WO2022210572A1 - Power reception device and power reception system - Google Patents

Abstract

The present invention addresses the problem of providing a power reception device and a power reception system which make it possible to reduce the possibility that power supply from a DC power source will be stopped. A power reception device (1) comprises a first terminal (11), second terminal (12), a converter (13), a voltage detection unit (14), and an output control unit (15). The first terminal (11) is connected to a DC bus (4) to which DC power is supplied from a DC power source (3). The second terminal (12) is connected to a load (5). The converter (13) converts at least one of a voltage and an electric current which is input from the DC bus (4), and outputs the converted voltage and/or current to the load (5). The voltage detection unit (14) detects the input voltage of the first terminal (11). The output control unit (15) controls the output power of the converter (13) on the basis of the input voltage which has been detected by the voltage detection unit (14). Specifically, the output control unit (15) starts suppression of the output power when the input voltage is less than or equal to a first setting voltage, and stops suppressing the output power when the input voltage is greater than or equal to a second setting voltage which is greater than the first setting voltage.

Description

Power receiving device and power receiving system

The present disclosure relates to a power receiving device and power receiving system, and more particularly to a power receiving device and power receiving system for controlling output power to a load.

The wiring duct connection member described in Patent Document 1 is characterized by having a connecting portion that is electrically connected to a conductor provided in the wiring duct as it is inserted into the wiring duct.

With the wiring duct connecting member as described in Patent Document 1, there was a demand to prevent the power supply from the power supply from stopping due to excessive power supplied to the load by the wiring duct connecting member.

JP 2012-238517 A

The present disclosure is made in view of the above reasons, and aims to provide a power receiving device and a power receiving system that can reduce the possibility that power supply from a DC power supply will stop.

A power receiving device according to one aspect of the present disclosure includes a first terminal, a second terminal, a converter, a voltage detection section, and an output control section. The first terminal is connected to a DC bus supplied with DC power from a DC power supply. A load is connected to the second terminal. The converter converts at least one of voltage and current input from the DC bus and outputs the converted voltage to the load. The voltage detection section detects an input voltage of the first terminal. The output control section controls output power of the converter based on the input voltage detected by the voltage detection section. The output control unit starts suppressing the output power when the input voltage becomes equal to or less than a first set voltage, and the input voltage becomes equal to or greater than a second set voltage that is higher than the first set voltage. In this case, the suppression of the output power is stopped.

A power receiving system according to one aspect of the present disclosure includes one or more power receiving devices, and a DC bus to which DC power is supplied from a DC power supply. The one or more power receiving devices are connected to the DC bus.

FIG. 1 is a schematic circuit diagram of a power receiving system according to an embodiment. FIG. 2 is a schematic perspective view of the same power receiving system. FIG. 3 is a side cross-sectional view of a DC bus and a power receiving device included in the power receiving system. FIG. 4 is an exploded perspective view of a main part of the power receiving system of the same. FIG. 5 is a schematic perspective view of a DC bus and a power receiving device included in the power receiving system; FIG. 6 is a flow chart for explaining an output power suppression operation in the power receiving system. FIG. 7 is an explanatory diagram for explaining the suppression operation of the output power in the first state of the power receiving system of the same. FIG. 8 is a graph showing an example of temporal changes in input power, output power, and input voltage in the same power receiving system. FIG. 9 is an explanatory diagram for explaining the suppression operation of the output power in the second state of the power receiving system.

A power receiving device 1 according to an embodiment of the present disclosure and a power receiving system 2 including the power receiving device 1 will be described in detail with reference to the drawings. Note that the embodiments and modifications described below are merely examples of the present disclosure, and the present disclosure is not limited to the embodiments and modifications. Other than this embodiment and modifications, various modifications can be made according to the design and the like within the scope of the technical idea of the present disclosure. Each drawing described in the following embodiments is a schematic drawing, and the ratio of the size and thickness of each component in the drawing does not necessarily reflect the actual dimensional ratio. . Moreover, the following embodiments (including modifications) may be combined as appropriate and implemented.

(1) Overview A power receiving system 2 according to the present embodiment includes one or more power receiving devices 1 and a DC bus 4 to which DC power is supplied from a DC power supply 3, as shown in FIG. One or more power receiving devices 1 are connected to the DC bus 4 .

