ITMI20000116A1 - METHOD FOR THE CONTROL OF AN INVERTER TYPE AIR CONDITIONER - Google Patents

Description

"METHOD FOR CHECKING AN INVERTER TYPE AIR CONDITIONER"

DESCRIPTION

The present invention relates to a method for controlling an inverter type air conditioner and, in particular, to a method for controlling an inverter type air conditioner capable of obtaining a stable circulation of a refrigerant adjusting an operating frequency when a temperature difference obtained by comparing the surface temperature of a condenser and an evaporator with an ambient air temperature, is equal to a predetermined temperature difference.

Generally, a cooling and heating device is classified as an on-off air conditioner which is turned on and off according to an operation mode of an inverter type air conditioner and compressor. The inverter type air conditioner controls the rotational operation of the compressor.

As illustrated in Figure 1, a conventional inverter type air conditioner comprises a compressor 11 for compressing a refrigerant gas, a four-way valve 15 for changing the direction of circulation of a refrigerant gas compressed by the compressor 11 on the basis of: a operating mode for raising and lowering an internal temperature, an internal heat exchanger 13 connected to the four-way valve 15 by means of a tube for exchanging heat between a gas in the tube and internal air, a reducing valve 14 connected to the internal heat exchanger 13 by means of a tube for controlling the pressure of a gas flowing into the tube, and an external heat exchanger 12 connected to the reducing valve 14 by means of a tube for exchanging heat between a gas in the tube and external air.

The conventional inverter type air conditioner thus structured performs a cooling and heating operation based on the condensation or evaporation of a refrigerant gas by the internal heat exchanger, and the direction of circulation of the refrigerant gas is changed according to each corresponding operating mode. The above operation will be described in greater detail.

At first, when the conventional inverter type air conditioner operates in the heating mode, the refrigerant gas circulates in the system. That is to say, the gas emitted by the compressor receives a certain pressure from the internal heat exchanger installed between the four-way valve 15 and the reducing valve 14 and is then condensed so as to increase the temperature of the gas- and the temperature of the internal heat exchanger. The internal heat exchanger 13, having an increased temperature, increases the internal temperature on the basis of a heat exchange with ambient internal air. The temperature of the gas, which has lost heat due to the ambient air, is decreased and flows into the external heat exchanger 12 through the reducing valve 14 and the pipe and the gas is evaporated from the external heat exchanger 12 and made flow into compressor 11.

When the inverter-type air conditioner operates in the cooling mode, the gas circulates as follows: the gas emitted by the compressor receives a pressure in the external heat exchanger 12 installed between the four-way valve 15 and the reducing valve 14 and it is condensed so as to increase the gas temperature and therefore decrease the temperature of the external heat exchanger 12. The external heat exchanger 12, having an increased temperature, radiates heat to an external ambient air. The gas having a decreased temperature from the external heat exchanger Ί3 passes through the reduction valve 14 and is evaporated by the internal heat exchanger 13, so that the gas receives heat from the internal air to decrease the temperature in the internal space. The gas, which has lowered the internal temperature by means of the heat exchanger, flows into the compressor 11 through the tube.

Therefore, when a user operates the inverter type air conditioner in the cooling or heating mode, a microcomputer (not shown) of the air conditioner determines a direction of circulation of the refrigerant gas. In addition, the microcomputer detects a user-set temperature and indoor and outdoor temperatures and determines an operating frequency to drive compressor 11. In this condition, the compressor is driven at an operating frequency based on an inverter circuit, so that the air conditioner inverter-type air functions in a certain way established by the user. In this case, the operating frequency of the compressor is a factor for adjusting the magnitude of the pressure of the indoor heat exchanger and the outdoor heat exchanger. If the operating frequency is high, the pressure difference between the indoor heat exchanger ^ and the outdoor heat exchanger is increased. If the operating frequency is reduced, the pressure difference between them is decreased.

Indoor heat exchanger and outdoor heat exchanger function as condenser or evaporator according to the gas circulation direction or cooling mode and heating mode.

That is, in the heating mode, the indoor heat exchanger has the function of condensing and the outdoor heat exchanger has the function of evaporation. In the cooling mode, the indoor heat exchanger has the evaporation function and the outdoor heat exchanger has the condensation function.

Therefore, since the functions of the indoor and outdoor heat exchanger are opposite according to the gas circulation direction in the inverter type air conditioner, as shown in figure 2, the heat exchange operation of the type air conditioner inverter will be explained using the terms condenser and evaporator.

Figure 2 is a P-h graph of a circulating gas used in the inverter type air conditioner. In figure 2, "A" represents ^ a plot of a relationship between a pressure P and an enthalpy h, and B1 -B4 represent the trace of a circulating gas, "C" represents the trace of an air temperature in which heat was exchanged with the condenser, and "D" represents the trace of an air temperature where heat was exchanged with the evaporator.

