JPWO2018066055A1 - DC power supply system - Google Patents

Abstract

A first input terminal connected via a first cable to an external device including a main power supply and an auxiliary power supply receiving power from the main power supply; and an external device supplied from the external device via the first input terminal Power conversion unit for converting and outputting a voltage of the direct current power, a first input voltage detection unit for detecting an input voltage of the first power conversion unit, and an input detected by the first input voltage detection unit A DC power supply system comprising: a first controller for stopping the first power converter when the voltage is equal to or lower than a lower limit voltage.

Description

  The present invention relates to a DC power supply system.

  DESCRIPTION OF RELATED ART Conventionally, the apparatus which distributes the electric power from an electric power supply source, and supplies electric power to several loads is known (for example, refer patent document 1).

JP, 2014-192994, A

  However, in the prior art, there was a case where the supply of power was excessively received from the power supply source. For example, when the power supply source is a secondary battery, there is a possibility that the secondary battery may be deteriorated by the excessive power supply.

  In addition, when the power supply source is a secondary battery for driving a vehicle, the remaining power of the secondary battery decreases due to excessive power supply, resulting in a so-called battery-out state, and the original use of driving the vehicle In some cases, the secondary battery can not be used as an application.

  An object of the present invention is to provide a DC power feeding system capable of receiving power from a power source in an appropriate range.

  One aspect of the present invention for solving the above problems is a first input terminal connected to an external device including a main power supply and an auxiliary power supply receiving power supply from the main power supply via a first cable, and A first power conversion unit that converts and outputs a voltage of DC power supplied from the external device via one input terminal; and a first input voltage detection unit that detects an input voltage of the first power conversion unit; And a first controller configured to stop the first power converter when the input voltage detected by the first input voltage detector is equal to or lower than a lower limit voltage.

  According to the present invention, power can be supplied from the power supply source in an appropriate range.

It is a figure showing typically the direct-current feed system in a 1st embodiment. FIG. 1 is a diagram showing an example of the configuration of a vehicle M on which a power supply device 10 is mounted. FIG. 6 is a view showing another example of the configuration of a vehicle M on which the power supply device 10 is mounted. It is a figure which shows an example of a structure of the power supply side power converter device 100 accommodated in 1st housing | casing 100A. It is a flowchart which shows an example of the flow of the process by the power supply side controller 130 in 1st Embodiment. It is a figure which shows an example of a structure of the load side power converter device 200 accommodated in 2nd housing | casing 200A. It is a figure which shows the other example of a structure of the power supply side power converter device 100 accommodated in 1st housing | casing 100A. It is a flowchart which shows an example of the flow of the process by the power supply side controller 130 in 2nd Embodiment.

  Hereinafter, a DC power supply system according to an embodiment of the present invention will be described with reference to the drawings.

First Embodiment
[overall structure]
FIG. 1 is a view schematically showing a DC power supply system in the first embodiment. As illustrated, the DC power supply system is connected to, for example, a power supply device 10 (an example of an “external device”) mounted on a vehicle M. The vehicle M may be an engine vehicle powered by an internal combustion engine such as a gasoline engine, a hybrid vehicle, an electric vehicle, or a fuel cell vehicle. .

  The power supply device 10 includes a main power supply and an auxiliary power supply receiving power from the main power supply. In the configuration mounted on the vehicle M, the main power source includes an engine and an alternator, a motor that generates electric power using kinetic energy of the vehicle, an AC-DC converter, a DC-DC converter, a hybrid secondary battery, and an electric vehicle The auxiliary power supply is any one or a combination of secondary batteries, and is used to drive an on-vehicle load (as will be described later, a so-called accessory, which may include an engine starter motor in a vehicle equipped with an engine) Secondary battery. Details will be described later.

  The DC power feeding system includes, for example, the power supply-side power conversion device 100 housed in the first housing 100A, and the load-side power conversion device 200 housed in the second housing 200A. A load L is connected to the load-side power converter 200. The power supply device 10 and the power supply side power conversion device 100 are connected to each other via an input cable CAa. Moreover, the power supply side power converter device 100 and the load side power converter device 200 are mutually connected via middle cable CAb. The input cable CAa and the intermediate cable CAb may be detachable from the power conversion device 100 or the load conversion device 200 or may be fixedly connected. The input cable CAa is an example of the “first cable”, and the intermediate cable CAb is an example of the “second cable”.

