西班牙专利ES2539249A2 Recording of operating parameters of an intelligent electronic device

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专利摘要:
The present disclosure provides systems and methods for recording operating parameters of an intelligent electronic device (lED). A system may include a parameter acquisition module, a parameter storage module, and a memory management module. The parameter acquisition module may be configured to periodically obtain operating parameters of an lED at a first interval. The first interval may have a first time length to provide a first resolution of operation of the lED. The parameter storage module may be configured to store the operating parameters. The memory management module may be configured to delete, outside a first resolution period, a first portion of the operating parameters while maintaining a second portion of the operating parameters. The second portion may include operating parameters for each of a second interval. The second interval may have a second time length to provide a reduced second resolution of the operation of the lED.
公开号:ES2539249A2
申请号:ES201590037
申请日:2013-10-29
公开日:2015-06-29
发明作者:O. III SCHWEITZER Edmund；Ronald A. SCHWARTZ；E. WHITEHEAD David
申请人:Schweitzer Engineering Laboratories Inc；
IPC主号:

专利说明:

DESCRIPTION

Registration of operating parameters of an intelligent electronic device.

TECHNICAL FIELD 5

The present disclosure refers to the registration of operating parameters of an intelligent electronic device.

BRIEF DESCRIPTION OF THE DRAWINGS 10

Non-limiting and non-exhaustive embodiments of the disclosure are described herein, including various embodiments of the disclosure illustrated in the figures listed below.
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Figure 1 is a block diagram illustrating an embodiment of a system for recording operating parameters of an intelligent electronic device (IED).

Figure 2 is a block diagram illustrating another embodiment of a system for recording operational parameters of an IED. twenty

Figure 3 is a block diagram illustrating an embodiment of a registration module for recording operational parameters of an IED.

Figure 4 is a block diagram illustrating another embodiment of a registration module 25 for recording operational parameters of an IED.

Figure 5 illustrates an embodiment of exemplary operating parameters obtained by a registration module.
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Figure 6 is a schematic diagram illustrating an embodiment of resolution windows for operational parameters stored by a registration module.

Figure 7 illustrates the exemplary elimination of one part of the operational parameters, while maintaining another part in memory. 35

Figure 8 is a block diagram illustrating an embodiment of a monitoring module for monitoring the operation of an IED.

Figure 9 is a schematic diagram of a flow chart illustrating an embodiment of a procedure for storing operational parameters. 5

Figure 10 is a schematic diagram of a flow chart illustrating another embodiment of a method for storing operational parameters.

In the following description, numerous specific details are provided for a thorough understanding of the various embodiments disclosed herein. The systems and procedures disclosed herein may be implemented without one or more of the specific details, or with other procedures, components, materials, etc. In addition, in some cases, well-known structures, materials or operations may not be shown or described in detail in order to avoid obscuring aspects of the disclosure. In addition, the features, structures or features may be combined in any suitable manner in one or more alternative embodiments.

DETAILED DESCRIPTION 20

Intelligent electronic devices (IEDs) can be used to monitor, protect and / or control industrial and utility equipment, such as in an electrical power supply system. For example, an IED, such as a programmable logic controller (PLC), a protective relay, a real-time automation controller (RTAC), or the like, 25 can monitor, protect and / or control various components within an industrial system or utilitarian, such as an energy supply system (which may include, for example, the generation, transmission, distribution and / or consumption of electrical energy). IEDs can be monitored, controlled and / or managed using any of a wide variety of communication procedures. For example, IEDs can include 30 communication channels that use Ethernet or serial connections, and can implement any of a wide variety of communication protocols and security measures.

As used herein, the term "IED" may refer to any microprocessor-based device 35 that monitors, controls, automates and / or protects equipment.
monitored within a system. Such devices may include, for example, remote terminal units, differential relays, distance relays, directional relays, feeder relays, excess current relays, voltage regulator controls, voltage relays, switch fault relays, generator relays, motor relays, automation controllers, compartment controllers, meters, resetter controls, 5 communications processors, computer platforms, programmable logic controllers (PLCs), programmable automation controllers, input and output modules, motor drives and Similar. In addition, networking and communication devices can be incorporated into an IED, or be in communication with an IED. The monitored equipment may include conductors such as transmission lines, distribution lines, buses and the like, transformers, autotransformers, voltage regulators, tap-changers, capacitor banks, static VAR compensators, reactors, static synchronous compensators, inverters, generators , transmission lines between electric power systems, circuit breakers, switches, motors, fuses, loads and the like. The term IED can be used interchangeably to describe an individual IED or a system comprising multiple IEDs.

IEDs, like any electronic device, are subject to failure, operational errors or other events (IED events). These IED events may be due to normal wear and tear during use, manufacturing defects and / or events that cause damage or accelerated workloads for an IED. These IED events can cause the IED, unexpectedly or unexpectedly, to stop working. In some situations, the failure of an FDI, or other FDI events, can be inconvenient, costly and / or dangerous. For example, in the case of failure of an IED that is used to monitor, control, automate or protect equipment within an electrical power supply system, risks, as well as loss of energy, can result in large numbers of people. Therefore, there may be great interest in reducing the chances of negative FDI events, or in anticipating the failure, so that preventive measures, such as repair or replacement, can be carried out in advance.
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In order to anticipate failures or other events of IEDs or other devices, real-world use and data may be necessary. For example, newly developed FDI, or other products, even if well designed, may have unforeseen problems and vulnerabilities. Furthermore, it can be very difficult to predict the effect of real-world operating circumstances, and it may even be difficult to predict or understand what FDI events could have affected the longevity of an FDI. Therefore, the use
Effective and the recording of data during use can lead to extremely useful data in determining a cause of a failure or other FDI event, as well as in the prediction and / or monitoring of future failures.

