JP2004325035A - Air conditioning control device, air conditioning control program, air conditioning control method and air conditioning control system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an air conditioning control device 30, an air conditioning control program 31 and an air conditioning control method, producing an inexpensive and proper reduction in the energy consumption of an air-conditioner 11 to be installed in a building 60 which has a non-uniform air conditioning load with afforestation, without impairing pleasant feels of people in rooms. <P>SOLUTION: The air conditioning control device 30 for controlling the air-conditioner 11 for conditioning air in preset spaces in the building 60 having the plurality of spaces comprises a body temperature acquiring means 33 and a set temperature determining means 31. The body temperature acquiring means 33 acquires the temperatures of all or part of bodies 151, 152 wholly or partially defining the spaces 100a, 100b, 110a, 110b belonging to the preset spaces on the basis of at least the spaces 100a, 100b, 110a, 110b. The set temperature determining means uses the temperatures of all or part of the bodies 151, 152 for determining the set temperatures of the spaces 100a, 100b, 110a, 110b belonging to the preset spaces. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an air conditioning control device, an air conditioning control program, an air conditioning control method, and an air conditioning control system for controlling an air conditioner.
[0002]
[Prior art]
2. Description of the Related Art A method for reducing energy consumption of air conditioning in a building or the like without impairing the comfort of occupants has been proposed. Such a method includes, for example, a method using a PMV (Predicted Mean Vote) value (for example, see Patent Documents 1 and 2) and a method using weather information (for example, see Patent Document 3). .
[0003]
[Patent Document 1]
Japanese Patent Application Laid-Open No. 2-242037 (Section 2-5, FIG. 1)
[0004]
[Patent Document 2]
Patent No. 3139079 (Section 2-4, FIG. 1)
[0005]
[Patent Document 3]
JP-A-2003-74943 (Section 2-7, FIG. 6)
[0006]
[Problems to be solved by the invention]
In recent years, attempts have been made to green a part of the rooftop of a building or the like for the purpose of alleviating the heat island phenomenon and reducing the air conditioning load of the building or the like. It is said that if a part of the roof is greened, the air conditioning load of the building can be reduced. However, the reduction rate of the air-conditioning load is not always uniform in the building or the like, but depends largely on the greening place or greening area. However, the method according to Patent Document 3 is not designed on the assumption of a building or the like in which the air-conditioning load tends to be relatively uneven. That is, even if a plurality of air conditioners are installed in a building or the like, they are controlled in the same manner at almost the same timing. For this reason, it cannot be said that the method according to Patent Document 3 functions sufficiently in such a building or the like. For example, the estimation accuracy of the optimal set temperature may not be sufficient. That is, the room may be cooled too much during cooling, or the room may be heated too much during heating. For this reason, energy may be wasted. On the other hand, the methods disclosed in Patent Literature 1 and Patent Literature 2 require a considerable cost for measuring instruments and installation work thereof, and are not practical.
[0007]
An object of the present invention is to reduce the energy consumption of an air conditioner installed in a building or the like in which the air conditioning load is uneven due to greening or the like, inexpensively and appropriately without impairing the comfort of the occupants. An object of the present invention is to provide an air conditioning control device, an air conditioning control program, an air conditioning control method, and an air conditioning control system that can be reduced.
[0008]
[Means for Solving the Problems]
The air-conditioning control device according to claim 1 is an air-conditioning control device for controlling an air conditioner that air-conditions a predetermined space in a building having a plurality of spaces, wherein a frame temperature acquiring unit and a set temperature determination are determined. Means. Here, the “air conditioner” refers to an individual package type air conditioner, a multi-type air conditioner, or the like. When the air conditioner is a multi-type air conditioner, the “air conditioner” here is the indoor unit. Further, the “space” here refers to a room or an air-conditioning section (a range in which an air conditioner or an indoor unit of the air conditioner can perform air conditioning). The skeleton temperature obtaining means obtains at least a part or all of the temperature of the skeleton that partially or entirely partitions the space belonging to the predetermined space in units of the space. Note that the “framework” here refers to a wall (may include a window), a floor, a ceiling, or the like of a building room (including a space above and below the room depending on the case). . Further, the term "framework that partitions the entire space" refers to floors, ceilings, walls (may include windows) of the room, and the like, and the term "framework that partially partitions the space" refers to air conditioning. Floors and ceilings of the compartments, or floors, ceilings and walls (which may include windows). In addition, the “frame temperature” as used herein refers to the temperature of the frame itself, the surface temperature of the frame, or the radiation temperature of the frame. The set temperature determining means determines the set temperature of the air conditioner in each of the spaces belonging to the predetermined space by using the temperature of a part or the whole of the frame.
[0009]
Here, the skeleton temperature obtaining means obtains at least a part or all of the temperature of the skeleton that partially or entirely divides the space belonging to the predetermined space in units of the space. Then, the set temperature determining means determines the set temperature of the air conditioner in each of the spaces belonging to the predetermined space by using the temperature of a part or the whole of the frame. By the way, there is a theory that the sensible temperature of a person in a room depends not only on the temperature of the room but also on the temperature of a frame constituting the room (for example, see Non-Patent Document 1). According to this theory, for example, during cooling, if the temperature of the body is lower than the set temperature of the air conditioner for each space, raise the set temperature to such an extent that the comfort of the occupants is not impaired, and If the air conditioning control parameters can be derived to maintain the set temperature when the temperature is higher than the set temperature, air conditioning installed in buildings where the air conditioning load is uneven due to greening etc. The energy consumption of the machine can be reduced at low cost and appropriately without impairing the comfort of the occupants.
[0010]
(Non-patent document 1) http: // www. life. hyogo-u. ac. jp / hitomiu / onnetu. htm (working temperature)
The air-conditioning control device according to claim 2 is the air-conditioning control device according to claim 1, wherein the set temperature determining unit uses each of the spaces belonging to the predetermined space by using a part or all of the temperature of the frame. The set temperature of the air conditioner is determined so that the predetermined temperature index becomes constant. The “temperature index” here refers to a corrected effective temperature, an unpleasant index, an operating temperature, a WBGT index, a new effective temperature, or the like.
[0011]
Here, the set temperature determining means determines the set temperature of the air conditioner so that a predetermined temperature index of each of the spaces belonging to the predetermined space is constant using the temperature of a part or the whole of the body. For this reason, for example, during cooling, the temperature index changes when the body temperature is lower than the set temperature of the air conditioner, and the set temperature can be increased by the change, and the body temperature is higher than room temperature. If the air conditioning control parameters can be derived to maintain the set temperature when it is high, the consumption of air conditioners installed in buildings where the air conditioning load is uneven due to greening etc. The electric energy can be sufficiently reduced without impairing the comfort of the occupants.
[0012]
An air conditioning control device according to a third aspect is the air conditioning control device according to the first aspect, further comprising a humidity acquisition unit. The humidity acquiring means acquires the humidity of each of the spaces belonging to the predetermined space. Note that the humidity may be a measured value or an estimated value. Further, the set temperature determining means processes the humidity data using the temperature of a part or the whole of the frame, and sets the air conditioner of each space belonging to the predetermined space based on the processed humidity data. Determine the temperature.
[0013]
Here, the humidity acquiring means acquires the humidity of each space belonging to the predetermined space. Then, the set temperature determining means processes the humidity data by using the temperature of a part or the whole of the frame, and sets the air conditioner of each space belonging to a predetermined space based on the processed humidity data. Determine the temperature. Humidity is known to have a significant effect on human perceived temperature. For this reason, it is possible to indirectly perform the air conditioning control in consideration of the sensible temperature.
[0014]
An air conditioning control device according to a fourth aspect is the air conditioning control device according to the third aspect, wherein the humidity is estimated from weather information of an area where the building exists.
Here, it is not necessary to install a humidity sensor, an information collection device for estimating humidity, and the like in each space. Therefore, the temperature index and the like can be derived more easily.
[0015]
The air-conditioning control device according to claim 5 is the air-conditioning control device according to any one of claims 1 to 4, wherein the temperature of a part or the whole of the skeleton is the temperature of the inside air of the space, the position information of the space, And the estimated value based on the greening information of the building. The “temperature of the inside air in the space” here may be the temperature of the air suction port of the air conditioner. The “greening information” here refers to a greening place, a greening area, a greening density, and the like.
[0016]
Here, the temperature of a part or the whole of the skeleton can be obtained without introducing a new measuring instrument.
An air-conditioning control device according to a sixth aspect is the air-conditioning control device according to any one of the first to fourth aspects, wherein the temperature of a part or all of the skeleton is a measured value. Note that the temperature of a part of the skeleton can be measured using a temperature sensor or the like, and the entire temperature of the skeleton can be measured using a thermotracer or the like.
