JPH035139B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Technical Field The present invention relates to a two-wire switching device that switches a plurality of loads by turning on and off a power switch connected in series with a power supply line.

(b) Prior art and its drawbacks As a conventional two-wire load switching device, for example, there was one disclosed in Japanese Patent Publication No. 58-55639, but this device could only switch between two types of loads. I couldn't do it.

(c) Purpose of the Invention The purpose of the present invention is to provide a device capable of switching a plurality of loads in a two-wire system.

(d) Structure of the invention This invention can be summarized as follows.

A charging/discharging circuit including a capacitor charged by a commercial power source and a switching element connected in parallel to the capacitor and conducting based on the charge charged in the capacitor when the power switch is turned off,
Prepare one less number than the number of loads.

A switching circuit is provided which connects the charging and discharging circuits in a subordinate manner and switches which capacitor starts charging each time the power switch is turned off.

With the above configuration, the on/off state of the charging/discharging circuit changes by turning the power switch on/off within a certain period of time (until the discharge of the capacitor ends). Then, by capturing this state of change, multiple bidirectional thyristors are turned on and off.
The load is switched by changing the off state.

(e) Embodiment The figure is a circuit diagram of a two-wire load switching device that is an embodiment of the present invention.

A power switch SW is connected in series to the commercial power source E. Furthermore, triaxes Q1 to Q5, which are examples of bidirectional thyristors, are connected in series to the three loads L1 to L3 connected in parallel to the power supply E, respectively. In this example, the loads L1 and L2 are larger than the load L3, and accordingly, two triacs are configured to be connected in series to the loads L1 and L2. That is, the on/off of the load L1 is controlled by the triacs Q and Q2. Further, the on/off of the load L2 is controlled by the triaxes Q3 and Q4.

Zener diodes Q constituting gate elements are provided at the gates of the triacs Q2 and Q4, respectively.
6 and Q7 are connected in series. The Zener diodes Q6, Q7 and the gate of a triac Q5 for controlling on/off of the load L3 are connected to input terminals a, d of charge/discharge circuits A, B. A time constant circuit consisting of a capacitor C1 and a resistor R1 is connected to the Zener diode Q6, and a time constant circuit consisting of a capacitor C2 and a resistor R2 is connected to the Zener diode Q7. These two time constant circuits have the same time constant.

The first charging/discharging circuit A has a rectifier bridge D1 that rectifies an alternating current voltage input between input terminals a and b, and capacitors C3 and C4 are connected in parallel to the rectifier bridge D1. Furthermore, PUTQ10 with LEDD2 connected to the anode side is connected in parallel. A series circuit of a low resistance R3 and a high resistance R4 and a capacitor C5 for noise removal are connected between the PUTQ10 and the output terminal of the rectifier bridge D1. Capacitor C4 acts as a smoothing capacitor that rectifies the output of rectifying bridge D1, and is discharged through resistor R3 and resistor R5 when power switch SW is turned off. Further, the capacitor C3 is charged with the output voltage of the rectifier bridge D1 when the power switch SW is turned on, and when the power switch SW is turned off, the anode voltage of PUTQ10 is made higher than the gate voltage by the charged charge. That is, the PUTQ10 is made conductive by the charged charge. A resistor R6 is connected in series to the cathode side of PUTQ10.
This resistor R6 is for applying a charging voltage to the capacitor C3 when PUTQ10 is conductive.

The second charging/discharging circuit B is also the same as the first charging/discharging circuit A.
It has almost the same configuration as . The difference is that a diode D4 is connected to the capacitor C6. The purpose of this diode D4 is to prevent short-circuiting between the outputs of the rectifying bridge D3 via the capacitor C7.

The charge/discharge circuits A and B are cascaded together via a diode D5. This diode D5 connects the cathode terminal of PUTQ11 in the second charge/discharge circuit B to the first charge/discharge circuit A via the diode D4.
Connect to the rectified output terminal of

In the above configuration, the important elements for switching the load are capacitors C3 and C6 in charge/discharge circuits A and B.
A diode D5 connects both charge/discharge circuits A and B in series with resistors R6 and R7 and PUTQ10 and Q11.

Next, the operation of the above two-wire load switching device will be explained.

