JP2005273981A - Air conditioning system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an air conditioning system with air conditioning devices for actualizing fatigue recovery in his life each day and long-term physical condition improvement of a user himself. <P>SOLUTION: The air conditioning system comprises a control device 102 for receiving measurement data and state data output from a skin condition detecting device 101 for measuring and diagnosing the skin condition of the user and for outputting air conditioning recipe data corresponding to the measurement data and the state data, and the air conditioning devices 103-106 for receiving the air conditioning recipe data output from the control device 102 and conditioning air in accordance with the contents of the air conditioning recipe data. The user puts his skin in contact with the skin condition detecting device 101 and the data is transmitted to the control device 102, and the control device 102 creates the air conditioning recipe data in accordance with the state data of the user and transmits it to the air conditioning devices 103, 104. Thus, the physical condition of the user is accurately seized and air is conditioned to recover the physical condition. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a technique for actually measuring a human physiological state, particularly a skin state, and controlling an air conditioning device based on the actually measured skin state.

  In recent years, various improvements have been made to air conditioning equipment, and multifunctional devices that not only maintain a comfortable temperature but also perform operations with careful considerations such as humidity and wind power have become widespread. However, these have not led to driving with consideration of ecological information such as the user's sweating, hot flashing, and dryness.

  Therefore, a conventional air conditioning system has been proposed that performs appropriate air conditioning control by adding the air conditioning user's physiological state that changes according to the air conditioning environment to the criteria for air conditioning control (for example, Patent Document 1). FIG. 13 shows a conventional air conditioning system described in Patent Document 1. In FIG.

In FIG. 13, a mouse 1001 measures a physiological amount such as a user's body temperature and sweat, and a work environment such as air temperature and humidity, and a computer 1005 measures a physiological amount measured by the mouse 1001 and a measured value of the work environment. Is transmitted from the processing unit 1006 to the management computer 1008 via the interface unit 1007. In the management computer 1008, the interface unit 1009 receives the user's physiological quantity and the reported temperature, and calculates The unit 1010 re-evaluates the reported temperature, which is a psychological requirement of the user, from the viewpoint of physiological quantity, determines the control content of the air adjustment unit 1011, and actually controls the air adjustment unit 1011.
Japanese Patent Laying-Open No. 2003-42508 (page 14, FIG. 1)

  However, in the conventional configuration, the air conditioning control considering the user's physiological quantity is realized, but the user's work environment in the situation where the user works in the same space for a certain continuous time. In order to collect data at a specific location, it is not necessarily aimed at recovering fatigue in the user's own daily life or improving physical condition from a long-term perspective. It wasn't.

  The present invention solves the above-mentioned conventional problems, and grasps the physical condition in the life of the user of the air conditioner with physiological data, mainly data obtained from the skin, and aims to recover the physical condition from a long-term viewpoint. An object of the present invention is to provide an air conditioning system that realizes control of air conditioning equipment.

  In order to solve the conventional problems, the control device of the present invention includes measurement data indicating a result of measuring a physiological state including a skin condition of the user, and a result of measuring an air environment such as temperature and humidity. An air environment data to indicate, and state data indicating a result of diagnosing the skin condition, an interface unit for transmitting air adjustment recipe data indicating the operation content of each air conditioning device, and the measurement data received by the interface unit, Air condition data, a condition accumulating unit for accumulating condition data, and air adjustment recipe data composed of at least one or more parameters related to air adjustment corresponding to the condition data based on the measurement data, the air environment data, and the condition data And refer to the past state data stored in the state storage unit, and select the parameters that were in a worse state than the latest state data. A parameter determining unit that changes the parameter of the air adjustment recipe data corresponding to the deteriorated parameter by a predetermined value, determines the official air adjustment recipe data, and outputs it to the interface unit Features.

  This configuration does not collect the physiological state of the user at a specific location and performs air adjustment suitable for it, but does not take into account the location, and the air adjustment content considering the previous user's state Therefore, it is possible to adjust the comfortable air to improve the fatigue in the life of the user himself / herself and to improve the physical condition from a long-term viewpoint.

  Further, the control device of the present invention holds a table in which at least one parameter in the air adjustment recipe data is associated with a function held by at least one air adjustment device in the recipe determination unit, Referring to the table, search for an air conditioner that holds a function corresponding to each item of the air conditioner recipe data, select an air conditioner to be used for air adjustment, and for each of the selected air conditioners The air conditioning recipe data is created.

  With this configuration, when the recipe determination unit determines the air adjustment recipe data, the air adjustment necessary for realizing the optimum air adjustment for the user from at least one or more air adjustment devices existing in the house By selecting the device, it is possible to perform fine control that is much more optimal for the skin condition than the user himself / herself, and more efficient operation is possible.

  In addition, the control device of the present invention includes a state monitoring unit that monitors the state of each of at least one or more air conditioning devices, and after creating the air conditioning recipe data for the selected air conditioning device, in the state monitoring unit A recipe that does not output the air adjustment recipe data when the current operation status of the selected air conditioner is referred to and the air adjustment recipe data has the same contents as the current operation status of the selected air conditioner. And a determination unit.

