JPH09238434A - Control method for system power tap - Google Patents

Abstract

PROBLEM TO BE SOLVED: To input the power source of a slave device earlier than a master side device by supplying and stopping the power of the slave side AC output based on the detected results of a detecting means. SOLUTION: This device is constituted of a master side AC outlet 107, a detecting part 101, a threshold value correcting part 102, a threshold value setting part 103, a plurality of slave side outlets 108, 109, relay parts 104, 105 whose on-off control is conducted by a detected signal from the detecting part 101 and a power plug 112. Power is supplied from the master side receptacle 107 when the power source of a master device is turned on. The detecting part 101 turns on both the relay parts 104, 105 to conduct power source supply to the slave side receptacles 108, 109, detecting that the master device is turned on from a change in current, and in case it is not turned on, a threshold value is adjusted so as it may turn on by the threshold value setting part 103. It is thus possible to input the power source of the slave side device earlier than the master device.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a system power tap control system, and more particularly to a system power tap control system having an automatic power control function for a computer configured in a master / slave relationship and peripheral devices.

[0002]

2. Description of the Related Art As a conventional technique of an automatic power tap for supplying power to a plurality of other electronic devices in synchronization with power-on of an electronic device body, for example, Japanese Utility Model Laid-Open No. 5-9139 discloses a service of a master device. There has been proposed an automatic power tap configuration in which power is supplied to a slave device by power supply from an outlet, and the supply current is monitored to prevent overcurrent and to mitigate inrush current. As shown in FIG. 9, the automatic power tap proposed in the above publication includes power feed switches 8a to 8n for switching between energization and de-energization for each of the plurality of AC outlets 7a to 7n and energization command signals 9a to. Power supply sequence control means 9 for controlling the power supply states of the plurality of power supply switches 8a to 8n in a predetermined order based on 9n is provided.

In Japanese Utility Model Laid-Open No. 4-85679,
A master outlet, multiple slave outlets and electromagnetic relays are connected in parallel to the power plug, a current detector is provided on the circuit leading to the master outlet, and a solid that operates from the detection signal of this current detector on the circuit leading to the slave outlet. A solid state relay and a variable timer are provided. The solid state relay controls the electromagnetic relay to be turned on and off, and the normally open contact opens and closes the main circuit of the slave outlet. The variable timer turns on the solid state relay that energizes the slave outlet. There has been proposed a power strip configuration in which on / off control is performed.
This power strip detects the current of the master outlet and turns on / off the slave outlet.

Further, in Japanese Patent Laid-Open No. 143204/1993, as a method for controlling power between a server and a client connected by a LAN (local area network), the server responds to a connection request for a communication connection from the client. The connection is registered in the control table, and in response to the power-off instruction, the client notifies the server that is using the resource via the line, and the client in the control table is notified. Change to the unconnected state, wait for all the clients in the control table to be unconnected when all clients in the control table are unconnected in response to the server power off instruction, and wait for all of them to become unconnected. A power-off control method that is configured to turn off the power has been proposed.
This power-off control method is for collectively controlling the power supply of the server and the client, and is not for individually controlling the power supply of a large number of disk devices such as file servers and the server body.

[0005]

The above-mentioned prior art has a problem that it cannot be applied to an apparatus that requires sequential power supply control because of the overcurrent and inrush prevention functions.

That is, since a master device such as a computer performs a resource search immediately after power-on, if a slave device such as a file device is not powered-on first,
It is determined that the slave device is not connected and the system is constructed. For this reason, if the power-on sequence is incorrect, the peripheral device may not operate normally even if there is no failure or fault in the peripheral device. In particular, in a system that is operated for 24 hours, since the power is not turned on / off every day, there is no recognition of the order of turning on the power, and there is a possibility that a trivial matter may cause a big problem.

When it is necessary to comply with the power-on sequence, manual operation is indispensable, making it difficult to realize unmanned automatic operation.

