WO2015028062A1 - Differential protection method and differential protection device for performing a differential protection method - Google Patents

Abstract

The invention relates to a differential protection method for producing an error signal that indicates an error for a primary component (11, 21) of an electrical power supply system, in which at least two different measurement points (11a-b, 22a-c) of the primary component (11, 21) of the electrical power supply system have respective measured current values sensed at them, the measured current values are used to form a differential current value by means of addition using the correct arithmetic sign, and the error signal is produced if the differential current value exceeds a prescribed threshold value. In order to indicate the least expensive way possible of performing a differential protection method as reliably as possible even when the measured current values are transmitted over comparatively long distances, it is proposed that, for each measurement point (11a-b, 22a-c), an additional check is performed to determine whether the profile of the measured current values sensed at that point in each case has a sudden change, and the error signal is formed only if firstly the differential current value exceeds the prescribed threshold value and secondly the profile of the measured current values at at least one of the measurement points (11a-b, 22a-c) has a sudden change. The invention also relates to a differential protection device of corresponding design.

Description

description

Differential protection method and differential protection device for performing a differential protection method

The invention relates to differential protection method for generating an error signal indicating a fault in an electrical energy supply network, in which at at least two different measuring points of a primary component of the electrical power supply network respectively

Current measured values are detected, with the current measured values by sign-correct addition, a difference current value is formed, and the error signal is generated when the difference ^¬ current value exceeds a predetermined threshold. The invention also relates to a corresponding electrical differential protection device for carrying out a Diffe ^¬ rentialschutzverfahrens.

Differential protection devices are used to monitor various primary components of electrical power supply networks, at ^¬ game as pipes, cables, bus bars and transformers. In this case, the current flowing to the current measuring point is detected at at least two different measuring points ^¬ union of monitored primary component and the differential protection unit supplied. The differential protection device forms by sign-correct addition of the current measured values differential current values, which are used to assess the Betriebssituati ^¬ on the monitored primary component. In the error-free case, the difference current values lie in a range close to zero, since, in simplified terms, the current flowing into the component flows completely out of it again. However, resulting differential current values below a zero threshold over ^¬, so let this operating condition to a faulty loading, for example, an internal short circuit, close. In this case, the present fault current must be interrupted by opening of the primary component limiting switching devices, such as circuit breakers. For this generates the Differential protection device a corresponding error signal that causes the switching device to open their switch contacts. In order to assess the operating situation of the primary component, current ^measured values of at least two different measuring points at the respective ends of the monitored primary component are therefore required. In the case of a primary component with ends lying close to one another, eg a transformer, the current measured values can be transmitted as analog or digital measured values over a comparatively short connection to a differential protection device.

From the German patent application DE 23 39 931 AI, for example, differential protection devices are known in which the current measured values are transmitted in the form of analog current signals via elec ^¬ tric connection lines to a differential protection device. The formation of the differential current value takes place via a current measuring transducer to which the current measured values are supplied in a suitable form.

In contrast, in the case of a primary component with ends that are far apart, for example a cable several kilometers in length, the current measured values must be transmitted over a longer distance. In such a case, a separa ^¬ tes differential protection device is typically disposed at each of the ends of the primary component, which forms the respective differential current value from its own (local detected) flow ^¬ measured values and the EMP collected from the other end of the primary component current measured values. Also, with a primary component having multiple ends, eg, a branched line, current readings from each of the ends are required to properly perform the differential protection procedure. For this purpose, the current ^measured values detected locally at the respective measuring points must be transmitted between the individual differential protection devices. European Patent Specification EP 1 071 961 B1 discloses a differential protection method for a multiple-end line, in which the current measured values are transmitted via data lines between differential protection devices arranged at the respective measuring points.

Particularly in the case of differential protection systems in which the current measured values have to be transmitted over longer transmission distances, there is the problem of the assignment of the locally measured values to the measured values recorded at the remote ends. For this purpose, the local and the received measured values must be timed in such a way that the measured values acquired at the same time are compared with each other. For example, if the respective transmission time of the measured values between the individual differential ^¬ protection devices is known, the respective time of data acquisition by the difference between the reception timing of the measurement data in the local Differentialschutzge can advises ^¬ and the known transmission time can be determined.

