Transformer isolation response using DC link

文档序号:1821809 发布日期:2021-11-09 浏览:21次 中文

阅读说明:本技术 使用直流链路的变压器隔离响应 (Transformer isolation response using DC link ) 是由 苑春明 杨晓波 R·玛朱姆德 B·贝里格伦 F·迪奎森 潘久平 于 2020-03-27 设计创作,主要内容包括:公开了配电系统的独特的系统、方法、技术和设备。一个示例性实施例是一种交流(AC)配电系统,包括:第一变电站,第一变电站包括第一变压器和保护装置;第一配电网络部分,第一配电网络部分耦接到第一变压器;第二变电站;第二配电网络部分;DC互连系统,DC互连系统耦接在第一配电网络部分和第二配电网络部分之间;以及控制系统。该控制系统被构造成检测第一变压器或输电网络中的故障、将第一配电网络与故障隔离、确定DC互连系统的设定点、以及使用该设定点来操作DC互连系统以便将MVAC的部分从第二配电网络部分传输到第一配电网络部分。(Unique systems, methods, techniques, and apparatus of a power distribution system are disclosed. One exemplary embodiment is an Alternating Current (AC) power distribution system, comprising: the first transformer substation comprises a first transformer and a protection device; a first distribution network portion coupled to a first transformer; a second substation; a second power distribution network portion; a DC interconnection system coupled between the first power distribution network portion and the second power distribution network portion; and a control system. The control system is configured to detect a fault in the first transformer or power transmission network, isolate the first distribution network from the fault, determine a setpoint of the DC interconnection system, and operate the DC interconnection system using the setpoint to transmit a portion of the MVAC from the second distribution network portion to the first distribution network portion.)

1. An Alternating Current (AC) power distribution system comprising:

a first substation comprising a first transformer and a protection device, the first transformer being coupled to a power transmission network;

a first power distribution network portion coupled to the first transformer;

a second substation comprising a second transformer;

a second distribution network portion coupled to the second transformer, the second distribution network portion configured to receive a Medium Voltage Alternating Current (MVAC) from the second transformer;

a DC interconnection system coupled between the first power distribution network portion and the second power distribution network portion; and

a control system configured to detect a fault in the first transformer or the power transmission network, isolate a first distribution network from the fault using the protection device, determine a setpoint of the DC interconnection system after isolating the first distribution network, and operate the DC interconnection system using the setpoint to transmit a portion of the MVAC from the second distribution network portion to the first distribution network portion.

2. The AC power distribution system of claim 1, comprising a second DC interconnection system, wherein the first DC interconnection system is coupled to the second DC interconnection system through a DC power distribution network.

3. The AC power distribution system of claim 1, wherein the control system comprises a substation controller of the first substation and a converter controller of the DC interconnection system, and wherein the converter controller is configured to determine the set points of the DC interconnection system after the substation controller isolates the first distribution network using the protection device.

4. The AC power distribution system of claim 3 wherein said converter controller operates said DC interconnection system to effectively prevent total power interruption of said first power distribution network portion.

5. The AC power distribution system of claim 4 wherein the control system is configured to determine a second setpoint after the converter controller determines a first setpoint, and to communicate the second setpoint to the converter controller, wherein the converter controller is configured to operate the DC interconnection system using the second setpoint instead of the first setpoint.

6. The AC power distribution system of claim 1, wherein the control system is structured to close a tie switch in response to isolating the fault, determine that the second transformer is overloaded, and determine the set point in response to determining that the second transformer is overloaded.

7. The AC power distribution system of claim 1, wherein the control system determines that operating the DC interconnection system using the setpoint did not successfully restore the first power distribution network portion, responsively shed a plurality of non-critical loads, transmit the MVAC from a third power distribution network portion, and reconnect the shed plurality of non-critical loads.

8. A method for fault response in an Alternating Current (AC) power distribution system, comprising:

detecting, with a control system, a fault in a first transformer of a first substation or a power transmission network coupled to the first substation;

isolating, with the control system, a first distribution network portion from the fault using a protection device of the first substation;

after isolating a first power distribution network, determining, with the control system, a setpoint of a DC interconnection system coupled between the first and second power distribution network portions;

receiving, with the DC interconnection system, a Medium Voltage Alternating Current (MVAC) through a second distribution network and a second transformer of a second substation; and

operating, with the control system, the DC interconnect system using the set points to transmit the MVAC from the second power distribution network portion to the first power distribution network portion.

9. The method of claim 8, comprising: operating a second DC interconnection system to transfer power from the second DC interconnection system to the first interconnection system through a DC power distribution network.

10. The method of claim 8, wherein the control system comprises a substation controller of the first substation and a converter controller of the DC interconnection system, and wherein the converter controller is configured to determine the setpoints of the DC interconnection system after the substation controller isolates a first distribution network using the protection device.

11. The method of claim 10, wherein the converter controller is configured to operate the DC interconnection system so as to avoid total power interruption of the first power distribution network portion.

12. The method of claim 11, comprising: determining a second setpoint with the substation controller after determining a first setpoint and transmitting the second setpoint to the converter controller, and wherein the converter controller is configured to operate the DC interconnection system using the second setpoint instead of the first setpoint.

13. The method of claim 8, comprising: closing a tie switch in response to isolating the fault, determining a second transformer overload after closing the tie switch, and determining the set point in response to determining the second transformer overload.

