KR0177693B1 - Coolant cycle control method of inverter airconditioner - Google Patents

Abstract

According to the present invention, if the refrigerant cycle becomes temporarily unstable due to the imbalance of the heat exchange amount between the indoor and outdoor sides during the heating operation, the heat exchange amount of the indoor heat exchanger is adjusted by adjusting the rotation frequency of the indoor fan motor and the angle of the horizontal louver without stopping the compressor. To stabilize the refrigerant cycle, and operate the indoor fan / outdoor fan motors 14 and 22 and the compressor 1 to perform air conditioning, and to detect the total consumption current I consumed in the outdoor unit. 25) and a horizontal louver motor (15) for adjusting the angle of the horizontal louver (18 ') located at the discharge port of the indoor unit (10) up and down, during the operation of the compressor during heating operation. The total current consumptions I1 and I2 of the outdoor unit are detected from the current detection unit 25 at predetermined time t intervals to determine whether the increase in the total current consumption I2-I1 is equal to or greater than the predetermined current Ia. Status The refrigerant cycle judging step (S10) and that; Since the refrigerant cycle is unstable when the rising degree I2-I1 of the total current consumption is greater than or equal to the predetermined current Ia, the indoor fan motor 14 is stored after storing the rotation frequency of the indoor fan motor 14 and the position of the horizontal louver. And a heat exchange amount control step (S20) of increasing the heat exchange amount of the indoor heat exchanger 4 by controlling the horizontal louver motor 15 and controlling the horizontal louver motor 15 to the maximum open position. ; After the heat exchange amount control step S20, if the rising degree I2-I1 of the total detected current consumption is smaller than the predetermined current Ia, the refrigerant cycle is stable. ) Is a refrigerant cycle control method of the inverter air conditioner to perform the normal operation return step (S30) to operate the horizontal louver (18 ') to the position of the stored horizontal louver.

Description

Refrigerant cycle control method of inverter air conditioner

The present invention relates to an inverter air conditioner that directly controls the capacity of an air conditioner by varying the rotational speed of the compressor according to the indoor temperature. Particularly, the refrigerant cycle is temporarily caused by an imbalance between the indoor and outdoor heat exchange rates during heating operation. Method of controlling a refrigerant cycle of an inverter known regulator for stabilizing a refrigerant cycle because the heat exchange amount of an indoor heat exchanger is increased by adjusting the rotation frequency of the indoor fan motor and the angle of the horizontal louver without stopping the compressor. will be.

In the heating operation of the inverter air conditioner, the refrigerant cycle 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 14 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 the outdoor fan motor 22. Is driven so that the outdoor air is heat-exchanged in the outdoor heat exchanger (2) and then supplied to the outdoor again.

The compressor (1) functions to suck the refrigerant from the outdoor heat exchanger (2, evaporator) to lower the refrigerant pressure in the outdoor heat exchanger (2, evaporator) and to compress and discharge the refrigerant.

Here, the amount of heat emitted from the indoor heat exchanger (4, condenser) to the indoor air (indoor heat exchange amount) is the evaporative heat (outside heat exchange amount) taken from the outdoor heat exchanger (2, evaporator) to the outdoor air and the refrigerant in the compressor (1). Is the sum total of the work (compressor work) applied to compress the temperature (internal heat exchange rate = external heat exchange amount + compressor work). As the indoor side heat exchange amount is larger, the outdoor side heat exchange amount may be increased to warm the indoor air.

