JP5180172B2 - Air conditioning system - Google Patents

Description

  The present invention relates to an air conditioning system, and more particularly to an air conditioning system that harmonizes air in a space.

With recent global warming and the development of economic industries that are progressing on a global scale, efforts aimed at reducing CO ₂ emissions or reducing energy consumption are regarded as important. Against this background, various techniques for reducing energy consumed in office buildings and large stores and promoting energy saving have been proposed (see, for example, Patent Document 1).

  The system described in Patent Literature 1 dynamically groups air conditioners installed in the vicinity of a place where air conditioning that changes according to people entering and exiting or moving in a store or the like. Then, the grouped air conditioners are caused to execute the air conditioning operation in conjunction with each other.

JP 2009-174734 A

  In the system described in Patent Literature 1, air conditioning in a place where air conditioning needs to be performed is intensively executed by a plurality of grouped air conditioners. For this reason, air conditioning of a desired place is performed in a short time.

  However, in this system, the grouped air conditioners are operated uniformly without considering each efficiency. Accordingly, the efficiency of the grouped air conditioners as a whole is not necessarily good.

  The present invention has been made under the above circumstances, and an object thereof is to intensively air-condition the surroundings of each user inside a space while efficiently operating an air conditioner.

In order to achieve the above object, the air conditioning system of the present invention provides:
A first air conditioner that discharges conditioned air from the first outlet into the space;
A second air conditioner for discharging conditioned air from the second outlet into the space;
A communication terminal possessed by a user in the space for transmitting information on a desired temperature desired by the user;
A position detecting device for detecting a position of the communication terminal in the space;
Power consumption when operating both the first air conditioner and the second air conditioner so that the temperature at the position of the communication terminal matches the desired temperature;
Compared with the power consumption when driving one of the first air conditioner and the second air conditioner so that the temperature at the position of the communication terminal matches the desired temperature. And
From the comparison result, determine whether to operate both the first air conditioner and the second air conditioner, or to operate either one,
Based on the determination result, a control device that operates the first air conditioner and the second air conditioner;
Is provided.

  According to the present invention, the amount of conditioned air discharged from the discharge port is adjusted based on the relationship between the position of each communication terminal possessed by the user and the position of each discharge port. Thereby, the periphery of the user in the space can be intensively air-conditioned while operating the air conditioner efficiently.

It is a block diagram of the air-conditioning system concerning a 1st embodiment. It is a top view (the 1) of the space used as the object of air conditioning. It is a flowchart for demonstrating operation | movement of a controller. It is a figure for demonstrating the adjustment point of the discharge amount of conditioned air. It is a figure for demonstrating operation | movement of the air conditioning system which concerns on 2nd Embodiment. It is a block diagram of an air-conditioning system concerning a 3rd embodiment. It is a top view (the 2) of the space used as the object of air conditioning. It is a block diagram of an air-conditioning system concerning a 4th embodiment. It is a top view (the 3) of the space used as the object of air conditioning.

<< First Embodiment >>
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing a schematic configuration of an air conditioning system 10 according to the present embodiment. The air conditioning system 10 is a system that harmonizes the air inside a space 100 that is shared by many users, such as a floor partitioned into an office building.

  As shown in FIG. 1, the air conditioning system 10 includes a controller 20, an air conditioning unit 30, a duct 34, a blowout control unit 40, damper units 41 to 44, three positioning units 51 to 53, and four communication terminals 71 to 74. have.

  The air conditioning unit 30 includes an air conditioner 31 disposed in the space 100, an outdoor unit 32 disposed outside the space 100, and a measurement unit 35A that measures electric power supplied to the air conditioner 31 and the outdoor unit 32. 35B.

  The air conditioner 31 includes an evaporator, a blower fan that circulates air inside the space 100 via the evaporator, and a control unit that controls the output of the blower fan based on an instruction from the controller. The outdoor unit 32 includes a compressor, a condenser, a cooling fan that cools the condenser, and a control unit that controls the output of the compressor and the like based on instructions from the controller. Each component device of the air conditioner 31 and the outdoor unit 32 operates using power supplied from the power system as energy.

  Each of the measurement units 35A and 35B includes a wireless interface for wireless communication with the controller 20, a wattmeter for measuring the power supplied from the power system to the air conditioner 31 or the outdoor unit 32, and the amount of power supplied. It has a watt-hour meter to measure. Each of the measurement units 35 </ b> A and 35 </ b> B outputs the result of measurement by the wattmeter or watthour meter to the controller 20.

