JP6381788B2 - Outdoor environment information analysis system, outdoor environment information analysis method, and program - Google Patents

Description

  The present invention relates to an outdoor environment information analysis system, an outdoor environment information analysis method, and a program.

  There is known a system that uses an electric device having an indoor unit and an outdoor unit to notify an indoor user of information such as outdoor temperature. For example, the air conditioner disclosed in Patent Document 1 processes information related to the outdoor environment such as temperature and humidity measured by a sensor provided in the outdoor unit, and obtains a washing index, a forecast of future weather, and the like. The obtained laundry index and current and future weather information are reported through a notification unit provided in the indoor unit.

JP 2002-350558 A

  The air conditioner disclosed in Patent Document 1 processes only information related to the outdoor environment. For this reason, the user cannot know how far the air-conditioned indoor environment and the outdoor environment are far apart, and how much the outdoor environment is more comfortable or uncomfortable than the indoor environment.

  If the user in the room can know how comfortable or uncomfortable the outdoor environment is compared with the indoor environment prior to going out, the user can take action according to the outdoor environment. For example, the user can refrain from going out or stay outside for a long time because the outdoor is too hot or cold. Occurrence of health problems such as heat stroke can be prevented in advance during midsummer due to user actions such as refraining from going out. Further, when the indoor air conditioning is performed even though the outdoor is comfortable, the air conditioning can be stopped to contribute to energy saving.

  The present invention has been made under the above circumstances, and an object thereof is to notify a user in a room of information indicating the comfort of the outdoor environment based on the outdoor environment and the indoor environment.

To achieve the above object, the outdoor information acquisition unit of the outdoor environment information analysis system according to the present invention acquires outdoor information for specifying the state of the outdoor environment. The room information acquisition unit acquires room information for specifying the state of the room environment. The specifying unit specifies a difference in comfort between the outdoor environment and the indoor environment based on the state of the outdoor environment and the state of the indoor environment. The notification unit outputs information indicating a difference in comfort between the outdoor environment and the indoor environment . An outdoor information acquisition part acquires each measured value of outdoor temperature, outdoor humidity, and the amount of outdoor ultraviolet rays as outdoor information. The room information acquisition unit acquires measured values of the room temperature, the room humidity, and the amount of ultraviolet rays in the room as room information. Specifying unit, and the outdoor environmental conditions specified by the outdoor information, and indoor environment conditions specified by the indoor information, based on the difference, identifies the difference in comfort of the outdoor environment and indoor environment.

  ADVANTAGE OF THE INVENTION According to this invention, the information which shows the comfort of the outdoor environment based on an outdoor environment and an indoor environment can be alert | reported to the user in a room.

It is a block diagram which shows the structure of an air conditioner. It is a figure which shows the example of the data stored in the outdoor information table of an outdoor information acquisition apparatus. It is a figure which shows the example of the data stored in the room information table of a room information acquisition apparatus. It is a figure which shows the example of the data stored in the indoor information table of an indoor unit. It is a front view of a remote control. It is a figure which shows the example of the data stored in the outdoor information table of a remote control. It is a figure which shows the example of the data stored in the room information table of a remote control. It is a figure which shows the example of the data stored in an advice table. It is a flowchart of the acquisition process of the outdoor information by an outdoor information acquisition apparatus. It is a flowchart of the acquisition process of room information by a room information acquisition device. It is a flowchart of the acquisition process of the indoor information by an indoor unit. It is a flowchart of a recording process of indoor information and outdoor information by a remote controller. It is a flowchart which shows the outdoor information analysis process by a remote control.

  Hereinafter, an outdoor environment information analysis system according to an embodiment of the present invention will be described by taking an air conditioner 1 having an outdoor environment information analysis function as an example with reference to the drawings.

(Embodiment)
In FIG. 1, the structure of the air conditioner 1 which concerns on embodiment is shown. The air conditioner 1 has a function of analyzing information about the outdoor (outdoor) environment and information about the indoor environment and notifying the user of information indicating the degree of comfort of the outdoor environment, in addition to the normal air conditioning function. .

  The air conditioner 1 includes an indoor unit 300, an outdoor unit 500 that provides an air conditioning function in cooperation with the indoor unit 300, and a remote controller 400 that controls the operation of the air conditioner 1. The air conditioner 1 further includes an outdoor information acquisition device 10 that acquires information related to the outdoor environment, and an indoor information acquisition device 20 that acquires information related to the indoor environment.

  Hereinafter, the structure of each part is demonstrated in order. In the following description, the information related to the outdoor environment includes the outdoor temperature, the outdoor humidity, and the measured value (physical quantity) of the outdoor ultraviolet ray amount. Moreover, the outdoor temperature, the outdoor humidity, and the outdoor ultraviolet ray measurement values may be collectively referred to as outdoor information. The information related to the indoor environment includes a measured value (physical quantity) of the indoor temperature, the indoor humidity, and the indoor ultraviolet ray amount. The measured values of the room temperature, the room humidity, and the amount of ultraviolet rays in the room may be collectively referred to as room information.

  First, the configuration of the outdoor information acquisition apparatus 10 that functions as an outdoor information acquisition unit that acquires outdoor information will be described. The outdoor information acquisition apparatus 10 is installed outdoors. The outdoor information acquisition apparatus 10 includes an outdoor measurement unit 110 including a plurality of sensors, an RF (Radio Frequency) module 120 for wireless communication, an RTC (Real-Time Clock) 130 that measures the current time, a program, and data. A memory 140 to be stored and an MPU (Micro Processor Unit) 150 that controls the outdoor information acquisition apparatus 10 by executing a program are provided. The outdoor measurement unit 110, the RF module 120, the RTC 130, and the memory 140 are connected to the MPU 150 via a bus. The outdoor information acquisition apparatus 10 operates using power or a battery supplied via a power line (not shown) as a power source.

  The outdoor measurement unit 110 includes a temperature sensor 111, a humidity sensor 112, and an ultraviolet sensor 113. The temperature sensor 111 measures outdoor air temperature (hereinafter referred to as outdoor temperature). The humidity sensor 112 measures outdoor humidity (hereinafter referred to as outdoor humidity). The ultraviolet sensor 113 measures the amount of outdoor ultraviolet rays. The outdoor measurement unit 110 outputs the measured values measured by the temperature sensor 111, the humidity sensor 112, and the ultraviolet sensor 113 to the MPU 150 according to the control of the MPU 150.

