KR200148286Y1 - (cooling) heating apparatus control device - Google Patents

Abstract

The present invention relates to a control device for automatically controlling the operation of a (cooling) heating system. The control unit is a conventional two-wire control line in which an output unit by a relay contact is improved to a contactless switch circuit with an electronic circuit, and a load line and a power line are shared. It is a control circuit that enables construction.

Description

Remote control drive of (cooling) heating system

1 is a block diagram showing a conventional remote control drive.

2 is a block diagram showing an embodiment of the present invention.

3 and 4 are block diagrams showing examples of similar embodiments of the present invention.

Figure 5 is a block diagram showing an embodiment of the function expansion of the present invention.

6 is a block diagram showing an embodiment in which power is shared to a control load line.

The present invention relates to a device for controlling the operation of a (cooling) heating device, and a remote control driving device including a contactless electronic switch circuit capable of directly driving a high power AC power source. (Cooling) heating device (commonly referred to as solenoid valve or electric heater in this specification) generally includes a temperature controller (hereinafter referred to as a control device) for maintaining a certain range of room temperature based on a set temperature. It is installed as a means to improve the user's convenience and automatic (cooling) heating operation according to the change of room temperature by intermittent the power supplied to the (cooling) heating device. According to the trend of the user's demand for maintaining the room temperature precisely, most of the control devices are electronic circuits, and as a method of directly driving a high-power heating device such as a solenoid valve or an electric heater with the output of the electronic circuit, The same relay (2-3) was used. The relay (2-3) is a powerful means as an interface function to directly match between a control device using a low-power DC power supply and a load using a high-power AC power supply, the relay contact and the drive coil electrically insulated This is an appropriate way to take advantage of the fact that it does not interfere with each other. However, such a conventional relay contact driving method must configure a power source that is independent of a load line with a strong power fluctuation in order to drive the relay (2-3) itself. Since the same transformer (8-1) and rectifier circuit (8-2) should be provided, not only waste of power consumed by the transformer (8-1) and relay (2-3), but also due to the complexity of circuit components, etc. In addition, there are drawbacks such as troublesome in construction due to additional facilities such as AC Power of Fig. 1. In addition, it is easy to cause malfunction in the detection of room temperature due to the heat generation phenomenon commonly generated in transformers, etc. The limited lifetime also contributed to the reliability of the device.

On the other hand, an external adapter (direct current rectifier) may be used as a method to isolate the heat generation of the transformer, but there is another problem such as a cost increase in addition to this method. The necessity of designing a circuit has emerged.

The purpose of the present invention is to construct the output unit of the heating and cooling control unit by the solid-state switch circuit method, thereby achieving mass productivity through semi-permanent life, energy saving, and compact configuration, and furthermore, a wide range of voltages that allow the load line to be commonly used as a power line. It aims to provide a driving device circuit that can be expanded and configured with a control device circuit of advanced function that can maintain the room temperature comfortably by securing the function of the stable circuit.

The present invention is constructed according to a predetermined control signal by configuring an electronic switch circuit to which the driving circuit of the heating and cooling device is connected via the three-terminal control element (SCR, TRIAC, TR or FET) from the driving power supply of the cooling and heating device. The squelch circuit provides a contactless switching circuit portion constituting means for directly controlling a power supply of a (cooling) heating device.

In addition, the present invention connects the automatic current switching circuit which automatically switches the current path in response to the rise and fall of the power supply voltage to the current supply passage (constant voltage controller) of the control signal generation circuit, thereby reducing the ups and downs of the voltage fluctuation supplied from the control line. Stable supply of severe voltage to the control device allows the power line to be shared with the load line, providing a means to live in a 2-wire control line.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. 2 is a block diagram showing an embodiment of the present invention, the driving circuit unit (1) of the (cooling) heating device composed of a means for driving the heating and cooling device by controlling the power supplied to and supplied to the (cooling) heating device ; The bridge diode circuit 2-1 is connected between the power supply and the drive circuit portion of the air conditioning system so that the driving power of the (cooling) heating device can be controlled, and the control input terminal is connected to ANODE and CATHODE of the bridge diode circuit 2-1. Switching circuit portion 2 of the means for consistently connecting the ANODE and CATHOBE of the SCR (2-2) provided: control signal generation circuit portion (3) of the means for generating a TRIGGER ON-OFF signal based on the set room temperature: A constant voltage circuit section 4 of means for stabilizing the power supply voltage to supply power to the control signal generation circuit section; A temperature setting circuit section 5 of means for arbitrarily setting the room temperature; The driving circuit unit 1 of the heating and cooling device is connected to the output of the switching circuit unit 2, and the output of the control signal generating circuit unit 3 is connected to the control input terminal of the switching circuit unit 3, and the control signal generating circuit unit The reference voltage Vref supplied from the constant voltage circuit section 4 is connected to the first input terminal (3) and the temperature setting circuit section 5 is connected to the second input terminal.