  For example, the power supply-side power conversion device 100 is placed and used near the vehicle M, and the load-side power conversion device 200 is placed and used near the load L. Although FIG. 1 shows that the power source side power converter 100 is mounted on the outside of the vehicle M for the sake of convenience, the power source side power converter 100 may be used by being placed in the cabin of the vehicle M. Good. In this case, one end of the input cable CAa is connected to the power supply device 10 by being inserted into the engine room from a gap of a so-called half-opened bonnet in which the bonnet is not completely closed and is not locked. The other end of the input cable CAa is introduced into the vehicle compartment from the window of the vehicle M and connected to the power conversion device 100 placed in the vehicle compartment. Similarly, the intermediate cable CAb is also led out from the window of the vehicle M to the outside of the vehicle and connected to the load-side power conversion device 200. The power supply side power conversion apparatus 100 and the load side power conversion apparatus 200 are connected via the intermediate cable CAb, and thus can be used, for example, in a state of being separated by several tens of meters to several hundreds of meters from each other.

  The power supply side power conversion device 100 boosts the DC power supplied from the power supply device 10 via the input cable CAa, and outputs the DC power to the load side power conversion device 200. Further, the power supply side power conversion device 100 is in either the operating state or the stopping state according to the on / off of the switch SW provided in the first housing 100A. The switch SW is operated by the user, for example, on or off.

  The load-side power conversion device 200 steps down the power output by the power-supply-side power conversion device 100 and supplies the power to the load L.

  The load L is a lighting device, a radio, a home appliance, any electronic device such as a smartphone or a mobile phone or a motorized device, and is operated by DC power.

[Power supply]
FIG. 2 is a diagram showing an example of the configuration of a vehicle M on which the power supply device 10 is mounted. In the illustrated example, the vehicle M is an engine vehicle that is exclusively driven by an internal combustion engine. The vehicle M includes, for example, a power supply device 10 and an on-vehicle load 20. The power supply device 10 includes, for example, an engine 11, an alternator 12, a secondary battery 14, and an on-vehicle DC-DC converter 16.

  For example, the alternator 12 is connected to the engine 11 by the shaft SF and a belt (not shown), generates AC power using the rotational power of the engine 11, and converts it into DC power by the rectifier.

  The on-vehicle DC-DC converter 16 steps down DC power (DC) output from the alternator 12 and outputs it to the secondary battery 14 or the on-vehicle load 20. The DC power converted by the on-vehicle DC-DC converter 16 has, for example, a voltage of about 13.5-14.0 [V], and the voltage is about several [V] according to the type of the alternator 12 and the use environment. It may fluctuate and may be about 11 [V].

  The secondary battery 14 is, for example, a lead storage battery. The voltage (reference voltage) of the reference power of the secondary battery 14 conforms to the on-vehicle standard, and is, for example, about 12 [V] or 24 [V]. The reference voltage of the secondary battery 14 is, for example, a voltage called a rated voltage, a nominal voltage or the like. The secondary battery 14 stores (charges) the DC power output by the on-vehicle DC-DC converter 16 and discharges the stored power.

  The on-vehicle load 20 is, for example, an air conditioner, a lamp, various display devices in a vehicle room, an audio, and the like. The on-vehicle load 20 may include a starter motor that starts the engine 11. The on-vehicle load 20 operates using the DC power output by the on-vehicle DC-DC converter 16 and the DC power discharged by the secondary battery 14.

  As illustrated, the input cable CAa is connected to both the on-vehicle DC-DC converter 16 and the secondary battery 14 (for example, a terminal of the secondary battery 14) via a clip (not shown) or the like. Connected Therefore, the DC power discharged by the secondary battery 14 and the DC power output by the on-vehicle DC-DC converter 16 can be supplied to the power supply-side power conversion device 100 via the input cable CAa.

  FIG. 3 is a view showing another example of the configuration of the vehicle M on which the power supply device 10 is mounted. In the illustrated example, the vehicle M is a hybrid vehicle. The power supply device 10 mounted on a vehicle M, which is a hybrid vehicle, includes, for example, an engine 11, an on-vehicle AD-DC converter 13, a secondary battery 14, a drive motor 15, an on-vehicle DC-DC converter 16, and a hybrid And a secondary battery 17.

  The drive motor 15 is connected to the engine 11 by the shaft SF, generates electric power using kinetic energy which decreases when the vehicle M decelerates, and outputs the generated AC power to the on-vehicle AD-DC converter 13. Further, the drive motor 15 assists the engine 11 by rotating using the electric power output from the on-vehicle AD-DC converter 13. Here, instead of such a mechanism, a mechanism for separately providing a power generation motor and a drive (or regeneration) motor may be employed.

