JP6849445B2 - Specific device, breaker and specific method - Google Patents

Description

The present invention relates to a shutoff device that shuts off an electrical path.

A plurality of power feeding units provided in the power feeding device may supply power to the load at the same time.

For example, Patent Document 1 discloses a power supply device in which a plurality of power supply devices are connected in parallel to form a redundant system and supply electric power to an important load.

Further, Patent Document 2 discloses an electronic device including a plurality of circuit units having various functions and a power supply circuit for supplying electric power to the plurality of circuit units.

Further, Patent Document 3 discloses a parallel operation power supply system in which one large-capacity power supply is configured by a plurality of small-capacity power supplies.

Japanese Unexamined Patent Publication No. 05-038055 Japanese Unexamined Patent Publication No. 05-07612 Japanese Unexamined Patent Publication No. 10-108363

In a power supply system consisting of a power supply device in which multiple power supply units supply current to the load at the same time, the current is excessive for the load due to an abnormality in the power supply path for supplying power to the load unit, an abnormality in the load unit, or an abnormality in the power supply unit. May flow.

Then, since it is difficult to identify and restore the abnormal portion in the power supply system, it may be difficult to restore the power supply system. Therefore, it can be assumed that there is a risk that the power supply path, the load portion, etc. will be burnt out due to the continuous inflow of an excessive current into the load portion, and it will be more difficult to recover.

In order to avoid this danger, it is effective to cut off the output from the power supply device to the load. However, blocking the output from the power supply to the load means stopping the operation of the power supply. The overcurrent to the load may be generated due to the failure of the power feeding unit as described above. In that case, the power supply by the power supply device can be maintained by simply stopping the power supply from the power supply unit or replacing the power supply unit with a spare power supply unit. Nevertheless, the above-mentioned method of cutting off the output from the power supply device to the load stops the operation of the power supply device.

An object of the present invention is to provide a specific device or the like that can further secure the continuation of power supply to a load while suppressing the spread of damage in a power supply system or a load.

The specific device of the present invention includes a specific unit. From the current value of each current and the total current value of the total current, the specific unit specifies a cutoff point related to the cutoff of the continuity between the load and each of the power feeding devices. The current value of each of the currents is a current value supplied to the load from each of the plurality of power feeding devices of the power feeding device. The total current value is the current value of the total current supplied to the load from the set of the plurality of power feeding devices.

The specific device and the like of the present invention can secure the continuation of power supply to the load for a longer period of time while suppressing the spread prevention of damage in the power supply system and the load.

It is a conceptual diagram which shows the structural example of the power supply system of this embodiment. It is a conceptual diagram which shows the processing flow example of the process of specifying a cut-off point from N FETs (field-effect transistors). It is a conceptual diagram which shows the processing flow example of the determination process about whether the cutoff point is FET 131. It is a conceptual diagram which shows the processing flow example of the processing performed by a control unit. It is a conceptual diagram which shows the structure of the minimum specific apparatus of this invention.

[Configuration and operation]
FIG. 1 is a conceptual diagram showing a configuration of a power supply system 151 which is an example of the power supply system of the present embodiment. FIG. 1 also shows a load 201 that is a power supply target of the power supply system 151.

The power supply system 151 includes a power supply device 161 and a shutoff device 106.

The power feeding device 161 includes N units 171 to 17N, a current detection unit 121, and an FET 131. Here, FET is an abbreviation for field-effect transistor. The FET is, for example, a MOS-FET. Here, MOS is an abbreviation for Metal-Oxide-Semiconductor.

The unit 17n includes a converter 1n, a current detection unit 2n, and an FET 3n. Here, n is an integer of 1 or more and N or less, including the following description.

Power is input to the converter 1n from the terminal 4n. The converter 1n converts the input power into a predetermined DC power. The converter 1n is, for example, a DC-DC converter. Here, DC is an abbreviation for direct current. The converter 1n outputs the converted DC power to the current detection unit 2n.

The current detection unit 2n detects the current value of the output from the converter 1n, and sends the detected current value to the processing unit 111 of the breaking device 106. The current detection unit 2n continuously performs the detection and the transmission. The output from the converter 1n that has passed through the current detection unit 2n reaches the FET 3n.

The FET 3n conducts or cuts off the conduction between the source and the drain by supplying or stopping the supply of the gate voltage. Under normal conditions, the FET 3n is electrically connected between its source and drain by supplying a gate voltage. When the source and drain of the FET 3n are conducting, the output from the converter 1n is supplied to the FET 3n via the current detection unit 2n. Each of the FETs 3n is, for example, a MOS-FET.

