JP2011202891A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioner capable of responding to smaller air conditioning load and load fluctuation as well as allowing enlargement of capacity by a plurality of compressors.SOLUTION: The air conditioner 10 includes an outdoor-side unit 11 having a plurality of capacity-variable type compressors A, B, C connected in parallel, an indoor-side unit 12 connected to the outdoor-side unit 11 via a refrigerant pipe 13, and a control part 21 for operating/controlling the compressors A, B, C. The plurality of compressors A, B, C have capacities different from one another. The control part 21 serially starts the compressors A, B, C from the one with smaller capacity according to the air-conditioning load of the indoor-side unit 12.

Description

  The present invention relates to an air conditioner including a plurality of compressors in a heat source unit.

In recent years, an air conditioner having a refrigerant circuit in which a plurality of indoor units are connected to a large-capacity outdoor unit by a refrigerant pipe is used in a relatively large facility such as a building or a large store. This type of outdoor unit includes a plurality of compressors, and is configured to be able to cope with a high air conditioning load by controlling the operation of the plurality of compressors.
For example, Patent Document 1 discloses an air conditioner in which a plurality of variable capacity compressors are incorporated in a plurality of outdoor units, and the operation rotational speed of each compressor is controlled according to an air conditioning load. Has been.

International Publication No. 2004/088821

  In order to increase the capacity of the outdoor unit in order to cope with a higher air conditioning load, it is conceivable to increase the number of compressors built in the outdoor unit or increase the capacity of each compressor. However, the former case is not preferable because the outdoor unit increases in size and costs. In the latter case, if each compressor has a large capacity, it is impossible to cope with a small air-conditioning load, and it is difficult to cope with a small load fluctuation with good responsiveness. In the technique described in Patent Document 1, no particular consideration is given to dealing with such a small air conditioning load or load fluctuation.

  Also, recently, more than one compressor is operated more efficiently when the air conditioning load is small or medium rather than when all compressors are operated at the maximum capacity when the air conditioning load is large. Therefore, it is important to improve the capacity of the outdoor unit.

  An object of this invention is to provide the air conditioning apparatus which can respond to smaller air-conditioning load and load fluctuation | variation, while enabling large capacity (capacity increase) with a some compressor.

(1) The air conditioner of the present invention includes a heat source unit having a plurality of variable capacity compressors connected in parallel, a use side unit connected to the heat source unit via a refrigerant pipe, and the compressor. In the air conditioner including the control unit for operation control, the plurality of compressors have different capabilities from each other, and the control unit has a smaller capability according to the air conditioning load of the usage-side unit. It is characterized by starting sequentially from the compressor.

  The heat source unit of the air conditioner of the present invention includes a plurality of variable capacity compressors having different capacities. Then, the plurality of compressors are activated in order from the compressor having the smaller capacity by the control unit. Therefore, it is possible to operate the compressor in response to a smaller air conditioning load, and it is possible to cope with smaller fluctuations in the air conditioning load with good responsiveness. Further, when the air conditioning load of the use side unit increases, it is possible to cope with a higher air conditioning load by starting a compressor having a larger capacity.

(2) The control unit may be configured such that the operating capacity of the operating compressor is the lowest capacity of the operating compressor, and the other compressors in the stopped state whose starting priority is one lower than that of the operating compressor. It may be configured to activate the other compressor when the total becomes higher than a predetermined value with the minimum capacity.

  In the case where a plurality of compressors are provided, if these operating times are biased, the service life of a specific compressor is shortened, and the service life of the entire heat source unit is shortened. Further, since the efficiency of the compressor becomes worse as the operating capacity is higher, it is not preferable that only a specific compressor is operated at a high capacity. In the present invention, other compressors can be operated at the same time when the operating capacity of the operating compressor is relatively low, so that the operating time can be leveled and deterioration of efficiency can be prevented.

