JP7470923B2 - Power conversion system and method for constructing the power conversion system - Google Patents

Description

The present disclosure generally relates to a power conversion system and a method for constructing a power conversion system. More specifically, the present disclosure relates to a power conversion system for charging a storage battery of a mobile object and a method for constructing a power conversion system.

Patent Document 1 discloses a power conversion system to which an electric vehicle equipped with a storage battery is connected. This power conversion system includes a power conversion device and a connector connected to the power conversion device via a cable. The power conversion device has a main circuit that performs power conversion when the storage battery is charged and discharged. The connector is attached to an inlet of the electric vehicle to form a power supply path between the power conversion device and the storage battery.

JP 2015-89220 A

In the power conversion system described in Patent Document 1, a power conversion device having a main circuit is equipped with a cable and a connector. Therefore, in order to charge the storage battery of an electric vehicle, the power conversion device must be installed in the parking space of the electric vehicle, which makes it difficult to install the system.

The present disclosure has been made in consideration of the above points, and aims to provide a power conversion system that is easy to install, and a method for installing a power conversion system.

A power conversion system according to an aspect of the present disclosure includes a first power conversion device, a second power conversion device, and a cable support. The first power conversion device converts AC power input from a power system into DC power and outputs the DC power to a DC bus. The second power conversion device converts DC power input from the DC bus into charging power for a storage battery of a mobile body and outputs the charging power. The cable support supports a cable. The cable is connected between the mobile body and the second power conversion device to form a power supply path between the storage battery and the second power conversion device. The first power conversion device, the second power conversion device, and the cable support are configured separately from each other. The cable includes a first cable connected between the mobile body and the cable support, and a second cable that is a different type from the first cable and is connected between the cable support and the second power conversion device. The power conversion system further includes a connection unit that connects the first cable and the second cable to each other. The second cable has a load capacity larger than that of the first cable. The charging power converted by the second power conversion device is supplied to the storage battery via the first cable and the second cable supported by the cable support. The storage battery is charged with the charging power.

A power conversion system according to an aspect of the present disclosure includes a second power conversion device and a cable support. The second power conversion device is configured separately from the first power conversion device, and converts DC power input from a DC bus into charging power for a storage battery of a mobile body and outputs the converted power. The first power conversion device converts AC power input from a power system into DC power and outputs the converted power to the DC bus. The cable support supports a cable. The cable is connected between the mobile body and the second power conversion device to form a power supply path between the storage battery and the second power conversion device. The second power conversion device and the cable support are configured separately from each other. The cable includes a first cable connected between the mobile body and the cable support, and a second cable of a different type from the first cable and connected between the cable support and the second power conversion device. The power conversion system further includes a connection unit that connects the first cable and the second cable to each other. The second cable has a higher load capacity than the first cable. The charging power converted by the second power conversion device is supplied to the storage battery via the first cable and the second cable supported by the cable support. The storage battery is charged with the charging power.

A method for constructing a power conversion system according to one aspect of the present disclosure is a method for constructing the power conversion system described above. This construction method has a first step and a second step. The first step is a step of connecting the cable to the second power conversion device. The second step is a step of connecting the first power conversion device and the second power conversion device with a DC cable that constitutes the DC bus.

This disclosure has the advantage that the system is easy to install.

FIG. 1 is a schematic diagram showing an overall configuration including a power conversion system according to an embodiment of the present disclosure. FIG. 2 is a schematic diagram showing a configuration of the power conversion system. FIG. 3 is a schematic diagram showing an example of installation of the power conversion system. FIG. 4 is a schematic diagram showing an overall configuration including a power conversion system according to a modified example. FIG. 5 is a schematic diagram showing a modified example of the cable support. FIG. 6 is a schematic diagram showing another modified example of the cable support. FIG. 7 is a schematic diagram showing a modified example of the connection portion of the cable support. FIG. 8 is a schematic diagram showing another modified example of the connection portion of the cable support. FIG. 9 is a schematic diagram showing yet another modified example of the connection portion of the cable support.

(1) Overview The power conversion system 100 of the present embodiment is installed in, for example, a residential facility such as a detached house or an apartment building, or a non-residential facility such as an office, a store, or a nursing home. The power conversion system 100 is a system for supplying power (charging) to a storage battery 31 of a mobile object 3 in these facilities (see FIG. 1 ). In the present embodiment, as an example, a case will be described in which the power conversion system 100 is installed in a house H1 that is a detached house.

The mobile unit 3 includes a power unit such as an electric motor, and a storage battery 31 as a power source that supplies power to the power unit. The mobile unit 3 converts electrical energy (power) input from the storage battery 31 into mechanical energy (driving force) in the power unit, and moves using this mechanical energy. The mobile unit 3 includes a power control circuit 32. The power control circuit 32 charges the storage battery 31 with charging power that does not exceed a predetermined maximum value.

Here, the moving body 3 is a vehicle 30. The vehicle 30 is, for example, an electric vehicle that runs using electric energy stored in a storage battery 31. In this disclosure, the "electric vehicle" is, for example, an electric car that runs using the output of an electric motor, or a plug-in hybrid vehicle that runs using a combination of the output of an engine and the output of an electric motor. The electric vehicle may be a senior car, a two-wheeled vehicle (electric motorcycle), a three-wheeled vehicle, an electric bicycle, or the like.

As shown in FIG. 1, the power conversion system 100 includes a first power conversion device 11, a second power conversion device 12, and a cable support 2. In the following description, the first power conversion device 11 and the second power conversion device 12 may be collectively referred to as the "power converter 1."

The first power conversion device 11 converts the AC power input from the power system 4 into DC power and outputs it to the DC bus DB1. In other words, the first power conversion device 11 has the function of an AC/DC converter that converts the input AC power into DC power of a predetermined magnitude and outputs it.

The second power conversion device 12 converts the DC power input from the DC bus DB1 into charging power for the storage battery 31 of the mobile object 3 and outputs it. In other words, the second power conversion device 12 has the function of a DC/DC converter that converts the input DC power into DC power of a predetermined magnitude and outputs it.

