KR100358100B1 - auto-controlling method of an air-conditioner - Google Patents

Abstract

Disclosed is an automatic operation control method of an air conditioner, which has a function of rapidity of rapidly reaching an indoor temperature and reaches a target temperature, and at the same time satisfies the comfort function of maintaining an appropriate cooling temperature. This control method compares the room temperature with the target temperature and operates the blowing fan at the first air volume when the room temperature is higher than the target temperature. The blowing fan is operated at each of the flow rates while gradually increasing the flow rate until the first flow rate reaches the second flow rate, and the blowing fan is operated at the second flow rate until the room temperature reaches the target temperature. If the indoor temperature is not higher than the target temperature during operation at each air flow rate, the operation is switched to natural wind operation. The first air volume is the minimum air volume with the shortest refrigerant stabilization time, and the second air volume is set with the maximum air volume. Since the blower fan is initially operated with the minimum air flow rate, the coolant temperature stabilization time is the shortest, and the coolant temperature is the lowest, so that a rapid cooling effect can be obtained. By operating the blower fan while increasing the airflow step by step, it is possible to prevent the refrigerant from becoming unstable. Thereafter, the blowing fan is continuously operated until the indoor temperature reaches the target temperature at the maximum amount of air flow, so that the effect of cooling to the desired target temperature can be quickly obtained.

Description

{Auto-controlling method of an air-conditioner}

The present invention relates to an operation control method of an air conditioner, and more particularly, to an automatic operation control method of an air conditioner that automatically controls an indoor temperature and an indoor air volume.

In general, an air conditioner is a device for keeping indoor air in a comfortable state, and is often called an air conditioner or an air conditioner. Such an air conditioner has a function of controlling temperature, humidity, and air flow distribution suitable for human activity in a certain space, and at the same time removing dust in the air. On the other hand, comfortable indoor temperature is based on human sense, and the standard is different for each individual, but in summer, the temperature difference between outside and indoor is 5 ~ 6 ℃, and the room temperature is 25 ~ 29 ℃ and humidity is about 60 ~ 70%. In winter, the room temperature is known to be 18 ~ 21 ℃, humidity is about 55 ~ 70% is preferred.

1 is a block diagram showing the basic structure of the air conditioner as described above. Here, reference numeral 10 is an indoor unit, 11 is an indoor heat exchanger, 12 is a blowing fan, 20 is an outdoor unit, 21 is a compressor, 22 is an outdoor heat exchanger, 23 is a cooling fan, 24 is a capillary tube, 30 is a control unit, 32 is an operation mode. The setting unit 34 is a temperature setting unit and 36 is an indoor temperature detecting unit.

The controller 30 controls driving states of the compressor 21, the blowing fan 12, the cooling fan 23, and the like. That is, when the compressor 21 is operated by the control unit 30, the compressor 21 compresses the refrigerant at room temperature to high temperature and high pressure. In addition, the compressed refrigerant is introduced into the outdoor heat exchanger 22 and heat exchanged with the outdoor air blown from the cooling fan 23 to release heat contained in the refrigerant to the outside. As such, the low-temperature and high-pressure liquid refrigerant heat-exchanged through the outdoor heat exchanger 22 is reduced in pressure through the capillary tube 24 and flows into the indoor heat exchanger 11 in a low-temperature and low-pressure state. The refrigerant in the indoor heat exchanger (11) exchanges heat with the indoor air blown from the blower fan (12), absorbs the heat of the indoor air, and converts it to room temperature. Therefore, the room is cooled because the cool wind blows heat to the refrigerant is blown indoors.

Such a conventional air conditioner executes a cooling operation while controlling the air volume and temperature automatically or manually. In the automatic operation mode, the target temperature Ts is automatically set to 24 deg. C, and the air volume is controlled by natural wind. The target temperature Ts is normally set automatically, but if a change is desired, the target temperature Ts may be varied within a range of ± 2 ° C. at an automatically set temperature through the temperature setting unit 34.

