KR20010003069A - Control method for a heat pump type multi air-conditioner - Google Patents

Abstract

PURPOSE: An operation control method is provided to achieve an improved heating efficiency by effectively controlling operation state of a compressor in accordance with mutual operation state of each of indoor units. CONSTITUTION: A method comprises a first step(S301,S302) of performing heating operation when an operation signal is input to any one of indoor units; a second step(S303,S304) of turning off an outdoor fan if it is judged as the first overload operation condition by the temperature of any one of the outdoor heat exchangers; a third step(S306,S307) of turning on the outdoor fan if it is an overload operation release condition during the first overload operation; a fourth step(S305,S308,S314) of continuously operating the compressor ignoring the second overload operation condition, if an operation signal is input to the other indoor unit and the temperature of the corresponding heat exchanger is the second overload operation condition while performing the first overload operation and the compressor is in operation; a fifth step(S313,S314) of turning off the compressor for a predetermined time period and re-starting the compressor, if an operation signal is input to the other indoor unit, the temperature of the corresponding heat exchanger is the second overload operation condition, and the compressor is not in operation; and a sixth step(S311,312) of turning on the outdoor fan if it is the first overload operation release condition while the compressor is in the second overload operation.

Description

Operation control method of combined air-conditioning multi air conditioner {Control method for a heat pump type multi air-conditioner}

The present invention relates to an operation control method for a multiple air conditioner for both air conditioning and heating. More specifically, in a multi air conditioner for air conditioning combined with a plurality of indoor units in one outdoor unit, the air conditioner for controlling the compressor's operating state efficiently It relates to an operation control method of an air conditioner.

In general, an air conditioner is a mechanical device that heats and heats a room by using a heat exchange process between a heat exchange medium and an ambient atmosphere that undergoes a phase change process while circulating a closed circuit, and recently, many indoor heat exchangers installed in different rooms are used. By connecting the units in parallel to a single compressor, there is provided a multiple air conditioner for both heating and cooling that can achieve higher efficiency at a lower cost.

An example of such a conventional air conditioning multi air conditioner is shown in FIG. 1. In the drawing, reference numeral 120 denotes an outdoor heat exchanger and includes an independent side circulation passage 121 and a multi side circulation passage 122.

One side of the independent side circulation passage 121 is connected to the independent side compressor 111 through the independent side 4-way valve 151, and the other side thereof is connected to the independent side indoor heat exchanger 141 through the capillary tube 131. . In addition, the independent side indoor heat exchanger 141 is connected to the independent side compressor 111 through the 4-way valve 151.

In addition, the multi-side circulation passage 122 is connected to the multi-side compressor 112, one side of which is connected to the multi-side compressor 112 through the multi-side four-way valve 152, the other side of the pair through the circulation pipe 101 divided into two It is connected to the multi-side indoor heat exchanger (142, 143). On the bifurcated circulation pipe 101, electric expansion valves 132 and 133 are respectively installed. In addition, the pair of multi-sided indoor heat exchangers 142 and 143 are connected to the multi-side four-way valve 152 through a circulation pipe 102 which is merged into one.

The air-conditioning combined multi-air conditioner according to an exemplary embodiment having such a configuration may be divided into independent cycles and multi-side cycles, and may operate independently of each other.

First, the independent cycle passes through the compressor 111, the 4-way valve 151, the independent side circulation passage 121 of the outdoor heat exchanger 120, the capillary tube 131, and the independent side outdoor heat exchanger 141. The cooling effect of lowering the temperature of the room in the independent indoor heat exchanger 141 is achieved by a circulation cycle returning to the independent compressor 111 through the 4-way valve 151.

Meanwhile, the circulation of the heat exchange medium is reversed by the operation of the four-way valve 151, that is, the independent side circulation passage of the capillary tube 131 and the outdoor heat exchanger 120 from the compressor 111 via the indoor heat exchanger 141. When the direction is made back to the independent compressor 111 via the 121, the independent indoor heat exchanger 141 increases the indoor temperature by the high temperature and high pressure heat exchange medium discharged from the compressor 111. Heating action takes place.

In addition, the multi-side compressor 112, the multi-side four-way valve 152, the multi-side circulation passage 122 of the outdoor heat exchanger 120, the electric expansion valve 132, 133 and the multi-side indoor heat exchanger ( The multi-side cycles circulating 142 and 143 also occur in the same manner as the independent side cycles.