The power receiving device 1 includes a first terminal 11 , a second terminal 12 , a converter 13 , a voltage detection section 14 and an output control section 15 . A first terminal 11 is connected to the DC bus 4 . A load 5 is connected to the second terminal 12 . The converter 13 converts at least one of voltage and current input from the DC bus 4 and outputs the converted voltage to the load 5 . The voltage detection section 14 detects the input voltage Vin of the first terminal 11 . Output control unit 15 controls output power Pout of converter 13 based on input voltage Vin detected by voltage detection unit 14 . Specifically, when the input voltage Vin becomes equal to or lower than the first set voltage V1, the output control unit 15 starts suppressing the output power Pout and sets the second set voltage where the input voltage Vin is higher than the first set voltage V1. When the voltage becomes equal to or higher than V2, suppression of the output power Pout is stopped. It should be noted that "stop" referred to here may be a temporary stop (suspension) or an end.

When the output power Pout to the load 5 connected to the DC bus 4 becomes larger than the rated power of the DC power supply 3, the input voltage Vin drops. In this embodiment, since the output power Pout is suppressed when the input voltage Vin becomes equal to or lower than the first set voltage V1, it is possible to suppress the input voltage Vin from becoming unstable. Moreover, this can prevent the output power Pout from becoming excessively large, and can reduce the possibility that the power supply from the DC power supply 3 to the DC bus 4 will stop.

(2) Details (2.1) Overall Configuration Hereinafter, the configuration of the power receiving system 2 according to the present embodiment will be described in detail with reference to FIGS. 1 to 5. FIG. Note that the numerical values, shapes, positions of constituent elements, positional relationships and connection relationships among a plurality of constituent elements, and the like shown below are examples, and are not intended to limit the present disclosure. Also, the drawings referred to below are all schematic drawings, and the size and length of each component in the drawings do not necessarily reflect the actual dimensions. 3 to 5, the arrows representing the front/rear, left/right, and up/down directions are only shown for the sake of explanation, and are not substantial.

The power receiving system 2 includes a DC bus 4 and one or more (three in this embodiment) power receiving devices 1 connected to the DC bus 4, as shown in FIGS. Furthermore, in this embodiment, the power receiving system 2 includes a DC power supply 3 such as an AC adapter that supplies DC power to the DC bus 4 . A DC power supply 3 such as an AC adapter converts AC power supplied from an AC power supply 6 into DC power and supplies the DC power to a DC bus 4 .

The DC bus 4 has a main body 41, two conductive bars (first conductive bar 42A and second conductive bar 42B), and a power supply member 43, as shown in FIG.

The main body 41 is formed in the shape of an elongated rectangular parallelepiped, and a groove 413 extending in the longitudinal direction is provided on one surface of the main body 41 . A power receiving device 1 , which will be described later, can be connected to any position in the longitudinal direction of the groove 413 , and the power receiving device 1 is supplied with DC power from the groove 413 . The main body 41 includes a metal first rail 411 and two synthetic resin second rails 412 . The first rail 411 includes two fitting portions 4111, and the two fitting portions 4111 are fitted with two mounting protrusions 18 of the power receiving device 1, which will be described later. The cross section of the body 41 perpendicular to the longitudinal direction of the DC bus 4 is C-shaped, and the interior of the C-shaped body 41 serves as the groove 413 .

The first conductive bar 42A and the second conductive bar 42B are plate-shaped members extending in the longitudinal direction of the DC bus 4, respectively, and are held by the two second rails 412 respectively. The first conductive bar 42A is electrically connected to the positive electrode of the DC power supply 3 . The second conductive bar 42B is electrically connected to the negative pole of the DC power supply 3 .

The power supply member 43 is located at the longitudinal end of the DC bus 4 as shown in FIGS. The power supply member 43 has a main body 431 , a wire entry hole 432</b>A, a wire entry hole 432</b>B, and a cover 433 . An electric wire 31A connected to the positive electrode of the DC power supply 3 is inserted into the wire entry hole 432A. The electric wire 31A is electrically connected to the first conductive bar 42A through the wire entry hole 432A. An electric wire 31B connected to the negative electrode of the DC power supply 3 is inserted into the wire entry hole 432B. The electric wire 31B is electrically connected to the second conductive bar 42B through the wire entry hole 432B. A cover 433 houses the main body 431 .

The power receiving device 1 has a housing 16 as shown in FIG.

The shape of the housing 16 is, for example, a rectangular parallelepiped. The housing 16 has an insertion port 162 on a surface 161 opposite to the surface on which the DC bus 4 is attached, for example. The receptacle 162 is a receptacle for a connector 51 (see FIG. 1) provided on the electric wire of the load 5 . In the present embodiment, the power receiving system 2 will be described with an example in which the connector 51 is a USB plug. That is, in this embodiment, the socket 162 is a USB outlet. Note that the connector 51 is not limited to a USB plug, and may be a power plug or the like. If the connector 51 is a power plug, the receptacle 162 is a power outlet.