[0017]
In this case, the temperature of the skeleton can be measured with high accuracy, although some facility and construction costs are required.
An air-conditioning control program according to claim 7, wherein the air-conditioning control program is for controlling an air conditioner that air-conditions a predetermined space in a building having a plurality of spaces. Comprising steps. In the skeleton temperature acquiring step, the temperature of a part or all of the skeleton that partially or entirely partitions the space belonging to the predetermined space is acquired at least in units of the space. In the set temperature determination step, the set temperature of the air conditioner in each of the spaces belonging to the predetermined space is determined using the temperature of a part or the whole of the frame.
[0018]
Here, when the air-conditioning control program is executed, in the skeleton temperature acquisition step, the temperature of a part or all of the skeleton that partially or entirely divides the predetermined space is acquired at least in units of the space. . Then, in the set temperature determining step, the set temperature of the air conditioner in each of the spaces belonging to the predetermined space is determined using the temperature of a part or the whole of the frame. By the way, there is a theory that the sensible temperature of a person in a room depends not only on the temperature of the room but also on the temperature of a frame constituting the room (for example, see Non-Patent Document 1). According to this theory, for example, during cooling, if the temperature of the body is lower than the set temperature of the air conditioner for each space, raise the set temperature to such an extent that the comfort of the occupants is not impaired, and If the air conditioning control parameters can be derived to maintain the set temperature when the temperature is higher than the set temperature, air conditioning installed in buildings where the air conditioning load is uneven due to greening etc. The energy consumption of the machine can be reduced at low cost and appropriately without impairing the comfort of the occupants.
[0019]
An air conditioning control method according to claim 8, which is an air conditioning control method for controlling an air conditioner that air-conditions a predetermined space in a building having a plurality of spaces, wherein a frame temperature obtaining step and a set temperature determination are performed. Comprising steps. In the skeleton temperature acquiring step, the temperature of a part or all of the skeleton that partially or entirely partitions the space belonging to the predetermined space is acquired at least in units of the space. In the set temperature determination step, the set temperature of the air conditioner in each of the spaces belonging to the predetermined space is determined using the temperature of a part or the whole of the frame.
[0020]
Here, when the air-conditioning control method is performed, in the skeleton temperature acquisition step, at least a part or all of the temperature of the skeleton that partially or entirely partitions the space belonging to the predetermined space is at least the predetermined space. Acquired in units. Then, in the set temperature determining step, the set temperature of the air conditioner in each of the spaces belonging to the predetermined space is determined using the temperature of a part or the whole of the frame. By the way, there is a theory that the sensible temperature of a person in a room depends not only on the temperature of the room but also on the temperature of a frame constituting the room (for example, see Non-Patent Document 1). According to this theory, for example, during cooling, if the temperature of the body is lower than the set temperature of the air conditioner for each space, raise the set temperature to such an extent that the comfort of the occupants is not impaired, and If the air conditioning control parameters can be derived to maintain the set temperature when the temperature is higher than the set temperature, air conditioning installed in buildings where the air conditioning load is uneven due to greening etc. The energy consumption of the machine can be reduced at low cost and appropriately without impairing the comfort of the occupants.
[0021]
An air conditioning control system according to a ninth aspect includes an air conditioning control device and an air conditioner. The air-conditioning control device is the air-conditioning control device according to any one of claims 1 to 6. The air conditioner is controlled by the air conditioning control device. Here, the “air conditioner” refers to an individual package type air conditioner, a multi-type air conditioner, or the like.
[0022]
Here, for example, at the time of cooling, if the temperature of the skeleton is lower than the set temperature of the air conditioner for each space, the set temperature is increased to such an extent that the comfort of the occupants is not impaired, and If the air conditioning control parameter is derived to maintain the set temperature when the air conditioner is higher than the set temperature and the air conditioner can be controlled by the parameter, it seems that the air conditioning load is uneven due to greening and the like. Energy consumption of an air conditioner installed in a modern building or the like can be reduced inexpensively and appropriately without impairing the comfort of the occupants.
[0023]
BEST MODE FOR CARRYING OUT THE INVENTION
In the present embodiment, an air conditioning control system that controls an air conditioner installed in a building will be described. The air-conditioning control system described in the present embodiment is described on the assumption that the air conditioner is performing a cooling operation. In the case of heating, it may be necessary to change the thermal index or reverse the relationship between the parameters, but it should be noted that the essential concept is the same as in the case of cooling.
[0024]
<About air conditioning control system>
[Constitution]
FIG. 1 shows a block diagram of an air conditioning control system 400 according to the present embodiment. The air conditioning control system 400 includes a plurality of multi-type air conditioners 10, stations 20, computers 30, and a weather information management server 80. The multi-type air conditioner 10 and the station 20 are installed in a building 60. The station 20 is installed in the management room 70. The computer 30 is installed in the information management center 50. The weather information management server 80 is installed in the weather information distribution center 90.
[0025]
[Connection configuration of system components]
The multi-type air conditioner 10 is connected to the station 20 via a transmission line. The station 20 is connected to the computer 30 via a network 40. Then, the computer 30 is connected to the weather information management server 80 via the network 40.
[0026]
[Component]
(1) Multi-type air conditioner 10
The multi-type air conditioner 10 includes one outdoor unit 12 for a plurality of indoor units 11. The indoor unit 11 and the outdoor unit 12 are connected via a refrigerant pipe and a transmission line. The indoor unit 11 is connected to the total heat exchanger unit 15 via a transmission line. In the present embodiment, it is assumed that the multi-type air conditioner 10 is performing a cooling operation.
[0027]
(2) Station 20
The station 20 includes a control unit 21 and a modem 23. The control unit 21 outputs the operation information (such as the set temperature of the indoor unit 11 and the value of the indoor unit temperature sensor) of the multi-type air conditioner 10 and the radiation temperature of the inner wall of the building 60 at intervals of 15 minutes from 4:55 in the morning. The value of the temperature sensor to be measured is collected, and the information is transmitted to the computer 30. When receiving the air-conditioning control table from the computer 30, the control unit 21 overwrites and updates the existing air-conditioning control table with the existing air-conditioning control table. Then, the control unit 21 controls the operation of the multi-type air conditioner 10 based on the air conditioning control table. The modem 23 is used to connect the station 20 to the computer 30.
[0028]
(3) Computer 30
The computer 30 includes an air conditioning control parameter derivation program 31, a management database 32, and a modem 33. The air-conditioning control parameter deriving program 31 includes an outside air introduction routine 31a, a refrigeration cycle routine 31b, and a set temperature routine 31c. The outside air introduction routine 31a uses the set temperature of the indoor unit 11 and the radiation temperature of a part of the wall that partitions the room of the building 60 or the radiation temperature of a part of the wall that partially partitions the air-conditioning partition. 15 ON / OFF control parameters and the ON / OFF control parameters of the indoor unit 11 of the multi-type air conditioner 10 are derived. The refrigeration cycle routine 31b performs refrigeration using the weather forecast information, the set temperature of the indoor unit 11, and the radiation temperature of a part of the wall that partitions the room of the building 60 or a part of the wall that partially partitions the air-conditioning partition. The on / off control parameter of the cycle operation suppression control function is derived. The “refrigeration cycle operation suppression control function” includes, for example, capacity control of the outdoor unit (setting of the upper limit value of the compressor, change of the evaporation temperature, etc.) and control of the operation / stop interval of the compressor (interval of the interval). Fixation, change of threshold value, etc.). The details of these controls are described in Patent Document 4. The set temperature routine 31c is set using the weather forecast information, the set temperature of the indoor unit 11, and the radiant temperature of a part of the wall that partitions the room of the building 60 or a part of the wall that partially partitions the air-conditioning partition. Deriving temperature parameters. The air-conditioning control parameter deriving program 31 creates an air-conditioning control table from control parameters derived in the outside air introduction routine 31a, the refrigeration cycle routine 31b, and the set temperature routine 31c. Then, the computer 30 transmits the air-conditioning control table to the station 20 via the network 40 when the air-conditioning control table has been changed by comparing the air-conditioning control table with the previous air-conditioning control table. The management database 32 stores information transmitted from the station 20 or the weather information management server 80. The modem 33 is used to connect the computer 30 and the weather information management server 80.
[0029]
(Patent Document 4) Japanese Patent Application No. 2002-21728 (FIG. 1)
(4) Weather information management server 80
The weather information management server 80 includes a weather database 81 and a modem 82. The weather database 81 holds various weather forecast information, for example, expected temperature and expected humidity for each area and time. The modem 82 is used to connect the weather information management server 80 and the computer 30.
