JP2018182905A - Power supply system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a power supply system capable of reducing an energy loss in power supply.SOLUTION: A power supply system 10 comprises: a power conditioner 100 to which DC voltage is supplied from a photovoltaic power generation system 1; and a first electrical apparatus 200 to which DC output voltage is supplied from the power conditioner 100. The first electrical apparatus 200 comprises a communication unit for transmitting voltage value information, information on a voltage value of DC input voltage required by the first electrical apparatus 200, to the power conditioner 100. The power conditioner 100 comprises: a first converter 109 for converting the DC voltage to DC reference voltage; a fifth converter 113 for converting the DC reference voltage to the DC output voltage; a communication unit 125 for receiving the voltage value information from the first electrical apparatus 200; and a control unit 124 that on the basis of the voltage value information, controls the fifth converter 113 to control a voltage value of the DC output voltage.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a power feeding system that includes a power conditioner and supplies DC power to an electric device by the power conditioner.

  In recent years, AC power for which voltage conversion is easy is the mainstream of transmitted power and supplied power, but since many electric devices use DC power internally, AC power supplied internally is used in the electric devices. Power conversion to DC power. In such power conversion, energy loss occurs.

  The generated power of natural renewable energy of solar power generation and wind power generation is direct current power, and charge and discharge power to storage batteries and electric vehicles is also direct current power. For this reason, the advantage of unifying from generation power to power consumption consistently with DC power is great.

  In the technology described in Patent Document 1, a DC voltage of 48 V is supplied from a control panel connected to a DC power generation unit such as a solar cell array, and a voltage conversion unit is provided in a feed path from the control panel to the load. A plurality of DC voltages of different voltages such as 5 V, 9 V and 12 V are supplied to the corresponding electric devices.

JP, 2010-288387, A

  However, in the technology described in Patent Document 1, it is not assumed that the voltage value of the DC voltage supplied to the electric device can be flexibly changed and supplied according to the electric device supplying the DC voltage. Therefore, when the electrical device to which the DC voltage is supplied is changed to another electrical device requiring a DC voltage of a voltage value different from that of the electrical device, it is necessary to perform voltage conversion inside the other electrical device. there were. Energy loss occurs even with such voltage conversion.

  This invention is made in view of the above, Comprising: It aims at obtaining the electric power feeding system which can reduce the energy loss in electric power supply.

  In order to solve the problems described above and to achieve the object, the feed system according to the present invention includes a power conditioner to which a first DC voltage is supplied from a first DC power supply. The feed system includes a first electrical device to which a first DC output voltage is supplied from a power conditioner. The first electrical device includes a communication unit that transmits, to the power conditioner, first voltage value information that is information on a voltage value of a first DC input voltage required by the first electrical device. The power conditioner includes a first converter unit that converts a first DC voltage to a DC reference voltage. The power conditioner includes a second converter unit that converts a DC reference voltage into a first DC output voltage. The power conditioner includes a communication unit that receives the first voltage value information from the first electric device. The power conditioner includes a control unit that controls the second converter unit based on the first voltage value information to control the voltage value of the first DC output voltage.

  According to the present invention, it is possible to reduce energy loss in power supply.

A configuration diagram showing an example of a power feeding system according to a first embodiment of the present invention The block diagram which shows an example of the 1st electric equipment in FIG. 1 The figure for demonstrating the operation | movement at the time of heating of the said outdoor unit in case the compressor in FIG. 2 is an outdoor unit of an air conditioner. The figure for demonstrating the operation | movement at the time of cooling of the said outdoor unit in case the compressor in FIG. 2 is an outdoor unit of an air conditioner. The block diagram which shows an example of the 2nd electric equipment in FIG. 1 The block diagram which shows an example of the 3rd electric equipment in FIG. 1 Sequence diagram of the power supply process performed by the power supply system of FIG. 1 The block diagram which shows an example of the electric power feeding system concerning Embodiment 2 of this invention. The block diagram which shows an example of the electric power feeding system concerning Embodiment 3 of this invention. The block diagram which shows an example of the 1st electric equipment in FIG. The block diagram which shows an example of the 2nd electric equipment in FIG. 9 The block diagram which shows an example of the electric power feeding system concerning Embodiment 4 of this invention. The block diagram which shows an example of the electric power feeding system concerning Embodiment 4 of this invention. The block diagram which shows an example of the 1st electric equipment in FIG. The block diagram which shows an example of the 2nd electric equipment in FIG. The block diagram which shows an example of the 3rd electric equipment in FIG. Sequence diagram of power supply processing at the time of a power failure of the commercial system executed by the power supply system of FIG. The figure which shows that the control part in the electric power feeding system of Embodiment 1 to Embodiment 4 is a processing circuit. The figure which shows that the control part in the electric power feeding system of Embodiment 1 to Embodiment 4 is a processor.

  Hereinafter, a power supply system according to an embodiment of the present invention will be described in detail based on the drawings. The present invention is not limited by the embodiment.

Embodiment 1
First, a power supply system according to a first embodiment of the present invention will be described. FIG. 1 is a block diagram showing an example of a power supply system according to a first embodiment of the present invention.

  The power supply system 10 illustrated in FIG. 1 includes a power conditioner 100, a first electric device 200, a second electric device 300, and a third electric device 400. The power conditioner 100 and the first electric device 200 are connected via the connection terminal 101 of the power conditioner 100 and the connection terminal 201 of the first electric device 200. DC power is supplied to the first electric device 200 from the power conditioner 100. The power conditioner 100 and the second electric device 300 are connected via the connection terminal 102 of the power conditioner 100 and the connection terminal 301 of the second electric device 300. DC power is supplied from the power conditioner 100 to the second electric device 300. The power conditioner 100 and the third electric device 400 are connected via the connection terminal 103 of the power conditioner 100 and the connection terminal 401 of the third electric device 400. DC power is supplied from the power conditioner 100 to the third electric device 400.

  Power conditioner 100 and solar power generation system 1 are connected via connection terminal 104 of power conditioner 100. The power conditioner 100 is supplied with DC power which is generated power from the photovoltaic power generation system 1. The solar power generation system 1 is an example of a first DC power supply. The power conditioner 100 and the wind power generation system 2 are connected via the connection terminal 105 of the power conditioner 100. The power conditioner 100 is supplied with DC power which is generated power from the wind power generation system 2. The wind power generation system 2 is an example of a first DC power supply. Power conditioner 100 and storage battery 3 are connected via connection terminal 106 of power conditioner 100. The power conditioner 100 is supplied with DC power, which is discharge power, from the storage battery 3, and the power conditioner 100 supplies DC power, which is charging power, to the storage battery 3. Storage battery 3 is an example of a second DC power supply. Power conditioner 100 and electric vehicle 4 are connected via connection terminal 107 of power conditioner 100. The power conditioner 100 is supplied with DC power, which is discharge power, from the electric vehicle 4, and the power conditioner 100 supplies DC power, which is charging power, to the electric vehicle 4. The electric vehicle 4 is an example of a second DC power supply. Power conditioner 100 and commercial system 5 are connected via connection terminal 108 of power conditioner 100. AC power is supplied to the power conditioner 100 from the commercial power system 5, and the power conditioner 100 supplies AC power, which is reverse flow power, to the commercial power system 5.