14. The method of claim 8, comprising: determining that operating the DC interconnect system using the setpoint did not successfully restore the first power distribution network portion, shedding a plurality of non-critical loads in response to the determination, transmitting an MVAC from a third power distribution network portion, and reconnecting the shed plurality of non-critical loads.

15. A control system for fault response in a Medium Voltage Alternating Current (MVAC) network, comprising:

a substation controller of a first substation; and

a converter controller of a DC interconnection system, the DC interconnection system being coupled between a first distribution network portion and a second distribution network portion and communicating with the substation controller,

wherein the substation controller is configured to detect a fault in a first transformer of a first substation or a power transmission network coupled to the first substation, and to isolate a first distribution network from the fault using a protection device of the first substation, and

wherein the converter controller is configured to operate a DC interconnection system using setpoints after isolating the first power distribution network and to transmit a Medium Voltage Alternating Current (MVAC) from the second power distribution network portion to the first power distribution network portion.

16. The control system of claim 15, comprising a second DC interconnection system, wherein the first DC interconnection system is coupled to the second DC interconnection system through a DC distribution network.

17. The control system of claim 15 wherein the converter controller operates the DC interconnection system to effectively prevent total power interruption of the first power distribution network portion.

18. The control system of claim 17, wherein the control system is configured to determine a second setpoint after determining a first setpoint, and to communicate the second setpoint to the converter controller, wherein the converter controller is configured to operate the DC interconnection system using the second setpoint instead of the first setpoint.

19. The control system of claim 15, wherein the control system is structured to close a tie switch in response to isolating the fault, determine a second transformer overload, and determine the set point in response to determining the second transformer overload.

20. The control system of claim 15, wherein the control system determines that operating the DC interconnect system using the setpoint did not successfully restore the first power distribution network portion, shed a plurality of non-critical loads in response, transmit an MVAC from a third power distribution network portion, and reconnect the shed plurality of non-critical loads.

Background

The present disclosure relates generally to Medium Voltage Alternating Current (MVAC) power distribution networks. In power distribution systems, redundant transformer capacity is necessary to avoid or limit system downtime following component failure. Some distribution substations are designed with and operate with one redundant transformer (N-1 reliability) or two redundant transformers (N-2 reliability). To give an example of N-1 reliability, a distribution substation may include two high voltage/medium voltage (HV/MV) transformers of equal rated capacity, with peak loads serviced by the substation being less than 60% of the total transformer capacity. If one transformer of the substation has to be isolated due to a component failure or a line failure, the total load of the substation can be served by the remaining transformers. In some urban power grids, distribution substation designs may require N-2 level reliability. For example, if the load of a substation can be served by two transformers of equal rating, two additional transformers need to be installed at the substation. When one transformer fails and one transformer is undergoing maintenance, the total load of the substation can be served by the remaining transformers within their nominal or emergency rated capacity.

Existing MVAC power distribution networks suffer from several shortcomings and drawbacks. The need for increased capacity and the increased demands for network resiliency have created significant challenges. In order to increase network capacity, the conventional approach is to build new substations or to expand existing substations. Building new substations is costly and may not be feasible in some urban areas. Upgrading existing substations requires a significant amount of downtime to replace existing transformers and transmission lines. To increase network resiliency, the conventional approach is to obtain emergency power support from adjacent substations by closing a Normally Open (NO) tie switch. If the required capacity is immediately available from the adjacent substation, the power restoration (service restoration) process may take tens of seconds by closing the NO tie switch. Otherwise, an adjacent substation may take tens of minutes to make the required capacity available by transmitting some load to other feeders. In view of these and other shortcomings in the art, there is a great need for unique apparatuses, methods, systems, and techniques disclosed herein.

Disclosure of illustrative embodiments

In order to clearly, concisely and exactly describe the non-limiting exemplary embodiments of the present disclosure, the manner and process of making and using them, and to enable them to be practiced, made and used, reference will now be made to certain exemplary embodiments (including those illustrated in the drawings), and specific language will be used to describe them. It will nevertheless be understood that no limitation of the scope of the disclosure is thereby intended, and that the disclosure includes and protects such alterations, modifications, and further applications of the exemplary embodiments as would occur to one skilled in the art having the benefit of this disclosure.

Disclosure of Invention

Exemplary embodiments of the present disclosure include unique systems, methods, techniques, and devices for fault response in medium voltage alternating current electrical distribution networks. Further embodiments, forms, objects, features, advantages, aspects, and benefits of the present disclosure shall become apparent from the following description and drawings.

Drawings

Fig. 1-2 illustrate an exemplary medium voltage alternating current power distribution network.

Fig. 3-5 illustrate exemplary processes for fault response.

Detailed Description

Referring to fig. 1, an exemplary Medium Voltage Alternating Current (MVAC) distribution network 100 is illustrated that is configured to receive High Voltage Alternating Current (HVAC) power from a power transmission network 101 and provide the MVAC to a medium voltage load or a medium/low voltage (MV/LV) substation coupled to a feeder line through a feeder circuit. As just one example, network 100 may be an urban power distribution network. It is understood that for certain applications, medium voltage refers to a voltage greater than or equal to 1kV and less than 100kV, high voltage refers to a voltage greater than or equal to 100kV, and low voltage refers to a voltage less than 1 kV. For certain other applications, medium voltage refers to a voltage greater than or equal to 1kV and less than or equal to 72kV, high voltage refers to a voltage greater than 72kV, and low voltage refers to a voltage less than 1 kV. It should also be appreciated that the topology of the network 100 is illustrated for purposes of explanation and is not intended as a limitation of the present disclosure. For example, network 100 may include more or fewer substations, feeder lines, protection devices, tie switches, transformers, or DC interconnect systems, to name a few. Although network 100 is illustrated with a single line diagram, network 100 may be configured to deliver single phase or multi-phase power.

