WO2016002218A1 - 漏電保護装置および漏電保護システム - Google Patents
漏電保護装置および漏電保護システム Download PDFInfo
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- WO2016002218A1 WO2016002218A1 PCT/JP2015/003309 JP2015003309W WO2016002218A1 WO 2016002218 A1 WO2016002218 A1 WO 2016002218A1 JP 2015003309 W JP2015003309 W JP 2015003309W WO 2016002218 A1 WO2016002218 A1 WO 2016002218A1
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- switch
- leakage
- storage battery
- branch
- conductive path
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02H—EMERGENCY PROTECTIVE CIRCUIT ARRANGEMENTS
- H02H3/00—Emergency protective circuit arrangements for automatic disconnection directly responsive to an undesired change from normal electric working condition with or without subsequent reconnection ; integrated protection
- H02H3/16—Emergency protective circuit arrangements for automatic disconnection directly responsive to an undesired change from normal electric working condition with or without subsequent reconnection ; integrated protection responsive to fault current to earth, frame or mass
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02H—EMERGENCY PROTECTIVE CIRCUIT ARRANGEMENTS
- H02H3/00—Emergency protective circuit arrangements for automatic disconnection directly responsive to an undesired change from normal electric working condition with or without subsequent reconnection ; integrated protection
- H02H3/26—Emergency protective circuit arrangements for automatic disconnection directly responsive to an undesired change from normal electric working condition with or without subsequent reconnection ; integrated protection responsive to difference between voltages or between currents; responsive to phase angle between voltages or between currents
- H02H3/32—Emergency protective circuit arrangements for automatic disconnection directly responsive to an undesired change from normal electric working condition with or without subsequent reconnection ; integrated protection responsive to difference between voltages or between currents; responsive to phase angle between voltages or between currents involving comparison of the voltage or current values at corresponding points in different conductors of a single system, e.g. of currents in go and return conductors
- H02H3/33—Emergency protective circuit arrangements for automatic disconnection directly responsive to an undesired change from normal electric working condition with or without subsequent reconnection ; integrated protection responsive to difference between voltages or between currents; responsive to phase angle between voltages or between currents involving comparison of the voltage or current values at corresponding points in different conductors of a single system, e.g. of currents in go and return conductors using summation current transformers
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J3/00—Circuit arrangements for ac mains or ac distribution networks
- H02J3/28—Arrangements for balancing of the load in a network by storage of energy
- H02J3/32—Arrangements for balancing of the load in a network by storage of energy using batteries with converting means
- H02J3/322—Arrangements for balancing of the load in a network by storage of energy using batteries with converting means the battery being on-board an electric or hybrid vehicle, e.g. vehicle to grid arrangements [V2G], power aggregation, use of the battery for network load balancing, coordinated or cooperative battery charging
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
- H02J7/0029—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries with safety or protection devices or circuits
- H02J7/0031—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries with safety or protection devices or circuits using battery or load disconnect circuits
Definitions
- the present invention generally relates to a leakage protection device and a leakage protection system using the leakage protection device, and more particularly, to a leakage protection device configured to perform leakage protection when the occurrence of leakage is detected, and leakage protection using the leakage protection device About the system.
- V2H Vehicle-to-Home
- a storage battery battery mounted on an electric vehicle as a distributed power source.
- electric power not used for driving the vehicle can be supplied to an electric load at home.
- a storage battery can be charged using midnight power.
- a technology that detects the occurrence of earth leakage (ground fault) when charging a storage battery mounted on a vehicle, and performs the earth leakage protection by stopping charging when the occurrence of earth leakage is detected.
- ground fault ground fault
- Document 1 Japanese Patent No. 5369833
- the present invention has been made in view of the above-mentioned reasons, and the purpose thereof is a leakage protection device capable of performing leakage protection when the occurrence of leakage is detected during charging and discharging of a storage battery, and leakage protection using the same. To provide a system.
- the earth leakage protection device (1) of the present invention is configured to detect the occurrence of earth leakage in the conductive path (7) for transmitting power exchanged between the storage battery (21) and the system power source (3).
- a control unit (12) configured to control the open / close state of each of the second switches (62) provided in the control unit based on the detection result of the leakage detection unit (11).
- the control unit (12) is configured to detect the first switch (61) and the second switch (62).
- At least the first switch (61) is opened, and when the leakage detector (11) detects the occurrence of leakage during the discharge of the storage battery (21), the first switch ( 61) and the second switch (62), at least the second switch (62) is opened.
- the leakage protection system (10) includes the leakage protection device (1), the first switch (61) provided in the conductive path (7), and the first switch in the conductive path (7).
- the second switch (62) provided closer to the storage battery (21) than the first switch (61).
- leakage protection can be performed when leakage is detected during charging and discharging of the storage battery.
- FIG. 1 illustrates one or more embodiments in accordance with the present teachings, but are by way of example and not limitation.