  The power conditioner 100 converts a DC voltage supplied from the solar power generation system 1 into a DC reference voltage, and a second converter 109 converts the DC voltage supplied from the wind power generation system 2 into a DC reference voltage. And the converter 110 of FIG. The power conditioner 100 bi-directionally converts the DC voltage supplied from the storage battery 3 and the DC reference voltage bidirectionally, the DC voltage supplied from the electric vehicle 4 and the DC reference voltage. And a fourth converter 112 for converting. The direct current voltage supplied from the solar power generation system 1 and the direct current voltage supplied from the wind power generation system 2 are examples of a first direct current voltage. The first converter 109 and the second converter 110 are an example of a first converter unit. The direct current voltage supplied from the storage battery 3 and the direct current voltage supplied from the electric vehicle 4 are examples of a second direct current voltage. The third converter 111 and the fourth converter 112 are an example of a third converter unit. The power conditioner 100 converts a DC reference voltage into a fifth converter 113 that converts the DC reference voltage into a DC output voltage output from the connection terminal 101, and a sixth converter 114 converts the DC reference voltage into a DC output voltage output from the connection terminal 102. And a seventh converter 115 for converting a DC reference voltage into a DC output voltage output from the connection terminal 103. The fifth converter 113 is an example of a second converter unit. The sixth converter 114 is an example of a fourth converter unit. The seventh converter 115 is an example of a fifth converter unit. Power conditioner 100 includes an inverter 116 which bi-directionally converts an AC voltage and a DC reference voltage supplied from commercial system 5. The inverter 116 is an example of an inverter unit.

  Power conditioner 100 includes a switch 117 that opens and closes an electric path between fifth converter 113 and connection terminal 101, and a switch 118 that opens and closes an electric path between sixth converter 114 and connection terminal 102; A switch 119 opens and closes an electric path between the seventh converter 115 and the connection terminal 103, and a switch 120 opens and closes an electric path between the connection terminal 108 and the inverter 116. The switch 117 is an example of a second switch. The switch 118 is an example of a third switch. The switch 119 is an example of a fourth switch. The switch 119 is an example of a first switch. Power conditioner 100 includes a connection portion 121 of first converter 109, second converter 110, and inverter 116, a third converter 111, a fourth converter 112, a fifth converter 113, a sixth converter 114, and the like. A diode 123 is provided between the seventh converter 115 and the connection portion 122. The anode side of the diode 123 is connected to the connection portion 121, and the cathode side of the diode 123 is connected to the connection portion 122.

  The power conditioner 100 includes a control unit 124 and a communication unit 125. The control unit 124 and the communication unit 125 are connected. The control unit 124 includes a first converter 109, a second converter 110, a third converter 111, a fourth converter 112, a fifth converter 113, a sixth converter 114, a seventh converter 115, and an inverter 116. Control each one. Control unit 124 controls switches 117, 118, 119 and 120, respectively. The communication unit 125 can mutually communicate with the first electric device 200, the second electric device 300, and the third electric device 400, respectively.

  In the present embodiment, the communication unit 125 receives, from the first electric device 200, voltage value information of a DC input voltage required by the first electric device 200 described later. The communication unit 125 receives, from the second electric device 300, voltage value information of a DC input voltage required by the second electric device 300 described later. The communication unit 125 receives, from the third electric device 400, voltage value information of a DC input voltage required by the third electric device 400 described later.

  In the present embodiment, control unit 124 controls fifth converter 113 based on the voltage value information of the DC input voltage required by first electric device 200 received by communication unit 125. The control unit 124 controls the sixth converter 114 based on the voltage value information of the DC input voltage required by the second electric device 300 received by the communication unit 125. The control unit 124 controls the seventh converter 115 based on the voltage value information of the DC input voltage required by the third electric device 400 received by the communication unit 125.

  Next, the first electric device in FIG. 1 will be described. FIG. 2: is a block diagram which shows an example of the 1st electric equipment in FIG.

  The first electric device 200 shown in FIG. 2 includes a converter 202, a drive unit 203, a compressor 204, a power supply circuit unit 207, a control unit 208, a communication unit 209, and a backup power supply 210.

  The first electric device 200 is connected to the power conditioner 100 via the connection terminal 201. The first electric device 200 is supplied with DC power from the power conditioner 100 via the connection terminal 201. Converter 202 converts a DC input voltage input from connection terminal 201, that is, a DC output voltage supplied from connection terminal 101 of power conditioner 100, into a DC drive voltage required by drive unit 203. The drive unit 203 is supplied with the DC drive voltage converted by the converter 202. The drive unit 203 operates the compressor 204. The compressor 204 includes a direct current motor 205 and a heat exchanger 206.

  The power supply circuit unit 207 converts the DC input voltage input from the connection terminal 201, that is, the DC output voltage supplied from the connection terminal 101 of the power conditioner 100 into a DC control voltage required by the control unit 208. The control unit 208 is supplied with the DC control voltage converted by the power supply circuit unit 207. Control unit 208 controls converter 202 and drive unit 203, respectively. The control unit 208 and the communication unit 209 are connected. The communication unit 209 can mutually communicate with the power conditioner 100. The control unit 208 transmits voltage value information, which is information on the voltage value of the DC input voltage required by the first electric device 200, to the power conditioner 100 via the communication unit 209. The backup power supply 210 supplies a DC control voltage to the control unit 208 when the supply of DC power from the power conditioner 100 to the first electric device 200 is stopped.

  In the present embodiment, the voltage value of the DC drive voltage required by the drive unit 203 is a voltage value between 300V and 400V. The control unit 208 transmits voltage value information indicating that the voltage value of the DC input voltage required by the first electric device 200 is 300 V to the power conditioner 100 via the communication unit 209. The voltage value information indicating that the voltage is 300 V is an example of first voltage value information. The power conditioner 100 receiving the voltage value information controls the fifth converter 113 to output a DC output voltage having a voltage value of 300 V from the connection terminal 101. When the voltage value of the DC drive voltage required by drive unit 203 exceeds 300 V, converter 202 requires a DC input voltage required by drive unit 203 for the DC input voltage of 300 V input from connection terminal 201. Step-up to a DC drive voltage having a voltage value exceeding 300 V. The drive unit 203 is supplied with a direct-current drive voltage of 300 V or a direct-current drive voltage having a voltage value higher than 300 V boosted by the converter 202.

  In the present embodiment, the voltage value of the DC control voltage required by the control unit 208 is a voltage value of 12V. The power supply circuit unit 207 steps down a direct current input voltage of 300 V input from the connection terminal 201 to a direct current control voltage of 12 V which is a direct current control voltage required by the control unit 208. The control unit 208 is supplied with a 12V DC control voltage stepped down by the power supply circuit unit 207.

