巴西专利BR112013001568B1 CONTINUOUS GROUNDING SYSTEM FOR USE IN AN ALTERNATE CURRENT SYSTEM INCLUDING A TRANSFORMER, ELECTRIC

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专利摘要:
continuous uninterruptible ac grounding system for power system protection. The present invention relates to a continuous grounding system for use in an alternating current system that includes a transformer. the system includes a switch assembly connected between a transformer neutral of a transformer and a ground, the switch assembly having an open position and a closed position, the open position interrupting the path through the switch assembly between the electrical connection and the transformer neutral, and the closed position establishing a path connecting the electrical connection in the transformer neutral through the switch assembly, where in normal operation of the AC electrical device the switch assembly remains in a closed position. the system also includes a dc blocking component positioned in parallel with the tap-changer assembly and connected between the transformer neutral and ground. the system further includes a control circuit configured to control the switch assembly, the control circuit including a sensor configured to actuate the switch assembly to an open position upon detection of a predetermined harmonic signal threshold in one of the transformer phases. or a predetermined dc current threshold between the transformer neutral and ground.
公开号:BR112013001568B1
申请号:R112013001568-3
申请日:2011-07-19
公开日:2021-08-03
发明作者:Frederick R. Faxvog；Wallace Jensen；Gale Nordling；Greg Fuchs；David Blake Jackson；Terry Lee Volkmann；James Nicholas Ruehl；Brian Groh
申请人:Emprimus, Llc；
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专利说明:

