JPWO2020152837A1 - Air conditioning system, operation control method and program - Google Patents

Abstract

Provide systems, methods, and programs that can reduce the time required to reach the set temperature and reduce power consumption. This system includes a plurality of indoor units and one or more outdoor units, and information related to operation from the indoor unit and the outdoor unit that are operating in response to an operation instruction among the plurality of indoor units and one or more outdoor units. The acquisition means (30) for acquiring the above, and the control means (34) for instructing the operation of at least one indoor unit that has not received the operation instruction according to the acquired information.

Description

The present invention relates to an air conditioning system including a plurality of indoor units and one or more outdoor units, an operation control method, and a program for causing a computer to execute the operation control.

When one space (air conditioning control area) such as an office is large, there are many cases where an air conditioning system equipped with a plurality of indoor units is introduced. In such a system, an operation command is received for each indoor unit, and operation is performed for each indoor unit.

In a system that operates for each indoor unit, the indoor unit cannot be selected even though there are other indoor units that affect the position specified by the user, so the air conditioning intended by the user is realized. Can't.

Therefore, for the purpose of realizing the air conditioning intended by the user, it is possible to select an indoor unit that affects the air conditioning environment (temperature, humidity, etc.) at a designated position in the air conditioning control area from among a plurality of indoor units. The configured device has been proposed (see, for example, Patent Document 1).

Japanese Patent No. 5787998

In the device described in Patent Document 1, only the indoor unit that affects the air-conditioning environment at the designated position is selected. For example, when only one unit is selected, it takes a long time to reach the set temperature, and the selected indoor unit operates with a large amount of electric power, so that there is a problem that the power consumption becomes large.

In view of the above problems, the present invention is an air conditioning system including a plurality of indoor units and one or more outdoor units.
An acquisition means for acquiring information related to operation from the indoor unit and the outdoor unit that are operating in response to an operation instruction among a plurality of indoor units and one or more outdoor units.
Depending on the acquired information, an air conditioning system is provided that includes a control means for instructing operation of at least one indoor unit that has not received an operation instruction.

According to the present invention, it is possible to shorten the time required to reach the set temperature and reduce the power consumption.

The figure which showed the configuration example of the air conditioning system. The figure which illustrated the connection state of an indoor unit, an outdoor unit, and a centralized controller. The figure which illustrated the hardware configuration of the centralized controller. The figure which showed the example which specified a plurality of indoor units in each group. The figure which illustrated the group information managed by a centralized controller. A block diagram illustrating the functional configuration of the centralized controller. A flowchart showing an example of the flow of operation control by a centralized controller. The figure explaining the cooperative operation of an indoor unit. The figure which showed the example which cancels the cooperative operation of some indoor units according to the operation efficiency.

FIG. 1 is a diagram showing a configuration example of an air conditioning system. The air conditioning system includes a plurality of indoor units installed in the same space and one or more outdoor units installed outside the space. Further, the air conditioning system includes a remote controller for the user to operate an air conditioner including a pair of an indoor unit and an outdoor unit, and a centralized controller as a control device for controlling the air conditioning system.

The system illustrated in FIG. 1 is for operating 16 indoor units 10 installed in a large room with a floor inside a building, 4 outdoor units 11 installed outdoors, and each indoor unit 10. It is composed of 16 remote controllers 12 and a centralized controller 13.

The indoor unit 10 is a ceiling-mounted indoor unit, and includes a fan that sucks and blows out indoor air, a heat exchanger that heats or cools the sucked air, and a control board that controls the fan. Further, the indoor unit 10 includes a temperature sensor for measuring the suction temperature (indoor temperature) and a temperature sensor for measuring the blowout temperature.

The control board of the indoor unit 10 communicates with the remote controller 12 operated by the user, receives an instruction from the remote controller 12, operates or stops the indoor unit 10, and sets or changes the operation mode, temperature, air volume, and the like. conduct. Further, the control board of the indoor unit 10 communicates with the centralized controller 13 to provide information related to operation such as a set temperature, a set air volume, and a measured indoor temperature.

The outdoor unit 11 includes a fan that sucks in and blows out outside air, a heat exchanger that heats or cools the sucked air, a compressor that circulates a refrigerant as a heat medium between the indoor unit 10 and the outdoor unit 11. It is equipped with a control board that controls fans and compressors, and various sensors. The outdoor unit 11 shown in FIG. 1 is a multi-type outdoor unit capable of connecting a plurality of indoor units that send refrigerant.