  In the air conditioning unit 30 configured as described above, the refrigerant liquefied by the condenser by being compressed by the compressor of the outdoor unit 32 is sent to the evaporator of the air conditioner 31 via the circulation hose 33. Then, the refrigerant evaporated in the evaporator returns to the compressor of the outdoor unit 32 through the circulation hose 33. As described above, when the refrigerant circulates between the air conditioner 31 and the outdoor unit 32, heat exchange is performed between the refrigerant and the air in the space 100, and heat exchange is performed between the refrigerant and the outside air. Is performed, the air inside the space 100 is harmonized. The conditioned air (hereinafter also referred to as conditioned air) is discharged to the duct 34 by the blower fan of the air conditioner 31.

  In the air conditioning unit 30, under the instruction of the controller, the control units provided in the air conditioner 31 and the outdoor unit 32 respectively cooperate to control the output of devices such as a blower fan, a compressor, and a cooling fan. Thus, the temperature of the conditioned air discharged to the duct 34 and the discharge amount are adjusted.

  The duct 34 has two portions, namely, four discharge ports 34a to 34d arranged in the space 100 and a duct main body 34e serving as a passage through which conditioned air discharged from the tone adjustment device 31 moves to the discharge ports 34a to 34d. ing. The discharge ports 34 a to 34 d provided in the duct 34 are disposed so as to be appropriately dispersed so that the conditioned air is evenly distributed in the space 100.

  FIG. 2 is a plan view of the space 100. As can be seen from FIG. 2, the discharge ports 34 a to 34 d are positioned on the floor surface of the space 100 at substantially the center of regions A <b> 1 to A <b> 4 defined by straight lines L <b> 1 and L <b> 2 parallel to the X axis and the Y axis, respectively. Are arranged to be. Thereby, the conditioned air discharged from the discharge port 34a is discharged mainly into the space on the area A1. Moreover, the conditioned air discharged from the discharge port 34b is discharged mainly into the space on the area A2. In addition, the conditioned air discharged from the discharge port 34c is mainly discharged into the space on the region A3. In addition, the conditioned air discharged from the discharge port 34d is discharged mainly into the space on the region A4.

  Returning to FIG. 1, each of the damper units 41 to 44 is provided corresponding to each of the discharge ports 34 a to 34 d. Each of the damper units 41 to 44 includes an opening / closing plate that opens and closes the discharge ports 34a to 34d, and a drive motor that moves the opening / closing plate to define the opening degree of the discharge ports 34a to 34d.

  The blowing control unit 40 adjusts the opening degree of each of the discharge ports 34 a to 34 d by moving the opening and closing plates via the drive motors of the damper units 41 to 44 based on the instruction from the controller 20.

  The communication terminals 71 to 74 are wireless communication terminals possessed by the users 81 to 84 in the space 100. The communication terminals 71 to 74 transmit identification information ID including a code assigned to each communication terminal in response to a ranging request signal from the positioning units 51 to 53. This identification information ID is received by each of the positioning units 51-53. Hereinafter, the identification information of the communication terminals 71 to 74 is displayed as IDn, respectively. Note that n is an integer from 1 to 4 corresponding to each of the communication terminals 71 to 74.

  Each of the users 81 to 84 can transmit information on the temperature of the space 100 desired by the user 81 to 84 to the controller 20 via the communication terminals 71 to 74. For example, when the user 81 to 84 changes the value of the set temperature displayed on the display screen of the communication terminal 71 to 74 with a button or direction key provided on the communication terminal 71 to 74, the changed value is desired. Set as temperature STn. Each of the communication terminals 71 to 74 transmits the set temperatures ST1 to ST4 to the controller 20 as information (IDn, STn) in association with the identification information ID1 to ID4.

  Each of the communication terminals 71 to 74 has a temperature sensor that measures the air temperature. Each of the communication terminals 71 to 74 transmits the air temperatures T1 to T4 measured via the temperature sensor to the controller 20 as information (IDn, Tn) in association with the identification information ID1 to ID4.

  Each of the positioning units 51 to 53 is disposed at a known position in the space 100. Specifically, as can be seen with reference to FIG. 2, each of the positioning unit 51 and the positioning unit 53 is disposed in the vicinity of the −Y side corner of the space 100. The positioning unit 52 is disposed in the central part on the + Y side of the space 100.