However, in this multi-side cycle, a heating and cooling action can be performed at two places through a pair of multi-side indoor heat exchangers 142 and 143. In this multi-side cycle, the motor-expanded valves 132 and 133 serve as capillaries 131 of the independent cycle. That is, as the opening degree of the electric expansion valves 132 and 133 is adjusted, the flow rate of the heat exchange medium transferred to the multi-side indoor heat exchanger 142 and 143 during cooling and the multi of the outdoor heat exchanger 120 during heating. The flow rate of the heat exchange medium transferred to the side circulation passage 122 is adjusted.

In addition, when one of the pair of multi-sided indoor heat exchangers 142 and 143 (for example, 142) is not used, the electric expansion valve 132 installed on the indoor heat exchanger 142 side is closed so that the indoor It is preferable that the heat exchange medium cannot be circulated to the heat exchanger 142. However, in order to solve the refrigerant pooling problem of the indoor heat exchanger 142, the unused indoor-side electric expansion valve 132 is finely opened without being completely closed. Thus, a small amount of refrigerant flows through the indoor heat exchanger 142.

The conventional air-conditioning combined multi-air conditioner as described above is usually controlled by a microcomputer installed respectively in an indoor unit and an outdoor unit, and such a control block diagram is illustrated in FIG. 2.

As shown, a plurality of indoor units 20, 30, 40 are connected to one outdoor unit 10, and typically, the outdoor unit 10 is installed in an outdoor space and each indoor unit 20, 30, 40 is installed. ) Are installed in different indoor spaces. In addition, the outdoor unit 10 and the indoor unit 20, 30, 40 are provided with microcomputers 17, 23, 33, 43 for controlling the respective components. Here, the indoor unit 20 is an independent side indoor unit, and the indoor units 30 and 40 are multi-side indoor units connected to one compressor 112 (see FIG. 1).

In addition, the outdoor unit 10 includes a power supply unit 11 for supplying driving power to the microcomputer 17, and an outdoor heat exchanger temperature sensor 19 that detects and transmits the surface temperature of the outdoor heat exchanger 120 to the microcomputer 17. Is prepared. In addition, the compressor driving unit 12 for selectively driving the compressors 111 and 112, the electric expansion valve driving unit 13 for adjusting the opening degree of the electric expansion valves 132 and 133, and the outdoor fan 15 4-way valve drive unit 16 for controlling the flow direction of the heat exchange medium by operating the outdoor fan drive unit 14 to improve the heat exchange efficiency of the outdoor heat exchanger 120 and the 4-way valves 151 and 152. ) Is provided.

The compressor driver 12, the motor expansion valve driver 13, the outdoor fan driver 14, and the four-way valve driver 16 are controlled by the microcomputer 17. In addition, a communication unit 18 for communication with a plurality of indoor units 20, 30, 40 is connected to the microcomputer 17.

The indoor units 20, 30 and 40 have a power source unit 21, 31 and 41 for supplying driving power to each of the microcomputers 23, 33 and 43, and the temperature of the room to detect the microcomputer ( 23, 33, 43, and the indoor temperature sensor 29, 39, 49, and the key input unit 24 for inputting operation commands by the user to the microcomputers 23, 33, 43. 34 and 44 are provided.

In addition, the operation is controlled by each of the microcomputers 23, 33, 43, and drives the indoor fans 26, 36, 46 to improve the heat exchange efficiency of the indoor heat exchangers 141, 142, 143. An indoor fan drive unit 25, 35, 45 for improving is provided. In addition, communication units 22, 32, 42 for communication with the outdoor unit 10 are connected to the microcomputers 23, 33, 43, and the communication units 22, 32, 42 are connected to a communication line ( It is connected to the communication unit 18 of the outdoor unit 10 via 50.

The conventional air-conditioning combined multi-air conditioner configured as described above is air-cooled or heated a plurality of indoor units 20, 30, 40 respectively or simultaneously by mutual communication control of the microcomputers 17, 23, 33, 43. The operation can be performed as described above.