The control board of the outdoor unit 11 receives an instruction from the remote controller 12 via the indoor unit 10, operates or stops the outdoor unit 11 according to the instruction, and controls the fan and the compressor. Various sensors include a temperature sensor for measuring the outside temperature, a sensor for measuring the current supplied to the compressor, a sensor for measuring the flow rate of the refrigerant, a sensor for measuring the pressure of the refrigerant, and the like.

The remote controller 12 instructs the indoor unit 10 to start or stop the indoor unit 10. In addition, the remote controller 12 instructs to set or change the operation mode, temperature, air volume, and the like.

The centralized controller 13 controls the entire system, communicates with the control board of each indoor unit 10 and the control board of each outdoor unit 11, acquires information necessary for control, and gives necessary instructions.

FIG. 2 is a diagram illustrating a connection state between the indoor unit, the outdoor unit, and the centralized controller. The indoor unit 10 and the outdoor unit 11 are connected by a refrigerant pipe 14. The indoor unit 10, the outdoor unit 11, and the centralized controller 13 are connected by a communication network 15.

In FIG. 2, the air conditioning system includes four refrigerant systems including four indoor units 10 and one outdoor unit 11 connected by one refrigerant pipe 14. All the indoor units 10, the outdoor units 11, and the centralized controller 13 are connected by a communication network 15.

The number of refrigerant systems shown in FIG. 2 and the number of indoor units 10 and outdoor units 11 constituting one refrigerant system are examples, and may be other than these. Further, the communication means of the communication network 15 may be any means as long as communication can be performed between the devices. Therefore, the communication between the devices may be wired communication using a communication cable or the like, or wireless communication using Wi-Fi or the like.

Each indoor unit 10 and each outdoor unit 11 is assigned identification information for identifying a communication partner on the communication network 15. The identification information is an address, such as an ID number that does not overlap with other devices. The identification information can be set manually by the system administrator. In FIG. 2, i11 to i44 are assigned as ID numbers to each of the 16 indoor units 10, and o1 to o4 are assigned as ID numbers to each of the four outdoor units 11.

The refrigerant is adiabatically compressed by the compressor of the outdoor unit 11, becomes high temperature, and is discharged. When used for heating, the high-temperature refrigerant discharged from the compressor is supplied to the heat exchanger of the indoor unit 10 through the refrigerant pipe 14. When used as an air conditioner, the high-temperature refrigerant emitted from the compressor is supplied to the heat exchanger of the outdoor unit 11 and cooled by heat exchange with the outside air. After that, the refrigerant is adiabatically expanded by an expansion valve or the like, and the temperature is further lowered. The refrigerant having a low temperature in this way is supplied to the heat exchanger of the indoor unit 10 through the refrigerant pipe 14.

The indoor unit 10 exchanges heat between the supplied refrigerant and the air sucked by the fan by a heat exchanger, and blows out warm air or cooled air into the room. The heat-exchanged refrigerant is returned to the outdoor unit 11 again through the refrigerant pipe 14. The refrigerant used for heating is adiabatically expanded by an expansion valve or the like of the outdoor unit 11, the temperature is lowered, heat is exchanged with the outside air by a heat exchanger, and then the refrigerant is supplied to the compressor. The refrigerant used for cooling is supplied to the compressor. The refrigerant circulates between the indoor unit 10 and the outdoor unit 11 connected by the refrigerant pipe 14 in this way.

FIG. 3 is a diagram illustrating the hardware configuration of the centralized controller. The centralized controller 13 includes a CPU 20, an input / output unit 21, a communication unit 22, a RAM 23, a memory disk 24, and a power supply unit 25. The CPU 20 and the like are connected to the bus 26 and exchange information with each other via the bus 26.

The CPU 20 is a one-chip microcomputer that executes system operation control. The input / output unit 21 has a display panel and an input button, receives an input for a user to make a setting or an instruction, and displays the current operating state of the indoor unit 10.

The memory disk 24 stores an OS (Operating System), a program for performing operation control, driver software, data acquired by data communication, and the like. The RAM 23 provides a work area for the CPU 20. Therefore, the CPU 20 reads the above program from the memory disk 24, expands it into the RAM 23, and executes the program to execute the operation control of the system.

The communication unit 22 performs data communication with each indoor unit 10 and each outdoor unit 11 connected by the communication network 15. The power supply unit 25 receives power from an outlet or the like, converts an alternating current into a direct current used by the CPU 20 or the like, and supplies the alternating current to the CPU 20 or the like.

