DE112014006809T5 - Air conditioning control, air conditioning control method and program - Google Patents

Abstract

A control algorithm database (121) stores a plurality of types of control algorithms to control an air conditioner. A characteristic database (123) stores specific characteristics for a building in which the air conditioning system is installed. An environment data maintainer (131) controls a communication unit (11) and obtains environmental data of the interior and exterior of the structure. A predictor (132), based on the obtained environmental data and characteristics, performs a simulation using each control algorithm for controlling the air conditioner and predicts a control result for each of the control algorithms. A selector (133) evaluates each control result based on an energy saving power and a comfort level, and selects a control algorithm among the control algorithms. A controller (134) controls the air conditioning system based on the selected control algorithm.

Description

Technical area

The present invention relates to an air conditioning controller, an air conditioning control method and a program capable of appropriately controlling an air conditioner installed in a structure such as a building.

Background to the prior art

Recently, there is a growing demand for energy-saving air conditioners installed in a structure such as a building. Consequently, manufacturers of air conditioners are anxious to improve the energy saving performance by, for example, making the performance of the air conditioners more efficient, and controlling the air conditioner in accordance with an air conditioning load.

Such conventional techniques for controlling the air conditioners include, for example, as disclosed in Patent Literature 1, a operation planning system (navigation system) for predicting a thermal load in a structure and selecting the number of air conditioners to be operated (air conditioning heat source devices) and their operation scheme.

List of quoted writings

patent literature

• Patent Literature 1: unexamined Japanese Patent Application Kokai Publication No. 2011-002112

Summary of the invention

Technical problem

According to the above-explained system disclosed in Patent Literature 1, the power saving performance is improved by setting an operating schedule of the air conditioner in accordance with the predicted thermal load. However, controlling the air conditioner by simply selecting, for example, the number of air conditioners to be operated in accordance with the thermal load in a room may lead to temperature irregularities and thus reduce the comfort of the user.

The present disclosure has been made to overcome the above-mentioned problems, and an object of the present disclosure is to provide an air conditioning controller, an air conditioning control method, and a program capable of appropriately controlling an air conditioner while maintaining both comfort level and energy saving performance be accomplished.

the solution of the problem

To achieve the above object, the present disclosure provides an air conditioning controller for controlling an air conditioner installed in a structure, the air conditioning controller including: an algorithm memory configured to store a plurality of types of control algorithms; a characteristic memory configured to store characteristics specific to the structure; an environment data maintainer configured to obtain environmental data of an interior area and an exterior area of the structure; a predictor configured to perform a simulation using each of the control algorithms for controlling the air conditioner based on the obtained environment data and the characteristics, and to predict a control result for each of the control algorithms; a selector configured to evaluate each predicted control result based on an energy saving performance and a comfort level, and selecting a control algorithm among the control algorithms; and a controller configured to control the air conditioning system based on the selected control algorithm.

Advantageous Effects of the Invention

According to the present disclosure, the results of the simulations performed by applying the plurality of types of control algorithms for controlling an air conditioner are respectively evaluated based on energy saving performance and comfort level. In addition, the air conditioner is controlled based on the control algorithm selected in accordance with the ratings. Thus, the air conditioner can be suitably controlled while accomplishing both comfort level and power saving performance.

Brief description of the drawings

1 FIG. 10 is a schematic diagram showing an exemplary overall structure of an air conditioning system according to an embodiment of the present disclosure; FIG.

2 FIG. 10 is a block diagram showing an exemplary structure of an air conditioning controller according to an embodiment of the present disclosure; FIG.

3 Fig. 12 is a schematic diagram showing an exemplary control algorithm database;

4 Fig. 12 is a schematic diagram showing an exemplary control result predicted by a simulation; and

5 FIG. 10 is a flowchart illustrating an example air conditioning control process according to an embodiment of the present disclosure. FIG.

Description of the embodiments

Hereinafter, embodiments of the present disclosure will be explained in detail with reference to the accompanying drawings. Like or similar components in the drawings are designated by the same reference numerals.