  The on-vehicle AD-DC converter 13 converts alternating-current power (AC) generated by the drive motor 15 into direct-current power (DC) and reduces the voltage to output to the on-vehicle DC-DC converter 16 and the secondary battery 17 for hybrid. . Further, the on-vehicle AD-DC converter 13 converts DC power discharged by the hybrid secondary battery 17 into AC power and boosts the DC power, and outputs the DC power to the drive motor 15 through an inverter (not shown).

  The on-vehicle DC-DC converter 16 steps down DC power output by the on-vehicle AD-DC converter 13 or the hybrid secondary battery 17 and outputs the DC power to the secondary battery 14 or the on-vehicle load 20.

  The hybrid secondary battery 17 is, for example, a lithium ion battery, a nickel hydrogen battery, a redox flow battery, etc., and has an output voltage higher than that of the secondary battery 14 and has a capacity of the secondary battery 14. The capacity is several times to several tens times larger than that of

[Power-side power converter]
FIG. 4 is a diagram showing an example of the configuration of the power supply-side power conversion device 100 housed in the first housing 100A. As illustrated, the first housing 100A is provided with a power supply side input terminal ILa, a power supply side output terminal OLa, and a switch SW, and the power supply side input is provided from the outside of the first housing 100A. An input cable CAa is connected to the terminal ILa, and an intermediate cable CAb is connected to the power supply side output terminal OLa. The power supply side input terminal ILa is an example of the “first input terminal”.

  The power supply side power converter 100 includes, for example, an input voltage detection unit 101, an input current detection unit 102, an output current detection unit 103, an output voltage detection unit 104, a diode 105, and a power supply DC−. A DC converter 110, a controller (hereinafter, for CTL) DC-DC converter 120, and a power supply side controller 130 are provided. The input-side voltage detection unit 101 is an example of a “first input voltage detection unit”, and the output-side voltage detection unit 104 is an example of a “first output voltage detection unit”. Also, the power supply side DC-DC converter 110 is an example of a “first power conversion unit”, and the power supply side controller 130 is an example of a “first controller”.

  The power supply side DC-DC converter 110 boosts the DC power supplied via the power supply side input terminal ILa and outputs the DC power to the side of the power supply side output terminal OLa. For example, the power supply DC-DC converter 110 boosts DC power supplied via the input terminal connected to the power supply input terminal ILa by switching the switching element at a desired duty ratio. . For example, the power supply side DC-DC converter 110 boosts the DC power to about 60 [V].

  Input-side voltage detection unit 101 and input-side current detection unit 102 are provided on the input side of power supply-side DC-DC converter 110. The input-side voltage detection unit 101 detects a voltage (input voltage Vin) between the positive electrode and the negative electrode of the input terminal of the power supply-side DC-DC converter 110. The input-side current detection unit 102 detects the current (input current Iin) flowing to the positive electrode of the input terminal of the power-supply-side DC-DC converter 110.

  The output side current detection unit 103, the output side voltage detection unit 104, and the diode 105 are provided on the output side of the power supply side DC-DC converter 110. The output side current detection unit 103 detects the current (output current Iout) flowing to the positive electrode of the output terminal of the power supply side DC-DC converter 110. The output-side voltage detection unit 104 detects a voltage (output voltage Vout) between the positive electrode and the negative electrode of the output terminal of the power supply-side DC-DC converter 110. The detection units on the input side and the output side output detection signals indicating the detection values to the power supply controller 130. The diode 105 prevents current from flowing from the power supply side output terminal OLa to the output terminal of the power supply side DC-DC converter 110.

  The CTL DC-DC converter 120 converts DC power output via the power supply side input terminal ILa into power usable by the power supply controller 130 and outputs the power to the power supply controller 130.

  The power supply side controller 130 is realized, for example, by a processor such as a CPU (Central Processing Unit) executing a program stored in a program memory (not shown). Further, part or all of the functions of the power supply side controller 130 may be realized by hardware such as LSI (Large Scale Integration), ASIC (Application Specific Integrated Circuit), or FPGA (Field-Programmable Gate Array). , May be realized by cooperation of software and hardware. The power supply side controller 130 operates by the power converted by the CTL DC-DC converter 120 being supplied.

  The power supply side controller 130 controls the power supply side DC-DC converter 110 based on the detection signals output by the various detection units. Hereinafter, the flow of processing by the power supply side controller 130 will be described using a flowchart.

  FIG. 5 is a flow chart showing an example of the flow of processing by the power supply side controller 130 in the first embodiment. If the switch SW is turned off during the processing of this flowchart, the power supply controller 130 may stop the power DC-DC converter 110 as an interrupt process.