In addition to the operation settings for each indoor unit 10 (individual), the input / output unit 21 divides each room (area) representing the installation space of a plurality of indoor units 10 and the area into two or more spaces (blocks) for each block. Operation settings can also be made. Further, the input / output unit 21 can also set the operation for each refrigerant system or each remote controller 12.

The operation settings include cooling / heating selection, temperature, air volume, wind direction settings, and the like. The input / output unit 21 includes an Enter button, a Ser button, an Esc button, and a direction button in order to set the operation thereof. The user uses these buttons to select and input items necessary for operation settings.

FIG. 4 is a diagram showing an example in which a plurality of indoor units are grouped and designated for each group. The centralized controller 13 specifies and registers the indoor unit included in the area, further divides the area into each block, specifies and registers the indoor unit included in each block, and operates in the registered area unit and block unit. Has a function to control. In this example, grouping can be set in two stages, area and block, but the grouping is not limited to this.

In the example shown in FIG. 4, 16 indoor units i11 to i14, i21 to i24, i31 to i34, and i41 to i44 are designated in the area 40. Each outdoor unit is connected to four indoor units by a refrigerant pipe 14.

In the example shown in FIG. 4, the area 40 is divided into three blocks 41 to 43. Eight indoor units i11 to i14 and i21 to i24 are designated for the block 41. Six indoor units i31 to i34, i41, and i43 are designated as the block 42. Two indoor units i42 and i44 are designated for the block 43.

The centralized controller 13 holds area / block management information in order to manage the indoor units designated in the area 40 and the indoor units designated in the blocks 41 to 43. FIG. 5 is a diagram showing an example of area / block management information. The area / block management information holds the area identification information that identifies the area assigned to each area in association with the block identification information that identifies each block included in the area. In FIG. 5, the area identification information is defined as "area 1 (first office)" with respect to the area 40. Further, the block identification information is "block 1 (north)" for block 41, "block 2 (east)" for block 42, and "block 3 (west)" for block 43.

The area / block management information holds an ID number that identifies the indoor unit in association with each block identification information. In the example shown in FIG. 5, the indoor units i11 to i14 and i21 to i24 are associated with the block 1 (north).

In addition to the function of controlling the operation in units of such areas and blocks, the centralized controller 13 may have a function of proportionally calculating the power consumption charge for each space when installed in a commercial facility or the like.

By the way, when the user goes to work on a holiday or early in the morning, only a part of the indoor unit 10 and the outdoor unit 11 are operated to perform air conditioning. In this case, it takes a long time for the indoor temperature to reach the set temperature, and the operated indoor unit 10 and outdoor unit 11 are operated with large power consumption regardless of the operating efficiency.

Therefore, in order to shorten the time required to reach the set temperature and reduce the power consumption, the centralized controller 13 is configured as follows.

FIG. 6 is a block diagram illustrating the functional configuration of the centralized controller 13. The centralized controller 13 realizes various functions as functional means by reading and executing the program stored in the memory disk 24 into the RAM 23. Therefore, the centralized controller 13 includes acquisition means 30, setting means 31, calculation means 32, determination means 33, control means 34, and notification means 35 as functional means. At this time, the centralized controller 13 uses the RAM 23 and the memory disk 24 as the storage means 36.

Here, the centralized controller 13 will be described as having these functional means, but the present invention is not limited to this, and a server device or the like connected via a network to which the air conditioning system is connected has these functional means. You may.

The acquisition means 30 acquires information related to operation from the indoor unit 10 and the outdoor unit 11 that are operating in response to an operation instruction among the plurality of indoor units 10 and one or more outdoor units 11. The information related to the operation is the setting information set for the indoor unit 10 and the outdoor unit 11, the output values of various sensors mounted on the indoor unit 10 and the outdoor unit 11, and the like.

The setting information includes the temperature, air volume, wind direction, operation mode set for the indoor unit 10 by the remote controller 12, the compressor setting value set for the outdoor unit 11, and the like. The output values of the various sensors are room temperature, blowout temperature, outside air temperature, compressor current value, refrigerant flow rate, refrigerant pressure, and the like.

The acquisition means 30 acquires these information at regular time intervals, and stores the information for a fixed period in the storage means 36 together with the acquisition time.

The setting means 31 accepts the designation of the area or block and the designation of the indoor unit constituting each block, associates the identification information of the area with the block and the indoor unit, and stores the area / block management information in the storage means 36. Register with.