[0030]
<About Building 60>
[External Configuration of Building 60]
FIG. 2 is a perspective view of a building 60 in which the multi-type air conditioner 10 to be controlled is installed. On the roof of the building 60, a water storage tank 64, a roof outlet 63, and the outdoor unit 12 of the multi-type air conditioner 10 are provided. Greening spaces 61 and 62 are provided in a space that is not occupied by the water storage tank 64, the roof exit 63, and the outdoor unit 12. The green spaces 61 and 62 are provided for the purpose of alleviating the heat island phenomenon and reducing the air conditioning load of the building 60. Further, it is said that the effect of reducing the air-conditioning load increases as the position is closer to the green spaces 61 and 62. In this building 60, the green spaces 61 and 62 do not cover the entire roof. For this reason, it is presumed that a relatively uneven air conditioning load is generated in the building 60 not only in the Z-axis direction but also in the X-axis direction and the Y-axis direction (for each axis, see the lower right of FIG. 2). ).
[0031]
[Internal Configuration of Building 60]
In FIG. 2, the air conditioners in the section indicated by reference numeral 100 and the section indicated by reference number 110 are shown in FIGS. 3 and 4, respectively.
In FIG. 3, the section 100 has two rooms 100a and 100b. One indoor unit 11 is provided in each of the rooms 100a and 100b. The indoor unit 11 is connected to an outdoor unit 12 installed on a rooftop via a transmission line and refrigerant pipes 203a and 203b. An electronic expansion valve 202 is provided on the refrigerant pipe (liquid pipe) 203a. The indoor unit 11 is connected to the controller 204 via a transmission line. Further, the controller 204 is provided with a temperature sensor 205. The temperature sensor 205 measures the radiation temperature of the wall 152 in the vicinity. Each indoor unit 11 is connected to the total heat exchanger unit 15 via a transmission line. One end of the total heat exchanger unit 15 is connected to each of the rooms 100a and 100b via duct pipes 302a and 302b, and the opposite end is connected to the outside space via duct pipes 302a and 302b penetrating the outer wall 151. Connected to. The total heat exchanger unit 15 operates / stops according to a command issued from the station 20.
[0032]
In FIG. 4, section 110 has one room. In the room, two indoor units 11 are provided. In this case, the control of the indoor unit 11 is not performed for each room but for each air conditioning section. Here, it is assumed that the air-conditioning sections 110a and 110b are partitioned by the ceiling, floor, walls 151 and 152, and the boundary surface 500 of the air-conditioning area (spread in the depth direction in FIG. 2). Of course, the boundary surface 500 cannot be visually recognized. In other words, the boundary surface 500 is merely a measure of a region in which each indoor unit 11 can sufficiently exhibit its air conditioning capacity. If the air conditioning capacity of the indoor unit 11 is not sufficient for the size of the room or the like, the air conditioning section may be considered to be partitioned by a ceiling, a floor, and a plurality of boundary surfaces. This is the same even when one indoor unit 11 is installed in one room. In such a case, it is necessary to measure the radiation temperature of the ceiling or floor.
<Derivation of air conditioning control parameters>
[Flow of deriving air conditioning control parameters]
FIG. 5 is a flowchart showing a flow of deriving the air conditioning control parameters.
[0033]
In FIG. 5, the processes shown in steps S11 to S16 are executed every 15 minutes from 5:00 to 22:00 on a scheduled day. In step S11, the computer 30 checks whether the current time is the first processing time. Here, the first processing time is 5:00. If the current time is the first processing time as a result of the confirmation in step S11, the process proceeds to step S12. If the current time is not the first processing time as a result of the check in step S11, the process proceeds to step S14. In step S12, the computer 30 receives the radiation temperature Tkm of each room of the building 60 transmitted from the station 20, and stores the radiation temperature information in the management database 32. In step S13, the computer 30 receives the weather forecast information transmitted from the weather information management server 80, and stores the weather forecast information in the management database 32. Here, the weather forecast information includes the expected temperature and the expected humidity of the area where the building 60 is located every 15 minutes on that day. In the refrigeration cycle routine R1, the computer 30 partially divides the weather forecast information, the set temperature of the indoor unit 11, and a part of the walls 151 and 152 or the air-conditioning sections 110a and 110b that define the rooms 100a and 100b of the building 60. The on / off control parameter of the operation suppression control function of the refrigeration cycle is derived using the radiation temperature of a part of the walls 151 and 152 to be turned on. In step S14, it is confirmed whether the current time is the second processing time. Here, the second processing time is a time at 15-minute intervals from 5:00 to 22:00. If the current time is the second processing time as a result of the confirmation in step S14, the process proceeds to the outside air introduction routine R2. If the current time is not the second processing time as a result of the confirmation in step S14, the process proceeds to step S15. In the outside air introduction routine R2, the computer 30 sets the temperature of the indoor unit 11 and a part of the walls 151 and 152 that partition the rooms 100a and 100b of the building 60 or the walls 151 and 151 that partially partition the air-conditioning partitions 110a and 110b. The on / off control parameters of the total heat exchanger unit 15 and the on / off control parameters of the indoor unit 11 of the multi-type air conditioner 10 are derived using the radiation temperature of a part of the air conditioner 152. In the set temperature routine R3, the computer 30 divides the weather forecast information (information on the outside air temperature and the absolute humidity of the outside air, etc.), the set temperature of the indoor unit 11, and one of the walls 151 and 152 partitioning the rooms 100a and 100b of the building 60. A set temperature parameter is derived using the radiation temperature of a part of the walls 151 and 152 that partially define the unit or the air conditioning sections 110a and 110b. In step S15, the air-conditioning control parameter deriving program 31 creates an air-conditioning control table from the control parameters derived in the refrigeration cycle routine R1, the outside air introduction routine R2, and the set temperature routine R3. In step S16, the computer 30 compares the air-conditioning control table with the previous air-conditioning control table and checks whether the air-conditioning control table has been changed. As a result of the check in step S16, if the air conditioning control parameter has been changed, the process proceeds to step S17. If the result of the check in step S16 shows that no change has been made to the air-conditioning control parameters, the computer 30 waits until the next processing time. In step S17, the computer 30 transmits the air conditioning control table to which the change has been made to the station 20.
[0034]
[Refrigeration cycle routine 31b]
FIG. 6 is a flowchart showing the flow of the process of the refrigeration cycle routine 31b.
In FIG. 6, in step S21, the computer 30 calculates an outside air discomfort index As. In step S22, the computer 30 controls the temperature sensor 205 provided for each room 100a, 100b or each air conditioning section 110a, 110b in which the indoor unit 11 (the connected outdoor unit 12 is limited to the same one). , And outputs the minimum value Tkm (Min) of the radiation temperatures Tkm. In step S23, the computer 30 checks whether the set temperature Tr of the indoor units 11 of the rooms 100a and 100b or the air conditioning sections 110a and 110b corresponding to the minimum value Tkm (Min) is equal to or higher than the minimum value Tkm (Min). . As a result of the confirmation in step S23, when the set temperature Tr of the indoor unit 11 is equal to or higher than the minimum value Tkm (Min), the process proceeds to step S25. As a result of the check in step S23, when the set temperature Tr of the indoor unit 11 is lower than the minimum value Tkm (Min), the process proceeds to step S24. In step S24, the computer 30 performs a process of determining that the comparative discomfort index Ac is equal to the limit discomfort index As. In step S25, the computer 30 performs a process of adding the correction term C (Tr−Tkm (Min)) to the limit discomfort index As to obtain the comparative discomfort index Ac. In step S26, the computer 30 checks whether the outside air discomfort index As is equal to or less than the comparative discomfort index Ac. As a result of the confirmation in step S26, when the outside air discomfort index As is equal to or smaller than the comparative discomfort index Ac, the process proceeds to step S27. As a result of the confirmation in step S26, when the outside air discomfort index As is larger than the comparative discomfort index Ac, the process proceeds to step S28. In step S27, the computer 30 sets the operation suppression control function on / off control parameter of the refrigeration cycle to “on”. In step S28, the computer 30 sets the operation suppression control function on / off control parameter of the refrigeration cycle to “off”.
[0035]
[Outside air introduction routine 31a]
FIG. 7 is a flowchart showing the flow of the processing of the outside air introduction routine 31a.