(3) When the plurality of compressors operate at the minimum capacity and the required capacity corresponding to the air conditioning load of the use side unit is further reduced, the control unit starts from a compressor with a lower starting priority. It may be configured to stop.
In this case, more compressors can be operated simultaneously with the lowest possible air conditioning load, and the operation time of the plurality of compressors can be leveled to prevent deterioration in efficiency.

(4) The control unit may be configured to operate each compressor with a capacity corresponding to a ratio of the minimum capacity of each compressor while the plurality of compressors are operating.
With such a configuration, only a specific compressor does not operate with high capacity, and each compressor can be operated efficiently according to capacity.
In addition, for example, when the air conditioning load of the use side unit is reduced and the operation capacity of all the compressors is reduced to the minimum capacity and the operation capacity of a certain compressor reaches the minimum, If the operating capacity of the compressor does not reach the minimum capacity, it is necessary to rapidly reduce the operating capacity of the compressor, and the efficiency deteriorates. In the present invention, such a problem can be solved.

(5) The said control part may be comprised so that each compressor may be operated by the capability according to the ratio of the maximum capability of each compressor, while the some compressor is drive | operating.
With such a configuration, only a specific compressor does not operate with high capacity, and each compressor can be operated efficiently according to capacity.
Also, for example, when the air conditioning load of the user side unit increases and the operation capacity of all the compressors is increased to the maximum capacity, even if the operation capacity of a certain compressor reaches the maximum, other compression If the operating capacity of the machine does not reach the maximum capacity, it is necessary to rapidly increase the operating capacity of the compressor, and the efficiency deteriorates. In the present invention, such a problem can be solved.

  According to the present invention, it is possible to cope with smaller air-conditioning loads and load fluctuations while increasing the capacity with a plurality of compressors.

It is a schematic structure figure showing the air harmony device concerning a 1st embodiment of the present invention. It is a schematic diagram which shows the compressor of the air conditioning apparatus shown by FIG. It is a flowchart which shows the procedure of starting / stopping control of a compressor. It is a graph which shows the change of the driving capability of a compressor. It is the a section enlarged view of FIG. It is a schematic diagram which shows the compressor of the air conditioning apparatus which concerns on the 2nd Embodiment of this invention. It is a flowchart which shows the procedure of the starting / stopping control of the compressor in the embodiment. It is a graph which shows the change of the driving capability of the compressor concerning a modification. It is the c section enlarged view of FIG.

<< First Embodiment >>
[Overall configuration of air conditioner]
FIG. 1 is a configuration diagram illustrating an air conditioner 10 according to a first embodiment of the present invention.
The air conditioning apparatus 10 according to the present embodiment includes a refrigerant circuit that performs a vapor compression refrigeration cycle by circulating the refrigerant. The refrigerant circuit includes an outdoor unit (heat source unit) 11, an indoor unit (use unit) 12, and a refrigerant pipe 13 connecting them.

The indoor unit 12 includes an expansion mechanism 15 and an indoor heat exchanger 16. The expansion mechanism 15 uses an electric expansion valve capable of adjusting the refrigerant pressure and the refrigerant flow rate.
The indoor side heat exchanger 16 is, for example, a cross fin tube type heat exchanger, and is used to exchange heat with indoor air. The indoor unit 12 is configured to take in indoor air into the indoor unit 12 by a fan (not shown), exchange heat with the indoor heat exchanger 16, and then blow it out indoors. In addition, in the air conditioning apparatus 10 of this Embodiment, the indoor unit 12 is made into one unit, However, Two or more indoor units 12 may be connected in parallel.

  The outdoor unit 11 includes compressors A and B, an outdoor heat exchanger 18, and a four-way switching valve 19. The outdoor unit 11 is provided with two compressors A and B, and these two compressors A and B are connected in parallel. Each of the compressors A and B is a variable capacity type (variable capacity type) compressor, and the operation speed of the motor is changed stepwise or continuously by inverter control of the built-in motor. Is possible.