Problems arise here, for example, when the over ^¬ transfer time is not constant, or if the transmission time differences occur in forward and reverse directions. In addition, it may happen that the receiving time can not be determined correctly across systems by slow divergence of the local system times of the respective differential protection devices.

Such uncertainty in the temporal alignment of the local and the received measurement values, a Überfunk- can tion of the differential protection device be brought about a difference current value is formed at the correct sign addition does not belong together measured values, which sets an error with respect to the primary component, which did ^¬ plural nonexistent is. This may result in false triggers that affect the proper operation of the power grid. A remedy could be provided, for example, by synchronizing the internal timers of the differential protection devices with one another via an external timer system, for example by means of the time signal contained in the GPS signal. For this, however, special receiving systems, such as GPS receiver, in the differential protection devices are necessary, which have an increasing effect on the price of the device.

Another possibility is to carry out a rough plausibility check as to whether the expected transmission time matches the time of reception of the respective measured values. For example, if measurement values received significantly delay or early ge ^¬ genüber the expected time, it may rentialschutzgeräte to a disturbance of the temporal synchronization of the individual differential closed and the threshold value for

Evaluation of the differential current can be adjusted accordingly.

The invention has for its object to provide a possible kos ^¬ tengünstige way with which a differential protection method can be performed as reliably as possible even during the transmission of current readings over relatively long distances.

To solve this problem, a method of the type mentioned initially is so trained that is reviewed at ^¬ additionally for each measuring point whether the course of there each ER preconceived current measurements is cracked, and the error ^¬ signal is formed only if on the one hand, the difference current ^¬ value exceeds the predetermined threshold value, and on the other hand the course of the current measuring values comprising at least one of the measuring points a jump.

The inventive method an error signal can be only be produced with high reliabil ^¬ sigkeit when a threshold value is exceeded by the differential current value is in fact due to an error in the monitored primary component, while an induced solely by erroneous time measurement value approximation Threshold exceeded does not result in the delivery of an error signal.

The method according to the invention can be used particularly advantageously if the current measured values detected at the different measuring points are transmitted in the form of data telegrams via a communication network. For example, the communication network may be an IP-based communication network configured in any configuration. In particular, if the data ^¬ legramme be routed within the communication network over several network components, such as routers, switches or bridges, differences in transmission times may occur.

The difference current value can be compared for example with a ^¬ Pa as parameters fixed predetermined threshold. However, it is considered to be particularly advantageous if, to check whether the difference current value is the predetermined

Exceeds the threshold, also stabilizing values are formed from the current measured values of a ^¬ individual measuring points and is checked as part of a trigger area determining whether an image formed by reference to a differential current value and a respective associated stabilization value measurement-value pair in a predetermined tripping range, and detected an exceeding of the threshold value when the measured value pair is within the tripping range.

In practice, because that is the absence of ideal conditions and the differential current value does not becomes zero in the error-free case übli ^¬ cherweise exactly it is advisable to use ^¬ worth a suitable comparison for the differential current value. For this purpose, the so-called stabilization ^¬ approximate value is used, depending on the different component lent calculated. For example, the stabilizing value results in Leitungsdif ^¬ ferentialschutz as a sum of the amounts of the respective current measurements. The use of a Stabili ^¬ sierungswertes for differential protection is known. Plotting a differential current value and an associated Sta ^¬ bilisierungswert on in a trigger diagram, there is the particular pair of measured values either inside or outside ei ^¬ nes specified trip region, so that, by evaluating the position of the measurement value pair of a decision regarding the formation of the error signal can be made.: the Fehlersig ^¬ nal is then generated when the pair of measured values is within the predetermined trigger range. A further advantageous embodiment of the invention ^shown SEN method provides that for checking whether the profile of the measured current values includes a jump on ^¬ at a measuring point, the difference between an actual measured current value and a an integer number N of periods earlier detected current measured value is formed, and the presence of a jump in the current profile is detected when this difference exceeds a pre ^¬ given jump threshold.