  The RF module 120 performs wireless communication with other devices capable of wireless communication according to the control of the MPU 150. For example, the RF module 120 wirelessly transmits outdoor information acquired by the outdoor measurement unit 110 to the remote controller 400.

  The RTC 130 operates by a power source (battery or the like) different from the power source of the outdoor information acquisition apparatus 10 and measures the current time. When the RTC 130 is requested by the MPU 150 for the current time, the RTC 130 notifies the MPU 150 of the current time.

  The memory 140 is composed of a flash memory or the like, and includes an outdoor information table 141. As shown in FIG. 2, the outdoor information table 141 stores the date and time (year / month / day and time) when the measurement value was acquired, and outdoor information (temperature, humidity, and amount of ultraviolet rays).

  The MPU 150 illustrated in FIG. 1 includes a processor, a work memory, and the like, and executes a program stored in the memory 140 to control the outdoor information acquisition apparatus 10.

  The MPU 150 causes the outdoor measurement unit 110 (the temperature sensor 111, the humidity sensor 112, and the ultraviolet sensor 113) to measure the outdoor temperature, the outdoor humidity, and the outdoor ultraviolet ray amount at regular intervals (for example, 0 minutes and 30 minutes per hour). The MPU 150 acquires the measurement value from the outdoor measurement unit 110 and stores it in the outdoor information table 141 of the memory 140 in association with the current time measured by the RTC 130. In addition, the MPU 150 periodically transmits the measurement value with the latest acquisition date among the measurement values stored in the outdoor information table 141 to the remote control 400 via the RF module 120 (for example, 20 minutes and 50 minutes per hour). Send.

  Next, the configuration of the room information acquisition device 20 will be described. The room information acquisition device 20 acquires room information and transmits the acquired room information to the remote controller 400. That is, the indoor information acquisition device 20 functions as an indoor information acquisition unit together with the indoor unit 300.

  The room information acquisition device 20 is installed indoors. The room information acquisition apparatus 20 includes a room measurement unit 210 that acquires a measurement value of the amount of ultraviolet rays in the room information, an RF module 220 for wireless communication, an RTC 230 that measures the current time, and a memory that stores programs and data. 240, MPU250 which executes a program and controls room information acquisition device 20 is included. The indoor measurement unit 210, the RF module 220, the RTC 230, and the memory 240 are connected to the MPU 250 via a bus. The room information acquisition device 20 operates using power or a battery supplied via a power line (not shown) as a power source.

  The indoor measurement unit 210 includes an ultraviolet sensor 211 and outputs a measured value of the amount of indoor ultraviolet light measured by the ultraviolet sensor 211 to the MPU 250. The RF module 220 is a wireless communication module. The RTC 230 measures the current time.

  The memory 240 is composed of a flash memory or the like, and includes an indoor information table 241. As shown in FIG. 3, the indoor information table 241 stores the date and time (year / month / day and time) when the measurement value of the ultraviolet ray amount is acquired and the measurement value of the ultraviolet ray amount in association with each other.

  The MPU 250 shown in FIG. 1 causes the indoor measurement unit 210 (ultraviolet sensor 211) to measure the amount of indoor ultraviolet rays periodically (for example, every hour at 0 and 30 minutes). The MPU 250 acquires the measurement value from the indoor measurement unit 210 and stores it in the indoor information table 241 in association with the current time measured by the RTC 230. Further, the MPU 250 periodically (for example, 20 minutes and 50 minutes per hour) sends the latest measured value of the measurement values stored in the room information table 241 to the remote controller 400 via the RF module 220. Send.

  The indoor unit 300 is installed indoors and is connected to the outdoor unit 500 via the refrigerant pipe P1 and the communication line C1. The indoor unit 300 performs various operations related to air conditioning in cooperation with the outdoor unit 500 in accordance with operation instructions from the remote controller 400 in the same manner as an indoor unit of a normal air conditioner.

  The indoor unit 300 includes a sensor for acquiring indoor environment information such as room temperature in order to perform air conditioning processing. In the present embodiment, the indoor unit 300 uses the remote control to transmit the indoor information acquired by each sensor. 400. That is, the indoor unit 300 functions together with the room information acquisition device 20 as a room information acquisition unit that acquires room information.

  Specifically, the indoor unit 300 includes an indoor measurement unit 310 that measures indoor temperature and indoor humidity, an RF module 320, an RTC 330, a memory 340, and an MPU 350. The indoor measurement unit 310, the RF module 320, the RTC 330, and the memory 340 are connected to the MPU 350 via a bus. The indoor unit 300 operates with power supplied via a power line (not shown).

  The indoor measurement unit 310 includes a temperature sensor 311 and a humidity sensor 312 that are installed around the air inlet of the indoor unit 300. The temperature sensor 311 measures the temperature of the intake air of the indoor unit 300. The humidity sensor 312 measures the humidity of the intake air of the indoor unit 300. The indoor measurement unit 310 outputs the temperature measured by the temperature sensor 311 and the humidity measured by the humidity sensor 312 to the MPU 350.

  The RF module 320 transmits the measured values of the room temperature and the room humidity acquired by the room measurement unit 310 to the remote controller 400. The RTC 330 measures the current time.

  The memory 340 includes a flash memory or the like, and includes an indoor information table 341 for storing measured values of room temperature and room humidity. As shown in FIG. 4, the indoor information table 341 stores the date and time (year / month / day and time) when the measurement value was acquired, the temperature and humidity measurement values in association with each other. The data stored in the room information table 341 is overwritten whenever the room measurement unit 310 acquires a new measurement value.

  While the indoor unit 300 is operating, the MPU 350 causes the indoor measurement unit 310 (temperature sensor 311 and humidity sensor 312) to measure the indoor temperature and the indoor humidity at predetermined times (0 minutes and 30 minutes per hour). The MPU 350 stores the acquired measured values of the room temperature and the room humidity in the room information table 341 of the memory 340 in association with the current time measured by the RTC 330. When the remote controller 400 requests the measured values of the room temperature and the room humidity, the MPU 350 sends the latest measured value of the measured values stored in the room information table 341 via the RF module 320. To the remote control 400.

