JP6563886B2 - Power feeding device, power receiving device, and power feeding method - Google Patents

Description

  The present invention relates to a technique for supplying power via a signal line, and particularly to a technique for supplying power via a relay device.

  A communication system that supplies power from a communication device having a power supply function to a communication device on a power receiving side via a metallic communication line that transmits a signal for data communication is widely used. When such a communication system is configured based on Ethernet (registered trademark), it is called PoE (Power over Ethernet). In addition, when power is supplied to a plurality of power receiving devices, the power feeding device may supply power to the power receiving devices via the relay device. In the configuration in which power is supplied to the power receiving device via the relay device, the relay device can supply the power receiving device with power obtained by subtracting the power consumption of the own device from the power supplied from the power feeding device.

  In a communication system that supplies power to each communication device via a metallic communication line that transmits a signal, in order to perform communication stably, it is necessary to supply power to each communication device stably. Therefore, power supply control to each communication device is performed so that the total amount of power supplied to each communication device does not exceed the amount of power that can be supplied. In order to accurately control the power supply, even when a power receiving device, that is, a communication device on the power receiving side is newly connected, the power consumption can be accurately grasped and the total amount of power consumed by the power receiving device can be supplied. It is necessary to control so as not to exceed excessive power. Therefore, in a communication system that supplies power to each communication device via a metallic communication line that transmits a signal, a technique for acquiring information on power consumption of the power receiving device has been developed. As such a technique for acquiring information on the power consumption of the power receiving apparatus, for example, a technique as disclosed in Patent Document 1 is disclosed.

  The communication system of Patent Document 1 includes a power supply side device and a plurality of power reception side devices. The power supply side device and each power receiving side device are connected via a LAN (Local Area Network) cable. Each power receiving device in Patent Literature 1 notifies the power receiving device of information on the maximum operating power for each operation mode. The power supply side device of Patent Document 1 controls the operation mode of each power receiving side device so as to fall within a range in which the supplied power can be supplied, based on the power consumption information acquired from each power receiving side device.

JP 2014-90234 A

  However, the technique of Patent Document 1 is not sufficient in the following points. In the communication system of Patent Literature 1, each power receiving device directly notifies the power feeding device of the information on the maximum power consumption. Therefore, in the communication system of Patent Document 1, when a relay device is used between the power supply side device and the power reception side device, the power supply side device cannot acquire information on the power consumption of the power reception side device. Therefore, in Patent Document 1, when a relay device is used, the power supply side device cannot accurately grasp the power consumption, and there is a risk that the operation of the communication system becomes unstable due to insufficient supply power. is there. Therefore, the technique of Patent Document 1 is not sufficient as a technique for accurately grasping power consumption and performing stable power supply control when power is supplied via a relay device.

  In order to solve the above-described problem, an object of the present invention is to provide a power feeding device that can accurately grasp power consumption and perform stable power feeding control even when power feeding is performed via a relay device. .

  In order to solve the above-described problems, the power supply apparatus of the present invention includes a power supply unit, a communication unit, an information acquisition unit, a determination unit, and a determination result transmission unit. The power supply means supplies power to the relay device via the first signal line having conductivity. The communication unit transmits and receives data to and from the relay device that operates based on the power supplied by the power supply unit via the first signal line. The information acquisition means has means for acquiring power consumption information of the relay apparatus from the relay apparatus. In addition, the information acquisition unit further includes a unit that acquires, via the relay device, information on power consumption of the power receiving device that operates based on the power supplied from the relay device. The determination unit determines whether power can be supplied to the power receiving device based on the total power consumption of the relay device and the power consumption of the power receiving device acquired by the information acquisition unit and the power value that can be supplied by the own device. The determination result transmission unit transmits information indicating whether power can be supplied to the power receiving device determined by the determination unit, to the power receiving device via the relay device.

  In the power feeding method of the present invention, power is supplied to the relay device via the first signal line having conductivity. According to the power feeding method of the present invention, information on the power consumption of the relay device is acquired from the relay device, and information on the power consumption of the power receiving device that operates based on the power supplied from the relay device is acquired via the relay device. The power supply method of the present invention determines whether power can be supplied to the power receiving device based on the acquired total value of the power consumption of the relay device and the power consumption of the power receiving device and the power value that can be supplied by the device itself. The power supply method of the present invention transmits information indicating whether or not the determined power supply to the power receiving device is possible to the power receiving device via the relay device.

  According to the present invention, even when power is supplied via a relay device, power consumption can be accurately grasped and stable power supply control can be performed.

It is a figure which shows the outline | summary of a structure of the 1st Embodiment of this invention. It is a figure which shows the outline | summary of a structure of the 2nd Embodiment of this invention. It is a figure which shows the structure of the electric power feeder of the 2nd Embodiment of this invention. It is a figure which shows typically the path | route of the electric power in the electric power feeder of the 2nd Embodiment of this invention. It is a figure which shows the structure of the power receiving apparatus of the 2nd Embodiment of this invention. It is a figure which shows typically the path | route of the electric power in the power receiving apparatus of the 2nd Embodiment of this invention. It is a figure which shows the structure of the relay apparatus of the 2nd Embodiment of this invention. It is a figure which shows typically the path | route of the electric power in the relay apparatus of the 2nd Embodiment of this invention. It is a figure which shows the example of a structure of the flame | frame in the 2nd Embodiment of this invention. It is a figure which shows the example of a data structure of the electric power information storage part in the 2nd Embodiment of this invention. It is a figure which shows the outline | summary of a structure of the 3rd Embodiment of this invention. It is a figure which shows the structure of the electric power feeder of the 3rd Embodiment of this invention. It is a figure which shows the structure of the power receiving apparatus of the 3rd Embodiment of this invention. It is a figure which shows the example of a structure of the flame | frame in the 3rd Embodiment of this invention. It is a figure which shows typically the path | route of the electric power in the power receiving apparatus of the 3rd Embodiment of this invention. It is a figure which shows typically the transmission path | route of the alive monitoring information in the 3rd Embodiment of this invention.

(First embodiment)
A first embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 shows an outline of the configuration of the power supply apparatus according to this embodiment. The power supply apparatus of this embodiment includes a power supply unit 1, a communication unit 2, an information acquisition unit 3, a determination unit 4, and a determination result transmission unit 5. The power supply means 1 supplies power to the relay device via the first signal line having conductivity. The communication unit 2 transmits / receives data to / from the relay device that operates based on the power supplied from the power supply unit 1 via the first signal line. The information acquisition unit 3 includes a unit that acquires information on power consumption of the relay device from the relay device. The information acquisition unit 3 further includes a unit that acquires, via the relay device, information on the power consumption of the power receiving device that operates based on the power supplied from the relay device. The determination unit 4 determines whether power can be supplied to the power receiving device based on the total power consumption of the relay device and the power consumption of the power receiving device acquired by the information acquisition unit 3 and the power value that can be supplied by the own device. To do. The determination result transmission unit 5 transmits information indicating whether power can be supplied to the power receiving device determined by the determination unit 4 to the power receiving device via the relay device.

  In the power supply apparatus according to the present embodiment, the information acquisition unit 3 acquires the power consumption information of the power receiving apparatus that operates based on the power supplied from the relay apparatus via the relay apparatus. In the power supply apparatus of this embodiment, the determination unit 4 determines whether power can be supplied to the power receiving apparatus based on the total value of the power consumption of the relay apparatus and the power consumption of the power receiving apparatus and the power value that can be supplied by the own apparatus. doing. Since the power supply apparatus according to the present embodiment determines whether power can be supplied using the power consumption information of the power receiving apparatus acquired via the relay apparatus, it appropriately determines whether the supplied power is within a supplyable range. be able to. In addition, since the power supply apparatus according to the present embodiment transmits information indicating whether or not power can be supplied from the determination result transmission unit 5 to the power reception apparatus via the relay apparatus, the power reception apparatus and the power supply availability information are shared and supplied. Power can be supplied within the possible range. As a result, by using the power supply device of the present embodiment, even when power is supplied via the relay device, it is possible to accurately grasp power consumption and perform stable power supply control.

(Second Embodiment)
A second embodiment of the present invention will be described in detail with reference to the drawings. FIG. 2 shows the configuration of the communication system of this embodiment. The communication system according to the present embodiment includes a power feeding device 10, a power receiving device 20, a relay device 30, and a host device 40. The communication system of the present embodiment includes four power receiving devices 20 including a power receiving device 20-1, a power receiving device 20-2, a power receiving device 20-3, and a power receiving device 20-4. In addition, the communication system according to the present embodiment includes two relay apparatuses, a relay apparatus 30-1 and a relay apparatus 30-2.