In addition, as shown in FIG. 2, the inverter air conditioner control device includes a key input unit 11 through which a user inputs an operation control signal, an indoor temperature sensor 12 that detects an indoor temperature, and an operation state according to a control signal. And a user display unit 13 for displaying to the user, an indoor fan motor 14 for blowing air heat-exchanged through the indoor heat exchanger 4 according to the control signal to the room, and a horizontal louver positioned at the discharge port according to the control signal. Up and down by the horizontal louver motor 15 to adjust the angle of the air discharged to the room up and down, and the signal input from the key input unit 11 and the room temperature sensor 12 by a predetermined program An indoor unit 10 including an indoor unit control unit 16 for controlling each load; The outdoor temperature sensor 21 for detecting the outdoor temperature, the outdoor fan motor 22 for blowing air heat-exchanged through the outdoor heat exchanger 2 according to the control signal to the outside, and an AC voltage as a commercial power supply Converter unit 23 for converting to a converter, an inverter unit 24 for converting a DC voltage input from the converter unit 23 into an AC voltage according to an input control signal, and supplying it to the compressor 1, and the converter unit 23. In accordance with the current detection unit 25 for detecting the total consumption current which is the current consumed and supplied to the outdoor unit through the control unit, and according to the control signal input from the indoor unit 10 and the input signal of the outdoor temperature sensor 21 to a predetermined program An outdoor unit 20 including an outdoor unit control unit 26 for controlling each load by the unit; And indoor and outdoor transceivers 17 and 27 for transmitting and receiving signals from the indoor unit controller 16 and the outdoor unit controller 26.

When the outdoor unit controller 26 is supplied with a control signal from the indoor unit controller 16, the outdoor unit control unit 26 controls the control signal and the total current consumption detected by the outdoor temperature and current detection unit 25 detected by the outdoor temperature sensor 21. Each load is controlled according to the above. In particular, the case where the total current consumption rises is divided into the following three processes.

First, the discharge pressure, which is the pressure of the refrigerant discharged from the compressor 1, rises rapidly during operation, and the ratio of the suction pressure and the discharge pressure, that is, the compression pressure, that is the refrigerant pressure sucked into the compressor 1 rises. As described in the refrigerant cycle during the heating operation, the sum of the outdoor heat exchanger and the compressor work must be balanced with the indoor heat exchanger during the heating operation. However, if the indoor heat exchanger is small and the heat exchange is not balanced, the refrigerant cycle becomes unstable. When the ratio of the suction pressure and the discharge pressure rises, a pressure sensor is installed on the discharge side of the compressor 1, and when the discharge pressure exceeds the set pressure, the compressor 1 is stopped to protect the compressor 1 and the refrigerant cycle is stable. The compressor was then run again.

Second, 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 time passes by stopping the heating operation. In this state, when the compressor 1 is operated at the operating frequency for the heating operation, the liquid refrigerant is sucked into the compressor 1 and has a greater specific gravity than the compressor lubricant oil, and is located below the compressor 1 and the compressor lubricant oil is located in the compressor 1. Located in the upper part. Accordingly, by the compression operation of the compressor 1, the compressor lubricating oil located in the upper part of the compressor 1 is discharged to the outside of the compressor 1 before the liquid cold cotton, and the discharge pressure rises and the compressor lubricating oil is increased due to the compression of the liquid refrigerant. This is the case.

At this time, before the compressor 1 is operated, a small current flows in the compressor 1 to preheat the compressor to a predetermined temperature or higher, and then the compressor 1 is operated at an operating frequency or the compressor 1 is operated for a predetermined time. It is operated by operating to minimize the discharge amount of liquid refrigerant and then operate at the operating frequency to prevent the compression of liquid refrigerant and pre-ejection of compressor lubricant.

Third, since the operating frequency of the compressor 1 is increased too fast, the difference between the suction pressure and the discharge pressure increases, and the operating frequency of the compressor 1 is increased too slowly, so that the liquid refrigerant is sucked into the compressor 1. In this case, the speed of increasing the operating frequency of the compressor 1 is adjusted according to the characteristics of the compressor 1 and the outdoor temperature. That is, the operating frequency is gradually increased by increasing the constant frequency at predetermined time intervals.

FIG. 3A is a schematic cross-sectional view showing the inside of the indoor unit 10. Indoor air is sucked through the inlet port 19 by the indoor fan 5 as shown by an arrow, and heat exchanged in the indoor heat exchanger 4, and then the outlet port 18. It is fed indoors through.

In general, the indoor unit controller 16 operates the horizontal louver motor 15 to increase the cooling efficiency as shown in FIG. 3B during the cooling operation, and thus, the horizontal louver 18 'at the discharge port 18 of the indoor unit. Tilted upwards so that the heat-exchanged cold air is discharged upwards as shown by the arrow, and the horizontal louver motor 15 is operated to increase the heating efficiency as shown in (b) of FIG. 3b during the heating operation. Tilt downward so that the heat-exchanged warm air is discharged downward as shown by the arrow.