  First, when the power is supplied from the CTL DC-DC converter 120, the power supply controller 130 reads a program from the program memory and starts processing (step S100).

  Next, the power supply controller 130 determines whether or not the input voltage Vin is within the first range with reference to the detection signal output by the input voltage detection unit 101 (step S102). The first range is a voltage range based on 12 [V] which is one of the reference voltages of the secondary battery 14. For example, the first range is a voltage range from the lower limit 9 [V] to the upper limit 14 [V] based on 12 [V].

  If the input voltage Vin is within the first range, the power supply controller 130 sets a control parameter for controlling the power supply DC-DC converter 110 as the first parameter (step S104). The control parameters are, for example, lower limit voltage VinL and upper limit voltage VinH for input voltage Vin, upper limit current IinH for input current Iin, boost ratio α, lower limit voltage VoutL and upper limit voltage VoutH for output voltage Vout, upper limit current IoutH for output current Iout, etc. including.

  Lower limit voltage VinL is, for example, a value near the minimum value of the voltage supplied by “main power supply” such as alternator 12 and is set to a value slightly lower than the reference voltage of secondary battery 14 which is “auxiliary power supply”. Be done. The minimum value of the voltage supplied by the “main power supply” is, for example, the minimum value (for example, 11.0 [V]) of the generated voltage of the alternator 12. This value is also a value less than the reference voltage of the secondary battery 14. The lower limit voltage VinL is set, for example, within a fluctuation range of about 5% on the plus side and the minus side based on the minimum value of the voltage supplied by the “main power supply”. For example, when the minimum value of the voltage supplied by the "main power supply" is 11 [V], the lower limit voltage VinL is set in the range of 10.45 to 11.55 [V]. The fluctuation range may be only the negative side or the positive side of the minimum value of the voltage supplied by the “main power supply”.

  The upper limit voltage VinH is, for example, a value slightly lower than the upper limit voltage of the first range. The slightly lower value is, for example, a value about 10% lower than the value to be compared. For example, when the upper limit voltage of the first range is 14 [V], the upper limit voltage VinH is set to 12 [V], 13 [V] or the like which is about 10% lower. The upper limit current IinH is set to, for example, a current value about half of the maximum current that can be discharged by the secondary battery 14.

  Lower limit voltage VoutL, upper limit voltage VoutH and upper limit current IoutH are set based on DC power assumed to be output from power supply side DC-DC converter 110. Specifically, lower limit voltage VoutL, upper limit voltage VoutH and upper limit current IoutH are set based on boost ratio α in power supply side DC-DC converter 110.

  For example, the power supply controller 130 sets the lower limit voltage VinL value for the input voltage Vin to about 11 V, the upper limit voltage VinH value to about 13 V, and the upper limit current IinH value to the input current Iin as the first parameter. A) The step-up ratio α is set to about 5 times. Further, since the power supply side controller 130 sets the boost ratio α to about five times, the first parameter further has a value exceeding the upper limit voltage VoutH with respect to the output voltage Vout by more than five times the assumed input voltage Vin ( For example, the output voltage Vout after boosting is set to about 10% more, the lower limit voltage VoutL to the output voltage Vout is set to a value smaller than the number [V] of the upper limit voltage VoutH, and the upper limit current IoutH to the output current Iout is , And is set to a value less than 1/5 times the assumed input current Iin.

  On the other hand, when the input voltage Vin is not within the first range, the power supply controller 130 further determines whether the input voltage Vin is within the second range (step S106). The second range is a voltage range based on 24 [V] which is one of the reference voltages of the secondary battery 14. For example, the second range is a voltage range from the lower limit 18 [V] to the upper limit 30 [V] based on 24 [V].

  When the input voltage Vin is within the second range, the power supply controller 130 sets a control parameter for controlling the power supply DC-DC converter 110 as a second parameter (step S108). For example, as the second parameter, the power supply controller 130 sets the lower limit voltage VinL value to the input voltage Vin of about 22 [V], the upper limit voltage VinH value to about 26 [V], and the upper limit current IinH value to the input current Iin 14 [14 A) The step-up ratio α is set to about 2.5 times. Further, since the power supply side controller 130 sets the boost ratio α to about 2.5 times, the upper limit voltage VoutH with respect to the output voltage Vout is further 2.5 times the assumed input voltage Vin as the second parameter. The lower limit voltage VoutL for the output voltage Vout is set to a value smaller than the number [V] of the upper limit voltage VoutH, and the upper limit current IoutH for the output current Iout is 1/2 of the input current Iin assumed. Set the value less than 5 times.

