KR900004925Y1 - Temperature control circuit for airconditioner - Google Patents

Abstract

No content.

Description

Air temperature control circuit

The accompanying drawings are the thermostat control circuit of the present invention air conditioner.

* Explanation of symbols for main parts of the drawings

1: photodetector circuit 2: temperature control circuit at bedtime

3: Normal temperature control circuit 4: Output selection circuit

5: Relay drive circuit FAN: Fan

COMP: Compressor CP ₁ -CP ₃ : Comparator

Cds: Optical Sensor TH: Dummyster

VR ₁ , VR ₂ : Variable resistors ND ₁ -ND ₆ : NAND gate

I ₁ : Inverter TR ₁ -TR ₄ : Transistor

R ₁ -R ₁₀ : Resistor RL ₁ , RL ₂ : Relay

RL ₁₁ , RL ₁₂ : Relay switch RL ₁ , RL ₂ : Relay

The present invention relates to an automatic temperature control circuit of an air conditioner. Especially, when the compressor is driven at bedtime, the fan is driven only to automatically adjust the indoor temperature to a certain temperature, and then the compressor and the fan are changed when the indoor temperature is lower than the predetermined temperature. It relates to an automatic temperature control control circuit of an air conditioner which stops simultaneously.

In the conventional air conditioner, if the user simply sets the temperature to a comfortable temperature (X ⁺ -1 ° C) and then drives the air conditioner, the blower fan is always driven, and the compressor is repeatedly turned on and off. When the air conditioner is driven at bedtime, the blower fan continues to run, so oxygen deficiency phenomenon (the same phenomenon as the operation of the fan) occurs in the room, which not only impairs health but also increases unnecessary power consumption.

The present invention, in consideration of such a conventional defect, when the room temperature is more than a certain temperature when going to bed at the same time to operate the compressor and the fan at the same time to automatically adjust the room temperature to a certain temperature, and then to design the compressor and the fan at the same time. When described in detail with the accompanying drawings as follows.

1 is a circuit diagram of a thermostat control circuit of an air conditioner according to the present invention, and as shown therein, a connection point of a resistor (R ₁ ) (R ₂ ) and a connection point of a resistor (R ₃ ) and an optical sensor (Cds) are comparators (CP ₁ ). The photodetector circuit 1 is connected to the non-inverting (+) and inverting input terminals (-) of the photodetector circuit 1, and the output terminal of the comparator CP ₁ of the photodetector circuit 1 is a resistor R ₈ (R ₉ ). ) Are connected to the base of transistors TR ₁ and TR _2, respectively, and its collector and emitter are connected to the inverting input terminal (-) together with the variable resistor VR ₁ through a resistor R ₅ in common. R ₄ ) and the non-inverting input terminal (+) of the comparator CP ₂ to which the connection point of the dummyster TH is connected, and the output terminal of the comparator CP ₂ is connected to its non-inverting input terminal through R ₆ . The temperature control circuit 2 is connected to the positive terminal to form the temperature control circuit 2 at bedtime, and the connection point of the resistor R ₁₀ , the variable resistor VR ₂ , and the resistor R ₁₁ is connected to the inverting input terminal (−). R ₄ ) and dummy Connected to the non-inverting input terminal (+) of the comparator (CP _3), the connection point is connected to the H) and gwehan connected to its non-inverting input terminal (+) through An output terminal of the comparator (CP ₃₎ resistance (R ₁₂₎ The output terminal A of the photodetector circuit 1 is commonly connected to the input terminal of the NAND gate ND ₁ , and the output terminal of the usual temperature control circuit 3 is configured. (C) is connected to an input terminal of the NAND gate ND ₂ , and an output terminal of the NAND gate ND ₁ is an output terminal B of the temperature control circuit 2 at the time of going to sleep through the inverter I ₁ . And a common connection to the input terminal of the NAND gate ND ₆ through the NAND gate ND ₄ , and the output terminal of the NAND gate ND ₂ through the NAND gate ND ₃ at the time of sleep. ) output terminal (B) constituting the common connection to the output selection circuit 4 to the input terminal of the NAND gate (ND ₅₎ with, and the output of The output of the selection circuit 4, the terminal (D), (E) is a resistance (R ₁₃₎ via each an (R ₁₅₎ resistance (R ₁₄₎ (R ₁₆₎ and a transistor (TR ₃₎ connected to the base of (TR ₄₎ And the collectors of transistors TR ₃ and TR ₄ are connected in parallel to the diodes D ₁ , D ₂ and relays RL ₁ , RL ₂ to form a relay drive circuit 5, and relay RL _1. ) (switch of _{RL 2) (RL 11) (} RL 12) is to be configured by each connected to with the AC power source (AC) fan (fAN) and the compressor (COMP), the switch (RL ₁₁₎ is a relay (RL ₁ ) Is open when driven, the switch RL ₁₂ is short-circuited when the relay RL ₂ is driven, and reference numeral Vcc is a power supply terminal.

