METHOD AND SYSTEM FOR PROGRAMMING AND IMPLEMENTING AUTOMATIC FAULT ISOLATION AND SERVICE RESTORATION

专利摘要:
method and system for programming and implementing automatic fault isolation and restoration using sequential logic. The present invention relates to a method and system for programming and implementing automatic fault isolation and high speed fault detection restoration of circuits in power distribution networks using sequential logic and point-to-point communication, is provided. high-speed fault detection of circuits in power distribution networks uses protective relay devices (14) that segment a distribution line (11) having intelligent electronic devices (ied) (22) associated with switching devices (20) which communicate point-to-point via a communication system (30) to provide fast and accurate fault location information in distribution systems with sequential logic.
公开号:BR112013026353B1
申请号:R112013026353-9
申请日:2012-03-14
公开日:2021-08-17
发明作者:Andre Smit
申请人:Siemens Industry, Inc.；
IPC主号:

专利说明:

FIELD OF THE INVENTION
[0001] The present invention relates to distribution systems and, more particularly, to a method and system for programming and implementing automatic fault isolation and high-speed fault detection service restoration of circuits in distribution networks. power using sequential logic in a decentralized programmable logic controller (PLC) structure and point-to-point communication. BACKGROUND OF THE INVENTION
[0002] The protection of power distribution systems involves detecting, locating and initiating the removal of a fault from the power system. Identifying the location of faults is an important process. Protective relays are extensively used for larger protective functions. Protection systems and circuit breakers are installed at strategic locations along the feeder for the purpose of detecting faults that cause excess current to flow and automatically disconnect it from the source. Manual operations are usually required to isolate the fault section, and this can take several hours during which time many users are without electricity.
[0003] Time classification techniques are often used to minimize the number of disconnected users when isolating a fault. Time classified protective systems have protection devices in successive zones that are arranged to operate in times that are classified through the equipment sequence so that after a fault occurs, only the one relevant to the fault zone completes the trip function . A disadvantage of time classification schemes is that they are slow to identify faulty zones, and due to the required time separation it is assumed that there is a single source powering the system. This method is not suitable when operating with multiple variable sources similar to wind and solar generation, and will require continuous adaptive adjustment changes.
[0004] A slow isolation problem and restoration of power distribution system failures lead to unwanted increase in power outages. It is still typical today for these actions to be performed by driving a line installer on tap-changer trucks. The lack of energy for the most part directly leads to loss of revenue for Utilities, fines imposed by inspectors on utilities, and loss of production on part of electrical consumers similar to factories that are dependent on a constant supply of electrical energy.
[0005] The problem of creating an intelligent distribution network was hampered by the existence of old communication systems, protocols and communication infrastructures. The problem with feeder distribution today is that systems do not have the ability to inelegantly isolate the faulted section and restore these feeders after a fault has been cleared from the system. The isolation and restoration procedure has been, to a large extent, a slow manual process, either carried out through manual switching in the field by the line installer, or utility technicians/electricians, or switching remotely by an operator through a service center. very simple PLC type field device RTU-connected distribution control. Several attempts have been made to create centralized systems that would collect data for field devices and then process this information centrally into logic equations to perform the so-called "distribution feeder automation". These systems are all notoriously slow to gather data from the field and present it to the Control Center. It can take several minutes before the fault can be isolated by repeatedly switching to a fault using a clearing process to isolate the fault.
[0006] Current Systems act extremely slowly, and may take minutes to react to changing system conditions. This is undesirable, and causes unwanted power outages while faults are being isolated or restored. Manual switching on the switch or remote switching of a SCADA control system is commonly used. Non-communication systems called "loop" automation systems are used with reclosers. These systems act in the presence of voltage measured at the switching point and local logic. Today's intelligent systems use specially adapted communication protocols similar to DNP3 to communicate between devices to achieve constrained logic. These systems are vendor specific, and are not open for adaptation or modification by the user as their needs may change. These systems are also restricted to a small number of switching devices. The system also takes place on a master device to carry out desired logic.
[0007] A number of systems exist addressing circuit failure detection in power distribution networks such as those described in United States Publication/Patent Nos. 6,603,649; 6,687,573; 6,697,240, 7,636,616; 7,773,360; 2008/0024142; and 2009/0290275, all of which are incorporated herein by reference.
[0008] There is a need in the art for a scheme that can clearly detect a faulty zone in a shorter time, and with less impact on the connected power network, and that is also immune to the effect of the introduction of distributed generation in the distribution of feeder networks. There is also a need in the art for a system that does not require a master type or arrangement symbol.
[0009] The present invention fulfills these needs. SUMMARY OF THE INVENTION
[00010] Broadly speaking, the invention provides a method and system for programming and using automatic fault isolation and high speed fault detection restoration of circuits in power distribution networks using point-to-point communication.
[00011] This invention improves power outage times dramatically by providing a true "smart grid" solution. By combining hardware, software and communication building blocks with new and innovative logic equations, a technical solution as well as a distribution process of creating fast new point-to-point operation based on the distribution feeder automation systems is provided. .
[00012] The invention provides a distribution feeder automation system that is based on a point-to-point network that can isolate failed feeder sections, and provides faster fault isolation and faster restoration of feeders after a fault is removed than available on the market today. This method can be used to greatly enhance rapid deployment to provide a means to accelerate the development of the US "Smart Grid". This invention will also provide a backbone to develop newer and more innovative protection solutions to further enhance the future "Smart Grid".
[00013] In one embodiment of the present invention, protective relay devices are associated with automatic switches/reclosers, such as in a protection setting override zone, where protective relay devices include microprocessors, and may be referred to as Devices Intelligent Electronics (IED). Such microprocessors can comprise, for example, programmable logic controllers (PLCs) for the associated control design. A high-speed communication system (such as fiber link, WiMax, WiFi, or other wired and wired transport technologies, or a mixture of these), is provided between the protective relay devices for point-to-point communication. Protective relay devices are capable of exchanging messages, eg GOOSE (Generic Object Oriented Substation Event) messages under the IEC61850 standard. The protective relay devices are then adapted to test for faults in a unique way, and communicate with each other to provide fast and accurate fault location information on distribution feeder systems.
[00014] The invention can be implemented in numerous modes, including as a system, a device/apparatus, a method, or a computer-readable medium. Various embodiments of the invention are discussed below.
[00015] In one embodiment, the invention comprises a method for programming and implementing automatic fault isolation and restoration of service in power distribution networks having protective relay devices comprising processing and communication capabilities, and associated with switching devices, comprising: (a) storage, based on a topology of a power distribution network, of information to be used in automatic fault isolation and service restoration, comprising operating mode information, system state information, and information of failure; (b) grouping the operating mode information, system status information, and fault information into functional groups for message; (c) programming in each of the protective relay devices a plurality of operating sequences which when executed control the associated switching devices when a fault detection element identifies a faulty section of the network, in which each operating sequence is based on the operating mode information, system status information, and fault information; (d) sharing of operating mode information, system status information, and fault information, via peer-to-peer messaging between all of the protective relay devices, via a high-speed communication system; and (d) performing a sequential isolation operation comprising a correct operational sequence based on mode information, system state information, and fault information to isolate the faulted section in a series of sequential steps.
[00016] In one embodiment, the system state information comprises a position of each primary switching device on a feeder; the fault information comprises detected fault positions, and is used as a trigger to initiate the sequential isolation operation; and the operating mode information comprises one or more of automatic mode, section control mode, restore mode, storm mode, simulation mode, and load balance mode.
[00017] More specifically, the operating mode information comprises one or more automatic modes that provide automatic operation to detect, isolate, and restore faults; section control mode that provides opening of a section of line for pre-programmed logic steps; restore mode which provides restoration to a normal state once the fault has been repaired; storm mode which provides protection change operation as well as operational sequences; simulation mode that provides testing of operational sequences; and load balancing mode that provides indication of the best possible open point on a feeder to distribute a load evenly between two sources.
[00018] In a further embodiment, the operational sequences comprise logical sequences implemented using a plurality of logical gates. Logical gates comprise logical AND gates representing a binary information sequence programmed in relay logic which when filled in will cause a switching device to operate, and together with the switching devices of the system create a distributed sequential logical system. The logic information is configured to a binary relay output that is connected to primary switch operating circuits to close and open the primary switch. One or more of the reclosers, switches and circuit breakers are activated to isolate the failing section in a series of sequential steps. Protective relay devices comprise intelligent devices having a microprocessor and a communication system.
[00019] In a further embodiment, the invention comprises a system for programming and implementing automatic fault isolation and restoration of service in power distribution networks, comprising a plurality of protective relay devices in a power distribution network, each protective relay device comprising a processor and associated with switching devices for fault isolation and restoration of service; a communication device associated with each protective relay device that provides point-to-point communication between the protective relay devices, in which the message in the communication device comprises defined functional groups that groups operating mode information, system status information, and defined fault information based on a power distribution network topology, information to be used in automatic fault isolation and service restoration, in which each communication device provides operating mode information sharing, system state information , and fault information, via peer-to-peer messaging between all of the protective relay devices, via a high-speed communication system; in which each protective relay device has programmed in it a plurality of operational sequences which when executed control the associated switching devices when a fault detection element identifies a faulty section of the network, in which each operational sequence is based on information from mode of operation, system state information, and fault information, such that a sequential isolation operation comprising a correct operational sequence based on the mode information, system state information, and fault information, is performed to isolate the section. failing in a series of sequential steps.
[00020] A tangible computer-readable medium is also provided in an embodiment which comprises instructions when executed by a processor implementing the steps of the invention. The methods of the present invention can be implemented as a computer program product with a tangible (non-transient) computer-readable medium having code thereon.
[00021] As an apparatus, the present invention may include microprocessor-based protective devices or programmed RTU's or PLC, according to the steps of the present invention.
[00022] Consequently, an advantage of the present invention is that the method can clearly detect a faulted zone in a shorter time with less impact on the connected power network that is immune to system impedance and source variations. Additional advantages include an increased number of switching devices, high speed operation (Operating speeds in milliseconds as opposed to seconds or minutes), high speed fault detection and isolation, and Open protocol (eg IEC61850).
