JP2021044978A - Power conversion system - Google Patents

Abstract

To provide a power conversion system which can safely start a plurality of apparatuses by power supplied from a battery device.SOLUTION: A power conversion system 10 includes: a power conversion device 300 for travelling for converting power supplied via a transformer into drive power for motors M1-4M for travelling; a power conversion device 100 for auxiliary power supply having an AC-DC power conversion part 110 for load and a DC-AC power conversion part 120 for load, and for outputting to the drive power of an AC load and a DC load; a battery device 200; and an auxiliary machine group 600. The battery device 200 includes: a common first power line for supplying power from a battery pack BT to the power conversion device for travelling, the power conversion device for auxiliary power supply and the auxiliary machine group; and a second power line connected in parallel with the first power line, and having a resistor CHRe and a first contactor CHK for switching a power supply path between the first power line and the second power line.SELECTED DRAWING: Figure 2

Description

Embodiments of the present invention relate to power conversion systems.

When an electric vehicle passes through a non-electrical section in which power is not supplied to the overhead wire, the electric vehicle is not supplied with power from the overhead wire. In addition, when a power failure occurs, the power supply from the overhead line is stopped.

In these cases, power was not supplied to the traction motor mounted on the electric vehicle and auxiliary equipment such as the compressor and blower, and there was a possibility that the electric vehicle could not be moved to a safe place until it recovered from a power failure, for example. ..

JP-A-2017-225280

For example, it is being considered to mount a battery device on an electric vehicle as an emergency power source for moving the electric vehicle to a safe place in the event of a power failure. When power is supplied from the battery device to the traction motor or auxiliary device in an emergency, the device is started after the battery device charges a capacitor provided between the power terminals of the traction motor or auxiliary device. At this time, if the difference between the voltage of the battery device and the voltage of the capacitor is large, a large current flows through the power line or the capacitor that supplies power, which causes a failure of the device. Therefore, when charging the capacitor, it is necessary to supply electric power from the battery device via the resistor. If this resistor is provided for each device connected to the battery device, the number of parts for forming the system increases, and it is difficult to miniaturize the system. In addition, if a resistor is provided for each device, the control may be complicated.

An embodiment of the present invention has been made in view of the above circumstances, and an object of the present invention is to provide a power conversion system capable of safely starting a plurality of devices by electric power supplied from a battery device.

The power conversion system according to the embodiment includes a transformer that steps down the power from the overhead wire, and a traveling AC-DC power conversion unit that converts and outputs AC power supplied through the secondary winding of the transformer. , Connected to the driving DC-AC power conversion unit that converts the DC power output from the traveling AC-DC power conversion unit into the driving power of the driving motor, and the input end of the traveling DC-AC power conversion unit. A traveling power converter having the first capacitor, a load AC-DC power converter that converts AC power supplied through the tertiary winding of the transformer into DC power, and the load The load DC-AC power converter that converts the DC power converted by the AC-DC power converter into the AC power used to drive the AC load and the DC load and outputs it, and the load DC-AC power. An auxiliary power supply power conversion device having a second capacitor connected to the input end of the conversion unit, a power line connecting the load AC-DC power conversion unit and the load DC-AC power conversion unit, and , A battery device connected to a power line connecting the traveling AC-DC power conversion unit and the traveling DC-AC power conversion unit, and a power line connecting the auxiliary power supply power conversion device and the battery device. It is supplied from an auxiliary power converter that converts the connected and supplied power into three-phase AC power, a third capacitor connected to the input end of the auxiliary power converter, and an auxiliary power converter. The battery device includes an auxiliary device that operates by the generated power, and an auxiliary machine group having the assembled battery, the assembled battery, the traveling power conversion device, the auxiliary power supply power conversion device, and the auxiliary power supply. A common first power line for supplying power to the auxiliary equipment group, a second power line connected in parallel with the first power line, a resistor provided in the second power line, and a power supply path are the first power line. A first contactor for switching between the second power line and the second power line is provided.

FIG. 1 is a schematic side view of a railroad vehicle equipped with the power conversion system of the embodiment. FIG. 2 is a diagram schematically showing a configuration example of the power conversion system of the embodiment. FIG. 3 is a diagram schematically showing another configuration example of the power conversion system of the embodiment.

Hereinafter, the power conversion system of the embodiment will be described with reference to the drawings.
FIG. 1 is a schematic side view of a railroad vehicle equipped with the power conversion system of the embodiment.
The railroad vehicle 1 of the present embodiment includes a vehicle body 2, two bogies 3, and a power conversion system 10.

The vehicle body 2 is formed in a rectangular parallelepiped shape that is long in the assumed traveling direction of the railway vehicle 1. A space that can accommodate passengers is formed inside the vehicle body 2. A current collector 400 is projected upward from the ceiling of the vehicle body 2. The current collector 400 is configured so that it can come into contact with the overhead wire.

The bogie 3 is attached under the floor of the vehicle body 2 via a bogie spring such as an air spring. A pair of axles 11 extending in the width direction (directions substantially orthogonal to the assumed traveling direction and the vertical direction) are rotatably supported on the bogie 3. Wheels 12 are attached to each of these axles 11 (one wheel 12 is not shown).

Each of the bogies 3 is equipped with a traction motor M for rotating each axle 11. That is, four traveling motors M (traveling motors M1 to M4 shown in FIG. 2) are mounted on the railway vehicle 1.
The power conversion system 10 is mounted, for example, in a portion located between a pair of bogies 3 under the floor of the vehicle body 2.

