KR19980084647A - Temperature control device of air conditioner and its method - Google Patents

Abstract

According to an aspect of the present invention, there is provided an apparatus and method for controlling a temperature of an air conditioner, wherein the indoor unit heat-exchanges indoor air sucked through an inlet and discharges it through a discharge port. The indoor temperature is measured by calculating the average value of the temperature of each of the plurality of temperature data transmitting unit for transmitting the indoor unit, and the temperature of each part of the room transmitted by the plurality of temperature data transmitting unit, the compressor according to the difference between the measured room temperature and the set temperature Control means for controlling the, the temperature distribution of the entire room can be kept constant at a temperature set by the user.

Description

Temperature control device of air conditioner and its method

The present invention relates to a temperature control apparatus and method for an air conditioner for receiving temperature data of each part of a room and maintaining a constant temperature distribution of the entire room.

In general, an air conditioner includes a heating device that warms indoor cold air and supplies it to a room, and a cooling device that supplies cold indoor hot air to a room.

In addition, there is also a cooling and heating device that combines the cooling function and the heating function, a situation that includes a clean function for cleaning the contaminated indoor air.

1 shows an indoor unit of an air conditioner (commonly referred to as an air conditioner) that functions as an air conditioner among the above air conditioners.

Of course, the air-conditioning device of course includes an outdoor unit not shown.

As shown in FIG. 1, reference numeral 1 denotes an indoor main body (hereinafter, referred to as an indoor unit) of an air conditioner, and an intake port 3 for sucking indoor air is formed on the front of the indoor unit 1, In the lower part of the front surface of the indoor unit 1, a discharge port 5 for discharging air (cold or warm air) heat-exchanged by a heat exchanger described later is formed.

In addition, a remote control receiver 7 for receiving a remote control signal transmitted from a remote controller 9 (hereinafter referred to as a remote controller) is provided on the right side of the discharge port 5, and the discharge port 5 is provided with the discharge port 5. Wind vane 11 for adjusting the direction of the air discharged into the room through the up and down is installed.

On the other hand, the remote control unit 9 has an operation mode (automatic, cooling, dehumidification, blowing, etc.) of the air conditioner desired by the user, start / stop of operation, set temperature, air volume of the air discharged through the discharge port 5, and A plurality of function keys are provided to input the wind direction and the like.

FIG. 2 is a side cross-sectional view of the indoor unit of FIG. 1 in a state where the indoor unit is installed on a wall, and the same parts as in FIG.

As shown in FIG. 2, the inside of the indoor unit 1 has a straight shape at the rear side of the intake port 3 so as to heat-exchange the indoor air sucked through the intake port 3 to cold or warm air by the latent heat of evaporation of the refrigerant. A heat exchanger (13) is provided, and at the lower rear side of the heat exchanger (13), the indoor air is sucked through the suction port (3) and the air heat exchanged in the heat exchanger (13) is discharged (5). An indoor fan 15 for discharging into the room is installed.

In addition, a duct member 17 is installed inside the indoor unit 1 to guide the flow of air sucked through the suction port 3 and discharged to the discharge port 5.

In the air conditioner configured as described above, when the user operates the remote controller 9 to input the desired operation mode and the set temperature, and then turns on the operation / stop key (hereinafter referred to as the operation key), the indoor fan 15 is driven. The indoor air starts to be sucked into the indoor unit 1 through the suction port 3 according to this.

At this time, by detecting the temperature of the indoor air sucked through the suction port (3) and compares with the set temperature, and determines the rotational frequency of the compressor according to the difference between the set temperature and the room temperature to drive the compressor.

When the compressor is driven, the heat exchanger 13 is heat-exchanged in accordance with the circulation of the refrigerant, so that the indoor air sucked into the indoor unit 1 is passed by the heat exchanger 13 by the latent heat of evaporation of the refrigerant flowing in the heat exchanger 13. The air is discharged through the discharge port 5 while being guided by the duct member 17 while being heat-exchanged with cold or warm air, and the air direction is controlled according to the wind direction angle of the wind vane 11. Air conditioning operation is performed.