During normal operation, the source and drain of the FET 3n are conducted by supplying a voltage to the gate. Therefore, a current is supplied to the load 201 from each of the converters 1n. Then, the current detection unit 121 detects the total current supplied to the load 201 from each of the converters 1n. Then, the current detection unit 121 sends a current value representing the total current supplied to the load 201 to the processing unit 111 of the cutoff device 106. The current detection unit 121 continuously performs the detection and the transmission.

The processing unit 111 specifies a portion to be cut off from the current value sent from the current detection units 2n and 121 from each of the FETs 3n and 131. An example of a specific operation of the cutoff point is as follows, for example.

The processing unit 111 reads the design value of the current value detected by the current detection unit 2n and the first threshold value from the recording unit 116. Then, the processing unit 111 determines whether or not the value (first difference) obtained by subtracting the design value from each current value sent from each of the current detection units 2n is larger than the first threshold value. The processing unit 111 continuously makes the determination for each current value continuously sent from each of the current detection units 2n, for example, at predetermined time intervals.

When the processing unit 111 determines that the first difference is larger than the first threshold value with respect to the current value sent from any of the current detection units 2n, the processing unit 111 sends the determined current value. Information for identifying the current detection unit 2n is sent to the control unit 126.

The control unit 126 receives the specific information from the processing unit 111 and cuts off the conduction between the source and the drain of the FET 3n immediately following the current detection unit 2n specified by the specific information.

After that, for example, the administrator of the power supply system 151 takes measures such as causing the spare unit to supply power to the load 201 instead of the unit 17n that cuts off the continuity. This is because the increase in the output current from the converter 1n causes the occurrence of failure of the converter 1n to be estimated. The manager or the like may take measures to switch only the converter 1n of the unit 17n whose continuity is cut off to a spare converter.

On the other hand, the processing unit 111 performs the following operation independently of the above operation.

The processing unit 111 reads the second threshold value from the recording unit 116. Then, the processing unit 111 derives the total value of the current values sent from each current detection unit 2n. Then, the processing unit 111 derives a value (second difference) obtained by subtracting the total value from the total current value sent from the current detection unit 121.

The processing unit 111 determines whether the second difference is larger than the second threshold value. The processing unit continuously makes the determination, for example, at predetermined time intervals.

Then, when the processing unit 111 determines that the second difference is larger than the second threshold value, the processing unit 111 sends information to the control unit 126 that the blocking point is the FET 131.

Upon receiving the transmission of the information, the control unit 126 releases the voltage application to the gate of the FET 131 and cuts off the conduction between the source and the drain thereof.

After that, for example, the administrator of the power supply system 151 takes measures such as switching the entire power supply device 161 to another power supply device. This is because the occurrence of the third difference strongly estimates the occurrence of problems such as current leakage due to the electric path between each of the FETs 3n of the unit 17n and the current detection unit 121. The manager may replace the wiring between each of the FETs 3n and the current detection unit 121 with a spare wiring. The manager may also repair the wiring between each of the FETs 3n and the current detection unit 121.

The recording unit 116 holds the above-mentioned first threshold value, second threshold value, design value of the current value detected by the current detection unit 2n, and design value of the total current value detected by the current detection unit 121. The recording unit 116 records other information instructed by the processing unit 111. The recording unit 116 also sends the information to be held to the processing unit 111 according to the instruction of the processing unit 111.
[Processing flow]
FIG. 2 is a conceptual diagram showing an example of a processing flow of processing for specifying a blocking location from N FETs 3n, which is performed by the processing unit 111 of the blocking device 106 shown in FIG.

The process shown in FIG. 2 is based on the premise that each of the N current detection units 2n shown in FIG. 1 sequentially sends the detected current values to the processing unit 111.

The processing unit 111 starts the processing shown in FIG. 2, for example, when the power is turned on.

Then, the processing unit 111 sets the timer setting time t1 to 0 as the processing of S101, and starts measuring the elapsed time from the time t1 = 0. Here, it is assumed that the processing unit 111 can use a timer (not shown).

Next, the processing unit 111 determines the design value from each of the current values sent from each of the N current detection units 2n and the current value detected by the current detection unit 2n read from the recording unit 116 as the processing of S102. Each of the subtracted values (first difference) is derived.