The cable support 2 supports the cable C1. The cable C1 is connected between the mobile body 3 and the second power conversion device 12 to form a power supply path between the storage battery 31 and the second power conversion device 12. A connector CN1 is attached to the tip of the cable C1. The connector CN1 is configured to be connectable to the inlet 34 of the mobile body 3. In other words, when the connector CN1 is connected to the inlet 34, the DC power (charging power) output from the second power conversion device 12 is supplied to the storage battery 31 via the cable C1 supported by the cable support 2.

In this disclosure, a "cable" refers to a linear member in which one or more electric wires are protected by a sheath (outer cover). In addition, in this disclosure, an "electric wire" can include not only a bare electric wire that is an electric conductor, but also an insulated electric wire in which an electric conductor is covered with an insulating material.

In this disclosure, the support of cable C1 by the cable support 2 does not only mean a mode in which cable C1 is temporarily supported by user U1 (see FIG. 3) hanging cable C1 on it so as not to impede the passage of user U1 when connector CN1 is not in use. In other words, in this disclosure, the support of cable C1 by the cable support 2 also means, in principle, permanent support of cable C1 without requiring attachment or detachment by user U1.

In this embodiment, the first power conversion device 11, the second power conversion device 12, and the cable support 2 are configured separately from one another. Specifically, as shown in FIG. 3, the housing 11A housing the functional parts of the first power conversion device 11, the housing 12A housing the functional parts of the second power conversion device 12, and the housing 2A housing the functional parts of the cable support 2 are configured separately from one another. In other words, the first power conversion device 11, the second power conversion device 12, and the cable support 2 are mechanically separated from one another.

For this reason, in this embodiment, the first power conversion device 11, the second power conversion device 12, and the cable support 2 can be handled individually. Therefore, this embodiment has the advantage that the system is easier to install compared to handling a device in which the first power conversion device 11, the second power conversion device 12, and the cable support 2 are integrated.

(2) Details Hereinafter, the power conversion system 100 of the present embodiment will be described in detail with reference to the drawings.

(2.1) Overall Configuration First, the overall configuration including the power conversion system 100 will be described with reference to Fig. 1. In this embodiment, the power conversion system 100 realizes the function of the power conversion system 100 by cooperating with an appliance control device 5 installed inside the house H1.

The power converter 1 and the equipment control device 5 of the power conversion system 100 are configured to be able to communicate with each other. In this disclosure, "able to communicate" means that information can be exchanged directly or indirectly via a network or a repeater, etc., by an appropriate communication method such as wired communication or wireless communication. In other words, the power converter 1 and the equipment control device 5 can exchange information with each other. In this embodiment, the power converter 1 and the equipment control device 5 can communicate with each other bidirectionally, and both the transmission of information from the power converter 1 to the equipment control device 5 and the transmission of information from the equipment control device 5 to the power converter 1 are possible.

The equipment control device 5 is a device that controls at least the power converter 1. The equipment control device 5 controls the start and stop of charging of the storage battery 31 of the mobile object 3 by the power converter 1 by outputting a charging start signal to instruct the power converter 1 to start charging and a charging stop signal to instruct the power converter 1 to stop charging. Therefore, for example, by a user U1 performing a predetermined operation on the equipment control device 5, it is possible to instruct the power converter 1 to start charging the storage battery 31 or to stop charging the storage battery 31.

In this embodiment, the device control device 5 is connected to a network such as the Internet via a router. Therefore, the device control device 5 can communicate with an information terminal carried by the user U1 via the router, or the router and the network. The information terminal is, for example, a smartphone, a tablet terminal, or a personal computer. Therefore, the user U1 can instruct the start of charging the storage battery 31 or the stop of charging the storage battery 31 not only by directly operating the device control device 5, but also by operating the information terminal.

The power converter 1 is a charging facility for charging the storage battery 31 of the mobile object 3. In this embodiment, the power converter 1 is installed inside the house H1. A cable C1 is connected to the power converter 1. The tip of the cable C1 has a connector CN1 that is removably connected to the inlet 34 of the mobile object 3. With the connector CN1 connected to the inlet 34, the power converter 1 is connected to the mobile object 3 via the cable C1, so that it is possible to supply power to the storage battery 31 of the mobile object 3 via the cable C1, and the storage battery 31 can be charged.

The mobile object 3 includes a storage battery 31, a power control circuit 32, and an ECU (Electronic Control Unit) 33. The power control circuit 32 is a circuit that receives power from the power converter 1 and charges the storage battery 31. In this embodiment, the power control circuit 32 has a function of discharging the storage battery 31 in addition to charging the storage battery 31. The ECU 33 controls the power control circuit 32 based on a signal (here, a signal based on the CHAdeMO (registered trademark) standard, as an example) transmitted via a communication line L2 (described later) of the cable C1.

(2.2) Power Conversion System Next, the power conversion system 100 will be described with reference to Figures 1 to 3. The power conversion system 100 includes a first power conversion device 11 and a second power conversion device 12 as a power converter 1, and a cable support 2.

As shown in FIG. 2, the first power conversion device 11 includes a main circuit 111, a control circuit 112, and a communication unit 113. In the first power conversion device 11, the main circuit 111, the control circuit 112, and the communication unit 113 are all housed in a rectangular parallelepiped housing 11A (see FIG. 3). In this embodiment, the housing 11A is installed in a house H1, as shown in FIG. 3.

The main circuit 111 is a bidirectional AC/DC converter, with one end connected to the power system 4 and the other end connected to the main circuit 121 of the second power conversion device 12 via a DC cable C2, which is a DC bus DB1. The main circuit 111 has, for example, multiple switching elements connected in a full bridge configuration, and converts DC power to AC power or AC power to DC power by PWM (Pulse Width Modulation) controlling the multiple switching elements by a control circuit 112.