  The power supply apparatus 10 and the power receiving apparatus 20-1 and the power supply apparatus 10 and the relay apparatus 30-1 and the relay apparatus 30-2 are connected by a metallic communication line, that is, a conductive signal line. . Further, the relay device 30-1 and the power receiving device 20-2 and the relay device 30-2, the power receiving device 20-3, and the power receiving device 20-4 are also connected by a metallic communication line. The power supply device 10 and the host device 40 are also connected by a signal line.

  As illustrated in FIG. 2, the power feeding device 10 is connected to the power receiving device 20-1, the relay device 30-1, and the relay device 30-2, and is further connected to the host device 40. The relay device 30-1 is further connected to the power receiving device 20-2. Relay device 30-2 is further connected to power receiving device 20-3 and power receiving device 20-4. The power receiving device 20 and the relay device 30 may be other numbers. For example, two or more power receiving apparatuses 20 that are directly connected to the power feeding apparatus 10 may be used. Further, the power receiving device 20 connected to one relay device 30 may be three or more. Further, the number of relay devices 30 connected to the power supply device 10 may be three or more.

  The communication system according to the present embodiment is a data communication system that transmits and receives data between the power receiving device 20 and the host device 40 via the power supply device 10 and the relay device 30. The communication system of this embodiment is configured as Ethernet (registered trademark). In addition, the power receiving device 20 and the relay device 30 are configured by electric power supplied from the power supply device 10 via the metallic communication line. That is, the communication system according to the present embodiment is configured as PoE (Power over Ethernet). The power receiving device 20 is, for example, a communication device such as an access point for wireless communication, or an electronic device having a communication function such as a measurement device or a camera.

  A configuration of the power supply apparatus 10 will be described. FIG. 3 shows a configuration of the power supply apparatus 10 of the present embodiment. The power supply apparatus 10 includes a signal transformer 11, a power filter 12, a power supply unit 13, a signal processing unit 14, a higher-order signal transformer 15, a power signal processing unit 16, and a power supply availability determination unit 17. A power information storage unit 18 is provided. In addition, the power supply apparatus 10 includes an upper port that performs connection with a signal line connected to the upper apparatus 40. In addition, the power supply apparatus 10 includes a power reception side port that performs connection with a metallic communication line connected to the power reception apparatus 20 or the relay apparatus 30.

  The power supply apparatus 10 according to the present embodiment includes three signal transformers 11 including a signal transformer 11-1, a signal transformer 11-2, and a signal transformer 11-3. The power supply apparatus 10 according to the present embodiment includes three power filters, that is, a power filter 12-1, a power filter 12-2, and a power filter 12-3. The signal lines on one side of the signal transformer 11 and the power filter 12 are connected to the power receiving side port.

  In the present embodiment, the signal lines of the signal transformer 11-1 and the power filter 12-1 are the power reception side port A, and the signal lines of the signal transformer 11-2 and the power filter 12-2 are the power reception side port B. It is connected. The signal lines of the signal transformer 11-3 and the power filter 12-3 are connected to the power receiving side port C. Four or more signal transformers 11 and power filters 12 may be provided.

  The signal transformer 11 is a transformer for performing data communication with the power receiving device 20 or the relay device 30. The signal transformer 11 is provided between the signal processing unit 14 and the power receiving side port. The signal transformer 11 converts the signal output from the signal processing unit 14 into a voltage signal based on the standard of the communication network and outputs the signal. The signal transformer 11 converts a signal input via the power receiving side port into a voltage signal used inside the power supply apparatus 10 and outputs the signal to the signal processing unit 14.

  The power filter 12 is a filter that superimposes the power output from the power supply unit 13 on the metallic communication line. The power filter 12 is provided between the power supply unit 13 and the power receiving side port.

  The power supply unit 13 supplies power to the power receiving device 20 and the relay device 30 via the power receiving side port. The power supply unit 13 outputs power to the power filter 12 based on the control of the power supply availability determination unit 17. The power supply unit 13 supplies power based on the power supplied from the external power source.

  FIG. 4 schematically shows a power path when power is supplied in the power supply apparatus 10 of the present embodiment. In FIG. 4, the power path is indicated by broken-line arrows. As shown in FIG. 4, the power output from the power supply unit 13 is superimposed on a signal line connecting the signal transformer 11 and the power receiving side port via the power filter 12. The power superimposed on the signal line connecting the signal transformer 11 and the power receiving side port is output from the power receiving side port and supplied to the power receiving device 20 or the relay device 30 connected to the power receiving side port via the metallic communication line. Is done. Further, the power supply unit 13 of the present embodiment corresponds to the power supply unit 1 of the first embodiment.

  The signal processing unit 14 has a switching function of identifying the transmission destination of the input signal and outputting it to a route according to the transmission destination. The signal processing unit 14 is connected to the signal transformer 11, the higher-order signal transformer 15, and the power signal processing unit 16. The signal processing unit 14 of the present embodiment corresponds to the communication unit 2 of the first embodiment.

  The upper signal transformer 15 is a transformer for communicating with the upper device 40. The upper signal transformer 15 is provided between the signal processing unit 14 and the upper port. The upper signal transformer 15 converts the signal output from the signal processing unit 14 into a signal voltage for communication with the upper device 40 and outputs the signal voltage. The upper signal transformer 15 converts a signal input via the upper port into a voltage signal used in the power supply apparatus 10 and outputs the signal to the signal processing unit 14.

  The power signal processing unit 16 has a function of managing information on power consumption of the power receiving device 20 and the relay device 30. In addition, the power signal processing unit 16 has a function of managing information on whether power can be supplied to the power receiving device 20 and the relay device 30. The power signal processing unit 16 is connected to the signal processing unit 14, the power supply availability determination unit 17, and the power information storage unit 18.

  When the power signal processing unit 16 receives the power consumption information of the power receiving device 20 and the relay device 30 as the power consumption information from each device, the power signal processing unit 16 stores the received power consumption information in the power information storage unit 18. Further, based on the control of the power supply availability determination unit 17, the power signal processing unit 16 sends information indicating whether power supply is possible to the power receiving device 20 and the relay device 30 as power supply availability information using a power signal. The power signal processing unit 16 of the present embodiment corresponds to the information acquisition unit 3 and the determination result transmission unit 5 of the first embodiment.

  The power supply availability determination unit 17 has a function of determining whether power can be supplied to the power receiving device 20 and the relay device 30. The power supply availability determination unit 17 is connected to the power supply unit 13, the power signal processing unit 16, and the power information storage unit 18.

  The power supply availability determination unit 17 determines whether power can be supplied to each device based on the power consumption information and the maximum power supply information stored in the power information storage unit 18. The maximum power supply information is set in advance as the maximum value of power that can be supplied by the power supply apparatus 10. When determining whether power can be supplied to each device, the power supply availability determination unit 17 generates information indicating whether power supply is possible for each device as power supply availability information. The power supply availability determination unit 17 sends to the power signal processing unit 16 power supply availability information, information on the transmission destination of the power availability information, and information requesting transmission of the power availability information. The power supply availability determination unit 17 of the present embodiment corresponds to the determination unit 4 of the first embodiment.

  The power information storage unit 18 has a function of storing power consumption information and maximum power supply power information. The power information storage unit 18 stores the power consumption information of each device in association with the identifier information of each device. In the present embodiment, information on the address of each device is used as information on the identifier of each device. As the identifier information of each device, information other than an address may be used as long as the information can identify each device. The power information storage unit 18 is configured by, for example, a nonvolatile semiconductor memory device.

  A configuration of the power receiving device 20 will be described. FIG. 5 shows a configuration of the power receiving device 20 of the present embodiment. The power receiving device 20 includes a signal transformer 21, a power signal processing unit 22, a main circuit 23, a power filter 24, a power receiving unit 25, and a power distribution control unit 26. In addition, the power receiving device 20 includes a power supply side port that performs connection with a metallic communication line connected to the power supply device 10 or the relay device 30.

  The signal transformer 21 is a transformer for performing data communication with the power supply apparatus 10 or the relay apparatus 30. The signal transformer 21 is provided between the power signal processing unit 22 and the power supply side port.

  The signal transformer 21 converts the signal output from the power signal processing unit 22 into a voltage signal based on the standard of the communication network and outputs the signal to the power supply side port. The signal transformer 21 converts a signal input via the power supply side port into a voltage signal used inside the power receiving device 20 and outputs the signal to the power signal processing unit 22.

