DE10151319A1 - Protection for electrical supply systems by directional comparison, involves isolating defect points in very small sections of sound network independently of network operating method - Google Patents

Abstract

The method involves isolating defect points in very small sections of sound network independently of the method of operation of the meshed network. Transformers can also be included in this protection system. Protection is guaranteed for a network containing a so-called tripod arrangement or an arrangement with a greater number of legs. Independent claims are also included for the following: a circuit for directional comparison wear protection.

Description

Technical field

Electrical power supply networks are provided with protective devices to prevent one Failure to limit the destructive effects at the short circuit point.

The present invention relates to a protective method and a protective device suitable is a meshed medium voltage or higher or higher in the voltage level to protect the underlying network selectively.

In particular, this protection is the one aimed at known ones offered by the market UMZ relays can also be equipped to accommodate a so-called tripod protect. A tripod or multi-leg in the sense of four and more is usually used operated when supply tasks are to be performed without a complete The electrical switchgear is equipped for space or cost reasons must be dispensed with, or an additional primary connection to be laid separately should. In the main, the method and the device can be applied to the protected objects Use the line and busbar in the meshed network.

In many cases there are also defects with this version of the protection system faulty transformers can be switched off.

The usual, used to realize the supply of consumers with electrical energy Supply network operated with open rings, can be integrated with little effort Transfer a higher quality mesh with a multi-leg version if the Protection requirements are given. A meshed network offers consumers of Electrical energy higher security of supply with less investment, and the Tension stability even in the presence of extreme load fluctuations is not endangered.

Known technology

The well-known method of time grading is used in ring networks and two-sided networks applied with the help of the energy direction. With separate signal wires Direction of the short circuit as seen from the installation location of the converter, and from the Protection relay manufacturers referred to as signal comparison.

In the case of meshed networks, distance protection is also used as an additional protection criterion. The state of the art in the field of protection offers extensive technical literature, where the following should be listed as representative of the overall scope:
Clemens-Rothe, protection technology in electrical energy systems: Verlag Technik GmbH, Berlin 1991
Protection and station control technology: Lectures of the ETG conference on March 3rd and 4th, 1998 in Dresden: VDE-Verlag, 1998 (EGT technical report; 71)

The international and German patent specifications, e.g. B. DE 694 13 067 T2, 24 03 903, 26 02 805 show the differentiated sub-areas of protection, mainly from the Patent classification H02h can be found.

One component of the invention is the interrogation system of the protective devices among one another Auxiliary signal lines that can be laid on different routes in the ground than that Primary cable z. B. the medium voltage level. Here is the same patent classification H02 h priority, and representative are the patents DE 35 37 072 A1; and DE 44 09 880 A1 called.

In practice, the protection criteria listed lead to disadvantages. There are too high Protection tripping times, and the protective structure becomes too confusing. With distance protection  there is also the fact that with short cable runs, impedance evaluation also with digital ones Relay is not possible.

Overall, such a protection concept, equipped with the known protection criteria, a complicated protection structure, so that in practice such concepts are hardly used Application because problems arise in the operation of the network, which with a simple protective structure is not available. For this reason, the networks in usually operated with so-called open rings.

The invention shows a protection system which is able with simple means, also with a meshed network To protect tripod assemblies. With the application of the invention, the design of protection clearly, so that the network operator has the advantages of a meshed network compared to a ring network with an open driving style.

The direction comparison query protection according to the invention (RVa protection) points towards the conventional protection differences, which are explained below. From the Word choice RVa protection should show that not only the short-circuit direction as Protection criterion is compared, but other queries are also used. First in the evaluation of all protection criteria by means of information evaluation of the data the fault location is separated from the remote site, resulting in said simple location Protective structure with good results.

Further comments

Mesh networks, or also ring networks fed on two sides, are known to be structured in such a way that when errors occur, the fault location is switched off on both sides without a Power is interrupted on the busbars of the feeding stations. That offers the advantage that if a cable fault occurs in the network, the Elt supply to the Consumer continues uninterrupted. Energy interruptions are reduced then only on the rare cases of busbar faults and errors, which in connection with the infeed from the higher voltage level in the Related.

For normal operation, they also offer the advantage that one in network nodes high short-circuit power which guarantees high withdrawals without impermissible To allow voltage drops.

