JP2021045002A - Charger - Google Patents

Abstract

To effectively use power from a single phase AC power supply when power from the single phase AC power supply is supplied to a common power terminal.SOLUTION: A charger 10 includes a common switch 46 which is provided on a fourth wiring 45 and becomes an open state when power from a three-phase AC power supply is supplied to a common power terminal 15, and becomes a closed state when power from a single phase AC power supply 12 is supplied to the common power terminal 15. By that the common switch 46 becomes a closed state when power from the single phase AC power supply 12 is supplied to the common power terminal 15, a connection between a first wiring 41 and a second wiring 42 through a fourth wiring 45 is allowed by the common switch 46. By this, a first AC-DC converter 21 and a second AC-DC converter 22 are connected in parallel.SELECTED DRAWING: Figure 2

Description

The present invention relates to a charging device that charges a battery with power from a three-phase AC power source or a single-phase AC power source.

The charging device has an AC / DC converter that converts AC power from a three-phase AC power supply or a single-phase AC power supply into DC power in order to charge the battery with power from a three-phase AC power supply or a single-phase AC power supply. ing. For example, the charging device of Patent Document 1 has three AC / DC conversions in order to enable the battery to be charged with electric power regardless of whether the three-phase AC power supply is connected or the single-phase AC power supply is connected. It is configured with a vessel. Such a charging device includes one shared power supply terminal to which power is supplied from a three-phase AC power supply and a single-phase AC power supply, and a plurality of three-phase power supply terminals to which power is supplied from a three-phase AC power supply. It is equipped with a ground terminal. Further, the charging device includes a first wiring for connecting the shared power supply terminal and one AC / DC converter. Further, the charging device includes a plurality of second wirings for connecting the three-phase power supply terminal and the AC / DC converter other than the AC / DC converter connected to the first wiring. Further, the charging device includes a plurality of third wirings for connecting the ground terminal and each of the AC / DC converters.

Then, for example, when the power from the three-phase AC power supply is supplied to the shared power supply terminal, the AC power is supplied from the three-phase AC power supply to one AC / DC converter via the shared power supply terminal and the first wiring. , AC power is supplied from the three-phase AC power supply to each of the AC-DC converters other than the AC-DC converter connected to the first wiring via the plurality of three-phase power supply terminals and the plurality of second wirings. As a result, the AC power is converted into DC power by each AC / DC converter. Further, for example, when power from a single-phase AC power supply is supplied to the shared power supply terminal, AC power is supplied from the single-phase AC power supply to one AC / DC converter via the shared power supply terminal and the first wiring. AC power is converted to DC power by two AC-DC converters. Therefore, according to such a configuration, the battery can be charged with the power from the three-phase AC power supply or the single-phase AC power supply by one kind of charging device. It is not necessary to separately prepare a charging device compatible with a single-phase AC power supply.

Japanese Unexamined Patent Publication No. 2012-115006

As described above, when the power from the single-phase AC power supply is supplied to the shared power supply terminal, the AC power from the single-phase AC power supply is supplied to only one AC / DC converter, and the remaining two AC power from a single-phase AC power supply is not supplied to the AC / DC converter. Therefore, in a charging device having such a configuration, when power is supplied from the single-phase AC power supply to the shared power supply terminal, the charging capacity is equivalent to that of one of the three AC-DC converters. The power from the phase AC power supply may not be used effectively.

The present invention has been made to solve the above problems, and an object of the present invention is to effectively utilize the power from the single-phase AC power supply when the power from the single-phase AC power supply is supplied to the shared power supply terminal. The purpose is to provide a charging device that can.

The charging device that solves the above problems converts the AC power from the three-phase AC power supply or the single-phase AC power supply into DC power in order to charge the battery with the power from the three-phase AC power supply or the single-phase AC power supply. At least three AC-DC converters, one shared power supply terminal to which power is supplied from the three-phase AC power supply and the single-phase AC power supply, and a plurality of three-phases to which power is supplied from the three-phase AC power supply. The first wiring that connects the power supply terminal, the ground terminal, the shared power supply terminal, and the one AC / DC converter, the three-phase power supply terminal, and the AC / DC conversion that is connected to the first wiring. A charging device including a plurality of second wirings for connecting each of the AC / DC converters other than the device, and a plurality of third wirings for connecting the ground terminal and each of the AC / DC converters. A fourth wiring for connecting the first wiring and one of the plurality of second wirings, and the fourth wiring are provided, and power from the three-phase AC power supply is supplied to the shared power supply terminal. It is provided with a shared switch that is opened when the power is supplied to the shared power supply terminal and closed when power is supplied from the single-phase AC power supply to the shared power supply terminal.

