JP2006336875A - Air-conditioning control system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To match environment evaluation as a result of analysis of air-conditioning report with hot/cool feeling tendency in updated air-conditioning report. <P>SOLUTION: This air-conditioning control system comprises a correction content adjusting means for comparing environment evaluation values of an environment evaluation model constructing an air-conditioning report analyzing means and the updated report, and instructing the correction content to an environment evaluation correcting means, the correction content instructed by the correction content adjusting means to the environment evaluation correcting means is given to make the environment evaluation values of the environment evaluation model constructing the air-conditioning report analyzing means and the updated report be agreed with each other. Further this system comprises an environment evaluating means for calculating a quantitative environment evaluation value on the basis of the environment evaluation model and an environment measurement value, and an environment evaluation displaying means for displaying the environment evaluation values, and the environment evaluation displaying means displays the environment evaluation values calculated by the environment evaluating means. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a control system for an air conditioner.

  As a control method of the air conditioner, the building user in the living room inputs a report on the thermal environment (hereinafter referred to as the air conditioning report), for example, “hot” or “cold” sense, and this is used for the thermal feeling and comfort of the thermal environment Some of them are used for the evaluation of safety (hereinafter referred to as environmental evaluation) and are operated while changing the setting of the air conditioner. As an example, in Japanese Patent No. 3214317, a PPD (Predicted Percentage of Dissatisfied) curve is applied to an air conditioning report as a tendency of thermal sensation of a group to provide the most comfortable environment. In other examples (patents 3214317, H5-322258, and H6-94292 do not describe this as described in Matsubara's earlier application), the air conditioning declaration and the thermal sensation tendency are managed for each individual. From there, the tendency of thermal sensation as a group is derived, so that the comfort evaluation about the group is not dragged to the declaration of a small number of individuals. As described above, there is an example in which the air conditioning control using the air conditioning report is characterized by how the air conditioning report is used when evaluating the environment.

Japanese Patent No. 3214317

  In the method using the air conditioning report, not only the latest report but also the past report is considered and analyzed, and the environment is often evaluated. The reason is that it is intended to perform an environmental evaluation that is closer to the sense of the building user even when the conditions of the thermal environment, such as room temperature, change after the report. However, the problem here is that the environmental evaluation as an analysis result of the air conditioning declaration does not necessarily match the environmental evaluation of the latest air conditioning declaration. If this is the case, it cannot be said that the environmental evaluation accurately captures the sense of the building user, and there is a possibility that the effect expected by the air conditioning control such as “to realize the most comfortable environment” may not be obtained. Although the declaration itself contains errors, it can be considered that it does not match, but when presenting the thermal sensation tendency estimated by the air-conditioning control unit to the building user, the latest air conditioning declaration is immediately after the declaration. If there is a deviation from the building, the building user may not be convinced. There is a demand for a method of using an air conditioning report that matches the estimation result with the actual report and that can accurately analyze the true thermal sensation tendency of the building user.

  FIG. 1 shows a means for realizing the air conditioning control apparatus of the present invention. An air conditioning declaration input means 100 for a building user to input an air conditioning declaration, an environmental measuring means 110 for measuring an environmental state such as a room temperature as a numerical value, and an environmental evaluation model by analyzing the air conditioning declaration from the input air conditioning declaration and the environmental measurement values. The control content planning means 120 for determining the control content of the air conditioner from the result, the air conditioner control execution means 130 for transmitting the control command to the air conditioner and executing the control content, and displaying the environmental evaluation value of the environmental evaluation model And environmental evaluation display means 135. The control content planning means 120 includes an air conditioning declaration recording means 140 that accumulates the past air conditioning declarations and the environmental measurement values at that time as analysis data, and an environmental evaluation correction that corrects the contents of the air conditioning declaration data or the environmental evaluation model. Means 150, air conditioning declaration analysis means 160 for analyzing the air conditioning declaration and constructing an environmental evaluation model for environmental evaluation, comparing the environmental evaluation values of the environmental evaluation model and the latest declaration, Correction content adjustment means 170 for instructing the amount and quantity, control content determination means 180 for concretely determining the control content from the target value of the environmental evaluation value and the environmental evaluation model and creating a control command, the environmental evaluation model and the environmental measurement value And environmental evaluation means 190 for quantitatively performing environmental evaluation.

