JPH03108231A - Multi-circuit control device - Google Patents

Abstract

PURPOSE:To obtain a semi-permanent life and realize high insulation by closing a contact switch when at least one of multiple noncontact switches is closed, and opening the contact switch when all multiple noncontact switches are opened. CONSTITUTION:When all semiconductor control elements 13a-13d are to be opened while one semiconductor control element 13d is closed and other semiconductor elements are opened, a control circuit 15 cuts off the gate signal to open the semiconductor control element 18d based on the off-action of the lowest-stage remote control switch 6A. The circuit 15 detects that all elements 13a-13d are opened and drives a mechanical switch 12 to open a main circuit contact 125, and the insulation of the circuit is secured. The circuit frequently opened or closed is on/off-controlled by semiconductor control elements, and the main circuit contact is opened only when all branch circuits are opened.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a multi-circuit control device that relatively frequently opens and closes many branch circuits, such as lighting control circuits.

[Prior Art] The configuration of a conventional example will be described with reference to FIGS. 6 and 7.

FIG. 6 and FIG.
FIG. 1 is a layout diagram partially showing a conventional multi-circuit control device disclosed in the publication, and a circuit diagram showing a remote control relay and a remote control switch of the conventional multi-circuit control device.

In Fig. 6, the conventional multi-circuit control device has a distribution board (1
), a plurality of remote control relays (3), a terminal unit (4) for driving the remote control relay, a control terminal (5), etc.

In FIG. 7, a control power source (7) and a control power source (7) are shown.
) and a remote control switch (6) connected at one end to the remote control relay (3) and at the other end to the control power source (7).

The remote control relay (3) has a drive coil (31) connected to the control power source (7), and a cathode connected to the drive coil (31).
a diode (32) connected to 1); a diode (33) whose anode is connected to the drive coil (31);
It consists of a main circuit contact (34) connected to diodes (32) and (33), and a switching contact (35) interlocked with this main circuit contact (34).

The remote control switch (6) also includes a diode (61) whose anode is connected to the main circuit contact (34) of the remote control relay (3), and a diode (62) whose cathode is connected to the main circuit contact (34). , a switch (63) connected to the diodes (61) and (62) and the other end connected to the control power supply (7), a resistor (64) connected to the main circuit contact (34), and a cathode connected to this switch (63). A diode (65) connected to a resistor (64), a cathode connected to this diode (65) and an anode connected to a control power supply (7).
an LED (6B) connected to the main circuit contact (34), a resistor (6) connected to the main circuit contact (34), and an anode connected to this resistor (6).
) and an LED (69) whose anode is connected to this diode (68) and whose cathode is connected to the control power supply (7).

Next, the operation of the above-mentioned conventional example will be explained.

As shown in Figures 6 and 7, remote control relay (3)
is 0N10 F of the main circuit by the main circuit contact (34).
It controls F, and is generally a contact point.

The basic principle of controlling the terminal unit (4) for driving the remote control relay is the ON10 of the remote control switch (6).
A control signal similar to FF control (unidirectional half-wave output) drives the drive coil (31) of the remote control relay (3) to control the main circuit contact (34) to turn on or off,
At the same time, the switching contact (35) is also switched. This switching contact (
35) switches to block the unidirectional half-wave and operates to prevent any further current from flowing. This is a known means as a two-wire control system.

[Problem to be solved or attempted by the invention] In the conventional multi-circuit control device as described above, the main circuit opening/closing control is performed using contacts, so mechanical means must be used to drive the main circuit. There is also a large amount of energy,
This is uneconomical, and particularly when controlling multiple circuits such as lighting circuits, there is a problem in that it is necessary to use a power supply with a large capacity.

Here, of course, we need to change the contact mechanism to a non-contact mechanism (
SSR, etc.) can be considered. However, simply converting a contact point to a non-contact point causes a new problem. In other words, by making the switch non-contact, it is not possible to ensure sufficient insulation between the main circuit side of the switching section and the load side (this is also affected by the protection circuit of the semiconductor), and if you touch the load side circuit with the intention of opening it, you may receive an electric shock or other injury. This has the problem of not being easily put to practical use because it can lead to personal injury and disasters such as fires due to leakage current.

