JP2005321929A - Power controller - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power controller capable of performing power interlock control even in a system where a peripheral apparatus such as an RAID apparatus is connected to a server. <P>SOLUTION: In the system in which at least one peripheral apparatus 1 is connected through a power interlock tap 3 to a server 2, power is supplied from the power interlock tap 3 to the server 2. The power interlock tap 3 is provided with a current detecting means 3a for detecting a current flowing through the server 2, thereby giving a power control signal in accordance with the current flowing through the server based on a current value detected by the current detecting means 3a to the peripheral apparatus. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a power supply control device, and more particularly to a power-on device that links power-on to peripheral devices. In recent years, the amount of information used in computers has been increasing in speed and capacity. RAID devices as peripheral devices for storing this information are also increasing in speed and capacity. In addition, the open (generalization) of the RAID device requires low cost and connection with various server devices.

  However, in order to connect to a RAID device, a power control signal from the host side is necessary, and many servers do not have this power control signal generation circuit. For this reason, to turn on the power by connecting to the RAID device, it is necessary to manually turn on the power manually. In this case, it is necessary to power on the RAID device before the higher-level device is activated. If the time is not enough, the RAID device will not be incorporated into the system. In addition, the system cannot be operated with unmanned systems. For this reason, it is necessary to turn on / off the power by some means.

  The RAID device is turned on and off by a power control signal from the host to realize power supply interlocking with the host. For this reason, there is no problem when the host device connected to the RAID device is a host, but when the host device to be connected is a server-related device, a problem occurs in the power supply interlocking control. The reason is that the server does not have a power control function for controlling power-on / off of lower-level devices.

As this type of conventional apparatus, for example, when a representative computer requests a schedule for powering off another computer, a power control device is provided in each computer, and the date and time of disconnection of the computer corresponding to the power control device is registered. A technique is known (for example, refer to Patent Document 1). There is also known an apparatus that preferentially selects a specific power input and supplies power to a device (for example, see Patent Document 2).
JP 2003-122456 A (page 4, page 5, FIG. 1) JP 2000-284865 A (page 4, FIG. 2)

  In the above-described conventional technology, only a system for connecting a RAID device and a host has been put into practical use, and connection with a host device that does not have a power control signal output such as a server in which the host device is considered open is possible There wasn't. Further, in order to realize the interlocking of the power sources, it is necessary to separately prepare a host device having a power control output terminal. In the future, in order to promote openness and cost reduction of the system, it was necessary to implement power supply interlocking by some means.

  The present invention has been made in view of such a problem, and an object of the present invention is to provide a power supply control device capable of performing power supply interlocking control even in a system in which a peripheral device such as a RAID device and a server are connected. It is said.

The present invention provides a device for monitoring the current consumption of a server for connection between a host device having no power control terminal and a peripheral device (RAID device) and sending a power control signal to the RAID device when the current increases. Provided separately, a power interlocking tap is provided between the RAID device and the server to realize power control in accordance with power on / off of the server. Further, when there are a plurality of connected RAID devices, it is possible to limit the devices that are linked by setting the devices that are linked to the power supply in advance. In addition, when a RAID device is added, the configuration information is obtained from the server so that the added RAID device can automatically recognize the device configuration and control the added RAID device. Is.
(1) The invention described in claim 1 is as follows. FIG. 1 is a principle block diagram of the present invention. In the figure, at least one peripheral device 1 is provided as a peripheral device. Reference numeral 1a denotes a plurality of hard disk devices (HDD) provided in the peripheral device. For example, a RAID device is used as this type of peripheral device. The RAID apparatus 1 is supplied with an AC voltage of 100 V (note that the value of the AC voltage is not limited to 100 V. It may be a voltage having other values). The AC voltage 100V is input to an internal circuit via a switch (not shown).

