JP2006209486A - Power supply voltage monitoring system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a low-cost power supply voltage monitoring system that has independent power supply monitoring functions for a variety of voltages. <P>SOLUTION: The power supply voltage monitoring system comprises a reference power supply; a switch for turning the reference power supply on and off; a plurality of voltage conversion means for converting the voltage of the reference power supply into a plurality of voltages via the switch; and a plurality of voltage monitoring means for monitoring the levels of the voltages converted by the voltage conversion means. When either of the voltages converted by the voltage conversion means exceeds a predetermined level, a signal is issued from the voltage monitoring means so as to turn the switch off. At least one of the plurality of voltage monitoring means is formed using a CPU. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a power supply voltage monitoring system in which the voltage of a reference power supply is input via a switch and boosted or lowered to be supplied to various circuits, as in a device such as a process input / output module. The present invention relates to a power supply voltage monitoring system configured to turn off the switch when at least one of the voltages exceeds a predetermined voltage level.

  In power supply monitoring, the following documents are known for detecting instability of a supplied power supply voltage. The technology described in that document is based on a power monitoring circuit configuration for a device having a mixture of circuits operated by different DC power supplies. In addition to the power monitoring circuit for each DC power supply that detects an abnormality in the DC power supply, the system runs away. A watchdog timer circuit to monitor is provided, and when one power supply monitoring circuit inputs a reset signal output from the watchdog timer circuit, it outputs with one reset signal that is the same as the power supply monitoring detected by its own circuit. is there.

JP 2000-339069 A

  FIG. 4 shows a power supply voltage monitoring system configured to turn off the reference power supply when at least one of the voltages obtained by stepping up or down the voltage of the reference power supply exceeds a predetermined voltage level. .

In FIG. 4, 1 is a switch for turning on and off a reference power supply voltage (for example, 24 V).
2a, 2b... 2n are regulators (voltage converting means) connected to the switch 1, and the regulator 2a steps down the 24V reference voltage to 12V. The regulator 2b is connected to the subsequent stage of the regulator 2a and steps down the voltage of 12V to 9V, and the regulator 2n similarly steps down the voltage of 9V to 5V.

  Reference numerals 3a, 3b,... 3n are power supply monitoring means. The power supply monitoring means 3a monitors the voltage level of the voltage 12V (OVP overvoltage protection, UVP undervoltage protection) stepped down by the regulator 2a, and the power supply monitoring means 3b The voltage level (OVP, UVP) of the voltage 9V stepped down by the regulator 2b is monitored, and the power supply monitoring means 3n monitors the voltage level of the voltage 5V stepped down by the regulator 2n.

An OR circuit 4 receives a signal transmitted from the power supply monitoring means when any of the power supply voltages monitored by the power supply monitoring means 3a to 3n exceeds a predetermined level.
Although not shown in the figure, each stepped-down voltage is sent to various circuits (electronic devices) and functions as an operating voltage of those circuits.

  In the power supply voltage monitoring system described above, when any voltage among the voltages converted by the regulators 2a to 2n exceeds a predetermined level, various circuits (electronic devices) operating at the voltage are broken down. Including abnormalities. The power supply monitoring units 3 a to 3 n detect that any one of these voltages exceeds a predetermined voltage level, and transmit a control signal to the OR circuit 4. The OR circuit 4 transmits the signal to the switch 1 to turn it off. As a result, various circuits using the voltage converted voltage can be protected.

However, in the above-described conventional example, since all voltage monitoring means are configured by hardware, there is a problem that the scale of circuit mounting increases and the cost increases.
The present invention has been made to solve the above problems, and an object thereof is to provide a low-cost power supply monitoring system having a conventional independent power supply monitoring function for various voltages. .

In order to achieve such a subject, the present invention provides the following:
A reference power supply, a switch for turning on and off the reference power supply, a plurality of voltage converting means for converting the voltage of the reference power supply into a plurality of voltages via the switch, and monitoring each voltage level converted by the voltage converting means In the voltage monitoring device comprising a plurality of voltage monitoring means, and when any of the voltages converted by the voltage conversion means exceeds a predetermined level, the voltage monitoring means emits a signal to turn off the switch, At least one of the plurality of voltage monitoring means is configured using a CPU.