- like numerals refer to the same or similar elements.
- FIG. 1 shows a schematic configuration of a leakage protection device 1 and a leakage protection system 10 including the leakage protection device 1 according to the present embodiment.
- the leakage protection system 10 uses V2H (Vehicle) to supply discharge power of a storage battery 21 (battery) mounted on a vehicle 2 (electric vehicle) to one or more electric loads 43 in the home. to Home)
- V2H Vehicle
- Each of the leakage protection device 1 and the leakage protection system 10 of the present embodiment performs leakage protection when the occurrence of leakage is detected during charging and discharging of the storage battery 21.
- the earth leakage protection by each of the earth leakage protection apparatus 1 and the earth leakage protection system 10 of this embodiment is not limited to the charging / discharging of the storage battery 21 of the vehicle 2 used for the V2H system. Can also respond.
- AC power is supplied from the system power supply 3 to the plurality of electric loads 43 via the distribution board 4 (the main breaker 41 and the plurality of branch breakers 42).
- the power conversion device 5 includes a power conversion unit 51 that is electrically connected to the system power supply 3 via the distribution board 4.
- the power conversion unit 51 includes a power conversion circuit that converts AC power supplied from the system power supply 3 into DC power.
- the power conversion unit 51 is electrically connected to the storage battery 21 mounted on the vehicle 2 via a leakage detecting unit 11, a first switch 61, and a second switch 62, which will be described later.
- the storage battery 21 is charged by supplying the direct-current power generated by the power conversion unit 51 to the storage battery 21.
- the electric power stored in the storage battery 21 can be used not only for driving the vehicle 2 (electric vehicle), but also the surplus electric power can be supplied to one or more electric loads 43 in the home.
- the electricity bill can be reduced by charging the storage battery 21 at midnight when the electricity rate is cheap, and discharging the storage battery 21 during the daytime when the electricity rate is expensive and supplying power to one or more electrical loads 43. .
- the power conversion unit 51 supports bidirectional power conversion.
- the power conversion unit 51 converts the DC power, which is the discharge power of the storage battery 21, into AC power, links it with the system power supply 3, and supplies it to the electric load 43 via the distribution board 4.
- the storage battery 21 and the distribution board 4 are electrically connected by the conductive path 7 including a pair of electrical paths.
- the power exchanged between the power supply 21 and the system power supply 3 is transmitted.
- the high potential side is referred to as a high potential side electric circuit 71
- the low potential side is referred to as a low potential side electric circuit 72.
- the first switch 61 is provided in the conductive path 7 in the power conversion device 5 and conducts or blocks the conductive path 7 according to the open / close state.
- the first switch 61 includes a pair of contacts (first high potential side contact 611 and first low potential side contact 612) provided in the high potential side electrical circuit 71 and the low potential side electrical circuit 72, respectively. Is provided.
- the first high potential side contact 611 conducts the high potential side electric circuit 71 in the closed state and interrupts the high potential side electric circuit 71 in the open state.
- the first low potential side contact 612 conducts the low potential side electric circuit 72 in the closed state and interrupts the low potential side electric circuit 72 in the open state.
- the open / close state of the first switch 61 (the first high potential side contact 611 and the first low potential side contact 612) is controlled by the control unit 12 of the leakage protection device 1, and leakage occurs. It is normally controlled to be closed.
- the second switch 62 is provided in the conductive path 7 in the vehicle 2 and conducts or blocks the conductive path 7 according to the open / close state.
- the second switch 62 has a pair of contacts (second high potential side contact 621 and second low potential side contact 622) provided on the high potential side electrical circuit 71 and the low potential side circuit 72, respectively. Is provided.
- the second high potential side contact 621 conducts the high potential side electric circuit 71 in the closed state and interrupts the high potential side electric circuit 71 in the open state.
- the second low potential side contact 622 conducts the low potential side electric circuit 72 in the closed state, and interrupts the low potential side electric circuit 72 in the open state.
- the open / close state of the second switch 62 (the second high potential side contact 621 and the second low potential side contact 622) is controlled by the control unit 12 of the leakage protection device 1, and leakage occurs. It is normally controlled to be closed.
- the leakage protection device 1 is provided in the power conversion device 5, the leakage detection unit 11 is configured to detect the occurrence of leakage in the conductive path 7, and the control unit 12 detects the detection result of the leakage detection unit 11. Is configured to control the open / close states of the first switch 61 and the second switch 62, respectively.
- the leakage detection unit 11 is configured to detect the occurrence of leakage in the conductive path 7 based on the current flowing in the conductive path 7.
- the leakage detection unit 11 is configured by, for example, a current detector, and detects the balance / unbalance between the current flowing through the high potential side circuit 71 and the current flowing through the low potential side circuit 72. The occurrence of leakage in the conductive path 7 is detected.
- the current detector is, for example, a flux gate type or Hall element type current detector.
