JP5980087B2 - Uninterruptible power system - Google Patents

Description

  The present invention relates to an uninterruptible power supply capable of measuring the surrounding environment of a connected computer and notifying the abnormality of the surrounding environment.

  An uninterruptible power supply (UPS) is a device that can supply power to a connected computer without causing a momentary interruption when the voltage of a commercial power supply drops or a power failure occurs.

  The uninterruptible power supply includes a battery with a large capacity to supply power to the computer. For the uninterruptible power supply, since maintenance of the battery is an important matter for ensuring the reliability, there is one that notifies the user of the battery replacement time as shown in Patent Document 1 below.

JP 2002-287857 A

  As mentioned above, although there is technology to notify the user when the battery of the uninterruptible power supply is replaced, measure the surrounding environment of the computer to which the uninterruptible power supply is connected, and notify the abnormality of the surrounding environment, There is no technology to shut down the connected computer when the surrounding environment is abnormal.

  In recent years, the power of one or more computers is backed up by one or more uninterruptible power supplies. In the field, it is possible to measure the surrounding environment of each computer connected to the uninterruptible power supply, to report abnormalities in the surrounding environment, and to shut down the connected computer when the surrounding environment is abnormal There is a request to have a function.

  The present invention has been made in order to meet the conventional demands of the field as described above, and provides an uninterruptible power supply device that can measure the surrounding environment of a connected computer and can notify the abnormality of the surrounding environment. Objective.

  The uninterruptible power supply according to the present invention includes an input unit, a threshold storage unit, a comparison unit, an abnormality notification unit, and a shutdown control unit.

The input unit inputs detection values of a plurality of sensors that detect the surrounding environment of the computer. The threshold value storage unit stores a threshold value for reporting an abnormality in the surrounding environment of the computer. The comparison unit compares the detection value of each sensor input from the input unit with the threshold value stored in the threshold value storage unit. The abnormality notification unit notifies the abnormality of the surrounding environment of the computer when the detection value exceeds the threshold value as a result of the comparison in the comparison unit. The shutdown control unit shuts down the connected computer when the detected value exceeds the threshold value. The sensor registration unit registers whether to shut down when the detected value exceeds the threshold value. The computer registration unit registers a computer to be shut down. The shutdown control unit shuts down the computer when the computer in which the abnormality notification unit has notified the abnormality is registered in the computer registration unit.

  According to the uninterruptible power supply according to the present invention configured as described above, when an abnormality occurs in the surrounding environment of the computer to which the uninterruptible power supply is connected, the abnormality in the surrounding environment of the computer is notified. be able to.

It is a whole lineblock diagram of the uninterruptible power supply concerning this embodiment. It is a block diagram of the control part of the uninterruptible power supply shown in FIG. 3 is an operation flowchart of the LAN interface card shown in FIG. 2. It is a subroutine flowchart which shows operation | movement of step S130 of the operation | movement flowchart shown in FIG.

  Next, the uninterruptible power supply according to this embodiment will be described with reference to the drawings.

[Configuration of uninterruptible power supply]
FIG. 1 is an overall configuration diagram of the uninterruptible power supply according to the present embodiment. The uninterruptible power supply (UPS) 100 includes a UPS main body 110 and a LAN interface card 120. The UPS main body 110 supplies backup power to computers such as the server 160 and the PC 170. The LAN interface card 120 is a card that is inserted into a slot of the UPS main body 110.

  The LAN interface card 120 can connect a maximum of 16 sensors such as the sensors 150A, 150B, 150C,. The sensors 150A, 150B, 150C,... 150P are temperature sensors or humidity sensors provided around the server 160 and the PC 170 in order to detect the surrounding environment of the server 160 and the PC 170. Specifically, the sensors 150A, 150B, 150C,... 150P are installed in a rack or a room that houses the server 160 and the PC 170. The sensors 150A, 150B, 150C,... 150P are daisy chain connected.

  When there is an abnormality in the temperature and humidity (surrounding environment) around the server 160 and PC 170 detected by the sensors 150A, 150B, 150C,. To the user. The notification of abnormalities in the surrounding environment may be performed using images and sounds on the UPS main body 110, or images and sounds may be transmitted to the user or notified by e-mail.