In FIG. 7, in step S31, the computer 30 partially sets the walls 151 and 152 or the air-conditioning sections 110a and 110b that define the rooms 100a and 100b in which the indoor units 11 are installed. It is checked whether the radiation temperature of the partitions 151 and 152 is equal to or higher than the radiation temperature Tkm. As a result of the confirmation in step S31, when the set temperature Tr is equal to or higher than the radiation temperature Tkm of the walls 151 and 152, the process proceeds to step S33. As a result of the check in step S31, if the set temperature Tr is lower than the radiation temperature Tkm of the walls 151 and 152, the process proceeds to step S32. In step S32, the computer 30 performs a process for determining that the comparison temperature difference ΔTc is equal to the reference temperature difference ΔTb. In step S33, the computer 30 performs a process of adding a correction term − (Tr−Tkm) / 2 to the reference temperature difference ΔTb to obtain a comparison temperature difference ΔTc. In step S34, the computer 30 checks whether the difference (Tr−Tom) between the set temperature Tr and the outside air temperature Tom is equal to or greater than the comparison temperature difference ΔTc. As a result of the confirmation in step S34, when the difference (Tr−Tom) is equal to or larger than the comparative temperature difference ΔTc, the process proceeds to step S35. As a result of the confirmation in step S34, if the difference (Tr−Tom) is smaller than the comparison temperature difference ΔTc, the process proceeds to step S38. In step S35, the computer 30 sets the on / off control parameter of the total heat exchanger unit 15 to “on”. In step S36, the computer 30 sets the ON / OFF control parameter of the indoor fan of the indoor unit 11 to “OFF”. In step S37, the computer 30 sets the open / close control parameter of the electronic expansion valve 202 to “closed”. In step S38, the computer 30 sets the on / off control parameter of the total heat exchanger unit 15 to “off”. In step S39, the computer 30 sets the ON / OFF control parameter of the indoor fan of the indoor unit 11 to “ON”. In step S40, the computer 30 sets the open / close control parameter of the electronic expansion valve 202 to “open”.
[0036]
At this time, the air supply is performed without passing through the heat exchange element of the total heat exchanger unit 15.
[Set temperature routine 31c]
FIG. 8 is a flowchart showing the flow of the processing of the set temperature routine 31c.
[0037]
In FIG. 8, in step S41, the computer 30 obtains the sensible temperature Ta of the room 100a, 100b or the air conditioning sections 110a, 110b using the weather forecast information (information on the outside air temperature and the outside air humidity, etc.). In step S42, the computer 30 determines whether the set temperature Tr of the indoor unit 11 is a wall 151 or 152 that partitions the rooms 100a and 100b in which the indoor unit 11 is installed or a wall 151 that partially partitions the air-conditioning partitions 110a and 110b. , 152 is higher than the radiation temperature Tkm. As a result of the confirmation in step S42, if the set temperature Tr is equal to or higher than the radiation temperature Tkm of the walls 151 and 152, the process proceeds to step S44. As a result of the confirmation in step S42, if the set temperature Tr is lower than the radiation temperature Tkm of the walls 151 and 152, the process proceeds to step S43. In step S43, the computer 30 performs a process for determining that the set temperature Tr is equal to the new set temperature Ts. In step S33, the computer 30 performs a process for determining that the new set temperature Ts is equal to 2Ta-Tkm. The equation Ts = 2Ta−Tkm is an equation derived from [Equation 1] representing the standard operating temperature.
[0038]
[Equation 1] Ta = (Ts + Tkm) / 2
In step S45, the computer 30 changes the set temperature parameter to “Ts”.
<Features of air conditioning control system 400>
(1)
In the air-conditioning control system 400 according to the present embodiment, for each room 100a, 100b or each air-conditioning section 110a, 110b in the building 60, the walls 151, 152 that partition the rooms 100a, 100b or the wall that partially partitions the air-conditioning section In consideration of the radiation temperatures of 151 and 152, the operation / stop of the indoor fan of the indoor unit 11, the opening / closing of the electronic expansion valve 202, and the operation / stop of the total heat exchanger unit 15 are determined. For example, at the time of cooling, even if there is not a sufficient difference between the set temperature and the outside air temperature, if the radiation temperature of the walls 151 and 152 is low, the indoor fan of the indoor unit 11 of the multi-type air conditioner 10 The operation stops, the expansion valve 202 closes, and the total heat exchanger 15 actively introduces outside air. In other cases, the indoor fan of the indoor unit 11 of the multi-type air conditioner 10 operates, the expansion valve 202 opens, and the total heat exchanger unit 15 stops. Therefore, even when the building has a relatively uneven air conditioning load, such as the building 60 shown in the present embodiment, it is possible to appropriately determine the timing of introducing the outside air. Therefore, outside air can be introduced for a longer time than when the conventional technique is used. In addition, the amount of energy consumed by the multi-type air conditioner 10 can be reduced by increasing the outside air introduction.
[0039]
(2)
In the air-conditioning control system 400 according to the present embodiment, the walls 151 and 152 or the air-conditioning sections 110a and 110b that partition the rooms 100a and 100b in the room 100a, 100b or the air-conditioning sections 110a and 110b in the building 60 are partially formed. The operation of the refrigeration cycle is controlled in consideration of the radiation temperatures of the walls 151 and 152 which are partitioned into the refrigeration cycle. Therefore, even in a building having a relatively uneven air conditioning load, such as the building 60 shown in the present embodiment, the frequency of starting and stopping the compressor can be simply and appropriately suppressed as a whole.
[0040]
(3)
In the air conditioning control system 400 according to the present embodiment, when the radiation temperature is lower than the set temperature of the indoor unit 11 for each room 100a, 100b or each air conditioning section 110a, 110b in the building 60, the set temperature is increased, When the temperature is higher than the set temperature of the indoor unit 11, an air conditioning control parameter is derived so as to maintain the set temperature. Therefore, even in a building having a relatively uneven air conditioning load, such as the building 60 shown in the present embodiment, the power consumption of the air conditioner can be reduced without impairing the comfort of the occupants. It can be reduced sufficiently.
[0041]
<Modification>
(1)
In the air conditioning control system 400 according to the above-described embodiment, the air conditioner to be controlled is the multi-type air conditioner 10, but the control object may be an individual packaged air conditioner instead. In this case, the derivation of the refrigeration cycle operation suppression control function parameter in the refrigeration cycle routine 31b can be performed for each of the rooms 100a and 100b or each of the air conditioning sections 110a and 110b. In the outside air introduction routine 31a, when cooling can be performed only with outside air, the air conditioner (such as a compressor) may be stopped at the same time as taking in outside air. By doing so, there is a possibility that an energy saving effect greater than that of the multi-type air conditioner 10 can be obtained.
[0042]
(2)
In the air-conditioning control system 400 according to the above embodiment, a part of the walls 151 and 152 that partition the rooms 100a and 100b of the building 60 or the walls 151 and 152 that partially partition the air-conditioning sections 110a and 110b by the temperature sensor 205. Was measured, but instead of this, a part of the ceiling or floor that partitions the rooms 100a and 100b of the building 60 or the ceiling that partially partitions the air-conditioning partitions 110a and 110b by the temperature sensor 205. Alternatively, the radiation temperature of a part of the floor may be measured.
[0043]
(3)
In the air-conditioning control system 400 according to the above embodiment, a part of the walls 151 and 152 that partition the rooms 100a and 100b of the building 60 or the walls 151 and 152 that partially partition the air-conditioning sections 110a and 110b by the temperature sensor 205. Was measured, but instead of this, the temperature sensor 205 was used to measure the radiant temperature of the entire frame that partitions the rooms 100a and 100b of the building 60 or the entire frame that partially partitions the air-conditioning sections 110a and 110b. It may be measured. Such a measurement can be achieved by using a thermo tracer or the like. In this case, although some equipment and construction costs are required, the temperature of the skeleton can be accurately measured.
[0044]
(4)
In the refrigeration cycle routine 31b according to the above embodiment, a part of the walls 151 and 152 that partition the rooms 100a and 100b of the building 60 or a part of the walls 151 and 152 that partially partition the air conditioning sections 110a and 110b. The operation suppression control function on / off control parameter of the refrigeration cycle has been derived in consideration of the radiation temperature. / Off control parameter may be derived. By doing so, not only the air conditioning load generated from around the skeleton that partitions the rooms 100a and 100b and the skeleton that partially partitions the air conditioning partitions 110a and 110b, but also the air conditioning generated from the objects existing inside the rooms 100a and 100b. The load can also be reflected in the control parameters. The heat value may be a measured value or an estimated value. In addition, the heat generation amount is estimated based on the number of people detecting sensor, the infrared camera, the thermo tracer, the lighting that is turned on / off according to the presence / absence (estimation from the ON / OFF state time), and the power consumption of the rooms 100a and 100b. It is possible. In this case, the on / off control parameters for the operation suppression control function of the refrigeration cycle are derived as in the flowcharts shown in FIGS.