- the low potential side electric circuit 72 is electrically connected to the ground by the impedance circuit 730 and the ground line 73.
- the impedance circuit 730 is a high resistance, preferably a resistance of 40 k ⁇ or more.
- one end of the ground line 73 is connected to a position between the power conversion unit 51 and the leakage detection unit 11 in the low potential side electric circuit 72 via the impedance circuit 730. That is, the leakage detection unit 11 of the power conversion device 5 is provided closer to the storage battery 21 than the connection point between the conductive path 7 and the ground side. Then, the leakage detector 11 detects the occurrence of leakage in the conductive path 7 between the leakage detector 11 and the storage battery 21.
- the leakage detection by the leakage detection unit 11 will be described with reference to FIGS.
- the current (DC current) output from the power converter 51 is assumed to be I1.
- the current flowing through each of the high potential side circuit 71 and the low potential side circuit 72 becomes I 1, and the current I 1 is supplied to the storage battery 21. That is, the current flowing through the high potential side circuit 71 and the low potential side circuit 72 is in an equilibrium state at the current detection location of the leakage detection unit 11, and the leakage detection unit 11 determines that no leakage has occurred.
- the current flowing through the high potential side circuit 71 is I1
- the current (DC current) output from the storage battery 21 is I2.
- the current flowing in each of the high potential side circuit 71 and the low potential side circuit 72 becomes I 2, and I 2 is supplied to the power converter 51. That is, the current flowing through the high potential side circuit 71 and the low potential side circuit 72 is in an equilibrium state at the current detection location of the leakage detection unit 11, and the leakage detection unit 11 determines that no leakage has occurred.
- the leakage detector 11 can detect the occurrence of leakage in the conductive path 7 both when the storage battery 21 is charged and discharged.
- the control unit 12 is configured to be able to communicate with the first switch 61 and the second switch 62, and the first switch 61 and the second switch 62. Controls the open / close state of.
- the control unit 12 is connected to each of the first switch 61 and the second switch 62 via, for example, dedicated first and second communication lines, and the first and second communications. By transmitting a control signal through the line, the open / close states of the first switch 61 and the second switch 62 are individually controlled.
- the communication method between the control unit 12 and the first switch 61 and the second switch 62 is not limited to the above. For example, power line communication (PLC: Power : Line ⁇ Communication) using the conductive path 7 or Wireless communication may be used.
- PLC Power line communication
- control part 12 controls the open / close state of each of the 1st switch 61 and the 2nd switch 62 based on the detection result of the leak detection part 11.
- the control unit 12 switches the first switch 61 from the closed state to the open state when the leakage detection unit 11 detects the occurrence of leakage during charging of the storage battery 21.
- the first switch 61 is located on the upstream side of the current flowing through the conductive path 7 (see FIG. 2). Therefore, when the first switch 61 is opened and the conductive path 7 is interrupted, leakage protection for stopping current supply to the leakage point is performed. That is, the flow of the leakage current that passes through the leakage point can be stopped.
- the control unit 12 switches the second switch 62 from the closed state to the open state when the leakage detection unit 11 detects the occurrence of leakage when the storage battery 21 is discharged.
- the second switch 62 is located on the upstream side of the current flowing through the conductive path 7 (see FIG. 3). Therefore, the second switch 62 is opened and the conductive path 7 is interrupted, so that leakage protection is performed to stop the current supply to the leakage point. That is, the flow of the leakage current that passes through the leakage point can be stopped.
- the leakage protection device 1 of the present embodiment includes the leakage detection unit 11 and the control unit 12.
- the leakage detection unit 11 detects the occurrence of leakage in the conductive path 7 that transmits power exchanged between the storage battery 21 and the system power supply 3.
- the control unit 12 determines whether the first switch 61 provided in the conductive path 7 and the second switch 62 provided on the storage battery 21 side of the first path 61 in the conductive path 7 Control is performed based on the detection result of the detection unit 11. Specifically, when the leakage detection unit 11 detects the occurrence of leakage during charging of the storage battery 21, the control unit 12 is at least a first switch among the first switch 61 and the second switch 62. 61 is opened. In addition, the controller 12 opens at least the second switch 62 of the first switch 61 and the second switch 62 when the leakage detection unit 11 detects the occurrence of leakage when the storage battery 21 is discharged. Put it in a state.
- the leakage protection system 10 of the present embodiment is provided on the storage battery 21 side of the leakage protection device 1, the first switch 61 provided in the conductive path 7, and the first switch 61 in the conductive path 7. And a second switch 62.
- an intermediate conductive path constituting a part of the conductive path 7 is electrically connected between a first switch 61 and a second switch 62. That is, the conductive path 7 includes, in addition to the intermediate conductive path, a first conductive path electrically connected between the power conversion unit 51 and the first switch 61, and the second switch 62.
- a second conductive path electrically connected to the storage battery 21.