Then, as the processing of S103, the processing unit 111 compares each of the first differences with the first threshold value read from the recording unit 116, and whether any of the first differences is equal to or greater than the first threshold value. To make a judgment about. Here, the first threshold value is a threshold value for the first difference, which is predetermined for the processing of S103 and is held by the recording unit 116. The first threshold value is for determining that the first difference is not due to noise or the like but is substantial. The first threshold is selected from values that cannot be explained by the presence of noise or the like.

If the determination result of the processing of S103 is yes, the processing unit 111 performs the processing of S105.

On the other hand, when the determination result by the processing of S103 is no, the processing unit 111 performs the processing of S107.

When the processing unit 111 performs the processing of S105, the processing unit 111 transmits the FET 3n in the immediately subsequent stage of the current detection unit 2n that has sent the current value determined that the first difference is equal to or greater than the first threshold value. Specify as a cutoff point.

Then, the processing unit 111 sends the information representing the FET 3n specified by the processing of S105 to the control unit 126 as the processing of S106.

Then, the processing unit 111 performs the processing of S107.

When the processing of S107 is performed, the processing unit 111 determines whether to end the processing shown in FIG. 2 as the same processing. The processing unit 111 makes the determination based on, for example, the presence or absence of input of end information from the outside. The termination information is, for example, due to the power being turned off in the shutoff device 106 shown in FIG.

If the determination result in S107 is yes, the processing unit 111 ends the processing shown in FIG.

On the other hand, when the determination result by S107 is no, the processing unit 111 performs the processing of S104.

When the processing of S104 is performed, the processing unit 111 determines whether or not the elapsed time at which the measurement is started by the processing of S101 exceeds the time ΔT. Here, ΔT is a threshold value of the elapsed time set in advance for performing one process loop shown in FIG. 2 for each time ΔT.

If the determination result of the processing of S104 is yes, the processing unit 111 repeats the processing of S101 described above.

On the other hand, when the determination result by the processing of S104 is no, the processing unit 111 performs the processing of S104 again.

FIG. 3 is a conceptual diagram showing an example of a processing flow of a determination process of whether or not the interrupting point is the FET 131, which is performed by the processing unit 111 of the interrupting device 106 shown in FIG. The process shown in FIG. 3 is performed in parallel with the process shown in FIG.

The process shown in FIG. 3 is based on the premise that each of the current detection units 2n and 121 shown in FIG. 1 sequentially sends the detected current values to the processing unit 111.

The processing unit 111 starts the processing shown in FIG. 3, for example, when the power is turned on.

Then, the processing unit 111 sets the timer setting time t2 to 0 as the processing of S201, and starts measuring the elapsed time from the time t2 = 0. Here, it is assumed that the processing unit 111 can use a timer (not shown).

Next, the processing unit 111 derives the sum of the current values sent from each of the current detection units 2n as the processing of S202.

Then, the processing unit 111 derives a second difference, which is a value obtained by subtracting the sum of the current values derived by the processing of S202 from the total current value sent by the current detection unit 121 as the processing of S203.

Then, the processing unit 111 determines whether the second difference derived by the processing of S203 is equal to or greater than the second threshold value read from the recording unit 116.

If the determination result of the processing of S205 is yes, the processing unit 111 performs the processing of S207.

On the other hand, when the determination result by the processing of S205 is yes, the processing unit 111 performs the processing of S209.

When the processing unit 111 performs the processing of S207, the processing unit 111 specifies the FET 131 as a cutoff point as the same processing.

Then, as the process of S208, the processing unit 111 notifies the control unit 126 shown in FIG. 1 that the FET 131 is a cutoff point.

Then, the processing unit 111 performs the processing of S209.

When the processing of S209 is performed, the processing unit 111 determines whether to end the processing shown in FIG. 3 as the same processing. The processing unit 111 makes the determination based on, for example, the presence or absence of input of end information from the outside. The termination information is, for example, due to the power being turned off in the shutoff device 106 shown in FIG.

When the determination result in S209 is yes, the processing unit 111 ends the processing shown in FIG.

On the other hand, when the determination result by S209 is no, the processing unit 111 performs the processing of S206.

When the processing of S206 is performed, the processing unit 111 determines whether or not the elapsed time at which the measurement is started by the processing of S206 exceeds the time ΔT. Here, ΔT is a threshold value of the elapsed time set in advance for performing one process loop shown in FIG. 3 for each time ΔT.

If the determination result of the processing of S206 is yes, the processing unit 111 repeats the processing of S201 described above.

On the other hand, when the determination result by the processing of S206 is no, the processing unit 111 performs the processing of S206 again.