According to this, when the power from the three-phase AC power supply is supplied to the shared power supply terminal, the shared switch is opened, so that the first wiring via the fourth wiring and the plurality of second wirings are open. The connection with one is cut off. Then, AC power is supplied from the three-phase AC power supply to one AC / DC converter via the shared power supply terminal and the first wiring, and the three-phase AC power supply also supplies the plurality of three-phase power supply terminals and the plurality of second wirings. AC power is supplied to each of the AC / DC converters other than the AC / DC converter connected to the first wiring via the above, and the AC power is converted into DC power by each AC / DC converter. On the other hand, when the power from the single-phase AC power supply is supplied to the shared power supply terminal, the shared switch is closed, so that the first wiring via the fourth wiring and one of the plurality of second wirings can be connected. The connection is allowed by the shared switch. As a result, the AC / DC converter connected to the first wiring and one of a plurality of AC / DC converters other than the AC / DC converter connected to the first wiring are connected in parallel. Then, AC power is supplied from the single-phase AC power supply to each of the AC / DC converters connected in parallel, and the AC power is converted into DC power by each of the AC / DC converters connected in parallel. Therefore, when the power from the single-phase AC power supply is supplied to the shared power supply terminal, the charging capacity of each AC / DC converter connected in parallel is obtained, so only one AC / DC converter can be supplied from the single-phase AC power supply. Compared with the case where the AC power is not supplied, the power from the single-phase AC power supply can be effectively utilized when the power from the single-phase AC power supply is supplied to the shared power supply terminal.

In the charging device, the AC / DC converter connected to the first wiring and the AC / DC converter connected to the second wiring connected to the first wiring by the fourth wiring are respectively. The second wiring, which has a voltage detection unit and is connected to the first wiring by the fourth wiring, has a welding determination switch between the connection point of the fourth wiring and the three-phase power supply terminal. It is provided with a welding determination unit that determines that the shared switch is welded when a voltage is detected from the plurality of voltage detection units when the shared switch and the welding determination switch are opened. It is good.

According to this, it is possible to prevent the power from the three-phase AC power supply from being supplied to the shared power supply terminal even though the shared switch is welded.

According to the present invention, when the power from the single-phase AC power supply is supplied to the shared power supply terminal, the power from the single-phase AC power supply can be effectively utilized.

The schematic diagram of the charging device which shows the state which power is supplied from the three-phase AC power source to the common power source terminal in 1st Embodiment. Schematic diagram of a charging device showing a state in which power from a single-phase AC power supply is supplied to the shared power supply terminal. A flowchart for explaining the control of the control device. The schematic diagram of the charging device which shows the state which the electric power from a three-phase AC power source is supplied to the common power source terminal in 2nd Embodiment. Schematic diagram of a charging device showing a state in which power from a single-phase AC power supply is supplied to the shared power supply terminal. A flowchart for explaining the control of the control device.

(First Embodiment)
Hereinafter, the first embodiment in which the charging device is embodied will be described with reference to FIGS. 1 to 3.
As shown in FIGS. 1 and 2, the charging device 10 charges the battery 13 with electric power from the three-phase AC power source 11 or the single-phase AC power source 12. As shown in FIG. 1, the three-phase AC power supply 11 is a three-phase four-wire system. As shown in FIG. 2, the single-phase AC power supply 12 is a single-phase two-wire system. As shown in FIGS. 1 and 2, the charging device 10 includes a connection terminal 14 connected to the connector 11a of the three-phase AC power supply 11 or the connector 12a of the single-phase AC power supply 12.

The connection terminal 14 has one shared power supply terminal 15 to which power is supplied from the three-phase AC power supply 11 and the single-phase AC power supply 12. Further, the connection terminal 14 has two three-phase power supply terminals 16 and 17 to which power is supplied from the three-phase AC power supply 11. Further, the connection terminal 14 has a ground terminal 18.

The charging device 10 converts the AC power from the three-phase AC power supply 11 or the single-phase AC power supply 12 into DC power in order to charge the battery 13 with the power from the three-phase AC power supply 11 or the single-phase AC power supply 12. It includes a first AC / DC converter 21, a second AC / DC converter 22, and a third AC / DC converter 23, which are DC converters. Therefore, the charging device 10 of the present embodiment uses the AC power from the three-phase AC power supply 11 or the single-phase AC power supply 12 in order to charge the battery 13 with the power from the three-phase AC power supply 11 or the single-phase AC power supply 12. It is equipped with three AC / DC converters that convert to DC power. The first AC / DC converter 21, the second AC / DC converter 22, and the third AC / DC converter 23 are connected in parallel to the battery 13.

The first AC / DC converter 21 includes a first voltage sensor 31 that detects a voltage applied to the first AC / DC converter 21. The first voltage sensor 31 is built in the first AC / DC converter 21. The second AC / DC converter 22 includes a second voltage sensor 32 that detects the voltage applied to the second AC / DC converter 22. The second voltage sensor 32 is built in the second AC / DC converter 22. The third AC / DC converter 23 includes a third voltage sensor 33 that detects the voltage applied to the third AC / DC converter 23. The third voltage sensor 33 is built in the third AC / DC converter 23.

The charging device 10 includes a first wiring 41 and two second wirings 42 and 43. The first wiring 41 connects the shared power supply terminal 15 and the first AC / DC converter 21 which is one AC / DC converter. The two second wirings 42 and 43 are the second AC / DC converter 22 which is an AC / DC converter other than the first AC / DC converter 21 connected to the three-phase power supply terminals 16 and 17 and the first wiring 41. And the third AC / DC converter 23 are connected to each other. Specifically, the second wiring 42 connects the three-phase power supply terminal 16 and the second AC / DC converter 22. The second wiring 43 connects the three-phase power supply terminal 17 and the third AC / DC converter 23.

