JP5398433B2 - Electric railway power system - Google Patents

Description

  The present invention relates to a power system of a power system applied to an electric railway.

  In general, a DC feeding system is known as a power system applied to electric railways. The DC feeding system is a system in which AC power from a commercial power source such as an electric power company is converted into DC power and supplied to an electric vehicle via a train line such as an overhead line.

  Moreover, in order to charge the regenerative power generated from the electric vehicle, a power storage device may be provided on the overhead line. For example, a power storage device that is charged in accordance with an increase in overhead line voltage is disclosed (for example, see Patent Document 1). Moreover, in order to suppress regeneration invalidation, the electric power storage apparatus provided with the resistance apparatus for discharging surplus regenerative electric power is disclosed (for example, refer patent document 2). Furthermore, a hybrid inverter system for electric railway that regenerates electric power to an electric railway company is disclosed (for example, see Non-Patent Document 1).

JP 2003-220859 A JP 2004-358984 A

"Hybrid inverter system for electric railway", Toshiba review, Toshiba Corporation, 2007, Vol. 62, No. 8, p53-56

  However, in the electric railway electric power system as disclosed in the prior art document, there is no limitation on the regenerated electric power being returned to the electric power system of the electric power company. In addition, since the electric power returned to the power company is collected at a low price or free of charge, there is no profit from the power sales by the railway operator.

  Therefore, an object of the present invention is to provide an electric railway power system that can effectively use electric power of an electric railway electric power system that generates regenerative electric power.

An electric railway power system according to an aspect of the present invention includes an AC bus that receives AC power supplied from an AC power system, and a power flow detection that detects a power flow between the AC power system and the AC bus. Means, forward conversion means for converting AC power received by the AC bus into DC power and supplying it to the train line; DC power supplied to the train line is converted to AC power and supplied to the AC bus When the power flow detected by the reverse conversion means, the charging means for charging the power supplied to the train line, and the power flow detection means flows in the AC power system, the power flow flows in the direction of the AC bus. to stream, and control means for controlling to charge said charging means, variable AC load that stores an AC load fluctuation information indicating the fluctuation estimated power consumption of the connected alternating current load to said AC buses And an information storage unit, based on the stored the AC load change information to the AC load fluctuation information storage unit, and controls the charging or discharging of said charging means.

  ADVANTAGE OF THE INVENTION According to this invention, the electric power system for electric railways which can utilize effectively the electric power of the electric power system for electric railways which generate | occur | produces regenerative electric power can be provided.

1 is a configuration diagram showing a configuration of an electric railway power system to which a power management system according to a first embodiment of the present invention is applied. The block diagram which shows the structure of the electric power system for electric railways to which the electric power management system which concerns on the 2nd Embodiment of this invention was applied. The block diagram which shows the structure of the electric power system for electric railways to which the electric power management system which concerns on the 3rd Embodiment of this invention was applied. The graph for demonstrating control of the storage battery using the load fluctuation information of the power management system which concerns on 3rd Embodiment. The block diagram which shows the structure of the electric power system for electric railways to which the electric power management system which concerns on the 4th Embodiment of this invention was applied. The graph for demonstrating control of the storage battery using the load variation information of the memory | storage device accompanying the buck-boost chopper circuit which concerns on 4th Embodiment.

  Embodiments of the present invention will be described below with reference to the drawings.

(First embodiment)
FIG. 1 is a configuration diagram showing a configuration of an electric railway power system 10 to which the power management system 1 according to the first embodiment of the present invention is applied. In addition, the same code | symbol is attached | subjected to the same part in subsequent figures, the detailed description is abbreviate | omitted, and a different part is mainly described. In the following embodiments, the same description is omitted.

  The electric railway power system 10 is connected to the AC power system 2 through an AC bus BS. The AC power system 2 is a power system provided with a commercial power source. The AC power system 2 is, for example, a power system of an electric power company.

  The electric railway power system 10 includes a power management system 1, a plurality of transformers 3, a plurality of PWM converters 4 and 5, a step-up / step-down chopper circuit 6, a storage battery 7, a plurality of high-voltage power distribution facilities 8, An wattmeter 9 is provided.

  The power management system 1 monitors the voltage, current, and power in the electric railway power system 10 (substation). Specifically, the power management system 1 monitors the power flow detected by the power flow detector 9, the SOC of the storage battery 7, and the like. The power management system 1 is an overall control device in a substation. The power management system 1 controls various facilities in the electric railway power system 10 by outputting a control command based on various monitored information. The power management system 1 is installed in the power command center CS.

