JP7159736B2 - air conditioner - Google Patents

Description

The present invention relates to an air conditioner in which a plurality of indoor units are connected to an outdoor unit.

In an air conditioner in which multiple indoor units are connected to an outdoor unit, the evaporating temperature in the indoor heat exchanger of each indoor unit that functions as an evaporator during cooling operation is set to a predetermined target value (hereinafter referred to as the target evaporating temperature). Also, during heating operation, the condensation temperature in the indoor heat exchanger of each indoor unit that functions as a condenser is a predetermined target value (hereinafter referred to as the target condensation temperature) that is different from that during cooling operation. There is one in which the rotation speed of the compressor is controlled so as to be (for example, Patent Document 1). Here, the target evaporating temperature and the target condensing temperature are the evaporating temperature and the condensing temperature required for the indoor unit to exhibit the rated capacity, which is the maximum value of the air conditioning capacity exhibited by the indoor unit. In the air conditioner of Patent Document 1, the target evaporation temperature and the target condensation temperature are not changed even when the air conditioning capacity required by each indoor unit is all smaller than the rated capacity, and the evaporation temperature and the condensation temperature are always the target. The rotation speed of the compressor is controlled so as to achieve the evaporation temperature and the target condensation temperature. For this reason, in the air conditioner of Patent Document 1, there is a problem that the compressor is driven at an unnecessarily high rotational speed, resulting in deterioration of energy saving performance.

On the other hand, during cooling operation and heating operation, the target evaporating temperature and An air conditioner in which a target condensing temperature is determined has been proposed (for example, Patent Document 2). In the air conditioner described in Patent Literature 2, during cooling operation, if the air conditioning capacity required by each indoor unit is smaller than the rated capacity, the target evaporation temperature is higher than the rated capacity. Further, during heating operation, if the air conditioning capacity required for each indoor unit is smaller than the rated capacity, the temperature of the target condensing capacity is lower than the rated capacity. Then, the rotational speed of the compressor is controlled so that the evaporation temperature and the condensation temperature reach the target evaporation temperature and the target condensation temperature. Therefore, unlike the air conditioner of Patent Document 1, the compressor is not driven at an unnecessarily high rotational speed, and the power consumption of the air conditioner is suppressed, thereby improving energy saving.

JP-A-2-230063 JP 2014-238179

By the way, when an air conditioner having a plurality of indoor units is performing air-conditioning operation, some of the indoor units may be in operation and some may be inactive. When the stopped indoor unit starts to operate, the temperature difference between the set temperature and the indoor temperature in the indoor unit that starts operation (hereinafter referred to as the operation start indoor unit) The temperature difference between the set temperature and the room temperature of the indoor unit (hereinafter referred to as the already operating indoor unit) becomes larger than the temperature difference, and the air conditioning capacity required by the operating indoor unit may become larger than the air conditioning capacity required by the already operating indoor unit. be.

In the above case, if the rotation speed of the compressor is controlled so that the target evaporating temperature or target condensing temperature can be achieved according to the air conditioning capacity required by the indoor unit that has started operating, There is a risk that the capacity will be significantly larger than the air conditioning capacity actually required by the indoor units already in operation. In such a state, until the indoor temperature detected by the indoor unit that has started operating reaches the set temperature, there is a risk that the already operating indoor unit will exhibit more air conditioning capacity than required and will frequently repeat thermo-off/thermo-on.

The present invention solves the problems described above, and when controlling the rotation speed of the compressor according to the air conditioning capacity required by each indoor unit, the comfort when the operation start indoor unit appears An object of the present invention is to provide an air conditioner capable of improving

In order to solve the above problems, the air conditioner of the present invention provides an outdoor unit having a compressor, a plurality of indoor units having indoor temperature detection means for detecting the indoor temperature, and driving control of the compressor. and control means. The control means takes in the indoor temperature detected by the indoor temperature detection means from each indoor unit and the set temperature, which is the target temperature for air conditioning operation set in each indoor unit, and subtracts the indoor temperature from the set temperature for each indoor unit. The maximum required capacity is determined based on the largest maximum temperature difference among the absolute values of each temperature difference. Then, when there is an operation-started indoor unit that has started operating from a stopped state during air-conditioning operation, the control means subtracts a predetermined capacity subtraction value from the maximum required capacity if the required capacity reduction condition is satisfied. This value is used as the system required capacity for determining the compressor rotation speed, and if the required capacity reduction condition is not satisfied during the air conditioning operation, the maximum required capacity is taken as the system required capacity. The required capacity reduction condition is that the number of indoor units that have started operation from a stopped state is one, and the required capacity of the indoor unit that has started to operate is the maximum required capacity, and the number of indoor units other than the Each temperature difference in the already operating indoor units is within a predetermined range, and the temperature difference of the operating indoor unit is larger than the average value of the temperature differences of the already operating indoor units by a predetermined value. do.

In the air conditioner of the present invention as described above, if the required capacity reduction condition is satisfied during air conditioning operation, the value obtained by subtracting the capacity subtraction value from the required capacity of the indoor unit at which operation is started is taken as the system required capacity, and the required capacity reduction condition is not established, the required capacity of the indoor unit that has started operation is taken as the system required capacity. As a result, when the number of revolutions of the compressor is controlled according to the air conditioning capacity required by each indoor unit, frequent repetition of thermo-off/thermo-on of already operating indoor units when an indoor unit starts operation is suppressed. can

BRIEF DESCRIPTION OF THE DRAWINGS It is explanatory drawing of the air conditioning apparatus in embodiment of this invention, (A) is a refrigerant circuit diagram, (B) is a block diagram of an outdoor unit control means. It is an indoor unit operating state table in the embodiment of the present invention. Fig. 4 is a flow chart showing processing for determining the air conditioning capacity required by each indoor unit in the embodiment of the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. As an embodiment, an air conditioner in which ten indoor units are connected in parallel to an outdoor unit and all of the indoor units can perform cooling operation or heating operation at the same time will be described as an example. The present invention is not limited to the following embodiments, and various modifications can be made without departing from the gist of the present invention.

