KR20090029885A - Valve driving circuit of a thermostat - Google Patents

Abstract

A valve driving circuit of a temperature controller is provided to reduce the number of wirings to two by operating a relay switch with a PTC element. A valve driving circuit of a temperature controller comprises: a PTC(Positive Temperature Coefficient) element in which electric resistance is increased and voltage of input alternating current power source is decreased; first and second switches(SW1,SW2) parallely connected between a signal line and a motor; a relay switch(4) having a first switch terminal(1), a second switch terminal(2) and a third switch terminal(3); and a relay driving part(5) controlling a switching direction of the relay switch by using the voltage of both ends of the PTC element. The switching direction of the relay switch is controlled with the relay driving part.

Description

VALVE DRIVING CIRCUIT OF A THERMOSTAT}

The present invention relates to a valve drive circuit of a thermostat, and more particularly, to a valve drive circuit of a thermostat having a simpler configuration through a modification of the configuration of the drive circuit.

In general, residential buildings, such as houses and apartments, use oil boilers, gas boilers, and cogeneration districts as the main heating devices for indoor heating, and these boilers have a front for operation and control such as heating, hot water supply, and timers. It uses an integrated main controller (microcom) and a room controller analog type thermostat. Here, the analog type thermostat is connected to a 2-wire wire to have a configuration to supply a user command supplied from the room temperature controller to the main controller through the 2-wire wire to enable the operation and control as described above. do.

However, in the case of using the conventional analog type room temperature controller, since the room temperature and the set temperature are set to analog, it is difficult to set a desired room temperature, and the main unit of the analog signal supplied from the room temperature controller Since the boiler is operated after converting from the controller to digital, there is a problem that the main controller becomes bulky, and a separate configuration is added to convert the analog signal into the digital signal, thereby increasing the cost. There is a problem.

Therefore, due to the above-mentioned problems, digital room temperature controllers are mainly used in recent years, and such digital temperature controllers generally control motors using temperature control switches and relay switches. In this case, in order to drive the relay switch, since the AC controller must receive AC power in a crossing manner, the control operation as described above is generally performed using three wires.

That is, the digital temperature controller according to the related art has an additional number of components due to the three wires required relationship, and also the appearance of the digital temperature controller is not good in appearance due to the difficult relationship of the three wires. There was this. In addition to the above-described problems, there was also a problem that compatibility with the conventional analog temperature controller was not easy due to the difference in the number of wirings.

Therefore, the present applicant needs to find a problem as described above, that is, a method of reducing three wires to two wires.

SUMMARY OF THE INVENTION The present invention has been made in an effort to solve the problems as described above, and to provide a motor-driven circuit of a temperature controller for reducing the number of wirings by two by driving a relay switch using a PTC element. It is done.

In addition, the thermostat valve driving circuit having the configuration as described above is another technical object to increase the compatibility with the conventional products while improving the ease of installation by reducing the number of the wiring.

The thermostat valve driving circuit of the present invention for achieving the above object, the valve control circuit of the thermostat comprising an AC power source, a temperature control switch unit and a drive unit such as a motor connected and operated by the AC power source. A PTC device comprising: a PTC element for increasing or decreasing an electrical resistance and for lowering a voltage of an input AC power supply; First and second switches connected in parallel between a signal line through which a driving current of the motor flows and the motor; A relay switch having a first switch terminal connected to the signal line, a second switch terminal connected to the first switch, and a third switch terminal connected to the second switch; In the valve driving circuit of the thermostat comprising a; a relay driver for controlling the switching direction of the relay switch by using the voltage across the PTC element, the switching direction of the relay switch is controlled by the relay driver ,

The relay driver may include: a current attenuator for attenuating a current of the input AC power source; A bridge rectifying circuit for full-wave rectifying a voltage of an AC power supply whose current is attenuated; A smoothing circuit for removing ripples carried by full-wave rectified DC voltage; And a relay coil excited by a DC voltage from which ripple is removed to control a switching direction of the relay switch.