Network 100 includes high voltage/medium voltage (HV/MV) substations 110, 120, and 130, each of which is configured to receive HVAC from power transmission network 101 and provide MVAC to one or more power distribution network components 141, 143, 151, 153, 161, and 163. Each substation of network 100 includes two transformers, a plurality of protection devices, a bus section, tie switches, and a substation controller.

Substation 110 includes transformers 111 and 113, a plurality of protection devices including devices 117 and 119, a substation controller 115, medium voltage buses 114 and 116, and tie switches 112. Each transformer 111, 113 is configured to receive HVAC from network 101, step down the voltage of the HVAC to a medium voltage, and output MVAC. The plurality of protection devices are configured to interrupt or prevent current flow. For example, protection device 117 may be opened to isolate transformer 111 from distribution network portion 141, and protection device 119 may be opened to isolate transformer 113 from distribution network portion 143. As just one example, each protection device and tie switch 112 may include a circuit breaker and intelligent electronics.

The substation controller 115 is configured to communicate with the plurality of protection devices of the substation 110, the tie switch 112, the substation 120, and the DC interconnect system 170. In certain embodiments, the substation controller 115 communicates with a central controller, such as a Distribution Management System (DMS) or a supervisory control and data acquisition System (SCADA). The substation controller 115 communicates with the substation 120 over the communication channel 103 and with the DC interconnect system 170 over the communication channel 175. The communication channels 103 and 175 may be wired or wireless and may use a communication protocol such as the IEC 61850 standard communication protocol. It should be understood that any or all of the aforementioned features of the substation 110 may also be present in other substations disclosed herein.

The substation 120 includes transformers 121 and 123, a plurality of protection devices including devices 127 and 129, medium voltage buses 124 and 126, tie switches 122, and a substation controller 125. Each transformer 121, 123 is configured to receive HVAC from the network 101, step down the voltage of the HVAC to a medium voltage, and output MVAC. The substation controller 125 is configured to communicate with the plurality of protection devices of the substation 120, tie switches 122 and 155, substations 110 and 130, and DC interconnection systems 170 and 180. Substation controller 125 communicates with substations 110 and 130 over communication channels 103 and 105, with DC interconnect system 170 over communication channel 177, and with DC interconnect system 180 over communication channel 185. The communication channels 105, 177 or 185 may be wired or wireless and may use a communication protocol such as the IEC 61850 standard communication protocol.

Substation 130 includes transformers 131 and 133, a plurality of protection devices including devices 137 and 139, medium voltage buses 134 and 136, tie switches 132, and substation controller 135. Each transformer 131, 133 is configured to receive HVAC from the network 101, step down the voltage of the HVAC to a medium voltage, and output MVAC. The substation controller 135 is configured to communicate with the plurality of protection devices of the substation 130, the tie switch 132, the substation 120, and the DC interconnect system 180. The substation controller 135 communicates with the substation 120 over the communication channel 105 and with the DC interconnect system 180 over the communication channel 187. The communication channel 187 may be wired or wireless and may use a communication protocol such as the IEC 61850 standard communication protocol.

Each transformer of each substation is coupled to a distribution network part. The transformer 111 is coupled to the distribution network portion 141. Transformer 113 is coupled to distribution network portion 143. The transformer 121 is coupled to the distribution network portion 151. Transformer 123 is coupled to distribution network portion 153. Transformer 131 is coupled to distribution network portion 161. The transformer 133 is coupled to the distribution network portion 163. The transformer may be coupled to more than one distribution network portion by closing tie switches or by operating a DC interconnection system.

Each distribution network section includes a plurality of busbars, protection devices, feeder lines and loads. For example, the distribution network portion 141 includes a bus 144, a protection device 142, a feeder line 148, and a load 146. Each power distribution network portion may be selectively coupled to another power distribution network portion by a tie switch. The power distribution network portion 141 may be coupled to the power distribution network portion 143 by the tie switch 112. The power distribution network portion 151 may be coupled to the power distribution network portion 153 by one or more of tie switches 122 and 155. The power distribution network portion 161 may be coupled to the power distribution network portion 163 by a tie switch 132. The power distribution network portion 161 may be coupled to the power distribution network portion 153 by tie switches 156 and 167. In certain embodiments, one or more loads may be replaced by a medium/low voltage (MV/LV) substation.