The calculation means 32 calculates the power consumption of the indoor unit 10 and the outdoor unit 11 during operation by using the information acquired by the acquisition means 30 and stored in the storage means 36, and calculates the operation efficiency from the power consumption.

The determination means 33 determines whether or not the indoor unit 10 and the outdoor unit 11 during operation are inefficient operation based on the operation efficiency calculated by the calculation means 32. Whether or not the operation is inefficient can be determined by whether or not there are an indoor unit and an outdoor unit whose operating efficiency is below the threshold value for a certain period of time or longer. When it is determined that the operation is inefficient, it indicates that the operation efficiency is low only with the indoor unit 10 and the outdoor unit 11 during operation.

When the control means 34 determines that the operation is inefficient, the control means 34 changes the current operation setting to an operation setting including at least one other indoor unit in order to improve the operation efficiency, and the control means 34 changes the operation setting to include the other indoor unit. Instruct driving. The other indoor unit that gives an instruction to operate is an indoor unit that has not been instructed to operate and has been stopped. In this way, in addition to an arbitrary indoor unit, operating in conjunction with another indoor unit is called interlocking operation.

When the operation setting is input to an arbitrary indoor unit 10 and the indoor unit 10 notifies the operation setting change, the control means 34 cancels the interlocking operation. At this time, the control means 34 stops the indoor unit 10 that operates in conjunction with the indoor unit 10 other than the indoor unit 10 that has transmitted the notification.

Further, when any indoor unit 10 during operation receives an instruction to stop operation, the indoor unit 10 notifies the control means 34 that the instruction to stop operation has been received, and stops its own operation. .. Upon receiving the notification, the control means 34 instructs the indoor unit 10 in interlocking operation to stop, and cancels the interlocking operation.

The notification means 35 notifies the user when inefficient operation continues even after a certain period of time has elapsed after all the indoor units 10 included in the area have been operated. The notification is, for example, by displaying a message calling attention such as "The room does not cool", "The room does not warm up", "Is the window open?" On the display screen of the input / output unit 21. Will be done. In addition to displaying a message, the notification may be made by voice.

FIG. 7 is a flowchart showing an example of operation control processing by the centralized controller 13. When the power is turned on and started in step S1, the centralized controller 13 starts communication with all the indoor units 10 and the outdoor units 11 connected to the air conditioning network in step S2, and confirms the connection. The acquisition means 30 acquires basic information from all the indoor units 10 and the outdoor units 11 in this communication. The basic information is system configuration information such as the number of refrigerant systems existing on the air conditioning network, the configuration of the indoor unit and the outdoor unit of each refrigerant system, the ID number, capacity, and model of each device. The acquisition means 30 stores the acquired basic information in the storage means 36.

The centralized controller 13 constantly communicates with each indoor unit 10 and each outdoor unit 11, and the acquisition means 30 acquires information related to the operation of each indoor unit 10 and each outdoor unit 11. The control means 34 grasps the operation state of each device from the information acquired by the acquisition means 30, transmits an operation setting command to an arbitrary indoor unit 10, and enters a normal processing state for automatic control. Once in the normal processing state, group registration of indoor units for designating the air-conditioning space becomes possible.

The determination means 33 determines in step S3 whether to register or change the air-conditioned space. The determination means 33 determines whether or not the user has selected the group registration function of the indoor unit 10 by using the input / output unit 21. If it is determined to be carried out, the process proceeds to step S4, the setting means 31 accepts the selection, and displays the indoor unit list or the current area and block registration status. The indoor unit list is displayed when group registration is not set, and the current area and block registration status is displayed when group registration has been performed in the past. If it is determined not to carry out, the process proceeds to step S6.

When registering a new group, the user inputs a block name and selects an indoor unit that constitutes the block from the displayed indoor unit list. Next, the user inputs the area name and selects the blocks that make up the area. The storage means 36 can store the layout drawing (layout drawing) of the area in advance, and the setting means 31 superimposes each indoor unit on the layout drawing when displaying the indoor unit list, and which indoor unit is in which position. It is possible to easily grasp whether or not is installed.

When changing the registration status of the current area and block, the user deletes the existing group registration and registers it again. The setting means 31 registers by storing the input area name, block name, and identification information of the indoor unit selected for each block in the storage means 36 in association with each other.

After registering the group, the user selects or inputs the interlocking operation condition. The interlocking operation condition is a condition set as a priority item regarding the operation of the system. Examples of the interlocking operation condition include a condition "power consumption priority" that prioritizes power consumption and a condition "speed priority" that prioritizes the time until the set condition such as the set temperature is reached. In step S5, the setting means 31 sets the interlocking operation condition by storing the interlocking operation condition selected by the user in the storage means 36.