  The remote controller 400 is connected to the indoor unit 300 wirelessly or by wire. The remote controller 400 transmits a signal indicating an operation instruction of the user to the indoor unit 300 as in the conventional air conditioner remote controller.

  Furthermore, the remote controller 400 functions as a specifying unit that specifies the degree of outdoor comfort (outdoor recommendation level) based on the outdoor information and the indoor information, and a notification unit that notifies the specified outing recommendation level. Specifically, the remote controller 400 processes the outdoor information and the indoor information, and specifies the state of the outdoor environment from the outdoor information and specifies the state of the indoor environment from the indoor information. The remote controller 400 identifies the degree of outdoor comfort (recommended degree of going out) based on the difference from the state of the indoor environment. Furthermore, the remote controller 400 notifies (presents) advice regarding going out corresponding to the recommended degree of going out as information regarding the specified degree of recommended going out. In the following description, detailed descriptions of configurations similar to the outdoor information acquisition device 10, the indoor information acquisition device 20, and the indoor unit 300 described above are omitted. Note that the following description will focus on the configuration related to the analysis of information related to the outdoor and indoor environment and the process of notifying information indicating the comfort of the outdoor environment.

  The remote control 400 includes an input device 410 as a user interface, an RF module 420 for wireless communication, an RTC 430 that measures the current time, a memory 440 that stores various programs and data, an MPU 450 that executes the program and controls the remote control 400, A display device 460 serving as a user interface. The input device 410, the RF module 420, the RTC 430, the memory 440, and the display device 460 are connected to the MPU 450 via a bus. The remote controller 400 operates using power supplied through a power line (not shown) or a battery (not shown) as a power source.

  The input device 410 includes various buttons and outputs an information signal indicating a user instruction by button operation to the MPU 450. FIG. 5 shows the appearance (front) of the remote controller 400. The input device 410 includes an operation on / off button 411 for instructing to start or stop the operation of the air conditioner 1, a temperature button 415 for adjusting the set temperature, a humidity button 416 for adjusting the set humidity, and various operations. A cooling button 412, a dehumidifying button 413, and a heating button 414 are provided. Furthermore, the remote control 400 includes a notification button 417 for requesting advice regarding going out. The input device 410 may include a touch panel instead of various buttons.

  The RF module 420 performs wireless communication with the outdoor information acquisition device 10, the indoor information acquisition device 20, and the indoor unit 300, respectively, under the control of the MPU 450. The RTC 430 measures the current time.

The memory 440 includes a flash memory or the like, and includes an outdoor information table 441 and an indoor information table 442. The outdoor information table 441 stores outdoor information supplied from the outdoor information acquisition device 10. As shown in FIG. 6A, the configuration of the outdoor information table 441 is the same as the outdoor information table 141 of the outdoor information acquisition apparatus 10 shown in FIG. The room information table 442 stores room information supplied from the room information acquisition device 20 and the indoor unit 300.
As shown in FIG. 6B, the room information table 442 includes the date and time (year / month / day and time), the temperature (room temperature), the humidity (room humidity), and the ultraviolet ray measurement value when the measured values of room information were acquired. Stored in association. When new outdoor information and indoor information are supplied to the remote controller 400, the outdoor information and indoor information stored in the outdoor information table 441 and the indoor information table 442 are overwritten.

  Furthermore, the memory 440 stores a formula table 443 that stores formula information for calculating the degree of recommendation for going out, and an advice table 444 that stores information about advice to the user corresponding to the recommendation level for going out as shown in FIG. 6C. To do.

  Reference is again made to FIG. The MPU 450 includes a processor, a work memory, and the like, and executes a program stored in the memory 440 to control the remote controller 400.

  The MPU 450 stores the indoor information supplied from the outdoor information acquisition device 10, the indoor information acquisition device 20, and the indoor unit 300 and the measured value of the outdoor information in the indoor information table 442. Further, the MPU 450 analyzes the indoor information stored in the indoor information table 442 and the measured values of the outdoor information at a predetermined timing (for example, when there is a request for advice regarding going out), and provides advice regarding going out. Is displayed on the display device 460.

  As shown in FIG. 5, the display device 460 includes two liquid crystal screens 461 and 462 and displays various types of information on the liquid crystal screens 461 and 462 according to the control of the MPU 450. Information relating to the operation of the air conditioner 1 is displayed on the liquid crystal screen 461. In the illustrated example, the liquid crystal screen 461 displays the current time, temperature (set temperature), humidity (set humidity), outside air temperature (outdoor temperature), and outside humidity (outdoor humidity). On the liquid crystal screen 462, additional information such as advice on going out recommendation is displayed.

  Refer to FIG. 1 again. The outdoor unit 500 is installed outside and is connected to the indoor unit 300 via the refrigerant pipe P1 and the communication line C1. The outdoor unit 500 performs various operations such as a cooling operation and a heating operation by circulating the refrigerant in the refrigerant pipe P1 in cooperation with the indoor unit 300. The outdoor unit 500 transmits and receives control signals and the like related to operation with the indoor unit 300 via the communication line C1. In the present embodiment, outdoor unit 500 does not perform processing related to analysis of information related to the outdoor and indoor environment and notification of information indicating the comfort of the outdoor environment.

  Hereinafter, a specific method for the remote controller 400 to specify the recommended degree of going out indicating the degree of outdoor comfort will be described. In addition, the latest measured value (acquisition date is the closest to the present time) is used for each measured value outdoors and indoors.