[0001] This application is being filed on July 19, 2011, as a PCT International Patent Application in the name of Emprimus, Inc., a US national company, applicant for designation of all countries except the US, and Frederick R. Faxvog, Wallace Jensen, Gale Nordling, Greg Fuchs, David Blake Jackson, Terry Lee Volkmann, James Nicholas Ruehl, and Brian Groh, all US citizens applying for US designation only. CROSS REFERENCE TO RELATED REQUESTS
[0002] The present application claims priority from US Provisional Application Number 61/366,088, filed July 20, 2010, US Provisional Application Number 61/408,319, filed October 29, 2010, US Provisional Application Number 61/430.388, filed on January 6, 2011, US Provisional Application Number 61/437,498, filed January 28, 2011, US Provisional Application Number 61/486,635, filed May 16, 2011, and US Utility Application Number 13/159,374, filed on June 13, 2011. Descriptions of these applications are hereby incorporated by reference in their entirety. FIELD OF TECHNIQUE
[0003] The present description refers generically to an electrical protection device for electrical equipment; specifically, the present invention relates to a continuous, uninterruptible AC grounding system usable for power system protection. BACKGROUND
[0004] Electrical equipment, and specifically electrical equipment that operates using alternating current, is subject to varying signals and input conditions. In typical arrangements, AC devices in the United States expect to receive a 60 Hz power line source (or 50 Hz in Europe) having a predetermined magnitude (eg 120 Volts). Although these power sources can vary slightly, devices made for use with a specific current can typically handle some slight variation in the received power signal.
[0005] In some cases, a power signal can vary widely due to harmonics or other external conditions. Harmonics and near-DC currents can be a result of, for example, Geomagnetic (Solar) storms or other electrical equipment, such as switching power sources, arc equipment, welding equipment, etc., which are in the same power grid or local power circuit. Harmonics and near-DC currents can cause the input voltage and current (and resulting energy) of a power signal to vary dramatically, causing the potential for damage to electrical equipment connected to that power source.
[0006] For example, it is widely recognized that geomagnetic storms or the E3 pulse associated with a high altitude electromagnetic pulse (HEMP) can induce dc or near dc currents called Geomagnetic Induced Currents (GIC) in components of generation, transmission systems , and high voltage power distribution, that is, power transmission lines and power transformers. These DC currents can cause half-cycle saturation in power transformer cores which in turn can result in excessive reactive power losses, heating, damage and/or failure of such transformers. In addition, half-cycle saturation can cause harmonics to be generated from the primary frequency (50 or 60 Hz). This harmonic content in turn can cause power system relays to trip, which can decouple required compensating components. This in turn can result in the collapse of local or wide-area portions of an energy grid.
[0007] Over approximately the last two decades, several suggested proposals to reduce currents induced by GIC or HEMP (E3) in power systems have been proposed. These solutions generally take one of a few forms. A first class of solutions uses a capacitive circuit to simultaneously provide the AC ground path and a lockout for induced DC currents. These solutions generally include a set of switches that allow switching between a normal grounded transformer connection and a ground through the capacitive circuit. These solutions can allow you to unintentionally open ground connections to the transformer neutral, or require expensive electronics to handle ground fault conditions. These capacitive circuit solutions may require readjustment of power system relay settings compared to current operating parameters.
[0008] A second class of solutions generally include the continuous use of active components used to reduce the potentially harmful GIC events of DC or near DC currents in the transformer neutral-to-ground connection. These solutions typically require expensive power electronics, and are constantly on, so any failure would make these systems unreliable.
[0009] A third class of solutions generally uses a resistive proposal in which fixed value resistors are used to continuously reduce the DC current in the neutral-to-ground connection of a transformer; however in these proposals, the resistor typically must have a high resistance value and would only reduce, not eliminate the neutral DC or near DC current. In addition, during installation of these classes of solution a readjustment of the power system relay settings may be required. As such, there is no solution that provides a reliable, low-cost protection circuit compatible with current power supply systems.
[00010] For these and other reasons, improvements are desired. SUMMARY
[00011] According to the following description, the above and other problems can be solved by the following: In a first aspect, a continuous grounding system for use in an alternating current system that includes a transformer is described. The system includes a switch assembly connected between a transformer neutral ground connection and a ground, the switch assembly having an open position and a closed position, the open position interrupting the path through the switch between the electrical connection and the earth connection, and the closed position establishing a path connecting the electrical connection to the earth connection through the switch assembly, wherein in normal operation of the alternating current electrical device the switch assembly remains in a closed position. The system also includes a DC blocking component positioned in parallel with the switch assembly and connected between the transformer neutral and ground. The system further includes a control circuit configured to control the switch assembly, the control circuit including a sensor configured to actuate the switch assembly to an open position upon detection of a harmonic signal over one or more transformer power phases. or a predetermined limit of DC current between the transformer neutral and ground.
[00012] In a second aspect, an electrical protection circuit is described. The electrical protection circuit includes a switch assembly connected between a ground connection of a transformer neutral and a ground, the switch assembly having an open position and a closed position, the open position interrupting the path through the switch between the connection. electrical connection and the earth connection, and the closed position establishing a path connecting the electrical connection to the earth connection through the switch assembly, wherein in normal operation of the alternating current electrical device the switch assembly remains in a closed position. The electrical protection circuit also includes a DC blocking component positioned in parallel with the switch assembly and connected between the transformer neutral and earth. In the circuit, the switch assembly is movable between the closed position and the open position via an electronic control input, the electronic control input actuating the switch assembly to an open position upon occurrence of a harmonic signal on one or more transformer power phases or a predetermined limit of dc current between the transformer neutral and ground.
[00013] In a third aspect, a method to protect electrical equipment in an alternating current circuit from damage due to direct current or harmonic effects is described. The method includes holding a switch assembly in a closed position during normal operation of the alternating current circuit, the switch assembly electrically connected between the electrical equipment transformer neutral and a ground. The method further includes, when detecting either a harmonic signal above a predetermined threshold or a DC current above a predetermined threshold, opening the switch assembly, thereby blocking the DC current by an electrically connected DC blocking component in parallel. with the switch assembly between the earthing connection of the electrical equipment and the earth.
[00014] In a further aspect, a method for testing an electrical protection circuit is described. The method includes opening a switch assembly connected between a transformer neutral and a ground, and injecting an alternating current voltage of a frequency other than a transformer voltage frequency over the transformer neutral. The method further includes measuring a current through a DC blocking component while injecting the alternating current voltage, and determining whether the measured current represents an electrical characteristic within a preset limit. If outside the preset limit, the method includes indicating the presence of a fault in the electrical protection circuit.
[00015] In another aspect, a method for method for testing an electrical protection circuit includes injecting a direct current signal over the transformer neutral, determining whether a switch assembly connected between a transformer neutral and a ground opens in response. to the direct current signal, and, if the switch assembly fails to open, indicate the presence of a fault in the electrical protection circuit.
[00016] In another aspect, a method for method for testing an electrical protection circuit includes injecting a harmonic signal into the harmonic sensor, determining whether a switch assembly connected between a transformer neutral and a ground opens in response to the harmonic signal, and, if the switch assembly fails to open, indicate the presence of a fault in the electrical protection circuit.
[00017] In still a further aspect, the electrical equipment support includes an upper surface that has an open structure, a plurality of support legs that maintain the upper surface at an elevation above the ground, the support legs mounted on one or more grounded stakes, and electrical equipment positioned on the top surface and electrically connected between a high-energy transformer ground bushing and the ground. BRIEF DESCRIPTION OF THE DRAWINGS
[00018] Figure 1 is a schematic front plan view of a protected transformer using the methods and systems described herein;
[00019] Figure 2 illustrates an exemplary embodiment of an electrical protection circuit usable within a continuous earthing system, according to a possible embodiment of the present description, as installed in a power generation or distribution site;
[00020] Figure 3A illustrates a continuous grounding system that includes a second exemplary embodiment of an electrical protection circuit, according to a possible embodiment of the present description;
[00021] Figure 3B illustrates a continuous grounding system that includes a second exemplary embodiment of an electrical protection circuit, according to a possible additional embodiment of the present description;
[00022] Figure 4 illustrates a method for self-testing a direct current blocking device, according to a possible embodiment of the present description;
[00023] Figure 5 illustrates an additional exemplary embodiment of an electrical protection circuit, according to a possible embodiment of the present description;
[00024] Figure 6 illustrates an exemplary embodiment of an electrical protection circuit that includes varying levels of resistance, according to a possible embodiment of the present description;