[00023] Other aspects and advantages of the invention will become apparent from the following detailed description taken in conjunction with the accompanying drawings, illustrating, by way of examples, the principles of the invention.
[00024] All patents, patent applications, provisional applications, and publications referred to or cited herein, or from which a claim for priority benefit has been made, are hereby incorporated by reference in their entirety to the extent that they are not inconsistent with the explicit teachings of this descriptive report. BRIEF DESCRIPTION OF THE DRAWINGS
[00025] In order that the manner in which the above stated advantages and objectives of the invention are obtained, a more particular description of the invention described briefly above will be taken by reference to the specific embodiments thereof which are illustrated in the attached drawings. Understanding that these drawings represent only typical embodiments of the invention and are therefore not to be considered a limitation of its scope, the invention will be described and explained with additional specificity and detail through the use of the accompanying drawings, in which:
[00026] FIG. 1a is a block diagram of an embodiment of the invention.
[00027] FIG. 1b is an example of a WiMAX wireless communication infrastructure and components used in a FLISR system.
[00028] FIG. 1c is a block diagram of a differential fault detection method using three relays.
[00029] FIG. 2a is a flowchart showing the steps of an embodiment of the invention.
[00030] FIG. 2b is a block diagram of a differential RMS failure detection method measured in three stages.
[00031] FIG. 2c is a block diagram of a three-stage jump detector fault detection method.
[00032] FIG. 3 is a block diagram showing point-to-point failure detection.
[00033] FIG. 4 is a block diagram showing peer-to-peer state sharing.
[00034] FIG. 5 is a block diagram showing peer-to-peer mode sharing.
[00035] FIG. 6 is a block diagram showing point isolation logic.
[00036] FIG. 7 is a block diagram showing point reset logic.
[00037] FIG. 8 shows an IED programming process.
[00038] FIG. 9a shows an operational sequence of the test feeder.
[00039] FIG. 9b shows logical feeder sequences.
[00040] FIG. 9c shows distributed sequential logic.
[00041] FIG. 10 shows IED programming for isolation and reset. DETAILED DESCRIPTION OF THE INVENTION
[00042] Broadly speaking, the invention provides a method and system for programming and using automatic fault isolation and high speed fault detection restoration of circuits in power distribution networks using point-to-point communication. The method and apparatus comprises high-speed fault detection of circuits in power distribution networks using Intelligent Electronic Devices (IED) associated with switching devices that communicate point-to-point to provide fast and accurate fault location information in power systems. feeder distribution over wireless communication networks. Sequential logic provides intelligent reconnection and load transfer schemes.
[00043] A typical feeder system is provided by a substation through a circuit breaker and includes at least three of the following types of switching devices distributed along the line: reclosers, isolating switches, disconnectors, airbreak switches, and fuses. In addition, capacitor banks and voltage regulators are included in many installations.
[00044] A system equipped with Distribution Feeder Automation would also include equipment for detecting, locating and isolating faults, and a means to restore power to undamaged sections of the lines. This additional functionality is referred to as Fault Supply Location, Isolation and Restoration (FLISR). Other typical system components include VAR control and dispatch equipment to maintain power factor, and gear control to regulate line voltage.
[00045] FIG. 1a shows a simplified view of a portion of an exemplary electrical power distribution system 10 that includes fault protection devices 14 (F1, F2, F3...). Generally, in such an arrangement, a source 12a (S1) is coupled to a distribution line 11 along with an alternating source 12b (S2) coupled to the distribution line 11 by a normally open device 15 (N/O) and the supply devices. fault protection 14 (F1, F2, F3...) segments distribution line 11 into segments/zones (Zone 1-2, Zone 2-3, etc.) including 16a (Stable Zone 1-2), 16b ( Faulted Zone 2-3). In this example, the distribution system 10 comprises a plurality of electrical energy sources 12a, 12b, shown here as sources S1, S2 connected to a plurality of users or loads (e.g., factories, homes, etc., not shown) through of an electrical distribution line 11 such as conventional electrical power lines. The distribution line 11 has a plurality of fault protection devices/protective relay devices 14 (individually labeled F1, F2, ...FN) placed at predetermined points along the line, including, for example, a switch N/ The normally open F4 in this particular arrangement. The representation of the number and arrangement of fonts, users, lines and devices in FIG. 1a is arbitrary and there can be many different configurations and virtually any number of each of these components in any given distribution system.
[00046] Protective relay devices 14 are associated with automatic switches/reclosers 20 (eg a group of reclosers, switches, or a combination of both, within a loop), such as a protection setting override zone . The protective relay here preferably comprises microprocessor based devices such as Intelligent Electronic Devices 22 (IEDs - any device incorporating one or more processors with the ability to receive or send data/control to or from an external source) having a controller of programmable logic (PLC) and a communication processor and protocol such as an IEC 61850 (open standard communication processor as a part of the Technical Committee of the International Electrotechnical Commission (IEC) 57 (TC57), reference architecture for electrical power). The IED 22 PLC mainly comprises a CPU, memory areas, and circuitry suitable for receiving input/output data. Processors in protection devices perform certain logical tasks based on their programming. Numerous input terminals receive allowed logic states from sensors and switches (eg "0"/"1", or "on"/"off"). Output terminals initiate events, such as triggering a circuit. Protection relays 14 are devices that are used as a sensing element to detect abnormal conditions in the distribution system. An automatic circuit recloser is a self-contained device that can detect and interrupt fault currents, as well as automatically reclose in an attempt to re-energize a line.
[00047] Protective relay device 14 is connected with current and voltage sensors, or voltage transformers (VTs), and current transformers (CTs), not shown, to monitor power flow. Current and voltage sensors provide the necessary input of data used to determine logical sequences in fault detection. The loop can usually contain 3 - 20 switching devices within a device group or loop. A typical feeder has 7-10 switching stations.
[00048] A high-speed communication system 30 (such as fiber, link, WiMax, WiFi, or other wired or wireless transport technologies, or a mixture thereof), is provided between the devices for point-to-point communication. Generally speaking, such a distribution network with point-to-point communication capabilities is disclosed in commonly owned, co-pending U.S. Patent Application Serial No. 12/967,191, filed December 14, 2010, and described in further detail herein. See, for example, FIG. 1b. Information is then made available to each of the other smart devices about the communication channel located within that particular loop. For example, an Ethernet support can be wired over twisted-pair copper cable, fiber, or an Internet Protocol (IP)-based radio system, wideband over power line (BPL), or subscriber line. digital (DSL). Devices 14 are capable of exchanging messages, eg GOOSE messages (Generic Object Oriented Substation Event) under the IEC61850 Standard (These protocols can operate over TCP/IP networks and/or substation LANs using high speed switched Ethernet to obtain required response times of < 4 ms for protective relays). End-to-end functionality via IEC 61850 generic object-oriented substation event messages (GOOSE) not only provides binary data, but analog values as well. There is therefore no need for a master-slave arrangement, as IEC 61850 provides point-to-point communication capability. Since the devices all communicate in a point-to-point manner, some of the input devices that would normally be required in a loop-automation system can be eliminated.
[00049] Devices 14 are configured to test for faults using differential protection (that is, electrical quantities entering and leaving the protected zone are compared and if the network is zero, no faults are assumed to exist) and communicate with each other to provide fast and accurate fault location information distribution systems.
[00050] Differential method can detect fault line sections. In one embodiment, three relays are used to provide fault detection functionality for the two line sections. Data communication between relays (such as Differential Relay/ANSI-87,) includes message over a wireless network (such as IEC61850 GOOSE message) to transfer all analog and binary information between devices. See, for example, FIG. 1c. The self-healing logic can reside in individual intelligent electrical device (IED) groups located on the feeder loops. IEDs 22 handle the self-healing functionality, and attempt to clear the faults, isolate and then, after the fault is cleared, initiate the restore logic. Fault location information is processed in milliseconds with differential equations using point-to-point communications between switching points. The system performs fault detection, isolation and restoration (FDIR) functions with decentralized automation, sometimes described as Fault Locating, Isolating and Restoring Service (FLISR). The individual self-regeneration loop breaks the network into message segments, and allows the utility to further define the logic of the regeneration process for its distribution system.
[00051] Each PLC contains multiple AND gates that perform switching steps, which when combined, create logical sequences that control the isolation and restoration processes. Sequences for load balancing and load transfer can also be programmed. In this way, the system has complete flexibility to execute desired sequences based on operating mode, fault information, and system state, simply combined into a single AND gate.
[00052] Each relay can be programmed to operate in different modes to satisfy system and environmental requirements as directed by a remote control point or SCADA system. Modes of operation include auto (FLISR), remote, manual, reset, load control, load balancing, storm, and the like.
[00053] Referring to FIGURES 2a - 2c, the test method used here for failures essentially comprises three stages. The method detects failures in a power distribution system 10 having at least one source 12a coupled to a distribution line 11 comprising a plurality of fault protection devices 14 that segment the distribution line 11 into a plurality of protected zones 16a, 16b, the fault protection devices 14 having processing and communication capabilities, and associated with switching devices 20. In the method, for each protected zone 16a, 16b defined by a pair of fault protection devices 14 at either end, one first local fault protection device 14 (F1) at a first end, and a second remote fault protection device 14 (F2) at a second end, the steps include STEP 1 (101) receiving as input of an average value local square root (RMS) of a positive sequence current II of the first local fault protection device, and a remote RMS value of the positive sequence current I2 of the second remote fault protection device, in which the RMS values are communicated between the fault protection devices via event messages; STEP 2 (102) determination for each fault protection device in the pair of a current differential between current Ii and current I2 to set a binary value for each fault protection device in the pair based on a sequence current setting positive minimum measure; STEP 3 (103) individually set each fault protection device to a first stage state of torque 0 if the current differential is less than an expected load (set If in this zone, then set the first stage state as one binary 1; STEP 4 (104) communication between each fault protection device via event messages of the first stage states and then comparison of the first stage states in which if any fault protection device has the first state setting of binary 0 stage, individually setting of each fault protection device of the second stage state as binary 0, further setting of the second stage state as a binary 1; STEP 5 (105) communication between each fault protection device, via event messages of the second stage states and then comparison of the second stage states, in which if any fault protection device has the second stage state that of torque 0, individually setting of each fault protection device a final state as binary 0, further setting the final state as a binary 1; and STEP 6 (106) indication of a non-fault situation if both end states are binary 0, still indication of a fault. Other embodiments are variations of these steps as shown in the following tables.
[00054] These steps are essentially performed in three stages. In stage 1, the local RMS value of the positive sequence current l is subtracted from the upstream RMS value of the positive sequence current, and given a value (eg 1 or 0) based on a positive sequence current setting. minimum measure. GOOSE messages can be used to distribute the RMS values. In addition, the positive and negative jumps associated with individual phase currents or positive sequence currents caused by a fault will be detected and shared, and can be used as an AND or OR function across the remaining stages.
[00055] In Stage 2, the results from both ends of the line are then added and compared to form a result at each point. Binary values are used.
[00056] In Stage 3, Stage 2 results are then added and compared at each point to form the final local result in which a binary 1 or high will indicate a failed zone. This method will allow indication of a faulted zone within a 200 msec time frame over a wireless communication network.
[00057] For a stable zone as between F1 and F2 in Fig. 1 and with reference to Fig. 2, the following tables represent the sequence of steps: Table 1a. Stable Zone 1 - 2 (Note: » indicates a GOOSE value; PU = per unit)

