KR20140096870A - Air conditioner and controlling method thereof - Google Patents

Abstract

The present invention relates to an air conditioner comprising multiple compressors; multiple oil level sensors installed in the respective compressors, and sensing oil levels in the respective compressors; multiple oil separators connected to the respective compressors, and separating oil from an oil-mixed refrigerant discharged from the respective compressors; multiple oil recovery pipes connecting the compressors and the oil separators respectively; a bypass pipe connecting the oil recovery pipes; an electronic expansion valve installed on at least one of the oil recovery pipes; and a control part controlling the opening degrees of the electronic expansion valves according to the oil levels in the respective compressors. According to the present invention, the oil levels in the respective compressors can be maintained equally.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an air conditioner,

The present invention relates to an air conditioner and a control method thereof. More particularly, the present invention relates to an air conditioner and a control method thereof that can keep the oil level of each of a plurality of compressors of an air conditioner equal.

The air conditioner is a device that performs cooling or heating through heat entering and exiting in a process of passing through a series of refrigerant cycles of compression-condensation-expansion-evaporation of refrigerant. In such an air conditioner, a compressor constitutes a part of the refrigerant cycle and compresses the refrigerant. Compressor is a device with high friction and high risk of breakage due to high pressure and temperature.

Lubrication and cooling are very important for ensuring the reliability of such a compressor, and it is oil to perform such lubrication and cooling. That is, a certain amount of oil must be always maintained in the compressor.

In the process of compressing and discharging the refrigerant in the compressor, a part of the oil vaporizes and is mixed with the refrigerant and is discharged together with the refrigerant. In addition, some of the oil may be discharged together with the refrigerant by the pressure at which the refrigerant is discharged.

If the above-mentioned oil discharge phenomenon accumulates, the amount of oil retained in the compressor is gradually reduced, and a certain amount of oil to be maintained in the compressor can not be guaranteed. Accordingly, conventionally, an oil separator is provided in a discharge pipe of a compressor to separate oil separated from the refrigerant, and the separated oil is returned to the compressor so that a predetermined amount or more of oil is retained in the compressor.

However, in the case where a plurality of compressors are provided, in particular, when the amounts of the refrigerant discharged are different due to the different capacities of the plurality of compressors, the amount of oil discharged from each compressor is different due to the amount of discharged oil. This results in breakage of the compressor and adversely affects the entire air conditioning system.

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems, the present invention provides an air conditioner capable of keeping the oil level of each of a plurality of compressors at the same level.

The present invention also provides a control method of the air conditioner.

The present invention relates to a compressor comprising: a plurality of compressors; A plurality of oil level sensors provided in each of the plurality of compressors for measuring an oil level of each of the plurality of compressors; A plurality of oil separators connected to each of the plurality of compressors to separate oil from oil mixed refrigerant discharged from each of the plurality of compressors; A plurality of oil return pipes connecting each of the plurality of compressors and each of the plurality of oil separators; A bypass pipe connecting the plurality of oil return pipes; An electronic expansion valve provided in at least one of the plurality of oil return pipes; And a controller for controlling an opening degree of the electronic expansion valve according to an oil level height of each of the plurality of compressors.

When the oil level of the oil of one of the plurality of compressors is lower than the oil level of the oil of the other compressor, the control unit controls the electronic expansion valve The opening degree of the electronic expansion valve provided in the oil return pipe connected to the other compressor can be reduced.

In addition, when the oil level of the oil of all of the plurality of compressors is less than a predetermined height, the control unit can stop the operation of the air conditioner and perform the oil recovery operation.

Further, the oil return pipe may further include a suction pipe connecting the accumulator and the compressor, and the oil return pipe may be spaced apart from the suction pipe.

In addition, the electronic expansion valve may be located closer to the compressor than the joint portion of the bypass pipe and the oil return pipe located in the oil return pipe provided with the electronic expansion valve.