1 is a schematic representation showing an exemplary overall structure of an air conditioning system 1 according to an embodiment of the present disclosure. The air conditioning system 1 is a system for controlling an air conditioner (outdoor unit 20 and indoor unit 30 ), which is installed in a building, such as a building. The air conditioning system 1 includes an air conditioning control 10 , the outdoor unit 20 , the indoor unit 30 ( 30a . 30b ) and a remote control 40 ( 40a . 40b ). The air conditioning control 10 , the outdoor unit 20 and the indoor unit 30 among the aforementioned units are via an air conditioning communication network 90 communicating with each other. In addition, the indoor unit 30 and the remote control 40 for example, communicating with each other via a communication line.

The structure of in 1 illustrated air conditioning system 1 is an example and may be modified as necessary. For example, a suitable number of indoor units 30 installed in accordance with the size of a room in a building, a building plan (floor plan) and the like. Furthermore, there is a suitable number of outdoor units 20 in correspondence with the number of indoor units 30 and the like installed. The air conditioning system 1 may be modified as necessary to have a structure corresponding to such an actual structure.

The air conditioning control 10 controls the outdoor unit 20 and the indoor unit 30 via the air conditioning communication network 90 , Details of the air conditioning control 10 are explained below.

The outdoor unit 20 is installed on the outside of a house roof or the like of the structure and is controlled by the air conditioning controller 10 or the like controlled. The outdoor unit 20 includes, for example, a compressor and a heat source side heat exchanger, and is connected to the indoor unit 30 ( 30a . 30b ) connected via pipelines. The outdoor unit 20 circulates a cooling medium between the outdoor unit 20 and the indoor unit 30 over the pipelines. In addition, the outdoor unit contains 20 For example, a sensor to measure environmental data such as temperature and humidity, and sends the measured environmental data (outside temperature (ambient temperature) and outside air humidity) via the air conditioning communication network 90 to the air conditioning control 10 ,

The indoor unit 30 ( 30a . 30b ) is installed in a room, for example on a ceiling, in the building and is controlled by the air conditioning control 10 and / or the remote control 40 ( 40a . 40b ) controlled. The indoor unit 30 For example, it includes an expansion valve, a load-side heat exchanger, and the like, and is piped to the outdoor unit 20 connected. The indoor unit 30 causes the load side heat exchanger to evaporate or condense the cooling medium, and performs air conditioning of a room to be conditioned. Furthermore, the indoor unit contains 30 For example, a sensor to measure environmental data such as temperature and humidity, and sends the measured environmental data (for example, room temperature and indoor air humidity near the ceiling) over the air conditioning communication network 90 to the air conditioning control 10 , As explained below, by the remote control 40 measured environmental data also in the indoor unit 30 collected, and the indoor unit 30 thus sends such environmental data also to the air conditioning control 10 ,

The remote control 40 ( 40a . 40b ) is installed in a room, for example on a wall, in the building. The remote control 40 For example, it includes a liquid crystal display and buttons, and is connected to the indoor unit via a communication line and the like 30 connected. Further shows the remote control 40 on the liquid crystal display the operating status of the indoor unit 30 and the like, and detects depression of a button and accepts an operation specified by a user. The remote control 40 further includes, for example, a sensor to measure environmental data such as temperature and humidity, and sends the measured environmental data (for example, room temperature and indoor air humidity near a wall) to the indoor unit 30 ,

Subsequently, the air conditioning control 10 in detail with reference to 2 explained. 2 FIG. 10 is a block diagram for illustrating an exemplary structure of the air conditioning controller. FIG 10 according to an embodiment of the present disclosure. As shown in the figure, the air conditioning controller includes 10 a communication unit 11 , a data store 12 and a processor 13 ,

The communication unit 11 is for example a communication interface with the outdoor unit 20 and the indoor unit 30 via the air conditioning communication network 90 communicated. The communication unit 11 is through the processor 13 controlled, receives the environment data and the like from the outdoor unit 20 and the indoor unit 30 , and sends command data to the outdoor unit 20 and the indoor unit 30 ,

The data store 12 serves as a secondary memory (auxiliary memory), and includes, for example, a readable and writable nonvolatile semiconductor memory such as a flash memory. The data store 12 stores a control algorithm database 121 , a control results database 122 and a Kenndatenbank 123 , which are explained below. Furthermore, the data store stores 13 through the processor 13 programs to be executed.