In this embodiment, the main circuit 111 has a function of converting the AC power output by the power system 4 into DC power of a predetermined magnitude and outputting it to the second power conversion device 12. In addition, in this embodiment, the main circuit 111 has a function of converting the DC power output by the second power conversion device 12 into AC power of a predetermined magnitude and outputting it to the power system 4. In other words, the first power conversion device 11 has a function of converting the DC power input from the DC cable C2 (DC bus DB1) into AC power and outputting it to the power system 4.

At least a part of the control circuit 112 is composed of a microcontroller having one or more processors and a memory. In other words, at least a part of the control circuit 112 is realized by a computer system having one or more processors and a memory, and the computer system functions as a part of the control circuit 112 by the one or more processors executing a program stored in the memory. The program is pre-recorded in the memory of the control circuit 112 here, but it may be provided through a telecommunications line such as the Internet, or recorded on a non-transitory recording medium such as a memory card. The control circuit 112 also has a driver for driving multiple switching elements of the main circuit 111. The control circuit 112 may be composed of, for example, an FPGA (Field-Programmable Gate Array) or an ASIC (Application Specific Integrated Circuit).

The control circuit 112 has a function of controlling the main circuit 111 to start or stop charging the storage battery 31 by receiving a command from the device control device 5 or the information terminal via the communication unit 113. In this embodiment, the control circuit 112 also has a function of controlling the main circuit 111 to convert DC power from the second power conversion device 12 into AC power and output it to the load (including the distribution board) in the house H1, for example, during a power outage in the power system 4.

The communication unit 113 has a function of communicating with the device control device 5. As a communication method between the communication unit 113 and the device control device 5, an appropriate communication method such as wireless communication or wired communication is adopted. In the present embodiment, as an example, the communication method between the communication unit 113 and the device control device 5 is wired communication conforming to a communication standard such as a wired LAN (Local Area Network). The communication protocol for communication between the communication unit 113 and the device control device 5 is, for example, Ethernet (registered trademark) or ECHONET Lite (registered trademark), etc.

The communication unit 113 also has a function of communicating with the communication unit 123 (described later) of the second power conversion device 12. As a communication method between the communication unit 113 and the communication unit 123 of the second power conversion device 12, an appropriate communication method such as wireless communication or wired communication is adopted. In the present embodiment, as an example, the communication unit 113 performs wired communication with the communication unit 123 of the second power conversion device 12 via the communication line L2 of the DC cable C2.

As shown in FIG. 2, the second power conversion device 12 includes a main circuit 121, a control circuit 122, and a communication unit 123. In the second power conversion device 12, the main circuit 121, the control circuit 122, and the communication unit 123 are all housed in a rectangular parallelepiped housing 12A (see FIG. 3). In this embodiment, the housing 12A is installed in the house H1, as shown in FIG. 3.

The main circuit 121 is a bidirectional DC/DC converter, with one end connected to the first cable C11 and the other end connected to the main circuit 111 of the first power conversion device 11 via a DC cable C2. The main circuit 121 has, for example, one or more switching elements, and adjusts and outputs the input DC power by PWM-controlling the one or more switching elements by a control circuit 122.

In this embodiment, the main circuit 121 has a function of converting the DC power output by the first power conversion device 11 into DC power of a predetermined magnitude and outputting it to the storage battery 31 via the first cable C11 and the connector CN1. Also, in this embodiment, the main circuit 121 has a function of converting the DC power discharged from the storage battery 31 via the first cable C11 and the connector CN1 into DC power of a predetermined magnitude and outputting it to the first power conversion device 11. In other words, the second power conversion device 12 has a function of adjusting the discharge power (DC power) discharged from the storage battery 31 and outputting it to the DC bus DB1.

In this way, in this embodiment, the power conversion system 100 has a function of controlling the discharge of the storage battery 31. Therefore, in this embodiment, a V2H (Vehicle To Home) system can be constructed by outputting the discharged power of the storage battery 31 of the mobile object 3 to a load (including a distribution board) of the house H1.

At least a part of the control circuit 122 is composed of a microcontroller having one or more processors and memory. In other words, at least a part of the control circuit 122 is realized in a computer system having one or more processors and memory, and the computer system functions as part of the control circuit 122 by the one or more processors executing a program stored in the memory. Here, the program is pre-recorded in the memory of the control circuit 122, but it may be provided via a telecommunications line such as the Internet, or recorded on a non-transitory recording medium such as a memory card. The control circuit 122 also has a driver for driving one or more switching elements of the main circuit 121. The control circuit 122 may be composed of, for example, an FPGA or an ASIC.

The control circuit 122 has a function of controlling the main circuit 121 to start or stop charging the storage battery 31 by receiving commands from the equipment control device 5 or the information terminal via the communication unit 123 and the communication unit 113 of the first power conversion device 11. In this embodiment, the control circuit 122 also has a function of controlling the main circuit 121 to adjust the discharge power (DC power) from the storage battery 31 and output it to the first power conversion device 11, for example, during a power outage in the power system 4.

The communication unit 123 has a function of communicating with the communication unit 113 of the first power conversion device 11. As a communication method between the communication unit 123 and the communication unit 113 of the first power conversion device 11, an appropriate communication method such as wireless communication or wired communication is adopted. In the present embodiment, as an example, the communication unit 123 performs wired communication with the communication unit 113 of the first power conversion device 11 via the communication line L2 of the DC cable C2.

The communication unit 123 also has a function of communicating with the mobile body 3. An appropriate communication method such as wireless communication or wired communication is adopted as the communication method between the communication unit 123 and the mobile body 3. As an example in this embodiment, the communication unit 123 performs wired communication with the mobile body 3 via the communication line L2 of the cable C1. As an example in this embodiment, the communication unit 123 performs communication to check the connection between the power converter 1 and the mobile body 3 and to check the status of the mobile body 3, etc., using signals based on at least the CHAdeMO (registered trademark) standard.

