined stagger time to generate a reserve trip signal to shut down the own line, provided that predetermined overload tripping conditions are met. For example, the overload trip conditions are less stringent than the main trip conditions. The backup protection function is intended, for example, to ensure that an overload situation is remedied, even if there is no "correct" fault situation on the own line, which is detected by the main contactor function.

The protective devices 14, 15, 16 and 17, for example, belong to the same switchgear 24 and are powered by the same station battery 25 with energy.

If there is now a short circuit in the section 10, for example in the line section between the protective devices 14 and 13, the main protective functions of these two protective devices 14 and 13 will be triggered and the fault will be switched off so that the remaining lines of the energy supply system 20 are in operation stay.

However, such an error scenario could also be different in an unfavorable case. Assuming, for example, that the station battery 25 has failed and at the same time a short circuit occurs between the protective devices 14 and 13, where the protective function of the protective device 14 would not trigger, as well as protective functions of the protective devices 15, 16 and 17, since these also be fed from the failed station battery 25.

Since the fault in FIG. 1 on the left side is thus not switched off, overloading of the lines assigned to the protective devices 10, 11 and 12 would possibly take place. tions, which may lead to the generation of reserve trip signals and to switch off these lines delayed after the predetermined stagger times, although the corresponding lines themselves are not faulty.

In a corresponding manner, protective devices 30 and 31 in adjacent sections 32 and 33 of the energy supply system would also be able to be triggered with a time delay, so that switching off several sections of the energy supply system 20 or even all sections of the energy supply system 20 may occur.

FIG. 2 shows an exemplary embodiment of a power supply system which is equipped with exemplary embodiments of protection devices 40 to 47 according to the invention. In contrast to the energy supply system according to FIG. 1, the protective devices 40 to 47 in the energy supply system 20 according to FIG. 2 are each provided with a communication device 70 with an antenna 71 (see FIG. 3) for communication with indirectly or immediately adjacent protective devices and equipped with a controller 72 connected to the communication device 70; An exemplary embodiment of the protective devices 40 to 47 is shown by way of example in FIG. 3. The communication devices can be wired, for example via networks such as the Internet, or wirelessly, for example via radio.

The control device 72 may have, for example, an input device 73 into which adjacent protective devices for defining one or more secondary protection zones can be input on the user side. Alternatively or additionally, the control device 72 may have a zoning function 74, which is based on predetermined topology data of the energy. gieversorgungsanlage 20 can determine one or more secondary protection zones automatically.

Also, the protection device may include a Zeitsynchronisiereinrichtung 75, which in comparison to the adjacent

Protective devices enables time-synchronous measurement of current measured values; in this case, the controller 72 is preferably connected to the time synchronizer 75 and is adapted to time synchronously receive the current readings of its own line to the neighboring protection devices.

The communication devices make it possible for the protective devices of each section of the energy supply system 20 to be able to communicate with one another and thus to form secondary protection zones defined by the protective devices. Thus, in the exemplary embodiment according to FIG. 2, the protective devices 40 to 47 form a secondary protection zone 50. In this example, the protective devices 45-47 function as internal protective devices, around which a closed outer shell 51 of the secondary protection zone 50 by the external protective devices 40 -43 is defined.

Each of the protective devices 40 to 47 now measures the current on its own line, preferably in a phase-selective manner, and generates corresponding current-indicator measured quantities that are transmitted to all other protective devices of the secondary protection zone 50. Thus, in each protection device, all information is present which allows each protection device individually and autonomously, according to the Kirchoffoff law, to determine whether or not there is an error within the secondary protection zone 50. For example, each protection device can form, with the correct sign, the current sum indicator Ig, which indicates the current flowing into the secondary protection zone 50, for example according to: Ig = I l + 12 + 13 + 14

In order to enable a corresponding formation of the current sum, the protective devices preferably measure their current measured values in a time-synchronized manner and provide their current measured values with corresponding time stamps. Time stamps of this kind can be obtained, for example, from GPS or other radio signals.