The remote controller 400 first calculates the discomfort index from the measured temperature and humidity for each of the outdoor and indoor areas. The discomfort index is an index that expresses a sense of discomfort when a human lives in terms of temperature and humidity. When temperature (air temperature) is T (° C.) and humidity is H (%), the discomfort index is expressed by the following equation.
Discomfort index = 0.81 × T + 0.01 × H × (0.99 × T-14.3) +46.3

The remote controller 400 calculates the outdoor and indoor discomfort indices from the above formulas using the measured values of the outdoor and indoor temperatures and humidity. Generally, it is known that the discomfort index when a person feels comfort is 65 to 70. Here, an intermediate value of 67.5 is set as an optimum value at which a person feels most comfortable. The remote controller 400 determines how far the outdoor and indoor discomfort indices are from the optimum value (67.5). Specifically, the remote controller 400 obtains the absolute value of the difference between the outdoor and indoor discomfort index and the optimum value, as shown in the following equation.
Outdoor difference D1 = | 67.5−outdoor discomfort index |
Indoor difference D2 = | 67.5−indoor discomfort index |

In order to compare the outdoor environment with the indoor environment, the remote controller 400 obtains a difference D3 between the outdoor environment and the indoor environment, which is an absolute value of the difference between the difference D1 and the difference D2, using the following formula.
Difference D3 = | difference D1 outside the room-difference D2 inside the room |

  The difference D3 between the outdoor environment and the indoor environment described above is a value indicating how far the outdoor environment and the indoor environment are far from each other. It can be said that the larger the value of the difference D3, the farther the indoor environment and the outdoor environment are. That is, it can be said that the larger the value of the difference D3 is, the less comfortable the outdoor environment is compared to the indoor environment being air-conditioned.

Moreover, it is generally known that exposure to a large amount of ultraviolet rays adversely affects the human body. Here, the outdoor ultraviolet light amount is compared with the indoor ultraviolet light amount, and when the difference is large, the outdoor ultraviolet light amount is large, so that the outdoor environment is not comfortable. The remote controller 400 obtains a difference D4 between the outdoor ultraviolet light amount and the indoor ultraviolet light amount using the following equation.
Ultraviolet light amount difference D4 = outdoor ultraviolet light amount-indoor ultraviolet light amount

The recommended degree of going out is obtained from a value obtained by combining the difference D3 between the outdoor environment and the indoor environment and the difference D4 in the ultraviolet ray amount calculated as described above. Here, an absolute value of a value obtained by multiplying the difference D3 between the outdoor environment and the indoor environment and the difference D4 in the amount of ultraviolet rays is set as the recommended degree of going out. As shown in the following formula, the remote controller 400 multiplies the difference D3 between the outdoor environment and the indoor environment and the difference D4 in the amount of ultraviolet light to calculate the recommended degree of going out.
Recommended degree of going out S = | difference D3 between outdoor environment and indoor environment × D4 difference in ultraviolet light amount |

  Furthermore, the remote controller 400 refers to the advice table 444 in the memory 440, and acquires the stage corresponding to the calculated outing recommendation degree S and advice information. The remote control 400 controls the display device 460 to display the stage corresponding to the recommended outing degree S and advice information on the liquid crystal screen 462 of the remote control 400 shown in FIG. As described above, the remote controller 400 specifies the recommended degree of going out and presents advice based on the specified recommended degree of going out.

  Next, operation | movement of the air conditioner 1 which has the said structure is demonstrated. In the air conditioner 1, the indoor unit 300 and the outdoor unit 500 cooperate to perform an air conditioning operation in accordance with an instruction from the remote controller 400. On the other hand, in the air conditioner 1, the outdoor information acquisition device 10, the indoor information acquisition device 20, the indoor unit 300, and the outdoor unit 500 cooperate to report (present) the analysis of indoor information and outdoor information and advice regarding going out. The operation | movement which concerns on is performed.

  The operation related to the analysis of the indoor information and the outdoor information performed by the air conditioner 1 and the notification (presentation) of the advice regarding going out are the processing related to the acquisition of the outdoor information and the indoor information, the processing related to the recording of the outdoor information and the indoor information, the outdoor And processing related to analysis of information and room information.

First, processing related to acquisition of outdoor information and indoor information will be described.
FIG. 7 shows a flowchart of the outdoor information acquisition process performed by the outdoor information acquisition apparatus 10. As shown in the figure, while the outdoor information acquisition apparatus 10 is powered on, the MPU 150 executes a program stored in the memory 140 and performs the following outdoor information acquisition process.

  The MPU 150 periodically acquires the current time from the RTC 130, determines whether it is the scheduled time (0 minutes per hour or 30 minutes per hour) for acquiring outdoor information (step S101), and if it is determined (step S101) ; Yes), outdoor temperature, outdoor humidity, and outdoor ultraviolet light amount are acquired (step S102). Specifically, the MPU 150 instructs the outdoor measurement unit 110 to measure outdoor temperature, outdoor humidity, and outdoor ultraviolet light amount. The outdoor measuring unit 110 measures the outdoor temperature by the temperature sensor 111, the outdoor humidity by the humidity sensor 112, and the amount of outdoor ultraviolet light by the ultraviolet sensor 113. The outdoor measurement unit 110 outputs measured values of outdoor temperature, outdoor humidity, and outdoor ultraviolet light amount to the MPU 150. The MPU 150 stores each measurement value supplied from the outdoor measurement unit 110 in the outdoor information table 141 together with the current time acquired from the RTC 130 (step S103). The MPU 150 returns to the process of S101 again.

  On the other hand, if the MPU 150 determines in step S101 that it is not the scheduled time for acquiring outdoor information (0 minutes per hour or 30 minutes per hour) (step S101; No), the scheduled time for transmitting outdoor information to the remote control 400 (20 minutes per hour) Or, it is determined whether or not it is 50 minutes per hour (step S104). When the MPU 150 determines that the scheduled time has come (step S104; Yes), among the measured values of the outdoor information stored in the outdoor information table 141, the latest measured value (outdoor temperature, outdoor humidity, outdoor ultraviolet light) is obtained. The measured value) is transmitted to the remote controller 400 via the RF module 120 (step S105). After executing the process of step S105, the MPU 150 repeats the processes after step S101 again. If it is determined in step S104 that it is not the scheduled transmission time of outdoor information (step S104; No), the MPU 150 returns to step S101 again. The above is the outdoor information acquisition process performed by the outdoor information acquisition apparatus 10.

