JP6828969B1 - Judgment method and program by power supply device, information processing system, power supply device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply device having a configuration having redundancy, which can quickly determine that a problem has occurred in a part of power supplies connected in parallel. A power supply device is a power supply having a switch at an output, and a plurality of power supplies connected in parallel via the switch, output voltages of the plurality of power supplies, and parallel connection via the switch. A determination unit for determining a power source in which a problem has occurred in the plurality of power sources is provided based on the output voltages of the plurality of power sources as a whole. [Selection diagram] Fig. 3

Description

The present invention relates to a power supply device, an information processing system, a determination method and a program by the power supply device.

Some devices that perform information processing systems and the like have redundancy in the power supply.
Patent Document 1 discloses, as a related technique, a technique relating to a power supply device in which a plurality of DC-DC converter modules are connected in parallel to supply DC power to a load.

Japanese Unexamined Patent Publication No. 06-121524

By the way, in a power supply device having a configuration in which (N + 1) power supplies are connected in parallel to provide redundancy, the parasitic impedance in the wiring for supplying power from the power supply device to the load and the oring provided between the power supply device and the load. The element causes a voltage drop. As a function for adjusting this voltage drop, there are generally called a remote sense function or a remote sensing function. The remote sense function is a function of feeding back the voltage applied to the load to the control unit of the power supply device and adjusting the output voltage of the power supply device so that the voltage applied to the load approaches the target voltage.

However, when the remote sense function is used in a power supply device with a redundant configuration, if some problem occurs in one of the multiple power supplies connected in parallel and the output voltage of the power supply device becomes overvoltage, The voltage supplied to the load is also overvoltage. Therefore, the output voltage of the normal power supply among the plurality of power supplies connected in parallel is adjusted based on the overvoltage supplied to the load by the remote sense function. In other words, the normal power supply among the multiple power supplies connected in parallel recognizes that the output voltage has become higher than the target voltage due to the remote sense function, even though it outputs the target voltage, and the output voltage. Works to lower. As a result, all the power supplies connected in parallel have an abnormal voltage lower than the target voltage, and the power supply device cannot supply the necessary power to the load.

In general, a product that uses a power supply device having a redundant configuration is required to have high reliability. Therefore, in a product that uses a power supply device having a redundant configuration, it may not be allowed to stop the power supply from the power supply device to the load. Therefore, in a power supply device having a redundant configuration, it is desirable that a desired voltage can be supplied from the power supply device to the load even when a problem occurs in a part of the power supplies connected in parallel.
Therefore, in a power supply device having a redundant configuration, there is a need for a technique that can quickly determine that a problem has occurred in a part of the power supplies connected in parallel.

Each aspect of the present invention is intended to provide a power supply device, an information processing system, a determination method and a program by the power supply device, which can solve the above problems.

In order to achieve the above object, according to one aspect of the present invention, the power supply device is a power supply having a switch at the output, a plurality of power supplies connected in parallel via the switch, and the plurality of power supplies. A determination unit for determining a power source in which a problem has occurred in the plurality of power sources is provided based on each output voltage and the output voltage of the entire plurality of power sources connected in parallel via the switch.

In order to achieve the above object, according to another aspect of the present invention, the information processing system includes the above power supply device and an information processing device to which power is supplied from the power supply device.

In order to achieve the above object, according to another aspect of the present invention, the determination method by the power supply device is a power supply having a switch at the output, and includes a plurality of power supplies connected in parallel via the switch. It is a determination method by a power supply device, and includes determining a power source in which a problem has occurred in the plurality of power sources based on the output voltage of each of the plurality of power sources.

In order to achieve the above object, according to one aspect of the present invention, the program is a computer of a power supply having a switch at the output and having a plurality of power supplies connected in parallel via the switch. , The determination of the power source in which the trouble has occurred in the plurality of power sources is executed based on the output voltage of each of the plurality of power sources.

According to each aspect of the present invention, it is possible to quickly determine that a defect has occurred in a part of the power supplies connected in parallel in the power supply device having a redundant configuration.