- each of the earth leakage protection device 1 and the earth leakage protection system 10 is conductive among the first switch 61 and the second switch 62 according to the charging and discharging of the storage battery 21.
- the switch located on the upstream side of the current flowing in the path 7 is opened. Specifically, when a leakage occurs during charging of the storage battery 21, the first switch 61 provided on the system power supply 3 side is opened, and the conductive path 7 is cut off on the upstream side of the current flowing through the conductive path 7. By doing so, leakage protection is performed.
- each of the leakage protection device 1 and the leakage protection system 10 of the present embodiment flows to the conductive path 7 according to the charging and discharging of the storage battery 21 when a leakage occurs in the conductive path 7.
- the conductive path 7 is interrupted on the upstream side of the current.
- the leakage protection device 1 is built in the power conversion device 5, but may be configured separately from the power conversion device 5.
- the first switch 61 is built in the power conversion device 5, but may be configured separately from the power conversion device 5.
- the second switch 62 is built in the vehicle 2, but may be configured separately from the vehicle 2.
- the control unit 12 controls the first switch 61 and the second switch 62 according to charging and discharging of the storage battery 21.
- the controller 12 may be configured to sequentially open the first switch 61 and the second switch 62 when the leakage detection unit 11 detects the occurrence of a leakage. Since the first switch 61 and the second switch 62 are sequentially controlled to be in the open state, the conductive path 7 is interrupted between the upstream side and the downstream side of the current flowing through the conductive path 7, thereby providing more reliable protection. It is possible to improve the safety.
- control part 12 is comprised so that the 1st switch 61 and the 2nd switch 62 may be made into an open state in the order decided according to the time of charge of the storage battery 21, and the time of discharge. Also good.
- the control unit 12 opens the second switch 62 after opening the first switch 61.
- the control part 12 makes the 1st switch 61 an open state after opening the 2nd switch 62, when the leak detection part 11 detects generation
- the switch on the upstream side of the current flowing in the conductive path 7 is preferentially selected from the first switch 61 and the second switch 62.
- the leakage protection can be performed earlier.
- the switch on the downstream side of the current flowing through the conductive path 7 is also opened to interrupt the conductive path 7, leakage protection can be performed more reliably, and safety can be further improved.
- control part 12 may be comprised so that both the 1st switch 61 and the 2nd switch 62 may be made into an open state simultaneously, when the leak detection part 11 detects generation
- the conductive path 7 is interrupted between the upstream side and the downstream side of the current flowing through the conductive path 7, so that more reliable protection can be performed and the safety can be further improved.
- the leakage detection unit 11A of the present modification has a leakage current in the conductive path 7 based on a current flowing in the ground line 73 that electrically connects the conductive path 7 (low potential side electric path 72) and the ground via the impedance circuit 730. Is configured to detect the occurrence of
- the earth leakage detection unit 11 ⁇ / b> A is composed of, for example, a flux gate type or Hall element type current detector, and detects a current flowing through the impedance circuit 730 and the ground line 73.
- a flux gate type or Hall element type current detector detects a current flowing through the impedance circuit 730 and the ground line 73.
- the leakage detection unit 11A has a configuration in which only one line (ground wire 73) is surrounded by a core (not shown), whereas the leakage detection unit 11 described above has two lines (high potential side circuit). 71 and the low potential side electric circuit 72) are surrounded by a core (see FIG. 1). Therefore, the leakage detection unit 11A of the present modification can be reduced in size as compared with the leakage detection unit 11.
- the charge / discharge circuit 22 is electrically connected to the storage battery 21 instead of the power conversion unit 51 described above, and power conversion is performed using the charge / discharge circuit 22.
- the charge / discharge circuit 22 is electrically connected between the second switch 62 and the storage battery 21.
- the charging / discharging circuit 22 converts AC power supplied from the system power supply 3 into DC power and supplies it to the storage battery 21, and converts DC power output from the storage battery 21 into AC power. DC-AC conversion supplied to the load 43 is performed.
- the conductive path 7 ⁇ / b> A of the present modification is composed of a pair of electric paths 70 a and 70 b that transmit AC power, and one of the electric paths 70 b is electrically connected to the ground via the ground line 73. Specifically, the neutral wire on the secondary side of the pole transformer (distribution transformer) is grounded via the ground wire 73.
- the conductive path 7A includes a first conductive path electrically connected between the distribution board 4 and the first switch 61, and a second switch 62. And a second conductive path electrically connected between the storage battery 21 and the storage battery 21.
- the leakage detection unit 11B of the present modification is configured by a current detector using, for example, a current transformer (CT), and balances current flowing in each of the pair of electric circuits 70a and 70b constituting the conductive path 7A. By detecting the imbalance, the occurrence of leakage in the conductive path 7A, specifically, the electric circuit 70a, is detected.