As shown in Figure 2, the condenser temperature B1 is higher than the air temperature C in a part where the condenser is installed, and the evaporator temperature B3 is lower than the air temperature D in a part where the condenser is installed. installed the evaporator, for the circulation of the gas, so that heat exchange takes place with air near the condenser and the evaporator. That is, the condenser temperature B1 is higher than the air temperature C, so the heat is transferred to the air, and since the evaporator temperature D is lower than the air temperature D, heat is received. That is, in the conventional air conditioner, the condenser temperature must be set to be higher than the ambient air temperature, and the evaporator temperature must be set to be lower than the air temperature. room to implement a cooling and heating function.

However, since the range of ambient air temperatures is variable, it is difficult to operate the inverter-type air conditioner by setting the condenser temperature to be higher than the ambient air temperature, and to fix the evaporator temperature accordingly. so that it is lower than the ambient air temperature. That is, in the case of the heating mode, when the outdoor temperature is changed from -10 ° C to 15 ° C, the indoor temperature is changeable from 0 ° C to 30 ° C, and in the case of the cooling mode, when the external temperature is modified from 15 ° C to 35 ° C, the internal temperature must be modifiable from 15 ° C to 30 ° C.

Therefore, in the conventional inverter type air conditioner, to meet the ambient temperature and maintain a proper indoor temperature for a certain temperature set by a user, it is difficult to control the operation described above. That is, when the outdoor temperature is 35 ° C, in case a user sets the temperature at 18 ° C and the * inverter type air conditioner operates in the cooling mode, the longer the air conditioner of the inverter type operates, the more the internal temperature is decreased. For example, the temperature is decreased from 20 ° C to 19 ° C. At this time, even when the operating frequency is continuously decreased, since the information corresponding to a temperature difference between the condenser and the evaporator is not introduced into the control information, the cooling circulation does not take place adequately.

Consequently, an object of the present invention is to provide a method for controlling an inverter-type air conditioner capable of obtaining a stable circulation of a refrigerant by adjusting the operating frequency when the temperature difference obtained by comparing the surface temperature of a condenser and an evaporator with an ambient air temperature equals a fixed temperature difference.

To achieve these objectives, a method is provided for controlling an inverter-type air conditioner, according to the present invention, comprising a temperature detection step for detecting the surface temperature "of a condenser and an evaporator and the temperature ambient air of the condenser and evaporator, a phase of comparing the detected surface temperatures of the condenser and evaporator and the detected ambient air temperatures of the condenser and evaporator, and a phase of operating the system by means of a frequency previously established operating temperature when the evaporator ambient air temperature is higher than the evaporator surface temperature by a first fixed temperature, and when the detected condenser surface temperature is higher than the condenser ambient air temperature by a second fixed temperature and, if not, operating the system at a frequency higher than the previously set operating frequency.

Advantages, objects and additional features of the invention will become more apparent from the following description.

The present invention will be better understood from the detailed description that follows and from the attached drawings given for illustrative purposes only and therefore not limitative of the invention, and in which:

Figure 1 is a view illustrating the construction of a conventional inverter type air conditioner;

- figure 2 is a graph P-h (pressure and enthalpy) of the circulation of a circulating gas of an air conditioner; And

Figure 3 is a flow chart illustrating a method for controlling an inverter-type air conditioner according to the present invention.

As shown in Figure 1, the method for controlling an inverter type air conditioner is suitable for a conventional inverter type air conditioner.

In the method for controlling an inverter-type air conditioner according to the present invention, in the STI step, electrical power is supplied to an inverter-type air conditioner. When a user sets a temperature, a microcomputer detects the temperature of the internal and external intake air and determines an operating frequency to operate a compressor based on the detected temperature. When the compressor operates on the basis of the determined operating frequency, a compressor pressure and an evaporator pressure are generated. The microcomputer activates the system so that in phase ST2 a certain pressure difference is maintained between the condenser and the evaporator.

At this time, the microcomputer determines, in step ST3, whether the inverter type air conditioner is operating in a cooling mode or a heating mode. When it is judged that the inverter type air conditioner is set to operate in the cooling mode, a surface temperature of an indoor heat exchanger (evaporator) is detected, which draws in indoor air having a certain temperature, and carries out heat exchange. with internal air, and an internal intake air temperature. Subsequently, in phase ST4, it is evaluated whether the difference between the temperature of the internal intake air and a surface of the internal heat exchanger is or is not greater than 2 ° C.

