JP6847604B2 - Power interchange system - Google Patents

Description

The present invention relates to a power interchange system, particularly a power interchange system using a DC constant voltage type power supply.

In recent years, as a distributed power supply system in which relatively small-scale power generation devices are distributed and supplied, when a grid power source exists, power from the grid power source is used by using a solar battery, a storage battery, or other batteries. A power system that can keep the supply amount constant and can use each device organically by integrating each device in the system device when there is no system power supply is often used. ..

As an example, in addition to a DC / DC converter that adjusts the DC voltage output from the solar cell and a first bidirectional DC / DC converter that adjusts the DC voltage input and output to the DC battery, an automobile battery A DC / DC converter, a first bidirectional DC / DC converter, and a second bidirectional DC converter, which comprises a second bidirectional DC / DC converter for adjusting the DC voltage input to / from the automobile battery. The DC / DC converter is organically controlled by the control unit to keep the amount of power supplied from the grid power supply constant, and when the grid power supply fails, the solar battery, storage battery, and automobile battery are organically used for loading. A distributed power supply system has been proposed to supply power to (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2015-76977 (pages 4-6, FIG. 1)

In the distributed power supply system and other conventional distributed power supply systems disclosed in Patent Document 1, the power value between the input device and the output device connected to the power bus is commanded, and a power interchange command is specified. The method is adopted. Therefore, in consideration of conversion efficiency and the like, it is necessary to perform complicated calculations especially when there are many input / output devices. Further, when a plurality of power devices (input / output devices) operate in the same operation at the same time, for example, when the input to the power bus is 20 kW, the two power devices are set to output 15 kW and 10 kW, respectively. There is a problem such as an error.

The present invention has been made by paying attention to the above-mentioned problems, and prioritizes control among a plurality of electric power devices, and inputs / outputs are controlled by a fixed set value from the one with the highest priority. Along with the implementation, the power surplus is intended to provide a power interchange system in which lower priority power values can be controlled to reduce excess and deficiency.

The invention according to claim 1 is a power bus, an input type power source that supplies power from a power input source to the power bus, detects the voltage of the power bus and controls the input, and power from the power bus to a power output destination. An output type power supply that supplies power, detects the voltage of the power bus, and controls the output, a bidirectional power supply that has two functions of the input type power supply and the output type power supply, and the input type power supply and the output type power supply. And the said when functioning as the input type power source and the input type power source in the power interchange system provided with the power control means which gives an operation command to the bidirectional power source and controls input / output of power to the power bus. The bidirectional power supply has a constant voltage control function that prevents the voltage from becoming higher than the set constant voltage in order to prevent excessive power from being applied to the power bus, and is an input type power supply having a large constant voltage set value or both. The feature is that the higher the power supply, the higher the priority of putting power into the power bus.

Further, the invention according to claim 2 is such that in the power interchange system according to claim 1, the output type power source and the bidirectional power source when functioning as the output type power source do not take too much power from the power bus. Therefore, the output type power supply and the bidirectional power supply, which have a constant voltage control function to prevent the voltage from becoming lower than the set constant voltage and have a smaller constant voltage setting value, have a higher priority for taking power from the power bus. The feature is that it is set to.

Further, according to the third aspect of the present invention, in the power interchange system according to the first or second aspect, the bidirectional power source preferentially inputs power from any of a plurality of power input sources. However, when issuing an operation command to determine which of the multiple power output destinations the power is preferentially sent, it functions as an upper limited voltage and an output type power supply when functioning as an input type power supply. By providing a voltage difference with the lower limited voltage of the time and arranging them in order, the stable voltage of the power bus is determined by the balance between the input power and the output power, and the power interchange control is automatically performed. It is characterized by.

According to the present invention, the control order among a plurality of electric power devices is assigned, and the input / output control is performed from the one with the highest priority according to a certain set value, and the power shortage / surplus in the electric power bus is performed. As for, because the power equipment with low priority controls to reduce the excess and deficiency.
1) It is possible to easily determine the priority of power interchange simply by designating a one-dimensional data sequence for the input device and the output device connected to the power bus.
2) The bus voltage rises when the output power from the input device to the power bus increases, and the bus voltage drops when the input power from the power bus to the output device increases. It is possible to realize a power supply / reception relationship with the output device, and automatically generate a flow of power from the power surplus device to the power shortage device without external adjustment.
3) A function as a power buffer can be realized by setting a device having bidirectional charging / discharging such as a storage battery in an arbitrary priority order.
4) Since the function as the power source of each input / output device is the operation of the CV (Constant Voltage) value, no special function expansion is required.
5) When setting the input / output of power, it is not necessary to calculate the input / output to keep the internal power of the system constant.
The effect is obtained.