The power receiving device 1 further includes a cylindrical portion 20, two mounting projections 18, two power receiving terminals 19, and a release operation portion 17, as shown in FIG.

The tubular part 20 is cylindrical and protrudes rearward from the rear surface of the housing 16 . The tubular portion 20 is inserted into the groove portion 413 of the DC bus 4 .

Two mounting protrusions 18 protrude in opposite directions from the peripheral surface of the tubular portion 20 .

Here, how to attach the power receiving device 1 and the DC bus 4 will be described. First, the tubular portion 20 of the power receiving device 1 is inserted into the groove portion 413 so that the two mounting projections 18 protrude along the longitudinal direction of the groove portion 413 of the DC bus. Next, the power receiving device 1 is rotated by 90 degrees around the axis of the tubular portion 20 . As a result, the two fitting portions 4111 provided on the main body 41 of the DC bus 4 and the two mounting protrusions 18 are respectively fitted, and the power receiving device 1 is held in the groove portion 413 of the DC bus 4 .

The two power receiving terminals 19 protrude rearward from the rear surface of the housing 16 . Each tip of the two power receiving terminals 19 is bent. In a state in which the power receiving device 1 is held in the groove portion 413 of the DC bus 4, the power receiving terminal 19 on the positive side of the two power receiving terminals 19 is connected to the first conductive bar 42A on the positive side, and the power receiving terminal 19 on the negative side is connected to the first conductive bar 42A. It is connected to the second conductive bar 42B on the negative electrode side. As a result, the power receiving device 1 is electrically connected to the DC bus 4 and supplied with DC power from the DC power supply 3 via the DC bus 4 . Then, when the connector 51 provided on the electric wire of the load 5 is connected to the insertion port 162 of the power receiving device 1 , DC power is supplied from the DC bus 4 to the load 5 via the power receiving device 1 . In addition, the kind of the load 5 is not specifically limited. Examples of the load 5 include computer terminals (personal computers, smartphones, tablet terminals, etc.), computer terminal attachments (monitors, speakers, microphones, etc.), lighting equipment (desk lights, etc.), network cameras, sensors (temperature sensors, humidity sensors, illuminance sensors, etc.), game machines and air conditioners (desktop fans, etc.).

The release operation section 17 is held by the housing 16 . The release operation part 17 can move in a predetermined direction by applying a force. A restoring force of a spring housed in the housing 16 acts on the release operation portion 17 . Therefore, when the power receiving device 1 is held in the groove 413 of the DC bus 4 and no force is applied to the release operation portion 17, the distal end portion (claw portion 171) of the release operation portion 17 does not touch the housing. 16 and inserted into the groove 413 of the DC bus 4 . As a result, the casing 16 (power receiving device 1 ) is restricted from rotating about the axis of the cylindrical portion 20 , and is restricted from being removed from the DC bus 4 . When the release operation portion 17 is pushed forward, the tip portion (claw portion 171 ) of the release operation portion 17 comes out of the groove portion 413 , so that the casing 16 (power receiving device 1 ) is rotated with respect to the DC bus 4 . be able to. In this state, when the power receiving device 1 is rotated by 90 degrees around the axis of the cylindrical portion 20, the projecting directions of the two mounting projections 18 are aligned with the longitudinal direction of the groove portion 413 of the DC bus. As a result, the tubular portion 20 of the power receiving device 1 can be pulled out from the groove portion 413 and the power receiving device 1 can be removed from the DC bus 4 .

In addition, in the present embodiment, the power receiving device 1 has a power conversion unit 10 as shown in FIG. Power conversion unit 10 controls the value of output power Pout from power receiving device 1 to load 5 connected to receptacle 162 .

The power conversion unit 10 includes, for example, two first terminals 11, for example, two second terminals 12, a converter 13, a voltage detection unit 14, an output control unit 15, and a storage unit 101.

The two first terminals 11 are connected to the two power receiving terminals 19 respectively. That is, the two first terminals 11 are electrically connected to the DC bus 4 via the two power receiving terminals 19 .

The two second terminals 12 are respectively connected to a power supply terminal and a ground terminal provided inside a receptacle 162 which is, for example, a USB outlet. Here, the power terminal and ground terminal are terminals that are connected to the power line and ground line of the connector 51 (USB terminal) when the connector 51 (USB terminal) of the load 5 is connected to the insertion port 162 . be. That is, the two second terminals 12 are electrically connected to the load 5 via the power supply terminal and the ground terminal.

