KR19980043380A - Prevention method of compressing liquid refrigerant during initial heating operation of inverter air conditioner - Google Patents

Abstract

The present invention relates to an inverter air conditioner that directly controls the vehicle body's capability by varying the number of revolutions of the compressor. In particular, the compressor is operated at a minimum operating frequency at which the compressor motor can be rotated when the outdoor temperature is low during the initial heating operation. To increase the surface temperature of the compressor and operate the compressor at the operating frequency during heating operation to protect the compressor by preventing the compression of liquid refrigerant.When the heating operation start signal and the compressor operation signal are applied, the outdoor temperature An operation determination step of determining whether the outdoor temperature applied by the sensor is equal to or less than a first predetermined temperature which is a temperature at which the gas refrigerant is liquefied; If the outdoor temperature is less than the first predetermined temperature in the operation determination step, if the compressor surface temperature is lower than the second predetermined temperature, which is the temperature at which the liquid refrigerant is dissolved in the compressor lubricating oil, the minimum operation that the compressor motor can be rotated by controlling the inverter unit. After operating the compressor motor at a frequency, the liquid refrigerant to operate the compressor motor at a target operating frequency which is the operating frequency set during heating operation by controlling the inverter unit when the surface temperature of the compressor is higher than the second predetermined temperature or a predetermined time elapses. A method of preventing compression of liquid refrigerant during initial heating operation of an inverter air conditioner, characterized in that to perform a compression prevention operation step.

Description

Prevention method of compressing liquid refrigerant during initial heating operation of inverter air conditioner

The present invention relates to an inverter air conditioner that directly controls the vehicle body's capability by varying the rotational speed of the compressor according to the room temperature. Particularly, when the outdoor temperature is low during the initial heating operation, the presser motor may rotate. Compress the liquid refrigerant during the initial heating operation of the inverter air conditioner to protect the compressor by preventing the compression of the liquid refrigerant by operating the compressor at the minimum operating frequency and then operating the compressor at the operating frequency during the heating operation. It relates to a prevention method.

The refrigerant cycle of the inverter air conditioner is formed of a compressor (1), an indoor heat exchanger (4), a capillary tube (3), an outdoor heat exchanger (2), and a compressor (1) as shown in FIG. The indoor fan 5 is driven by the indoor fan motor 6 so that the indoor air is heat exchanged in the indoor heat exchanger 4 and then supplied to the room again, and the outdoor fan 7 is supplied to the outdoor fan motor 8. Driven to allow the outdoor air to be heat exchanged in the outdoor heat exchanger (2) and then supplied to the outdoor again.

That is, the gas refrigerant evaporated in the outdoor heat exchanger (2, evaporator) is a high temperature and high pressure gas refrigerant compressed by the compressor (1) and liquefied even at room temperature. The high temperature and high pressure gas refrigerant is cooled by indoor air in an indoor heat exchanger (4, condenser) to release heat of condensation, and then liquefied to form a liquid refrigerant at room temperature and high pressure. The liquefied room temperature and high pressure liquid refrigerant becomes a low pressure and low temperature liquid refrigerant that is easily evaporated between the capillary tubes 3. The low temperature low pressure liquid refrigerant passing through the capillary tube 3 is sent to the outdoor heat exchanger (2, evaporator) to take heat away from the outside and evaporate to become a low temperature low pressure gas refrigerant.

As described above, the compressor 1 functions to suck the refrigerant of the outdoor heat exchanger 2 and the evaporator to reduce the refrigerant pressure in the outdoor heat exchanger 2 and the evaporator, and to compress and discharge the refrigerant.

In this way, the gaseous refrigerant vaporized in the outdoor heat exchanger 2 is sucked into the compressor 1 and is located in the upper part of the compressor 1, and the compressor lubricating oil is located in the lower part of the compressor 1. By the compression operation of the compressor 1, the gas refrigerant located in the upper portion of the compressor 1 is compressed and discharged into the gas refrigerant of high temperature and high pressure.