It is a circuit block diagram which shows an example of the Embodiment of this invention, and shows the schematic structure of the power interchange system. It is a figure which shows the setting condition of the system setting example in the power interchange system shown in FIG. It is a figure which shows the operating range of the setting condition of the system setting example in the power interchange system shown in FIG. It is a flow diagram for demonstrating the operation control in the input device of the input priority 1st place in the power interchange system shown in FIG. Similarly, it is a flow diagram for demonstrating the operation control in the output device of the output priority 3rd place in a power interchange system. Similarly, it is a flow diagram for demonstrating the operation control in the output device of the output priority 2nd place in a power interchange system. Similarly, it is a flow diagram for demonstrating the operation control in the input device of the input priority 2nd place in a power interchange system. Similarly, it is a flow diagram for demonstrating the operation control in the input device of the input priority 3rd place in a power interchange system. Similarly, it is a flow diagram for demonstrating the operation control in the output device which has the 1st output priority in a power interchange system. It is a circuit block diagram which shows another Embodiment of this invention and shows the schematic structure of the power interchange system.

Hereinafter, the present invention will be described in more detail according to the embodiments. FIG. 1 is a circuit block diagram showing a configuration of a power interchange system according to an embodiment of the present invention using a DC constant voltage power supply.

As shown in FIG. 1, this power interchange system includes a system power supply 1, an inverter 2, a solar panel 3, a solar inverter 4, a storage battery 5, a charger / discharger 6, an EV (electric vehicle) battery 7 and a charge. The discharger 8, the control system (control unit) 9, the inverter 2, the solar inverter 4, the power bus 10 connected to the chargers and dischargers 6, 8 respectively, and the control signal from the control system 9 are transmitted to the inverter 2, the solar inverter. It is composed of a communication line 11 for input to each of the 4 and the chargers and dischargers 6 and 8, respectively. The control system 9 is connected to the host control system (EMS) 22. Then, in this power interchange system, the system power supply 1, the solar panel 3, the storage battery 5, and the EV battery 7 exchange power with each other so as to transfer or receive power to each other.

In this power interchange system, there are a plurality of power input sources, the power is concentrated, and the power is distributed and supplied to a plurality of power output destinations. The above-mentioned circuit configuration itself in this system is not particularly different from the conventional circuit configuration, but in this power interchange system, the control between a plurality of power devices is prioritized, and the priority is fixed from the highest priority. Input / output control is performed according to the set value of. By performing such control, the power device having a low priority reduces the excess / deficiency of the power shortage / surplus in the power bus.

Specifically, as shown in FIG. 2, in this power interchange system, the input from the solar inverter 4 of the solar panel 3, which is an input type power supply having a constant voltage control function to the power bus 10, has a set voltage of 420 V. Below, the input from the inverter 2 of the system power supply 1 which is the input type power supply is the set voltage 390V or less, and the input (storage battery voltage) from the charger / discharger 6 of the storage battery 5 which is the input type power supply is the set voltage 380V or less. , Each is set so that the input to the power bus 10 operates. As shown in FIG. 3, in these input devices, the solar inverter 4 of the solar panel 3 has a voltage of 420 V or less of the power bus 10, the inverter 2 of the system power supply 1 has a voltage of 390 V or less of the power bus 10, and the storage battery 5. When the charger / discharger 6 has a voltage of 380 V or less of the power bus 10, each input to the power bus 10 is executed.

Further, when the voltage of the power bus 10 is larger than 370V for the EV battery 7 which is an output type power supply having a constant voltage control function from the power bus 10 to the power output destination, the power bus is supplied to the storage battery 5 which is an output type power supply. When the voltage of 10 is larger than 400V, the system power supply (regeneration) 1 which is an output type power supply is set so that the output from the power bus 10 operates when the voltage of the power bus 10 is larger than 410V. .. As shown in FIG. 3, these output devices have an output to the EV battery 7 exceeding 370V, an output to the storage battery 5 exceeding 400V, an output to the system power supply 1 exceeding 410V, and from the power bus 10. The output of each is executed.

Here, the system power supply 1 and the storage battery 5 are bidirectional power supplies having two functions of an input type power supply and an output type power supply, respectively, but for convenience, when they function as an input type power supply, they are input type. They are called power supplies, and when they function as output power supplies, they are called output power supplies.