In one embodiment, data logging for an IED can be done using event-based tracking 5. For example, data can be recorded during the use of a device and, if an event occurs, a small amount of data can be saved before and / or after the event. Data not sufficiently close in time to the event can be deleted or overwritten. Sometimes, the information is stored in the same memory as other operational data of an IED. 10

Some embodiments of the present disclosure provide and describe the recording of operational parameters of an IED for long periods of time. In some embodiments, events that occur well in advance of an FDI event may also provide information about the FDI event. For example, the trends in the deterioration of a voltage at a specific terminal, or the increase in memory errors for an IED, may be indications that the IED may be slowly declining towards the fault. Some embodiments of the present disclosure provide and describe the recording of operational parameters even if it is not known that those parameters affect the operation or failure of an IED. Some embodiments of the present disclosure 20 provide and describe the storage of operational parameters with different resolutions over time.

According to one embodiment, the instruction and embodiments provided herein may lead to an increased utility of the recorded data. According to one embodiment, the instruction and embodiments herein may allow the identification of events that may have indicated or accelerated events or failures of an IED. According to one embodiment, the instruction and embodiments herein may allow for the early prediction of certain events of an IED.
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Aspects of certain embodiments described herein may be implemented as software modules or components. As used herein, a software module or component may include any type of computer instruction, or computer executable code, located within or on a computer readable storage medium, or a non-transient, readable storage medium. 35 per computer, and may include firmware. A software module, for example, can
comprise one or more physical or logical blocks of computer instructions, which may be organized as a routine, a program, an object, a component, a data structure, etc., that performs one or more tasks or implements specific types of data abstract.
5
Some of the infrastructure that can be used with the embodiments disclosed herein is already available, such as: general purpose computers, computer programming tools and techniques, digital storage media and communications networks. A computer may include a processor, such as a microprocessor, a microcontroller, logic circuits or the like. The processor may include a special purpose processing device, such as an ASIC, a PAL, a PLA, a PLD, a Field Programmable Gate Formation, or other custom or programmable device. The computer may also include a computer readable storage device, such as non-volatile memory, static RAM, dynamic RAM, ROM, CD-ROM, disk, tape, magnetic, optical or flash memory, or other means of computer readable storage.

The phrases "connected with" and "in communication with" refer to any form of interaction between two or more components, including mechanical, electrical, magnetic and electromagnetic interaction. Two components can be connected to each other, even if they are not in direct contact with each other, and even if there may be intermediate devices between the two components. For example, in many cases, a first component may be described herein as "connected" to a second component when, in truth, the first component is connected to the second component by a third component, a cable section, a electric trace, another first component, another second component and / or another electrical component.

Certain components described herein, such as inverters, capacitors, resistors, inductors, input connectors, output connectors, transformers and the like, are described in their broadest sense. One skilled in the art will recognize that various alternative components or configurations can produce an equivalent circuit or an equivalent component. Such modifications are considered within the scope of this disclosure.

The embodiments of the disclosure will be optimally understood with reference to the 35 drawings, in which equal parts are designated with equal numbers throughout their entirety.
extension. The components of the disclosed embodiments, as generally described and illustrated in the figures herein, could be arranged and designed in a wide variety of different configurations. Therefore, the following detailed description of the embodiments of the disclosure systems and procedures is not intended to limit the scope of the disclosure, as claimed, but is merely representative of possible embodiments. In other cases, well-known structures, materials or operations are not shown or described in detail, to avoid obscuring aspects of the present disclosure. In addition, the stages of a procedure should not necessarily be executed in any specific order, or even sequentially, nor should the stages be executed only once, unless otherwise specified.

Although various embodiments and descriptions herein refer to a power supply system, the principles and applications described herein are applicable to various types of industrial, utilitarian, or other computer systems.

Figure 1 is a schematic block diagram illustrating an embodiment of a system 100 for recording operational parameters of an IED. In one embodiment, the system 100 is an electrical energy supply system, or a part of an electrical energy supply system. System 100 includes a registration module 102, a protective relay 104 and memory 106. The protective relay 104 can be an exemplary IED for which operational parameters can be registered. In one embodiment, the protective relay 104 monitors the conductor 108 and / or includes a processor. The protective relay 104 can obtain information from the conductor 108 using, for example, a current transformer (CT), a potential transformer (PT) or the like.

The registration module 102 may register operating parameters of an IED, such as a protective relay 104. The registration module 102 may include a hardware device and / or may include software running on a device. For example, the registration module 102 30 may include hardware separately from the protective relay 104. As another example, the registration module 102 may include hardware integrated within the protective relay 104. In one embodiment, the registration module 102 includes software or firmware running on an IED, such as protective relay 104, an industrial PC, or other IED.
35
In one embodiment, the registration module 102 periodically obtains operational parameters.
of the protective relay 104 in a first interval having a first time duration. Obtaining the operating parameters in the first defined interval can provide a resolution of the operation of the protective relay 104. In one embodiment, the registration module 102 stores the operating parameters. The registration module 102 can store the operating parameters in the memory 106 or in any other location. In one embodiment, the registration module 102 deletes, outside of a first resolution period, a first part of the stored operating parameters and maintains a second part of the operating parameters. The second part may include operational parameters for each second interval. Each second interval can have a time duration greater than the first time duration. The second, longer, time duration may provide a second resolution of the operation of the protective relay 104. The second resolution may have a reduced resolution over that of the first original resolution.

Memory 106 may include any type of memory for information storage. In one embodiment, memory 106 may include magnetic memory such as a magnetic hard disk drive. In one embodiment, memory 106 includes solid state memory such as flash memory. One skilled in the art will understand that, in variable embodiments, any type of memory capable of storing computer readable information can be used. In one embodiment, memory 106 includes external or internal memory to another device. For example, memory 106 may be an external hard disk drive, or it may be an internal hard disk drive, or a memory card stored within another IED.

The protective relay 104 is only one embodiment of an IED for which the operating parameters can be registered. In one embodiment, the protective relay 104 detects faults 25 or other conditions or events of the power system in a conductor 108, which may be, for example, a distribution line or a transmission line, or that performs any other distribution function electric power The protective relay 104 may be a digital and / or analog protective relay. In one embodiment, the conductor 108 is used to transmit energy from one location to another location. In other embodiments, protective relay 30 104 can be replaced with any other type of IED, such as an industrial PC, or the like.