However, when the outdoor temperature is low, the gaseous refrigerant evaporated in the outdoor heat exchanger 2 becomes a liquid refrigerant by the low outdoor temperature when the heating operation is stopped and time passes. In this state, when the compressor is operated at the operating frequency for the heating operation, the liquid refrigerant is sucked into the compressor 1 so that the specific gravity is greater than that of the compressor lubricating oil, so that the liquid refrigerant is located in the lower part of the compressor 1 and the compressor lubricating oil is stored in the compressor 1. It is located at the top. Accordingly, the compressor lubricating oil located in the upper part of the compressor 1 is discharged together with the liquid refrigerant to the outside of the compressor 1 by the compression operation of the compressor 1.

Then, the liquid refrigerant into which the liquid refrigerant flows into the compressor 1 is compressed, thereby aging the insulating paper of the compressor motor, and the compressor lubricant is discharged to the outside of the compressor 1 before the liquid refrigerant, and the compressor lubricant is insufficient. Lubrication of the mechanical part in the inner part of the compressor due to wear of the compressor mechanical part has a problem of shortening the life of the compressor and noise.

In order to solve the problems caused by the compression of the liquid refrigerant in the compressor, a heating wire is wound around the surface of the compressor, and when the surface temperature of the compressor is lower than the predetermined temperature because the outdoor temperature is low, a weak current flows in the heating wire so that the temperature of the compressor is higher than the predetermined temperature. By then raising the compressor at a set operating frequency, this method prevents the compressor from operating below a predetermined temperature.

In addition, conventionally, when the outdoor surface is low and the surface temperature of the compressor is lower than the predetermined temperature, a weak current (that is, a small current such that the compressor motor does not rotate) is flowed to the compressor motor to increase the winding temperature of the compressor motor to thereby set the temperature in the compressor. By raising the temperature, and then operating the compressor at the set operating frequency, this method also prevents the compressor from operating below the predetermined temperature.

However, the conventional method of increasing the temperature of the compressor surface by heating the heating wire on the surface of the compressor by heating the heating wire has a problem in that a heating wire is wound on the surface of the compressor during production, and there is a problem of leakage of current when the production cost is increased. The method of flowing a small current such that the compressor motor does not rotate to the winding of the has a problem that takes a long time to increase the temperature of the compressor above a predetermined temperature.

An object of the present invention is to solve the above-mentioned shortcomings, when the outdoor temperature is low during the initial heating operation, by operating the compressor at the minimum operating frequency that the compressor motor can rotate to increase the surface temperature of the compressor and then heating the compressor It is to provide a method for preventing the liquid refrigerant compression during the initial heating operation of the inverter air conditioner to protect the compressor by preventing the aging of the compressor motor insulating paper by preventing the compression of the liquid refrigerant by operating at the operating frequency at the time of operation.

The present invention provides an outdoor temperature sensor for detecting the outdoor temperature, a compressor surface temperature sensor for detecting the surface temperature of the compressor, an inverter unit for converting a direct current voltage into an alternating voltage according to an applied control signal, and supplying it to the compressor motor, and the outdoor temperature. In the inverter air conditioner composed of a microcomputer for outputting a control signal to the inverter unit in accordance with the compressor surface temperature and the input signal from each sensor, the microcomputer receives the heating operation start signal and the compressor operation signal, An operation determination step of determining whether to apply the liquid refrigerant compression prevention operation by determining whether the applied outdoor temperature is equal to or less than a first predetermined temperature which is a temperature at which the gas refrigerant is liquefied; If the outdoor temperature is less than the first predetermined temperature as a result of the determination of the operation determination step, if the compressor surface temperature is lower than the second predetermined temperature which is the temperature at which the liquid refrigerant is dissolved in the compressor lubricating oil, the compressor motor may be rotated by controlling the inverter unit. After operating the compressor motor at the minimum operating frequency, if the compressor surface temperature is more than the second predetermined temperature or a predetermined time elapses, the inverter unit is controlled to operate the compressor motor at the target operating frequency which is the operating frequency set during the heating operation. Characterized in that the liquid refrigerant compression prevention operation step.