[0045]
9 and 10, in step S51, the computer 30 calculates an outside air discomfort index As. In step S52, the computer 30 controls the temperature sensor 205 provided for each room 100a, 100b or each air-conditioning section 110a, 110b in which the indoor unit 11 (limited to those connected to the same outdoor unit 12) is installed. , And outputs the minimum value Tkm (Min) of the radiation temperatures Tkm. In step S53, the computer 30 obtains the calorific value Qc of the room 100a, 100b or the air conditioning section 110a, 110b. In step S54, it is checked whether or not the set temperature Tr of the indoor unit 11 of the room 100a, 100b or the air conditioning section 110a, 110b corresponding to the minimum value Tkm (Min) is equal to or higher than the minimum value Tkm (Min). As a result of the confirmation in step S54, when the set temperature Tr of the indoor unit 11 is equal to or higher than the minimum value Tkm (Min), the process proceeds to step S56. As a result of the confirmation in step S54, when the set temperature Tr of the indoor unit 11 is lower than the minimum value Tkm (Min), the process proceeds to step S55. In step S55, the computer 30 performs a process of determining that the first comparative discomfort index Ac1 is equal to the limit discomfort index As. In step S56, the computer 30 performs a process of adding the correction term C (Tr−Tkm (Min)) to the limit discomfort index As to obtain the first comparative discomfort index Ac1. In step S57, the computer 30 checks whether or not the reference heat generation amount Qb is equal to or larger than the heat generation amount Qc of the room 100a, 100b or the air conditioning sections 110a, 110b. As a result of the confirmation in step S57, if the reference calorific value Qb is equal to or greater than the calorific value Qc of the room 100a, 100b or the air conditioning sections 110a, 110b, the process proceeds to step S59. As a result of the confirmation in step S57, if the reference calorific value Qc is less than the calorific value Qc of the room 100a, 100b or the air conditioning section 110a, 110b, the process proceeds to step S58. In step S58, the computer 30 performs a process for determining that the second comparative discomfort index Ac2 is equal to the first comparative discomfort index Ac1. In step S59, the computer 30 performs a process of adding the correction term D (Qb-Qc) to the first comparative discomfort index Ac1 as a second comparative discomfort index Ac2. In step S60, the computer 30 checks whether the outside air discomfort index As is equal to or less than the second comparative discomfort index Ac2. As a result of the confirmation in step S60, if the outside air discomfort index As is equal to or smaller than the second comparative discomfort index Ac2, the process proceeds to step S61. As a result of the confirmation in step S60, when the outside air discomfort index As is larger than the second comparative discomfort index Ac2, the process proceeds to step S62. In step S61, the computer 30 sets the operation suppression control function on / off control parameter of the refrigeration cycle to “on”. In step S62, the computer 30 sets the operation suppression control function on / off control parameter of the refrigeration cycle to “off”.
[0046]
(5)
In the outside air introduction routine 31a according to the previous embodiment, the processing from step S31 to step S40 shown in FIG. 7 is performed, but the processing from step S71 to step S80 shown in FIG. May be. At this time, the air supply is performed without passing through the heat exchange element of the total heat exchanger unit 15.
[0047]
In FIG. 11, in step S71, the computer 30 determines that the set temperature Tr of the indoor unit 11 partially covers the walls 151 and 152 or the air-conditioning sections 110a and 110b that partition the rooms 100a and 100b in which the indoor unit 11 is installed. It is checked whether the radiation temperature of the partitions 151 and 152 is equal to or higher than the radiation temperature Tkm. As a result of the check in step S71, if the set temperature Tr is equal to or higher than the radiation temperature Tkm of the walls 151 and 152, the process proceeds to step S73. As a result of the confirmation in step S71, if the set temperature Tr is lower than the radiation temperature Tkm of the walls 151 and 152, the process proceeds to step S72. In step S72, the computer 30 performs a process for determining that the comparison outside air temperature Tc is equal to the reference outside air temperature Tb. In step S73, the computer 30 performs a process of adding the correction term − (Tr−Tkm) / 2 to the reference outside air temperature Tb to obtain the comparison outside air temperature Tc. In step S74, the computer 30 checks whether the room temperature Trm of the room 100a, 100b or the air conditioning section 110a, 110b is higher than the set temperature Tr and the outside air temperature Tom is lower than the comparison temperature Tc. As a result of the confirmation in step S74, if the room temperature Trm of the room 100a, 100b or the air conditioning section 110a, 110b is higher than the set temperature Tr and the outside air temperature Tom is lower than the comparison temperature Tc, the process proceeds to step S75. As a result of the confirmation in step S74, if the room temperature Trm of the room 100a, 100b or the air conditioning section 110a, 110b is higher than the set temperature Tr and the outside air temperature Tom is not lower than the comparison temperature Tc, the process proceeds to step S78. In step S75, the computer 30 sets the on / off control parameter of the total heat exchanger unit 15 to “on”. In step S76, the computer 30 sets the ON / OFF control parameter of the indoor fan of the indoor unit 11 to “OFF”. In step S77, the computer 30 sets the open / close control parameter of the electronic expansion valve 202 to “closed”. In step S78, the computer 30 sets the on / off control parameter of the total heat exchanger unit 15 to “off”. In step S79, the computer 30 sets the ON / OFF control parameter of the indoor fan of the indoor unit 11 to “ON”. In step S80, the computer 30 sets the open / close control parameter of the electronic expansion valve 202 to “open”.
[0048]
(6)
In the air conditioning control system 400 according to the previous embodiment, the total heat exchanger unit 15 directly takes in outside air into the room, but instead, the total heat exchanger unit 15 is partially provided underground. Outside air may be taken in via piping. Generally, the ground is always kept at a substantially constant temperature. That is, the temperature in the ground is lower than the temperature of the outside air in a relatively hot time, and the temperature in the ground is higher than the temperature of the outside air in a relatively cold time. For this reason, when the outside air passes through the underground piping, heat exchange occurs with the underground heat. Therefore, the outside air is cooled in a relatively hot time, and the outside air is heated in a relatively cold time. In this way, the energy of the building 60 can be more efficiently saved.
[0049]
(7)
In the air conditioning control system 400 according to the above embodiment, the air conditioning equipment as shown in FIG. 3 is introduced into the section 100, but instead, the air conditioning equipment as shown in FIG. May be done. In the section 100 shown in FIG. 12, one air supply fan 311 is provided for each of the rooms 100a and 100b. Further, a plurality of exhaust fans 313 are provided behind the ceiling. Further, a temperature sensor 205 is provided so as to correspond to the position of each exhaust fan 313. The temperature sensor 205 measures the radiation temperature of the ceiling. In addition, two outside air introduction paths are provided (a path that directly takes in outside air, and a path that takes in outside air through a pipe 320 partially provided underground), and a three-way solenoid valve is provided at a branch point thereof. 319 are provided. In this case, the control parameters are derived as shown in the flowcharts of FIGS.
