KR100770335B1 - Multi thermostat - Google Patents

Abstract

A multi temperature regulator is provided to supply voltage to a light switch without using a battery by integrating an internal temperature regulator with the light switch. A multi temperature regulator includes a micom(380), a source voltage driving unit(310), and a wireless transceiver(360). The source voltage driving unit receives a switching signal from the micom and supplies a source voltage. The wireless transceiver receives a transmitting instruction from the micom, and transmits and receives a signal to/from an external device using a radio frequency scheme. When the source voltage driving unit supplies the source voltage during a small energy supplement, the voltage of a zener diode connected to a TRIAC(TRC) is less than a breakdown voltage and the TRIAC is turned off. When the source voltage driving unit supplies the source voltage during a large energy supplement, the voltage of a zener diode connected to a TRIAC(TRC) is over than a breakdown voltage and the TRIAC is turned on.

Description

Multi thermostat

1 is an overall configuration diagram of an individual heating thermostat incorporating a conventional lighting control device.

2 is a view showing the appearance of a multi-temperature controller according to the present invention.

3 is a block diagram of a multi-temperature controller according to the present invention.

4 is a view illustrating a power driving principle of the power driving unit according to the present invention.

The present invention relates to a multi-temperature controller, and more particularly, a light switch and a temperature controller are integrally configured, and the temperature controller relates to a system for transmitting and receiving a signal to and from the valve controller in a radio frequency (RF) manner.

1 is an overall configuration diagram of an individual heating thermostat incorporating a conventional lighting control device. In general, the light switch 20 may be connected to the individual heating temperature controller 30 in a simple structure.

On the other hand, in order to operate the light only by the light touch of the light switch 20, a relay driving method or a TRC driving method is required.

The MCU, the relay driver 50 and the TRC driver 60 are actually mounted on the PCB in the individual heating thermostat 30, but are shown separately from the outside for convenience of description, and the light switch 20 has a mechanical feel. Instead of the push button switch (LOCK type), I changed it to a light touch tact switch instead of the LOCK type.

Of course, it is designed to know the position of the switch at night by attaching LED indicator lamps around the switch, and it is more convenient to attach a dimmer function to adjust the brightness of the light (when the lamp is a resistive load). The heating thermostat is completed.

The relay and TRC driving power use DC power flowing through the individual heating temperature controller 30, so it can be easily manufactured even without a separate DC power supply. In the case of TRC driving, the lamp 10 turns on the discharge lamp using the ballast. Since there are many types of, it is composed of TRC driving circuit capable of inductive load.

The valve automatic ON / OFF regulator in each room does not control the temperature of each room in individual heating, but it is a regulator that can conveniently turn ON / OFF only the valve (auto valve) in each room. In the figure, a central temperature controller and each valve automatic ON / OFF controller are shown attached to the individual heating temperature controller 30.

As described above, a light switch is connected to and used in the conventional individual heating temperature controller, but there is a problem in that a separate wiring is required to transmit and receive a signal with the valve controller.

The present invention is to solve the above problems, the internal temperature controller does not require a separate wiring for transmitting and receiving a signal with the valve controller and at the same time requires a battery or a separate power supply for the power supply (battery) It is an object to provide a multi-temperature controller that does not.

The present invention includes a power driving unit for driving a power by receiving a switching signal from the microcomputer, the power driving unit charges the current of the input power to the capacitor to drive the power through a resistor and a zener diode connected to the charge current in series with each other In this case, when the power driver drives the power supply during the period of low energy supply among the input waveforms during each cycle of the AC power, the voltage of the zener diode connected in parallel to the TRC becomes less than the breakdown voltage, and the TRC is turned off. When the power drive unit drives the power supply during the period of high energy supply of the input waveform during each cycle of the AC power supply, the voltage of the zener diode connected in parallel to the TRC becomes more than the breakdown voltage, so that the TRC is in the ON state Present the thermostat.

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

2 is a view showing the appearance of a multi-temperature controller according to the present invention. Referring to FIG. 2, the appearance of the multi-temperature controller according to the present invention is represented by the display unit 100, the temperature controller 110, and the light switch 120.

The display unit 100 is a window that displays room temperature, time, and function. For example, room temperature is displayed as "25 ° C", time is displayed as "10:00", and functions are displayed as "room temperature setting", "scheduled timer setting" and "boiler running". do. The display unit 100 is a system for allowing a person in the room to see the appearance of the multi-temperature controller to grasp the room temperature, time, and function at a time.

Temperature controller 110 is a system for adjusting the temperature of the room and the corresponding function. For example, it is a case where room temperature is set to 30 degreeC. It is a system that can be operated easily by a person in the room when raising the temperature to start the boiler or lowering the temperature when the boiler is not needed.

The light switch 120 is a system provided for supplying power to the indoor light and may be provided to blink at least one indoor light. That is, in the case where there are several lights in the room, it is a system that enables individual lights to blink individually.

3 is a block diagram of a multi-temperature controller according to the present invention. Referring to FIG. 3, the multi-temperature controller according to the present invention may include a power driver 310, a function key input unit 320, a memory unit 330, a temperature sensor 340, an oscillator 350, and a wireless transceiver 360. ) And a display unit 370, which are connected to the microcomputer 380.