Next, in the power interchange system having the above configuration, an example of a processing procedure for controlling device operation and device stop of each input / output device according to the voltage of the power bus 10 is shown in FIGS. 4 to 9. This will be described with reference to the figure. FIG. 4 is a flow related to an input operation from the solar panel 3 to the power bus 10, FIG. 5 is a flow related to an output operation from the power bus 10 to the grid power supply 1, and FIG. 6 is a storage battery from the power bus 10. FIG. 7 shows a flow related to an output operation to 5 (charging the storage battery 5), FIG. 7 shows a flow related to an input operation from the system power supply 1 to the power bus 10, and FIG. 8 shows an input from the storage battery 5 to the power bus 10 (storage battery). 5 Discharge) The flow related to the operation, FIG. 9 shows the flow related to the output (EV battery 7 charging) operation from the power bus 10 to the EV battery 7 (see FIG. 3).

When the control process by the control system 9 is started, in step ST1 in the flow chart shown in FIG. 4, the voltage Vb of the power bus 10 and the set voltage V1 = 420V are compared, and the voltage Vb of the power bus 10 is larger than the set voltage 420V. Determine if it is less than or equal to. When the voltage Vb of the power bus 10 is 420 V or less (Vb ≦ 420 V), the process proceeds to step ST2, and when the voltage Vb is larger than 420 V (Vb> 420 V), the process proceeds to step ST7.

In step ST2, it is determined whether the device is input / output. Here, since it is the start of the processing operation, the process proceeds to step ST3 based on the determination that the device is the solar panel 3 which is the input device. When it is determined that the device is not an input device, the process proceeds to step ST9 in the flow chart shown in FIG.

In step ST3, the operation of the solar panel 3 and the solar inverter 4 as input devices is selected, and the process proceeds to step ST4. In step ST4, it is determined whether or not the operating conditions such as voltage are satisfied. When the operating conditions are satisfied, the determination is YES and the process proceeds to step ST5. In step ST5, the solar panel 3 and the solar inverter 4 are operated, and 50 kW of electric power is input to the electric power bus 10. Then, the process proceeds to step ST9. On the other hand, when it is determined in step ST4 that the operating conditions are not satisfied, the determination NO shifts to step ST6, stops the apparatus, and proceeds to step ST9.

Further, in step ST7, it is determined whether the device is input / output. Here, since it is the start of the processing operation, the process proceeds to step ST8 based on the determination that the device is the solar panel 3 which is the input device, the device is stopped, and the process proceeds to step ST9. When it is determined that the device is not an input device, the process proceeds to step ST9. By the above processing operation, 50 kW of electric power is input from the solar panel 3 to the electric power bus 10 via the solar inverter 4 when the voltage Vb is 420 V or less.

Next, in step ST9, the voltage Vb of the power bus 10 is compared with the set voltage V2 = 410V, and it is determined whether the voltage Vb is greater than or less than the set voltage 410V. When the voltage Vb of the power bus 10 is larger than 410V (Vb> 410V), the process proceeds to step ST10, and when the voltage Vb is 410V or less (Vb ≦ 410V), the process proceeds to step ST15.

In step ST10, which of the input and output devices is, that is, the system power supply 1 is an input device that inputs power to the power bus 10, or receives power from the power bus 10, that is, an output as a regenerative device. Determine if it is a device. The device here is an output device that receives electric power from the electric power bus 10. Therefore, when it is determined in step ST10 that the device is an output device, the process proceeds to step ST11. When it is determined that the device is not an output device, the process proceeds to step ST17 in the flow chart shown in FIG.

In step ST11, the operation of the system power supply 1 and the inverter 2 which are output devices is selected. Subsequently, in step ST12, it is determined whether or not the operating conditions such as power failure, voltage, and electric power are satisfied. Here, since it is the first operation as an output device, the EV battery 7 which is preferentially operated is not charged and the storage battery 5 is not operated, and the operating conditions of the system power supply 1 are not satisfied. Move to ST13. Then, in step ST13, the output (regeneration) to the system power supply 1 is left stopped, and the process proceeds to step ST17.

Further, in step ST15, it is determined whether the device is input / output. Since the device here is an output device that receives power from the power bus 10, the process proceeds to step ST16, and the output (regeneration) to the system power supply 1 remains stopped and the device proceeds to step ST17. When it is determined that the device is not an output device, the process proceeds to step ST17.