  Next, the operation of the outdoor unit when the compressor 204 in FIG. 2 is an outdoor unit of an air conditioner will be described. FIG. 3 is a diagram for explaining the heating operation of the outdoor unit when the compressor 204 in FIG. 2 is the outdoor unit of the air conditioner. FIG. 4 is a diagram for explaining the cooling operation of the outdoor unit when the compressor 204 in FIG. 2 is the outdoor unit of the air conditioner. The heat exchanger 206 has a medium for heat exchange circulating inside the heat exchanger 206. Inside the heat exchanger 206 there are warm and cool media.

  As shown in FIG. 3, at the time of heating, heat exchange is performed between the outdoor air and the heat exchanger 206, and the medium absorbs the heat of the outdoor air, and the temperature changes from -10 ° C to 0 ° C. Become. Next, the DC motor 205 operates to boost the pressure of the medium by the compressor 211, and the temperature of the medium becomes 0 ° C to 60 ° C. Next, heat exchange is performed between the room air and the heat exchanger 206, and the room air absorbs the heat of the medium to warm the room, and the medium heats the room air to cause the temperature to increase. 60 ° C to 20 ° C. Then, the pressure of the medium is reduced by the expansion valve 212, and the temperature of the medium becomes 20 ° C to -10 ° C. Next, heat exchange is performed between the outdoor air and the heat exchanger 206, and the medium absorbs the heat of the outdoor air so that the temperature becomes -10 ° C to 0 ° C. The room is warmed by repeating such an operation.

  As shown in FIG. 4, at the time of cooling, heat exchange is performed between the outdoor air and the heat exchanger 206, and the medium heats the outdoor air so that the temperature becomes 60 ° C. to 20 ° C. Then, the pressure of the medium is reduced by the expansion valve 212, and the temperature of the medium becomes 20 ° C to -10 ° C. Next, heat is exchanged between the room air and the heat exchanger 206, and the room air gives heat to the medium to cool the room, and the medium absorbs the heat of the room air to make the temperature It goes from -10 ° C to 0 ° C. Next, the DC motor 205 operates to boost the pressure of the medium by the compressor 211, and the temperature of the medium becomes 0 ° C to 60 ° C. Next, heat exchange is performed between the outdoor air and the heat exchanger 206, and the medium heats the outdoor air to a temperature of 60 ° C. to 20 ° C. By repeating such an operation, the room is cooled.

  Next, the second electric device in FIG. 1 will be described. FIG. 5 is a block diagram showing an example of the second electric device in FIG.

  The second electric device 300 shown in FIG. 5 includes a drive unit 302, a compressor 303, a power supply circuit unit 306, a control unit 307, a communication unit 308, and a backup power supply 309.

  The second electric device 300 is connected to the power conditioner 100 via the connection terminal 301. The second electric device 300 is supplied with DC power from the power conditioner 100 via the connection terminal 301. The drive unit 302 is supplied with a DC input voltage input from the connection terminal 301, that is, a DC output voltage supplied from the connection terminal 102 of the power conditioner 100. The drive unit 302 operates the compressor 303. The compressor 303 includes a direct current motor 304 and a heat exchanger 305.

  The power supply circuit unit 306 converts a direct current input voltage input from the connection terminal 301, that is, a direct current output voltage supplied from the connection terminal 102 of the power conditioner 100 into a direct current control voltage required by the control unit 307. The control unit 307 is supplied with the DC control voltage converted by the power supply circuit unit 306. The control unit 307 controls the drive unit 302. The control unit 307 and the communication unit 308 are connected. Communication unit 308 can mutually communicate with power conditioner 100. The control unit 307 transmits voltage value information, which is information on the voltage value of the DC input voltage required by the second electric device 300, to the power conditioner 100 via the communication unit 308. The backup power supply 309 supplies a DC control voltage to the control unit 307 when the supply of DC power from the power conditioner 100 to the second electric device 300 is stopped.

  In the present embodiment, the voltage value of the DC drive voltage required by the drive unit 302 is a voltage value of 150V. The control unit 307 transmits voltage value information to the effect that the voltage value of the DC input voltage required by the second electric device 300 is 150 V to the power conditioner 100 via the communication unit 308. The voltage value information to the effect that the voltage is 150 V is an example of the second voltage value information. The power conditioner 100 receiving the voltage value information controls the sixth converter 114 to output a DC output voltage having a voltage value of 150 V from the connection terminal 102. The DC input voltage input from the connection terminal 301, that is, the voltage value of the DC output voltage supplied from the connection terminal 102 of the power conditioner 100 is 150 V, which is the same as the voltage value of the DC drive voltage required by the drive unit 302. Therefore, a direct current input voltage of a voltage value of 150 V is supplied to the drive unit 302 without voltage conversion.

  In the present embodiment, the voltage value of the DC control voltage required by the control unit 307 is a voltage value of 12V. The power supply circuit unit 306 steps down a DC input voltage having a voltage value of 150 V input from the connection terminal 301 to a DC control voltage of 12 V, which is a DC control voltage required by the control unit 307. The control unit 307 is supplied with a 12V DC control voltage stepped down by the power supply circuit unit 306.

  Next, the third electric device in FIG. 1 will be described. FIG. 6 is a block diagram showing an example of the third electric device in FIG.

  The third electric device 400 shown in FIG. 6 includes a converter 402, a drive unit 403, an operation unit 404, a regulator 405, a control unit 406, a communication unit 407, and a backup power supply 408.

  The third electric device 400 is connected to the power conditioner 100 via the connection terminal 401. The third electric device 400 is supplied with DC power from the power conditioner 100 via the connection terminal 401. Converter 402 converts a DC input voltage input from connection terminal 401, that is, a DC output voltage supplied from connection terminal 103 of power conditioner 100, into a DC drive voltage required by drive unit 403. The drive unit 403 is supplied with the DC drive voltage converted by the converter 402. The drive unit 403 operates the operation unit 404.

  The regulator 405 converts the DC input voltage input from the connection terminal 401, that is, the DC output voltage supplied from the connection terminal 103 of the power conditioner 100 into a DC control voltage required by the control unit 406. The control unit 406 is supplied with the DC control voltage converted by the regulator 405. Control unit 406 controls converter 402 and drive unit 403, respectively. The control unit 406 and the communication unit 407 are connected. The communication unit 407 can communicate with the power conditioner 100. The control unit 406 transmits voltage value information, which is information on the voltage value of the DC input voltage required by the third electric device 400, to the power conditioner 100 via the communication unit 407. The backup power supply 408 supplies a DC control voltage to the control unit 406 when the supply of DC power from the power conditioner 100 to the third electric device 400 is stopped.