The converter 13 is connected to the two first terminals 11 and controls DC power (output power Pout) by DC-DC converting at least one of the voltage and current input from the DC bus 4 . Converter 13 is also connected to two second terminals 12 and outputs output power Pout to load 5 .

The voltage detection unit 14 detects the input voltage Vin between the two first terminals 11 and outputs a signal SigVin indicating the detected input voltage Vin to the output control unit 15, as shown in FIG.

The output control unit 15 controls the output power Pout that the converter 13 outputs to the load 5 based on the value of the input voltage Vin indicated by the received signal SigVin. Specifically, when the input voltage Vin becomes equal to or lower than the first set voltage V1, the output control unit 15 starts suppressing the output power Pout and sets the second set voltage where the input voltage Vin is higher than the first set voltage V1. When the voltage becomes equal to or higher than the voltage V2, the suppression of the output power Pout is interrupted.

The storage unit 101 stores set values such as a first set voltage V1, a second set voltage V2, and a first set time T10 described later. The storage unit 101 includes a rewritable non-volatile memory such as EEPROM (Electrically Erasable Programmable Read-Only Memory) and flash memory.

The control operation of the output power Pout by the power conversion unit 10 will be described in detail in "(2.2) Output power suppression operation".

In this embodiment, the power receiving device 1 further includes a notification unit 102 . The power receiving device 1 further includes a display unit 103 . Notification unit 102 notifies that output control unit 15 is suppressing output power Pout. The display unit 103 is a light-emitting device including, for example, a multicolor light-emitting LED (Light Emitting Diode), and the lighting state of the display unit 103 is controlled by the notification unit 102 . The notification unit 102 notifies that the output control unit 15 is suppressing the output power Pout by changing the lighting state of the display unit 103, for example.

(2.2) Suppression Operation of Output Power The control operation of the output power Pout by the power receiving system 2 of the present embodiment will be described with reference to the flow charts of FIGS. 6 and 7 to 9. FIG.

First, as shown in FIG. 7, two power receiving devices 1 (power receiving device 1A and power receiving device 1B) are connected to a DC bus 4, and two loads 5 (load 5A and load 5B) are connected to the power receiving device 1A and power receiving device 1B. ) are respectively connected (first state X1). A DC power supply 3 is connected to the DC bus 4 , and the DC power supply 3 supplies DC power (input power Pin) to the DC bus 4 .

In the first state X1, the DC power supply 3 can supply a maximum input power Pin of 100 W to the DC bus 4, but if the power consumption of the load 5 is lower than the rated power (eg 100 W), the power consumption of the load 5 The corresponding input power Pin is supplied to the DC bus 4 . Here, as shown in FIG. 8, output power Pout (first output power PoutA) of 40 W, for example, is supplied to load 5A from DC bus 4 via power receiving device 1A. In other words, the converter 13 (converter 13A) included in the power receiving device 1A outputs the first output power PoutA of 40 W to the load 5A. For example, output power Pout (second output power PoutB) of 40 W is supplied to load 5B from DC bus 4 via power receiving device 1B. In other words, the converter 13 (converter 13B) included in the power receiving device 1B outputs the second output power PoutB of 40 W to the load 5B. That is, the input power Pin is 80 W, which is the sum of the first output power PoutA and the second output power PoutB. Therefore, the first state X1 is a state in which the DC power supply 3 supplies the DC bus 4 with the input power Pin of 80 W, which is less than the rated power (for example, 100 W). In this embodiment, when the power consumption of the load 5 becomes larger than the rated power (for example, 100 W) of the DC power supply 3, the power supply capacity of the DC power supply 3 becomes insufficient, and the input applied to the power receiving device 1 from the DC bus 4, for example, A decrease in the voltage Vin or the like may occur. Moreover, in this embodiment, when the power consumption of the load 5 becomes larger than the maximum allowable power (for example, 120 W) of the DC power supply 3, the DC power supply 3 may stop supplying power.

As shown in FIG. 8, in the first state X1, the DC bus 4 applies a voltage of, for example, 24 V (input voltage Vin) to the two first terminals 11 of each of the power receiving device 1A and the power receiving device 1B. FIG. 8 is a graph showing changes over time in the input power Pin supplied to the DC bus 4 by the DC power supply 3 and changes over time in the input voltage Vin. Time t0 is an arbitrary time in the first state X1.

Next, assume a state (second state X2) in which another power receiving device 1 (power receiving device 1C) and another load 5 (load 5C) are connected to the DC bus 4.