Next, in step ST17, the voltage Vb of the power bus 10 is compared with the set voltage V3 = 400V, and it is determined whether the voltage Vb is greater than or less than the set voltage 400V. When the voltage Vb of the power bus 10 is larger than 400V (Vb> 400V), the process proceeds to step ST18, and when the voltage Vb is 400V or less (Vb ≦ 400V), the process proceeds to step ST23.

In step ST18, it is confirmed whether the device is input / output, that is, whether the storage battery 5 is an input device that inputs electric power to the electric power bus 10 or an output device that receives electric power from the electric power bus 10. , It is determined whether the storage battery 5 is an input device that discharges electric power to the electric power bus 10 or an output device that receives and charges electric power from the electric power bus 10. The device here is an output device that receives electric power from the electric power bus 10. Therefore, when the device is determined to be the output device in step ST18, the process proceeds to step ST19. When it is determined that the device is not an output device, the process proceeds to step ST25 in the flow chart shown in FIG. 7.

In step ST19, the operation of the storage battery 5 and the charger / discharger 6 which are output devices is selected. Subsequently, in step ST20, it is determined whether or not the operating conditions, such as the storage battery capacity, SOC, and device error, are satisfied. Here, since the EV battery 7, which is the first operation as an output device and is preferentially operated, is not being charged and does not satisfy the operating conditions of the storage battery 5, the process proceeds to step ST21 according to the determination NO. Then, in step ST21, the output to the storage battery 5 is left stopped, and the process proceeds to step ST25.

Further, in step ST23, it is determined whether the device is input / output. Since the device here is an output device that receives electric power from the power bus 10, the process proceeds to step ST24, and the output to the storage battery 5 remains stopped and the device proceeds to step ST25. When it is determined that the device is not an output device, the process proceeds to step ST25.

Next, in step ST25, the voltage Vb of the power bus 10 is compared with the set voltage V4 = 390V, and it is determined whether the voltage Vb is greater than or less than the set voltage 390V. When the voltage Vb of the power bus 10 is 390 V or less (Vb ≦ 390 V), the process proceeds to step ST26, and when the voltage Vb is larger than 390 V (Vb> 390 V), the process proceeds to step ST31.

In step ST26, it is determined whether the device (system power supply 1) is an input device or an output device. Here, the process proceeds to step ST27 based on the determination that the device is an input device. When it is determined that the device is not an input device, the process proceeds to step ST33 in the flow chart shown in FIG.

In step ST27, the operation of the system power supply 1 and the inverter 2 which are the input devices is selected, and the process proceeds to step ST28. In step ST28, it is determined whether or not the operating conditions such as power failure, voltage, and electric power are satisfied. When it is determined that the operating conditions are satisfied, the determination is YES and the process proceeds to step ST29. In step ST29, the system power supply 1 and the inverter 2 are operated, and 20 kW of electric power is input to the electric power bus 10. Then, the process proceeds to step ST33. On the other hand, when it is determined in step ST28 that the operating conditions are not satisfied, the process proceeds to step ST30 according to the determination NO, the apparatus is stopped, and the process proceeds to step ST33.

Further, in step ST31, it is determined whether the device is input / output. Here, based on the determination that the device is the system power supply 1 which is the input device, the process proceeds to step ST32, the device is stopped, and the process proceeds to step ST33. When it is determined that the device is not an input device, the process proceeds to step ST33. By the above processing operation, 20 kW of electric power is input from the system power supply 1 to the power bus 10 via the inverter 2 when the voltage Vb is 390 V or less.

Next, in step ST33, the voltage Vb of the power bus 10 is compared with the set voltage V5 = 380V, and it is determined whether the voltage Vb is greater than or less than the set voltage 380V. When the voltage Vb of the power bus 10 is 380 V or less (Vb ≦ 380 V), the process proceeds to step ST34, and when the voltage Vb is larger than the set voltage 380 V (Vb> 380 V), the process proceeds to step ST39.

In step ST34, it is determined whether the device (storage battery 5) is input / output. Here, the input is from the storage battery 5 to the power bus 10, and therefore, the process proceeds to step ST35 based on the determination that the device is an input device. When it is determined that the device is not an input device, the process proceeds to step ST41 in the flow chart shown in FIG.