  The outdoor heat exchanger 18 is a cross fin tube type heat exchanger, for example, and is used for exchanging heat with a refrigerant using air as a heat source. The outdoor unit 11 is configured to take outside air into the inside by a fan (not shown), and perform heat exchange with the outdoor heat exchanger 18 and then blow out to the outside.

The four-way switching valve 19 reverses the flow of the refrigerant, switches the refrigerant discharged from the compressors A and B to the outdoor heat exchanger 18 and the indoor heat exchanger 16, and supplies the cooling operation and the heating operation. And can be switched.
Specifically, at the time of cooling operation, the four-way switching valve 19 is switched as indicated by a solid line so that the refrigerant flows in the direction indicated by the solid line arrow, thereby causing the refrigerant discharged from the compressors A and B to flow outside the outdoor heat exchanger. 18 and the refrigerant that has passed through the expansion mechanism 15 is supplied to the indoor heat exchanger 16. At this time, the outdoor heat exchanger 18 functions as a condenser, condenses and liquefies the high-temperature and high-pressure gas refrigerant compressed by the compressors A and B, and the indoor heat exchanger 16 functions as an evaporator. The low-temperature and low-pressure liquid refrigerant after passing through the mechanism 15 is evaporated and vaporized.

  During the heating operation, the refrigerant flow is reversed by switching the four-way switching valve 19 as indicated by the dotted line, and the refrigerant flows in the direction indicated by the dotted arrow. As a result, the outdoor heat exchanger 18 functions as an evaporator to evaporate and vaporize the low-temperature and low-pressure liquid refrigerant after passing through the expansion mechanism 15, and the indoor heat exchanger 16 functions as a condenser. The high-temperature and high-pressure gas refrigerant compressed by A and B is condensed and liquefied.

  The expansion mechanism 15, the four-way switching valve 19, the compressors A and B, and the like are operated by a controller (control unit) 21 in accordance with an on / off operation of an operation switch of the air conditioner 10 and sensor outputs such as a temperature sensor and a pressure sensor. Be controlled. In particular, the compressors A and B are controlled by the controller 21 so as to satisfy the required capacity corresponding to the air conditioning load of the indoor unit 12. The air conditioning load varies depending on, for example, the indoor air condition (temperature, humidity), and when a plurality of indoor units 12 are connected, the operation of any indoor unit 12 is performed. It also fluctuates when is started or stopped.

[Compressor operation control]
As described above, the outdoor unit 11 of the present embodiment incorporates two variable capacity compressors A and B, and the compressors A and B have different capacities. It is supposed to be. In the present embodiment, the compressor indicated by A is a small capacity compressor, and the compressor indicated by B is a high capacity compressor.
For example, as shown in FIG. 2, the small capacity compressor A has a capacity (capacity) of 2 to 20 (kw), and the large capacity compressor B has a capacity of 3 to 25 (kw). (Capacity).

  In the air conditioner 10 of the present embodiment, starting priority is set for the two compressors A and B, and the controller 21 starts in order from the compressors A and B having the highest starting priority. Operation control is performed so that Further, the controller 21 performs operation control so that the compressors A and B in operation are stopped in the order opposite to the starting priority order. And this starting priority is set so that the compressor A having a smaller capacity is higher.

  In this embodiment, since the capacity of the compressor A is 2 to 20 (kw) and the capacity of the compressor B is 3 to 25 (kw), the starting priority of the compressor A is high, and the compressor B The boot priority of is low.