(A) measuring an oil level of each of the plurality of compressors through a plurality of oil level sensors provided in each of the plurality of compressors; (b) determining whether the oil level of the oil in the first compressor, which is one of the plurality of compressors in the step (a), is lower than the oil level of the oil in the second compressor which is one compressor; And (c) if it is determined in the step (b) that the oil level of the oil of the first compressor is lower than the oil level of the oil of the second compressor, the amount of oil recovered by the first compressor is increased, 2 compressor to reduce the amount of oil recovered by the compressor.

If it is determined that the oil level of the oil of the first compressor is lower than the oil level of the oil of the second compressor in the step (b), the step (c) Increasing the opening degree of the first electronic expansion valve provided in the connected first oil return pipe and reducing the opening degree of the second electronic expansion valve provided in the second oil return pipe connected to the second compressor.

After the step (c), (d) after the lapse of a predetermined time from the step (c), measuring the oil level of the oil in the first compressor and the oil level of the oil in the second compressor; (e) determining whether the height of the oil level of the first compressor and the height of the oil level of the second compressor are the same in the step (d); (f) if it is determined in the step (e) that the oil level of the oil of the first compressor and the oil level of the oil of the second compressor are the same, the first oil return pipe connected to the first compressor 1 opening of the first electronic expansion valve and opening of the second electronic expansion valve provided in the second oil return pipe connected to the second compressor.

If it is determined that the oil level of the oil of the first compressor is different from the oil level of the oil of the second compressor in the step (e), the step (f) And determining whether the oil level of the oil of the second compressor and the oil level of the oil of the second compressor are less than a predetermined height.

If it is determined in step (f) that the height of the oil level of the first compressor and the height of the oil level of the oil in the second compressor are less than a preset height, the oil recovery operation The method may further comprise the step of:

Through the present invention, it is possible to keep the height of the oil level of each of the plurality of compressors the same. In particular, even when the amounts of the refrigerant discharged from the plurality of compressors differ from each other, the oil balances of the plurality of compressors can be matched.

This ensures reliable operation of the compressor and prevents failure due to oil shortage.

1 is a schematic view showing an air conditioner according to an example of the present invention.
Fig. 2 is an enlarged view of a portion A in Fig. 1. Fig.
3 is a block diagram showing a control unit of the air conditioner and a related configuration according to an example of the present invention.
4 and 5 are views showing the flow of oil in an air conditioner according to an example of the present invention.
6A and 6B are flowcharts showing a control method of an air conditioner according to an example of the present invention.

Hereinafter, a configuration of an air conditioner according to an example of the present invention will be described in detail with reference to the drawings.

1 is a schematic view showing an air conditioner according to an example of the present invention.

Referring to FIG. 1, an air conditioner according to an example of the present invention may include an outdoor unit 10, a distribution unit 20, and an indoor unit 30.

The outdoor unit 10 may include, for example, a compressor 100, an oil separator 200, a heat exchanger 300, an expansion unit 400, an accumulator 500, and a four-way valve 600.

The compressor 100 serves to compress and discharge the refrigerant in a state of high temperature and high pressure. 1 shows two compressors 100a and 100b as an example, but the compressor 100 is not limited thereto and the number of the compressors 100 may be one or more.

The oil separator 200 is connected to the discharge side of the compressor 100 and separates the oil from the refrigerant discharged from the compressor 100 and sends the separated oil to the compressor. In FIG. 1, two oil separators 200a and 200b are shown as an example, but the present invention is not limited thereto and may be provided in the same manner as the number of compressors 100 described above.

The heat exchanger 300 includes, for example, a blowing fan (not shown) to cause the flow of the outside air (outdoor air) by the rotation of the blowing fan, and the refrigerant flowing between the refrigerant flowing in the heat exchanger 300 and the outside air Heat exchange occurs. The heat exchanger (300) functions as a condenser when the air conditioner performs cooling operation and functions as an evaporator when the air conditioner performs heating operation.

The expanding part (400) serves to expand the refrigerant flowing through the expanding part (400). The expansion unit 400 shown in FIG. 1 serves to inflate refrigerant and supply it to the heat exchanger 300 when the heat exchanger 300 described above is used as an evaporator, for example.