[00025] Figure 7 illustrates a second exemplary embodiment of an electrical protection circuit that includes varying levels of resistance, according to a possible embodiment of the present description;
[00026] Figure 8 illustrates an additional exemplary embodiment of a continuous grounding system that uses a resistive and capacitive circuit network, according to a possible additional embodiment of the present description;
[00027] Figure 9 illustrates an additional exemplary embodiment of a continuous grounding system, in accordance with the principles of the present description;
[00028] Figure 10 is a perspective view of an exemplary electrical equipment support, according to a possible embodiment of the present description; and
[00029] Figure 11 is a schematic front view of the electrical equipment support of Figure 10 having an electrical equipment mounted on it, according to a possible embodiment of the present description. DETAILED DESCRIPTION
[00030] In general, the present description describes systems and methods to protect power utility transformers and other electrical or electromechanical equipment from harmful DC currents and as a result of harmonic content in a power line. Large dc neutral currents and harmonic voltages can be the result of geomagnetic (solar) storms, high altitude electromagnetic pulse E3 (HEMP-E3) or other electrical equipment such as switching power supplies, welding equipment. arc, plasma cutting, electrical discharge machining equipment, arc lamps, etc., which are on the same power grid or local power circuit. Overall, this description describes methods and systems for detecting harmonic content of a 50 Hz or 60 Hz power line source, and potentially damaging neutral DC currents, to allow critical electrical equipment to be switched to an operating mode protective in case such harmonics or DC currents are detected.
[00031] According to various embodiments described herein, the protection of high voltage power systems from GIC (solar storms) and EMP E3 pulses is achieved using an uninterruptible continuous AC grounding circuit which utilizes a blocking mechanism. Switch-controlled DC to eliminate geomagnetic and EMP induced currents (E3 pulse). A DC blocking component (which includes one or more capacitors, resistors or combinations thereof) is wired in place to provide an uninterruptable AC ground path for HV power systems, for example at the neutral of HV transformers or auto-transformers set to "Y". Under normal operation a second parallel ground path provides a standard, very low impedance ground path through a closed switch assembly.
[00032] The continuous grounding systems described herein provide a grounding scheme that is compatible with standard transformer grounding schemes and as such will require no change to power system relay settings. When either high dc (or near dc) currents or a high harmonic energy content are detected, a switch assembly is opened, thereby blocking or attenuating the dc or near dc current in the system. Blocking near DC or DC currents prevents half-cycle saturation of transformers and thereby protects them from excessive reactive power losses, overheating and damage. In addition, blocking DC currents prevents the generation of harmonics in partially saturated transformers. Such power harmonics can potentially trip power system relays, which in turn can cause local or wide-area power outages. Furthermore, in certain embodiments described herein, the electrical protection circuits included in such a continuous earthing system are designed (configured) to handle earth faults under either the normal or protective GIC operating mode.
[00033] Figure 1 is a schematic front view of an exemplary electrical equipment protected in accordance with the features of the present description, and a physical arrangement of certain components of the present description. In the embodiment shown, a piece of electrical equipment, shown as a high voltage transformer 100, is electrically connected to an electrical protection circuit 102. The electrical protection circuit 102 may, for example, include at least a portion of the devices described below. , according to the modalities shown in Figures 2-9. The high voltage transformer 100 is typically mounted on a concrete block for stability and ground insulation. An electrical protection circuit 102 is electrically connected to high voltage transformer 100 as discussed above, contained within a housing, and placed on electrically grounded supports 103. In addition to protecting against GIC events, all control electronics (semiconductor devices) is contained within an EMP/IEMI shielded housing 104 and electrically filtered electrically connected to the electrical protection circuit 102 and the high voltage transformer 100, and includes a switch detection and control circuit 105. It should be noted that without the housing shielded and filtered 104 the system is capable of protecting transformers against GIC events but not against EMP E3 pulse threats.
[00034] In certain embodiments, electrical protection circuit 102 includes the switch assemblies and DC blocking components discussed in Figures 2-9, while control system 104 contains the switch detection and actuation circuit; however, other component arrangements for an electrical protection device may be provided.
[00035] Referring now to Figure 2, a first generalized embodiment of an electrical protection circuit 200 is shown, in accordance with the present description. Circuit 200 is generally connected between a transformer neutral 10 of a transformer 12 (shown as transformer Y in the embodiment shown) and a ground 14. Electrical protection circuit 200 includes a switch assembly 202 that includes an electrically controlled switch 204 connected. between the transformer neutral 10 and the ground 14. A shunt resistor 206 can be connected between the switch 204 and the ground 14, which can be used to detect the DC current flowing between the transformer neutral 10 and the ground 14 In certain embodiments, shunt resistor 206 would typically have a low resistance, on the order of a few milliohms, to allow for a low impedance ground connection across the switches. In another embodiment, the shunt resistor 206 could be replaced with a Hall-effect current sensor or other non-contact current sensor. In addition, an electrically controlled high voltage ground switch 208 may be connected between transformer neutral 10 and switch 204, for example, to protect switch 204 from high voltages during an earth fault event. In some embodiments, ground 14 may be connected to a station ground grid, while in other embodiments it may be connected to the transformer housing which is in turn grounded.
[00036] Switch 204 can be any of a variety of electrically controlled fast acting switches, such as a high voltage circuit breaker. In the embodiment shown, switch 204 is a normally closed connection which can be quickly opened via an electrical control input an exemplary detection and control circuit that can be connected to the control input is further discussed in connection with Figure 3, below.
[00037] A DC blocking component 210 is connected in parallel with the switch assembly 202 between the transformer neutral 10 and ground 14. As further explained in the drawings below, the DC blocking component 210 may include one or more direct current blocking devices (eg, capacitors or resistors) capable of inserting some blocking of a current path between ground 14 and transformer neutral 10 to prevent harmful dc or near dc currents in the transformer neutral 10 which in turn would cause possible damage to the transformer 12. Depending on the specific application, a blocking device 210 either capacitive or resistive (or some combination thereof could be used in the protection circuit 302. Furthermore, in certain modes, the DC blocking component 210 is wired to ground 14, thereby providing an AC ground for the transformer (or other power component) even if the switches 204 and 208 inadvertently malfunction.
[00038] In normal operation, the transformer neutral 10 is grounded through the switch assembly 202. That is, the switch assembly 202, which includes the switch 204 and the high voltage ground switch 208, is normally in a closed position. This corresponds to the standard grounding configuration used by utilities; consequently, a grounding system as described herein does not require readjustments to the utility electrical equipment to which it is wired prior to use. In this first mode of operation, the DC blocking component 210 is not energized because the switching assembly creates a short around it. If a ground fault is detected while operating in this normal operating mode (no GIC), grounding through the switch assembly will handle the ground fault current until the power system relays isolate the faulty equipment. When the presence of either high energy harmonics or an almost DC current in the neutral-to-ground connection is detected, the switch assembly is opened by the GIC detection and control electronics. In this second mode of operation the DC blocking component 210 provides AC ground to the transformer neutral. This mode of operation protects against the dc or near dc currents associated with either GIC or EMP E3 events. This protective GIC mode remains operational until a power system operator declares that the event is over and closes switch assembly 202 again.
[00039] In some embodiments, to account for an extremely unlikely event that a GIC and ground fault would occur simultaneously, a 212 surge suppressor, sometimes known as a varistor or a MOV (metal oxide varistor) or other such surge suppressor device, would trip to protect the blocking components 210. The switch assembly 208 would then be closed again by a signal from a relay that detects a fault current through the transformer neutral of the current transformer 214 which in turn will trip. the high voltage switch 208 to close again. Therefore surge suppressor 212 provides initial grounding within one earth fault cycle and until tap-changer assembly 202 can be closed again. It is noted that the probability of this simultaneous event (GIC and ground failure) is so small that in practice this may never occur in the lifetime of the system.
[00040] To reduce the cost of the 212 surge suppressor, it may be desirable to use a low cost surge suppressor which is a sacrificial device so that it only protects for one event and then will require replacement. After the surge suppressor has been sacrificed, it by design becomes a short circuit to ground. A second option is to incorporate additional surge suppressors in the initial installation with switches so that if the first suppressor is sacrificed a second can be switched as a replacement as needed. A third option is to incorporate a very heavy duty surge arrestor in the initial installation which will ensure that the surge arrestor will withstand many earth fault events without failing.
[00041] By opening the switch assembly, the DC blocking component 210 shown in Figure 2 provides the AC grounding path to the transformer neutral 10, while at the same time blocking the DC or near DC induced by a storm. geomagnetic or an EMP E3 event. The DC lockout both protects transformer 12 from entering a half-cycle saturation which in turn can cause excessive reactive power losses, overheating, damage or even transformer failure. In addition, DC lockout also prevents the generation of harmonics in the power system which in turn can prevent tripping power relays, disconnecting power compensation components, excessive reactive power loading, and potentially collapse. of either small or large portions of the energy grid.