It is to operate a meshed medium-voltage network (sub-network of an urban area) advantageous, a uniform protection tripping time for both protection throughout the network the cable and power cable sets, as well as for the branch lines or To ensure busbar systems. The uniform protection period Directional comparison protection time (RV time) is still different depending on the staggering Reserve protection times assigned. From the explanations it can be seen that the realization protection of the meshed network by means of directional overcurrent protection becomes. Distance relays are becoming increasingly common for the protection of directional UMZ Tasks used with the aim of better localizing the fault location in the event of a fault can.

Using four-wire control wire connections between the respective neighboring stations are set up, the directional overcurrent protection receives the information about the fault location in the Way, whether the fault points in the direction of the cable, or the busbar, and whether furthermore the fault inside or outside the protected area with the cable accordingly associated equipment.

The term protection zone outside of DIN VDE 0435 part 110 would also be here Protection section applicable, however, a conceptual definition is due to the special and extended view not possible. In particular, the different range goes beyond of reserve protection the concrete definition.  

To ensure RVa protection, information is exchanged via a Twin wire as the transmission line, and via the second twin wire as the receiving line. in the In contrast to the general system of signal comparison, the division with RV protection the tasks in sending and receiving on separate transmission lines made because of this division of the busbar protection even in RV time, which in Network can be realized with an advantageous time of 0.5 s. For this it is necessary in to install a query rail at the respective stations. This is the rail Information provided, "one or more outlets of the station are in the direction of the cable short-circuit current-carrying, or the short-circuit point is located Busbar area ". In other words, a current direction comparison in the respective busbar section by means of directional overcurrent protection over the Query rail made, and depending on the fault location, the associated protection area determined.

Such a query offers the great advantage that busbars are usually connected to the conventional directional UMZ protection can be connected. In many cases according to the busbar protection, designed as a differential protection. This becomes possible because the feeding cable is included in the protective section, and thus the required Provides impedance up to the short circuit point that the relay needs for the direction decision. This also ensures protection if the protective devices without pre-fault voltage To protect the object.

The general function of the RV protection is such that in the event of a cable fault, the two Exchange the neighboring protection relays the directional information, evaluate it and close it come to the conclusion, "we have to switch off the fault by switching off the active one Detach net ".

At the same time, they deliver the opposite of the short-circuit feed direction to the feed point Information that the fault lies with you and everyone else in the short circuit lying relays have to pass this due to non-responsibility. Here, too Difference to the signal comparison visible. This will be in each one Protection area only checked the two states, whether the responsibility condition yes or no is satisfied.

In the event of a busbar fault, the information content of the query bus ensures that the feed switches of the respective neighboring stations switch off the short circuit at the RV time. Contrary to the short-circuit feed direction, the relay lying in the current path is also here the information is supplied, the short circuit is to be passed through without switching off.

Strictly speaking, the information evaluation for the short circuit to be carried out Areas as follows: The switch-off command is given either after the expiry of the respective Relay set reserve time, so that if necessary the task of reserve protection is to be fulfilled or the switch-off time is ∞ because a reserve protection time is not provided. The time step ∞ is only a conceptual variable that is functional in the protective relay superscript times can be parameterized, but is not used here. In the practical implementation becomes the timing element ∞ or better the concrete one Trigger mechanism brought about by the remote station via the send contact. At the the other primary cable end is switched on by means of the circuit breaker tripping circuit Contact looped into the controller to make the decision about the To get the trigger condition yes or no.

In the event of a cable fault, the trigger condition arises directly between the both primary cable ends or the circuit breaker pair. When there is a busbar fault the trigger condition is automatically due to the peculiarity of the RVA protection system extended protection area.

As usual, the RVa apron is superior to reserve protection in the event that due to an error e.g. B. in the control cable network, the RV time exceeded without switching off  and cannot contribute to troubleshooting. This reserve protection is with the known selective protection and by means of time graduation and additional use of Energy direction realized.

The passage of information from the now known fault location to the relays in the direction of the dining point can be subject to race phenomena. It is the case that the relays pick up at the fault location with the RV time. After the RV-0.5 s time has elapsed, they provide two pieces of information.

• 1. Initiate circuit breaker tripping.
• 2. To inform the relays located in the guideway current path that the Reserve protection time or tripping time of ∞ is to be canceled.