  Here, the correction content adjusting unit 170 causes the environmental evaluation correction unit 150 to correct the air conditioning declaration data or the environmental evaluation model until the environmental evaluation values of the environmental evaluation model and the latest report are considered to be the same, and the air conditioning declaration analysis is performed. By causing the means 160 to analyze again, the environmental evaluation model and the environmental evaluation value of the latest report coincide with each other, and the control command generation means 180 and the air conditioner control execution means 130 control the air conditioner based on the coincident environmental evaluation value. be able to.

  Further, by displaying the environmental evaluation value of the environmental evaluation means 190 on the environmental evaluation display means 135, the building user can know the environmental evaluation of the air conditioning control device, and the environmental evaluation is consistent with his own environmental evaluation. I can confirm that.

  With this air conditioning control device, in the air conditioning control that uses the result of analyzing the air conditioning declaration, the environmental evaluation by the air conditioning declaration analysis matches the environmental evaluation of the latest air conditioning declaration, so the reporter's feelings can be captured more accurately The air conditioner can be controlled based on the environmental evaluation. In addition, since the reporter is informed of this, the reporter can be satisfied.

  In a building such as an office building, the application of the present invention in a system that reflects the air conditioning declaration of a building user in the control and operation of the air conditioner will be described.

FIG. 2 is a system configuration diagram of this embodiment. Within building 290, BA (Building
Automation) A central monitoring device 210 exists on the network 200. The central monitoring device 210 performs facility monitoring control, and has a facility operation database 215 that records data and measurement values necessary for monitoring control. In addition, an air conditioning controller 230 is connected to the BA network 200 via a field controller 220. Air conditioning indoor units 240a to 240k are installed in the use area 295 of the building 290, and refrigerant is supplied from outdoor air conditioning outdoor units 250a to 250m (not shown in the figure). The air conditioning controller 230, the air conditioning indoor units 240a to 240k, and the air conditioning outdoor units 250a to 250m transmit and receive control signals through the air conditioning control line 202. Here, the air conditioner is assumed to be a packaged air conditioner, but a central heat source type capable of individual air conditioning by VAV (Variable Air Volume) or the like may be used. In the use area 295, PCs (Personal Computers) 260a to 260n used by the building users are installed on a desk or the like and connected to each other by an OA network (intranet) 201. The BA network 200 and the OA network 201 are connected with the central monitoring device 210 as a gateway.

In this system, the central monitoring device 210 receives air conditioning declarations from building users from the PCs 260a to 260n, and air conditioners (air conditioner indoor units 240a to 240k, air conditioner outdoor units 250a to 250a).
250m). Specifically, for example, the start / stop of the air conditioner indoor units 240a to 240k, the set temperature, and the outputs of the air conditioner outdoor units 250a to 250m are determined based on the air conditioner declaration, and a control command is issued to the air conditioner controller 230. The operation results of the air conditioner such as the start / stop state, the set temperature, and the power consumption are recorded in the facility operation database 215, and become a material that takes into account the control contents from the next time.