On the other hand, when performing the heating operation for at least one indoor unit 20, 30, 40 by the above configuration, in order to prevent the overload of the compressor (111) 112, the indoor heat exchanger (141) When the temperature of (142) (143) is higher than the primary overload reference temperature (typically 53 ° C), the outdoor fan 15 is turned off, and the temperature of the indoor heat exchanger 141, 142, 143 is raised to 2 When the differential overload reference temperature (normally 60 ° C) or more, the compressor (111) 112 is stopped and a predetermined delay time (approximately 3 minutes) is applied, and then the compressor (111) 112 is controlled to restart. Protects the compressors 111 and 112 from overload operation. Each reference temperature and delay time are the most preferable results obtained through repeated experiments.

In addition, when performing the cooling or heating operation of only one indoor unit 30 of the multi-sided indoor unit 30, 40, the microcomputer 17 of the outdoor unit 10 is an electric expansion valve of the indoor unit 30 ( 132 is opened and the electric expansion valve 133 of the unused indoor unit 40 is finely opened to control a small amount of refrigerant to flow in the indoor heat exchanger 143 to solve the refrigerant pooling problem. As described throughout.

3A and 3B are flowcharts showing the operation control method of the conventional air-conditioning combined multi-air conditioner, whereby the control method for the heating operation of the multi-side indoor unit 30, 40 will be described in more detail.

First, in the indoor side, as shown in FIG. 3A, when one of the indoor units 30 and 40 inputs an operation signal to the microcomputer 33 and 43 through the key input unit 34 and 44 (S101), The microcomputers 33 and 43 of the indoor unit turn on the indoor fans 36 and 46 and output a driving signal to the outdoor unit 10. The driving signal is transmitted to the communication unit 18 of the outdoor unit via the communication unit 32 and 42 and the communication line 50 of the indoor unit 30 and 40 (S102 to S103).

Therefore, as shown in FIG. 3B, the microcomputer 17 of the outdoor unit 10 determines whether the driving signal output from the indoor units 30 and 40 has been input through the communication unit 18. By turning on the electric expansion valves 132 and 133 of the indoor units 30 and 40 outputted, the heat exchange medium is circulated to the corresponding indoor heat exchangers 142 and 143, and the 4-way valve 152, The compressor 112 and the outdoor fan 15 are turned on to perform a heating operation (S201 to S202).

In this state in which the heating operation is performed, the indoor side compares / determines the temperature of the indoor heat exchangers 142 and 143 with the primary overload reference temperature (53 ° C.) in order to prevent the compressor 112 from being overloaded. When the temperature of the heat exchangers 142 and 143 becomes equal to or higher than the primary overload reference temperature (53 ° C.), an outdoor fan off signal is output to the outdoor unit 10 (S104 to S105).

Therefore, the microcomputer 17 of the outdoor unit 10 determines whether the outdoor fan off signal output from the indoor unit 30 or 40 is input and performs the primary overload prevention operation by turning off the outdoor fan 15 ( S203-S204).

In addition, when the indoor side turns off the outdoor fan 15 by the primary overload prevention operation as described above, when the temperature of the indoor heat exchangers 142 and 143 decreases to be below the primary overload release temperature (50 ° C.). The outdoor fan on signal is output to the outdoor unit 10 (S106 to S108).

Therefore, the microcomputer 17 of the outdoor unit 10 releases the primary overload prevention operation by turning on the outdoor fan 15 according to the outdoor fan on signal output from the indoor units 30 and 40 and returns to the initial mode. (S205-S207).

On the other hand, although the indoor side turns off the outdoor fan 15 by the primary overload prevention operation as described above, the temperature of the indoor heat exchangers 142 and 143 is further increased to obtain the secondary overload reference temperature (typically 60 ° C.). ), The compressor off signal is output to the outdoor unit 10 while the outdoor fan 15 is turned off as described above, and then the standby state is maintained until the compressor on signal is input from the outdoor unit 10 ( S106, S109, S110). In addition, even in such a standby state, when the temperature of the indoor heat exchangers 142 and 143 is detected to be below the primary overload release temperature (50 ° C.), the outdoor fan on signal is output to the outdoor unit 10 (S111 to S112). ).