I will briefly explain natural wind control. The controller 30 determines a temperature difference (ΔT = Tr-Ts) between the target temperature Ts and the room temperature Tr, and controls the rotational speed of the blower fan 12 between the strong wind and the breeze according to the size of ΔT. Control to change automatically. The larger the ΔT, the greater the air volume by operating the rotational speed of the blower fan 12, and the smaller the ΔT, the lower the airflow rate by operating the smaller rotational speed of the blower fan 12. Here, the rotational speed of the blowing fan 12 may be determined to be variable in proportion to the temperature difference ΔT between the maximum strong wind and the minimum low wind. For example, when △ T is 2 ℃ or higher (indoor temperature is 2 ℃ higher than target temperature), it is operated with maximum strong wind, and when △ T is 0 ℃ or lower (indoor temperature is equal to or higher than target temperature). If it is less than or equal to), it is possible to operate with the minimum value breeze, and when ΔT is a value between 0 ° C. and 2 ° C., it can be operated while varying in proportion to ΔT between strong wind and breeze. In the autonomous driving mode, the rotational speed of the blowing fan 12 may be automatically variable between strong winds and breezes. Specific values such as the strong wind value and the breeze value may vary slightly depending on the model and cooling capacity of the air conditioner. For example, in the case of a 9-plane air conditioner, the rotational speed of the blowing fan 12 is usually about 1000 rpm for strong winds and about 860 rpm for breezes, and about 930 rpm for weak winds between strong winds and breezes. .

According to the automatic operation control method of the conventional air conditioner as described above, according to the natural wind operation to automatically control the rotational speed of the blowing fan according to the temperature difference (ΔT) between the target temperature (Ts) and the room temperature (Tr). By driving, it is possible to maintain an appropriate cooling temperature to satisfy the function of comfort. However, since the air volume is controlled by the temperature difference ΔT between the current temperature Tr and the target temperature Ts, the air volume gradually decreases from the strong wind to the breeze as the current temperature approaches the target temperature. Therefore, as the current temperature approaches the target temperature, there is a problem in that the cooling rate is lowered to satisfy the function of rapidity.

Accordingly, the present invention has been made to solve the above-mentioned problems, the object of the present invention is to provide a function of comfort that can maintain an appropriate cooling temperature while having a function of rapid speed of reaching the target temperature at a high speed. It is to provide an automatic operation control method of the air conditioner that can be satisfied at the same time.

1 is a block diagram showing the basic structure of a general air conditioner;

2 is a flowchart illustrating a method for automatically controlling an air conditioner according to the present invention;

3 is a graph showing the cooling rate according to the air volume in the air conditioner; And

4 is a graph showing the stabilization trend of the refrigerant temperature with time in the air conditioner.

Explanation of symbols on the main parts of the drawings

11: indoor heat exchanger 12: blowing fan

21 compressor 22 outdoor heat exchanger

30: control unit 32: operation mode setting unit

34: temperature setting unit 36: room temperature detection unit

Automatic operation control method of the air conditioner according to the present invention for achieving the above object,

(a) When the indoor temperature is higher than the target temperature by comparing the room temperature with the target temperature, the blower fan is operated for an appropriate time at each air volume while gradually increasing the air volume until the first air volume reaches the second air volume. step;

(b) operating the blower fan at a second air volume until the room temperature reaches the target temperature; And

(c) if the indoor temperature is not higher than the target temperature in steps (a) and (b), the method includes switching to natural wind operation.

The first air flow rate is set as the minimum air flow rate with the shortest refrigerant stabilization time, and the second air flow rate is set as the maximum air flow rate.

In the step (a), the predetermined time of operation at each of the air flow rate is set to a value obtained by subtracting the stabilization time of the refrigerant by the previous operating air flow amount from the stabilization time of the refrigerant by the air flow rate, provided that The predetermined time of operation is set to the stabilization time of the refrigerant by the first air volume.

According to the control method of the automatic operation of the air conditioner according to the present invention, if the target temperature is set, first operating the blow fan at a first air flow rate, that is, a minimum air flow rate with a short refrigerant stabilization time, and then a second air flow at the first air flow rate. The blower fan is operated for an appropriate time at each wind speed while increasing the air flow step by step until the air flow rate is reached, and the blower fan continues to operate at the second air flow rate, that is, the maximum wind speed, until the room temperature reaches the target temperature. Done.

Therefore, during the initial operation of the air conditioner, the blower fan is operated with the minimum air flow rate as well as the first air flow rate, that is, the refrigerant stabilization time is the shortest, and the temperature of the refrigerant is also the lowest. In addition, the temperature of the discharged cold air is the lowest to obtain a rapid cooling effect. In addition, since the blowing fan is operated while increasing the air volume step by step until the first air volume reaches the second air volume, it is possible to prevent the refrigerant from becoming unstable. In addition, since the blowing fan continues to operate until the indoor air temperature reaches the target temperature at the second air flow rate, that is, the maximum air flow rate, it is possible to obtain an effect of rapidly cooling to a desired target temperature, thereby satisfying the function of rapidity.