First, the control algorithm database 121 with reference to 3 explained. 3 FIG. 13 is a schematic diagram illustrating an example control algorithm database. FIG 121 shows. The control algorithm database 121 stores a variety of types of algorithms for controlling the outdoor unit 20 and the indoor unit 30 (that is the air conditioning). In 3 Designations shown indicate designations given to the control algorithms. In the 3 The recommended environment shown defines the environment (for example, temperature and weather) that is recommended when using the appropriate control algorithm. In the 3 The control details shown indicate certain details of the algorithms. The control details are given in sentences to facilitate understanding, but in practice, for example, various control parameters and conditions of use are defined in numerical data.

Returning to 2 saves the control results database 122 a log of the actual control results. For example, the control result database stores 122 Operating data, for example, ON / OFF of the air conditioner and its temperature setting, air conditioner power consumption data, and the indoor and outdoor room environmental data, all of which are obtained when the air conditioner (the outdoor unit 20 and the indoor unit 30 ) is controlled in accordance with the control algorithm.

The identification database 123 stores data indicating a property specific to the building (object). For example, stores the Kenndatenbank 123 Data such as the size of the structure and the building materials, data on types of building equipment such as the air conditioner and lighting, and their installation positions, data on the number of set resident (users), a standard position, and the like, and size data the furniture and its placement position.

The processor 13 includes a central processing unit (CPU), a read only memory (ROM), a random access memory (RAM), and the like (all not shown), and controls the entire air conditioning controller 10 , The processor 13 includes as its functions an environment data maintainer 131 , a predictor 132 , a selector 133 and a controller 134 , The CPU uses the RAM as a work memory and, if necessary, performs various in the ROM or the data memory 12 stored programs, whereby the aforementioned functions are realized.

The environment data maintainer 131 controls the communication unit 11 , and receives the environmental data from the exterior and interior of the structure. That is, the environment data maintainer 131 receives the environmental data, such as temperature and humidity, which are detected by the sensor of the outdoor unit 20 and the sensor of the indoor unit 30 (or the remote control 40 ) are measured. The environmental data may include a CO ₂ concentration, air flows (directions and strengths), and the like.

The predictor 132 results based on the environment data maintainer 131 obtained environmental data and in the characteristic memory 123 stored characteristics a simulation (for example, heat flow simulation) using each in the control algorithm database 121 stored control algorithm, and predicts a control result for each control algorithm. The predictor 132 may also be a simulation using each control algorithm based on data, in addition to the above data also in the control result database 122 perform stored actual control results. Furthermore, the predictor 132 the control algorithms for the simulation by applying the in explained above 3 narrow down the recommended environment. That is, the predictor 132 may constrain the control algorithms so that only control algorithms are controlled in which the current environment data matches the defined recommended environment, and can perform simulation only with the control algorithms that are likely to be highly effective.

In particular, the predictor says 132 through the simulation like in 4 previously displayed control result. That is, the predictor 132 divides the room (the room to be air-conditioned) into several sections, and predicts the temperature of each section, a direction of the airflow and its magnitude. The predictor 132 predicts such control results for each control algorithm.

