JPH0341845B2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention provides that after the power of the power-controlled device is turned on in response to a command from the power-controlled device, the power of the power-controlled device is switched on. In addition to preventing the power from being turned off due to an abnormality in the controlling device or a disconnection of the power control line, the power controlling device can only turn off the power to the controlled device when the controlled device has turned on the power off permission signal. This relates to a remote power control system that allows the power to be turned off.

[Prior art and problems]

When remotely controlling the power supply of a slave system from the host side, there is a possibility that the host side system goes down or
If you do not protect the slave system from abnormalities in the interface between the host and the slave system,
When the power on the host side goes out or the interface cable breaks, the power on the slave system also goes down, and the slave system's own local job, which does not require connection with the host system, becomes unable to continue. Put it away.

[Purpose of the invention]

The present invention is based on the above considerations, and includes:
It is an object of the present invention to provide a remote power supply control method that protects a system on the power-controlled side from the above-mentioned abnormal conditions and improves the reliability of the system as a whole.

[Means to achieve the purpose]

For this reason, the remote power control system of the present invention includes a power controlled device, a power controlled device, one end of which is input to the power supply section of the power controlled device, and the other end of which is connected to the power controlled device. a pair of power supply control lines that can be short-circuited by the contacts of the first relay; a power-on flip-flop provided on the power-controlled device; and a power-off permission flip-flop provided on the power-controlled device. A flip-flop, a contact point of a second relay connected in parallel to the power control line pair, and when the power-on flip-flop is set, the first relay is driven to connect the power control line pair to the power supply control line pair. a first relay driving means that short-circuits one end of the first relay and sets the first relay in an inoperable state when the power-on flip-flop is reset to release the short-circuit at the other end of the pair of power supply control lines through its contacts; When the power-off enable flip-flop is reset, the second relay is operated to short-circuit the power supply control line pair at its contact, and when the power-off enable flip-flop is set, the second relay is activated. a second relay driving means that puts the second relay in a non-operating state and releases the short-circuit of the power supply control line pair through its contacts; a power off permission signal line for sending an on power off permission signal to the power control side device; Flip for on
If the flip-flop is not reset and the above power-off enable signal is on, the above-mentioned power-on flip
The device is characterized in that it is configured to reset the flop.

[Embodiments of the invention]

Hereinafter, the present invention will be explained with reference to the drawings.

FIG. 1 is a diagram showing an example of a system to which the present invention is applied. In Figure 1, 1-1 to 1
-4 is an optical coupling device, 2 is a ring management device, 3-1
3 to 3-7 are processors, and 4 is a ring-shaped transmission path. The system shown in Figure 1 uses a talk ring type LAN (LOCAL AREA).
NETWORK). The ring management device 2 controls the entire LAN. The optical coupling device 1-i (i=1, 2, . . . ) has the function of coupling the connected processor to the ring-shaped transmission line 4 or bypassing it, as well as a relay for controlling the power supply of the processor (Fig. (not shown). Power control of the processor connected to the optical coupling device 1-i is managed by the ring management device 2. The ring-shaped transmission line 4 is composed of an optical fiber.

FIG. 2 is a diagram showing the configuration of one embodiment of the main parts of the processor and the optical coupling circuit. In FIG. 2, 5 is a power-off enable flip-flop, 6 is an inverter, 7 is a transistor, 8 is a relay winding, and 9
is a relay contact, 10 is a resistor, 11 and 12 are power control lines, 13 is a power-off permission signal line, 14 is a relay winding, 15 is a relay contact wire, 16 is a resistor, 17 is a transistor, 18 is a power-on flip・Flop, 19 is driver, 20 is receiver, 21
is the microprocessor, 22 is the ROM, and 23 is the
RAM 24 and 25 indicate line control units, respectively.

When the power-on flip-flop 18 is set, the transistor 17 turns on, current flows through the relay winding 14, and the relay contact 15 closes.
A current flows through the power supply section, and the processor 3-2 is powered on. When processor 3-2 is powered on, power-off enable flip-flop 5 is reset. When power-off enable flip-flop 5 is reset, transistor 7 turns on, current flows through relay winding 8, and closes relay contact 9. Therefore, even if the power supply control lines 11 and 1
Even if processor 2 is disconnected, power to processor 3-2 remains on. When the job of processor 3-2 is completed and the power can be turned off,
The power
Off-permit flip-flop 5 is set.
As a result, the relay contact 9 is opened, and at the same time, a power-off permission signal is sent to the optical coupling device 1-2 via the signal line 13. In addition, the optical coupling device 1-2
A processor 3-3 is also connected to the processor 3-3, and it goes without saying that portions 5 to 20 are provided corresponding to the processor 3-3.