The power tap proposed in Japanese Utility Model Laid-Open No. 4-85679 can be applied to equipment without a service outlet as compared with the automatic power tap proposed in Japanese Utility Model Laid-Open No. 5-9139. However, these conventional techniques are not without problems.

That is, in the power tap described in Japanese Utility Model Laid-Open No. 4-85679, the power tap must be prepared depending on the current value of the device connected to the master outlet.

This is because when a power tap for a large-scale server is used in a small-scale device, the on-state cannot be detected because the current when the device is powered on is small, while the power-strip of the small-scale device is not detected. This is because when used for a large-scale server, the dark current when the power is turned off is detected and it is always on.

Further, when this conventional power strip is applied to a device in consideration of energy saving, in a device provided with a power saving mode, for example, the power supply of a disk device or a display device is automatically cut off depending on the use condition. Even if there is no problem in the normal mode, the power may be turned off when the power saving mode is entered. For this reason, the peripheral device is powered off even though the master device is powered on, and the master device cannot be used normally.

Therefore, the present invention has been made to solve the above-mentioned problems, and it can be realized from an information processing apparatus such as a notebook EWS (engineering workstation) which consumes less power to a multi-CPU ( It can support server devices with large power consumption such as multi-processor configuration, and can also support on-current changes in power saving mode during the operation of energy-saving type devices. Furthermore, master side device (computer body) An object of the present invention is to provide a system power tap control method having a power-on sequence control function capable of powering on a slave device (file device or the like) earlier.

[0013]

In order to achieve the above-mentioned object, the present invention provides a detection means for detecting the power-on / off state of the master device based on the AC outlet used current of the master-side device, and the current value of the master device. Threshold value correcting means for correcting the threshold value for detecting the on / off state of the master device in the detecting means, the threshold value setting means for variably setting the threshold value, and the detecting means. A control system for a system power tap, comprising: a relay unit that supplies / stops power to an AC outlet on the slave side according to a detection result.

Further, according to the present invention, the detection means for detecting the power on / off state of the master device by the AC outlet use current of the master side device, and the power supply / power supply of the slave side AC outlet based on the detection result of the detection device. In the case of the power supply sequence control and the relay unit that performs the stop, the power supply to the AC outlet of the master side device is temporarily stopped, and after a predetermined time is supplied to the AC outlet of the slave side, the master side is provided. Sequence control means for controlling resumption of power supply to the AC outlet, sequence setting means for setting time to the sequence control means, and control signal from the sequence control means to the master side AC outlet. A system part including a master-side relay section for supplying / stopping power supply. To provide a control method of-tapped.

Further, according to the present invention, the detecting means for detecting the power on / off state of the master device by the AC outlet used current of the master side device, and the master in the detecting means according to the magnitude of the current value of the master device. Threshold value correction means for correcting the threshold value for detecting the on / off state of the device, threshold value setting means for variably setting the threshold value, and power supply sequence control to the AC outlet of the master side device Of the sequence control means for controlling the resumption of power supply to the AC outlet on the master side after a predetermined time after the power supply to the AC outlet on the slave side is temporarily stopped and after the power is supplied to the AC outlet on the slave side. From the sequence setting means for setting time to the sequence control means AC by the control signal of the master side
A master-side relay section for supplying / stopping power supply to the outlet; and a slave-side relay section for supplying / stopping power supply to the slave-side AC outlet according to a control signal from the sequence control means. A system power tap control method is provided.

[0016]

According to the present invention, the system power tap temporarily stops supplying power to the AC outlet on the master side, supplies power to the AC outlet on the slave side, and then, after a certain period of time, supplies power to the AC outlet on the master side. The sequence control means for controlling the restart of the power supply of the master side and the master side relay section for supplying / stopping the power supply to the master side AC outlet under the control of this sequence control means are included. After the AC outlet of the slave device is turned on at the time set to, the AC outlet of the master side can be turned on, and the power of the computer system having a master / slave relationship can be freely turned on.

Further, according to the present invention, by providing the threshold value correcting section for correcting the detection result of the ON / OFF state depending on the magnitude of the current of the master device, the magnitude of the ON current flowing through the AC outlet on the master side is small. Power supply to the AC outlet on the slave side accurately.