As shown in FIG. 1A, the air conditioner 1 in this embodiment includes one outdoor unit 2 and ten indoor units connected in parallel to the outdoor unit 2 via liquid pipes 8 and gas pipes 9. 5-1 to 5-10 (only two of them are drawn in FIG. 1(A)). More specifically, the closing valve 25 of the outdoor unit 2 and the liquid pipe connection portion 53 of each indoor unit 5 are connected by the liquid pipe 8 . Also, the closing valve 26 of the outdoor unit 2 and the gas pipe connection portion 54 of each indoor unit 5 are connected by the gas pipe 9 . Thus, the outdoor unit 2 and the ten indoor units 5 are connected by the liquid pipes 8 and the gas pipes 9 to form the refrigerant circuit 10 of the air conditioner 1 .

<Configuration of outdoor unit>
First, the outdoor unit 2 will be explained. The outdoor unit 2 includes a compressor 21, a four-way valve 22, an outdoor heat exchanger 23, an outdoor unit expansion valve 24, a closing valve 25 to which the liquid pipe 8 is connected, and a closing valve to which the gas pipe 9 is connected. 26 , an accumulator 27 , an outdoor unit fan 28 , and an outdoor unit control means 200 . These devices except for the outdoor unit fan 28 and the outdoor unit control means 200 are connected to each other by refrigerant pipes described in detail below to form an outdoor unit refrigerant circuit 20 forming a part of the refrigerant circuit 10. ing.

The compressor 21 is a variable capacity compressor that can vary its operating capacity by being driven by a motor (not shown) whose rotational speed is controlled by an inverter. A refrigerant discharge side of the compressor 21 is connected to a port a of the four-way valve 22 to be described later by a discharge pipe 41 . The refrigerant suction side of the compressor 21 is connected to the refrigerant outflow side of the accumulator 27 by a suction pipe 42 .

The four-way valve 22 is a valve for switching the direction of refrigerant flow in the refrigerant circuit 10, and has four ports a, b, c, and d. The port a is connected to the refrigerant discharge side of the compressor 21 by the discharge pipe 41 as described above. The port b is connected to one refrigerant inlet/outlet of the outdoor heat exchanger 23 by a refrigerant pipe 43 . The port c is connected to the refrigerant inflow side of the accumulator 27 by a refrigerant pipe 46 . The port d is connected to the closing valve 26 and the outdoor unit gas pipe 45 .

The outdoor heat exchanger 23 exchanges heat between the refrigerant and outside air taken into the outdoor unit 2 by the rotation of the outdoor unit fan 28, which will be described later. As described above, one refrigerant inlet/outlet of the outdoor heat exchanger 23 and the port b of the four-way valve 22 are connected by the refrigerant pipe 43 . The other refrigerant inlet/outlet of the outdoor heat exchanger 23 and the closing valve 25 are connected by an outdoor unit liquid pipe 44 . The outdoor heat exchanger 23 functions as a condenser 6 when the air conditioner 1 performs a cooling operation, and functions as an evaporator when the air conditioner 1 performs a heating operation.

The outdoor unit expansion valve 24 is provided in the outdoor unit liquid pipe 44 . The outdoor unit expansion valve 24 is an electronic expansion valve driven by a pulse motor (not shown). , the amount of refrigerant flowing out of the outdoor heat exchanger 23 is adjusted. The degree of opening of the outdoor unit expansion valve 24 is set so that the degree of superheating of the refrigerant on the refrigerant outlet side of the outdoor heat exchanger reaches the target degree of superheating of the refrigerant, which will be described later, when the air conditioner 1 is performing heating operation. is adjusted. Further, the degree of opening of the outdoor unit expansion valve 24 is fully opened during cooling operation.

As described above, the accumulator 27 is connected to the port c of the four-way valve 22 by the refrigerant pipe 46 on the refrigerant inflow side, and is connected to the refrigerant suction side of the compressor 21 by the suction pipe 42 on the refrigerant outflow side. The accumulator 27 separates the refrigerant that has flowed into the accumulator 28 from the refrigerant pipe 46 into gas refrigerant and liquid refrigerant, and causes the compressor 21 to suck only the gas refrigerant.

The outdoor unit fan 28 is made of a resin material and arranged near the outdoor heat exchanger 23 . The outdoor unit fan 28 is rotated by a fan motor (not shown) to draw outside air into the outdoor unit 2 from a suction port (not shown), and the outside air heat-exchanged with the refrigerant in the outdoor heat exchanger 23 is discharged from an outlet (not shown) to the outside of the room. Discharge to the outside of machine 2.

In addition to the configuration described above, the outdoor unit 2 is provided with various sensors. As shown in FIG. 1A, a discharge pipe 41 is provided with a discharge pressure sensor 31 for detecting the pressure of the refrigerant discharged from the compressor 21 and a temperature sensor for detecting the temperature of the refrigerant discharged from the compressor 21. A discharge temperature sensor 33 is provided for detection. A suction pressure sensor 32 for detecting the suction pressure, which is the pressure of the refrigerant sucked into the compressor 21, and the temperature of the refrigerant sucked into the compressor 21 are provided near the refrigerant inlet of the accumulator 28 in the refrigerant pipe 46. A suction temperature sensor 34 is provided.

Between the outdoor heat exchanger 23 and the outdoor unit expansion valve 24 in the outdoor unit liquid pipe 44, the temperature of the refrigerant flowing into the outdoor heat exchanger 23 or the temperature of the refrigerant flowing out of the outdoor heat exchanger 23 is detected. A heat exchanger temperature sensor 35 is provided for this purpose. An outside air temperature sensor 36 for detecting the temperature of the outside air flowing into the inside of the outdoor unit 2, ie, the outside air temperature, is provided near the suction port (not shown) of the outdoor unit 2 .

Further, the outdoor unit 2 is provided with outdoor unit control means 200 which is the control means of the present invention. The outdoor unit control means 200 is mounted on a control board housed in an electrical component box (not shown) of the outdoor unit 2, and as shown in FIG. , and a sensor input unit 240 .