  In the present embodiment, the third electric device 400 is, for example, an LED (Light Emitting Diode) lighting device, an information device such as a notebook computer and a small liquid crystal television, and other home appliances. For example, when the third electric device 400 is a small liquid crystal television, the operating unit 404 is a backlight for obtaining the brightness of the liquid crystal television, and the driving unit 403 is an inverter for lighting the backlight. Since the third electric device 400 is a home appliance, the control unit 406 instructs the power conditioner 100 via the communication unit 407 that the voltage value of the DC input voltage required by the third electric device 400 is 50 V. Send voltage value information. The voltage value information indicating that the voltage is 50 V is an example of third voltage value information. The power conditioner 100 receiving the voltage value information controls the seventh converter 115 to output a DC output voltage having a voltage value of 50 V from the connection terminal 103. Converter 402 converts a direct current input voltage having a voltage value of 50 V input from connection terminal 401 into a direct current drive voltage required by drive unit 403. The drive unit 403 is supplied with a DC drive voltage that has been voltage-converted by the converter 402.

  In the present embodiment, the voltage value of the DC control voltage required by control unit 406 is a voltage value of 12V. The regulator 405 steps down the DC input voltage having a voltage value of 50 V input from the connection terminal 401 to a DC control voltage of a voltage value of 12 V, which is a DC control voltage required by the control unit 406. In this embodiment, since the difference between the voltage value of the DC input voltage and the voltage value of the DC control voltage is smaller compared to the first electric device 200 and the second electric device 300, an inexpensive voltage such as the regulator 405 is used. It is possible to use a converter. The control unit 406 is supplied with a 12V DC control voltage stepped down by the regulator 405.

  Next, the power supply process performed by the power supply system of FIG. 1 will be described. FIG. 7 is a sequence diagram of power feeding processing performed by the power feeding system of FIG.

  In step S101, the control unit 208 of the first electric device 200 causes the power conditioner 100 via the communication unit 209 to have a voltage value indicating that the voltage value of the DC input voltage required by the first electric device 200 is 300 V. Send information The voltage value information to the effect that the voltage is 300 V is an example of the first voltage value information.

  Next, the control unit 124 of the power conditioner 100 controls the fifth converter 113 based on the voltage value information transmitted in step S101 received by the communication unit 125 of the power conditioner 100 (step S102). Specifically, control unit 124 controls fifth converter 113 such that fifth converter 113 converts the DC reference voltage into a DC output voltage of 300 V.

  Next, the power conditioner 100 supplies a DC output voltage of 300 V from the connection terminal 101 to the first electric device 200 (step S103). A DC output voltage of 300 V is an example of a first DC output voltage.

  In step S104, the control unit 307 of the second electrical device 300 causes the power conditioner 100 to communicate via the communication unit 308 a voltage value indicating that the voltage value of the DC input voltage required by the second electrical device 300 is 150 V. Send information

  Next, the control unit 124 of the power conditioner 100 controls the sixth converter 114 based on the voltage value information transmitted in step S104 received by the communication unit 125 of the power conditioner 100 (step S105). Specifically, control unit 124 controls sixth converter 114 such that sixth converter 114 converts the DC reference voltage into a DC output voltage of 150V.

  Next, the power conditioner 100 supplies a DC output voltage of 150 V to the second electric device 300 from the connection terminal 102 (step S106). The DC output voltage of 150 V is an example of a second DC output voltage.

  In step S107, the control unit 406 of the third electric device 400 causes the power conditioner 100 via the communication unit 407 to have a voltage value indicating that the voltage value of the DC input voltage required by the third electric device 400 is 50 V. Send information

  Next, the control unit 124 of the power conditioner 100 controls the seventh converter 115 based on the voltage value information transmitted in step S107 received by the communication unit 125 of the power conditioner 100 (step S108). Specifically, the control unit 124 controls the seventh converter 115 such that the seventh converter 115 converts the DC reference voltage into a 50 V DC output voltage.

  Next, the power conditioner 100 supplies a DC output voltage of 50 V to the third electric device 400 from the connection terminal 103 (step S109). The 50 V DC output voltage is an example of a third DC output voltage.

  According to the power feeding process shown in FIG. 7, the DC drive voltage required by the drive unit 203 of the first electric device 200, the drive portion 302 of the second electric device 300, and the drive portion 403 of the third electric device 400 The DC output voltage of the same value as the voltage value of the first electric device 200 or the same as the voltage value of the DC input voltage required by the first electric device 200, the second electric device 300, and the third electric device 400 is Conditioner 100 supplies the first electric device 200, the second electric device 300, and the third electric device 400, respectively. The energy loss at the time of voltage conversion increases as the number of voltage conversion increases, and also increases as the value of the current flowing in the electric path of the voltage converter increases. In the first electric device 200, the second electric device 300, and the third electric device 400, the number of times of voltage conversion is less than or equal to one, and it is further compared to the case where the main DC voltage of 48 V is supplied. Since a high voltage DC voltage is supplied, the value of the current flowing through the electric path can be reduced, and energy loss in voltage conversion can be reduced. Thereby, in the feed system 10, energy loss in the power supply can be reduced.

  Further, according to the power supply processing shown in FIG. 7, the electric device to which the DC output voltage is supplied transmits voltage value information of the DC input voltage required by the electric device to the power conditioner 100, and the power conditioner 100 A DC output voltage having the same voltage value as that of the DC input voltage required by the electric device is supplied to the electric device. As a result, even when the electric device to which the DC output voltage is supplied is changed, the power conditioner 100 keeps the voltage value of the DC output voltage to be supplied to the electric device according to the electric device supplying the DC output voltage. Can be flexibly changed and supplied.

  According to the present embodiment, the connection portion 121 of the first converter 109, the second converter 110, and the inverter 116, the third converter 111, the fourth converter 112, the fifth converter 113, and the sixth converter A diode 123 is provided between the junction 114 of the 114 and the seventh converter 115, the anode side of the diode 123 is connected to the junction 121, and the cathode side of the diode 123 is connected to the junction 122. The direct current power supplied from the solar power generation system 1 and the direct current power supplied from the wind power generation system 2 are natural regenerated energy, and can be reversely flowed to the commercial grid 5 because they can be purchased by the power company. The direct current power supplied from the storage battery 3 and the direct current power supplied from the electric vehicle 4 are powers that can not be purchased by the power company. By the diode 123 described above, it is possible to prevent the reverse flow impossible power and the reverse flow enable power from being mixed and supplied to the commercial grid 5.

  In the present embodiment, although the solar power generation system 1 and the wind power generation system 2 are connected to the power conditioner 100, at least one of them may be connected to the power conditioner 100. Moreover, although the storage battery 3 and the electric vehicle 4 are connected to the power conditioner 100, at least one of them may be connected to the power conditioner 100.

  In this embodiment, although the solar power generation system 1 and the wind power generation system 2 are connected to the power conditioner 100, a power generation system that supplies power capable of reverse flow such as a geothermal power generation system and a biomass power generation system is connected. May be In addition, although the storage battery 3 and the electric car 4 are connected to the power conditioner 100, a power generation system that supplies power that can not reverse power flow such as a home fuel cell power generation system using city gas and hydrogen is connected. It is also good.