Further, according to the present invention, the threshold value correcting means can set the ON current detected by the AC outlet on the master side in accordance with the normal operation and the power saving mode of the energy saving type computer. Therefore, when entering the power saving mode, the AC on the master side
Even if the current flowing through the outlet decreases, the AC outlet on the slave side is prevented from being turned off.

[0019]

Embodiments of the present invention will be described in detail below with reference to the drawings.

[0020]

First Embodiment FIG. 1 is a diagram showing the configuration of the first embodiment of the present invention. Referring to FIG. 1, a first embodiment of the present invention is directed to a master side AC outlet (outlet) 10.
7, a detection unit 101, a threshold value correction unit 102 that corrects the threshold value of the detection unit 101, a threshold value setting unit 1 for variably setting the threshold value
03, a plurality of slave-side outlets 108, 109, relays of the slave-side outlets 108, 109 which are ON / OFF controlled by a detection signal from the detection unit 101, and a power plug 112. There is.

When the master device is powered on, power is supplied from the master side outlet 107. At this time, the detection unit 10
1 detects the power-on of the master device from the change in the current and turns on both the relay units 104 and 105 to supply power to the slave side outlets 108 and 109.

Next, the function of the threshold value correction unit 102 will be described with reference to the timing waveform chart of FIG.

In the threshold value correction unit 102,
The threshold value is set for the current detected by the detection unit 101, as shown in FIG. That is, when the current value flowing through the detection unit 101 exceeds the threshold value, both relay units 104 and 105 change from OFF to ON, and power is supplied to the slave device side.

When the relay units 104 and 105 are not turned on, the threshold value setting unit 103 adjusts the threshold value so that they are turned on.

When the master device is provided with an energy saving mechanism, the current detected by the detecting unit 101 changes depending on the usage state even when the power is on.
That is, as shown in FIG. 2, the current detected by the detection unit 101 decreases in the power save (power saving) mode.

However, since the threshold value is set to be lower than the current value in the power save mode, the relay unit 10 also operates in the power save mode.
4, 105 are kept in the ON state, and the slave side outlets 108, 109 are not turned off. If the current value in the power save mode varies depending on the device and the slave side outlets 108 and 109 are turned off, the threshold value setting unit 103 prevents the slave side outlets 108 and 109 from being turned off. The threshold value is adjusted to a certain value.

In the above embodiment, the number of the outlets on the slave side is two, but the number of outlets may be two or more.

[0028]

Second Embodiment Next, a second embodiment of the present invention will be described. FIG. 3 is a diagram showing a configuration of the second exemplary embodiment of the present invention. With reference to FIG. 3, in the present embodiment, the master side outlet 207, the detection unit 201, and the master side outlet 207.
Relay unit 206, a sequence control unit 210 for inputting detection signals from the detection unit 201, a sequence setting unit 211, a plurality of slave-side outlets 208, 209, and slaves of the slave-side outlets 208, 209 which are relays from the sequence control unit 210 The master side outlet 20 is provided with relay units 204 and 205 that are on / off controlled by a switching signal.
The sequence control unit 2 also turns on / off the relay unit 206
10.

When the master device is turned on, power is supplied from the master side outlet 207. When power is required to be supplied in advance to the master device in the slave device, the sequence setting unit 211 causes the required delay time T1,
Set T2, T3, and T4 in advance.

Here, T1 is an outlet 20 on the master side.
7 is the time from when the relay unit 206 of No. 7 is turned on to when it is turned off (temporarily disconnected).

T2 is the time from turning off the relay unit 206 of the master side outlet 207 to turning on the relay unit 204 of the slave side outlet 208.

T3 is the time from when the relay unit 204 of the slave side outlet 209 is turned on to when the relay unit 205 of the slave side outlet 209 is turned on.

T4 is the time from when the relay unit 205 of the slave side outlet 208 is turned on to when the relay unit 206 of the master side outlet 207 is turned on (reclosed).