1 is a view showing a refrigerant cycle of a typical inverter air conditioner,

2 is a block diagram showing the configuration of a typical inverter air conditioner,

Figure 3 is a flow chart for explaining a liquid refrigerant compression prevention method during the initial heating operation of the inverter air conditioner of the present invention.

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

S10: operation determination step S20: liquid refrigerant compression prevention operation step

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

2 and 3, the embodiment of the present invention, the outdoor temperature sensor 11 for detecting the outdoor temperature, the compressor surface temperature sensor 12 for detecting the compressor surface temperature, and the converter unit 13 The inverter unit 15 converts the transmitted DC voltage into an AC voltage according to the input control signal and supplies the same to the AC motor, and the inverter unit according to the outdoor temperature, the compressor surface temperature, and an input signal from each sensor. In the inverter air conditioner consisting of a microcomputer (16) for outputting a control signal to the 15, the microcomputer 16 detects the outdoor temperature in the outdoor temperature sensor 11 when the heating operation start signal and the compressor operation signal is applied An operation determination step (S10) of determining whether or not to perform a liquid refrigerant compression prevention operation by determining whether the temperature is equal to or less than a first predetermined temperature (T1 = 0 ° C), which is a temperature at which the gaseous refrigerant is liquefied (outdoor temperature ≤ 0); When the outdoor temperature is less than or equal to the first predetermined temperature (T1 = 0 ° C) in the operation determination step (S10) (outdoor temperature ≤ 0), the compressor surface temperature is a second predetermined temperature (T2) at which the liquid refrigerant is dissolved in the compressor lubricant. = 0 ° C.) (compressor surface temperature 0), after controlling the inverter unit 15 to operate the compressor motor 14 at the minimum operating frequency at which the compressor motor 14 can be rotated, the compressor surface temperature is When the second predetermined temperature (T2 = 0 ° C.) or more (compressor surface temperature ≥ 0) or a predetermined time (t = 3 minutes) elapses, the inverter unit 15 controls the target operation which is an operating frequency set during heating operation. A liquid refrigerant compression preventing operation step S20 of operating the compressor motor 14 at a frequency is performed.

The microcomputer 16 first determines that the compressor is operated for the first time during the heating operation when the heating operation start signal is applied in the operation determination step S10 and the compressor operation signal is applied. It is determined whether to operate the liquid refrigerant compression prevention through the outdoor temperature before operating.

That is, when the outdoor temperature is equal to or lower than the first predetermined temperature T1, which is the temperature at which the gas refrigerant is liquefied, it is determined that the gas refrigerant in the pipe between the outdoor heat exchanger and the compressor is liquefied by the low outdoor temperature during the stopping of the heating operation. Prevention operation step (S20) is performed.

In addition, the microcomputer 16 detects the compressor surface temperature in the liquid refrigerant compression prevention operation step (S20), so that the compressor surface temperature is equal to or greater than a second predetermined temperature (T2 = 0 ° C.) at which the liquid refrigerant is dissolved in the compressor lubricant (T2). Determine whether or not ≥ 0). As a result of the determination, when the compressor surface temperature is lower than the second predetermined temperature (T2 = ° C) (compressor surface temperature T2), the inverter unit 15 is controlled to determine a minimum operating frequency at which the compressor motor 14 may rotate. The compressor motor 14 is operated.

The microcomputer 16 controls the inverter unit 15 when the compressor surface temperature becomes higher than the second predetermined temperature or when a predetermined time (t = 3 minutes) elapses after the compressor motor 14 is operated at the minimum operating frequency. To operate the compressor motor 14 at the target operating frequency.