2 is a server, and 3 is a power supply interlocking tap provided between the peripheral device 1 and the server 2. AC 100 V is applied to the power interlocking tap 3 and is supplied to the server 2 via the inside of the power interlocking tap 3. Further, the server 2 is configured to notify the apparatus configuration information to the power interlocking tap 3. Reference numeral 3a denotes current detection means for detecting a current flowing in the server 2 provided in the power supply interlocking tap 3. A power control signal (power on / off control signal) is output from the power interlocking tap 3 to the RAID (peripheral) device 1.
(2) In the invention according to claim 2, in the case where the standby tap and the power-on threshold that are different for each server are set, the power-operated tap automatically sets the standby current and the power-on threshold. It is made to be able to detect.
(3) The invention described in claim 3 is characterized in that the power can be turned on manually even in an environment where it is difficult to turn on the power automatically due to power noise or the like.
(4) The invention according to claim 4 is characterized in that the power interlocking tap has a function of performing power control to an arbitrary device with respect to a connected peripheral device.
(5) In the invention according to claim 5, the power supply interlocking tap periodically obtains information on peripheral devices connected from the server, and can automatically cope with an increase in the number of peripheral devices. It is characterized by that.

(1) According to the invention described in claim 1, even in a system in which a peripheral device such as a RAID device and a server are connected, power supply interlocking control can be performed by providing a power supply interlocking tap.
(2) According to the invention described in claim 2, in the case where a plurality of servers are provided, it is possible to prevent malfunctions due to variations in setting by the operator.
(3) According to the invention described in claim 3, when automatic control is impossible, it is possible to manually power on the peripheral device.
(4) According to the invention described in claim 4, it is possible to perform power-on control for each peripheral device by providing a power-on threshold specific to each connected peripheral device.
(5) According to the fifth aspect of the present invention, the power supply interlocking tap periodically acquires information on the peripheral device from the server, and can automatically cope with an increase in the number of peripheral devices.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. First, the operation of the present invention will be described with reference to FIG. Here, a case where a RAID device is used as the peripheral device will be described as an example. The current detection means 3a of the power supply interlocking tap 3 measures the standby current (standby current) of the server 2. Then, a determination criterion when the power is turned on is set from the measured standby current. For example, four times the standby current is used as the determination reference value. If the current detection means 3a detects a current exceeding the determination reference value, it is determined that power is supplied to the server 2. In conjunction with this power supply, a power-on signal is given to the peripheral device 1. In this way, according to the present invention, power can be supplied to the RAID device in conjunction with the time when power is supplied to the server 2, and power supply interlocking control can be performed.

  FIG. 2 is a block diagram showing an embodiment of the power supply interlocking tap. The same components as those in FIG. 1 are denoted by the same reference numerals. In the figure, reference numeral 3a denotes a current detection circuit as current detection means for detecting a current flowing in the power supply line. Examples of the current detection circuit 3a include a method of connecting a resistor in series with the circuit and detecting a current from the current drop, a method of using a CT (current transformer), and the like. The 100V power that has passed through the current detection circuit 3a is supplied to a server 2 (not shown) as a host device.

  A control circuit 10 receives the output of the current detection circuit 3a and performs various controls. As the control circuit 10, for example, a microcomputer is used. Reference numeral 12 denotes a power-on signal generation circuit that receives a control signal from the control circuit 10 and generates a power control signal (power on / off signal) for the RAID device 1. A configuration table 11 is connected to the control circuit 10 and stores configuration information about the RAID device. The control circuit 10 is connected to the server 2 (not shown) and obtains configuration table data from the server 2. The operation of the circuit thus configured will be described as follows.

  The current detection circuit 3a always measures the standby current to the server 2. The control circuit 10 determines a reference value for determining that power is supplied from the standby current to the server 2. Specifically, for example, the reference value is four times the standby current. When the current detected by the current detection circuit 3a exceeds the reference value, the power supply interlocking tap 3 determines that power is supplied to the server 2 and sends a power control signal to the RAID device 1 to supply power. .

  Further, the configuration data from the server 2 is periodically sent and stored in the configuration table 11. Accordingly, information such as the addition of the RAID device 1 obtained by the server 2 is also stored in the configuration table 11. Therefore, by referring to the configuration table 11 by the control circuit 10, it is possible to know information on the added RAID device, and automatically perform power supply interlocking control on the added RAID device.

  According to the present invention, the power-off control of the RAID device can also be performed. That is, when the detection current of the current detection circuit 3a becomes a standby current, the control circuit 10 can turn off the supply of power from the power-on signal generation circuit 12 to the RAID device.