  The power signal processing unit 22 has a function of transmitting information indicating power consumption of its own device to the power supply apparatus 10 or the relay apparatus 30 as power consumption information. The power signal processing unit 22 has a function of receiving power supply availability information from the power supply apparatus 10 or the relay apparatus 30. The power signal processing unit 22 is connected to the signal transformer 21, the main circuit 23, and the power distribution control unit 26, respectively.

  The power signal processing unit 22 transmits power consumption information indicating the power consumption of the own device to the power supply device 10 or the relay device 30 by a power signal. Further, the power signal processing unit 22 receives a power signal based on the power supply availability information from the power supply apparatus 10 or the relay apparatus 30. The power signal processing unit 22 extracts power supply availability information from the received power signal, and sends the extracted power supply availability information to the power distribution control unit 26.

  The power signal processing unit 22 operates in the data transmission mode when the power supply availability information indicates that power supply is possible. The data transmission mode is a state in which data can be transmitted and received between the signal transformer 21 and the main circuit 23 via the power signal processing unit 22, and the power signal processing unit 22 does not perform processing related to the content of the signal. It means a state.

  The main circuit 23 is a circuit that performs processing related to the main function of the power receiving device 20. The main circuit 23 operates by transmitting / receiving data to / from the host device 40. For example, when the power receiving device 20 is a communication terminal device, the main circuit 23 performs processing related to data transmission / reception performed with the host device 40. For example, when the power receiving device 20 is a measurement device or a camera, the main circuit 23 performs processing related to acquisition of measurement data and video data and transmission of the acquired data to the host device 40.

  The main circuit 23 operates with power supplied from the power distribution control unit 26. The main circuit 23 is connected to the power signal processing unit 22. The main circuit 23 transmits and receives data to and from the host device 40 when the power signal processing unit 22 is in the data transmission mode.

  The power filter 24 is a filter that receives power superimposed on the metallic signal line. The power filter 24 is provided between the power receiving unit 25 and the power supply side port.

  The power receiving unit 25 receives power supplied from the power supply apparatus 10 or the relay apparatus 30 via the power supply side port. The power receiving unit 25 outputs the received power to the power distribution control unit 26.

  The power distribution control unit 26 controls the supply and stop of power to the power signal processing unit 22 and the main circuit 23. The power distribution control unit 26 supplies power to the power signal processing unit 22 and the main circuit 23 when the power supply availability information sent from the power signal processing unit 22 indicates a power supply enabled state. The power distribution control unit 26 stops supplying power to the power signal processing unit 22 and the main circuit 23 when the power supply availability information sent from the power signal processing unit 22 indicates that power supply is not possible. The power signal processing unit 22 and the power distribution control unit 26 are connected by a signal line that transmits and receives control signals such as power supply availability information and a signal line that supplies power from the power distribution control unit 26 to the power signal processing unit 22. Yes.

  FIG. 6 schematically shows a power path when power is supplied in the power receiving device 20 of the present embodiment. In FIG. 6, the power path is indicated by broken-line arrows. As shown in FIG. 6, the power supplied to the power receiving device 20 from the power supply side port is received by the power receiving unit 25 via the power filter 24. The power receiving unit 25 sends the received power to the power distribution control unit 26. The power distribution control unit 26 supplies power to the power signal processing unit 22 and the main circuit 23 based on the power transmitted from the power receiving unit 25.

  The configuration of the relay device 30 will be described. FIG. 7 shows the configuration of the relay device 30 of this embodiment. The relay device 30 includes a power supply side signal transformer 31, a power signal processing unit 32, a main circuit 33, a power supply side power filter 34, a power reception unit 35, and a power distribution control unit 36. The relay device 30 further includes a power receiving side signal transformer 37, a power receiving side power filter 38, and a power supply unit 39. In addition, the relay device 30 includes a power supply side port that performs connection with the metallic communication line connected to the power supply device 10. In addition, the relay device 30 includes a power receiving side port for connecting to the metallic communication line connected to the power receiving device 20.

  The relay device 30 receives power supplied from the power supply device 10 and supplies power to the power receiving device 20 based on the supplied power. The relay device 30 is a device having a power receiving function and a power feeding function.

  The power supply side signal transformer 31 is a transformer for performing data communication with the power supply apparatus 10. The power supply side signal transformer 31 is provided between the power signal processing unit 32 and the power supply side port. The power supply side signal transformer 31 converts the signal output from the power signal processing unit 32 into a voltage signal based on the standard of the communication network and outputs the signal. Further, the power supply side signal transformer 31 converts a signal input via the power supply side port into a voltage signal used inside the relay device 30 and outputs the signal to the power signal processing unit 32.

  The power signal processing unit 32 has a function of transmitting information indicating the power consumption of its own device to the power supply apparatus 10 as power consumption information. The power signal processing unit 32 has a function of receiving power supply availability information from the power supply apparatus 10. The power signal processing unit 32 is connected to the power supply side signal transformer 31, the main circuit 33, and the power distribution control unit 36.

  The power signal processing unit 32 transmits power consumption information indicating the power consumption of its own device to the power supply apparatus 10 by a power signal. Further, the power signal processing unit 32 receives a power signal based on the power supply availability information from the power supply apparatus 10. The power signal processing unit 32 extracts power supply availability information from the received power signal, and sends the extracted power supply availability information to the power distribution control unit 36.

  The power signal processing unit 32 operates as the data transmission mode when the power supply availability information indicates that power supply is possible. In the data transmission mode, data can be transmitted and received between the power-supply-side signal transformer 31 and the main circuit 33 via the power signal processing unit 32. The power signal processing unit 32 performs processing related to the content of the signal. It means no state.

  The main circuit 33 is a circuit that performs processing related to the main function of the relay device 30. In addition, the main circuit 33 operates with power supplied from the power distribution control unit 36. The main circuit 33 is connected to the power signal processing unit 32 and the power-receiving-side signal transformer 37, respectively. The main circuit 33 relays data communication between the power supply apparatus 10 and the power reception apparatus 20 when the power signal processing unit 32 is in the data transmission mode.

  The power supply-side power filter 34 is a filter that receives power superimposed on the metallic signal line. A signal line branched between the power supply side port and the power supply side signal transformer 31 is connected to the power supply side power filter 34. The power feeding side power filter 34 is provided between the power receiving unit 35 and the power feeding side port.

  The power receiving unit 35 receives power supplied from the power supply apparatus 10 via the power supply side port. The power receiving unit 35 outputs the received power to the power distribution control unit 36.

  The power distribution control unit 36 controls the supply and stop of power to the power signal processing unit 32, the main circuit 33, and the power supply unit 39. The power distribution control unit 36 supplies power to the power signal processing unit 32, the main circuit 33, and the power supply unit 39 based on the power transmitted from the power receiving unit 35. The power distribution control unit 36 supplies power to the power signal processing unit 32, the main circuit 33, and the power supply unit 39 when the power supply availability information sent from the power signal processing unit 32 indicates a power supply enabled state. The power distribution control unit 36 stops supplying power to the power signal processing unit 32, the main circuit 33, and the power supply unit 39 when the power supply availability information sent from the power signal processing unit 32 indicates that power supply is not possible. To do.

  The power signal processing unit 32 and the power distribution control unit 36 are connected by a signal line that transmits and receives control signals such as power supply availability information and a signal line that supplies power from the power distribution control unit 36 to the power signal processing unit 32. Yes.

  The power-receiving-side signal transformer 37 is a transformer for performing data communication with the power receiving apparatus 20. The power reception side signal transformer 37 is provided between the main circuit 33 and the power reception side port. The power-receiving-side signal transformer 37 converts the signal output from the main circuit 33 into a voltage signal based on the standard of the communication network and outputs the signal to the power-receiving-side port. In addition, the power-receiving-side signal transformer 37 converts the signal input via the power-receiving-side port into a voltage signal used inside the relay device 30 and outputs the signal to the main circuit 33.

  The power reception side power filter 38 is a filter that superimposes the power output from the power supply unit 39 on the metallic communication line. The signal line on the output side of the power receiving side power filter 38 is connected to the signal line connecting the power receiving side signal transformer 37 and the power receiving side port. The power receiving side power filter 38 superimposes the power supplied from the power supply unit 39 on the signal line connecting the power receiving side signal transformer 37 and the power receiving side port.

  The power supply unit 39 supplies power to the opposing power receiving device 20 via the power receiving side port. The power supply unit 39 outputs the power supplied from the power distribution control unit 36 to the power receiving side power filter 38.