  Each of the positioning units 51 to 53 receives a response signal from the time at which the distance measurement request signal is transmitted when receiving a response signal from the communication terminals 71 to 74 after transmitting the distance request signal to the communication terminals 71 to 74. Based on the time until the set time, the distances D1 to D3 to the communication terminals 71 to 74 as the transmission source are estimated.

  For example, the time from when the positioning units 51 to 53 transmit a ranging request signal and receive a response signal is T1. The time from when the communication terminals 71 to 74 receive the distance measurement request signal and the response signal is transmitted is T2. This time T2 is a time required for the communication terminals 71 to 74 to perform signal processing. For this reason, the time T2 does not vary depending on the distance between the positioning units 51 to 53 and the communication terminals 71 to 74, and is always constant. On the other hand, the difference T3 between the time T1 and the time T2 varies depending on the distance between the positioning units 51-53 and the communication terminals 71-74. This difference T3 is the time required for electromagnetic waves to reciprocate between the positioning units 51-53 and the communication terminals 71-74. Therefore, the positioning units 51 to 53 estimate the distance Dn (n = 1, 2, 3) using the following equation (1). In addition, V in following Formula (1) is the speed of the electromagnetic waves used for communication with the positioning units 51-53 and the communication terminals 71-74, and is equivalent to the speed of light.

  Dn = V × (T3 / 2) (1)

  Then, the positioning units 51 to 53 associate the estimated distances D1 to D3 with the identification information ID1 to ID4 of the communication terminal, and position information (IDn, D1), position information (IDn, D2), or position information ( IDn, D3) is transmitted to the controller 20.

  The controller 20 performs wireless communication with the air conditioner 31, the outdoor unit 32, the communication terminals 71 to 74, and the positioning units 51 to 53. And based on the information from the communication terminals 71-74 and the positioning units 51-53, the air conditioning apparatus 31, the outdoor unit 32, and the blowing control unit 40 are controlled centrally.

  Hereinafter, the operation of the controller 20 will be described with reference to FIG.

  FIG. 3 is a flowchart showing processing executed by the controller 20. When each component device of the air conditioning system 10 is activated, the controller 20 first communicates with the positioning units 51 to 53 in the first step S101, and position information (IDn, D1) about each communication terminal 71 to 74. , Position information (IDn, D2) and position information (IDn, D3) are acquired.

  In the next step S102, the controller 20 determines each communication terminal 71-74 from the distance between each communication terminal 71-74 and each positioning unit 51-53 and the known position in the space 100 of each positioning unit 51-53. The position Ln in the space 100 of each of 74 is calculated.

  In general, the users 81 to 84 move on the floor surface of the normal space 100. For this reason, the position Ln can be expressed with reference to an XY coordinate system having, for example, the left end corner of the space 100 in FIG. Therefore, the controller 20 includes the position information (IDn, D1), the position information (IDn, D2), the position information (IDn, D3) for each of the communication terminals 71 to 74, and the XY coordinates of the positioning units 51 to 53. The position Ln (x, y) of each of the communication terminals 71 to 74 is calculated from the system position coordinates.

  In the next step S103, the controller 20 specifies the areas A1 to A4 where the communication terminals 71 to 74 are located while referring to the positions Ln (x, y) of the communication terminals 71 to 74. And the ratio of the quantity of the conditioned air discharged from the discharge ports 34a-34d is calculated according to the number of the communication terminals 71-74 located in each area | region A1-A4.

  For example, as shown in FIG. 4, the communication terminal 71 and the communication terminal 72 are located in the area A1, the communication terminal 73 is located in the area A2, the communication terminal 74 is located in the area A3, When the communication terminal is not located, the controller 20 determines the ratio of the amount of conditioned air discharged from the discharge ports 34a to 34d, for example, 2/4: 1/4: 1/4: 0/4.

  In the next step S104, the controller 20 communicates with each of the communication terminals 71 to 74, and acquires information (IDn, TSn) regarding the set temperature.

  In the next step S105, the controller 20 communicates with each of the communication terminals 71 to 74, and acquires information (IDn, Tn) regarding the air temperature.