The storage unit 220 is, for example, a flash memory, and stores a control program for the outdoor unit 2, detection values corresponding to detection signals from various sensors, driving states of the compressor 21 and the outdoor unit fan 28, and information transmitted from each indoor unit 5. It stores operation information (including operation/stop information, operation modes such as cooling/heating), the rated capacity of the outdoor unit 2, and the required capacity of each indoor unit 5. The communication unit 230 is an interface that communicates with each indoor unit 5 . The sensor input unit 240 takes in detection results from various sensors of the outdoor unit 2 and outputs them to the CPU 210 .

The CPU 210 periodically (for example, every 30 seconds) takes in values detected by various sensors via the sensor input unit 240, and receives signals including operation information transmitted from each indoor unit 5 via the communication unit 230. is entered. The CPU 210 adjusts the degree of opening of the outdoor unit expansion valve 24 and controls the driving of the compressor 21 and the outdoor unit fan 28 based on the input various information.

<Configuration of each indoor unit>
Next, ten indoor units 5-1 to 5-10 will be described. The ten indoor units 5-1 to 5-10 all have the same configuration, and include an indoor heat exchanger 51, an indoor unit expansion valve 52, a liquid pipe connection portion 53, a gas pipe connection portion 54, An indoor unit fan 55 is provided. These constituent devices except for the indoor unit fan 55 are connected to each other by refrigerant pipes described in detail below to form the indoor unit refrigerant circuit 50 forming a part of the refrigerant circuit 10 .

The indoor heat exchanger 51 exchanges heat between the refrigerant and the indoor air taken into the indoor unit 5 from a suction port (not shown) by the rotation of the indoor unit fan 55, which will be described later. One refrigerant inlet/outlet of the indoor heat exchanger 51 and the liquid pipe connection portion 53 are connected by the indoor unit liquid pipe 71 , and the other refrigerant inlet/outlet and the gas pipe connection portion 54 a are connected by the indoor unit gas pipe 72 . The indoor heat exchanger 51 functions as an evaporator when the air conditioner 1 performs cooling operation, and functions as a condenser when the air conditioner 1 performs heating operation. The refrigerant pipes are connected to the liquid pipe connection portion 53 and the gas pipe connection portion 54 by welding, flare nuts, or the like.

The indoor unit expansion valve 52 is provided in the indoor unit liquid pipe 71 . The indoor unit expansion valve 52 is an electronic expansion valve, and when the indoor heat exchanger 51 functions as an evaporator, that is, when the indoor unit 5 performs cooling operation, the degree of opening of the indoor unit expansion valve 52 is determined by the refrigerant outlet of the indoor heat exchanger 51 ( The degree of superheating of the refrigerant at the gas pipe connecting portion 54 side) is adjusted to the target degree of superheating of the refrigerant. Further, when the indoor heat exchanger 51 functions as a condenser, that is, when the indoor unit 5 performs heating operation, the degree of opening of the indoor unit expansion valve 52 is determined by the refrigerant outlet (liquid pipe connection) of the indoor heat exchanger 51. 53 side) is adjusted to the target refrigerant subcooling degree. Here, the target refrigerant superheating degree and the refrigerant subcooling degree are the refrigerant superheating degree and the refrigerant subcooling degree necessary for exhibiting sufficient cooling capacity or heating capacity in each of the indoor units 5-1 to 5-10. is.

The indoor unit fan 55 is made of a resin material and arranged near the indoor heat exchanger 51 . The indoor unit fan 55 is rotated by a fan motor (not shown) to take indoor air into the interior of the indoor unit 5 from a suction port (not shown), and the indoor air heat-exchanged with the refrigerant in the indoor heat exchanger 51 is discharged from an outlet (not shown). released into the room from

In addition to the configuration described above, the indoor unit 5 is provided with various sensors. Between the indoor heat exchanger 51 and the indoor unit expansion valve 52 in the indoor unit liquid pipe 71, a liquid side temperature sensor 61 for detecting the temperature of the refrigerant flowing into or out of the indoor heat exchanger 51 is provided. is provided. The indoor unit gas pipe 72 is provided with a gas-side temperature sensor 62 that detects the temperature of the refrigerant flowing out of or flowing into the indoor heat exchanger 51 . An indoor temperature sensor 63 that detects the temperature of indoor air flowing into the indoor unit 5 is provided near the suction port (not shown) of the indoor unit 5 .

<Operation of refrigerant circuit>
Next, the flow of the refrigerant in the refrigerant circuit 10 and the operation of each part during the air conditioning operation of the air conditioner 1 according to the present embodiment will be described with reference to FIG. 1(A). In the following description, the case where the air conditioner 1 performs the heating operation will be described first, and then the case where the air conditioner 1 performs the cooling operation will be described. The solid line arrows in FIG. 1A indicate the flow of refrigerant during heating operation. The dashed arrows in FIG. 1(A) indicate the flow of refrigerant during cooling operation.

<Heating operation>
As shown in FIG. 1, when the air conditioner 1 performs heating operation, the four-way valve 22 is in the state indicated by the solid line, that is, the port a and the port d of the four-way valve 22 are in communication, and the port b and port c are switched to communicate with each other. Thereby, the refrigerant circuit 10 becomes a heating cycle in which each indoor heat exchanger 51 functions as a condenser and the outdoor heat exchanger 23 functions as an evaporator.

When the compressor 21 is driven in a state where the refrigerant circuit 10 functions as a heating cycle, the refrigerant discharged from the compressor 21 flows through the discharge pipe 41, flows into the four-way valve 22, and flows from the four-way valve 22 to the outdoor unit gas pipe 45. and flows into the gas pipe 9 via the closing valve 26 .