FIG. 2 is a diagram schematically showing a configuration example of the power conversion system of the embodiment.
The power conversion system 10 of the present embodiment utilizes the high-voltage AC power supplied from the overhead wire to drive the traveling motors M1 to M4 (traveling motor M shown in FIG. 1) and auxiliary equipment devices 620 to 640 (auxiliary equipment group). 600), a predetermined electric power can be supplied to the DC load device LDC and the AC load device LAC.

In the embodiment, the traveling motors M1 to M4 are, for example, induction motors.
In the embodiment, the AC load LAC is a load of the railway vehicle 1 excluding the traveling motors M1 to M4, and is, for example, an electronic device operating at an AC voltage of 100 volts.
Further, in the embodiment, the DC load LDC is a load of a railway vehicle excluding the traveling motors M1 to M4, and is, for example, an electronic device or a battery that operates at a DC voltage.

The power conversion system 10 of the present embodiment includes, for example, an auxiliary power supply power conversion device 100, a battery device 200, and a traveling power conversion device 300.
High-voltage AC power is supplied to the traveling power converter 300 from the overhead wire via the current collector 400 and the traveling windings (primary winding 500 and secondary winding 302) of the main transformer.

The traveling power conversion device 300 converts the high-voltage AC power stepped down by the transformer into traveling AC power and supplies it to the traveling motors M1 to M4. As a result, the traveling power conversion device 300 generates traveling torque in the traveling motors M1 to M4 to drive the railway vehicle.

The traveling power conversion device 300 includes, for example, a contactor 312, a resistor 314, a traveling AC-DC power conversion unit 320, a traveling DC-DC power conversion unit 330, and a capacitor (first capacitor) C1. It includes C2, a traveling power control unit 310, a first terminal T31, and a second terminal T32.

The contactor 312 is connected to the positive electrode wire and is connected in parallel to the resistor 314. Further, the traveling power conversion device 300 includes, for example, a coil (not shown) for electromagnetically operating the contactor 312.
The traveling charging circuit switches between a cutoff state and a conduction state of the contactor 312 according to the control of the traveling power control unit 310. When the supply of high-voltage AC power is started, the contactor 312 is in the cutoff state and then switched to the conductive state.

The traveling AC-DC power conversion unit 320 includes a switching circuit (not shown) including a plurality of switching elements connected between a power line on the high potential side and a power line on the low potential side to which high-voltage AC power is supplied. The traveling AC-DC power converter 320 is also referred to as a converter. The traveling AC-DC power converter 320 may be any of a boost converter, a step-down converter, and a step-up / down converter. The switching element included in the switching circuit is, for example, an IGBT (insulated gate bipolar transistor), but the present invention is not limited to this, and other types of switching elements may be used.

The traveling AC-DC power conversion unit 320 can convert the supplied high-voltage AC power into DC power by switching the switching element between the conductive state and the cutoff state according to the control by the traveling power control unit 310. it can.

The traveling AC-DC power conversion unit 320 and the traveling DC-DC power conversion unit 330 are electrically connected by a power line on the high potential side and a power line on the low potential side. The power line on the high potential side is electrically connected to the first terminal T21 of the battery device 200 via the first terminal T31. The power line on the low potential side is electrically connected to the second terminal T22 of the battery device 200 via the second terminal T32.

Further, the traveling AC-DC power conversion unit 320 and the traveling DC-DC power conversion unit 330 are provided with a common grounding wire. The ground wire is grounded via the third terminal T33.
The capacitor C1 is connected between the power line on the high potential side and the ground line.
The capacitor C2 is connected between the ground wire and the power line on the low potential side.
That is, the capacitors C1 and C2 are connected to the DC input end of the traveling DC-AC power conversion unit 330.

The traveling DC-AC power conversion unit 330 includes a switching circuit (not shown) including a plurality of switching elements bridge-connected between the power line on the high potential side and the power line on the low potential side. The traveling DC-AC power conversion unit 330 is also referred to as an inverter. The traveling DC-AC power conversion unit 330 includes three sets of a switching element on the upper bridge side and a switching element on the lower bridge side corresponding to each of the three phases of the traveling motors M1 to M4. Each switching element is, for example, an IGBT, but the present invention is not limited to this, and other types of switching elements may be used.

The traveling DC-AC power conversion unit 330 switches the switching element of each phase of the traveling motor M between the conductive state and the cutoff state according to the control of the traveling power control unit 310, thereby transmitting the DC power to the traveling AC. Convert to electric power.

The mileage control unit 310 is realized by, for example, a processor such as a CPU (Central Processing Unit) or an MPU (Micro Processing Unit) executing a program stored in a program memory. Further, some or all of these functional units may be realized by hardware such as LSI (Large Scale Integration), ASIC (Application Specific Integrated Circuit), or FPGA (Field-Programmable Gate Array). The traveling power control unit 310 can be operated by, for example, the operating power of 100 V converted by the auxiliary power supply power conversion device 100. The traveling power control unit 310 controls the contactor 312, the traveling AC-DC power conversion unit 320, and the traveling DC-DC power conversion unit 330.

High-voltage AC power is supplied to the auxiliary power supply power conversion device 100 from the overhead wire via the current collector 400 and the load windings (primary winding 500 and tertiary winding 102) of the main transformer. The AC power supplied from the load windings (primary winding 500 and tertiary winding 102) of the main transformer is the AC supplied from the traveling windings (primary winding 500 and secondary winding 302) of the main transformer. The voltage is lower than the electric power.