The charging device 10 includes a plurality of third wirings 44. The third wiring 44 is drawn out from the first AC / DC converter 21, the second AC / DC converter 22, and the third AC / DC converter 23, respectively. Therefore, the charging device 10 includes three third wirings 44. Each third wiring 44 connects the ground terminal 18, the first AC / DC converter 21, the second AC / DC converter 22, and the third AC / DC converter 23, respectively. Specifically, the three third wirings 44 are integrated into one on the way and connected to the ground terminal 18. The three third wires 44 are connected to the ground.

The charging device 10 includes a fourth wiring 45 that connects the first wiring 41 and the second wiring 42. Therefore, the fourth wiring 45 connects the first wiring 41 and one of the plurality of second wirings 42 and 43. The charging device 10 includes a shared switch 46. The shared switch 46 is provided in the fourth wiring 45. The shared switch 46 is in the open state when power is supplied from the three-phase AC power supply 11 to the shared power supply terminal 15, and is closed when power is supplied from the single-phase AC power supply 12 to the shared power supply terminal 15. Become.

When the shared switch 46 is closed, the shared switch 46 allows the connection between the first wiring 41 and the second wiring 42 via the fourth wiring 45, and the first AC / DC converter 21 and the second AC / DC converter 21. 22 is connected in parallel. The voltage of the first AC / DC converter 21 connected to the first wiring 41 and the voltage of the second AC / DC converter 22 connected to the second wiring 42 connected to the first wiring 41 by the fourth wiring 45 are respectively. It has a first voltage sensor 31 and a second voltage sensor 32 as detection units.

The charging device 10 includes a welding determination switch 47. The welding determination switch 47 is provided on the second wiring 42. Therefore, the welding determination switch 47 is provided in the second wiring 42 connected to the first wiring 41 by the fourth wiring 45. The welding determination switch 47 is provided between the connection point of the fourth wiring 45 in the second wiring 42 and the three-phase power supply terminal 16. The welding determination switch 47 is in a closed state that allows the supply of AC power from the three-phase power supply terminal 16 to the second AC / DC converter 22 via the second wiring 42, and the three-phase power supply terminal 16 to the second. It is possible to switch between an open state in which the supply of AC power to the second AC / DC converter 22 via the wiring 42 is cut off.

The charging device 10 includes a control device 50. The control device 50 is electrically connected to the first voltage sensor 31, the second voltage sensor 32, and the third voltage sensor 33. The control device 50 transmits the detection information regarding the voltage detected by each of the first voltage sensor 31, the second voltage sensor 32, and the third voltage sensor 33 to the first voltage sensor 31, the second voltage sensor 32, and the third voltage. Received from each of the sensors 33.

The control device 50 is electrically connected to the shared switch 46. The control device 50 stores in advance a program for opening and closing the shared switch 46 based on the detection information received from each of the first voltage sensor 31, the second voltage sensor 32, and the third voltage sensor 33. Further, the control device 50 is electrically connected to the welding determination switch 47. The control device 50 stores in advance a program for opening and closing the welding determination switch 47 based on the detection information received from each of the first voltage sensor 31, the second voltage sensor 32, and the third voltage sensor 33. Further, the control device 50 includes, for example, a display 50a for displaying information about the charging device 10.

As shown in FIG. 1, for example, when the connection terminal 14 and the connector 11a of the three-phase AC power supply 11 are connected, the shared switch 46 is opened and the three-phase AC power supply 11 to the first AC / DC converter. Power is supplied to 21, the second AC / DC converter 22, and the third AC / DC converter 23. Further, as shown in FIG. 2, for example, when the connection terminal 14 and the connector 12a of the single-phase AC power supply 12 are connected, the shared switch 46 is closed and the single-phase AC power supply 12 is connected to the first AC / DC. Power is supplied to the converter 21 and the second AC / DC converter 22.

Next, the operation of the first embodiment will be described.
As shown in FIG. 3, when the connection terminal 14 is connected to the connector 11a of the three-phase AC power supply 11 or the connector 12a of the single-phase AC power supply 12, the control device 50 first makes initial settings in step S11. The shared switch 46 and the welding determination switch 47 are opened. Next, in step S12, the control device 50 determines whether or not the first voltage sensor 31 has detected the voltage. When the control device 50 determines in step S12 that the first voltage sensor 31 has not detected the voltage, the control device 50 proceeds to step S21 to perform an abnormality determination.

When the control device 50 shifts to step S21 from the determination result of step S12 and performs an abnormality determination, for example, in the charging device 10, the first wiring 41 is broken, or the first wiring 41 and the first AC / DC are disconnected. Information indicating that there is a possibility that an abnormality has occurred in the connection portion with the converter 21 or that the first AC / DC converter 21 has failed is displayed on the display 50a.