Hereinafter, the operation control (start / stop control) of the compressors A and B will be described in detail with the numerical values shown above as an example.
FIG. 3 is a flowchart showing the operation control procedure of the compressor. FIG. 4 is a graph showing changes in the operating capacities of the compressors A and B, and FIG. 5 is an enlarged view of part a in FIG.
As shown in FIG. 3, when receiving an operation start signal by operating an operation switch (not shown) (step S1), the controller 21 first starts the compressor A having a lower capacity according to the start priority (step S2). ). The compressor A is controlled in operating capacity (operating speed) so as to satisfy the required capacity corresponding to the operating state of the indoor unit 12 and the air conditioning load. The compressor A becomes an independent operation until the compressor B is started.

  Thus, by starting the compressor A having a smaller capacity (capacity) in preference to the compressor B, the outdoor unit 11 can be operated in response to a smaller air conditioning load. In other words, the larger the capacity (capacity) of the compressor, the larger the displacement of the refrigerant, and the more difficult it becomes to operate at a low rotational speed. It is possible to perform the operation with a number and to cope with a smaller air conditioning load. In addition, since a compressor having a smaller capacity can cope with a smaller load fluctuation with higher responsiveness, starting the compressor A having a smaller capacity in preference to the compressor B causes a smaller load fluctuation. Can also respond.

  Next, the controller 21 determines whether or not the operating capacity of the compressor A is increased (whether or not the required capacity is increased) according to the required capacity based on the air conditioning load of the indoor unit 12. (Step S3). When the operating capacity of the compressor A is increased, the controller 21 next determines whether or not the operating capacity of the compressor A is equal to or greater than a predetermined value Z1 (step S4). And when the driving capability of the compressor A is more than the predetermined value Z1, the compressor B is started (step S5).

The condition of step S4 will be described in detail.
The predetermined value Z1, which is a condition for starting the compressor B, is given by the sum of the minimum capacity PA _min of the compressor A and the minimum capacity PB _min of the compressor B as shown in the following equation (1). is a value obtained by multiplying the constant alpha ₁ in.
Z1 = (PA _min + PB _min ) × α ₁ (1)

That is, in this embodiment, the minimum capacity of the compressor A is PAmin = 2 (kw), since a minimum capacity of the compressor B is _PB min = 3 (kw), the sum of these is 5 (kw) When a predetermined constant α ₁ is applied, Z1 = 5α ₁ (kw) is obtained. And if the driving capability of the compressor A becomes ₅ (alpha) ₁ (kw) or more, the controller 21 will start the compressor B (step S5).

The constant α ₁ is a value that satisfies α ₁ > 1, and is set to α ₁ = 1.2 to 1.5, for example. In this case, the predetermined value Z1 is 5 × 1.2 to 1.5 = 6.0 to 7.5 (kw). That is, when the operating capacity of the compressor A reaches 6.0 to 7.5 (kw), the compressor B is started. In the present embodiment, it is assumed that α ₁ = 1.2 and that the compressor B is started when the operating capacity of the compressor A reaches 6 (kw) (see FIG. 5).

Predetermined value Z1 is, without considering the constant alpha _1,
Z1 = PA _min + PB _min (1) ′
It is also possible. However, in this case, a predetermined value Z2 that is a stop condition of the compressor B, which will be described later, and the predetermined value Z1 coincide with each other, and if the air conditioning load fluctuates in the vicinity of the predetermined values Z1 and Z2, the compressor B is started. Stops (starts and stops) are frequently performed in a short time. Such start / stop is a burden on the compressor, which increases energy consumption and decreases efficiency. Therefore, as the predetermined value Z1, by a value obtained by adding the constant alpha ₁ as in the above formula (1), it is possible to reduce the start-stop of the compressor B.

  Further, the predetermined value Z1 is a value at which both the compressors A and B can be operated in a state of almost the minimum capacity, and by starting both the compressors A and B in such a low capacity state, The operation time can be leveled as much as possible, and a decrease in the service life of the outdoor unit 11 due to variations in the operation time can be prevented. Further, since the efficiency of the compressors A and B deteriorates as the operating rotational speed is higher, the compressor A is prevented from rotating alone to a high rotational speed, thereby enabling more efficient operation.