The registration module 102, the memory 106 and the protective relay 104 can be communicated by any means of communication known in the art. In one embodiment, the components 102 to 106 of system 100 communicate using a device bus.
major, a network interface, wired or wireless, or the like. A serial port, a universal serial bus (USB) or another communication port or bus can be used for communication.

Figure 2 is a schematic block diagram illustrating another embodiment of a system 200 for recording operational parameters of an IED 202. Similar to the system 200 of Figure 1, the system 200 of Figure 2 includes a registration module 102 and a memory 106. However, the system 200 also includes multiple IEDs 202, 204, a clock 206 and a remote client 208. Additionally, the registration module 102 is integrated with the IED 202, which also includes the internal memory 210 and a processor 212. The system 10 200 also includes an interface 214, which can allow IEDs 202 and 204, external memory 106, clock 206 and remote client 208 to be communicated. In one embodiment, remote client 208 is communicates with the registration module 102 via interface 214, via network 216.
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IED 202 and additional IEDs 204 may be any type of IED, such as remote terminal units, differential relays, distance relays, directional relays, feeder relays, excess current relays, voltage regulator controls, voltage relays, switch failure relays, generator relays, motor relays, automation controllers, compartment controllers, meters, resetter controls, 20 communication processors, computer platforms, programmable logic controllers (PLCs), programmable automation controllers, input and output modules, motor impellers and the like. The IED 202 includes an integrated registration module 102, the internal memory 210 and the processor 212. The IED 202 can perform one or more monitoring, protection or control functions within the system 200. According to one embodiment, the processor 212 and memory 210 is used by IED 202 to execute instructions corresponding to its function within system 200. In one embodiment, memory 210 is used to store instructions to be executed by processor 212, as well as other information. Additional FDI 204 may also be any of the FDI described above. In one embodiment, both IED 202 and additional IEDs 204 30 are protective relays and each protects equipment of the power system, such as conductor 108. According to one embodiment, additional IEDs 204 are part of an inherited distribution system. electric power The IED 202 may be an updated IED 202 that performs a similar, protection or management function, to that of the IED 204.
35
The registration module 102 is included within the IED 202. In one embodiment, the module of
register 102 is an individual hardware device mounted within an IED 202 enclosure. Of course, in other embodiments, the registration module 102 may be externally mounted to an IED 202. In one embodiment, the registration module 102 is mounted alone. partially within the FDI. The registration module 102 may be connected to an internal communication bus of the IED 202. In one embodiment, the registration module 102 5 includes electrical connections with a circuit within the IED 202. For example, the electrical connections, or others, with parts of a circuit, or with other internal elements of the IED, may allow the registration module 102 to collect information, such as voltages, current and / or temperature, in different locations without consulting IED 202. The registration module 102 may be wired in parallel or in series to a bus or circuit within IED 10 202.

In one embodiment, the registration module 102 includes instructions to be executed by the processor 212. The instructions of the registration module 102 can be stored in the internal memory 210 or in the external memory 106. The registration module 102 can operate at the level of a real-time operating system, or it can operate as a virtual machine.

In one embodiment, the registration module 102 is used to record operational parameters of the host IED 202. For example, the registration module 102 can obtain operational parameters 20 from the IED 202 and store them in internal memory 210 and / or in external memory 106. The registration module 102 may store operating parameters in memory, regardless of the memory used by the IED 202. Storage in the external memory and / or the backup of operating parameters may allow a reduced probability of loss after an IED failure. 202. 25

In one embodiment, the registration module 102 is used to record operational parameters of the additional IEDs 204. A registration module 102 performed in software instructions may include a virtual machine for each of the IEDs 202 and 204. The registration module 102 may include a hardware device that communicates with the additional IEDs 204 30 via an interface 214. For example, the registration module 102 may request operational parameters from the additional IEDs 204.

The external clock 206 may provide redundancy for the clocks within the IEDs 202 and 204. The external clock 206 may be used to verify errors in an IED clock 202 and 35 204. For example, the registration module 102 may use the external clock 206 to verify the
precision of the clock, the fluctuation of the clock and the like, of the clocks of the IEDs 202 and 204. In one embodiment, the time of the external clock 206 is recorded with operational parameters, to ensure accurate registration of the event of FDI events. The external clock can provide a common time for each of the IEDs in the network. The common time can be obtained from a universal time, such as that obtained using GPS, or from the signals of the 5 WWV or WWVB radio stations. The common time can be provided by a local common time source, such as the time of a communication network, or a time server.

Remote client 208 can be used to access IEDs 202 and 204, as well as external memory 106, and external clock 206. For example, remote client 208 can be used to extract information stored by any of the other components. in system 200, or it can be used to change configurations, monitor or perform other administrative actions in system 200. For example, remote client 208 may be able to access data stored by register module 102. In one embodiment, remote client 208 receives notifications or other information from IEDs 202 and 204, memory 106 and / or clock 206. Thus, a user may not need to be at the headquarters of IEDs 202 and 204 to check their operational status or View your current or past operational parameters. Remote client 208 may include a device, an Internet browser or another client. Exemplary remote clients 208 include a computing device such as a desktop computer, a laptop, a tablet computer, a smartphone, or the like.

Remote client 208 may be located in a remote location with respect to IEDs 202 and 204. For example, remote client 208 may communicate with IEDs 202 and 204 via a network 216, such as a local area network, a network Wide area or Internet. The network 216 can be connected via the interface 214 with the IEDs 202 and 204, the external memory 106 and / or the clock 206. The interface 214 can include any means of communication or cable known in the art, as well as using any protocol . Interface 214 can be an Ethernet interface, wireless or wired.
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Figure 3 is a schematic block diagram illustrating an embodiment of a registration module 102. The registration module 102 includes a parameter acquisition module 302, a parameter storage module 304 and a memory management module 306. The registration module 102 can record operating parameters of an IED such as the protective relay 104 of Figure 1, or the IEDs 202 and 204 of Figure 2. 35