[0050]
13 and 14, in step S101, the computer 30 determines that the set temperature Tr of the indoor unit 11 is equal to or higher than the radiation temperature Tkm of the walls 151 and 152 that partition the rooms 100a and 100b in which the indoor unit 11 is installed. Check if. As a result of the check in step S101, if the set temperature Tr is equal to or higher than the radiation temperature Tkm of the walls 151 and 152, the process proceeds to step S103. As a result of the confirmation in step S101, if the set temperature Tr is lower than the radiation temperature Tkm of the walls 151 and 152, the process proceeds to step S102. In step S102, the computer 30 performs a process of determining that the first comparison temperature difference ΔTc1 is equal to the first reference temperature difference ΔTb1. In step S103, the computer 30 performs a process of adding a correction term − (Tr−Tkm) / 2 to the first reference temperature difference ΔTb1 to obtain a first comparison temperature difference ΔTc1. In step S104, the computer 30 performs a process of making the second comparison temperature difference ΔTc2 equal to the second reference temperature difference ΔTb2 (note that the first reference temperature difference ΔTb1 and the second reference temperature difference ΔTb2 are ΔTb1 <ΔTb2). Is set to be.) In step S105, the computer 30 performs a process of adding the correction term − (Tr−Tkm) / 2 to the second reference temperature difference ΔTb2 to obtain a second comparison temperature difference ΔTc2. In step S106, the computer 30 makes a determination based on the difference (Tr−Tom) between the set temperature Tr of the indoor unit 11 and the outside air temperature Tom (Tr−Tom), the first comparison temperature difference ΔTc1, and the second comparison temperature difference ΔTc2. If the result of the determination in step S106 is that the difference (Tr−Tom) is lower than the first comparison temperature ΔTc1, the process proceeds to step S107. If the result of the determination in step S106 is that the difference (Tr−Tom) is equal to or higher than the first comparison temperature ΔTc1 and lower than the second comparison temperature ΔTc2, the process proceeds to step S111. If the result of the determination in step S106 is that the difference (Tr−Tom) is equal to or larger than the second comparison temperature difference ΔTc2, the process proceeds to step S116. In step S107, the computer 30 sets the on / off control parameter of the air supply fan 311 to “off”. In step S108, the computer 30 sets the on / off control parameters of all the exhaust fans 313 to “off”. In step S109, the computer 30 sets the ON / OFF control parameter of the indoor fan of the indoor unit 11 to “ON”. In step S110, the computer 30 sets the open / close control parameter of the electronic expansion valve 202 to “open”. In step S111, the computer 30 sets the control parameters of the three-way solenoid valve 319 such that the outside air is taken in through the underground pipe 320. In step S112, the computer 30 sets the on / off control parameter of the air supply fan 311 to “on”. In step S113, the computer 30 sets the on / off control parameter of the exhaust fan 313 corresponding to the position of the temperature sensor 205 indicating the highest temperature to “on”. In step S114, the computer 30 sets the ON / OFF control parameter of the indoor fan of the indoor unit 11 to “OFF”. In step S115, the computer 30 sets the opening / closing control parameter of the electronic expansion valve 202 to “closed”. In step S116, the computer 30 sets the control parameters of the three-way solenoid valve 319 so as to directly take in outside air. In step S117, the computer 30 sets the on / off control parameter of the air supply fan 311 to “on”. In step S118, the computer 30 sets the on / off control parameter of the exhaust fan 313 corresponding to the position of the temperature sensor 205 indicating the highest temperature to “on”. In step S119, the computer 30 sets the ON / OFF control parameter of the indoor fan of the indoor unit 11 to “OFF”. In step S120, the computer 30 sets the open / close control parameter of the electronic expansion valve 202 to “closed”.
[0051]
In this way, it is possible to more efficiently save energy in the building 60 without impairing the comfort of the occupants.
In addition, as shown in FIG. 15, when only one exhaust fan 317 is provided in the exhaust duct 302b, the opening / closing or opening / closing degree of the exhaust damper 315 may be controlled. Furthermore, the temperature sensor 205 may be removed, and the priority of the operation of the exhaust fan 313 may be determined based only on the greening information (such as the distance from the greening place).
[0052]
(8)
In the set temperature routine 31c according to the previous embodiment, the processing from step S41 to step S45 shown in FIG. 8 is performed, but the processing from step S91 to step S96 shown in FIG. May be.
Here, before describing the flowchart shown in FIG. 16, basic items for understanding the processing contents of step S93 and step S94 will be described. In the set temperature routine according to the present modification, a table as shown in FIG. 17 is prepared in advance. In this table, the indoor absolute humidity Ai is determined such that the discomfort index is 74.6 at any comfort limit temperature Tm. Further, it has been clarified by verification by the present applicant that the room absolute temperature Ai and the outside air absolute humidity Ao are represented by a linear relationship. The outside air absolute humidity Ao can be obtained from weather information. Therefore, if this relationship is used, the indoor absolute humidity Ai can be predicted from the weather information. Then, the set temperature can be changed based on the predicted indoor absolute humidity Ai such that the indoor discomfort index maintains 74.6. Therefore, for example, if the indoor humidity decreases, the comfort limit temperature increases. Therefore, the set temperature can be increased. For this reason, this method contributes to energy saving of the air conditioner. This method is described in detail in Patent Document 3. However, according to the method disclosed in Patent Document 3, even when a non-uniform temperature distribution is likely to occur as in the building 60, the set temperature can be changed only uniformly. This is because the outside air absolute humidity Ao obtained from the weather information is one. In order to cope with such a building 60, the above table is improved as shown in FIG. Here, a correction term A (Tm) is added to the outside air absolute humidity Ao. The contents of the correction term A (Tm) are shown in steps S93 and S94 of the flowchart shown in FIG. That is, when the temperature of the skeleton that partitions the rooms 100a and 100b or the temperature of the skeleton that partially partitions the air-conditioning partitions 110a and 110b is lower than the set temperature, a table is created according to the temperature of the skeleton. Therefore, even in the building 60 in which an uneven temperature distribution is likely to occur, the set temperature can be changed for each of the rooms 100a and 100b or the air-conditioning sections 110a and 110b in accordance with the frame temperature. At this time, the sensible temperatures in the rooms 100a and 100b or the air-conditioning sections 110a and 110b are the values in the rightmost column in FIG.
[0053]
In FIG. 16, in step S91, the computer 30 obtains the outside air absolute humidity Aob from the weather forecast information. In step S92, the computer 30 determines that the set temperature Tr of the indoor unit 11 is a wall 151 or 152 that partitions the rooms 100a and 100b in which the indoor unit 11 is installed or a wall 151 that partially partitions the air-conditioning partitions 110a and 110b. , 152 is higher than the radiation temperature Tkm. As a result of the check in step S92, if the set temperature Tr is equal to or higher than the radiation temperature Tkm of the walls 151 and 152, the process proceeds to step S94. As a result of the confirmation in step S92, if the set temperature Tr is lower than the radiation temperature Tkm of the walls 151, 152, the process proceeds to step S93. The process of step S93 is performed in steps of 1 ° C from the comfort limit temperature Tm of 18 ° C to 30 ° C. In step S93, the computer 30 performs a process of determining that the correction terms A (Tm) are all equal to zero. Also in the process of step S94, the comfort limit temperature Tm is performed in steps of 1 ° C from 18 ° C to 30 ° C. In step S94, the computer 30 performs a process for determining that the correction term A (Tm) is equal to C (Tm) × (Tm-Tkm). In step S95, the computer 30 derives a comfort limit temperature Tm that satisfies the condition of Ao (Tm) ≦ Aob <Ao (Tm + 1). In step S96, the computer 30 sets the set temperature parameter to “Tm”.
[0054]
In this way, it is possible to indirectly perform the air conditioning control in consideration of the perceived temperature (9).
In the air-conditioning control system 400 according to the previous embodiment, the processing from step S11 to step S17 shown in FIG. 5 is performed, but the processing from step S131 to step S139 shown in FIG. May be.
[0055]
In FIG. 19, the processing from step S131 to step S139 is executed at an interval of 15 minutes from 5:00 to 22:00 on a scheduled day. In step S131, the computer 30 checks whether the current time is the first processing time. Here, the first processing time is 5:00. If the current time is the first processing time as a result of the confirmation in step S131, the process proceeds to step S132. If the current time is not the first processing time as a result of the check in step S131, the process proceeds to step S134. In step S132, the computer 30 receives the radiation temperature Tkm of each room of the building 60 transmitted from the station 20, and stores the radiation temperature information in the management database 32. In step S133, the computer 30 checks whether the current time is the third processing time. Here, the third processing time is a time of one hour interval from 5:00 to 22:00. If the current time is the third processing time as a result of the confirmation in step S133, the process moves to step S134. If the current time is not the third processing time as a result of the check in step S132, the process proceeds to step S135. In step S134, the computer 30 receives the weather information transmitted from the weather information management server 80, and stores the weather information in the management database 32. Here, the weather information is an expected temperature and an expected humidity every 15 minutes on the day of the area where the building 60 exists. In step S135, the computer 30 checks whether the current time is the fourth processing time. Here, the fourth processing time is 5:00. If the current time is the fourth processing time as a result of the confirmation in step S135, the process moves to the refrigeration cycle routine R1. If the current time is not the fourth processing time as a result of the confirmation in step S135, the process proceeds to step S136. In the refrigeration cycle routine R1, the computer 30 partially divides the weather information, the set temperature of the indoor unit 11, and a part of the walls 151 and 152 or the air-conditioning sections 110a and 110b that divide the rooms 100a and 100b of the building 60. The on / off control parameters of the operation suppression control function of the refrigeration cycle are derived using the radiation temperature of a part of the walls 151 and 152. In step S136, the computer 30 checks whether the current time is the second processing time. Here, the second processing time is a time at 15-minute intervals from 5:00 to 22:00. If the current time is the second processing time as a result of the confirmation in step S136, the process proceeds to the outside air introduction routine R2. If the current time is not the second processing time as a result of the check in step S136, the process proceeds to step S138. In the outside air introduction routine R2, the computer 30 sets the temperature of the indoor unit 11 and a part of the walls 151 and 152 that partition the rooms 100a and 100b of the building 60 or the walls 151 and 151 that partially partition the air-conditioning partitions 110a and 110b. The on / off control parameters of the total heat exchanger unit 15 and the on / off control parameters of the indoor unit 11 of the multi-type air conditioner 10 are derived using the radiation temperature of a part of the air conditioner 152. In the set temperature routine R3, the computer 30 causes the weather information (information on the outside air temperature and the absolute humidity of the outside air, etc.), the set temperature of the indoor unit 11, and a part of the walls 151 and 152 that partition the rooms 100a and 100b of the building 60. Alternatively, the set temperature parameter is derived by using the radiation temperature of a part of the walls 151 and 152 that partially partition the air conditioning sections 110a and 110b. In step S137, the air-conditioning control parameter deriving program 31 creates an air-conditioning control table from the control parameters derived in the refrigeration cycle routine R1, the outside air introduction routine R2, and the set temperature routine R3. In step S138, the computer 30 compares the air-conditioning control table with the previous air-conditioning control table to check whether the air-conditioning control table has been changed. If it is determined in step S138 that the air conditioning control parameter has been changed, the process proceeds to step S139. If the result of the check in step S138 indicates that no change has been made to the air-conditioning control parameters, the computer 30 waits until the processing time. In step S139, the computer 30 transmits the air conditioning control table to the station 20.