In addition, since the natural wind operation is quickly performed after reaching the desired target temperature, the comfort function can be satisfied at the same time.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the automatic operation control method of the air conditioner according to the present invention will be described in detail. The same components as in the prior art will be described by applying the same reference numerals.

Figure 2 is a flow chart showing an embodiment of the automatic operation control method of the air conditioner according to the present invention, Figure 3 is a graph showing the cooling rate according to the air volume in the air conditioner, Figure 4 is a time in the air conditioner It is a graph showing the stabilization trend of the refrigerant temperature according to.

First, (a) when the indoor temperature is higher than the target temperature by comparing the indoor temperature and the target temperature, the blowing fan is gradually increased until the air flow reaches the second air flow rate from the first air flow rate to the second air flow rate. Perform the steps to start up.

That is, in step 211, the room temperature sensor 36 detects the current room temperature Tr.

In step 213, the controller 30 determines the temperature difference between the target temperature Ts and the room temperature Tr, ΔT (ΔT = Tr-Ts), and compares whether or not ΔT is greater than zero. That is, it is compared whether or not the room temperature Tr is higher than the target temperature Ts. Usually, the target temperature Ts is automatically applied to the temperature which has already been set, that is, 24 ° C. When the user wants to change the target temperature Ts, the user may change the temperature by the temperature setting unit 34 within a range of ± 2 ° C. from the preset target temperature Ts.

In step 215, when the room temperature Tr is higher than the target temperature Ts, the blowing fan 12 is operated for the first predetermined time with the first air volume. Here, the first air volume is most preferably selected to the minimum amount of air operated in the air conditioner of the present invention. That is, it operates with a breeze. It is preferable that the first predetermined time is selected within a time at which the cooling rate is the fastest when the wind speed is operated, that is, the coolant temperature stabilization time T ₁ of the breeze, or a time range thereof.

3 and 4, in the initial operation state of the air conditioner, it is understood that the cooling rate is faster as the air volume is weaker until a predetermined time elapses, and the cooling rate is faster as the air volume is stronger after a certain time elapses. Can be. This is interpreted to be because, in the initial operation state, the cooler temperature is stabilized faster as the air volume is weaker, and therefore the temperature of the cold air discharged is lower as the air volume is weaker.

Compared to the cooling rate in Figure 3, the last time the cooling time is short compared to the case of the strong wind in the case of the strong wind, low breeze, but in the early case of the low wind, the cooling speed is faster than the case of the strong wind, strong wind have. In addition, in FIG. 4, the stabilization time of the refrigerant temperature is respectively T ₁ , T ₃ , and T ₂ in the case of the breeze, the weak wind, and the strong wind, respectively, and the stabilization time of the refrigerant temperature is shorter than that of the mild wind and the strong wind. Can be.

In step 217, when the room temperature Tr is not higher than the target temperature Ts, the operation is switched from the initial operation step to the natural wind operation step.

Natural wind driving step (S104), that is, the control unit 30 is switched to the driving step to control to change the rotational speed of the blowing fan 12 according to the size of ΔT. That is, the larger the ΔT, the greater the air volume by operating the rotational speed of the blower fan 12, and the smaller the ΔT, the lower the airflow rate by operating the lowered rotational speed of the blower fan 12, thereby maintaining a constant cooling temperature. It is driving to let.

In step 219, it is checked whether the first predetermined time, i.e., the coolant temperature stabilization time T ₁ has elapsed, and if the first predetermined time has not elapsed, returns to step S211, and when Follow these steps:

That is, in step 221, after the first predetermined time elapses, that is, after the coolant temperature stabilization time T ₁ elapses, the room temperature sensing unit 36 detects the current room temperature Tr again. .

In step 223, the controller 30 determines the temperature difference between the input target temperature Ts and the measured room temperature Tr, i.e., ΔT (ΔT = Tr-Ts), and whether ΔT is greater than zero. That is, it is compared whether or not the room temperature Tr is higher than the target temperature Ts.

In operation 225, when the indoor temperature Tr is higher than the target temperature Ts, the blowing fan 12 is operated with a weak wind of one step higher than the breeze. In order to provide the fastest cooling speed, the operation time of the weak wind is preferably the coolant temperature stabilization time (T ₃ ) of the low wind coolant temperature stabilization time (T ₁ ), and may be selected within the time range. Do. .