The auxiliary power supply power conversion device 100 converts the low-voltage AC power obtained by stepping down the high-voltage AC power by a transformer into load AC power and supplies it to the AC load LAC. That is, the auxiliary power supply power conversion device 100 drives the AC load LAC by the load AC power.

Further, the auxiliary power supply power conversion device 100 converts the low-voltage AC power obtained by stepping down the high-voltage AC power by a transformer into DC power for load and supplies it to the DC load LDC. That is, the auxiliary power supply power conversion device 100 drives the DC load LDC by the load DC power.

Further, the auxiliary power supply power conversion device 100 can convert high-voltage AC power into predetermined DC power and supply it to the battery device 200. That is, the auxiliary power supply power conversion device 100 can supply the charging power of the battery device 200.

The auxiliary power supply power conversion device 100 includes, for example, a load AC-DC power conversion unit 110, a load DC-AC power conversion unit 120, an AC load DC-AC power conversion unit 130, a chopper circuit 150, and the like. It includes a first terminal T11, a second terminal T12, a capacitor (second capacitor) C3, and a load transformer (primary winding 122, secondary winding 124, and tertiary winding 140).

The load AC-DC power conversion unit 110 converts the low-voltage AC power supplied from the current collector 400 via the load windings (primary winding 500 and tertiary winding 102) of the main transformer into DC power.
The load AC-DC power conversion unit 110 includes, for example, a switching circuit (not shown) including a plurality of switching elements connected between the power line on the high potential side and the power line on the low potential side. The plurality of switching elements are, for example, IGBTs (insulated gate bipolar transistors) having built-in diodes connected in antiparallel, but other types of switching elements may be used.
The load AC-DC power conversion unit 110 may include, for example, a circuit of any of a boost converter, a step-down converter, and a buck-boost converter.

The chopper circuit 150 is electrically connected to the fifth terminal T25 and the sixth terminal T26 of the battery device 200 via the first terminal T11 and the second terminal T12, and is output from the load AC-DC power conversion unit 110. The DC power is converted into a predetermined voltage and supplied to the battery device 200. The chopper circuit 150 converts the DC power supplied from the battery device 200 into a predetermined voltage and supplies it to the DC side of the load AC-DC power conversion unit 110.

The DC-AC power conversion unit 120 for load includes a switching circuit (not shown) including a plurality of switching elements bridge-connected between the power line on the high potential side and the power line on the low potential side.
The load DC-AC power conversion unit 120 is also referred to as an inverter. Each switching element is, for example, an IGBT (Insulated Gate Bipolar Transistor). Other types of switching elements may be used as the switching elements. The load DC-AC power conversion unit 120 converts DC power into load AC power by arbitrarily switching the switching element between the conductive state and the cutoff state according to the control of the load power control unit 170.

On the load AC-DC power conversion unit 110 side of the load DC-AC power conversion unit 120, a capacitor C3 is provided in parallel with the load AC-DC power conversion unit 110 and the load DC-AC power conversion unit 120. It is connected. That is, the capacitor C3 is connected to the DC input end of the load DC-AC power conversion unit 120.

The capacitor C3 is set to a capacity capable of supplying stable power to the AC load LAC and the DC load LDC side in the load DC-AC power conversion unit 120. That is, the capacity of the capacitor C3 is the AC load LAC and the DC load LDC when the railway vehicle is traveling in a non-electric section (also referred to as a section) where the AC power supplied from the current collector 400 stops or when there is a power failure. It does not have to be a high capacity that compensates for the supply of AC power for loading.

The load AC power converted by the load DC-AC power conversion unit 120 is supplied to the DC load LDC via the primary winding 122, the tertiary winding 140, and the rectifier of the load transformer.
Further, the load AC power converted by the load DC-AC power conversion unit 120 includes the primary winding 122, the secondary winding 124, the rectifier, and the AC load DC-AC power conversion unit 130 of the load transformer. It is supplied to the AC load LAC via.

The DC-AC power conversion unit 130 for AC load includes a plurality of switching elements bridge-connected between the power line on the high potential side and the power line on the low potential side, similarly to the DC-AC power conversion unit 120 for load described above. It is equipped with a switching circuit (not shown). The AC load DC-AC power conversion unit 130 converts DC power into AC power by switching the switching element between a conductive state and a cutoff state.

The load power control unit 170 is realized by, for example, a processor such as a CPU (Central Processing Unit) or an MPU (Micro Processing Unit) executing a program stored in the program memory. Further, some or all of these functional units may be realized by hardware such as LSI (Large Scale Integration), ASIC (Application Specific Integrated Circuit), or FPGA (Field-Programmable Gate Array). The load power control unit 170 is configured to be operable by supplying, for example, 100 V of operating power converted by the auxiliary power supply power converter 100.

The load power control unit 170 controls the load AC-DC power conversion unit 110, the load DC-AC power conversion unit 120, the AC load DC-AC power conversion unit 130, and the chopper circuit 150.

The battery device 200 includes a first terminal T21 to a sixth terminal T26.
The first terminal T21 and the second terminal T22 are electrically connected to the traveling power converter 300. The third terminal T23 and the fourth terminal T24 are electrically connected to the auxiliary equipment group 600. The fifth terminal T25 and the sixth terminal T26 are electrically connected to the auxiliary power supply power converter 100.