The power supplied from the AC power is supplied to the driving circuit unit 1 of the cooling and heating device via the bridge diode 2-1, but the current of the circuit is connected to ANODE and CATHODE of the bridge circuit 2-1. It is turned on only when SCR is turned on, and it is kept electrically open when SCR is turned off. The power supply to the driving circuit of the air conditioning unit is in a state of being cut off. [The control element is generally referred to as a three-terminal control element because it is composed of an input terminal, an output terminal, and a control input terminal (gate) like the SCR, TRIAC, or transistor, and the same term is used in the present specification.]

The reference voltage Vref supplied to the first input terminal of the control signal generation circuit portion is shared by dividing the output voltage of the constant voltage circuit portion 4 by the resistors 4-1 and 4-2. Since the temperature sensor (5-1) in which the resistance value changes in accordance with the change in the indoor temperature is connected in parallel, the reference voltage Verf corresponding to the change in the indoor temperature is automatically changed. The automatic change is to perform a detection operation to automatically control the heating device when the room temperature changes, compared to the set voltage of the temperature setting circuit section described later.

The second input terminal of the control signal generating circuit portion is connected to a temperature setting circuit portion 5 which can be arbitrarily set by the user with the variable resistor 5-2, and automatically according to the voltage set arbitrarily by the temperature setting circuit portion and the room temperature. By comparing the changed reference voltage Vref, the voltage comparator 3-1 generates a control signal for turning on or off the switching circuit 2 when the room temperature changes.

The control signal generation circuit unit deletes the temperature sensor (5-1) and the variable resistor (5-2) connected to the input terminal, and when the switch control circuit is configured to switch the switch signal on and off by manual operation, the automatic control function is deleted. As a control device capable of driving with any switch operation signal, of course, a detailed description thereof is omitted, but the term "control function" in the present specification refers to all of these functions.

Such a control device circuit has a structure in which the bridge diode circuit 2-1 and the SCR circuit 2-2 are always connected mechanically between a power supply and a load (driving circuit part of a heating device) according to the presence or absence of a control signal. It is composed of a non-contact semi-permanent switching circuit because it controls the power supply electrically, and the gate drive current of SCR is extremely small. The coin power can be greatly reduced.

3 is a block diagram showing another embodiment of the present invention, in which the bridge diode circuit and the SCR are replaced with a TRIAC (2-3). Therefore, the control signal generating circuit unit needs a trigger signal generator that can turn on TRIAC, for example, a zero-crossing switch in the form of a ONE CHIP. The input terminal of the zero-crossing switch generally includes a voltage comparator, so that the automatic control signal generation function corresponding to the indoor temperature setting and the temperature change can be easily configured.

FIG. 4 is an example that can be utilized even when the driving circuit of the air conditioner is operated by a low voltage DC power supply by replacing the SCR of FIG. 2 with a transistor (or FET 2-4), and matching the polarity of the DC power supply. The power supplied to the control unit by the bridge diode circuit is automatically corrected for polarity even if it is not connected. 4 is a diagram showing an application of the present invention, and the operation description is similar to that of FIG.

FIG. 5 is a block diagram showing an example of a configuration in which the power supply of the control signal generation circuit section 3 is shared by the output of the bridge diode circuit 2-1 of FIG. 2, and is shown from ANODE of the bridge diode circuit. The resistor 6-1 is connected so that the stepped down voltage can be supplied normally. When the SCR is turned on, the voltage of the ANODE can be directly supplied to the input voltage of the constant voltage device. A bridge diode circuit (2-1) connects the collector and the emitter, and connects the base of the transistor (6-2) to the control signal generation circuit portion to connect the transistor when the output of the control signal generation circuit portion is turned on. ) And the power supply circuit of the control signal generation circuit section (3).

Since ANODE of SCR TURN OFF bridge diode circuit is applied with very high voltage of 100 ~ 200V, the voltage is applied to the constant voltage circuit part 40101 power supply with the proper voltage stepped down about 4V through the resistor 6-1. However, when SCR is turned on, the ANODE voltage is very low as about 4V, so when stepped down by the resistor 6-1, the proper voltage is not supplied to the constant voltage circuit section 4, so that the control signal generating circuit section 3 does not operate. Do not.