The accumulator 500 serves to separate the two-phase refrigerant introduced into the accumulator 500, that is, the refrigerant mixed with the liquid phase and the vapor phase, and to supply only the gaseous phase refrigerant to the compressor 100.

The four-way valve (600) regulates the flow direction of the refrigerant discharged from the compressor (100) to adjust the operation mode of the air conditioner. That is, the four-way valve 600 controls the air conditioner to perform the cooling operation or the heating operation.

The distribution unit 20 includes a refrigerant pipe for connecting the outdoor unit 10 and the indoor unit 30 and various valves and controls the refrigerant flow between the outdoor unit 10 and the indoor unit 30 . The distribution unit 20 is a configuration that may not be included in the air conditioner as the case may be.

The indoor unit (30) includes a heat exchanger (not shown) and an expansion unit (not shown). The indoor unit (30) performs cooling or heating in the room through a heat exchanger.

Fig. 2 is an enlarged view of a portion A in Fig. 1. Fig. That is, Fig. 2 is a configuration diagram showing a main part of the present invention.

2, an outdoor unit 10 according to an exemplary embodiment of the present invention includes a plurality of compressors 100a and 100b, a plurality of oil level sensors 110a and 110b, a plurality of oil separators 200a and 200b, A plurality of oil return pipes 730a and 730b, a bypass pipe 900, a plurality of electronic expansion valves 900a and 900b, and a control unit 1000. [

The plurality of compressors 100a and 100b may be, for example, two as shown in Fig. Hereinafter, for convenience of explanation, the case where there are two compressors 100a and 100b is described as an example, but the present invention is not limited thereto.

Hereinafter, each of the plurality of compressors 100a and 100b will be referred to as a first compressor 100a and a second compressor 100b.

The first compressor (100a) and the second compressor (100b) compress refrigerant and discharge refrigerant under high temperature and high pressure. The first compressor 100a and the second compressor 100b may have different amounts of refrigerant discharged due to their different capacities. In this case, the first compressor 100a and the second compressor 100b The amount of oil discharged may also vary.

Each of the plurality of compressors 100a and 100b may be provided with a plurality of oil level sensors 110a and 110b. That is, the first compressor 100a may include a first oil level sensor 110a and the second compressor 100a may include a second oil level sensor 110a.

The oil level sensors 110a and 110b measure the oil level of the oil in the compressors 100a and 100b. The oil level sensors 110a and 110b may divide the height of the oil level by the presence or absence of the oil at the position where the oil levels are measured, You may.

Each of the plurality of compressors 100a and 100b is connected to a plurality of oil separators 200a and 200b through discharge pipes 720a and 720b. That is, the first compressor 100a is connected to the oil separator 200a by the first discharge pipe 720a and the second compressor 100b is connected to the oil separator 200b by the second discharge pipe 720b do. At this time, the discharge pipes 720a and 720b are connected to the discharge side of the compressors 100a and 100b.

With this structure, the refrigerant compressed by the first compressor 100a flows into the first oil separator 200a, and the refrigerant compressed by the second compressor 100b flows into the second oil separator 200b do.

The oil separators 200a and 200b separate the oil from the oil mixed refrigerant introduced from the compressors 100a and 100b. The first oil separator 200a separates oil from the oil mixed refrigerant introduced from the first compressor 100a and the second oil separator 200b separates the oil from the oil mixed refrigerant introduced from the second compressor 100b, .

The oil separators 200a and 200b are connected to the compressors 100a and 100b through the oil return pipes 730a and 730b. At this time, the oil return pipes 730a and 730b may be connected to the suction pipe 710 connecting the compressors 100a and 100b and the accumulator 500.

The oil return pipes 730a and 730b are connected directly to the case of the compressors 100a and 100b so that the oil flowing through the oil return pipes 730a and 730b flows directly to the compressors 100a and 100b . In this case, compared with the case where the oil return pipes 730a and 730b are connected to the suction pipe 710, the cooling efficiency is increased. This is because the oil in the oil return pipes 730a and 730b is high in pressure and the refrigerant in the suction pipe 710 is in a low pressure state, so that high pressure and low pressure are directly connected to each other, causing pressure loss.

