KR19980062274U - Current control circuit when driving solenoid - Google Patents

Abstract

The present invention relates to a current control circuit for driving a solenoid applied to an electric pressure cooker, in particular, charging the capacitor for a certain time before driving the solenoid, and at the beginning of the solenoid driving, the current is supplied to the capacitor charged voltage excessively during the initial driving This is to prevent the malfunction of electronic circuit caused by the voltage drop of Vcc by the current and to maintain the operation stability of solenoid.

In order to achieve the above object, the present invention provides a control unit 10 for controlling the driving of the transistor TR, a constant voltage source generator 20 and an electronic circuit unit for generating a constant voltage source in the coil L of the solenoid SOL. 30) In the solenoid driving circuit configured as above, the capacitor is charged with the Vcc voltage before driving the solenoid for a predetermined time, and when the solenoid (SOL) is driven, the initial current is supplied to the solenoid with the voltage charged to the capacitor to drop the voltage of Vcc during the initial driving. It characterized in that it comprises a drive current control circuit portion 40 of the solenoid to prevent.

Description

Current control circuit when driving solenoid

The present invention relates to a current control circuit for driving a pressure discharge solenoid applied to an electric pressure thermal rice cooker, and in particular, before the solenoid is driven, the capacitor is charged with an input voltage by RC timing, and the solenoid is driven with a voltage charged to the capacitor. The present invention relates to a current control circuit for driving a solenoid that prevents malfunction of an electronic circuit caused by Vcc fluctuation voltage drop (transient current) during initial operation of the solenoid by supplying a current to the solenoid to prevent the constant voltage generator from being overloaded. .

In particular, the present invention provides a driving current control circuit of a solenoid that prevents the voltage drop of the constant voltage generator during initial operation by charging the capacitor with the input voltage for a predetermined time before driving the solenoid and supplying a current at the voltage charged to the capacitor during the solenoid driving. It is.

In addition, the present invention is to set the RC timing to charge the capacitor at a predetermined time with the Vcc voltage before the solenoid driving, the charging and discharging capacitor supplying the current charged in the capacitor to the solenoid during the solenoid driving, and setting the solenoid driving range voltage to the upper limit. The present invention provides a Zener diode and a rectifier diode for rectifying the Vcc current and the voltage charged in the capacitor.

1 is a diagram of a conventional solenoid driving circuit, and as shown in FIG. 1, a control unit 10 for controlling driving of a transistor TR, and a constant voltage source generator for generating a constant voltage source in a coil L of a solenoid SOL ( 20) and the electronic circuit unit 30.

That is, the base side of the transistor TR having the emitter side grounded is connected to the control unit 10, and the collector side of the transistor TR is connected to one terminal of the coil L of the solenoid SOL and the solenoid SOL. The other terminal of the coil L is configured by connecting the constant voltage source generator 20 and the electronic circuit unit 30.

In the conventional solenoid drive circuit configured as described above, when the transistor TR is turned on, the constant voltage source Vcc generated by the constant voltage source generator 20 is applied to the coil L of the solenoid SOL to operate the solenoid SOL. .

At this time, if the solenoid continues to operate as a large amount of current flows through the coil of the solenoid, the heat generation amount of the solenoid is reduced or a lot of power is lost. Also, malfunction of the electronic circuit part occurs due to Vcc fluctuation, that is, voltage drop during initial operation of the solenoid. Of course, the problem occurred such that the operation stability of the solenoid is lowered when driving the solenoid.

Therefore, the present invention has been made to solve the conventional problems as described above, the purpose of which is to prevent the voltage drop of the constant voltage generator during the initial driving to prevent the malfunction of the electronic circuit generated due to the Vcc variable voltage drop solenoid drive Is to provide a time current control circuit.

More specifically, before driving the solenoid, the capacitor is charged to the capacitor with Vcc voltage by RC timing, and when the solenoid is driven, the current is supplied to the solenoid as much as the voltage charged to the capacitor to minimize the Vcc fluctuation voltage drop during initial operation of the solenoid. By preventing the malfunction of the generated electronic circuit and by supplying a stable power supply to prevent a lot of power loss and at the same time to improve the operation stability of the solenoid.

1 is a conventional solenoid drive circuit diagram

2 is a circuit diagram of the present invention for the current control when driving the solenoid

Explanation of symbols on the main parts of the drawings

10: control unit 20: constant voltage source generation unit

30 electronic circuit portion 40 solenoid drive current control circuit portion

1: RC timing TR: Transistor

C: Capacitor D1, D2: Rectifier Diode

ZD: Zener Diode SOL: Solenoid

L: coil

Features of the present invention to achieve the above object, the control unit 10 for controlling the drive of the transistor (TR) and the external voltage applied to a constant voltage source of a predetermined size to the coil (L) of the solenoid (SOL) In the solenoid driving circuit comprising the constant voltage source generator 20 and the electronic circuit unit 30: Charge the capacitor for a predetermined time at the Vcc voltage before the solenoid driving, and supplies the current as much as the voltage charged to the capacitor during the solenoid initial drive Characterized in that the drive current control circuit portion 40 of the solenoid for controlling the unnecessary current during the initial drive.