  The PWM converters 4 and 5 are converters having both forward conversion and reverse conversion functions. The PWM converters 4 and 5 are PWM (Pulse Width Modulation) controlled by a control command from the power management system 1. The PWM converters 4 and 5 convert AC power supplied from the AC bus BS via the transformer 3 into DC power. The PWM converters 4 and 5 supply the converted DC power to the feeder circuit (the overhead line KS and the rail RL). The PWM converters 4 and 5 convert the regenerative power supplied from the feeder circuit into AC power. The PWM converters 4 and 5 supply the converted AC power to the AC bus BS via the transformer 3.

  The step-up / down chopper circuit 6 is provided between the DC side of the PWM converter 5 and the storage battery 7. The step-up / step-down chopper circuit 6 controls the charging or discharging of the storage battery 7 by increasing or decreasing the DC voltage. The step-up / down chopper circuit 6 is controlled by the power management system 1.

  The storage battery 7 charges the power (energy) of the feeder circuit. The storage battery 7 discharges electric power (energy) to the feeder circuit. The storage battery 7 is charged or discharged according to the operation of the step-up / step-down chopper circuit 6. The SOC (state of charge) of the storage battery 7 is monitored by the power management system 1.

  The high voltage distribution facility 8 is a load of the high voltage distribution system. For example, the high-voltage power distribution facility 8 is an elevator, an escalator, lighting, or air conditioning. The high-voltage power distribution facility 8 may be a regenerative power source in the case of an elevator or the like.

  The power flow detector 9 detects the power flow between the AC power system 2 and the AC bus BS. The power flow detector 9 is, for example, a power meter. The power flow detected by the power flow detector 9 is monitored by the power management system 1.

  The electric vehicle 11 travels with DC power supplied from a feeder circuit during powering. At the time of regeneration, the electric vehicle 11 supplies (returns) regenerative power to the feeder circuit and decelerates (regenerative braking).

  Next, the operation of the power management system 1 will be described.

  When it is desired to lower the SOC of the storage battery 7, the power management system 1 controls the step-up / step-down chopper circuit 6 to discharge the storage battery 7 if the power flow is in the direction flowing through the AC bus BS. At this time, the power management system 1 controls the PWM converter 5 to perform an inverse conversion operation.

  When the PWM converter 5 is performing the forward conversion operation, when the power flow is directed to the AC power system 2, the power management system 1 controls the step-up / step-down chopper circuit 6 to charge the storage battery 7. Start.

  For example, when the PWM converter 5 is performing a forward conversion operation, the power management system 1 performs the reverse conversion operation (operation for supplying energy from the feeder circuit to the AC bus BS in order to prevent regeneration and invalidation). ) And the power flow detected by the power flow detector 9 is generated in the direction of the AC power system 2 (the power company side). At this time, the power management system 1 controls the step-up / step-down chopper circuit 6 so as to charge the storage battery 7. Thereby, the power flow which flows in the direction of the AC power system 2 on the power company side is suppressed.

  According to the present embodiment, the power management system 1 controls the charging of the storage battery 7 when the power flow detected by the power flow detector 9 is directed to the AC power system 2 on the power company side. The power flow toward the grid 2 can be suppressed.

  When discharging the storage battery 7, the feeder circuit is not always conveniently loaded. In addition, even if there is a load, if the regenerative vehicle is supplying power to the load, if the storage battery 7 actively supplies power, the train being regenerated may be regenerated and expired. Therefore, when the storage battery 7 discharges directly to the feeder circuit, the discharge power of the storage battery depends on the load state of the feeder circuit. On the other hand, the power management system 1 uses the PWM converter 5 to regenerate the energy discharged from the storage battery 7 to regenerate the storage battery 7 without depending on the load state of the feeder circuit. It can be discharged.

  Therefore, the electric railway power system 10 controls the power storage device / converter so as to suppress the power flow to the AC power system on the power company side, thereby suppressing the amount of power purchased by the railway operator from the power company. it can. Moreover, it leads also to the load leveling of the electric railway AC system BS and the feeder system, and the electric railway power system 10 contributes to system stabilization on the electric power company side.

(Second Embodiment)
FIG. 2 is a configuration diagram showing a configuration of an electric railway power system 10A to which the power management system 1A according to the second embodiment of the present invention is applied.