The DC interconnect system 170 includes an AC/AC power converter 171 and a converter controller 173 (also referred to as a DC interconnect system controller). The DC interconnect system 170 may also include one or more transformers and tie switches, to name a few. AC/AC power converter 171 is configured to transmit MVAC between power distribution network portions 143 and 151. The AC/AC power converter 171 may be configured as a back-to-back converter, with two AC/DC power converters positioned in close proximity to each other and coupled by a DC bus. AC/AC power converter 171 may also be configured as a point-to-point system, where two AC/DC power converters are located remotely from each other and coupled to the distribution line. In some embodiments, AC/AC power converter 171 replaces the existing tie switch. In other embodiments, the AC/AC power converter 171 forms a new connection between the power distribution network portion 143 and the power distribution network portion 151. The converter controller 173 is configured to operate the AC/AC converter 171 using either commands received from a central controller (such as set points) or commands based at least in part on local measurements (such as input voltage and current). Controller 173 may be configured to receive measurements from DC link voltage sensors, current sensors, and voltage sensors coupled to the bus adjacent to system 170, to name a few. It should be appreciated that any or all of the aforementioned features of the DC interconnect system 170 may also be present in other DC interconnect systems disclosed herein.

The DC interconnect system 180 includes an AC/AC power converter 181 and a converter controller 183. AC/AC power converter 181 is configured to transmit MVAC between power distribution network portions 153 and 161.

The control system of the network 100 (including the substation controllers, the converter controllers and any central controllers) is configured to operate the controllable devices of the network 100 in order to increase the power capacity and resilience of the network 100. The controllable devices may include AC/AC power converters, protective relays, protective devices, capacitor banks, and voltage regulators, to name a few.

The control system of the network 100 operates the DC interconnection system of the network 100 in order to enable the power capacity of the network 100 to be increased by sharing the transformer capacity with neighbouring substations. Power sharing among substations using a DC interconnection system provides additional transformer capacity (in effect one or more redundant transformers) for each substation. This additional transformer capacity can be used for fast power restoration of healthy parts of the distribution network after a transformer or transmission line failure, thereby increasing network resiliency.

By transferring transformer capacity between substations using a DC interconnection system, additional loads may be added to network 100. For example, if the capacity of the DC interconnection system 170 is 15% of the transformer capacity of the substation 110, the load service capacity of the substation 110 may increase from 60% to 75% of the total transformer capacity.

Under normal operating conditions, the DC interconnect system may actively participate in power distribution system economic dispatch or operate in a static synchronous compensation mode. In one normal operating mode, the total power supply to the loads of the distribution network portions 151 and 153 is shared by the controllable power flow of the transformer 121, the transformer 123 and the adjacent substations through the DC interconnection systems 170 and 180. In a second normal mode of operation, the loads of the distribution network portions 151 and 153 are served by the transformers 121 and 123, and the available capacity of the DC interconnection systems 170 and 180 is used as spinning reserve.

In a fault response mode (where one transformer of substation 120 experiences a fault and is isolated), the loads of the distribution network portions 151 and 153 may be fully serviced by transmitting power using the remaining transformers of substation 120 and being supplied with controllable power from adjacent substations through the DC interconnection systems 170 and 180. It should be understood that any or all of the foregoing features of the network 100 may also be present in other MVAC power distribution networks disclosed herein.

Referring to fig. 2, an exemplary MVAC power distribution network 200 is illustrated that is structured to receive HVAC power from a power transmission network 201 and provide MVAC through feeder lines to medium voltage loads or MV/LV substations coupled to feeder lines. It should be appreciated that the topology of the network 200 is illustrated for purposes of explanation and is not intended as a limitation of the present disclosure. Although network 200 is illustrated with a single line diagram, network 200 may be configured to deliver single phase or multi-phase power.

Network 200 includes HV/MV substations 210, 220, and 230, which are configured to receive HVAC from power transmission network 201 and provide MVAC to distribution network portions 241, 243, 251, 253, 261, and 263. Each substation comprises two transformers, a plurality of protection devices, a tie switch, a bus and a substation controller.

Substation 210 includes transformers 211 and 213, a plurality of protection devices including devices 217 and 219, bus bars 214 and 216, tie switch 212, and substation controller 215. Each transformer 211, 213 is configured to receive HVAC from the network 201, step down the voltage of the HVAC to a medium voltage, and output MVAC. The substation controller 215 is configured to communicate with the plurality of protection devices of the substation 210, the substation 220, the tie switch 212, the DC interconnect system 270, the DC interconnect system 290, and the DMS controller 208. The substation controller 215 communicates with the substation 220 over the communication channel 203; communicate with DC interconnect systems 270 and 290 via communication channels 275 and 292, respectively; and communicates with the DMS controller 208 over the communication channel 206. The communication channels 203, 206, 275 or 292 may be wired or wireless and may use a communication protocol such as the IEC 61850 standard communication protocol. It should be appreciated that any or all of the aforementioned features of the substation 210 may also be present in other substations disclosed herein.

Substation 220 includes transformers 221 and 223, a plurality of protection devices including devices 227 and 229, busbars 224 and 226, tie switch 222, and substation controller 225. Each transformer 221, 223 is configured to receive HVAC from the network 201, step down the voltage of the HVAC to a medium voltage, and output MVAC. The substation controller 225 is configured to communicate with the plurality of protection devices of the substation 220, the substation 210, the substation 230, the tie switch 222, the tie switch 255, the DC interconnection system 270, the DC interconnection system 280, and the DMS controller 208. Substation controller 225 communicates with substations 210 and 230 over communication channels 203 and 205; communicate with the DC interconnect system 270 via a communication channel 277; communicate with the DC interconnect system 280 over a communication channel 285; and communicates with the DMS controller 208 over a communication channel 207. The communication channels 205, 207, 277 or 285 may be wired or wireless and may use a communication protocol such as the IEC 61850 standard communication protocol.