In one embodiment, the parameter acquisition module 302 obtains operational parameters from an IED. The parameter acquisition module 302 can obtain the operating parameters in a periodic interval. The periodic interval may have a first time duration, so that the parameter acquisition module 302 obtains operating parameters approximately once for each first time duration 5. The operating parameters can therefore provide a first operating resolution of the IED. For example, if the parameter acquisition module 302 obtains operational parameters every millisecond, the operational parameters can provide a resolution of one millisecond of the operation of the IED.
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The parameter acquisition module 302 can obtain operational parameters by requesting operational parameters from an IED. In one embodiment, the parameter acquisition module 302 can send a request to another device, or to an IED, such as a host IED 202, a protective relay 104 or other IED 204. The request can be sent by a bus or port of Communications, internal or external. In one embodiment, the request may be sent by a communications interface 214, such as an Ethernet interface. The parameter acquisition module 302 can receive one or more messages with information regarding operating parameters. In one embodiment, an IED can be configured to send operating parameters only when requested. The parameter acquisition module 302 can receive operating parameters from an IED according to a fixed schedule. For example, parameter acquisition module 302 can receive operational parameters from an IED at certain times without sending a request.

In one embodiment, the parameter acquisition module 302 obtains operational parameters by sampling a voltage, a current, a temperature or the like, at a location within an IED. The registration module 102 may be at least partially mounted within an IED and the parameter acquisition module 302 may sample a location within the IED to obtain operational parameters. For example, the parameter acquisition module 302 can sample a voltage through a connection with a location within an IED circuit. In one embodiment, the parameter acquisition module 302 may have a connection with a bus or other location within the IED, where the parameter acquisition module 302 can obtain operational parameters by collecting data during the operation of the IED. For example, the parameter acquisition module 302 may be able to obtain data by direct connection, without requiring the IED to perform a specific operation to send to the parameter acquisition module
302 operational parameters.
The parameter acquisition module 302 may be a software module operating within an IED. According to one embodiment, the parameter acquisition module 302 receives operational parameters from another process running in an IED. For example, a process in the IED can track the occurrence of bit errors, voltages at specific locations in a circuit, connection attempts, or the like. The parameter acquisition module 302 can receive information from the process and thereby obtain operational parameters.

The operating parameters obtained by the parameter acquisition module 302 10 can vary considerably. According to one embodiment, the parameter acquisition module 302 obtains hardware operating parameters or, in other words, data regarding the hardware of the IED. Exemplary hardware operating parameters may include voltages, currents, impedances, temperatures or the like. The hardware operational parameters can be obtained by directly sampling an operational parameter 15 or receiving a report of an operational parameter from an IED. For example, hardware operating parameters may be obtainable with or without IED processing activity. This may allow a parameter acquisition module 302 to obtain data without stopping an IED, or without the IED even needing to know that operational parameters are being collected. As another example, an IED may be able to obtain 20 hardware operating parameters on its own, so it may be more cost effective to receive these operating parameters from the IED.

According to one embodiment, the parameter acquisition module 302 obtains software operating parameters or, in other words, data regarding the operation of the software and / or the transmission or storage of data. Exemplary operating parameters of the software may include the activity of a processor or other component, the time of the clock, the accuracy of the clock, the fluctuation of the clock, the origin of the clock, the currently connected individuals, the connections attempted, the changes of configuration, information regarding the operation of a communication port, software bit errors (memory errors) or the like. In one embodiment, the software parameters can only be obtained by receiving a message from the IED, by a parameter acquisition module 302, which includes code executing in the IED. For example, a registration module 102 that is a hardware device independent of an IED may need to request and / or receive operational parameters from the IED. 35

The operating parameters obtained by the parameter acquisition module 302 may include effective parametric values. For example, the operating parameter for an output voltage from a power supply can be 120.32 volts. Alternatively, or additionally, the operational parameters may include an indicator 5 indicating whether or not a parameter is within a predefined operating window. For example, an operational parameter may include a ‘1’, a ‘Yes’, a ‘Truth’, or another indicator to indicate that an effective current voltage is within an acceptable range. In one embodiment, a parametric value can be considered as normal within a certain range and can be seen as not worthy of any extra memory to store an effective value. In other embodiments, the effective value may be stored to provide more accurate data that may be useful in rebuilding what may have caused an IED to fail. The parameter acquisition module 302 that obtains the operating parameters may include comparing an operating parameter with the predefined operating window. fifteen

In one embodiment, the parameter acquisition module 302 obtains all the operational parameters of interest in each interval. For example, the parameter acquisition module 302 can obtain a current parameter value or indicator for each operating parameter. In another embodiment, the parameter acquisition module 302 may obtain some operating parameters less frequently than in each interval. For example, some operational parameters may not require storage of the total resolution provided by the interval.

Figure 5 illustrates an embodiment of a report 500 of operating parameters 502 25 obtained by the parameter acquisition module 302. The labels 504 indicate a meaning of the operating parameters 502. According to one embodiment, the report 500 includes operating parameters 502 which have been obtained in a predetermined interval. For example, each of the operating parameters 502 may correspond to the time of the "IED Clock" and "Recorder Clock" parameters. 30

Operating parameters 502 may include a wide variety of different types of parameters. Operating parameters 502 may include a voltage of a power supply input. Operating parameters 502 may include a voltage of a power supply output. Operating parameters 502 may include a voltage of 35 a node within a circuit. Operating parameters 502 may include a
temperature of a process and / or the percentage activity of the processors. Operating parameters 502 may include a current time of an IED clock, a register module clock and / or a source used to update the IED clock or the register module clock. Operating parameters 502 may include values indicating whether or not a current clock accuracy and / or a clock fluctuation are acceptable. Operational parameters 502 may include a list of users that are currently connected to an IED or other system. Operating parameters 502 may include a total number of connections in the last hour and / or a number of failed connection attempts. Operating parameters 502 may include information regarding configurations that have changed, and who made the changes. Operating parameters 502 may include the availability of one or more communication ports. Operating parameters 502 may include a certain number of software bit errors since the last interval, or in a last predetermined amount of time. Software bit errors may include errors in the memory that have been detected and / or fixed.
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The operating parameters 502 of Figure 5 are provided for illustrative purposes only. Numerous operating parameters 502, additional or alternative, can be obtained and / or stored in various embodiments. For example, currents, impedances or voltages can be obtained at locations within an electrical circuit, the operating status of chips or other systems, or other information. In one embodiment, the operational state of a communications port or channel can be obtained. For example, a report that includes round trip delay measurement, measurement of channel asymmetry and lost packet totals may be included as part of report 500 of Figure 5. The operating parameters 502 obtained may vary in FDI base. For example, different operating parameters can be collected, for a protective relay 25, than for an RTAC. Similarly, fewer operating parameters, or additional operating parameters, may be included, depending on the level of detail required regarding the operation of a desired IED.