It is a figure which shows an example of the structure of the information processing system by one Embodiment of this invention. It is a figure which shows an example of the processing flow of the information processing system by one Embodiment of this invention. It is a figure which shows the power-source device of the minimum structure by embodiment of this invention. It is a schematic block diagram which shows the structure of the computer which concerns on at least one Embodiment.

Hereinafter, embodiments will be described in detail with reference to the drawings.
<Embodiment>
As shown in FIG. 1, the information processing system 1 according to the embodiment of the present invention includes a power supply device 10 and an information processing device 20 (an example of a load). The information processing system 1 is a system in which the power supplied from the power supply device 10 to the information processing device 20 has redundancy.

The power supply device 10 is a device that supplies electric power to the information processing device 20.
The power supply device 10 includes power supply module units 101a1, 101a2, ..., 101aN, a control unit 102, and a voltage detection circuit 103.
Hereinafter, the power supply module units 101a1, 101a2, ..., 101aN are collectively referred to as the power supply module unit 101. In FIG. 1, the power supply module portions 101a2 to 101a (N-1) are omitted.

The power supply module unit 101a1 includes a voltage adjusting unit 1011a1 (an example of a power supply), a voltage detection circuit 1012a1, and a MOSFET (Metal-Oxide-Semiconductor Field-Effective Transistor) switch 1013a1 (an example of a switch).

The power supply module unit 101a2 includes a voltage adjusting unit 1011a2 (an example of a power supply), a voltage detection circuit 1012a2, and a MOSFET switch 1013a2 (an example of a switch).
The power supply module section 101a (N-1) includes a voltage adjusting section 1011a (N-1) (an example of a power supply), a voltage detection circuit 1012a (N-1), and a MOSFET switch 1013a (N-1) (an example of a switch). Be prepared.

The power supply module unit 101aN includes a voltage adjusting unit 1011aN (an example of a power supply), a voltage detection circuit 1012aN, and a MOSFET switch 1013aN (an example of a switch).
The voltage adjusting units 1011a1, 1011a2, ..., 1011aN are collectively referred to as a voltage adjusting unit 1011 (an example of a power supply). Further, the voltage detection circuits 1012a1, 1012a2, ..., 1012aN are collectively referred to as a voltage detection circuit 1012. Further, the MOSFET switches 1013a1, 1013a2, ..., 1013aN are collectively referred to as a MOSFET switch 1013 (an example of a switch).

The control unit 102 includes a voltage control unit 1021 (an example of a second control unit), an overvoltage control unit 1022, and a switch control unit 1023 (an example of a first control unit).
The overvoltage control unit 1022 includes a calculation unit 1022a (an example of a determination unit, an example of a first control unit, an example of a second control unit), and a storage unit 1022b.

Each of the voltage adjusting unit 1011, the voltage detection circuit 1012, and the MOSFET switch 1013 includes a first terminal, a second terminal, and a third terminal. The voltage control unit 1021 includes a first terminal, a second terminal, a third terminal, ..., A first (N + 2) terminal. The overvoltage control unit 1022 includes a first terminal, a second terminal, a third terminal, a fourth terminal, ..., A third (N + 3) terminal. The switch control unit includes a first terminal, a second terminal, ..., A first (N + 1) terminal. The voltage detection circuit 103 includes a first terminal, a second terminal, a third terminal, and a fourth terminal. The information processing device 20 includes a first terminal.

Each of the first terminals of the voltage adjusting unit 1011 is a terminal that receives a voltage from the outside. The second terminal of the voltage adjusting unit 1011a1 is connected to the first terminal of the voltage detection circuit 1012a1. The third terminal of the voltage adjusting unit 1011a1 is connected to the third terminal of the voltage control unit 1021. The second terminal of the voltage adjusting unit 1011a2 is connected to the first terminal of the voltage detection circuit 1012a2. The third terminal of the voltage adjusting unit 1011a2 is connected to the fourth terminal of the voltage control unit 1021. The second terminal of the voltage adjusting unit 1011aN is connected to the first terminal of the voltage detection circuit 1012aN. The third terminal of the voltage adjusting unit 1011aN is connected to the third (N + 2) terminal of the voltage control unit 1021.