That is, the oil return pipes 730a and 730b serve as passages for sending the oil separated by the oil separators 200a and 200b to the compressors 100a and 100b. The first oil recovery pipe 730a connects the first oil separator 200a to the first compressor 100a and the second oil recovery pipe 730b connects the second oil separator 200b and the second compressor 100b. 100b.

The bypass pipe 800 connects the first oil return pipe 730a and the second oil return pipe 730b. That is, the oil separated by the first oil separator 200a can be introduced into the second compressor 100b and the oil separated by the second oil separator 200b can be introduced into the first compressor 100b through the bypass pipe 800, And may be introduced into the compressor 100a.

A first leg portion 810a is formed at a portion where the bypass pipe 800 and the first oil return pipe 730a communicate with each other and a portion where the bypass pipe 800 and the second oil return pipe 730b communicate A second joint portion 810b is formed.

The electronic expansion valves 900a and 900b are provided in the oil return pipes 730a and 730b, respectively. The first electronic expansion valve 900a is provided in the first oil return pipe 730a and the second electronic expansion valve 900b is provided in the second oil return pipe 730b.

The electronic expansion valves 900a and 900b are positioned closer to the compressors 100a and 100b than the joint portions 810a and 810b. The first electronic expansion valve 900a and the first leg portion 810a located in the first oil return pipe 730a are arranged such that the first electronic expansion valve 900a is connected to the first compressor 100a. The second electronic expansion valve 900b and the second leg portion 810b located in the second oil return pipe 730b are arranged in such a manner that the second electronic expansion valve 900b is connected to the second leg portion 810b, And is located close to the compressor 100a. Here, the close proximity does not mean the physical distance, but means that the oil return pipes 730a and 730b are positioned closer to each other as viewed from the viewpoint of the refrigerant flowing through the oil return pipes 730a and 730b.

When the electronic expansion valves 900a and 900b are positioned closer to the compressors 100a and 100b than the joint portions 810a and 810b, the bypass pipe 800 is connected to the compressor 100a or 100b using the electronic expansion valves 900a and 900b. It is advantageous to control the amount of oil flowing through. For example, when the opening degree of the first electronic expansion valve 900a is reduced and the second electronic expansion valve 900b is maintained, a part of the oil flowing through the first oil return pipe 730a flows into the first leg portion To the second oil return pipe 730b through the bypass pipe 800 connected to the second oil return pipe 810a. Conversely, when the opening degree of the first electronic expansion valve 900a is increased and the second electronic expansion valve 900b is maintained, a part of the oil flowing through the second oil return pipe 730a flows into the second leg portion 810b, To the first oil return pipe 730a through the bypass pipe 800 connected to the first oil return pipe 730a.

The control unit 1000 controls the opening degree of the electronic expansion valves 900a and 900b according to the oil level of the oil of each of the plurality of compressors 100a and 100b.

The control unit 1000 determines that the oil level of the oil of the first compressor 100a is higher than the oil level of the oil of the second compressor 100b when the oil level of the first compressor 100a and the oil level of the second compressor 100b are different, The opening degree of the electronic expansion valves 900a and 900b is controlled to increase or decrease when the oil level of the oil of the first compressor 100a is lower than the oil level of the oil of the second compressor 100b.

More specifically, if the oil level of the oil of the first compressor 100a is higher than the oil level of the oil of the second compressor 100b, the controller 1000 controls the first oil return pipe 100a connected to the first compressor 100a, The opening degree of the first electronic expansion valve 900a provided in the second oil return pipe 730a is reduced or the opening degree of the second electronic expansion valve 900b provided in the second oil return pipe 730b connected to the second compressor 100b is reduced .

Conversely, if the oil level of the first compressor 100a and that of the second compressor 100b are the same, the control unit 1000 controls the opening degree of the electronic expansion valves 900a and 900b.

However, this does not mean that the control unit 1000 can not change the opening degree of the electronic expansion valves 900a and 900b when the oil level of the first compressor 100a and the second compressor 100b is the same It will be apparent to those skilled in the art that, depending on the case, it may vary.