  FIG. 8 shows a flowchart of room information (indoor ultraviolet ray amount) acquisition processing performed by the room information acquisition apparatus 20. While the room information acquisition apparatus 20 is powered on, the MPU 250 of the room information acquisition apparatus 20 executes the program stored in the memory 240 to perform the room information acquisition process shown in FIG. This acquisition process is substantially the same as the outdoor information acquisition process shown in FIG. 7, but the MPU 250 measures only the amount of indoor ultraviolet rays as room information and stores the measured value in the room information table 241 (steps S202 and 203). ). Further, the MPU 250 transmits the latest indoor ultraviolet ray measurement value to the remote control 400 in step S205. The above is the process for acquiring room information (the amount of ultraviolet rays in the room) performed by the room information acquisition apparatus 20.

  FIG. 9 shows a flowchart of the indoor information (room temperature, room humidity) acquisition process performed by the indoor unit 300. During the operation of the air conditioner 1, the MPU 350 of the indoor unit 300 executes the program stored in the memory 340, and performs the indoor information acquisition process shown in FIG. This acquisition process is substantially the same as the outdoor information acquisition process shown in FIG. 7, but MPU 350 does not periodically transmit the measured value of the indoor information to remote controller 400. When the MPU 350 receives an information signal for requesting room information from the remote controller 400 in step S304 (step S304; Yes), the MPU 350 transmits the latest measured values of room temperature and room humidity to the remote controller 400 (step S305). On the other hand, when it is determined in step S304 that there is no request for room information from the remote controller 400 (step S304; No), the MPU 350 returns to the process of step S301 again. The above is the acquisition process of the room information (room temperature and room humidity) performed by the indoor unit 300.

  Next, processing related to recording of outdoor information and indoor information will be described. The remote controller 400 records the indoor information and outdoor information received from the outdoor information acquisition device 10 and the indoor information acquisition device 20 in the memory 440. During the operation of the air conditioner 1, the MPU 450 of the remote controller 400 executes the program stored in the memory 440 at a predetermined time interval (for example, every 10 minutes) and performs the process shown in FIG. The MPU 450 determines whether or not the outdoor information measurement value is received from the outdoor information acquisition apparatus 10 (step S401). When the MPU 450 determines that the measurement value of the outdoor information has been received (step S401; Yes), the MPU 450 updates and records the received measurement value of the outdoor information in the outdoor information table 441 together with the current time acquired from the RTC 430 (step S402). . On the other hand, if the MPU 450 determines that the measured value of the outdoor information has not been received (step S401; No), the process proceeds to step S403.

  The MPU 450 determines whether or not the measured value of the room information (the amount of ultraviolet rays in the room) has been received from the room information acquisition apparatus 20 (step S403). When the MPU 450 determines that the measurement value of the indoor ultraviolet ray amount has been received (step S403; Yes), the MPU 450 transmits an information signal requesting the measurement value of the room temperature and the room humidity to the indoor unit 300 via the RF module 420. (Step S404). On the other hand, when the MPU 450 determines in step S403 that it has not received the measurement value of the indoor ultraviolet ray amount from the room information acquisition apparatus 20 (step S403; Nо), the recording process of the outdoor information and the room information is ended.

  When the MPU 450 receives the measured values of the indoor temperature and the indoor humidity from the indoor unit 300 (step S405; Yes), the MPU 450 receives the measured value received from the indoor unit 300 and the measured value received from the indoor information acquisition device 20 in step S302. The current time is updated and recorded in the room information table 442 (step S406). Thereafter, the MPU 450 ends the outdoor information and indoor information recording process. On the other hand, when the MPU 450 does not receive the measurement value in the period determined from the indoor unit 300 in step S405 (step S405; Nо), the MPU 450 ends the outdoor information and indoor information recording process. In this way, the outdoor information table 441 and the indoor information table 442 of the remote control 400 regularly record the latest outdoor information and measured values of the indoor information.

  Next, processing related to analysis of outdoor information and indoor information will be described. The remote controller 400 analyzes the outdoor information and the indoor information, and specifies the outing calculation degree. FIG. 11 shows a flowchart of outdoor information analysis processing of the remote controller 400.

  The user presses the notification button 417 of the remote control 400 shown in FIG. 5 during operation of the air conditioner 1 in order to request the air conditioner 1 for advice regarding going out. When the MPU 450 of the remote controller 400 determines that the notification button 417 has been pressed, the MPU 450 executes the program stored in the memory 440 and performs the processing shown in FIG. At this time, the outdoor information acquisition device 10, the indoor information acquisition device 20, and the indoor unit 300 execute the outdoor information and indoor information acquisition processing shown in FIGS. In addition, the remote controller 400 executes the recording processing of the indoor information and the outdoor information at a determined timing, and the outdoor information table 441 and the indoor information table 442 of the remote controller 400 include the latest outdoor information and measured values of the indoor information. Is stored.

  The MPU 450 obtains an outdoor discomfort index from the measured values of the outdoor temperature and outdoor humidity read from the outdoor information table 441, and obtains a difference D1 that is an absolute value of the difference between the outdoor discomfort index and the optimum value (67.5) ( Step S501). Subsequently, the MPU 450 obtains an indoor discomfort index from the measured values of the indoor temperature and the indoor humidity read from the indoor information table 442, and a difference that is an absolute value of the difference between the indoor discomfort index and the optimum value (67.5). D2 is obtained (step S502). Next, the MPU 450 obtains the absolute value of the difference between the difference D1 obtained in step S501 and the difference D2 obtained in step S502 as the difference D3 between the outdoor environment and the indoor environment (step S503). Subsequently, the MPU 450 obtains a difference D4 between the outdoor and indoor ultraviolet ray measurement values read from the outdoor information table 441 and the indoor information table 442 (step S504).

  Next, MPU450 calculates | requires the value which multiplied difference D3 calculated | required by step S503 and difference D4 calculated | required by step S504 as a going-out recommendation degree (step S505). The MPU 450 acquires information regarding the calculated recommended degree of going out (the stage corresponding to the recommended degree of going out and advice) from the advice table 444 illustrated in FIG. 6C. The MPU 450 displays information related to the recommended degree of going out on the liquid crystal screen 462 of the remote control 400 as shown in FIG. 5 (step S506). Thereafter, the MPU 450 ends the outdoor information analysis process. The above is the processing related to the analysis of the outdoor information and the indoor information of the remote controller 400 and the specification of the recommended degree of going out.