Substation 230 includes transformers 231 and 233, a plurality of protection devices including devices 237 and 239, buses 234 and 236, tie switch 232, and substation controller 235. Each transformer 231, 233 is configured to receive HVAC from network 201, step down the voltage of the HVAC to a medium voltage, and output MVAC. Substation controller 235 is configured to communicate with the plurality of protection devices of substation 230, substation 220, tie switch 232, DC interconnect system 280, and DC interconnect system 294. The substation controller 235 communicates with the substation 220 over the communication channel 205; communicate with the DC interconnect systems 280 and 294 over communication channels 287 and 296, respectively; and communicates with the DMS controller 208 over a communication channel 209. The communication channels 287, 209 and 296 may be wired or wireless and may use a communication protocol such as the IEC 61850 standard communication protocol.

Each transformer of each substation is coupled to the distribution network portion by one or more normally closed protection devices. The transformer 211 is coupled to the distribution network portion 241. The transformer 213 is coupled to the distribution network portion 243. Transformer 221 is coupled to distribution network portion 251. The transformer 223 is coupled to the distribution network portion 253. Transformer 231 is coupled to power distribution network portion 261. The transformer 233 is coupled to the distribution network portion 263.

Each distribution network portion includes a plurality of bus bars, protection devices, and loads. For example, the distribution network portion 241 includes a bus 244, a protection device 242, a feeder 248, and a load 246. Each power distribution network portion may be selectively coupled to another power distribution network portion by a tie switch. The power distribution network portion 241 may be coupled to the power distribution network portion 243 through the tie switch 212. The power distribution network portion 251 may be coupled to the power distribution network portion 253 by one or more of the tie switches 222 and 255. The power distribution network portion 261 may be coupled to the power distribution network portion 263 through the tie switch 232.

Each of the DC interconnection systems of network 200 is coupled by a DC distribution network 202. The DC interconnect systems 270 and 280 each include an AC/AC power converter that includes a DC link between two AC/DC power converters. For example, the AC/AC power converters of DC interconnect system 270 include AC/DC power converters 271 and 279 coupled by a DC link 278. DC link 278 may be a bus or a DC distribution line, to name a few. The DC link of each DC interconnect system is coupled to a DC distribution network 202. Each AC/DC power converter is configured to receive MVAC, convert the MVAC to Medium Voltage Direct Current (MVDC), and output the MVDC to a DC link. Each AC/DC power converter is also configured to receive MVDC from the DC link, convert the MVDC to MVAC, and output the MVAC. The DC interconnect system 270 also includes a converter controller 273 configured to operate AC/DC power converters 271 and 279. The DC interconnect system 280 includes an AC/AC power converter 281 and a converter controller 283. In certain embodiments, network 200 includes a renewable energy source or energy storage system coupled to network 202. For example, network 200 may include an array or set of solar cells coupled to network 202.

The DC interconnect systems 290 and 294 each include a single AC/DC power converter and a converter controller configured to operate the AC/DC power converter. The DC interconnect system 290 includes an AC/DC power converter 291 and a converter controller 293. AC/DC power converter 291 is configured to receive MVAC from power distribution network portion 241, convert MVAC to MVDC, and output MVDC to network 202. AC/DC power converter 291 is further configured to receive MVDC from network 202, convert MVDC to MVAC, and output MVAC to power distribution network portion 241. Converter controller 293 is configured to operate AC/DC power converter 291. AC/DC power converter 295 of DC interconnect system 294 is configured to receive MVAC from power distribution network portion 263, convert the MVAC to MVDC, and output the MVDC to network 202. AC/DC power converter 295 is also configured to receive MVDC from network 202, convert MVDC to MVAC, and output MVAC to power distribution network portion 263. The converter controller 297 is configured to operate the AC/DC power converter 295.

The DMS controller 208 is configured to coordinate the operation of the DC interconnect system of the network 200, including determining set points for each of the power converters. During the fault response mode, the converter controllers of each DC interconnect system may initially operate independently to provide emergency power support or power restoration to the isolated healthy portion of the power distribution network. After power restoration, the DMS controller 208 is configured to determine a setpoint for each power converter and transmit the setpoint to each DC interconnect system for implementation. The DMS controller 208 may use the protection device switch states, as well as power flow data for the feeder, transformer and AC/AC power converter to generate set points, to name a few. The set point may be generated by considering the required power support and headroom availability (headroom availability).

Coordinating power delivery by the DMS controller 208 using the network 202 increases the reliability of the network 200. For example, because each of the three substations of network 200 includes redundant transformers, network 200 actually has N-3 reliability. The spare transformer capacity may be used to service additional load areas while maintaining the desired N-1 or N-2 reliability requirements. In the case where the network 200 requires N-1 reliability, the load service capability of the distribution network is increased by two transformers (equivalent to building a fourth substation).

Referring to fig. 3, an exemplary process 300 for responding to a transformer fault in an MVAC power distribution network including a substation, a distribution network portion, and one or more DC interconnect systems is illustrated. Process 300 is implemented by a network control system that may include a centralized controller, one or more substation controllers, and one or more converter controllers. It should be further appreciated that a number of variations and modifications to the process 300 are contemplated, including for example, omitting one or more aspects of the process 300, adding further conditional statements (conditional) and operations, performing operations or conditional statements by a controller other than the one identified below, and/or reorganizing or separating the operations and conditional statements into separate processes.

