JPH0232854B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a sequential power-on method for sequentially powering on a plurality of equipment units.

In recent years, when monitoring and controlling a plurality of equipment units such as peripheral equipment or external storage devices, computer systems using microcomputers have been introduced, and a large number of equipment units can be efficiently monitored and controlled. However, turning on power to these equipment units is done manually, regardless of the computer, and the computer determines whether or not each equipment unit is powered on, and then determines whether these power supplies have been established. As a result, processing is performed using normal routines.

By the way, when power is applied to multiple equipment units equipped with electric motors at almost the same time, excessive inrush current flows, so in order to suppress this, relays (hereinafter referred to as relays), time-limited relays (hereinafter referred to as timers), etc. are used. A sequential input circuit is used.

As shown in FIG. 1, in a conventional order-on circuit, when a switch 101 in a power supply device 100 is manually closed, a relay 102 is energized and a contact 102-a is turned on.
With the operation of , conduction occurs between terminals T ₁ and T ₂ . As a result, the power supply voltage Vcc is supplied to the equipment unit 10, and the relay 11 (K1) connected in parallel to this power supply circuit is energized. in this case,
The normally open contact K1-a of the relay 11 is connected to the timer 12 (T
1), and when the relay 11 is energized, the timer 12 is also energized, and after a certain period of time,
The normally open contact T1-a of this timer 12 is closed.

The normally open contact T1-a of this timer 12 turns on the power circuit of the equipment unit 11 (not shown) in the same way that the contact 102-a turns on the power of the equipment unit 10. FIG. 1 shows the nth equipment unit n0.

That is, when the normally open contact T1-a of the timer 12 is closed, the power supply voltage Vcc is supplied to the equipment unit n0, and the relay n1 (Kn) connected in parallel to the power supply circuit of this equipment unit n0 is energized. At the same time, the normally open contact of relay n1
Timer n2 (Tn) is also excited via Kn-a. After a certain period of time has elapsed since the timer n2 was energized, the normally open contact Tn-a of the timer n2 is closed, and the next equipment unit is turned on.

By turning on the power to each equipment unit 10...n0... in this manner, excessive inrush current can be suppressed to a low level even when a plurality of equipment units are provided with electric motors.

In such a conventional sequence input circuit, a timer and a relay must be added to each equipment unit, and special cables are required to sequentially connect the equipment units, and their configuration and assembly are difficult. This method has the drawbacks of being complicated and somewhat less reliable because it involves mechanical elements.

The present invention has been made to eliminate the above-mentioned drawbacks, and does not require mechanically operated elements such as relays and timers, or special cables for connecting devices, is simple in configuration, and has high reliability. The purpose is to provide an order input method that can improve the results.

In order to achieve the above object, the order input method of the present invention provides a switching element in each power supply circuit of a plurality of equipment units, and adds a program timer function to the firmware of a computer system that controls and monitors the equipment units. The switching elements are sequentially made conductive according to the firmware program, and power is sequentially applied to the plurality of equipment units.

Hereinafter, the order input method of the present invention will be explained with reference to the accompanying drawings.

FIG. 2 is a block diagram showing the configuration of an order input circuit that implements the order input method according to the present invention. In the figure, the same reference numerals as in FIG. 1 indicate the same elements. is an electric motor, 1
4, n4 are equipment units 10 and n0, respectively.
15 is a thyristor as a switching element inserted in each power supply circuit of the equipment unit, 16, n6 is an input/output circuit that sends data of the equipment unit to the outside or receives and temporarily stores control signals. are shown respectively.

On the other hand, 200 is a control device that controls and monitors the equipment units 10...n0..., in this case, it is also equipped with a function to sequentially turn on power to the equipment units 10...n0..., 201 is a microcomputer;
02 is a program that does not need to be changed much.
Firmware written in ROM or PROM, etc., which also has the function of a program timer, 203
204 is a control circuit that generates a power-on signal for the equipment unit 10...n0..., and thyristor 15, n5.
205 is a memory, 206 is a data register for transferring data between the equipment unit and the control device 200, and 207 is the equipment unit 10...n.
0... to output a control signal and store the status signal of the selected equipment unit in the data register 206, respectively.

The operation of the sequential entry circuit configured as shown in FIG. 2 will be explained below.

First, when power is turned on to the control device 200, it is reset to the initial state and the firmware 200 is turned on.
02, the program starts from address 0, and first determines whether or not the equipment units 10...n0... are connected to the control device 200. This judgment is made by the microcomputer 201 at the multiplexer 20.
7 are sequentially scanned, the signals of the input/output circuits 16 . . . n6 .

Next, the equipment unit 10...n0... and the control device 20
When the connection with 0 is confirmed, firmware 202
operates the control circuit 203 and the drive circuit 20
4 (LD1), the thyristor 15 in the equipment unit 10 is made conductive, and this equipment unit 10
Turn on the power. Here, firmware 20
2 has a timer created by software, that is, it has the function of a program timer, so after a certain period of time has elapsed after outputting the power-on signal of the equipment unit 10, the control circuit 203 is operated, and the control circuit 203 is activated via the drive circuit 204. Make the thyristor in the next equipment unit conductive and turn on its power circuit.

Thereafter, these operations are repeated in the same manner to turn on the power to all equipment units.

In this way, when all the equipment units are powered on, the status signals of the input/output circuits 16...n6... are taken into the microcomputer 201 via the signal lines 210...2n0... based on the scanning of the multiplexer 207. It is determined whether or not power has been applied to each equipment unit, and the result is stored in the memory 205. However, if any of the equipment units is not powered on, the operator will be informed of the number of the equipment unit that is not powered on and appropriate measures will be taken.

In this way, when power is supplied to all the equipment units, just as if the firmware 202 did not have the program timer function,
Perform routine control and monitoring as usual.

In this way, if a computer system equipped with firmware is used to control or monitor equipment units such as peripheral devices or external storage devices, it is necessary to replace the ROM that constitutes the firmware, or to replace the PROM. This firmware can easily be provided with a program timer function by rewriting the .

In addition, by adopting the above configuration, the device unit only needs to insert a switching element such as a thyristor into the power supply circuit. It is possible to eliminate the need for operating elements and the need for special cables for order input.
This greatly simplifies the configuration of the sequential entry circuit.

Furthermore, in the above-mentioned sequential input circuit,
Reliability can be improved because everything is replaced with electronic control, and costs can be significantly reduced because normal lines are shared.

As is clear from the above description, according to the sequential input method of the present invention, the circuit configuration can be extremely simplified, and reliability can be improved and costs can be significantly reduced.

[Brief explanation of drawings]

FIG. 1 is a circuit diagram showing the configuration of a conventional order entry circuit, and FIG. 2 is a block diagram showing an example of an order entry circuit implementing the order entry method according to the present invention. 10,n0...Equipment unit, 11,n1,1
02...Relay, 12, n2...Time-limited relay, 1
3, n3...Electric motor, 14, n4...Power supply, 1
5, n5...thyristor, 16, n6...input/output circuit, 100...power supply device, 101...switch, 200...control device, 201...microcomputer, 202...firmware, 203
... Control circuit, 204 ... Drive circuit, 205
...Memory, 206...Data register, 207
...Multiplexer.

Claims (1)

[Claims] 1. A switching element is provided in each power supply circuit of a plurality of equipment units, the firmware of a computer system that controls and monitors the equipment unit is provided with a program timer function, and the switching element is activated according to the program of the firmware. 1. A sequential power-on method characterized in that the plurality of equipment units are sequentially made conductive and power is turned on to the plurality of equipment units in sequence.