On the other hand, when the control device 50 determines in step S12 that the first voltage sensor 31 is detecting the voltage, the control device 50 proceeds to step S13. Then, in step S13, the control device 50 determines whether or not the second voltage sensor 32 detects the voltage. When the control device 50 determines in step S13 that the second voltage sensor 32 has not detected the voltage, the control device 50 proceeds to step S14. Then, in step S14, the control device 50 determines whether or not the third voltage sensor 33 has detected the voltage.

When the control device 50 determines in step S14 that the third voltage sensor 33 has detected the voltage, the control device 50 proceeds to step S15 and switches the welding determination switch 47 from the open state to the closed state. As a result, the supply of AC power from the three-phase power supply terminal 16 to the second AC / DC converter 22 via the second wiring 42 is permitted. Then, in step S16, the control device 50 determines whether or not the second voltage sensor 32 detects the voltage.

When the control device 50 determines in step S16 that the second voltage sensor 32 is detecting the voltage, the control device 50 proceeds to step S17, and in step S17, the power from the three-phase AC power supply 11 is supplied to the shared power supply terminal 15. It is determined that the battery can be charged by the three-phase AC power supply 11. Then, in the charging device 10, when the power from the three-phase AC power supply 11 is supplied to the shared power supply terminal 15, the first AC / DC conversion is performed from the three-phase AC power supply 11 via the shared power supply terminal 15 and the first wiring 41. AC power is supplied to the vessel 21. Further, AC power is supplied from the three-phase AC power supply 11 to the second AC DC converter 22 and the third AC DC converter 23 via the two three-phase power supply terminals 16 and 17 and the two second wirings 42 and 43. Will be done. The AC power supplied to each of the first AC / DC converter 21, the second AC / DC converter 22, and the third AC / DC converter 23 is the first AC / DC converter 21, the second AC / DC converter 22, and the third AC / DC converter 23. It is converted into DC power by the third AC / DC converter 23.

On the other hand, if the control device 50 determines in step S16 that the second voltage sensor 32 has not detected the voltage, the control device 50 proceeds to step S21 to perform an abnormality determination. When the control device 50 shifts to step S21 from the determination result of step S16 and performs an abnormality determination, for example, in the charging device 10, the second wiring 42 is broken, or the second wiring 42 and the second AC / DC are disconnected. Information indicating that there is a possibility that an abnormality has occurred in the connection portion with the converter 22 or that the second AC / DC converter 22 has failed is displayed on the display 50a.

On the other hand, if the control device 50 determines in step S14 that the third voltage sensor 33 has not detected the voltage, the control device 50 proceeds to step S18 and switches the shared switch 46 from the open state to the closed state. As a result, the connection between the first wiring 41 and the second wiring 42 via the fourth wiring 45 is allowed by the shared switch 46, and the first AC / DC converter 21 and the second AC / DC converter 22 are connected to each other. Connected in parallel. Then, the current flowing through the first wiring 41 also flows through the fourth wiring 45 to the second wiring 42. Subsequently, in step S19, the control device 50 determines whether or not the second voltage sensor 32 has detected the voltage.

When the control device 50 determines in step S19 that the second voltage sensor 32 is detecting the voltage, the control device 50 proceeds to step S20, and in step S20, the power from the single-phase AC power supply 12 is supplied to the shared power supply terminal 15. It is determined that the voltage is high, and that the battery can be charged by the single-phase AC power supply 12.

On the other hand, if the control device 50 determines in step S19 that the second voltage sensor 32 has not detected the voltage, the control device 50 proceeds to step S21 to perform an abnormality determination. When the control device 50 shifts from the determination result in step S19 to step S21 and performs an abnormality determination, in the charging device 10, for example, the second AC / DC converter 22 is more than the welding determination switch 47 in the second wiring 42. There is a possibility that the part on the side is broken, the connection part between the second wiring 42 and the second AC / DC converter 22 is abnormal, or the second AC / DC converter 22 is out of order. Information is displayed on the display 50a.

When the control device 50 determines in step S13 that the second voltage sensor 32 has detected a voltage, the control device 50 proceeds to step S22 to perform a welding determination. In the welding determination, although the welding determination switch 47 is in the open state, the first voltage sensor 31 and the second voltage sensor 32 each detect the voltage, so that the shared switch 46 is in the closed state. It is determined that the first wiring 41 and the second wiring 42 are connected by the shared switch 46.

Therefore, the control device 50 states that the shared switch 46 is welded when the voltage is detected from the first voltage sensor 31 and the second voltage sensor 32 when the shared switch 46 and the welding determination switch 47 are opened. It functions as a welding determination unit for determination. When the control device 50 makes a welding determination, the control device 50 displays information on the display 50a that the shared switch 46 is welded and is in a closed state.

In the first embodiment, the following effects can be obtained.
(1-1) The charging device 10 is provided in the fourth wiring 45 and is opened when the power from the three-phase AC power supply 11 is supplied to the shared power supply terminal 15, and the single-phase AC power supply is supplied to the shared power supply terminal 15. A shared switch 46 that is closed when power is supplied from the 12 is provided.