As shown in FIG. 2, the cable support 2 supports a portion of the cable C1. The cable support 2 also supports a portion of the cable C1 by housing it in a rectangular parallelepiped housing 2A (see FIG. 3). In this embodiment, as shown in FIG. 3, the housing 2A is installed outside the house H1 in the parking space A1 of the mobile object 3. In other words, the cable support 2 is installed independently on the ground (here, the parking space A1).

In this embodiment, the cable C1 has a first cable C11 and a second cable C12. The first cable C11 is connected between the moving body 3 and the cable support 2. The second cable C12 is a different type from the first cable C11, and is connected between the cable support 2 and the second power conversion device 12. In other words, in this embodiment, the first cable C11 and the second cable C12 are different types from each other.

In this embodiment, except for the case where two cables obtained by cutting one cable C1 are the first cable C11 and the second cable C12, the first cable C11 and the second cable C12 are basically of different types. Specifically, the first cable C11 and the second cable C12 are of different types because they have different diameter dimensions. Also, the first cable C11 and the second cable C12 are of different types because they contain different numbers of electric wires. In addition, the first cable C11 and the second cable C12 can also be said to be of different types if the cable structures, materials, or manufacturers are different.

In this embodiment, the first cable C11 is, for example, a cab-tire cable. Also, in this embodiment, the second cable C12 is, for example, a cross-linked polyethylene insulated vinyl sheath cable (CV cable). Also, in this embodiment, the first cable C11 and the second cable C12 each have one or more (here, two) power lines L1 and one or more (here, multiple) communication lines L2. Furthermore, in this embodiment, the DC cable C2 is a CV cable like the second cable C12, and has one or more power lines L1 and one or more communication lines L2.

The cable support 2 (power conversion system 100) further includes a connection unit 20 that connects the first cable C11 and the second cable C12 to each other. In this embodiment, the connection unit 20 is housed inside the housing 2A of the cable support 2. In other words, the connection unit 20 is provided inside the cable support 2.

In other words, the cable support 2 has a connection part 20 to which the first cable C11 and the second cable C12 are connected. The first cable C11 can also be considered a cable connected to the mobile object 3 to supply DC power to the storage battery 31 of the mobile object 3. The second cable C12 can also be considered a cable connected to the power converter 1 that converts AC power from the power system 4 into DC power and outputs it to the storage battery 31.

In this embodiment, the connection portion 20 has a first terminal 21 to which the first cable C11 is connected, and a second terminal 22 to which the second cable C12 is connected. That is, in this embodiment, the first cable C11 is fixed (supported) to the cable support 2 by connecting one end of the first cable C11 to the first terminal 21. Also, the second cable C12 is fixed (supported) to the cable support 2 by connecting one end of the second cable C12 to the second terminal 22.

The first terminal 21 and the second terminal 22 are connected via an electric circuit 23. The electric circuit 23 is a conversion circuit that converts the electrical connection so that, for example, one or more power lines L1 and one or more communication lines L2 of the first cable C11 can be connected to one or more power lines L1 and one or more communication lines L2 of the second cable C12. Of course, the electric circuit 23 may be a simple electric conductor that connects one or more power lines L1 and one or more communication lines L2 of the first cable C11 to one or more power lines L1 and one or more communication lines L2 of the second cable C12.

In this embodiment, as shown in FIG. 3, a portion of the cable C1 is laid underground between the cable support 2 and the first power conversion device 11. Similarly, a portion of the DC cable C2 is laid underground between the first power conversion device 11 and the second power conversion device 12. In the ground, the cable C1 is passed through a pipe C3, such as a metal conduit. The hardness of the pipe C3 is higher than the hardness of the sheath (outer skin) of the cable C1.

(3) Advantages Advantages of the power conversion system 100 of the present embodiment will be described below with comparison with a power conversion system of a first comparative example and a power conversion system of a second comparative example.

The power conversion system of the first comparative example differs from the power conversion system 100 of the present embodiment in that the power converters (first power conversion device and second power conversion device) are built into the cable support, that is, the cable support, the first power conversion device, and the second power conversion device are integrated. In the power conversion system of the first comparative example, the power converters are built into the cable support, so the housing of the cable support is inevitably large. Furthermore, the housing of this cable support needs to be installed in a parking space for the purpose of charging the storage battery of the mobile object.

For this reason, in the power conversion system of the first comparative example, since the housing of the cable support is relatively large, a large number of installers are required to install the housing in the parking space, and the locations where the housing can be installed are likely to be limited. Furthermore, depending on the area of the parking space, it may not be possible to install the cable support in the first place. In addition, in the power conversion system of the first comparative example, since the power converter is built into the cable support, a problem may arise in that measures must be taken to suppress the temperature rise of the power converter due to sunlight. Furthermore, in the power conversion system of the first comparative example, the temperature rise of the power converter due to sunlight may prevent the system from performing its original performance.

The power conversion system of the second comparative example differs from the power conversion system 100 of the present embodiment in that the cable support and the power converter are configured separately, that is, the first power conversion device and the second power conversion device are configured integrally. In the power conversion system of the second comparative example, unlike the power conversion system of the first comparative example, the power converter is not built into the cable support, so that the above-mentioned problems associated with sunlight can be solved by installing the power converter, for example, on the north-facing side of a house. However, in the power conversion system of the second comparative example, since the first power conversion device and the second power conversion device are configured integrally, the size of the power converter housing is unavoidable. For this reason, in the power conversion system of the second comparative example, the number of installers required to install the power converter housing tends to be large, and the location where the housing can be installed is limited, which may cause problems.

In contrast, in the power conversion system 100 of this embodiment, the first power conversion device 11, the second power conversion device 12, and the cable support 2 are configured separately from one another. Therefore, in this embodiment, it is possible to reduce the size of each of the housings 11A of the first power conversion device 11, the housing 12A of the second power conversion device 12, and the housing 2A of the cable support 2, compared to when the housings 11A, 12A, and 2A are integrated. In addition, by reducing the size of each of the housings 11A, 12A, and 2A, it is possible to reduce the weight.