Refrigerant flowing through the gas pipe 9 is branched to the indoor units 5-1 to 5-10 via each gas pipe connection portion . The refrigerant that has flowed into the indoor units 5 - 1 to 5 - 10 flows through each indoor unit gas pipe 72 and flows into each indoor heat exchanger 51 . The refrigerant that has flowed into each indoor heat exchanger 51 exchanges heat with the indoor air taken into each indoor unit 5 by the rotation of each indoor unit fan 55, and is condensed.

In this way, each indoor heat exchanger 51 functions as a condenser, and the indoor air heated by exchanging heat with the refrigerant in each indoor heat exchanger 51 is blown into the room from an outlet (not shown). The room in which the indoor units 5-1 to 5-10 are installed is heated.

The degree of opening of the refrigerant flowing from each indoor heat exchanger 51 into each indoor unit liquid pipe 71 is adjusted so that the degree of refrigerant supercooling at the refrigerant outlet side of each indoor heat exchanger 51 becomes the target degree of refrigerant supercooling. The pressure is reduced when passing through each indoor unit expansion valve 52 . Here, the target refrigerant subcooling degree is determined based on the heating capacity required in each of the indoor units 5-1 to 5-10. Further, the heating capacity is determined in each of the indoor units 5-1 to 5-10 based on the temperature difference between the set temperature and the room temperature detected by the indoor units 5-1 to 5-10. be.

The refrigerant decompressed by each indoor unit expansion valve 52 flows out from each indoor unit liquid pipe 71 to the liquid pipe 8 via each liquid pipe connecting portion 53 . The refrigerant that joins the liquid pipe 8 and flows into the outdoor unit 2 through the closing valve 25 flows through the outdoor unit liquid pipe 44 so that the degree of superheat of the refrigerant at the refrigerant outlet side of the outdoor heat exchanger 23 becomes the target degree of superheat of the refrigerant. The pressure is further reduced when passing through the outdoor unit expansion valve 24 whose opening is adjusted to . Here, the target refrigerant degree of superheat is obtained by performing a test or the like in advance and stored in the storage unit 220 of the outdoor unit control means 200. The outdoor heat exchanger 23 that functions as an evaporator during heating operation If the degree of superheating of the refrigerant at the refrigerant outlet side of is set as the target degree of superheating of the refrigerant, it is a value that confirms that liquid backflow does not occur.

The refrigerant decompressed by the outdoor unit expansion valve 24 flows through the outdoor unit liquid pipe 44 and into the outdoor heat exchanger 23, and is taken into the outdoor unit 5 by the rotation of the outdoor unit fan 28, which is set to the maximum rotation speed. It evaporates by exchanging heat with the outside air. Refrigerant that has flowed from the outdoor heat exchanger 23 into the refrigerant pipe 43 flows through the four-way valve 22, the refrigerant pipe 46, the accumulator 27, and the suction pipe 42 in that order, is sucked into the compressor 21, and is compressed again.

<Cooling operation>
When the air conditioner 1 performs cooling operation, as shown in FIG. , port c and port d are switched to communicate with each other. Thereby, the refrigerant circuit 10 becomes a heating cycle in which each indoor heat exchanger 51 functions as an evaporator and the outdoor heat exchanger 23 functions as a condenser.

When the compressor 21 is driven while the refrigerant circuit 10 functions as a cooling cycle, the refrigerant discharged from the compressor 21 flows through the discharge pipe 41 into the four-way valve 22 and flows from the four-way valve 22 through the refrigerant pipe 43. and flows into the outdoor heat exchanger 23 . The refrigerant that has flowed into the outdoor heat exchanger 23 exchanges heat with the outside air taken into the outdoor unit 2 by the rotation of the outdoor unit fan 28, and is condensed. The refrigerant that has flowed out from the outdoor heat exchanger 23 to the outdoor unit liquid pipe 44 passes through the outdoor unit expansion valve 24 that is fully opened, and flows out to the liquid pipe 8 via the closing valve 25 .

Refrigerant flowing through the liquid pipe 8 flows into the indoor units 5-1 to 5-10 via the respective liquid pipe connection portions 53. As shown in FIG. The refrigerant flowing into the indoor units 5-1 to 5-10 flows through each indoor unit liquid pipe 71, and the degree of opening is adjusted so that the refrigerant superheat degree at each refrigerant outlet of each indoor heat exchanger 51 becomes the target refrigerant superheat degree. is decompressed when passing through each of the indoor unit expansion valves 52 in which is adjusted. Here, the target refrigerant superheat degree is determined based on the cooling capacity required for each of the indoor units 5-1 to 5-10. Also, the cooling capacity is determined in each of the indoor units 5-1 to 5-10 based on the temperature difference between the set temperature and the room temperature detected by the indoor units 5-1 to 5-10. be.

The refrigerant flowing into each indoor heat exchanger 51 from each indoor unit liquid pipe 71 exchanges heat with the indoor air taken into the indoor units 5-1 to 5-10 by the rotation of each indoor unit fan 55. Evaporate. In this way, each indoor heat exchanger 51 functions as an evaporator, and the indoor air cooled by exchanging heat with the refrigerant in each indoor heat exchanger 51 is blown into the room from an outlet (not shown). The room in which the indoor units 5-1 to 5-10 are installed is cooled.

The refrigerant flowing out from each indoor heat exchanger 51 to each indoor unit gas pipe 72 flows out to gas pipe 9 via each gas pipe connecting portion 54 . The refrigerant that joins the gas pipe 9 and flows into the outdoor unit 2 through the closing valve 26 flows through the outdoor unit gas pipe 45, the four-way valve 22, the refrigerant pipe 46, the accumulator 27, and the suction pipe 42 in this order, and is sucked into the compressor 21. and compressed again.