The power driver 310 receives a switching signal from the microcomputer 380 to drive the power, and may include a reservation timer for blinking a lamp at a predetermined time. Each element in the power supply driver 310 is connected to each node 1, 2, 3, ..., 10, and is also referred to as TRC (triac, TRIAC). Let's look at how to drive the power according to the ON / OFF.

Let's take a look at how to drive the power when the TRC OFF. When TRC is OFF, power is input and the input current flows through C1, R1, and D2 to C2, and the input current through C2 flows to D1, R1, and C1, so the current is charged to C2. The charged current is driven by a power source having a constant voltage by R2 and ZD1. As described above, when the power is driven even when TRC OFF, the driving power may be drawn out by the power driving unit.

On the contrary, let's look at the power driving method of the power driving unit when TRC ON. TRC should be turned on to drive the power during the time when energy supply is high among the AC input waveforms of TRC which is 60Hz. Here, when the TRC is driven, the TRC is driven when the voltages of the zener diodes ZD2 and ZD3 are greater than the breakdown voltage in order to turn on the energy supply for a large time. That is, while TRC is ON, input current flows to R5, ZD2 and D3 to operate Q2, and input current flows to R3 and R4 to operate Q1. And the voltage V _CC is After being applied, some of the current through which Q3 is operated flows through R7 to Q2, and another portion of the current flows through R10 to Q1.

Let's look at how to turn on / off the lamp by the operation of the electric switch SW. SW is turned off, and the port of the TRC driving microcomputer 380 has a low impedance and a low voltage. When the voltage is OFF, Q1 and TRC remain OFF because the base voltage of Q1 is 0V. When the voltage is in the ON state, whenever the voltage between ZD2 and ZD3 is greater than the breakdown voltage, the base voltage is supplied to Q1, and Q1 and TRC repeat the ON / OFF cycles at 60 Hz to turn on the lamp.

The function key input unit 320 inputs the divided voltage to the microcomputer by an ON / OFF operation of at least one key. An indoor temperature setting function for adjusting a room temperature and a reservation timer setting function for operating at a predetermined time are provided. Or input the setting function for boiler operation. The voltage V _CC is supplied through R11, and the divided voltages of R11, R12, R13, R14, and R15 are input to the analog / digital port of the microcomputer 380 according to the function key operation. That is, the function voltage changes the divided voltage according to the combination of ON / OFF operation of the function keys such as temperature up (UP), temperature down (DOWN), functions and settings. A current flows through R12, when DOWN is turned on, a current flows through R13. When the function is turned on, a current flows through R14. When the setting is turned on, a current flows through R15. The number of divided voltages according to the equation is 2 ⁴ = 16.

The memory unit 330 receives various matters about the setting value set by the function key input unit 320 through the microcomputer 380 and maintains various setting values. The memory unit 330 is used to maintain temperature setting values or functions during power failure. do. Looking at the configuration of the memory unit 330, voltage V _CC is supplied to pin 8, pins 1, 2, 3, 4, 7 is grounded, pins 5, 6 are connected to the microcomputer 380 have. Therefore, the temperature setting is received from the microcomputer 380 through pins 5 and 6.

The temperature detector 340 allows the divided voltages of the resistor and the NTC thermistor resistor to be input to the analog / digital port of the microcomputer 380 according to the temperature change. As the NTC thermistor resistors vary, the voltages of R16 and NTC thermistor resistors vary.

The oscillator 350 receives the oscillation signal from the microcomputer 380 and oscillates at a predetermined frequency.

The wireless transceiver 360 receives a transmission command from the microcomputer 380 to an external device including a valve controller, and transmits and receives a signal with an external device including the valve controller in an RF manner. Therefore, transmission and reception of signals can be performed without additional wiring. All wireless communication devices, including radio transceivers, have a high frequency to transmit the voice signal frequency far and then receive it as an antenna and lower it back to the original frequency, and a base band unit to accurately reproduce high frequency signals. And it consists of three parts, such as a logic unit, the wireless transceiver 360 is a portion in which the transmitting and receiving high-frequency unit of the communication device is integrated into one.

The display unit 370 receives information on the room temperature, time, and function from the microcomputer 380 and displays the information on the outside.

4 is a view illustrating a power driving principle of the power driving unit according to the present invention. Referring to FIG. 4, the fluorescent lamp 300 includes a ballast 301 and a condenser 302, and the fluorescent lamp 300 is switched by switching the light switch 310 connected to one line (B line). You can see that blinks. In particular, in the present invention, one line (A line) of the power line is connected to the ballast 301 inside the fluorescent lamp 300, the other line (B line) of the power line through the light switch 310, the fluorescent lamp 300 It is connected to the internal ballast 301. At this time, when the light switch 310 is turned on, the fluorescent lamp 300 is turned on, and when the light switch 310 is turned off, the fluorescent lamp 300 is turned off.

