KR20110009532A - Illumination and heating integrated controller - Google Patents

Abstract

PURPOSE: An illumination and heating integrated controller is provided to control illumination with only the power of an illumination load by driving a MICOM and a relay for controlling illumination with power supplied to the illumination load. CONSTITUTION: A relay(110) controls the on/off of a power source. The power source is connected to an illumination load. A MICOM(120) for controlling illumination controls a relay operation. A rectifier circuit(130) full-wave rectifies the power supplied to the illumination load. A power supply unit(140) changes a first voltage into a second voltage and supplies changed voltage to the MICOM.

Description

ILLUMINATION AND HEATING INTEGRATED CONTROLLER}

The present invention relates to an integrated heating and heating regulator, and more specifically, in addition to the main microcomputer for heating control, and separately provided with a light control microcomputer and a latch relay for controlling the on / off of the light, the light control for power supply from the light load By driving the microcomputer and relay, even if the main microcomputer does not operate due to power supply to the main microcomputer or other defects, the present invention relates to a lighting heating integrated regulator that can control lighting with only the power of the lighting load without additional power supply.

With the development of information and communication technology, the development and mass production of home devices, which are key devices for implementing ubiquitous homes in the home network field, are being actively conducted. As a part of such home network technology, technologies for developing sensors and devices in the heating, lighting, gas, and living environment areas, and wireless and convergence of heterogeneous devices are being developed.

As a kind of home device, convergence products such as integrated lighting heating switch and temperature flow integrated proportional control valve, bathroom heating system, collective light switch, direct gas circuit breaker, cleaning robot, home care robot, CO2 sensor, etc. Devices have been released and are becoming more widespread.

The development and spread of the illumination heating integrated regulator of the home device is gradually increasing. In order to configure the integrated lighting and heating regulator, the lighting switch circuit should be additionally configured in the heating controller. For the control of the lighting switch, control should be performed by using a constant voltage based module circuit or a microcomputer. Since these circuits must use a separate power supply device, this requires a separate wiring for supplying power other than a light switch.

In addition, relays and triacs (TRCs) are typical examples of devices used to control the lighting, and there is a disadvantage in that heat generation becomes severe when triacs are used. Thus, when the triac is used in the integrated heating and heating thermostat, a serious problem may occur that the temperature is higher than the actual temperature to be measured by affecting the temperature measuring sensor. In addition, when using the triac may flicker depending on the type of load lighting, there is a problem that you need to install a capacitor directly to the lighting.

In order to solve this problem, a relay can be used. However, when a general relay is used, a constant power must be supplied to the relay while the relay is driven.

According to the problems of the prior art, it is possible to supply its own power from the power line connected through the load of the light switch without the installation work of the lighting switch and the heating controller of each room, so that the lighting control function is not supplied to the heating controller. There is a need for the development of integrated lighting and heating regulators.

The present invention has been made in order to improve the prior art as described above, in addition to the heating control main microcomputer and the lighting control microcomputer and a latch relay for controlling the on / off of the light, and the illumination through the power supplied from the lighting load By operating the control microcomputer and relay, it is an object of the present invention to provide a lighting heating integrated regulator that can control lighting with only the power of the lighting load without additional power supply even when the main microcomputer is not supplied with power or other defects do not operate. do.

In order to achieve the above object and solve the problems of the prior art, the integrated heating and heating regulator according to an embodiment of the present invention, a relay for controlling the on / off (on / off) of the power supplied to the lighting load ; A lighting control microcomputer connected to a heating control circuit and controlling an operation of the relay according to an on / off input of the lighting load power of a user through the heating control circuit; A rectifier circuit for full wave rectification of the power supplied to the illumination load when the illumination load is off; And a power supply circuit converting the voltage of the full-wave rectified power source into a first voltage and supplying the relay to the relay, and converting the first voltage into a second voltage to supply the lighting control microcomputer.