  On the other hand, when the input voltage Vin is not within the second range, the power supply controller 130 stops the power supply DC-DC converter 110 (step S110). By this, the processing of this flowchart ends.

  Next, the power supply controller 130 determines whether the input voltage Vin exceeds the lower limit voltage VinL and is lower than the upper limit voltage VinH with reference to the control parameter (step S112).

  When the input voltage Vin is equal to or lower than the lower limit voltage VinL or higher than the upper limit voltage VinH, the power supply side controller 130 proceeds to the process of S110 and stops the power supply side DC-DC converter 110. Thus, the power supply side controller 130 stops the power supply side DC-DC converter 110 when the input voltage Vin is at least the lower limit voltage VinL or less.

  Here, since the reference voltage is a value close to the voltage when the secondary battery 14 is fully charged, the voltage of the discharged power falls below the lower limit voltage VinL by discharging a little. Therefore, even if the DC power supply system continues to receive power supply from the power supply device 10, the secondary battery 14 is maintained with a certain charging rate maintained. As a result, it is possible to prevent the secondary battery 14 from being in the overdischarged state (a state of so-called battery exhaustion), and power can be supplied from the power supply device 10 within an appropriate range.

  In addition, when the DC power is output from the power supply device 10 to the power supply side input terminal ILa, the generated voltage of the "main power supply" may vary. In this case, when the lower limit voltage VinL is set to a voltage (for example, about 11.5 [V]) significantly higher than the minimum value of the generated voltages of the “main power supply” without considering the voltage variation, the input voltage Vin Becomes lower than the lower limit voltage VinL, the power supply side DC-DC converter 110 is stopped, and power supply to the load L may be stopped frequently.

  On the other hand, by setting lower limit voltage VinL to the minimum value of the generated voltage of “main power supply”, voltage variation is allowed and power is supplied from “main power supply”. Is prevented from being stopped frequently, and it becomes easier to stably supply power to the load L.

  On the other hand, when the input voltage Vin exceeds the lower limit voltage VinL and is lower than the upper limit voltage VinH, the power supply side controller 130 refers to the detection signal output from the input side current detection unit 102 and the control parameter to input. It is determined whether the current Iin exceeds the upper limit current IinH (step S114).

  When the input current Iin exceeds the upper limit current IinH, the power supply side controller 130 proceeds to the process of S110 and stops the power supply side DC-DC converter 110. As a result, the secondary battery 14 can be prevented from instantaneously discharging a large amount of power.

  On the other hand, when the input current Iin does not exceed the upper limit current IinH, the power supply controller 130 controls the power supply DC-DC converter 110 to boost DC power with the boost ratio α indicated by the control parameter (step S116).

  Next, the power supply controller 130 refers to the detection signal output from the output voltage detection unit 104 and the control parameter to determine whether the output voltage Vout exceeds the lower limit voltage VoutL and is less than the upper limit voltage VoutH. It is determined (step S118). When the output voltage Vout is equal to or lower than the lower limit voltage VoutL or higher than the upper limit voltage VoutH, the power supply side controller 130 proceeds to the process of S110 and stops the power supply side DC-DC converter 110.

  On the other hand, when the output voltage Vout exceeds the lower limit voltage VoutL and is less than the upper limit voltage VoutH, the power supply side controller 130 outputs with reference to the detection signal output by the output side current detection unit 103 and the control parameter. It is determined whether the current Iout exceeds the upper limit current IoutH (step S120). If the output current Iout does not exceed the upper limit current IoutH, the power supply controller 130 proceeds to the process of S112.

  On the other hand, when the output current Iout exceeds the upper limit current IoutH, the power supply side controller 130 proceeds to the process of S110 and stops the power supply side DC-DC converter 110. Thus, for example, when abnormal DC power is output due to a failure of the power supply side DC-DC converter 110 or the like, the power supply side DC-DC converter 110 can be stopped. In addition, when the power line is short-circuited or the like, and power having a voltage higher than the output voltage Vout of the power-side DC-DC converter 110 leaks to the output side of the power-side DC-DC converter 110, or another power source is connected. In this case, the output voltage Vout becomes equal to or lower than the lower limit voltage VoutL or higher than the upper limit voltage VoutH, so that the power supply side DC-DC converter 110 can be stopped. As a result, the safety of the DC power supply system can be enhanced.

