KR20010036767A - operation control method of air-conditioner - Google Patents

Abstract

PURPOSE: A method for controlling operation of air conditioner is provided to minimize temperature change when the indoor temperature is set to a desired temperature, while avoiding over-cooling. CONSTITUTION: A method comprises a step(S205) of sensing the indoor temperature after starting of operation of air conditioner; a step(S210) of comparing the sensed temperature with a desired temperature, obtaining the difference between the two temperatures and judging whether the difference is higher than 1 Deg.C; a step(S220) of judging whether the temperature difference is between 0 and 1 Deg.C, if the difference is lower than 1 Deg.C; a step(S230) of judging whether the temperature difference is higher than -1 Deg.C if the difference is lower than 0 Deg.C which mean that the indoor temperature is lower than the desired temperature; and a step(S240) of operating the compressor at a lower operation frequency if the temperature difference is between 0 and 1 Deg.C.

Description

Operation control method of air conditioner

The present invention relates to an operation control method of an air conditioner, and more particularly, to an operation control method of an air conditioner that can more efficiently control the operation of a compressor by using an indoor temperature and a desired temperature during operation of an air conditioner. It is about.

The air conditioner has been put to practical use for more than 30 years, and was used as the ROOM COOLER in the early days of commercialization, and its function was only for cooling. Later, around 1970, HEAT PUMP type air conditioners were developed, and now the name AIRCONDITION has been settled, and air conditioning, heating, humidity control, and air cleaning are used to control indoor air conditions. It plays a role of maintaining the most suitable state according to the use and purpose.

Hereinafter, the operation control method of the conventional air conditioner will be described with reference to the accompanying drawings.

1 is a schematic configuration diagram of an air conditioner.

As shown in FIG. 1, in general, an air conditioner absorbs heat from indoor air when a cold half operation mode is set, and a heat exchanger 10 through which a vaporized refrigerant flows, and cold air passing through the heat exchanger 10 to an indoor side. It is comprised including the indoor unit 50 equipped with the indoor fan 70 which discharges. In addition, the air conditioner includes a compressor 20 for generating a high temperature and high pressure refrigerant, a heat exchanger 30 through which the refrigerant supplied from the compressor 20 loses heat from outdoor air, and liquefied refrigerant flows, and the heat exchanger ( An outdoor unit 60 including an outdoor fan 80 for discharging the air passing through the 30 to the outside, a pipe 40 through which the refrigerant is circulated is connected between the indoor unit 50 and the outdoor unit 60.

In addition, the indoor unit 50 and the outdoor unit 60 have a built-in microcomputer (not shown) for controlling each component, and the microcomputer is also required for control between the indoor unit 50 and the outdoor unit 60 with each other. Send and receive data. In addition, various sensing means (not shown) are installed in the indoor unit 50 and the outdoor unit 60 to detect the state of the air conditioner during operation.

This will briefly look at the operation of the air conditioner configured as described above.

First, when a user sets a desired temperature (set temperature) using key input means (not shown), the temperature is recognized by the microcomputer of the indoor unit 50. Then, the microcomputer transmits the desired temperature to the outdoor unit 60 through communication means (not shown), and the microcomputer of the outdoor unit 60 performs the control to drive the compressor 20 by inputting the desired temperature. That is, the cool air generated by the heat exchanger 10 of the indoor unit 50 by the driving of the compressor 20 is supplied to the indoor side by the rotation of the indoor fan 70. This lowers the room temperature to the desired temperature. In addition, in order to prevent the inside of the outdoor unit 60 from being overheated by the driving of the compressor 20, the outdoor fan 30 operates to discharge the warm air inside the outdoor unit to the outside so that the air conditioner operates smoothly.

After that, when the indoor unit 50 receives a signal that the indoor temperature has reached the desired temperature, the microcomputer of the outdoor unit 60 outputs a signal for stopping the operation of the compressor 20.

