KR790002174Y1 - Control system - Google Patents

Abstract

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Description

Controller

1 to 4 are circuit diagrams of a control device of the present invention.

5 is a waveform diagram for explaining the operation.

The present invention is to control the controlled device according to the fire detection operation of the fire detector using the thyristor having excellent characteristics as a switching element, and to recover the thyristors periodically and to automatically turn on and off the controlled device according to the fire situation at that time. It relates to a control device to control to (ON, OFF) and described in detail by the accompanying drawings as follows.

1 shows the basic configuration of the control device of the present invention, where Re is a controlled device such as an arbitrary control device or its control relay, P is an oscillation circuit, r is a protection resistor, and SCR is a fire detector. Thyristors are used as switching elements (not shown), and these are direct current feed and signal lines. Connected between. The oscillation circuit P drives the relay F, which is connected in parallel to the resistor r and the series circuit of the thyristor SCR.

In the operation of the circuit, when the signal is exposed to the gate G of the thyristor SCR, the thyristor SCR is turned on, and current flows to the circuit of the Re-Pr-SCR so that the controlled device Re operates and the oscillator circuit P The rash begins. For this reason, relay F operates intermittently and periodically opens and closes contact f. When the contact f is closed, the thyristor SCR is short-circuited and becomes voltage-free and turned off. When the contact f is open, the thyristor SCR is again supplied with a voltage, and when there is a signal input at the gate G, the thyristor SCR is turned on.

Similarly, the thyristor SCR is periodically reset, but turned on while a signal is input to the gate G. When the signal input disappears, the thyristor SCR remains off after being reset, and the controlled device and oscillator circuit P are disconnected to charge the operation.

2 shows a modified example of the present invention. In this drawing, the controlled device Re is a direct current feed and signal line of the contact L of the relay L, the diode D, and the resistor r ₂ in series. The thyristor SCR is connected between the relay L, the resistor r ₁ and its feed and signal lines in series. The oscillating circuit P is connected to the power supply via the contact l, and the relay F is always the closed contact f ₁ and the always open contact f ₂ , which is connected in series, and also the resistor r ₁ and the series circuit of the thyristor SCR. Connected. C ₁ is a capacitor and is connected between the connection point of the contacts f ₁ and f _{2 and} the connection point of the resistor r ₁ and the thyristor SCR. C ₂ is a capacitor and is connected in parallel with the resistor r ₂ and the series circuit of the controlled device Re. The thyristor SCR is attached to a fire detector (not shown). When the fire detector detects a fire, a signal input is conducted to the gate G to feed and signal the line. Short circuit between The diode D, the capacitor C ₂ and the resistor r ₁ constitute a time constant circuit for maintaining the operation of the controlled device.

Referring to the operation of this circuit, when a signal enters the gate G of the thyristor SCR, the thyristor is turned on, and a current flows through the circuits of the Lr ₁ -SCR, so that the relay L is operated. The capacitor C ₁ is charged with the polarity as shown in the circuit of Lf ₁ -C ₁ -SCR. The contact l closes due to the operation of the relay L, and current flows in the circuits of lP and lDr ₂ -Re so that the controlled device Re operates after charging the capacitor C ₂ , and the oscillation circuit P starts to oscillate immediately.

Relay F is to open the contact point f ₁ doeyeo the intermittent operation with the lungs and f _2, and also a closed contact f ₁ and f ₂ of a contact opening. In the former state, the capacitor C ₁ discharges in the circuit of C ₁ -f ₂ -SCR and turns off the thyristor SCR. In the latter state, the capacitor C ₁ is charged as shown and contrasted with the control state of the thyristor SCR.

When the thyristor SCR is turned off, the relay L is disconnected and the contact l is opened, so that the generator circuit P is disconnected. At this time, the power to the controlled device Re is cut off, but the operation stops because the capacitor C ₂ is connected in parallel. When the oscillating circuit P is disconnected and the relay F opens the contact f ₂ , the power supply voltage is applied to the thyristor SCR, so as long as a signal is input to the gate G, the relay L operates. This causes the contact l to be closed and to repeat as described above.

When the signal pressure is lost at the gate G, the thyristor SCR of the reset does not operate, and the controlled device Re stops operation after the discharge of the capacitor C ₂ is completed. Therefore, even when the thyristor SCR is periodically conducting again, the controlled device Re continues to operate during the discharge of the capacitor C ₂ , so that the operating state of the controlled device does not simultaneously operate when the thyristor SCR is turned on or off.