FIG. 4 is a conceptual diagram showing an example of a processing flow of processing performed by the control unit 126 shown in FIG.

The control unit 126 starts the process shown in FIG. 4, for example, when the power is turned on.

Then, as a process of S301, the control unit 126 determines whether or not the information representing the FET specified as the cutoff position is sent from the processing unit 111 shown in FIG.

When the determination result by the process of S301 is yes, the control unit 126 performs the process of S302.

On the other hand, when the determination result by the process of S301 is no, the control unit 126 performs the process of S301 again.

When the control unit 126 performs the processing of S302, the control unit 126 cuts off the conduction between the source and the drain of the FET specified as the cutoff position in the information determined to have been sent by the processing of S301. The control unit 126 performs the interruption by, for example, stopping the voltage supply to the gate of the FET.

Then, the control unit 126 determines whether to end the process shown in FIG. 4 as the process of S303. The control unit 126 makes the determination based on, for example, the presence or absence of input of end information from the outside. The termination information is, for example, due to the power being turned off in the shutoff device 106 shown in FIG.

When the determination result by S303 is yes, the control unit 126 ends the process shown in FIG.

On the other hand, when the determination result by S303 is no, the control unit 126 performs the process of S301 again.
[effect]
As described above, the power supply system 151 measures the amount of increase in the current value related to the output from each unit 17n and the amount of increase in the total current value related to the output in the subsequent stage of each unit connected in parallel.

Then, when the amount of increase in the current value related to the output from each of the units 17n exceeds the first threshold value, it is considered that an abnormality has occurred inside the unit 17n, and the power supply from the unit 17n is stopped.

When the increase in the total current value is equal to or greater than the sum of the increases in the current value related to the output from each unit 171n, the power supply from the power supply device 161 to the load 201 is stopped. The reason for this stop is that it is presumed that an abnormality has occurred in the portion after the output from each unit 17n.

By the above operation, the power supply system 151 enables the quick identification of the abnormal part and the stop of the power supply according to the abnormal part. As a result, the power supply system 151 makes it possible to suppress the spread of damage to the load 201 and the like due to overlooking the abnormality and delaying the response to the abnormality.

If there is an abnormality only in the output current from a certain unit 171n, only the output current from that unit 171n is cut off. Therefore, at least, when the current is supplied from the spare unit to the load 201 after the interruption, the current supply from the power feeding device 161 to the load 201 can be continued.

When the converter 1n included in the power feeding device 161 is a DC-DC converter, the above effect is particularly remarkable. This is because the DC-DC converter includes a portion that converts the input DC power into alternating current, and the probability of failure due to the failure of the conversion portion is higher than that of other converters.

FIG. 5 is a conceptual diagram showing the configuration of the specific device 101x, which is the minimum specific device of the present invention.

The specific device 101x includes a specific unit 111x.

The identification unit 111x specifies a cutoff point related to continuity between the load and each power feeding device from the current value of each current and the total current value of the total current. The current value of each of the currents is a current value supplied to the load from each of the plurality of power feeding units of the power feeding device (not shown). The total current value is the current value of the total current supplied to the load from the set of the plurality of power feeding devices.

The specifying device 101x identifies the cutoff point from the current value of each current and the total current value of the total current. Therefore, the specific device 101x enables the user of the power feeding device to quickly take measures such as shutting off the cutoff portion and replacing the power feeding unit with a spare. Therefore, the specific device 101x can ensure the continuation of power supply to the load for a longer period of time while suppressing the prevention of the spread of damage in the power supply system and the load.

Therefore, the specific device 101x exhibits the effects described in the section [Effects of the Invention] according to the above configuration.

Although each embodiment of the present invention has been described above, the present invention is not limited to the above-described embodiment, and further modifications, substitutions, and adjustments can be made without departing from the basic technical idea of the present invention. Can be added. For example, the composition of the elements shown in each drawing is an example for facilitating the understanding of the present invention, and is not limited to the composition shown in these drawings.

Further, a part or all of the above-described embodiment may be described as in the following appendix, but is not limited to the following.

(Appendix A1)
The load is derived from the current value of each current supplied to the load from each of the plurality of power supply units of the power supply device and the total current value of the total current supplied to the load from the set of the plurality of power supply units. And a specific part that specifies the cutoff point related to the cutoff of the continuity with each of the power supply parts,
Specific device including.

(Appendix A2)
The specific device according to Appendix A1, wherein the cutoff point is specified from each of the power feeding portions and each of the loads, and between all of the power supply units and the load.