When the oil level of the oil in all of the compressors 100a and 100b is less than a predetermined height, the control unit 1000 stops the cooling operation or the heating operation of the air conditioner and performs the oil recovery operation.

Here, the oil recovery operation is an operation for recovering the oil that has not been properly filtered by the oil separators 200a and 200b and has flowed into the refrigerant pipe of the refrigerant cycle. When the air conditioner performs the oil recovery operation, the amount of opening of the valve such as the expansion portion (see 400 in Fig. 1) existing on the refrigerant pipe constituting the air conditioner is controlled to be sufficiently widened so that the refrigerant circulates rapidly, The oil that has been adhered to the oil is recovered.

Hereinafter, a control unit 1000 of an air conditioner according to an exemplary embodiment of the present invention will be described in detail with reference to the drawings.

3 is a block diagram showing a control unit of the air conditioner and a related configuration according to an example of the present invention.

Referring to FIG. 3, the control unit 1000 may include a determination unit 1100, a signal output unit 1200, and a time setting unit 1300.

The determination unit 1100 is connected to the first oil level measuring sensor 110a and the second oil level measuring sensor 110b to measure the oil level of the first compressor 100a measured from the respective oil level measuring sensors 110a and 110b The oil level of the oil and the oil level of the oil of the second compressor 100b. Then, the determination unit 1100 compares the oil level of the oil of the first compressor 100a with the oil level of the oil of the second compressor 100b.

The determination unit 1100 transmits the result of comparing the oil level of the oil of the first compressor 100a with the oil level of the oil of the second compressor 100b to the signal output unit 1200. [

The signal output unit 1200 generates a signal based on the result received from the determination unit 1100 and transmits the signal to the first electronic expansion valve 900a and the second electronic expansion valve 900b.

The signal output unit 1200 can output and transmit signals so as to increase or decrease the opening degree of the electronic expansion valves 900a and 900b as an example.

Through the time setting unit 1300, the user can set the time. Here, the time may be the time from the operation of the compressors 100a and 100b to the point at which the oil level measuring sensors 110a and 110b first measure the oil level of the oil. In addition, the oil level measuring sensors 110a and 110b may be a period for measuring the oil level of the oil in the compressors 100a and 100b.

For example, if the user inputs the time of 5 minutes through the time setting unit 1300, the oil level measuring sensors 110a and 110b measure the oil level of the oil 5 minutes before the operation of the compressors 100a and 100b The oil level of the oil is measured after 5 minutes. If the user inputs 5 minutes to the time setting unit 1300 as the oil level height measurement period of the oil, the oil level measurement sensors 110a and 110b calculate the oil level height of the oil . Therefore, the oil level height of the oil is measured through the time setting unit 1300 and the opening degree of the electronic expansion valves 900a and 900b is prevented from changing too frequently. Further, as will be described later, if the height of the oil surface of the plurality of compressors 100a, 100b is different even after a predetermined time, it is determined whether or not the oil recovery operation is necessary.

Hereinafter, the flow of oil in the air conditioner according to an example of the present invention will be described in detail with reference to the drawings.

4 and 5 are views showing the flow of oil in an air conditioner according to an example of the present invention. More specifically, FIG. 4 shows a case where the oil level of the oil of the first compressor 100a is higher than the oil level of the oil of the second compressor 100b. 5 shows a case where the oil level of the oil of the second compressor 100b is higher than the oil level of the oil of the first compressor 100a.

4, the oil level of the oil in the first compressor 100a is higher than the oil level of the oil level sensor 110a, and the oil level of the oil in the second compressor 100b is higher than that of the second oil level sensor 100b. (110b). The oil level sensors 110a and 110b are provided at the same height in the respective compressors 100a and 100b so that the oil level of the oil of the first compressor 100a is higher than the oil level of the oil of the second compressor 100b High.