  As described above, the air conditioner 1 specifies the recommended degree of going out from the outdoor information and the indoor information, which are physical quantities related to the outdoor and indoor environments, and displays information such as advice on going out on the liquid crystal screen 462 of the remote control 400. Therefore, the user who is indoors can know how comfortable or uncomfortable the outdoor environment is compared with the indoor environment while staying indoors. Therefore, the user can take action in consideration of the outdoor environment. For example, the user can postpone a plan (for example, a plan to clean a garden flower bed) in consideration of advice regarding going out recommendations.

  In addition, the present invention is not limited to the above embodiment, and various modifications and applications are possible.

  In the above-described embodiment, an example in which information regarding the recommended degree of going out is displayed on the liquid crystal screen 462 of the remote control 400 has been described as one mode of notification of the recommended degree of going out. However, the manner of reporting the recommended degree of going out is not limited to a visually recognizable manner. For example, the remote controller 400 may be provided with a speaker, and information on the recommended degree of going out may be notified by voice from the speaker. In addition, the remote controller 400 may transmit information regarding the recommended degree of going out to other computers, portable terminals, and the like by wireless / wired communication. In this case, another computer, portable terminal, or the like that has received the information related to the recommended degree of going out from the remote controller 400 reports the information related to the recommended degree of going out via its own display, speaker, or the like.

  Moreover, the outdoor information acquisition apparatus 10 does not need to be installed outdoors. The outdoor information acquisition device 10 may be installed indoors, and the outdoor measurement unit 110 may be provided in a device separate from the outdoor information acquisition device 10 installed outdoors. In this case, the outdoor measurement unit 110 provided in a separate outdoor device transmits the measured value of the acquired outdoor information to the indoor outdoor information acquisition device 10 by wireless or wired communication. For example, a HEMS (Home Energy Management System) controller may function as the outdoor information acquisition apparatus 10 (excluding the outdoor measurement unit 110), and various sensors installed outdoors may function as the outdoor measurement unit 110.

  Alternatively, each sensor included in the outdoor measurement unit 110 may be provided in the outdoor unit 500. Note that when the outdoor measurement unit 110 is provided in the outdoor unit 500, it is necessary to install the outdoor measurement unit 110 in a place where the outdoor unit 500 is not affected by exhaust heat of heat exchange or the like.

  Further, the temperature sensor 111, the humidity sensor 112, and the ultraviolet sensor 113 are not necessarily installed at the same location. The temperature sensor 111, the humidity sensor 112, and the ultraviolet sensor 113 may be installed at remote locations so that accurate measured values can be obtained. The outdoor measurement unit 110 includes a plurality of temperature sensors 111, humidity sensors 112, and ultraviolet sensors 113 installed at a plurality of locations. The outdoor information acquisition apparatus 10 includes a plurality of temperature sensors 111, humidity sensors 112, and ultraviolet sensors. You may make it transmit the average value of the measured value measured by 113 to the remote control 400. FIG.

  In the above-described embodiment, the remote controller 400, the outdoor information acquisition device 10, the indoor information acquisition device 20, and the indoor unit 300 (hereinafter, information acquisition device) transmit and receive information signals by wireless communication. 400 and other devices may perform wired communication. Further, wireless communication and wired communication may be mixed on a communication path between the remote controller 400 and another device. For example, data transmitted by the outdoor information acquisition device 10 may be transmitted to the remote controller 400 via a wireless LAN router and a wired LAN line.

  In the above-described embodiment, the outdoor information table 441 and the indoor information table 442 of the remote controller 400 include the current information posted by the RTC 430 when the remote controller 400 stores the measured values in the outdoor information table 441 and the indoor information table 442. The time is recorded. Alternatively, the information acquisition apparatus transmits information on the time when the measurement value is acquired from each sensor (acquisition time shown in FIGS. 2, 3, and 4) to the remote controller 400 together with the measurement value. The time information received from the information acquisition device may be stored in the outdoor information table 441 and the indoor information table 442.

  The air conditioner 1 may include a plurality of indoor units 300 that are installed within a certain range (for example, in the same building). At this time, the air conditioner 1 may include the same number of outdoor units 500 as the number of indoor units 300. Alternatively, the air conditioner 1 may include the outdoor units 500 that are fewer than the number of the indoor units 300 with respect to the plurality of indoor units 300. The outdoor information acquisition device 10 and the indoor information acquisition device 20 transmit the outdoor information and the measured value of the indoor information to each remote controller 400 provided in each indoor unit 300. Each remote control 400 analyzes the outdoor information and indoor information supplied from the outdoor information acquisition device 10 and the indoor information acquisition device 20, and the indoor information (indoor temperature and indoor humidity) supplied from the corresponding indoor unit 300, The degree of recommendation for going out can be calculated. Further, the air conditioner 1 may include only one remote controller 400 that centrally controls the plurality of indoor units 300. In this case, one remote controller 400 analyzes the outdoor information and the indoor information supplied from the outdoor information acquisition device 10 and the indoor information acquisition device 20 and the indoor information supplied from each indoor unit 300, and recommends the degree of going out. Is calculated.

  In the above-described embodiment, the remote controller 400 calculates the recommended degree of going out. For example, the indoor unit 300 or the outdoor information acquisition device 10 analyzes the indoor information and the outdoor information, and calculates the recommended degree of going out. May be. In this case, devices that measure outdoor information and indoor information (the outdoor information acquisition device 10, the indoor information acquisition device 20, and the indoor unit 300) transmit measured data to the indoor unit 300 or the outdoor information acquisition device 10.