Process 300 begins at operation 301, where a substation controller of a first substation detects a transformer fault in a transformer of the first substation. The fault may be a short circuit fault or a high impedance fault, to name a few. In other examples, a relay may detect a transformer fault, to name one example only.

Process 300 proceeds to operation 303, where the substation controller operates one or more protection devices of the first substation to isolate the faulty transformer from a healthy distribution network portion (also referred to as a healthy portion) coupled to the faulty transformer. In certain embodiments, the substation controller may operate a plurality of protection devices to efficiently operate a plurality of healthy distribution network portions from the effects of a faulty transformer.

The process 300 proceeds to operation 305 in which the converter controller determines set points and uses the emergency set points to operate the DC interconnect system to transfer MVAC power to the healthy portion in response to the isolation and before the healthy portion is powered down, thereby effectively providing emergency active and/or reactive power support. For example, in the event that the fault is a short circuit fault (causing a voltage drop on the bus approaching the DC interconnect system), the converter controller may provide maximum reactive power to the healthy part while also providing a rapidly increasing active power in response to measuring the bus. For example, the active power may be increased for a period of time between 60-100ms, to name just one possible range. As just one example, the maximum reactive power may be determined by the current rating of the DC interconnect system. In some embodiments where the DC interconnect system is unable to deliver sufficient power to meet the load requirements of the healthy portion, the control system may close tie switches coupled to the healthy portion in addition to or instead of operating the DC interconnect system. In certain embodiments, operation 305 is performed by the DC interconnection system controller using measurements generated by local sensors, such as a DC link voltage sensor, a current sensor that measures current received and output by the DC interconnection system, and a voltage sensor that measures a bus to which the DC interconnection system is coupled, to name a few. In certain embodiments, during operation 305, the plurality of DC interconnect systems are operated to transfer power.

Process 300 proceeds to operation 307 where all customers having loads coupled to healthy portions continue to receive service with less interference due to power being transferred from the DC interconnect system. Since the DC interconnect system responds to fault isolation before the healthy portion is powered down, the healthy isolated portion does not experience a total power outage. For example, by using a DC interconnect system, emergency power support may be provided to healthy parts in milliseconds rather than seconds or minutes.

Process 300 proceeds to operation 309 where a substation controller or centralized controller determines the set point for each DC interconnect system. The set points may include active power set points and reactive power set points that are determined to balance power flow and effectively reduce power loss through the DC interconnect system and the transformer to provide power to the healthy portion. Finally, the process 300 proceeds to operation 311, in which the determined set points are sent to the converter controller so that the DC interconnection system is operated using the set points determined by operation 309.

Referring to fig. 4, an exemplary process 400 for responding to a transformer fault in an MVAC power distribution network including a substation, a distribution network portion, and one or more DC interconnect systems is illustrated. Process 400 is implemented by a network control system, which may include a centralized controller, one or more substation controllers, and one or more converter controllers. It should be further appreciated that a number of variations and modifications to process 400 are contemplated, including for example omitting one or more aspects of process 400, adding further conditional statements and operations, performing operations or conditional statements by a controller other than the one identified below, and/or reorganizing or separating the operations and conditional statements into separate processes.

Process 400 begins with operation 401 in which a substation controller of a first substation detects a transformer fault in a transformer of the first substation. The fault may be a short circuit fault or a high impedance fault, to name a few. In other examples, a relay may detect a transformer fault, to name one example only.

Process 400 proceeds to operation 403 where the substation controller operates one or more protection devices of the first substation to isolate the faulty transformer from the healthy distribution network portion (also referred to as the healthy portion) coupled to the faulty transformer. In certain embodiments, the substation controller may operate a plurality of protection devices to efficiently operate a plurality of healthy distribution network portions from the effects of a faulty transformer.

Process 400 proceeds to operation 405 where the substation controller closes the normally open tie switch to effectively couple the healthy portion to the power source through the second transformer of the first substation or the transformer of the adjacent substation.

Process 400 proceeds to operation 407 where all customers having loads coupled to healthy portions continue to receive service as the tie switch is closed.

Process 400 proceeds to operation 409 where the substation controller determines that the transformer providing power to the reconnected healthy portion is experiencing an overload condition such that the current flowing through the transformer exceeds the rated current or current threshold of the transformer.

Process 400 proceeds to operation 411 where the substation controller determines a set point for one or more DC interconnect systems to effectively eliminate the overload by reducing the current through the overload transformer to a current magnitude less than the rated current of the transformer. The set point may be determined based on the rated current of the available transformers and the DC interconnect system. Finally, the process 400 proceeds to operation 413, where the substation controller sends the determined set points to the one or more DC interconnect systems and then uses the set points to operate the one or more DC interconnect systems.

Referring to fig. 5, an exemplary process 500 for responding to a transformer fault in an MVAC power distribution network including a substation, a distribution network portion, and one or more DC interconnect systems is illustrated. Process 500 is implemented by a network control system, which may include a centralized controller, one or more substation controllers, and one or more converter controllers. It should be further appreciated that a number of variations and modifications to the process 500 are contemplated, including for example, omission of one or more aspects of the process 500, addition of further conditional statements and operations, execution of operations or conditional statements by a controller other than the one identified below, and/or reorganization or separation of operations and conditional statements into separate processes.