In claim 2, in the plant power supply monitoring device according to claim 1,
The voltage monitoring means in the CPU is constituted by software installed in the firmware of the CPU.

In claim 3,
A first CPU in which software that functions as voltage monitoring means is installed in firmware, a second CPU connected to the CPU via a communication line, and a voltage from a reference power supply is taken in via a switch to perform voltage conversion. A first voltage converting means for outputting to the first CPU; a second voltage converting means connected to a subsequent stage of the first voltage converting means; and a voltage monitoring means for monitoring the voltage level of the second voltage converting means. When the power level of the first voltage conversion means exceeds a predetermined level, the first CPU turns off the switch via the communication line and the second CPU, and the power level of the second voltage conversion means reaches a predetermined level. When exceeded, the voltage monitoring means turns off the switch via the second CPU, and the first CPU and second voltage conversion means. Characterized by being configured to emit a reset signal to various circuits using the converted voltage.

  As is apparent from the above description, according to claims 1 and 2 of the present invention, software in which at least one of the plurality of voltage monitoring means is replaced with a CPU and the voltage monitoring means in the CPU is installed in the firmware of the CPU. Since it is configured by hardware, a large number of voltages can be monitored, and the use of expensive hardware (HW) can be minimized. .

  According to the third aspect of the present invention, the cost can be reduced by using hardware. The function of the first CPU 6a is stopped by using the reset signal of the power supply monitoring means 3 which is hardware, and various circuits are provided. Since the operation is stopped, the system can be surely stopped.

Hereinafter, the present invention will be described in detail with reference to the drawings.
In general, in a process input / output device or the like, a general-purpose one-chip microprocessor (μP) is used to realize self-diagnosis or switching. This general-purpose one-chip μP
In general, an AD converter is mounted as a standard.

  In the present invention, a voltage monitoring (OVP / UVP) function is realized by using this μP AD converter, and a part of the voltage monitoring means that has been individually configured by hardware (HW) is realized by μP. To do.

However, the voltage monitoring means of the 5V power source used for driving the μP is configured by hardware as usual.
When an overvoltage / undervoltage is detected by the power supply voltage monitoring function constituted by these μPs and hardware, the power supply is stopped by turning off 24V to the circuit.

FIG. 1 is a block diagram showing an embodiment of the present invention.
In FIG. 1, the same elements as those in the conventional example of FIG. Reference numeral 6 denotes a CPU, which has a multiplexer 6a and an AD converter 6b which are provided as standard. A plurality of voltages stepped down by the regulators 2 a to 2 c are input to the multiplexer 6 a through the switch (SW) 1. The AD converter 6b performs A / D conversion on the voltages sequentially taken in by the multiplexer and sends them to the voltage level diagnosis means 6c. The voltage level diagnosis means 6c is software incorporated in firmware (FW), and determines whether the voltage stepped down by the regulators 2a to 2c is maintained at a predetermined level.

  The final-stage regulator 2n is stepped down to 5V, which is the driving voltage of the CPU 6, and the output is input to the voltage monitoring means 3n configured by hardware. The voltage monitoring unit 3n diagnoses whether or not the stepped down voltage is maintained at a predetermined voltage level.

In the configuration described above, when any of the voltages stepped down by the regulator exceeds a predetermined level, a signal is issued to the OR circuit 4a to turn off the switch (SW) 1.
According to such a configuration, it is possible to monitor a large number of voltages simply by using a CPU used in the system and adding software for voltage level diagnosis to the firmware of the CPU. Use of wear (HW) can be minimized.

  FIG. 2 shows another embodiment, in which 1 is a switch for turning on and off a reference voltage (for example, 24V), 7 is a DC / DC converter for stepping down the reference voltage 24V to, for example, 9V and outputting it to the first CPU 6a and the regulator 2 (First voltage conversion means). Although not shown in the figure, the first CPU 6a has software that functions as first voltage monitoring means installed in the firmware.

  The regulator 2 (second voltage conversion means) receives the 9V voltage stepped down by the DC / DC converter 7 and steps down the voltage to 5V, for example. The stepped-down voltage of 5V is supplied as a power source for various circuits and is output to the second voltage monitoring means 3 comprising hardware (HW). Reference numeral 6 d denotes a second CPU connected to the first CPU via the communication line 8.