<Compressor control according to the air conditioning capacity required by the indoor unit>
The air conditioner 1 of the present embodiment described so far has a set temperature (hereinafter referred to as set temperature A temperature difference (hereinafter referred to as a temperature difference ΔT) is calculated by subtracting the indoor temperature detected by the indoor temperature sensor 63 (hereinafter referred to as an indoor temperature Tr) from the temperature Tp). Then, the required capacity based on the largest temperature difference ΔT among the temperature differences ΔT, that is, the air conditioning capacity required by the indoor units 5-1 to 5-10 (heating capacity during heating operation/cooling capacity during cooling operation) The maximum required capacity of the capacity) is used as the system required capacity, and the target evaporating temperature or the target condensing temperature is set based on this system required capacity, and the compressor 21 is operated so that the target evaporating temperature or the target condensing temperature can be achieved. The number of revolutions is controlled. In this way, by controlling the rotation speed of the compressor 21 so as to achieve the target evaporation temperature or the target condensation temperature, the indoor unit with the maximum required capacity and the air conditioning capacity other than the indoor unit with the maximum required capacity The required amount of refrigerant is supplied to each indoor unit having a smaller capacity.

FIG. 2 shows the set temperature Tp set in each of the indoor units 5-1 to 5-10 and the indoor temperature Tr detected by the indoor temperature sensor 63 of each of the indoor units 5-1 to 5-10. 3 is an indoor unit operating state table 300 stored for each of the units 5-1 to 5-10. Note that FIG. 2 shows, as an example, the indoor unit operating state table 300 when the air conditioner 1 is performing heating operation. This indoor unit operating state table 300 is stored in the storage unit 220 of the outdoor unit control means 200 .

Specifically, in the indoor unit operating state table 300, for each of the indoor units 5-1 to 5-10, the operation mode (here, all are "heating"), the set temperature Tp (unit: ° C.) , indoor temperature Tr (unit: °C), temperature difference obtained by subtracting the indoor temperature Tr from the set temperature Tp (unit: °C, hereinafter referred to as temperature difference ΔT), whether or not the indoor unit is started / The ability to indicate whether or not the operation start indoor unit indicated by "not applicable" and whether or not the required capacity reduction condition described later is satisfied and the predetermined capacity subtraction value is subtracted from the maximum required capacity is indicated by "applied"/"not applied" Six items of reduction application are stored.

Every time the CPU 210 of the outdoor unit control means 200 acquires a signal including that the set temperature Tp has been changed in each of the indoor units 5-1 to 5-10 via the communication unit 230, the CPU 210 of the indoor unit 5-1 Each time the indoor temperature Tr detected by the indoor temperature sensor 63 is taken in periodically (for example, every 3 minutes) in each of 5-10, the items of the set temperature Tp and the indoor temperature Tr in the indoor unit operation state table 300 are updated. do. Further, the CPU 210 calculates the temperature difference ΔT and updates the item of the temperature difference ΔT in the indoor unit operating state table 300 every time the set temperature Tp and the indoor temperature Tr are taken. Note that the temperature difference ΔT is obtained by subtracting the room temperature Tr from the set temperature Tp during the heating operation, and by subtracting the set temperature Tp from the room temperature Tr during the cooling operation.

In addition, the CPU 210 updates the operation mode item of the indoor unit operation state table 300 according to whether the indoor units 5-1 to 5-10 are operating or not. "cooling" if it is in heating mode, "heating" if it is in heating mode, and "stopped" if it is stopped. Note that CPU 210 receives an operation start signal or an operation stop signal from each of indoor units 5-1 to 5-10 via communication unit 230, thereby determining whether to start/stop operation of each indoor unit.

By the way, when the air conditioner 1 is performing the air conditioning operation, there are cases where some of the ten indoor units 5-1 to 5-10 are in operation and some are inactive. . Then, when the stopped indoor unit starts to operate, the temperature difference ΔT in the operating indoor unit is larger than the temperature difference ΔT in the already operating indoor unit, and the air conditioning capacity required by the operating indoor unit does not match the already operating It may be larger than the air conditioning capacity required by the indoor unit.

For example, among the indoor units 5-1 to 5-10, all the indoor units other than the indoor unit 5-6 are already operating indoor units, and the stopped indoor unit 5-6 has started operation. (In the indoor unit operating state table 300 in FIG. 2, the indoor unit 5-6 that has started operation is surrounded by a dashed line), and the indoor temperature detected by the indoor unit 5-6 immediately after the operation starts Since Tr is lower than the indoor temperature Tr detected by the other operating indoor units, the temperature difference ΔT between the indoor units 5-6 is 5.0° C., and the other operating indoor units continue heating operation. Assume that the temperature difference ΔT is 0° C. to 1.5° C. depending on the operation. In the following description, the temperature difference ΔT that is larger than the temperature difference ΔT of the other indoor units is referred to as the maximum temperature difference ΔTm. This is the maximum temperature difference ΔTm.

In the above state, the temperature difference ΔT when the indoor unit 5-6 starts operating becomes the maximum temperature difference ΔTm. This is the largest maximum required capacity among the air conditioning capacities required by the indoor units 5-1 to 5-10. Then, the target evaporating temperature or the target condensing temperature is set according to the system required capacity with the maximum required capacity as the system required capacity, and the rotational speed of the compressor 21 is controlled so that the target evaporating temperature or the target condensing temperature can be achieved. be. At this time, the indoor units other than the indoor unit 5-6 exhibit an air conditioning capacity greater than the air conditioning capacity required by each of the indoor units other than the indoor unit 5-6. For this reason, in the indoor units other than the indoor units 5-6, the indoor temperature Tr detected by each indoor unit may repeatedly rise and fall with the set temperature Tp as a boundary. , the indoor units other than the indoor units 5-6 may frequently repeat thermo-off and thermo-on.

Therefore, in the air conditioner 1 of the present embodiment, if the required capacity reduction condition is satisfied when the indoor unit that is stopped during air conditioning operation becomes the operation start indoor unit, the operation start indoor unit requests A predetermined subtraction value (hereinafter referred to as a capacity subtraction value), for example, a value corresponding to 10% of the maximum air conditioning capacity, is subtracted from the maximum value of the air conditioning capacity, and the capacity is subtracted from the air conditioning capacity requested by the indoor unit that starts operating. The rotational speed of the compressor 21 that can realize the reduced capacity.