  Further, the UPS 100 can shut down the server 160 and the PC 170 in which the surrounding environment is abnormal. Furthermore, the UPS 100 can accumulate detection data of the surrounding environment detected by the sensors 150A, 150B, 150C,. In addition, the aggregated data can be output to the outside. The user can know changes with time in the surrounding environment by analyzing the collected data.

  The above functions in the UPS 100 are realized by the LAN interface card 120.

[Configuration of LAN interface card]
FIG. 2 is a block diagram of the LAN interface card 120 of the UPS main body 110 shown in FIG. In this embodiment, the LAN interface card 120 is provided in the UPS 100, but the function of the LAN interface card 120 may be provided in the USP main body 110.

  The LAN interface card 120 includes an input unit 132, a threshold storage unit 134, a comparison unit 136, and an abnormality notification unit 138.

  The input unit 132 inputs detection values of a plurality of sensors 150A, 150B, 150C,... 150P that detect the surrounding environment of a computer such as the server 160 and the PC 170 shown in FIG. The detected values are the temperature around the computer and the humidity around it. Each sensor is registered in the sensor registration unit 133.

  The threshold value storage unit 134 stores a threshold value for reporting an abnormality in the surrounding environment of the computer. Specifically, the threshold is set to 60 ° C. for temperature and 95% for humidity. The threshold value may be set for each sensor registered in the sensor registration unit 133 or may be set collectively. Also, a plurality of different value thresholds may be set for each sensor so that different levels of abnormality can be reported depending on which threshold is exceeded.

  The comparison unit 136 compares the detection value of each sensor input from the input unit 132 with the threshold value stored in the threshold value storage unit 134. The comparison result is output to an abnormality notification unit 138 described later.

  The abnormality notifying unit 138 notifies the abnormality when the detected value exceeds the threshold value as a result of the comparison in the comparing unit 136. Various means for notifying abnormality can be considered. If the probability that the user is near the UPS main body 110 is high, the image may be displayed using the image or sound on the UPS main body 110. If the user is not near the UPS main body 110, the image or sound may be displayed to the user. May be sent or emailed.

  Further, the LAN interface card 120 includes a computer registration unit 142 and a shutdown control unit 140.

  The computer registration unit 142 registers a computer to be shut down when the detected value exceeds the threshold value. For example, when the server 160 is selected as a computer to be shut down from the server 160 and the PC 170 shown in FIG. 1, the server 160 is registered in the computer registration unit 142.

  The shutdown control unit 140 causes the registered computer to shut down when the computer in which the abnormality notification unit 138 has notified the abnormality is registered in the computer registration unit 142. Also, the power supply of the computer is stopped.

  For example, it is assumed that the server 160 illustrated in FIG. 1 is registered in the computer registration unit 142, and the temperature threshold value of the sensors around the server 160 stored in the threshold value storage unit 134 is 60 ° C. At this time, if the ambient temperature of the server 160 detected by the sensor is 65 ° C., the abnormality notification unit 138 notifies the abnormality, while the shutdown control unit 140 notifies the server 160 when this state continues for a certain period of time. The server 160 is shut down by outputting a shutdown command. Further, when the UPS main body 110 supplies power to the server 160, the supply can be stopped.

  Further, the LAN interface card 120 includes a data storage unit 144, a totaling unit 146, and a data output unit 148.

  The data storage unit 144 stores detection data of each sensor input from the input unit 132 for each sensor and each type of detection value. For example, when the sensors 150A and 150C are temperature sensors and the sensors 150B,..., 150P are humidity sensors, the detection value of the sensor 150A is 25 ° C., the detection value of the sensor 150C is 29 ° C., and the detection value of the sensor 150B. Is 75%, and so on, and the detection value of the sensor 150P is 77%.

  The totaling unit 146 totals the detection data stored in the data storage unit 144 at a predetermined time period. For example, the temperature and humidity detection values stored in the data storage unit 144 for each sensor are tabulated every 10 minutes, every hour, every day. The aggregation results totaled by the aggregation unit 146 are stored in the data storage unit 144.

  The data output unit 148 outputs the detection value or the total result stored in the data storage unit 144 in response to an external request.