  In the electric railway power system 10A according to the first embodiment shown in FIG. 1, the electric railway power system 10A replaces the power management system 1 with the power management system 1A, and replaces the step-up / down chopper circuit 6 with the converter 6A. The storage battery 7 is replaced with a storage battery 7A. In other respects, the electric railway power system 10A is the same as the electric railway power system 10 according to the first embodiment.

  The AC side of the converter 6A is connected to the AC bus BS via the transformer 3. A storage battery 7A is connected to the DC side of the converter 6A. The converter 6A is a converter having both forward conversion and reverse conversion functions. The converter 6A is, for example, a PWM control converter. The converter 6A controls charging or discharging of the storage battery 7A. Converter 6A is controlled by a control command from power management system 1A.

  Storage battery 7A charges the electric power (energy) of AC bus BS. Storage battery 7A discharges electric power (energy) to AC bus BS. The storage battery 7A is charged or discharged according to the operation of the converter 6A. The SOC of the storage battery 7A is monitored by the power management system 1A.

  Next, the operation of the power management system 1A will be described.

  The power management system 1A monitors the power flow detected by the power flow detector 9. The power management system 1A monitors the SOC of the storage battery 7A.

  When it is desired to lower the SOC of the storage battery 7A, the power management system 1A controls the converter 6A to discharge the storage battery 7A if the power flow is in a direction flowing through the AC bus BS. The power management system 1 </ b> A controls the converter 6 </ b> A to charge the storage battery 7 </ b> A when the power flow is directed to the AC power system 2.

  For example, the power management system 1A causes the PWM converter 4 to perform an inverse conversion operation (operation to supply energy from the feeder circuit to the AC bus BS) in order to prevent regeneration expiration, and is detected by the power flow detector 9 Assume that a power flow occurs in the direction of the AC power system 2. At this time, the power management system 1A controls the converter 6A so as to charge the storage battery 7A. Thereby, the power flow which flows in the direction of the grid side of the electric power company is suppressed.

  According to the present embodiment, the power management system 1A controls the charging of the storage battery 7A when the power flow detected by the power flow detector 9 is directed to the AC power system 2 on the power company side. The power flow toward the grid 2 can be suppressed.

  Storage battery 7A discharges energy to AC bus BS. Even when the train being regenerated is running, the power management system 1A can discharge the storage battery 7 without causing the train to expire. Therefore, similarly to the first embodiment, the power management system 1A can discharge the storage battery 7A without being restricted by the load state of the feeder circuit.

  Therefore, the electric railway power system 10A can suppress the amount of electric power purchased by the railway operator from the electric power company by effectively using the electric power in the electric power system. Further, the electric railway power system 10 can stabilize the power system.

(Third embodiment)
FIG. 3 is a configuration diagram showing a configuration of an electric railway power system 10B to which the power management system 1B according to the third embodiment of the present invention is applied.

  The electric railway power system 10B has a configuration in which, in the electric railway power system 10 according to the first embodiment shown in FIG. 1, the power management system 1 is replaced with the power management system 1B, and a storage device 21 is added. In other respects, the electric railway power system 10B is the same as the electric railway power system 10 according to the first embodiment.

  The storage device 21 stores in advance information on expected fluctuations in power consumption of the high-voltage distribution facility 8 (hereinafter referred to as “load fluctuation information”).

  The power management system 1 </ b> B acquires load variation information stored in the storage device 21 in order to control various facilities installed in the electric railway power system 10. In other respects, the power management system 1B is the same as the power management system 1 according to the first embodiment.

  FIG. 4 is a graph for explaining the control of the storage battery 7 using the load fluctuation information of the power management system 1B according to the present embodiment.

  The load fluctuation graph FL1 indicates the load fluctuation information stored in the storage device 21. The regenerative power fluctuation graph FP shows changes in the regenerative power (power supplied from the feeder circuit to the AC bus BS) that is monitored by the power management system 1B.

  A region D1 in which the regenerative power fluctuation graph FP exceeds the load fluctuation graph FL1 indicates power that cannot be consumed in the electric railway power system 10.

  The power management system 1B performs control to charge the storage battery 7 with the power indicated by the region D1. Specifically, the power management system 1B operates the step-up / step-down chopper circuit 6 in order to charge the storage battery 7 from time t11 to time t12 and from time t13 to time t14.

  According to the present embodiment, in addition to the operational effects of the first embodiment, the following operational effects can be obtained.