[00042] Also, to increase the reliability of the 210 DC blocking component, either a parallel bank of multiple capacitors or resistors could be used so that if one or more of these capacitors or resistors failed the others would still be available as components. Block.
[00043] In addition, to protect against the E1 and E2 portions of an electromagnetic pulse (EMP) and/or Intentional Electromagnetic Interference (IEMI), all sensitive detection and control electronics of such a system can be placed within a shielded enclosure and electrically filtered, such as the enclosure containing the control system 104 of Figure 1. All components which are not housed within the shielded enclosure do not contain sensitive semiconductor electronics and would thereby survive an EMP or a IEMI. In an alternative modality where the detection and control electronics are not placed inside a shielded and electrically filtered enclosure, the transformer will still be protected against the geomagnetic induced GIC. Additional details regarding the content of such a wrap are discussed in more detail below.
[00044] Referring now to Figure 3A a continuous grounding system 300 is shown which includes a second exemplary embodiment of an electrical protection circuit 302, in accordance with a possible embodiment of the present description. In this mode, the electrical protection circuit 302 generally corresponds to circuit 200 in Figure 2, but the DC blocking component 208 is illustrated as a capacitor 304. Although in certain embodiments a 15 kV, 3000 uF capacitor is used, other types of capacitors could be used as well.
[00045] Figure 3A also illustrates a detection and control circuit 310, according to a possible embodiment of the present description. The detection and control circuit 310 includes control electronics, such as a detection and control module 312, as well as a current sensing unit 314. A relay control circuit 316 is connected to the detection and control module 312, and generates a switch control output 313 used to actuate switches 204 and 208.
[00046] The 312 detection and control module detects harmonics which are generated in a half-cycle saturated transformer upon a GIC event. For example, module 312 may include a harmonic sensor that will measure the signal from a standard capacitive voltage transformer (CVT) 214 which is located over one of the transformer phases. When the signal from either the neutral DC current or the harmonic sensor exceeds a preset value, a signal is sent to open the two switches in switch assembly 202. The preset values will be selected by utility or system engineers. according to the protection requirements of each specific installation. Typical ranges for preset values of DC or near DC current are expected to be within the range of approximately 5 - 50 A. Typical ranges for preset values of power harmonic levels are expected to be within the range of approximately 1% to 10% of total harmonic distortion (THD). Current sensing circuit 314 measures neutral dc or near dc current caused by a geomagnetic storm through shunt resistor 206, and sends the result of this measurement to sensing and control module 312 to trigger relay control circuit 316 as necessary.
[00047] In the embodiment shown, the control circuit 310 is contained within a shielded envelope 320, and includes a plurality of filters 322 positioned on a periphery of the envelope 320 to prevent high frequency, high energy electromagnetic signals from entering the envelope, thereby exposing the sensitive detection and control electronics to interference and potential damage. Filters 322 may typically be a low-pass or band-pass filter with surge suppression to prevent any high voltage signals from entering the envelope. In the embodiment shown, shielded wrap 322 is an EMP/IEMI faraday shielded wrap with conductive gaskets around all door openings to provide radiative shielding from electromagnetic frequencies typically from approximately 14 kHz to 10 GHz. shown, a filter 322 is positioned over a power input 324, as well as over a CVT input 326, operator inputs and outputs 328, switch control output 313, and current sensing inputs 330 connecting across each. side of the shunt resistor 206. In addition, any fiber communications into and out of the wrap 320 will be filtered through a waveguide penetration in addition to appropriate cutoff, which will inherently provide protection against EMP and de IEMI.
[00048] In operation, when a GIC event is detected by the control circuit 310, the DC low voltage switch, i.e. the switch 204 will be opened by the relay control circuit 316, through the switch control output 313 After this action a signal will open the 208 high voltage ground switch. The 208 ground switch will then typically remain open for the duration of the geomagnetic storm event, typically on the order of a few hours to a day. During this period the DC blocking component 210, in this case capacitor 304, provides the AC ground of transformer neutral 10 of transformer 12. The action of re-closing ground switches 204 and 208 will typically be controlled by the operator of the system. energy after the geomagnetic storm has passed. However, some utility installations may prefer to configure their system to automatically close switches again, for example after a predetermined period of time.
[00049] Referring now to Figure 3B, an additional exemplary embodiment of a continuous grounding system 350 is shown. In this exemplary embodiment, a Hall Effect current sensor could alternatively be used in place of the shunt resistor 206 and the current sensing device 314 to measure the DC current at the neutral-to-ground connection of the transformer. In such modalities, the Hall Effect sensor would be sacrificed by an EMP or IEMI attack. There is also a question whether Capacitive Voltage Transformer (CVT) 214 would similarly be sacrificed by an EMP or IEMI attack.
[00050] To ensure that the transformer protection would continue its protective function under such an attack from an Electromagnetic Field (EM), a detector 352 could be added to this protection system as shown, connecting to the detection and control electronics 312 through of a filter 322. Detector 352 resides outside of envelope 320, and would allow detection of either an EMP E1 or E2 pulse or an IEMI pulse which in turn would be used to open the CC switch 204 and thereby turn on the protection of transformer required. The EM detector 352 could be top mounted on the side of the control housing and connected by shielded conduit to the shielded control electronics 310.
[00051] In various modalities, different types of electromagnetic detectors could be used. In exemplary embodiments, electromagnetic field detectors could include those described in Co-pending US Patent Application Number 12/906,902 entitled "Electromagnetic Field Detection Systems and Methods", the description of which is hereby incorporated by reference in the its entirety.
[00052] In operation, even if the Hall Effect sensor and/or the CVT 214 were damaged or destroyed by an electromagnetic event, the EM detector 352 would open the DC switch 204 which in turn would protect the HV 10 transformer.
[00053] Referring now to Figure 4, a test arrangement 400 using the continuous grounding system 300 of Figure 3 is shown in which a self-test procedure can be performed. In accordance with various embodiments of the present description, test arrangement 400 allows for either manual or automatic testing (e.g., at a preset interval). According to the modality shown, an exemplary test can be performed by opening the switch assembly 202 and injecting a voltage of a frequency different than that of the power system (50 or 60 Hz or its harmonic) into the neutral transformer connection, for example, using an AC 404 voltage source, and simultaneously measuring the current through the capacitor at this test frequency. The value of this current together with the value of the injected voltage gives a measure of the capacitance (or resistance) of the capacitor (or resistor). Capacitance C is simply given by: C = I/®V where I is the current through the capacitor, V is the injected voltage and ® is the angular frequency of the injected voltage (® = 2 πf). For the case of a resistor blocking device the resistance is given by R = V/I. Therefore, if the capacitance (or resistance) measured, at the frequency of the injected signal, is within a nominally acceptable range of its initially installed specified value then this self-test verifies that the capacitor (or resistor) is in working condition and is ready for either a GIC or an EMP E3 event. If the capacitance (or resistance) is outside a given acceptable range then a message will be generated and the protection system needs additional diagnostics to determine the root cause of the non-conforming capacitance reading. And if the capacitor (or resistor), switches or other components are not functioning properly, a replacement order for the defective component or components may be required.
[00054] If a resistor is used as the DC blocking device, a similar self-test can be run as for the capacitor case shown above. In this case, the injected signal would be used to measure the resistance of the resistor to ensure that it meets the specified value.
[00055] To protect against EMP E1 and E2 pulses, the 404, 406, 408 voltage and harmonic injection sources used in this self-test configuration will be housed within shielded envelope 320 with the other sensitive electronics in this test arrangement 400 The 402 current sensor used in this self-test configuration could be a Hall Effect current sensor which as this is a semiconductor device with an integrated amplifier would be sacrificed for a high energy EMP or IEMI event.
[00056] The test arrangement 400 of Figure 4 also illustrates an arrangement in which the test of electronic detection and control electronics could be performed. The test can be run either manually or automatically at a pre-set interval. This additional test can be performed by injecting a DC signal into the transformer neutral connection using a DC injection voltage component 408, thereby creating a DC current through the switch assembly 202 and through the shunt resistor 206. If the detection and control system is working properly, this will simulate the presence of a GIC CC current and cause the switch assembly to open. The switches can then be closed again to return to normal operating mode. In a similar way, a harmonic signal can be injected into the CVT 214 connection of the harmonic signal generator 406, thereby simulating a GIC harmonic event. If the harmonic detection and control electronics are working properly, this will cause the switch assembly to open. The switches can then be closed again to return to normal operating mode.
[00057] Figure 5 illustrates an additional exemplary embodiment of an electrical protection circuit 500, according to a possible embodiment of the present description. In this embodiment, a resistor 502 is positioned in series with capacitor 304 of Figures 3-4 to prevent ferroresonances caused by the combination of capacitor and transformer inductance. In this arrangement, surge suppressor 212 remains in parallel with capacitor 304, but not resistor 502. Typically the resistor resistance would be on the order of a few (0.5-3) ohms or less to match the impedance of capacitor 304. for a 50-60 Hz system. For this mode, all switching components and GIC detection electronics remain the same as those shown in Figures 3-4.