Therefore, this embodiment has the advantage that the construction of the power conversion system 100 is easy. Specifically, in this embodiment, the size and weight of each of the housings 11A, 12A, and 2A are relatively small, so that construction can be performed by a small number of construction workers.

In addition, in this embodiment, the space occupied by each of the housings 11A, 12A, and 2A is relatively small, which has the advantage of increasing the options for where to install each of the housings 11A, 12A, and 2A. For example, since the cable support 2, the first power conversion device 11, and the second power conversion device 12 are separate, it is possible to install only the cable support 2 in the parking space A1 even if the area of the parking space A1 is small. Then, it is possible to install the first power conversion device 11 and the second power conversion device 12 in a place other than the parking space A1 where there is ample installation space, such as in a house H1. In this case, since the housings 11A and 12A are separate, it is possible to install the first power conversion device 11 and the second power conversion device 12 in the house H1 according to the installation space situation.

In addition, in this embodiment, since the cable support 2, the first power conversion device 11, and the second power conversion device 12 are separate, it is possible to install the first power conversion device 11 and the second power conversion device 12 in a location that is not easily exposed to direct sunlight, such as inside the house H1 or under the eaves. Therefore, in this embodiment, there is no need to take measures to suppress the temperature rise of the power converter 1, as in the power conversion system of the first comparative example, and this has the advantage that the effort and cost required for measures can be reduced.

In this embodiment, the cable support 2 (power conversion system 100) includes a connection portion 20. Below, the advantages of including the connection portion 20 will be explained, along with a comparison with a cable support of a comparative example. The cable support of the comparative example differs from the cable support 2 of this embodiment in that it does not include the connection portion 20, that is, it supports a single cable instead of the first cable C11 and the second cable C12.

In the cable support of the comparative example, it is possible to use, for example, a cab-tire cable. A cab-tire cable is easy to handle when used outdoors, such as for charging a storage battery, and has excellent outdoor properties such as impact resistance, abrasion resistance, and weather resistance, but is not suitable for use in fixed installations indoors. Therefore, for example, using part of a cab-tire cable for fixed wiring indoors is not preferable from the standpoint of workability and cost.

In addition, the cable support of the comparative example may use, for example, a CV cable. Although CV cables are suitable for applications in which they are installed in a fixed position, they are difficult to handle when used outdoors, such as for charging storage batteries, and they lack outdoor characteristics such as impact resistance, abrasion resistance, and weather resistance. Therefore, for example, it is not desirable to use part of a CV cable outdoors. In this way, the cable support of the comparative example supports only one type of cable, which creates the problem that it is difficult to select an appropriate cable depending on the installation environment of the cable support.

In contrast, the cable support 2 of this embodiment is provided with a connection section 20, so that it is possible to select a cable suitable for the installation environment of the cable support 2. As an example, it is possible to connect a cab-tire cable as the first cable C11 and a CV cable as the second cable C12 at the connection section 20. In other words, in this embodiment, it is possible to select a cable that is easy to handle and has characteristics suitable for outdoor use, such as charging a storage battery, for the first cable C11, while selecting a cable suitable for a fixed installation application for the second cable C12. In addition, since the first cable C11 and the second cable C12 can be selected according to the installation environment of the cable support 2, it is possible to expect improvements in cost reduction, workability, appearance, etc., compared to wiring one type of cable.

(4) Modifications The above-described embodiment is merely one of various embodiments of the present disclosure. The above-described embodiment can be modified in various ways depending on the design, etc., as long as the object of the present disclosure can be achieved. Modifications of the above-described embodiment are listed below. The modifications described below can be applied in appropriate combination.

In the above-described embodiment, the power conversion system 100 may further include a third power conversion device 13 that adjusts the DC power input from the distributed power source 6 and outputs it to the DC bus DB1, as shown in FIG. 4. The third power conversion device 13 is a DC/DC converter and is connected to the DC bus DB1. The third power conversion device 13 has a function of converting the DC power output from the distributed power source 6 into DC power of a predetermined magnitude and outputting it to the first power conversion device 11 via the DC bus DB1.

In this embodiment, it is possible to supply power from the distributed power source 6 to the storage battery 31 without going through the first power conversion device 11 (i.e., an AC/DC converter) compared to the case where the distributed power source 6 is connected via a power conditioner. Therefore, in this embodiment, it is possible to reduce power conversion loss compared to the case where the distributed power source 6 is connected via a power conditioner. Note that the third power conversion device 13 may be configured separately from the first power conversion device 11 as shown in FIG. 4, or may be configured in the same housing as the first power conversion device 11 without being limited thereto.

Here, the distributed power source 6 may include a solar cell. In this embodiment, the surplus power generated by the solar cell that is not consumed by the load of the house H1 is charged to the storage battery 31, thereby supporting the power supply from the power grid 4 to the storage battery 31, for example by reducing the charging power of the storage battery 31 by purchasing power from the power grid 4.

The distributed power source 6 may also include a battery different from the storage battery 31. The third power conversion device 13 may have a function of converting the DC power input from the DC bus DB1 into charging power for the battery and outputting it to the battery. In this embodiment, it is possible to support the power supply from the power system 4 to the storage battery 31 by using the power stored in the battery. For example, even if it is desired to charge the storage battery 31 during a relatively inexpensive time period (for example, late at night) when the mobile body 3 is absent, it is possible to charge the storage battery 31 with the power stored in the battery when the mobile body 3 returns by charging the battery. In this embodiment, it is possible to charge the storage battery 31 with power exceeding the rated power of the first power conversion device 11 by adding up the power stored in the battery and the DC power supplied from the power system 4 via the first power conversion device 11. Furthermore, by using the power stored in the battery when charging the storage battery 31, the DC power supplied from the power grid 4 via the first power conversion device 11 can be reduced, making it difficult to trip the breaker in the house H1.