Returning to Figure 3, the parameter storage module 304 can store any 30 operating parameters, obtained by the parameter acquisition module 302. The parameter storage module 304 can store the operating parameters in internal memory to the registration module 102 , internal memory 210 in an IED and / or external memory 106. According to one embodiment, the parameter storage module 304 stores the operating parameters in independent memory. For example, the parameter storage module 304 can store the parameters
operating in memory separately from a memory used by a monitored IED or a registration module 102.
The parameter storage module 304 can store the operating parameters in a wide variety of formats. The parameter storage module 304 may store the operating parameters in a report format, such as that illustrated in Figure 5. The parameter storage module 304 may store the operating parameters in a table. For example, an individual row may correspond to operating parameters corresponding to the same interval, and different columns may correspond to different values for operating parameters. In one embodiment, for example, a row of a table may correspond to the report 500 of Figure 5 and a column may correspond to the voltages of the power supply over time. The parameter storage module 304 can store the operating parameters in a database, or with any other format.

In one embodiment, memory management module 306 manages the storage of the 15 operating parameters. The memory management module 306 can maintain or eliminate operating parameters to support different resolutions of operating parameters, depending on how old the operating parameters are. Reducing a resolution of stored operating parameters can reduce the amount of memory required. For example, by reducing the amount of operating parameters stored outside one or more resolution windows 20, the amount of required memory 106 or 206 of a system 100, 200 can be reduced. The memory management module 306 can delete operational parameters at times determined, to maintain variable resolutions for multiple resolution windows.
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According to one embodiment, the memory management module 306 deletes a portion of the operating parameters, as the operating parameters reach a certain age. For example, memory management module 306 can clear some operational parameters by releasing the corresponding memory for use. The memory management module 306 can delete, outside a first resolution period, a first part of the operating parameters 30, while maintaining a second part of the operating parameters. In one embodiment, the operating parameters stored for the time period corresponding to the first resolution period have a higher first resolution, while the stored operating parameters corresponding to a time period outside the first resolution period have a lower resolution. . The second part that is kept in memory may include operational parameters for each of a
Second interval The second interval may have a second time duration to provide a second reduced resolution, with respect to the first resolution, of the operation of the IED. For example, if the first resolution is twice as high as the second resolution, the second interval can be twice as long as the first interval, and a set of every two sets of operating parameters can be erased. Any other ratio between deleted and non-deleted operating parameters can also be used.

In one embodiment, the memory management module 306 also deletes, outside a second resolution period, a part of the second part of the operating parameters, while maintaining a third of the operating parameters. The third part of the 10 operating parameters may include operational parameters for each third interval having a third time duration, to provide a reduced third resolution of the operation of the IED. Thus, according to one embodiment, the resolution of the stored operating parameters begins at a first resolution and is consecutively reduced to a second resolution and a third resolution. fifteen

Figure 6 is a schematic diagram 600 illustrating exemplary resolution windows 602 to 608. The resolution windows include a first resolution window 602, a second resolution window 604, a third resolution window 606 and a fourth resolution window 608. Each resolution window 602 to 608 may include a time duration and a resolution. According to one embodiment, the time duration is a period of time represented by a time window and a resolution is the frequency of operational reports stored in memory.

According to one embodiment, the resolution windows 602 to 608 represent temporary windows 25 where different operating parameter resolutions are maintained by the memory management module 306. The arrow 610 indicates the most recent instant in time, while the locations on the left they correspond to previous moments in time. For example, arrow 610 may indicate the present, while the first resolution window 602 represents the last hour, the second resolution window 604 30 represents the last twenty-four hours, until the last hour, the third resolution window 606 represents the last year, until the last twenty-four hours, and the fourth resolution window 608 represents a period prior to the last year.

According to one embodiment, the first resolution window 602 is a period of time 35 where most of the operating parameters per unit of time are retained in the
memory. For example, the number of operational parameters, or reports of operational parameters, stored in a given time duration, can be reduced in the second resolution window 604, the third resolution window 606, and beyond. In one embodiment, the first resolution window 602 maintains operational parameters at a resolution of 1 per millisecond. For example, a report that includes all 5 operational parameters can be obtained by the parameter acquisition module 302, and stored by the parameter storage module 304, once every millisecond. An interval in which the parameter acquisition module 302 obtains operational parameters can determine the resolution of the first resolution window.
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According to one embodiment, as the operating parameters age, the memory management module 306 deletes a portion of the operating parameters. For example, as operational parameter reports pass from the first resolution window 602 to the second resolution window 604, the memory management module 306 can delete a portion of these reports to maintain a resolution corresponding to a resolution window 15 Current for operational parameters. The memory management module 306 can erase all operating parameters, except one set per minute, as the operating parameters move to the second resolution window. Similarly, additional deletions may occur as the data ages towards the third resolution window 606 and the fourth resolution window. Thus, one report can be stored per millisecond during the first resolution window 602, one report per minute can be stored during the second resolution window 604, one report per day can be stored during the third resolution window 606, and only abnormal data they can be stored during the fourth resolution window 608. Abnormal data may only include data that is located in time near an error, or a change in value, or other event that is out of the ordinary. In one embodiment, the abnormal data can never be deleted during a life cycle of a corresponding FDI.

The temporal durations and resolutions of the resolution windows 602 to 608 are only 30 copies. For example, any other resolution or time duration for each of the resolution windows 602 to 608 can be used without limitation. In one embodiment, the temporal durations of the resolution windows 602 to 608 increase as the period covered goes back to the past. For example, the second resolution window 604 may have a time duration greater than the first window of resolution 602. In one embodiment, the temporal resolutions of the windows of
Resolution 602 to 608 decrease. For example, the second resolution window 604 may have a resolution lower than that of the first resolution window 602.