Returning to 2 the selector evaluates 133 each by the predictor 132 predicted control result based on the energy saving performance and the comfort level, and selects a control algorithm among the control algorithms. The selector explained above 133 contains in particular an energy saving evaluator 133a and a comfort evaluator 133b ,

The energy saving evaluator 133a evaluate each one by the predictor 132 predicted control result based on the energy saving performance. For example, the energy saving evaluator rates 133a the predicted control result based on the energy saving performance, which is represented by a relation between a power consumption of the air conditioner (the outdoor unit 20 and the indoor unit 30 ) and their target power consumption is determined. Details will be explained below.

First, get the energy saving evaluator 133a from the predicted control result, a temperature setting and an operating time of the air conditioner (the outdoor unit 20 and the indoor unit 30 ) in a state in which the control algorithm is executed, and predicts the power consumption. In addition, the energy-saving evaluator reads 133a from the data store 12 the target power consumption set by the user. If no target power consumption is set, a hypothetical value (for example, a power consumption of the previous day) is used as the target power consumption. Subsequently, the energy saving evaluator calculates 133a an energy saving index of the control algorithm. The energy saving index is the reciprocal of the predicted power consumption in relation to the target power consumption per unit of time. For example, if the target power consumption is 1 kWh and the predicted power consumption is 2 kWh, the power-saving index is 0.5. The energy saving evaluator 133a evaluates the predicted control result based on the thus-determined energy-saving index (the energy-saving performance).

The comfort evaluator 133b rated based on the level of comfort each by the predictor 132 predicted control result. Details will be explained below.

First, the comfort evaluator determines 133b the comfort level for each section based on the one described above 4 shown control result. For the comfort level, a comfort rating index such as a new effective standard temperature (SET *) or predicted mean vote (PMV) is used. That is, the comfort level is calculated using an arithmetic expression of the predefined comfort score index. SET * and PMV are just examples, and other comfort rating indexes as well as an original rating function can be used to calculate the comfort level. Subsequently, the comfort evaluator intervenes 133b to one in the Kenndatenbank 123 stored standard position of the user and performs weighting of the comfort level (the comfort rating index or the like) in accordance with the number of people in the section and the like. In addition, the comfort evaluator rates 133b the predicted evaluation result based on the comfort level determined in this way.

Furthermore, the selector selects 133 the control algorithm with the highest energy saving performance and the highest level of comfort as explained above. For example, the selector normalizes 133 the determined energy saving index and comfort rating index, and performs a linear correction in such a manner that the maximum value of each normalized index is 1. In addition, the selector adds 133 the normalized comfort index with the normalized comfort index and selects the control algorithm that has the largest value.

The control 134 controls the outdoor unit 20 and the indoor unit 30 based on that by the selector 133 selected control algorithm. That is, the controller 134 controls the air conditioner based on the control algorithm which is highly valued in both the energy saving performance and the comfort level.

Subsequently, an operation of the air conditioning control 10 which employs such structures as explained above with reference to FIG 5 explained. 5 FIG. 10 is a flowchart illustrating an example An air conditioning control process according to an embodiment of the present disclosure.

First receives the air conditioning control 10 Environment data (step S501). That is, the environment data maintainer 131 gets the environmental data, as by the outdoor unit 20 and the indoor unit 30 (the remote control 40 ) measured temperature and humidity.

The air conditioning control 10 Limits the control algorithms (step S502). That is, the predictor 132 Limits the control algorithms to a simulation by applying the recommended environment shown in 3 to carry out as described above. For example, the predictor is adjacent 132 as objects for simulation, the control algorithms only on control algorithms in which the current environment data match the recommended environment.

The air conditioning control 10 performs a simulation using each control algorithm, and predicts each control result (step S503). That is, the predictor 132 results based on the environment data maintainer 131 obtained environmental data and in the Kenndatenbank 123 stored by using each control algorithm bounded in step S502, and predicts each control result for each control algorithm. The predictor 132 Furthermore, a simulation using each control algorithm based on data, in addition to the above-mentioned data in the control results database 122 perform stored actual control results.