The predetermined value Z1 is set by multiplying (PA _min + PB _min ) by a constant α ₁ , but a predetermined value, for example, a value of about 1 to 2 is added to (PA _min + PB _min ). It may be set by

When the two compressors A and B are started, the controller 21 sets the operation capacity PA of the compressor A and the operation capacity PB of the compressor B to the minimum capacity PA, as shown in the following equation (2). Distribution is performed based on the ratio of _min and PB _min (step S6).
PA: PB = PA _min : PB _min (2)

In the case of the present embodiment, the compressor A and the compressor B have a ratio of the minimum capacities PA _min and PB _min of 2 (kw): 3 (kw). To do.
In the above example, since the compressor B starts when the operating capacity of the compressor A reaches 6 (kw), both of the compressors A and B have a total operating capacity of 6 (kw). Distribute abilities at a ratio of (2: 3). Therefore, the operation capacity of the compressor A is 2.4 (kw), and the operation capacity of the compressor B is 3.6 (kw) (see FIG. 5).

Thus, by performing capacity distribution according to the ratio of the minimum capacity of the compressors A and B (PA _min : PB _min ), both the compressors A and B can be operated in a well-balanced manner. The efficiency does not deteriorate due to excessive increase in the driving capability of the machine.

As shown in FIG. 4, when the required capacity increases according to the air conditioning load of the indoor unit 12, the compressors A and B increase the operating capacity while maintaining the above ratio (2: 3). However, in the present embodiment, the maximum capacities PA _max and PB _max of the compressors A and B are 20 (kw) and 25 (kw), respectively (see FIG. 2), and the ratio of the maximum capacities PA _max and PB _max Is different from the minimum capacity ratio (2: 3). Therefore, before reaching 45 (kw), which is the sum of the maximum capacities PA _max and PB _max of both the compressors A and B, the compressor B first reaches the maximum capacity of 25 (kw). Only the machine A increases the driving ability up to the maximum 20 (kw). At this time, even if the increase in the operating capacity of the compressor B stops, the increasing rate of the operating capacity of the compressor A is temporarily increased so that the increase rate of the entire operating capacity does not fluctuate extremely (FIG. 4). B). Thereby, until the compressors A and B reach the maximum capacity, the overall operation capacity can be increased smoothly.

On the contrary, when the required capacity decreases from the state where the compressors A and B are operating at the maximum capacities PA _max and PB _max , the sum of the operating capacities of both the compressors A and B decreases with a certain slope. The compressors A and B are controlled. In this case, until the ratio of the two compressors A and B reaches the above ratio (2: 3), the operation capacity of only the compressor A is reduced, and the compressor B operates with the maximum capacity of 25 (kW). Continue. Then, when the ratio of the operating capacities of the compressors A and B reaches (2: 3), the operating capacities of both the compressors A and B are reduced. At this time, the decreasing rate of the operating capacity of the compressor A is moderate so that the decreasing rate of the operating capacity as a whole does not fluctuate extremely (see part b in FIG. 4).

As shown in FIG. 3, the controller 21 determines whether or not the compressors A and B are operating at the minimum capacity (minimum number of rotations) PA _min and PB _min while the two compressors A and B are operating. Is determined (step S7 in FIG. 3). That is, the controller 21 determines whether or not the sum of the operating capacities of the compressors A and B has reached a predetermined value Z2 indicated by the following equation (3).
_{Z2 = (PA min + PB min} ) ··· (3)

In the present embodiment, since the minimum capacity PA _min of the compressor A is 2 (kw) and the minimum capacity PB _min of the compressor B is 3 (kw), Z2 = 5 (kw).