In step ST35, the operation of the storage battery 5 and the charger / discharger 6 as input devices is selected, and the process proceeds to step ST36. In step ST36, it is determined whether or not the operating conditions, such as the storage battery capacity, SOC, and device error, are satisfied. When it is determined that the operating conditions are satisfied, the determination is YES and the process proceeds to step ST37. In step ST37, the storage battery 5 and the charger / discharger 6 are operated, and 20 kW of electric power is discharged and input to the electric power bus 10. Then, the process proceeds to step ST41. On the other hand, when it is determined in step ST36 that the operating conditions are not satisfied, the determination NO shifts to step ST38, stops the operation of the apparatus, and proceeds to step ST41.

Further, in step ST39, it is determined whether the device is input / output. Here, based on the determination that the device is the storage battery 5 which is the input device, the process proceeds to step ST40, the device is stopped, and the process proceeds to step ST41. When it is determined that the device is not an input device, the process proceeds to step ST41. By the above processing operation, 20 kW of electric power is input from the storage battery 5 to the electric power bus 10 via the charger / discharger 6 when the voltage Vb is 380 V or less.

Next, in step ST41, the voltage Vb of the power bus 10 is compared with the set voltage V6 = 370V, and it is determined whether the voltage Vb is greater than or less than the set voltage 370V. When the voltage Vb of the power bus 10 is larger than 370V (Vb> 370V), the process proceeds to step ST42, and when the voltage Vb is 370V or less (Vb ≦ 370V), the process proceeds to step ST47.

In step ST42, it is determined whether the device is input / output, that is, whether the EV battery 7 is an input device that inputs power to the power bus 10 or an output device that receives power from the power bus 10. After checking, it is determined whether the EV battery 7 is an input device that discharges power to the power bus 10 or an output device that receives and charges the power from the power bus 10. Here, when it is determined that the device is an output device to which power is supplied from the power bus 10, the process proceeds to step ST43. When it is determined that the device is not an output device, the processing operation is terminated.

In step ST43, the operation of the EV battery 7 and the charger / discharger 8 which are the output devices is selected, and the process proceeds to step ST44. In step ST44, it is determined whether or not the operating conditions such as the storage battery capacity, SOC, EV error, etc. are satisfied. When it is determined that the operating conditions are satisfied, the determination is YES and the process proceeds to step ST45. In step ST45, the EV battery 7 and the charger / discharger 8 are operated, and 10 kW of electric power is charged and output to the EV battery 7 from the power bus 10. Then, the processing operation is terminated. On the other hand, when it is determined in step ST44 that the operating conditions are not satisfied, the determination NO proceeds to step ST46, the apparatus is stopped, and the processing operation is terminated.

Further, in step ST47, it is determined whether the device is input / output. Since the device here is an output device that receives power from the power bus 10, the process proceeds to step ST48, the EV battery 7 is left stopped, and the processing operation is terminated. The processing operation is also terminated when it is determined that the device is not an output device.

By the above processing operation, the input from the solar panel 3 to the power bus 10 via the solar inverter 4, the input from the system power supply 1 to the power bus 10 via the inverter 2, and the power from the storage battery 5 to the charger / discharger 6 By the input to the bus 10, the charging of the EV battery 7 from the power bus 10 through the charger / discharger 8 is completed.

Subsequently, when the control process by the control system 9 is restarted, in step ST17 in the flow chart shown in FIG. 6, the voltage Vb of the power bus 10 and the set voltage V3 = 400V are compared, and the voltage Vb is higher than the set voltage 400V. Determine if it is greater or less than that. Here, the process proceeds to step ST18 based on the determination that the voltage Vb of the power bus 10 is larger than 400V (Vb> 400V).

In step ST18, it is determined whether the device (storage battery 5) is an input / output device, and the process proceeds to step ST19 based on the determination that the device is an output device. Then, the device operation is selected in step ST19, and the process proceeds to step ST20. In step ST20, it is determined whether or not the operating conditions are satisfied, but as the operating conditions, since the EV battery 7 having the priority 1 is already operating, the operating conditions related to the storage battery 5 having the priority 2 are set. Is pleased. Therefore, if the determination YES regarding the operating conditions is made, the process proceeds to step ST22. In step ST22, the storage battery 5 and the charger / discharger 6 are operated to charge and output 50 kW of electric power from the power bus 10 to the storage battery 5. As a result, charging of the storage battery 5 is completed.