The second terminal of the voltage detection circuit 1012a1 is connected to the first terminal of the MOSFET switch 1013a1. The third terminal of the voltage detection circuit 1012a1 is connected to the fourth terminal of the overvoltage control unit 1022. The second terminal of the voltage detection circuit 1012a2 is connected to the first terminal of the MOSFET switch 1013a2. The third terminal of the voltage detection circuit 1012a2 is connected to the fifth terminal of the overvoltage control unit 1022. The third terminal of the voltage detection circuit 1012aN is connected to the third (N + 3) terminal of the overvoltage control unit 1022.

Each of the second terminals of the MOSFET switch 1013 is connected to the first terminal of the voltage detection circuit 103. The third terminal of the MOSFET switch 1013a1 is connected to the second terminal of the switch control unit 1023. The third terminal of the MOSFET switch 1013a2 is connected to the second terminal of the switch control unit 1023. The third terminal of the MOSFET switch 1013aN is connected to the third (N + 1) terminal of the switch control unit 1023.

The first terminal of the voltage control unit 1021 is connected to the third terminal of the voltage detection circuit 103. The second terminal of the voltage control unit 1021 is connected to the first terminal of the overvoltage control unit 1022. The second terminal of the overvoltage control unit 1022 is connected to the first terminal of the switch control unit 1023. The third terminal of the overvoltage control unit 1022 is connected to the fourth terminal of the voltage detection circuit 103. The second terminal of the voltage detection circuit 103 is connected to the first terminal of the information processing apparatus 20.

The first terminal of the voltage control unit 1021 and the third terminal of the voltage detection circuit 103 are connected via the remote sense line L1. Further, each of the third terminal of the voltage adjustment unit 1011 and each of the third to third (N + 2) terminals of the voltage control unit 1021 are connected via the voltage adjustment unit control line L2. Further, each of the third terminal of the voltage detection circuit 1012 and each of the fourth to (N + 3) terminals of the overvoltage control unit 1022 are connected via the voltage sense line L3. Further, the third terminal of the overvoltage control unit 1022 and the fourth terminal of the voltage detection circuit 103 are connected via the voltage sense line L4. Further, each of the third terminal of the MOSFET switch 1013 and each of the second to second (N + 1) terminals of the switch control unit 1023 are connected via the MOSFET switch control line L5.

Each of the voltage adjusting units 1011 generates a voltage adjusted according to the control by the control unit 102 from the voltage received from the outside. Each of the voltage regulators 1011 connects the generated voltage to the voltage detection circuit 1012 via the corresponding voltage detection circuit 1012 and the corresponding MOSFET switch 1013 (ie, via the connected voltage detection circuit 1012). Output to the MOSFET switch 1013).

Each of the voltage detection circuits 1012 detects the value of the voltage output by the corresponding voltage adjusting unit 1011. Each of the voltage detection circuits 1012 outputs the detected voltage value to the overvoltage control unit 1022.

Each of the MOSFET switches 1013 is a switch in which the power supply module unit 101 is connected in parallel to realize the oring of the power supply module unit 101. Each of the MOSFET switches 1013 is turned on (that is, closed) or turned off (that is, open) according to the control by the switch control unit 1023. When each of the MOSFET switches 1013 is in the ON state, the voltage output by the corresponding voltage adjusting unit 1011 is output to the information processing apparatus 20 via the voltage detection circuit 103.

The overvoltage control unit 1022 includes a calculation unit 1022a and a storage unit 1022b.
The calculation unit 1022a compares the output end voltage Vl detected by each of the voltage detection circuits 1012a1 to 1012an with the output end overvoltage threshold value Vlov. Further, the calculation unit 1022a compares the load end voltage Vr detected by the voltage detection circuit 103 with the load end overvoltage threshold value Vrov.
The calculation unit 1022a determines whether or not the output end voltage Vl and the load end voltage Vr are normal based on the comparison results.