[0056]
In this way, it is possible to effectively utilize weather information that is updated sequentially.
(10)
In the air conditioning control system 400 according to the above-described embodiment, the radiation temperature of the walls 151 and 152 is measured using the temperature sensor 205. Alternatively, the radiation temperature may be estimated. Here, the radiation temperature is estimated by [Equation 2].
[0057]
[Equation 2] Tks = f (Trm (t))
(T is the hour every hour from 0:00 to 23:00)
In [Equation 2], the estimated radiation temperature Tks is expressed as a function of the temperature Trm of the rooms 100a and 100b at a certain time t (measured by the temperature sensor of the indoor unit 11). For example, it is conceivable to estimate the estimated body temperature Tks from the temperature Trm at 5:00. It is also conceivable to estimate the estimated body temperature Tks from the average value of the nighttime temperature Trm.
[0058]
In this way, the temperature of the skeleton can be obtained without introducing a new measuring instrument.
(11)
In the air conditioning control system 400 according to the above-described embodiment, the radiation temperature of the walls 151 and 152 is measured using the temperature sensor 205. Alternatively, the radiation temperature may be estimated. Here, the radiation temperature is estimated by [Equation 3].
[0059]
[Equation 3] Tks = f (Trm (t)) − g (room position, greening information)
(T is the hour every hour from 0:00 to 23:00)
In [Equation 3], the estimated radiation temperature Tks is a value obtained from a function of the temperature Trm of the rooms 100a and 100b at a certain time t (which can be measured by the temperature sensor of the indoor unit 11) and the positions of the rooms 100a and 100b. It is expressed as a difference from a value obtained from a function of the information (the sunshine and the like can be considered) and the greening information (greening place, greening area, greening density, etc.). The term f (Trm (t)) may be estimated from the temperature Trm at 5:00, for example. It is also conceivable to estimate from the average value of the nighttime temperature Trm. Regarding the item g (room position, greening information), it is conceivable that the building 60 is partitioned as shown in FIG. 20 (hereinafter, this partition is classified as greening influence classification sections 111, 112, 113, 114, 115, 116, 117, 118). As the simplest example, g (room position, greening information) = 2 in the greening effect classification section of FIG. 111, and g (room position, greening information) = 1. 5, g (room position, greening information) = 1.5 in the greening influence classification section of FIG. 113, and g (room position, greening information) = 1 in the greening influence classification section of FIG. In the greening influence classification section of No. 115, g (room position, greening information) is set to 2; in the greening influence classification section of FIG. 116, g (room position, greening information) is set to 0.5; It is conceivable that g (room position, greening information) = 0 in the influence classification section and g (room position, greening information) = 1 in the greening influence classification section shown in FIG. This is because in the case of cooling, it is expected that the closer to the greening location, the less the effect of the external heat load. It is considered that if the temperature unevenness of the building 60 is investigated in advance and such a value can be determined based on the knowledge of the investigation, the frame temperature can be more accurately estimated.
[0060]
(12)
In the air-conditioning control system 400 according to the previous embodiment, the operating temperature is mainly used, but instead of this, other thermal indexes, for example, the effective temperature, the corrected effective temperature, the discomfort index, the operating temperature, the cold air index, An equivalent cooling temperature, a WBGT index, a new effective temperature, or the like may be employed. Further, a physical quantity such as enthalpy may be used.
[0061]
(13)
In the air-conditioning control system 400 according to the above embodiment, the radiation temperature of the walls 151 and 152 is measured. Alternatively, the radiation temperature of the ceiling or floor may be measured. Alternatively, the surface temperatures of the walls 151 and 152 may be measured.
(14)
In the air conditioning control system 400 according to the above-described embodiment, the underground pipe 320 is provided outside the building 60, but the underground pipe 320 may be provided inside the building 60 instead. In this way, the heat radiation of the outside air passing underground can be suppressed.
[0062]
(15)
In the air-conditioning control system 400 according to the above embodiment, the skeleton temperature was obtained at 5:00, but in addition to this, the skeleton temperature was obtained at several minutes from 5:00 to 22:00. Is also good. By doing so, control parameters can be derived more finely. Therefore, the energy saving effect can be further improved.
[0063]
(16)
In the air-conditioning control system 400 according to the previous embodiment, the air-conditioning control parameter deriving program 31 is installed in the computer 30. Alternatively, the air-conditioning control parameter deriving program 31 may be installed in the station 20. However, in this case, it is necessary to establish a connection between the weather information management server 80 and the station 20.
[0064]
【The invention's effect】
In the air-conditioning control device according to the first aspect, the skeleton temperature obtaining means obtains at least a part or all of the temperature of the skeleton that partially or entirely partitions the space belonging to the predetermined space, at least in units of the space. Then, the set temperature determining means determines the set temperature of the air conditioner in each of the spaces belonging to the predetermined space by using the temperature of a part or the whole of the frame. By the way, there is a theory that the sensible temperature of a person in a room depends not only on the temperature of the room but also on the temperature of a frame constituting the room (for example, see Non-Patent Document 1). According to this theory, for example, during cooling, if the temperature of the body is lower than the set temperature of the air conditioner for each space, raise the set temperature to such an extent that the comfort of the occupants is not impaired, and If the air conditioning control parameters can be derived to maintain the set temperature when the temperature is higher than the set temperature, air conditioning installed in buildings where the air conditioning load is uneven due to greening etc. The energy consumption of the machine can be reduced at low cost and appropriately without impairing the comfort of the occupants.
[0065]
In the air-conditioning control device according to claim 2, the set temperature determining means uses the temperature of a part or the whole of the skeleton so that the predetermined temperature index of each of the spaces belonging to the predetermined space becomes constant. Determine the set temperature. For this reason, for example, during cooling, the temperature index changes when the body temperature is lower than the set temperature of the air conditioner, and the set temperature can be increased by the change, and the body temperature is higher than room temperature. If the air conditioning control parameters can be derived to maintain the set temperature when it is high, the consumption of air conditioners installed in buildings where the air conditioning load is uneven due to greening etc. The electric energy can be sufficiently reduced without impairing the comfort of the occupants.
[0066]
In the air conditioning control device according to the third aspect, the humidity acquiring means acquires the humidity of each of the spaces belonging to the predetermined space. Then, the set temperature determining means processes the humidity data by using the temperature of a part or the whole of the frame, and sets the air conditioner of each space belonging to a predetermined space based on the processed humidity data. Determine the temperature. Humidity is known to have a significant effect on human perceived temperature. For this reason, it is possible to indirectly perform the air conditioning control in consideration of the sensible temperature.
[0067]
When the air conditioning control device according to claim 4 is used, it is not necessary to install a humidity sensor or an information collecting device for estimating humidity in each space. Therefore, the temperature index and the like can be derived more easily.
When the air conditioning control device according to claim 5 is used, it is possible to obtain the temperature of a part or the whole of the frame without introducing a new measuring instrument.
[0068]
When the air-conditioning control device according to claim 6 is used, it is possible to measure the temperature of the skeleton with high accuracy, though it requires some equipment cost and construction cost.
When the air-conditioning control program according to claim 7 is executed, in the skeleton temperature obtaining step, at least a part or all of the temperature of the skeleton that partially or entirely partitions the space belonging to the predetermined space is at least the space unit. Is obtained by Then, in the set temperature determining step, the set temperature of the air conditioner in each of the spaces belonging to the predetermined space is determined using the temperature of a part or the whole of the frame. By the way, there is a theory that the sensible temperature of a person in a room depends not only on the temperature of the room but also on the temperature of a frame constituting the room (for example, see Non-Patent Document 1). According to this theory, for example, at the time of cooling, when the body temperature is lower than the set temperature of the air conditioner for each predetermined space, the set temperature is increased to a degree that does not impair the comfort of the occupants, and If the temperature of the skeleton is higher than the set temperature, if the air-conditioning control parameters can be derived so as to maintain the set temperature, it will be installed in buildings where the air-conditioning load is uneven due to greening etc. The energy consumption of the air conditioner can be reduced inexpensively and appropriately without impairing the comfort of the occupants.