[00058] In Figures 6-7, additional modalities are shown in which varying levels of resistance can be applied as part of the DC blocking component 210. In Figure 6, an electrical protection circuit 600 includes a bank of parallel resistors 602a- c with associated 604a-c switches connected in series with each 602 resistor are used to provide various levels of protection for geomagnetic storms or the E3 portion of an EMP event. The number of parallel 602 resistors and associated 604 switches can be adjusted according to the DC blocking or attenuation range required in the specific installation. In this mode, the control circuit 310 will include a number of preset neutral current and harmonic threshold levels to control the switches which have detected the severity of the event to be able to control the number of resistors 602 that will be switched to service. In the embodiment shown, an additional resistor 601 is included in parallel with resistors 602a-c to ensure some level of resistance when all switches are open.
[00059] In Figure 7, an electrical protection circuit 700 includes a bank of series resistors 702a-c and associated switches 704a-c connected in parallel, which are used to provide various levels of protection for geomagnetic storms or the E3 portion of an EMP event. An additional 701 resistor is positioned in series with the 702a-c resistors to ensure that when the 704a-c switches are closed some resistance remains in the path between transformer neutral 12 and ground 14. The number of resistors 702 in series and associated 704 switches can be adjusted according to the blocking range or DC attenuation required in the specific installation. In this mode the detection and control electronics will again need to be able to detect the severity of the event to be able to control the number of resistors that will be switched to service.
[00060] Figure 8 illustrates an additional exemplary embodiment of a continuous grounding system 800, according to a possible additional embodiment of the present description. The 800 continuous earthing system, compared to those described above, generally includes multiple resistors and switches used to protect transformer 10, for example, from either a high geomagnetic induced current (GIC) or high total harmonic signals in the transformer. Compared to electrical protection system 200 of Figure 2, system 800 includes a voltage divider circuit with interlocking components 810a and 810b in series, with parallel 812a-b surge suppressors and parallel 802a-b switch assemblies. Each of the 802a-b switch assemblies includes an 808a-b high voltage ground switch and an 804a-b DC switch. The use of multiple switch assemblies allows for lower repulsion voltage requirements for the 808a-b high voltage ground switches. Reducing this repulsion voltage requirement allows the use of standard off-the-shelf 808 high voltage ground switches.
[00061] Figure 9 is an additional exemplary schematic illustration of a 900 circuit used in an electrical protection device, according to a possible additional modality. In this mode, circuit 900 is generally analogous to that illustrated in Figure 5, but uses additive resistors connected in series. In this embodiment, a plurality of switch assemblies 904a-c, and 906a-c are connected in parallel, each allowing the connection of one of a series of resistors 902a-c. In the embodiment shown, resistors 902a-c have a typical 2 ohm resistance; however, other resistive values could be used as well. Between each of the resistors, a separate 904a-c and 906a-c switch connects to ground 14. Each 904a-c switch is connected in series with a protective ground switch 906a-c. Specifically, in this mode, more blocking resistor can be added to the circuit by progressively opening switch assemblies 904a-c and 906a-c.
[00062] Although in the embodiments of Figures 6-7 and 9 three resistor arrangements are used, it is understood that additional numbers of resistors could be used as well.
[00063] Although in the embodiments shown certain circuit values are provided, it is recognized that other circuit components or circuit values could also be used consistent with the discussion in the present specification.
[00064] Referring now to Figure 10, an exemplary equipment support 1000 is shown. Equipment bracket 1000 can be used to store and protect the circuit, as shown in Figures 2-9, above, at a power station, or at some other location near the electrical equipment to be protected. In some embodiments, the equipment support 1000 represents one embodiment of a structure on which the electrical protection circuit 102 of Figure 1 can be mounted.
[00065] In the embodiment shown, rig support 1000 includes a platform 1002 supported by a plurality of support legs 1004. Each of support legs 1004 is affixed to and rests on a peg 1006. Each peg 1006 is preferably or hollowed or otherwise submerged below ground, and provides a resilient base on which the equipment support resides.
[00066] Platform 1002 of equipment support 1000 includes an upper surface 1008 that has an open frame 1010 supported by a frame 1012. In some embodiments, the open frame 1010 is gridded, screened, or otherwise arranged in a manner. that water or snow cannot accumulate on this surface. The platform structure will typically be electrically grounded in accordance with energy industry standards.
[00067] In the embodiment shown, the 1000 full bracket is between approximately 1.8 m (6 ft) wide by 0.9 m (3 ft) deep by approximately 3.0 m (10 ft) high. In other embodiments, the 1000 bracket is approximately 3.0 m (10 ft) wide by approximately 1.2 m (4 ft) deep by approximately 3.0 m (10 ft) high. In an additional embodiment, bracket 1000 is approximately 4.8 m (16 ft) wide by approximately 1.2 m (4 ft) deep by approximately 3.0 m (10 ft) high. Other sizes could be used as well.
[00068] In the embodiment shown, equipment support 1000 is constructed of galvanized steel, including support legs and top surface. Poles 1006 may be concrete or some other resilient material including suitable bolt anchors. In alternative embodiments, equipment support 1000 may be constructed of an alternative metal or otherwise rigid and weather resistant material.
[00069] In total, the 1000 equipment stand provides a relatively small footprint and a low-cost structure that can be assembled in a factory and is collapsible for ease of transport. Bracket 1000 is constructed so that it is easy to reassemble at the power substation site.
[00070] As further illustrated in connection with Figure 11, equipment support 1000 is generally constructed to support any necessary electrical protection components that can be used to block harmful DC neutral currents which may arise from or from a geomagnetic storm ( Geomagnetic Induced Current (GIC) or an E3 Pulse associated with an Electromagnetic Pulse (EMP) weapon. The components shown in Figure 11 on bracket 1000 are a 1014 capacitor bank, a 1016 high energy resistor, and a 1018 surge suppressor. The 1014 capacitor bank can include one or more capacitors, and can be any one of a number of different configurations. In an exemplary embodiment, capacitor bank 1014 may correspond to capacitor 304, described above. Resistor 1016 can be, for example, a one ohm power resistor configured to support high current applications. In certain embodiments, resistor 1016 may correspond to power resistor 502 described above.
[00071] In the mode shown, capacitor bank 1014 is connected in series with resistor 1016 between a ground location and a neutral of a high voltage transformer. In some embodiments, resistor 1016 is separated from a ground connection through the equipment support by an insulating block (not shown) placed under resistor 1016 over open frame 1010. Other electrical isolation techniques could be used as well.
[00072] Surge arrestor 1018 is connected between a ground point and the neutral of a high voltage transformer. In some embodiments, surge suppressor 1018 corresponds to surge suppressor 212 described above. In certain embodiments surge suppressor 1018 has a metallic protective case over it which is open at the bottom so that if the suppressor were to enter its pressure release mode, any released gases or debris will be directed towards the ground in such a way not to damage any other equipment. Any equipment housed on the bracket under the surge suppressor will be adequately protected to prevent damage to such devices.
[00073] On the upper left side of bracket 1000 is a 1020 high voltage earthing switch. The 1020 earthing switch is connected to a 1022 motor drive by a shaft 1023 extending from the bottom of bracket 1000. bracket 1000 is a 1024 DC disconnect switch and 1026 shunt resistor. The 1024 DC disconnect switch allows the circuit on bracket 1000 to be disconnected from a high voltage transformer for maintenance.
[00074] Optionally, the control electronics can be included in a location near the 1000 equipment bracket to control one or more of the electrical components. In some embodiments, the control electronics may be housed within an electrically shielded enclosure to prevent damage to the electronics.
[00075] To electrically interconnect the various components, one or more electrical conductors 1050 and the electrical ground conductor 1060 are employed. The 1050 conductor is mounted over several 1030 high voltage insulators. 1040 electrical bushings are also shown on the tops of the capacitors, power resistor, and surge suppressor. EMP and IEMI protected electronics (eg 310 electronics described above) will typically, but not always, be housed within the substation control house (building).
[00076] Also, in certain arrangements, and for safety reasons, bracket 1000 will have a suitable fence around the bottom so that a person cannot enter the area under the bracket.
[00077] Furthermore, although in the equipment shown a specific arrangement of electrical equipment is shown, in alternative embodiments other electronic connections are possible as well. Exemplary electrical connections are illustrated in conjunction with Figures 2-9, above.
[00078] Altogether, it is recognized that various embodiments of the present description provide a number of advantages with respect to circuit protection, specifically with respect to either harmonic signals or DC current signals at a ground connection of an AC electrical equipment, such as as a transformer used for power generation or distribution. For example, blocking the neutral dc or near dc current prevents half-cycle saturation in the transformer core which in turn prevents the transformer from overheating, damaging or failing. In addition, DC blocking also improves power quality by reducing harmonics which can activate power system relays and cause greater instabilities as well as power failures. This greatly prevents utility power system relays from tripping, power offset disconnection, and other critical components, and in turn prevents the partial or total collapse of a power grid in the event of GIC or EMP events.
[00079] The above specification, examples and data provide a complete description of the manufacture and use of the composition of the invention. As many embodiments of the invention can be made without departing from the spirit and scope of the invention, the invention resides in the claims hereinafter appended.