However, in the conventional air conditioner configured as described above, since only the temperature of the indoor air sucked through the inlet port 3 is detected by using the temperature sensor mounted on the indoor unit 1, the room temperature of the entire room cannot be accurately detected. There is a problem in that the indoor temperature distribution cannot be kept constant because the driving of the compressor is controlled by comparing the room temperature and the set temperature of a part of the room detected only with the temperature sensor mounted on the indoor unit 1.

Therefore, the present invention has been made to solve the above problems, and after mounting a plurality of temperature sensors in each part of the room to detect the temperature of each part of the room, and transmits the temperature data wirelessly to the indoor unit, this transmission in the indoor unit Temperature control device and method for air conditioner that can keep indoor temperature distribution constant by user's set temperature by accurately measuring indoor room temperature by taking average value of data and precise temperature control To provide.

In order to achieve the above object, the temperature controller of an air conditioner according to the present invention includes a plurality of indoor units installed in a predetermined position of an indoor unit in which an indoor unit is installed to heat the indoor air sucked through an inlet and discharged through an outlet. A plurality of temperature data transmitters for sensing the temperature of each part and transmitting the same to the receiver of the indoor unit, and calculating the average value of the temperature of each part of the room transmitted by the plurality of temperature data transmitters to measure the indoor temperature, measured indoor Characterized in that the control means for controlling the compressor in accordance with the difference between the temperature and the set temperature.

In addition, the temperature control method of the air conditioner according to the present invention comprises a temperature input step of inputting a desired set temperature in a control method of the air conditioner for heat-exchanging the indoor air sucked through the inlet port to discharge through the outlet A temperature sensing step of sensing a temperature of each part of the indoor unit in which the indoor unit is installed, an average temperature calculating step of calculating an average value of the temperatures of each part of the room detected by the temperature sensing system, an average indoor temperature calculated from the temperature calculating step, and Compressor control step for controlling the compressor by performing fuzzy inference according to the difference of the set temperature input in the temperature input step, and by discharging the heat-exchanged air in the room in accordance with the operation of the compressor controlled in the compressor control step to indoor air conditioning Characterized in that consisting of the air conditioning operation step to perform.

1 is a perspective view showing an indoor unit of a general air conditioner,

2 is a side cross-sectional view of the indoor unit of FIG.

3 is a mounting structure diagram of a wireless temperature sensor applied to the present invention,

4 is a control block diagram of a temperature control device of an air conditioner according to an embodiment of the present invention;

5A and 5B are flowcharts showing a temperature control operation procedure of the air conditioner according to the present invention;

6 is a diagram showing a compressor operating frequency adjustment by the fuzzy inference of the present invention.

* Description of the symbols for the main parts of the drawings *

3: inlet port 5: discharge port

9: remote control 11: wind vane

13: heat exchanger 15: indoor fan

20: first temperature data transmitter 30: second temperature data transmitter

40: third temperature data transmitter 50: fourth temperature data transmitter

60: fifth temperature data transmitter 100: power supply means

102: remote control signal receiving means 104: control means

106: room temperature sensing means 110: compressor driving means

112: wind direction control means 114: fan motor driving means

116 display means

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

Fig. 3 is a structure diagram of the temperature data transmission unit to be applied to the present invention, and the same reference numerals and the same reference numerals will be used to designate the same parts as in the conventional construction, and redundant description thereof will be omitted.

As shown in FIG. 3, a plurality of temperature data transmitters 20, 30, 40, 50, and 60 detect the temperature of each part of the room and transmit it to the indoor unit 1 at the wall and the ceiling middle part of each room. The plurality of temperature data transmitters 20, 30, 40, 50, and 60 are each provided at a predetermined position in the room.

As shown in Fig. 4, the power supply means 100 converts a commercial AC voltage supplied from an AC power supply terminal (not shown) into a predetermined DC voltage required for the operation of the air conditioner, and outputs the remote control signal receiving means ( 102 is an infrared light transmitted from the remote controller 9 according to a key operation of the remote controller 9 for inputting a desired operation mode (automatic, cooling, dehumidification, blowing, etc.), a set temperature (Ts), a set wind direction, and the like. An optical receiver for receiving a signal.