Process 500 begins at operation 501, where a substation controller of a first substation detects a transmission fault in a transmission network coupled to the first substation. A transmission fault may be a total power outage caused by a short-circuit fault in the supply line from the transmission network to the substation or a fault on the high-voltage bus of the substation, to name a few.

Process 500 proceeds to operation 503 where the substation controller operates one or more protection devices of the first substation to isolate the transmission fault from a healthy distribution network (also referred to as a healthy portion) powered by the substation. The protection device may isolate the transmission fault by isolating the medium voltage bus of the substation from the transmission network. In certain embodiments, the substation controller may operate a plurality of protection devices to efficiently operate a plurality of healthy power distribution network portions from power transmission faults.

Process 500 proceeds to operation 505 where the converter controller operates the DC interconnect system to transfer the MVAC power to the healthy portion in response to the isolation and before the healthy portion is powered down, thereby effectively providing emergency active and/or reactive power support. For example, in the event of a loss of power supply from the power transmission network (causing a voltage drop in the distribution network), the control system may provide maximum reactive power to the healthy part while also providing a rapidly increasing active power. For example, the active power may be increased for a period of time between 60-100ms, to name just one possible range. As just one example, the maximum reactive power may be determined by the current rating of the DC interconnect system. In some embodiments where the DC interconnect system is unable to deliver sufficient power to meet the load requirements of the healthy portion, the control system may close tie switches coupled to the healthy portion in addition to or instead of operating the DC interconnect system. In certain embodiments, operation 505 is performed by the DC interconnection system controller using measurements generated by local sensors, such as a DC link voltage sensor, a current sensor that measures current received and output by the DC interconnection system, and a voltage sensor that measures a bus to which the DC interconnection system is coupled, to name a few. In certain embodiments, during operation 505, multiple DC interconnect systems are operated to transfer power.

Process 500 proceeds to conditional statement 509 where the substation controller determines whether the healthy portion was successfully recovered. In certain embodiments, the substation controller receives voltage and frequency measurements of healthy parts and determines that these measurements are within acceptable operating ranges.

If all healthy portions of the power distribution network are successfully restored, process 500 proceeds to operation 511 where the normally-open tie switch is closed to effectively couple other portions of the power distribution network to the reconnected healthy portions of the power distribution network. The newly coupled portions actually share power support for the healthy portions of the reconnection.

Process 500 proceeds to operation 513 where the substation controller determines whether the power distribution network remains stable after operation 511. The substation controller may determine that the distribution network is stable by comparing the bus voltage and frequency measurements to an acceptable operating range.

Process 500 proceeds to operation 515 where a substation controller or centralized controller determines set points for at least one DC interconnect system. The set points may include active power set points and reactive power set points that are determined to effectively reduce power losses and balance power flow through the DC interconnect system and the transformer to provide power to the healthy portion. The determined set points are sent to the converter controller so that the DC interconnection system is operated using the set points.

If the substation controller determines that the healthy portion was not successfully recovered, then the process 500 proceeds from conditional 509 to operation 517, where the substation controller shed (shed) non-critical loads coupled to the feeder line of the healthy portion. The load may be designated as non-critical by user input or a load priority table, to name a few. For example, the controller may determine which loads are non-critical based on the under-frequency level and the load priority in the load priority table.

Process 500 proceeds to operation 519 where the substation controller determines that the healthy portion is stable while providing power to the portion of the load coupled to the healthy portion and not shed during operation 517.

Process 500 proceeds to operation 521 where a substation controller or centralized controller of an adjacent substation determines set points for at least two DC interconnect systems and also closes the appropriate tie switches between feeder lines or substations to provide sufficient power to the healthy portion to fully restore all loads coupled to the healthy portion. The determined set points are sent to the converter controller such that the DC interconnection system is operated using the set points.

Further written description of several exemplary embodiments shall now be provided. One embodiment is an Alternating Current (AC) power distribution system, comprising: a first substation comprising a first transformer and a protection device, the first transformer being coupled to a power transmission network; a first distribution network portion coupled to a first transformer; a second substation comprising a second transformer; a second distribution network portion coupled to a second transformer, the second distribution network portion configured to receive a Medium Voltage Alternating Current (MVAC) from the second transformer; a DC interconnect system coupled between the first and second power distribution network portions; and a control system configured to detect a fault in the first transformer or power transmission network, isolate the first power distribution network from the fault using the protection device, determine a setpoint of the DC interconnection system after isolating the first power distribution network, and operate the DC interconnection system using the setpoint to transmit a portion of the MVAC from the second power distribution network portion to the first power distribution network portion.

In some forms of the aforementioned AC power distribution system, the system includes a second DC interconnection system, wherein the first DC interconnection system is coupled to the second DC interconnection system through a DC power distribution network. In certain forms the control system comprises a substation controller of the first substation and a converter controller of the DC interconnection system, and wherein the converter controller is configured to determine the set point of the DC interconnection system after the substation controller isolates the first distribution network using the protection device. In some forms the converter controller operates the DC interconnect system to effectively prevent total power interruption of the first power distribution network portion. In certain forms the control system is configured to determine a second setpoint after the converter controller determines the first setpoint, and to communicate the second setpoint to the converter controller, wherein the converter controller is configured to operate the DC interconnect system using the second setpoint instead of the first setpoint. In certain forms the control system is configured to close the tie switch in response to an isolation fault, determine that the second transformer is overloaded, and determine the set point in response to determining that the second transformer is overloaded. In some forms the control system determines that operating the DC interconnect system using the setpoint has not successfully restored the first power distribution network portion, responsively shed a plurality of non-critical loads, transmits the MVAC from the third power distribution network portion, and reconnects the shed plurality of non-critical loads.