The battery device 200 is, for example, a battery having a low insulation category. The battery device 200 includes, for example, an assembled battery BT in which storage battery cells such as a lithium ion battery are connected in series or in parallel, a plurality of contactors BLB1, BLB2, BatDK1, BatDK2, BatCK1, BatCK2, CHK, and a resistor CHRe. , A battery control unit 210 that controls the operation of a plurality of contactors BLB1, BLB2, BatDK1, BatDK2, BatCK1, BatCK2, and CHK.

The battery control unit 210 is realized by, for example, a processor such as a CPU (Central Processing Unit) or an MPU (Micro Processing Unit) executing a program stored in a program memory. Further, some or all of these functional units may be realized by hardware such as LSI (Large Scale Integration), ASIC (Application Specific Integrated Circuit), or FPGA (Field-Programmable Gate Array). The battery control unit 210 is configured to be operable by supplying, for example, operating power obtained by converting the discharge power from the assembled battery BT into a predetermined value.
The battery control unit 210 periodically acquires and monitors the current flowing through the assembled battery BT, the voltage of the storage battery cell, and the temperature of the storage battery cell, and calculates, for example, the SOC (state of charge) of the assembled battery BT. It controls the charging and discharging of the battery device 200.

The contactor BLB1 switches the electrical connection between the positive electrode terminal of the assembled battery BT and the positive main circuit. The contactor BLB2 switches the electrical connection between the negative electrode terminal of the assembled battery BT and the negative main circuit. That is, the contactor BLB1 and the contactor BLB2 are contactors (fourth contactors) that switch the electrical connection state between the assembled battery BT and the first power line (main circuit).

The contactor BatDK1 switches the electrical connection between the positive main circuit and the first terminal T21. The contactor BatDK2 switches the electrical connection between the negative main circuit and the second terminal T22. That is, the contactor BatDK1 and the contactor BatDK2 are contactors (second contactors) that switch the electrical connection state of the power line that supplies power from the assembled battery BT to the traveling DC-AC power conversion unit 330.

The contactor BatCK1 switches the electrical connection between the positive main circuit and the fifth terminal T25. The contactor BatCK2 switches the electrical connection between the negative main circuit and the sixth terminal T26. That is, the contactor BatCK1 and the contactor BatCK2 are contactors (third contactors) that switch the electrical connection state of the power line that supplies power from the assembled battery BT to the load DC-AC power conversion unit 120.

The contactor CHK and the resistor CHRe are connected in parallel. The contactor (first contactor) CHK is a positive main circuit (first main circuit on the positive side) extending between the positive terminal of the assembled battery BT and the first terminal T21, the third terminal T23, and the fifth terminal T25. (1 power line), the second power line connected via the resistor CHRe connected in parallel with the first power line and the path (first power line) connected without passing through the resistor CHRe are switched.

The auxiliary machine group 600 is electrically connected to the third terminal T23 and the fourth terminal T24 of the battery device 200.
DC power is supplied to the auxiliary machine group 600 from the battery device 200. The auxiliary machine group 600 may be supplied with the DC power discharged from the assembled battery BT of the battery device 200, but is not limited to this, and the DC power converted by the load AC-DC power conversion unit 110 is supplied. May be done. Further, the auxiliary equipment group 600 may be supplied with a power obtained by combining the DC power discharged from the assembled battery BT of the battery device 200 and the DC power converted by the load AC-DC power conversion unit 110.

The auxiliary machine group 600 includes, for example, a compressor 640 and blower motors 620 and 630 mounted on a railway vehicle.
The blower motors 620 and 630 are motors of a blower for cooling the traveling motors M1 to M4 mounted on the bogie 3 of a railroad vehicle, and are an inverter and a capacitor (third capacitor) C4 connected to the DC input end of the inverter. It is equipped with C5. The inverter is, for example, an auxiliary power conversion device that converts the power supplied from the battery device 200 into three-phase AC power and supplies it to the load.

The compressor 640 is a brake compressor, and includes an inverter and a capacitor (third capacitor) C6 connected to the DC input terminal of the inverter. The inverter is, for example, an auxiliary power conversion device that converts the power supplied from the battery device 200 into three-phase AC power and supplies it to the load.

In the power conversion system, the battery device 200 can function as a power source for the auxiliary equipment group 600.
For example, when the contactors BLB1, BLB2, and CHK are in the closed state (conducting state) and the contactors BatDK1, BatDK2, BatCK1, and BatCK2 are in the open state (blocking state), the positive electrode terminal of the assembled battery BT is the third. It is electrically connected to the terminal T23, and the negative electrode terminal is electrically connected to the fourth terminal T24. As a result, the battery device 200 can supply DC power to the auxiliary equipment group 600 connected to the third terminal T23 and the fourth terminal T24.

Further, the battery device 200 can function as a power source for the DC load LDC and the AC load LAC.
For example, when the contactors BLB1, BLB2, BatCK1, BatCK2, and CHK are in the closed state (conducting state) and the contactors BatDK1 and BatDK2 are in the open state (blocking state), the positive electrode terminal of the assembled battery BT is the fifth. It is electrically connected to the terminal T25, and the negative electrode terminal is electrically connected to the sixth terminal T26. That is, the battery device 200 can supply DC power to the chopper circuit 150 of the auxiliary power supply power conversion device 100 via the fifth terminal T25 and the sixth terminal T26. The chopper circuit 150 converts the voltage of the DC power supplied from the battery device 200 into a predetermined value, and supplies the DC power to the load DC-AC power conversion unit 120. As a result, the DC power output from the battery device 200 is converted, and power can be supplied to the DC load LDC and the AC load LAC.