权利要求:
Claims (29)
[0001]
1. Continuous grounding system (200, 300, 350, 400, 500, 600,700, 800, 900) for use in an alternating current system that includes a transformer (12), characterized in that it comprises: (a) a switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) connected between a neutral ground (10) connection of a transformer (12) and a ground (14), the switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) having an open position and a closed position, the open position interrupting the path through the switch between the electrical connection and the earth connection (14), and the closed position establishing a path that connects the electrical connection to the earth connection (14) through the switch assembly (204, 208, 804a-b, 808a-b , 904a-c, 906a-c, 1020, 1024), in which in normal operation of the alternating current electrical device the switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a- c, 1020, 1024) remains in a position closed connection; (b) a DC blocking component (210, 304, 601, 602a-c, 701, 702a-c, 810a-b, 908a-c, 1014) positioned in parallel with the switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) and connected between neutral (10) of transformer (12) and ground (14); and (c) a control circuit (105, 310) configured to control the switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024), the control circuit (105, 310) including a sensor configured to actuate the switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) to an open position upon detection of a signal harmonic in at least one phase of the transformer or a predetermined limit of dc or near dc current between neutral (10) of transformer (12) and ground (14).
[0002]
2. Continuous grounding system (200, 300, 350, 400, 500, 600,700, 800, 900), according to claim 1, characterized in that the DC blocking component (210, 304, 601, 602a -c, 701, 702a-c, 810a-b, 908a-c, 1014) is a capacitor (304) connected in parallel with the switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) between neutral (10) of transformer (12) and ground (14).
[0003]
3. Continuous grounding system (200, 300, 350, 400, 500, 600,700, 800, 900) according to claim 1, characterized in that the control circuit (105, 310) includes a harmonic sensor (312) configured to detect harmonic signals in at least one phase of the transformer.
[0004]
4. Continuous grounding system (200, 300, 350, 400, 500, 600,700, 800, 900) according to claim 1, characterized in that the control circuit (105, 310) includes a current sensor (206, 402) configured to detect the dc or apparent dc current flowing between the neutral (10) of the transformer (12) and the earth (14) through the switch assembly (204, 208, 804a-b, 808a- b, 904a-c, 906a-c, 1020, 1024).
[0005]
5. Continuous grounding system (200, 300, 350, 400, 500, 600,700, 800, 900), according to claim 1, characterized in that the DC blocking component (210, 304, 601, 602a -c, 701, 702a-c, 810a-b, 908a-c, 1014) includes a plurality of resistors (601, 602a-c, 701, 702a-c), each of the resistors selectively added to the DC blocking component (210, 304, 601, 602a-c, 701, 702a-c, 810a-b, 908a-c, 1014) by a switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a -c, 1020, 1024) corresponding.
[0006]
6. Continuous grounding system (200, 300, 350, 400, 500, 600,700, 800, 900) according to claim 5, characterized in that each of the plurality of resistors (701, 702a-c) is connected in series between the neutral (10) of the transformer (12) and the ground (14), and wherein a switch associated with each resistor is connected in parallel with that switch assembly (204, 208, 804a-b, 808a- b, 904a-c, 906a-c, 1020, 1024), whereby the opening of each switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024 ) adds the resistor associated with the DC blocking component (210, 304, 601, 602a-c, 701, 702a-c, 810a-b, 908a-c, 1014).
[0007]
7. Continuous grounding system (200, 300, 350, 400, 500, 600,700, 800, 900) according to claim 5, characterized in that each of the plurality of resistors (601, 602a-c) is connected in parallel between the neutral (10) of the transformer (12) and the earth (14), and wherein a commutator assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020 , 1024) associated with each resistor is connected in series with that switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024), whereby the closure of each switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) adds the resistor associated with the DC blocking component (210, 304, 601, 602a-c, 701 , 702a-c, 810a-b, 908a-c, 1014).
[0008]
8. Continuous grounding system (200, 300, 350, 400, 500, 600,700, 800, 900), according to claim 5, characterized in that by means of which a total resistance of the DC blocking component ( 210, 304, 601, 602a-c, 701, 702a-c, 810a-b, 908a-c, 1014) can be adjusted depending on the severity of DC or apparent DC current or harmonic signal.
[0009]
9. Continuous grounding system (200, 300, 350, 400, 500, 600,700, 800, 900), according to claim 1, characterized in that it further comprises an overvoltage protection element (212, 812a -b, 1018) electrically connected in parallel with the DC blocking component (210, 304, 601, 602a-c, 701, 702a-c, 810a-b, 908a-c, 1014) and between neutral (10) of the transformer (12) and the earth (14), the overvoltage protection element configured to protect against geomagnetic induced currents and concurrent earth faults that occur in the continuous earthing system (200, 300, 350, 400, 500, 600,700 , 800, 900).
[0010]
10. Continuous grounding system (200, 300, 350, 400, 500, 600,700, 800, 900), according to claim 9, characterized in that the overvoltage protection element comprises a surge suppressor.
[0011]
11. Continuous grounding system (200, 300, 350, 400, 500, 600,700, 800, 900) according to claim 1, characterized in that it further comprises a shunt resistor (206, 1026) electrically connected at series with the switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) between the switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) and the earth (14).
[0012]
12. Continuous grounding system (200, 300, 350, 400, 500, 600,700, 800, 900), according to claim 1, characterized in that it further comprises a Hall Effect current sensor connected in series with the switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) between the switch assembly (204, 208, 804a-b, 808a-b, 904a-c , 906a-c, 1020, 1024) and the earth (14).
[0013]
13. Continuous grounding system (200, 300, 350, 400, 500, 600,700, 800, 900) according to claim 1, characterized in that it further comprises a protection switch (208, 808a-b, 906a -c) electrically connected in series with a DC switch (204, 804a-c, 904a-c) between the DC switch and the neutral (10) of transformer (12), the protection switch configured to protect the switch DC against high voltages.
[0014]
14. Continuous grounding system (200, 300, 350, 400, 500, 600,700, 800, 900) according to claim 1, characterized in that the control circuit (105, 310) is housed within a electromagnetically shielded envelope (104, 320), the control circuit (105, 310) further including a plurality of filters positioned on a periphery of the electromagnetically shielded envelope and configured to protect the control circuit (105, 310) from damage by electromagnetic interference , intentional electromagnetic interference (IEMI) and electromagnetic pulse radiation (EMP) impinging on the electromagnetically shielded envelope.
[0015]
15. Continuous grounding system (200, 300, 350, 400, 500, 600,700, 800, 900) according to claim 14, characterized in that the switch assembly (204, 208, 804a-b, 808a -b, 904a-c, 906a-c, 1020, 1024) is located separately from the electromagnetically shielded enclosure while being electrically connected to the electromagnetically shielded enclosure.
[0016]
16. Continuous grounding system (200, 300, 350, 400, 500, 600,700, 800, 900) according to claim 14, characterized in that it further comprises an electromagnetic field detector (352) electrically connected to the circuit (105, 310) and positioned external to the electromagnetically shielded enclosure.
[0017]
17. Electrical protection circuit characterized by the fact that it comprises: (a) a switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) connected between a neutral ( 10) of a transformer (12) and a ground (14), the switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) having an open position and a closed position, the open position interrupting the path through the switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) between the electrical connection and the neutral (10) of transformer (12), and the closed position establishing a conductive path that connects the electrical connection at the neutral (10) of the transformer (12) through the switch assembly (204, 208, 804a-b, 808a-b, 904a- c, 906a-c, 1020, 1024), wherein for normal operation of the alternating current electrical device the switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024 ) remains in a closed position; and(b) a DC blocking component (210, 304, 601, 602a-c, 701, 702a-c, 810a-b, 908a-c, 1014) positioned in parallel with the switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) and connected between the neutral (10) of the transformer (12) and the ground (14); wherein the switch assembly (204, 208 , 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) is movable between the closed position and the open position via an electronic control input, the electronic control input actuating the switch assembly ( 204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) to an open position when a harmonic signal occurs in at least one phase of the transformer or a predetermined DC current threshold or almost DC between neutral (10) of transformer (12) and ground (14).
[0018]
18. Electrical protection circuit according to claim 17, characterized in that the CC blocking component (210, 304, 601, 602a-c, 701, 702a-c, 810a-b, 908a-c, 1014) is selected from the group consisting of: one or more capacitors; and one or more resistors.
[0019]
19. Electrical protection circuit according to claim 17, characterized in that a total resistance of the DC blocking component (210, 304, 601, 602a-c, 701, 702a-c, 810a-b, 908a -c, 1014) is adjustable to accommodate a DC or near DC current severity or harmonic signal severity.
[0020]
20. Electrical protection circuit according to claim 17, characterized in that it further comprises an overvoltage protection element (212, 812a-b, 1018) electrically connected in parallel with the DC blocking component (210, 304, 601, 602a-c, 701, 702a-c, 810a-b, 908a-c, 1014) and between the neutral (10) of the transformer (12) and the ground (14), the configured overvoltage protection element to protect against earth faults that occur concurrently with the protection circuit being in a blocking mode.
[0021]
21. Method to protect electrical equipment in an alternating current circuit from damage due to the effects of direct current or harmonics, characterized in that it comprises: maintaining a switch assembly (204, 208, 804a-b, 808a-b , 904a-c, 906a-c, 1020, 1024) in a closed position during normal operation of the alternating current circuit, the switch electrically connected between a neutral (10) of the electrical equipment and a ground (14); and when detecting either a harmonic signal above a predetermined threshold or an apparent dc or dc current above a predetermined threshold, open the switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024), thereby blocking the apparent DC or DC current to ground (14) through a DC blocking component (210, 304, 601, 602a-c, 701, 702a-c, 810a-b, 908a-c, 1014) positioned electrically connected in parallel with the switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) between the neutral (10) of the equipment electric and the ground (14).
[0022]
22. Method according to claim 21, characterized in that it further comprises, when detecting that the harmonic signal (312) or the apparent DC or DC current is above a second predetermined threshold, activating one or more switches to change the number of DC blocking components included in the path between the transformer's neutral (10) and ground (14).
[0023]
23. Method according to claim 21, characterized in that the detection of a harmonic signal occurs in a harmonic sensor (312) within a control circuit (105, 310) electrically connected to a control input of the switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024).
[0024]
24. Method according to claim 21, characterized in that the detection of a DC or near DC current occurs in a current sensor (206, 402) within a control circuit (105, 310) electrically connected at a switch assembly control input (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024).
[0025]
25. Method for automatically self-testing an electrical protection circuit, characterized in that it comprises the steps of: opening a switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) connected between a neutral (10) of a transformer (12) and a ground (14); injecting an alternating current voltage of a frequency other than a transformer voltage frequency over the neutral (10) of a transformer (12) ;measuring a current through a DC blocking component (210, 304, 601, 602a-c, 701, 702a-c, 810a-b, 908a-c) positioned while injecting the alternating current voltage; measure represents an electrical characteristic within a preset limit; ese outside the preset limit, indicate the presence of a fault in the electrical protection circuit.
[0026]
26. Method according to claim 25, characterized in that the method for testing is automatically performed at a preset interval.
[0027]
27. Method for automatically self-testing an electrical protection circuit, characterized in that it comprises: injecting a direct current signal over the neutral (10) of transformer (12); determining whether a switch assembly (204, 208, 804a -b, 808a-b, 904a-c, 906a-c, 1020, 1024) connected between a neutral (10) of transformer (12) and a ground (14) opens in response to the direct current signal; switch (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) fails to open, indicates the presence of a fault in the electrical protection circuit.
[0028]
28. Electrical equipment support (1000), characterized in that it comprises: an upper surface (1002) having an open frame (1010); a plurality of support legs (1004) that maintain the upper surface at an elevation above from the ground, the support legs mounted on one or more grounded stakes (1006); an electrical equipment positioned on the upper surface and electrically connected between a high energy transformer and the ground (14); wherein the electrical equipment includes: a switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) connected between a neutral (10) of a transformer (12) of a transformer and a ground (14), the switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) having an open position and a closed position, the open position interrupting the path through the switch between the electrical connection and the earth connection (14), and the closed position establishing a path that connects the electrical connection to the earth connection (14) through the switch assembly (204, 208, 804a-b , 808a-b, 904a-c, 906a-c, 1020, 1024) wherein in normal operation of the alternating current electrical device the switch remains in a closed position; and a DC locking component (210, 304, 601, 602a-c, 701, 702a-c, 810a-b, 908a-c, 1014) positioned in parallel with the switch assembly (204, 208, 804a-b, 808a-b, 904a-c, 906a-c, 1020, 1024) and connected between the earth connection and the earth (14).
[0029]
29. Electrical equipment support (1000), according to claim 28, characterized in that it further comprises a control electronics positioned close to the electrical equipment.