As a result, a comparatively simple criterion is specified with which a jump in the course of the current measured values can be established. For example, the parameter N may assume the value 2, in which case a jump would be detected if the difference ΔΙ from the current current measurement value I (t) and the current measurement value I (t-2T) previously recorded two periods ago exceeds the jump threshold value :

ΔΙ = I (t) I (t-2T).

The jump threshold S _Sp tion for example, can be set in depen ^¬ dependence of the approach for evaluating the differential current value ^¬ drawn threshold S _D iff, beispielswei ^¬ se can apply the following relationship for the jump threshold S _Sp tion:

³ jump 0.75 S diff.

Of course, other definitions are possible within the scope of the invention, and the jump threshold as Independent parameter regardless of the threshold S _D i _{ff be} set.

According to a further advantageous embodiment of the inventive method can also be provided that the result of checking a present leap in the course of the current measurement values in the form of a jump indicator ge ^¬ is jointly transmitted with the respective current measured value. This ensures that the jump indicator a ^¬ hits always on time when evaluating differential protection device, namely simultaneously with the ^¬ rence current value to be evaluated each for the Diffe current reading. In the case of transmission of the current measurement values in the form of data messages via a communications network on the one hand, the respective current measured value and on the other hand, the skip indicator ^¬ thus be transmitted in the same data telegram. The jump indicator can consist of a single bit (value 1 or 0) that indicates whether a jump has been detected (eg value 1) or whether the curve has no jump (eg value 0).

According to a further advantageous embodiment of the method according to the invention can also be provided that in the event that a threshold border differ- ence current value, but not a jump in the current profile is present ^¬, a warning signal is generated.

This warning signal can, for example, cause the generation of a warning message which causes the operator of the differential protection device to encounter problems with the transmission time of the differential protection device

Current readings and / or an inaccurate time synchronization of the individual differential protection devices indicates so that it can trigger appropriate maintenance activities. However, the warning signal can also be used, for example, to cause an automatic time alignment of all differential protection devices with a master time signal to restore a ge ^¬ exact time synchronization of the individual differential protection devices with each other. The above object is also achieved by a differential ^¬ apparatus for generating an error signal indicative of a Def ^¬ ler in an electrical power supply network, Ge dissolves, said differential protection device is arranged to at a measuring point of a primary component of the electrical ^¬'s power supply network current values detect, with their own current measuring values and the current measurement values at least one further at another measuring point of the primary märkomponente disposed differential protection device by sign-adding a differential current value to bil ^¬, and to generate the error signal when the differential current exceeds a predetermined threshold value, According to the invention, in that the differential protection device is also set up to receive the current measured values detected by the at least one further differential protection device, to check whether the course of the own current measured values or the course the current measured values of the at least one further differential protection device has a jump on ^¬, and only then to form the error signal when a ^¬ hand, the differential current value exceeds the predetermined threshold value and on the other hand, at least one of the characteristics of the current measuring values comprising a jump.

With regard to the advantages of the differential protection device according to the invention, reference is made to the advantages described for the method according to the invention. The Diffe ^¬ rentialschutzgerät invention is also set up to carry out any embodiment of the method according to the invention, so that everything can be obtained tialschutzgerät to the process is said also to the differentiation.

The invention will be explained in more detail below with reference to an exemplary embodiment. Show this

Figure 1 is a schematic view of one of two

Differential protection devices monitored Power supply line of an electrical power supply network;

Figure 2 is a schematic view of a mehrendi ^¬ gen monitored by differential protection devices power supply line; and a logic diagram for explaining an algorithm for generating an error signal.