Another exemplary embodiment is a method for fault response in an Alternating Current (AC) power distribution system, the method comprising: detecting, with a control system, a fault in a first transformer of a first substation or a power transmission network coupled to the first substation; isolating, with the control system, the first distribution network portion from the fault using a protection device of the first substation; after isolating the first power distribution network, determining, with the control system, a setpoint of a DC interconnection system coupled between the first power distribution network portion and the second power distribution network portion; receiving a Medium Voltage Alternating Current (MVAC) through a second distribution network and a second transformer of a second substation with the DC interconnection system; and operating, with the control system, the DC interconnect system using the setpoint to transmit the MVAC from the second power distribution network portion to the first power distribution network portion.

In some forms of the foregoing method, the method comprises: the second DC interconnection system is operated to transfer power from the second DC interconnection system to the first interconnection system through the DC distribution network. In certain forms the control system comprises a substation controller of the first substation and a converter controller of the DC interconnection system, and wherein the converter controller is configured to determine the set point of the DC interconnection system after the substation controller isolates the first distribution network using the protection device. In certain forms the converter controller is configured to operate the DC interconnect system so as to avoid total power interruption of the first power distribution network portion. In some forms, the method comprises: determining a second setpoint with the substation controller after determining the first setpoint and transmitting the second setpoint to the converter controller, and wherein the converter controller is configured to operate the DC interconnect system using the second setpoint instead of the first setpoint. In some forms, the method comprises: the method further includes closing the tie switch in response to the isolation fault, determining that the second transformer is overloaded after closing the tie switch, and determining the set point in response to determining that the second transformer is overloaded. In some forms, the method comprises: determining that operating the DC interconnect system using the setpoint did not successfully restore the first power distribution network portion, shedding a plurality of non-critical loads in response to the determination, transmitting the MVAC from the third power distribution network portion, and reconnecting the shed plurality of non-critical loads.

A further exemplary embodiment is a control system for fault response in a Medium Voltage Alternating Current (MVAC) network, the control system comprising: a substation controller of a first substation; and a converter controller of the DC interconnection system, the DC interconnection system being coupled between the first distribution network portion and the second distribution network portion and being in communication with the substation controller, wherein the substation controller is configured to detect a fault in a first transformer of the first substation or a power transmission network coupled to the first substation and to isolate the first distribution network from the fault using a protection device of the first substation, and wherein the converter controller is configured to operate the DC interconnection system using the setpoint after isolating the first distribution network and to transmit a Medium Voltage Alternating Current (MVAC) from the second distribution network portion to the first distribution network portion.

In some forms of the foregoing control system, the control system includes a second DC interconnection system, wherein the first DC interconnection system is coupled to the second DC interconnection system through a DC distribution network. In some forms the converter controller operates the DC interconnect system to effectively prevent total power interruption of the first power distribution network portion. In certain forms the control system is configured to determine a second setpoint after determining the first setpoint, and to communicate the second setpoint to the converter controller, wherein the converter controller is configured to operate the DC interconnect system using the second setpoint instead of the first setpoint. In certain forms the control system is configured to close the tie switch in response to an isolation fault, determine that the second transformer is overloaded, and determine the set point in response to determining that the second transformer is overloaded. In some forms the control system determines that operating the DC interconnect system using the setpoint has not successfully restored the first power distribution network portion, responsively shed a plurality of non-critical loads, transmits the MVAC from the third power distribution network portion, and reconnects the shed plurality of non-critical loads.

It is contemplated that various aspects, features, processes, and operations from the various embodiments may be used in any of the other embodiments, unless explicitly stated to the contrary. Certain operations illustrated may be implemented by a computer executing a computer program product on a non-transitory computer readable storage medium, where the computer program product includes instructions to cause the computer to perform one or more of the operations or issue commands to other devices to perform the one or more operations.

While the disclosure has been illustrated and described in detail in the drawings and foregoing description, such illustration and description are to be considered as illustrative and not restrictive in character, it being understood that only certain exemplary embodiments have been shown and described and that all changes and modifications that come within the spirit of the disclosure are desired to be protected. It should be understood that while the use of words such as "may be preferred," "preferably," "preferred," or "more preferred" utilized in the above description indicate that the feature so described may be more desirable, it may not be necessary, and embodiments lacking the same may be contemplated as within the scope of the disclosure, that scope being defined by the claims that follow. In reading the claims, it is intended that when words such as "a," "an," "at least one," or "at least one portion" are used there is no intention to limit the claims to only one item unless specifically stated to the contrary in the claims. The term "of … … can mean an association or contact with another item, as well as an attribution or contact with another item as informed by the context in which it is used. Unless expressly stated to the contrary, the terms "coupled to," "coupled with … …," and the like include indirect connections and couplings, and further include but do not require direct couplings or connections. When the language "at least a portion" and/or "a portion" is used, the item can include a portion and/or the entire item unless specifically stated to the contrary.

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