When it is determined that the compressors A and B are operating at the minimum capacity, the controller 21 then lowers the operating capacity of the compressors A and B according to the required capacity based on the air conditioning load. It is determined whether or not there is (required capacity is reduced) (step S8). In a situation where both the compressors A and B are operating at the minimum capacities PA _min and PB _min , since both cannot reduce the operating capacity any more, the operating capacity of the compressors A and B is further reduced. In this case, the controller 21 stops the compressor B having a low starting priority (step S9). As a result, as shown in FIG. 5, in a region where the required capacity is low, it is possible to cope with small air conditioning loads and small load fluctuations with good responsiveness by operating the compressor A having a smaller capacity alone. .

  When the operating capacity of the compressors A and B becomes 5 (kw) and the compressor B stops, the controller 21 performs control to increase the operating capacity of the compressor A to 5 (kw). Thereby, it is considered that the entire operation capacity does not stop suddenly as the compressor B stops.

  When the operation is switched to the operation of only the compressor A, the process returns to step S3 in FIG. 3, and the compressor B is started again when a predetermined condition is satisfied by the procedure of steps S3 to S5. In the flowchart shown in FIG. 3, the description about the operation stop of the air conditioner 10 is omitted, but when the controller 21 receives the operation stop signal during the operation of the air conditioner 10, all the compressors A, The operation of B is stopped and the process is terminated.

<< Second Embodiment >>
Although 1st Embodiment demonstrated the case where the two compressors A and B were provided in the outdoor unit 11, as shown in FIG. 6, the outdoor unit 11 has three compressors. A, B, and C may be provided. Hereinafter, operation control when three compressors A, B, and C are provided will be described.
In the present embodiment, the capacities of the compressors A and B are the same as those in the first embodiment, and the capacities of the compressor C are 5 to 30 (kw) larger than those of the compressors A and B. Therefore, the starting priority is A → B → C, and the stopping order is reversed.

FIG. 7 is a flowchart showing the operation control procedure of the compressor according to the second embodiment. In the present embodiment, the operation control procedures (steps S1 to S9) of the two compressors A and B with smaller capacities are the same as the operation control procedure of the first embodiment shown in FIG. The procedure for starting and stopping the third compressor C is newly added to the procedure.
Specifically, when the conditions of steps S7 and S8 in FIG. 7 are not satisfied (No), the process proceeds to step S13 instead of returning to the process of step S7 again. Then, the controller 21 determines whether or not the operating capacity of the compressors A and B is increased (whether or not the required capacity is increased) according to the required capacity based on the air conditioning load. When the operating capacity of the compressors A and B is increased, the controller 21 next determines whether or not the operating capacity of the compressors A and B is equal to or greater than a predetermined value Z3 represented by the following equation (4). Judgment is made (step S14). Then, when the operating capacities of the compressors A and B are equal to or greater than the predetermined value Z3, the compressor C is started (step S15).

The predetermined value Z3, which is a condition for starting the compressor C, is expressed by the following formula (4): the minimum capacity PA _min of the compressor A, the minimum capacity PB _min of the compressor B, and the compressor C the sum of the minimum capacity PC _min of being a value obtained by multiplying a predetermined constant alpha _2.
Z3 = (PA _min + PB _min + PC _min ) × α ₂ (4)

That is, in this embodiment, the minimum capacity of the compressor A is PA _min = 2 (kw), the minimum capacity of the compressor B is PB _min = 3 (kw), and the minimum capacity of the compressor B is PC _min = 5 ( kw), the sum of these is 10 (kw), and when multiplied by a predetermined constant α ₂ , 10α ₂ (kw) is obtained. Then, when the operating capacities of the compressors A and B become 10α ₂ (kw) or more, the compressor C is started (step S15).

The constant α ₂ is a value that satisfies α ₂ > 1, as with the constant α _{1 of the first} embodiment, and is set to α ₂ = 1.2 to 1.5, for example. In this case, the value of the predetermined value Z3 is 10 × 1.2 to 1.5 = 12.0 to 15.0 (kw). That is, when the sum of the operating capacities of the compressors A and B becomes 12.0 to 15.0 (kw), the compressor C is started. α ₂ may be a value different from α ₁ , but in the present embodiment, α ₂ = 1.2 similarly to α _1, and the total operation capacity of the compressors A and B is 12 (kw). Suppose that the compressor C is started up when the value is reached.