In the above embodiment, the cable support 2 is not limited to being installed independently on the ground, but may be installed by being attached to a part of the house H1 (building). For example, as shown in FIG. 5, the cable support 2 may be attached to the wall H11 of the house H1. Also, as shown in FIG. 6, the cable support 2 may be attached to the back side of the ceiling H12 of the house H1. In this case, the cable C1 (first cable C11) is suspended from the ceiling H12. In addition, the cable support 2 may be attached to a columnar member erected on the ground, not limited to a building. This aspect has the advantage that the cable support 2 can be easily installed in a good-looking manner without taking up installation space, for example, in a relatively narrow parking space A1 where it is difficult to install the cable support 2 independently.

In the above-described embodiment, at least one of the cable C1 and the DC cable C2 may be configured to be adjustable in length relative to the length of the cable C1. The DC cable C2 connects between the first power conversion device 11 and the second power conversion device 12 to form a DC bus DB1. This aspect has the advantage that the lengths of the cable C1 and the DC cable C2 can be optimized according to the environment in which the system is installed. Specifically, this aspect is expected to have the following two advantages.

First, by shortening the length of either cable C1 or DC cable C2, whichever is applied with a high voltage, there is an advantage that the cable to which the high voltage is applied is less likely to be exposed to the outside. In addition, by shortening the length of the cable to which the high voltage is applied, that is, the cable that requires high voltage resistance, there is an advantage that costs can be reduced.

Secondly, when the same amount of power is supplied to each of the cables C1 and DC cable C2, the current in the cable to which the high voltage is applied is relatively small. Therefore, there is an advantage in that the loss due to wiring impedance can be reduced by shortening the length of the cable to which the high voltage is applied.

In the above-described embodiment, the connection portion 20 may be provided on the outside of the cable support 2. For example, the connection portion 20 may be provided on the outside of the cable support 2, on one surface of the housing 2A of the cable support 2.

In the above-described embodiment, the first cable C11 and the second cable C12 do not have to be of different types. For example, the first cable C11 and the second cable C12 may be the same type of cable and connected at the connection part 20.

In the above-described embodiment, the power conversion system 100 (cable support 2) may not include the connection portion 20. In other words, the cable support 2 may support a single cable C1 that connects the mobile body 3 and the second power conversion device 12 in a single line.

In the above embodiment, the power conversion system 100 may not include the first power conversion device 11. That is, the power conversion system 100 may include only the second power conversion device 12 and the cable support 2. The second power conversion device 12 is configured separately from the first power conversion device 11, which converts AC power input from the power system 4 into DC power and outputs it to the DC bus DB1, and converts DC power input from the DC bus DB1 into charging power for the storage battery 31 of the mobile object 3 and outputs it. The cable support 2 supports the cable C1 that is connected between the mobile object 3 and the second power conversion device 12 and forms a power supply path between the storage battery 31 and the second power conversion device 12. The second power conversion device 12 and the cable support 2 are configured separately from each other.

In this power conversion system 100, similarly to the above-described embodiment, the second power conversion device 12 may have a function of adjusting the DC power discharged from the storage battery 31 and outputting it to the DC bus DB1. In addition, this power conversion system 100 may be connected not only to the first power conversion device 11 but also to the third power conversion device 13. In this case, the third power conversion device 13 may be configured separately from the first power conversion device 11, or may be configured in the same housing as the first power conversion device 11, without being limited thereto.

In the above-described embodiment, the power conversion system 100 may be constructed by the following construction method. That is, the construction method of the power conversion system 100 may have a first step and a second step. The first step is a step of connecting the cable C1 to the second power conversion device 12. The second step is a step of connecting the first power conversion device 11 and the second power conversion device 12 by the DC cable C2 that constitutes the DC bus DB1.

In the above embodiment, the power conversion system 100 can be configured as a V2H system, but this does not have to be the case. In other words, the power conversion system 100 may be configured only as a charging system that charges the storage battery 31. In this case, in the power conversion system 100, the power converter 1 only needs to have a unidirectional power conversion function from the power grid 4 to the storage battery 31.

In the above-described embodiment, the cable support 2 may be provided with an operation unit for instructing the start and stop of charging the storage battery 31. In this case, the user U1 can instruct the start and stop of charging the storage battery 31 by operating the operation unit without directly operating the device control device 5. Also, the operation unit may be provided in the connector CN1 instead of the cable support 2.

In the above embodiment, the housing 11A of the first power conversion device 11, the housing 12A of the second power conversion device 12, and the housing 2A of the cable support 2 may be configured separately from one another, and these housings 11A, 12A, and 2A may be arranged in any manner. For example, the housing 12A of the second power conversion device 12 may be arranged stacked on the housing 11A of the first power conversion device 11.

In the above-described embodiment, both the cable C1 and the DC cable C2 may be wired above ground, not underground. In this case, at least one of the cables C1 and the DC cable C2, and more specifically, the first cable C11 of the cable C1, is preferably provided with a simple contact protection measure by being passed through a pipe C3 having a predetermined hardness. As the pipe C3, for example, in addition to a metal conduit, a flexible conduit made of synthetic resin or the like may be used. In other words, the first cable C11 may be passed through a pipe (conduit) C3 having a predetermined hardness. This aspect has the advantage that it is possible to make it difficult for the user U1 to touch the first cable C11, which may be placed outside the house H1 (building).

In the above-described embodiment, the second cable C12 may have a higher load capacity than the first cable C11. This aspect has the advantage that it is easier to ensure the impact resistance of the second cable C12, which may be subjected to a higher voltage than the first cable C11.

In the above-described embodiment, it is preferable that the first cable C11 has a higher degree of flexibility (in other words, a smaller minimum bending radius) than the second cable C12. This aspect has the advantage that the first cable C11, which may be routed when charging the storage battery 31, can be made easier to handle.