According to this, when the power from the three-phase AC power supply 11 is supplied to the shared power supply terminal 15, the shared switch 46 is opened, so that the first wiring 41 and the second wiring via the fourth wiring 45 are opened. The connection with 42 is cut off. Then, AC power is supplied from the three-phase AC power supply 11 to the first AC / DC converter 21 via the shared power supply terminal 15 and the first wiring 41, and the three-phase AC power supply 11 to the two three-phase power supply terminals 16 , 17 and the second AC / DC converter 22 and the third AC / DC converter 23 are supplied with AC power via the second wirings 42 and 43. As a result, the AC power is converted into DC power by the first AC / DC converter 21, the second AC / DC converter 22, and the third AC / DC converter 23.

On the other hand, when the power from the single-phase AC power supply 12 is supplied to the shared power supply terminal 15, the shared switch 46 is closed, so that the first wiring 41 and the second wiring 42 are connected to each other via the fourth wiring 45. The connection is allowed by the shared switch 46. As a result, the first AC / DC converter 21 and the second AC / DC converter 22 are connected in parallel. Then, AC power is supplied from the single-phase AC power supply 12 to each of the first AC / DC converter 21 and the second AC / DC converter 22 connected in parallel, and the first AC / DC converter 21 and the second AC connected in parallel. AC power is converted into DC power by each of the DC converters 22. Therefore, when the power from the single-phase AC power supply 12 is supplied to the shared power supply terminal 15, the charging device 10 charges the first AC / DC converter 21 and the second AC / DC converter 22 connected in parallel. Become an ability. Therefore, compared to the case where the AC power from the single-phase AC power supply 12 is supplied to only one AC-DC converter, when the power from the single-phase AC power supply 12 is supplied to the shared power supply terminal 15, the first Since the 1 AC / DC converter 21 and the 2nd AC / DC converter 22 can be used, for example, the 1st AC / DC converter 21 and the 2nd AC / DC converter 22 can each output 3 kW. Even when the phase AC power supply 12 can output 6 kW, the charging device 10 can output 6 kW, and the power from the single-phase AC power supply 12 can be effectively utilized.

(1-2) The second wiring 42 is provided with a welding determination switch 47. Then, the control device 50 states that the shared switch 46 is welded when the voltage is detected from the first voltage sensor 31 and the second voltage sensor 32 when the shared switch 46 and the welding determination switch 47 are opened. judge. According to this, it is possible to prevent the power from the three-phase AC power supply 11 from being supplied to the shared power supply terminal 15 even though the shared switch 46 is in a welded state.

(1-3) According to the present embodiment, since the battery 13 can be charged with the electric power from the three-phase AC power source 11 or the single-phase AC power source 12 by one kind of charging device 10, the three-phase AC power source 11 It is not necessary to separately prepare a charging device corresponding to the above and a charging device corresponding to the single-phase AC power supply 12.

(1-4) The first voltage sensor 31, the second voltage sensor 32, and the third voltage sensor 33 are used in the first AC / DC converter 21, the second AC / DC converter 22, and the third AC / DC converter 23. Each is built-in. According to this, the first voltage sensor 31, the second voltage sensor 32, and the third voltage sensor 33 are the first AC / DC converter 21, the second AC / DC converter 22, and the third AC / DC converter 23, respectively. The configuration can be simplified as compared with the case where it is provided outside the.

(1-5) The control device 50 determines whether or not an abnormality has occurred in the charging device 10 based on the voltages detected by the first voltage sensor 31, the second voltage sensor 32, and the third voltage sensor 33. It can be determined.

(Second embodiment)
Hereinafter, a second embodiment in which the charging device is embodied will be described with reference to FIGS. 4 to 6. In the embodiments described below, the duplicated description will be omitted or simplified by assigning the same reference numerals to the same configurations as those in the first embodiment already described.

As shown in FIGS. 4 and 5, the charging device 10 includes a fourth wiring 55 that connects the first wiring 41 and the second wiring 43. Therefore, the fourth wiring 55 connects the first wiring 41 and one of the plurality of second wirings 42 and 43. The charging device 10 includes a shared switch 56. The shared switch 56 is provided in the fourth wiring 55. The shared switch 56 is in the open state when power is supplied from the three-phase AC power supply 11 to the shared power supply terminal 15, and is closed when power is supplied from the single-phase AC power supply 12 to the shared power supply terminal 15. Become.

When the shared switch 56 is closed, the shared switch 56 allows the connection between the first wiring 41 and the second wiring 43 via the fourth wiring 55, and the first AC / DC converter 21 and the third AC / DC converter 23 is connected in parallel. The voltage of the first AC / DC converter 21 connected to the first wiring 41 and the voltage of the third AC / DC converter 23 connected to the second wiring 43 connected to the first wiring 41 by the fourth wiring 55 are respectively. It has a first voltage sensor 31 and a third voltage sensor 33 as detection units.