In addition, the feature of the present invention

Hereinafter, the configuration according to an embodiment of the present invention in more detail based on the accompanying drawings as follows.

FIG. 2 is a circuit diagram of the present invention for controlling current when driving a solenoid, and as shown in FIG. 2, a control unit 10 for controlling driving of the transistor TR and a constant voltage source Vcc at a coil L of the solenoid SOL. The constant voltage source generator 20 and the electronic circuit unit 30 for generating a power supply and the Vcc voltage are charged to the capacitor for a predetermined time before driving the solenoid. The drive current control circuit unit 40 is configured to prevent the voltage drop of the constant voltage generating unit.

The driving current control circuit part 40 of the solenoid is a RC timing (1) for charging the capacitor at a predetermined time with a Vcc voltage before driving the solenoid, and a capacitor (C) for charging and discharging and supplying the current charged in the capacitor to the solenoid during the solenoid driving. And a zener diode (ZD) for setting the solenoid driving range voltage to meet the upper limit value, and rectification diodes (D1) and (D2) for rectifying the Vcc current and the voltage charged in the capacitor.

Referring to the effect of the present invention configured as described above are as follows.

First, the capacitor C receives an external power source, that is, a DC input, supplied to the constant voltage source generator 20 before driving the solenoid SOL and charges the resistor C through the resistor R. FIG. In this case, the capacitor C and the resistor R are referred to as RC timing 1.

In addition, the charging or discharging time of the voltage charged in the capacitor C is determined by the RC time constant according to the resistance of the resistor R. In addition, the Zener diode ZD connected in parallel to the capacitor C and the ground terminal is charged to the capacitor C as it is turned on when the voltage charged in the capacitor C rises above a predetermined value. Limit the magnitude of the voltage (greater than the voltage of Vcc).

In this way, a voltage of a predetermined magnitude is charged by a DC input applied to the constant voltage source generator 20 before driving the solenoid. In this state, when the transistor TR is turned on by the output signal from the controller 10, When a control signal of the controller 10 for driving the solenoid SOL is generated, the voltage charged in the capacitor C is applied to the coil L of the solenoid SOL through a second diode. Through the turn-on operation of the transistor TR is conducted to ground.

At this time, the Vcc voltage is also output from the constant voltage source generator 20, but the charging voltage of the capacitor C output from the second diode D2 is larger than that of the Vcc voltage, so that the Vcc voltage is blocked by the first diode D1. It keeps the state.

Subsequently, while the voltage charged in the capacitor C conducts to ground through discharge paths D2, SOL, and TR for a predetermined time, the voltage applied to the cathode of the first diode D1 is the Vcc voltage. When the voltage is equal to, the voltage applied to the solenoid SOL is actually a voltage applied to the cathode of the first diode D1, and is driven by the voltage Vcc and the voltage discharged from the capacitor C.

The present invention, which operates as described above, minimizes Vcc fluctuation voltage drop by supplying the solenoid with a current charged by a capacitor when driving the solenoid, and prevents a lot of power loss, and also operates the solenoid with a stable power supply. It is effective in maintaining stability and preventing malfunction of electronic circuits.

Claims (2)

A control unit 10 for controlling the driving of the transistor TR, a constant voltage source generator 20 and an electronic circuit unit for receiving an external DC voltage and applying a constant voltage source of a predetermined size to the coil L of the solenoid SOL. In the solenoid drive circuit comprising 30), The solenoid driving current control circuit unit 40 controls the unnecessary current during initial driving by charging the capacitor with the Vcc voltage for a predetermined time and supplying the current as much as the charged voltage during the initial driving of the solenoid. Current control circuit when driving solenoid. The method of claim 1, wherein the driving current control circuit portion 40 of the solenoid is a capacitor (C) is charged by an external DC voltage before driving the solenoid, and charged to the capacitor (C) above a specific voltage according to the solenoid driving range. A zener diode ZD connected in parallel with the capacitor C, a second diode D2 for providing a voltage discharged from the capacitor C to the coil L of the solenoid SOL, and Its cathode is connected to the cathode of the second diode D2 and the first diode D1 for providing the voltage generated by the constant voltage source generator 20 to the coil L of the solenoid SOL. Solenoid driving current control circuit, characterized in that consisting of.