Further, the battery device 200 can function as a power source for the traveling motors M1 to M4.
For example, when the contacts BLB1, BLB2, BatDK1, BatDK2, and CHK are in the closed state (conducting state) and the contacts BatCK1 and BatCK2 are in the open state (blocking state), the positive electrode terminal of the assembled battery BT is the first. The negative electrode terminal is electrically connected to the first terminal T31 of the traveling power converter 300 via the terminal T21, and the negative electrode terminal is electrically connected to the second terminal T32 of the traveling power converter 300 via the second terminal T22. To. That is, the battery device 200 can supply DC power to the traveling DC-AC power conversion unit 330 of the traveling power conversion device 300 via the first terminal T21 and the second terminal T22. As a result, the DC power output from the battery device 200 is converted, and power can be supplied to the traveling motors M1 to M4.

As described above, the battery device 200 includes a DC-AC power converter 330 for traveling and a DC-AC for load when, for example, a railroad vehicle is traveling in a non-electrical section or when emergency traveling is performed in the event of a power failure. It is possible to supply the discharge power of the assembled battery BT to the power conversion unit 120 and the auxiliary machine group 600.

The battery device 200 can function as a power source for both the traveling motors M1 to M4 and the auxiliary equipment group 600, for example.
For example, when a railroad vehicle makes an emergency run during a power outage, the battery device 200 may supply electric power to the traveling motors M1 to M4 and the auxiliary equipment group 600 to move the railroad vehicle to a safe place. it can.

At this time, the battery device 200 first charges the capacitors C1, C2, and C4-C6 in order to activate the traveling DC-AC power conversion unit 330 and the inverters mounted on the respective devices of the auxiliary equipment group 600. To do. When charging the capacitors C1, C2, and C4-C6, the contactor CHK of the battery device 200 is set to the open state (cut-off state), and the traveling DC-AC power converter 330 and the auxiliary machine are set via the resistor CHRe. DC power can be supplied to each device in the group 600 to charge the capacitors C1, C2, and C4-C6.

That is, since the resistor CHRe can be used as a common element when charging the capacitors C1, C2, and C4-C6 of a plurality of devices, it is not necessary to provide a resistor for charging in each device. ..

After the charging of the capacitors C1, C2, and C4-C6 is completed, the circuit breaker CHK is closed (conducting state). As a result, it is possible to prevent a large current from flowing to each device of the traveling DC-AC power conversion unit 330 and the auxiliary machine group 600 and causing the device to break down.

Here, the capacities of the capacitors C1, C2, and C4-C6 differ depending on the device, and the time required for charging each of them may also differ. Therefore, the running DC-AC power converter 330 and the inverter of the auxiliary equipment group 600 can start the start-up process when the charging of the capacitors C1, C2, and C4-C6 connected to the respective DC input ends is completed. It is in a state. However, if any of the capacitors C1, C2, and C4-C6 is not fully charged and the device connected to the fully charged capacitor is started, power is not supplied to the charging capacitor, and the other capacitors are not charged. It may interfere with the startup of the device.

Therefore, in the power conversion system 10 of the present embodiment, the running DC-AC power conversion unit 330 and the inverter of the auxiliary equipment group 600 are started up until all the capacitors C1, C2, and C4-C6 are charged. Does not start.

For example, when the charging of the capacitors C1 and C2 of the traveling DC-AC power converter 330 is not completed at the timing when the charging of the capacitor C4 of the inverter of the blower motor 620 is started, the inverter of the blower motor 620 is the capacitor C4. The activation process is started after a predetermined time has elapsed after the charging is completed. At this time, the predetermined time for the inverter of the blower motor 620 to stand by may be the time required for charging the capacitors C1 and C2 (for example, several tens of seconds), and the time required for charging the capacitors C1 and C2 to the capacitor C4. It may be the time obtained by subtracting the time required for charging, or it may be a preset time.

As described above, the inverter of the blower motor 620 is started after the charging of all the capacitors C1, C2, and C4-C6 is completed by performing the start processing after a predetermined time has elapsed after the inverter of the blower motor 620 is fully charged. Therefore, it is possible to activate the traveling DC-AC power conversion unit 330 and the auxiliary equipment group 600 by the discharge power from the battery device 200 to allow the railway vehicle to perform emergency traveling.

When the railroad vehicle makes an emergency run, it is not necessary to supply electric power to all the running motors M1 to M4, and at least one of the running motors M1 to M4 may operate. Therefore, at the time of emergency traveling, at least one of the traveling motors M1 to M4 may be electrically connected to the traveling power converter 300. In that case, if it is not necessary to start the entire auxiliary equipment group 600, the power supply path may be switched so that only the necessary equipment is electrically connected to the battery device 200.

Further, the battery device 200 can simultaneously function as, for example, a power source for the AC load LAC, the DC load LDC, and the auxiliary equipment group 600.
For example, due to a failure of the auxiliary power conversion device 100, high-voltage AC power cannot be obtained from the overhead wire via the load windings (primary winding 500 and tertiary winding 102) of the current collector 400 and the main transformer. In this case, the battery device 200 can simultaneously supply power to the AC load LAC, the DC load LDC, and the auxiliary equipment group 600.

Also in this case, the battery device 200 first charges the capacitors C3-C6 in order to activate the load DC-AC power conversion unit 120 and the inverters mounted on the respective devices of the auxiliary equipment group 600. When charging the capacitors C3-C6, the contactor CHK of the battery device 200 is set to the open state (cut-off state), and the DC-AC power converter 120 for load and the auxiliary equipment group 600 are respectively connected via the resistor CHRe. DC power can be supplied to the above-mentioned equipment to charge the capacitors C3-C6.