Therefore, the warm air discharged from the discharge port 18 of the indoor unit is mixed with the indoor air sucked in the inlet 19 of the indoor unit 10 during the heating operation, thereby reducing the amount of heat exchange in the indoor heat exchanger 4. do. Therefore, the indoor heat exchange amount, which is the heat exchange amount of the indoor heat exchanger 4, is smaller than the sum of the outdoor heat exchange amount and the compressor work (indoor heat exchange amount, the outside heat exchange amount + compressor work), and the refrigerant cycle becomes unstable. The refrigerant discharge pressure discharged from the instantaneously increases.

In this case, since the ratio between the refrigerant suction pressure and the refrigerant discharge pressure of the compressor 1 increases, the total current consumption value detected by the current detection unit 25 rapidly rises, so that the indoor unit controller 26 controls the compressor 1 as in the first case. ) To stabilize the refrigerant cycle, and then operate the compressor again to maintain the ratio between the refrigerant suction pressure and the refrigerant discharge pressure of the compressor (1) within the standard. As described above, the conventional inverter air conditioner control device stops the compressor to stabilize the refrigerant cycle when the ratio of the refrigerant suction pressure to the refrigerant discharge pressure of the compressor rises above a predetermined value and the total current consumption of the outdoor unit suddenly rises. In order to solve the temporary instability of the refrigerant cycle, the compressor was stopped and the operation of the compressor was repeatedly stopped and restarted.

An object of the present invention is to solve the above-mentioned shortcomings, and in particular, when the refrigerant cycle becomes temporarily unstable due to an imbalance between the indoor and outdoor heat exchange amounts during heating operation, the rotation frequency of the indoor fan motor and the angle of the horizontal louver are adjusted. In order to increase the heat exchange amount of the indoor heat exchanger to provide a refrigerant cycle control method of the inverter air conditioning to stabilize the refrigerant cycle without shutting down the compressor.

The refrigerant cycle control method of the inverter air conditioner according to the present invention performs an air conditioning by operating an indoor fan, an outdoor fan motor, and a compressor, and includes a current detector for detecting a total consumption current consumed by an outdoor unit, and a horizontal louver located at an outlet of the indoor unit. In the control method of the inverter air conditioner having a horizontal louver motor for adjusting the angle up and down, the total consumption current of the outdoor unit is detected at predetermined time intervals from the current detection during operation of the compressor during heating operation, and then the two total consumptions are detected. A refrigerant cycle determination step of judging whether or not the degree of increase of the current has risen more than a predetermined current to determine the state of the refrigerant cycle; As a result of the determination, when the rising degree of the total consumption current detected at a predetermined time interval rises more than the predetermined current, the refrigerant cycle is determined to be unstable, and the rotation frequency of the current indoor fan motor and the current horizontal louver position are stored. A heat exchange amount control step of operating the motor at the maximum rotation frequency and controlling the horizontal louver motor to adjust the horizontal louver to the maximum open position to increase the heat exchange amount of the indoor heat exchanger; After performing the heat exchange amount control step, the total current consumption is re-detected at predetermined time intervals, and if the detected increase in the total current consumption is less than the predetermined current, the refrigerant cycle is determined to be stable. It operates and returns the normal operation return step that controls the horizontal louver motor and adjusts the horizontal louver to the position of the stored horizontal louver.

1 is a diagram showing a refrigerant cycle of a typical inverter air conditioner.

2 is a block diagram showing the configuration of a general inverter air conditioner control device.

3 shows an indoor unit of a general inverter air conditioner.

3A is a schematic cross-sectional view showing the interior of the indoor unit.

3B is a partial cross-sectional view of the discharge port showing the direction of discharge air according to the horizontal louver position of the discharge port.

4 is a flow chart for explaining the operation of the embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

14: indoor fan motor 15: horizontal louver motor

18 ': horizontal louver 22: outdoor fan motor

25: current detector S10: refrigerant cycle determination step

S20: Heat exchange amount control step S30: Normal operation return step

An embodiment of the present invention will be described in detail with reference to FIGS. 3 and 4 as follows.