Therefore, the microcomputer 17 of the outdoor unit 10 stops the compressor 112 according to the compressor off signal output from the indoor units 30 and 40 and gives a predetermined delay time (about 3 minutes) (S208 to S209). ). In this state, when the outdoor fan on signal is input from the indoor units 30 and 40, the primary fan protection operation is released by turning on the outdoor fan 15 accordingly (S210 to S211). Thereafter, when the predetermined delay time elapses, the compressor 112 is restarted, and the compressor on-signal is output to the indoor units 30 and 40 and returned to the initial mode (S212 to S213).

In the indoor side, when the compressor on signal is input from the outdoor unit 10 to the microcomputers 33 and 43 of the indoor unit 10, the standby state is canceled and control is returned to the initial mode.

However, the operation control method of the conventional air-conditioning combined multi-air conditioner has a problem of lowering heating efficiency when operating a plurality of indoor units as follows. That is, as shown in FIG. 4, when the multi-side indoor unit 30 and 40 are all operated, when the temperature of at least one indoor heat exchanger (for example, 142) reaches 53 ° C., 1 The outdoor fan 15 is turned off as the vehicle overload operation, and thus the temperature of the indoor heat exchanger 142 is generally lowered.

At this time, when the indoor fan 46 is turned off as the other indoor unit 40 is turned off, a small amount of heat exchange medium flows to the indoor heat exchanger 143, thereby increasing the temperature of the indoor heat exchanger 143. In some cases, the temperature rises above the secondary overload reference temperature (60 ° C) (see section A). However, at this time, since the indoor unit 40 is turned off, the secondary overload prevention operation is not performed, and since the temperature of the indoor heat exchanger 143 is detected at the moment when the indoor unit 40 is turned on, the secondary immediately The compressor 112 is turned off by performing the overload prevention operation.

Here, the main factor of the temperature rise of the indoor heat exchanger 143 is caused by the stop of the indoor fan 46, although the indoor unit 40 is turned on and can be quickly lowered when it operates normally. By detecting only the temperature of 143 and further performing the overload prevention operation of turning off the compressor 112 until a predetermined time (see section B) has elapsed, the temperature of the indoor heat exchangers 142 and 143 is further lowered. There is a problem that the cold air is discharged to each room for a considerable time to lower the heating efficiency, and also lower the reliability of the product.

Accordingly, the present invention has been made in order to solve the above problems, the object of the present invention is to operate a compressor according to the operation state of each indoor unit in the air-conditioning combined multi-air conditioner connected to a plurality of indoor units in one outdoor unit The present invention provides an operation control method for a multi air conditioner for both heating and cooling by efficiently controlling a state and improving heating efficiency and product reliability.

1 is a block diagram of a conventional air-conditioning combined multi air conditioner,

2 is a control block diagram of FIG. 1;

Figure 3a and 3b is a flow chart showing the operation control method of the conventional air-conditioning combined multi air conditioner,

4 is a timing chart according to FIGS. 3A and 3B;

Figure 5 is a flow chart showing the operation control method of the air-conditioning combined multi air conditioner according to the present invention,

FIG. 6 is a timing chart of FIG. 5.

Explanation of symbols on the main parts of the drawings

10: outdoor unit 17: outdoor unit microcomputer

18: outdoor unit communication unit 22, 32, 42: indoor communication unit

20, 30, 40: indoor unit 23, 33, 34: indoor unit microcomputer

11, 112: compressor 120: outdoor heat exchanger

132, 133: electric expansion valve 141, 142, 143: indoor heat exchanger

A characteristic of the operation control method of the air-conditioning combined multi-air conditioner according to the present invention for achieving the above object is that a plurality of indoor units are connected to one outdoor unit and controlled by mutual communication through each microcomputer, In the control method of the air-conditioning combined multi air conditioner for cooling or heating operation by adjusting the circulation direction to solve the refrigerant pooling problem by flowing a small amount of heat exchange medium to the indoor heat exchanger of the unused indoor side, the plurality of the When the compressor is in operation according to the operation of any one of the indoor units, an operation signal of another indoor unit is input, and when the temperature of the indoor heat exchanger is a compressor overload operation condition, the compressor overload operation condition is ignored. The compressor is operated continuously.

When the compressor is not in operation, an operation signal of the other indoor unit is input, and when the temperature of the indoor heat exchanger is a compressor overload operation condition, the compressor is stopped for a predetermined delay time according to the compressor overload operation condition. After restarting, restart.