In step S6, the elapsed time is measured by a timer as a time measuring means, and it is determined whether or not the communication time to be periodically reached has been reached. If it is reached, the process proceeds to step S7, and if it is not reached, the process proceeds to step S11. In step S7, the acquisition means 30 acquires information related to operation from each indoor unit 10 and each outdoor unit 11. At this time, the acquisition means 30 acquires operation ON / OFF, operation mode, set temperature, set air volume, compressor ON / OFF, compressor set value, output values of various sensors, and the like as information related to operation. do. The information related to driving is not limited to the above, and may be other information that can be used for calculation of driving efficiency. The acquisition means 30 stores the acquired information in the storage means 36 for a certain period of time. At that time, the acquisition means 30 stores the information together with the measured time information.

In step S8, the calculation means 32 calculates the power consumption of the indoor unit 10 and the outdoor unit 11 during operation using the stored information, and calculates the operation efficiency from the power consumption. Computing means 32, of the stored information, using the total compressor current total value A _s in the outdoor unit 11 in operation _(A), the power supply voltage V (V), and a power factor phi, The power consumption W _s (kW) is calculated by the following equation 1. The power factor φ is the ratio of the power actually consumed (active power) to the apparent power represented by the product of the AC voltage and the current including the power not actually consumed (reactive power).

Further, assuming that the amount of heat produced by each outdoor unit 11 during operation is Q (kW), Q is the total value G (kg / s) of the refrigerant flows of all the compressors in the outdoor unit 11 during operation and the outdoor unit. 11 and specific enthalpy _H o of the refrigerant outlet (kJ / kg), with the outdoor unit 11 the inlet of the specific enthalpy _H i of the refrigerant (kJ / kg), is calculated by the following equation 2.

Among the above equation 2, H _o is the specific enthalpy which is converted from the liquid pipe temperature and pressure of the outdoor unit 11 outlet, H _i is been specific enthalpy converted from the outdoor unit 11 inlet gas pipe end and pressure. The current operating efficiency C is calculated by _{the following equation 3 using W s} calculated by the above equation 1 and Q calculated by the above equation 2.

The calculation means 32 also approximates the current air conditioning load D (kW). D has a cooling load D _c and a heating load D _h , and D _c and D _{h are the output value Ti} (° C.) of the suction temperature sensor of the indoor unit 10 and the output value of the blowout temperature sensor of the indoor unit 10. Assuming that T _b (° C.) and the air volume B (kg / s) of the indoor unit 10 and the specific heat of the air are 1 (kJ / kg ° C.), the calculation is performed by the following equation 4.

Each calculated value is stored in the storage means 36 together with the acquired information.

In step S9, the determination means 33 determines whether or not the operation is inefficient based on the operation efficiency calculated by the calculation means 32. Whether or not the operation is inefficient is determined by whether or not there is an outdoor unit 11 in which the value of C is less than (or less than or equal to) a preset threshold value for a certain period of time (X hours) or more. X differs depending on the interlocking operation conditions, and can be, for example, 2 minutes for "speed priority" and 5 minutes for "power consumption priority". Note that these times are examples, and are not limited to these values.

If it is determined in step S9 that the operation is inefficient, the process proceeds to step S10, and if it is determined that the operation is efficient, the process proceeds to step S11. In step S10, the control means 34 changes the operation setting and selects the indoor unit 10 to perform the interlocking operation. The control means 34 instructs the selected indoor unit 10 to operate.

FIG. 8 is a diagram illustrating interlocking operation. The user instructs the indoor unit i14 near the place where he / she is located to operate by the remote controller 12. At that time, the user sets a desired temperature. The operation instruction is also sent to the outdoor unit o1 having the same refrigerant system as the indoor unit i14, and the operation of the outdoor unit o1 is started together with the indoor unit i14.

The indoor unit i14 and the outdoor unit o1 are operated with a high load in order to bring the temperature in the wide area 40 close to the set temperature set by the user. Therefore, the determination means 33 determines that the operation is inefficient. Then, the control means 34 changes the operation setting to instruct the operation of at least one stopped indoor unit.

When the layout diagram is stored in the storage means 36, the control means 34 is in operation when instructing the indoor units i11 to i13, i21 to i24 and the outdoor unit o2 to operate with reference to the layout diagram. Instruct the wind direction to blow air toward the indoor unit i14. As a result, the set temperature set by the user can be reached quickly.