Referring to the effect of the present invention configured in this way in detail as follows.

In the state where AC power is applied and power is applied to the power supply terminal Vcc, the resistance value of the optical sensor Cds of the photodetector circuit 1 is kept low when there is light normally. Therefore, the output terminal of the comparator CP ₁ is divided by the resistor R ₃ and the optical sensor Cds and maintained lower than the reference voltage VA applied to the non-inverting input terminal (+). A high potential signal is output to an output terminal A of the photodetector circuit 1, and the high potential signal is input to one of the NAND gates ND ₁ and ND ₂ of the output selector circuit 4. Is applied to the base of the transistors TR ₁ and TR ₂ of the temperature control circuit 2 at the time of sleep, and the transistors TR ₁ and TR ₂ are turned off and on, respectively. It is divided by the resistor R ₅ and the variable resistor VR ₁ through the transistor TR ₂ , and the non-inverting of the comparator CP ₂ is applied to the reference voltage VD. It is applied to the input terminal (+).

Wherein the initially at room temperature to drive the air conditioning is above a predetermined temperature to more Mr (TH) resistance (R _4), and more Mr (TH) to maintain the low resistance state of the bed when the temperature control circuit (2) Divided by and applied to the inverting input terminal (-) of the comparator CP ₂ (CP ₃ ) as the comparison voltage VD, so that the comparator CP ₂ (CP ₃ ) is applied to its non-inverting input terminal (+). The output terminal B of the comparator CP ₂ (CP ₃ ), that is, the temperature control circuit 2 at bedtime and the normal temperature control circuit 3, is kept lower than the voltage VD VE. A high potential signal is output to (C).

That is, since the high potential signal is output to the output terminals (A) (B) (C) of the photodetector circuit 1, the bedtime and the usual temperature control circuits 2, 3, the photodetector circuit 1 And each of the high potential signals output to the output terminals (A) and (B) of the temperature control circuit 2 at the time of sleep is a low potential signal through the NAND gates ND ₁ and ND ₃ of the output selection circuit 4, respectively. Is output to NAND gate (ND ₄ ) (ND ₅ ) and the other input terminal, respectively, so high potential signal is output to NAND gate (ND ₄ ) (ND ₅ ) output terminal regardless of the other input signal. The high potential signal is output to the output terminal E of the NAND gate ND ₅ , that is, the output terminal E of the output selection circuit 4, thereby turning on the transistor TR ₄ of the relay driving circuit 5. Since the relay RL ₂ is driven and the switch RL ₁₂ is short-circuited, the AC power is applied to the compressor COMP to drive the compressor COMP. One, a high potential signal output to an output terminal of the NAND gate (ND ₄₎ is outputted as a low-potential signal to the output terminal (D) of the selected output via NAND gates (ND ₆₎ circuit 4, a relay driver circuit ( Since the transistor TR ₃ of 5) is turned off, the relay RL ₁ is not driven so that its switch RL ₁₁ is short-circuited, whereby the AC power AC is applied to the fan FAN so that the fan FAN Driven.

In this state, that is, when the compressor temperature and the fan are driven and the room temperature is lower than the predetermined temperature, the resistance value of the dummyster TH of the temperature control circuit 2 is kept high at bedtime. Thus, the comparison voltage Vc applied to the inverting input terminal (-) (-) of the comparator CP ₂ (CP ₃ ) and divided into the resistor R4 and the dummyster TH is a non-inverting input terminal (+). The low potential signal is output to the output terminals (B) and (C) of the temperature control circuit (2) and (3) at bedtime and in normal state by maintaining the state higher than the reference voltage (VD) (VE) applied to (+), The low potential signal output from the output terminal C of the usual temperature control circuit 3 is applied to the other input terminal of the NAND gate ND _{2 so} that a high potential signal is output regardless of the one input signal thereof. above signal is applied to one side input terminal of the NAND gate (ND ₅₎ via a NAND gate is applied to its other input terminal (ND ₃₎ Since the low potential signal is output to the output terminal of the NAND gate ND ₅ together with the high potential signal, the transistor TR ₃ of the relay driving circuit 5 is turned off, thereby driving the relay RL ₂ to stop. switch (RL ₁₂₎ is opened, so while the drive of the compressor (COMP) stops, so that the NAND gate (ND ₄₎ a low potential signal through the NAND gate (ND ₄₎ to one side input terminal of is applied to its other input signal Regardless, a high potential signal is output to its output terminal, and the output high potential signal is output as a low potential signal to the output terminal D of the output selection circuit 4 through the NAND gate ND ₆ . Since the transistor TR ₃ of the relay driving circuit 5 is turned off as described above by the output high potential signal and the relay RL ₁ is not driven, the switch RL ₁₁ is shorted and the fan FAN continues to be driven. Will be.