FIG. 1 shows a part 10 of an electrical energy supply network (not further described in the following). In the section 10, a primary component 11 is arranged, which may be, for example, a three-phase electrical free ^¬ line of the electrical energy supply network. The primary component 11 is monitored at its first end IIa means of a first differential protection device 12a and ih ^¬ rem second end IIb means of a second differential protection device 12b. For this purpose, for each phase 13a, 13b, 13c of the primary component 11 with first current ^{wall ¬} learning 14a at a first measuring point at the first end IIa of the primary component 11 and second current transformers 15a, 15b and 15c at a second measuring point at the second end IIb of the primary component 11 current signals recorded. Digital current measurement values are generated from the analo ^¬ gen current signals. The measured current values can be embodied, for example, as current- ^indicator measured values which indicate an indication of the amplitude and phase angle of the current signal at the time of detection. The determination of digital current measured values can be done either in the

Current transformers themselves, in the differential protection devices 12a, 12b or in a suitable measuring device, such as a Phasor Measurement Unit (PMU), a Remote Terminal Unit (RTU) or a merging unit done. Finally, the generated current measured values are fed to a data processing device, for example a CPU or a signal processor of the respective differential protection device 12a, 12b. The differential protection devices 12a and 12b are connected to one another by a communication connection 16, which is indicated only schematically in FIG. 1, and may be, for example, an IP-based communication network. However, any other communication link of any desired type for connecting the differential protection devices can 12a and 12b are turned ^¬ sets. Over this communication link 16 to the respective other differential protection device 12a and 12b, the separate power measurements are made available, that is, it can in each differential protection device 12a and 12b, respectively for each stage 13a, 13b, 13c of the protected object 11 depending ^¬ weils pairs of Both ends IIa and IIb recorded current readings are formed. Based on available in both differential protection devices 12a and 12b measured current values from both ends of IIa and IIb of the primary component 11 can be in one or differential ^¬ arresters both 12a and 12b by means of a data processing ^¬ means a difference between the amounts of current values for each phase (or a correct sign sum ) are formed as difference ^¬ current value and compared with a threshold.

For error-free primary component 11 of the current per phase entering into the protected object 11 is equal to the emerging from the protection ^¬ object 11 current, so that the difference of the sums of the power values (or their correct sign sum) the value should take zero. Speeds due to Wandlerungenauig-, measurement errors, accurate time synchronization of the differential rentialschutzgeräte 12a, 12b and transmission time differences ^¬ durable exactly in the transmission of the measured current values to the respective walls ^¬ ren differential protection device 12a, 12b takes the difference ^¬ current value in the error-free case, however, virtually never the Value zero, but is instead below a predetermined threshold. This smoldering ^¬ lenwert can either statically or dynamically, adapted for example to the height of the respective phase currents are determined. The threshold can be set as a separate parameter. However, it can also be provided a threshold crossing by evaluating the position of a measured value from the couple's differential current value and an associated Sta ^¬ bilisierungswert to consider in a release chart. For this purpose, are tested from mating, ie simultaneously detected, current measurement values formed differential current values and associated Stabili ^¬ sierungswerte and the location of the current value of a difference and a stabilizing existing value Measured value ^¬ pair in the operation diagram. If the measured value pair within a trigger range, is out of the monitored ^¬ simple primary component closed on a fault and generates the error signal.

Exceeds a certain phase of the differential current value exceeds the predetermined threshold, this indicates a Feh ^¬ ler with regard to the respective phase of the primary component 11, which is for example, a ground fault or a two- or multi-pole short circuit, ie a short circuit between two or can act more phases of Primärkompo ^¬ component. For the phase in which the fault has been detected, the differential protection devices 12a and 12b via control lines 17a, 17b from a corresponding Aus ^¬ release signal to phase-selectively switchable power switches 18 and 19, whereby the corresponding phase-related Leis ^¬ tion switch 18a, 18b, 18c or 19a, 19b, 19c is caused to open its switch contacts and the affected by the error phase 13a, 13b, 13c separated from the rest of Energieversor ^¬ supply network.

