KR200303150Y1 - Protection circuit of solenoid coil drive circuit - Google Patents

Abstract

The present invention relates to a protection circuit of a solenoid coil drive circuit that reduces the ripple voltage generated when the solenoid coil is operated to prevent shortening the lifespan of the closed safety relay due to the ripple voltage. Driver 1 for controlling the drive of the fail-safe relay FSR in response to the drive signal of 2), and fail-safe relay FSR for controlling the power supplied to the solenoid coil SC under the control of the driver 1. And a field effect transistor (FET) for interrupting the output power of the solenoid coil (SC) of the microcomputer (2), the ripple voltage generated when the driving power supply / blocking of the solenoid coil (SC) is performed. It characterized in that it comprises a ripple voltage removing unit (3) for removing the.

Description

Protection circuit of solenoid coil drive circuit

The present invention relates to a protection circuit of a solenoid coil driving circuit, and more particularly, to protect a solenoid coil driving circuit which can reduce the ripple voltage generated when the solenoid coil is operated to prevent the shortened life of the fail-safe relay due to the ripple voltage. It is about a circuit.

The conventional solenoid coil driving circuit is a microcomputer 101, a driving unit 102 and a fail safe relay (FSR), a field effect transistor (FET), a solenoid coil (SC) as shown in FIG. Consists of.

First, the microcomputer 101 generates a driving signal for driving the solenoid coil SC and supplies the driving signal to the driving unit 102 and the field effect transistor FET, respectively. Then, the fail-safe relay FSR is operated in the "on" state by the driving unit 102 receiving the driving signal, and the field effect transistor FET is in the "on" state by the driving signal of the microcomputer 101. Will be maintained.

Accordingly, the power supply Vcc applied to one side of the fail safe relay FSR flows to the ground through the fail safe relay FSR, the solenoid coil SC, and the field effect transistor FET to excite the solenoid coil SC.

However, when the driving signal output from the microcomputer 101 is cut off, the fail-safe relay FSR is operated by the driving unit 102 in an "off" state, and as the driving signal of the microcomputer 101 is cut off. The field effect transistor (FET) also remains "off".

Accordingly, the power supply Vcc applied to one side of the fail-safe relay FSR is cut off by the fail-safe relay FSR and the field effect transistor FET, so that the solenoid coil SC is not excited. It doesn't work.

However, when the ripple voltage generated when the driving power of the solenoid coil is supplied / disconnected back to the fail safe relay, a fail safe relay driven by a low voltage is damaged.

The purpose of the present invention to solve this problem is to remove the ripple voltage generated when the power supply to the solenoid coil is supplied / cut off, so that the components including the fail-safe relay, etc. can be prevented from being damaged by the ripple voltage It is to provide a protection circuit of the coil drive circuit.

The present invention for achieving the object as described above occurs when the fail-safe relay and the field effect transistor applied to the drive signal of the microcomputer to control the driving power of the solenoid coil, but is generated when the driving power is supplied / cut off to the solenoid coil It is characterized in that the ripple voltage to be raised.

1 is a circuit diagram showing a conventional solenoid coil driving circuit.

2 is a circuit diagram illustrating a protection circuit of the solenoid coil driving circuit according to the present invention.

Explanation of symbols on the main parts of the drawings

1: drive unit 2: microcomputer

3: ripple elimination part FSR: fail-safe relay

FET: Field Effect Transistor SC: Solenoid Coil

D: Diode C: Capacitor

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the protection circuit of the solenoid coil drive circuit according to the present invention.

FIG. 2 is a circuit diagram of a protection circuit of a solenoid coil driving circuit according to the present invention, and includes a microcomputer 2 and a driving unit 1 for controlling the driving of a fail-safe relay FSR by receiving a driving signal of the microcom 2. And a fail-safe relay (FSR) that intercepts the power supplied to the solenoid coil (SC) by the control of the drive unit 1, and a field effect transistor (FET) that intercepts the output power of the solenoid coil (SC) of the microcomputer (2). In the solenoid coil driving circuit comprising a), it comprises a ripple voltage removing unit (3) for removing the ripple voltage generated when the driving power supply / interrupt of the solenoid coil (SC).

In the figure, reference numeral C denotes a capacitor for removing the ripple voltage, and D denotes a diode for preventing the ripple voltage from flowing back to the power supply terminal.

The operation of the present invention configured as described above will be described.

When driving the solenoid coil SC as in the related art, the microcomputer 2 generates a driving signal and supplies the driving signal to the driving unit 1 and the field effect transistor FET, respectively. Then, the fail-safe relay FSR is operated in the "on" state by the driver 1 receiving the drive signal, and the field effect transistor FET is in the "on" state by the drive signal of the microcomputer 2. Will be maintained.

Accordingly, the power supply Vcc applied to one side of the fail safe relay FSR flows to the ground through the fail safe relay FSR, the solenoid coil SC, and the field effect transistor FET to excite the solenoid coil SC.

However, when the driving signal output from the microcomputer 2 is cut off, the fail-safe relay FSR is operated in the "off" state by the driving unit 1 and the driving signal of the microcomputer 2 is cut off. The field effect transistor (FET) also remains "off".

Accordingly, the power supply Vcc applied to one side of the fail-safe relay FSR is cut off by the fail-safe relay FSR and the field effect transistor FET, so that the solenoid coil SC is not excited. It doesn't work.

The ripple voltage generated when the fail-safe relay (FSR) and the field effect transistor (FET) are switched to an "on" or "off" state when the driving power supplied to the solenoid coil (SC) is supplied / blocked is a ripple voltage. It flows to ground through the capacitor C of the removal part 3.

Accordingly, it is possible to prevent breakage of components including the fail-safe relay FSR from the ripple voltage generated when the solenoid coil SC is operated.

As described above, the present invention blocks the ripple voltage generated when the solenoid coil is operated to the component including the fail-safe relay in controlling the driving of the fail-safe relay and the field effect transistor to control the driving power of the solenoid coil. As a result, it is possible to prevent the component including the fail-safe relay from being damaged due to the ripple voltage.

Claims (1)

The power supply supplied to the solenoid coil SC under the control of the microcomputer 2, the drive unit 1 which receives the drive signal of the microcomputer 2, and controls the drive of the fail-safe relay FSR, and the drive unit 1; A solenoid coil drive circuit comprising a fail-safe relay (FSR) for intermitting a circuit and a field effect transistor (FET) for interrupting the output power of the solenoid coil (SC) in accordance with a drive signal of the microcomputer (2), A capacitor (C) for flowing and removing the ripple voltage to ground and a diode (D) for preventing the ripple voltage from flowing back to the power supply terminal are provided, and the ripple generated when the driving power of the solenoid coil (SC) is supplied or cut off. And a ripple voltage removing unit (3) for removing the voltage.