The air conditioning control 10 calculates the energy saving index from the predicted control result (step S504). That is, the energy saving evaluator 133a calculates the energy saving index, which is determined by the relationship between the power consumption of the air conditioner (the outdoor unit 20 and the indoor unit 30 ) and their target power consumption is determined. In particular, the energy saving power evaluator receives 133a from the predicted control result, a temperature setting and operating time of the air conditioner in a state in which the control algorithm is executed, and predicts the power consumption. Furthermore, the energy saving evaluator reads 133a from the data store 12 the target power consumption set by the user. If no target power consumption is set, a hypothetical value (for example, power consumption of the previous day) is used as the target power consumption. In addition, the energy saving evaluator calculates 133a the energy saving index, which is the reciprocal of the predicted power consumption relative to the target power consumption per unit time.

The air conditioning control 10 calculates the comfort score index from the predicted control result (step S505). That is, the comfort evaluator 133b determines the comfort rating index for each section based on the in 4 shown control result as explained above. The comfort score index is calculated using an arithmetic expression such as SET * or PMV. Furthermore, the comfort evaluator attacks 133b to one in the Kenndatenbank 123 stored standard position of the user, and performs weighting of the comfort rating index in accordance with the number of persons in the section and the like.

The air conditioning control 10 selects the control algorithm based on the calculated energy saving index and comfort evaluation index (step S506). That is, the selector 133 Selects the control algorithm with the highest energy-saving performance and comfort level.

The air conditioning control 10 controls the air conditioner based on the selected control algorithm (step S507). That is, the controller 134 controls the outdoor unit 20 and the indoor unit 30 based on the control algorithm selected in step S506. At this time, the air conditioning controller stores 10 in the control results database 122 Control data (for example, an operation mode and a set temperature) during operation, the environment data, and the like.

The air conditioning control 10 performs such an air conditioning control process every predetermined time. As explained below, for example, when weather data is obtained from the outside area, the air conditioning control performs 10 Such air-conditioning control process at each time when the weather data are announced (for example, three times in a day).

As explained above, the air conditioning controller evaluates 10 According to some embodiments of the present disclosure, based on the energy saving performance and the comfort level, each of the results of the simulations using multiple types of control algorithms for controlling the air conditioner (the outdoor unit 20 and the indoor unit 30 ). In addition, the air conditioner is controlled based on the control algorithm selected by the ratings. Consequently, the air conditioner can be appropriately controlled while achieving both the comfort level and the energy saving performance.

Furthermore, the air conditioning controller uses 10 According to some embodiments of the present disclosure, the in 3 The recommended environment as described above, and limits the control algorithms for the simulation, thereby reducing the computational load and the like. That is, the prediction of the control result of the air conditioner using a heat airflow simulation and the like involves a larger computational load, and thus may require that the high-performance processor 13 (CPU or the like) for the air conditioning control 10 Must predict control results for many control algorithms. As in the present disclosure, by defining the recommended environment in which the control algorithm is likely to be highly effective, and limiting the control algorithms in which the current environment data matches the recommended environment, is any higher power processor 13 not required for a simulation, which reduces the cost of a product and the time it takes to complete the calculation.

According to the air conditioning control 10 In the above embodiment, explanation has been made for the case in which the comfort evaluator 133b the level of comfort for each section based on the in 4 as shown above receives control result and then performs weighting by the in the Kenndatenbank 123 saved default position of the user is accessed. Instead of the weighting, however, the comfort level can also be determined only in the section which corresponds to the standard position of the user. In this case, the control algorithm may be selected so that the comfort level at the place where the user resides is highly valued, and also the energy saving performance at the place where the user is not staying is highly valued.

According to the air conditioning control 10 In the above embodiment, explanation has been made for the case in which the selector 133 selects the control algorithm which is highly valued in both the energy saving performance and the comfort level. However, a setting allows the user to prioritize either the energy saving performance or the comfort level. For example, if the user makes a setting that prioritizes either energy saving or comfort level over the other, the selector can 133 either apply a higher weight for the prioritized power rating and select a control algorithm among the control algorithms. In this case, by allowing the user to select a higher importance assignment for either the power saving or the comfort level, the control algorithm that suits the needs and situation of the user, such as prioritizing the power saving performance, may be desirable when reducing the power consumption is to be selected.