  In this embodiment, the voltage value of the DC output voltage supplied from the connection terminal 101 is 300 V, the voltage value of the DC output voltage supplied from the connection terminal 102 is 150 V, and the DC output voltage supplied from the connection terminal 103 Of the voltage value of 50 V, but the DC output voltage of different voltage value is connected according to the voltage value of the DC input voltage required by the first electric device 200, the second electric device 300 and the third electric device 400 It may be supplied from 101, 102 and 103.

  According to "interpretation of the technical standards of electrical equipment, revised version on May 25, 2016", the ground voltage of the indoor electric path of the house shall be 150 V or less, and if the rated power consumption of the electric equipment is 2 kW or more, it shall be 300 V or less It is a standard. In the present embodiment, in view of the standard, the voltage value of the DC output voltage supplied from the connection terminal 101 is set to 300 V. For example, 400 V HVDC (High Volt-age Direct Current) to a home electric device When power supply is put into practical use, the voltage value of the DC output voltage supplied from the connection terminal 101 may be 400V. According to “Current Status and Trend of DC Power Supply Technology”, according to “Tetsushi Tsumura, NTT Facilities Inc.”, HVDC power supply of 400V DC voltage has already been put to practical use in data servers used for telecommunications.

  In the present embodiment, the power conditioner 100 includes the communication unit 125, the first electric device 200 includes the communication unit 209, the second electric device 300 includes the communication unit 308, and the third electric device 400 Since the communication unit 407 is provided, the power supply system 10 can operate as a home energy management system (HEMS). In this case, the power conditioner 100 can control and operate the first electric device 200, the second electric device 300, and the third electric device 400. For example, the power conditioner 100 can operate the setting mode of each electric device and set the energy saving mode.

Second Embodiment
Next, a power supply system according to a second embodiment of the present invention will be described. FIG. 8 is a block diagram showing an example of a feed system according to a second embodiment of the present invention. In a power supply system 10A according to a second embodiment of the present invention, a fourth electric device 500 having the same configuration as the first electric device 200 is connected to the power conditioner 100 in parallel with the first electric device 200. The fifth electric device 600 having the same configuration as the second electric device 300 is connected in parallel to the second electric device 300 to the power conditioner 100, and the sixth electric device having the same configuration as the third electric device 400 The point which 700 is connected to the power conditioner 100 in parallel with the 3rd electric equipment 400, and the point from which the function of the control part 124A mainly differs differs from Embodiment 1 mentioned above. Descriptions of configurations and operations overlapping with those of the first embodiment will be omitted, and different configurations and operations will be described below.

  The power supply system 10A shown in FIG. 8 includes a power conditioner 100A, a first electric device 200, a second electric device 300, a third electric device 400, a fourth electric device 500, and a fifth. An electric device 600 and a sixth electric device 700 are provided. The power conditioner 100A and the fourth electric device 500 are connected via the connection terminal 101 of the power conditioner 100A and the connection terminal 501 of the fourth electric device 500. The fourth electric device 500 is supplied with DC power from the power conditioner 100A. The power conditioner 100A and the fifth electric device 600 are connected via the connection terminal 102 of the power conditioner 100A and the connection terminal 601 of the fifth electric device 600. DC power is supplied to the fifth electric device 600 from the power conditioner 100A. The power conditioner 100A and the sixth electric device 700 are connected via the connection terminal 103 of the power conditioner 100A and the connection terminal 701 of the sixth electric device 700. DC power is supplied to the sixth electric device 700 from the power conditioner 100A.

  The power conditioner 100A includes a control unit 124A and a communication unit 125A. The control unit 124A and the communication unit 125A are connected. The control unit 124A includes a first converter 109, a second converter 110, a third converter 111, a fourth converter 112, a fifth converter 113, a sixth converter 114, a seventh converter 115, and an inverter 116. Control each one. Control unit 124A controls switch 117, switch 118, switch 119, and switch 120, respectively. The communication unit 125A mutually interacts with the first electric device 200, the second electric device 300, the third electric device 400, the fourth electric device 500, the fifth electric device 600, and the sixth electric device 700, respectively. It can communicate.

  In the present embodiment, communication unit 125A receives voltage value information of a DC input voltage required by first electric device 200 from first electric device 200, and also uses DC input voltage required by fourth electric device 500. Voltage value information is received from the fourth electrical device 500. The DC input voltage required by the fourth electric device 500 is an example of a fourth DC input voltage, and the voltage value information of the DC input voltage is an example of fourth voltage value information. The communication unit 125A receives the voltage value information of the DC input voltage required by the second electric device 300 from the second electric device 300, and the voltage value information of the DC input voltage required by the fifth electric device 600 is the fifth Is received from the electric device 600 of FIG. The communication unit 125A receives voltage value information of the DC input voltage required by the third electric device 400 from the third electric device 400, and the voltage value information of the DC input voltage required by the sixth electric device 700 is the sixth From the electric device 700 of FIG.

  In the present embodiment, control unit 124A uses the voltage value information of the DC input voltage required by first electric device 200 received by communication unit 125A and the voltage value information of the DC input voltage required by fourth electric device 500. Based on this, the fifth converter 113 is controlled. For example, control unit 124A calculates the average value of the voltage value of the DC input voltage required for the first electric device 200 by the fifth converter 113 and the voltage value of the DC input voltage required for the fourth electric device 500. The fifth converter 113 is controlled to convert it into a DC output voltage of The control unit 124A is the sixth based on the voltage value information of the DC input voltage required by the second electric device 300 received by the communication unit 125A and the voltage value information of the DC input voltage required by the fifth electric device 600. The converter 114 is controlled. The control unit 124A is a seventh based on the voltage value information of the DC input voltage required by the third electric device 400 received by the communication unit 125A and the voltage value information of the DC input voltage required by the sixth electric device 700. The converter 115 is controlled.

  According to this embodiment, the same effect as that of the above-described first embodiment can be obtained.

  In the present embodiment, two electrical devices are connected in parallel to one connection terminal of the power conditioner 100A, but three or more electrical devices may be connected in parallel. In this case, power conditioner 100A supplies, for example, a DC output voltage of an average value of voltage values of DC input voltages required by three or more electric devices to each of the three or more electric devices.

Third Embodiment
Next, a power supply system according to a third embodiment of the present invention will be described. FIG. 9 is a block diagram showing an example of a power supply system according to Embodiment 3 of the present invention. In the feed system 10B according to the third embodiment of the present invention, a DC output voltage is further supplied from the connection terminal 103 of the power conditioner 100 to the first electric device 200A and the second electric device 300A, and the first electric device The difference between the configuration of the second electric device 300A and that of the second electric device 300A is different from the first embodiment described above. Descriptions of configurations and operations overlapping with those of the first embodiment will be omitted, and different configurations and operations will be described below.

  A power feeding system 10B shown in FIG. 9 includes a power conditioner 100, a first electric device 200A, a second electric device 300A, and a third electric device 400. The power conditioner 100 and the first electric device 200A are connected via the connection terminal 101 of the power conditioner 100 and the connection terminal 201 of the first electric device 200A, and further, the connection terminal 103 of the power conditioner 100, And the connection terminal 213 of the first electric device 200A. The power conditioner 100 and the second electric device 300A are connected via the connection terminal 102 of the power conditioner 100 and the connection terminal 301 of the second electric device 300A, and further, the connection terminal 103 of the power conditioner 100, And the connection terminal 310 of the second electric device 300A.