In the next step S106, the controller 20 sets the air conditioner 31 and the outdoor unit 32 constituting the air conditioning unit 30 based on the information on the set temperature (IDn, TSn) and the information on the air temperature (IDn, Tn). Determine each output. Each output can be, for example, an average value _{T AVG} air temperature T1~T4 detected by each of the communication terminals 71 to 74 respectively, the average value _{ST AVG} set temperature ST1~ST4 set for each communication terminal 71 to 74, respectively _Can be determined according to the difference between the average value T _AVG and the average value ST _AVG .

  In the next step S107, the controller 20 transmits the determined output value to the air conditioner 31 and the outdoor unit 32. The control unit of the air conditioner 31 and the outdoor unit 32 controls the devices constituting the air conditioner 31 and the outdoor unit 32 based on the output value determined by the controller 20. Thereby, the air conditioning apparatus 31 and the outdoor unit 32 are operated with the output determined by the controller 20.

  In the next step S108, the controller 20 outputs information related to the ratio of the discharge amount calculated in step S103 to the blowing control unit 40. When the information regarding the ratio of the discharge amount is notified, the blowing control unit 40 controls each of the damper units 41 to 44 so that the amount of conditioned air discharged from each of the discharge ports 34a to 34d becomes the notified ratio. I do. Thereby, conditioned air is discharged from each of the discharge ports 34a to 34d at the ratio calculated in step S103.

  For example, when the information regarding the ratio (2/4, 1/4, 1/4, 0/4) is notified to the blowing control unit 40, the discharge amount of the conditioned air from the discharge ports 34a to 34d is When the discharge amount from the air conditioner 31 is a, the values are 2a / 4, a / 4, a / 4, and 0, respectively.

  Thereafter, the controller 20 repeatedly executes the processing from step S101 to step S108. Thereby, if the users 81-84 move to another area or change the value of the set temperature displayed on the display screen of the communication terminals 71-74, the air conditioner 31 and the outdoor unit 32 will be changed accordingly. The output and the discharge amount of conditioned air from the discharge ports 34a to 34d are adjusted as appropriate.

  As described above, in the present embodiment, ejection is performed from each of the ejection ports 34a to 34d based on the relationship between the positions of the communication terminals 71 to 74 possessed by the user and the positions of the ejection ports 34a to 34d. The amount of conditioned air is adjusted. Specifically, the discharge ports 34a to 34d are set such that the ratio of the amount of conditioned air discharged from the discharge ports 34a to 34d is a ratio determined according to the number of communication terminals 71 to 74 located in the regions A1 to A4. The amount of conditioned air discharged from each is adjusted.

  Thereby, the circumference | surroundings of the users 81-84 possessing the communication terminals 71-74 inside the space 100 can be intensively air-conditioned. Moreover, even if the users 81-84 move to another area within the space 100, the conditioned air discharged from the discharge ports 34a-34d depends on the positions of the users 81-84 having the communication terminals 71-74. Each discharge amount is adjusted. Thereby, the circumference | surroundings of the moving users 81-84 can be intensively air-conditioned, operating the air conditioning apparatus 31 and the outdoor unit 32 with optimal efficiency.

  In the above embodiment, the amount of conditioned air discharged from the discharge ports 34a to 34d is adjusted according to the number of communication terminals 71 to 74 located in the regions A1 to A4. This invention is not limited to this, For example, the average value of the desired temperature set to the communication terminals 71-74 in area | region A1-A4 is calculated for every area | region A1-A4. And it is good also as controlling the damper units 41-44 based on the calculated desired temperature, and adjusting the quantity of the conditioned air discharged from the discharge ports 34a-34d, respectively.

  For example, the average value of the set temperatures in the regions A1 to A4 and the difference between the average value and the upper limit temperature of 30 ° C. are obtained. And the damper units 41-44 are driven so that the discharge amount from each of the discharge ports 34a-34d becomes the ratio prescribed | regulated by this difference. For example, when the average values of the set temperatures in the regions A1 to A4 are 26 ° C., 27 ° C., 28 ° C., and 28 ° C., the discharge amount from each of the discharge ports 34a to 34d is 4: 3: 2: 2. The damper units 41 to 44 are controlled so that In this case, when the users 81 to 84 move to other areas, the discharge amount of the conditioned air in the movement destination area is adjusted based on the desired temperature of the moved users 81 to 84. Therefore, the air conditioning around the users 81 to 84 is performed according to the preferences of the users 81 to 84.