[00058] Table 1a Description: This table describes how the IEDs will react to a fault outside the protection zone. In this example, the current measured in both devices will increase at the same time and with the same magnitude. The following stages indicate how the IED's calculate the current differential and compare the results at least twice within the 200 msec time window to achieve a final result. Positive sequence current is used in this to keep GOOSE traffic to a minimum, individual phase measurements can be used if desired. This is the one and only stage that measured values are used. Direction is assumed to be non-critical in this radial application. Direction is determined by each IED to be forward or reverse through the system topology. Directional measurements that act as a measured value inverter must change direction. This function is used on non-radial systems.
[00059] Stage 1: The GOOSE value from the remote IED is now subtracted from the locally measured current. The difference value must be less than the expected load (Idiff adjustment) in this line section. If this is true, the IED will output a binary 0 value. The remote LED will perform the exact same calculation as described above. Each IED will then issue a value of binary 0 for Idiff. In Table 1a, a torque 0 result for both relays is achieved.
[00060] Stage 2: In this stage, the differential results Idiff or stage 1 are compared between the two IED's. Each IED will compare its Idiff result to that of the other Idiff from the received GOOSE. If any of the Idiff values are 0, this stage will output a 0 as a result. In Table 1a, a torque 0 result for both relays is achieved.
[00061] Stage 3: In this stage, the results of stage 2 are compared between the two IED's. Each IED will compare its stage 2 result to that of the other GOOSE IED's received. If any of stage 2's values are 0, this stage will output a 0 as a result. A zero result indicates a non-failure situation. In table 1a, a torque 0 result is achieved for both relays. Table 1b. Stable Zone 1 - 2 (Note: » indicates a GOOSE value, PJ = Positive Jump. NJ = Negative Jump)