In the above-described embodiment, as shown in FIG. 7, the connection portion 20 may have a temperature sensor 24. The temperature sensor 24 is disposed, for example, near either the first terminal 21 or the second terminal 22. Here, the temperature sensor 24 is disposed near the second terminal 22 where a poor connection of the cable may occur during on-site construction of the power conversion system 100. Note that the first cable C11 is already connected to the first terminal 21 when the cable support 2 is shipped, and if the pre-shipment inspection results are good, it is considered that the possibility of a poor connection occurring is low.

The temperature sensor 24 transmits the detection result to the control circuit 122 of the second power conversion device 12, for example, via the communication line L2 of the second cable C12. The control circuit 122 monitors the detection result of the temperature sensor 24, and when the temperature detected by the temperature sensor 24 exceeds the threshold temperature, the control circuit 122 stops the power supply from the second power conversion device 12 to the storage battery 31 by controlling the relay connected to the power line L1. In other words, when the detected temperature exceeds the threshold temperature, the temperature sensor 24 generates a trigger to stop the supply of DC power from the power converter 1 (here, the second power conversion device 12).

In this embodiment, even if a poor connection occurs in the cable, the temperature sensor 24 detects the temperature rise caused by the increase in contact resistance due to the poor connection, so that the poor connection in the cable can be detected early and the power supply can be stopped.

Here, the control circuit 122 may stop the operation of the second power conversion device 12 by controlling the main circuit 121 instead of controlling the relay, thereby stopping the power supply from the second power conversion device 12 to the storage battery 31. That is, the temperature sensor 24 may generate a trigger for stopping the operation of at least a part of the power converter 1 (here, the second power conversion device 12) when the detected temperature exceeds the threshold temperature. Furthermore, the temperature sensor 24 may generate a trigger for opening the connection of the permission signal line included in the communication line L2 of the second cable C12 when the detected temperature exceeds the threshold temperature. The permission signal line here is, for example, a signal line through which an operation permission/prohibition signal generated by the mobile unit 3 in the CHAdeMO standard flows. In this case, it is possible to prompt the storage battery 31 to stop the charging operation or discharging operation by using a constant signal monitoring function that is provided in advance in the second power conversion device 12. These aspects have the advantage that it is easy to avoid the occurrence of a portion to which a high voltage is applied to the cable C1 (the first cable C11 and the second cable C12).

In the above-described embodiment, as shown in FIG. 8, the connection portion 20 may have a fuse 25 disposed between the first terminal 21 and the second terminal 22. Here, the fuse 25 is connected in series to the electric circuit 23 between the first terminal 21 and the second terminal 22. This aspect has the advantage that even if a short circuit occurs due to a poor connection of the cable or the intrusion of a foreign object, the fuse 25 can be cut off to prevent the power supply from continuing in a short-circuit state.

In the above-described embodiment, as shown in FIG. 9, the connection portion 20 may not have the first terminal 21 and the second terminal 22. In other words, in the connection portion 20, the first cable C11 and the second cable C12 may be directly connected without going through the electric circuit 23.

(summary)
As described above, the power conversion system (100) according to the first aspect includes a first power conversion device (11), a second power conversion device (12), and a cable support (2). The first power conversion device (11) converts AC power input from a power system (4) into DC power and outputs the DC power to a DC bus (DB1). The second power conversion device (12) converts DC power input from the DC bus (DB1) into charging power for a storage battery (31) of a mobile body (3) and outputs the charging power. The cable support (2) supports a cable (C1). The cable (C1) is connected between the mobile body (3) and the second power conversion device (12) to form a power supply path between the storage battery (31) and the second power conversion device (12). The first power conversion device (11), the second power conversion device (12), and the cable support (2) are configured separately from each other.

This embodiment has the advantage that the system is easier to install compared to handling an apparatus in which the first power conversion device (11), the second power conversion device (12), and the cable support (2) are integrated.

In the power conversion system (100) according to the second aspect, in the first aspect, the second power conversion device (12) has a function of adjusting the DC power discharged from the storage battery (31) and outputting it to the DC bus (DB1). The first power conversion device (11) has a function of converting the DC power input from the DC bus (DB1) into AC power and outputting it to the power system (4).

According to this embodiment, the advantage is that by using the power stored in the storage battery (31), it is possible to support the supply of power to a load by purchasing power from the power grid (4) and to supply power to a load in an emergency such as a power outage.

The power conversion system (100) according to the third aspect further includes a third power conversion device (13) that adjusts the DC power input from the distributed power source (6) and outputs it to the DC bus (DB1) in the first or second aspect.

This embodiment has the advantage of reducing power conversion loss compared to connecting to the distributed power source (6) via a power conditioner.

In the power conversion system (100) according to the fourth aspect, in the third aspect, the distributed power source (6) includes a solar cell.

This embodiment has the advantage that it is possible to support the power supply from the power grid (4) to the storage battery (31) by using the power generated by the solar cell.

In the power conversion system (100) according to the fifth aspect, in the third aspect, the distributed power source (6) includes a battery different from the storage battery (31). The third power conversion device (13) has a function of converting the DC power input from the DC bus (DB1) into charging power for the battery and outputting it to the battery.

According to this embodiment, it is possible to support the power supply from the power grid (4) to the storage battery (31) by utilizing the power stored in the battery.

In the power conversion system (100) according to the sixth aspect, in any of the first to fifth aspects, the cable support (2) is installed by being attached to a part of the building (house (H1)).

This embodiment has the advantage that the cable support (2) can be easily installed in a visually appealing manner without taking up installation space, even in a relatively small parking space (A1) where it is difficult to install the cable support (2) independently.

In the power conversion system (100) according to the seventh aspect, in any of the first to fifth aspects, the cable support (2) is installed independently on the ground (parking space (A1)).

This embodiment has the advantage that it is possible to install the cable support (2) even if there is no building (house (H1)) or the like to which the cable support (2) can be attached in the vicinity of the parking space (A1).