Thus, in the air conditioner to adjust the room temperature to the desired temperature, the conventional air conditioner performed the operation by adjusting the operating frequency of the compressor (20). In this way, the higher the indoor temperature, that is, the larger the difference between the indoor temperature and the desired temperature, the compressor 20 has a high operating frequency. Thus, the compressor 20 is driven strongly, whereby the refrigerant is quickly circulated through the pipe 40. In this case, the microcomputer controls the motor of the indoor unit 50 to be driven strongly, whereby the indoor fan 70 is strongly rotated so that cold air of strong intensity is supplied to the indoor side. In this way the room temperature is adjusted to the desired temperature.

On the other hand, if the room temperature is low, that is, the difference between the room temperature and the desired temperature is small, the compressor 20 is driven at a low operating frequency. That is, since it is not necessary to supply a lot of cool air to the room, the compressor 20 only needs to be driven to maintain the current temperature, that is, the room temperature close to the desired temperature. In this way, the room temperature maintains the desired temperature.

As described above, the conventional air conditioner compares the room temperature with the desired temperature at the start of operation and controls the operation of the compressor by using the difference. In this way, if the room temperature is close to the desired temperature and there is no change in the room temperature for a predetermined time, the operating frequency of the compressor is changed. That is, the compressor was changed to a low operating frequency so that the room temperature was weakly driven to maintain the desired temperature.

As such, the conventional air conditioner controls only the operating frequency of the compressor to adjust and maintain the room temperature to the desired temperature. Therefore, in the conventional air conditioner, after the indoor temperature is set to the desired temperature, when the temperature change occurs, the operating frequency of the compressor is changed to adjust the indoor temperature to the desired temperature again. That is, the conventional air conditioner was not efficiently driven by varying the operating frequency of the compressor according to the temperature change and maintaining the room temperature at the desired temperature again.

In addition, when the operating frequency of the compressor is changed according to the temperature change, the compressor does not change the driving state quickly according to the changed operating frequency. Therefore, since the temperature adjustment is not performed within a short time after the room temperature deviates from the desired temperature, the room temperature rises again or unnecessary supercooling occurs. As a result, the conventional air conditioner did not provide an optimal cooling environment to the user.

Accordingly, an object of the present invention is to provide an operation control method for an air conditioner that can maintain an indoor temperature at a desired temperature by controlling an operating frequency of the compressor and an indoor air volume by using a difference between an indoor temperature and a desired temperature during operation of the air conditioner. will be.

1 is a schematic configuration diagram of a general air conditioner,

Figure 2 is a flow chart for the operation control method of the air conditioner according to the present invention.

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

10,30: heat exchanger 20: compressor

40: piping 50: indoor unit

60: outdoor unit 70: indoor fan

80: outdoor fan

The operation control method of the air conditioner according to the present invention for achieving the above object is to divide the difference between the room temperature and the desired temperature in several steps and to set the operating frequency of the compressor and the intensity of the indoor outdoor wind speed according to each step And a second step of detecting an indoor temperature during operation of the air conditioner, a third step of obtaining a difference between the room temperature and a desired temperature, and a subsequent operation of a predetermined value by the first step according to the difference. It is characterized by including four steps.

Here, first, when the difference between the indoor temperature and the desired temperature is greater than 1 degree, the compressor has a high operating frequency and the strength of the indoor / outdoor wind speed is strongly set. When the temperature difference is between 0 degrees and 1 degrees, the compressor has an intermediate operating frequency and the indoor and outdoor wind speed is set to medium. When the difference is between -1 degrees and 0 degrees, the compressor has a low operating frequency. The strength of outdoor wind speed is weak and the strength of indoor wind speed is set strong. Finally, when the difference is less than -1 degree, the operation of the compressor is stopped, the intensity of the indoor and outdoor wind speed is set to zero.