Is, for example, on the phase 13b, a ground fault is present, detect the differential protection devices 12a and 12b this Toggle handle of each threshold exceeded Diffe ^¬ rence current value and provide trigger signals to the phase claim related ^¬ NEN power switch 18b and 19b, respectively from, the phase 13b of the Separate primary component 11 from the power grid.

Although a three-phase primary component 11 is shown with only two ends IIa or IIb of Figure 1, which he ^¬ find new method can be used with several branches, also at any single or multiphase primary components with two or more ends, such as electrical bus bars.

Figure 2 shows a part 20 of an electrical power supply system with a Primärkompo ^¬ component in the form of a bus bar 21 with a branch 21 in a schematic view. For better clarity has been dispensed with the presentation of further outgoing from the busbar 21 branches. In addition, a single-phase representation has been chosen for the sake of simplicity; however, the bus bar 21 itself may have any number of phase conductors (eg, three).

The busbar 21 has in each case a measuring point 22a, 22b, 22c in the region of its ends and is delimited at each end by a respective power switch 23a, 23b, 23c. At the measuring points 22a, 22b, 22c secondary currents are detected with only schematically indicated current transformers and differential protection devices 24a, 24b, 24c supplied. These detect the secondary currents in the form of current ^measured values and use these current measured values to form a differential current value and possibly also a stabilization value. In addition exceeds the differential protection devices 24a-c ^¬ average the own current measured values via a communication link 25, which may be exemplified by a communications network with a ring structure, to the respective other Differentialschutzgerä ^¬ te. The differential protection devices communicate with the communication link 25 via network components 26a, 26b and 26c, which may, for example, be network switches. The measured current values received by the respective differential protection devices are added to the own current measured values used to form the difference current value and possibly a stabilization value. Using the respective differential current values, one or more of the differential protection devices 24a-c makes a decision as to whether or not there is an error with respect to the busbar 21 and, if necessary, generates an error signal.

Both in the exemplary embodiment according to FIG. 1 and in that according to FIG. 2, inaccurate time synchronization of the internal timers of the differential protection devices and / or different transmission times of the current measured values between the differential protection devices can lead to overfunctioning of the differential protection, ie recognizing one or more differential protection devices despite the error-free primary component, a significant differential current value and accordingly generate an error signal for triggering the respective circuit breaker. The erroneous calculation of the differential current value results in this case from the fact that current measuring values from different measuring points are used for its calculation, but that do not belong to one another in terms of time. Since such an overfunction should be avoided if possible, measures must be taken to stabilize the differential protection algorithm. Here ^¬ to indeed could be the size of the current value for evaluating the difference heranzuziehenden threshold value or the Auslö ^¬ sebereiches be adjusted accordingly, but this comes at the expense of sensitivity at a real vorlie ^¬ constricting error. Therefore, in connection with FIG. 3, an algorithm will be described with which simple means can be used to make a reliable distinction of a differential current value indicating an actual error from such difference current values which have been erroneously calculated on account of the above-mentioned effects. For this purpose, information about this is evaluated in addition to the differential current value whether the current profile having on one of the measuring points ^¬ a sharp curve. If such an erratic course with respect to at least one of the measuring points can be seen, it is based on an actually present Error detected, otherwise a faulty calculated differential current value is assumed.

In Figure 3, this purpose is shown overall showing the running in a differential protection device algorithm, a schematic logic circuit diagram, it being assumed that a differentiation ^¬ tialschutzsystem consists of three differential protection devices. The described method can be easily adapted to any number of differential protection devices. The algorithm shown in FIG. 3 is usually used in

Implemented form of a device software in the respective Differentialschutzge ^¬ advises.

In a first block 30a via a measuring device of the differential protection device, a local measured current value I _A ^¬ be placed riding. A local current reading is one such

Ammeter measured at the measuring point to which the differential protection device in question is assigned. In further blocks 30b and 30c, such current measured values I _B and I _c are provided which have been recorded by differential measuring devices arranged at remote measuring points and have been transmitted to the local differential protection device. The local measured current value I _A and the current measurement values ^¬ I _B and I _c can be determined, for example like in the form of Stromzei-.