And, the control means 104 is applied to the DC voltage output from the power supply means 100 to initialize the air conditioner, as well as the user according to the infrared light signal received by the remote control signal receiving means 102 A microcomputer that controls the overall operation of the air conditioner by judging the selected operating condition, wherein the control means 104 is a part of the room sensed by the plurality of temperature data transmitters 20, 30, 40, 50 and 60. Accurately measure the room temperature (Tr) throughout the room by calculating the average temperature.

The indoor temperature detecting means 106 detects the temperature of each part of the room to detect the room temperature (Tr) of the entire room, and the indoor temperature detecting means 106 detects the temperature of each corner of the room and displays the temperature of the indoor unit. First to fourth temperature data transmitters 20, 30, 40 and 50 for transmitting to a receiver installed at a predetermined position, and fifth temperature data for detecting the temperature of the indoor ceiling and transmitting it to a receiver installed at a predetermined position of the indoor unit. The transmitter 60 is comprised.

In addition, the first to fifth temperature data transmitters 20, 30, 40, 50, and 60 are temperature sensors 21, 31, 41, respectively, for sensing the temperature (Tr1 to Tr5) of the indoor air of each part of the attached room. 51, 61, and the A / D converter 23 for receiving analog data of the room temperature Tr1 to Tr5 detected by the temperature sensors 21, 31, 41, 51, and 61 and converting them to digital, respectively. And 33,43,53,63 and the temperature of each part of the room converted into digital by the A / D converters 23,33,43,53,63 to the indoor unit 1, respectively. Data transmitter 25, 35, 45, 55 for receiving a signal for requesting the temperature data transmission of each part of the room from the indoor unit (1) to the first to fifth temperature data transmitter (20, 30, 40, 50, 60) And 65).

In addition, the compressor driving means 110 is determined according to the difference between the temperature Ts set by the user by the remote controller 9 and the room temperature Tr of the entire room detected by the room temperature sensing means 106. Receiving a control signal output from the control means 104 drive control the compressor 111, the wind direction adjusting means 112 is discharged through the discharge port 5 in accordance with the wind direction set by the user by the remote control (9) The wind vane 11 is moved by driving the wind vane motor 113 by receiving a control signal output from the control unit 104 to adjust the direction of the air.

The fan motor driving means 114 inputs a control signal output from the control means 104 to adjust the wind speed of the air discharged through the discharge port 5 according to the air volume set by the user by the remote controller 9. The indoor fan motor 115 to control the rotation speed of the indoor fan 15 to adjust the air volume, and the display means 116 is the operating mode (automatic, cooling, dehumidification, blowing, Heating and the like) and the set temperature Ts, as well as the operation state of the air conditioner.

Hereinafter, the effect of the temperature control device and the method of the air conditioner configured as described above will be described.

5A and 5B are flow charts showing the temperature control operation procedure of the air conditioner according to the present invention, in which S denotes a step (STEP).

First, when power is applied to the air conditioner, the power supply means 100 converts a commercial AC voltage supplied from an AC power terminal (not shown) into a predetermined DC voltage required for driving the air conditioner, thereby driving each circuit and control means ( Output to 104).

Therefore, in step S1, the DC voltage output from the power supply means 100 is input from the control means 104 to initialize the air conditioner.

At this time, in step S2, the user operates the remote controller 9 to input the operation mode (for example, cooling), the set temperature Ts, and the set air volume of the desired air conditioner, and then press the operation key. In the present invention, a remote control signal corresponding to a key input is encoded by a predetermined protocol, and the encoded signal is modulated and transmitted as an infrared light signal.

When the infrared light signal is generated in the remote control unit 9, the remote control signal receiving unit 102 receives it and converts it into an electric signal, and demodulates the converted electric signal to drive an operation selection signal and an operation start signal (hereinafter, referred to as a driving signal). The control unit 104).

Accordingly, in step S3, the control means 104 determines whether the driving signal is input from the remote control signal receiving means 102, and when the driving signal is not input (NO), the air conditioner is placed in the operating standby state. The operation of step S3 or less is repeated while holding.