Here, the required capacity reduction condition is determined in advance by conducting a test or the like, and the required capacity reduction condition is satisfied if all of the following four requirements are satisfied.

Requirement 1: The number of indoor units to start operation is less than the predetermined number (for example, 1 unit)
Requirement 2: The required capacity based on the temperature difference ΔT in the indoor unit that has started operation is the maximum required capacity Requirement 3: The temperature difference ΔT of the already-operated indoor units other than the indoor unit that has started operation is within a predetermined range (for example, within 1.5°C)
Requirement 4: The temperature difference ΔT of the indoor unit that has started operation is higher than the average value of the temperature difference ΔT of the indoor units already in operation (hereinafter referred to as the average temperature difference ΔTa) by a predetermined value (for example, 2°C) or more.

That is, the required capacity reduction condition is a condition for judging whether or not exerting the air conditioning capacity required by the operating indoor unit has a large influence on the control of the already operating indoor unit.

The above-described four requirements of the required capacity reduction conditions will be described below. First, the first requirement (requirement 1) "the number of indoor units to be started is less than a predetermined number" will be described. If Requirement 1 is satisfied, there is a possibility that the indoor units other than the operation-starting indoor unit are already operating, and the temperature in the room where the indoor units 5-1 to 5-10 are installed is close to the set temperature. is considered to be high. In this case, if the air conditioning capacity required by the operating indoor unit becomes the maximum required capacity and the rotational speed of the compressor 21 is increased accordingly, the already operating indoor unit may frequently repeat thermo-off/thermo-on. On the other hand, if Requirement 1 is not satisfied, that is, if the number of indoor units to be started is two or more, there is a possibility that the temperature of the room in which the indoor units 5-1 to 5-10 are installed is not close to the set temperature. considered to be high. In this case, the air-conditioning capacity required by the operation-starting indoor unit becomes the maximum required capacity among all the air-conditioning capacities required by all the indoor units. It is better to enable the air conditioning capacity required by the indoor unit to be exhibited quickly. In other words, by determining whether or not Requirement 1 is satisfied, is there a possibility that the already operating indoor unit will frequently repeat thermo-off/thermo-on by responding to the maximum required capacity required by the operating indoor unit? , it is possible to determine whether the required air-conditioning capacity of a plurality of indoor units that have been started to operate should be exhibited quickly. Note that the specific numerical value of the predetermined number may be appropriately determined for each air conditioner according to the number of indoor units and the total value of the air conditioning capacity. One unit is assumed.

Next, the second requirement (requirement 2) that "the maximum required capacity is the required capacity based on the temperature difference ΔT at the start of operation of the indoor unit" will be described. If Requirement 2 is satisfied, controlling the rotation speed of the compressor 21 on the basis of the maximum required capacity of the indoor unit that has started operating may cause the already operating indoor unit to frequently repeat thermo-off/thermo-on. On the other hand, when Requirement 2 is not satisfied, one of the temperature differences ΔT in the indoor units already in operation is the maximum temperature difference ΔTm, and the maximum temperature difference ΔTm is not considered to be a very large value. For this reason, even if the compressor 21 is controlled so as to exhibit the maximum required capacity based on the maximum temperature difference ΔTm, it is unlikely that the indoor units that are already in operation will be frequently turned off/on. In other words, by judging whether or not Requirement 2 is satisfied, it is possible to determine the degree of influence of the air conditioning capacity required by the indoor unit to be started on the air conditioning environment of the room in which the indoor units 5-1 to 5-10 are installed. can judge.

Next, the third requirement (requirement 3), "the temperature difference ΔT of the indoor units already in operation is within a predetermined range" will be described. When the requirement 3 is satisfied, it indicates that the indoor temperature Tr is near the set temperature Tp in the indoor units already in operation other than the indoor units that have started operation, and the indoor units 5-1 to 5-10 are It is considered that the temperature of the room in which the device is installed is generally around the set temperature Tp. On the other hand, when the requirement 3 is not satisfied, the temperature difference ΔT of the already-operated indoor units other than the operation-started indoor unit is also a large value (even if it is not as large as the maximum temperature difference ΔTm), and the indoor units 5-1 to It is conceivable that there are a plurality of places where the temperature is not near the set temperature Tp in the room where 5-10 is installed. That is, by determining whether or not Requirement 3 is satisfied, it is determined whether or not the temperature of the room in which the indoor units 5-1 to 5-10 are installed is approximately near the set temperature Tp. can be done. A specific numerical value within the predetermined range may be appropriately determined for each air conditioner according to the number of indoor units, the size of the room in which it is installed, the air conditioning load of the room, and the like. In the harmony device 1, the temperature is within 1.5° C. as described above.

Finally, the fourth requirement (requirement 4) that "the temperature difference ΔT of the operating indoor unit is larger than the average temperature difference ΔTa of the already operating indoor units by a predetermined value" will be described. If Requirement 4 is satisfied, it means that the difference between the temperature difference ΔTm of the indoor unit that has started operation and the temperature difference ΔT of the indoor unit that has already been operated is large, and the air conditioning capacity required by the indoor unit that has started operation is the same as that of the already operated indoor unit. This means that it is a significantly large value for the required air conditioning capacity. On the other hand, if Requirement 4 is not satisfied, the difference between the temperature difference ΔTm of the indoor unit that has started operation and the temperature difference ΔT of the indoor unit that has already been operated is small, and the air conditioning capacity required by the indoor unit that has started operation is This means that it is not a significantly large value for the air conditioning capacity required by the machine. That is, by determining whether or not Requirement 4 is satisfied, it is possible to determine whether or not the air-conditioning capacity required by the indoor unit that has started operating is extremely large. Note that the specific numerical value of the predetermined value may be appropriately determined for each air conditioner according to the number of indoor units and the total value of the air conditioning capacity. 2°C or higher.