That is, since the resistor CHRe can be used as a common element when charging the capacitors C3-C6 of a plurality of devices, it is not necessary to provide a resistor for charging in each device.

After the charging of the capacitors C3-C6 is completed, the circuit breaker CHK is closed (conducting state). As a result, it is possible to prevent a large current from flowing to each device of the load DC-AC power conversion unit 120 and the auxiliary device group 600 and causing the device to fail.

The capacities of the capacitors C3-C6 differ depending on the device, and the time required for charging each may also differ. Therefore, the DC-AC power converter 120 for load and the inverter of the auxiliary equipment group 600 are in a state where the start-up process can be started when the charging of the capacitors C3-C6 connected to the respective DC input ends is completed. There is. However, if any of the capacitors C3-C6 is not fully charged and the device connected to the fully charged capacitor is started, power is not supplied to the charging capacitor and the other devices are started. May interfere.

Therefore, in the power conversion system 10 of the present embodiment, the load DC-AC power conversion unit 120 and the inverters of the auxiliary equipment group 600 do not start the start-up process until all the capacitors C3-C6 are charged.
For example, when the charging of the capacitor C3 of the load DC-AC power conversion unit 120 is not completed at the timing when the charging of the capacitor C4 of the inverter of the blower motor 620 is started, the inverter of the blower motor 620 is charged with the capacitor C4. After the completion, the start-up process is started after a predetermined time has elapsed. At this time, the predetermined time for the inverter of the blower motor 620 to stand by may be the time required for charging the capacitor C3 (for example, several tens of seconds), and is required for charging the capacitor C4 from the time required for charging the capacitor C3. It may be the time minus the time, or it may be a preset time.

As described above, by performing the start-up process after a predetermined time has elapsed after the inverter of the blower motor 620 is fully charged, the inverter of the blower motor 620 is started after all the charging of the capacitors C3-C6 is completed, and the battery The DC-AC power conversion unit 120 for load and the auxiliary equipment group 600 can be activated by the discharge power from the device 200 to supply power to the AC load LAC, the DC load LDC, and the auxiliary equipment group 600.

When the power converter 100 for the auxiliary power supply fails, it is not necessary to supply power to all of the AC load LAC, the DC load LDC, and the auxiliary equipment group 600. For example, the AC load LAC is not supplied with power, and the DC load LDC Power may be supplied only to the auxiliary equipment group 600. In this case, when the auxiliary power conversion device 100 fails, for example, the DC load LDC is electrically connected to the auxiliary power conversion device 100, and the AC load LAC is electrically cut off from the auxiliary power conversion device 100. You may. Further, if it is not necessary to start the entire auxiliary equipment group 600, the power supply path may be switched so that only the necessary equipment is electrically connected to the battery device 200.

As described above, according to the power conversion system 10 of the present embodiment, when charging the capacitor mounted on the connected device by the discharge power from the battery device 200, the capacitor is charged via the common resistor CHRe. It is possible to supply charging power, and it is possible to miniaturize the system without increasing the number of parts for forming the system.

Further, according to the power conversion system 10 of the present embodiment, when charging the capacitors mounted on the plurality of devices, the plurality of devices are started after the charging of all the capacitors is completed, so that the plurality of devices are safe. It will be possible to start up.
Therefore, according to the present embodiment, it is possible to provide a power conversion system capable of safely starting a plurality of devices by the power supplied from the battery device.

FIG. 3 is a diagram schematically showing another configuration example of the power conversion system of the embodiment.
In the power conversion system 10 shown in FIG. 3, the configuration of the battery device 200 is different from the configuration shown in FIG.
In the battery device 200 shown in FIG. 3, the contactor CHK and the resistor CHRe are connected in series in a path connected in parallel with the contactor BLB1. That is, between the positive electrode terminal of the assembled battery BT and the first terminal T21, between the positive electrode terminal of the assembled battery BT and the third terminal T23, and between the positive electrode terminal of the assembled battery BT and the fifth terminal T25. Each is provided with a path (first power line) connected via the contactor BLB1 and a path (second power line) connected via the contactor CHK and the resistor CHRe. The contactor CHK and the contactor BLB1 can switch the power supply path between the first power line and the second power line.
Except for the configuration of the battery device 200, the power conversion system 10 shown in FIG. 3 has the same configuration as the power conversion system 10 shown in FIG.

In the power conversion system 10 shown in FIG. 3, the battery device 200 can function as a power source for the auxiliary equipment group 600.
For example, when the contactors BLB1 and BLB2 are in the closed state (conducting state) and the contactors BatDK1, BatDK2, BatCK1, BatCK2, and CHK are in the open state (blocking state), the positive electrode terminal of the assembled battery BT is the third. It is electrically connected to the terminal T23, and the negative electrode terminal is electrically connected to the fourth terminal T24. As a result, the battery device 200 can supply DC power to the auxiliary equipment group 600 connected to the third terminal T23 and the fourth terminal T24.