As a result of the discrimination in step S3, when the operation signal is input (YES), the control means 104 controls to drive the indoor fan 15 to proceed to step S4 to perform the cooling operation of the air conditioner. The signal is output to the fan motor driving means 114.

Therefore, the fan motor driving means 114 drives the indoor fan 15 by controlling the rotation speed of the indoor fan motor 115 according to the set air volume.

Subsequently, in step S5, a signal for requesting data transmission is transmitted from the indoor unit 1 to the first temperature data transmitter 20 to measure the temperature of each part of the room. In step S6, the first temperature data transmitter 20 Receiving the data transmission request signal transmitted from the indoor unit 1 through the data transmission and reception unit 25 and detects the indoor air temperature (Tr1) of the corner where the first temperature data transmission unit 20 is attached by the temperature sensor 21 The analog data of the first room temperature Tr1 sensed by the temperature sensor 21 is input from the A / D converter 23 and converted into digital.

Accordingly, in step S7, the first room temperature data Tr1 converted into digital by the A / D conversion unit 23 is transmitted to the indoor unit 1 through the data transmission / reception unit 25, and in step S8 the indoor unit. In (1), a signal for requesting data transmission is transmitted to the second temperature data transmitter 30.

Therefore, in step S9, the second temperature data transmitter 30 receives the data transmission request signal transmitted from the indoor unit 1 through the data transmitter 35 and the room of the corner where the first temperature data transmitter 30 is attached. When the air temperature Tr2 is detected by the temperature sensor 31, the analog data of the second room temperature Tr2 detected by the temperature sensor 31 is input from the A / D converter 33 and then digitally received. In step S10, the second room temperature data Tr2, which is digitally converted by the A / D converter 23, is transmitted to the indoor unit 1 through the data transmitter / receiver 25.

Subsequently, in step S11, the indoor unit 1 transmits a signal for requesting data transmission to the third temperature data transmitter 40, and in step S12, the third temperature data transmitter 40 transmits the data transmitted from the indoor unit 1; When the request signal is received through the data transmitter / receiver 45 and the indoor air temperature Tr3 of the corner where the third temperature data transmitter 40 is attached is detected by the temperature sensor 41, the temperature sensor 41 detects the request. The analog data of the sensed third room temperature Tr4 is received by the A / D converter 43 and converted into digital.

Therefore, in step S13, the third room temperature data Tr3 converted into digital by the A / D conversion unit 43 is transmitted to the indoor unit 1 through the data transmission / reception unit 45, and in step S14 the indoor unit ( In 1), a signal for requesting data transmission is transmitted to the fourth temperature data transmitter 50.

Accordingly, in step S15, the fourth temperature data transmitter 50 receives the data transmission request signal transmitted from the indoor unit 1 through the data transmitter 55, so that the fourth temperature data transmitter 50 is located at the corner where the fourth temperature data transmitter 50 is attached. When the indoor air temperature Tr4 is sensed by the temperature sensor 51, the analog data of the fourth room temperature Tr4 sensed by the temperature sensor 51 is input from the A / D converter 53 and then digitally received. Convert to

Subsequently, in step S16, the fourth indoor temperature data Tr4, which is converted into digital by the A / D conversion unit 53, is transmitted to the indoor unit 1 through the data transmission / reception unit 55, and in step S17 the indoor unit ( In 1), the fifth temperature data transmitter 60 transmits a signal for requesting data transmission.

Therefore, in step S18, the fifth temperature data transmitter 60 receives the data transmission request signal transmitted from the indoor unit 1 through the data transmitter 65 and the room of the corner where the fifth temperature data transmitter 60 is attached. When the air temperature Tr5 is sensed by the temperature sensor 61, the analog data of the fifth room temperature Tr5 detected by the temperature sensor 61 is input from the A / D converter 63 and then digitally received. To convert.