[00062] Table 1b Description: The table describes the jump detector method for identifying a failed line section. The method only shares binary GOOSE information between IED's to arrive at a final result. The method is not affected by current direction, considering that only 1 source is connected to the feeder. This method comprises a local measurement to detect a sudden change or jump in current in either positive or negative directions. These hops are sent to adjacent IEDs, via GOOSE, for processing. Each jump will only be active for a predetermined time like a pulse. Two IED's must agree during this pulse period that a fault is present.
[00063] Stage 1: In this stage, each IED measures the phase currents for a positive jump or current increase, and a negative jump or current decrease that is more than the preset ΔIt value. The jump must be more than the ΔI t value, a binary 1 or 0 value is generated for both the positive jump and negative jump. These two jump indicators are pulse outputs, and will remain high for a preset time. In Table 1b, a binary 1 is reached for positive jumps in both relays, and the result of torque 0a in both IED's for negative jumps.
[00064] Stage 2: In this stage, the positive and negative jump information is compared through the AND function. Positive jump and negative jump signals form the local IED and the remote IED is put through two AND gates. The AND gates will produce a binary 1 if there is a local positive jump AND, a remote negative jump, OR a local negative jump AND a remote positive jump. This signal indicates a diff fault present as measured in any IED. In Table 1b, a torque 0 result is achieved for both relays.
[00065] Stage 3: In this stage, the final output signals from stage 2 are used in an AND function to finally determine the presence of a diff fault. If both IED's agree that a fault is present, a Fault Diff for the line section is issued by both devices. In Table 1b, we achieved a binary 0 result on both relays, thus no faults.
[00066] For a faulted zone as between F2 and F3 in Fig. 1a, and with reference to Fig. 2a - 2c, the following tables represent the sequence of steps: Table 2a. Faulted zone 2-3 (Note: » indicates a GOOSE value; PU = per unit)

[00067] Table 2a Description: This table describes how the IEDs will react to a fault within the protection zone. In this example, the current measured in one IED will increase and, at the same time, the current in the other IED will decrease. Current will flow into the current fault and does not reach this IED in position 3. The following stages indicate how the IED's calculate current differential and compare the results at least twice within the 200 msec time window to achieve a final result. Positive sequence current is used in this to keep GOOSE traffic to a minimum, individual phase measurements can be used if desired. Preferably, this is the first and only stage that measured values are used. Direction is assumed to be non-critical in this radial application. Direction is determined by each IED to be forward or reverse through the system topology. Directional measurement acting as a measured value inverter must change direction. This function is used on non-radial systems.
[00068] Stage 1: The GOOSE value from the IED is now subtracted from the locally measured current. The difference value must be less than the expected load (Idif setting) in this line section. If this is false, the IED will output a value of binary 1. The remote IED will perform the exact same calculation as described above. Each IED will then output a value of binary 1 for Idif. In Table 2a we have achieved a torque 1 result for both relays.
[00069] Stage 2: In this stage, the differential Idif or stage 1 results are compared between the two IED's. Each IED will compare its Idif result to that of the other Idif from the received GOOSE. If both Idif values are 1, this stage will issue a 1 as a result. In Table 2a we have achieved a torque l result for both relays.
[00070] Stage 3: In this stage the results of stage 2 are compared between the two IED's. Each IED will compare its stage 2 result to that of the other IEDs from the GOOSE received. IF both of the stage 2 values are 1, this stage will issue a 1 as a result. A result of 1 indicates a failure situation. In Table 2a we have achieved a torque l result for both relays. Table 2b. Faulted zone 2-3 (Note: » indicates a GOOSE value)