Software for a building user to make an air conditioning declaration is installed in the PCs 260a to 260n. With this air conditioning declaration software, the user can display the declaration screen shown in FIG.
It can be opened from the start menu of (Operation System). The air conditioning report screen 300 includes an information display area 310, a report area 320, and a position display area 330. In the information display area 310, the user name, the place selection list, the number of times the user reports the air conditioning on that day, the environmental measurement values such as room temperature and humidity (measurement values of the environmental state) are displayed. The items of the location selection list are described as a location name and location ID pair in the setting file of the air conditioning declaration software, and the location name is displayed in the selection list and can be selected by the user. The environmental measurement value is a value acquired on the BA network 200 and is received from the central monitoring device 210. In the reporting area 320, reporting buttons 340a to 340g are arranged, and the whole body warmth and coolness 7-point scales are “very difficult”, “satiful”, “slightly good”, “slightly hot”, “hot”, “very hot”, respectively. Corresponding to −3 to 3. Report button 340a
When 340g is pressed, the personal ID (for example, the air conditioning reporting software serial number and user name), the reporting value (user's environmental evaluation value) based on the whole body thermal sensation 7-point scale, and the location ID as a set are monitored centrally as air conditioning reporting data Transmitted to the device 210. In the position display area 330, a user position display axis 350, an area position display axis 360, and a control target position display axis 370 are displayed. On the user position display axis 350, the air conditioning control software operating in the central monitoring device 210 receives from the central monitoring device 210 a value obtained by receiving the user's air conditioning declaration and estimating the current thermal sensation of the user. A user position display 355 is shown. Similarly, in the area position display axis 360, a plurality of building users (self and other users) who belong to the place where the user is located (selected in the place selection list) and use the air conditioning declaration software are grouped. The thermal sensation is estimated from the air conditioning report and is shown as an area position display 365. On the control target position display axis 370, a control target value planned by the air conditioning control software is shown as a control target position display 375. The user can compare and refer to the three positions. The numerical value of the position may be written together. Since each position fluctuates according to a new air conditioning report or an environmental measurement value, reception from the central monitoring device 210 and redisplay are performed periodically. The air conditioning declaration screen 300 can be closed with a close button 390.

In order to receive an air conditioning report and perform an environmental evaluation from the air conditioning report, the central monitoring apparatus 210 performs the analysis process of FIG. In step 410, the user to be analyzed is specified from the personal ID of the air conditioning report, the past air conditioning reports of the user are collected from the facility operation database 215, and the environmental measurement values (temperature, humidity, wall temperature, etc.) around the user are collected. Is obtained from the BA. Since there are a plurality of environmental measurement points at different locations in BA, a measurement point corresponding to the location ID included in the air conditioning declaration is searched from a table in the facility operation database 215. The newly reported air conditioning declaration data is also recorded in the facility operation database 215. Steps 420 to 460 are repeated a specified number of times. In step 430, the user's environment evaluation model is constructed from the past air conditioning declaration data and the latest air conditioning declaration data. The environmental evaluation model is to quantitatively calculate an environmental evaluation value such as a user's thermal sensation and comfort by inputting an environmental measurement value, or conversely calculate an environmental state value from the environmental evaluation value. In this embodiment, a thermal sensation 7-point scale is used as a scale for environmental evaluation, and a decimal value of −3 to 3 is used as an environmental evaluation value. When obtaining environmental status values from environmental assessment values, if there are multiple types of environmental status values used by the environmental assessment model (for example, two temperatures and humidity instead of one temperature), one type of environmental status to be obtained. Other than the value, processing such as fixing the current measured value is required. In step 435, it is determined whether the construction of the environment evaluation model has been successful. If successful, the process proceeds to step 440, and if unsuccessful, the process proceeds to step 485. In step 440, it is determined whether the environmental evaluation value obtained by giving the environmental measurement value around the user to the environmental evaluation model constructed in step 430 and the environmental evaluation value included in the latest air conditioning report are the same, If they match, the process proceeds to step 470, and if they do not match, the process proceeds to step 450. Here, the criterion for determining whether or not the two values match is that the absolute value of the difference is equal to or less than a prescribed threshold value. In step 450, correction by adjusting the coefficient of the environment evaluation model itself or correction of air conditioning declaration data used for building the environment evaluation model is performed. The correction is performed in the direction in which the difference between the two values compared in step 430 is reduced. If Step 420 to Step 460 are repeated a predetermined number of times and if they do not match at Step 440, the process proceeds to Step 470. In step 470, it is determined whether the number of corrections in step 450 is within a specified upper limit number. If it is within the upper limit, it is determined that the correction is not necessary or the correction is successful, and the process proceeds to step 480, and the one constructed in step 430 is applied to the new environment evaluation model of the user. If it exceeds the upper limit, it is determined that the correction has failed, and the process proceeds to step 485 to take measures when the expected environmental evaluation model is not obtained. In step 490, an environment evaluation model as a group of places to which the user belongs is constructed based on the environment evaluation models of a plurality of users belonging to the same place including the user. The location to which each user belongs is specified by the location ID included in each person's latest air conditioning report. This place ID is registered in the facility operation database 215, and the user can be searched by searching for the place ID.