In the embodiment of the present invention, as shown in FIG. 3 and FIG. 4, the indoor fan and the outdoor fan motors 14 and 22 and the compressor 1 are operated to perform air conditioning, and the total current consumption I consumed in the outdoor unit. Of the inverter air conditioner having a current detecting unit 25 for detecting a pressure and a horizontal louver motor 15 for vertically adjusting the angle of the horizontal louver 18 'which is adjacent to the discharge port 18 of the indoor unit 10. In the control method, the total current consumption (I1, I2) of the outdoor unit is detected from the current detector (25) during the operation of the compressor during a predetermined time (t) during the heating operation, and then the degree of rise (I2) of the total current consumption (I) is detected. A refrigerant cycle determination step (S10) of determining whether the state of the refrigerant cycle is determined by determining whether or not I1 is rapidly increased to a predetermined current Ia or more (I2-I1? Ia); As a result of the determination, when the degree of rise (I2-I1) of the total current consumption (I1, I2) rapidly rises to a predetermined current (Ia) or more (I2-I1≥Ia), the refrigerant cycle is determined to be unstable, and thus the current indoor fan motor ( 14 stores the rotation frequency T1 and the current horizontal louver position P1, and then operates the indoor fan motor 14 at the maximum rotation frequency Tmax, and controls the horizontal louver motor 15 to control the horizontal louver. A heat exchange amount control step (S20) of adjusting the maximum opening position (Pmax) to increase the heat exchange amount of the indoor heat exchanger (4); After performing the heat exchange amount control step (S20), the total current consumptions I1 and I2 are redetected at intervals of a predetermined time t, and the rising degree I2-I1 of the detected total current consumption I is a predetermined current. (Ia) If a sudden rise above (I2-I1≥Ia) maintains the rotational frequency Tmax of the indoor fan motor 14 and the position Pmax of the horizontal louver as it is, and the rising degree of the total current consumption I is maintained. When (I2-I1) is smaller than the predetermined current (Ia), it is determined that the refrigerant cycle is stable (I2-I1Ia) and the indoor fan motor 14 is operated at the stored rotation frequency T1 and the horizontal louver motor 15 is turned on. Performing the normal operation return step (S30) of adjusting the horizontal louver to the position (P1) of the stored and stored horizontal louver by controlling.

In addition, the control apparatus of the inverter air conditioner to which the embodiment of the present invention is applied is the same in the conventional and its configuration as in FIG. 3, except in the case where it is determined that the refrigerant cycle is unstable by the total consumption current. This is different from the prior art.

When explaining an embodiment of the present invention as follows.

The indoor unit controller 16 starts the heating operation in the refrigerant cycle determination step S10, and when the compressor is in operation, the outdoor unit control unit 26 consumes the total current consumption of the outdoor unit at a predetermined time (t) interval through the current detector 2. The state of the refrigerant cycle is determined according to the rising degree (I2-I1) of the total current consumption (I) by receiving the detection of (I1, I2).

As a result of the determination, when the total degree of current consumption (I2-I1) is greater than the predetermined current (Ia) (I2-I1≥Ia) and the total consumption current (I) rapidly rises, the heat exchange amount in the room is insufficient and the refrigerant cycle is unstable. It is determined that the heat exchange amount control step (S20).

In the heat exchange amount control step (S20), the indoor unit controller 16 first stores the rotation frequency T1 of the current indoor fan motor 14 and the position P1 of the current horizontal louver in a storage location, and then stores the indoor fan motor 14. ) To the maximum rotational frequency (Tmax) to maximize the air volume, and control the horizontal louver motor 15 to adjust the horizontal louver 18 'to the maximum open position (Pmax) heat exchange of the indoor heat exchanger (4) Increase the amount.