For example, when the calculation unit 1022a determines that the load end voltage Vr does not exceed the load end overvoltage threshold Vlov and the output end voltage Vl does not exceed the output end overvoltage threshold Vlov, the output end voltage Vl and the load end voltage It is determined that Vr is normal. Then, the calculation unit 1022a transmits an instruction to turn each of the MOSFET switches 1013 into an ON state or an OFF state to the switch control unit 1023. In the instruction to turn off the state, the calculation unit 1022a determines that the output end voltage Vl and the load end voltage Vr are normal, and a current flows from the voltage detection circuit 103 side to the voltage detection circuit 1012 side in the MOSFET switch 1013. When it is determined that there is a possibility, an instruction to turn off each of the MOSFET switches 1013 passing the sensed current is transmitted to the switch control unit 1023 in order to maintain the oring state. For example, the arithmetic unit 1022a measures the voltage between the first terminal and the second terminal, that is, the voltage between the source and drain for each of the MOSFET switches 1013, and when the measured voltage becomes equal to or less than a predetermined threshold value. (That is, when the potential of the source is higher than the potential of the drain and the voltage difference is equal to or less than a predetermined threshold value), a current may flow from the voltage detection circuit 103 side to the voltage detection circuit 1012 side. judge.

Further, for example, when the calculation unit 1022a determines that the load end voltage Vr exceeds the load end overvoltage threshold value Vrov, it determines that an overvoltage abnormality has occurred at the load end. In this case, the calculation unit 1022a calculates the difference voltage Vdiv (Vdim = Vl-Vr) between the load end voltage Vr detected by the voltage detection circuit 103 and the output end voltage Vl detected by each of the voltage detection circuits 1012a1 to 1012an. .. The calculation unit 1022a compares each of the calculated difference voltages Vdiv. The calculation unit 1022a identifies the smallest difference voltage Vdiv among the calculated difference voltage Vdivs based on the comparison result.
Then, the calculation unit 1022a transmits an instruction to turn off the MOSFET switch 1013 corresponding to the smallest difference voltage Vdiv to the switch control unit 1023. Further, the calculation unit 1022a transmits an instruction to stop the voltage adjustment unit 1011 corresponding to the smallest difference voltage Vdiv to the voltage control unit 1021.

Further, for example, when the calculation unit 1022a determines that the output end voltage Vl exceeds the output end overvoltage threshold value Vlov, it determines that an overvoltage abnormality has occurred at the output end. In this case, the calculation unit 1022a transmits an instruction to turn off the MOSFET switch 1013 corresponding to the voltage detection circuit 1012 that has detected the output terminal voltage Vl to the switch control unit 1023. Further, the calculation unit 1022a transmits an instruction to stop the voltage adjustment unit 1011 corresponding to the voltage detection circuit 1012 to the voltage control unit 1021.

The storage unit 1022b stores the output end overvoltage threshold value Vlov and the load end overvoltage threshold value Vrov in advance.

The voltage control unit 1021 stops the voltage adjustment unit 1011 corresponding to the smallest difference voltage Vdif in response to an instruction from the calculation unit 1022a.

The switch control unit 1023 turns off the MOSFET switch 1013 corresponding to the smallest difference voltage Vdif in response to an instruction from the calculation unit 1022a.

Next, a process for detecting that a problem has occurred in a part of the parallel-connected power supplies performed by the information processing system 1 will be described.
Here, the processing flow of the information processing system 1 shown in FIG. 2 will be described.

The following processing is started, for example, by inputting start information to the information processing system 1 from the outside.
The calculation unit 1022a acquires the output terminal voltage Vl detected by each of the voltage detection circuits 1012a to 1012an via the voltage sense line L3 (step S101). Further, the calculation unit 1022a acquires the load end voltage Vr detected by the voltage detection circuit 103 via the voltage sense line L4 (step S101).