Thus, the same algorithm can also occur in the other differential ^¬ protection devices, the algorithm in block 31 to own current reading for shipment to other dif- ferentialschutzgeräte available. The provided

Current ^measured value, for example via a communication interface of the differential protection device to the Kommunikationsverbin ^¬ tion, eg a communication network, are submitted. For this purpose, the current measured value can be converted into the form of a data telegram, for example, which is subsequently transmitted. In block 32, a differential current value Ion _{f is} calculated from the own current measured value I _A and the received associated current measured values I _B and I _{c of} the other differential protection devices by sign-correct addition and transmitted to block 33.

In block 33, this difference current value Ion _{f is} compared with a threshold value S _D i _ff . As already mentioned, the ^¬ ser Schwellenwertverglich with a fixed may

Threshold or a dynamically adjusted threshold. The dynamically adjusted threshold value can be derived, for example, based on the position of a measured value pair formed from differential current and stabilizing current in a triggering diagram. If it is determined a threshold violation in block 33, ie the difference exceeds ^¬ current value Ioi _ff the threshold value S _D i _ff, a entspre ^¬ and fair output signal is supplied to one input of an AND gate 34th The provided in block 30a measured current value I _A is white ^¬ terhin used to the course of the local power measurement ^¬ values with respect to a possible current jump to investi ^¬ chen. If such a current jump occurs simultaneously with a significant difference current value, this indicates a spontaneously increasing current flow (eg resulting from a fault current) and thus an actually present error in the monitored primary component. To test for a current jump, the measured current value I _{A is} also fed to a block 35, which executes a jump detector. For this purpose, the current local current measured value can be compared, for example by subtraction, with a local current measured value previously recorded of an integer number N (N = 1... N) of period durations: ΔΙ = I (t) -I (tN * T).

If this difference lies above a predetermined threshold value S spmng, then one in the course of the local Current readings existing current jump detected and delivered a ent ^¬ speaking signal in the form of a jump indicator J _A to a first input of an OR gate 36. For example, the jump indicator may be a binary value indicating whether there is a jump (J _A = 1) or not (J _A = 0). In addition, the jump indicator J _{A is} also provided in a block 37 for shipment to the other differential protection devices. The transmission can take place, since ^¬ tentelegramms for example, within the same, with which also the current local measured current value I _A is transmitted.

Similarly, jump indicators J _B and J _{c of} the other differential protection devices are determined, transmitted to the local differential protection device and provided there in blocks 38a and 38b. The jump indicators J _B and J _{c of} the other differential protection devices are supplied to the other inputs of the OR gate 36.

The OR element 36 generates an output signal if at least one of the input-side applied jump indicators J _A- Jc indicates a current jump, ie if a current jump has been detected in the course of the respective current measurement values at at least one measuring point of the monitored primary component. The output signal generated by the OR gate 36 is supplied to the other input of the AND gate 34.

The AND gate 34 generates an output signal in the form of an error signal F indicating an error with respect to the primary component, if both the difference current value I onf exceeds the threshold value S _D iff at the same time and a jump in the course of the at least one measurement point of the primary component Current measured ^values recognized wor ^¬ is. In this way it can be achieved that in the presence ei ^¬ nes the threshold value S _D i _ff border differential current value i ^¬ _ü i _{ff /} but as in the absence of surge detection at least one measuring point of the primary component no error signal is generated, whereby the differential protection algorithm is stabilized against erroneous calculations of the differential current value, which are based on an inaccurate time synchronization of the differential protection devices and / or different transmission periods of the current measured values between the differential protection devices.

Optional can also be provided that in the event that at block 33, a threshold border difference is detected current value, but not a jump in the stream ^¬ extending at least one present at the measuring points, a warning signal is generated. This warning signal can beispielswei ^¬ se cause the generation of a warning message, the transfer time the operator of the differential protection device to problems with the excess of the current measurement values and / or indicative of an inaccurate time synchronization of the individual differential protection devices, making this appropriate maintenance procedures can hit ^¬. But the warning signal, for example, also there are ^¬ to use, start an automatic time synchronization of all differential protection devices with a master clock signal to ver ^¬ to restore an exact time synchronization of the individual differential protection devices together.