As a rule, the information in point 2 reaches the neighboring relays faster than the elimination the short-circuit current excitation. This fact can be explained by the inherent time of the Medium-voltage circuit breakers.

The neighboring relay or relays receive the information after 0.5 s that they are in RV time should work even though the short-circuit current is still present. The digital relays can be found under Circumstances may be so fast that your newly created command has an undesirable effect arrives. You would then trigger a sympathy. Such an event will According to the invention by means of timers that determine the decision of the race or Put sympathy on the right track, switched off.

information transfer

The RVa protection requires an exchange of information within to function the associated variable protection area. Already in the list of patent specifications The indicated manifold possibilities of information transfer are all applicable because information is transmitted via the auxiliary wire connection if an error occurs and to transmit one word with only one bit word width for fault shutdown is. The requirements regarding the transmission speed depend on the Protection tripping time. With RV time t = 0.5 s, the requirements are low, so that the different bus systems meet the requirements as well as a direct one Evaluation of the information by a relay circuit. With regard to monitoring the The signal in the responsible control center proves itself through information connections, To provide "Information transmission disrupted yes or no".

Because of the rush rate of the network control technology in the context of operating the electrical energy networks there are usually good opportunities, the necessary information transfer between the protection stations.

tripod

Often, power requirements arise during the construction of new buildings. B. on Foothills that can be inexpensively reinforced by adding to an existing one Exit a second one coming from a neighboring station of the mesh network Power cable clamped, so a tripod is realized. Also around There is the possibility to save shaft work by using so-called T-sleeves on suitable ones Realizing jobs. With overhead lines, the possibilities are very often used in Terrain to form network nodes.

The protection of such a network is advantageous to include in the meshing if it is equipped with the principle of three-leg comparison protection. Such a variant should be shown here.  

Embodiment fault location within the tripod

The conditions of the RV protection function tripod are first to be explained generally with the aid of Figure 1.

The starting point is a meshed network, of which 6 stations are shown. The cable is clamped in station B and forms a tripod for stations B, C and E. The short circuit is assumed in cable BE. Assuming that all circuit breakers of the stations are switched on, the RV protection reacts after a short circuit in this subnetwork according to Table 1. Table 1 and Figure 1 express the same technical facts with a different representation. The respective short-circuit energy directions are identified by the arrows in the cable connections.

The prevention of triggering is marked with a crossed yes in Figure 1 because the directional protection stimulates triggering. The three trips are prevented as follows: Switch AB by applying voltage to query rail B through relay BC, BE. The prevention of tripping of the other two switches is shown in Figure 1 using the arrow & no signal path. In the entire short-circuit network, tripping prevention works according to this principle.

On the expansion of Table 1 with regard to the creation of protective functions when z. B. the switch BC, BE was switched off before the short circuit occurred, should be omitted here.

The case is still interesting if the short-circuit point occurs in the busbar area as shown in Figure 2. The starting point is again a meshed network, shown with 7 stations, with all circuit breakers switched on.

The short circuit occurs in station C and the RV protection reacts according to Table 2 or Figure 2.

The mechanism of trip prevention is with the automatism already described identical.

The specific hardware embodiment of the RV protection z. B. for the illustrated tripod is shown in Figure 3. All three stations of the tripod are connected with 2 double wires in the ring. The logical functions required for this can be configured in the relay. The circuit is shown as an example with one PS 482 24 T basic equipment per station.

It is also possible to implement such an application that a customer of the Busbar receives energy that requires a longer protection tripping time than the RVa time. For this purpose, the customer can be connected to the query rail with his UMZ relay so that it fulfills its wishes for a longer release time with the condition can be that the upstream network can withstand the additional thermal conditions is. The customer also has the option of realizing a second infeed, and mesh them as described in the script. So he achieves a stable Busbar, and can do without complex switching devices.

Explanations of the circuit diagram RVa protection according to Figure 3

The short-circuit location is located on the cable route BE according to Figure 1. The functionality is preferably shown using the relays belonging to the switches BC, BE: CB and EF.