[Load side power converter]
FIG. 6 is a diagram showing an example of the configuration of the load-side power conversion device 200 housed in the second housing 200A. As illustrated, the second housing 200A is provided with a load side input terminal ILb and a plurality of load side output terminals OLb. Further, an intermediate cable CAb (not shown) is connected to the load-side input terminal ILb from the outside of the second housing 200A, and a cable for connecting the load L (not shown) to the load-side output terminal OLb is provided. Connected The plurality of load side output terminals OLb are, for example, USB terminals to which a cable of USB (Universal Serial Bus) standard can be connected, and are maintained at an output voltage of 5 [V] and an output current of 1 [A]. For example, about 40 load side output terminals OLb may be provided.

  The load-side power conversion device 200 includes, for example, load-side DC-DC converters 210-1 and 210-2. In the illustrated example, two load side DC-DC converters are provided, but they are changed to one or three or more according to the number of load side output terminals OLb provided in the second housing 200A. May be Hereinafter, these load side DC-DC converters are simply described as load side DC-DC converters 210 without distinction. The load-side DC-DC converter 210 is an example of a “second power converter”.

  The load-side DC-DC converter 210 steps down DC power supplied via the load-side input terminal ILb and outputs it to the load-side output terminal OLb. For example, the power supply side DC-DC converter 110 performs step-down operation by switching the switching element at a desired duty ratio with respect to the DC power supplied via the input terminal connected to the load side input terminal ILb. . For example, in order to correspond to the voltage of DC power boosted by the power-supply DC-DC converter 110, the load-side DC-DC converter 210 has a voltage range of about 36 to 72 V (hereinafter referred to as The DC power within the range 3) is stepped down and converted to 5 [V] of the USB standard. The load-side DC-DC converter 210 outputs the stepped-down DC power to each load-side output terminal OLb.

  According to the DC power supply system in the first embodiment described above, the input cable CAa is connected to the power supply device 10 including the main power supply such as the alternator 12 and the secondary battery 14 as an auxiliary power supply receiving power supply from the main power supply. A power supply side input terminal ILa connected via the power supply side DC, a power supply side DC-DC converter 110 for converting and outputting a voltage of DC power supplied from the power supply device 10 via the power supply side input terminal ILa; -The input side voltage detection unit 101 that detects the input voltage Vin of the DC converter 110, and the power supply side controller 130 that stops the power supply side DC-DC converter 110 when the input voltage Vin is lower than the lower limit voltage VinL. Power can be supplied from the power supply device 10 within the range. As a result, when the power supply device 10 is mounted on an engine vehicle, the secondary battery 14 is prevented from being in an overdischarged state by monitoring the power output to the power supply side DC-DC converter 110. be able to. Also, even when the power supply device 10 is mounted in a hybrid vehicle, it is possible to prevent the secondary battery 14 and the hybrid secondary battery 17 from being in the overdischarged state.

  Further, according to the first embodiment described above, for example, when the supply of the grid power from the power plant is stopped at the time of disaster, the “main power supply” mounted on the vehicle M by using the DC power feeding system. Alternatively, it is possible to temporarily use the “auxiliary power” power to operate electronic devices and the like around the victim.

  Moreover, according to the first embodiment described above, in order to connect the power supply-side power conversion device 100 and the load-side power conversion device 200 by the intermediate cable CAb, power is used at a shelter away from the vehicle M or the like. Can.

  Further, according to the first embodiment described above, since voltage conversion is performed in two steps, the influence of the voltage drop due to the intermediate cable CAb can be suppressed.

  Further, according to the first embodiment described above, since the power supplied by the “main power supply” or the “auxiliary power supply” is converted into a relatively low voltage USB standard voltage, the power consumption of a radio, a mobile phone, etc. A small amount of equipment can be used for a long time. As a result, it becomes easy to acquire disaster information etc., and the convenience for the disaster victims can be improved.

Second Embodiment
The second embodiment will be described below. The second embodiment is different from the first embodiment in that the first housing 100A is provided with a third input terminal ILa #. For example, another power supply having a reference voltage larger than the reference voltage of the “auxiliary power supply” included in the power supply device 10 is connected to the third input terminal ILa # via a cable or the like. The other power source is, for example, a secondary battery mounted on a special vehicle such as a forklift, and outputs DC power of about 48 [V]. Below, it demonstrates centering on the difference which concerns, and description about a common part is abbreviate | omitted.

  FIG. 7 is a diagram showing another example of the configuration of the power supply-side power conversion device 100 housed in the first housing 100A. As illustrated, the first housing 100A is provided with a power supply side input terminal ILa, a power supply side output terminal OLa, a switch SW, and a third input terminal ILa #. From the outside of 100 A, the input cable CAa is connected to the power supply side input terminal ILa, and the intermediate cable CAb is connected to the power supply side output terminal OLa. Further, the third input terminal ILa # is connected to a cable connected to the output terminal of the secondary battery of another power source. The DC power output by the secondary battery of the other power source is output to the output side of the power source side DC-DC converter 110 via the third input terminal ILa #.