As such, the present invention adjusts the strength of the indoor and outdoor wind speeds as well as the operating frequency of the compressor to maintain the indoor temperature at the desired temperature. That is, by considering the above factors, the present invention can keep the indoor temperature at the desired temperature and minimize the change.

That is, as described above, the present invention compares the indoor temperature with the desired temperature, and adjusts the intensity of the operating frequency and the indoor outdoor wind speed of the compressor in proportion to the difference. In this way, the indoor temperature can be approached to the desired temperature, and if there is no change in the indoor temperature for a certain time, the operating frequency of the compressor is changed, and the indoor and outdoor wind speeds are adjusted to maintain the indoor temperature.

Here, the operating frequency of the compressor and the intensity of the outdoor wind speed are proportional. That is, when the compressor is driven strongly at a high operating frequency, the temperature inside the outdoor unit increases much, and the outdoor fan is strongly rotated to prevent the element inside the outdoor unit from being damaged or malfunctioned due to overheating. Therefore, the outdoor wind speed becomes strong. However, when the compressor is weakly driven at a low operating frequency, the outdoor fan is weakly driven because the temperature increase inside the outdoor unit is also low, and therefore the strength of the outdoor wind speed is weak.

Next, the operation control method of the air conditioner according to the present invention will be described with reference to the accompanying drawings.

2 is a flowchart illustrating an operation control method of an air conditioner according to the present invention when the air conditioner is a cooling cycle.

When the air conditioner starts to operate, first, it detects the indoor temperature (step 205). The air conditioner is then operated so that the room temperature approaches the desired temperature. That is, by operating the compressor 20, the air conditioner supplies cool air to the indoor side, whereby the room temperature drops to the desired temperature. In this way, the room temperature reaches the desired temperature by the operation of the compressor 20.

The air conditioner is operated in proportion to the difference between the room temperature and the desired temperature. That is, the larger the difference between the desired temperature and the room temperature, that is, the higher the temperature of the room temperature, the compressor 20 is driven at a higher operating frequency. The strong driving of the compressor 20 causes an increase in the internal temperature of the outdoor unit 60 side, which causes the internal elements of the outdoor unit 60 side to operate unstablely or break. Therefore, the hot air on the outdoor unit side must be discharged to the outside, which is solved by rotating the outdoor fan 80. Therefore, the outdoor fan 80 is strongly rotated, whereby the outdoor wind speed becomes strong. In addition, the indoor fan 70 is strongly rotated to lower the temperature of the indoor side, whereby the strength of the indoor wind speed is increased.

When the air conditioner is operated and the room temperature is sensed, the room temperature is compared with the desired temperature. In operation 210, the difference between the two temperatures is obtained and the difference is greater than 1 degree. In this way, if the temperature difference is more than 1 degree, this means that the room temperature is high, and the compressor 20 is driven at a high operating frequency. That is, the compressor 20 is strongly driven, and the indoor and outdoor fans 70 and 80 are also strongly rotated, so that the strength of the indoor and outdoor wind speeds is strong. As such, when the difference between the indoor temperature and the desired temperature is greater than 1 degree, the operating frequency of the compressor 20 is set high, and the indoor temperature can be the desired temperature by strongly adjusting the intensity of the indoor / outdoor wind speed.

If the difference between the room temperature and the desired temperature is lower than 1 degree, it is determined whether the difference between the two temperatures is 0 or 1 degree (step 220). If the temperature difference is between 0 and 1 degree, this is a state in which the room temperature is almost close to the desired temperature, so that the compressor 20 is driven with medium intensity. That is, the compressor 20 is driven at a frequency of a medium magnitude in the operating frequency range. As a result, the outdoor fan 80 is also rotated to a medium intensity to output wind of medium intensity. In addition, since the indoor side does not need to be supplied with too strong cold air, the indoor fan 70 is also rotated in the middle, and the intensity of the indoor wind speed is about medium.