  Next, the first electric device in FIG. 9 will be described. FIG. 10 is a block diagram showing an example of the first electric device in FIG.

  In the first electric device 200A shown in FIG. 10, the DC input voltage input from the connection terminal 213, that is, the DC output voltage supplied from the connection terminal 103 of the power conditioner 100 is supplied to the power supply circuit unit 207.

  In the present embodiment, the voltage value of the DC control voltage required by the control unit 208 is a voltage value of 12V. The power supply circuit unit 207 steps down a direct current input voltage having a voltage value of 50 V input from the connection terminal 213 to a direct current control voltage of a voltage value of 12 V, which is a direct current control voltage required by the control unit 208.

  Next, the second electric device in FIG. 9 will be described. FIG. 11 is a block diagram showing an example of the second electric device in FIG.

  In the second electric device 300A shown in FIG. 11, the DC input voltage input from the connection terminal 310, that is, the DC output voltage supplied from the connection terminal 103 of the power conditioner 100 is supplied to the power supply circuit unit 306.

  In the present embodiment, the voltage value of the DC control voltage required by the control unit 307 is a voltage value of 12V. The power supply circuit unit 306 steps down a direct current input voltage having a voltage value of 50 V input from the connection terminal 310 to a direct current control voltage of a voltage value of 12 V, which is a direct current control voltage required by the control unit 307.

  According to the present embodiment, the power supply circuit unit 207 and the power supply circuit unit 306 step down the DC input voltage having a voltage value of 50 V to a DC control voltage having a voltage value of 12 V. As a result, compared with the power supply circuit unit 207 and the power supply circuit unit 306 of the first embodiment and the second embodiment described above, an element having a high withstand voltage is not necessary, and the power supply circuit is changed to an inexpensive regulator. It will also be possible. For example, the first electric device 200A can employ the regulator 405 instead of the power supply circuit unit 207. Similarly, the second electric device 300A can adopt the regulator 405 instead of the power supply circuit unit 306.

Fourth Embodiment
Next, a power supply system according to a fourth embodiment of the present invention will be described. 12 and 13 are configuration diagrams showing an example of a power supply system according to Embodiment 4 of the present invention. The power supply system 10C according to the fourth embodiment of the present invention mainly includes a control unit 124B of the power conditioner 100B, a control unit 208A of the first electric device 200B, and a control unit 307A of the second electric device 300B. Is different from the first embodiment described above in that the function of the control unit 406A of the electric device 400A is different. Descriptions of configurations and operations overlapping with those of the first embodiment will be omitted, and different configurations and operations will be described below.

  The feed system 10C shown in FIGS. 12 and 13 includes a power conditioner 100B, a first electric device 200B, a second electric device 300B, and a third electric device 400A. The power conditioner 100B includes a control unit 124B and a communication unit 125B.

  In the present embodiment, as shown in FIG. 12, at the time of a power failure of commercial system 5, control unit 124B of power conditioner 100B separates switch 120 from commercial system 5 for protection. Control to open. In addition, the control unit 124B of the power conditioner 100B is configured to open and close the switch 117 and the switch for supplying power to the first electric device 200B, the second electric device 300B, and the third electric device 400A that can operate normally. Control the switch 118 and the switch 119 in the open state. Thereafter, as shown in FIG. 13, the control unit 124B of the power conditioner 100B opens / closes when the first electric device 200B, the second electric device 300B, and the third electric device 400A can operate normally. Control the switch 117, the switch 118 and the switch 119 in the closed state.

  In the present embodiment, the communication unit 125B receives, from the first electric device 200B, a first diagnosis result as to whether or not the first electric device 200B can operate normally. The communication unit 125B receives, from the second electric device 300B, a second diagnosis result as to whether the second electric device 300B can operate normally. The communication unit 125B receives, from the third electric device 400A, a third diagnosis result as to whether the third electric device 400A can operate normally.

  In the present embodiment, control unit 124B controls switch 117 in the closed state when first electric device 200B can operate normally, based on the first diagnosis result. When the second electric device 300B can operate normally, the control unit 124B controls the switch 118 to the closed state based on the second diagnosis result. When the third electric device 400A can operate normally, the control unit 124B controls the switch 119 in the closed state based on the third diagnosis result.

  Next, the first electric device in FIG. 12 will be described. FIG. 14 is a block diagram showing an example of the first electric device in FIG.

  The first electric device 200B illustrated in FIG. 14 includes a converter 202, a drive unit 203, a compressor 204, a power supply circuit unit 207, a control unit 208A, a communication unit 209A, and a backup power supply 210.

  The control unit 208A includes a diagnosis unit 214 that diagnoses whether or not the first electric device 200B can operate normally. The diagnosis unit 214 is an example of a first diagnosis unit. Control unit 208A transmits the first diagnosis result by diagnosis unit 214 to power conditioner 100B via communication unit 209A.

  Next, the second electric device in FIG. 12 will be described. FIG. 15 is a block diagram showing an example of the second electric device in FIG.

  The second electric device 300B shown in FIG. 15 includes a drive unit 302, a compressor 303, a power supply circuit unit 306, a control unit 307A, a communication unit 308A, and a backup power supply 309.

  Control part 307A is provided with diagnostic part 311 which diagnoses whether the 2nd electric equipment 300B can operate normally. The diagnosis unit 311 is an example of a second diagnosis unit. Control unit 307A transmits the second diagnosis result by diagnosis unit 311 to power conditioner 100B via communication unit 308A.

  Next, the third electric device in FIG. 12 will be described. FIG. 16 is a block diagram showing an example of the third electric device in FIG.

  The third electric device 400A shown in FIG. 16 includes a converter 402, a drive unit 403, an operation unit 404, a regulator 405, a control unit 406A, a communication unit 407A, and a backup power supply 408.

  The control unit 406A includes a diagnosis unit 409 that diagnoses whether the third electric device 400A can operate normally. The diagnosis unit 409 is an example of a third diagnosis unit. Control unit 406A transmits the third diagnosis result by diagnosis unit 409 to power conditioner 100B via communication unit 407A.

  Next, the power feeding process at the time of a power failure of the commercial power system executed by the power feeding system of FIG. 12 will be described. FIG. 17 is a sequence diagram of power feeding processing at the time of a power failure of the commercial power system executed by the power feeding system of FIG. 12.

  In step S201, at the time of a power failure of the commercial power system 5, the control unit 124B of the power conditioner 100B controls the switch 120, the switch 117, the switch 118, and the switch 119 in an open state. It can be determined, for example, by monitoring the voltage value or the current value of the alternating current flowing in the electric path between the connection terminal 108 and the switch 120 whether or not the commercial power system 5 has a power failure. Thereby, the supply of the DC output voltage to the first electric device 200B, the second electric device 300B, and the third electric device 400A is stopped (steps S202, S207 and S212).