For example, if the rotation frequency T1 of the current indoor fan motor 14 is a heavy wind and the position P1 of the current horizontal louver is inclined downward as shown in (b) of FIG. The rotation frequency T1 of the motor 14 and the position P1 of the horizontal louver are stored. Then, the indoor fan motor 14 is operated at the maximum rotation frequency Tmax to maximize the amount of air flow, thereby increasing the amount of indoor air passing through the indoor heat exchanger 4, and operating the horizontal louver motor 15 to perform the As shown in (c) of FIG. 3b, the horizontal louver 18 'is positioned at the horizontal position which is the maximum opening position Pmax, thereby reducing the amount of warm air discharged from the discharge port 18 and sucked back through the suction port 19. The heat exchange amount of the indoor heat exchanger (4) is increased.

In this way, when the heat exchange amount of the indoor heat exchanger 4 is increased, the indoor heat exchange amount becomes similar to the sum of the outdoor heat exchange amount and the compressor work, and the refrigerant cycle is stabilized.

After performing the heat exchange amount control step (S20), the indoor unit controller 16 consumes the total consumption of the outdoor unit at a predetermined time (t) interval through the current detector 25 in the outdoor unit controller 26 in the normal operation returning step (S30). Re-detection of the currents I1 and I2 is input to determine whether the refrigerant cycle is stable according to the rising degree I2-I1 of the total current consumption I, and when the refrigerant cycle is stable, the process returns to the normal heating operation.

That is, the rising degree (I2-I1) of the total consumption current (I) redetected at predetermined intervals (t) becomes a predetermined current (Ia) or more (I2-I1≥Ia), and the total consumption current (I) rapidly rises. In this case, since the refrigerant cycle is still in an unstable state, in order to increase the heat exchange amount of the indoor heat exchanger 4, the indoor fan motor 14 is operated at the maximum rotation frequency Tmax and the position of the horizontal louver 18 is maximized as described above. Hold it in the open position (Pmax).

In the case where the rising degree (I2-I1) of the total current consumption (I) re-detected is smaller than the fusion current (Ia), it is determined that the refrigerant cycle is stable because the total consumption current (I2-I1Ia) does not increase rapidly. In the heat exchange amount control step S20, the indoor fan motor 14 is operated by the heavy wind of the rotation frequency T1 stored in the storage place, and the horizontal louver motor 15 is controlled to store the stored position P1 in FIG. As in b), the horizontal louver 18 'is adjusted to return to normal heating operation.

In the present invention, the refrigerant cycle control method of the inverter air conditioner adjusts the rotation frequency of the indoor fan motor and the angle of the horizontal louver up and down when the refrigerant cycle becomes temporarily unstable due to the imbalance of the heat exchange amount of the indoor and outdoor sides during the heating operation. By increasing the heat exchange amount of the indoor heat exchanger to stabilize the refrigerant cycle, it is useful to stabilize the refrigerant cycle without stopping the compressor, thereby reducing the number of stops and restarts of the compressor.

Claims (1)

Air conditioning is performed by operating indoor and outdoor fan motors and compressors, and includes a current detector for detecting the total consumption current consumed by the outdoor unit, and a horizontal louver motor for vertically adjusting the angle of the horizontal louver located at the discharge port of the indoor unit. In the control method of the inverter air conditioner, the total current consumption of the outdoor unit is detected at a predetermined time interval from the current detector during the operation of the compressor during the heating operation, and then it is determined whether the degree of increase of the total current consumption rises more than the predetermined current. A refrigerant cycle determination step of determining a state of a refrigerant cycle; As a result of the determination, when the rising degree of the total current consumption rises more than a predetermined current, the refrigerant cycle is determined to be unstable, and the rotation frequency of the current indoor fan motor is stored, and then the indoor fan motor is operated at the maximum rotation frequency. A heat exchange amount control step of controlling the horizontal louver motor to increase the heat exchange amount of the indoor heat exchanger by adjusting the horizontal louver to the maximum open position; After performing the heat exchange amount control step, the total current consumption is re-detected at predetermined time intervals, and if the detected increase in the total current consumption is less than the predetermined current, the refrigerant cycle is determined to be stable. Normal operation return step of operating and controlling the horizontal louver to adjust the horizontal louver to the position of the stored horizontal louver by controlling the horizontal louver motor; Refrigerant cycle control method of the inverter air conditioner, characterized in that for performing.