The first oil level sensor 110a and the second oil level sensor 110b measure the oil level of the first compressor 100a and the oil level of the oil of the second compressor 100b, And transmits it to the determination unit 1100. The transmission of the oil level measuring sensor may be performed after a predetermined time has elapsed from the operation of the compressors 100a and 100b to the time setting unit 1300. [ Then, the determination unit 1100 determines that the oil level of the oil of the first compressor 100a is higher than the oil level of the oil of the second compressor 100b based on the transmitted result. The determination unit 1100 transmits the determination result to the signal output unit 1200.

The signal output unit 1200 outputs a control signal to the first electronic expansion valve 900a so as to reduce the opening degree of the first electronic expansion valve 900a to be smaller than the current opening degree, for example.

In addition, the signal output unit 1200 outputs a control signal to the second electronic expansion valve 900b so as to increase the opening degree of the second electronic expansion valve 900b to be greater than the current opening degree, as another example.

The signal output unit 1200 also outputs a control signal to increase the opening degree of the second electronic expansion valve 900b so that the opening degree of the first electronic expansion valve 900a is reduced so as to increase the opening degree of each of the electronic expansion valves 900a and 900b ).

Thereafter, the opening degree of the first electronic expansion valve 900a or the second electronic expansion valve 900b is changed in accordance with the control signal transmitted from the signal output section 1200.

In this case, the oil separated from the first oil separator 200a reaches the first leg portion 810a along the first oil return pipe 730a (A). Some of the oil reaching the first joint portion 810a is recovered to the first compressor 100a (B), while the remaining portion of the oil flows through the bypass pipe 800 (C).

On the other hand, the oil separated from the second oil separator 200b reaches the second joint portion 810b along the second oil return pipe 730b (D), but does not flow to the bypass pipe 800, (E). ≪ / RTI >

As a result, the difference between the oil level of the oil of the first compressor 100a and the oil level of the oil of the second compressor 100b decreases and eventually the height becomes equal.

5, the height of the oil surface of the first compressor 100a is lower than that of the first oil level sensor 110a, and the height of the oil level of the second compressor 100b is lower than that of the second oil level sensor 100a. (110b). The oil level sensors 110a and 110b are provided at the same height in the respective compressors 100a and 100b so that the oil level of the oil of the first compressor 100a is higher than the oil level of the oil of the second compressor 100b Low.

The first oil level sensor 110a and the second oil level sensor 110b measure the oil level of the first compressor 100a and the oil level of the oil of the second compressor 100b, And transmits it to the determination unit 1100. The transmission of the oil level measuring sensor may be performed after a predetermined time has elapsed from the operation of the compressors 100a and 100b to the time setting unit 1300. [ Then, the determination unit 1100 determines that the oil level of the oil of the first compressor 100a is lower than the oil level of the oil of the second compressor 100b based on the transmitted result. The determination unit 1100 transmits the determination result to the signal output unit 1200.

The signal output unit 1200 outputs a control signal to the first electronic expansion valve 900a so as to increase the opening degree of the first electronic expansion valve 900a to be larger than the current opening degree, for example.

In addition, the signal output unit 1200 outputs a control signal to the second electronic expansion valve 900b so as to reduce the opening degree of the second electronic expansion valve 900b to be smaller than the current opening degree as another example.

The signal output unit 1200 outputs a control signal to decrease the opening degree of the second electronic expansion valve 900b so as to increase the opening degree of the first electronic expansion valve 900a so that each of the electronic expansion valves 900a and 900b ).

Thereafter, the opening degree of the first electronic expansion valve 900a or the second electronic expansion valve 900b is changed in accordance with the control signal transmitted from the signal output section 1200.

In this case, the oil separated from the second oil separator 200b reaches the second leg portion 810b along the second oil return pipe 730b (A '). Some of the oil reaching the second leg portion 810b is recovered to the second compressor 100b (B '), while the remaining portion of the oil flows through the bypass pipe 800 (C').

On the other hand, the oil separated from the first oil separator 200a reaches the first leg portion 810a along the first oil return pipe 730a, but does not flow into the bypass pipe 800, And recovered to the compressor 100a (E).

As a result, the difference between the oil level of the oil of the first compressor 100a and the oil level of the oil of the second compressor 100b decreases and becomes equal to the oil level of the oil of the second compressor 100b.