The option described last is not shown in FIG. 3 for the sake of clarity.

Claims

claims

A differential protection method for generating an error signal indicative of an error with respect to a primary component (11, 21) of an electrical power supply network, in which

- at least two different measuring points (lla-b, 22a-c) of the primary component (11. 21) of the electrical Ener ^¬ gieversorgungsnetzes each current measurement values are recorded, - with the current measurement values, a differential current value is formed by sign-addition, and

 the error signal is generated when the difference current value exceeds a predetermined threshold value,

d a d u r c h e c e n c i n e s that

- for each measuring point (lla-b, 22a-c) is additionally checks whether the profile of the current measurement values respectively detected ^¬ there comprises a jump; and

 - The error signal is formed only if on the one hand the

 Difference current value exceeds the predetermined threshold and on the other hand, the course of the current measurement values at at least one of the measuring points (lla-b, 22a-c) has a jump.

2. Differential protection method according to claim 1,

d a d u r c h e c e n c i n e s that

 - The measured at the different measuring points (lla-b, 22a-c) measured current values are transmitted in the form of data telegrams via a communication network.

3. The differential protection method according to claim 1 or 2, characterized in that:

to check whether the difference current value exceeds the predetermined threshold value, stabilization values are also formed from the current measured values of the individual measuring points (11a-b, 22a-c) and checked in the context of a trigger range check, whether a differential current value is used and each belonging to stabilization value formed measured value pair is in a predetermined tripping range, and

 an exceeding of the threshold value is detected if the measured value pair lies within the tripping range.

4. Differential protection method according to one of the preceding claims,

d a d u r c h e c e n c i n e s that

- to check whether the profile of the measured current values (lla-b, 22a-c) having a crack at a measuring point, the Diffe ^¬ ence is formed from a current measured current value and a an integer number N measured current value previously detected by periods; and

 - The presence of a jump in the current waveform is detected when this difference exceeds a predetermined jump threshold.

5. Differential protection method according to one of the preceding claims,

d a d u r c h e c e n c i n e s that

- The result of checking for an existing jump in the course of the current measured ^values in the form of a jump index ^¬ tors is transmitted together with the respective current reading.

6. Differential protection method according to one of the preceding claims,

d a d u r c h e c e n c i n e s that

 - In the event that a Threshold exceeding difference current value, but not a jump in the current waveform, a warning signal is generated.

7. A differential protection device (12a-b, 24a-c) for generating an error signal indicating an error with respect to a Primärkomp- component (11, 21) of an electric power network, wherein

- (, 24a-c 12a-b) is turned to the rich ^¬ tet differential protection device, at a measurement point (lla-b, 22a-c) of the Primärkom- component (11, 21) of the electrical energy supply network to detect current measured values, with its own current measured values and the current measured values of at least one further differential protection device (12a-b) arranged at another measuring point (11a-b, 22a-c) of the primary component (11, 21). to form 24a-c) by addition with the correct sign a difference current value, and to generate the error signal if the difference current value exceeds a predetermined threshold value over ^¬,

d a d u r c h e c e n c i n e s that

- the differential protection device (24a-c 12a-b) is also introduced ^¬ directed to (12a-b 24a-c) to receive from the at least one further differential protection device current measured values detected;

- The differential protection device (12a-b, 24a-c) is set to tet ^¬ check whether the course of their own current readings or the course of current readings of at least one other differential protection device (12a-b, 24a-c) ei ^¬ nen jump having; and

- The differential protection device (12a-b, 24a-c) to be incorporated rich ^¬ tet, to form the error signal only when a ^¬ hand, the differential current value exceeds the predetermined threshold value and on the other hand, at least one of the characteristics of the current measuring values comprising a jump.