The calculation unit 1022a compares the load end voltage Vr detected by the voltage detection circuit 103 with the load end overvoltage threshold value Vrov. The calculation unit 1022a determines whether or not the load end voltage Vr is normal based on the comparison result.
Specifically, the calculation unit 1022a determines whether or not the load end voltage Vr exceeds the load end overvoltage threshold value Vrov (step S102).

When the calculation unit 1022a determines that the load end voltage Vr does not exceed the load end overvoltage threshold value Vrov (NO in step S102), the calculation unit 1022a returns to the process of step S101.

Further, when the calculation unit 1022a determines that the load end voltage Vr exceeds the load end overvoltage threshold value Vrov (YES in step S102), it determines that an overvoltage abnormality has occurred at the load end. In this case, the calculation unit 1022a calculates the difference voltage Vdiv (Vdim = Vl-Vr) between the load end voltage Vr detected by the voltage detection circuit 103 and the output end voltage Vl detected by each of the voltage detection circuits 1012a1 to 1012an. (Step S103).

The calculation unit 1022a compares each of the calculated difference voltages Vdiv (step S104). The calculation unit 1022a identifies the smallest difference voltage Vdiv among the calculated difference voltage Vdivs based on the comparison result. Then, the calculation unit 1022a transmits an instruction to turn off the MOSFET switch 1013 corresponding to the smallest difference voltage Vdiv to the switch control unit 1023 (step S105). In response to this instruction from the calculation unit 1022a, the switch control unit 1023 turns off the MOSFET switch 1013 corresponding to the smallest difference voltage Vdif (step S105). Further, the calculation unit 1022a transmits an instruction to stop the voltage adjustment unit 1011 corresponding to the smallest difference voltage Vdiv to the voltage control unit 1021 (step S105). In response to this instruction from the calculation unit 1022a, the voltage control unit 1021 stops the voltage adjustment unit 1011 corresponding to the smallest difference voltage Vdif (step S105).

Further, the calculation unit 1022a compares the output end voltage Vl detected by each of the voltage detection circuits 1012a to 1012an with the output end overvoltage threshold value Vlov. The calculation unit 1022a determines whether or not the output terminal voltage Vl is normal based on the comparison results.
Specifically, the calculation unit 1022a determines whether or not the output end voltage Vl exceeds the output end overvoltage threshold value Vlov (step S202).

When the calculation unit 1022a determines that the output end voltage Vl does not exceed the output end overvoltage threshold value Vlov (NO in step S202), the calculation unit 1022a returns to the process of step S101.

Further, when the calculation unit 1022a determines that the output end voltage Vl exceeds the output end overvoltage threshold value Vlov (YES in step S202), the calculation unit 1022a determines that an overvoltage abnormality has occurred at the output end. In this case, the calculation unit 1022a transmits an instruction to turn off the MOSFET switch 1013 corresponding to the voltage detection circuit 1012 that has detected the output terminal voltage Vl to the switch control unit 1023 (step S203). The switch control unit 1023 turns off the MOSFET switch 1013 corresponding to the voltage detection circuit 1012 in response to this instruction from the calculation unit 1022a (step S203). Further, the calculation unit 1022a transmits an instruction to stop the voltage adjustment unit 1011 corresponding to the voltage detection circuit 1012 to the voltage control unit 1021 (step S203). The voltage control unit 1021 stops the voltage adjustment unit 1011 corresponding to the voltage detection circuit 1012 in response to this instruction from the calculation unit 1022a (step S203).

The information processing system 1 according to the embodiment of the present invention has been described above.
In the information processing system 1, the power supply device 10 is a plurality of voltage adjusting units 1011 having a MOSFET switch 1013 at the output, and a plurality of voltage adjusting units 1011 connected in parallel via the MOSFET switch 1013 and a voltage adjusting unit. Based on the output voltage of each of the 1011s and the output voltage of the entire 1011 voltage adjusting units connected in parallel via the MOSFET switch 1013, the voltage adjusting unit 1011 power supply in which a problem has occurred in the plurality of voltage adjusting units 1011 is determined. The calculation unit 1022a is provided.