The PTC element increases the electrical resistance by the half-wave rectified signal supplied from the temperature control switch unit during heating to lower the voltage of the input AC power supply,

The relay driver receives the voltage dropped by the PTC element during heating to switch the relay switch to the third switch terminal so that the driving current of the signal line is transferred to the motor through the relay switch and the second switch. It is a technical feature to make it supplied.

The above object of the present invention will become more apparent from the preferred embodiments of the present invention described below with reference to the accompanying drawings, by those skilled in the art.

As described above, the present invention has a technical advantage of reducing the number of wirings by using only a PTC element in the drive circuit of the room temperature controller, and also due to this technical advantage, according to the present invention The room thermostat has a technical advantage that it is easy to be compatible with the conventional analog type room thermostat.

In addition to the technical advantages described above, the temperature controller according to the present invention can reduce the occurrence rate of the failure than the conventional temperature controller, there is a technical advantage that the installation is convenient.

As such, the present invention is not limited to the embodiments of the present invention described above, and can be freely changed and modified. The free change of the present invention is not limited to the embodiment of the detailed description described above, and the free change is possible within the scope not exceeding the claims described below by the inventor.

Hereinafter, the present invention will be described in detail with reference to FIG. 1, which shows a valve driving circuit of a temperature controller according to the present invention.

As described above, the valve driving circuit of the thermostat according to the present invention allows the use of the PTC element to drive the thermostat using only two wires by using three conventional wirings. It is technical feature that we made.

Referring to FIG. 1, a motor driving circuit of a digital temperature controller according to an embodiment of the present invention having such technical features will be described.

Digital temperature controller according to the present invention is configured to include an AC power supply and a temperature control switch unit and a drive unit connected by the AC power, in a manner to control the operation of the drive unit by the operation of the temperature control switch unit It can be seen that the digital temperature controller is operated. In particular, this control operation is carried out via the relay switch 4, which is controlled by the relay driver 5.

Looking at the configuration as described above in more detail, the valve driving circuit of the digital temperature controller according to the present invention forms a PTC element at one end of the AC power supply, from both ends of the PTC element, the switch of the relay switch 4 The relay driver 5 for converting is connected and formed. In addition, the relay switch 4 includes a first switch SW1 and a second switch SW2 for controlling the operation of the driving unit. In one embodiment of the present invention, the drive unit uses an AC motor.

The PTC element disclosed in the valve driving circuit of the digital temperature controller configured as described above has a low resistance at low temperatures such as room temperature, and thus has conductivity. However, as the temperature increases, the electrical resistance rapidly increases in a relatively narrow temperature range. It is an element having. Therefore, in the present invention, by using the PTC element having the technical characteristics as described above to achieve the technical objects as described above of the present invention.

The relay driver 5 connected to both ends of the PTC element converts a commercial power input (generally, 220 V AC power) into a driving voltage and supplies the relay voltage to the relay coil 6, specifically, AC (AC). ) When the voltage and current of the power supply are input, the current of the input AC power is attenuated to a certain size, and the current is attenuated. Thereafter, the relay driver 5 removes the ripple carried by the full-wave rectified DC voltage and supplies the DC voltage from which the ripple is removed to the relay coil 6.

The relay driver 5 having such a function includes a current attenuator for attenuating the current of an AC power source, a bridge rectifying circuit for full-wave rectifying a voltage of an AC power source in which the current is attenuated, and a full-wave rectified DC. And a smoothing circuit for removing the ripples carried by the voltage, and a relay coil 6 which is excited by the DC voltage from which the ripple is removed and controls the switching direction of the relay switch 4.

The current attenuator includes a first resistor R1 and a first capacitor C1 connected in series between one end of the PCT element and the bridge rectifier circuit. This current attenuator attenuates the current of the AC power supply whose voltage is dropped by the PTC element and transfers it to the bridge circuit.

The bridge rectifier circuit is composed of four diodes D1 to D4 connected in a rhombus shape. The bridge rectifier circuit rectifies the input voltage of the AC power whose current is attenuated by the commercial AC voltage and the current attenuator to output the rectified DC voltage.