  With this configuration, when the recipe determination unit determines the air conditioning recipe data, the current state of at least one or more air conditioning devices existing in the house is referred to and the operation with the same content as the air conditioning recipe data has already been performed. In such a case, transmission of the air conditioning recipe data is stopped, so that transmission of duplicate contents can be avoided, and more efficient operation can be realized.

  The control device according to the present invention may be configured such that when the recipe determination unit stores the state data in the state storage unit, it is compared with the past state data that has already been stored, and is in a best state for the user. For example, when information indicating that the condition is the best condition is added to the state data and the state data better than the state data to which the best condition information is added is stored, the best condition information is updated and the state data is updated. In addition, the history of the generated air conditioning recipe data is recorded, and after the air conditioning recipe data is generated, the best condition information is added from the history of the generated air conditioning recipe data. Search for the air conditioning recipe data generated near the date and time of the status data, and select the best condition Based on the content of the air conditioning recipe data were derived emissions over changes to the air conditioning recipe data, and determines the formal air conditioning recipe data.

  With this configuration, it becomes possible to store and indicate the best condition in the long-term past data of the user, and the user can grasp his / her state and obtain useful information. In addition, the air adjustment that restores the user's best condition is achieved, so that the air can be adjusted more personally and at the same time the air can be recovered more quickly by the user. be able to. Furthermore, since it is possible to refer to the record of the output air conditioning recipe data, it is possible to analyze whether the generated recipe is a recipe that suits the user and to adjust the air more suitable for the user. Can do.

  In addition, the air conditioning system of the present invention includes measurement data indicating a result of measuring a physiological state including a user's skin state, air environment data indicating a result of measuring an air environment such as temperature and humidity, An interface unit that receives state data indicating the result of diagnosing the skin condition and transmits air adjustment recipe data indicating the operation content of each air conditioning device, the measurement data received by the interface unit, the air environment data, A state accumulation unit for accumulating the state data; and an air adjustment recipe including at least one parameter related to air adjustment corresponding to the state data based on the measurement data, the air environment data, and the state data Data is generated, and the previous state data stored in the state storage unit is referred to, and the state is worse than the latest state data. A parameter is detected, the parameter of the air adjustment recipe data corresponding to the deteriorated parameter is changed by a predetermined value, formal air adjustment recipe data is determined, and the air adjustment recipe data is sent to the interface unit A control device having a recipe determining unit for outputting, a skin state measuring unit for measuring the state of the epidermis and the amount of moisture in contact with the skin, and outputting as measurement data, and the skin state measuring unit is operated Measuring the air environment, such as temperature and humidity, and outputting as air environment data, the measurement data output from the skin condition measurement unit, and the air environment output from the environment measurement unit A symptom diagnosis unit that outputs state data obtained by diagnosing a user's skin state from the data together with the measurement data and the air environment data, and the measurement Output from the symptom diagnosis unit, an interface unit for transmitting the measurement data, the air environment data, and the state data to the control device. The measurement data, the air environment data, and the state data are stored in the state storage unit, and the measurement data, the air environment data, and the state data are transmitted to the control device via the interface unit. A skin condition detection device comprising: a unit, an interface unit that receives air conditioning recipe data from the control device, and transmits data relating to a current state to the control device; and from the control device via the interface unit A control for controlling the air adjustment according to the received air adjustment recipe data. And an air conditioner equipped with a control unit.

  This configuration generates air adjustment contents that take into account the current and past user conditions, regardless of the location, and selects the air adjustment equipment required to achieve the optimum air adjustment for the user. Therefore, it is possible to adjust the comfortable air to recover the fatigue of the user's own daily life and improve the physical condition from a long-term viewpoint. In addition, it is far more optimal for skin conditions than the user himself / herself, and fine control can be performed, and more efficient driving is possible. And it becomes possible to memorize | store and show the best condition in a user's long-term past data, a user's state can be grasped | ascertained and useful information can be obtained. In addition, the air adjustment that restores the user's best condition is achieved, so that the air can be adjusted more personally and at the same time the air can be recovered more quickly by the user. be able to. Furthermore, since it is possible to refer to the record of the output air conditioning recipe data, it is possible to analyze whether the generated recipe is a recipe that suits the user and to adjust the air more suitable for the user. Can do.

  According to the air conditioning system of the present invention, it is possible to provide a system that collects a user's physiological state and reflects it in the air conditioning without being bound by the place, considering the current and past user states. Air conditioning recipe data showing the operation details of the air conditioning device is generated, and the air conditioning equipment necessary for realizing the optimum air conditioning for the user is selected and operated. Comfortable air adjustment can be performed to improve fatigue in life and improve physical condition from a long-term perspective. In addition, it is far more optimal for skin conditions than the user himself / herself, and fine control can be performed, and more efficient driving is possible. And it becomes possible to memorize | store and show the best condition in a user's long-term past data, a user's state can be grasped | ascertained and useful information can be obtained. In addition, the air adjustment that restores the user's best condition is achieved, so that the air can be adjusted more personally and at the same time the air can be recovered more quickly by the user. be able to. Furthermore, since it is possible to refer to the record of the output air conditioning recipe data, it is possible to analyze whether the generated recipe is a recipe that suits the user and to adjust the air more suitable for the user. Can do.