  In this case, the damper units 41 to 44 are controlled based on, for example, the median value of the set temperatures in each of the regions A1 to A4 instead of the average value of the set temperatures in each of the regions A1 to A4. The amount of conditioned air discharged from each of 34d may be adjusted.

<< Second Embodiment >>
Next, a second embodiment of the present invention will be described with reference to the drawings. In addition, about the structure same or equivalent to 1st Embodiment, while using an equivalent code | symbol, the description is abbreviate | omitted or simplified.

  The air conditioning system 10 according to the present embodiment is the first implementation in that the outputs of the air conditioner 31 and the outdoor unit 32 are adjusted so that the power consumed by the air conditioning unit 30 does not exceed a predetermined target value. It differs from the air conditioning system 10 which concerns on a form.

  FIG. 5 shows a curve S1 and a curve S2 showing the relationship between time and power consumption. A curve S1 shows the transition of the amount of power consumed by the air conditioning unit 30 during a predetermined period such as the past week or month. A curve S2 shows a transition of the amount of power consumed by the currently operating measurement unit 30.

  The controller 20 determines the outputs of the air conditioner 31 and the outdoor unit 32 while monitoring the measurement results from the measurement unit 35A and the measurement unit 35B. Specifically, the outputs of the air conditioner 31 and the outdoor unit 32 are determined so that the amount of power in the air conditioning unit 30 indicated by the curve S2 is lower than the amount of power indicated by the curve S1. Then, the determined output value is transmitted to the air conditioner 31 and the outdoor unit 32. The control unit of the air conditioner 31 and the outdoor unit 32 controls the devices that constitute the air conditioner 31 or the outdoor unit 32 based on the output value determined by the controller 20.

  As a result, even if the power consumption in the air conditioning unit 30 temporarily exceeds the curve S1 as indicated by the curve S2 in FIG. 5, it finally falls below the management target value.

  In the present embodiment, the outputs of the air conditioner 31 and the outdoor unit 32 are determined while monitoring the measurement results from the measurement unit 35A and the measurement unit 35B. The present invention is not limited to this. For example, the controller 20 may adjust the outputs of the air conditioner 31 and the outdoor unit 32 by raising and lowering the set temperatures for the air conditioner 31 and the outdoor unit 32. Good.

<< Third Embodiment >>
Next, a third embodiment of the present invention will be described with reference to the drawings. In addition, about the structure same or equivalent to said each embodiment, while using an equivalent code | symbol, the description is abbreviate | omitted or simplified.

  As shown in FIG. 6, the air conditioning system 10 according to the third embodiment includes a controller 20, two air conditioning units 30 </ b> A and 30 </ b> B, three positioning units 51 to 53, and a communication terminal 71.

  FIG. 7 is a plan view of the space 100. As can be seen from FIG. 7, each of the discharge port 34a of the air conditioner 31 constituting the air conditioning unit 30A and the discharge port 34b of the air conditioner 31 constituting the air conditioning unit 30B is a straight line L2 parallel to the Y axis. It arrange | positions so that it may be located in the approximate center of area | region A1, A2 divided. Thereby, the conditioned air discharged from the discharge port 34a is discharged mainly into the space on the area A1. Moreover, the conditioned air discharged from the discharge port 34b is discharged mainly into the space on the area A2.

  The controller 20 specifies whether the area where the communication terminal 71 is located is the area A1 or the area A2 by the method described in the above embodiments. And each air conditioning unit 30A, 30B is drive | operated until the air temperature in which the communication terminal 71 is located becomes the user's 81 desired temperature. Next, the controller 20 operates the air conditioning units 30A and 30B while changing the output patterns of the air conditioning unit 30A and the air conditioning unit 30B, for example, every T time, and the air where the communication terminal 71 is located. The temperature is kept at the desired temperature of the user 81. At the same time, the amount of power consumed by the entire air conditioning unit 30A and the air conditioning unit 30B is measured every T time. And the output pattern when the electric energy is the smallest is specified. Hereinafter, this output pattern is referred to as an output pattern 1.

  Next, the controller 20 operates the air-conditioning unit 30A while changing the output pattern of the air-conditioning unit 30A that mainly air-conditions the space on the area A1 where the communication terminal 71 is located, every T time. The air temperature where 71 is located is maintained at the temperature desired by the user 81. At the same time, the amount of power consumed by the air conditioning unit 30A is measured every T time. And the output pattern when the electric energy is the smallest is specified. Hereinafter, this output pattern is referred to as an output pattern 2.