When the three compressors A, B, and C are started, the controller 21 calculates the operation capability PA of the compressor A, the operation capability PB of the compressor B, and the operation capability PC of the compressor C using the formula (5). Based on the predetermined distribution.
_{PA: PB: PC = PA min} : PB min: PC min ··· (5)

In the present embodiment, the compressors A, B, and C have a minimum capacity ratio (PA _min : PB _min : PC _min ) of 2 (kw): 3 (kw): 5 (kw). Therefore, the driving capacity is distributed according to this ratio.
In the above example, since the compressor C is activated when the operating capacities of the compressors A and B reach 12 (kw), the sum of the operating capacities of the compressors A, B, and C is 12 (kw). Distribute these abilities in a ratio of (2: 3: 5). Therefore, the operating capacity of the compressor A is 2.4 (kw), the operating capacity of the compressor B is 3.6 (kw), and the operating capacity of the compressor C is 6.0 (kw). Thus, by performing capacity distribution according to the ratio of the minimum capacity of the compressors A, B, and C, all the compressors can be operated in a balanced manner, and the operating capacity of any of the compressors is excessively increased. The efficiency will not deteriorate.

While the three compressors A, B, and C are operating, the controller 21 determines whether the compressors A, B, and C are operating at the minimum capacity (minimum rotation speed) PA _min , PB _min , and PC _min. Is determined (step S17 in FIG. 7). That is, the controller 21 determines whether or not the sum of the operating capacities of the compressors A, B, and C has reached a predetermined value Z4 expressed by the following equation (6).
_{Z4 = (PA min + PB min} + PC min) ··· (6)

In the present embodiment, the minimum capacity PA _min of the compressor A is 2 (kw), the minimum capacity PB _min of the compressor B is 3 (kw), and the minimum capacity PC _min of the compressor C is 5 ( kw), Z4 = 10 (kw).

When it is determined that the compressors A, B, and C are operating at the minimum capacity, the controller 21 next operates the compressors A, B, and C according to the required capacity based on the air conditioning load. It is determined whether or not it is necessary to lower (required capacity is reduced) (step S18). In the situation where the compressors A, B, and C are all operating at the minimum capacities PA _min , PB _min , and PC _min , the operating capacities cannot be lowered any more, so the compressors A, B, and C are operated. When the capacity is lower, the controller 21 stops the compressor C having a lower start priority (step S19).

When the compressor C stops, the controller 21 increases the operating capacity of the compressors A and B, and controls so that the total operating capacity of the compressors A and B becomes 10 (kw). Thus, consideration is given to the fact that the overall operating capacity does not drop rapidly as the compressor C stops. Further, the compressor A, when switched to the only operation B, the process returns to step S6 again, the compressor A, a minimum capacity _{PA min,} the ratio of _{PB min} of B (2: 3) to distribute the capacity in accordance with the.

The present invention is not limited to the embodiment described above, and can be appropriately changed in design.
For example, in the first and second embodiments, when a plurality of compressors are operating together, the ratio of these minimum capacities (PA _min : PB _min = 2: 3) or (PA _min : PB _The capacity is distributed at _min : PC _min = 2: 3: 5). As a modified example, the ratio of the maximum capacity of both (PA _max : PB _max = 20: 25 (= 4: 5). )) Or (PA _max : PB _max : PC _max = 20: 25: 30 (= 4: 5: 6)).