  In addition, according to the present invention, when the standby current and the power-on threshold value that are different for each server 2 are set, the power interlocking tap 3 automatically detects the standby current and the power-on threshold value that are different for each server. Can be done. In this way, it is possible to prevent malfunctions due to variations in settings by the operator.

  Further, according to the present invention, in an environment where it is difficult to turn on the power due to power noise or the like, the power can be turned on manually. Therefore, when automatic control of the power supply is impossible, the RAID apparatus 1 can be manually turned on.

  Further, according to the present invention, the power interlocking tap 3 can be configured such that the connected RAID device (peripheral device) 1 can perform power control to an arbitrary device. In this way, by providing a unique power-on threshold value for each connected RAID device 1, it is possible to perform power-on control for each RAID device.

  FIG. 3 is a block diagram showing an embodiment of the present invention. 1 and 2 are denoted by the same reference numerals. This figure shows a case where a server that does not have a RAID device, a power supply interlocking tap, and a power supply control output circuit is connected. In the figure, 1 is a RAID device, 2 is a server, and 3 is a power supply interlocking tap. The power supply interlocking tap 3 is disposed between the RAID device 1 and the server 2. Three RAID devices # 1 to # 3 are connected, and # 4 indicates a newly added RAID device.

  In the server 2, reference numeral 2a denotes a power supply unit (PSU: power supply unit) whose power supply is controlled by an on / off switch, and 2b denotes a configuration table in which information on the RAID device is stored. When the RAID device 1 is added, it is stored in the configuration table 2b. The contents of the configuration table 2b are transmitted to and stored in the configuration table 11 in the power supply interlocking tap 3.

  In the RAID device 1, 1a is a disk, 1b is a DC power supply (D-PSU) for supplying power to the disk 1a, and 1c is a power supply (C-PSU) for supplying power to a control circuit. A power supply control signal is notified from the power supply interlocking tap 3 to the RAID device 1 via RCI (Remote Cabinet INT). This RCI is connected to all the RAID devices 1 in an irrelevant manner. The operation of the system configured as described above will be described as follows.

  In the power supply interlocking tap 3, the current detection circuit 3a detects the current flowing through the power supply line when the power supply is connected to the server 2 (power is not turned on) (S1). This analog current is converted into a digital signal value by an A / D converter (not shown) inside the power supply interlocking tap. Then, it is recognized how much the standby current is (S2). When the standby current is recognized, the power supply reference value (threshold value) is automatically set (S3). This standby current value is obtained as an internal reference value by adding a margin. For example, if the standby current is 0.3 A, for example, the reference value of the power supply is about four times that, 0.3 × 4 = 1.2 (A).

  When the reference value of the power source is obtained, the control circuit 10 monitors the current of the current detection circuit 3a (S4). The control circuit 10 checks whether or not the current exceeds the determined reference value (threshold value) (S5). If the server 2 is turned on by the power-on operation, the current consumption of the server 2 increases and greatly exceeds the reference value set by the power supply interlocking tap 3. When the detected current exceeds the reference value, the control circuit 10 sets the interlocking device (S6). Specifically, a control signal for generating a power on / off signal of the RAID device is given to the power-on signal generation circuit 12. The power-on signal generation circuit 12 provides a power on / off (here, on) signal (power control signal) of the RAID device 1. This power control signal is notified to all RAID devices 1 via the RCI interface.

  The RAID device 1 for which power supply interlocking control is set in advance in the configuration table 11 is turned on by this power control signal. In this way, the RAID device 1 can be powered on in conjunction with the server 2 being powered on, and the system is started. Further, when a plurality of RAID devices are connected to the power supply interlocking with the server 2, the interlocking devices can be restricted by setting in advance. In this way, power is not turned on to devices that do not need to be turned on, and only devices that need to be turned on are linked to power.

  Further, the power supply interlocking tap 3 has a function of reading connection configuration information registered in the server 2 and can automatically read configuration information data even during operation. When the # 4 RAID device is newly added as shown in the figure by this automatic reading function, the addition of the RAID device is registered in the configuration table 2b of the server 2, so the information is the power interlocking tap 3 It is also registered in the internal configuration table 11. When the power is turned on next time, the added RAID device can also be turned on in conjunction with it.