If this current sum Ig is greater than or greater than a predefined threshold value Imax, then the protective devices will respectively generate a reserve trigger signal as the first backup protection function, which switches off its own line. Switching off by the first backup protection function preferably takes place without delay, at least faster than time-staggered, other backup protection functions.

If there is now a short circuit on the line between the protective devices 44 and 43 and at the same time a failure of the station battery 25, then in contrast to the arrangement according to FIG. 1, the protective devices 40, 41 and 42 will switch off immediately, and indeed still before time-delayed or staggered working reserve protection functions of the other sections 32 or 33 of the power system 20 can respond and cause switching off further sections 32 or 33, which are themselves error-free.

In a corresponding manner, the protective devices of the two other sections 32 and 33 of the energy supply system 20 shown in FIG. 1 also preferably form secondary protection zones 60 and 61 which prevent cross-section triggering of protective devices of other sections of the energy supply system. FIG. 4 shows a further exemplary embodiment for protecting a power supply system 20. In this exemplary embodiment, the communication devices of the protective devices transmit their measured current values to a central device 100, which in the example according to FIG. 4 is formed by a centrally arranged monitoring device and which checks with the current measured values of directly or indirectly adjacent protective devices using the Kirchhoff law whether an error has occurred within the respective defined by the protective devices considered secondary protection zone. If this is the case, the lines of the corresponding secondary protection zone are switched off.

For example, the central device 100 forms secondary protection zones 50, 60 or 61, as have already been explained above in connection with FIG.

With particular preference, the central device 100 computes, with the received current measured values, a large number of secondary protection zones which may or may not overlap, and tests for each secondary protection zone formed in this way whether there is an error or not. It is considered to be particularly advantageous if the definition of the secondary protection zones in the central device 100 is staggered and starts with large secondary protection zones for coarse fault location and is continued successively with decreasing secondary protection zones until the fault location is determined by determining a smaller, preferably smallest possible, secondary protection zone has been identified with fault behavior. By such

Procedure can be achieved that in the event of an error as little as possible lines of the power system 20 are turned off.