  When the analysis is completed, the central monitoring device transmits the values of the three positions 355, 365, and 375 to the air conditioning declaration software of the user who has declared the air conditioning and redisplays them. The display of the number of declarations is also updated. Thereby, the thermal sensation input by the user matches the position / numerical value of the user position display 355 that is the thermal sensation of the user estimated by the air conditioning control software. For a certain period of time after redisplay, the position before the declaration may be displayed so that the amount of movement of the position can be known. The user can know that his / her air conditioning report is taken into account by the movement of the user position display 355 before and after the report. Further, the user can know the difference in feeling between the user and the group by comparing the user position display 355 and the area position display 365. Air conditioning control is performed so that the area position matches the control target position, so even if you report air conditioning but it is hot or cold and you feel dissatisfied with air conditioning, find the cause of the difference in how you feel yourself and the group be able to. By comparing the user position display 355 and the control target position display 375, it can be estimated how uncomfortable it is. Further, the user can estimate whether the air-conditioning control is working well and how much the environment will change from now on by comparing the area position display 365 and the control target position display 375.

  The reconstructed user and area environment evaluation model is used for subsequent air conditioning control. That is, the set temperature and start / stop of the air conditioner are controlled so that the environmental evaluation value calculated from the environmental measurement value using the environmental evaluation model matches the control target value. It can also be used when an operation plan is made and a control target value is determined.

  As a method for constructing an environment evaluation model for an individual in step 430 (analysis method for air conditioning declaration), there are linear regression and logit analysis. In linear regression, the environmental measurement value is an explanatory variable and the environmental evaluation value is an objective variable, and a coefficient and an intercept relating to the environmental measurement value are obtained by a least square method. As an explanatory variable, only one type of environmental measurement value such as temperature may be used, or two or more types such as temperature and humidity may be used, or an environmental measurement such as the sensible temperature that is the average value of room temperature and wall temperature. A value processed value may be used. In the logit analysis, a logistic cumulative function (1) is prepared as a probability curve in which an environmental report value i (i = -3, -2, -1, 0, 1, 2) or less is declared. In the air conditioning declaration data, when the environmental declaration value is i or less, the objective variable is 1, and when it exceeds i, the objective variable is 0, and the environmental measurement value is an explanatory variable, and the logit curve is applied by the maximum likelihood method. Furthermore, the expected value of the environmental measurement value is calculated and tabulated in a range of a certain environmental measurement value (when room temperature is used as the environmental measurement value, for example, from room temperature 10 ° C. to 35 ° C. every 1 ° C.). Probit analysis can be performed in the same way as logit analysis. The function (2) taking a value of −3 to 3 can also be applied by regression. There is also a method of learning by back-propagation using a neural network with an environmental measurement value as an explanatory variable and an environmental evaluation value as an objective variable. By constructing the environmental evaluation model as described above, it is possible to convert an environmental measurement value into an environmental evaluation value for each individual or group. If calculation is impossible in each analysis or if the coefficient of determination is small by linear regression, it is determined in step 435 that the model construction has failed. In addition, the standard environment evaluation model is applied to any individual in the initial stage (for example, from the registration procedure to the central monitoring device 210 when the air conditioning reporting software starts to be used until the first air conditioning declaration).

  As a method for constructing the environmental evaluation model relating to the group in step 490, there is a method of taking an average value of environmental evaluation values of a plurality of users within a certain range of environmental measurement values and making a table. When taking a weighted average value, the facility operation database 215 has a weight for each user.

  As an example of the correction method in step 450, there is a method of weighting the latest report. This corresponds to handling one piece of data as input data and making it input data, and can be applied regardless of the construction method of the environment evaluation model. The weight is increased every time correction is repeated.