Hereinafter, a control method of an air conditioner according to an example of the present invention will be described in detail with reference to the drawings.

6A and 6B are flowcharts showing a control method of an air conditioner according to an example of the present invention.

Referring to FIGS. 6A and 6B, operation of a plurality of compressors 100a and 100b is started (S110).

Then, it is determined whether the time set in the time setting unit 1300 has elapsed from the start of operation of the plurality of compressors 100a and 100b (S120). If the predetermined time has elapsed, step S130 will be described later. If the predetermined time has not elapsed, step S120 is performed again.

The oil level of each of the plurality of compressors 100a and 100b is measured through a plurality of oil level sensors 110a and 110b provided in each of the plurality of compressors 100a and 100b, The height is compared by the determination unit 1100 of the control unit 1000 (S130). That is, the oil level of the oil of the first compressor 100a is measured by the first oil level sensor 110a and the oil level of the oil of the second compressor 100b is measured by the second oil level sensor 110b Is measured. Thereafter, the measured oil level height of the first compressor 100a and the oil level height of the second compressor 100b are compared. In other words, whether the oil level of the oil of the first compressor 100a is lower than the oil level of the oil of the second compressor 100b or the oil level of the oil of the second compressor 100b is higher than the oil level of the oil of the first compressor 100a, Is lower than the oil level of the oil of the oil pan.

If it is determined in step S130 that the oil level of the oil of the first compressor 100a is lower than the oil level of the oil of the second compressor 100b, the controller 1000 controls the oil level of the oil recovered in the first compressor 100a And controls the electronic expansion valves 900a and 900b to decrease the amount of oil recovered by the second compressor 100b (S140).

If it is determined in step S130 that the oil level of the oil in the second compressor 100b is lower than the oil level of the oil in the first compressor 100a, the controller 1000 controls the oil level of the oil recovered in the second compressor 100b The electronic expansion valves 900a and 900b are controlled so as to increase the amount and reduce the amount of oil recovered in the first compressor 100a (S150).

If it is determined in step S130 that the oil level of the oil of the first compressor 100a is equal to the oil level of the oil of the second compressor 100b, the controller 1000 determines whether the opening degree of the electronic expansion valves 900a, (S160).

After the lapse of a predetermined time set in the time setting unit 1300, the oil level of the oil of the first compressor 100a is measured again through the first oil level sensor 110a (S140, S150, or S160) The oil level of the oil of the second compressor 100b is measured again through the second oil level sensor 110b and then the oil level of the oil of the first compressor 100a measured by the second compressor 100b is measured, (S170).

If it is determined in step S170 that the oil level of the oil of the first compressor 100a is equal to the oil level of the oil of the second compressor 100b, the controller 1000 controls the opening degree of the electronic expansion valves 900a and 900b (S180).

If it is determined in step S170 that the oil level of the oil of the first compressor 100a is not the same as the oil level of the oil of the second compressor 100b, the oil level of the oil of the first compressor 100a, It is determined whether the oil level of the oil of the oil pan 100b is less than a preset height (S190). Here, the preset height may be, for example, a height provided with the oil level sensors 110a and 110b, but is not limited thereto and may be set by a user.

If it is determined in step S190 that the height of the oil level of the first compressor 100a and the height of the oil level of the oil of the second compressor 100b are less than a preset height, the controller 1000 controls the system operation of the air conditioner Operation or heating operation) is stopped, and the oil recovery operation is entered (S200).

If it is determined in step S190 that the height of the oil level of the first compressor 100a and the height of the oil level of the second compressor 100b are not less than the predetermined height, the compressors 100a and 100b The opening degree of the electronic expansion valves 900a and 900b is controlled so that more oil is recovered (S210).

Even when a plurality of compressors 100a and 100b are used in one refrigerant cycle by the control method of the air conditioner such as the one described above, the oil level between the compressors 100a and 100b can be adjusted. That is, the failure of the compressors 100a and 100b due to the oil shortage is prevented.