  Embodiments of the present invention will be described below with reference to the drawings.

(Embodiment 1)
FIG. 1 is a plan view schematically showing an example of a usage situation of the air conditioning system according to Embodiment 1 of the present invention.

  In FIG. 1, reference numeral 101 denotes a skin condition detection device that detects the skin condition of the user of the air conditioning system and measures the air environment at that time, and 102 denotes the user from the skin condition detection device 101. A control device that receives skin measurement data, state data, and air environment data and determines a recipe for air conditioning. 103 to 106 are air conditioning devices that are operated and controlled according to the recipe output from the control device 102. It is.

  FIG. 2 is a block diagram showing in detail the configuration of the air conditioning system according to Embodiment 1 of the present invention.

  In FIG. 2, a skin condition detection apparatus 101 is brought into contact with the skin to measure a skin condition measuring unit 201 that measures the condition of the epidermis and the amount of moisture, a symptom diagnosis unit 202 that diagnoses skin symptoms, and a data flow The control unit 203 includes a state storage unit 204 that stores data, an environment measurement unit 205 that measures an air environment such as air temperature and humidity, and an interface unit 206 that transmits data. It includes a recipe determination unit 207 that generates air adjustment recipe data indicating the operation content of the vehicle, an interface unit 208 that transmits and receives data, a state storage unit 209 that stores data, and a state monitoring unit 210 that monitors the operation status of the air conditioning apparatus. Is done. The air conditioner 103 includes an interface unit 211 that transmits and receives data, a control unit 212 that adjusts air, and an output unit 213 that operates in accordance with instructions from the control unit 212. The air conditioner 104 includes the air conditioner 103 and the air conditioner 103. Similarly, it includes an interface unit 214 that transmits and receives data, a control unit 215 that adjusts air, and an output unit 216 that operates according to instructions from the control unit 215.

  When the user goes outside, the skin state detection device 101 is brought into contact with the skin (the number and frequency of the operation may vary depending on the user). In the skin state detection device 101, the skin state measurement unit 201 measures the skin condition of the user, adds the date and time to the measurement data, and outputs the result to the symptom diagnosis unit 202. On the other hand, the environment measuring unit 205 measures the air environment such as temperature and humidity when the skin condition of the user is measured by the skin condition measuring unit 201, and outputs it to the symptom diagnosing unit 202. When the measurement data and the air environment data are input, the symptom diagnosis unit 202 diagnoses the user's current skin condition from the data, and controls the condition data together with the measurement data and the air environment data as basic data. The data is output to the unit 203. When the state data, the measurement data, and the air environment data are input from the symptom diagnosis unit 202, the control unit 203 stores them in the state storage unit 204. When the user transmits stored data from the skin condition detection device 101 to the control device 102 at home, the control unit 203 stores the state data and measurement stored in the state storage unit 204. Data and air environment data are transmitted to the control device 102 via the interface unit 206.

  When the control device 102 receives the state data, the measurement data, and the air environment data from the skin state detection device 101 via the interface unit 208, the recipe determination unit 207 reads the data accumulated so far in the state storage unit 209. Referring to the comparison, the current state of the air conditioners 103 and 104 in the state monitoring unit 210 is grasped, and the operation contents of the air conditioners 103 and 104 that match the user's condition data are generated, and the air It transmits to the air conditioners 103 and 104 through the interface unit 208 as air adjustment recipe data indicating the operation contents of the adjusters 103 and 104. Then, the received state data, measurement data, and air environment data are stored in the state storage unit 209.

  When the air conditioning apparatuses 103 and 104 receive the air conditioning recipe data from the control device 102 via the interface units 211 and 214, the air conditioning apparatus 103 has the control unit 212, and the air conditioning apparatus 104 has the control unit 215. The output units 213 and 216 are controlled in accordance with the air adjustment recipe data. Needless to say, the air conditioners 105 and 106 perform the same operation as the air conditioners 103 and 104.

  FIG. 3A is a diagram showing measurement data collected by the skin condition measurement unit 201 and air environment data collected by the environment measurement unit 205, and FIG. 3B is diagnosed by the symptom diagnosis unit 202. It is a figure which shows the state data.