In the power conversion system (100) according to the eighth aspect, in any of the first to seventh aspects, at least one of the cable (C1) and the DC cable (C2) is configured so that the length of the DC cable (C2) relative to the length of the cable (C1) can be adjusted. The DC cable (C2) connects between the first power conversion device (11) and the second power conversion device (12) to form a DC bus (DB1).

This aspect has the advantage that the lengths of the cable (C1) and the DC cable (C2) can be optimized depending on the environment in which the system is installed.

In the power conversion system (100) according to the ninth aspect, in any of the first to eighth aspects, the cable (C1) has a first cable (C11) and a second cable (C12). The first cable (C11) is connected between the moving body (3) and the cable support (2). The second cable (C12) is a different type from the first cable (C11) and is connected between the cable support (2) and the second power conversion device (12). The power conversion system (100) further includes a connection part (20) that connects the first cable (C11) and the second cable (C12) to each other.

This embodiment has the advantage that it is possible to select a suitable cable depending on the installation environment of the cable support (2).

In the power conversion system (100) according to the tenth aspect, in the ninth aspect, the connection part (20) is provided inside the cable support (2).

This embodiment has the advantage that the connection portion (20) is not exposed to the outside of the cable support (2), improving the appearance.

The power conversion system (100) according to the eleventh aspect includes a second power conversion device (12) and a cable support (2). The second power conversion device (12) is configured separately from the first power conversion device (11) and converts DC power input from a DC bus (DB1) into charging power for a storage battery (31) of a mobile body (3) and outputs the converted power. The first power conversion device (11) converts AC power input from a power system (4) into DC power and outputs the DC power to the DC bus (DB1). The cable support (2) supports a cable (C1). The cable (C1) is connected between the mobile body (3) and the second power conversion device (12) to form a power supply path between the storage battery (31) and the second power conversion device (12). The second power conversion device (12) and the cable support (2) are configured separately from each other.

This embodiment has the advantage that the system is easier to install compared to handling an apparatus in which the first power conversion device (11), the second power conversion device (12), and the cable support (2) are integrated.

The construction method of the power conversion system (100) according to the twelfth aspect is a construction method of the power conversion system (100) according to any one of the first to tenth aspects. This construction method has a first step and a second step. The first step is a step of connecting a cable (C1) to the second power conversion device (12). The second step is a step of connecting the first power conversion device (11) and the second power conversion device (12) with a DC cable (C2) constituting a DC bus (DB1).

This embodiment has the advantage that the system is easier to install compared to handling an apparatus in which the first power conversion device (11), the second power conversion device (12), and the cable support (2) are integrated.

The configurations according to the second to tenth aspects are not essential to the power conversion system (100) and may be omitted as appropriate.

REFERENCE SIGNS LIST 100 Power conversion system 11 First power conversion device 12 Second power conversion device 13 Third power conversion device 2 Cable support 20 Connection unit 3 Mobile body 31 Storage battery 4 Power system 6 Distributed power source A1 Parking space (ground)
C1 Cable C11 First cable C12 Second cable C2 DC cable DB1 DC bus H1 House (building)

Claims (11)

a first power conversion device that converts AC power input from a power grid into DC power and outputs the DC power to a DC bus;
a second power conversion device that converts the DC power input from the DC bus into charging power for a storage battery of the mobile object and outputs the charging power;
a cable support connected between the moving body and the second power conversion device to support a cable forming a power supply path between the storage battery and the second power conversion device,
the first power conversion device, the second power conversion device, and the cable support are configured separately from one another,
The cable includes:
A first cable connected between the moving body and the cable support;
a second cable of a different type from the first cable and connected between the cable support and the second power converter;
a connection portion that connects the first cable and the second cable to each other,
The second cable has a higher load capacity than the first cable,
the charging power converted by the second power conversion device is supplied to the storage battery via the first cable and the second cable supported by the cable support;
The storage battery is charged with the charging power.
Power conversion systems. the second power conversion device has a function of adjusting DC power discharged from the storage battery and outputting the adjusted DC power to the DC bus;
The first power conversion device has a function of converting DC power input from the DC bus into AC power and outputting the AC power to the power grid.
The power conversion system of claim 1 . a third power conversion device that adjusts DC power input from a distributed power source and outputs the adjusted DC power to the DC bus;
The power conversion system according to claim 1 or 2. The distributed power source includes a solar cell.
The power conversion system of claim 3 . the distributed power source includes a battery different from the storage battery;
the third power conversion device has a function of converting DC power input from the DC bus into charging power for the battery and outputting the charging power to the battery.
The power conversion system of claim 3 . The cable support is installed by being attached to a part of a building.
The power conversion system according to any one of claims 1 to 5. The cable support is installed freestanding on the ground.
The power conversion system according to any one of claims 1 to 5. At least one of the cable and a DC cable that connects between the first power conversion device and the second power conversion device and configures the DC bus is configured to be adjustable in length with respect to the length of the cable.
The power conversion system according to any one of claims 1 to 7. The connection portion is provided inside the cable support.
The power conversion system according to any one of claims 1 to 8. a first power conversion device that converts AC power input from a power grid into DC power and outputs the DC power to a DC bus, and a second power conversion device that converts the DC power input from the DC bus into charging power for a storage battery of a mobile object and outputs the charging power;
a cable support connected between the moving body and the second power conversion device to support a cable forming a power supply path between the storage battery and the second power conversion device,
The second power conversion device and the cable support are configured separately from each other,
The cable includes:
A first cable connected between the moving body and the cable support;
a second cable of a different type from the first cable and connected between the cable support and the second power converter;
a connection portion that connects the first cable and the second cable to each other,
The second cable has a higher load capacity than the first cable,
the charging power converted by the second power conversion device is supplied to the storage battery via the first cable and the second cable supported by the cable support;
The storage battery is charged with the charging power.
Power conversion systems. A method for constructing a power conversion system according to any one of claims 1 to 9,
a first step of connecting the cable to the second power converter;
a second step of connecting the first power conversion device and the second power conversion device with a DC cable constituting the DC bus,
How to install a power conversion system.

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