[0069]
When the air-conditioning control method according to claim 8 is performed, in the skeleton temperature acquiring step, at least a part or all of the temperature of the skeleton that partially or entirely partitions the space belonging to the predetermined space is at least a space unit thereof. Is obtained by Then, in the set temperature determining step, the set temperature of the air conditioner in each of the spaces belonging to the predetermined space is determined using the temperature of a part or the whole of the frame. By the way, there is a theory that the sensible temperature of a person in a room depends not only on the temperature of the room, but also on the temperature of the frame constituting the room (for example, see Non-Patent Document 1). According to this theory, for example, during cooling, if the temperature of the body is lower than the set temperature of the air conditioner for each space, raise the set temperature to such an extent that the comfort of the occupants is not impaired, and If the air conditioning control parameters can be derived to maintain the set temperature when the temperature is higher than the set temperature, air conditioning installed in buildings where the air conditioning load is uneven due to greening etc. The energy consumption of the machine can be reduced at low cost and appropriately without impairing the comfort of the occupants.
[0070]
In the air-conditioning control system according to claim 9, for example, at the time of cooling, when the body temperature of each space is lower than the set temperature of the air conditioner, the set temperature is set to such an extent that the comfort of the occupants is not impaired. If the temperature of the skeleton is higher than the set temperature, the air conditioning control parameters can be derived so as to maintain the set temperature, and if the air conditioner can be controlled by the parameters, the air conditioning load will be reduced and the air conditioning load will be reduced. The energy consumption of the air conditioner installed in a non-uniform building or the like can be reduced inexpensively and appropriately without impairing the comfort of the occupants.
[Brief description of the drawings]
FIG. 1 is a block diagram of an air conditioning control system 400.
FIG. 2 is a perspective view of a building 60.
FIG. 3 is a diagram showing an air conditioner (when one indoor unit 11 is installed in one room).
FIG. 4 is a diagram showing an air conditioner (when a plurality of indoor units 11 are installed in one room).
FIG. 5 is a flowchart showing a flow of deriving an air conditioning control parameter. FIG. 6 is a flowchart showing a flow of processing of a refrigeration cycle routine 31b.
FIG. 7 is a flowchart showing the flow of processing of an outside air introduction routine 31a.
FIG. 8 is a flowchart illustrating a flow of processing of a set temperature routine 31c.
FIG. 9 is a flowchart (1) illustrating a flow of processing of a refrigeration cycle routine according to a modified example (4).
FIG. 10 is a flowchart (2) illustrating a flow of processing of a refrigeration cycle routine according to a modified example (4).
FIG. 11 is a flowchart illustrating a flow of processing of an outside air introduction routine according to a modification (5).
FIG. 12 is a diagram illustrating an air conditioner according to a modification (7).
FIG. 13 is a flowchart (1) illustrating a flow of processing of an outside air introduction routine 31a according to a modification (7).
FIG. 14 is a flowchart (2) illustrating a flow of processing of an outside air introduction routine 31a according to a modification (7).
FIG. 15 is a diagram illustrating another air conditioner according to a modification (7).
FIG. 16 is a flowchart illustrating a processing flow of a set temperature routine 31c according to a modification (8).
FIG. 17 is a table for explaining a relationship among an outside air absolute humidity, an indoor absolute humidity, and a set temperature.
FIG. 18 is a conceptual diagram of control parameters created in a set temperature routine.
FIG. 19 is a flowchart illustrating derivation of an air conditioning control parameter according to a modification (9).
FIG. 20 is a diagram showing greening influence classification sections 111, 112, 113, 114, 115, 116, 117 and 118 of a building 60 according to a modification (10).
[Explanation of symbols]
Reference Signs List 10 Multi-type air conditioner 11 Indoor unit 12 Outdoor unit 15 Total heat exchanger unit 20 Station 21 Control units 23, 33, 82 Modem 30 Computer 31 Air conditioning control parameter derivation program 31a Outside air introduction routine 31b Refrigeration cycle routine 31c Set temperature routine 32 Management database 40 Network 50 Information management center 60 Green building 61, 62 Green space 63 Rooftop exit 64 Water storage tank 70 Management room 80 Weather information management server 81 Weather database 90 Weather information distribution center 100, 110 Sections 100a, 100b Rooms 110a, 110b Air conditioning Sections 111, 112, 113, 114, 115, 116, 117, 118
Greening effect classification section 151 Outer wall 152 Wall 202 Electronic expansion valve 203a Refrigerant pipe (liquid pipe)
203b Refrigerant pipe (gas pipe)
204 Controller 205 Temperature sensor 302a Duct piping (air supply side)
302b Duct piping (exhaust side)
311 Air supply fan 313, 317 Exhaust fan 315 Exhaust damper 319 Three-way solenoid valve 320 Underground piping 400 Air conditioning control system 500 Boundary surface of air conditioning area

Claims (9)

An air conditioning control device (30) for controlling an air conditioner (11) that air-conditions a predetermined space in a building (60) having a plurality of spaces,
The temperature of a part or all of the frame (151, 152) that partially or entirely partitions the space (100a, 100b, 110a, 110b) belonging to the predetermined space is set at least in the space (100a, 100b). , 110a, 110b) unit temperature acquiring means (33) to acquire in units;
A set temperature of the air conditioner (11) in each of the spaces (100a, 100b, 110a, 110b) belonging to the predetermined space is determined by using a part or all of the temperature of the frame (151, 152). Setting temperature determining means (31) to be performed;
An air conditioning control device (30), comprising: The set temperature determining means (31) uses a part or all of the temperature of the frame (151, 152) to determine a predetermined temperature of each of the spaces (100a, 100b, 110a, 110b) belonging to the predetermined space. Determining a set temperature of the air conditioner (11) such that the temperature index is constant;
An air-conditioning control device (30) according to claim 1. A humidity acquisition unit that acquires humidity of each of the spaces (100a, 100b, 110a, 110b) belonging to the predetermined space;
The set temperature determining means (31) processes the data of the humidity by using a part or all of the temperature of the frame (151, 152), and based on the processed data of the humidity, the predetermined temperature. Determining a set temperature of the air conditioner (11) in each of the spaces (100a, 100b, 110a, 110b) belonging to the space;
An air-conditioning control device (30) according to claim 1. The humidity is estimated from weather information of an area where the building (60) exists.
An air conditioning control device (30) according to claim 3. The temperature of a part or all of the skeletons (151, 152) includes the temperature of the inside air of the space (100a, 100b, 110a, 110b), the position information of the space (100a, 100b, 110a, 110b), and the building. It is an estimated value estimated based on the greening information of the object (60).
An air conditioning control device (30) according to any of the preceding claims. The temperature of a part or all of the skeleton (151, 152) is a measured value.
An air conditioning control device (30) according to any of the preceding claims. An air conditioning control program (31) for controlling an air conditioner (11) that air-conditions a predetermined space in a building (60) having a plurality of spaces,
The temperature of a part or all of the frame (151, 152) that partially or entirely partitions the space (100a, 100b, 110a, 110b) belonging to the predetermined space is set at least in the space (100a, 100b). , 110a, 110b) obtaining a frame temperature in units of:
A set temperature of the air conditioner (11) in each of the spaces (100a, 100b, 110a, 110b) belonging to the predetermined space is determined by using a part or all of the temperature of the frame (151, 152). A set temperature determining step to be performed;
An air conditioning control program comprising: An air conditioning control method for controlling an air conditioner (11) that air-conditions a predetermined space in a building (60) having a plurality of spaces,
The temperature of a part or all of the frame (151, 152) that partially or entirely partitions the space (100a, 100b, 110a, 110b) belonging to the predetermined space is set at least in the space (100a, 100b). , 110a, 110b) obtaining a frame temperature in units of:
A set temperature for determining a set temperature of the air conditioner in each of the spaces (100a, 100b, 110a, 110b) belonging to the predetermined space using a part or all of the temperature of the frame (151, 152); A decision step;
An air conditioning control method comprising: An air conditioning control device (20, 30) according to any one of claims 1 to 6,
An air conditioner (10) controlled by the air conditioning control device (20, 30);
An air conditioning control system comprising:

Images