  In the skin condition detection apparatus 101, when the measurement data and air environment data shown in FIG. 3A are input from the skin condition measurement unit 201 and the environment measurement unit 205, the symptom diagnosis unit 202 receives [epidermis] and [moisture]. , [Blood flow], [fibrous tissue], [sebum] data and the air environment at that time, [temperature], [humidity] data, based on the theory about general skin, the user's time Diagnose your skin condition. The general theory of the skin is that the epidermis is rough, it is highly sensitive to skin irritation, or it is weak to dryness, and because the fibrous tissue is disturbed, it is highly sensitive to ultraviolet rays. , Refers to specialized knowledge about the skin. Here, as a result of diagnosis based on the general theory from the measurement data shown in FIG. 3 (a), as shown in FIG. 3 (b), it is an evaluation item as to whether it depends on physical condition or season. [Physical condition / season-dependent type] is an evaluation item for level 3 and whether or not it is sensitive to ultraviolet rays. [Ultraviolet sensitive type] is level 3, sensitive to skin irritation like sensitive skin. [Skin irritation high sensitivity type] is an evaluation item for whether or not the skin is strong. Level 4 is an evaluation item for whether or not it is dry. [Dry type] is for level 3, whether or not allergic symptoms have occurred. The evaluation item [Allergy type] is Level 1, and the evaluation item is whether the sensitivity to physical stimuli such as wind and dust is strong. [Physical stimulus high sensitivity type] results in Level 3. It has been.

  Below, a user who is working outside on a windy and very cold day feels discomfort around his face and measures the skin condition with the skin condition detection device 101 about twice in between work. When the air conditioner such as an air conditioner is operated after returning home, the recipe determining unit 207 measures the skin condition with the skin condition detecting device 101 again and transmits data to the control device 102. The flow until data is determined will be described in detail with reference to the drawings.

  FIG. 3A and FIG. 3B are diagrams illustrating measurement data, air environment data, and state data after the user returns home.

  4 (a), 4 (b), FIG. 5 (a), and FIG. 5 (b) are measurements transmitted from the skin condition detection device 101 to the control device 102 and measured by the user outdoors. FIG. 4 is a diagram showing data, air environment data, and state data. FIG. 4 is a diagram at 12:03 on the same day, and FIG. 5 is a diagram at 16:45 on the same day.

  The recipe determination unit 207 in the control device 102 is the state data of FIG. 4B and FIG. 5B collected outdoors from the skin state detection device 101 via the interface unit 208, FIG. 4A. When the measurement data and air environment data of FIG. 5 (a), the state data of FIG. 3 (b) collected after returning home, and the measurement data and air environment data of FIG. 3 (a) are received, Data FIG. 4 (a), FIG. 4 (b), FIG. 5 (a), and FIG. 5 (b) are stored in the state storage unit 209, and the air conditioners 103 and 104 are obtained from only the state data of FIG. The air adjustment recipe data which is the operation content of is generated.

  The recipe determination unit 207 holds in advance six air adjustment recipe data items associated with the six evaluation items in the state data FIG. 3B diagnosed by the symptom diagnosis unit 202.

  FIG. 6 is a diagram showing air adjustment recipe data generated by the recipe determination unit 207 corresponding to the state data of FIG.

  In FIG. 6, first, with respect to [physical condition / seasonally dependent type], which is an evaluation item of the state data of FIG. 3B, oxygen is sufficiently taken into the body and impurities in the body are sufficiently discharged to recover the physical condition. [Oxygen] in the sense of aiming to reduce the amount of active oxygen generated in the dermis by exposure to ultraviolet rays [antioxidant component] For [Skin irritation sensitive type], it is an item called [Negative ion] in the sense of taking negative ions into the body and improving aging skin sensitive to skin irritation. ] Is an item called [Humidity] in the sense that drying is prevented by optimizing the humidity. For [Allergic Type], dust and allergens that are the main cause of allergies are removed. In the sense, [anti-dust-allergue For [Physical stimulation high sensitivity type], the item is [Fine wind] in the sense that the skin sensitive to physical stimulation is not damaged by wind, etc., and each of these six items has a level value. Fits and constitutes air conditioning recipe data. The level values in the six items reflect the level values in the state data FIG. 3B as they are.

  When the recipe determination unit 207 generates the air adjustment recipe data in the flow as described above, the state data of the outdoor user stored in the state storage unit 209 is shown in FIGS. 4B and 5B. Refer to and evaluate the air conditioning recipe data once generated.

  FIG. 7 is a flowchart showing a flow until the recipe determination unit 207 evaluates the generated air conditioning recipe data by comparing it with outdoor data and determines it as formal air conditioning recipe data.

  In FIG. 7, when the recipe determination unit 207 generates the air adjustment recipe data FIG. 6 (S1), first, the state data stored in the state storage unit 209 is referred to FIG. 4 (b) and FIG. 5 (b). (S2). Next, the level value in each evaluation item in FIG. 4 (b) and FIG. 5 (b) referred to and the level value in each item in the air adjustment recipe data FIG. 6 are compared to determine whether there is a difference. (S3). Here, if there is a difference, the magnitude of the difference is investigated, and it is determined whether or not the difference is equal to or higher than a predetermined level (for example, level 1 in the worsening direction) (S4). If there is no difference, the air adjustment recipe data FIG. 6 is determined as a formal recipe as it is (S6). If the level of difference is 1 or more in the worsening direction, in the air adjustment recipe data FIG. 6, the item whose level of difference is 1 or more in the worsening direction is corrected to a degree corresponding to that level (S5). The corrected air adjustment recipe data is determined as a formal recipe (S6), and if the level of difference is less than 1 or if it is 1 or more in the improvement direction, the formal air adjustment is performed without modification. The recipe data is determined (S6). In the case of the air conditioning recipe data FIG. 6, as a result of comparison with FIGS. 4 and 5, the level values of “dry type”, “ultraviolet sensitive type”, and “skin sensitive high sensitive type” are deteriorated by 1 or more. Therefore, the air conditioning recipe data FIG. 6 is changed to [humidity] for [dry type], [antioxidant component] for [ultraviolet sensitive type], and [negative ion] level for [skin sensitive high sensitive type]. It is corrected to the official air conditioning recipe data.