  The fluctuation of the power consumption of the high-voltage power distribution facility 8 can be estimated in advance based on the tendency for each date and time. Accordingly, the power management system 1B systematically manages the SOC of the storage battery 7 based on the load variation information stored in advance (for example, to follow the target SOC of time series power storage that has been optimized and set in advance). In this way, the electric railway power system 10B can be stably controlled. Further, even if the power flow detector 9 fails, the power management system can control charging / discharging of the storage battery based on the data in the storage device, which contributes to improvement of system redundancy.

(Fourth embodiment)
FIG. 5 is a configuration diagram showing a configuration of an electric railway power system 10C to which the power management system 1C according to the fourth embodiment of the present invention is applied.

  The electric railway power system 10C is the electric railway electric power system 10B according to the third embodiment shown in FIG. Instead, the storage device 21 is replaced with a storage device 21C. In other respects, the electric railway power system 10C is the same as the electric railway power system 10 according to the third embodiment.

  The power management system 1C is the same as the power management system 1 according to the first embodiment, except that the buck-boost chopper circuit 6C is controlled instead of the buck-boost chopper circuit 6.

  The storage device 21C is provided in the step-up / step-down chopper circuit 6C. In the storage device 21C, the load fluctuation information of the high-voltage distribution facility 8 is stored in advance, as in the third embodiment.

  The step-up / step-down chopper circuit 6C controls charging or discharging of the storage battery 7 based on load variation information stored in the storage device 21C in addition to the control command from the power management system 1C.

  FIG. 6 is a graph for explaining the control of the storage battery 7 using the load fluctuation information of the storage device 21 associated with the step-up / step-down chopper circuit 6C according to the present embodiment.

  The load fluctuation graph FL2 indicates the load fluctuation information stored in the storage device 21.

  A region D2 in which the load fluctuation graph FL2 is negative indicates energy that is consumed negatively in the electric railway power system 10C, that is, energy returned to the AC power system 2. When the load fluctuation graph FL2 is negative, the PWM converter 4, the PWM converter 5, or the high-voltage distribution load 8 under the AC system BS is regenerated, and the power cannot be consumed in the electric railway system 10C. Is the case.

  The step-up / step-down chopper circuit 6C controls the storage battery 7 to be charged with the electric power indicated by the region D2. Specifically, the step-up / step-down chopper circuit 6C operates to charge the storage battery 7 from time t21 to time t22. The operation according to the control command of the power management system 1C of the step-up / down chopper circuit 6C is the same as that of the power management system 1 according to the first embodiment.

  According to the present embodiment, the configuration in which the step-up / step-down chopper circuit 6C controls the storage battery 7 based on the load fluctuation information of the high-voltage distribution facility 8 stored in advance in the storage device 21C is the same as in the third embodiment. An effect can be obtained. Thereby, the electric railway power system 10C can control the storage battery 7 independently of the control by the power management system 1C with only the equipment provided on the storage battery 7 side.

  In each embodiment, the configuration of the electric power system for electric railway, the facilities provided, and the like are simply described for convenience of explanation. Therefore, the configuration of the electric railway power system is not limited to the embodiment. Similarly, the type or number of facilities provided in the electric railway power system is not limited to the embodiment. For example, the PWM converters 4 and 5 may have only one function of forward conversion or reverse conversion. Any number of PWM converters 4 and 5 may be provided. In addition, when the power management system 1 or the like performs control for charging the storage batteries 7 and 7A in order to suppress the power flow in the direction of flowing to the AC power system 2, the PWM provided in the electric railway power system 10 and the like. The equipment such as the converters 4 and 5 may be controlled in any way.

  Moreover, in 3rd Embodiment and 4th Embodiment, although demonstrated about charging the storage battery 7 based on the load fluctuation information memorize | stored in the memory | storage device 21, you may discharge the storage battery 7. FIG. For example, the electric railway power systems 10 </ b> B and 10 </ b> C may perform control to discharge the storage battery 7 when the power consumption is high based on the load fluctuation information. Moreover, you may control PWM converters 4 and 5 etc. as needed. Furthermore, although the configuration based on the storage battery 7 according to the first embodiment has been described, the configuration based on the storage battery 7A according to the second embodiment can be similarly configured.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. Moreover, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

  DESCRIPTION OF SYMBOLS 1 ... Power management system, 3 ... Transformer, 4, 5 ... PWM converter, 6 ... Buck-boost chopper circuit, 7 ... Storage battery, 8 ... High voltage distribution equipment, 10 ... Electric railway power system, 11 ... Electric car, BS ... bus, CS ... power command center, KS ... overhead, RL ... rail.

