KR102495660B1 - Sub-module of lamp switch - Google Patents

Abstract

The present invention relates to a light switch submodule, and more specifically, to a triac switch unit including a triac for connecting or disconnecting a light and AC power in series, and controlling ON/OFF of the triac, obtained from the input terminal. A circuit unit comprising a circuit for supplying a part of power to the output terminal, wherein the circuit unit includes first and second circuits respectively forming different power flow paths between an input terminal and an output terminal, Accordingly, the voltage applied to the gate of the triac is controlled and power is supplied to the load through only one of the first and second circuits, so that a separate power is not applied to the driving circuit of the light switch. , In the method of amplifying the voltage from the input power supply to create a driving voltage by itself and apply it to the driving circuit, a light switch submodule that can prevent flicker when the light flickers and stably supplies the driving voltage by using a transformer It relates to a light switch submodule provided.

Description

Light switch sub module {SUB-MODULE OF LAMP SWITCH}

The present invention relates to a light switch submodule, and more particularly, to amplify a voltage from input power to generate a driving voltage and apply it to a driving circuit without separately applying a separate power to a driving circuit of a large load light switch. In a method, it relates to a light switch sub-module capable of preventing a flicker phenomenon when a light flickers and stably supplying a driving voltage.

An electronic switch is a device that starts or closes a circuit or performs an opening/closing operation at high speed by using electronic properties. In particular, compared to analog switches, the electronic switch applied to the ON/OFF of lights controls the ON/OFF of the switch through remote control, hand clap, voice recognition, human body detection, and RF wireless communication even if the user does not have to move to directly press the switch. It is very convenient because it can be done, and it can be turned on/off automatically, so it can reduce power consumption caused by not accidentally turning off the power of the light switch. Thanks to this convenience, there is a trend of replacing analog switches with electronic switches in recent light switches.

On the other hand, in general, a driving circuit of an electronic switch for driving a light using an LED performs a function of receiving power, rectifying, amplifying, and oscillating to convert the light source of the light into a form of DC power that can be turned on. In addition, the driving circuit includes a control unit including various elements in order to implement more diverse functions in controlling ON/OFF of lights. Here, various elements included in the control unit may include, for example, an LED, a human body sensor, an infrared light receiving sensor, and a bidirectional RF chip. On the other hand, if several of these elements are added, the size of the load of the control unit increases. When the size of the load of the control unit increases, the power consumed by the load increases. Referring to FIG. 1 , the triac Q1 controlling AC power is not completely turned on, so the current flowing through the lamp is limited. Therefore, a flicker phenomenon occurs in which the lights are continuously and minutely flickered and turned on, resulting in a problem that causes eye fatigue to the user. Conventionally, there was a problem in that the above-mentioned flicker phenomenon could not be solved because conduction of the triac could not be controlled.

In addition, since the size of the load of the control unit is large, leakage current flows to the load of the control unit even when the light is turned off, and a small amount of light is continuously turned on by the leakage current, resulting in an increase in power waste.

Moreover, in order to replace the analog switch of the existing light with an electronic switch, a power supply of 220V or 110V is normally required. However, since the N-phase power must be drawn from the pipe in order to replace the switch with an electronic switch, a large construction cost is incurred. In order to solve this problem, a method of simply using only the R-phase power to apply a separate power to the driving circuit by amplifying the voltage from the input power to generate a driving voltage and applying it to the driving circuit has been used. However, since the load of the control unit is relatively greater than the load of the lamp, it is difficult to generate a driving voltage. For example, when the power of the lamp is a small load of 20W to 100W, the driving circuit of the electronic switch requires a driving voltage of DC 5-12V, but the R phase + terminal and N phase - terminal have little current. Because of the flow, there was a difficult problem in making a sufficient driving voltage.

In summary, in a sub-module in which a voltage is amplified from an input power source to generate a driving voltage and apply it to the driving circuit without separately applying a separate power to the driving circuit of the light switch, a flicker phenomenon occurs when the light flickers As a result, there is a big problem in that power is wasted and it is difficult to stably supply a driving voltage to a large-capacity load.

Korean Patent Registration No. 10-2148885 (“Flicker free converter for dimming including a switch”, 2020.08.21.)