  FIG. 8 is a diagram showing the formal air conditioning recipe data after correction.

  As shown in FIG. 8, the recipe determination unit 207 has two levels for the “humidity” item, the “antioxidant component”, and the “skin irritation high sensitivity type” items from the level values in the air conditioning recipe data FIG. 6. Increase the level by one.

  Here, in the recipe determination unit 207, the item having the highest level value of each of the six evaluation items is extracted from the state data stored in the state storage unit 209, and air adjustment recipe data is created by combining them. However, when this method is adopted, the level value indicating the worst state so far is the level of each item of the air conditioning recipe data regardless of the current user state data. If the current user's condition has been recovered slightly, there is a risk of excessive care being given to the user. Therefore, as described above, once the air conditioning recipe data is created from the current user state data, the evaluation items that have been in a bad state are extracted from there and correspond to the evaluation items. By applying a correction to the air conditioning recipe data items by a predetermined level value, care can be taken with an intermediate value between the worst state and the current state, making it the optimal air conditioning recipe for the user. Data can be generated.

  The recipe determination unit 207 grasps in advance which one of the air conditioning devices in the house is necessary in order to actually realize each of the six items of the air conditioning recipe data. Based on the determined air conditioning recipe data FIG. 8, the air conditioning device to be used is selected.

  FIG. 9 is a diagram showing a table in which the functions held by each of the plurality of air conditioners and the six items of the air conditioner recipe data are referred to when the recipe determining unit 207 selects the air conditioner. is there.

  When the air adjustment recipe data is determined, the recipe determination unit 207 refers to the table FIG. 9 that is held in advance, and searches for which air conditioner each item of the air adjustment recipe data relates to. . After searching, it is confirmed that the level value of each item of the air conditioning recipe data falls within the range of the level value described in the table, and if so, the air conditioning device that holds the function for that item is Selected. If it does not fall within the range of level values, the search continues until a matching item is found.

  FIG. 10 is a flowchart showing a flow from when the recipe determination unit 207 determines the air adjustment recipe data until the air adjustment device is selected and the air adjustment recipe data is output to the air adjustment device.

  In FIG. 10, the recipe determination unit 207 first investigates whether or not the six items in the air adjustment recipe data FIG. 8 are equal to or higher than a predetermined level value (S7 to S9). Here, a predetermined level value is assumed to be level 2. In each item, if the level value is level 2 or more, an air conditioning device having a function corresponding to the item is extracted and determined with reference to FIG. 9 (S10). Then, based on the output level corresponding to the level value of the item of the air adjustment recipe data, the output level to the corresponding air adjustment device is determined (S11). Here, when the level value of the air adjustment recipe data is not equal to or higher than level 2, it is determined that the air adjustment device having the function corresponding to the item is not sufficient for use, and the unnecessary air adjustment device is referred to as the unnecessary air adjustment device. Does not output air conditioning recipe data (S14). When the output level to the adopted air conditioner is determined, first, the state monitoring unit 210 is accessed, and the current condition of the corresponding air conditioner is confirmed (S12). Adjustment recipe data is output (S13). In the state monitoring unit 210, if the corresponding air conditioner has already been activated at the same level as the determined output level, the air conditioner recipe data is not output to the air conditioner. (S14). Air conditioning recipe data According to Fig. 8, the level of each item is only 2 [anti-dust / allergen], so the air conditioner 105 having a function corresponding to [anti-dust / allergen] is adopted this time The air adjustment recipe data is not output to the air adjustment device 105. On the other hand, in the remaining five items, since the level is 2 or more, the air conditioner 103 having a function corresponding to [oxygen] and [antioxidant component], and a function corresponding to [negative ion] and [humidity] are provided. The output level is determined for the air conditioner 104 and the air conditioner 106 having a function corresponding to [breeze], and after referring to the state monitoring unit 210, the current level is not the same output level, respectively. The air conditioning recipe data is output to the air conditioning device (here, the state monitoring unit 210 obtains data on the current state for each of the plurality of air conditioning devices at a predetermined interval. , Update every time.)