Figure 7 illustrates the exemplary removal of a portion of operating parameters from a portion of memory 700. The portion of memory 700 may include a portion of memory 5 within internal memory 210 or external memory 106. The memory portion 700 is shown hosting reports of operating parameters 702 to 704. According to one embodiment, the reports include deleted reports 702, which are to be deleted as reports age from one resolution window to the next, and reports maintained 704, They can be kept in memory. 10

Reports maintained 704 are shown and include every fourth report, while deleted reports 702 include three out of four reports. This forms a 1/3 ratio between deleted and maintained reports. This proportion is exemplary only, and may vary. For example, the ratio between reports maintained and deleted, between the first resolution window 602 and the second resolution window 604 in Figure 6 can be 1 / 59,000, because the resolution changes from one per millisecond to one per minute ( 1,000 milliseconds per second and 60 seconds per minute).

The memory management module 306 can delete the deleted reports 702. The memory management module 306 can keep the reports kept 704 in the memory unchanged. For example, reports maintained 704 can be stored without any modification to the data. In one embodiment, the maintained reports 704 may be modified to include averages for parametric values based on the deleted reports 702. For example, the operational parameters of a maintained report 704 may be averaged and / or combined with the operational parameters of three of deleted reports 702.

An operational parameter can be averaged by adding the values of a certain number of operating parameters and dividing by the number of added operational parameters. For example, an operational parameter of the percentage of processing activity for four different reports can be added and divided by four to give an average percentage of the processor activity. An operational parameter can be combined by adding operational parameters. For example, an operational parameter of the software bit errors for four different reports may be added to create the operational parameter 35 for a maintained report 704. In one embodiment, an operational parameter may
be combined by performing a logical operation "O" or "NO-O". For example, an operational parameter of the acceptable accuracy of the clock for a report maintained 704 may be "No" or "False" if any one of four different reports has a "No" or "False" value. Similarly, an operational parameter of the acceptable accuracy of the clock for a report maintained 704 may be "Yes" or "True" if any one of four different reports has a value of 5 "Yes" or "True".

The embodiment of the registration module 102 of Figure 3, set forth above, can provide a range of advantages according to some of the above variations. For example, data regarding the operation of an IED can be maintained for long periods of time. With the use of variable resolution windows, data for long periods of time can be stored with low memory requirements. Maintaining data for long periods may allow trends or causes of FDI events that occurred long before an FDI event to be recognized. For example, if an IED fails, a large amount of data can be analyzed to determine the cause or factors that contributed to the failure of the IED. A technician or other user may be able to identify an abnormality that occurred hours, days or months before the failure of the IED. Similarly, long-term trends for operational parameters can be evaluated to see how an FDI works as it ages. Thus, the registration module 102 of Figure 3 can support better collection and better data storage, allowing a better understanding of the operation and the causes of events within an IED.

Figure 4 is a schematic block diagram illustrating another embodiment of a registration module 102. Similar to Figure 3, the registration module 102 of Figure 4 includes a parameter acquisition module 302, a module of storage of parameters 304 and a memory management module 306. Modules 302 to 306 may have any of the variations or functionalities set forth herein. The registration module 102 also includes a communication module 402 and a monitoring module 404. In some embodiments, the registration module 102 30 of Figure 3 may also include the communication module 402 and / or the monitoring module 404.

Communication module 402 can provide functionality for registration module 102, to communicate with other modules, devices or systems. For example, communication module 352 may enable register module 102 to communicate with the relay.
protector 104 and / or external memory 106 of Figure 1. Similarly, communication module 402 can enable communication with external clock 206, network 216, remote client 208 and IEDs 204 of Figure 2.

In one embodiment, communication module 402 includes hardware and / or software to communicate with other modules, devices or systems, using any protocol or interface. Communication module 402 can communicate with other devices, modules or systems, using an Ethernet connection and an Ethernet protocol, or any other interface and any other network, wired or wireless protocol. Similarly, other interfaces, buses and / or protocols can be used. The communication module 402 10 can send and / or receive messages for the other modules 302 to 306 and 404. For example, the communication module 402 can send messages to the IEDs requesting operational parameters. As another example, communication module 402 can send notifications to another device or system, such as remote client 208, regarding the operation of registration module 102 or a monitored IED. fifteen

In one embodiment, the communication module 402 may include a remote access module 406. The remote access module 406 may support access to the registration module 102 from a remote location. For example, the remote access module 406 may allow access to the configurations of the registration module 102, the stored operating parameters 20, or the like, to a remote client 208, over a network such as a local area network (LAN) , a wide area network (WAN) or the Internet. The remote access module 406 can serve a Web page or other visual interface for a user to connect and / or access the registration module 102.
25
The monitoring module 404 can monitor the operation of one or more FDI. In one embodiment, the monitoring module monitors said one or more FDI by comparing the operating parameters with one or more monitoring rules. The monitoring module 404 can detect the occurrence of an IED event, defined by the rules, and / or perform an action defined by the rule. The monitoring module 404 can provide a notification to a remote client 208.

Figure 8 is a schematic block diagram illustrating an embodiment of a monitoring module 404. The monitoring module 404 can monitor FDI, detect FDI events and / or perform defined actions. The 404 monitoring module 35 includes an 802 rule module, an 804 detection module and a notification module
806

In one embodiment, the 802 rule module stores one or more rules that define one or more IED events. For example, rule module 802 may store a rule that defines a certain change in operating parameters, a trend in operating parameters or another event, such as an IED event. The rules may define FDI events corresponding to causes of immediate failure and / or FDI events that correspond to events that have or indicate long-term impacts on an FDI.

The 802 rule module can support the modification of the rules. For example, a user 10 on a remote client 208 may be able to connect to a registration module 102, or an IED, and add, delete or modify rules stored by the rule module 802. A user can recognize an IED event additional that it would be useful to detect in an IED, and you can add a new rule, to be stored by the 802 rule module, which defines that IED event. In one embodiment, the 802 rule module provides an interface for viewing and / or modifying rules.