类似技术:

公开号 | 公开日 | 专利标题

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同族专利:

公开号 | 公开日

US8878396B2|2014-11-04|

CA2805652A1|2012-01-26|

BR112013001568A2|2016-05-10|

JP2018050465A|2018-03-29|

EP2596565B1|2016-03-23|

WO2012012426A2|2012-01-26|

US20120019965A1|2012-01-26|

EP2596565A2|2013-05-29|

KR20130047741A|2013-05-08|

JP6251322B2|2017-12-20|

JP2016185071A|2016-10-20|

JP6560731B2|2019-08-14|

AU2011282288B2|2015-09-17|

JP2013532937A|2013-08-19|

KR101911417B1|2018-12-19|

CA2805652C|2018-12-04|

AU2011282288A1|2013-02-07|

JP6008853B2|2016-10-19|

WO2012012426A3|2012-05-10|

MX2013000738A|2013-06-28|

CN103222145A|2013-07-24|

CN103222145B|2016-08-17|

HK1186006A1|2014-02-28|

IL224228A|2016-04-21|

DK2596565T3|2016-07-04|

引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

US1865409A|1930-05-28|1932-06-28|Gen Electric|Protective apparatus|

US3619723A|1970-09-30|1971-11-09|Gen Electric|Sensitive peak current detector for ground fault protection circuits|

US3916261A|1974-02-25|1975-10-28|Square D Co|Ground fault protective system including improved impedance detecting means|

JPS5484527U|1977-11-29|1979-06-15|

US4153891A|1977-12-16|1979-05-08|General Electric Company|Transient voltage distribution improving line shield for layer wound power transformer|

US4297738A|1979-10-29|1981-10-27|Electric Power Research Institute, Inc.|Apparatus for and method of detecting high impedance faults on distribution circuits with delta connected loads|

JPH0519805B2|1982-07-13|1993-03-17|Mitsubishi Electric Corp|

JPS6062806U|1983-10-07|1985-05-02|

US4654806A|1984-03-30|1987-03-31|Westinghouse Electric Corp.|Method and apparatus for monitoring transformers|

JP2607648B2|1988-11-24|1997-05-07|株式会社日立製作所|Power converter|

US5179489A|1990-04-04|1993-01-12|Oliver Bernard M|Method and means for suppressing geomagnetically induced currents|

US5136453A|1990-04-04|1992-08-04|Oliver Bernard M|Method and means for suppressing geomagnetically induced currents|

US5390064A|1992-07-07|1995-02-14|American Superconductor Corp.|Current limiters in power utility applications|

JP2513663Y2|1992-08-31|1996-10-09|日新電機株式会社|Neutral point grounding device|

CA2183176C|1995-08-18|2000-10-24|Brian R. Pelly|High power dc blocking device for ac and fault current grounding|

US5684466A|1995-09-12|1997-11-04|The Charles Machine Work, Inc.|Electrical strike system control for subsurface boring equipment|

US5982276A|1998-05-07|1999-11-09|Media Fusion Corp.|Magnetic field based power transmission line communication method and system|

US5930099A|1998-06-30|1999-07-27|Siemens Westinghouse Power Corporation|Grounding arrangement for a powerline system|

US6362628B2|1998-12-21|2002-03-26|Pass & Seymour, Inc.|Arc fault circuit detector device detecting pulse width modulation of arc noise|

JP2001028829A|1999-07-13|2001-01-30|Toshiba Corp|Digital protection relay|

JP3593027B2|2000-12-14|2004-11-24|三菱電機株式会社|High voltage switch circuit failure detection device|

WO2004013951A2|2002-08-05|2004-02-12|Engineering Matters, Inc.|Self-powered direct current mitigation circuit for transformers|

US7529069B1|2002-08-08|2009-05-05|Weems Ii Warren A|Apparatus and method for ground fault detection and location in electrical systems|

JP4474115B2|2003-05-26|2010-06-02|関西電力株式会社|Storage battery discharge characteristics measuring device|

SE527406C2|2004-05-10|2006-02-28|Forskarpatent I Syd Ab|Method and DC diverter for protection of power system against geomagnetically induced currents|

US8849595B2|2005-10-27|2014-09-30|Charles L. Manto|System and method for providing certifiable electromagnetic pulse and RFI protection through mass-produced shielded containers and rooms|

CN2847637Y|2005-11-18|2006-12-13|中国电力科学研究院|Device for suppressing transformer neutral point DC current by capacitance method|

DE102006055575B4|2006-11-21|2016-12-08|Siemens Aktiengesellschaft|Device for flexible energy transmission and for deicing a high voltage line by means of direct current|

CN100517897C|2006-11-24|2009-07-22|华中科技大学|Direct current current-limiting device of neutral point of grounding transformer|

US7589943B2|2007-03-24|2009-09-15|Ramirez Vanessa De Los Angeles|GIC reducer|

CN100574038C|2007-03-30|2009-12-23|马志强|A kind of electric potential compensation process of subduing high-voltage grid transformer neutral point direct current electric current|