That is, at this time. In SCR TURN ON, one side of the control signal is also applied to the base of the transistor 6-2 to conduct the transistor 6-2, and the transistor 6-2 conducts the ANODE and the constant voltage circuit part of the bridge diode circuit. A short circuit is connected to the input terminal to directly connect a voltage substantially equal to that of the ANODE of the bridge diode circuit to be supplied to the input voltage of the constant voltage circuit unit 4. Although not specifically illustrated in the circuit, the automatic current switching circuit unit 6 may add a protection circuit for compensating for the voltage lost in the output of the control signal generator and the transistor itself. In this embodiment of FIG. 5, since the power supplied from the driving circuit part of the (cooling) heating device can be shared without a separate power supply line for supplying the control device, the heating / cooling device and the control device can be connected only by the 2-wire control line. It becomes a convenient structure for the construction of the bar connection line.

FIG. 6 is a block diagram showing another example of the temperature setting circuit section 5. The timer signal is supplied to one input terminal of the control signal generating circuit section 3 of FIG. By supplying the output of the timer signal generating circuit section 7 which generates the timer output voltage with the gradually rising voltage, the control signal generating circuit section has one cycle of actuation and stop, and constitutes means for arbitrarily adjusting the interval of one cycle.

The timer signal generating circuit unit 7 generates an output voltage for a predetermined period of time, for example, 60 minutes, but gradually rises stepwise in the form of a staircase wave. A characteristic in which the signal waveform in one cycle is reset as a whole. The input signal of the temperature setting circuit section 5 of the control signal generating circuit section 3 coupled to it as a circuit having a sawtooth wave form, and the control signal generating circuit section 3 ) Output is turned on for a predetermined period, for example, 10 minutes. OFF for 50 minutes, and ON for 20 minutes if the voltage is set at 2: 4. The control signal is generated at intervals of 1 cycle which are turned off for 40 minutes. The timer signal generation circuit is a circuit that can be easily understood by those skilled in the art using a D / A converter, and thus a detailed description thereof will be omitted. The control device of the embodiment of FIG. 6 can arbitrarily vary the operation period for a predetermined period by the timer signal generation circuit 7, and when the temperature setting circuit unit 5 is additionally connected, the set operation period is changed when the indoor temperature changes. Automatically changing function is added, so it is realized as an advanced function control device that can maintain a comfortable indoor temperature. One kind of ONE CHIP A / D CONVERTER that can configure the timer signal generation circuit includes a voltage comparator function. When using this, the timer signal generator and the control signal generator can be integrated into the ONE CHIP configuration. As such, such a configuration is shown to show the extension of the present invention.

As can be seen from the above description, according to the present invention, the control unit output unit for controlling the operation of the (cooling) heating unit is configured in a solid-state switch circuit method, which greatly extends the lifespan compared to the conventional relay method. The circuit is simple, and the loss of driving power consumed by the switch circuit can be negligibly reduced, which can greatly reduce unnecessary energy and share the control line of the (cooling) heating unit and the power supply line of the control unit. It is possible to make it easy to construct, and it is an advantageous design.

Claims (3)

A remote control device installed between a power supply and a driving unit of a (cooling) heating unit and controlling a driving of the (cooling) heating unit as a connecting line, wherein the power is added to the (cooling) heating unit and controlled to supply (cooling) heating. A driving circuit portion comprising means for driving the device: connecting a bridge diode circuit between a power supply and the driving circuit portion, and connecting the input and output terminals of the three-terminal control element to ANODE and CATHODE of the bridge diode circuit consistently; A switching circuit unit controlling power supply to the driving circuit unit according to a control signal supplied to a control input terminal of the terminal type control element; Control signal generation circuit portion of the means for connecting to the control input terminal of the switching circuit unit and comparing the reference voltage of the first input terminal and the set voltage of the second input terminal to generate the indoor temperature detection and the output of the ON-OFF control signal as a timer signal: A constant voltage circuit part of means for supplying power to various circuit parts by stabilizing a power supply voltage connected to the circuit; connecting the power supply and the driving circuit part of a (cooling) heating device to an input / output terminal of the switching circuit part, wherein the switching circuit part And an output terminal of the control signal generating circuit unit connected to the control input terminal of the control unit, wherein the output of the constant voltage circuit unit is connected to a power supply of the control apparatus. The switching circuit unit according to claim 1, wherein the switching circuit unit connects ANODE and CATHODE of the TRIAC composed of a three-terminal control element to the power source and the driving circuit unit to supply power to the driving circuit unit according to a control signal supplied to the control input terminal. Remote control driving device of the (cooling) heating apparatus comprising a. The control circuit of claim 1, wherein the power supply passage connected to the constant voltage circuit unit is normally supplied with a voltage stepped down by a resistor, and when the switching circuit unit is driven, the resistance is excluded and is directly connected to the power supply to stabilize the supply voltage. A remote control driving device for a (cooling) heating device, characterized in that it further comprises an automatic current switching circuit of means for sharing the load line with the power supply passage.