According to the air conditioning control 10 In the above embodiment, explanation has been made for the case where the characteristic database 123 stores the standard position of the user and the like. However, in the case of a room for certain purposes, for example, a meeting room, a change in the number of persons or the like in accordance with the time may be obtained based on reservation data and the like. Furthermore, a motion sensor and the like may be further installed in a room to detect the current position of the user (approximate position) which may be used to perform weighting and the like of the comfort level judgment.

According to the above embodiment, the explanation has been made for the case where the sensor for measuring the environmental data such as temperature and humidity in the outdoor unit 20 , the indoor unit 30 and the remote control 40 is provided. However, similar sensors may be installed in the interior and exterior of the structure to obtain more detailed environmental data. In addition, the environmental data is not limited to temperature, humidity, and the like measured by a sensor, and may include various weather data that can be obtained from the outdoor area. If on the climate control 10 for example via the communication unit 11 can also be accessed via an external network (the Internet, etc.), the air conditioning controller receives weather data of a predefined sensor (for example, a public or private weather data distribution server). The weather data may include not only the current weather data but also forecast data (weather forecast data) for a few hours later.

According to the air conditioning control 10 In the above embodiment, the explanation was made for the case where the target power consumption is a fixed value (a target value or the like) when the energy-saving index is calculated in step S504 as explained above. However, when the weather data (for example, weather forecast data such as the weekly forecast) is obtained from the outdoor area, the power consumption that can be used at the current day can be obtained from such weather data. For example, if a prediction indicates that the ambient temperature is relatively low, and from Starting the next day hot days, the target power consumption can be set low. In this case, the target target power consumption can be effectively distributed and used.

According to the air conditioning control 10 In the above embodiment, explanation has been made for the case in which the control algorithms are narrowed by using the recommended environment in step S502 as explained above. However, the control algorithms can also be narrowed down in other ways, as necessary. For example, the control algorithms may be constrained so that they are preferably selected from the control algorithms that are based on those in the control results database 122 stored past control results have a higher impact. The actual air conditioning effect may in some cases differ from the simulation result due to the effect of a heat source placed in the room, a layout change of the space division, and the like. Thus, by effectively utilizing the control result of the actual execution of the control algorithm, the control algorithm more appropriate to the actual environment can be selected.

According to the above embodiment, the explanation has been made for the case where the air conditioning controller 10 the outdoor unit 20 and the indoor unit 30 controls. In addition to the above units, for example, when an auxiliary component such as a blower is installed, a simulation which also includes an operation of such a blower may be performed so that the blower is included as the target apparatus.

According to the above embodiment, the explanation has been made for the case where the air conditioning controller 10 performs the simulation and predicts the control result. However, an external server or the like may also perform the simulation, and the control result for the air conditioning control 10 provide. If, for example, on the climate control 10 also over an external network (the Internet etc.) over the communication unit 11 can be accessed, the air conditioning controller provides the environment data, the characteristics, each control algorithm, and the like to a predefined external server (eg, an arithmetic spare operation server) and requests a simulation. In addition, when each of the control results is received from the external server, the air conditioning controller evaluates 10 each control result based on the energy saving performance and the comfort level, and selects a control algorithm among the control algorithms in the manner explained above. It should be noted that the air conditioning controller may continue to request the evaluation of the power saving performance and the comfort level from the external server.

Further, according to the above embodiment, the explanation was made for the case where the special use air conditioning control 10 is used. However, an operating program that controls the operations of the air conditioning 10 can be applied to an existing personal computer, information terminal or the like, whereby it is possible for the personal computer or the like to be used as the air conditioning controller 10 of the present disclosure.