The connection of the compensating rail can be seen from the stations B, C and E belonging to the tripod. When the short circuit occurs, the fault is recognized by all three relays in the forward direction. The normally open contacts of the k 52.1 establish the connection 6 to 7, and the interrogation rails become live. The positive pole of your own station is connected to the query track. The contacts k 52.1 of the switches CD, BA and EF which feed the short circuit, but which are respectively in front of the busbar, remain in the switch position shown for short-circuit protection in the event of a short circuit. Your U 52 thus get high signal L and the contacts k 51.1 and k 51.2 within the tripod configuration BC / BE, CB and EB are opened. This information is sent to the remote stations DC, AB and FE, whereupon these relays occupy their switches with a switch-off block in RV time. The contacts of the k 51.1 and k 51.2 each remain closed since U 52 is in the low state. This situation leads to tripping in RVa time for all three switches, which can be read from the logic diagram in Figure 5 or can be verified with a relay test.

Embodiment transmission of the short circuit

On the basis of Figures 1 and 2 and the short-circuit points marked therein, it can also be seen in the following manner that switches have to conduct the short-circuit current even after the RVa time has elapsed. The short-circuit energy direction corresponds to the arrow mark and extends from A to B. It is here RVa-time does not disable the switch pair AB, BA in its functioning, the short circuit current after the expiration of are considered with reference to the image. 4 The protection relay of the switch BC, BE detects the forward direction so that the k 52.1 closes and transfers the + potential via contact 7 to contact 6. Since the relay of the switch BA sees the error in the reverse direction, the + potential of BC, BE is transmitted in this over the interrogation rail to k 52 (5), and is forwarded to U 52 for the purpose of establishing the send pass condition. K 51.1 (BA) opens, and U 51 (9) AB receives the resulting low signal. The logic processes this information into a blockage of the execution of the trigger after the RVa time, which can be seen in Tables 1 and 2. In picture 1 and 2 this blockage is marked with the crossed out yes. The mechanism shown in Figure 4 is an explanatory representation that must still be stored in the relay in the form of a configuration which is described in more detail in the details. The user can do this himself, because the relay manufacturer has created the conditions for this with the internal processor programming.

The trigger prevention described acts on the same mechanism Remote station from A entrance. Because a meshed network is protected, everyone is The supply switch is blocked as described, without the to the feed point of the network Information transmission from the short circuit point must be passed through, because this begins on the query rail of the respective supply switch, and then becomes Remote site forwarded. The events in the overall primary circuit and those in parallel ongoing information processes in the protection pairs enable sufficient stability when implementing short command times. The advantage of such a query is that simultaneous implementation of busbar protection in the distribution network. With the This circuit is always checked whether there is one from the busbar current flowing away. If so, the short circuit is not in the Busbar area. The reliability of this information is high because in As part of the short-circuit direction determination at least two primary cable impedances Query can be consulted. The dead zone in the short-circuit direction determination leads therefore no problems.

If a reserve protection time has been parameterized in the relay, the designated one runs Time step at the beginning of the short-circuit occurrence. The one following the expired Reserve time starting trigger mechanism that the relay in connection with the Query of the short-circuit direction initiated no longer depends on the information content of the Counterpart, or an information defect.

The expiry of timers of the reserve protection is rarely registered, which is a indicates sufficient stability of the protection system.  

Explanations for the RVa protection circuit diagram Fig. 4

The switch and relay pair AB and BA shown should be shown as a representative for all existing switch pairs, on which the functional mechanism is repeated in the correct manner. The RVa protection Fig. 4 differs from the tripod arrangement Fig. 3 only in the contacts and logic arrangements of send and receive that have been carried out once. For all other elements there is no distinction between Figure 4 and Figure 5.

First, the logic plan Figure 5, which applies to RVa protection Figure 4, will be described. The protection trip input is queried via the U 51 module, in line 3 the time t2 = 100 ms is set. It causes logic output 1 (t) 042.033 to deliver a 100 ms high signal in line 4 if U 51 has switched to low. The reserve protection in line 3 is set to 0.85 s, the first relay time after the RV time. Due to the relay address 017.007 was used for this. The Send function includes the assignment of input U 52 to output relay k51, as can be seen in Figure 4. The use of the k51 as a break contact is realized using the address 150.098 quiescent current. The activation of Kuri L forward 036.018 and UMZ I << 040.029 by k52 on the query rail does not differ in either arrangement. There is also no difference in the wire break function. This is a signal that does not have a direct protective effect. The influence on the protection system is exerted through human-machine communication. The time of t2 = 1 s can also advantageously be defined so that it corresponds to the largest relay time in the network. Figure 6 differs from Figure 5 only in the path of protection tripping in that U 53 is also connected in parallel to input U 51.