  After step S202, the diagnosis unit 214 of the first electric device 200B diagnoses whether or not the first electric device 200B can operate normally (step S203). The method of diagnosis by the diagnosis unit 214 is assumed to use failure diagnosis of JTAG (Join Test Action Group: IEEE 1149.1). For example, a unique failure diagnosis of the first electric device 200B or an original failure A means or function capable of determining whether or not normal operation can be used may be used.

  Next, the control unit 208A of the first electric device 200B transmits the first diagnosis result by the diagnosis unit 214 to the power conditioner 100B via the communication unit 209A (step S204).

  Next, the control unit 124B of the power conditioner 100B controls the switch 117 based on the first diagnosis result received by the communication unit 125B (step S205). When the first electric device 200B can operate normally, the control unit 124B controls the switch 117 to the closed state based on the first diagnosis result. When the first electric device 200B can not operate normally, the control unit 124B controls the switch 117 to an open state based on the first diagnosis result. As a result, the supply of the DC output voltage to the first electric device 200B is maintained or stopped (step S206).

  After step S207, the diagnosis unit 311 of the second electric device 300B diagnoses whether or not the second electric device 300B can operate normally (step S208). The diagnosis by the diagnosis unit 311 is the same method as the diagnosis by the diagnosis unit 214.

  Next, the control unit 307A of the second electric device 300B transmits the second diagnosis result by the diagnosis unit 311 to the power conditioner 100B via the communication unit 308A (step S209).

  Next, the control unit 124B of the power conditioner 100B controls the switch 118 based on the second diagnosis result received by the communication unit 125B (step S210). When the second electric device 300B can operate normally, the control unit 124B controls the switch 118 to the closed state based on the second diagnosis result. When the second electric device 300B can not operate normally, the control unit 124B controls the switch 118 to an open state based on the second diagnosis result. As a result, the supply of the DC output voltage to the second electric device 300B is maintained or resumed (step S211).

  After step S212, the diagnosis unit 409 of the third electric device 400A diagnoses whether the third electric device 400A can operate normally (step S213). The diagnosis by the diagnosis unit 409 is the same method as the diagnosis by the diagnosis unit 214.

  Next, the control unit 406A of the third electric device 400A transmits the third diagnosis result by the diagnosis unit 409 to the power conditioner 100B via the communication unit 407A (step S214).

  Next, the control unit 124B of the power conditioner 100B controls the switch 119 based on the third diagnosis result received by the communication unit 125B (step S215). When the third electric device 400A can operate normally, the control unit 124B controls the switch 119 in the closed state based on the third diagnosis result. When the third electric device 400A can not operate normally, the control unit 124B controls the switch 119 to an open state based on the third diagnosis result. As a result, the supply of the DC output voltage to the third electric device 400A is maintained or resumed (step S216).

  According to the power feeding process at the time of a power failure of the commercial system shown in FIG. 17, the power conditioner 100B can be separated from the commercial system 5 and protected at the time of the power failure of the commercial system 5. In addition, the power supply to the first electric device 200B, the second electric device 300B and the third electric device 400A is temporarily stopped, and the first electric device 200B and the second electric device 300B which can operate normally. Since power supply can be resumed only for the third electric device 400A, safe power recovery is possible.

  In the present embodiment, control is performed using backup power supplies 210, 309 and 408 when the supply of DC output voltage to first electric device 200B, second electric device 300B and third electric device 400A is stopped. Although DC control voltage is supplied to units 208A, 307A and 406A, as in the third embodiment described above, switch 119 is closed even at the time of a power failure of commercial system 5, and the control unit The DC control voltage may be supplied to 208A, 307A and 406A. In this case, the network device, the fire alarm, and the security device relating to safety, which are desired to operate even when the commercial system 5 fails, can be operated even when the commercial system 5 fails.

  Note that some or all of the functions of control units 124, 124A, 124B, 208, 208A, 307, 307A, 406, and 406A in power supply systems 10, 10A, 10B, and 10C according to the first to fourth embodiments are the same. It may be realized by the processing circuit 20. 18 shows that the control units 124, 124A, 124B, 208, 208A, 307, 307A, 406 and 406A in the feed systems 10, 10A, 10B and 10C according to the first to fourth embodiments are the processing circuit 20. FIG.

  The processing circuit 20 is dedicated hardware. That is, the processing circuit 20 may be, for example, a single circuit, a complex circuit, a programmed processor, a parallel programmed processor, an application specific integrated circuit (ASIC), a field-programmable gate array (FPGA), or a combination thereof. It is Parts of control units 124, 124A, 124B, 208, 208A, 307, 307A, 406 and 406A in power supply systems 10, 10A, 10B and 10C of the first to fourth embodiments are dedicated and separate from the rest. Hardware may be used.

  Control sections 124, 124A, 124B, 208, 208A, 307, 307A, 406 and 406A in power supply systems 10, 10A, 10B and 10C according to the first to fourth embodiments execute programs stored in memory 40. It may be a processor 30 that FIG. 19 shows that the control units 124 124 A 124 B 208 208 A 307 307 A 406 and 406 A in the power supply systems 10 10 A, 10 B and 10 C according to the first to fourth embodiments are the processor 30. FIG. The processor 30 is a central processing unit (CPU), a processing device, an arithmetic device, a microprocessor, a microcomputer, or a digital signal processor (DSP).

  When control units 124, 124A, 124B, 208, 208A, 307, 307A, 406, and 406A in power supply systems 10, 10A, 10B, and 10C according to the first to fourth embodiments are processors 30, the control unit 124. , 124A, 208, 208A, 307, 307A, 406 and 406A are realized by the processor 30 and software or firmware. The software or firmware is written as a program and stored in the memory 40. The processor 30 implements the functions of the control units 124, 124A, 124B, 208, 208A, 307, 307A, 406 and 406A by reading and executing the program stored in the memory 40.

  That is, when control units 124, 124A, 124B, 208, 208A, 307, 307A, 406 and 406A of the first to fourth embodiments are the processor 30, the feeding system of the first to fourth embodiments is provided. Each of 10, 10A, 10B and 10C is for storing a program that results in the steps executed by a part of components constituting each of feeding systems 10, 10A, 10B and 10C. Memory 40 of FIG. A program stored in a memory 40 causes a computer to execute a procedure or a method executed by a part of components constituting each of the power supply systems 10, 10A, 10B and 10C of the first to fourth embodiments. It can be said that The memory 40 is non-volatile, such as RAM (Random Access Memory), ROM (Read Only Memory), flash memory, EPROM (Erasable Programmable Read Only Memory), EEPROM (registered trademark) (Electrically Erasable Programmable Read-Only Memory). Or volatile semiconductor memory, magnetic disk, flexible disk, optical disk, compact disk, mini disk, or DVD (Digital Versatile Disk).

  Control sections 124, 124A, 124B, 208, 208A, 307, 307A, 406 and 406A in power supply systems 10, 10A, 10B and 10C of the first to fourth embodiments are configured of processor 30 and memory 40. It may be realized by a processing circuit.