In addition, the lighting heating integrated regulator according to an embodiment of the present invention, a circuit board including a temperature measuring circuit connected to the temperature measuring sensor; An adjuster case including an accommodating portion accommodating the circuit board and having a first groove formed on a first sidewall to accommodate the temperature measuring sensor; And a blocking wall formed between the first sidewall and the circuit board and having a second groove for receiving a wire connecting the temperature measuring circuit and the temperature measuring sensor.

According to the integrated heating and heating regulator of the present invention, without the installation work of the light switch and the heating controller of each room, it is possible to supply its own power from the power line connected through the load of the light switch, even if the power of the heating controller is not supplied The control function can achieve the effect.

In addition, according to the integrated lighting and heating regulator of the present invention, by installing a blocking wall and a vent in the regulator case accommodated by the circuit board to minimize the effect of heat generated in the circuit board to the temperature measuring sensor, the temperature measuring sensor is external The effect of sensing the temperature more accurately can be obtained.

In addition, according to the illumination heating integrated regulator of the present invention, by combining the controller case and the display panel with each other through the fastening between the convex groove and the concave groove coated with the adhesive material, various numbers emitted from the circuit board accommodated in the regulator case The effect is that the letter I can be displayed more accurately through the corresponding area of the display panel.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing the internal circuit of the lighting heating integrated regulator according to an embodiment of the present invention.

Illumination heating integrated regulator according to an embodiment of the present invention is a latch relay (latch relay) 110, lighting control microcomputer 120, rectifier circuit 130, power supply circuit 140, transformer (150) , The first bridge diode 151, the diode unit 160, the heating control circuit 170, the main microcomputer 171, the first photocoupler 172, the second photocoupler 173, and the DC-PLC communication unit 181. ), A touch sensor IC 182, a temperature and function setting unit 183, a display unit 184, and a data storage unit 185.

The latch relay 110 controls on / off of power supplied to the lighting load 101. While the internal relay is a relay similar to RAM having volatile data that loses previous output information when the power is turned on / off, the latch relay 110 maintains the previous output information even when the power is turned on or off. It is a ROM-like relay with volatile data. The latch relay 110 may control the maintenance of the on state or the off state of the lighting load 101 according to the user's on / off input according to this characteristic.

The lighting control microcomputer 120 is connected to the heating control circuit 170 and controls the operation of the latch relay 110 according to the on / off input of the power of the lighting load 101 of the user through the heating control circuit 170. . That is, when the user inputs the on / off of the lighting load 101 through the touch sensor IC 182, the on / off input signal of the user is transmitted to the main micom 171 and the lighting control micom 120, The lighting control microcomputer 120 may control the on / off of the lighting load 101 through the latch relay 110 according to the on / off input signal of the user.

The lighting control microcomputer 120 may be connected to the main microcomputer 171 of the heating control circuit 170. The lighting switch input signal of the user through the touch sensor IC 182 may be input to the lighting control microcomputer 120 and the main microcomputer 171, respectively. When power is applied to the main microcomputer 171, the lighting control microcomputer 120 ignores the light switch input signal directly input from the touch sensor IC 182 and receives the light switch input from the main microcomputer 171. According to the signal, the on / off of the lighting load 101 may be controlled through the latch relay 110.

In addition, the lighting control microcomputer 120 is connected to the main microcomputer 171 of the heating control circuit 170, the light switch input signal of the user through the touch sensor IC 182 is the lighting control microcomputer 120 and the main microcomputer Each of them may be input to 171. When no power is applied to the main microcomputer 171, the lighting control microcomputer 120 receives the lighting load 101 through the latch relay 110 according to the illumination switch input signal directly input from the touch sensor IC 182. You can control the on / off of.

The rectifier circuit 130 performs full wave rectification of the power supplied to the illumination load 101 when the illumination load 101 is in an off state. The rectifier circuit 130 may provide power to each circuit by full-wave rectifying the power supplied through the line connected through the lighting load 101 at the N terminal connected to the commercial AC power supply 110V or 220V. To this end, the rectifier circuit 130 may include a second resistor R2, a third capacitor C3, and a second bridge diode 131. The second bridge diode 131 may be connected to the power supply circuit 140, the channel 101, the latch relay 110, and the diode unit 160.