  Next, the controller 20 uses the power consumption when the air conditioning unit 30A and the air conditioning unit 30B are operated for T hours with the output pattern 1 and the power consumption when the air conditioning unit 30A is operated with the output pattern 2 for T hours. Compare

  Next, when the power consumption when the air-conditioning unit 30A and the air-conditioning unit 30B are operated with the output pattern 1 is smaller in the output pattern 1, the controller 20 thereafter performs the air-conditioning unit 30A and the air-conditioning unit 30A and The air conditioning unit 30B is operated with the output pattern 1. On the other hand, if the power consumption when the air conditioning unit 30A is operated in the output pattern 2 is smaller in the output pattern 2, the controller 20 thereafter selects only the air conditioning unit 30A in the output pattern 2 in the situation shown in FIG. drive.

  Thereby, in this embodiment, it becomes possible to air-condition the circumference | surroundings of the user 81 efficiently with little electric power.

  In the present embodiment, the air conditioning unit 30A and the air conditioning unit 30B each have the outdoor unit 32. The present invention is not limited to this, and one outdoor unit may be shared by the air conditioning unit 30A and the air conditioning unit 30B.

<< Fourth Embodiment >>
Next, a fourth embodiment of the present invention will be described with reference to the drawings. In addition, about the structure same or equivalent to said each embodiment, while using an equivalent code | symbol, the description is abbreviate | omitted or simplified.

  As shown in FIG. 8, the air conditioning system 10 according to the fourth embodiment includes a controller 20, two air conditioning units 30A and 30B, three positioning units 51 to 53, and four communication terminals 71 to 74. doing.

  FIG. 9 is a plan view of the space 100. As can be seen from FIG. 9, each of the discharge port 34a of the air conditioner 31 constituting the air conditioning unit 30A and the discharge port 34b of the air conditioner 31 constituting the air conditioning unit 30B is a straight line L2 parallel to the Y axis. It arrange | positions so that it may be located in the approximate center of area | region A1, A2 divided. Thereby, the conditioned air discharged from the discharge port 34a is discharged mainly into the space on the area A1. Moreover, the conditioned air discharged from the discharge port 34b is discharged mainly into the space on the area A2.

  The controller 20 specifies whether the area where the communication terminals 71 to 74 are located is the area A1 or the area A2 by the method described in the above embodiments. And according to the number of the communication terminals 71-74 located in each area | region A1, A2, it determines whether to drive | operate both the air conditioning unit 30A and the air conditioning unit 30B, or to drive any one.

  For example, as a method for determining the air conditioning unit to be operated, when the difference in the number of communication terminals 71 to 74 in each of the areas A1 and A2 is equal to or less than a predetermined value, both the air conditioning units 30A and 30 are operated. To do. Moreover, when the difference of the number of the communication terminals 71-74 in each area | region A1, A2 is more than predetermined value, the air conditioning which discharges conditioned air to the area | region where the number of the communication terminals 71-74 located is larger Operate the unit.

  Thereby, in this embodiment, it becomes possible to air-condition the circumference | surroundings of the users 81-84 efficiently with little electric power.

  In the present embodiment, based on the number of communication terminals 71 to 74 in each of the areas A1 and A2, it is determined whether to operate both the air conditioning unit 30A and the air conditioning unit 30B or one of them. The present invention is not limited to this, and an average value of the desired temperature is calculated for each of the areas A1 and A2, and both the air conditioning unit 30A and the air conditioning unit 30B are operated in consideration of this average value, or either It may be decided whether to drive either one.

  Moreover, in this embodiment, when the difference of the number of the communication terminals 71-74 in each area | region A1, A2 is below a predetermined value, both air-conditioning unit 30A and air-conditioning unit 30B are drive | operated, and each area | region A1. When the difference in the number of communication terminals 71 to 74 at A2 is equal to or greater than a predetermined value, the air conditioning unit that discharges conditioned air to the region where the number of communication terminals 71 to 74 located is larger. The present invention is not limited to this, and when the difference in the number of communication terminals 71 to 74 in each of the areas A1 and A2 is equal to or less than a predetermined value, both the air conditioning units 30A and 30B are operated. When the difference in the number of communication terminals 71 to 74 in each of the areas A1 and A2 is equal to or greater than a predetermined value, both the air conditioning units 30A and 30B are operated, and the number of communication terminals 71 to 74 located is The output of the outdoor unit 32 of the air conditioning unit that air-conditions the smaller area may be set to zero. In this case, the air conditioning unit that air-conditions the area with the smaller number of communication terminals 71 to 74 is operated in the air blowing mode. Thereby, the air inside the space 100 can be circulated while reducing power consumption.