  Some countermeasure examples of step 485 are shown. As a method for coping with a case where the construction of the environmental evaluation model fails, there is a change of the environmental evaluation model. For example, a straight line / curve that always passes through the corresponding point between the environmental measurement value and the environmental evaluation value of the latest air conditioning declaration, a regression formula using past declaration data, and a pattern (straight line / curve) selected from the latest air conditioning declaration alone Can be applied as an environmental evaluation model. If the number of corrections in step 450 exceeds the upper limit, the environmental assessment model generated in step 430 is used, and the building user's air conditioning declaration screen says “There is a gap in the estimation of thermal sensation.” For example, it is possible to display that there is a difference between the environmental evaluation model and the environmental evaluation value of the latest air conditioning declaration.

  Based on the environmental evaluation model obtained above, after grasping the thermal sensation of building users, a control target value is set for the environmental evaluation value, and the environmental state value corresponding to the control target of the environmental evaluation value is determined from the environmental evaluation model. Air-conditioning control can be performed to realize. Even for one control target value, the equivalent environmental state value differs for each group (location). Note that the correspondence between air conditioners to be controlled and places (groups) is stored in the equipment operation database 215 as a table, and the environment evaluation model used for each air conditioner is selected from this correspondence. The control target value can be determined freely, but the building manager can input it at the central monitoring device 210, or the air conditioning control software can adjust the energy cost for a certain period to be less than the value specified by the building manager. Conceivable.

  The following is a supplement to this embodiment. When the occupancy state is taken by transmitting a signal notifying that the PC is being used from the air conditioning declaration software to the central monitoring device 210, the occupant is in the room when issuing a control command to the air conditioning controller 230. The environmental evaluation model of the group may be reconstructed using only the environmental evaluation model of the existing user. If there is only one user at one place, the estimated position of the individual matches the estimated position of the group.

  The air conditioning declaration data used for construction of the environmental evaluation model may be weighted according to a time series, that is, new declarations. Although the weight becomes smaller as it gets older, the initial value of the weight may be the weight added by the correction in step 450.

When the air conditioning report is made continuously from the same user in a short time, the previous air conditioning report may be replaced with the latest report. This makes it possible to remove the distortion of the environmental evaluation model caused by taking into consideration the previous air conditioning declaration when the wrong feeling is reported and input again. In the case where declarations are continuously made with the same level of thermal sensation, the air conditioning declaration may be replaced by raising the declaration value to one level higher (for example, from “hot” to “very hot”).

As an evaluation index of comfort, PMV (Predicted Mean Vote), SET ^* (Standard
Effective temperature) is generally used, but in the present invention, which scale is used is not the essence of the invention, and any scale may be used. For example, when PMV is used as a comfort index and the correction coefficient of the PMV calculation formula is obtained from the air conditioning declaration, the PMV declaration value is used as an objective variable when the environmental evaluation model is constructed, and the environmental evaluation model calculates PMV from the environmental measurement value. Deserve.

  The system configuration and the content of air conditioning control are almost the same as in the first embodiment. The difference is that the air conditioning declaration screen is as shown in FIG. 5, and the thermal sensation can be reported as a continuous value from -3 to 3 (not an integer value), and in accordance with this, the environmental evaluation model is also set as a continuous environmental evaluation value. It is to handle. Even if it is said to be a continuous value, the computer calculation is a finite value. The construction method of the environmental evaluation model is basically the same as that of the first embodiment.

The configuration of the air conditioning report screen will be described below. The difference from the air conditioning report screen 300 in the air conditioning report screen 500 of FIG. 5 is that the part where the user inputs a thermal sensation is a report area 520. The user moves the report bar 540 by clicking and dragging on the report axis 530 and presses the report execution button 550 to perform an air conditioning report with continuous environmental evaluation values to the central monitoring device 210. On this air conditioning report screen, the user can include a difference in feeling that is finer than in the first embodiment in the report, and the air conditioning control software can also grasp the difference and perform fine air conditioning control.