The charging device 10 includes a welding determination switch 57. The welding determination switch 57 is provided on the second wiring 43. Therefore, the welding determination switch 57 is provided in the second wiring 43 connected to the first wiring 41 by the fourth wiring 55. The welding determination switch 57 is provided between the connection point of the fourth wiring 55 in the second wiring 43 and the three-phase power supply terminal 17. The welding determination switch 57 is in a closed state that allows the supply of AC power from the three-phase power supply terminal 17 to the third AC / DC converter 23 via the second wiring 43, and the three-phase power supply terminal 17 to the second. It is possible to switch between an open state in which the supply of AC power to the third AC / DC converter 23 via the wiring 43 is cut off.

The control device 50 is electrically connected to the shared switch 56. The control device 50 stores in advance a program for opening and closing the shared switch 56 based on the detection information received from each of the first voltage sensor 31, the second voltage sensor 32, and the third voltage sensor 33. Further, the control device 50 is electrically connected to the welding determination switch 57. The control device 50 stores in advance a program for opening and closing the welding determination switch 57 based on the detection information received from each of the first voltage sensor 31, the second voltage sensor 32, and the third voltage sensor 33.

In the following description, the shared switch 46 provided in the fourth wiring 45 will be referred to as the "first shared switch 46", and the shared switch 56 provided in the fourth wiring 55 will be referred to as the "second shared switch 56". ". Further, the welding determination switch 47 provided in the second wiring 42 is described as "first welding determination switch 47", and the welding determination switch 57 provided in the second wiring 43 is referred to as "second welding determination". Switch 57 ”.

Next, the operation of the second embodiment will be described.
As shown in FIG. 6, when the connection terminal 14 is connected to the connector 11a of the three-phase AC power supply 11 or the connector 12a of the single-phase AC power supply 12, the control device 50 first makes initial settings in step S31. The first shared switch 46, the second shared switch 56, the first welding determination switch 47, and the second welding determination switch 57 are opened. Next, in step S32, the control device 50 determines whether or not the first voltage sensor 31 has detected the voltage. When the control device 50 determines in step S32 that the first voltage sensor 31 has not detected the voltage, the control device 50 proceeds to step S51 to perform an abnormality determination.

When the control device 50 shifts from the determination result of step S32 to step S51 and performs an abnormality determination, for example, in the charging device 10, the first wiring 41 is broken, or the first wiring 41 and the first AC / DC are disconnected. Information indicating that there is a possibility that an abnormality has occurred in the connection portion with the converter 21 or that the first AC / DC converter 21 has failed is displayed on the display 50a.

On the other hand, when the control device 50 determines in step S32 that the first voltage sensor 31 is detecting the voltage, the control device 50 proceeds to step S33. Then, in step S33, the control device 50 determines whether or not the second voltage sensor 32 detects the voltage. When the control device 50 determines in step S33 that the second voltage sensor 32 has not detected the voltage, the control device 50 proceeds to step S34. Then, in step S34, the control device 50 determines whether or not the third voltage sensor 33 has detected the voltage.

When the control device 50 determines in step S34 that the third voltage sensor 33 has not detected the voltage, the control device 50 proceeds to step S35 and switches the first welding determination switch 47 from the open state to the closed state. As a result, the supply of AC power from the three-phase power supply terminal 16 to the second AC / DC converter 22 via the second wiring 42 is permitted. Then, in step S36, the control device 50 determines whether or not the second voltage sensor 32 detects the voltage.

When the control device 50 determines in step S36 that the second voltage sensor 32 has detected a voltage, the control device 50 proceeds to step S37 and switches the second welding determination switch 57 from the open state to the closed state. As a result, the supply of AC power from the three-phase power supply terminal 17 to the third AC / DC converter 23 via the second wiring 43 is permitted. Then, in step S38, the control device 50 determines whether or not the third voltage sensor 33 has detected the voltage.

When the control device 50 determines in step S38 that the third voltage sensor 33 has detected the voltage, the control device 50 proceeds to step S39, and in step S39, the power from the three-phase AC power supply 11 is supplied to the shared power supply terminal 15. It is determined that the battery can be charged by the three-phase AC power supply 11. Then, in the charging device 10, when the power from the three-phase AC power supply 11 is supplied to the shared power supply terminal 15, the first AC / DC conversion is performed from the three-phase AC power supply 11 via the shared power supply terminal 15 and the first wiring 41. AC power is supplied to the vessel 21. Further, AC power is supplied from the three-phase AC power supply 11 to the second AC DC converter 22 and the third AC DC converter 23 via the two three-phase power supply terminals 16 and 17 and the two second wirings 42 and 43. Will be done. The AC power supplied to each of the first AC / DC converter 21, the second AC / DC converter 22, and the third AC / DC converter 23 is the first AC / DC converter 21, the second AC / DC converter 22, and the third AC / DC converter 23. It is converted into DC power by the third AC / DC converter 23.

On the other hand, if the control device 50 determines in step S38 that the third voltage sensor 33 has not detected the voltage, the control device 50 proceeds to step S51 to perform an abnormality determination. When the control device 50 shifts to step S51 from the determination result of step S38 and performs an abnormality determination, for example, in the charging device 10, the second wiring 43 is broken, or the second wiring 43 and the third AC / DC are disconnected. Information indicating that there is a possibility that an abnormality has occurred in the connection portion with the converter 23 or that the third AC / DC converter 23 has failed is displayed on the display 50a.