- CT current transformer
- the leakage protection device 1 of the present modification can also detect the occurrence of leakage in the conductive path 7A that transmits AC power. Then, when a leakage occurs in the conductive path 7A, the leakage protection device 1 blocks the conductive path 7A on the upstream side of the current flowing through the conductive path 7A according to charging and discharging of the storage battery 21. Thereby, since the leakage protection device 1 of the present modification can perform leakage protection regardless of whether the storage battery 21 is charged or discharged, safety is improved and damage to the device can be prevented.
- FIG. 2 The schematic block diagram of the earth-leakage protection apparatus 1 of this embodiment and the earth-leakage protection system 10 provided with this is shown in FIG.
- the conductive path 7 ⁇ / b> B that transmits the power exchanged between the storage battery 21 and the system power supply 3 branches from the main circuit 74 that electrically connects the storage battery 21 and the system power supply 3, and the main circuit 74.
- control part 12A of this embodiment controls the opening-and-closing state of branch switch 63 provided in branch circuit 75.
- a plurality of branch circuits 75 are branched from the main circuit 74, and each of the plurality of branch circuits 75 is electrically connected to the electrical load 44 via the branch switch 63.
- symbol is attached
- the main electric path 74 of the conductive path 7B in the present embodiment electrically connects the storage battery 21 and the system power source 3. That is, the main electric circuit 74 has the same configuration as that of the conductive path 7 of the first embodiment, in other words, the conductive path 7 of the first embodiment has only the main electric circuit 74 in the conductive path 7B of the present embodiment.
- the first switch 61 is provided in the main electric circuit 74 in the power conversion device 5, and the second switch 62 is provided in the main electric circuit 74 in the vehicle 2.
- Each branch electric circuit 75 is an electric circuit branched from the main electric circuit 74 between the first switch 61 and the second switch 62, and is electrically connected to an electric load 44 operated by DC power.
- the conductive path 7 ⁇ / b> B in the present embodiment includes three branch electric circuits 75, and an electric load 44 is electrically connected to each branch electric circuit 75. In the present embodiment, each electric load 44 is electrically connected to the ground.
- the number of branch electric circuits 75 is not limited to three, and may be one or a plurality other than three.
- each branch electric circuit 75 is provided with a branch switch 63 that conducts or cuts off the branch electric circuit 75 according to the open / close state.
- the branch switch 63 has the same configuration as that of the first switch 61 and the second switch 62, and includes a pair of contacts provided on each of the pair of circuit paths constituting the branch circuit 75. Further, the branch switch 63 is configured to be able to communicate with the control unit 12A of the leakage protection device 1 in the same manner as the first switch 61 and the second switch 62.
- the open / close state of the branch switch 63 is controlled by the control unit 12A, and is controlled to be closed during normal times when no leakage occurs.
- the repeater 8 is connected to the preceding stage of the branch switch 63 in each branch circuit 75.
- the repeater 8 includes a power conversion unit 81 configured by a DC-DC converter circuit, and the power conversion unit 81 supplies the DC power output from the power conversion unit 51 of the power conversion device 5 or the storage battery 21 to a desired value. It is converted to DC power and supplied to the electrical load 44.
- the power converter 81 causes the influence of voltage fluctuation and current steep fluctuation in the conductive path 7B. Is suppressed. That is, the power conversion unit 81 stabilizes the power supply quality in the conductive path 7B and suppresses the influence of the load fluctuation of the electric load 44 on the system power supply 3.
- the power conversion unit 81 is connected to the upstream of the branch switch 63 as the relay 8, but is not limited to this connection position, and an electric power is connected between the system power supply 3 and the electric load 44. As long as they are connected.
- the power conversion unit 81 may be provided after the branch switch 63, in a connection plug of the electric load 44, or in the electric load 44.
- the power conversion unit 81 may be provided in the main electric circuit 74 (for example, the output stage of the power conversion device 5), and one power conversion unit 81 may be configured to supply DC power to each electric load 44. .
- the charging / discharging circuit 22 like the 2nd modification in Embodiment 1 (refer FIG.
- the branch electric circuit 75 branched from the main electric circuit 74 transmits the alternating current power, and is the electric load which operates with the alternating current power 44 is connected.
- the power conversion unit 81 connected between the system power supply 3 and the electric load 44 is configured by an AC-AC conversion circuit that converts AC power into desired AC power.
- branch electric circuits 75 are branched from the main electric circuit 74, and when the respective branch electric circuits 75 are distinguished, they are referred to as branch electric circuits 75a, 75b, and 75c.
- a branch switch 63a and an electric load 44a are connected to the branch circuit 75a
- a branch switch 63b and an electric load 44b are connected to the branch circuit 75b
- a branch switch 63c and an electric load 44c are connected to the branch circuit 75c. It is connected.
- control unit 12A opens the first switch 61 and the second switch 62 when the leakage detection unit 11 detects the occurrence of leakage. Further, the control unit 12A opens all the branch switches 63.