  FIG. 8 schematically shows a power path when power is supplied from the power supply apparatus 10 to the power receiving apparatus 20 in the relay apparatus 30 of the present embodiment. In FIG. 8, the power path is indicated by broken-line arrows. As shown in FIG. 8, the power supplied to the relay device 30 from the power supply side port is received by the power receiving unit 35 via the power supply side power filter 34. The power receiving unit 35 sends the received power to the power distribution control unit 36. The power distribution control unit 36 supplies power to the power signal processing unit 32, the main circuit 33, and the power supply unit 39 based on the power transmitted from the power receiving unit 35.

  In FIG. 8, the power output from the power supply unit 39 is superimposed on the signal line connecting the power receiving side signal transformer 37 and the power receiving side port via the power receiving side power filter 38. The power superimposed on the signal line connecting the power-receiving-side signal transformer 37 and the power-receiving-side port is output from the power-receiving-side port and supplied to the power receiving device 20 connected to the power-receiving-side port via the metallic communication line. .

  The relay device 30 illustrated in FIG. 7 has a configuration in which only one power receiving device 20 is connected to the power receiving side port, but the relay device 30 has a configuration in which a plurality of power receiving devices 20 can be connected. It may be. In the case of a configuration in which a plurality of power receiving devices 20 are connected, the power receiving side signal transformers 37, the power receiving side power filters 38, and the power receiving side ports are provided in accordance with the number of power receiving devices 20 connected.

  The host device 40 transmits and receives data to and from the power receiving device 20 via the power feeding device 10 and the relay device 30. For the host device 40, for example, an information processing device such as a server is used. The host device 40 of this embodiment is operated by an external power supply. The host device 40 may also be configured to receive power from the power supply device 10.

  The operation of the communication system of this embodiment will be described. In the communication system having the configuration illustrated in FIG. 2, an example will be described in which the relay device 30-1 is connected to the power receiving side port B of the power supply device 10 and the power receiving device 20-2 is further connected to the relay device 30-1.

  First, an operation when the relay device 30-1 is connected to the power feeding device 10 will be described. In the following description, the relay device 30-1 is represented as the relay device 30. When the relay device 30 is connected to the power receiving side port B of the power supply device 10 via the metallic communication line, supply of power from the power supply device 10 to the relay device 30 is started. The power output from the power supply unit 13 of the power supply apparatus 10 is superimposed on the signal line via the power filter 12. The power superimposed on the signal line is output from the power receiving side port. The power output from the power receiving side port of the power supply apparatus 10 is transmitted through the metallic communication line and supplied to the relay apparatus 30.

  The power that is superimposed on the metallic communication line and supplied to the relay device 30 is received by the power receiving unit 35 via the power supply-side power filter 34. When receiving the power supplied from the power supply apparatus 10, the power receiving unit 35 sends the received power to the power distribution control unit 36. When power is transmitted from the power receiving unit 35, the power distribution control unit 36 supplies the transmitted power only to the power signal processing unit 32. That is, at this time, the power distribution control unit 36 does not supply power to the main circuit 33 and the power supply unit 39.

  When the power consumption of the power signal processing unit 32 is sufficiently smaller than the power consumption of the main circuit 33, the power supplied from the power supply apparatus 10 to the relay apparatus 30 is larger than that during normal operation of the relay apparatus 30. Small enough. Therefore, when power is supplied only to the power signal processing unit 32, there is no possibility that the power supply from the power supply apparatus 10 to the relay apparatus 30 will be in an overcurrent state.

  The power signal processing unit 32 starts to operate when receiving power supply from the power distribution control unit 36. When the operation starts, the power signal processing unit 32 outputs power consumption information indicating the maximum value of power consumption of the own device to the power supply side signal transformer 31 as a power signal. The maximum value of the power consumption of the own device in the relay device 30 means the power consumption when all the functions of the relay device 30 including the main circuit 33 are operated.

  When a power signal based on the power consumption information is input, the power supply side signal transformer 31 converts the received power signal into a power signal having a voltage conforming to the communication standard, and outputs the signal. The power signal output from the power supply side signal transformer 31 is output from the power supply side port of the relay device 30 to the metallic communication line.

  The power signal output from the relay device 30 is transmitted through the metallic communication line and input to the power receiving side port of the power supply device 10. The power signal input to the power receiving side port of the power supply apparatus 10 is input to the signal transformer 11. When the power signal is input, the signal transformer 11 converts the received power signal into a voltage signal used inside the relay device 30 and sends the signal to the signal processing unit 14.

  When the signal processing unit 14 receives the power signal based on the power consumption information, the signal processing unit 14 refers to the identifier of the received signal to check whether the data is control data such as normal data or power consumption information. First, a signal is distributed to each port based on the transmission destination. The signal processing unit 14 refers to the input Ethernet header and performs address learning for each port based on the address of the transmission source. Assuming that “01” is set in the transmission source address of the Ethernet header of the power signal, the signal processing unit 14 registers “01” as an address corresponding to the power receiving side port to which the relay device 30 is connected.

In the communication system according to the present embodiment, the normal data and the power signal are configured in the Ethernet frame format. FIG. 9 schematically shows an example of a frame format in the communication system of the present embodiment. As shown in the example of FIG. 9, the Ethernet frame of the present embodiment includes a header, an identifier, data, and FCS (Frame Check Sequence). The header is composed of information such as TYPE indicating the destination address, source address, and frame type. In the example of FIG. 9, information for determining whether the frame is a normal data frame or a power signal frame is added to the identifier area.
The normal data and the power signal are discriminated by an identifier assigned to each. When the frame is based on a power signal, the data area is configured by power consumption information or power supply availability information.

  When detecting that the received frame is a power signal, the signal processing unit 14 extracts power consumption information. When the signal processing unit 14 extracts the power consumption information, the information for identifying the relay device 30 and the power consumption information are associated with each other and stored in the power information storage unit 18. In the present embodiment, the information identifying the relay device 30 uses the address of the relay device 30.

  FIG. 10 schematically shows the configuration of data stored in the power information storage unit 18. As shown in FIG. 10, the power information storage unit 18 stores information on the maximum power that can be supplied by the power supply apparatus 10 and information on the power consumption of each device associated with each device address and each device address. Has been.

  When receiving the power consumption information from the relay device 30, the power supply availability determination unit 17 compares the total power consumption value of each device whose information is stored in the power information storage unit 18 with the maximum value of power that can be supplied. . When the total value of power consumption is less than or equal to the maximum value of power that can be supplied, the power supply availability determination unit 17 determines that power can be supplied to the newly connected device, that is, power can be supplied. When the total value of power consumption is equal to or less than the maximum value of power that can be supplied, the power supply availability determination unit 17 determines that power cannot be supplied to a newly connected device.

  When determining whether or not power can be supplied, the power supply availability determination unit 17 sends information indicating whether or not power supply is possible to the power signal processing unit 16. When receiving the power supply availability information, the power signal processing unit 16 generates a power signal to be sent to the relay device 30 based on the received power availability information. When the power signal to be sent to the relay device 30 is generated, the power signal processing unit 16 sends the generated signal to the signal processing unit 14.

  When receiving the power signal, the signal processing unit 14 refers to the header to determine the transmission destination. When the transmission destination is the address “01” indicating the relay device 30, the signal processing unit 14 sends a power signal to the signal transformer 11 connected to the corresponding power receiving side port.

  When the signal transformer 11 receives the power signal, the signal transformer 11 converts the received signal into a signal having a voltage for communication using the metallic communication line and outputs the signal. The power signal output from the signal transformer 11 is output from the power supply apparatus 10 to the metallic communication line via the power receiving side port.

  The power signal output from the power supply apparatus 10 is transmitted through the metallic communication line and input to the power supply side port of the relay apparatus 30. The power signal input from the power supply side port to the power supply apparatus 10 is input to the power supply side signal transformer 31.

  When the power signal is input, the power supply side signal transformer 31 converts the power signal into a voltage signal used in the relay device 30 and sends the signal to the power signal processing unit 32. When the power signal processing unit 32 receives the power signal, the power signal processing unit 32 extracts power supply availability information from the received power signal and confirms whether the power supply from the power supply apparatus 10 is possible. When the power supply availability information indicates that power supply is possible, the power signal processing unit 32 operates in the data transmission mode.

  When the power signal processing unit 32 extracts the power supply availability information, the power signal processing unit 32 sends the extracted power availability information to the power distribution control unit 36. When receiving the power supply availability information, the power distribution control unit 36 confirms whether the power supply from the power supply apparatus 10 is possible. When power can be supplied, the power distribution control unit 36 starts supplying power to the main circuit 33 and the power supply unit 39.