When the power receiving device 1C to which the load 5C is connected is connected to the DC bus 4 at time t1, for example, 10 minutes after time t0, the DC bus 4 is connected to the load 5C via the power receiving device 1C as shown in FIG. Supply of output power Pout (third output power PoutC) is started. That is, the converter 13 (converter 13C) included in the power receiving device 1C starts supplying the third output power PoutC to the load 5C. As a result, output of the third output power PoutC is started from time t1 as shown in FIG. Along with this, the input power Pin, which is the sum of the first output power PoutA, the second output power PoutB, and the third output power PoutC, starts increasing from 80W from time t1.

At time t2, for example, 2 minutes and 30 seconds after time t1, when the input power Pin exceeds 100 W, which is the rated power of the DC power supply 3, the DC power supply 3 cannot maintain a constant input voltage Vin, and the input voltage Vin is 24V. starts to decrease (ST1). In the second state X2, the DC bus 4 applies the input voltage Vin to the two power receiving terminals 19 of each of the power receiving devices 1A to 1C. The input voltage Vin is detected by the voltage detection unit 14 (voltage detection unit 14A to voltage detection unit 14C) provided in each of the power receiving devices 1A to 1C. The voltage detection unit 14A to voltage detection unit 14C output a signal SigVin indicating the detection result of the input voltage Vin to the output control unit 15 (output control unit 15A to output control unit 15C) provided in each of the power receiving devices 1A to 1C. do. Based on the value of the input voltage Vin indicated by the received signal SigVin, each of output control unit 15A to output control unit 15C outputs first output power PoutA to third Control the output power PoutC.

At time t3, which is, for example, 5 minutes after time t1 (2 minutes and 30 seconds after time t2), the input voltage Vin decreases to the first set voltage V1, for example 23 V, as shown in FIG. 8 (ST2: YES). Then, when the third output power PoutC increases to, for example, 40 W, the output control unit 15C controls the converter 13C to start suppressing the third output power PoutC (ST3). Note that the input power Pin becomes 120 W at time t3, for example. Since the output control unit 15C starts suppressing the third output power PoutC, the third output power PoutC and the input power Pin start decreasing from time t3. Along with this, the input voltage Vin starts increasing from time t3.

Here, the value of the first set voltage V1 is, for example, 23 V during the first set time T10, which is, for example, 10 minutes after the converter 13 starts supplying power to the load 5 connected to the second terminal 12. It is a certain first set value V11, and after the first set time T10 has passed since the converter 13 starts supplying power to the load 5 connected to the second terminal 12, it is a second set value V12, which is, for example, 22 V. . Note that in the present embodiment, the power receiving device 1 and the load 5 communicate with each other, and information on the time when power supply to the load 5 is started is stored in the storage unit 101 of the power receiving device 1 . Also, the elapsed time from the start of power supply to the load 5 is measured by the clock function of the output control unit 15 of the power receiving device 1, for example. As a result, as shown in FIG. 8, the first set voltage V1 set in the output controller 15C is 23 V for 10 minutes after the converter 13C starts supplying power to the load 5C at time t1. Therefore, as described above, when the input voltage Vin decreases to 23 V at time t3, five minutes after time t1, the output controller 15C starts suppressing the third output power PoutC. Further, the converters 13A and 13B have started supplying power to the loads 5A and 5B, respectively, before time t0, and 15 minutes or more have passed since the power supply started at time t3. The first set voltage V1 set to each of the output control units 15B is 22V. Therefore, when the input voltage Vin decreases to 23 V at time t3, as shown in FIG. 8, the output controllers 15A and 15B do not start suppressing the first output power PoutA and the second output power PoutB. As a result, among the plurality of loads 5 connected to the DC bus 4, the output power Pout of the load 5 connected later, such as the load 5C, can be preferentially suppressed. Note that the power consumption of the load 5 generally tends to be greater immediately after the start of power supply than after that, and the value of the first set time T10 is such that the power consumption immediately after the start of power supply increases. It is preferable to set the time to be longer than the time to be set.

Next, at time t4 after, for example, five minutes from time t3, the input voltage Vin increases to the second set voltage V2, for example 24 V (ST4: YES), and the third output power PoutC decreases to, for example, 20 W. , the output control unit 15C suspends suppression of the third output power PoutC (ST5). At time t4, the input power Pin becomes 100 W as shown in FIG. Note that the first set value V11 is higher than the second set value V12 and lower than the value of the second set voltage V2. When the output control unit 15C stops suppressing the third output power PoutC at time t4, the third output power PoutC and the input power Pin start increasing again, and accordingly the input voltage Vin starts decreasing again.