The present invention has been made to solve the above problems, in a method of amplifying a voltage from an input power source to generate a driving voltage by itself and applying it to the driving circuit without separately applying a separate power source to the driving circuit of the light switch, A light switch submodule having a plurality of power flow paths, controlling the voltage applied to the triac gate according to the amount of power required by the load, and selecting a power flow path that can be boosted to stably supply power to the load. is in providing

In order to solve the above problems, the present invention is a light switch in which an AC power source 10 and a lamp 20 and input terminals (A and B nodes) are connected in series and output terminals (C and D nodes) are connected to a load 1400 In the submodule 1000, a triac switch unit including a triac 1101 having positive and negative ends connected to the input terminal and connecting or disconnecting the lamp 20 and the AC power supply 10 in series. 1100, and a circuit connected to the input terminal, the triac, and the output terminal, controlling ON/OFF of the triac, and supplying a part of the power obtained from the input terminal to the output terminal. The circuit unit includes first and second circuits respectively forming different power flow paths between the input terminals (nodes A and B) and the output terminals (nodes C and D), and Accordingly, power may be supplied to the load through only one of the first and second circuits while controlling the voltage applied to the gate of the triac 1101 .

Meanwhile, the first circuit may include a first AC/DC converter 1210 having one end connected to the input terminal and outputting a DC voltage by receiving an alternating current.

On the other hand, the second circuit is connected to a transformer 1220 having a primary side connected to the input terminal, boosting and outputting an input voltage to a secondary side, and a secondary side of the transformer, receiving an AC input and outputting a DC voltage. It may include a second AC / DC converter 1230 that does.

In addition, the second circuit includes a variable resistance unit 1240 connected in series between the input terminal and the transformer and having a variable resistance, and a switch RY2 connected between the transformer and the gate terminal of the triac. A switch unit 1250 and a bias unit 1260 including a resistor R2 connected between a gate terminal of the triac 1101 and a cathode terminal of the triac 1101 may be included.

Meanwhile, resistance of the variable resistance means when the amount of power required by the load is relatively large may be lower than resistance of the variable resistance means when the amount of power required by the load is relatively small.

Further, the variable resistance means includes at least one resistor and at least one switch, and the resistance of the variable resistance means when the switch is turned ON is greater than the resistance of the variable resistance means when the switch is turned OFF. can be small

Also, ON and OFF of the switch of the variable resistance unit may be selected by a user's input.

Also, the switch of the variable resistance means may be a latching relay.

Also, the switch of the variable resistance unit may be a dip switch.

Meanwhile, the light switch submodule 1000 is provided between the outputs of the first and second power flow paths and the output terminals (C and D nodes), converts the input voltage into a predetermined DC voltage, and converts the input voltage to the output terminal (C). , D node) may further include a DC/DC converter 1300 supplying.

Meanwhile, the ratio of the number of turns of the primary winding to the secondary winding of the transformer 1210 is 1:N, and N may be 4 or more and 10 or less.

Meanwhile, the first resistor R1, which is any one of at least one resistor included in the variable resistance means, may be equal to or greater than 1 kΩ and equal to or less than 1.8 kΩ.

The present invention according to the above configuration, in the light to which the electronic switch is applied, the flicker phenomenon that occurs when the light is turned on when the load of the control unit is large and the phenomenon that the light is turned on finely that occurs when the light is turned off can be eliminated. Accordingly, there is a great effect of solving problems such as power waste and eye fatigue.

1 is a configuration diagram of a conventional electronic switch.
2 is a schematic diagram of the light switch submodule of the present invention.
3 is a circuit diagram of the light switch submodule of the present invention.
4 is a circuit diagram of the first path of the light switch submodule of the present invention.
5 is a circuit diagram of a second path of the light switch submodule of the present invention.

Since the present invention can make various changes and have various embodiments, specific embodiments are illustrated in the drawings and described in detail. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

It is understood that when an element is referred to as being “connected” or “connected” to another element, it may be directly connected or connected to the other element, but other elements may exist in the middle. It should be.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs.

Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in this application, it should not be interpreted in an ideal or excessively formal meaning. don't

Hereinafter, the technical idea of the present invention will be described in more detail using the accompanying drawings.

Since the accompanying drawings are only examples shown to explain the technical idea of the present invention in more detail, the technical idea of the present invention is not limited to the form of the accompanying drawings.