This invention was made in order to solve the above-mentioned problems, and it uses semiconductor control elements for control elements that are frequently opened and closed to make them contactless, and all semiconductor control elements are turned off (
A mechanical contact is provided that opens when the circuit is open (open circuit) and closes when at least one semiconductor control element is ON (closed circuit), and normally opens and closes without contact, so the lifespan is semi-permanent and When the circuit is cut off, it opens at the contact point, achieving high insulation, which prevents dangers such as electric shock during inspections and fires due to electrical leakage after lights are turned off. It is an object of the present invention to obtain a multi-circuit control device that can reduce the number of circuits.

[Means for Solving the Problems] A multi-circuit control device according to the present invention includes the following means.

(i) A contact switchgear connected to the main circuit power supply.

(ii) A plurality of non-contact switchgears that are connected to this contact switchgear and distribute power to loads.

(iii) When at least one of the plurality of non-contact switchgears is closed, the contact switchgear is closed, and when all of the plurality of non-contact switchgears are open, the contactor is closed. Control means for controlling the switchgear to open the circuit.

[Function] In this invention, a plurality of non-contact switching devices,
Power is distributed to the loads.

Further, when at least one of the plurality of non-contact switchgears is open, the contact switchgear is closed by the control means, and when all of the plurality of non-contact switchgears are open, the contact switchgear is closed. The contact switching device is opened.

[Embodiment] The structure of an embodiment of the present invention will be described with reference to FIGS. 1, 2, 3, and 4.

FIG. 1 is a circuit diagram showing an embodiment of the present invention.

In FIG. 1, one embodiment of the present invention has a power supply terminal (11) connected to a main circuit power supply (not shown), and a li! connected to this power supply terminal (11). A mechanical quantitative switching device 2) and semiconductor control elements (13a), (13b) such as triacs connected to this mechanical switching device (12).
, (13c) and (13d), and load terminals (14) connected to these semiconductor control elements (13a) to (13d).
), a mechanical switchgear (12) and a semiconductor control element (1
A control circuit (15) connected to 3a) to (13d);
Control terminals S1 and S2 connected to this control circuit (15)
, S3 and 54 (16), and a common terminal (red) (17) connected to a control circuit (15).

FIG. 2 is a wiring diagram showing an embodiment of the present invention and a remote control switch.

In Fig. 2, a two-wire remote control switch (6^) whose red terminal is connected to the control terminal 5l (16) of the multi-circuit control device (10) and whose white terminal is connected to one end of the control power supply (7) and a two-wire remote control switch (6^) whose red terminal is connected to the control terminal 32 (1B) and whose white terminal is connected to the control power supply (7), and whose red terminal is connected to the control terminal 53.
(16) and whose white terminal is connected to the control power supply (7), and a two-wire remote control switch (6^) whose red terminal is connected to the control terminal 54 (16) and whose white terminal is connected to the control power supply (7). 7) A two-wire remote control switch (
6^) is shown. Note that the other end of the control power source (7) is connected to the common terminal (17).

FIG. 3 shows a mechanical opening/closing device (12
) is a circuit diagram showing.

In Figure 3, the mechanical switchgear (12) is a diode (121) whose cathode is connected to the control circuit (15).
, a diode (122) whose anode is connected to the control circuit (15), and diodes (121) and (122).
A switching contact (123) connected to the switching contact (123) and one end connected to the switching contact (123)
123) and a drive coil (124) whose other end is connected to a control circuit (15), and a main circuit contact (125) that is interlocked with the switching contact <123>.

FIGS. 4(a) and 4(b) are circuit diagrams showing two examples of the remote control switch (6^) shown in FIG. 2.

In Fig. 4(a), - of the remote control switch (6^)
An example is a diode (6
1) and a diode whose cathode is connected to the red terminal (
62), a switch (63a) with one end connected to the diode (61) and the other end connected to the white terminal, and a switch (63a) with one end connected to the diode (62) and the other end connected to the white terminal. 63b) and a resistor (64) connected between the red terminal and the white terminal.

In FIG. 4(b), another example of the remote control switch (68) is a diode (68) whose anode is connected to the red terminal.
61), a diode (62) whose cathode is connected to the red terminal, and a switch (63a) whose one end is connected to the diode (61) and the other end is connected to the white terminal.
A switch (63b) with one end connected to the diode (62) and the other end connected to the white terminal, an operation display LED (6B) whose cathode is connected to the red terminal, and one end connected to this operation display LED (66). A resistor (64) connected to the terminal and the other end connected to the white terminal, a resistor (67) connected to the red terminal, and an anode connected to this resistor (67) and a cathode connected to the white terminal. Display the operation E
D(69).