Further, the battery device 200 can function as a power source for the DC load LDC and the AC load LAC.
For example, when the contactors BLB1, BLB2, BatCK1, and BatCK2 are in the closed state (conducting state) and the contactors BatDK1, BatDK2, and CHK are in the open state (blocking state), the positive electrode terminal of the assembled battery BT is the fifth. It is electrically connected to the terminal T25, and the negative electrode terminal is electrically connected to the sixth terminal T26. That is, the battery device 200 can supply DC power to the chopper circuit 150 of the auxiliary power supply power conversion device 100 via the fifth terminal T25 and the sixth terminal T26. The chopper circuit 150 converts the voltage of the DC power supplied from the battery device 200 into a predetermined value, and supplies the DC power to the load DC-AC power conversion unit 120. As a result, the DC power output from the battery device 200 is converted, and power can be supplied to the DC load LDC and the AC load LAC.

Further, the battery device 200 can function as a power source for the traveling motors M1 to M4.
For example, when the contacts BLB1, BLB2, BatDK1, and BatDK2 are in the closed state (conducting state) and the contacts BatCK1, BatCK2, and CHK are in the open state (blocking state), the positive electrode terminal of the assembled battery BT is the first. The negative electrode terminal is electrically connected to the first terminal T31 of the traveling power converter 300 via the terminal T21, and the negative electrode terminal is electrically connected to the second terminal T32 of the traveling power converter 300 via the second terminal T22. To. That is, the battery device 200 can supply DC power to the traveling DC-AC power conversion unit 330 of the traveling power conversion device 300 via the first terminal T21 and the second terminal T22. As a result, the DC power output from the battery device 200 is converted, and power can be supplied to the traveling motors M1 to M4.

As described above, the battery device 200 includes a DC-AC power converter 330 for traveling and a DC-AC for load when, for example, a railroad vehicle is traveling in a non-electrical section or when emergency traveling is performed in the event of a power failure. It is possible to supply the discharge power of the assembled battery BT to the power conversion unit 120 and the auxiliary machine group 600.

The battery device 200 can function as a power source for both the traveling motors M1 to M4 and the auxiliary equipment group 600, for example.
For example, when a railroad vehicle makes an emergency run during a power outage, the battery device 200 may supply electric power to the traveling motors M1 to M4 and the auxiliary equipment group 600 to move the railroad vehicle to a safe place. it can.

At this time, the battery device 200 first charges the capacitors C1, C2, and C4-C6 in order to activate the traveling DC-AC power conversion unit 330 and the inverters mounted on the respective devices of the auxiliary equipment group 600. To do. When charging the capacitors C1, C2, and C4-C6, the contactor BLB1 of the battery device 200 is set to the open state (blocked state), the contactor CHK is set to the closed state (conducting state), and the contactor CHK is set to the closed state (conducting state) via the resistor CHRe. DC power can be supplied to the traveling DC-AC power conversion unit 330 and each device of the auxiliary equipment group 600 to charge the capacitors C1, C2, and C4-C6.

That is, since the resistor CHRe can be used as a common element when charging the capacitors C1, C2, and C4-C6 of a plurality of devices, it is not necessary to provide a resistor for charging in each device. ..

After the charging of the capacitors C1, C2, and C4-C6 is completed, the contactor CHK is opened (blocked state). As a result, it is possible to prevent a large current from flowing to each device of the traveling DC-AC power conversion unit 330 and the auxiliary machine group 600 and causing the device to break down.

Further, the battery device 200 can simultaneously function as, for example, a power source for the AC load LAC, the DC load LDC, and the auxiliary equipment group 600.
For example, due to a failure of the auxiliary power conversion device 100, high-voltage AC power cannot be obtained from the overhead wire via the load windings (primary winding 500 and tertiary winding 102) of the current collector 400 and the main transformer. In this case, the battery device 200 can simultaneously supply power to the AC load LAC, the DC load LDC, and the auxiliary equipment group 600.

Also in this case, the battery device 200 first charges the capacitors C3-C6 in order to activate the load DC-AC power conversion unit 120 and the inverters mounted on the respective devices of the auxiliary equipment group 600. When charging the capacitors C3-C6, the contactor BLB1 of the battery device 200 is set to the open state (cut-off state), the contactor CHK is set to the closed state (conducting state), and the DC for load is set via the resistor CHRe. DC power can be supplied to the AC power conversion unit 120 and each device of the auxiliary equipment group 600 to charge the capacitors C3-C6.

That is, since the resistor CHRe can be used as a common element when charging the capacitors C3-C6 of a plurality of devices, it is not necessary to provide a resistor for charging in each device.

After the charging of the capacitors C3-C6 is completed, the circuit breaker CHK is opened (circuited state). As a result, it is possible to prevent a large current from flowing to each device of the load DC-AC power conversion unit 120 and the auxiliary device group 600 and causing the device to fail.

As described above, according to the power conversion system 10 shown in FIG. 3, similarly to the power conversion system 10 described above, when charging the capacitor mounted on the connected device by the discharge power from the battery device 200. It is possible to supply charging power via a common resistor CHRe, and it is possible to miniaturize the system without increasing the number of parts for forming the system.

Further, according to the power conversion system 10 shown in FIG. 3, when charging the capacitors mounted on a plurality of devices, the plurality of devices are started after the charging of all the capacitors is completed, so that the plurality of devices are safe. It will be possible to start up.
Therefore, according to the power conversion system 10 shown in FIG. 3, it is possible to provide a power conversion system capable of safely starting a plurality of devices by the power supplied from the battery device.