On the other hand, in the multi temperature controller, since only one wire (B line) is connected, the control circuit supply voltage cannot be received. For this reason, the capacitor 302 is attached to allow the A and B lines to be connected together through the capacitor 302 to supply voltage to the multi temperature controller.

5 is a view showing the structure and equivalent circuit of the TRC used in the light switching unit according to the present invention. Referring to Figure 5, it can be seen the structure and equivalent circuit of the TRC used in the light switching unit of the multi-temperature controller according to the present invention.

As shown in (a), the TRC is a bidirectional three-terminal control rectifier having three electrodes: an anode (T1), a cathode (T2), and a gate. When a gate signal is applied to the TRC, it remains ON until T ₁ and T ₂ are powered off. The power source connected to T ₁ and T ₂ is AC, so it has a frequency of 60Hz per second.

As shown in (b), when the anode is given a negative potential and the cathode is given a positive potential, the SCR is turned off. When the gate current flows to the gate, the SCR is turned on. The voltage when the SCR is turned on is called a breakdown voltage.

Once the SCR is turned on, the gate current is not turned off even if the gate current is reduced. To turn it off, the anode potential must be made zero or negative. As described above with reference to FIG. 3, in the present invention, when the driving power can be drawn out from the power driving unit, the voltage of the zener diode connected in parallel to the TRC becomes less than the breakdown voltage, and the TRC is turned off. When the power is driven during the time when the energy supply is high among the input waveforms, the voltage of the zener diode connected in parallel to the TRC becomes more than the breakdown voltage and the TRC is turned ON.

Accordingly, the TRC is not in the ON state until the drive power can be drawn out from the power source driving unit, and the TRC is in the ON state only when the drive power cannot be drawn out from the power source driving unit.

Although the technical idea of the multi-temperature controller as described above has been described with the accompanying drawings, this is intended to exemplarily describe the best embodiment of the present invention and not to limit the present invention. In addition, it will be apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit of the present invention.

The multi-temperature controller of the present invention does not require separate wiring because the internal temperature controller transmits and receives signals to and from the valve controller in an RF manner, and at the same time, since the internal temperature controller is integrated with the light switch, power supply is not possible. This eliminates the need for a power supply battery or separate power source.

Claims (7)

Micom; Receiving a switching signal from the microcomputer to drive power; A first node and a second node to which an AC power source is input; A first zener diode (ZD3), a first resistor (R8), and a second resistor (R9) connected between the first node and a third node; A first transistor Q3 and a third resistor R10 connected between the third node and the microcomputer; A fourth resistor (R5), a second zener diode (ZD2), and a first diode (D3) connected between the first node and a fourth node; A second transistor Q2 coupled between the fifth node and ground; A fifth resistor (R7) connected between the third node and the fifth node; A first capacitor C1 and a sixth resistor R1 connected between the sixth node and the seventh node; TRC (TRC) coupled between the second node and the sixth node; A second diode (D1) connected between the seventh node and ground; A third diode D2 connected between the seventh node and an eighth node; A second capacitor C2 connected between the eighth node and the ground; A seventh resistor R3 connected between the sixth node and a ninth node; An eighth resistor R4 and a third transistor Q1 connected between the ninth node and the ground; A ninth resistor R2 connected between the eighth node and the tenth node; And a third zener diode ZD1 and a third capacitor C3 connected in parallel to each other between the tenth node and ground, wherein the base voltages of the first, second, and third transistors are respectively the third node. A power supply unit supplied from a fourth node and a microcomputer, and a gate voltage of the TRC supplied from the ninth node; And And a wireless transceiver for receiving a transmission command from the microcomputer to an external device and transmitting and receiving a signal with the external device in an RF manner. When the power supply unit charges the current of the input power to the capacitor to drive the power supply through a resistor and a zener diode connected in series with each other, When the power driver drives the power supply during a period of low energy supply among the input waveforms of the AC power cycle, the voltage of the zener diode connected in parallel to the TRC becomes less than the breakdown voltage, and the TRC is turned off. When the power drive unit drives the power supply during the period of high energy supply of the input waveform during each cycle of the AC power supply, the voltage of the zener diode connected in parallel to the TRC becomes more than the breakdown voltage, so that the TRC is in the ON state Thermostat. The method of claim 1, And the external device is a valve controller. The method of claim 1, The power drive unit multi temperature controller, characterized in that it comprises a reservation timer for blinking the light at a certain time. The method of claim 1, A function key input unit for inputting a divided voltage to the microcomputer by an ON / OFF operation of at least one key; A memory unit configured to maintain a temperature by receiving information regarding a temperature set by the function key input unit through a microcomputer; A temperature sensing unit configured to input a divided voltage of a resistor and an NTC thermistor resistor into the microcomputer according to a temperature change; An oscillator receiving the oscillation signal from the microcomputer and oscillating at a predetermined frequency; And A display unit configured to receive information regarding an indoor temperature, a time, and a function from the micom and display the information on the outside; Multi-temperature controller, characterized in that it further comprises. The method of claim 4, wherein The function key input unit may include any one of an indoor temperature setting function for adjusting an indoor temperature, a reservation timer setting function for operating at a predetermined time, or a setting function for boiler operation. delete delete

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