The determination means 33 periodically determines whether or not the operation is inefficient. If it is determined that the indoor units i11 to i14, i21 to i24 and the outdoor units o1 and o2 in the block 41 are still inefficiently operated, the control means 34 changes the operation setting and the block 41 changes the operation setting. Instructs the operation of the stopped indoor unit in the included area 40. As a result, all the indoor units and outdoor units in the area 40 are operated.

In this way, when the set interlocking operation condition is "power consumption priority", the control means 34 selects and selects groups in the order of groups with a small number of indoor units in order to reduce power consumption as much as possible. It is possible to instruct the stopped indoor units in the group to operate. If the refrigerant system is grouped, the operation of the indoor unit that is stopped in the refrigerant system is instructed, and if it is still judged to be inefficient operation, the operation of the indoor unit that is stopped in the block is instructed. be able to.

On the other hand, when the set interlocking operation condition is "speed priority", the control means 34 is a stopped indoor unit in the area 40 in order to operate more indoor units in order to bring the room closer to the set temperature quickly. And instruct the operation of the outdoor unit. The control means 34 operates all the indoor units and outdoor units in the area, and if it is not inefficient operation, the number of indoor units and outdoor units to be operated can be reduced. Therefore, the control means 34 can select groups in the order of the group having the largest number of indoor units, and instruct the stopped indoor units in the selected group to operate.

Before the control means 34 selects the indoor unit 10 to perform the interlocking operation, the determination means 33 determines whether the cause of the inefficient operation is wasteful operation or insufficient capacity from the load D of the indoor unit 10 currently in operation. To judge. This is because in the case of wasteful operation, even if the indoor unit 10 is additionally operated, the time required to reach the set temperature is not shortened and extra power is consumed.

FIG. 9 is a diagram showing an example in which a part of the indoor units during operation is determined to be wasteful operation and the part of the indoor units is stopped. The determination means 33 determines whether the operation is wasteful or the capacity is insufficient, depending on whether or not the load D of some of the indoor units during operation, which is calculated by the calculation means 32, continues to be 0 or less for X hours or more. .. When the load D of the indoor unit continues to be 0 or less for X hours or more, it does not contribute to the air conditioning of the block at all, so it can be determined that the operation is wasteful.

When all the indoor units i31 to i34, i41, i43 and the outdoor units o3 and o4 in the block 42 are operated and the room temperature reaches the set temperature, for example, the compressor of the outdoor unit o4 frequently stops operating. The thermo-off state is set, and the load of the indoor units i41 and i43 connected to the outdoor unit o4 becomes almost zero.

When the determination means 33 detects that the load of the indoor units i41 and i43 is substantially 0 for X hours (operation stopped state), the indoor units i41 and i43 and the outdoor unit o4 determine that the operation is useless. In response to this, the control means 34 instructs the indoor units i41 and i43 and the outdoor unit o4 that are in wasteful operation to be stopped. The indoor units i41 and i43 and the outdoor unit o4 stop their operation in response to an instruction from the control means 34.

When the load D of some of the indoor units during operation continues to be equal to or higher than the threshold value for X hours or more, the load is too large and the operation is inefficient, so that the determination means 33 can determine that the capacity is insufficient. ..
When the determination means 33 determines that the capacity is insufficient, the control means 34 executes the following control.

When the interlocking operation condition is "power consumption priority", the control means 34 confirms whether or not there is a stopped indoor unit having the same refrigerant system as the indoor unit in the block to which the indoor unit being operated belongs. do. If present, the control means 34 sets the set temperature of the stopped indoor unit to the average set temperature of the operating indoor unit, and instructs the stopped indoor unit to operate.

The control means 34 confirms whether or not there is a stopped indoor unit of another refrigerant system in the same block only when there is no stopped indoor unit of the same refrigerant system in the same block. If present, the control means 34 sets the set temperature of the stopped indoor unit of another refrigerant system to the average set temperature of the operating indoor unit, and instructs the stopped indoor unit to operate.

If it is determined that the capacity is still insufficient even after operating all the indoor units in the block, the control means 34 instructs the operation of the stopped indoor units in the area to which the block belongs. In this case as well, the control means 34 sets the set temperature of the stopped indoor unit to the average set temperature of the operating indoor unit. As a result, all the indoor units in the area are operated.

When the interlocking operation condition is "speed priority", the control means 34 confirms whether or not there is a stopped indoor unit in the area. If present, the control means 34 instructs the stopped indoor unit in the area to operate. As a result, all the indoor units in the area are operated.