Furthermore, a distribution method of such a program is optional and such a program may be stored in a manner stored in a computer-readable storage medium, for example as a CD-ROM (Compact Disk Read-Only Memory), a DVD (Digital Versatile Disk), a magnetic disk. optical diskette (MO diskette) or a memory card or distributed over a communication network such as the Internet.

Above, some exemplary embodiments are given for illustrative purposes. Although particular embodiments are set forth above, it will be recognized by those skilled in the art that changes in form and details may be made without departing from the broader spirit and scope of the invention. Accordingly, the description and drawings are to be interpreted as illustrative and not in a limiting sense. Accordingly, this detailed description is not to be interpreted in a limiting sense, and the scope of the invention is defined only by the appended claims in conjunction with the full scope of equivalents which may claim the claims.

Industrial applicability

The present invention may be configured to provide the air conditioning controller, the air conditioning control method and the program capable of appropriately controlling the air conditioner while achieving both the comfort level and the energy saving performance.

LIST OF REFERENCE NUMBERS

1

Cooling system

10

air conditioning control

20

outdoor unit

30 (30a, 30b)

indoor unit

40 (40a, 40b)

Remote control

90

Cooling communication network

11

communication unit

12

data storage

13

processor

121

Control algorithm database

122

Control results database

123

Identification database

131

Environmental data preserver

132

projectionist

133

selector

133a

Energy-saving power Contributor

133b

Comfort Contributor

134

control

Claims (6)

An air conditioning controller for controlling an air conditioner installed in a structure, the air conditioning controller comprising: an algorithm memory configured to store a plurality of types of control algorithms; a characteristic memory configured to store characteristics specific to the structure; an environment data maintainer configured to obtain environmental data of an interior area and an exterior area of the structure; a predictor configured to perform a simulation using each of the control algorithms for controlling the air conditioner based on the obtained environment data and the characteristics, and to predict a control result for each of the control algorithms; a selector configured to evaluate each predicted control result based on an energy saving performance and a comfort level, and selecting a control algorithm among the control algorithms; and a controller configured to control the air conditioning system based on the selected control algorithm. The air conditioning controller of claim 1, wherein the selector comprises a comfort evaluator arranged to evaluate the predictor predicted by the predictor based on the comfort level calculated using a predefined arithmetic expression of a comfort rating index; the characteristics stored in the characteristic memory include a default position of a user in the structure, and the comfort evaluator rates the comfort level at the standard position contained in the characteristics. The air conditioning controller of claim 1, wherein when the user makes an adjustment to prioritize either the energy saving performance or the comfort level over the other, the prioritization selector applies a higher weighting and selects the control algorithm among the control algorithms. The air conditioning controller of claim 1, wherein the algorithm memory stores each of the control algorithms in conjunction with recommended environmental data, and the predictor uses the control algorithms used to perform the simulation in accordance with a relationship between the environmental data obtained by the environmental data maintainer and the recommended environmental data , limited. An air conditioning control method for controlling an air conditioner installed in a structure, the method comprising: an environment data preservation step for obtaining environmental data of an interior area and an exterior area of the structure; a pre-calculation step of executing, based on the obtained environmental data and structure specific characteristics, a simulation using each of a plurality of types of control algorithms for controlling the air conditioner, and predicting a control result for each of the control algorithms; a selecting step of evaluating each predicted control algorithm based on an energy saving performance and a comfort level, and selecting a control algorithm among the control algorithms; and a control step of controlling the air conditioner based on the selected control algorithm. A program for causing a computer to control an air conditioner installed in a structure to function as: an environment data maintainer configured to obtain environmental data of an interior and exterior of the structure; a predictor configured to simulate using a variety of types of data based on the obtained environmental data and structural characteristics for the structure Execute control algorithms for controlling the air conditioner, and predict a control result for each of the control algorithms; a selector configured to evaluate each predicted control result based on an energy saving performance and a comfort level, and selecting a control algorithm among the control algorithms; and a controller configured to control the air conditioning system based on the selected control algorithm.

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