[00071] Table 2b Description: The table describes the jump detector method for identifying a failed line section. The method only shares binary GOOSE information between IED's to arrive at a final result. The method is not affected by current direction as only 1 source is connected to the feeder. This method comprises a local measurement to detect a sudden change or jump in current in either a positive or negative direction. These hops are sent to adjacent IEDs, via GOOSE, for processing. Each jump will only be active for a predetermined time as a pulse. Two IED's must agree during this pulse period that a fault is present.
[00072] Stage 1: In this stage, each IED measures the phase currents for a positive jump or current increase, and a negative jump or current decrease, which is more than the preset Δ11 value. The jump must be more than the ΔI1 value, a binary 1 or 0 value is generated for both positive jump and negative jump. These two jump indicators are pulse outputs, and will remain high for a preset time. In Table 2b we get for F2 a binary 1 for a positive jump, and a binary 0 for a negative jump, and in F3 we get a binary 0 for a positive jump, and a binary 1 for the negative jump.
[00073] Stage 2: In this stage, the positive jump and negative jump information is compared through an AND function. Positive jump and negative jump signals form the local IED and the remote IED is put through two AND gates. AND gates will produce a binary 1 if there is a local positive jump AND a remote negative jump, OR a local negative jump AND a remote positive jump. The signal indicates a diff fault present as measured on any IED. In Table 2b we have achieved a binary 1 result for both relays.
[00074] Stage 3: In this stage, the final stage 2 output signals are used in an AND function to finally determine the presence of a differential fault. If both IED's agree that a fault is present, a final Diff Fault for the line section is issued by both devices. In Table 2b a result of torque 1 is achieved in both relays, thus the differential fault is detected.
[00075] Upon detection of a fault in this example, breakers F2 and F3 can be opened to isolate the fault.
[00076] Point-to-point messages are used to distribute the RMS values to local differential equations and stage state information.
[00077] The test method can also be used to act as a permissive trip scheme to allow faster disconnect for low current or high impedance faults. Furthermore, conductor break detection can also be used to disable the differential function if desired.
[00078] The slow switching problem is solved by using IEC61850 Ethernet-based protocol as opposed to Serial DNP 3 communication protocols. Ethernet provides a high-speed data bus, and IEC61850 provides GOOSE messages that provide point capability. to the point. IEC61850 was not intended to be used over wireless systems outside the confines of a substation.
[00079] Fault isolation and restoration of service is also provided using relays as a decentralized system of PLCs. Feeders usually contain several primary switching devices, including circuit breakers, reclosers, and main switches that can be used to isolate fault sections of a line. A main switch cannot interrupt power failure, but a circuit breaker or recloser can. If a fault occurs between two switches in an in-line section, the first upstream breaker or recloser must be opened before the main switches can be operated to isolate the faulted section. Then, the upstream breaker or recloser can be closed to restore service to the section without line failure.
[00080] The information used to produce such switching decisions is typically based on the detection of a fault and a determination of its location between two primary switching devices. In addition, current state supply knowledge is used to determine when it is safe to operate a primary switch. A switching procedure can usually be established to isolate a section of line fault and restore power to unaffected sections. In an automatic system, it is also important to know which operating mode is being used, for example, auto mode, simulation mode, test mode, and storm modes.
[00081] The message can be used to distribute fault, state, and mode information among all devices, thereby allowing switching functions to be based on data received from the rest of the feeder. The GOOSE message, for example, can be transmitted at very high speeds over WiMAX networks.
[00082] The following steps are taken to realize a FLISR system.
[00083] First is the definition of Operating Modes. The definition of operating modes is used when a SCADA system is to perform remote manual operations. The system or an HMI provides operating mode information for all relays in an automatic feeder system using source specific multicast commands (SSM).
[00084] For example, the system provides operation in auto mode, sectional control, restore, storm, simulate, and load balance mode. In Auto Mode, the system will operate on itself to detect and isolate faults. It can also restore section without fail. If auto mode is OFF, control of individual switches is possible from the control points. In Section Control Mode, the operator can open a line section for pre-programmed logic steps. Restore Mode is used to restore the system to normal state once the fault has been repaired. Storm Mode is provided to give the ability to change protection operation as well as operational sequences. Simulation Mode provides the ideal testing tool for testing the operating sequences of the system. The controllers will mimic the operation of the primary switches and provide feedback to the HMI's. In Load Balance mode, the system will indicate the best possible open point on a feeder to distribute the load evenly between two sources. Alarms provide operational data and non-operation data to control points and SCADA.
[00085] The system can include multiple control points. Three control points can be used, one being an HMI connected via a substation computer, with the other two each being a relay with a programmable graphic interface connected to two circuit breakers that supply the feeder. In addition to providing protection, relays provide mode and control information to other devices using GOOSE messaging, thus making the most basic form of control.
[00086] Local protection and control logic functions including direct line tag, protection strip, lockout, and battery status information can be included in each relay's programming. A standard fault detection relay and control logic file can be created for a breaker, a recloser, and a trip switch.
[00087] Fault Detection is performed independent of SCADA during protection operation to identify a faulted section. Fault Isolation is a series of sequential steps that lead to isolation of a faulted section. A mix of reclosers, switches and circuit breakers can be switched in pre-programmed sequences. Overloading of a line section can be detected and reported to the operator.
[00088] Next is the definition of Status Information. The system state information used to produce an informed switching decision, including the position of each primary switching device on a feeder, is defined. 52a and 52b contact information is used and transmitted between all relays. Each relay thus has real-time information about the state of the total feeder. The system is based on information shared between all controllers. GOOSE messages related to operating modes, status and fault information are shared among all controllers. An operating sequence is thus selected by operating mode and current state. This sequence will then start executing as soon as the fault detection element identifies a system fault. Any operation is therefore dependent on a Mode and a Failure State.
[00089] Next is the definition of Logical Sequences. Each operation is a simple logical AND gate that if populated will cause one switch operation. They can be numerous, and ports on each device for different operational requirements. Because the GOOSE message operation speed over WiMAX is fast enough to perform required sequential switching logic, it allows for the elimination or minimization of the use of regulators in the system. This approach ensures that the system would not have any real conditions caused by the communication and/or change in the conditions of the communication system.
[00090] The first step in defining logical sequences is to determine the actual operating sequences required for a particular feeder. The approach uses, for example, a graphical tool created in a spreadsheet to plan all the sequences. After the switching devices on the feeder are specified, directional conventions and normal operating state are defined.
[00091] Information related to operating mode, primary switch status, feeder section faults, and sectional control are included. All information is preferably given in the form of torque as indicated on the bars located below the feeder representation in Fig. 9a. A color system can be used to simplify planning and highlighting changes.
[00092] The second step is to list all possible logical sequences for a feeder. The list includes, for example, the following sequences: One fault in each section of line; Restoration for each isolated line section; Transfer logic for source loss; Sectional insulation; Sectional restoration; and Load balancing.
[00093] The current list can contain, for example, 24 possible sequences that can be considered. The processes include defining complete logical sequences as shown in Fig. 9b.
[00094] The first state indicates a normal state. The second state indicates that a fault has occurred (change to binary 1) and that an operation to open breaker P1 is required by the relay in P1. This is called the trigger state. In the third state, breaker P1 changed from binary 1 to binary 0, indicating that an operation to open recloser P2 must be issued by the relay in P2. In the fourth state, recloser P2 changed from binary 1 to binary 0, indicating that an operation to close recloser P3 must be issued by the relay in P3. This completes the first sequence.