In another aspect of the present invention, a plurality of indoor units are connected to one outdoor unit, controlled by mutual communication through each microcomputer, and performing cooling or heating operation by adjusting the circulation direction of the heat exchange medium, In the operation control method of the air-conditioning combined multi-air conditioner to solve the refrigerant pooling problem by flowing a small amount of heat exchange medium to the indoor heat exchanger, when the operation signal is input to any one of the plurality of indoor units, the indoor fan, Heating the electric expansion valve, the compressor and the outdoor fan to perform heating operation; Turning off the outdoor fan if the primary overload operation condition is caused by the temperature of any one of the indoor heat exchangers during the heating operation; And an operation signal of another indoor unit is input while the compressor is in operation according to any one indoor unit operation during the primary overload operation, and if the temperature of the indoor heat exchanger is a secondary overload operation condition, the secondary unit Continuously operating the compressor, ignoring an overload operating condition.

During the primary overload operation, while the compressor is not in operation, an operation signal of the other indoor unit is input, and if the temperature of the indoor heat exchanger is a secondary overload operation condition, the compressor is turned off for a predetermined time. The method further includes the step of restarting.

The method may further include turning on the outdoor fan when the first overload operation is released during the second overload operation in which the compressor is turned off for a predetermined time.

And turning on the outdoor fan if the primary overload operation is released during the primary overload operation.

Therefore, in the multi-purpose air conditioner combined with a plurality of indoor units in one outdoor unit, an operation signal of another indoor unit is input while the compressor is in operation according to the operation of any one indoor unit among the plurality of indoor units. When the temperature of the indoor heat exchanger is a compressor overload operation condition, the compressor is continuously operated by ignoring the compressor overload operation condition, thereby efficiently controlling the operation conditions of the compressors according to the operating conditions of the respective indoor units, thereby heating efficiency and It will improve the reliability of the product.

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

FIG. 5 is a flowchart illustrating an operation control method for a multiple air conditioner for both heating and cooling according to the present invention, and FIG. 6 is a timing chart of FIG. 5.

According to a preferred embodiment of the present invention, a plurality of indoor units 20, 30, 40 are connected to one outdoor unit 10, and the microcomputers 17, 23, 33, 43 are mutually connected. Controlled by communication, and controlling the circulation direction of the heat exchange medium to perform the cooling or heating operation, but to solve the refrigerant pooling problem by flowing a small amount of heat exchange medium to the indoor heat exchanger (132, 133) of the unused indoor side In the operation control method of the air conditioner combined multi-air conditioner, when the operation signal is input to any one of the plurality of indoor units (30, 40), the corresponding indoor fan (36) (46), electric expansion valve (132) 133, heating the compressor 112 and the outdoor fan 15 to perform a heating operation (S301 ~ 302); Turning off the outdoor fan 15 if the primary overload operation condition is caused by the temperature of any one of the indoor heat exchangers 132 and 133 during the heating operation (S303 to S304); Turning on the outdoor fan 15 when the primary overload operation is released during the primary overload operation (S306 to S307); During the first overload operation, the operation signal of the other indoor units 30 and 40 is input while the compressor 112 is in operation according to the operation of any one indoor unit 30 or 40. If the temperature of the heat exchanger (142, 143) is a secondary overload operation condition, ignoring the secondary overload operation condition and continuously operating the compressor (S305) (S308) (S314); During the primary overload operation, when the compressor 112 is not in operation, the operation signals of the other indoor units 30 and 40 are input, and the temperature of the corresponding indoor heat exchangers 142 and 143 is increased. Turning off the compressor 112 for a predetermined time when the secondary overload operation condition is performed (S308-310) (S313-314); During the secondary overload operation in which the compressor 112 is turned off for a predetermined time, the outdoor fan 15 is turned on if the primary overload operation is released.

Here, the present invention is a plurality of indoor units 20, 30, 40 are connected to one outdoor unit 10 is controlled by mutual communication through each microcomputer 17, 23, 33, 43, At this time, since the control process of each indoor unit 20, 30, 40 is the same as the conventional technique described with reference to FIG. 3A, the multi-side is described with reference to FIG. 3A which describes the control process of the indoor unit and FIG. The control method for the heating operation of the indoor unit 30, 40 will be described in more detail.