In the present embodiment, the description has been made assuming that the number of slave side outlets is two, but the same is true for two or more.

Next, the relay operation of this embodiment will be described. Referring to the timing waveform diagram of FIG. 4, when the power of the master device is turned on, the detection unit 201 detects the power-on and stops the power supply to the master side outlet 207 after T1 time. Turns the relay unit 206 from ON to OFF. At this time, the detection unit 201
Notifies the sequence control unit 210 of the apparent power-off of the master device due to the turning off of the relay unit 206. However, since the sequence control unit 210 is executing the sequence,
Ignore power off of the master unit.

The sequence control unit 210 turns on the relay unit 205 after turning on the relay unit 205 after T2 in order to turn on the slave side outlet 208.

Further, the sequence control unit 210 turns on the relay unit 204 from OFF to ON after T3 time in order to turn ON the slave side outlet 209.

Finally, in order to turn on the power of the master device again, the sequence control unit 210 turns the relay unit 206 from OFF to ON after T4. Sequence control unit 210
Confirms that the detection unit 201 detects that the master device is powered on, and completes the sequence operation. In the above sequence, all devices are powered on.

When the master device is switched off after the start of the sequence operation, the detection unit 201 again notifies the sequence control unit 210 that the master device is powered off after the completion of the sequence operation. At this time, since the sequence is not being executed, the sequence control unit 210 turns off both the slave side outlets 208 and 209.

[0040]

Third Embodiment A third embodiment of the present invention will be described below. FIG. 5 is a diagram showing the configuration of the third exemplary embodiment of the present invention. With reference to FIG. 5, in the present embodiment, the master side outlet 307, the detection unit 301, and the master side outlet 307.
Relay unit 306, threshold value correction unit 302 that corrects the threshold value of detection unit 301, threshold value setting unit 303 that variably sets the threshold value,
Sequence control unit 310, sequence setting unit 311, a plurality of slave side outlets 308, 309, relays of the slave side outlets 308, 309, and relay units 304, 305 that are on / off controlled by a switching signal from the sequence control unit 310. Is equipped with.

When the master device is turned on, power is supplied from the master side outlet 307. When advance power supply is required for the device on the slave side, necessary delay times T1, T2, T3, T4 are set in the sequence setting unit 311.

Here, T1 is an outlet 30 on the master side.
7 is the time from when the relay unit 306 is turned on to when it is turned off (temporarily disconnected).

T2 is the time from turning off the relay unit 306 of the master side outlet 307 to turning on the relay unit 304 of the slave side outlet 308.

T3 is the time from when the relay unit 304 of the slave side outlet 308 is turned on to when the relay unit 305 of the slave side outlet 309 is turned on.

T4 is the time from when the relay unit 305 of the slave side outlet 309 is turned on to when the relay unit 306 of the master side outlet 307 is turned on (reclosed).

In the present embodiment, the description has been made assuming that there are two slave side outlets, but the same applies to the case of two or more outlets.

Next, the relay operation of this embodiment will be described. Referring to the timing waveform diagram of FIG. 6, when the power of the master device is turned on, the detection unit 301 detects the power on,
Since the power supply to the master side outlet 307 is stopped after T1 time, the sequence control unit 310 sets the relay unit 10
Turn 6 on → off.

At this time, the detection unit 301 has the relay unit 306.
The sequence control unit 310 is notified of the apparent power-off of the master device due to the turning off of the sequence control unit 310.
Since 10 is executing the sequence, the power-off of the master device is ignored.

The sequence control section 310 turns on the relay section 304 after turning on the relay section 304 after T2 in order to turn on the slave side outlet 308.

Further, the sequence control unit 310 turns on the relay unit 305 from OFF to ON after T3 in order to turn on the slave side outlet 309.

Finally, in order to turn on the power of the master device again, the sequence control unit 310 turns the relay unit 306 off → on after T4. Sequence control unit 31
When 0, it is confirmed that the detection unit 301 detects that the master device is powered on, and the sequence operation is completed. With the above, the power of all the devices is turned on.