  Note that only the input unit 132, the threshold storage unit 134, the comparison unit 136, the abnormality notification unit 138, the computer registration unit 142, and the shutdown control unit 140 may be provided in the LAN interface card 120, or the input unit 132 and the threshold storage unit 134. The comparison unit 136, the abnormality notification unit 138, the computer registration unit 142, the shutdown control unit 140, the data storage unit 144, the totaling unit 146, and the data output unit 148 may all be provided in the LAN interface card 120.

[Operation of LAN interface card]
Next, the operation of the LAN interface card 120 will be described in detail based on the flowcharts of FIGS. FIG. 3 is an operation flowchart of the LAN interface card 120 shown in FIG. FIG. 4 is a subroutine flowchart showing the operation in step S130 of the operation flowchart shown in FIG. The flowchart of FIG. 3 shows the process of the measured value deviation monitoring function of the LAN interface card 120, and the flowchart of FIG. 4 shows the process of the measured value totaling function.

(Measured value deviation monitoring function processing)
First, the user registers a sensor connected to the LAN interface card 120 in the sensor registration unit 133. In this embodiment, since a maximum of 16 sensors can be daisy chained, a maximum of 16 sensors can be registered in the sensor registration unit 133. (Step S110).

  Next, the user stores the threshold value of the sensor in the threshold value storage unit 134. If the sensor type is a temperature sensor, the temperature is stored as a threshold, and if the sensor is a humidity sensor, the humidity is stored as a threshold. In the present embodiment, the notification level is set to two levels of “attention level deviation” and “warning level deviation”. Therefore, the threshold value storage unit 134 stores two threshold values: a first threshold value for notifying “attention level deviation” and a second threshold value for notifying “warning level deviation”.

  For example, the first threshold value of the temperature sensor for the server 160 shown in FIG. 1 is 50 ° C., the second threshold value is 70 ° C., the first threshold value of the humidity sensor is 85%, and the second threshold value is 95%. (Step S120).

  When the measurement value measurement starts, the input unit 132 inputs the detection value of each sensor, and outputs the input detection value to the comparison unit 136 and the data storage unit 144. The comparison unit 136 compares the detection value of each sensor input from the input unit 132 with the first threshold value and the second threshold value stored in the threshold value storage unit 134. On the other hand, the data storage unit 144 stores the detection value of each sensor input from the input unit 132 at regular intervals (step S130).

  The comparison unit 136 compares the detection value of each sensor input from the input unit 132 with the threshold value stored in the threshold value storage unit 134, and when the detection value of the sensor exceeds the first threshold value (step S140). The abnormality notifying unit 138 is notified of this, and the abnormality detecting unit 138 notifies the outside of the attention. For example, when a sensor that detects the temperature around the server 160 detects a temperature that exceeds the first threshold value of 50 ° C., the abnormality notification unit 138 notifies the outside of the attention. The user can recognize that there is a possibility that some abnormality has occurred by seeing the notice of attention (step S150).

  Next, when the detection value of the sensor exceeds the second threshold value (step S160), the abnormality notification unit 138 notifies the fact and the abnormality detection unit 138 notifies the outside of the warning. For example, when the sensor that detects the ambient temperature of the server 160 detects a temperature that exceeds the second threshold of 70 ° C., the abnormality notification unit 138 issues a warning notification to the outside. The warning notification means that the situation is more urgent than the attention notification. The user can recognize that a certain urgent abnormality has occurred by seeing the warning notification (step S170).

  Next, when the detection value of the sensor with the shutdown setting exceeds the second threshold value (step S180), the shutdown control unit 140 outputs a shutdown command to the computer registered in the computer registration unit 142. The computer that has received the shutdown command performs a shutdown process. The UPS main body 110 can also stop the power supply of the computer after the shutdown command is completed. (Step S190).

(Measured value aggregation function processing)
The sensor connected to the input unit 132 detects the temperature or humidity around the sensor. The detected value of temperature or humidity is stored in the data storage unit 144 (step S131).

  The aggregation unit 146 aggregates the temperature and humidity detection data measured for 10 minutes for each sensor when 10 minutes have elapsed based on the clock information managed by the LAN interface card 120 (step S132). . The aggregation result is stored in the data storage unit 144 as 10-minute data (step S133).

