KR940001029Y1 - Timer circuit - Google Patents

Abstract

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Description

Timer circuit

1 is a conventional timer circuit diagram.

2 is a timer circuit diagram of the present invention.

3 is an operating waveform diagram of a power supply and a relay in FIG.

* Explanation of symbols for main parts of the drawings

PUT1: Programmable Unijunction Tr

SCR1, SCR10: Silicon Controlled Rectifier

TNR1: Surge Abserb

The present invention relates to a timer circuit, and more particularly, to a small timer circuit and a short timer control.

A conventional timer circuit that is generally used, as shown in FIG. 1, applies a power source AC to a diode D1 and a light emitting element LED1 through a relay RY1, and outputs the output of the diode d1 to silicon. A constant of the capacitor C3 is applied to the variable resistor VR2 via the anode of the control rectifying element SCR1 and the capacitor C1 and the voltage divided by the variable resistor VR2 is connected to the anode of the PUT PUT1. When the voltage is charged, the silicon controlled rectifier SCR1 is turned on at this voltage.

Referring to the operation and problems with respect to the conventional circuit configured as described above in detail as follows.

First, when the power source AC is applied, the current is half-wave rectified in the diode D1 through the relay RY1 and a predetermined voltage is accumulated in the capacitor C1 through the resistor R2, where the relay RY1 is a PUT ( Since the impedance of PUT1 is large, a small current flows and the relay RY1 is not turned on. In addition, a current flows through the light emitting diode LED1 through the resistor R1 to be turned on to indicate that the power supply AC is applied to the timer circuit and the time delay circuit is in operation. In addition, when voltage is applied across the capacitor C1, the reference voltage is formed at the semi-fixed resistor VR2, and the current is gradually charged to the capacitor C3 through the variable resistor VR1, and the charging voltage is 0.5% of the reference voltage. When the voltage rises above V, the PUT PUT1 1 is turned on, and the current of the capacitor C3 flows to the gate of the silicon control rectifier SCR1 to be turned on, so that the relay RY1 is energized. When the relay RY1 is energized, the contact of the relay RY1 is moved to maintain magnetic holding and the light emitting diode LED1 is turned off. At this time, the resistor R4 and the capacitor C2 are used for the gate voltage and noise protection of the silicon controlled rectifier SCR1, and the variable resistor VR1 adjusts an arbitrary delay time.

However, since the above-mentioned circuit performs half-wave rectification, since the voltage of the oscillator circuit is not a constant voltage, a large amount of time error occurs due to the variation of the applied voltage, and when the light emitting diode LED1 is in operation of the relay RY1, the light goes out. Therefore, it is not possible to distinguish whether the actual relay RY1 is turned off or turned off or the power supply AC is turned off, and when the reverse voltage is generated in the relay RY1, the silicon control rectifier SCR1 is reversed. There is a risk of destruction.

Accordingly, the present invention allows the constant voltage to be supplied to the system in consideration of the deficiencies of the conventional circuit as described above, and indicates the operating state of the system and prevents the destruction of the silicon-controlled rectifier by the reverse voltage. The explanation is as follows.

FIG. 2 is a circuit diagram according to the present invention, in which a surge absorber (TNR1) is connected in parallel to a power source AC and a light emitting device through resistors R11 and R12 through a diode 11 as shown in FIG. Connect the LED11) and the diode D11 and connect the anode of the silicon control rectifier SCR10 in series with the light emitting diode LED12 via the relay RY11 and the other side of the relay RY11 in series. And the anode of PUT (PUT11) 1 through resistors VR11, R16, and R14, respectively, connected to the zener diode ZD11 and capacitor C11 connected in parallel with each other via a diode D13 and a resistor R13. The gates are connected to each other, and the anode capacitor C14 of the PUT (PUT11) 1 is connected, and the cathode is connected to the gate of the resistor R17, the capacitor C13, and the silicon control rectifier SCR10 in common.

Referring to the operation and effects of the circuit of the present invention configured as described above in detail as follows.

First, when the power source AC is applied, the current is half-wave rectified in the diode D13 through the relay RY11 coil, the voltage drops in the resistor R13, and is converted into a constant voltage in the zener diode ZD11, thereby condensing the capacitor C11. ) To a certain voltage. When a constant voltage is maintained at both ends of the capacitor C11, the voltage is divided by the resistor R14 to provide a reference voltage of oscillation, and the current gradually flows to the capacitor C14 through the variable resistor VR11 and the resistor R16. When the voltage of the capacitor C14 becomes 0.5V or more than the reference voltage when the battery is charged, the PUT (PUT11) 1 is turned on to discharge the capacitor C14. Accordingly, the silicon control rectifier SCR10 triggers on the gate thereof. The voltage is turned on to thereby turn the relay RY11 on. The silicon control rectifier SCR10 is turned on during the (+) potential of the input power source AC and is interrupted during the (−) potential, but the accumulated energy of the relay RY11 is reduced to the diode D12 and the resistor ( The silicon control rectification element SCR10 may be turned on again because it is tracked through R11).

When the relay RY11 is turned on, the light emitting diode LED12 is turned on to indicate that the relay RY11 is in operation. At this time, the resistor R12 is a current limiting resistor for turning on the light emitting diode LDED11 and the light emitting diode ( LED11 indicates that power (AC) is being applied to the circuit. In addition, the capacitor C12 is used to prevent noise of the PUT PUT11, and the diode D11 is used for reverse voltage protection of the silicon controlled rectifier SCR10.

As described above, the present invention allows the constant voltage to be supplied to the system, displays the operating state of the system, and prevents the destruction of the silicon controlled rectifier (SCR10) due to the reverse voltage.

Claims (1)

An anode of the silicon controlled rectifier SCR10 is connected in series with a power supply AC in parallel with a surge abserb TNR1 and through a diode 11 through resistors R11 and R12 in series with the light emitting diode LED12. The other side of the relay RY11 is connected to the zener diode ZD11 and the capacitor C11 connected in parallel through the diode D13 and the resistor R13 connected in series, and to the resistors VR11 and R16. Connect the anode and gate of the PUT (PUT11) 1 to each other through R14, and connect the capacitor C14 to the anode of the PUT (PUT11), and connect the cathode of the resistor R17, the capacitor C13 and the silicon control station. A timer circuit comprising: a common connection to a gate of a child (SCR10).