US7755869B2|2007-08-22|2010-07-13|Northlake Engineering, Inc.|Ground protection device for electronic stability and personal safety|

CN101207273B|2007-11-15|2011-04-20|上海市电力公司超高压输变电公司|Method for inhibiting voltage transformer noise caused by DC magnetic biasing|

US8300378B2|2008-09-19|2012-10-30|Advanced Fusion Systems, Llc|Method and apparatus for protecting power systems from extraordinary electromagnetic pulses|

US8248740B2|2008-09-19|2012-08-21|Advanced Fusion Systems, Llc|High speed current shunt|

CN201312117Y|2008-12-03|2009-09-16|徐成飞|Neutral point flexible resistor grounding running device for electric network|

CN201345536Y|2009-01-22|2009-11-11|广东省电力工业局试验研究所|Transformer neutral point capacitance-resistance mixed type inhibition direct current device|

WO2010149217A1|2009-06-26|2010-12-29|Abb Technology Ag|Method for protecting transformers, and a transformer|

CA2777814C|2009-10-16|2018-03-27|David Jackson|Electromagnetic field detection systems and methods|

US8537508B2|2010-07-20|2013-09-17|Emprimus, Llc|Sensing and control electronics for a power grid protection system|

US9018962B2|2012-04-25|2015-04-28|Advanced Power Technologies, Inc|Method and apparatus for protecting power transformers from large electro-magnetic disturbances|USRE48775E1|2010-07-20|2021-10-12|Techhold, Llc|Self-testing features of sensing and control electronics for a power grid protection system|

US8537508B2|2010-07-20|2013-09-17|Emprimus, Llc|Sensing and control electronics for a power grid protection system|

US9018962B2|2012-04-25|2015-04-28|Advanced Power Technologies, Inc|Method and apparatus for protecting power transformers from large electro-magnetic disturbances|

US9077172B2|2012-05-21|2015-07-07|Emprimus, Llc|Self-testing features of sensing and control electronics for a power grid protection system|

US9564753B2|2012-05-21|2017-02-07|Emprimus, Llc|Transformer protection circuit and method|

WO2014114339A1|2013-01-24|2014-07-31|Siemens Aktiengesellschaft|Modular multi‑stage inverter comprising surge arrester|

KR102286535B1|2013-02-20|2021-08-05|엠프리머스, 엘엘씨|Overvoltage protection for power systems|

US9136693B1|2013-02-26|2015-09-15|Reliance Controls Corporation|Generator with selectively bonded neutral connection|

JP6251380B2|2013-03-13|2017-12-20|トランスオーシャンセドコフォレックスベンチャーズリミテッド|Breaker design for power system fault tolerance|

CN103220899B|2013-04-01|2015-11-25|中联重科股份有限公司|A kind of screen type variable grounding control device, system, method and engineering machinery|

CN103515929A|2013-09-23|2014-01-15|广东电网公司电力科学研究院|Direct current balancing device|

EP2863236B1|2013-10-18|2019-12-04|ABB Schweiz AG|Test system for high voltage components|

US9396866B2|2013-11-04|2016-07-19|Alberto Raul Ramirez|Blocker of geomagnetically induced currents |

CN104749412B|2013-12-30|2018-04-10|西门子公司|The sampling system of earth leakage protective device|

US9260015B2|2014-01-09|2016-02-16|Ford Global Technologies, Inc.|Method and system for contactor weld detection|

US10107839B1|2014-06-12|2018-10-23|Fiber Optic Sensor Systems Technology Corporation|Fiber optic sensor system for detection of electric currents and other phenomena associated with geomagnetic disturbances|

NL2013296B1|2014-08-01|2016-09-21|Citytec B V|System for distributing electrical energy.|

CN104466907A|2014-11-19|2015-03-25|广州高澜节能技术股份有限公司|Transformer neutral point capacitance type DC blocking device|

WO2016100934A1|2014-12-18|2016-06-23|Ali Mohd Hasan|Apparatus for mitigation of adverse effects of geomagnetically induced currents on transformers|

EP3243251A1|2015-01-06|2017-11-15|Emprimus, LLC|Systems and methods for actuating a transformer neutral blocking system|

US10971922B2|2015-04-23|2021-04-06|New York University|Reduction of geomagnetically induced currents by neutral switching|

EP3230803B1|2015-04-24|2019-11-13|HP Indigo B.V.|Charge roller positioning|

US10126348B2|2015-04-29|2018-11-13|ZTZ Service International, Inc.|Combined on-line bushing monitoring and geo-magnetic induced current monitoring system|

US10451660B2|2015-06-30|2019-10-22|Utopus Insights, Inc.|Monitoring operating conditions of a transformer during major electromagnetic disturbances|

CN105391028A|2015-11-05|2016-03-09|国网四川省电力公司电力科学研究院|Neutral-point direct-current elimination resistance-capacitance device of transformer and method|

US9940519B2|2016-06-24|2018-04-10|Fotonation Limited|Image processing method and system for iris recognition|

CN106129993A|2016-07-11|2016-11-16|国网河南省电力公司郑州供电公司|Distribution network neutral ground structure that 10kV cable rate is higher and earthing method thereof|

CN106199275A|2016-07-22|2016-12-07|安徽亚辉电气自动化有限公司|A kind of device for power quality analysis|

US10985559B2|2017-02-03|2021-04-20|Techhold Llc|Method and system for improved operation of power grid components in the presence of direct current |

CN106990332B|2017-06-06|2019-05-07|国网重庆市电力公司电力科学研究院|A kind of method for locating single-phase ground fault based on power distribution network data processing|

US10530151B2|2018-01-09|2020-01-07|Timothy A Carty|System and method for suppressing electromagnetic pulse-induced electrical system surges|

EP3531523A1|2018-02-23|2019-08-28|General Electric Technology GmbH|Fault handling|

CN108258671B|2018-03-26|2019-06-28|湖南大学|Short circuit current discharge device and method|

CN108711840B|2018-05-30|2019-06-18|湖南大学|A kind of fault current inhibition device and method|

AU2019351145A1|2018-09-28|2021-05-20|Techhold, Llc|Power grid protection via transformer neutral blocking systems and triggered phase disconnection|

CN110994552B|2019-12-05|2021-07-27|华中科技大学|Autonomous switching method of neutral point ground current suppression device of transformer|

US20210367418A1|2020-05-22|2021-11-25|Techhold, Llc|Overvoltage protection assembly|

法律状态:
2018-12-26| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

2019-07-09| B06T| Formal requirements before examination [chapter 6.20 patent gazette]|

2020-04-14| B06A| Notification to applicant to reply to the report for non-patentability or inadequacy of the application [chapter 6.1 patent gazette]|

2021-02-23| B06A| Notification to applicant to reply to the report for non-patentability or inadequacy of the application [chapter 6.1 patent gazette]|

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

2021-08-03| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 19/07/2011, OBSERVADAS AS CONDICOES LEGAIS. PATENTE CONCEDIDA CONFORME ADI 5.529/DF, QUE DETERMINA A ALTERACAO DO PRAZO DE CONCESSAO. |

优先权:

申请号 | 申请日 | 专利标题

US36608810P| true| 2010-07-20|2010-07-20|

US61/366,088|2010-07-20|

US40831910P| true| 2010-10-29|2010-10-29|

US201161430388P| true| 2011-01-06|2011-01-06|

US61/430,388|2011-01-06|

US201161437498P| true| 2011-01-28|2011-01-28|

US61/437,498|2011-01-28|

US201161486635P| true| 2011-05-16|2011-05-16|

US61/486,635|2011-05-16|

US13/159,374|2011-06-13|

US13/159,374|US8878396B2|2010-07-20|2011-06-13|Continuous uninterruptable AC grounding system for power system protection|

PCT/US2011/044536|WO2012012426A2|2010-07-20|2011-07-19|Continuous uninterruptable ac grounding system for power system protection|

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