Further, when the control process by the control system 9 is restarted again, in step ST9 in the flow chart shown in FIG. 5, the voltage Vb of the power bus 10 and the set voltage V2 = 410V are compared, and the voltage Vb is the set voltage 410V. Determine if it is greater than or less than that. Here, the process proceeds to step ST10 based on the determination that the voltage Vb of the power bus 10 is larger than 410V (Vb> 410V).

In step ST10, it is determined whether the device (system power supply 1) is input / output, and the process proceeds to step ST11 based on the determination that the device is an output device. Then, the device operation is selected in step ST11, and the process proceeds to step ST12. In step ST12, it is determined whether or not the operating condition is satisfied, but as the operating condition, the EV battery 7 of priority 1 and the storage battery 5 of priority 2 are already in operation, so that the operating condition is priority 3. The operating conditions related to the grid power supply 1 are satisfied. Therefore, if the determination YES regarding the operating conditions is made, the process proceeds to step ST14. In step ST14, the system power supply 1 and the inverter 2 are operated, and the power of 20 kW from the power bus 10 is regeneratively output to the system power supply 1. As a result, the regenerative output to the system power supply 1 is completed.

Needless to say, the above embodiment is an example, and the scope of the present invention is not limited to the contents of the above-described embodiment.

That is, in the above-described embodiment, the system power supply 1, the solar panel 3, and the storage battery 5 are used as input sources, and the storage battery 5, the EV battery 7, and the system power supply (regeneration) 1 are used as output sources (among these, the system power supply 1, the solar panel 3 and the storage battery 5 are used as output sources. The grid power supply 1 and the storage battery 5 are bidirectional power supplies that can be both input sources and output sources), and a simple power interchange system with a relatively small number of power supplies has been described as an example. And the inverter 2, the solar panel 3 and the solar inverter 4, the storage battery 5 and the charger / discharger 6, and the EV battery 7 and the charger / discharger 8, as well as the EV battery 12 and the charger / discharger 13, the fuel cell 14 and the electric power. It can be a power grid system including a converter 15, a wind generator 16, a power converter 17, a generator 18, a power converter 19, and a load 20 and a power converter 21. The load 20 referred to here is, for example, household electric appliances such as refrigerators, washing machines, and televisions, and production machinery and equipment.

Such an electric power interchange system has the EV battery 12 and the charger / discharger 13, the fuel cell 14 and the electric power converter 15, the wind power generator 16 and the electric power converter, which are bidirectional power sources, with respect to the electric power interchange system shown in FIG. It requires many components in that it includes a device 17, a generator 18, a power converter 19, and various loads 20 and a power converter 21, but the EV battery 12 is used as an input / output source by that amount. The fuel cell 14, the wind generator 16 and the generator 18 can be used as an input source, and the load 20 can be used as an output source. Compared with the power interchange system shown in FIG. 1, power interchange via the power bus 10. There is an advantage that the input source / output source can be performed with a margin.

1 System power supply 2 Inverter 3 Solar panel 4 Solar inverter 5 Storage battery 6, 8, 13 Charger / discharger 7, 12 EV battery 9 Control system 10 Power bus 11 Communication line 14 Fuel battery 15, 17, 19, 21 Power converter 16 Wind generator 18 Generator 20 Load

Claims (1)

Power bus and
An input-type power supply that supplies power from a power input source to the power bus, detects the voltage of the power bus, and controls the input.
An output type power supply that supplies power from the power bus to the battery for an electric vehicle , detects the voltage of the power bus, and controls the output.
A bidirectional power supply having two functions of the input type power supply and the output type power supply,
An electric power control means for instructing the input type power source, the output type power source, and the bidirectional power source to input / output power to the power bus, and
In a power interchange system equipped with
The input type power supply and the bidirectional power supply when functioning as the input type power supply are provided with a constant voltage control function for preventing the voltage from becoming higher than the set constant voltage in order to prevent excessive power from being applied to the power bus. In addition, the input type power supply or bidirectional power supply with a larger constant voltage setting value is set so that the priority for inputting power to the power bus is higher .
The output type power supply and the bidirectional power supply when functioning as the output type power supply have a constant voltage control function for preventing the voltage from becoming lower than the set constant voltage in order not to take too much power from the power bus. , Output type power supply and bidirectional power supply with smaller constant voltage setting value are set so that the priority of taking power from the power bus is higher.
The set value of the constant voltage of the output type power supply is the set value of the constant voltage of the input type power supply, the set value of the constant voltage of the input type power supply, and the set value of the constant voltage of the input set voltage of the bidirectional power supply. A power interchange system characterized by being lower than any of them.

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