  When the supply of power to the main circuit 33 and the power supply unit 39 is started, the entire device of the relay device 30 becomes operable. When power supply to the power supply unit 39 is started, power supply to the power receiving device 20 is enabled when the power receiving device 20 is connected to the power receiving side port via the metallic communication line. In addition, since the power signal processing unit 32 operates in the data transmission mode, data communication is possible between the power supply side signal transformer 31 and the main circuit 33.

  When the power supply availability information indicates that power supply is not possible, the power distribution control unit 36 stops all power supply when confirming that power supply is not possible. Since all power supply from the power distribution control unit 36 to each part of the relay device 30 is stopped, the relay device 30 stops operating and enters a shutdown state. The relay device 30 in the shutdown state receives power from the metallic communication line by reconnecting the power supply side port, and enters an initial state.

  Next, an operation when the power receiving device 20-2 is connected to the relay device 30-1 after the entire device of the relay device 30-1 becomes operable will be described. In the following description, the relay device 30-1 is represented as the relay device 30 and the power receiving device 20-2 is represented as the power receiving device 20.

  When the power receiving device 20 is connected to the power receiving side port of the relay device 30 via the metallic communication line, supply of power from the relay device 30 to the power receiving device 20 is started. The power output from the power supply unit 39 of the relay device 30 is superimposed on the signal line via the power reception side power filter 38. The power superimposed on the signal line is output from the power receiving side port. The power output from the power receiving port of the relay device 30 is transmitted through the metallic communication line and supplied to the power receiving device 20.

  The electric power superimposed on the metallic communication line and supplied to the power receiving device 20 is received by the power receiving unit 25 through the power filter 24. When receiving the power supplied from the relay device 30, the power receiving unit 25 sends the received power to the power distribution control unit 26.

  When power is sent from the power receiving unit 25, the power distribution control unit 26 supplies the sent power only to the power signal processing unit 22. That is, at this time, the power distribution control unit 26 does not supply power to the main circuit 23.

  When the power consumption of the power signal processing unit 22 is sufficiently smaller than the power consumption of the main circuit 23, the power supplied from the relay device 30 to the power receiving device 20 is larger than that during normal operation of the power receiving device 20. Small enough. Therefore, when supplying power only to the power signal processing unit 22, there is no possibility that the power supply from the relay device 30 to the power receiving device 20 becomes an overcurrent state.

  The power signal processing unit 22 starts to operate when receiving power supply from the power distribution control unit 26. When the operation starts, the power signal processing unit 22 outputs power consumption information indicating information on the maximum value of power consumption of the own device to the signal transformer 21 as a power signal. The maximum value of the power consumption of the own device in the power receiving device 20 refers to the power consumption when all the functions of the power receiving device 20 including the main circuit 23 are operated.

  When a power signal based on the power consumption information is input, the signal transformer 21 converts the received power signal into a power signal having a voltage conforming to the communication standard, and outputs the signal. The power signal output from the signal transformer 21 is output from the power supply side port of the power receiving device 20 to the metallic communication line.

  The power signal output from the power receiving device 20 is transmitted through the metallic communication line and input to the power receiving side port of the relay device 30. The power signal input to the power receiving side port of the relay device 30 is input to the power receiving side signal transformer 37. When the power signal is input, the power-receiving-side signal transformer 37 converts the received power signal into a voltage signal used inside the power receiving device 20 and sends the signal to the main circuit 33. When receiving the power signal, the main circuit 33 sends the received power signal to the power signal processing unit 32.

  When receiving the power signal, the power signal processing unit 32 operates in the data transmission mode, and therefore outputs the received power signal to the power supply side signal transformer 31. When the power supply signal transformer 31 receives the power signal, the power supply signal transformer 31 converts the received power signal into a voltage based on the communication standard and outputs the voltage to the metallic communication line via the power supply port.

  The power signal output from the relay device 30 is transmitted through the metallic communication line and is input to the power receiving side port B of the power supply device 10. The power signal input to the power receiving side port B of the power supply apparatus 10 is input to the signal transformer 11. When the power signal is input, the signal transformer 11 converts the received power signal into a voltage signal used inside the power supply apparatus 10 and sends the signal to the signal processing unit 14.

  When the signal processing unit 14 receives the power signal based on the power consumption information, the signal processing unit 14 refers to the identifier of the received signal to check whether the data is normal data or a power signal such as power consumption information. First, a signal is distributed to each port based on the transmission destination. The power signal processing unit 32 refers to the input Ethernet header and performs address learning for each port based on the address of the transmission source.

  Assuming that “02” is set in the transmission source address of the Ethernet header of the power signal, the signal processing unit 14 registers “02” as an address corresponding to the power receiving side port B to which the power receiving device 20 is connected.

  When detecting that the received frame is a power signal, the power signal processing unit 32 extracts power consumption information. When the power signal processing unit 32 extracts the power consumption information, the power signal processing unit 32 associates the information for identifying the power receiving device 20 with the power consumption information and stores the information in the power information storage unit 18. In the present embodiment, the information identifying the power receiving device 20 uses the address of the power receiving device 20.

  When the power supply availability determination unit 17 receives the power consumption information of the power receiving device 20 via the relay device 30, the total power consumption value of each device whose information is stored in the power information storage unit 18 and the power that can be supplied Compare the maximum values of. When the total value of power consumption is equal to or less than the maximum value of power that can be supplied, the power supply availability determination unit 17 determines that power can be supplied to the newly connected power receiving device 20, that is, power can be supplied. When the total value of power consumption is equal to or less than the maximum value of power that can be supplied, the power supply availability determination unit 17 determines that power cannot be supplied to a newly connected device.

  When determining whether or not power can be supplied, the power supply availability determination unit 17 sends information indicating whether or not power supply is possible to the power signal processing unit 16. When receiving the power supply availability information, the power signal processing unit 16 generates a power signal to be sent to the relay device 30 based on the received power availability information. When the power signal to be sent to the relay device 30 is generated, the power supply availability determination unit 17 sends the generated signal to the signal processing unit 14.

  When receiving the power signal, the signal processing unit 14 refers to the header to determine the transmission destination. When the transmission destination is the address “02” indicating the relay device 30, the signal processing unit 14 sends a power signal to the signal transformer 11 connected to the corresponding power receiving side port B.

  When the power supply side signal transformer 31 receives the power signal, the power supply side signal transformer 31 converts the received signal into a signal having a voltage for performing communication through the metallic communication line and outputs the signal. The power signal output from the signal transformer 11 is output from the power supply apparatus 10 to the metallic communication line via the power receiving side port B.

  The power signal output from the power supply apparatus 10 is transmitted through the metallic communication line and input to the power supply side port of the relay apparatus 30.

  The power signal input to the relay device 30 via the power supply side port is sent to the power supply side signal transformer 31. When the power supply side signal transformer 31 receives the power signal, the power supply side signal transformer 31 converts the received power signal into a voltage signal used in the relay device 30 and sends the signal to the power signal processing unit 32. Since the power signal processing unit 32 operates in the data transmission mode, when receiving the power signal, the power signal processing unit 32 outputs the received power signal to the power-receiving-side signal transformer 37. When receiving the power signal, the power-receiving-side signal transformer 37 converts the power signal into a voltage signal conforming to the communication standard, and outputs the power signal to the metallic communication line via the power-receiving-side port.

  The power signal output from the relay device 30 is transmitted through the metallic communication line and input to the power receiving device 20. The power signal input to the power receiving device 20 from the power supply side port is input to the signal transformer 21.

  When the power signal is input, the signal transformer 21 converts the power signal into a voltage signal used in the power receiving device 20 and sends the signal to the power signal processing unit 22. When the power signal processing unit 22 receives the power signal, the power signal processing unit 22 extracts power supply availability information from the received power signal, and confirms whether power supply from the power supply apparatus 10 is possible. When the power supply availability information indicates that power supply is possible, the power signal processing unit 22 operates in the data transmission mode.

  In addition, when the power signal processing unit 22 extracts the power supply availability information, the power signal processing unit 22 sends the extracted power availability information to the power distribution control unit 26. When the power distribution control unit 26 receives the power supply availability information, the power distribution control unit 26 confirms whether power supply from the power supply apparatus 10 is possible. When power can be supplied, the power distribution control unit 26 starts supplying power to the main circuit 23. When the supply of power to the main circuit 23 is started, the entire device of the power receiving device 20 becomes operable.

  When the power supply availability information indicates that power supply is not possible, the power distribution control unit 26 stops all power supply when confirming that power supply is not possible. Since all power supply from the power distribution control unit 26 to each part of the power receiving device 20 is stopped, the power receiving device 20 stops its operation and enters a shutdown state. The power receiving device 20 in the shutdown state receives the power supplied via the relay device 30 from the metallic communication line by reconnecting the power supply side port, and enters an initial state.