Table 1

Protection functions in the event of a cable fault in the tripod area

Mains operation: all circuit breakers on

Table 2

Protection functions in the event of a busbar fault in the tripod area

Mains operation: all circuit breakers on

Claims (16)

1. The method and circuit arrangement for a directional comparison protection (RVa protection), characterized in that the protection is guaranteed in a meshed electrical power supply network. In this mesh network, the defect points are separated from the healthy network in the smallest sections regardless of the network mode of operation. Transformers can also be included in this protection system. 2. The method and circuit arrangement for RVa protection according to claim 1, characterized characterized in that the protection z. B. in a mesh network, where a so-called tripod, or higher quality multi-leg is installed, without restrictions for both Network configurations is guaranteed. 3. The method and circuit arrangement for an RVa protection according to claims 1-2, characterized in that the protection relays of outgoers of different protection stations which have a common primary connection are connected in pairs at the level of the secondary protection by information connections and data are exchanged via these lines, with which protection area decisions can be made.

• 1. 3.1. The information connections, which may differ from the primary connections in the course of the route, consist of a twin wire send and a twin wire reception.

4. The method and circuit arrangement for RVa protection according to claims 1-3, characterized in that a query rail or query rail systems is to be installed and used for the fulfillment of the protection task in each protection station of the network.

• 1. 4.1. With the help of the query bar, the state is answered, all short-circuit currents flow into the busbar, yes or no.

5. The method and circuit arrangement for RVa protection according to claims 1-4, characterized characterized in that the busbar protection is implemented without this Differential protection must be provided. The guarantee arises because that of cables leading to the busbars in the protection area from the neighboring stations are incorporated. (As a result, the input values reach sizes above the Response value of the dead zone in the relay. 6. The method and circuit arrangement for RVa protection according to claims 1-5, characterized in that, with the aid of the direct direction comparison, the test is carried out to determine whether the short circuit is within the cable route.

• 1. 6.1. The data exchange send and receive takes place between the protective devices of the two cable ends.

7. The method and circuit arrangement for RVa protection according to claims 1-6, characterized in that the protection area is designed to be variable depending on the fault pattern, and the method and also the circuit arrangement is designed in such a way that the protection area feed lines and busbar means are caused by a busbar fault logical evaluation is assigned, and in the event of a cable fault the protection area of the cable route is also automatically determined by means of a logical query.

• 1. 7.1. The data exchange send and receive takes place between the protective devices of the circuit breakers that feed the busbar from the opposite station.
  • 1. 7.1.1. The data transfer takes place between two locations that are at the ends of at least two primary cable routes. The busbar area is also bridged.

8. The method and circuit arrangement for RVa protection according to claims 1-7, characterized in that the query and comparison information in the overall network has a defined direction.

• 1.1.1. Because in the meshed network all switched-on equipment has a short-circuit current in the event of a fault, the defined direction of information ensures that only the faulty protective area is switched off.
  • 1. 8.1.1. The activity of the shutdown to be carried out has the effect that, contrary to the direction of the short circuit up to the feed points, all relays which are ready to switch off but which are intended to allow the short-circuit current to be passed through are blocked.

9. The method and circuit arrangement for RVa protection according to claims 1-8, characterized in that all directed UMZ protection devices offered by the market are suitable for fulfilling the task of realizing RVa protection.

• 1.1.1. Devices with distance protection can be used advantageously for directional UMZ protection, because within the scope of the operational management, the area of the fault location can be narrowed down quickly and accurately.

10. The method and circuit arrangement for RVa protection according to claims 1-9, characterized in that, faults in the energy network on a cable or overhead line transmission line does not lead to voltage loss at the feed points.

• 1.1.19. In the switching stations, where there is only one primary transmission link without intermediate switching stations, a short circuit only leads to a voltage drop and not to a power failure. In the event of a fault, the consumers are practically supplied without interruption.
• 2. 10.2. The claim 10 opens a philosophy of achieving a high supply stability during the shutdown of faulty transmission elements without voltage interruption in the electrical power supply network, without switching devices or network replacement systems having to establish the stability conditions.
• 3. 10.3. The stability of a network prepared by meshing is increased, where only the function of an error shutdown has to be realized, compared to the task that in connection with the error shutdown, a switchover from the so-called healthy network must take place at the same time.
• 4. 10.4. The healthy network according to claim 10.11 makes it easy in a meshed network to implement several busbars according to claim 10.1 in special network sections.