As a result of the evaluation of stage ST4, if the indoor intake air temperature is higher than the surface temperature of the indoor heat exchanger by 2 ° C, outdoor air is drawn in and the outdoor heat exchanger (condenser), which exchanges heat with the external air, it detects the surface temperature and the temperature of the external intake air. If the difference between the surface temperature of the external heat exchanger and the temperature of the external intake air is greater than 2 ° C, in phase ST5 the compressor is activated at a previously established operating frequency.

As a result of stage ST4, if the difference between the indoor intake air temperature and the surface temperature of the indoor heat exchanger is less than 2 ° C, or as a result of stage ST5, if the difference between the surface temperature of the external heat exchanger and the temperature of the external intake air is lower than 2 ° C, the compressor is activated, in phase ST8, on the basis of an operating frequency higher than the previously established operating frequency.

As a result of the evaluation of step ST3, if the inverter type air conditioner is set up to operate in the heating mode, indoor air having a certain temperature is drawn in, and a surface temperature of the indoor heat exchanger (condenser) is detected which exchanges heat with the internal air and the temperature of the internal intake air. Then, in step ST6, it is evaluated ■ whether the difference between the surface temperature of the internal heat exchanger and the temperature of the internal intake air is greater than 2 ° C.

As a result of the evaluation of stage ST6, if the difference between the surface temperature of the indoor heat exchanger and the temperature of the indoor intake air is greater than 2 ° C, outdoor air is drawn in and the outdoor heat exchanger (evaporator) , which exchanges heat with the external air, detects the surface temperature and the temperature of the external intake air. Subsequently, if the difference between the temperature of the external intake air and the surface temperature of the external heat exchanger is higher than 2 ° C, the compressor, in step ST7, is activated on the basis of the previously established operating frequency.

As a result of step ST6, if the difference between the surface temperature of the indoor heat exchanger and the temperature of the indoor intake air is less than 2 ° C, or as a result of step ST7, if the difference between the temperature of the external intake air and the surface temperature of the external heat exchanger is lower than 2 ° C, in step ST8 the compressor is operated on the basis of an operating frequency higher than the previously established operating frequency.

Therefore, in the method for controlling an inverter-type air conditioner according to the present invention, the difference between the indoor intake air temperature and the surface temperature of the indoor heat exchanger is kept above the minimum of / - 2 ° C, and the difference between the temperature of the external intake air and the surface temperature of the external heat exchanger is kept above - / + 2 ° C.

Also, the difference between the indoor intake air temperature and the surface temperature of the indoor heat exchanger must be greater than 2 ° C, or the difference between the surface temperature of the outdoor heat exchanger and the air temperature d external suction must be higher than 2 ° C. Otherwise, the operating frequency of the compressor is gradually increased, and then the system is operated by decreasing the pressure (temperature) of the internal heat exchanger to achieve stable refrigerant circulation.

The difference between the surface temperature of the indoor heat exchanger and the temperature of the indoor intake air must be greater than 2 ° C, or the difference between the temperature of the outdoor intake air and the surface temperature of the heat exchanger outside must be above 2 ° C. If not, the operating frequency of the compressor must be gradually increased, then the system is operated by increasing the pressure (temperature) of the external heat exchanger to achieve a stable circulation of the refrigerant.

As described above, in the method for controlling the operating frequency of an inverter-type air conditioner according to the present invention, a temperature variation of the indoor and outdoor intake air in the cooling and heating modes is compared with the surface temperature of the internal and external heat exchanger to determine an operating frequency of the compressor, so that the operation of the compressor is controlled by applying the thus determined operating frequency to the inverter circuit. In this case, even when the indoor and outdoor intake air temperatures are varied, stable circulation of the cooling and heating refrigerant can be achieved, thereby increasing the efficiency of the inverter type air conditioner.

While the preferred embodiment of the present invention has been described for illustrative purposes, those skilled in the art will understand that various modifications, additions and variations are possible without departing from the scope and spirit of the invention as set forth in the appended claims.

Claims (3)

R IV EN D ICA Z ION I 1. Method for controlling an inverter-type air conditioner on the basis of an operating frequency, characterized in that it comprises: a temperature detection phase to detect the surface temperature of a condenser and an evaporator and a temperature of the ambient air of the condenser and evaporator; - a step to compare the detected surface temperature of the condenser and evaporator and the detected ambient air temperature of the condenser and evaporator; And - a step to activate the system by means of an operating frequency previously established when the ambient air temperature of the evaporator is higher than a first temperature fixed to the surface temperature of the evaporator, and when the detected surface temperature of the condenser is higher than a second temperature set at the ambient air temperature of the condenser and, if not, activate the system at a frequency higher than the previously set operating frequency. 2. Method according to claim 1, characterized in that it further comprises a step for fixing the temperature by a user. 3. Method according to claim 1, characterized in that said first and second previously set temperatures are respectively 2 ° C.