On the other hand, when the control device 50 determines in step S36 that the second voltage sensor 32 does not detect the voltage, the control device 50 proceeds to step S40 and switches the first welding determination switch 47 from the closed state to the open state. Then, the control device 50 proceeds to step S41 and switches the first shared switch 46 from the open state to the closed state. As a result, the connection between the first wiring 41 and the second wiring 42 via the fourth wiring 45 is allowed by the first shared switch 46, and the first AC / DC converter 21 and the second AC / DC converter 22 And are connected in parallel. Then, the current flowing through the first wiring 41 also flows to the second wiring 42 via the first shared switch 46. Subsequently, the control device 50 determines in step S42 whether or not the second voltage sensor 32 detects the voltage.

When the control device 50 determines in step S42 that the second voltage sensor 32 has detected a voltage, the control device 50 proceeds to step S43 and switches the second shared switch 56 from the open state to the closed state. As a result, the connection between the first wiring 41 and the second wiring 43 via the fourth wiring 55 is allowed by the second shared switch 56, and the first AC / DC converter 21 and the third AC / DC converter 23 And are connected in parallel. Then, the current flowing through the first wiring 41 also flows through the second wiring 43 via the second shared switch 56. Subsequently, the control device 50 determines in step S44 whether or not the third voltage sensor 33 has detected the voltage.

When the control device 50 determines in step S44 that the third voltage sensor 33 is detecting the voltage, the control device 50 proceeds to step S45, and in step S45, the power from the single-phase AC power supply 12 is supplied to the shared power supply terminal 15. It is determined that the voltage is high, and that the battery can be charged by the single-phase AC power supply 12.

On the other hand, if the control device 50 determines in step S42 that the second voltage sensor 32 has not detected the voltage, the control device 50 proceeds to step S51 to perform an abnormality determination. When the control device 50 shifts from the determination result of step S42 to step S51 and performs an abnormality determination, the control device 50 converts the second AC / DC in the charging device 10, for example, rather than the first welding determination switch 47 in the second wiring 42. There is a possibility that the part on the device 22 side is broken, the connection part between the second wiring 42 and the second AC / DC converter 22 is abnormal, or the second AC / DC converter 22 is out of order. Information to that effect is displayed on the display 50a.

Further, when the control device 50 determines in step S44 that the third voltage sensor 33 has not detected the voltage, the control device 50 proceeds to step S51 to perform an abnormality determination. When the control device 50 shifts from the determination result of step S44 to step S51 and performs an abnormality determination, the control device 50 converts the third AC / DC in the charging device 10, for example, rather than the second welding determination switch 57 in the second wiring 43. There is a possibility that the part on the device 23 side is broken, the connection part between the second wiring 43 and the third AC / DC converter 23 is abnormal, or the third AC / DC converter 23 is out of order. Information to that effect is displayed on the display 50a.

When the control device 50 determines in step S33 that the second voltage sensor 32 is detecting the voltage, the control device 50 proceeds to step S52 to perform a welding determination. In this welding determination, although the first welding determination switch 47 is in the open state, the first voltage sensor 31 and the second voltage sensor 32 each detect the voltage, so that the first shared switch 46 is in the closed state. Therefore, it is determined that the first wiring 41 and the second wiring 42 are connected by the first shared switch 46. Then, when the welding determination is made, the control device 50 displays information on the display 50a that the first common switch 46 is welded and is in the closed state.

Further, when the control device 50 determines in step S34 that the third voltage sensor 33 has detected the voltage, the control device 50 proceeds to step S52 to perform a welding determination. In this welding determination, although the second welding determination switch 57 is in the open state, the first voltage sensor 31 and the third voltage sensor 33 each detect the voltage, so that the second shared switch 56 is in the closed state. Therefore, it is determined that the first wiring 41 and the second wiring 43 are in a state of being connected by the second shared switch 56. Then, when the welding determination is made, the control device 50 displays information on the display 50a that the second common switch 56 is welded and is in the closed state.

In the second embodiment, in addition to the effects similar to those of the first embodiment (1-2), (1-3), (1-4), and (1-5), the following effects are obtained. be able to.
(2-1) When the power from the single-phase AC power supply 12 is supplied to the shared power supply terminal 15, the first AC / DC converter 21 and the single-phase AC power supply 12 via the first wiring 41 and the second wiring 42. AC power is supplied to the second AC / DC converter 22, and the AC power is converted into DC power by the first AC / DC converter 21 and the second AC / DC converter 22. Further, AC power is also supplied from the single-phase AC power supply 12 to the third AC / DC converter 23 via the first wiring 41 and the second wiring 43, and the AC power is converted into DC power by the third AC / DC converter 23. Will be done. Therefore, when the power from the single-phase AC power supply 12 is supplied to the shared power supply terminal 15, the charging device 10 has the first AC / DC converter 21, the second AC / DC converter 22, and the third AC / DC converter 23. It becomes the charging capacity of. Therefore, compared to the case where the AC power from the single-phase AC power supply 12 is supplied to only one AC-DC converter, when the power from the single-phase AC power supply 12 is supplied to the shared power supply terminal 15, the first Since the 1 AC / DC converter 21, the 2nd AC / DC converter 22, and the 3rd AC / DC converter 23 can be used, for example, the 1st AC / DC converter 21, the 2nd AC / DC converter 22, and Even if the third AC / DC converter 23 can output 3 kW each and the single-phase AC power supply 12 can output 9 kW, the charging device 10 can output 9 kW, and the single-phase AC power supply 12 can output 9 kW. You can make effective use of electricity.