That is, if the compressor surface temperature is equal to or greater than the second predetermined temperature (T2? 0), the liquid refrigerant is dissolved in the compressor lubricating oil so that the liquid refrigerant and the compressor lubricating oil are not separated into two layers in the compressor. However, if the compressor surface temperature is lower than the second predetermined temperature (T20), the liquid refrigerant is separated from the compressor lubricating oil. Among these two liquids, the liquid refrigerant having the higher specific gravity is located in the lower part of the compressor, and the compressor lubricant having the lower specific gravity is located in the upper part of the compressor. When the compressor is compressed, the compressor lubricating oil is discharged before the liquid refrigerant, and the compressor lubricating oil in the compressor is insufficient. Here, the second predetermined temperature T2, which is the temperature at which the liquid refrigerant is dissolved in the compressor lubricating oil, depends on the type of refrigerant.

Therefore, as described above, when the compressor surface temperature is increased to be equal to or greater than the second predetermined temperature T2 (compressor surface temperature T2), and the compressor is operated at the target operating frequency, the liquid refrigerant is dissolved in the compressor lubricating oil. By operating at the operating frequency, the compressor prevents the compressor lubricant from being discharged before the liquid refrigerant. Accordingly, it is possible to prevent the occurrence of noise due to lack of compressor lubricating oil and wear of the compressor mechanical part, thereby shortening the life of the compressor.

In addition, to reduce the liquid refrigerant compressed and discharged from the compressor, it is necessary to reduce the liquid refrigerant sucked into the compressor. That is, when the outdoor temperature is lower than the first predetermined temperature T1 and the liquid refrigerant is sucked into the compressor, if the compressor is rotated at the minimum operating frequency at the initial stage of the compressor operation as described above, the compressor may be rotated at the target operating frequency. It is possible to reduce the amount of liquid refrigerant sucked into. Accordingly, aging of the compressor insulating paper can be prevented.

In the present invention, a method for preventing liquid refrigerant compression during initial heating operation of an inverter air conditioner is to increase the surface temperature of the compressor by first operating the compressor at a minimum operating frequency at which the compressor motor can rotate when the outdoor temperature is low during the initial heating operation. Next, by operating the compressor at the target operating frequency, by reducing the amount of liquid refrigerant sucked into the compressor and the amount of liquid refrigerant discharged from the compressor to prevent the compression of the liquid refrigerant to prevent the aging of the compressor motor insulation paper and to prevent noise It is useful to protect.

Claims (1)

An outdoor temperature sensor for detecting an outdoor temperature, a compressor surface temperature sensor for detecting a surface temperature of the compressor, an inverter unit for converting a DC voltage into an AC voltage according to an applied control signal and supplying it to a compressor motor, and the outdoor temperature and the compressor surface. In the inverter air conditioner consisting of a microcomputer for outputting a control signal to the inverter unit according to the temperature and the input signal from each sensor, When the heating commencement start signal and the compressor operation signal are applied, the microcomputer determines whether the outdoor temperature applied by the outdoor temperature sensor is less than or equal to the first predetermined temperature at which the gas refrigerant is liquefied and determines whether to perform the liquid refrigerant compression prevention operation. A driving determination step; If the outdoor temperature is less than the first predetermined temperature as a result of the determination of the operation determination step, if the compressor surface temperature is lower than the second predetermined temperature which is the temperature at which the liquid refrigerant is dissolved in the compressor lubricating oil, the compressor motor may be rotated by controlling the inverter unit. After operating the compressor motor at the minimum operating frequency, if the compressor surface temperature is more than the second predetermined temperature or a predetermined time elapses, the inverter unit is controlled to operate the compressor motor at the target operating frequency which is the operating frequency set during the heating operation. A liquid refrigerant compression preventing operation step; Preventing liquid refrigerant compression during the initial heating operation of the inverter air conditioner, characterized in that for performing.