Next, the relay operation when the power switch of the master device is turned off after the start of the sequence will be described with reference to FIG.

When the power switch of the master device is turned off after the start of the sequence, after the sequence is completed, the detection unit 30
1 turns off the power of the master device again and the sequence control unit 3
Notify 10.

At this time, since the sequence is not being executed,
The sequence control unit 310 uses the slave side outlet 30.
Turn off 8,309.

FIG. 8 is a flow chart showing the sequence control of the second embodiment and this embodiment. Referring to FIG. 8, when the sequence control is being performed, the delay time T
When 1 to T4 are set and the signal from the detection unit is on (step 803), the master side relay unit is turned off according to the set time (step 804), and then the slave side according to the set delay time. After sequentially turning on the relay units of (1) (step 805) and turning on all the slave side relay units, the master side relay unit is turned on according to the set delay time (step 807). And
When the detection unit detects that the power is off (step 808), all the relay units on the slave side are turned off (step 80).
9). On the other hand, when the sequence control is not in progress, the relay unit on the slave side is turned on (step 813) when the detection unit detects the power-on (step 812), and the slave unit is turned on when the detection unit detects the power-off. The relay unit on the side is turned off (step 814).

Next, the relay operation when the threshold value is not properly set will be described with reference to FIG. It is assumed that the threshold value correction unit 302 is set for the current detected by the detection unit 301 as shown by the solid line 102a in FIG.

In the power save mode, the detection unit 301
The current detected at will decrease. At this time, the threshold value 102a is made improper, and the current 101a detected by the detection unit 301 falls below the threshold value (102a),
The sequence control unit 310 turns off the relay units 304 and 305 and stops the power supply to the slave side outlets 308 and 309.

However, in the present embodiment, the threshold value setting unit 303 sets the threshold value to
If the value shown by the broken line 102b in FIG.
The current 101a detected by 01 is the threshold value 1
It does not fall below 02b, and the slave side outlet 30
The power supply of 8 and 309 is maintained.

According to the above-described embodiment, the sequence control unit can turn on the power supply of the slave device such as the file device at the time set by the sequence setting unit. No manual operation is required in, and unmanned automatic driving is possible. Although the present invention has been described with respect to each of the above embodiments, the present invention is not limited to the above embodiments, and it goes without saying that various embodiments conforming to the principle of the present invention are included.

[0060]

As described above, according to the present invention,
Since the sequence control unit is configured to turn on the power supply of the slave device such as the file device at the time set by the sequence setting unit, there is an effect that it is possible to cope with a device requiring sequential power-on.

Therefore, according to the present invention, the power supply of the slave side device is turned on before the master device, and when the master device such as a computer searches the resource of the slave side device at the time of turning on the power source, it is ensured. A system can be constructed by recognizing connected devices. As a result, according to the present invention, no manual operation is required when powering on a plurality of slave devices, and unattended automatic operation is possible.

Furthermore, according to the present invention, in a plurality of devices, it is possible to prevent the power supplies from being turned on at the same time, so that it is possible to prevent an overcurrent and an inrush current.

Further, according to the present invention, there is an effect that it is not necessary to prepare the power tap depending on the magnitude of the current of the device connected to the master outlet. This is because the threshold value correction unit and the threshold value setting unit allow the threshold value to be variably set according to the current of the detection unit when using a large-scale server or a small-scale device.

Furthermore, when applied to a device in consideration of energy saving, the disk and the display device are automatically turned off and on depending on the usage condition.
Although the current detected by the detector changes, according to the present invention,
The threshold value correction unit and the threshold value setting unit allow the threshold value in the detection unit to be variably set, which has the effect of realizing a highly reliable system that avoids malfunctions.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration of a first exemplary embodiment of the present invention.

FIG. 2 is a timing chart for explaining the operation of the relay unit according to the first embodiment of the present invention.

FIG. 3 is a diagram showing a configuration of a second exemplary embodiment of the present invention.