Looking at whether or not the four requirements of the required capacity reduction conditions described above apply to the operating states of the air conditioner 1 listed in the indoor unit operating state table 300 in FIG. Since there is only one unit, it satisfies Requirement 1 of the required capacity reduction conditions. Next, among the temperature differences ΔT of the indoor units 5-1 to 5-10, the temperature difference ΔT of the indoor unit 5-6, which is the operation start indoor unit, is 5.0° C., which is the largest maximum temperature difference ΔTm. , satisfies Requirement 2 of the required capacity reduction conditions. Next, since the temperature difference ΔT of each indoor unit other than the indoor units 5-6 is within 1.5° C., the requirement 3 of the required capacity reduction condition is satisfied. The average temperature difference ΔTa of the temperature differences ΔT of the indoor units other than the indoor units 5-6 is (1.50+1.00+0+1.00+1.00+0.50+0+1.00+0.50)/9≈0.72°C. , the maximum temperature difference ΔTm: 5.0° C. is higher than the average temperature difference ΔTa: 0.72° C. by 2° C. or more. Therefore, if the states of the indoor units 5-1 to 5-10 are the states shown in the indoor unit operation state table 300 in FIG. Since it is satisfied, the required capacity reduction condition is satisfied.

Based on the above, in the indoor unit operation state table 300, only the indoor unit 5-6 is set to "applicable" (all other indoor units are "not applicable"), and the indoor unit 5-6 Only the item of capacity reduction application is "applied" (all other indoor units are "non-applied"). When there is no indoor unit to start operation, all the items of the indoor unit to start operation of the indoor unit operating state table 300 are set to "not applicable", and all the items of capacity reduction application are set to "not applicable". In the outdoor unit 2, the temperature difference ΔT in the indoor units 5-6 is defined as the maximum temperature difference ΔTm, and a capacity subtraction value equivalent to 10% of the maximum required capacity is subtracted from the maximum required capacity determined based on this maximum temperature difference ΔTm. The subtracted value is used as the required system capacity, and the target evaporating temperature or the target condensing temperature is set according to the required system capacity, and the rotational speed of the compressor 21 is controlled so that the target evaporating temperature or the target condensing temperature can be achieved. be done.

Then, after a predetermined time (hereinafter referred to as a predetermined time tp) has elapsed since the control of the rotation speed of the compressor 21 was started as described above, the set temperature is Tp and the room temperature Tr are taken in to calculate the current temperature difference ΔT (hereinafter referred to as the current temperature difference ΔTn). The air conditioning capacity determined based on the temperature difference ΔTn is defined as the required system capacity, and the target evaporating temperature or the target condensing temperature is set according to the required system capacity so that the target evaporating temperature or the target condensing temperature can be achieved. The rotation speed of the compressor 21 is controlled. On the other hand, if the calculated current temperature difference ΔTn is less than the maximum temperature difference ΔTm, the maximum temperature difference ΔT of each of the indoor units 5-1 to 5-10 including the indoor unit 5-6 is reached. A target evaporating temperature or a target condensing temperature is set according to the air conditioning capacity determined based on the above, and the rotational speed of the compressor 21 is controlled so that the target evaporating temperature or the target condensing temperature can be achieved.

Here, the predetermined time tp is the time from when the indoor unit 5-6 starts to operate to when the indoor temperature Tr detected by the indoor unit 5-6 changes. This is the time required, for example, the time (3 minutes×3=9 minutes) required for taking in the indoor temperature Tr three times after the indoor unit 5-6 starts operating.

<Flow of processing related to control related to compressor control>
Next, using the flowchart of FIG. 3, when the air conditioner 1 in the present embodiment performs the air conditioning operation, the CPU 210 of the outdoor unit control means 200 is requested by each of the indoor units 5-1 to 5-10. The flow of processing when controlling the rotation speed of the compressor 21 in order to realize the air conditioning capacity that is required will be described. In FIG. 3, ST represents a processing step, and the number following ST represents the step number. Note that FIG. 3 only refers to the processing related to the present invention, and the description and explanation of other general controls related to the air conditioner 1 are omitted. Further, in FIG. 3, in addition to the set temperature Tp, the room temperature Tr, the temperature difference ΔT, the maximum temperature difference ΔTm, the current temperature difference ΔTn, and the predetermined time tp, Ar is the required system capacity, and Ar is the maximum required capacity. Arm and ability subtraction value are Arp.

First, the CPU 210 takes in the set temperature Tp and the room temperature Tr of each of the indoor units 5-1 to 5-10 (ST1). Specifically, the CPU 210 acquires, via the communication unit 230, the set temperature Tp transmitted from the indoor unit that has started operating or the indoor unit whose set temperature Tp has been changed by the user. Further, the CPU 210 periodically (every three minutes) acquires the indoor temperature Tr detected by the indoor temperature sensor 63 of each of the indoor units 5-1 to 5-10 via the communication unit 230. FIG. As described above, the CPU 210 updates the items of the set temperature Tp and the room temperature Tr in the indoor unit operating state table 300 stored in the storage unit 220 each time the set temperature Tp and the room temperature Tr are taken in. do.

Next, the CPU 210 subtracts the indoor temperature Tr from the set temperature Tp of each of the indoor units 5-1 to 5-10, and calculates the temperature difference ΔT for each of the indoor units 5-1 to 5-10 (ST2 ). Each time the CPU 210 calculates the temperature difference ΔT of each of the indoor units 5-1 to 5-10, the temperature difference ΔT in the indoor unit operation state table 300 stored in the storage unit 220 as an absolute value. Update the difference ΔT item.

Next, CPU 210 extracts maximum temperature difference ΔTm from among temperature differences ΔT calculated in ST2, and determines maximum required capacity Arm based on this maximum temperature difference ΔTm (ST3).

Next, CPU 210 determines whether or not the required capacity reduction condition is satisfied (ST4). As described above, the required capacity reduction condition is that the number of indoor units to be started is one, the temperature difference ΔT of the indoor units to be started is the maximum temperature difference ΔTm, and the number of indoor units that are already in operation The temperature difference ΔT of the indoor units is within 1.5°C, and the maximum temperature difference ΔTm is 2°C or more higher than the average temperature difference ΔTa obtained using the temperature differences ΔT of the indoor units already in operation.