As such, the lighting and heating integrated regulator according to an embodiment of the present invention, since the rectifier circuit 130 supplies full-wave rectification of power to each circuit, the lighting load 101 is completely used even without a separate fastening capacitor. Can be turned off. That is, when half-wave rectification is used, a phenomenon (aka, half-fire or ghost fire) that cannot be completely turned off depending on the type of lighting load may occur. Should be connected. On the contrary, in the present invention, since the rectifier circuit 130 supplies full-wave rectified power, it is possible to prevent the phenomenon that the lighting load 101 is not completely turned off as described above even without a separate phase condenser.

The power supply circuit 140 converts the voltage of the full-wave rectified power source into a first voltage and supplies it to the latch relay 110, and converts the first voltage into a second voltage and supplies it to the lighting control microcomputer 120. . The power supply circuit 140 may include a first capacitor C1, a first zener diode D1, a constant voltage regulator U1, and a second capacitor C2.

The full-wave rectified power through the rectifier circuit 130 flows into the power supply circuit 140 and is limited to the first voltage through the first zener diode D1 to be supplied to the latch relay 110. The first voltage may be implemented as 12V, which is a power supply suitable for driving the latch relay 110, and the first zener diode D1 may be implemented as a zener diode having a breakdown voltage of 12V.

The first voltage may be converted into a second voltage by the constant voltage regulator U1 and supplied to the lighting control microcomputer 120. The second voltage may be implemented as 5V, which is a power supply suitable for driving the lighting control microcomputer 120. That is, the constant voltage regulator U1 may be implemented as an IC that converts the first voltage 12V into the second voltage 5V and outputs the converted voltage.

When the lighting load 101 is in an on state, the transformer 150 transforms the voltage of the power supplied to the lighting load 101 into a third voltage.

The first bridge diode 151 performs full wave rectification on the power transformed to the third voltage.

The power supply circuit 140 may smooth the full wave rectified power through the first capacitor C1, and then limit the smoothed power supply voltage to the first voltage to supply the latch relay 110. In addition, the power supply circuit 140 may supply the lighting control microcomputer 120 by limiting the first voltage to the second voltage.

When the lighting unit 101 is turned on, the diode unit 160 may limit the voltage of the power supplied to the transformer 150 according to the output of the lighting unit 101. Accordingly, heat generated in the transformer 150 may be minimized according to the output of the lighting load 101. To this end, the diode unit 160 may include a fifth diode D5 and a sixth diode D6.

The heating control circuit 170 may include a first photocoupler 172, a second photocoupler 173, a main microcomputer 171, and a temperature measuring unit. In addition, the integrated heating and heating regulator according to the present invention can receive a command for lighting and heating from the user through the touch sensor IC 182, and required for heating control from the valve control box through the DC-PLC communication unit 181 Power and communication can be supplied.

In addition, the temperature and function setting unit 183, which can be implemented as a touch sensor, can receive the user's temperature and various functions, and can store various data necessary for lighting control and heating control in the data storage unit 185. The lighting control information and the heating control information may be provided to the user through the display unit 184.

The data storage unit 185 receives data set through the temperature and function setting unit 183 through the main microcomputer 171 and maintains various setting values. The data storage unit 185 may maintain temperature setting values or functions during power failure. The temperature measuring unit inputs the divided voltage of the resistor and the NTC thermistor resistor to the A / D Convert port of the main microcomputer according to the temperature change, and the divided voltage varies as the NTC thermistor resistor is changed. By measuring the temperature can be measured and displayed on the display unit 184.

Figure 2 is a view showing the appearance of the integrated heating and heating regulator according to an embodiment of the present invention.