- the conductive path 7B is electrically connected to the main electric circuit 74 that electrically connects the storage battery 21 and the system power supply 3 and from the main electric circuit 74, and is electrically connected to one or more electric loads 44. And one or more branch electric circuits 75 to be connected.
- the first switch 61 is provided in the main electric circuit 74
- the second switch 62 is provided in the main electric circuit 74 closer to the storage battery 21 than the first switch 61.
- the control unit 12A further controls the open state of the branch switch 63 provided in the branch circuit 75.
- the control unit 12A sets not only the first switch 61 and the second switch 62 but also the branch switch 63 in the open state. can do.
- the conductive path 7B is interrupted between the upstream side and the downstream side of the current flowing through the conductive path 7B (the main electrical path 74 and the one or more branching electrical paths 75)
- leakage protection can be performed more reliably. Further, damage to the electric load 44 can be prevented.
- the leakage protection system 10 of the present embodiment includes the leakage protection device 1 configured as described above, the first switch 61 provided in the main circuit 74, and the storage battery 21 side of the main circuit 74 relative to the first switch 61.
- a second switch 62 and a power converter 81 are provided.
- the power conversion unit 81 is electrically connected between the system power supply 3 and the electrical load 44, converts power supplied from the system power supply 3 to power, and supplies the power to the electrical load 44.
- the power conversion unit 81 stabilizes the power quality of the conductive path 7B, and the influence of the load fluctuation of the electric load 44 on the system power supply 3 can be suppressed.
- the electrical load 44c is configured with an emergency load (for example, a guide light, an IP phone, etc.) that should be preferentially used in the event of a power failure when the power supply from the system power supply 3 stops.
- an emergency load for example, a guide light, an IP phone, etc.
- the control unit 12A keeps the second switch 62 connected to the storage battery 21 and the branch switch 63c connected to the electrical load 44c (emergency load) in a closed state during a power failure. 1 switch 61 and branch switches 63a and 63b are opened. Thereby, the discharge electric power of the storage battery 21 is supplied to the electrical load 44c (emergency load), and the electrical load 44c can be operated. In this case, since it is necessary to continue the operation of the control unit 12A, power is supplied to the control unit 12A from the main electric circuit 74 between the first switch 61 and the second switch 62. It is desirable.
- the conductive path 7 ⁇ / b> B includes a plurality of branch electric circuits 75. Then, when the power supply from the system power supply 3 is stopped, the control unit 12A determines a specific branch switch 63c that is predetermined among the plurality of branch switches 63 provided in each of the plurality of branch circuits 75, and the first Each of the two switches 62 is opened. Thereby, the specific electric load 44c (emergency load) can be operated using the storage battery 21 even at the time of a power failure.
- the earth leakage detection unit 11 may be provided at a position where the occurrence of earth leakage can be detected even during a power failure.
- a leakage detection unit is provided between the branch point of the branch circuit 75 and the second switch 62, and the low potential side circuit on the storage battery 21 side of the leakage detection unit is connected to the ground.
- the control unit 12A opens the second switch 62 and the branch switch 63c to which the electrical load 44c (emergency load) is connected when the leakage detection unit detects the occurrence of a leakage during a power failure. To do. That is, the control unit 12A opens all of the first switch 61, the second switch 62, and the branch switches 63a to 63c.
- the control unit 12A controls all of the plurality of branch switches 63 and each of the second switches 62. Open. Thereby, since the conductive path 7B is interrupted between the upstream side and the downstream side of the current flowing through the conductive path 7B (the main electric path 74 and the branch electric path 75), the leakage protection can be more reliably performed, and the electric load 44 is further reduced. Can also be prevented.
- control unit 12A of the present embodiment includes a leakage specifying unit 121 that specifies a leakage point.
- the control unit 12A opens the first switch 61, the second switch 62, and each branch switch 63, respectively. Thereafter, the controller 12A controls the first switch 61 and the second switch so that the combinations of the switching states of the first switch 61, the second switch 62, and the branch switches 63 are different from each other. Each open / close state of the switch 62 and each branch switch 63 is controlled in turn.
- the earth leakage specifying unit 121 determines the location of the earth leakage based on the combination of the open / close states of the first switch 61, the second switch 62, and the branch switches 63 and the detection result of the earth leakage detection unit 11. Identify.
- the leakage detection unit 121 determines that there is a leakage point on the path of the current flowing through the closed switch. For example, it is assumed that when only the first switch 61 is in a closed state and the second switch 62 and each branch switch 63 are in an open state, the leakage detection unit 11 detects the occurrence of a leakage. In this case, the leakage specifying unit 121 determines that a leakage has occurred in the conductive path 7B between the first switch 61, the second switch 62, and each branch switch 63. Then, the control unit 12A performs leakage protection by opening each of the first switch 61, the second switch 62, and each branch switch 63.