  In the above description, the item “temperature” is not provided in the six items of the air adjustment recipe data. However, the recipe determination unit 207 has a temperature comfortable for the user in advance (for example, 27 in summer). It keeps the concept that it is set to around ℃ and around 20 ℃ in winter, referring to the outside air temperature, and the state monitoring unit 210 always monitors whether it is a comfortable temperature and always aims at a comfortable temperature Separately, air conditioning recipe data is generated and output to the corresponding air conditioning device in the same manner as other air conditioning recipe data. Therefore, only the air conditioning recipe data related to temperature is generated at certain intervals regardless of whether the user measures skin condition or not, and is output to the corresponding air conditioning device to maintain a comfortable temperature. doing.

  When the air conditioning apparatus 103 receives the air conditioning recipe data from the control device 102 via the interface unit 211, the control unit 212 controls the output unit to realize the contents of the air conditioning recipe data. In addition, a plurality of air conditioners perform the same operation as the air conditioner 103 and perform their respective roles.

  According to this configuration, the recipe determination unit 207 collects the physiological state of the user at a specific location and does not perform air adjustment suitable for the user, but adjusts the air in consideration of the previous user state. Since the content is generated, it will provide a system that collects the user's physiological state and reflects it in the air conditioning without being bound by the place. It is possible to adjust the air comfortably so as to improve the physical condition from a natural viewpoint.

  Further, according to such a configuration, the recipe determination unit 207 selects an air conditioner necessary for realizing the air conditioner recipe data from a plurality of air conditioners present in the house, for example, [physical Stimulus Sensitive Type]-The user who is level 5 sensuously or customarily activates an air conditioner that is an air conditioner after returning home, the recipe determination unit 207 displays the air conditioning recipe data as [ ]-Level 5 is determined, so air conditioner operation that may cause wind irritation is stopped, and air conditioning recipe data is output to the radiant heater, which is an air conditioner corresponding to [Fine Wind] As a result, it is far more optimal for skin conditions than the user himself / herself, and fine control can be performed, and more efficient driving is possible.

  In the present embodiment, the measurement data measured by the skin condition detection device 101 and the contents of the air environment data are specified and described. However, any other data that can be collected as physiological data for the user can be used. For example, diagnosis of symptoms using the data may be performed. Further, in the above description, the state data, which is the result of diagnosis by the symptom diagnosis unit 202, is described by specifying the contents of the six evaluation items. However, if the result is diagnosed from the collected measurement data and air environment data, Any shape is acceptable.

  In the present embodiment, it has been described that the recipe determination unit 207 holds in advance six items corresponding to the evaluation items of the state data, but a plurality of air conditioners as shown in FIG. It may be determined by extracting items that are deeply related to the items of the state data from the table in which the functions and the items of the air conditioning recipe data are associated with each other. Further, in the above description, the level value of the evaluation item of the state data is reflected as it is in the level value, but it may be determined according to some rule.

  In the present embodiment, since the recipe determination unit 207 performs selection of the air conditioning device in order to realize the optimum operation, the air conditioning recipe data is generated in consideration of energy saving, without starting the equipment wastefully. You may make it do.

  In the present embodiment, it is assumed that the user transmits data from the skin condition detection device 101 to the control device 102 after returning home, but the interface units 206 and 208 transmit and receive via the Internet network. You can go. Even if the user makes a timer reservation for the air conditioning device in advance, if the data is transmitted from the skin condition detection device 101 to the control device 102 outdoors, the recipe determination unit 207 performs air adjustment according to the timer time. Adjustment recipe data is generated, and when the user returns home, air adjustment that is optimal for the user's condition may already be performed.

(Embodiment 2)
A second embodiment of the present invention will be described with reference to the drawings used in the first embodiment.

  In FIG. 2, the recipe determination unit 207 compares the state data output from the skin state detection device 101 with the state data stored in the state storage unit 209 and determines whether the state is the best state for the user. The best condition information is added and stored in the best state data. The recipe determination unit 207 keeps a history of the date and time each time the air adjustment recipe data is output.

  The recipe determination unit 207 determines air adjustment recipe data based on the state data in the same manner as in the first embodiment, and then refers to the state data to which the best condition information stored in the state storage unit 209 is added. To do. Then, the air conditioning recipe data output immediately before the date of the best condition information is searched and extracted from the air conditioning recipe data history recorded so far. Thereafter, the content of the air adjustment recipe data history is reflected on the once generated air adjustment recipe data, and final air adjustment recipe data is determined.

  In general, the recipe determination unit holds information on the conditions of good skin (in this case, the level value for the evaluation item), and the user's condition is determined accordingly. Determine if is the best.

  The present embodiment will be specifically described below on the assumption that the best state data of the user up to now is diagnosed at 10:20 on Saturday, November 15, 2003.

  FIG. 11A is a diagram illustrating the status data of the user who is determined to be in the best state, and FIG. 11B is a diagram illustrating the air adjustment recipe data output immediately before the best status. It is.

  When the recipe determination unit 207 determines the air adjustment recipe data for each of the plurality of air conditioning apparatuses in the same manner as in the first embodiment, the best state data stored in the state storage unit 209 is illustrated in FIG. Refer to Then, the air adjustment recipe data FIG. 11B output immediately before 10:20 on Saturday, November 15, 2003 is extracted from the history. Best level data The level value in each evaluation item in FIG. 11 (a) and the level value in each item in the air adjustment recipe data FIG. 8 once generated were compared. To figure out. Then, the previously output air adjustment recipe data FIG. 11 (b) is compared with the air adjustment recipe data FIG. 8, and the level value is increased and corrected for the items whose level value is equal to or greater than the predetermined value among the respective items. multiply.