Here, the value of the first set voltage V1 is changed during the second set time T20, which is, for example, 15 minutes after the converter 13 increases the output power Pout supplied to the load 5 connected to the second terminal 12. For example, the first set value V11 is 23 V, and after the second set time T20 has elapsed after the converter 13 increases the output power Pout supplied to the load 5 connected to the second terminal 12, the first set value V11 is 22 V, for example. 2 is the set value V12. Here, when the period of the second set time T20 after the output power Pout starts to increase overlaps with the period after the first set time T10 or more has passed since the start of power supply to the load 5, the first set time As for the value of the voltage V1, the first set value V11 is preferentially set over the second set value V12. That is, for 15 minutes after the converter 13C increases the third output power PoutC at time t4, the first set voltage V1 that the output control unit 15C uses as a reference for starting suppression of the third output power PoutC is 23V. . Therefore, when the input voltage Vin decreases to 23 V again at time t5 after 10 minutes from time t4, the output controller 15C resumes suppression of the third output power PoutC. At time t5, the third output power PoutC is 40W and the input power Pin is 120W. Note that the "increase in the output power Pout" referred to here includes not only the case where the output power Pout changes from a decrease to an increase as in the above embodiment, but also the case where the output power Pout changes from a constant state to an increase.　

Then, at time t6 after, for example, five minutes from time t5, when the input voltage Vin increases again to the second set voltage V2 of 24 V, the output control unit 15C suspends suppression of the third output power PoutC. At this time, the third output power PoutC is 20W and the input power Pin is 100W. In this way, by controlling the time-varying third output power PoutC, for example, between 20 W and 40 W as shown in FIG. can be controlled.

Note that the output control unit 15C transmits the first notification signal Sig1 to the notification unit 102C while the third output power PoutC is being suppressed. The first notification signal Sig1 is a signal indicating that the output control unit 15C is suppressing the third output power PoutC. While the notification unit 102C does not receive the first notification signal Sig1, the display unit 103C included in the power receiving device 1C is turned off. The provided display unit 103C is made to emit red light, for example. That is, while the power receiving device 1C is suppressing the third output power PoutC, the display unit 103C emits red light, and the user visually confirms that the power receiving device 1C is suppressing the third output power PoutC. can do. As a result, for example, a user using the load 5C connected to the power receiving device 1C can change the usage of the load 5C and take measures such as lowering the third output power PoutC. Note that the notification unit 102C may change the lighting state of the display unit 103C between when it is not receiving and when it is receiving, and the method of changing the lighting state can be changed as appropriate.

Also, the output control unit 15C transmits the second notification signal Sig2 to the power receiving device 1A and the power receiving device 1B while the third output power PoutC is being suppressed. The second notification signal Sig2 is a signal indicating that the output control unit 15C is suppressing the third output power PoutC. The second notification signal Sig2 is transmitted via the DC bus 4 by power line communication, for example. While the notification unit 102A of the power receiving device 1A and the notification unit 102B of the power receiving device 1B are receiving the second notification signal Sig2, the display units 103A and 103B emit blue light, for example. That is, while the power receiving device 1C is suppressing the third output power PoutC, the display units 103A and 103B emit blue light, and the user sees that the other power receiving device 1C is suppressing the third output power PoutC. This can be visually confirmed from the appearance of the power receiving device 1 other than the power receiving device 1C. That is, the lighting state of the display unit 103 when one power receiving device 1 out of the plurality of power receiving devices 1 is suppressing the output power Pout, and the power receiving device other than one power receiving device 1 out of the plurality of power receiving devices 1 1 is suppressing the output power Pout, the lighting states of the display units 103 of the power receiving apparatuses 1 are different from each other. In other words, the first power receiving device, which is one power receiving device 1 among the plurality of power receiving devices 1, suppresses the output power Pout, and the second power receiving device other than the first power receiving device among the plurality of power receiving devices 1 The lighting state of the display unit 103 of the first power receiving apparatus is different between when the apparatus suppresses the output power Pout. As a result, for example, a user using the load 5A connected to the power receiving device 1A or the load 5B connected to the power receiving device 1B changes the usage of the load 5A or the load 5B to change the first output power PoutA or the second output power PoutA. Measures such as lowering the output power PoutB can be taken.