- the leakage detection unit 11 does not detect the occurrence of the leakage. Determines that a leakage has occurred in either the vehicle 2 or each of the electrical loads 44.
- the controller 12A fixes the first switch 61 in the closed state, and closes the second switch 62 and each branch switch 63 one by one in order. For example, it is assumed that a leakage is generated in the electric load 44b.
- the leakage detector 11 does not detect the occurrence of leakage when the branch switch 63b is open, but detects the occurrence of leakage when the branch switch 63b is closed.
- the leakage detector 11 does not detect the occurrence of leakage when the first switch 61 is closed and the branch switch 63b is open, and the first switch 61 and the branch switch 63b In the closed state, the leakage detection unit 11 detects the occurrence of leakage. From the above result, the leakage detection unit 121 determines that the electrical load 44b is a leakage point.
- the control unit 12A closes the first switch 61, the second switch 62, and the branch switches 63a and 63c. Only the branch switch 63b is opened. Thereby, the electric load 44b which is a leakage point can be disconnected from the conductive path 7B, and power can be transferred between the system power supply 3, the storage battery 21, and the electric loads 44a and 44c.
- the leakage protection device 1 of the present embodiment includes the leakage specifying unit 121 that specifies a leakage point. Then, when the leakage detection unit 11 detects the occurrence of the leakage, the control unit 12A makes the combinations of the open / close states of the first switch 61, the second switch 62, and the branch switch 63 different from each other. The open / close states of the first switch 61, the second switch 62, and the branch switch 63 are sequentially controlled.
- the leakage detection unit 121 specifies a leakage point based on the combination of the open / close states of the first switch 61, the second switch 62, and the branch switch 63 and the detection result of the leakage detection unit 11.
- a leakage point specified by the leakage specifying unit 121 may be notified to the user using a notification unit (not shown) configured with a monitor or the like. Thereby, the user can grasp
- the casing of the power conversion device 5 in the present embodiment is electrically connected to the ground line 73, and the casing of the power conversion device 5 and the ground are electrically connected via the ground line 73. (See FIG. 6). Thereby, the grounding used for leakage detection and the grounding of the casing of the power converter 5 used for protection can be shared by one grounding wire 73.
- the electric load 44 is a distributed power source (for example, a storage battery, a solar power generation device, etc.) which generate electric power. ).
- the power conversion unit 81 is configured by, for example, an AC-DC conversion circuit.
- the high potential side electric circuit 71 may also be electrically connected to the ground by an impedance circuit 731 and a ground line 73.
- the impedance circuit 731 has a high resistance, preferably a resistance of 40 k ⁇ or more.
- the series circuit of the impedance circuits 730 and 731 is electrically connected between the high potential side circuit 71 and the low potential side circuit 72, and the connection point of the impedance circuits 730 and 731 is connected by the ground line 73. Electrically connected to earth.
- leakage detector 11 may be a current detector provided between the connection point of impedance circuits 730 and 731 and ground.
- the current detector may be a current transformer, for example.
- the high potential side electric circuit 71 may also be electrically connected to the ground by the impedance circuit 731, the leakage detection unit 11 ⁇ / b> A and the ground line 73.
- the impedance circuit 731 has a high resistance, preferably a resistance of 40 k ⁇ or more.
- the series circuit of the impedance circuits 730 and 731 is electrically connected between the high potential side circuit 71 and the low potential side circuit 72, and the connection point of the impedance circuits 730 and 731 is the leakage detection unit 11A. And it is electrically connected to the ground by a grounding wire 73.
- the connection point is electrically connected to the ground line 73 via the leakage detection unit 11A.
- the leakage detector 11A may be a current detector such as a current transformer.