  In the above-described embodiment, the indoor information and the outdoor information include information on temperature (air temperature), humidity, and the amount of ultraviolet rays. Or the outdoor measurement part 110 of the outdoor information acquisition apparatus 10 may be further provided with a wind speed sensor, and may measure the outdoor wind speed. When the measured value of the wind speed acquired by the outdoor measuring unit 110 is larger than the determined threshold value, the remote controller 400 may adjust the calculated outdoor discomfort index by a determined value. For example, in summer, the outdoor discomfort index is decreased by a certain value (that is, the discomfort index is brought close to a pleasant value), and in winter, the outdoor discomfort index is increased (that is, the discomfort index is increased to a pleasant value). (Closer). The remote control 400 obtains the recommended degree of going out from the discomfort index taking into account the wind speed.

  In the embodiment described above, the recommended degree of going out is calculated from the difference between the discomfort index in the outdoors and the discomfort index in the room, and the difference between the amount of ultraviolet rays in the room and the amount of ultraviolet rays in the outdoors. Not limited to. Since the discomfort index is obtained by counting “sultry heat” from the correlation between temperature and humidity, the recommended degree of going out may be obtained by a different method depending on the season. For example, in winter, an outdoor temperature, an outdoor humidity, and an outdoor wind speed may be used to obtain a body temperature, and the recommended degree of going out may be calculated from the body temperature and the amount of ultraviolet rays. In addition, as a method for calculating the sensory temperature, a conventional Misnar calculation formula, a Linke calculation formula, or the like may be used.

  Or you may specify the going-out recommendation degree as follows. The outing index may be obtained from the outdoor information and the indoor information, and the recommended degree of going out corresponding to the calculated outing index may be obtained by referring to a correspondence table between the outing index and the recommended degree of going out.

For example, as shown in the following formula, the outing index may be obtained by taking the square root of the difference between the outdoor temperature and the indoor temperature, the humidity, and the amount of ultraviolet rays.
Outing index I = ((outdoor temperature−indoor temperature) ² + (outdoor humidity−indoor humidity) ²⁺ (outdoor ultraviolet ray amount—indoor ultraviolet ray amount) ² ) ^1/2
In addition, a step of recommending an outing index and an outing and a going-out index table that defines a correspondence between advices are prepared in the memory 440 in advance, and a step corresponding to the calculated outing index with reference to the outing index table is performed. , Can give advice and more.

  The outdoor measurement unit 110 of the outdoor information acquisition apparatus 10 may further include a raindrop sensor to detect whether it is raining outdoors. When the outdoor measuring unit 110 detects that it is raining outdoors, the remote controller 400 may change the recommended outing degree value calculated by the above-described method so as to approach the unrecommended value.

  Furthermore, the outdoor measurement unit 110 of the outdoor information acquisition apparatus 10 may have a function of detecting air pollutants. For example, the outdoor measurement unit 110 detects a photochemical oxidant, a suspended particulate matter (SPM), and a fine particulate matter (PM2.5) that cause photochemical smog. The remote control 400 changes the value of the recommended degree of going out calculated by the above method so as to approach a value that is not recommended for going out according to the amount of the air pollutant detected.

  In winter, since the difference between the ultraviolet rays in the outdoor and indoors may be small, for example, the calculation method of the recommended degree of going out may be changed between summer and winter. For example, in winter, the recommended degree of going out may be calculated considering only the discomfort index.

  Furthermore, the advice table 444 shown in FIG. 6C does not use the same table throughout the year, but may use an advice table 444 prepared for each season or for each month, for example. In this way, it is possible to propose appropriate advice according to the season or the like to the user.

  The memory 440 of the remote controller 400 may store a plurality of advice tables 444 corresponding to the user's age and the ages of main residents in the room where the indoor unit 300 is installed. When a user corresponds to an infant or an elderly person, the hot and humid outdoor environment in summer has a great influence on health. For this reason, an advice table 444 for infants and elderly people and a normal advice table 444 are prepared so that advice to refrain from going out even when the calculated recommended degree S of going out is not so large. deep.

  In the above-described embodiment, remote controller 400 specifies the recommended degree of going out from outdoor information at a certain point in time (the previous measurement time closest to the current time) and the measured value of the indoor information. Furthermore, the remote controller 400 may notify information specified or assumed from outdoor information and measured values of indoor information within a determined period. For example, the remote controller 400 predicts a future change in the outdoor environment (this time the outdoor temperature will increase further, etc.) from the measured outdoor information measured three hours before the current time, and displays the predicted contents. It is possible to notify the user.

  In the above-described embodiment, outdoor information and indoor information analyzed by the remote controller 400 are measured values of outdoor and indoor temperature, humidity, and ultraviolet light amount. However, the outdoor information and indoor information analyzed by the remote controller 400 are actually The measured value may not be measured. For example, the outdoor data may be statistical data created from measured values such as outdoor temperature, humidity, and amount of ultraviolet rays measured within a certain period. For room information, room temperature and room humidity set values set by the user may be used as room information. In this case, the remote control 400 uses statistical data of outdoor information stored in a memory or the like in advance, and set values of room temperature and room humidity as analysis targets.

  In the following description, the information (physical quantity) related to the outdoor environment includes measured values of outdoor temperature, outdoor humidity, and outdoor ultraviolet light amount. The measured values of outdoor temperature, outdoor humidity, and outdoor ultraviolet light amount may be collectively referred to as outdoor information. The information (physical quantity) related to the indoor environment includes measured values of indoor air temperature, indoor air humidity, and indoor ultraviolet light quantity. The measured values of indoor air temperature, indoor air humidity, and indoor ultraviolet light amount may be collectively referred to as room information.

  In the above-described embodiment, the degree of outdoor comfort (recommended degree of going out) has been described as including a plurality of values as shown in FIG. 6C. However, in the present invention, the recommended degree of going out is two. It may contain only values. For example, the remote control 400 binarizes the value of the recommended outing degree S according to whether the value of the recommended outing degree S obtained by the above-described expression of recommended degree of going out exceeds a predetermined threshold. Any advice of “can go out of the room” / “cannot go out” may be proposed.

  In the above-described embodiment, the outdoor environment information analysis system of the present invention has been described using an air conditioner having an outdoor environment information analysis function as an example, but the embodiment of the present invention is not limited thereto. The outdoor environment information analysis system according to the present invention can also be realized by other electrical equipment having the outdoor environment information analysis function as described above. As an example of another electric device, an electric device including an outdoor unit and an indoor unit such as a TV door phone, an interphone, and a water heater is desirable.