First, when the power switch SW is turned on, the triac Q is turned on via the Zener diodes Q6 and Q7.
2, a gate current is supplied to Q4. As a result, loads L1 and L2 are driven. At the same time, the capacitors C3 and C4 of the first charging/discharging circuit A are charged. However, the second charging/discharging circuit B
Capacitors C6 and C7 are not charged. This is because at this time, the phase difference between the voltages at both terminals of the diode D5 is zero. The reason why this phase difference is 0 is that the time constant circuit of capacitor C1 and resistor R1 and the time constant circuit of capacitor C2 and resistor R2 have the same time constant. Since the phase difference between the voltages across the diode D5 is 0, no charging current flows from the input terminal d to the capacitors C6 and C7. That is, the power switch
When SW is first turned on, only capacitors C3 and C4 of the first charging/discharging circuit A are charged.

When the power switch SW is turned off in this state, the anode voltage of PUTQ10 becomes higher than the gate voltage due to the charge in the capacitor C3. Therefore, based on its charging charge, PUTQ10
conducts. At this time, since the resistor R4 has a high resistance, the charge in the capacitor C4 is PUTQ10.
without increasing the gate voltage of resistor R5.
It is discharged by When the power switch SW is turned on while PUTQ10 is conductive, the output terminals of the rectifying bridge D1 become conductive.
Therefore, the potential at the input terminal point a of the first charging/discharging circuit A decreases, and the gate current supplied to the triac Q2 stops. That is, load L1
turns off. A gate current is supplied to triac Q4. As a result, there is a transition from a state where loads L1 and L2 are on to a state where only load L2 is on. On the other hand, in this state, since PUTQ10 of the first charging/discharging circuit A is in a conductive state, the capacitor C of the second charging/discharging circuit B
6, C7 starts charging. That is, input terminal d→
A charging current flows through the rectifier bridge D3 → capacitors C6, C7 → diode D5, and the capacitors C6,
C7 is charged.

When the power switch SW is turned off again in the above state, this time due to the charge in capacitor C6,
PUTQ11 becomes conductive. In the charging/discharging circuit A, since the capacitor C3 is charged by the voltage across the resistor R6 when the PUTQ10 is on, the PUTQ10 also maintains a conductive state due to this charged charge. In other words, the power switch is turned on for the second time.
When SW is turned off, both PUTQ10 and Q11 become conductive.

When the power switch SW is turned on again in the above state, the potential of the input terminal a is low because PUTQ10 is conductive in the first charge/discharge circuit A, and therefore the load L1 remains in the off state. Furthermore, in the second charging/discharging circuit B, since PUTQ11 is in a conductive state, the voltage at its input terminal d decreases, and no gate current is supplied to the triac Q4. That is, the load L2 is turned off. On the other hand, PUTQ
By conducting both Q10 and Q11,
The input terminals c and d of the second charging/discharging circuit B are electrically connected, and as a result, a gate current is supplied to the triac Q5. That is, the load L3 is turned on.

By repeatedly turning the power switch SW on and off as described above, the loads are switched so that the loads L1 and L2 are turned on first, then the load L2 is turned on, and finally the load L3 is turned on. Can be done.

Furthermore, even if there are four or more loads, if you prepare one less charge/discharge circuit than the number of loads and connect them in series with diodes, you can switch those loads with one power switch. It can be carried out.

(f) Effects of the Invention As described above, according to the present invention, even if there are three or more loads, it is possible to switch the loads in a two-wire system using one power switch.

[Brief explanation of the drawing]

The figure is a circuit diagram of a two-wire load switching device that is an embodiment of the present invention. A...First charge/discharge circuit, B...Second charge/discharge circuit, Q10, Q11...PUT (switching element), Q1 to Q5...Triack (bidirectional thyristor). C3, C6...Capacitors (charged with commercial power).

Claims (1)

[Claims] 1. A plurality of bidirectional thyristors connected in series to each of n parallel-connected loads (n≧3), a capacitor charged by a commercial power source, and connected in parallel to this capacitor. n-1 charging/discharging circuits each including a switching element that conducts based on the charge charged in the capacitor when the power switch is turned off, and the charging/discharging circuit are cascaded, and charging starts each time the power switch is turned off. a switching circuit that switches the capacitors in the n-1 charging/discharging circuits; A two-wire load switching device comprising: a load selection circuit that selects a bidirectional thyristor that causes a gate current to flow depending on whether or not it is conductive.