In addition, in FIG. 2, each remote control switch (68),
Semiconductor control elements (13a) to (13) corresponding to each
d) is configured to perform ON10FF control of the main circuit.

By the way, the contact switchgear of the present invention is a mechanical switchgear (12) in the above-mentioned embodiment of the present invention, and the plurality of non-contact switchgear of the present invention is a semiconductor control element (12).
3a) to (13d), and the control means of the present invention is a control circuit (15).

Next, the operation of the above embodiment will be explained with reference to FIG.

FIG. 5 is a waveform diagram showing the operation of each part in an embodiment of the present invention.

For example, if the remote control switch (6^) at the top of FIG. In order to close (13a), the control circuit (15) operates as follows.

As shown in FIG. 5, semiconductor control elements (13a) to (
13d) are all open circuits, the control circuit (15
) receives the ON signal of the remote control switch (6^), sends a drive signal to the drive coil <124') of the mechanical switch (12), and closes the main circuit contact (125).

Next, a gate signal is sent to close the semiconductor control element (13a). As a result, the semiconductor control element (13a) becomes conductive and supplies power to the load connected to it. The semiconductor control elements (13b) to (13d) are similarly controlled.

Here, the control circuit (15) includes a semiconductor control element (13a
) to (13d) is controlled to be ON (closed), the mechanical switching device (12) is controlled to remain open.

Next, by operating the remote control switch (6^),
Optionally set the semiconductor control elements (13a) to (13d) to 0N1.
After 0FF control, when one semiconductor control element (13d) is closed and the others are open, when this is opened to make all semiconductor control elements (13a) to (13d) open. Let's think about it.

Based on the OFF operation of the remote control switch (6^) at the bottom of FIG.
It acts to cut off the gate signal to turn off the semiconductor control element (13d) and open the semiconductor control element (13d). Next, the control circuit (15) controls all the semiconductor control elements (13
The mechanical switching device (12) detects that m) to (13d) are open and opens the main circuit contact (125).
It operates to drive the circuit and ensure insulation of the electrical circuit. In one embodiment of the present invention, as described above, semiconductor control elements (13m) to (13d) are used in the branch circuit, and a mechanical switching device (12) with contacts is provided in the main circuit, so that it is frequently opened and closed. The main circuit contacts are opened only when all branch circuits are open, which improves the insulation of the electrical circuit, making it a long-life, energy-saving, and safe device. This has the effect of making it possible to realize the following.

[Effects of the Invention] As explained above, the present invention includes a contact switchgear connected to a main circuit power supply, a plurality of non-contact switchgears connected to the contact switchgear and distributed power to loads, When at least one of the plurality of non-contact switchgears is closed, the contact switchgear is closed, and when all of the plurality of non-contact switchgears are open, the contact switchgear is opened. Since it is equipped with a control means to control the operation, the lifespan is semi-permanent because it normally opens and closes without contact.
In addition, when all circuits are cut off, the contacts open, so high insulation can be achieved, preventing dangers such as electric shocks during inspections and fires due to electrical leakage after lights are turned off. This has the effect that the amount can also be reduced.

[Brief explanation of drawings]

Fig. 1 is a circuit diagram showing an embodiment of the present invention, Fig. 2 is a wiring diagram showing an embodiment of the invention and a remote control switch, and Fig. 3 is a mechanical switching device of an embodiment of the invention. 4 (a> and (b) are circuit diagrams showing two examples of the remote control switch shown in FIG. 2, and FIG. 5 is a waveform diagram showing the operation of each part of an embodiment of the present invention. Fig. 6 is a layout diagram showing a part of a conventional multi-circuit control device, and Fig. 7 is a circuit diagram showing a remote control relay and a remote control switch of the conventional multi-circuit control device. Control device, (11) ・
... Power supply terminal, (12) ... Mechanical switchgear. (13a) to (13d)... semiconductor control element,
(14) ... load terminal, (15) ... control circuit, (16) ... control terminal, (17) ... common terminal. In each figure, the same reference numerals indicate the same or equivalent parts.

Claims (1)

[Claims] A contact switchgear connected to the main circuit power supply, a plurality of non-contact switchgears connected to the contact switchgear and distributing power to loads, and at least one of the plurality of non-contact switchgears are closed. The present invention is characterized by comprising a control means for controlling the contact switching device to close the circuit when the contact switching device is closed, and to open the contact switching device when all of the plurality of non-contact switching devices are open. Multi-circuit control device.