However, if the difference between the room temperature and the desired temperature is lower than 0 degrees, that is, if the room temperature is lower than the desired temperature, it is determined whether the temperature difference is greater than -1 degrees again (step 230). In this way, when the temperature difference is between -1 degrees and 0 degrees, the compressor 20 is driven at a low operating frequency. That is, since the air conditioner needs to be operated to maintain the room temperature at the desired temperature, the compressor 20 is weakly driven. As a result, the outdoor fan 80 is also weakly rotated, and the strength of the outdoor wind speed is weakened. In addition, since the cool air supplied to the indoor side needs only to maintain the indoor temperature at a desired temperature, the indoor fan 70 is weakly rotated, whereby the strength of the indoor wind speed is weakened.

When the air conditioner is operated and the difference between the room temperature and the desired temperature is lower than -1 degree, that is, when the room temperature becomes lower than (desired temperature-1 degree), it is determined that the air conditioner does not need to be operated anymore. If the room temperature is lower than the desired temperature, it provides a rather unpleasant environment for the user. Therefore, the air conditioner stops operation, whereby the compressor 20 stops driving, and the indoor and outdoor fans 70 and 80 are stopped to rotate, so that the strength of the indoor and outdoor wind speed becomes zero.

As described above, the operation control method of the air conditioner according to the present invention considers the operation frequency of the compressor and the indoor outdoor wind speed in order to maintain the indoor temperature at the desired temperature. As a result, the larger the difference is in proportion to the difference between the indoor temperature and the desired temperature, the compressor has a high operating frequency and is driven strongly, and the indoor and outdoor fans are strongly rotated, thereby increasing the strength of the indoor and outdoor wind speeds. On the contrary, the smaller the difference, the lower the driving frequency of the compressor is driven weakly, the strength of the indoor and outdoor wind speed is also weak.

That is, the present invention adjusts the operating frequency of the compressor and the strength of the indoor outdoor wind speed so that the indoor temperature is close to the desired temperature. Then, if there is no change in the room temperature for a certain period of time, the operating frequency of the compressor is changed, and the speed of the indoor outdoor wind speed is adjusted by changing the rotation speed of the indoor / outdoor fan to change the indoor discharge temperature. Therefore, the air conditioner according to the present invention can maintain the desired temperature without severe temperature change after the outdoor temperature reaches the desired temperature.

The operation control method of the air conditioner according to the present invention configured as described above controls not only the operating frequency of the compressor but also the amount of indoor and outdoor air in maintaining the indoor temperature at a desired temperature. As described above, the compressor is efficiently driven by controlling various factors in maintaining the room temperature.

In addition, the present invention has the advantage that the change in temperature is minimized after the room temperature is set to the desired temperature, and also because the response to the temperature change is made quickly, supercooling is suppressed and the user can live in an optimal cooling state. .

Claims (5)

A first step of dividing the difference between the indoor temperature and the desired temperature in several steps, and setting the operating frequency of the compressor and the strength of the indoor / outdoor wind speed according to each step; A second step of sensing an indoor temperature during operation of the air conditioner; Obtaining a difference between the room temperature and the desired temperature; And a fourth step of subsequently driving to a value preset by the first step according to the difference. The method of claim 1 wherein: If the difference is greater than 1 degree, the compressor has a high operating frequency and the strength of the indoor and outdoor wind speed is strong control method of the air conditioner, characterized in that set. The method of claim 1 wherein: When the difference is between 0 degrees and 1 degrees, the compressor has an intermediate operating frequency and the strength of the indoor / outdoor wind speed is set to medium. The method of claim 1 wherein: If the difference is between -1 to 0 degrees, the compressor has a low operating frequency and the strength of the outdoor wind speed is weak, the strength of the indoor wind speed is set strong. The method of claim 1 wherein: And when the difference is less than -1 degree, driving of the compressor is stopped, and the strength of the indoor / outdoor wind speed is set to zero.