  The aggregation unit 146 aggregates the temperature and humidity detection data measured for one hour for each sensor when one hour has passed based on the clock information managed by the LAN interface card 120 (step S134). . The aggregation result is stored in the data storage unit 144 as 1 hour data (step S135).

  When 24 hours have elapsed based on the clock information managed by the LAN interface card 120 (step S136), the totaling unit 146 totalizes the temperature and humidity detection data measured for 24 hours for each sensor. . The aggregation result is stored in the data storage unit 144 as data for one day (step S137).

  When one month has passed based on the clock information managed by the LAN interface card 120 (step S138), the counting unit 146 obtains temperature and humidity detection data measured for one month for each sensor. Tally. The total result is stored in the data storage unit 144 as data for one month (step S139).

  Detection data and total data for 10 minutes, 1 hour, 1 day, and 1 month stored in the totaling unit 146 can be imported from the outside via the data output unit 148. By monitoring these aggregated data, it is possible to grasp changes in the environment in which computers such as the server 160 and the PC 170 are placed. The time period for collecting the detection data is not limited to 10 minutes, 1 hour, 1 day, and 1 month as in the above example, and daily report data, monthly report data, annual report data, and the like may be set as appropriate. . Further, the totaling unit 146 calculates a maximum value, a minimum value, an average value, a median value, a standard deviation, and the like for a certain period of time for the detection data, and stores them in the data storage unit 144. Also good.

  As described above, according to the uninterruptible power supply according to the present embodiment, in addition to supplying power to the connected computer, an abnormality in the environment where the computer is placed can be detected at a plurality of levels, You can also grasp changes.

100 uninterruptible power supply,
110 UPS body,
120 LAN interface card,
132 input section,
133 sensor registration unit,
134 threshold storage unit,
136 comparison part,
138 Abnormality notification unit,
140 Shutdown controller,
142 computer registration department,
144 Data storage unit 146 Totaling unit,
148 data output unit,
150A, 150B, 150C, ... 150P sensor,
160 servers,
170 PC.

Claims (9)

An input unit for inputting detection values of a plurality of sensors for detecting the surrounding environment of the computer to be backed up;
A threshold storage unit for storing a threshold for notifying the abnormality of the surrounding environment of the computer;
A comparison unit that compares the detection value of each sensor input from the input unit with a threshold value stored in the threshold value storage unit;
As a result of the comparison in the comparison unit, when the detected value exceeds the threshold value, an abnormality notification unit for notifying abnormality,
When the detected value exceeds the threshold value, and a shutdown control unit to shut down the computer connected, it was closed, and further,
A sensor registration unit for registering whether to shut down when the detected value exceeds the threshold; a computer registration unit for registering a computer to be shut down;
When the computer in which the abnormality notification unit has notified the abnormality is registered in the computer registration unit, a shutdown control unit for shutting down the computer,
An uninterruptible power supply comprising:   A plurality of different values for the threshold are set for each of the sensors, and the abnormality notification unit notifies a plurality of different levels of abnormality depending on which threshold of the plurality of thresholds the threshold value exceeds. The uninterruptible power supply according to claim 1. The uninterruptible power supply according to claim 1 , wherein the shutdown control unit outputs a shutdown command to a computer to be shut down. The uninterruptible power supply according to claim 3 , wherein the shutdown control unit stops the supply of power to the computer that has output the shutdown command. The uninterruptible power supply according to any one of claims 1 to 4 , further comprising a data storage unit that stores detection data of each sensor input from the input unit. 6. The data storage unit according to claim 5 , further comprising a totaling unit that totals the detection data stored in the data storage unit at a predetermined time period, and the totaling result by the totaling unit is stored in the data storage unit. Uninterruptible power supply. The uninterruptible power supply according to claim 6 , further comprising a data output unit that outputs detection values or total results stored in the data storage unit in response to an external request. The uninterruptible power supply according to any one of claims 1 to 7 , wherein the plurality of sensors are connected in a daisy chain. The uninterruptible power supply according to any one of claims 1 to 8 , wherein the surrounding environment is at least one of a temperature and a humidity around the plurality of computers.

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