Illumination heating integrated regulator according to an embodiment of the present invention includes a regulator case 200, a rear case 300, and a display panel 400. The regulator case 200 may accommodate a circuit board for performing the illumination heating integrated control operation according to the present invention. The power supply circuit board may be accommodated in the rear case 300. The display panel 400 may display the temperature, time, setting, etc. provided by the circuit board accommodated in the regulator case 200, and perform a function of transferring a control command received from a user to the circuit board. Can be.

3 is a view showing the configuration of the adjuster case according to an embodiment of the present invention.

The circuit board 210 may be accommodated in the regulator case 200 according to the embodiment of the present invention. The circuit board 210 includes a temperature measuring circuit connected to the temperature measuring sensor 231. The first sidewall 211 of the adjuster case 200 includes a first groove 212. The temperature measuring sensor 231 may be accommodated in the first groove 212. That is, the temperature measuring sensor 231 may be fastened to the first groove 212 so as to be exposed to the outside of the regulator case 211 and sense the external temperature.

The regulator case 200 includes a blocking wall 220. The blocking wall 220 includes a second groove 221. The wire 232 connecting the circuit board 210 and the temperature measuring sensor 231 may be accommodated in the second groove 221. That is, the wire 232 may be connected to the temperature measuring sensor 231 through the first groove 212, and may be connected to the circuit board 210 through the second groove 221.

The blocking wall 220 may be formed between the first sidewall 211 and the circuit board 210. As illustrated in FIG. 2, the barrier wall 220 may have a first sidewall 211 and a circuit board 210. In addition, when the first groove 221 is formed in the first side of both sides of the first side wall 211, the second groove 212 is a blocking wall facing the second side of the first side wall 211 ( It may be formed on the second side of the 220.

That is, the second groove 221 may be formed at a position facing the connection terminal of the circuit board 210 to which the wire 232 is connected. In addition, the first groove 212 may be formed at a position spaced as far as possible from the position where the second groove 221 is formed. For example, as shown in FIG. 2, when the second groove 221 is formed on the right side of the blocking wall 220, the first groove 212 may be formed on the left side of the first side wall 211. Can be.

As such, when the first grooves 212 and the second grooves 221 are formed to be spaced apart from each other, errors in external temperature measurement due to heat generated from the circuit board 210 may be minimized. That is, the blocking wall 220 is installed inside the controller case 200 to block the circuit board 210 and the temperature measuring sensor 231 from each other, and connect the circuit board 210 and the temperature measuring sensor 231 to each other. By forming the first groove 212 and the second groove 221 through which the wire 232 passes, as far as possible from each other, the temperature measuring sensor 231 is generated from the circuit board 210 that can be received when measuring the external temperature. The effect of heat can be minimized.

In addition, an air vent may be formed on the first sidewall 211 of the regulator case 200. Therefore, according to the tuyeres and the blocking wall 220 installed on the first side wall 211, the temperature of the space formed between the first side wall 211 and the blocking wall 220 is generated in the circuit board 210. By minimizing the influence of heat, it is possible to maintain the same temperature as the outside temperature. Accordingly, the temperature measuring sensor 231 may sense the external temperature more accurately without being affected by the internal temperature of the controller case 200 formed at a temperature higher than the external temperature by the heat generated from the circuit board 210.

4 is a view showing a coupling configuration between the controller case and the display panel of the integrated heating and heating regulator according to an embodiment of the present invention.

According to one embodiment of the present invention, the adjuster case 200 may be combined with the rear case 300 and the display panel 400. The display panel 400 may be provided with a convex groove 410 and the controller case 200 may be provided with a concave groove 201 in order to be coupled to the controller case 200. The adjuster case 200 and the display panel 400 may be coupled to each other due to the fastening between the convex grooves 410 and the concave grooves 201.

An adhesive material may be applied to the inner edge 411 of the convex groove 410 of the display panel 400. When the convex groove 410 is fastened to the concave groove 201, the adhesive material applied to the convex groove 410 inner edge 411 is formed on the inner surface 202 of the concave groove 201 of the regulator case 200. While adhered to, the adjuster case 200 and the display panel 400 may be strongly coupled to each other at the correct position.