  When the relay device 30 and the power receiving device 20 are in a normal operation state, that is, in a state where all the functions are operating, the power receiving device 20 and the host device 40 that are operating by receiving power supply from the power supply device 10 Data communication is performed between them.

  In the communication system according to the present embodiment, when the relay device 30 is connected to the power supply device 10 via the metallic communication line, the relay device 30 uses the power signal processing unit 32 based on the power supplied from the power supply device 10. Only the power is operated, and the power consumption information is transmitted to the power supply apparatus 10. Since the power consumption information is transmitted by operating only the minimum functions necessary for transmitting the power consumption information, the power supply apparatus 10 consumes the relay apparatus 30 while avoiding a state where the power supply capacity is exceeded. Power information can be acquired.

  In addition, when the power supply apparatus 10 determines that power can be supplied to the relay apparatus 30, the power supply apparatus 10 transmits a power signal indicating that power can be supplied to the relay apparatus 30. When the relay device 30 receives information indicating that power supply is possible, the relay device 30 activates all the functions and starts supplying power to the power receiving device 20. By starting the supply of power to the relay device 30 in this way, when the relay device 30 is newly connected to the power supply device 10, power supply can be started without causing a shortage of power supply.

  When the power receiving device 20 is further connected to the relay device 30, the power receiving device 20 operates only the power signal processing unit 22 based on the power supplied from the relay device 30, and displays the power consumption information. 30 to the power supply apparatus 10. Since the power consumption information is transmitted by operating only the minimum functions necessary for transmitting the power consumption information, the power supply apparatus 10 consumes the power receiving apparatus 20 while avoiding a state where the power supply capacity is exceeded. Power information can be acquired.

  When the power supply apparatus 10 determines that power can be supplied to the power receiving apparatus 20, the power supply apparatus 10 transmits a power signal indicating that power can be supplied to the power receiving apparatus 20. When receiving the information indicating that power can be supplied, the power receiving device 20 sets all functions to the operating state. By starting the supply of power to the power receiving device 20 in this way, when the power receiving device 20 is newly connected via the relay device 30, it is possible to start feeding without causing a shortage of power supply. .

  In the communication system of the present embodiment, even when the power receiving device 20 and the relay device 30 are newly connected as described above, each device performs power reception start operation in a plurality of stages, resulting in insufficient power supply. It is possible to avoid a problem in the operation of the system. Therefore, the communication system of the present embodiment can continue data communication stably even when a new device is connected.

  In the communication system according to the present embodiment, power consumption information and power supply availability information are transmitted and received using an Ethernet frame. Therefore, in the communication system according to the present embodiment, it is possible to transmit and receive power consumption information and power supply availability information using a frame in the same format as the main signal used for data communication. Therefore, in the communication system of the present embodiment, transmission / reception of power consumption information and power supply availability information can be performed without requiring new equipment. As described above, the communication system according to the present embodiment can accurately grasp power consumption and perform stable power supply control without requiring complicated equipment even when power is supplied via a relay device. .

(Third embodiment)
A third embodiment of the present invention will be described in detail with reference to the drawings. FIG. 11 shows an outline of the configuration of the communication system of the present embodiment. In the communication system according to the second embodiment, the power signal processing unit of the power receiving apparatus operates in the data transmission mode during normal operation. The communication system according to the present embodiment is characterized in that the power signal processing unit continues processing even during normal operation and notifies the power supply apparatus of the operation state of the own apparatus.

  The communication system according to the present embodiment includes a power feeding device 50, a power receiving device 60, a relay device 30, and a host device 40. The communication system according to the present embodiment includes four power receiving devices 60 including a power receiving device 60-1, a power receiving device 60-2, a power receiving device 60-3, and a power receiving device 60-4. In addition, the communication system according to the present embodiment includes two relay apparatuses, a relay apparatus 30-1 and a relay apparatus 30-2. Each device is connected via a metallic communication line or the like as in the second embodiment. The number of power reception devices 60 and relay devices 30 may be other numbers.

  In the communication system of the present embodiment, the configurations of the relay device 30 and the higher-level device 40 are the same as those of the second embodiment.

  The configuration of the power feeding device 50 will be described. FIG. 12 shows a configuration of the power supply apparatus 50 of the present embodiment. The power supply device 50 includes a signal transformer 51, a power filter 52, a power supply unit 53, a signal processing unit 54, a higher-order signal transformer 55, a power signal processing unit 56, and a power supply availability determination unit 57. A power information storage unit 58 is provided. In addition, the power supply device 50 includes a higher-order port that performs connection with a signal line connected to the higher-order device 40. In addition, the power feeding device 50 includes a power receiving side port that performs connection with a metallic communication line connected to the power receiving device 60 or the relay device 30.

  The configurations and functions of the signal transformer 51, the power filter 52, the power supply unit 53, the higher-order signal transformer 55, and the power supply availability determination unit 57 of the present embodiment are the same as the parts having the same names in the second embodiment. .

  In addition to the same function as the signal processing unit 14 of the second embodiment, the signal processing unit 54 has a function of processing a power signal based on life / death monitoring information. The alive monitoring information refers to information that notifies the power supply apparatus 50 whether the power receiving apparatus 60 is operating normally or is in a stopped state. The signal processing unit 54 refers to the header of the frame input from the signal transformer 51 and confirms whether an identifier indicating life / death monitoring information of the power receiving device 60 is added to the header. When an identifier indicating alive monitoring information is added to the header, the signal processing unit 54 sends the alive monitoring information to the power signal processing unit 56.

  The power signal processing unit 56 has a function of performing alive monitoring of the power receiving device 60 in addition to the same function as the power signal processing unit 16 of the second embodiment. The power signal processing unit 56 determines that an abnormality has occurred in the power receiving device 60 when information indicating abnormality is sent as life / death monitoring information from the power receiving device 60. In addition, the power signal processing unit 56 confirms whether the life / death monitoring information is received within the reference time for the power receiving device 60 registered in the power information storage unit 58. The reference time is set in advance as a time for determining the connection state of the power receiving device 60 and the occurrence of an abnormality in the main body of the power receiving device 60. The reference time is set to be longer than the time interval at which the power receiving device 60 transmits the alive monitoring information.

  When the power signal processing unit 56 determines that an abnormality has occurred in the power receiving device 60, the power signal processing unit 56 deletes the information of the power receiving device 60 that has been determined to have an abnormality from the power information storage unit 58. Further, when the power signal processing unit 56 receives life / death monitoring information indicating that the power signal processing unit 56 is operating normally, the power signal processing unit 56 stores the received date / time information in the power information storage unit 58 and information on the identifier of the power receiving device 60 that is the transmission source. Save it in association. The identifier information of the power receiving device 60 that is the transmission source is set using the address of the power receiving device 60.

  In addition to the same information as in the second embodiment, the power information storage unit 58 has a function of storing information on the date and time when the alive monitoring information is received in association with the identifier information of the power receiving device 60.

  A configuration of the power receiving device 60 will be described. FIG. 13 shows the configuration of the power receiving device 60 of this embodiment. The power receiving device 60 includes a signal transformer 61, a power signal processing unit 62, a main circuit 63, a power filter 64, a power receiving unit 65, a power distribution control unit 66, an abnormality detection unit 67, and a charge / discharge. A circuit 68 is provided. In addition, the power receiving device 60 includes a power supply side port for connecting to a metallic communication line connected to the power supply device 50 or the relay device 30.

  The configurations and functions of the signal transformer 61, the main circuit 63, the power filter 64, and the power receiving unit 65 of the present embodiment are the same as the parts having the same names in the second embodiment.

  In addition to the same function as the power signal processing unit 22 of the second embodiment, the power signal processing unit 62 has a function of transmitting the operation state of the own device to the power supply device 50 as life / death monitoring information.

  When the power receiving device 60 is operating normally, the power signal processing unit 62 generates life / death monitoring information indicating that the power reception device 60 is normal every predetermined time, and supplies the power signal based on the life / death monitoring information to the power feeding device 50. Send to. The predetermined time for generating the life and death monitoring information is set in advance as an interval that does not affect the data communication processing due to the load increase while appropriately performing the life and death monitoring. The power signal processing unit 62 adds a header indicating life / death monitoring information to the header of the Ethernet frame, and transmits a power signal based on the life / death monitoring information.