  Hereinafter, processing by the power supply side controller 130 in the second embodiment will be described using a flowchart.

  FIG. 8 is a flow chart showing an example of the flow of processing by the power supply side controller 130 in the second embodiment. If the switch SW is turned off during the processing of this flowchart, the power supply controller 130 may stop the power DC-DC converter 110 as an interrupt process.

  First, when power is supplied from the CTL DC-DC converter 120, the power supply controller 130 reads a program from the program memory and starts processing (step S300).

  Next, the power supply controller 130 determines whether or not the input voltage Vin is within the first range with reference to the detection signal output from the input voltage detection unit 101 (step S302).

  If the input voltage Vin is within the first range, the power supply controller 130 sets a control parameter for controlling the power supply DC-DC converter 110 as the first parameter (step S304).

  On the other hand, when the input voltage Vin is not within the first range, the power supply controller 130 further determines whether the input voltage Vin is within the second range (step S306).

  If the input voltage Vin is within the second range, the power supply controller 130 sets a control parameter for controlling the power supply DC-DC converter 110 as a second parameter (step S308).

  On the other hand, when the input voltage Vin is not within the second range, the power supply controller 130 stops the power DC-DC converter 110 (step S310). By this, the processing of this flowchart ends.

  Next, the power supply controller 130 refers to the detection signal output by the output current detection unit 103, and determines whether another power supply is connected to the third input terminal ILa # (step S312). For example, when the output current Iout is larger than a predetermined value, the power supply controller 130 determines that the other power supply is connected to the third input terminal ILa #. The predetermined value is, for example, an average value of the output voltage detected by the output side current detection unit 103 over a predetermined period. In addition, when the switch for detecting insertion of the cable is provided in the third input terminal ILa #, the power supply side controller 130 is connected to the other power supply to the third input terminal ILa # based on the state of the switch. It may be determined whether or not it is.

  When the other power supply is connected to the third input terminal ILa #, the power supply side controller 130 changes the boost ratio α, the lower limit voltage VoutL, the upper limit voltage VoutH and the upper limit current IoutH among the set control parameters (step S314) . For example, the power supply side controller 130 refers to the detection signal outputted by the output side voltage detection unit 104 to specify what the voltage of the DC power outputted from the secondary battery which is the other power supply is, and specify The boosting ratio α is changed based on the voltage. Specifically, the power supply controller 130 sets the first parameter to about 3.5 times so that the boosted output voltage Vout is smaller than the output voltage 48 [V] of the secondary battery which is the other power supply. In the second parameter, the boost ratio α is changed to about 1.8 times. The power supply controller 130 also changes the lower limit voltage VoutL, the upper limit voltage VoutH, and the upper limit current IoutH in accordance with the change of the boosting ratio α. This can suppress the flow of current from the other power supply connected to the third input terminal ILa # to the power supply-side power conversion device 100.

  Next, the power supply controller 130 determines whether the input voltage Vin exceeds the lower limit voltage VinL and is lower than the upper limit voltage VinH with reference to the control parameter (step S316). If the input voltage Vin is equal to or lower than the lower limit voltage VinL or higher than the upper limit voltage VinH, the power supply controller 130 proceeds to the process of S310 and stops the power supply DC-DC converter 110.

  On the other hand, when the input voltage Vin exceeds the lower limit voltage VinL and is lower than the upper limit voltage VinH, the power supply side controller 130 refers to the detection signal output from the input side current detection unit 102 and the control parameter to input. It is determined whether the current Iin exceeds the upper limit current IinH (step S318).

  When the input current Iin exceeds the upper limit current IinH, the power supply side controller 130 proceeds to the process of S310 and stops the power supply side DC-DC converter 110.

  On the other hand, when the input current Iin does not exceed the upper limit current IinH, the power supply controller 130 controls the power supply DC-DC converter 110 to boost DC power at the boost ratio α indicated by the control parameter (step S320).

  Next, the power supply controller 130 refers to the detection signal output from the output voltage detection unit 104 and the control parameter to determine whether the output voltage Vout exceeds the lower limit voltage VoutL and is less than the upper limit voltage VoutH. It is determined (step S322). When the output voltage Vout is equal to or lower than the lower limit voltage VoutL or higher than the upper limit voltage VoutH, the power supply side controller 130 proceeds to the process of S310 and stops the power supply side DC-DC converter 110.