[00095] Next is the Logic Programming in Relays. Relay logic programming is performed using the following procedure. Each binary information string is programmed as an AND gate in relay logic. For the sequence indicated in Fig. 9b, an AND gate on relay P1 must be programmed to open the circuit breaker according to a torque section information located below the feeder graphical representation for the trigger state. This logic is represented simply in Fig. 9c. The next AND gate is then programmed into relay P2, and the last into P3, thereby creating a simple distributed sequential logic system.
[00096] The programming procedure for a complete feeder system can be automated by developing software tools for desired operation in very little time. For the feeder discussed above, in an example embodiment, 125 AND gates or operations have been programmed into the relays.
[00097] A bench test simulation setup can also be implemented in the relays to increase the speed of testing sequences. Software tools can be developed to include all strings to be hosted.
[00098] The simulation tool can essentially mimic the primary switches and apply faults and reset commands to the relays. The tool is also used in field commissioning to prove the total system without switching a primary device, or disruption of service to customers.
[00099] The GOOSE message control is mostly handled by the IEC61850 configuration tool. All messages can be evaluated as having a priority rating of 7, the highest possible. Each relay preferably sends a message to keep data traffic to a minimum. A typical GOOSE message contains at least 120 bytes of main data, and every bit of binary data adds 10 bytes to the message size. The objective is to keep the cyclical data below 500 kb/s on each switching device so that a 10 Mb/s communication system supporting 20 devices can be used at acceptable levels.
[000100] The relay at P1 contains 37 bits of different binary information in a simple GOOSE message that is made available to other relays in the system. This adds no more than 500 bytes of data to the communication system. Therefore, there is enough capacity to expand functionality and communication features. A GOOSE terminology table is created to simplify programming, and make it more understandable.
[000101] A simple WiMax System will now be described. These systems typically employ a web-based setup wizard that can be accessed through a standard browser. The base station configuration includes an operating mode setting, which is set to run standalone operation. The IP Address and Subnet Masks are also configured.
[000102] An IP address tracking system is used to simplify the identification of device types and their locations within the system. The setting for switching mode can be set to L2 switching. The frequency can be adjusted to 3,600,000 KHz, and the transmit power to 12 dBm in a 10 MHz bandwidth.
[000103] Subscriber unit settings are applied through a similar process using a web interface. The first setting adds a channel to the scanner. The frequency can be adjusted to 3,600,000 KHz, and the transmit power to 12 dBm for the channel. Frame duration can be set to 5 ms, and IP address and subnet information are supported.
[000104] A System Programming Service plays a significant role in the amount of latency experienced. During initial testing, a BE failure or best effort adjustment can be used with the base station. The use of UGS or unsolicited grant service adjustment may be recommended for use with relays in the system. This tweak improves the latency of GOOSE messages significantly.
[000105] Peer-to-peer state sharing on information using IEC61850 "GOOSE" is provided. It removes the need to have a master device, thereby reducing system cost. It improves uptime by removing the inherent latencies of a master slave system. The solution included minimizing the number of GOOSE messages as well as required conventions to produce understandable and repeatable programming.
[000106] The solution still provides new grouping of GOOSE messages into functional groups. Groups include fault detection, modes, and state.
[000107] Fault Detection (P1 - 3 Switches or Reclosers) is shown in FIG. 3. Failure detection is shared using GOOSE. The fault position is detected, and is used as a trigger to initiate the sequential isolation operation. Fault detection or fault location when detected will make this information known to other relays in the system. This information is typically used as a trigger by the system to initiate a sequence of system switching operations to isolate only faulty line sections and restore power to fault-free sections.
[000108] Fault information when detected is sent from devices connected to a line section to all other devices using GOOSE messages. This fault information will remain in a logic high until it is reset by an operator or line man at the device located at the switching location.
[000109] If a fault is detected on the line section between P1 and P2 by the relays located at P1 and P2, the relays would then both set an RS flip flop memory function to indicate that Fault 1-2 is logic high or present . This high logic information that Fault 1-2 is present is sent by both devices as a Goose Message to other devices in the system.
[000110] Fault 1-2 high will be sent as a Goose message, eg by P1', the relays on P2 and P3 will subscribe to this information from P1.
[000111] Fault 2-3 high will be sent as a Goose message, eg by P2, the relays on P1 and P3 will subscribe to this information from P1.
[000112] State Sharing (P1 - 3 Switches or Reclosers) is shown in FIG. 4. Status information is shared using GOOSE (Open/Closed). It is used as a trigger for sequential operation. A device can only operate once a state of another device is changed.
[000113] State sharing is important information that needs to be shared by all devices. This creates a system made by each of the relays in P1, P2 and P3 that is fully informed of the total system topology. This information is used to create a sequential series of operations. A sequential system is very stable and immune to system switching operating conditions. Relay P1, P2 and P3 is hard wired to the associated primary switch via binary inputs. Contact information indicates whether the primary switch is open or closed. The open and closed information is sent as a Goose message from P1, P2 and P3, providing the real-time state of the associated primary switch. P1 will subscribe to the status information of P1 and P3. P2 will subscribe to the status information of P1 and P3. P3 will subscribe to the status information for P1 and P2.
[000114] Mode sharing (P1 - 3 Switches or Reclosers; Master = RTU or substation controller or SCADA or P1, P2, P3, or combination of all) is shown in FIG. 5. Mode information is shared using GOOSE, or via SCADA central command. It includes Auto Mode (On/Off), Reset (On/Off), Simulation Mode (On/Off) and Local. It is used as a logical operation selection switch for sequential operation. A device can only operate once the mode of another device has changed.
[000115] Mode sharing is used to select a programmed operating sequence to be followed by relays in a group. This information can be provided to the relays on P1 P2 and P3 via various means. Information can be provided through traditional select switches connected to binary inputs of relays, eg to relays located at P1. P1 will then send a goose message to P2 and P3 to inform them of the selected operating mode. Information can also be supplied by an RTU or SCADA system to the relays via an additional communication interface. Mode information can include various modes, for example, Auto mode, Restore mode, Storm mode, Section control mode, or any mode that may lead to the selection of a different sequence that needs to be performed.
[000116] Simple logic gates are used to build advanced logic systems as depicted in FIG. 6 and 7. The use of simple logic makes the system very easy to implement and understand. This results in a new feeder automation using GOOSE and protection relays or IED's. Fig. 6 (Point Reset Logic) shows the number of gate entries used to generate sequential operations based on Faults, State and Mode. A similar logic program is used for each system switching operation. Fig. 7 (Point Isolation Logic) shows the number of port inputs used to generate sequential operations based on Faults, State and Mode. A similar logic program is used for each system switching operation.
[000117] The Fault, State and Mode Goose information that each relay subscribes to is configured on a series of AND gates in the relay's PLC function to perform an operation. This operation in FIG. 6 represents the information used for the relay to issue a command to close or open the connected primary switch. If all AND gate inputs are high, the AND gate output will be high. This high logic information is configured for a binary output of the relay that is hard wired to the primary switch operating circuits to close and open the primary switch. An AND gate can be used to perform the logic as depicted in FIGURES 6 and 7. The representation of 3 AND gates was merely used to clearly separate fault and status information generated by the relays, and the modes generated for an external source.
[000118] A simple sequential switching logic programming technique is provided. A new programming process is used to produce logic quickly and accurately through a graphical representation followed by a sequential table. See FIG. 8. This technique provides a distribution process that can be followed, simple step by simple step, to create an advanced logic system that will switch sequentially. Sequential firing is a prerequisite for fast operation. The system overcomes the varying latency of a wireless system with IED's and WiMax without a control, creating a process to program a point-to-point logic system that is immune to the communication and operating speeds of primary switch equipment.