As described above, in a light switch, an electronic switch that controls ON/OFF of a light using electronic properties is widely used. In order to change from an analog switch of an existing lamp to an electronic switch, a power supply of 220V or 110V is normally required. However, since the N-phase power must be drawn from the pipe in order to replace the switch with an electronic switch, a large construction cost is incurred. In order to solve this problem, a method of simply using only the R-phase power to apply a separate power to the driving circuit by amplifying the voltage from the input power to generate a driving voltage and applying it to the driving circuit has been used.

1 shows a conventional electronic switch driving circuit. When elements with various functions are added to the controller (Load) in order to implement various functions in the electronic switch of the light, the load of the controller (Load) increases accordingly. Conventionally, when the power consumed by the load increases within a certain driving voltage, there is a problem in that the lamp does not properly turn on and flickers due to insufficient power required for the lamp. Specifically, referring to FIG. 1 , a flicker phenomenon occurs because the triac Q1 controlling the AC power of the lamp is not completely conducted when a large amount of load is applied. Conventionally, the triac Q1 could not be controlled, so the flicker phenomenon could not be solved under heavy load. In addition, since the load 1400 is large, there is also a problem in that leakage current flows and the light is slightly turned on even in an OFF state, increasing power waste.

In order to solve this problem, the light switch submodule of the present invention is divided into first and second paths, which are paths through which power flows, and only uses one of the first and second paths according to the amount of power required by the load 1400. made it flow 2 is a schematic diagram of the second pathway of the present invention. In the present invention, by supplying the voltage boosted by the transformer 1220 to the load 1400, sufficient power is supplied to the lamp 20 even under heavy load, and at the same time, the triac 1101 is controlled to prevent flicker. There is a great effect that can be. This will be described in detail with reference to FIG. 3 .

In the light switch submodule 1000 in which the AC power source 10 and the lamp 20 and the input terminals (A and B nodes) are connected in series and the output terminals (C and D nodes) are connected to the load 1400 , a triac switch unit 1100 including a triac 1101 having positive and negative ends connected to the input terminal and connecting or disconnecting the lamp 20 and the AC power supply 10 in series, and the input terminal , a circuit unit 1200 connected to the triac and the output terminal, controlling ON/OFF of the triac, and including a circuit for supplying a part of power obtained from the input terminal to the output terminal, the circuit unit comprising: and first and second circuits respectively forming different power flow paths between the input terminals (nodes A and B) and the output terminals (nodes C and D), and according to the amount of power required by the load 1400, the trie The voltage applied to the gate of the evil 1101 may be controlled and power may be supplied to the load through only one of the first and second circuits.

Preferably, when the amount of power required by the load 1400 is relatively small, power is supplied to the load 1400 through only the first circuit, and in the case of a large capacity load in which the amount of power required by the load 1400 is large, the Power may be supplied to the load 1400 only through the second circuit.

Here, the relatively small amount of power required by the load 1400 may be when the amount of power required is 30 W or less, and the relatively large amount of power required by the load 1400 may be greater than 30 W.

Meanwhile, referring to FIG. 4 , the first circuit may include a first AC/DC converter 1210 having one end connected to the input terminal and outputting a DC voltage by receiving an alternating current.

On the other hand, referring to FIG. 5, the second circuit has a transformer 1220 having a primary side connected to the input terminal, boosting an input voltage to the secondary side and outputting it, and one end connected to the secondary side of the transformer, It may include a second AC/DC converter 1230 that receives AC and outputs DC voltage.

Referring to FIG. 3 , the other end of the first AC/DC converter 1210 is connected to the other end of the second AC/DC converter 1230, and the outputs of the first and second circuits are connected to the first and second circuits, respectively. It may be output to the other end of the AC/DC converter.

In addition, the second circuit includes a variable resistance unit 1240 connected in series between the input terminal and the transformer and having a variable resistance, and a switch RY2 connected between the transformer and the gate terminal of the triac. It may include a switch unit 1250, and a bias unit 1260 including a resistor R2 connected between the gate terminal of the triac 1101 and the cathode terminal of the triac 1101.

The light switch unit 1250 controls ON/OFF of the triac switch 1100, and ON/OFF of the light 20 is controlled according to ON/OFF of the triac switch 1100. can

The bias unit 1260 may form a predetermined potential difference between a gate end and a cathode end of the triac 1101 so that the triac 1101 may properly operate.