  FIG. 12 is a diagram showing the air adjustment recipe data after the air adjustment recipe data FIG. 8 is corrected in consideration of the best state.

  Comparing the air conditioning recipe data FIG. 11 (b) and the air conditioning recipe data FIG. 8, when the best condition was derived for the items [oxygen] and [anti-dust / allergens] Therefore, for each item, level values, for example, when the difference between the level values is 1 or more and 2 or less, 1 is increased, and when the difference is greater than 2, the difference is divided by 2, and the quotient value ( If the quotient is not an integer, it is changed according to a predetermined rule, such as rounding up the number after the decimal point to an integer), and finally the air adjustment recipe data shown in FIG. 12 is determined. To do. Thereafter, the operation is performed in the same manner as in the first embodiment until the air conditioner operates according to the contents of the air condition recipe data.

  According to such a configuration, since the recipe determination unit 207 stores the state of the user in the best condition, it is possible to indicate a change from the current state to the user. It is possible to grasp the status of and to obtain useful information.

  Further, according to such a configuration, the recipe determination unit 207 uses the air conditioning recipe data generated from the current state data of the user, the state data at the best condition of the user and the air adjustment recipe data actually output. In order to constantly compare and reflect, the air condition that restores the user's best condition will be adjusted. The air can be adjusted. Furthermore, since it is possible to refer to the record of the output air conditioning recipe data, it is possible to analyze whether the generated recipe is a recipe that suits the user and to adjust the air more suitable for the user. Can do.

  In the present embodiment, the recipe determination unit 207 does not touch on the comparison of the state data to which the user's best condition information is added and the current state data, but provides the user with information on the change. You may generate and display advice about it, how the external situation such as the weather has changed since you recorded the best, and how you lived It is also possible to collate with information such as whether or not, predict the change in the state of the user from the information, reflect it in the air adjustment recipe data, and provide it to the user as advice. The present invention can be realized by a program, which can be recorded on a recording medium and transferred.

  The air conditioning system according to the present invention has a device that measures and accumulates data of a user's physiological state, and controls the device by utilizing changes between the accumulated data and current data. It is useful as a controller for electrical equipment such as home appliances and equipment. It can also be applied to uses such as medical treatment devices in the medical field.

The top view which showed typically an example of the use condition of the air conditioning system in Embodiment 1 of this invention The block diagram which showed in detail the structure of the air conditioning system in Embodiment 1 of this invention (A) Measurement data collected by skin condition measurement unit 201 and air environment data collected by environment measurement unit 205 (b) Diagram showing state data diagnosed by symptom diagnosis unit 202 (A) Measurement data collected by skin condition measurement unit 201 and air environment data collected by environment measurement unit 205 (b) Diagram showing state data diagnosed by symptom diagnosis unit 202 (A) Measurement data collected by skin condition measurement unit 201 and air environment data collected by environment measurement unit 205 (b) Diagram showing state data diagnosed by symptom diagnosis unit 202 The figure which shows the air adjustment recipe data which the recipe determination part 207 produces | generates Flowchart showing a flow until the recipe determination unit 207 determines the generated air conditioning recipe data as formal air conditioning recipe data. Figure showing the corrected air conditioning recipe data after correction The figure which showed the table which matched each item of air adjustment recipe data, and the function of each air conditioner Flow chart showing the flow from when the recipe determination unit 207 determines the air adjustment recipe data until the air adjustment device is selected and the air adjustment recipe data is output to the air adjustment device. (A) The figure which shows the user's state data judged to be the best state (b) The figure which shows the air adjustment recipe data output just before the best state The figure which shows the air-conditioning recipe data after applying correction in consideration of the best state Block diagram showing the configuration of a conventional air conditioning system

Explanation of symbols

DESCRIPTION OF SYMBOLS 101 Skin condition detection apparatus 102 Control apparatus 103 Air adjustment apparatus 104 Air adjustment apparatus 105 Air adjustment apparatus 106 Air adjustment apparatus 201 Skin condition measurement part 202 Symptom diagnosis part 203 Control part 204 State storage part 205 Environment measurement part 206 Interface part 207 Recipe determination Unit 208 Interface unit 209 Status storage unit 210 Status monitoring unit 211 Interface unit 212 Control unit 213 Output unit 214 Interface unit 215 Control unit 216 Output unit 1001 Mouse 1002 Skin temperature measurement unit 1003 Sweating amount measurement unit 1004 Temperature / humidity measurement unit 1005 Computer 1006 Processing unit 1007 Interface unit 1008 Management computer 1009 Interface unit 1010 Arithmetic unit 1011 Air adjustment unit

Claims (6)