When the control means 34 determines that the determination means 33 is not inefficient operation, the control means 34 operates the indoor unit and the outdoor unit belonging to a block other than the block to which the indoor unit to which the operation instruction is received belongs, in which the number of indoor units is smaller than the area. Instruct to stop. This reduces the number of indoor units to be operated.

If the control means 34 determines that the determination means 33 is not inefficient operation even if the indoor unit belonging to the block is operated, only the indoor unit that has received the operation instruction is operated, and the operation of the other indoor units is stopped. To instruct. At this time, if there is an outdoor unit in operation other than the outdoor unit connected to the indoor unit that has received the operation instruction, the control means 34 also instructs the operation of the outdoor unit in operation to be stopped.

When the interlocking operation condition is "power consumption priority", the number may be increased one by one instead of greatly increasing from one indoor unit started by the user to all the indoor units of the same refrigerant system. The same applies when increasing to all indoor units in the block or all indoor units in the area, one indoor unit of another refrigerant system in the same block, and one indoor unit in another block in the area. It may be increased one by one.

The determination of inefficient operation is performed every X hours, and even when the interlocking operation condition is "power consumption priority", when the inefficient operation is stopped, the number of indoor units to be interlocked can be reduced. The control to reduce the number of indoor units that operate in conjunction is the opposite of the control to increase the number of indoor units described above, and all indoor units in the area, all indoor units in the block, and indoors activated by the user in the block. All indoor units with the same refrigerant system as the machine, and indoor units started by the user are reduced in this order.

The centralized controller 13 can hold the information of the layout diagram of the area, and can display each indoor unit on the layout diagram. In this case, since the control means 34 knows the installation position of each indoor unit, the set temperature of the stopped indoor unit during the interlocking operation is not the average set temperature of the indoor unit during operation, but the closest operating indoor unit. It can be set to the set temperature of the indoor unit.

After operating all the indoor units in the area, if the state of inefficient operation due to insufficient capacity continues even after a certain period of time has passed, the notification means 35 notifies the user to call attention. The fixed time in this case can be a time interval longer than the time interval for determining whether or not the operation is inefficient, such as 5 × X hours. The 5 × X time is an example, and is not limited to this.

With reference to FIG. 7 again, in step S11, the determination means 33 determines whether or not the remote controller 12 has been operated by the user during the interlocking operation. The determination means 33 can determine the presence / absence of the operation depending on the presence / absence of the notification that the operation has been received from the indoor unit that has received the operation. If there is no operation, the process returns to step S3, and the determination as to whether or not the operation is inefficient is performed again. When there is an operation, in step S12, the determination means 33 determines whether or not the indoor unit that has been operated is the indoor unit that is performing the interlocking operation.

If the indoor unit is not in the interlocking operation, the process returns to step S3, and the determination of whether or not the operation is inefficient is performed again. If the indoor unit is in interlocking operation, the process proceeds to step S13. Whether or not the indoor unit is in the interlocking operation can be determined by whether or not the operated indoor unit belongs to any of the area, the block, and the refrigerant system in which the interlocking operation is being performed.

In step S13, the control means 34 changes the operation setting or the like according to the content of the received operation, and releases all the related interlocking controls. Specifically, the control means 34 instructs all the indoor units that have been instructed to operate for the interlocking operation, except for the indoor unit that has been operated, to stop the operation. When the user's operation is to stop the indoor unit, the operation of all the indoor units instructed to be operated for the interlocking operation is instructed to be stopped, including the indoor unit that has been operated.

The control means 34 is determined to be wasteful operation, and when the indoor unit that has stopped operation is operated by the user's operation, the operation is stopped if it is similarly determined to be wasteful operation. Therefore, nothing is performed at this stage. Do not control.

After canceling the interlocking operation in step S13, the process returns to step S3 again, it is possible to determine whether or not the operation is inefficient operation, and the interlocking operation can be performed.

In this way, not only the indoor unit that the user has instructed to operate, but also other indoor units are operated in conjunction with each other to shorten the time required to reach the set temperature, improve the operating efficiency, and reduce the power consumption. Can be reduced. Further, since the operation efficiency can be improved and the control according to the interlocking operation conditions can be realized, it is possible to efficiently perform the power demand operation control satisfying the air conditioning demand condition.