First, in the indoor side, as shown in FIG. 3A, when one of the indoor units 30 and 40 inputs an operation signal to the microcomputer 33 and 43 through the key input unit 34 and 44 (S101), The microcomputers 33 and 43 of the indoor unit turn on the indoor fans 36 and 46 and output a driving signal to the outdoor unit 10. The driving signal is transmitted to the communication unit 18 of the outdoor unit via the communication unit 32 and 42 and the communication line 50 of the indoor unit 30 and 40 (S102 to S103).

Therefore, as shown in FIG. 5, the microcomputer 17 of the outdoor unit 10 determines whether the driving signal output from the indoor units 30 and 40 has been input through the communication unit 18. By turning on the electric expansion valves 132 and 133 of the indoor units 30 and 40 outputted, the heat exchange medium is circulated to the corresponding indoor heat exchangers 142 and 143, and the 4-way valve 152, The compressor 112 and the outdoor fan 15 are turned on to perform a heating operation (S301 to S302).

In this state in which the heating operation is performed, the indoor side compares / determines the temperature of the indoor heat exchangers 142 and 143 with the primary overload reference temperature (53 ° C.) in order to prevent the compressor 112 from being overloaded. When the temperature of the heat exchangers 142 and 143 becomes equal to or higher than the primary overload reference temperature (53 ° C.), an outdoor fan off signal is output to the outdoor unit 10 (S104 to S105).

Therefore, the microcomputer 17 of the outdoor unit 10 determines whether the outdoor fan off signal output from the indoor unit 30 or 40 is input and performs the primary overload prevention operation by turning off the outdoor fan 15 ( S303 ~ S304).

In addition, when the indoor side turns off the outdoor fan 15 by the primary overload prevention operation as described above, when the temperature of the indoor heat exchangers 142 and 143 decreases to be below the primary overload release temperature (50 ° C.). The outdoor fan on signal is output to the outdoor unit 10 (S106 to S108).

Therefore, the microcomputer 17 of the outdoor unit 10 releases the primary overload prevention operation by turning on the outdoor fan 15 according to the outdoor fan on signal output from the indoor units 30 and 40 and returns to the initial mode. (S305-S307).

On the other hand, although the indoor side turns off the outdoor fan 15 by the primary overload prevention operation as described above, the temperature of the indoor heat exchangers 142 and 143 is further increased to obtain the secondary overload reference temperature (typically 60 ° C.). ), The compressor off signal is output to the outdoor unit 10 while the outdoor fan 15 is turned off as described above, and then the standby state is maintained until the compressor on signal is input from the outdoor unit 10 ( S106, S109, S110). In addition, even in such a standby state, when the temperature of the indoor heat exchangers 142 and 143 is detected to be below the primary overload release temperature (50 ° C.), the outdoor fan on signal is output to the outdoor unit 10 (S111 to S112). ).

At this time, the microcomputer 17 of the outdoor unit 10 determines whether other indoor units 30 and 40 are in operation (S308). Accordingly, when the other indoor units 30 and 40 are in operation, the compressor 112 is continuously operated while ignoring the secondary overload operation condition, and the compressor on signal is transmitted to the indoor units 30 and 40 accordingly. After the output is returned to the initial mode (S314).

On the other hand, when the other indoor units 30 and 40 are not in operation, the microcomputer 17 of the outdoor unit 10 stops the compressor 112 according to the compressor off signal output from the indoor units 30 and 40, and then predetermined The delay time (about 3 minutes) is set (S309 ~ S310). In this state, when the outdoor fan on signal is input from the indoor units 30 and 40, the outdoor fan 15 is thereby turned on to release the primary overload protection operation (S311 to S312). Thereafter, when the predetermined delay time elapses, the compressor 112 is restarted, and the compressor on-signal is output to the indoor units 30 and 40 and returned to the initial mode (S313 to S314).

In the indoor side, when the compressor on signal is input from the outdoor unit 10 to the microcomputers 33 and 43 of the indoor unit 10, the standby state is canceled and the control is returned to the initial mode.

Referring to the operation of the present invention as described above in more detail with reference to the time chart of Figure 6, as shown, the multi-side indoor unit (30, 40) is in operation, at least one indoor heat exchange When the temperature of the group (for example, 142) reaches 53 ° C, the outdoor fan 15 is turned off as the primary overload operation, so that the temperature of the indoor heat exchanger 142 is generally lowered.