Further, according to the power conversion system 10 described above, the battery device 200 is connected between the load AC-DC power conversion unit 110 and the AC load DC-AC power conversion unit 120, and an auxiliary machine is connected to the battery device 200. By connecting the group 600, the battery device 200 can function as a power source for the auxiliary equipment group 600. Therefore, according to the power conversion system 10, power is supplied from the battery device 200 to the auxiliary equipment group 600 even if the current collector 400 does not supply power when the railroad vehicle is traveling in a non-powered section or when there is a power failure. Can continue to supply. As a result, according to the power conversion system 10, it is possible to suppress a decrease in the power supplied to the auxiliary equipment group 600.

Further, according to the power conversion system 10, the load winding of the main transformer is wound by connecting the battery device 200 between the load AC-DC power conversion unit 110 and the AC load DC-AC power conversion unit 120. When the power supplied to the load AC-DC power conversion unit 110 is reduced, the power corresponding to the decrease in power is discharged from the battery device 200, so that the load DC-AC power conversion unit 120 is discharged from the battery device 200. Can supply discharge power to. As a result, according to the power conversion system 10, it is possible to suppress a decrease in the power supplied to the AC load LAC and the DC load LDC of the railway vehicle.

Further, according to the power conversion system 10, since the load AC-DC power conversion unit 110 includes a switching circuit including a plurality of switching elements, the DC power output from the load AC-DC power conversion unit 110 is stabilized. Can be made to. That is, according to the load AC-DC power conversion unit 110, it is possible to convert to DC power having less time change than a rectifier using a diode. As a result, according to the power conversion system 10, when the DC power from the load AC-DC power conversion unit 110 to the load DC-AC power conversion unit 120 decreases, the load DC-AC power from the battery device 200 Discharge power can be quickly supplied to the conversion unit 120.

Further, according to the power conversion system 10, since the discharge power can be supplied from the battery device 200, the capacity of the capacitor C3 is supplied to the AC load LAC and the DC load LDC when the railway vehicle passes through the non-electric section. It is not necessary to increase the capacity in consideration of the capacity for compensating for electric power.

Further, according to the power conversion system 10, the DC power output from the load AC-DC power conversion unit 110 is stabilized by being controlled by the chopper circuit 150, and is output from the load AC-DC power conversion unit 110. By supplying the generated power to the battery device 200, the battery device 200 can be charged without giving a large load to the charging resistance of the battery device 200.

Further, according to the power conversion system 10, the battery device 200 can be discharged in an emergency to supply DC power to the traveling DC-AC power conversion unit 330. As a result, according to the power conversion system 10, the railway vehicle can be driven by driving the traveling motors M1 to M4 using the discharge power of the battery device 200 in an emergency.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

M1 to M4 ... Travel motor, C1-C6 ... Condenser, CHK ... First contactor, CHRe ... Resistor, 100 ... Auxiliary power supply power converter, 102, 302, 500 ... Main transformer, 110 ... Load AC- DC power converter, 120 ... DC-AC power converter for load, 130 ... DC-AC power converter for AC load, 200 ... Battery device, BT ... Assembly battery, 300 ... Running power converter, 320 ... For running AC-DC power converter, 330 ... DC-AC power converter for running, 400 ... current collector, 600 ... auxiliary equipment group.

Claims (5)

A transformer that steps down the power from the overhead line,
The traveling AC-DC power conversion unit that converts and outputs the AC power supplied through the secondary winding of the transformer and the DC power output from the traveling AC-DC power conversion unit for traveling. A traveling power conversion device having a traveling DC-AC power conversion unit that converts the driving power of a motor and a first capacitor connected to an input end of the traveling DC-AC power conversion unit.
A load AC-DC power conversion unit that converts AC power supplied through the tertiary winding of the transformer into DC power, and a DC power converted by the load AC-DC power conversion unit are used as an AC load and It has a load DC-AC power conversion unit that converts and outputs AC power used to drive a DC load, and a second capacitor connected to the input end of the load DC-AC power conversion unit. Power converter for auxiliary power supply and
The power line connecting the load AC-DC power conversion unit and the load DC-AC power conversion unit, and the traveling AC-DC power conversion unit and the traveling DC-AC power conversion unit are connected. With the battery device connected to the power line,
An auxiliary power conversion device connected to a power line connecting the auxiliary power supply power conversion device and the battery device and converting the supplied power into three-phase AC power, and an input terminal of the auxiliary power conversion device. A third capacitor connected to an auxiliary machine, and an auxiliary machine group having an auxiliary machine operated by the electric power supplied from the power conversion device for the auxiliary machine are provided.
The battery device includes a common first power line and a first power line that supply power from the assembled battery to the traveling power conversion device, the auxiliary power supply power conversion device, and the auxiliary equipment group. A power conversion system including a second power line connected in parallel with the power line, a resistor provided in the second power line, and a first contactor for switching a power supply path between the first power line and the second power line. The power conversion system according to claim 1, wherein the first contactor is connected in parallel with the resistor in the first power line. The power conversion system according to claim 1, wherein the first contactor is connected in series with the resistor in the second power line. Claims 1 to 3, wherein when the auxiliary machine is started by the DC power supplied from the battery device, the start-up process is started after a predetermined time has elapsed from the completion of charging of the third capacitor. The power conversion system according to any one of the above. The battery device includes a second contactor that switches the electrical connection state of the power line that supplies power from the assembled battery to the traveling DC-AC power conversion unit, and the load DC-AC power conversion unit from the assembled battery. Any of claims 1 to 4, comprising a third contactor for switching the electrical connection state of the power line for supplying power to the battery and a fourth contactor for switching the electrical connection state between the assembled battery and the power line. The power conversion system according to item 1.

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