That is, when there is light in the room, the fan FAN is always driven by the output signal of the photodetector circuit 1, and the compressor COMP is always at the output signal of the temperature control circuit 3, that is, at room temperature. Therefore, the operation is the same as the conventional air conditioner is stopped and stopped. At the time of sleep, that is, when there is no light, the resistance value of the optical sensor Cds of the photodetector circuit 1 is maintained at a high state, so that the resistance is divided by the resistor R ₃ and the optical sensor Cds and divided into comparators ( The comparison voltage VB applied to the inverting input terminal (-) of CP ₁ ) is divided by the resistor R ₁ (R ₂ ) and is higher than the reference voltage VA applied to its non-inverting input terminal (+). The state is maintained and a low potential signal is output to the comparator CP ₁ output terminal, that is, the output terminal A of the photodetector circuit 1, and the low potential signal is the NAND gate ND of the output selection circuit 4. ₁ ) (ND ₂ ) is commonly applied to the input terminal and one input terminal, and is applied to the base of the transistors TR ₁ and TR ₂ of the temperature control circuit 2 at the time of sleep, so that the transistors TR ₁ and TR ₂ are It is divided by the respective on and off and therefore the power source of the power supply terminal (Vcc) via a resistor (R ₇₎ and a transistor (TR ₁₎ resistance (R ₅₎ and variable resistor (VR ₁₎ based on It is applied to the non-inverting input terminal (+) of the comparator (CP ₂₎ to the pressure (VD).

Here, at the time of bedtime driving the air conditioner, the room temperature becomes a predetermined temperature or more, so that the resistance value of the dummyster TH of the temperature control circuit 2 at the time of bedtime is kept low so that the resistance R ₄ and the dummyster ( Is divided by TH) and applied to the inverting input terminal (-) of the comparator CP ₂ (CP ₃ ) as the comparison voltage VD, so that the comparator CP ₂ (CP ₃ ) is connected to its non-inverting input terminal (+). The output terminal of the comparator CP ₂ (CP ₃ ), that is, the output terminal of the temperature control circuit 2 at the time of sleep and the temperature control circuit 3 at ordinary times, is kept lower than the applied reference voltage VD VE. A high potential signal is output to (B) (C).

That is, a low potential signal is output to the output terminal A of the photodetector circuit 1, and a high potential signal is output to the output terminals B and C of the temperature control circuit 2 and 3 at bedtime and everyday. Since the low and high potential signals are output to the output terminals A and B of the photodetector circuit 1 and the temperature control circuit 2 at bedtime, the NAND gates of the output selection circuit 4 the ND ₁₎ (ND ₃₎ to the high potential, and is output to the low-potential signal of NAND gate (ND ₄₎ (ND ₅₎ since one side and the other side input refurbished input each of NAND gates (ND ₅₎ has its other input signal through each Regardless, the high potential signal is outputted to the output terminal, and the high potential signal is outputted to the output terminal E of the NAND gate ND ₅ , that is, the output terminal E of the output selection circuit 4. The transistor TR ₄ is turned on, and accordingly, the relay RL ₂ is driven so that its switch RL ₁₂ is short-circuited so that the AC power source AC is supplied to the compressor COMP. In addition, the compressor COMP is driven and the other input terminal of the NAND gate ND ₄ has a high potential signal output from the output terminal B of the temperature control circuit 2 at the time of sleep. ₁ ) is inverted into a low potential signal through ₁ ), so that a high potential signal is output to the output terminal of the NAND gate ND ₄ regardless of one input signal thereof, and the high potential signal is output through the NAND gate ND ₆ . Since the transistor TR ₃ of the relay driving circuit 5 is turned off as a low potential signal to the output terminal D of the selection circuit 4, the relay RL ₁ is not driven and its switch RL ₁ is short-circuited. Accordingly, the AC power source AC is applied to the fan FAN to drive the fan FAN.