[000119] This figure represents the complete process of planning the implementation of the required sequential sequences.
[000120] The first step is to create a graphical representation of the topology of the feeder, and make certain assumptions similar to the direction of energy flow in the feeder. The topology in FIG. 8 shows a circuit breaker connected to a recloser, connected to a switch connected to a switch, and finally connected to a recloser. The connection of the bottom recloser to the adjacent feeder is not shown in this representation.
[000121] The state of each primary switch can be represented by a color change, or by a symbol change indicating the position. In FIG. 8, red indicates a closed position of a primary switch, and green an open position.
[000122] Efficiency by graphical means of planning is done to show how the feeder primary switch states change in order to isolate a faulted section and restore power to the non-faulted line sections. In the "step 1" planning section, the sequence steps can be described as: Normal feeder state with a detected fault between the circuit breaker and the first recloser.
[000123] Step 2 shows that the circuit breaker is required to open.
[000124] Step 3 indicates that the recloser must effectively open the failed section insulation.
[000125] Step 4 indicates the closing of the background recloser required to provide power to the line from the source or adjacent feeder.
[000126] The next step is to transform this graphical information into high "1" or low "0" logic binary information in a table or spreadsheet. Each step is now represented by a series of high and low information. At the bottom of the table, an output or action is taken based on the graphical planning done before.
[000127] IED programming is constructed of simple and/or gated to achieve complex sequential switching schemes. The process is designed to build custom systems quickly and effectively. IED programming can comprise the following steps. Step 1, Base Program Control and desired Operational Modes of Simulation Logic. Step 2 Create new topology according to graphic plan and State and Program Mode, inputs and outputs in the relay. Step 3 Download All Goose Messages. Step 4 Interconnect Connect all State, Mode and fault indication GOOSE Messages in IEC61850 configuration tool and test. Step 5 Schedule all Isolation and Restore logic by Isolation and Restore sequence tables. Step 6 Connect all relays to a switch to form a private Ethernet network.
[000128] Then, each logic step can be tested after programming completion through simulation functionality (each IED is equipped with simulation mode), including fault application and dynamic test run for full sequence, and restoration application and performing a dynamic test for a complete sequence. This function has great advantages when developing system logic. The logic can be tested immediately after programming the logic in the IED's connected to the communication network. The system can thus be bench tested without being installed on primary switchgear equipment. After the logic is developed, the customer will now have the ability to laboratory test the previous intended system for primary equipment erection. Once installed in the field, the complete system can be tested to the SCADA system without primary gear changeover and disruption to customers. A simple opening and closing of each piece of primary switch equipment last will be required. This will shorten the commissioning and times, and inherent supply cuts to consumers.
[000129] Simulation mode models the operation of switching devices by effectively disconnecting protection relays from the system. Operator HMIs receive simulated system status information as if the system were actually online and operating. Simulated faults can be applied to line sections to test sequences of operation, without changing the physical state of any primary switching device. The performance and functionality of a total FLISR system, including the related communication network, can be tested and evaluated.
[000130] The solution provides a switch over logic in the IED's. IED's were not designed with this functionality in mind. Interlocking also presents problems, but both problems have been overcome by using double-point commands in the IED's. Each IED is equipped with simulation mode. Mode Actions include: Output logic disconnect for open and closed contacts IED, Connection to RS Flip Flop logic, Binary Input Position Status Disconnect, and Position State Connection to RS Flip Flop.
[000131] The system is based on an IED that is typically used as a distribution feeder protection relay with IEC61850 communication. The system can use ready-to-use programming software for the IEDs that is simple to use.
[000132] While the invention is described in terms of various preferred embodiments, it will be appreciated that the invention is not limited to circuit break and disconnect devices. The inventive concepts can be employed in conjunction with any number of devices, including circuit breakers, reclosers, and the like. When faults are detected, circuit breakers are tripped, alarm indications are sent to system control, or other protection schemes can be initiated.
[000133] The logic units used in a total system for microprocessor-based protection devices, as known in the art, may include input transformers, low-pass filters, sample holding amplifiers, multiplexers, programmable gain amplifiers, converters A/D, and the like.
[000134] Point-to-point communication (such as generic object oriented substation event messages (GOOSE) of the IEC 61850 standard) enables distribution relays to communicate with others connected to the communication network without having a master device. As such, a relay can reset the distribution system after a fault occurs depending on programming. Any of a number of point-to-point communication schemes are contemplated here.
[000135] Computer program code to perform operations of the invention described above can be written in a variety of languages for developmental convenience. For example, PLCs can be programmed using application software on personal computers using standards-based programming languages (eg IEC 61131-3). PLCs are usually programmed using application software on personal computers. The computer is connected to the PLC via Ethernet, RS-232, RS-485 or RS-422 cabling. The programming software allows entry and editing of ladder style logic (Ladder Logic Diagram Programming). Stair logic is a programming language that represents a program by a graph diagram based on relay-based logic hardware circuit diagrams. It is mainly used to develop software for Programmable Logic Controllers (PLCs) used in industrial control applications. The name is because programs in this language resemble stairs, with two vertical rails and a series of horizontal steps between them.
[000136] PLC functionality includes, for example, sequential relay control, motion control, process control, distributed control systems and networks. In certain examples, PLRs (programmable logic relays) can be used. More modern PLCs can communicate over a network to some other system, such as a computer that operates a SCADA (Supervisory Control AND Data Acquisition) system, or a web browser. In addition, computer program code for performing operations of the embodiments of the present invention may also be written in other programming languages, such as a dialect that resembles BASIC or C, or another programming language with appropriate bindings for an environment. of real-time application.
[000137] The code in which a program of the present invention is described can be included as a firmware in a RAM, a ROM and a flash memory. Otherwise, the code may be stored on a tangible computer-readable storage medium, such as a magnetic tape, a floppy disk, a hard disk, a compact disk, a photomagnetic disk, DVD. The present invention can be configured for use in a computer, or an information processing apparatus that includes memory, such as a central processing unit (CPU), a RAM and a ROM, as well as a storage medium, such as a hard drive.
[000138] The "step-by-step process" for performing the functions claimed herein is a specific algorithm, and is shown in the descriptive report text as prose and/or in flowcharts. The software program instructions create a special proposal machine to carry out the particular algorithm. In any claim herein in which the disclosed structure is a computer, or microprocessor, programmed to perform an algorithm, the disclosed structure is not the general purpose computer, but rather the general purpose computer programmed to perform the disclosed algorithm.
[000139] A general purpose computer, or microprocessor, can be programmed to perform the algorithm/steps of the present invention creating a new machine. The general purpose computer/microprocessor becomes a special purpose computer as it is programmed to perform particular functions in accordance with instructions from the software program of the present invention. The software program instructions that perform the algorithm/steps electrically change the general purpose computer/microprocessor by creating electrical trajectories within the device. These electrical trajectories create a proposal machine to carry out the particular algorithm/steps.
[000140] While various embodiments of the present invention have been shown and described herein, it will be obvious that such embodiments are provided by way of example only. Numerous variations, changes and substitutions can be made without departing from the invention here. Accordingly, it is intended that the invention be limited only by the spirit and scope of the appended claims.