For example, the ring management device 2 is connected to the processor 3-2.
When turning on the power, a remote power-on command is sent to the optical coupling device 1-2 onto the ring transmission line 4. The optical coupling device 1-2 knows which processor is to be powered on based on the information contained in the command, and selects the power-on flip-flop 1 of the corresponding processor 3-2.
Set 8. This closes the relay tangent 15 and turns on the power to the processor 3-2. Once the power on the processor 3-2 side is turned on, the relay contact 9 closes, and the power control line 1
Even if processors 1 and 12 are released, the power to processor 3-2 is not turned off.

When the ring management device 2 turns off the power to the processor 3-2, it sends a remote power-off command to the optical coupling device 1-2 onto the ring transmission line 4. When the optical coupling device 1-2 receives the command, it resets the corresponding power-on flip-flop 18 if the power-off permission signal is on. When the power-off permission signal is off, the power-on flip-flop 18 is not reset.

The power off enable flip-flop 5 is programmably set/resettable and is reset by the system when the job is finished and the power may be turned off. When the power-off permission is set, the relay contact 9 is released, so when the optical coupler 1-2 resets the power-on flip-flop 18, the relay contact 15 is released and the processor 3- 2 power goes out.

〔Effect of the invention〕

As is clear from the above description, according to the present invention, when the power to the power controlled device is turned on in response to a command from the power controlling device, the relay of the power controlled device operates, and the power controlled device operates. Since a power-on instruction signal is continuously input to the power supply unit of the side device, even when the power control side device goes down or the power control line is disconnected, the power to the power controlled side device does not go down.

In addition, under the condition where a failure occurs such as the contact of the second relay in the power-controlled device remains open, the power-on state of the power-controlled device is This is maintained by the closed state of the contact of the relay, so if the power control side device resets the flip-flop for power-on without permission, the power supply of the power control side device will be interrupted while the power control side device is in the middle of executing a job. A situation occurs in which the switch is turned off. In the present invention, the power-on flip-flop is not reset when the power-off permission signal is off, so that the above-mentioned situation can be prevented from occurring.

[Brief explanation of drawings]

FIG. 1 is a diagram showing an example of the field of application of the present invention, and FIG. 2 is a diagram showing an embodiment of the configuration of a main part of a processor and an optical coupling circuit. 1-1 to 1-4...optical coupling device, 2...ring management device, 3-1 to 3-7...processor, 4...ring-shaped transmission line, 5...power-off permission flip-flop, 6...Inverter, 7
...Transistor, 8...Relay winding, 9...Relay contact, 10...Resistor, 11 and 12...Power control line, 13...Power off permission signal line, 14...Relay winding, 15... Relay contact, 16...resistance,
17...Transistor, 18...Flip-flop for power-on, 19...Driver, 20...
...Receiver, 21...Microprocessor, 22
...ROM, 23...RAM, 24 and 25...line control section.

Claims (1)

[Scope of Claims] 1. A power-controlled device; a power-controlled device; and a first relay whose one end is input to the power supply section of the power-controlled device and whose other end is input to the power source of the power-controlled device. a pair of power supply control lines that can be short-circuited by the contacts of the above; a power-on flip-flop provided on the power-controlled device; a power-off enable flip-flop provided on the power-controlled device; When the contacts of a second relay connected in parallel to the power control line pair and the power-on flip-flop are set, the first relay is driven to short-circuit the other end of the power control line pair. and a first relay driving means for setting the first relay in a non-operating state when the power-on flip-flop is reset to release the short circuit at the other end of the power supply control line pair through its contact;・When the power-off permission flip-flop is reset, the second relay is operated to short-circuit the power supply control line pair at its contacts, and when the power-off permission flip-flop is set, the second relay is activated. a second relay driving means for inactivating the power control line pair and releasing the short-circuit of the power control line pair through its contacts; and a power-off permission signal line for sending an on power-off permission signal to the device;
If the flip-flop is not reset and the above power-off enable signal is on, the above-mentioned power-on flip
A remote power control system configured to reset a flop.