  The functions of the plurality of constituent elements constituting each of power supply systems 10, 10A, 10B and 10C of the first to fourth embodiments are partially realized by dedicated hardware, and the remaining portion is realized by software or firmware. You may Thus, the functions of the plurality of components constituting each of power supply systems 10, 10A, 10B and 10C of the first to fourth embodiments are realized by hardware, software or firmware, or a combination thereof. be able to.

  The configuration shown in the above embodiment shows an example of the contents of the present invention, and can be combined with another known technique, and one of the configurations is possible within the scope of the present invention. It is also possible to omit and change parts.

  Reference Signs List 1 solar power generation system, 2 wind power generation system, 3 storage batteries, 4 electric vehicles, 5 commercial power systems, 10, 10A, 10B, 10C power supply system, 20 processing circuits, 30 processors, 40 memories, 100, 100A, 100B power conditioners , 101, 102, 103, 104, 105, 106, 107, 108, 201, 213, 301, 310, 401, 501, 601, 701 connection terminals, 109 first converter, 110 second converter, 111 third Converter, 112 fourth converter, 113 fifth converter, 114 sixth converter, 115 seventh converter, 116 inverter, 117, 118, 119, 120 switch, 121, 122 connection portion, 123 diode, 124 , 124A, 124B 208, 208A, 307, 307A, 406, 406A control unit, 125, 125A, 125B, 209, 209A, 308A, 308A, 407, 407A communication unit, 200, 200A, 200B first electric device, 202, 402 converter, 203, 302, 403 Drive Unit, 204, 303 Compressor, 205, 304 DC Motor, 206, 305 Heat Exchanger, 207, 306 Power Supply Circuit Unit, 210, 309, 408 Backup Power Supply, 211 Compressor, 212 Expansion Valve, 214 , 311, 409 diagnostic unit, 300, 300 A, 300 B second electric device, 400, 400 A third electric device, 404 operation unit, 405 regulator, 500 fourth electric device, 600 fifth electric device, 700 6 electrical equipment.

Claims (7)

A power conditioner to which a first DC voltage is supplied from a first DC power supply,
A first electric device to which a first DC output voltage is supplied from the power conditioner;
The first electrical device is
The communication unit includes a communication unit that transmits, to the power conditioner, first voltage value information that is information on a voltage value of a first DC input voltage required by the first electric device.
The power conditioner is
A first converter unit for converting the first DC voltage into a DC reference voltage;
A second converter unit for converting the DC reference voltage into the first DC output voltage;
A communication unit that receives the first voltage value information from the first electrical device;
And a control unit configured to control the second converter unit based on the first voltage value information to control a voltage value of the first DC output voltage. The first DC power supply is a DC power supply that supplies power capable of reverse flow;
The power conditioner is
A second DC voltage is supplied from a second DC power supply that supplies power that can not reverse power flow,
An inverter unit that bi-directionally converts an AC voltage supplied from a commercial system and the DC reference voltage;
A third converter unit that bi-directionally converts the second DC voltage and the DC reference voltage;
And a diode provided between the connection portion of the first converter portion and the inverter portion, and the third converter portion.
The feed system according to claim 1, wherein an anode side of the diode is connected to the connection portion, and a cathode side of the diode is connected to the third converter portion. A second electrical device to which a second DC output voltage is supplied from the power conditioner;
And a third electric device to which a third DC output voltage is supplied from the power conditioner,
The second electric device is
The communication unit includes a communication unit that transmits, to the power conditioner, second voltage value information that is information on a voltage value of a second DC input voltage required by the second electric device.
The third electric device is
A communication unit for transmitting, to the power conditioner, third voltage value information that is information on a voltage value of a third DC input voltage required by the third electric device;
The power conditioner is
A fourth converter unit for converting the DC reference voltage into the second DC output voltage;
A fifth converter unit configured to convert the DC reference voltage into the third DC output voltage;
The communication unit of the power conditioner receives the second voltage value information from the second electrical device and the third voltage value information from the third electrical device, respectively.
The control unit controls the voltage value of the second DC output voltage by controlling the fourth converter unit based on the second voltage value information, and controls the fifth converter unit. The power supply system according to claim 2, wherein the control of the voltage value of the third DC output voltage is performed based on the third voltage value information. The voltage value of the second DC output voltage is smaller than the voltage value of the first DC output voltage,
The voltage value of the third DC output voltage is smaller than the voltage value of the second DC output voltage,
The feed system according to claim 3, wherein the third DC output voltage is further supplied from the power conditioner to the first electric device and the second electric device. The power conditioner is
A first switching unit for opening and closing an electric path between the inverter unit and the commercial system;
A second switching unit for opening and closing an electric path between the second converter unit and the first electric device;
A third switching unit for opening and closing an electric path between the fourth converter unit and the second electric device;
And a fourth opening / closing unit that opens / closes an electric path between the fifth converter unit and the third electric device.
The first electrical device is
A first diagnostic unit that diagnoses whether the first electrical device can operate normally;
The communication unit of the first electric device transmits a first diagnosis result by the first diagnosis unit to the power conditioner,
The second electric device is
A second diagnostic unit that diagnoses whether the second electrical device can operate normally;
The communication unit of the second electric device transmits, to the power conditioner, a second diagnosis result by the second diagnosis unit.
The third electric device is
A third diagnostic unit that diagnoses whether the third electrical device can operate normally;
The communication unit of the third electric device transmits a third diagnosis result by the third diagnosis unit to the power conditioner,
At the time of a power failure of the commercial system, the control unit of the power conditioner controls the first opening / closing unit, the second opening / closing unit, the third opening / closing unit, and the fourth opening / closing unit to open. Control the second open / close unit based on the first diagnosis result received from the first electric device, and based on the second diagnosis result received from the second electric device. And controlling the third open / close unit, and controlling the fourth open / close unit based on a third diagnosis result received from the third electric device. The feed system according to 4. The power conditioner is
A first switching unit for opening and closing an electric path between the inverter unit and the commercial system;
A second switching unit for opening and closing an electric path between the second converter unit and the first electric device;
A third switching unit for opening and closing an electric path between the fourth converter unit and the second electric device;
And a fourth opening / closing unit that opens / closes an electric path between the fifth converter unit and the third electric device.
At the time of a power failure of the commercial system, the control unit of the power conditioner controls the first opening / closing unit, the second opening / closing unit, and the third opening / closing unit to an open state, and the fourth opening / closing unit The feed system according to claim 4, characterized in that the unit is controlled to be closed. A fourth electric device to which the first DC output voltage is supplied from the power conditioner;
The fourth electric device is
A communication unit for transmitting, to the power conditioner, fourth voltage value information that is information on a voltage value of a fourth DC input voltage required by the fourth electric device;
The communication unit of the power conditioner receives the fourth voltage value information from the fourth electric device;
The control unit controls the second converter unit based on the first voltage value information and the fourth voltage value information to control the voltage value of the first DC output voltage. The feed system according to claim 1, characterized in that:

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