The smoothing circuit consists of a second capacitor C2 connected in parallel between the bridge rectifier circuit and the relay coil 6. This smoothing circuit removes the ripple carried by the DC voltage rectified by the bridge rectifying circuit and transfers the ripple to the relay coil 6.

Both ends of the relay coil 6 are connected to the bridge rectifier circuit and connected in parallel with the second capacitor C2 of the smoothing circuit. The relay coil 6 is excited by the DC voltage with the ripple removed to control the switching direction of the relay switch 4.

On the other hand, the part corresponding to the temperature control switch unit constituting the component of the present invention is configured to include a pulse signal generator for generating a pulse signal and a diode for half-wave rectifying the input AC power (AC).

The operation of the driving circuit of the digital temperature controller according to an embodiment of the present invention including the above configuration will be described in detail with reference to FIG. 1.

In non-heating, the relay switch 4 is connected to the second switch terminal 2, wherein the current on the signal line is supplied to the AC motor along the first switch SW1. That is, normally, the first switch SW1 is ON (closed), but when the AC motor is in the stop position, the first switch SW1 is OFF (opened).

When heating is required, an oscillation signal is generated at the temperature control switch to generate half-wave rectification at both ends of the temperature control switch, and then the half-wave rectification is supplied to the PTC device.

In this case, the PTC element suddenly increases in resistance, and the voltage at both ends thereof reaches 180 V, and the voltage at both ends of the PCT element is converted into a driving voltage of about 12 V by the relay driver 5. At this time, the relay coil 6 is excited by the driving voltage to change the switching direction of the relay switch 4, which switches the switching direction from the second switch terminal 2 to the third switch terminal 3. When the relay switch 4 is switched in this way, the current on the signal line is supplied to the AC motor through the second switch SW2 connected to the third switch terminal 3, thereby allowing the AC motor to be driven again. And heating is performed.

That is, as described above, the present invention uses the PTC element to turn on and off the driving circuit of the digital temperature controller by using only two wiring lines as shown in the drawing. It can be seen that.

Meanwhile, in the above embodiment of the present invention, the present invention will be described based on the valve driving circuit of the digital temperature controller. However, the present invention is not limited to the digital temperature controller. It is also possible to use the motor-driven valve drive circuit of the temperature controller.

1 is a view showing a motorized drive circuit of a temperature controller according to the present invention.

<Explanation of symbols of main parts in drawings>

1: first switch terminal 2: second switch terminal

3: third switch terminal 4: relay switch

5: relay driving unit 6: relay coil

SW1: first switch SW2: second switch

Claims (4)

In the valve drive circuit of the thermostat comprising an AC power source, a temperature control switch unit connected to and operated by the AC power source and a drive unit such as a motor, PTC element which increases or decreases an electric resistance and drops the voltage of an input AC power supply; First and second switches SW1 and SW2 connected in parallel between the signal line through which the driving current of the motor flows and the motor; The first switch terminal 1 connected to the signal line, the second switch terminal 2 connected to the first switch SW1, and the third switch terminal 3 connected to the second switch SW2 are connected. Having a relay switch 4; And a relay driver 5 for controlling a switching direction of the relay switch 4 by using voltages at both ends of the PTC element. And a switching direction of the relay switch is controlled by the relay driving unit. The method of claim 1, wherein the relay driver 5, A current attenuator for attenuating the current of the input AC power source; A bridge rectifying circuit for full-wave rectifying a voltage of an AC power supply whose current is attenuated; A smoothing circuit for removing ripples carried by full-wave rectified DC voltage; And And a relay coil (6) which is excited by a DC voltage from which ripple is removed to control the switching direction of the relay switch. The method of claim 1, The PTC element valve driving circuit of the temperature controller, characterized in that the electrical resistance is increased by the half-wave rectified signal supplied from the temperature control switch unit during heating or non-heating to drop the voltage of the input AC power. The method of claim 1, The relay driver 5 receives the voltage dropped by the PTC element during heating or non-heating and switches the relay switch 4 to the third switch terminal 3 so that the driving current of the signal line is increased. The valve driving circuit of the temperature controller, characterized in that to be supplied to the motor through the relay switch (4) and the second switch (SW2).

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