Abstract
Description
本実施形態における漏電保護装置1およびこれを備える漏電保護システム10の概略構成を図1に示す。本実施形態では漏電保護システム10(漏電保護装置1)を、車両2(電気自動車)に搭載された蓄電池21(バッテリー)の放電電力を家庭の1または複数の電気負荷43に供給するV2H(Vehicle to Home)システムに用いる場合について説明する。本実施形態の漏電保護装置1および漏電保護システム10の各々は、蓄電池21の充電時および放電時に漏電の発生を検出した際に漏電保護を行う。なお、本実施形態の漏電保護装置1および漏電保護システム10の各々による漏電保護は、V2Hシステムに用いる車両2の蓄電池21の充放電時に限定せず、例えば定置型蓄電装置の蓄電池の充放電時にも対応することができる。
本実施形態の漏電保護装置1およびこれを備える漏電保護システム10の概略構成図を図6に示す。本実施形態において、蓄電池21と系統電源3との間で授受される電力を伝送する導電路7Bは、蓄電池21と系統電源3とを電気的に接続する主電路74と、主電路74から分岐し、電気負荷44が接続された分岐電路75とを備えた構成である。そして、本実施形態の制御部12Aは、分岐電路75に設けられる分岐開閉器63の開閉状態を制御する。図6の例では、複数の分岐電路75が主電路74から分岐し、複数の分岐電路75の各々は、分岐開閉器63を介して電気負荷44と電気的に接続されている。なお、実施形態1と同様の構成には、同一符号を付して説明を省略する。
Claims (10)
- 蓄電池と系統電源との間で授受される電力を伝送する導電路における漏電の発生を検出するように構成される漏電検出部と、
前記導電路に設けられる第1の開閉器、および前記導電路において前記第1の開閉器よりも前記蓄電池側に設けられる第2の開閉器それぞれの開閉状態を、前記漏電検出部の検出結果に基づいて制御するように構成される制御部とを備え、
前記制御部は、前記蓄電池の充電時に前記漏電検出部が漏電の発生を検出した場合、前記第1の開閉器と前記第2の開閉器とのうち少なくとも前記第1の開閉器を開状態にし、前記蓄電池の放電時に前記漏電検出部が漏電の発生を検出した場合、前記第1の開閉器と前記第2の開閉器とのうち少なくとも前記第2の開閉器を開状態にする
ことを特徴とする漏電保護装置。 - 前記制御部は、前記漏電検出部が漏電の発生を検出した場合、前記第1の開閉器と前記第2の開閉器とを順に開状態にするように構成される
ことを特徴とする請求項1記載の漏電保護装置。 - 前記制御部は、前記蓄電池の充電時に前記漏電検出部が漏電の発生を検出した場合、前記第1の開閉器を開状態にした後に前記第2の開閉器を開状態にし、前記蓄電池の放電時に前記漏電検出部が漏電の発生を検出した場合、前記第2の開閉器を開状態にした後に前記第1の開閉器を開状態にするように構成される
ことを特徴とする請求項2記載の漏電保護装置。 - 前記導電路は、前記蓄電池と前記系統電源とを電気的に接続する主電路と、前記主電路から分岐し、1つ以上の電気負荷と電気的に接続される1つ以上の分岐電路とを備え、
前記第1の開閉器は、前記主電路に設けられ、
前記第2の開閉器は、前記主電路において前記第1の開閉器よりも前記蓄電池側に設けられ、
前記制御部は、前記1つ以上の分岐電路に設けられる1つ以上の分岐開閉器の開閉状態をさらに制御するように構成される
ことを特徴とする請求項1~3のうちいずれか1項に記載の漏電保護装置。 - 前記1つ以上の分岐電路は、複数の分岐電路であり、
前記制御部は、前記系統電源からの電力供給が停止した場合、前記複数の分岐電路それぞれに設けられた複数の分岐開閉器のうち予め決められた特定の分岐開閉器、および前記第2の開閉器それぞれを閉状態にするように構成される
ことを特徴とする請求項4記載の漏電保護装置。 - 前記制御部は、前記系統電源からの電力供給の停止時に前記漏電検出部が漏電の発生を検出した場合、前記複数の分岐開閉器のすべて、および前記第2の開閉器それぞれを開状態にするように構成される
ことを特徴とする請求項5記載の漏電保護装置。 - 漏電箇所を特定する漏電特定部を備え、
前記制御部は、前記漏電検出部が漏電の発生を検出した場合、前記第1の開閉器と前記第2の開閉器と前記1つ以上の分岐開閉器との各開閉状態の組み合わせが互いに異なるように、前記第1の開閉器と前記第2の開閉器と前記1つ以上の分岐開閉器との各開閉状態を順に制御し、
前記漏電特定部は、前記第1の開閉器と前記第2の開閉器と前記1つ以上の分岐開閉器との各開閉状態の組み合わせと、前記漏電検出部の検出結果とに基づいて漏電箇所を特定するように構成される
ことを特徴とする請求項4~6のうちいずれか1項に記載の漏電保護装置。 - 前記漏電検出部は、前記導電路とアースとを電気的に接続する接地線に流れる電流に基づいて、前記導電路における漏電の発生を検出するように構成される
ことを特徴とする請求項1~7のうちいずれか1項に記載の漏電保護装置。 - 請求項1~8のうちいずれか1項に記載の漏電保護装置と、
前記導電路に設けられる前記第1の開閉器と、
前記導電路において前記第1の開閉器よりも前記蓄電池側に設けられる前記第2の開閉器とを備える
ことを特徴とする漏電保護システム。 - 請求項4~7のうちいずれか1項に記載の漏電保護装置と、
前記主電路に設けられる前記第1の開閉器と、
前記主電路において前記第1の開閉器よりも前記蓄電池側に設けられる前記第2の開閉器と、
前記系統電源と前記電気負荷との間に電気的に接続され、前記系統電源からの供給電力を電力変換して前記電気負荷に供給する電力変換部とを備える
ことを特徴とする漏電保護システム。
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