By doing so, the power supply device 10 can quickly determine that a problem has occurred in a part of the power supplies connected in parallel in the power supply device having a redundant configuration.

Further, in the information processing system 1, when the calculation unit 1022a determines the voltage adjustment unit 1011 in which the defect has occurred in the plurality of voltage adjustment units 1011, the power supply device 10 is connected to the output of the voltage adjustment unit 1011 in which the defect has occurred. The MOSFET switch 1013 is disconnected.

By doing so, the power supply device 10 is connected to the information processing device 20 in an N redundant configuration, and among the power supply module units 101a2 to 101a (N-1) using the remote sense function, which voltage adjustment unit 1011 The calculation unit 1022a detects whether the output voltage of the above is higher than expected, turns off the MOSFET switch 1013 for information processing from the calculation unit 1022a via the switch control unit 1023, and causes an abnormal power supply module. By disconnecting the unit 101 from the power supply path, it is possible to continue power supply to the information processing device 20 which is a load.

As a result, the power supply device 10 is a load from the power supply device 10 even when a problem occurs in a part of the voltage adjusting units 1011 connected in parallel in the power supply device 10 having a redundant configuration. A desired voltage can be supplied to the information processing device 20.

Further, in the information processing system 1, when the calculation unit 1022a determines the voltage adjusting unit 1011 in which the defect has occurred in the plurality of voltage adjusting units 1011, the power supply device 10 stops the voltage adjusting unit 1011 in which the defect has occurred.

By doing so, the power supply device 10 is connected to the information processing device 20 in an N redundant configuration, and among the power supply module units 101a2 to 101a (N-1) using the remote sense function, which voltage adjustment unit 1011 The calculation unit 1022a detects whether the output of the above is higher than expected, and overvoltage protection is applied to the output voltage of the voltage adjustment unit 1011 to protect the elements and peripheral circuits in the power supply module unit 101. ..

As a result, the power supply device 10 is a load from the power supply device 10 even when a problem occurs in a part of the voltage adjusting units 1011 connected in parallel in the power supply device 10 having a redundant configuration. A desired voltage can be supplied to the information processing device 20.

The power supply device 10 having the minimum configuration according to the embodiment of the present invention will be described.
As shown in FIG. 3, the power supply device 10 having the minimum configuration according to the embodiment of the present invention includes a plurality of power supplies 10a and a determination unit 10b.
The plurality of power supplies 10a are power supplies having a switch at the output, and are connected in parallel via the switch.
The determination unit 10b determines the power supply in which the problem has occurred in the plurality of power supplies 10a based on the output voltage of each of the plurality of power supplies 10a and the output voltage of the entire plurality of power supplies 10a connected in parallel via the switch. judge.

By doing so, the power supply device 10 is a power supply device having a configuration having redundancy, and it is possible to quickly determine that a problem has occurred in a part of the power supplies connected in parallel.

In the processing according to the embodiment of the present invention, the order of the processing may be changed as long as the appropriate processing is performed.

For example, in the process according to the embodiment of the present invention, as shown in FIG. 2, the processes of steps S102 to S105 and the processes of steps S201 to S202 are processed in parallel, that is, the arithmetic unit 1022a processes in parallel. It was explained as.
However, in another embodiment of the present invention, the calculation unit 1022a processes in series, that is, the processes of steps S102 to S105 are performed and then the processes of steps S201 to S202 are performed, or the steps. The processing of steps S102 to S105 may be performed after the processing of S201 to step S202.

Although the embodiment of the present invention has been described, the above-mentioned information processing system 1, power supply device 10, information processing device 20, and other control devices may have a computer system inside. The process of the above-mentioned processing is stored in a computer-readable recording medium in the form of a program, and the above-mentioned processing is performed by the computer reading and executing this program. A specific example of a computer is shown below.
FIG. 4 is a schematic block diagram showing a configuration of a computer according to at least one embodiment.