  In this case, an average value of the desired temperature may be calculated for each of the areas A1 and A2, and the air conditioning unit that sets the output of the outdoor unit 32 to zero may be determined in consideration of the average value.

  Moreover, in this embodiment, when the difference of the number of the communication terminals 71-74 in each area | region A1, A2 is below a predetermined value, both air-conditioning unit 30A and air-conditioning unit 30B are drive | operated, and each area | region A1. When the difference in the number of communication terminals 71 to 74 at A2 is equal to or greater than a predetermined value, the air conditioning unit that discharges conditioned air to the region where the number of communication terminals 71 to 74 located is larger. The present invention is not limited to this, and both the air conditioning unit 30A and the air conditioning unit 30B are operated based on the efficiency of the air conditioning units 30A and 30B, or either one of the air conditioning unit 30A and the air conditioning unit 30B is operated. You may decide.

  For example, based on the number of all the communication terminals 71 to 74 in the space 100, the air temperature at the position of each communication terminal 71 to 74, and the temperature outside the space 100, the position of each communication terminal 71 to 74. Calculate the output required to set the air temperature at the desired temperature. If the efficiency when the calculated output is borne by the air conditioning unit 30A and the air conditioning unit 30B is higher than the efficiency borne by any one of the air conditioning units, the air conditioning unit 30A and the air conditioning unit 30B. Drive both. On the other hand, when the efficiency when the calculated output is borne by the air conditioning unit 30A and the air conditioning unit 30B is lower than the efficiency when borne by any one of the air conditioning units, the air conditioning unit 30A and the air conditioning unit 30B. Drive one of them.

  Specifically, when the predicted output is 1800 W, each of the air conditioning unit 30A and the air conditioning unit 30B bears an output of 900 W, but the efficiency of each of the air conditioning unit 30A and the air conditioning unit 30B is 60%. Then, it is necessary to input 3000 W in total to the air conditioning unit 30A and the air conditioning unit 30B. On the other hand, when operating only the air conditioning unit 30A, the air conditioning unit 30A will bear the output of 1800W. If the efficiency of the air conditioning unit 30A is 50%, the air conditioning unit 30A has 3600W of power. Input is required. In this case, both the air conditioning unit 30A and the air conditioning unit 30B are operated.

  Further, as described above, both the air conditioning unit 30A and the air conditioning unit 30B are operated based on the efficiency of each of the air conditioning unit 30A and the air conditioning unit 30B, or one of the air conditioning unit 30A and the air conditioning unit 30B is operated. In this case, the determination may be made based on the efficiency of the outdoor unit 32 of each of the air conditioning unit 30A and the air conditioning unit 30B, instead of the efficiency of each of the air conditioning unit 30A and the air conditioning unit 30B. Furthermore, if one of the air conditioning unit 30A and the air conditioning unit 30B is operated, only the air conditioner 31 may be operated for the other air conditioning unit.

  Further, in the present embodiment, the case where each of the air conditioning unit 30A and the air conditioning unit 30B includes one air conditioner 31 and one outdoor unit 32 has been described. The present invention is not limited to this, and each of the air conditioning unit 30A and the air conditioning unit 30B may have a plurality of air conditioners that share the outdoor unit 32.

  As mentioned above, although embodiment of this invention was described, this invention is not limited by said each embodiment.

  For example, the number of communication terminals in each of the above embodiments is an example, and the air conditioning system 10 may have one or more or four or more communication terminals.

  In addition, the number of positioning units in each of the above embodiments is an example, and the air conditioning system 10 may have four or more positioning units. When the user moves only on the floor of the space 100, the number of positioning units may be two.

  Moreover, in each said embodiment, although control according to the number of the communication terminals located in area | region A1-A4 corresponding to the discharge port which conditioned air discharges was performed, it is not restricted to this, The discharge which conditioned air discharges Control according to the number of communication terminals within a predetermined distance from the exit may be performed.