(3) Modifications The embodiment described above is merely one of various embodiments of the present disclosure. The above-described embodiment can be modified in various ways according to design and the like, as long as the object of the present disclosure can be achieved. Hereinafter, power receiving devices 1 and power receiving systems 2 according to modifications of the above embodiment will be listed. However, components common to the power receiving device 1 and the power receiving system 2 of the above-described embodiment are denoted by the same reference numerals, and description thereof will be omitted as appropriate. Moreover, each configuration of the modified example described below can be applied in appropriate combination with each configuration described in the above embodiment.

The power receiving device 1 may include multiple receptacles 162 .

The power receiving device 1 may include an audio output device, and the notification unit 102 notifies the user that the output control unit 15 is suppressing the output power Pout by a notification sound, voice, or the like output from the audio output device. You may

The power receiving device 1 and the power receiving system 2 in the present disclosure include computer systems. A computer system is mainly composed of a processor and a memory as hardware. Functions of the power receiving device 1 and the power receiving system 2 according to the present disclosure are realized by the processor executing a program recorded in the memory of the computer system. The program may be recorded in advance in the memory of the computer system, may be provided through an electric communication line, or may be recorded in a non-temporary recording medium such as a computer system-readable memory card, optical disk, or hard disk drive. may be provided. A processor in a computer system consists of one or more electronic circuits, including semiconductor integrated circuits (ICs) or large scale integrated circuits (LSIs). Integrated circuits such as ICs or LSIs are called differently depending on the degree of integration, and include integrated circuits called system LSI, VLSI (Very Large Scale Integration), or ULSI (Ultra Large Scale Integration). In addition, FPGAs (Field-Programmable Gate Arrays), which are programmed after the LSI is manufactured, or logic devices capable of reconfiguring the connection relationships inside the LSI or reconfiguring the circuit partitions inside the LSI, shall also be adopted as processors. can be done. A plurality of electronic circuits may be integrated into one chip, or may be distributed over a plurality of chips. A plurality of chips may be integrated in one device, or may be distributed in a plurality of devices. A computer system, as used herein, includes a microcontroller having one or more processors and one or more memories. Accordingly, the microcontroller also consists of one or more electronic circuits including semiconductor integrated circuits or large scale integrated circuits.

At least part of the functions of the power receiving system 2, for example, the functions of the power conversion unit 10, may be realized by the cloud (cloud computing) or the like.

(4) Summary As described above, the power receiving device (1) of the first aspect includes the first terminal (11), the second terminal (12), the converter (13), and the voltage detection section (14). and an output control unit (15). The first terminal (11) is connected to a DC bus (4) supplied with DC power from a DC power supply (3). A load (5) is connected to the second terminal (12). The converter (13) converts at least one of the voltage and current input from the DC bus (4) and outputs it to the load (5). A voltage detector (14) detects an input voltage (Vin) of a first terminal (11). An output control section (15) controls the output power (Pout) of the converter (13) based on the input voltage (Vin) detected by the voltage detection section (14). Specifically, the output control unit (15) starts suppressing the output power (Pout) when the input voltage (Vin) becomes equal to or lower than the first set voltage (V1), and the input voltage (Vin) When the second set voltage (V2), which is larger than one set voltage (V1), is reached, the suppression of the output power (Pout) is stopped.

According to this aspect, it is possible to prevent the output power (Pout) from becoming excessive, and reduce the possibility that the power supply from the DC power supply (3) to the DC bus (4) will stop.

In the power receiving device (1) of the second aspect, in the first aspect, the output control section (15) reduces the input voltage (Vin) to the first set voltage (V1 ), the suppression of the output power (Pout) is resumed.

According to this aspect, it is possible to continuously suppress the output power (Pout).

In the power receiving device (1) of the third aspect, in the first or second aspect, the value of the first set voltage (V1) is the load (5 ) is set to the first set value (V11) for a first set time (T10) after the start of power feeding. Further, the value of the first set voltage (V1) is, after the first set time (T10) has passed since the converter (13) started supplying power to the load (5) connected to the second terminal (12), This is the second set value (V12). The first set value (V11) is higher than the second set value (V12) and lower than the value of the second set voltage (V2).　

According to this aspect, it is possible to preferentially suppress the output power (Pout) of the load (5) that is later connected to the DC bus (4).

In the power receiving device (1) of the fourth aspect, in the first or second aspect, the value of the first set voltage (V1) is the load (5 ) is at the first set value (V11) for the second set time (T20) after the output power (Pout) supplied to ) is increased. Further, the value of the first set voltage (V1) is set for the second set time (T20 ) is the second set value (V12). The first set value (V11) is higher than the second set value (V12) and lower than the value of the second set voltage (V2).

According to this aspect, it is possible to continuously suppress the time-varying output power (Pout).