In one embodiment, the detection module 804 compares the operating parameters with the rules stored by the 802 rule module. For example, the detection module can compare the rules with operating parameters obtained by the parameter acquisition module 302. The Detection module 804 can detect an IED event based on a comparison of a rule with the operating parameters. The monitoring module 404 can activate an action in response to detection by the detection module 804 of an IED event. An action undertaken by the monitoring module 404 may include sending a notification, modifying a configuration, energizing an IED, or the like.

In one embodiment, notification module 806 notifies a user or device of an occurrence of an IED event. For example, the notification module 806 can send a message, using a communication module 402, to a remote client 208. The notification 30 may include information regarding the occurrence of FDI, including its severity, the time of occurrence and the like. The notification may be an alarm that indicates that a failure, or other event of FDI, has taken place, or is predicted to take place. Remote client 208, or a user of remote client 208, may be able to take action based on the notification. 35

Figure 9 is a schematic diagram of a flow chart illustrating an embodiment of a method 900 for recording operational parameters of an IED. The procedure 9 can be performed by a registration module 102, such as the registration module 102 of Figures 3 or 4.
5
The procedure 900 may include obtaining, by the parameter acquisition module 302, the operational parameters of an IED. The operating parameters can be obtained 902 in a defined range, which can result in a first resolution of the operation of the IED. The parameter acquisition module 302 can obtain 902 the operational parameters by directly sampling a part of a circuit, or by listening on a bus or interface of an IED. In one embodiment, the parameter acquisition module 302 obtains 902 the operational parameters by requesting and / or receiving operational parameters from an IED, through a communication interface. For example, parameter acquisition module 302 can obtain 902 operating parameters by sending or receiving a message over an Ethernet connection. fifteen

The method 900 may include the storage, by the parameter storage module 304, of operational parameters. The parameter storage module 304 can store 904 the operating parameters obtained 902 by the parameter acquisition module 302 in an internal or external memory to an IED. In one embodiment, parameter storage module 304 stores 904 operating parameters in independent memory. For example, independent memory can be a memory device or a part of memory that is not used by an IED. The storage 904 of the operating parameters in independent memory can reduce the chance of loss of the operating parameters in the case of FDI failure. 25

Figure 10 is a schematic diagram of a flow chart illustrating another embodiment of a method 1000 for recording operational parameters of an IED. Steps 902 to 904 and 1002 to 1020 are only exemplary and may not be included in all embodiments. In fact, different embodiments may include any one, or a combination of two or more of any of steps 902 to 904 and 1002 to 1020 of procedure 1000.

Procedure 1000 includes obtaining 902, by the parameter acquisition module 302, of operational parameters of an IED. Obtaining 902 of the operating parameters 35 can be performed with any of the variations set forth in relation to Figure 9,
or elsewhere in this disclosure. In one embodiment, obtaining 902 of the operational parameters includes the request 1002, for the parameter acquisition module, of operational parameters. For example, parameter acquisition module 302 can send a request, to an IED, for operational parameters. Obtaining 902 of the operating parameters may include the receipt 1004, by the acquisition module of 5 parameters 302, of the operating parameters. For example, the parameter acquisition module 302 can receive the operational parameters in a message from an IED.

Obtaining 902 of the operative parameters may include comparison 1006, by the parameter acquisition module 302, of an operative parameter with an operative window 10. The operating window can be a range for the operating parameter that is considered normal. For example, if it is considered normal for an input voltage of a power supply to be between 115 and 125 volts, the parameter acquisition module 302 can compare a current voltage reading with the normal range between 115 and 125 volts. If the operating parameter is within the normal range, an indicator indicating that the operating parameter is normal can be obtained and / or stored.

Procedure 1000 may include storage 904, by a parameter storage module 304, of operational parameters. The storage 904 of the operative parameters can be performed with any of the exposed variations 20 in relation to Figure 9, or elsewhere in the present disclosure.

The procedure 1000 may include the removal 1008, by a memory management module 306, of a portion of the operating parameters, and the maintenance of other operational parameters in memory. The memory management module 306 can erase 25 1008 the part of operating parameters outside a first resolution period, to reduce the stored operation resolution for the IED, up to a second resolution. The part of the operating parameters that are not deleted can include parameters for each of a second interval. For example, memory management module 306 can erase 1008 all reports, except one, for a second interval. As another example, if the original resolution is 1 report per millisecond and the next resolution is 1 report per second, the memory management module can erase 1008 all reports, except one for every second.

Procedure 1000 may also include additional reductions in resolution. In one embodiment, the procedure 1000 includes the elimination 1010, by a management module
of memory 306, of an additional part of operating parameters. The memory management module 306 can erase 1010 the additional part of the operating parameters outside a second resolution period, to reduce the stored operation resolution for the IED, up to a third resolution. The part of the operating parameters that are not deleted can include parameters for each of a third interval. For example, the memory management module 306 can erase 1010 all reports, except one, for the third interval. As another example, if the second resolution is 1 report per second and the next resolution is 1 report per hour, memory management module 306 can erase 1010 all reports, except one, for every hour.
10
Procedure 1000 may include monitoring 1012 of one or more FDI. In one embodiment, a monitoring module 404 can monitor 1012 an IED to detect problems or problematic IED events. Monitoring 1012 of one or more IEDs may include storage 1014, by an 802 rule module, of one or more rules that define IED events. The rules may define FDI events corresponding to 15 causes of immediate failure and / or FDI events that correspond to events that have, or indicate, long-term impacts on an FDI. For example, an IED event defined by a rule may indicate that, probably, an IED will fail soon. In one embodiment, monitoring 1012 of one or more FDI includes the detection, by a detection module 804, of an IED event, based on one or more of the stored rules 1014. 20 Monitoring 1012 of one or more FDI it may include providing 1018 a notification of the occurrence of the detected IED event 1016. For example, providing 1018 a notification may include sending a message to a remote client 208, or to another device.