  In the above-described configuration, when the power source level stepped down by the DC / DC converter 7 exceeds a predetermined level, the first CPU 6a transmits a signal to the second CPU 6d via the communication line 8. The second CPU 6d generates a control signal using the signal as a trigger to turn off the switch 1.

  When the power supply level stepped down by the second voltage conversion means (regulator) 2 exceeds a predetermined level, the voltage monitoring means 3 turns off the switch 1 via the second CPU 6d and sends a reset signal to the first CPU 6a. To stop the function of this CPU. This reset signal is also sent to various circuits to stop the operation of the various circuits operating at 5V.

  According to the above configuration, the voltage fluctuation of the DC / DC converter 7 is detected using the voltage monitoring means by software installed in the first CPU 6a, so that the cost can be reduced by using the conventional hardware. Further, since the function of the first CPU 6a is stopped using the reset signal of the power supply monitoring means 3 which is hardware and the operation of various circuits is stopped, the system can be surely stopped.

FIG. 3 shows another embodiment, in which the first CPU 6a shown in FIG. 2, the regulator 2, and the voltage monitoring means 3 by hardware are configured in a plurality of stages.
In the figure, 1 is a switch for turning on and off a reference voltage (for example, 24V), 7 is a DC / DC converter for stepping down a 24V reference voltage to 9V, 2a, 2b,. The voltage of 9V stepped down in step 7 is further stepped down to 5V.

  A voltage of 9V is input to a plurality of CPUs 6a in which software 6c (see FIG. 2) functioning as first voltage monitoring means is installed in the firmware to monitor whether or not it is at a predetermined voltage level. Further, the voltage of 5V stepped down by the regulators 2a, 2b,... 2n is output to the second voltage monitoring means 3a, 3b,.

The outputs of the second voltage monitoring means 3a, 3b,... 3n are also inputted to the plurality of CPUs 6a1, 6a2,.
A communication line 8 connects the first CPUs 6a1, 6a2,... 6an to each other and is connected to the second CPU 6d. The 9V and 5V voltages are supplied as power sources for various circuits (not shown).

  According to the above-described configuration, since the safe circuit is configured only by the first CPU, cost reduction can be realized.

The above description merely shows a specific preferred embodiment for the purpose of explanation and illustration of the present invention. For example, in the embodiment, the voltage of 24V is shown as 15V, 12V, 9V, and 5V by the regulator, but it is not limited to these values, and can be appropriately boosted or lowered according to the voltage used in the circuit.
Therefore, the present invention is not limited to the above-described embodiments, and includes many changes and modifications without departing from the essence thereof.

It is a block diagram which shows one Example of the power supply monitoring apparatus of this invention. It is a figure which shows another Example. It is a figure which shows another Example. It is a figure which shows an example of the power supply monitoring apparatus conventionally used.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Switch 2 Regulator 3 Voltage monitoring normal means 4 OR circuit 6 CPU
7 DCDC converter 8 Communication line

Claims (3)

  A reference power supply, a switch for turning on and off the reference power supply, a plurality of voltage converting means for converting the voltage of the reference power supply into a plurality of voltages via the switch, and monitoring each voltage level converted by the voltage converting means In the voltage monitoring device comprising a plurality of voltage monitoring means, and when any of the voltages converted by the voltage conversion means exceeds a predetermined level, the voltage monitoring means emits a signal to turn off the switch, A power supply monitoring device comprising at least one of a plurality of voltage monitoring means using a CPU.   2. The plant power supply monitoring apparatus according to claim 1, wherein the voltage monitoring means in the CPU is configured by software installed in the firmware of the CPU. A first CPU in which software that functions as voltage monitoring means is installed in firmware, a second CPU connected to the CPU via a communication line, and a voltage from a reference power supply is taken in via a switch to perform voltage conversion. A first voltage converting means for outputting to the first CPU; a second voltage converting means connected to a subsequent stage of the first voltage converting means; and a voltage monitoring means for monitoring the voltage level of the second voltage converting means. When the power level of the first voltage conversion means exceeds a predetermined level, the first CPU turns off the switch via the communication line and the second CPU, and the power level of the second voltage conversion means reaches a predetermined level. When exceeded, the voltage monitoring means turns off the switch via the second CPU, and the first CPU and second voltage conversion means. Power monitoring apparatus characterized by being configured to emit a reset signal to various circuits using the converted voltage.

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