  On the other hand, when the output voltage Vout exceeds the lower limit voltage VoutL and is less than the upper limit voltage VoutH, the power supply side controller 130 outputs with reference to the detection signal output by the output side current detection unit 103 and the control parameter. It is determined whether the current Iout exceeds the upper limit current IoutH (step S324). If the output current Iout does not exceed the upper limit current IoutH, the power supply side controller 130 proceeds to the process of S312.

  On the other hand, when the output current Iout exceeds the upper limit current IoutH, the power supply side controller 130 proceeds to the process of S310 and stops the power supply side DC-DC converter 110. By this, the processing of this flowchart ends.

  According to the DC power feeding system in the second embodiment described above, power can be supplied from the power supply device 10 in an appropriate range, as in the first embodiment described above.

  Further, according to the DC power feeding system in the second embodiment described above, since the third input terminal ILa # is further provided, various kinds of output voltages such as 12 [V], 24 [V], and 48 [V] are provided. It can correspond to a power supply source and can supply power to the load L for a longer time. As a result, the convenience for the user can be further improved.

  Hereinafter, other embodiments (modifications) will be described. In the embodiment described above, although the DC power feeding system has been described as receiving power supply from the power supply device 10 mounted on the vehicle M, the present invention is not limited to this, for example, receiving power supply from a fuel cell installed in a house. It is also good.

DESCRIPTION OF SYMBOLS 10 ... Power supply device, 11 ... Engine, 12 ... Alternator, 13 ... On-vehicle AC-DC converter, 14 ... Secondary battery, 15 ... Drive motor, 16 ... On-vehicle DC-DC converter, 17 ... Secondary battery for hybrids, SF ... Shaft, 20: vehicle load, 100: power supply side power converter, 101: input voltage detection unit, 102: input current detection unit, 103: output current detection unit, 104: output voltage detection unit, 105: diode 110: power supply side DC-DC converter, 120: CTL DC-DC converter, 130: power supply side controller, 100A: first housing 100A, ILa: power supply side input terminal, OLa: power supply side output terminal, 200: Load-side power converter, 210: Load-side DC-DC converter, 200 A: second housing, ILb: load-side input terminal, OLb: load Output terminals, L ... load, M ... vehicle, CAa ... input cable, Cab ... intermediate cable

Claims (9)

A first input terminal connected via a first cable to an external device including a main power supply and an auxiliary power supply receiving power from the main power supply;
A first power conversion unit configured to convert and output a voltage of DC power supplied from the external device via the first input terminal;
A first input voltage detection unit that detects an input voltage of the first power conversion unit;
A first controller for stopping the first power converter when the input voltage detected by the first input voltage detector is equal to or lower than a lower limit voltage;
DC power supply system comprising The first input terminal is connected to the part connected to both the main power supply and the auxiliary power supply in the external device via the first cable.
The DC power supply system according to claim 1. The lower limit voltage is set near the minimum voltage output by the main power supply,
The DC power supply system according to claim 1. The lower limit voltage is set to a value lower than the maximum voltage of the auxiliary power supply,
The direct current | flow electric power feeding system of Claim 3. The plurality of output terminals provided on the output side of the first power conversion unit, the plurality of output terminals each outputting DC power of a constant voltage,
The DC power supply system according to claim 1. A second power converter provided between the first power converter and the plurality of output terminals and connected to the first power converter and the plurality of output terminals via a second cable, The power conversion apparatus further comprises a second power conversion unit that converts a voltage of direct current power output by the first power conversion unit and outputs a constant voltage direct current power to each of the plurality of output terminals.
The DC power supply system according to claim 5. The first power converter is housed in a first housing provided with the first input terminal,
The second power converter is housed in a second housing provided with the plurality of output terminals,
The first housing is further provided with a first output terminal connected to an output terminal of the first power converter;
The second housing is further provided with a second input terminal connected to the input terminal of the second power conversion unit,
The first output terminal and the second input terminal are connected by the second cable,
The DC power supply system according to claim 6. The device further includes a first output voltage detection unit that detects an output voltage of the first power conversion unit,
The first power conversion unit boosts and outputs a voltage of DC power supplied from the external device via the first input terminal,
The first controller stops the first power converter when the output voltage detected by the first output voltage detector is equal to or higher than the voltage of the DC power boosted by the first power converter. ,
The DC power supply system according to claim 1. Further, another power supply having a reference voltage larger than the reference voltage of the auxiliary power supply can be connected to the output side of the first power conversion unit,
The first controller reduces the degree of boosting of the DC power by the first power converter based on the voltage of the DC power output from the other power source detected by the first output voltage detector. ,
The DC power supply system according to claim 8.

Images