  Moreover, the outdoor environment information analysis system according to the present invention can be realized by using a normal computer system regardless of a specific electric device having an outdoor environment information analysis function. For example, a program for performing the above operation is stored in a computer-readable recording medium (CD-ROM, MO, etc.) and distributed to a computer connected to a network, and the program is distributed to the computer system. You may comprise the outdoor environment information analysis system which performs the above-mentioned process by installing.

  Further, the method for providing the program to the computer is arbitrary. For example, the program may be uploaded to a bulletin board (BBS) on a communication line and distributed to a computer via the communication line. The program may be transmitted by a modulated wave obtained by modulating a carrier wave with a signal representing the program, and a device that receives the modulated wave may demodulate the modulated wave to restore the program. Then, the computer activates this program and executes it in the same manner as other applications under the control of the OS. Thus, the computer functions as an outdoor environment information analysis system that executes the above-described processing.

  Various embodiments and modifications can be made to the present invention without departing from the broad spirit and scope of the present invention. The above-described embodiments are for explaining the present invention and do not limit the scope of the present invention. In other words, the scope of the present invention is shown not by the embodiments but by the claims. Various modifications made within the scope of the claims and within the scope of the equivalent invention are considered to be within the scope of the present invention.

  According to the present invention, an electric device such as an air conditioner can notify an indoor user of information indicating the degree of outdoor comfort based on the difference between the outdoor environment and the indoor environment.

  DESCRIPTION OF SYMBOLS 1 Air conditioner, 10 Outdoor information acquisition apparatus, 20 Indoor information acquisition apparatus, 110 Outdoor measurement part, 111,311 Temperature sensor, 112,312 Humidity sensor, 113,211 Ultraviolet sensor, 120,220,320,420 RF module, 130, 230, 330, 430 RTC, 140, 240, 340, 440 Memory, 141, 441 Outdoor information table, 150, 250, 350, 450 MPU, 210 Indoor measuring unit, 241, 341, 442 Indoor information table, 300 Indoor Machine, 310 indoor measuring unit, 400 remote control, 410 input device, 443 formula table, 444 advice table, 460 display device, 461, 462 liquid crystal screen, 500 outdoor unit.

Claims (6)

An outdoor information acquisition unit for acquiring outdoor information for identifying the state of the outdoor environment;
An indoor information acquisition unit for acquiring indoor information for identifying the state of the indoor environment;
And wherein the state of the outdoor environment based on the room environment state identifying unit that identifies the differences in comfort of the indoor environment and the outdoor environment,
A notification unit for outputting information indicating a difference between the comfort of the indoor environment and the outdoor environment,
With
The outdoor information acquisition unit acquires each measurement value of outdoor temperature, outdoor humidity and outdoor ultraviolet light amount as the outdoor information,
The indoor information acquisition unit acquires each measured value of indoor temperature, indoor humidity, and indoor ultraviolet light amount as the indoor information,
The specifying unit is configured to determine the comfort of the outdoor environment and the indoor environment based on a difference between the state of the outdoor environment specified by the outdoor information and the state of the indoor environment specified by the indoor information. Identify the difference between
Outdoor environment information analysis system. The specifying unit obtains an outdoor discomfort index from the outdoor temperature and the outdoor humidity, obtains an indoor discomfort index from the indoor temperature and the indoor humidity, a difference between the outdoor discomfort index and the indoor discomfort index, and the difference between the outdoor UV dose and UV dose of said chamber, based on, to identify the difference between the comfort of the indoor environment and the outdoor environment,
The outdoor environment information analysis system according to claim 1. The outdoor information acquired by the outdoor information acquisition unit further includes a measured value of outdoor wind speed,
When the outdoor wind speed is larger or smaller than a predetermined threshold, the specific unit adjusts the outdoor discomfort index obtained from the outdoor temperature and the outdoor humidity.
The outdoor environment information analysis system according to claim 2. The specific unit obtains an outdoor sensory temperature from the outdoor temperature and the outdoor humidity, and an indoor sensory temperature from the indoor temperature and the indoor humidity. Based on the difference between the sensory temperature in the outdoor and the sensory temperature in the room , to identify the difference between the comfort of the indoor environment and the outdoor environment,
The outdoor environment information analysis system according to claim 1. An outdoor information acquisition step of acquiring outdoor information for identifying the state of the outdoor environment;
An indoor information acquisition step of acquiring indoor information for identifying the state of the indoor environment;
A specifying step of based on said outdoor environmental conditions and the state of the indoor environment, identifies the difference in comfort of the indoor environment and the outdoor environment,
And a notification step for outputting information indicating the difference between the comfort of the indoor environment and the outdoor environment,
Have
In the outdoor information acquisition step, as the outdoor information, each measured value of outdoor temperature, outdoor humidity and outdoor ultraviolet light amount is acquired,
In the room information acquisition step, as the room information, each measurement value of room temperature, room humidity, and indoor ultraviolet light amount is obtained,
The comfort of the in certain steps, the a state of the outdoor environment identified by the outdoor information, based on the difference between the states of the indoor environment identified by the indoor information, the indoor environment and the outdoor environment Identify the difference between
Outdoor environment information analysis method. On the computer,
An outdoor information acquisition function for acquiring outdoor information for identifying the state of the outdoor environment;
An indoor information acquisition function for acquiring indoor information for identifying the state of the indoor environment;
Wherein the state of the outdoor environment based on the room environment conditions, and the specific function of specifying the differences in comfort of the indoor environment and the outdoor environment,
A notification function for outputting information indicating a difference between the comfort of the indoor environment and the outdoor environment,
Realized,
In the outdoor information acquisition function, as the outdoor information, each measured value of outdoor temperature, outdoor humidity and outdoor ultraviolet light amount is acquired,
In the room information acquisition function, as the room information, each measured value of room temperature, room humidity and indoor ultraviolet light amount is obtained,
The comfort of the in particular function, the a state of the outdoor environment identified by the outdoor information, based on the difference between the states of the indoor environment identified by the indoor information, the indoor environment and the outdoor environment To identify the difference between
program.

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