11. The method and circuit arrangement for RVa protection according to claims 1-10, characterized in that a uniform RVa protection time can be selected in the entire network. A concrete response time of 0.5 s proves to be advantageous. It applies to all equipment in the network where transformers are not excluded.

• 1.1.1. If consumers in the network are fed with a particular importance for the electrical energy supply, they can easily achieve a protection tripping time that is greater than the RVa time.
• 2. 11.2. The solution to the technical problem of a protection tripping time greater than the RVa time is fulfilled by the statement of claim 4.
• 3.1.3. The protection relay in the consumer circuit must be switched to the query rail with the UMZ tI << contact, thus RVa time <customer protection tripping time is realized.
  • 1. 11.3.1. Claim 11.3 is also fulfilled under the condition of claim 10, namely in such a way that the feeding busbar continues the rest of the supply without interruption despite the existence of a short circuit in the customer system.
  • 2.13.3.2. Stable supply busbars according to claim 10 and 11.1, offer the customer the possibility of a permanent supply without switching devices or mains replacement systems,
• 4. 11.4. In addition to the RVa period, it also has selective reserve protection times that also include circuit breaker failure protection.
  • 1.1.4.1. The reserve protection can advantageously be implemented by means of time grading with additional use of the energy direction.

12. The method and circuit arrangement for RVa protection according to claims 1-11, characterized in that an unselective protection triggering, caused by a race event, does not take place because timing elements are arranged in the input circuit in such a way that they are prevented.

• 1. 12.1. The race event or the triggering of sympathy takes place because the short-circuit shutdown is initiated because of the expiry of the RVa time, but the simultaneous de-energization of the query rail sometimes leads to false shutdowns. Corresponding relays receive the information in the phase of the short-circuit current that has not yet been switched off due to the circuit breaker intrinsic time, so that the RVa time cannot be suppressed long enough. They also initiate the unwanted shutdown based on the race.

13. The method and circuit arrangement for RVa protection according to claims 1-12, characterized characterized that there is no change in the switching status in the network mode it is necessary to change the setting values on the respective protection relays. A It is not necessary to adapt the protection to the respective network mode. 14. The method and circuit arrangement for RVa protection according to claims 1-13, characterized in that station outlets are connected to the associated remote stations via information connections, or are connected by logical queries. The associated remote station is predetermined in planning. In the event of an error, the remote station thus realized asks for the short-circuit location, so that the sending and receiving point of the data transfer result from the logical queries and answers. In the case of a relay that is not excited or backward excited, this state is also an active send and receive date, and is therefore part of the chain of decisions regarding a possible protection trip. A non-energized relay is present when the associated circuit breaker is in the off position. The bitwise transmission of the data allows the use of all transmission methods, such as. B. to a bus line.

• 1. 14.1. Circuit breakers that are in the off position according to the operating mode do not have a negative impact on the overall protection behavior in the network.
  • 1. 14.1.1. The RVa protection in a radiation network switches off the defect in RV time
  • 2. 14.1.2. The healthy network extensions behind the fault location are switched off, as is customary in selective protection, depending on the process.
  • 3. 14.1.3. Meshing or de-meshing of the network can be made possible without protective measures, provided that the network planning requirements have been met.
  • 4. 14.1.3.1. RVa protection paths are often implemented in the event that they can be produced for a transition switching state without delay and additional actions if necessary

15. The method and circuit arrangement for RVa protection according to claims 1-14, characterized characterized in that the send and receive lines z. B. by finding the Broken veins are continuously monitored by placing the interference signal on an occupied Network control center is activated. The transmission capacity of the data line is restored established before active protection information has to be transmitted. 16. The method and circuit arrangement for RVa protection according to claims 1-15, characterized in that the protection of a meshed network is not dependent on the protection technology of digital protection relays. A pair of protections can be mixed, ie if protection already exists with mechanical relays at one end, an electrical protection device of the 2nd generation electronics or 3rd generation digital relay can be provided on the remote station, all generation devices can be equipped with the directional UMZ function. can be assigned as the counterpart of the pair.

• 1. 16.1. The cost-saving connection of digital protection to the network control technology with sufficient information transfer compared to the conditions of mechanical and electronic protection is a decisive advantage.