The method 1000 may include provision 1020, by a remote access module 406, 25 for remote access to stored data. In one embodiment, remote access module 406 provides 1020 remote access to devices in a remote location. The remote access module 406 can provide 1020 remote access to devices located remotely, over a network, such as a LAN, a WAN or the Internet. The remote access module 406 can provide 1020 remote access by providing a Web page, 30 or other interface, for a user to connect to a registration module 102, or an IED, using a remote client 208.

The foregoing description provides numerous specific details for a thorough understanding of the embodiments described herein. However, the 35 skilled in the art will recognize that one or more of the specific details may be
omitted, modified and / or replaced by a similar process or system.

5

权利要求:
Claims (25)
[1]

1. A system for recording operational parameters of an intelligent electronic device (IED), comprising:
an IED that operates within an electrical power supply system; and 5
a registration module comprising:
a parameter acquisition module, configured to periodically obtain operational parameters of an IED in a first interval having a first time duration, to provide a first operation resolution of the IED;
a parameter storage module, configured to store the operative parameters 10; Y
a memory management module, configured to delete, outside of a first resolution period, a first part of the operating parameters, while maintaining a second part of the operating parameters, in which the second part comprises operating parameters for each second interval with a second time duration, 15 to provide a second reduced resolution of the operation of the IED.

[2]
2. The system of claim 1, wherein the parameter storage module is configured to store the operating parameters in independent memory.
twenty
[3]
3. The system of claim 1, wherein the registration module is integrated with the IED.

[4]
4. The system of claim 1, wherein the registration module comprises discrete hardware, separately from the IED. 25

[5]
5. The system of claim 4, wherein the registration module is at least partially mounted within the IED.

[6]
6. The system of claim 5, wherein the registration module communicates with the IED 30 via an internal bus.

[7]
7. The system of claim 4, wherein the registration module is externally mounted to the IED and communicates with the IED through a communication interface.
35
[8]
8. The system of claim 6, wherein the communication interface comprises a
Ethernet connection

[9]
9. The system of claim 1, wherein the registration module is configured to store operational parameters of one or more additional IEDs.
5
[10]
10. The method of claim 1, wherein the IED comprises a digital protective relay.

[11]
11. The method of claim 1, wherein the stored operating parameters are remotely accessible. 10

[12]
12. The method of claim 1, wherein the second part of the operating parameters comprises modified operating parameters, wherein the modified operating parameters comprise modified operating parameters based on the first deleted part of the operating parameters. fifteen

[13]
13. The method of claim 12, wherein the modified operating parameters comprise averaged values of operating parameters, based on the first part deleted.
twenty
[14]
14. The method of claim 12, wherein the modified operating parameters comprise combined values of operating parameters, based on a logical operation on the first part.

[15]
15. An apparatus for recording operating parameters of an intelligent electronic device 25 (IED) in an electrical power supply system, the apparatus comprising:
a parameter acquisition module, configured to periodically obtain operational parameters of an IED, in a first interval having a first time duration, to provide a first operation resolution of the IED;
a parameter storage module, configured to store the operational parameters 30; Y
a memory management module, configured to delete, outside of a first resolution period, a first part of the operating parameters, while maintaining a second part of the operating parameters, in which the second part comprises operating parameters for each second interval, with a second time duration, 35 to provide a second reduced resolution of the operation of the IED.

[16]
16. A non-transient, computer-readable medium, with instructions encoded therein, the instructions being configured to be executed by a processor to:
periodically obtain operational parameters of an IED in a first interval that has a first time duration, to provide a first operating resolution of the IED;
store operating parameters; Y
delete, outside of a first resolution period, a first part of the operating parameters, while maintaining a second part of the operating parameters, in which the second part comprises operating parameters for each second interval, with a second time duration , to provide a second reduced resolution of the operation of the IED.

[17]
17. A procedure for monitoring an intelligent electronic device (IED) in an electrical power supply system, the procedure comprising:
periodically obtain operational parameters of an IED in a first interval that has a first time duration, to provide a first operation resolution of the IED, the IED being configured to manage the operation of a part of an electrical power supply system; Y
store a part of the operating parameters in independent memory, for a 20-year cycle of IED life.

[18]
18. The method of claim 17, further comprising deleting, outside a first resolution period, a first part of the operating parameters, while maintaining a second part of the operating parameters, wherein the second part 25 comprises operational parameters for each second interval with a second time duration, to provide a second reduced resolution of the operation of the IED.

[19]
19. The method of claim 18, further comprising deleting, outside a second resolution period, a part of the second part of the operational parameters 30, while maintaining a third of the operational parameters for each third interval with a third temporary duration, to provide a third reduced resolution of the operation of the IED.

[20]
20. The method of claim 19, wherein the first time duration 35 comprises approximately one millisecond, the second time duration comprises
approximately one second and the third temporary duration comprises approximately one day.

[21]
21. The method of claim 17, further comprising requesting operational parameters from the IED. 5

[22]
22. The method of claim 21, wherein the request for operational parameters comprises making the request through a communication interface.

[23]
23. The method of claim 22, wherein the communication interface 10 comprises an Ethernet connection.

[24]
24. The method of claim 17, wherein the operating parameters comprise an indicator indicating whether or not a parameter is within a predefined operating window. fifteen

[25]
25. The method of claim 24, wherein obtaining the operating parameters comprises comparing an operating parameter with the predefined operating window.
twenty

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同族专利:

公开号 | 公开日

ES2539249R1|2016-03-08|

ES2539249B1|2016-12-27|

US9581976B2|2017-02-28|

US20140128999A1|2014-05-08|

CA2890200A1|2014-05-08|

AU2013338156A1|2015-05-14|

WO2014070712A3|2014-07-03|

MX2015004673A|2015-08-07|

WO2014070712A2|2014-05-08|

BR112015009923A2|2017-12-12|

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优先权:

申请号 | 申请日 | 专利标题

US13/668,737|US9581976B2|2012-11-05|2012-11-05|Recording of operating parameters of an intelligent electronic device|

US13/668,737|2012-11-05|

PCT/US2013/067224|WO2014070712A2|2012-11-05|2013-10-29|Recording of operating parameters of an intelligent electronic device|

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