At this time, when the indoor fan 46 is turned off as the other indoor unit 40 is turned off, a small amount of heat exchange medium flows to the indoor heat exchanger 143, thereby increasing the temperature of the indoor heat exchanger 143. In some cases, the temperature rises above the secondary overload reference temperature (60 ° C) (see section A). At this time, in the related art, since the temperature of the indoor heat exchanger 143 is detected at the moment when the indoor unit 40 is turned on, a secondary overload prevention operation is performed immediately so that the compressor 112 is turned off. Since the indoor unit 30 is operating, the compressor 112 is operated continuously without turning off the compressor 112 (see section B).

Here, the main factor of the temperature rise of the indoor heat exchanger 143 is caused by the stop of the indoor fan 46, and is rapidly lowered as the indoor unit 40 is turned on and operated normally, and the conventional compressor 112 is It maintains a temperature relatively higher than the temperature when it is turned off (see symbols a and b). Therefore, it is possible to prevent cold air from being discharged to each room and to prevent overload of the compressor 112, thereby improving heating efficiency and product reliability.

As described above, according to the operation control method of the air-conditioning combined multi air conditioner according to the present invention, in the air-conditioning combined multi-air conditioner in which a plurality of indoor units are connected to one outdoor unit, the operation of any one indoor unit of the plurality of indoor units is performed. When the compressor is in operation, an operation signal of another indoor unit is input. At this time, when the temperature of the indoor heat exchanger is a compressor overload operation condition, the compressor is continuously operated by ignoring the compressor overload operation condition. In accordance with the mutual operating state of the efficient operation of the compressor operating state has the effect of improving the heating efficiency and product reliability.

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 (6)

A plurality of indoor units are connected to one outdoor unit and controlled by mutual communication through each microcomputer, and cooling or heating operation is performed by adjusting the circulation direction of the heat exchange medium, and a small amount of heat exchange medium is transferred to an indoor heat exchanger of an unused indoor side. In the operation control method of the air-conditioning combined air conditioner for solving the refrigerant pooling problem by flowing, When the compressor is in operation according to any one of the indoor units of the plurality of indoor units, an operation signal of another indoor unit is input, and at this time, when the temperature of the indoor heat exchanger is a compressor overload operation condition, the compressor overload operation condition Ignoring the operation to control the operation of the air-conditioner combined multi air conditioner, characterized in that for continuously operating the compressor. The compressor of claim 1, wherein the operation signal of the other indoor unit is input while the compressor is not in operation, and when the temperature of the indoor heat exchanger is a compressor overload operation condition, the compressor is in accordance with the compressor overload operation condition. And restarting the engine after stopping the engine for a predetermined delay time. A plurality of indoor units are connected to one outdoor unit and controlled by mutual communication through each microcomputer, and cooling or heating operation is performed by adjusting the circulation direction of the heat exchange medium, and a small amount of heat exchange medium is transferred to an indoor heat exchanger of an unused indoor side. In the operation control method of the air-conditioning combined air conditioner for solving the refrigerant pooling problem by flowing, Performing a heating operation by turning on a corresponding indoor fan, an electric expansion valve, a compressor, and an outdoor fan when an operation signal is input to any one of the indoor units; Turning off the outdoor fan if the primary overload operation condition is caused by the temperature of any one of the indoor heat exchangers during the heating operation; And During the primary overload operation, while the compressor is in operation according to one indoor unit operation, an operation signal of another indoor unit is input, and if the temperature of the indoor heat exchanger is a secondary overload operation condition, the secondary overload Ignoring the operating conditions, the operation control method of the air-conditioner combined multi air conditioner comprising the step of continuously operating the compressor. According to claim 3, During the primary overload operation, the operation signal of the other indoor unit is input while the compressor is not in operation, and if the temperature of the indoor heat exchanger is a secondary overload operation condition, the compressor is After the off for a predetermined time operation control method for the air-conditioning combined multi air conditioner further comprising the step of driving again. The air conditioner of claim 4, further comprising: turning on the outdoor fan when the primary overload operation is released during the second overload operation in which the compressor is turned off for a predetermined time. Operation control method. The method of claim 3, further comprising: turning on the outdoor fan when the primary overload operation is released during the primary overload operation.