Accordingly, in step S19, the fifth indoor temperature data Tr5, which is converted into digital by the A / D conversion unit 63, is transmitted to the indoor unit 1 through the data transmission / reception unit 65, and in step S20 the indoor unit. The control means 104 calculates an average value Tr of the first to fifth indoor temperature data Tr1 to Tr5 transmitted to (1).

Therefore, in step S21, the control means 104 determines whether the temperature Ts set by the user is smaller than the room temperature Tr of the whole room calculated as an average value, and the set temperature Ts is the average room temperature Tr. If not smaller (NO), the flow returns to step S20 to repeat the operation of step S20 and below.

As a result of the discrimination in step S21, when the set temperature Ts is smaller than the average room temperature Tr (YES), the process proceeds to step S22 to perform fuzzy inference.

As shown in Fig. 6, the fuzzy inference is a temperature difference E representing the difference between the set temperature Ts and the average room temperature Tr, and the amount of change {E (t) of the temperature difference E changing at 40 second intervals. -E (t-1)}, the lowest operating frequency of the compressor 111 is inferred by using the temperature change amount? E as an input variable.

That is, when the temperature difference E is -3 ° C and the temperature change amount △ is -0.1, the operating frequency of the compressor 111 initially set is increased according to the difference between the room temperature Tr and the set temperature Ts, and the temperature difference When (E) is + 3 ° C. and the temperature change amount ΔE is +0.1, the capacity of the compressor is varied while decreasing the operating frequency of the compressor 111 set accordingly.

Therefore, in step S23, the control signal for driving the compressor 111 at the operating frequency of the compressor 111 determined by performing the above perch inference is output to the compressor driving means 110.

Accordingly, the compressor driving means 110 drives the compressor 111 according to the operating frequency determined by the control means 104.

When the compressor 111 is driven, the indoor fan 15 is driven into the indoor unit 1 through the suction port 3 while the indoor fan 15 is driven, and the indoor air sucked through the suction port 3 exchanges heat. Heat is exchanged by cold air by the latent heat of evaporation of the refrigerant flowing in the base 13.

The air heat-exchanged by the cold air in the heat exchanger 13 is moved upward to adjust the wind direction up and down according to the wind direction angle of the wind vane 11 rotatably installed in the discharge port 5 to terminate the operation while performing indoor cooling. .

According to the temperature control apparatus and method of the air conditioner according to the present invention as described above, after mounting a plurality of temperature sensors in each part of the room to sense the temperature of each part of the room, the temperature data is wirelessly transmitted to the indoor unit. Since the indoor unit takes the average of the transmitted data and judges the room temperature, it accurately detects the room temperature of the entire room and enables accurate temperature control. Therefore, the indoor unit can maintain the room temperature distribution at the temperature set by the user. .

Claims (4)

In the indoor unit to discharge the indoor air sucked through the suction port to discharge through the discharge port, The indoor temperature is calculated by detecting a temperature of each part of the indoor unit in which the indoor unit is installed and calculating an average value of the temperature of each part of the room transmitted by the plurality of temperature data transmitters. And a control means for measuring and controlling the compressor according to the difference between the measured room temperature and the set temperature. The method of claim 1, The temperature data transmitting unit includes a temperature sensor for detecting a room temperature of a predetermined part of the room, an A / D converter for converting analog data of the room temperature detected by the temperature sensor into digital, and a digital by the A / D converter. And a data transmitter for transmitting the temperature of each part of the room converted to the indoor unit. In the control method of the air conditioner to heat the indoor air sucked through the suction port to discharge through the discharge port, A temperature input step of inputting a desired set temperature by the user; A temperature sensing step of sensing the temperature of each part of the room where the indoor unit is installed; An average temperature calculation step of calculating an average value of the temperatures of each part of the room sensed by the temperature sensing system; A compressor control step of controlling the compressor by performing fuzzy inference according to the difference between the average indoor temperature calculated in the temperature calculating step and the set temperature input in the temperature input step; And an air conditioning operation step of performing indoor air conditioning by discharging the heat-exchanged air into the room according to the operation of the compressor controlled by the compressor control step. The method of claim 3, And the compressor control step performs fuzzy inference according to the difference between the average indoor temperature and the set temperature.