In this state, that is, when the compressor (COMP) and the fan (FAN) is driven to go to room temperature or less at bedtime, the resistance value of the dummy (TH) of the temperature control circuit (2) during the bedtime is maintained to be high The comparison voltage VC applied to the inverting input terminal (-) (-) of the comparator CP ₂ (CP ₃ ) by splitting the resistor R ₄ and the dummyster TH is a non-inverting input terminal (+) thereof. The low potential signal is output to the output terminals (B) and (C) of the temperature control circuit (2) and (3) at bedtime and in normal state by maintaining the state higher than the reference voltage (VD) (VD) applied to (+), The NAND gate ND ₅ outputting the low potential signal output from the output terminals A and C of the photodetector circuit 1 and the temperature control circuit 3 as a high potential signal through the NAND gate ND ₂ . ), the low potential signal through the NAND gate (ND ₅₎ with the high potential signal through the NAND gate (ND ₃₎ is applied to one input terminal being applied to its other input terminal of the On the other hand, because the output transistor (TR ₃₎ of a relay driver circuit (5) is turned off, so that that the drive of the relays, the drive of the (RL ₂₎ is stopped, so that its switch (RL12) opening the compressor (COMP) stops, the NAND gate (ND _4), so that a high potential signal is applied through the NAND gate (ND ₁₎ to one side input terminal of the NAND gate with a high potential signal by the inverter (I ₁₎ is applied to its other input terminal (ND ₄ Is output as a low potential signal, and the output low potential signal is output as a high potential signal to the output terminal D of the output selection circuit 4 through the NAND gate ND ₆ , and to the low potential signal. As a result, the transistor TR ₃ of the relay driving circuit 5 is turned on in the opposite direction and the relay RL ₁ is driven so that the switch RL ₁₁ is opened so that the AC power AC is not applied to the fan FAN. The driving of the fan FAN is stopped. That is, when there is no light in the room at bedtime, the compressor (COMP) and the fan (FAN) are simultaneously operated by the output signal of the photodetector circuit 1 and the output signals of the bedtime and usual temperature control circuits (2) (3). Drive and stop.

As described above, the present invention operates the fan only when the compressor is driven at bedtime, and automatically adjusts the room temperature to a predetermined temperature, and when the temperature is lower than the predetermined temperature, the compressor and the fan are controlled to be stopped at the same time. By eliminating the oxygen shortage phenomenon, it is possible not only to realize healthy cooling but also to prevent unnecessary power consumption.

Claims (1)

A photodetector circuit is connected by connecting the connection point of the resistors R ₁ and R ₂ and the connection point of the resistor R ₃ and the optical sensor Cds to the non-inverting (+) and inverting input terminals (-) of the comparator CP ₁ . (1), the output terminal side of the comparator CP ₁ of the photodetector circuit 1 is connected to the base side of the transistors TR ₁ (TR ₂ ), and the collector and emitter side thereof have a common resistance (R). ₅ ) is connected to the non-inverting input terminal (+) of the comparator (CP ₂ ) to which the connection point of the resistor (R ₄ ) and the dummyster (TH) is connected to the inverting input terminal (-) together with the variable resistor (VR ₁ ). The output terminal of the comparator CP ₂ is feedback-connected to its non-inverting input terminal (+) through the resistor R ₆ to form a temperature control circuit 2 at bedtime, and includes a resistor R ₁₀ and a variable resistor ( The connection point of VR ₂ ) and the resistor R ₁₁ is connected to the non-inverting input terminal (+) of the comparator CP ₃ to which the connection point of the resistor R ₄ and the dummyster TH is connected to the inverting input terminal (−). An output terminal of the comparator and connected (CP ₃₎ An output terminal (A) of the section (R _12), its non-inverting input terminal (+) feedback connected to a constant temperature control circuit 3, the configuration, and a to said optical detection - taking (1) in through the NAND gate (ND ₁₎ The common terminal is connected to the input terminal of the NAND gate ND ₂ together with the output terminal C of the usual temperature control circuit 3, and the output terminal of the NAND gate ND ₁ is connected to an inverter ( I ₁ ) is commonly connected to the input terminal of the NAND gate ND ₆ through the NAND gate ND ₄ together with the output terminal B of the temperature control circuit 2 through the bedtime, and the NAND gate ND _2. ) Is connected to the input terminal of the NAND gate ND ₅ together with the output terminal B of the temperature control circuit 2 through the NAND gate ND ₃ to form the output selection circuit 4. and the output side of the output terminal (D) (E) of the selection circuit 4, the transistor (TR ₃₎ connected to the base side of the (TR ₄₎ and a transistor (TR ₃₎ (TR ₄ ), The collector side is connected to the relay RL ₁ (RL ₂ ) to configure the relay drive circuit 5, and the switches RL ₁₁ (RL ₁₂ ) of the relay RL ₁ (RL ₂ ) are AC power (AC). ) And a fan and compressor (COMP) respectively connected to the configuration of the automatic temperature control circuit of the air conditioner.