  Similar to the second embodiment, the air conditioning declaration screen is different from the first embodiment. In addition, since the environmental evaluation value has two axes, two environmental evaluation models are prepared for each axis. Another environmental evaluation value may be calculated using the environmental evaluation values output by the two environmental evaluation models. The environmental evaluation value to be reported is a continuous value as in the second embodiment. The air conditioning report screen allows the user to evaluate the environment from two different aspects and report the air conditioning. Therefore, the air conditioning control software can also capture the user's senses from various perspectives and can use it for air conditioning control.

The configuration of the air conditioning report screen will be described below. In the air conditioning report screen 600 of FIG. 6, the information display area 310 and the close button 390 are the same as those of the air conditioning report screen 300. The difference is that portions corresponding to the reporting area 320 and the position display area 330 are grouped in the reporting area 620. Further, environmental evaluation has two axes, a temperature report axis 640 related to temperature and a humidity report axis 650 related to humidity. In the report input / display area 625, contour lines relating to another environmental evaluation value obtained from the environmental evaluation value from the temperature and the environmental evaluation value from the humidity are displayed as the iso-comfort line 690. Has helped. The meanings of the user position display 660, area position display 670, and control target position display 680 are the same as the user position display 355, area position display 365, and control target position display 375. The user position input display 665 is a part for the user to specify his / her feeling, and overlaps with the user position display 660 when the air conditioning report screen is opened or immediately after the report. When the user clicks and drags this or moves it within the report input / display area 625 by clicking one point in the report input / display area 625, and then presses the report execution button 630, the air conditioning report is made. . The positions of the temperature report bar 645 on the temperature report axis 640 and the humidity report bar 655 on the humidity report axis 650 are linked to the position of the user position input display 665, and move between the temperature report bar 645 and the humidity report bar 655. As a result, the user position input display 665 can be moved.

  The air conditioning declaration screen shown in the above embodiment may be realized not only as software operating on the PC but also by hardware such as a remote controller.

  Similar to the second embodiment, the air conditioning declaration screen is different from the first embodiment. The display method of the user position / area position / control target position is different from the first embodiment. The display of the user position and the area position continuously shows not only one current thermal sensation but also a thermal sensation tendency with respect to room temperature.

  The configuration of the air conditioning report screen will be described below. In the air conditioning report screen 700 of FIG. 6, the information display area 310, the report area 320, and the close button 390 are the same as those of the air conditioning report screen 300. The position display area 730 includes a user position display axis 750 and an area position display axis 760. These display axes do not display only one value of the thermal sensation with respect to the current room temperature as in the first embodiment, but continuously indicate the thermal sensation tendency with respect to the room temperature. It is not a feeling but room temperature. On the user position display axis 750, a user position display 755 is shown. The user position display 755 is a belt-like display corresponding to the whole body thermal sensation 7-point scale, the left end corresponds to “very cold”, the right end corresponds to “very hot”, and the center corresponds to “just good” Based on the result estimated by the environmental evaluation means 190 from the air conditioning report, it is made to correspond to the room temperature. The room temperature marker 780 is the current room temperature, and the user position display 755 at this position matches the content of the latest air conditioning report.

  Similarly to the user position display axis 750, an area position display axis 765 and a room temperature marker 785 are also displayed on the area position display axis 760. On the area position display 765, a control target position 775 is shown. The air conditioning control software adjusts the set temperature of the air conditioner in each area so that the room temperature matches the control target position. That is, the room temperature corresponding to the control target position is set as the set temperature. FIG. 7 shows another example of the air conditioning report screen.

  It can be incorporated into controllers and building management systems that control air conditioners.