Claims (8)

An AC bus for receiving AC power supplied from the AC power system;
A power flow detection means for detecting a power flow between the AC power system and the AC bus;
Forward conversion means for converting alternating current power received by the alternating current bus into direct current power and supplying it to the train line;
DC power supplied to the train line is converted to AC power, and reverse conversion means for supplying the AC bus to the AC power line;
Charging means for charging power supplied to the train line;
When the power flow detected by the power flow detection means is in a direction flowing through the AC power system, control means for controlling the charging means to flow the power flow in the direction of the AC bus ; and
AC load fluctuation information storage means for storing AC load fluctuation information indicating the estimated fluctuation of the power consumption of the AC load connected to the AC bus,
The electric railway power system , wherein the control means controls charging or discharging of the charging means based on the AC load fluctuation information stored in the AC load fluctuation information storage means . An AC bus for receiving AC power supplied from the AC power system;
A power flow detection means for detecting a power flow between the AC power system and the AC bus;
Forward conversion means for converting alternating current power received by the alternating current bus into direct current power and supplying it to the train line;
DC power supplied to the train line is converted to AC power, and reverse conversion means for supplying the AC bus to the AC power line;
Charging means for charging power supplied to the AC bus;
When the power flow detected by the power flow detection means is in a direction flowing through the AC power system, control means for controlling the charging means to flow the power flow in the direction of the AC bus ; and
AC load fluctuation information storage means for storing AC load fluctuation information indicating the estimated fluctuation of the power consumption of the AC load connected to the AC bus,
The electric railway power system , wherein the control means controls charging or discharging of the charging means based on the AC load fluctuation information stored in the AC load fluctuation information storage means . When the power flow detected by the power flow detection means is in a direction flowing through the AC power system, the control means includes the forward conversion means or the reverse conversion means to flow the power flow in the direction of the AC bus. It controls, The electric system for electric railways of Claim 1 or Claim 2 characterized by the above-mentioned. 3. The control unit according to claim 1 , wherein the control unit controls the forward conversion unit or the reverse conversion unit based on the AC load variation information stored in the AC load variation information storage unit. The electric railway power system described. AC power received from the AC power system to the AC bus is converted to DC power by a forward converter and supplied to the train line, and DC power supplied to the train line is converted to AC power by an inverse converter and the AC For electric railways provided with a rechargeable battery for supplying power to the bus and charging the power supplied to the train line, and provided with a power flow detector for detecting a power flow between the AC power system and the AC bus An electric railway power system control device for controlling an electric power system,
When the power flow detected by the power flow detector is in a direction flowing through the AC power system, control means for controlling the rechargeable battery to charge the power flow in the direction of the AC bus ; and
AC load fluctuation information storage means for storing AC load fluctuation information indicating the estimated fluctuation of the power consumption of the AC load connected to the AC bus,
The control device for an electric railway power system, wherein the control means controls charging or discharging of the rechargeable battery based on the AC load fluctuation information stored in the AC load fluctuation information storage means . AC power received from the AC power system to the AC bus is converted to DC power by a forward converter and supplied to the train line, and DC power supplied to the train line is converted to AC power by an inverse converter and the AC A rechargeable battery for supplying power to the bus and charging the power supplied to the AC bus is provided, and for an electric railway provided with a power flow detector for detecting a power flow between the AC power system and the AC bus An electric railway power system control device for controlling an electric power system,
When the power flow detected by the power flow detector is in a direction flowing through the AC power system, control means for controlling the rechargeable battery to charge the power flow in the direction of the AC bus ; and
AC load fluctuation information storage means for storing AC load fluctuation information indicating the estimated fluctuation of the power consumption of the AC load connected to the AC bus,
The control device for an electric railway power system, wherein the control means controls charging or discharging of the rechargeable battery based on the AC load fluctuation information stored in the AC load fluctuation information storage means . In the case where the power flow detected by the power flow detector is in a direction flowing through the AC power system, the control means includes the forward converter or the reverse converter in order to flow a power flow in the direction of the AC bus. It controls, The control apparatus of the electric system for electric railways of Claim 5 or Claim 6 characterized by the above-mentioned. The said control means controls the said forward converter or the said reverse converter based on the said AC load fluctuation information memorize | stored in the said AC load fluctuation information storage means, The Claim 5 or Claim 6 characterized by the above-mentioned. The control apparatus of the electric power system for electric railways as described.

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