Claims

claims 1. Protection device (40-47) for protecting a protective device associated with the electrical line, hereinafter called own line, a power system (20) with a main protection function in the event of an error on its own line in a timely manner a main trigger signal to switch off its own line generated, if predetermined main protection tripping conditions are met, characterized in that - That the protection device has a communication device (70) for communication with indirectly or immediately adjacent protection devices and a control device (72) connected to the communication device, and - that the control device for forming a backup protection function is configured such that it based on the transmitted current measured values (11-14) of adjacent protection devices, using Kirchoff law, can check whether an error has occurred within one or more secondary protection zones (50) defined by the neighboring protection devices, and that it can generate a back-up enable signal to shut off its own line an error has occurred within one of these secondary protection zones. 2. Protection device according to claim 1, characterized in that at least one of the secondary protection zones (50) with at least one inner protection device (44-47), which is completely contained within the secondary protection zone (50), and with at least one additional, electrically external protection device (40-43), thereby electrically surrounding the at least one inner protection device around a closed outer shell (51) of the secondary protection zone (50) is defined by the external protection devices. 3. Protection device according to one of the preceding claims, characterized in that the control device has an input device (73), can be entered in the user-side adjacent protective devices for establishing one or more secondary protection zones. 4. Protection device according to one of the preceding claims, characterized in that the control device has a zoning function (74), which can automatically determine one or more secondary protection zones (50, 60, 61) based on predetermined topology data of the energy supply system (20). 5. Protection device according to claim 4, characterized in that the zoning function (74) is designed such that an automatic formation of the secondary protection zones in dependence on the quality and / or the existence of a communication connection to the adjacent protective devices takes place. 6. Protective device according to one of the preceding claims, characterized in that the protective device also has a second reserve protection function, which differs from the first reserve protection function, which is suitable in the event of an overload situation on the own line without fulfillment of the predetermined main protection trip conditions a predetermined stagger time delays to generate a second reserve trip signal to shut down the own line, if predetermined overload tripping conditions are met. 7. Protection device according to claim 6, characterized in that the control device is designed such that it deactivates the second reserve protection function when the protective devices of the secondary protection zones is a communication link and their current measured values are received. 8. Protection device according to claim 6 or 7, characterized in that the control device is designed such that it activates the second reserve protection function when there is no communication connection to the protection devices of the secondary protection zones and no current measured values are received. 9. Protection device according to one of the preceding claims, characterized in that the control device is designed such that it operates the first backup protection function and the second backup protection function in parallel and during the stagger time of the second backup protection function based on the transmitted current readings of the protection devices of the secondary protection zones using the Kirchoffoff law checks whether an error has occurred within the secondary protection zones assigned to it and that it permanently or temporarily blocks generation of the second reserve trigger signal if it determines that an error has not occurred within any of its assigned secondary protection zones. 10. Protection device according to one of the preceding claims, characterized in that the protective device comprises a Zeitsynchronisiereinrichtung (75), which allows a relative to the neighboring protection devices time-synchronous measurement of the current measured values. 11. Protective device according to one of the preceding claims, characterized in that the control device is adapted to form pointer measurement values as current measured values. 12. Protection device according to claim 11, characterized in that the control device is suitable for measuring the pointer measurement quantities in accordance with IEEE Standard C37.118. 13. Protection device according to claim 11 or 12, characterized in that the control device is adapted to send their pointer measuring with the communication device to the neighboring protection devices, in particular via a wired or wireless telephone or data connection, for example via Ethernet or Internet. 14. Protective device according to one of the preceding claims, characterized in that the control device is suitable for phase-selectively measuring the current measured values of electrical phase conductors of its own line and for forming phase-selective current measured values. 15. A method for operating a protective device, in particular according to one of the preceding claims, characterized - That a secondary protection zone (50) with at least one inner protection device (44-47), which is completely contained within the secondary protection zone (50), and with at least one additional electrically external protection device (40-43) is formed, whereby electrically around the at least one inner protective device around a closed outer Sheath (51) of the secondary protection zone is defined by external protective equipment, and - That the secondary protection zone formed in this way is entered into a control device of the protective device. 16. Arrangement with a plurality of protective devices according to one of the preceding claims 1-14 for protecting a power supply system, wherein the protective devices form at least two to be monitored secondary protection zones (50, 60, 61). 17. Arrangement according to claim 16, characterized in that at least one of the protective devices belongs to at least two, preferably otherwise non-overlapping, secondary protection zones. 18. A method for protecting a given electrical line of a power supply system, wherein with a main protection function of a protective device in the event of a fault on the given line a main trigger signal for switching off the predetermined line is generated, if predetermined HauptSchutzauslösebedingungen are met, characterized in that with communication devices current readings indirectly or immediately adjacent other protection devices to a Central device (100) is checked with the Kirchhoffsehen law is checked whether an error has occurred within one or more defined by the neighboring protection devices secondary protection zones, and a first reserve trip signal for switching off the predetermined line is generated if such an error is present , 19. The method according to claim 18, characterized in that the control device of the protective device assigned to the predetermined line is used as the central device (100). 20. The method according to claim 18, characterized in that a centrally arranged monitoring device is used as the central device, which is in communication communication with the protective device associated with the predetermined line. 21. The method according to any one of the preceding claims 18-20, characterized in that the definition of the secondary protection zones takes place in the centrally arranged monitoring device. 22. The method according to any one of the preceding claims 18-21, characterized in that the definition of the secondary protection zones is staggered and begins with large secondary protection zones for coarse fault location and continues with smaller secondary protection zones until the fault location by determining a smaller, preferably the smallest possible, secondary protection zone has been identified with fault behavior.