On the other hand, the resistance of the variable resistance means 1400 when the amount of power required by the load 1400 is relatively large compared to the resistance of the variable resistance means 1240 when the amount of power required by the load is relatively small. it may be less

Further, the variable resistance means includes at least one resistor and at least one switch, and the resistance of the variable resistance means when the switch is turned ON is greater than the resistance of the variable resistance means when the switch is turned OFF. it can be small

Referring to FIGS. 3 and 5 , preferably, the variable resistance unit 1240 may include a first resistor R1 and a first switch RY1 connected in parallel. The variable resistance unit 1240 may have a resistance whose size is changed according to ON/OFF of the first switch RY1. When the first switch RY1 is ON, the variable resistance unit 1240 The resistance of preferably converges to 0, and when the first switch RY1 is OFF, the resistance of the variable resistance means 1240 may preferably correspond to the first resistance R1. Therefore, since the resistance of the variable resistance means converges to 0 when the switch is turned on, it may be smaller than the resistance of the variable resistance means when the switch is turned off.

In addition, the voltage applied to the gate terminal of the triac 1101 can be controlled by turning on/off the variable resistor unit 1240 .

Also, ON and OFF of the switch of the variable resistance unit may be selected by a user's input.

The user's input may be ON when the flicker phenomenon occurs in the lamp 20 .

Also, the switch of the variable resistance unit may be any one of a relay, a dip switch, and a latching relay.

More preferably, the switch of the variable resistance means may be a latching relay.

A latching relay is a relay that, once power is turned on, fixes it with a mechanical element so that the state is continuously maintained, and consumes less power in an internal coil than a general switch.

With this configuration, there is an effect of supplying sufficient power required for the lamp 20 by reducing power consumed by components other than the lamp 20 to the maximum.

Meanwhile, the light switch submodule 1000 is provided between the other ends of the first and second AC/DC converters and the output terminals (nodes C and D), and converts an input voltage into a predetermined DC voltage to convert the output terminal ( It may further include a DC/DC converter 1300 supplying the C and D nodes).

Meanwhile, the ratio of the number of turns of the primary winding to the secondary winding of the transformer 1210 is 1:N, and N may be 4 or more and 10 or less.

Preferably, N may be 5, and more preferably, N may be adjusted according to the amount of power consumed by the load 1400.

Meanwhile, the first resistor R1, which is any one of the at least one resistor included in the variable resistance unit, may be greater than or equal to 1 kΩ and less than or equal to 1.8 kΩ.

Preferably, the first resistor R1 may be 1 kΩ.

When the resistance of the first resistor R1 is less than 1 kΩ, the voltage across the triac switch 1100 decreases, and thus the voltage across the first AC/DC converter 1210 is below a predetermined level. so that power cannot be delivered to the load through the first circuit. In addition, when the first resistance R1 is 1.8 kΩ or more, since the AC load voltage state of the A node of the input terminal is lower than that of the C node, an error occurs in the circuit. Therefore, for stability, the first resistance R1 may be greater than or equal to 1 kΩ and less than or equal to 1.8 kΩ.

The operation of the first circuit and the second circuit of the preferred light switch submodule 1000 of the present invention described above will be described.

First, the operation of the first circuit will be explained. The first circuit may be applied when the size of the load 1400 is relatively small.

Referring to FIG. 4 , when the resistance of the variable resistance unit 1240 in the first circuit is relatively large, that is, the first switch RY1 is turned OFF, the resistance of the variable resistance unit 1240 becomes the first resistance R1 In the case of corresponding to , a relatively low voltage is applied to the gate of the triac 1101, and the ON resistance of the triac increases, and accordingly, the voltage of the input terminals (A and B nodes) increases to the first AC/DC converter 1210. When an input voltage higher than a predetermined voltage is applied, power may be delivered to the load through the first circuit.

In other words, referring to FIG. 4 , when the first switch is OFF, the first AC/DC converter 1210 is turned on by receiving the voltage across the triac switch 1100, and the Turned off, the power rectified by the first AC/DC converter 1210 may be supplied to the load 1400 .