As shown in FIG. 4, the computer 5 includes a CPU 6, a main memory 7, a storage 8, and an interface 9.
For example, each of the above-mentioned information processing system 1, power supply device 10, information processing device 20, and other control devices is mounted on the computer 5. The operation of each processing unit described above is stored in the storage 8 in the form of a program. The CPU 6 reads a program from the storage 8, expands it into the main memory 7, and executes the above processing according to the program. Further, the CPU 6 secures a storage area corresponding to each of the above-mentioned storage units in the main memory 7 according to the program. The program includes BIOS141 and BMC firmware 131.

Examples of the storage 8 include HDD (Hard Disk Drive), SSD (Solid State Drive), magnetic disk, optical magnetic disk, CD-ROM (Compact Disk Read Only Memory), DVD-ROM (Digital Versaille Disk Read). , Semiconductor memory and the like. The storage 8 may be internal media directly connected to the bus of computer 5, or external media connected to computer 5 via an interface 9 or a communication line. When this program is distributed to the computer 5 via a communication line, the distributed computer 5 may expand the program in the main memory 7 and execute the above processing. In at least one embodiment, the storage 8 is a non-temporary tangible storage medium.

Further, the above program may realize a part of the above-mentioned functions. Further, the program may be a file that can realize the above-mentioned functions in combination with a program already recorded in the computer system, a so-called difference file (difference program).

Although some embodiments of the present invention have been described, these embodiments are examples and do not limit the scope of the invention. Various additions, omissions, replacements, and changes may be made to these embodiments without departing from the gist of the invention.

1 ... Information system 5 ... Computer 6 ... CPU
7 ... Main memory 8 ... Storage 9 ... Interface 10 ... Power supply device 10a ... Power supply 10b ... Judgment unit 20 ... Information processing devices 101, 101a1, 101a2, ... 101aN ... Power supply module 102 ... Control unit 103, 1012, 1012a1, 1012a2, ..., 1012aN ... Voltage detection circuit 1011, 1011a1, 1011a2, ..., 1011aN ... Voltage adjustment unit 1013 10,13a1, 1013a2, ..., 1013aN ... MOSFET switch 1021 ... Voltage control unit 1022 ... Overvoltage control unit 1022a ... Calculation unit 1022b ... Storage unit 1023 ... Switch control unit

Claims (8)

A power supply having a switch at the output, and a plurality of power supplies connected in parallel via the switch,
A determination unit for determining a power supply in which a problem has occurred in the plurality of power supplies based on the output voltage of each of the plurality of power supplies and the output voltage of the entire plurality of power supplies connected in parallel via the switch.
Power supply with. The determination unit
Based on the difference voltage between the output voltage of each of the plurality of power supplies and the output voltage of the entire plurality of power supplies connected in parallel via the switch, the power supply in which the problem has occurred in the plurality of power supplies is determined.
The power supply device according to claim 1. The determination unit
Determine the power supply that has a problem in the power supply corresponding to the smallest difference voltage among the output voltages of the plurality of power supplies and the output voltages of the plurality of power supplies connected in parallel via the switch. ,
The power supply device according to claim 2. When the determination unit determines a power source in which a problem has occurred in the plurality of power sources, the first control unit that disconnects the switch connected to the output of the power source in which the problem has occurred.
The power supply device according to any one of claims 1 to 3. When the determination unit determines a power source in which a problem has occurred in the plurality of power sources, a second control unit that stops the power source in which the problem has occurred.
The power supply device according to any one of claims 1 to 4. The power supply device according to any one of claims 1 to 5.
An information processing device to which power is supplied from the power supply device and
Information processing system equipped with. A power supply having a switch at the output, which is a determination method by a power supply device including a plurality of power supplies connected in parallel via the switch.
To determine the power supply in which a problem has occurred in the plurality of power supplies based on the output voltage of each of the plurality of power supplies.
Judgment method by the power supply device including. To a computer of a power supply device having a switch on the output and having a plurality of power supplies connected in parallel via the switch.
To determine the power supply in which a problem has occurred in the plurality of power supplies based on the output voltage of each of the plurality of power supplies.
A program that executes.

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