Means for realizing the air conditioning control device. System Configuration. The air-conditioning report screen of Example 1. Air conditioning declaration analysis process flow. The air-conditioning report screen of Example 2. The air-conditioning report screen of Example 3. Another example of the air conditioning declaration screen.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 ... Air-conditioning report input means, 110 ... Environmental measurement means, 120 ... Control content planning means, 130 ... Air-conditioner control execution means, 135 ... Environmental evaluation display means, 140 ... Air-conditioning report recording means, 150 ... Environmental evaluation correction means, 160 ... Air conditioning declaration analysis means, 170 ... Correction amount content adjustment means, 180 ... Control command generation means, 190 ... Environmental evaluation means, 200 ... BA network, 201 ... OA network (intranet), 202 ... Air conditioning control line, 210 ... Central monitoring Apparatus, 215 ... Equipment operation database, 220 ... Field controller, 230 ... Air conditioning controller, 240a-240k ... Air conditioning indoor unit, 250a-250m ... Air conditioning outdoor unit, 260a-
260n ... Personal computer, 290 ... Building, 295 ... Usage area, 300, 500, 600 ... Air conditioning report screen, 310 ... Information display area, 320, 520, 620 ... Report area, 330 ... Position display area, 340a to 340g ... Report Button 350, user position display axis, 355, 660, user position display, 360, area position display axis, 365, 670, area position display, 370, control target position display axis, 375, 680, control target position display, 390 ... Close button, 410 to 490 ... Air conditioning report analysis processing procedure, 530 ... Report axis, 540 ... Report bar, 550 ... Report execution button, 625 ... Report input / display area, 630 ... Report execution button, 640 ... Temperature report axis, 645 ... Temperature reporting bar, 650 ... Humidity reporting axis 655 ... humidity declaration bar, 665 ... user position input display, 690 ... etc comfortable line.

Claims (5)

  An air conditioning declaration input means for the facility user to input an air conditioning declaration, an environmental measurement means for measuring an environmental state such as a room temperature as a numerical value, an air conditioning declaration input from the air conditioning declaration input means, and an environment obtained from the environmental measurement means An air conditioning declaration recording means for recording measured values, an air conditioning declaration analyzing means for constructing an environmental evaluation model from the air conditioning declaration and the environmental measurement values recorded in the air conditioning declaration recording means, and an environmental evaluation correction for correcting the environmental evaluation model And a correction content adjustment unit that compares the environmental evaluation values of the environmental evaluation model constructed by the air conditioning declaration analysis unit and the latest report, and instructs the environmental evaluation correction unit of the correction content, and the correction content adjustment unit The correction content instructed to the environmental evaluation correction means is to match the environmental evaluation values of the environmental evaluation model constructed by the air conditioning declaration analysis means and the latest declaration. Air-conditioner control system.   2. The air conditioner control system according to claim 1, further comprising: control content determining means for determining control content for the air conditioner; and control content display means for displaying the control content of the control content determining means. Is an air conditioner control system that determines control contents from an environmental evaluation model constructed by the environmental evaluation means and a control target value.   3. The air conditioning control system according to claim 2, further comprising air conditioner control execution means for executing monitoring control of the air conditioner, wherein the air conditioner control execution means executes the control content instructed by the control content planning means. Air conditioner control system.   2. The air conditioning control system according to claim 1, further comprising: an environmental evaluation unit that calculates a quantitative environmental evaluation value from the environmental evaluation model and the environmental measurement value; and an environmental evaluation display unit that displays the environmental evaluation value. The air conditioner control system, wherein the evaluation display means displays an environmental evaluation value calculated by the environmental evaluation means. An air conditioning declaration input means for the facility user to input an air conditioning declaration, an environmental measurement means for measuring an environmental state such as a room temperature as a numerical value, an air conditioning declaration input from the air conditioning declaration input means, and an environment obtained from the environmental measurement means An air conditioning declaration recording means for recording measured values, an air conditioning declaration analyzing means for constructing an environmental evaluation model from the air conditioning declaration recorded in the air conditioning declaration recording means and the environmental measurement values, the environmental evaluation model, and the environmental measurement values Environmental evaluation means for calculating a quantitative environmental evaluation value from the above, and environmental evaluation display means for displaying the environmental evaluation value, wherein the environmental evaluation value display means is an environment for each individual calculated from the environmental evaluation model. Displaying at least two of the evaluation value, the environmental evaluation value for each group calculated from the environmental evaluation model, and the control target value of the environmental evaluation value in air conditioning control Air conditioning control system according to claim.

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