Although the air conditioning system, method and program of the present invention have been described in detail with the above-described embodiments, the present invention is not limited to the above-described embodiments, and other embodiments, additions and modifications are made. , Deletion, etc. can be changed within the range that can be conceived by those skilled in the art, and any aspect is included in the scope of the present invention as long as the action / effect of the present invention is exhibited. Therefore, a program product such as a recording medium on which the above program is recorded is also included in the scope of the present invention.

10 ... Indoor unit 11 ... Outdoor unit 12 ... Remote controller 13 ... Centralized controller 14 ... Refrigerant piping 15 ... Communication network 20 ... CPU
21 ... Input / output unit 22 ... Communication unit 23 ... RAM
24 ... Memory disk 25 ... Power supply unit 26 ... Bus 30 ... Acquisition means 31 ... Setting means 32 ... Calculation means 33 ... Judgment means 34 ... Control means 35 ... Notification means 36 ... Storage means 40 ... Areas 41 to 43 ... Blocks

Claims (12)

An air conditioning system equipped with multiple indoor units and one or more outdoor units.
An acquisition means for acquiring information related to operation from the plurality of indoor units and the indoor unit and the outdoor unit that are operating in response to an operation instruction among the one or more outdoor units.
An air conditioning system including a control means for instructing operation of at least one indoor unit that has not received an operation instruction according to the acquired information. Based on the acquired information, it includes a means for determining whether the indoor unit and the outdoor unit in operation are inefficient operation.
The air conditioning system according to claim 1, wherein the control means instructs at least one indoor unit that has not received the operation instruction to operate when it is determined that the operation is inefficient. The plurality of indoor units are grouped into at least one for each remote controller that gives an operation instruction, for each installation area that divides the installation space into a plurality of installation spaces, and for each installation space.
The air conditioning system according to claim 1 or 2, wherein the control means instructs an indoor unit that has not received an operation instruction in the group to which the indoor unit that is operating belongs to operate. The air conditioning according to any one of claims 1 to 3, wherein the control means changes the indoor unit instructing the operation according to the conditions set as priorities regarding the operation of the air conditioning system. system. The plurality of indoor units are grouped for each remote controller that gives an operation instruction, for each installation area that divides the installation space into a plurality of units, and for each installation space.
The acquisition means acquires the information at regular time intervals and obtains the information.
When the condition set as a priority item regarding the operation of the air conditioning system is power consumption priority, the control means selects a group in order from the group having the smallest number of indoor units, and issues an operation instruction in the selected group. The air conditioning system according to any one of claims 1 to 4, which instructs the indoor unit that has not received the operation to operate. The plurality of indoor units are grouped for each remote controller that gives an operation instruction, for each installation area that divides the installation space into a plurality of installation spaces, and for each installation space.
The acquisition means acquires the information at regular time intervals and obtains the information.
When the condition set as a priority item regarding the operation of the air conditioning system is speed priority, the control means selects a group in order from the group having the largest number of indoor units, and the group having the largest number of indoor units. If is selected, the indoor unit that has not received the operation instruction in the selected group is instructed to operate, and if other groups are selected, the indoor unit that is operating in response to the operation instruction outside the selected group is instructed. The air conditioning system according to any one of claims 1 to 4, which instructs the machine to stop operation. The control means according to any one of claims 1 to 6, wherein when the indoor unit in operation receives an operation stop instruction, the control means instructs the indoor unit in operation to stop the operation in response to the operation instruction. The described air conditioning system. The air conditioning system according to any one of claims 1 to 7, further comprising a notification means for alerting the user by display or voice when the set temperature is not reached even after operating the plurality of indoor units. .. A storage means for storing the layout drawings of the plurality of indoor units is included.
The claim means that when instructing an indoor unit that has not received the operation instruction to operate the control means, the control means refers to the layout drawing and instructs the wind direction to blow air toward the indoor unit during the operation. The air conditioning system according to any one of 1 to 8. Any of claims 1 to 9, wherein the control means instructs the indoor unit connected to the outdoor unit to stop the operation when it detects that the outdoor unit is in the stopped state based on the acquired information. The air conditioning system according to claim 1. It is a method of controlling the operation of an air conditioning system including a plurality of indoor units and one or more outdoor units by a control device.
A step of acquiring information related to operation from the indoor unit and the outdoor unit in which the control device is operating in response to an operation instruction among the plurality of indoor units and the one or more outdoor units.
An operation control method including a step of instructing operation of at least one indoor unit to which the control device has not received an operation instruction according to the acquired information. A program for causing a computer to execute each step included in the operation control method according to claim 11.

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