Measurement data indicating the results of measuring physiological conditions including the skin condition of the user, air environment data indicating the results of measuring the air environment such as temperature and humidity, and status indicating the results of diagnosing the skin condition An interface unit for receiving data and transmitting air conditioning recipe data indicating the operation content of each air conditioning device;
A state storage unit that stores the measurement data, the air environment data, and the state data received by the interface unit;
Based on the measurement data, the air environment data, and the state data, air adjustment recipe data including at least one parameter related to air adjustment corresponding to the state data is generated and stored in the state storage unit The parameter that is in a worse state than the latest state data is detected by referring to the past state data that has been set, and the parameter of the air adjustment recipe data corresponding to the deteriorated parameter is set to a predetermined value. A control device including a recipe determination unit that applies a change, determines formal air conditioning recipe data, and outputs the data to the interface unit. In the recipe determination unit,
A table in which at least one parameter in the air adjustment recipe data is associated with a function held by at least one air adjustment device is stored, each table of the air adjustment recipe data is referred to the table. Searching for an air conditioner having a function corresponding to the item, selecting an air conditioner to be used for air adjustment, and creating the air adjustment recipe data for each of the selected air conditioners The control device according to claim 1. A state monitoring unit that monitors the state of each of the at least one air conditioning device;
After creating the air conditioning recipe data for the selected air conditioning device, the state monitoring unit refers to the current operating status of the selected air conditioning device, and the air conditioning recipe data is stored in the selected air conditioning device. The control device according to claim 2, further comprising: a recipe determination unit that does not output the air adjustment recipe data when the content is the same as the current operation status. In the recipe determination unit,
When storing the state data in the state storage unit, the state data is compared with the past state data that has already been stored, and if it is the best state for the user, information indicating that the state is the best condition is added. When accumulating state data better than the state data to which the best condition information is added, the best condition information is updated and added to the state data, and a history of the generated air conditioning recipe data is recorded. After the air conditioning recipe data is generated, the air conditioning recipe data generated near the date and time of the state data to which the best condition information is added is searched from the history of the generated air conditioning recipe data. The empty condition based on the content of the air conditioning recipe data from which the best condition is derived. Control device according to claim 1, multiplied by the change in the adjustment recipe data, and determines the formal air conditioning recipe data. Measurement data indicating the results of measuring physiological conditions including the skin condition of the user, air environment data indicating the results of measuring the air environment such as temperature and humidity, and status indicating the results of diagnosing the skin condition An interface unit for receiving data and transmitting air conditioning recipe data indicating the operation content of each air conditioning device;
A state storage unit that stores the measurement data, the air environment data, and the state data received by the interface unit;
Based on the measurement data, the air environment data, and the state data, air adjustment recipe data including at least one parameter related to air adjustment corresponding to the state data is generated and stored in the state storage unit The parameter that is in a worse state than the latest state data is detected by referring to the past state data that has been set, and the parameter of the air adjustment recipe data corresponding to the deteriorated parameter is set to a predetermined value. A control device including a recipe determining unit that applies a change, determines formal air adjustment recipe data, and outputs the data as air adjustment recipe data to the interface unit;
A skin condition measurement unit that measures the state of the epidermis and the amount of moisture in contact with the skin and outputs it as measurement data;
An environment measuring unit that measures the air environment, such as temperature and humidity when the skin condition measuring unit is operated, and outputs it as air environment data; and
The measurement data output from the skin condition measurement unit and the state data diagnosed by the user's skin condition from the air environment data output from the environment measurement unit are output together with the measurement data and the air environment data. Symptom diagnosis department to
A state storage unit for storing the measurement data, the air environment data, and the state data;
An interface unit for transmitting the measurement data, the air environment data, and the state data to the control device;
The measurement data, the air environment data, and the state data output from the symptom diagnosis unit are stored in the state storage unit, and the measurement data, the air environment data, and the state data are stored via the interface unit. A skin condition detection device comprising a control unit for transmitting to the control device;
An interface unit for receiving air conditioning recipe data from the control device and transmitting data relating to the current state to the control device;
An air conditioning apparatus comprising: a control unit that controls adjustment of air according to the air conditioning recipe data received from the control device via the interface unit;
An air conditioning system comprising: Computer
Measurement data indicating the results of measuring physiological conditions including the skin condition of the user, air environment data indicating the results of measuring the air environment such as temperature and humidity, and status indicating the results of diagnosing the skin condition An interface unit for receiving data and transmitting air conditioning recipe data indicating the operation content of each air conditioning device;
A state storage unit that stores the measurement data, the air environment data, and the state data received by the interface unit;
Based on the measurement data, the air environment data, and the state data, air adjustment recipe data including at least one parameter related to air adjustment corresponding to the state data is generated and stored in the state storage unit The parameter that is in a worse state than the latest state data is detected by referring to the past state data that has been set, and the parameter of the air adjustment recipe data corresponding to the deteriorated parameter is set to a predetermined value. A program for making a change, determining formal air adjustment recipe data, and functioning as a recipe determination unit that outputs the data as air adjustment recipe data to the interface unit.

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