FIG. 4 is a timing chart for explaining the operation of the relay section in the second embodiment of the present invention.

FIG. 5 is a diagram showing a configuration of a third exemplary embodiment of the present invention.

FIG. 6 is a timing chart for explaining the operation of the relay unit according to the third embodiment of the present invention.

FIG. 7 is a timing chart for explaining the operation of the relay section in the third embodiment of the present invention.

FIG. 8 is a flowchart for explaining sequence control in the second and third embodiments of the present invention.

FIG. 9 is a diagram showing a configuration of a conventional power strip.

[Explanation of symbols]

 101 detection unit 101a current value of detection unit 102 threshold value correction unit 102a threshold current value (inappropriate) 102b threshold current value (adequate) 103 threshold value setting unit 104 relay unit of slave side outlet 1 05 slave side outlet 2 Relay section 106 Master side outlet relay section 107 Master side outlet 108 Slave side outlet 1 109 Slave side outlet 2 110 Sequence control section 111 Sequence setting section 201 Detection section 204 Slave side outlet 1 relay section 205 Slave side outlet 2 relay section 206 Master-side outlet relay unit 207 Master-side outlet 208 Slave-side outlet 1 209 Slave-side outlet 2 210 Sequence control unit 211 See Sense setting section 301 Detection section 302 Threshold value correction section 303 Threshold value setting section 304 Slave side outlet 1 relay section 305 Slave side outlet 2 relay section 306 Master side outlet relay section 307 Master side outlet 308 Slave side outlet 1 309 Slave Side outlet 2

Claims (4)

[Claims] 1. A detection means for detecting a power-on / off state of the master device based on a current used by an AC outlet of the master-side device, and an on / off state of the master device in the detection device according to a magnitude of a current value of the master device. Threshold value correction means for correcting the threshold value for detecting the off state, threshold value setting means for variably setting the threshold value, and power supply / stop of the slave AC outlet depending on the detection result of the detection means. A system power tap control method characterized by having a relay section that performs. 2. Detecting means for detecting a power-on / off state of the master device based on an AC outlet used current of the master-side device, and a relay for supplying / stopping power to the slave-side AC outlet based on the detection result of the detecting means. And the power supply sequence control, the power supply to the AC outlet of the master side device is temporarily stopped, and after a predetermined time is supplied to the slave side AC outlet, the master side AC outlet is supplied. Sequence control means for controlling resumption of power supply to the master, sequence setting means for setting time to the sequence control means, and power supply / stop to the AC outlet on the master side by a control signal from the sequence control means. The master side relay section that performs Your system. 3. A detection means for detecting a power-on / off state of the master device by using an AC outlet used current of the master-side device, and an on / off state of the master device in the detection means according to a magnitude of a current value of the master device. Threshold value correction means for correcting the threshold value for detection of the off state, threshold value setting means for variably setting the threshold value, and power supply to the AC outlet of the master side device during power sequence control. A sequence control unit that controls the restart of the power supply to the master-side AC outlet after a predetermined time has elapsed after the suspension and the power supply to the slave-side AC outlet, and a time setting for the sequence control unit. And a control signal from the sequence control means. A master-side relay unit that supplies / stops power to the master-side AC outlet; and a slave-side relay unit that supplies / stops power to the slave-side AC outlet according to a control signal from the sequence control unit. A system power tap control method characterized by the following. 4. The sequence control means stops the power supply to the AC outlet on the master side after a predetermined time when the detection means detects the power-on of the master device during the power supply sequence control. In order to do so, the master-side relay unit is turned off, and at this time, the notification of the apparent power-off of the master device due to the turning-off of the master-side relay unit from the detection unit is ignored, and the slave-side In order to turn on the AC outlet, a plurality of relay units on the slave side are turned on after a predetermined time, and in order to turn on the power of the master device again, the master side relay unit is turned on and the power supplies of all devices are turned on. The control method of the system power tap according to claim 2 or 3, wherein the control is performed so that the power is turned on.