In step 227, when the room temperature Tr is not higher than the target temperature Ts, the operation is switched from the initial operation step to the natural wind operation step.

In step 229, it is checked whether the operation time of the mild wind, that is, the refrigerant temperature stabilization time T ₃ of the mild wind-the coolant temperature stabilization time T ₁ of the breeze has passed, and if this time has not elapsed, step S221. Return to and follow the next step if it has passed.

Next, (d) operating the blower fan at the second air volume until the room temperature Tr reaches the target temperature Ts.

That is, in step 231, after the predetermined time elapses by the weak wind, that is, after the refrigerant temperature stabilization time T ₃ of the mild wind elapses, the refrigerant temperature stabilization time T ₁ of the breeze elapses, The room temperature Tr is detected again.

In step 233, the controller 30 determines a temperature difference between the input target temperature Ts and the measured room temperature Tr, that is, ΔT (ΔT = Tr−Ts), and the indoor temperature Tr is Compare whether or not it is higher than the target temperature (Ts).

In step 235, when the indoor temperature Tr is higher than the target temperature Ts, the blowing fan 12 is operated with a strong wind of one step higher than the weak wind. Since the strong wind is the highest amount of air, the blowing fan 12 is continuously operated with strong wind until the room temperature Tr reaches the target temperature Ts in order to achieve the fastest cooling rate.

In step 237, when the room temperature Tr is not higher than the target temperature Ts, the operation is switched from the initial operation step to the natural wind operation step S217.

Thus, it is possible to reach the desired target temperature at high speed.

According to the automatic operation control method of the air conditioner according to the present invention as described above, according to the automatic operation control method of the air conditioner according to the present invention, first, when the target temperature is set, the first air volume with a short refrigerant stabilization time That is, after operating the blower fan with the minimum air flow rate, the blower fan is operated for an appropriate time at each air flow rate while gradually increasing the air flow rate until the first air flow rate reaches the second air flow rate, and the room temperature is maintained at the target temperature. The blower fan continues to operate at the second air flow rate, that is, the maximum air flow rate, until the air flow rate is reached.

Therefore, during the initial operation of the air conditioner, the blower fan is operated with the minimum air flow rate as well as the first air flow rate, that is, the refrigerant stabilization time is the shortest, and the temperature of the refrigerant is also the lowest. In addition, the temperature of the discharged cold air is the lowest to obtain a rapid cooling effect. In addition, since the blowing fan is operated while increasing the air volume step by step until the first air volume reaches the second air volume, it is possible to prevent the refrigerant from becoming unstable. In addition, since the blowing fan continues to operate until the indoor air temperature reaches the target temperature at the second air flow rate, that is, the maximum air flow rate, it is possible to obtain an effect of rapidly cooling to a desired target temperature, thereby satisfying the function of rapidity.

In addition, since the natural wind operation is quickly performed after reaching the desired target temperature, the comfort function can be satisfied at the same time.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes are intended to fall within the scope of the claims set forth.

Claims (5)

(a) comparing the room temperature with the target temperature and operating the blowing fan while gradually increasing the air volume until the second air volume is reached from the first air volume when the indoor temperature is higher than the target temperature; (b) comparing the indoor temperature with the target temperature when the air volume reaches the second air volume in step (a); and operating the blower fan at the second air volume when the indoor temperature is high as a result of the comparison; And (c) when the indoor temperature is not higher than the target temperature in steps (a) and (b), converting to natural wind; Automatic operation control method of the air conditioner comprising a. The method of claim 1, wherein the first air flow rate is set to a wind flow rate that takes the shortest time to stabilize the temperature of the refrigerant. The method of claim 1, wherein the second air flow rate is set to a maximum air flow rate. The method of claim 1, wherein in the step (a), the time at which the blowing fan is operated at the first air volume and the time at which the second air volume is operated is operated at the time when the temperature of the refrigerant is stabilized by operating at the air volume. It is set to the time value minus the time that the temperature of the refrigerant is stabilized by operating with the air volume, except that the time when the blowing fan is operated with the first air volume is set to the time when the temperature of the refrigerant is stabilized by operating with the first air volume. Automatic operation control method of air conditioner. The method according to claim 1, wherein the air volume gradually increased from the first air volume to the second air volume is divided into three stages of breeze, weak wind, and strong wind.