As such, the controller case 200 and the display panel 400 are coupled to each other in a more accurate position through the fastening of the convex groove 410 and the concave groove 201 and the adhesive material, thereby being accommodated in the controller case 200. Various numbers or letters, such as temperature or function setting that are emitted through LEDs on the circuit board, may be displayed more accurately through the corresponding area of the display panel 400.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above-described embodiments, which can be variously modified and modified by those skilled in the art to which the present invention pertains. Modifications are possible. Accordingly, the spirit of the present invention should be understood only by the claims set forth below, and all equivalent or equivalent modifications thereof will belong to the scope of the present invention.

1 is a view showing the internal circuit of the lighting heating integrated regulator according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

101: light load 110: latch relay

120: lighting control microcomputer 130: rectifier circuit

140: power supply circuit 150: transformer

151: first bridge diode 160: diode

170: heating control circuit 171: main microcomputer

172: first photocoupler 173: second photocoupler

181: DC-PLC communication unit 182: touch sensor IC

183: temperature and function setting unit 184: display unit

185: data storage unit

Claims (8)

A relay controlling on / off of power supplied to the lighting load; A lighting control microcomputer connected to a heating control circuit and controlling an operation of the relay according to an on / off input of the lighting load power of a user through the heating control circuit;  A rectifier circuit for full wave rectification of the power supplied to the illumination load when the illumination load is off; And A power supply circuit converts the voltage of the full-wave rectified power source into a first voltage and supplies it to the relay, and converts the first voltage into a second voltage to supply the lighting control microcomputer. Illuminated heating integrated regulator comprising a. The method of claim 1, The power supply circuit, A zener diode having the first voltage as a breakdown voltage; And A constant voltage regulator converting the first voltage into a second voltage and outputting the second voltage Illuminated heating integrated regulator comprising a. The method of claim 1, Wherein said first voltage is 12 volts and said second voltage is 5 volts. The method of claim 1, A transformer for transforming the voltage of the power supplied to the lighting load into a third voltage when the lighting load is on; A bridge diode for full wave rectification of the power transformed into the third voltage; And A diode unit installed at one end of the transformer and limiting a voltage of power supplied to the transformer according to the output of the lighting load when the lighting load is in an on state More, The power supply circuit smoothes the full wave rectified power through a first capacitor, supplies the smoothed power supply voltage to the relay by limiting the voltage of the smoothed power supply to the first voltage, and converts the first voltage to the second voltage. Illuminating heating integrated regulator, characterized in that the supply to the lighting control microcomputer to limit. The method of claim 1, The lighting control microcomputer is connected to the main microcomputer of the heating control circuit, and the lighting switch input signal of the user is input to the lighting control microcomputer and the main microcomputer, respectively, and the power is applied to the main microcomputer, the lighting. The control micom ignores the light switch input signal input directly and controls the on / off of the light load through the relay according to the light switch input signal received from the main micom, and power is applied to the main micom. If not, the lighting control microcomputer is a heating and heating integrated regulator, characterized in that for controlling the on / off of the lighting load through the relay in accordance with the lighting switch input signal directly input to the lighting control microcomputer. A circuit board including a temperature measuring circuit connected to the temperature measuring sensor; An adjuster case including an accommodating portion accommodating the circuit board and having a first groove formed on a first sidewall to accommodate the temperature measuring sensor; And A barrier wall formed between the first side wall and the circuit board and having a second groove for receiving an electric wire connecting the temperature measuring circuit and the temperature measuring sensor; Illuminated heating integrated regulator comprising a. The method of claim 6, The first sidewall and the blocking wall are formed in parallel with each other, and when the first groove is formed on the first side of both sides of the first sidewall, the second groove faces the second side of the first sidewall. Illumination heating integrated regulator, characterized in that formed on the second side of the blocking wall. The method of claim 6, And the first side wall of the regulator case includes a blower.

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