  FIG. 14 schematically illustrates an example of a frame configuration sent from the power receiving device 60 to the power feeding device 50. The power signal of the second embodiment is set as a signal for notifying power consumption information and power supply availability information. However, in this embodiment, the power signal is further set as a signal for notifying alive monitoring information. In the case of a signal for notifying life / death monitoring information, information indicating that it is life / death monitoring information is added to the identifier area of the Ethernet frame. FIG. 14 shows an example in which the power signal identifier for notifying the power consumption information and the power supply availability information is set as “power 1”, and the identifier of the power signal for notification of alive monitoring information is set as “power 2”.

  When the abnormality detection unit 27 detects an abnormality, the power signal processing unit 62 generates life / death monitoring information indicating that an abnormality has occurred, and transmits a power signal based on the life / death monitoring information to the power supply apparatus 50.

  The power signal processing unit 62 operates based on the power supplied from the power distribution control unit 66 via the charge / discharge circuit 68. Therefore, even when the supply of power from the power distribution control unit 66 is stopped, the power signal processing unit 62 supplies life / death monitoring information indicating that an abnormality has occurred based on the power supplied from the charge / discharge circuit 68. Can be transmitted to the device 50. Further, the power signal processing unit 62 of the present embodiment continues the signal processing without operating as the data transmission mode even when the power supply availability information indicates that power supply is possible.

  The power distribution control unit 66 has the same function as the power distribution control unit 26 of the second embodiment. The power distribution control unit 66 of this embodiment supplies power to the power signal processing unit 62 via the charge / discharge circuit 68. When the power distribution control unit 66 receives information indicating that an abnormality has been detected from the abnormality detection unit 67, the power distribution control unit 66 stops supplying power to the power signal processing unit 62 and the main circuit 63.

  FIG. 15 schematically shows a power path when power is supplied in the power receiving device 60 of the present embodiment. In FIG. 15, the power path is indicated by broken-line arrows. As shown in FIG. 15, the power supplied from the power supply side port to the power receiving device 60 is received by the power receiving unit 65 via the power filter 64. The power receiving unit 65 sends the received power to the power distribution control unit 66. The power distribution control unit 66 supplies power to the power signal processing unit 62 and the main circuit 63 based on the power transmitted from the power receiving unit 65. The power distribution control unit 66 supplies power to the power signal processing unit 62 through the charge / discharge circuit 68.

  The abnormality detection unit 67 has a function of monitoring the operating state of the power receiving device 60 and detecting an abnormality. For example, the abnormality detection unit 67 determines that an abnormality has occurred when an overcurrent occurs in the power receiving device 60 or when a malfunction occurs in the operation of the main circuit 63. When detecting an abnormality, the abnormality detection unit 67 sends information indicating that an abnormality has occurred to the power signal processing unit 62 and the power distribution control unit 66.

  The charge / discharge circuit 68 has a function of storing power supplied from the power distribution control unit 66. When the supply of power from the power distribution control unit 66 is stopped, the charge / discharge circuit 68 causes the power signal processing unit 62 to send a power signal based on life / death monitoring information indicating that an abnormality has occurred to the power feeding device 50. It has a function of holding power necessary for transmission. For example, the charge / discharge circuit 68 includes a capacitor having a capacity capable of holding power necessary for the power signal processing unit 62 to transmit a power signal to the power supply apparatus 50. The charge / discharge circuit 68 may be configured using a secondary battery such as a lithium ion battery.

  The operation of the communication system of this embodiment will be described. In the communication system having the configuration illustrated in FIG. 11, a case will be described in which after feeding is started, the power feeding device 50 and the power receiving device 60-2 transmit and receive life / death monitoring information via the relay device 30-1. In the communication system of the present embodiment, the operation from the determination of whether power supply is possible based on the power consumption information to the start of power supply is the same as in the second embodiment. Therefore, hereinafter, only the operation when the power feeding apparatus 50 manages the life / death monitoring information of the power receiving apparatus by transmitting the life / death monitoring information from the power receiving apparatus 60-2 will be described. In the following description, the power receiving device 60-2 is represented as the power receiving device 60.

  When power is supplied from the power feeding device 50 to the power receiving device 60 via the relay device 30, the host device 40 and the power receiving device 60 transmit and receive data via the power feeding device 50 and the relay device 30. During normal operation, the power signal processing unit 62 of the power receiving device 60 sends a power signal based on life / death monitoring information indicating the operating state of the power receiving device 60 to the power feeding device 50 at predetermined time intervals. When the power receiving device 60 is operating normally during normal operation, the power signal processing unit 62 generates a power signal based on life / death monitoring information indicating that the power receiving device 60 is operating normally every predetermined time. Send to 50.

  In addition, during normal operation, the abnormality detection unit 67 of the power receiving device 60 monitors the operation state of the power receiving device 60 and checks whether there is an abnormality. When detecting the abnormality, the abnormality detecting unit 67 sends information indicating that the abnormality has been detected to the power signal processing unit 62 and the power distribution control unit 66.

  When the power distribution control unit 66 receives information indicating an abnormality from the abnormality detection unit 67, the power distribution control unit 66 stops supplying power to the power signal processing unit 62 and the main circuit 63. When the supply of power to the power signal processing unit 62 and the main circuit 63 is stopped, the power receiving device 60 is in a state where it does not receive the supply of power from the power supply device 50 via the relay device 30.

  When the supply of power from the power distribution control unit 66 is stopped, the main circuit 63 stops operating. In addition, the power signal processing unit 62 is supplied with power by the discharge of the charge / discharge circuit 68 and continues the operation state.

  When the power signal processing unit 62 receives the information detecting the abnormality from the abnormality detection unit 67, the power signal processing unit 62 generates life and death monitoring information indicating that an abnormality has occurred. When generating the life / death monitoring information indicating that an abnormality has occurred, the power signal processing unit 62 transmits the generated life / death monitoring information to the power supply apparatus 50 based on the power supplied by the charging / discharging circuit 68 by discharging. After the power signal processing unit 62 transmits a power signal based on life and death monitoring information indicating that an abnormality has occurred, when all the power stored in the charge / discharge circuit 68 is discharged, the power receiving device 60 stops its operation. And enters the shutdown state.

  A power signal based on the alive monitoring information transmitted from the power receiving device 60 is sent to the power supply device 50 via the relay device 30.

  A power signal based on the life and death monitoring information input to the power feeding device 50 is input to the signal processing unit 54 via the signal transformer 51. When the signal processing unit 54 monitors the header of the input frame and detects that it is a power signal based on life / death monitoring information, the signal processing unit 54 outputs the received power signal to the power signal processing unit 56.

  When the power signal processing unit 56 receives the power signal based on the alive monitoring information, the power signal processing unit 56 extracts the alive monitoring information and determines the operating state of the power receiving device 60. When the power receiving device 60 is operating normally, the power signal processing unit 56 stores the date and time when the life / death monitoring information is received in the power information storage unit 58 in association with the identifier information of the power receiving device 60. When the date and time when the alive monitoring information is received is stored, the power signal processing unit 56 stands by until the next signal is input.

  When the life / death monitoring information includes information indicating that an abnormality has occurred in the power receiving device 60, the power signal processing unit 56 deletes the information of the power receiving device 60 stored in the power information storage unit 58. When the information of the power receiving device 60 in which an abnormality has occurred is deleted, the power signal processing unit 56 deletes information that matches the address of the power receiving device 60 that is the source of alive monitoring information from the power information storage unit 58.

  Since the information of the power receiving device 60 in which power supply has been stopped due to an abnormality being detected has been deleted from the power information storage unit 58, the power supply availability determination unit 57 newly receives the power reception in which an abnormality has occurred when determining whether power supply is possible. The total power consumption value is calculated excluding the power consumption of the device 60.

  FIG. 16 schematically illustrates a power signal path based on life / death monitoring information that can be sent from each power receiving device 60 to the power feeding device 50 via the relay device 30 in the communication system according to the present embodiment. As illustrated in FIG. 16, the power feeding device 50 collects life / death monitoring information from the power receiving device 60 directly or via the relay device 30. By collecting the alive monitoring information from each power receiving device 60, the power feeding device 50 can more appropriately control power feeding.

  The communication system of this embodiment has the same effect as the communication system of the second embodiment. Further, the power supply device 50 of the communication system according to the present embodiment can more accurately recognize the total power consumption of each device by obtaining the operating state of the power receiving device 60 as life / death monitoring information. For this reason, the communication system according to the present embodiment can exclude power consumption of the power receiving device 60 that is not operating when determining whether or not power can be supplied. Therefore, the power supply can be efficiently controlled based on the operating state of the power receiving device 60. Can do.