If the required capacity reduction condition is not satisfied (ST4-No), the CPU 210 sets the maximum required capacity Arm determined in ST3 as the system required capacity Ar, and the target evaporation temperature or target set according to this system required capacity Ar. The rotational speed of the compressor 21 is set to a speed that can achieve the condensing temperature, that is, the rotational speed that allows the compressor 21 to exhibit the maximum required capacity Arm (ST11), and the process returns to ST1.

If the required capacity reduction condition is satisfied (ST4-Yes), the CPU 210 subtracts the capacity subtraction value Arp from the maximum required capacity Arm determined in ST3, that is, the air conditioning capacity required by the indoor unit to be started. Let the required system capacity Ar be the number of revolutions of the compressor 21 that can achieve the target evaporation temperature or the target condensing temperature set according to this required system capacity Ar, that is, the capacity subtraction value of the compressor 21 from the maximum required capacity Arm A rotation speed at which the Arp can be reduced (ST5) and a timer is started (ST6). In addition, CPU210 has a time-measurement function.

Next, the CPU 210 determines whether or not a predetermined time t has elapsed since the time measurement was started in ST6 (ST7). If the predetermined time t has not passed (ST7-No), the CPU 210 returns the process to ST7 and waits for the predetermined time t to pass.

If the predetermined time t has passed (ST7-Yes), the CPU 210 resets the timer (ST8), and the indoor unit having the maximum temperature difference ΔTm in ST3, that is, the latest set temperature Tp of the indoor unit that started operation. and the indoor temperature Tr are taken in to calculate the current temperature difference ΔTn (ST9).

Next, the CPU 210 determines whether or not the current temperature difference ΔTn calculated in ST9 is greater than or equal to the maximum temperature difference ΔTm extracted in ST3 (ST10). When comparing the current temperature difference ΔTn and the maximum temperature difference ΔTm, the CPU 210 uses each absolute value for comparison.

If the current temperature difference ΔTn is not equal to or greater than the maximum temperature difference ΔTm (ST10-No), the CPU 210 returns the process to ST1. If the current temperature difference ΔTn is greater than or equal to the maximum temperature difference ΔTm (ST10-Yes), the CPU 210 advances the process to ST11.

As described above, in the air conditioner 1 of the present embodiment, if the required capacity reduction condition is satisfied during air conditioning operation, a predetermined capacity subtraction value from the air conditioning capacity required by the indoor unit to start operation is taken as the required system capacity, and the rotational speed of the compressor 21 at which this required system capacity can be exhibited. As a result, it is possible to prevent frequent repetition of thermo-off/thermo-on in already-operated indoor units other than the indoor unit whose operation has been started due to a demand for high air conditioning capacity in the indoor unit whose operation has been started.

Further, as described above, the current temperature difference ΔTn of the operation-starting indoor unit is calculated after a predetermined time has passed since the value obtained by subtracting the predetermined capacity subtraction value from the air-conditioning capacity required by the operation-starting indoor unit is used as the system required capacity. If this temperature difference is equal to or greater than the temperature difference ΔT immediately after the start of operation of the indoor unit, the required capacity based on the current temperature difference ΔTn is set as the system required capacity, and the compression that can exhibit this system required capacity. is the number of revolutions of the machine 21. As a result, when a high air-conditioning capacity is really required for the reason that the air-conditioning load is high at the start of operation of the indoor unit, the air-conditioning capacity can be exhibited, so that the user's comfort is not impaired.

1 air conditioner 2 outdoor unit 5-1 to 5-10 indoor unit 21 compressor 51 indoor heat exchanger 63 indoor temperature sensor 200 outdoor unit control means 210 CPU
220 storage unit 230 communication unit 240 sensor input unit Ar required capacity Arm maximum required capacity Arp capacity subtraction value Tp set temperature Tr room temperature ΔT temperature difference ΔTa average temperature difference ΔTm maximum temperature difference ΔTn current temperature difference t predetermined time

Claims (3)

an outdoor unit having a compressor;
a plurality of indoor units having indoor temperature detection means for detecting indoor temperature;
a control means for controlling the driving of the compressor;
has
The control means is
When there is an indoor unit that has started operating from a stopped state during air conditioning operation, if the required capacity reduction condition is satisfied, a predetermined maximum required capacity among the required capacities of the plurality of indoor units The value obtained by subtracting the capacity subtraction value of is the system required capacity for determining the rotation speed of the compressor,
If the required capacity reduction condition is not satisfied during air conditioning operation, the maximum required capacity is set as the system required capacity,
The required capacity reduction condition is that the number of indoor units that are started to operate from a stopped state is less than a predetermined number, and the required capacity of the indoor units that are started to operate is the maximum required capacity, and Each of the temperature differences in the already-operated indoor units other than the operation-started indoor unit is a value within a predetermined range, and the operation-started indoor unit is higher than the average value of the temperature differences of the already-operated indoor units Suppose that the temperature difference between the machines is large by a predetermined value,
An air conditioner characterized by: The control means is
When a required capacity reduction condition is established during air conditioning operation and a value obtained by subtracting a predetermined capacity subtraction value from the maximum required capacity is set as the system required capacity, the system required capacity is maintained for a predetermined time,
After the predetermined time has elapsed, calculating the current temperature difference by subtracting the indoor temperature from the set temperature in the operation-started indoor unit;
If the absolute value of the current temperature difference is greater than the temperature difference immediately after the start-up indoor unit starts operating, the required capacity based on the current temperature difference is set as the system required capacity.
The air conditioner according to claim 1, characterized by: The control means is
From each of the indoor units, the indoor temperature detected by the indoor temperature detection means and the set temperature that is the target temperature for air conditioning operation set in each of the indoor units are taken in, and the indoor Subtract the temperature to get the temperature difference,
The required capacity of the indoor unit having the largest maximum temperature difference among the absolute values of the temperature differences is defined as the maximum required capacity.
The air conditioner according to claim 1 or 2.

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