Although the preferred embodiments of the present invention have been described, the present invention is not limited to the specific embodiments described above. It will be apparent to those skilled in the art that numerous modifications and variations can be made in the present invention without departing from the spirit or scope of the appended claims. And equivalents should also be considered to be within the scope of the present invention.

100: compressor 200: oil separator
300: Heat exchanger 400: Expansion part
500: accumulator 600: four-way valve
710: suction pipe 720: discharge pipe
730: Oil recovery pipe 800: Bypass piping
900: Electronic expansion valve 1000: Control unit

Claims (10)

A plurality of compressors;
A plurality of oil level sensors provided in each of the plurality of compressors for measuring an oil level of each of the plurality of compressors;
A plurality of oil separators connected to each of the plurality of compressors to separate oil from oil mixed refrigerant discharged from each of the plurality of compressors;
A plurality of oil return pipes connecting each of the plurality of compressors and each of the plurality of oil separators;
A bypass pipe connecting the plurality of oil return pipes;
An electronic expansion valve provided in at least one of the plurality of oil return pipes; And
And a control unit for controlling the opening degree of the electronic expansion valve according to the oil level height of each of the plurality of compressors.
Air conditioner.
The method according to claim 1,
When the oil level of the oil of one of the plurality of compressors is lower than the oil level of the oil of the other compressor,
Wherein the control unit increases the opening degree of the electronic expansion valve provided in the oil return pipe connected to the one compressor or reduces the opening degree of the electronic expansion valve provided in the oil return pipe connected to the other compressor,
Air conditioner.
The method according to claim 1,
When the oil level of the oil in all of the plurality of compressors is less than a preset height,
Wherein the control unit stops the operation of the air conditioner and performs the oil recovery operation,
Air conditioner.
The method according to claim 1,
Further comprising a suction pipe connecting the accumulator and the compressor,
Wherein the oil return pipe is spaced apart from the suction pipe,
Air conditioner.
The method according to claim 1,
Wherein the electronic expansion valve is disposed closer to the compressor than a joint portion of the bypass pipe and the oil return pipe located in the oil return pipe provided with the electronic expansion valve,
Air conditioner.
(a) measuring an oil level of each of the plurality of compressors through a plurality of oil level sensors provided in each of the plurality of compressors;
(b) determining whether the oil level of the oil in the first compressor, which is one of the plurality of compressors in the step (a), is lower than the oil level of the oil in the second compressor which is one compressor; And
(c) if it is determined in the step (b) that the oil level of the oil of the first compressor is lower than the oil level of the oil of the second compressor, the amount of oil recovered by the first compressor is increased, And reducing the amount of oil recovered by the compressor.
Control method of air conditioner.
The method according to claim 6,
The step (c)
(c ') If it is determined in the step (b) that the oil level of the oil of the first compressor is lower than the oil level of the oil of the second compressor, Increasing the opening degree of the first electronic expansion valve and reducing the opening degree of the second electronic expansion valve provided in the second oil return pipe connected to the second compressor,
Control method of air conditioner.
The method according to claim 6,
After the step (c)
(d) measuring an oil level of the oil of the first compressor and a oil level of the oil of the second compressor after a predetermined time elapses from the step (c);
(e) determining whether the height of the oil level of the first compressor and the height of the oil level of the second compressor are the same in the step (d);
(f) if it is determined in the step (e) that the oil level of the oil of the first compressor and the oil level of the oil of the second compressor are the same, the first oil return pipe connected to the first compressor 1 opening of the first electronic expansion valve and the opening of the second electronic expansion valve provided in the second oil return pipe connected to the second compressor,
Control method of air conditioner.
9. The method of claim 8,
The step (f)
(f ') If it is determined that the oil level of the oil of the first compressor is different from the oil level of the oil of the second compressor in the step (e), the oil level of the oil of the first compressor, Determining whether the oil level of the oil in the oil chamber is less than a predetermined height.
Control method of air conditioner.
10. The method of claim 9,
After the step (f)
(g) performing the oil recovery operation when it is determined in the step (f) that the oil level of the oil of the first compressor and the oil level of the oil of the second compressor are less than a predetermined height,
Control method of air conditioner.

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