Each of the above embodiments can be modified and implemented as follows. Each of the above embodiments and the following modified examples can be implemented in combination with each other within a technically consistent range.

○ In the first embodiment, the charging device 10 may be configured not to include the welding determination switch 47.
○ In the second embodiment, the charging device 10 may not include the first welding determination switch 47 and the second welding determination switch 57.

○ In each of the above embodiments, the first voltage sensor 31, the second voltage sensor 32, and the third voltage sensor 33 are the first AC / DC converter 21, the second AC / DC converter 22, and the third AC / DC converter. It does not have to be built in each of the 23. For example, the first voltage sensor 31, the second voltage sensor 32, and the third voltage sensor 33 are outside the first AC / DC converter 21, the second AC / DC converter 22, and the third AC / DC converter 23, respectively. It may be provided.

○ In each of the above embodiments, the shared switches 46 and 56 are not switched to the open state or the closed state based on the voltage detected by the first voltage sensor 31, the second voltage sensor 32, and the third voltage sensor 33. For example, the shared switches 46 and 56 may be switched in advance to the open state or the closed state depending on the application of the charging device 10. In short, the shared switches 46 and 56 are opened when the power from the three-phase AC power supply 11 is supplied to the shared power supply terminal 15, and the power from the single-phase AC power supply 12 is supplied to the shared power supply terminal 15. In some cases, it may be closed.

○ In each of the above embodiments, the first AC / DC converter 21, the second AC / DC converter 22, and the third AC / DC converter 23 are the first voltage sensor 31, the second voltage sensor 32, and the third voltage sensor. The configuration may not include each of the 33.

○ In each of the above embodiments, the charging device 10 may be configured to include four or more AC / DC converters.
○ In each of the above embodiments, one plurality of third wirings 44 are connected to each of the ground terminal 18, the first AC / DC converter 21, the second AC / DC converter 22, and the third AC / DC converter 23. Each may be connected to the connection terminal 14 without being aggregated in. In this case, the connection terminal 14 has a plurality of ground terminals 18 according to the number of the third wiring 44.

-In each of the above embodiments, the single-phase AC power supply 12 may be a single-phase three-wire system.

10 ... Charging device, 11 ... Three-phase AC power supply, 12 ... Single-phase AC power supply, 13 ... Battery, 15 ... Shared power supply terminal, 16, 17 ... Three-phase power supply terminal, 18 ... Ground terminal, 21 ... AC / DC converter 1st AC / DC converter, 22 ... 2nd AC / DC converter which is an AC / DC converter, 23 ... 3rd AC / DC converter which is an AC / DC converter, 31 ... 1st voltage sensor which is a voltage detector , 32 ... 2nd voltage sensor which is a voltage detection unit, 41 ... 1st wiring, 42, 43 ... 2nd wiring, 44 ... 3rd wiring, 45, 55 ... 4th wiring, 46, 56 ... shared switch, 47, 57 ... Welding determination switch, 50 ... A control device that functions as a welding determination unit.

Claims (2)

At least three AC / DC converters that convert AC power from the three-phase AC power supply or single-phase AC power supply into DC power in order to charge the battery with power from the three-phase AC power supply or single-phase AC power supply.
One shared power supply terminal to which power is supplied from the three-phase AC power supply and the single-phase AC power supply, and
A plurality of three-phase power supply terminals to which power is supplied from the three-phase AC power supply, and
Ground terminal and
The first wiring that connects the shared power supply terminal and the one AC / DC converter,
A plurality of second wirings for connecting the three-phase power supply terminal and the AC / DC converter other than the AC / DC converter connected to the first wiring, respectively.
A charging device including a plurality of third wirings for connecting the ground terminal and each of the AC / DC converters.
A fourth wiring that connects the first wiring and one of the plurality of second wirings,
It is provided in the fourth wiring and is opened when the power from the three-phase AC power supply is supplied to the shared power supply terminal, and when the power from the single-phase AC power supply is supplied to the shared power supply terminal. A charging device characterized by having a shared switch that is closed. The AC / DC converter connected to the first wiring and the AC / DC converter connected to the second wiring connected to the first wiring by the fourth wiring each have a voltage detection unit. And
The second wiring connected to the first wiring by the fourth wiring is provided with a welding determination switch between the connection point of the fourth wiring and the three-phase power supply terminal.
When the shared switch and the welding determination switch are opened, a welding determination unit for determining that the shared switch is welded when a voltage is detected from the plurality of voltage detection units is provided. The charging device according to claim 1.

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