  Moreover, in each said embodiment, it is good also as displaying the power consumption per user in the space 100 on the display screen of the communication terminals 71-74. Thereby, since a user can recognize power consumption visually, the energy saving consciousness of each user can be improved.

  Various embodiments and modifications of the present invention are possible without departing from the broad spirit and scope of the present invention. Further, the above-described embodiment is for explaining the present invention, and does not limit the scope of the present invention. That is, the scope of the present invention is shown not by the embodiments but by the claims. Various modifications within the scope of the claims and within the scope of the equivalent invention are considered to be within the scope of the present invention.

  The air conditioning system of the present invention is suitable for harmonizing air in a space.

DESCRIPTION OF SYMBOLS 10 Air conditioning system 20 Controller 30 Air conditioning unit 31 Air conditioning apparatus 32 Outdoor unit 33 Circulation hose 34 Duct 34a-34d Outlet 34e Duct main body 35A, 35B Measurement unit 40 Outlet control unit 41-44 Damper unit 51-53 Positioning unit 71-74 Communication terminal 81-84 User 100 Space A1-A4 area L1, L2 Straight line S1, S2 Curve

Claims (5)

A first air conditioner that discharges conditioned air from the first outlet into the space;
A second air conditioner for discharging conditioned air from the second outlet into the space;
A communication terminal for a user in the space to transmit information on a desired temperature desired by the user; a position detection device for detecting a position of the communication terminal in the space;
Power consumption when operating both the first air conditioner and the second air conditioner so that the temperature at the position of the communication terminal matches the desired temperature;
Compared with the power consumption when driving one of the first air conditioner and the second air conditioner so that the temperature at the position of the communication terminal matches the desired temperature. And
From the comparison result, determine whether to operate both the first air conditioner and the second air conditioner, or to operate either one,
A control device for controlling the output of the first air conditioner and the output of the second air conditioner based on the determination result;
Air conditioning system equipped with. A first air conditioner that discharges conditioned air into the space;
A second air conditioner that discharges conditioned air into the space;
A communication terminal for a user in the space to transmit information on a desired temperature desired by the user; a position detection device for detecting a position of the communication terminal in the space;
Based on the number of the communication terminals in the space, the temperature at the position of the communication terminal, and the temperature outside the space, an output when the temperature at the position of the communication terminal is set to the desired temperature. Predict,
The first air conditioner and the second air conditioner so that the sum of the output of the first air conditioner and the output of the second air conditioner is equal to the predicted output. The efficiency of the entire first air conditioner and the second air conditioner when both are operated,
Efficiency of the one air conditioner when one of the first air conditioner and the second air conditioner is operated so that the output is equal to the predicted output And based on
A controller that determines whether to operate both the first air conditioner and the second air conditioner, or to operate either one;
Air conditioning system equipped with. A first air conditioner that has a first heat exchanger that exchanges heat with air outside the space, and that discharges air conditioned in the space from a first outlet;
A second air conditioner that has a second heat exchanger that exchanges heat with air outside the space, and that discharges air conditioned in the space from a second discharge port;
A communication terminal for a user in the space to transmit information on a desired temperature desired by the user; a position detection device for detecting a position of the communication terminal in the space;
Based on the number of the communication terminals in the space, the temperature at the position of the communication terminal, and the temperature outside the space, an output when the temperature at the position of the communication terminal is set to the desired temperature. Predict,
The first air conditioner and the second air conditioner so that the sum of the output of the first air conditioner and the output of the second air conditioner is equal to the predicted output. The efficiency of the entire first heat exchanger and the second heat exchanger when both are operated,
Such that the output is equal to the predicted output, when operating the air conditioning apparatus of any one-way of the first air conditioner and the second air conditioner, of the one air conditioner Based on the efficiency of the heat exchanger,
A controller that determines whether to operate both the first air conditioner and the second air conditioner, or to operate either one;
Air conditioning system equipped with. The said control apparatus operates the said air conditioning apparatus provided with the other, and circulates the air inside the said space, when one of the said 1st heat exchanger and the said 2nd heat exchanger is drive | operated. 3. The air conditioning system according to 3 . The air conditioning system according to any one of claims 1 to 4 , wherein power consumption of the air conditioner per user in the space is displayed on each of the communication terminals.

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