  In the communication systems of the second and third embodiments, data is transmitted and received between the host device and the power receiving device via the power supply device and the relay device, but data may be transmitted and received between the power receiving devices. . When data is transmitted and received between power receiving apparatuses, the power supply apparatus and the relay apparatus each have a switch function and a router function.

  In the communication system of the third embodiment, life / death monitoring information is transmitted from the power receiving device 60 to the power feeding device 50. In addition to such a configuration, alive monitoring information may be transmitted to the power feeding device 50 from a relay device having an abnormality detection function. The life and death monitoring information is also transmitted from the relay device to the power supply device 50, so that the power supply device 50 can accurately calculate the total value of power consumption even when an abnormality occurs in the relay device. As a result, the power feeding device 50 can more efficiently control power feeding based on the operation state of the relay device. In addition, when the life and death monitoring information is transmitted from the relay device to the power feeding device 50, for example, the relay device is configured to include a charge / discharge circuit similarly to the power receiving device 60, so that the relay device is abnormally connected. The life / death monitoring information can be transmitted even when the service is stopped.

DESCRIPTION OF SYMBOLS 1 Power supply means 2 Communication means 3 Information acquisition means 4 Judgment means 5 Judgment result transmission means 10 Power supply apparatus 11 Signal transformer 12 Power filter 13 Power supply section 14 Signal processing section 15 Upper signal transformer 16 Power signal processing section 17 Power supply determination unit 18 Power information storage unit 20 Power receiving device 21 Signal transformer 22 Power signal processing unit 23 Main circuit 24 Power filter 25 Power power receiving unit 26 Power distribution control unit 30 Relay device 31 Power supply side signal transformer 32 Power signal processing Unit 33 Main circuit 34 Power-feed-side power filter 35 Power-receiving unit 36 Power distribution control unit 37 Power-receiving-side signal transformer 38 Power-receiving-side power filter 39 Power supply unit 40 Host device 50 Power-feed device 51 Signal transformer 52 Power filter 53 Power supply unit 54 Signal processing unit 55 56 Power signal processing unit 57 Power supply availability determination unit 58 Power information storage unit 60 Power receiving device 61 Signal transformer 62 Power signal processing unit 63 Main circuit 64 Power filter 65 Power power receiving unit 66 Power distribution control unit 67 Abnormality detection unit 68 Charging Discharge circuit

Claims (10)

Power supply means for supplying power to the relay device via the first signal line having conductivity;
Communication means for transmitting and receiving data to and from the relay device operating based on the power supplied by the power supply means, via the first signal line;
Means for acquiring power consumption information of the relay device from the relay device; means for acquiring power consumption information of a power receiving device operating based on power supplied from the relay device via the relay device; An information acquisition means comprising:
Based on the power consumption of the relay device acquired by the information acquisition means and the power value that can be supplied by the own device, means for determining whether or not power can be supplied to the relay device; and the information acquired by the information acquisition means A determination unit having a unit for determining whether or not to supply power to the power receiving device based on a total value of power consumption of the relay device and the power consumption of the power receiving device, and a power value that can be supplied by the own device;
Means for transmitting to the relay device information indicating whether or not power can be supplied to the relay device determined by the determination device based on the power consumption of the relay device; and A determination result transmitting unit comprising: a unit configured to transmit information indicating whether power can be supplied to the power receiving device determined based on a total power consumption of the power receiving device to the power receiving device via the relay device;
Equipped with a,
The information acquisition unit determines that the determination unit determines that power can be supplied to the relay device, and the determination result transmission unit transmits information indicating that power can be supplied to the relay device to the relay device. After the transmission, information on power consumption of the power receiving device connected to the relay device is acquired . The communication means performs data transmission / reception with each of the plurality of power receiving devices,
The information acquisition means acquires power consumption information for each of the power receiving devices from each of the plurality of power receiving devices,
When the information on the power consumption is newly sent from any one of the power receiving devices, the determining means determines that the power consumption of the relay device and the total power consumption of all the power receiving devices are Based on the power value that can be supplied, determine whether power can be supplied to the power receiving device that is the transmission source of the information on the power consumption that has been newly sent,
2. The power supply apparatus according to claim 1, wherein the determination result transmission unit transmits power supply availability information to the power receiving apparatus that is a transmission source of the newly transmitted power consumption information. The determination means does not add the power consumption value of the power receiving device that has transmitted the information detecting the abnormality when calculating the total power consumption of the relay device and the power consumption of all the power receiving devices. The power feeding apparatus according to claim 2, wherein First communication means for transmitting and receiving data to and from the power feeding device via the first signal line having conductivity;
Second communication means for transmitting and receiving data to and from the power receiving device via the second signal line having conductivity;
A relay device power receiving means for receiving power supplied from the power supply device via the first signal line;
Power supply means for supplying power to the power receiving device via the second signal line based on the power received by the relay device power receiving means;
Data relay means for relaying data transmitted and received between the power receiving device and the power feeding device;
Information on the power consumption of the own device is transmitted to the power supply device, information on whether or not power can be supplied to the own device is acquired from the power supply device, and the power consumption sent from the power receiving device connected to the own device. Power supply information acquisition means having means for transmitting information to the power supply apparatus and acquiring information on whether or not power supply to the power reception apparatus is possible from the power supply apparatus ;
When indicating that the information of the power supply permission obtained from the power feeding device can be powered to its own device, wherein to receive power for operating the functions of the apparatus required for the supply of power to the power receiving device a power supply control means that Gyosu control relay device receiving means,
Equipped with a,
The power supply information acquisition unit transmits the power from the power receiving device connected to the own device when the relay device power receiving unit starts to receive power for operating the function of the own device necessary for supplying power to the power receiving device. A relay device that transmits the received power consumption information to the power feeding device. Power receiving means for receiving power supplied from the relay device via the second signal line having conductivity;
Data communication means for transmitting and receiving data to and from the relay device via the second signal line based on the power received by the power receiving means;
When the relay device starts operation of a function necessary for power supply, information on the power consumption of the own device is transmitted to the power supply device via the relay device, and information on whether power supply to the own device is possible, Power supply availability information acquisition means for acquiring from the power supply device via the relay device;
When the power supply availability information acquired from the power supply device indicates that power supply is possible, a power supply control unit that controls the power reception unit to receive power for operating all the functions of the device,
A power receiving device comprising:   The power supply control means controls the power reception means to stop receiving power when the power supply availability information acquisition means acquired from the power supply apparatus indicates that the power supply availability information indicates that power supply is not possible. The power receiving device according to claim 5, wherein the power receiving device is a power receiving device. Power storage means for storing the power received by the power receiving means;
An anomaly detecting means for detecting an anomaly of the own device;
Further comprising
The power supply control means controls the power receiving means to stop receiving power when the abnormality detecting means detects an abnormality, and the power supply availability information acquiring means is a power stored in the power storage means. The power receiving device according to claim 5, wherein information indicating that an abnormality has occurred is transmitted to the power feeding device based on the information. A power feeding device according to any one of claims 1 to 3,
The relay device according to claim 4, wherein the relay device is connected to the power feeding device via a first signal line having conductivity.
The power receiving device according to any one of claims 5 to 7, wherein the power receiving device is connected to the relay device through a second signal line having conductivity.
With
The power receiving device transmits information on power consumption of the power receiving device to the power feeding device via the relay device,
The power supply device determines whether or not power can be supplied to the power receiving device based on a total value of power consumption of the relay device and power consumption of the power receiving device and a power value that can be supplied by the power device. A communication system, wherein information indicating whether power can be supplied to the device is transmitted via the relay device. The relay device transmits power consumption information of the relay device to the power supply device, and when receiving information indicating that power can be supplied from the power supply device, starts power supply to the power reception device,
The communication according to claim 8, wherein the power receiving device transmits information on power consumption of the power receiving device to the power feeding device based on the power supplied from the power feeding device via the relay device. system. In the power feeding device,
Supplying power to the relay device via the first signal line having conductivity;
Obtaining information on the power consumption of the relay device from the relay device,
Based on the power consumption of the relay device and the power value that can be supplied by the own device, it is determined whether power can be supplied to the relay device,
When power supply to the relay device is possible, information on the power consumption of the power receiving device that operates based on the power supplied from the relay device is acquired via the relay device,
Based on the acquired power consumption of the relay device and the total power consumption of the power receiving device, and the power value that can be supplied by the device itself, determine whether power can be supplied to the power receiving device,
A power feeding method, wherein information indicating whether or not the determined power supply to the power receiving device is possible is transmitted to the power receiving device via the relay device.

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