3 shows an example of using a PUT oscillator as a reset oscillator. In this circuit diagram, PUT (Programmable, Unijunction Transistor) Q _{1 to} Q ₄ are transistors, R ₁ to R ₉ are resistors C ₃ and C ₄ are capacitors, and D ₁ is diodes. These diodes D ₁ , capacitor C ₄ , resistors R ₃ , R ₃ , and transistors Q ₁ , Q _{2 form} the time constant circuit described above. Other symbols in the figures are shown in the same manner as in the first and second degrees. In this circuit, when a signal enters the gate G of the thyristor SCR, the thyristor is turned on, and the feed and signal line (DC power supply) -R ₂ -R ₉ -SCR-Q ₃ Feeding and signal line (DC power supply) Current flows through the circuit of. Transistor Q ₄ powers its base via thyristor SCR It is turned on, so it turns on. In the circuit of R ₂ -Q ₄ -D ₁ -C ₄ , the capacitor C ₄ is charged. In the circuit of R ₂ -Q ₄ -R ₇ -a, a voltage is applied to the anode a of the PUT. do.

When the capacitor C ₄ is charged, the transistor Q ₂ is turned on via the resistor R _3. As a result, the transistor Q ₁ is turned on to operate the controlled device Re. When the capacitor C ₃ is charged through the resistor R ₇ and reaches a predetermined terminal voltage determined by the voltage given to the gate G, the PUT is turned on and the capacitor C ₃ discharges. At this time, the transistor Q ₃ is turned off because the resistor R ₆ , which has supplied the base current, is shorted by the PUT, and thus the thyristor SCR is turned off. When the discharge of capacitor C ₃ is completed, the PUT is turned off and transistor Q ₃ is made conductive. Therefore, when the signal enters the gate G again, the thyristor SCR is turned on and the above operation is repeated. When the input signal is lost to the gate G, the thyristor SCR remains off after reset, and the controlled device Re causes the capacitor C ₄ to discharge through the base emitter of the resistor R ₃ and the transistor Q ₂ so that the transistor Q ₂ , When Q ₁ turns off, the power is cut off to stop the operation.

4 is another embodiment using a smoke switch as a topic detector. In this figure, RE is a fire door which is controlled by the contact re of the controlled device Re composed of a relay as an emergency device such as a flue gas device. Q ₅ is a transistor, R ₁₀ , R ₁₁ is a resistor, D ₂ is a Jenny diode, and the other symbols are the same as those in FIG.

In this apparatus, each semiconductor element is turned off in a normal state. When smoke occurs due to a fire, the thyristor SCR attached to the detector S is turned on by entering a gate G. R ₂ -R ₉ -SCR- The current flows in the circuit configuration of.

The transistor Q ₄ is turned on by the voltage drop generated in the resistor R ₉ , and the capacitors C ₃ and C ₄ are charged by the circuits of Q ₄ -R ₇ -C ₃ and Q ₄ -D ₁ -C ₄ . When the capacitor C ₄ is charged, the transistor Q ₂ is turned on via the resistor R ₈ , which turns on the transistor Q ₁ , and the controlled device Re operates. As a result, contact re is closed and emergency equipment RE is operated.

When the capacitor C ₃ is charged to the predetermined voltage, the PUT discharges and the transistor Q ₅ is turned on. As a result, the thyristor SCR and the PUT oscillator are turned off by shorting the power supply side. When the discharge of the capacitor C ₃ is completed, the transistor Q ₅ is turned off and the power supply short is released.

If the fire is still occurring, the thyristor SCR is turned on because a signal is input to the gate G.

Since the controlled device Re is operated until the capacitor C ₄ has finished discharging, the contact re does not open even during reset, so the emergency equipment RE continues to operate as long as smoke is generated. When the fire smoke is eliminated, the signal input to the gate G is lost, so that the thyristor SCR is not turned on after reselling and is turned off.

5 shows the voltage waveforms of each part, where 1 is the on and off state of the thyristor SCR, 2 is the on and off state of the controlled device Re, and 3 is the oscillation output state of the PUT. The reset of the thyristor SCR is repeated for a short period of time when the PUT oscillator generates an output pulse, and this period T ₁ is determined by the time constant R ₇ C ₃ . The operation of the controlled device Re is delayed by the time T ₂ of the turn of the thyristor SCR, and this time T ₂ is determined according to a time constant obtained by multiplying the resistance Rd of the diode D ₁ by the capacity of the capacitor C ₄ . The time T ₃ from the thyristor SCR off until the controlled device Re opens the contact is determined by the time constant C ₄ R ₈ .

Therefore, by the time constant C ₄ R ₈ defined by the capacitor C ₄ and the resistor R ₈ of the time constant circuit, as shown in FIG. 2, the controlled device Re continues to operate while the thyristor SCR periodically recovers. Doing.

As described in detail above, according to the present invention, the thyristor of the fire detector is periodically restored, and the gate input of the thyristor is constantly monitored, and the controlled device can be continuously operated while the gate input is present, and an alarm facility is provided. It is very effective when used in fire protection equipment.

Claims (1)

Fire detector that connects power supply and signal line and fires thyristor SCR when conducting fire detection, and shorts signal line, and oscillation circuit P which operates when thyristor shorts signal line and periodically recovers thyristor, And a controlled device Re having a time constant circuit, the thyristor conducting with a fire detection signal and continuing operation while repeating recovery by the oscillation circuit.