Next, the operation of the second circuit will be explained. The second circuit may be applied when the size of the load 1400 is a relatively large capacity load.

Referring to FIG. 5 , when the resistance of the variable resistance means 1240 is relatively small, that is, when the first switch RY1 is turned on and the resistance of the variable resistance means 1240 converges to 0, the triac 1101 ) is applied to the gate, the ON resistance of the triac 1101 is reduced, and a sufficiently large current can be applied to the lamp. However, in this case, the voltage across the input terminals (A, B nodes) is low Therefore, it is difficult to supply sufficient energy to the load through the first circuit. Therefore, in the present invention, by supplying power to the load 1400 by boosting the voltage through the transformer 1220 of the second circuit, the effect of supplying sufficient power to the lamp 20 and stably supplying power to the large-capacity load at the same time there is

In other words, when the first switch is ON, the voltage boosted by the transformer 1220 is input, the first AC/DC converter 1210 is turned ON, and the second AC/DC converter 1230 is turned OFF, and the power rectified by the second AC/DC converter 1230 may be supplied to the load 1400.

With this configuration, when the load of the control unit is large, it is possible to eliminate the flicker phenomenon that occurs when the light is turned on and the phenomenon that the light is turned on finely when the light is turned on and off, thereby wasting power and causing eye fatigue, etc. There is a great effect that can solve the problem of

The present invention is not limited to the above embodiments, and the scope of application is diverse, and various modifications and implementations are possible without departing from the gist of the present invention claimed in the claims.

10: AC power
20: light
1000: light switch submodule
1100: triac switch unit
1101 : Triac
1200: circuit part
1210: first AC / DC converter
1220: Transformer
1230: second AC / DC converter
1240: variable resistance means
1250: light switch unit
1260: bias unit

Claims (11)

In a light switch submodule having an AC power source and a lamp and an input terminal connected in series and an output terminal connected to a load,
a triac switch unit including a triac having positive and negative ends connected to the input terminal and connecting or disconnecting the lamp and the AC power supply in series; and
A circuit unit configured of a circuit connected to the input terminal, the triac, and the output terminal, controlling ON/OFF of the triac, and supplying a part of power obtained from the input terminal to the output terminal;
The circuit part,
First and second circuits respectively forming different power flow paths between the input end and the output end;
Supplying power to the load through only one of the first and second circuits while controlling the voltage applied to the gate of the triac according to the amount of power required by the load;
The second circuit,
a transformer connected to the input terminal and a primary side and boosting and outputting an input voltage to a secondary side; and
a second AC/DC converter having one end connected to the secondary side of the transformer, receiving an alternating current and outputting a direct current voltage;
a variable resistance means connected in series between the input terminal and the transformer and having a variable resistance;
a light switch unit including a switch connected between the transformer and the gate end of the triac; and
and a bias unit including a resistor connected between the gate end of the triac and the cathode end of the triac.
A light switch submodule comprising:
According to claim 1,
The first circuit,
To include a first AC/DC converter having one end connected to the input end and outputting a direct current voltage by receiving an alternating current
A light switch submodule comprising:
delete delete According to claim 1,
The resistance of the variable resistance means when the amount of power required by the load is relatively large is smaller than the resistance of the variable resistance means when the amount of power required by the load is relatively small.
A light switch submodule comprising:
According to claim 5,
The variable resistance means,
at least one resistor and at least one switch;
The resistance of the variable resistance means when the switch is ON is smaller than the resistance of the variable resistance means when the switch is OFF.
A light switch submodule comprising:
According to claim 6,
ON and OFF of the switch of the variable resistance means,
selected by user input
A light switch submodule comprising:
According to claim 6,
The switch of the variable resistance means is a latching relay
A light switch submodule comprising:
According to claim 1,
It is provided between the other end of the first and second AC / DC converters and the output end,
Further comprising a DC / DC converter for converting the input voltage into a predetermined DC voltage and supplying it to the output terminal
A light switch submodule comprising:
According to claim 1,
The ratio of the number of turns of the primary winding to the secondary winding of the transformer is 1:N,
N is 4 or more and 10 or less
A light switch submodule comprising:
According to claim 6,
The first resistor (R1), which is any one of the at least one resistor included in the variable resistance means, is 1 kΩ or more and 1.8 kΩ or less.
A light switch submodule comprising:

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