权利要求:
Claims (20)
[0001]
1. Method for programming and implementing automatic fault isolation and restoration of service in power distribution networks having protective relay devices (14) comprising processing and communication capabilities and associated with switching devices (20), characterized in that comprising, (a) storage, based on a topology of a power distribution network, information to be used in automatic fault isolation and service restoration, comprising operating mode information, system state information, and information of failure; (b) grouping the operating mode information, system status information, and fault information into functional groups for message; (c) programming in each of the protective relay devices (14) a plurality of operating sequences which, when executed, control associated switching devices (20) when a fault detection element identifies a faulty section in the network, wherein each operational sequence is based on operating mode information, system status information, and fault information; (d) sharing the operating mode information, system status information, and fault information, via peer-to-peer messaging between all of the protective relay devices (14), via a high-speed communication system (30); and (e) performing a sequential isolation operation comprising an appropriate operational sequence based on mode information, system state information, and fault information to isolate the faulted section in a series of sequential steps.
[0002]
2. Method according to claim 1, characterized in that the system status information comprises a position of each primary switching device (20) in a feeder.
[0003]
3. Method according to claim 1, characterized in that the fault information comprises detected fault positions, and is used as a trigger to initiate the sequential isolation operation.
[0004]
4. Method according to claim 1, characterized in that the operating mode information comprises one or more of automatic mode, section control mode, restoration mode, storm mode, simulation mode, and mode of load balancing.
[0005]
5. Method according to claim 1, characterized in that the operating mode information comprises one or more automatic mode that provides automatic operation to detect, isolate, and restore faults; section control mode that provides opening of a section of line for pre-programmed logic steps; restore mode which provides restoration to a normal state once the fault has been repaired; storm mode which provides protection change operation as well as operational sequences; simulation mode that provides testing of operational sequences; and load balancing mode which provides indication of a best possible open point on a feeder to distribute a load evenly between two sources (12a, 12b).
[0006]
6. Method according to claim 1, characterized in that the operational sequences comprise logical sequences implemented using a plurality of logical gates.
[0007]
7. Method according to claim 6, characterized in that the logic gates comprise logic AND gates representing a binary information sequence programmed in relay logic which, when filled, will cause an operation of a switching device (20) , and together with the switching devices (20) of the system creates a distributed sequential logical system.
[0008]
8. Method according to claim 7, characterized in that the logic information is configured for a binary output of the relay that is connected to operating circuits of the primary switch (20) to close or open the primary switch.
[0009]
9. Method according to claim 1, characterized in that one or more of reclosers (P2, P3), switches (20) and circuit breakers (P1) are activated to isolate the failing section in a series of sequential steps .
[0010]
10. Method according to claim 1, characterized in that the protective relay devices (14) comprise intelligent devices having a microprocessor and a communication system (30).
[0011]
11. System for programming and implementing automatic fault isolation and restoration of service in power distribution networks, characterized in that it comprises a plurality of protective relay devices (14) in a power distribution network, each device a protective relay (14) comprising a processor and associated with switching devices (20) for fault isolation and restoration of service; a communication device associated with each protective relay device (14) which provides point-to-point communication between the protective relay devices (14), in which the message in the communication device comprises defined functional groups that group operating mode information , system state information, and fault information defined based on a topology of the power distribution network, information to be used in automatic fault isolation and service restoration, in which each communication device provides information-sharing mode. operation, system status information, and fault information, via peer-to-peer messaging between all of the protective relay devices (14), via a high-speed communication system (30); in which each protective relay device (14) has programmed therein a plurality of operational sequences which when executed control the associated switching devices (20) when a fault detection element identifies a faulty section of the network, in which each sequence operating mode is based on operating mode information, system state information, and fault information, such that a sequential isolation operation comprising an appropriate operating sequence based on operating mode information, system state information, and fault information. failure is performed to isolate the failing section in a series of sequential steps.
[0012]
12. System according to claim 11, characterized in that the system status information comprises a position of each primary switching device (20) in a feeder.
[0013]
13. System according to claim 11, characterized in that the fault information comprises detected fault positions, and is used as a trigger to initiate the sequential isolation operation.
[0014]
14. System according to claim 11, characterized in that the operating mode information comprises one or more of an automatic mode that provides automatic operation to detect, isolate and restore failures; section control mode that provides opening of a section of line for pre-programmed logic steps; restore mode which provides restoration to a normal state once the fault has been repaired; storm mode which provides protection change operation as well as operational sequences; simulation mode that provides testing of operational sequences; and load balancing mode which provides indication of a best possible open point on a feeder to distribute a load evenly between two sources (12a, 12b).
[0015]
15. System according to claim 11, characterized in that the operational sequences comprise logical sequences implemented using a plurality of logic gates.
[0016]
16. System according to claim 15, characterized in that the logic gates comprise logic AND gates representing a binary information sequence programmed in the relay logic that when filled will cause an operation of a switching device (20), and together with the switching devices (20) of the system creates a distributed sequential logical system.
[0017]
17. System according to claim 16, characterized in that the logic information is configured for a binary output of the relay that is connected to operating circuits of the primary switch to close or open the primary switch.
[0018]
18. System according to claim 11, characterized in that one or more of reclosers (P2, P3), switches (20) and circuit breakers (P1) are activated to isolate the failing section in a series of sequential steps .
[0019]
19. System according to claim 11, characterized in that the protective relay devices (14) comprise intelligent devices having a microprocessor and a communication system (30).
[0020]
20. A tangible computer-readable medium, characterized in that it comprises instructions that, when executed by a processor, implement the steps as defined in claim 1.

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WO2012141835A9|2013-11-21|

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US9052731B2|2015-06-09|

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WO2012141835A2|2012-10-18|

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US8634175B2|2014-01-21|

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US20140136006A1|2014-05-15|

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US20120265360A1|2012-10-18|

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WO2012141835A3|2012-12-20|

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法律状态:
2018-04-24| B25G| Requested change of headquarter approved|Owner name: SIEMENS INDUSTRY, INC. (US) |

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2018-12-18| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

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2019-08-13| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

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2021-03-09| B06A| Patent application procedure suspended [chapter 6.1 patent gazette]|

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2021-06-08| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

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2021-08-17| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 14/03/2012, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

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申请号 | 申请日 | 专利标题

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US13/085,603|2011-04-13|

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US13/085,603|US8634175B2|2011-04-13|2011-04-13|Method and system for programming and implementing automated fault isolation and restoration using sequential logic|

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PCT/US2012/029028|WO2012141835A2|2011-04-13|2012-03-14|Method and system for programming and implementing automated fault isolation and restoration using sequential logic|

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