For example, when the outdoor unit 11 includes two compressors A and B, as shown in FIG. 8, the compressors A and B are the sum of the maximum capacities PA _max and PB _max 45 (kw). The driving ability is increased while maintaining the ratio (4: 5) until the value reaches. That is, in the first embodiment shown in FIG. 4, the compressor B first reached the maximum capacity PB _max, and the operating capacity of the compressor A had to be rapidly increased (see part b in FIG. 4). By distributing the capacities at a ratio (4: 5) of the maximum capacities PA _max and PB _max of the compressors A and B, there is no need to rapidly increase the operating capacity of one compressor A (d in FIG. 8). Part) and both compressors A and B can be operated in a balanced manner in the high capacity range.
Further, when the operating capacity is reduced from the state where the compressors A and B are operated at the maximum capacity 45 (kw), the operating capacity of both the compressors A and B is maintained while maintaining the ratio (4: 5). Can be reduced smoothly without sudden fluctuations.

However, in this modification, as shown in FIG. 9, immediately before the stop of the compressor B, the operating capacity of the compressor B reaches the minimum capacity PB _min (= 3 (kw)) first. There is also a detrimental effect that the driving ability needs to be reduced temporarily but temporarily.
Therefore, in order to eliminate the adverse effects of the first and second embodiments (FIGS. 4 and 5) and the modified examples (FIGS. 8 and 9) as described above, the region where the driving ability is low (for example, the sum of the driving ability). Is less than 20 (kw)), the operating capacity of the compressors A and B is distributed at the ratio (2: 3) of the minimum capacity PA _min and PB _min , and in the region where the operating capacity is high (20 (kw) or more) The operating capacities of the compressors A and B may be distributed at a ratio (4: 5) of the maximum capacities PA _max and PB _max .

  The numerical values (kw) of the capacities of the compressors A, B, and C shown in the above embodiment are merely examples, and are not limited thereto. Moreover, it is preferable to combine a compressor with a small capacity | capacitance and a compressor with a large capacity | capacitance by the ratio of maximum rotation speed by 1: 1.5-1: 2.5, and it is more preferable to set it as 1: 2.

10: Air conditioner 11: Outdoor unit (heat source unit)
12: Indoor unit (use side unit)
13: Refrigerant piping 21: Controller (control unit)
A, B, C: Compressor

Claims (5)

A heat source unit (11) having a plurality of variable capacity compressors (A, B, C) connected in parallel, and a use side unit (connected to the heat source unit (11) via a refrigerant pipe (13) ( 12) and an air conditioner comprising a controller (21) for controlling the operation of the compressor (A, B, C),
The plurality of compressors (A, B, C) have different capabilities from each other,
The said control part (21) starts sequentially from the compressor (A, B, C) with smaller capacity | capacitance according to the air-conditioning load of the said utilization side unit (12), The air conditioning apparatus characterized by the above-mentioned.   The controller (21) is configured such that the operating capacity of the operating compressor (A, B, C) is the minimum capacity of the operating compressor (A, B, C) and the operating compressor (A , B, C) when the starting priority is one lower than the sum of the minimum capacities of the other compressors (A, B, C) that are stopped, the other compressor ( The air conditioning apparatus according to claim 1, wherein A, B, C) is activated.   The control unit (21) operates when a plurality of the compressors (A, B, C) are operated at the minimum capacity and the required capacity corresponding to the air conditioning load of the use side unit (12) is reduced. The air conditioner according to claim 1 or 2, wherein the compressor (A, B, C) having a lower starting priority is stopped. While the plurality of compressors (A, B, C) are in operation, the control unit (21) has the minimum capacity (PA _min , PB _min , PC _min ) of each compressor (A, B, C). The air conditioner according to any one of claims 1 to 3, wherein each compressor (A, B, C) is operated with a capacity according to a ratio. While the plurality of compressors (A, B, C) are operating, the control unit (21) has the maximum capacity (PA _max , PB _max , PC _max ) of each compressor (A, B, C). The air conditioner according to any one of claims 1 to 3, wherein each compressor (A, B, C) is operated with a capacity according to a ratio.

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