  FIG. 4 is a block diagram showing details of the function of the power interlock tap. Reference numeral 3a denotes a current detection circuit which detects a flowing current as an analog signal. This analog signal enters the subsequent control circuit 10. The control circuit 10 has a digital conversion function, a current value automatic setting function, a control function based on a threshold value, an interlocking device setting function, and a periodic configuration table data acquisition function. Then, the control circuit 10 converts the analog signal of the current detection circuit 3a into a digital signal and automatically sets a threshold value for supplying power to the RAID device. The control output of the control circuit 10 is output to the RCI circuit 12 (same as the power-on signal generation circuit 12 in FIG. 2). The RCI circuit 12 functions as a power-on / off signal generation circuit and is given to the RAID device 1.

  According to the present invention, as described above, even a server without a power supply control output circuit can construct a RAID device and a power supply interlocking system, and can automatically turn on / off the entire system. In addition, when a plurality of RAID devices are connected, it has a function of limiting the devices to be linked by setting in advance in the power supply interlocking tap.

  Furthermore, by automatically reading the configuration connection data held by the server, the newly added device can be turned on in conjunction with no human intervention from the next power on. As a result, it is possible to connect to various servers, and it is possible to reduce the cost and open the system. Further, setting of the power interlocking tap and power control of the entire system can be performed without human intervention, and a stable power interlocking system can be provided.

  Hereinafter, specific embodiments will be described. A power supply interlocking system for a RAID device and a server using a power interlocking tap will be described. This power interlocking tap is connected to a server that does not have a power control function for lower-level devices, and power interlocking with the RAID device is enabled. Thereby, it becomes possible to perform power control of the whole system unattended. In addition, by setting in advance, it is possible to link only devices that require power link. Further, even for newly added devices, the configuration information is automatically read from the server, so that the connection is automatically recognized and the power is turned on without human intervention.

  The power supply interlocking tap has four output ports. Current detection is possible for each port, and a power supply interlocking function by port can also be set. When a server with an odd number of ports is powered on, only the devices connected in the odd order are linked to the RAID device. In addition, if it is set in advance, it is possible to set a RAID device linked to each port. Furthermore, by automatically acquiring the configuration connection information from the server for each port, it becomes possible to automatically perform power supply interlocking of the RAID device added for each port without human intervention. As a result, it becomes possible to automatically select a device required for each port and turn on the power.

In the above-described embodiment, the case of a RAID device as an example of the peripheral device has been described. However, the present invention is not limited to this, and other types of peripheral devices can be used.
As described above, according to the present invention, it is possible to connect the power sources to various servers in conjunction with each other. By using an inexpensive server, the system device can be made low-cost, open, reliable, and an expansion device. Automatization and automatic recognition can be performed, and power supply to unnecessary devices can be avoided, thereby contributing to power saving.

It is a principle block diagram of the present invention. It is a block diagram which shows the example of 1 embodiment of a power supply interlocking | linkage tap. It is a block diagram which shows one embodiment of this invention. It is a block diagram which shows the function details of a power supply interlocking tap.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Peripheral device 2 Server 3 Power supply interlocking tap 3a Current detection means

Claims (5)

In a system in which at least one peripheral device and a server are connected via a power interlocking tap,
The power supply interlocking tap is configured to supply power to the server, and the power supply interlocking tap is provided with current detection means for detecting the current flowing through the server,
A power supply control device characterized in that a power supply control signal corresponding to the current flowing through the server is given to the peripheral device based on the current value detected by the current detection means.   The power-interlocking tap can automatically detect the standby current and the power-on threshold when different standby currents and power-on thresholds are set for each server. The power supply control device according to claim 1.   2. The power supply control device according to claim 1, wherein the power supply control device is configured so that the power can be turned on manually even in an environment where it is difficult to automatically turn on the power due to power noise or the like.   The power supply control device according to claim 1, wherein the power supply interlocking tap has a function of performing power control to an arbitrary device with respect to a connected peripheral device.   2. The power supply according to claim 1, wherein the power supply interlock tap periodically obtains information on peripheral devices connected from the server, and can automatically cope with the addition of peripheral devices. Control device.

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