(Appendix A3)
The specific device according to Appendix A1 or Appendix A2 that identifies one of the cutoff points.

(Appendix A4)
When it is determined that the amount of increase in current from each of the power feeding units exceeds the first threshold value, the power supply unit and the load related to the amount of increase determined to exceed the first threshold value The specific device according to any one of Supplementary A1 to Supplementary A3, which specifies the interval as the cutoff point.

(Appendix A5)
When the value obtained by subtracting the sum of the outputs from each of the power feeding units from the total current exceeds the second threshold value, the space between all of the above and the load is specified as the cutoff point. The specific device according to any one of A4.

(Appendix A6)
The specific device according to any one of Supplementary A1 to Supplementary A5, wherein the power feeding unit includes a DC-DC converter.

(Appendix A7)
The specific device according to any one of Supplementary A1 to Supplementary A6, wherein the power feeding unit is a DC-DC converter.

(Appendix A8)
The specific device according to any one of Supplementary A1 to Supplementary A7, further comprising a first detection unit for detecting the current value of each of the currents.

(Appendix A9)
The specific device according to any one of Supplementary A1 to Supplementary A8, further comprising a second detection unit for detecting the total current value.

(Appendix B1)
A breaking device including a control unit capable of controlling the breaking of continuity at the breaking point specified by the specific device described in any one of Supplementary A1 to Supplementary A9.

(Appendix B2)
The specific device described in any one of Supplementary A1 to Supplementary A9, and
A breaking device including a control unit capable of controlling the breaking of continuity at the breaking point specified by the specific device.

(Appendix B3)
The blocking device according to Appendix B1 or Appendix B2, further comprising the blocking location.

(Appendix B4)
The shutoff device according to Appendix B3, wherein the cutoff point is a switch.

(Appendix B5)
A breaker according to Appendix B3 or Appendix B4, wherein the cutoff point is a field effect transistor.

(Appendix C1)
From each of the current values supplied to the load by each of the plurality of power supply units of the power supply device and the current values supplied to the load by all of the plurality of power supply units, electricity between the load and each of the power supply units is obtained. A specific method for identifying a route blockage.

(Appendix D1)
From each of the current values supplied to the load by each of the plurality of power feeding units of the power feeding device and the current values supplied to the load by all of the plurality of power feeding units, electricity between the load and each of the above. A specific program that causes a computer to execute a process that identifies a route block.

11, 12, 1n, 1N converters 21, 22, 2n, 2N, 121 Current detectors 31, 32, 3n, 3N, 131 FETs
41, 42, 4N terminals 101, 101x Specified device 106 Breaking device 111 Processing unit 111x Specified unit 116 Recording unit 126 Control unit 151 Power supply system 161 Power supply device 171, 172, 17n, 17N Unit 201 Load

Claims (7)

The load is derived from the current value of each current supplied to the load from each of the plurality of power supply units of the power supply device and the total current value of the total current supplied to the load from the set of the plurality of power supply units. And a specific part that specifies the cutoff point related to the cutoff of the continuity with each of the power supply parts,
Equipped with a,
When it is determined that the value obtained by subtracting the design value from the current value of each current exceeds the first threshold value, the cutoff point is the subtracted value determined to exceed the first threshold value. It is determined that the value obtained by subtracting the sum of the outputs from each of the power supply units from the total current value exceeds the second threshold value at the cutoff point between the power supply unit and the load. If so, it is between all the feeding parts and the load.
Specific device. The specific device according to claim 1 , wherein the power feeding unit includes a DC (direct current) -DC converter. The specific device according to claim 1 or 2 , further comprising a first detection unit for detecting the current value of each current and a second detection unit for detecting the total current value. A breaking device including a control unit capable of controlling the breaking of conduction at the breaking point specified by the specific device according to any one of claims 1 to 3. The shutoff device according to claim 4 , further comprising the cutoff portion. The shutoff device according to claim 5, wherein the cutoff point is a switch. From each of the current values supplied to the load by each of the plurality of power supply units of the power supply device and the total current which is the current value supplied to the load by all of the plurality of power supply units, the load and the power supply unit are used. identify blocking portion of the electrical path between each,
When it is determined that the value obtained by subtracting the design value from the current value of each current exceeds the first threshold value, the cutoff point is between the power feeding unit and the load related to the reduced value. If it is determined that the value obtained by subtracting the sum of the outputs from each of the power supply units from the total current exceeds the second threshold value, the cutoff points are combined with all the power supply units and the load. Between
Specific method.

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