In the power receiving device (1) of the fifth aspect, in any one of the first to fourth aspects, the notification unit (102) notifying that the output control unit (15) is suppressing the output power (Pout) ) is further provided.

According to this aspect, it can be confirmed that the power receiving device (1) is suppressing the output power (Pout).

A power receiving system (2) of a sixth aspect includes one or more power receiving devices (1) of any one of the first to fifth aspects and a DC bus to which DC power is supplied from a DC power supply (3). (4) and One or more power receiving devices (1) are connected to the DC bus (4).

According to this aspect, it is possible to prevent the output power (Pout) from becoming excessive, and reduce the possibility that the power supply from the DC power supply (3) to the DC bus (4) will stop.

In the power receiving system (2) of the seventh aspect, in the sixth aspect, the one or more power receiving devices (1) include a plurality of power receiving devices (1). A plurality of power receiving devices (1) are connected to a DC bus (4). The plurality of power receiving devices (1) includes a first power receiving device whose output power (Pout) is suppressed by an output control unit (15) and a second power receiving device other than the first power receiving device. The first power receiving device transmits a signal indicating that the output power (Pout) is being suppressed to the second power receiving device.

According to this aspect, it is possible to notify the second power receiving device that the first power receiving device is suppressing the output power (Pout).

The power receiving system (2) of the eighth aspect further includes a DC power supply (3) in the sixth or seventh aspect. A DC power supply (3) converts AC power into DC power and supplies it to a DC bus (4).

According to this aspect, it is possible to prevent the output power (Pout) from becoming excessive, and reduce the possibility that the power supply from the DC power supply (3) to the DC bus (4) will stop.

It should be noted that the second to fifth aspects are not essential configurations for the power receiving device (1), and can be omitted as appropriate. Also, the seventh and eighth aspects are not essential components of the power receiving system (2), and can be omitted as appropriate.

1 power receiving device 2 power receiving system 3 DC power supply 4 DC bus 5 load 11 first terminal 12 second terminal 13 converter 14 voltage detection unit 15 output control unit 102 notification unit V1 first set voltage V2 second set voltage Pout output power T10 1 set time T20 2nd set time V11 1st set value V12 2nd set value Vin Input voltage

Claims (8)

1. a first terminal connected to a DC bus to which DC power is supplied from a DC power supply;
   a second terminal to which a load is connected;
   a converter that converts at least one of voltage and current input from the DC bus and outputs the voltage to the load;
   a voltage detection unit that detects the input voltage of the first terminal;
   an output control unit that controls the output power of the converter based on the input voltage detected by the voltage detection unit;
   The output control unit is
   starting to suppress the output power when the input voltage becomes equal to or lower than a first set voltage;
   A power receiving device that stops suppressing the output power when the input voltage becomes equal to or higher than a second set voltage that is higher than the first set voltage.
2. The power receiving device according to claim 1, wherein the output control unit restarts the suppression of the output power when the input voltage becomes equal to or lower than the first set voltage again after stopping the suppression of the output power.
3. The value of the first set voltage is
   a first set value for a first set time after the converter starts supplying power to the load connected to the second terminal;
   a second set value after the first set time has elapsed since the converter started supplying power to the load connected to the second terminal;
   The power receiving device according to claim 1 or 2, wherein the first set value is higher than the second set value and lower than the value of the second set voltage.
4. The value of the first set voltage is
   a first set value for a second set time after the converter increases the output power supplied to the load connected to the second terminal;
   a second set value after the second set time elapses after the converter increases the output power supplied to the load connected to the second terminal;
   The power receiving device according to claim 1 or 2, wherein the first set value is higher than the second set value and lower than the value of the second set voltage.
5. The power receiving device according to any one of claims 1 to 4, further comprising a notification unit that notifies that the output control unit is suppressing the output power.
6. One or more power receiving devices according to any one of claims 1 to 5, and a DC bus to which DC power is supplied from a DC power supply,
   A power receiving system in which the one or more power receiving devices are connected to the DC bus.
7. the one or more power receiving devices includes a plurality of the power receiving devices;
   The plurality of power receiving devices are connected to the DC bus,
   The plurality of power receiving devices include a first power receiving device whose output power is suppressed by the output control unit and a second power receiving device other than the first power receiving device,
   The power receiving system according to claim 6, wherein the first power receiving device transmits a signal indicating that the output power is being suppressed to the second power receiving device.
8. further comprising the DC power supply;
   The DC power supply converts AC power into DC power and supplies it to the DC bus.
   The power receiving system according to claim 6 or 7.

Images