JP6056095B1 - Server device, environment measuring device, and air blowing system - Google Patents

Abstract

An environment measuring apparatus capable of measuring an environmental state of a place desired by a user, a blower system for reproducing the wind speed of the place in real time or afterward based on the environmental state measured by the environment measuring apparatus, and the like I will provide a. An environment measuring device is communicable with a portable terminal and a fan, and measures a wind speed at an installation location, an encoding section 2b that converts the measured wind speed signal into wind speed data, and wind speed data. By including a file generation unit 2c that generates a file to be included and a communication unit 6 that transmits the file to the portable terminal and the fan, and by transmitting the file including the wind speed data to the fan via the portable terminal, The fan is encouraged to regenerate the air at the wind speed based on the wind speed data. In addition, a file including existing wind speed data is edited with a portable terminal or a personal computer and transmitted to a fan or the like, thereby providing a reproduction environment for a unique wind pattern desired by the user. [Selection] Figure 2

Description

  The present invention relates to an environmental measurement device that measures an environmental state such as wind speed and temperature, for example, and in particular, an environmental measurement device that measures an environmental state of a desired place and a fan at a wind speed related to the environmental state by a fan or the like. It is related with the ventilation system etc. which made it possible to realize.

  Conventionally, there is an electric fan that can adjust the wind speed by switching a switch. There is also a fan that automatically adjusts the wind speed based on the temperature of the installation location.

  For example, Patent Literature 1 discloses a fan that controls driving of a fan motor based on a temperature measured by a temperature sensor. On the other hand, Patent Document 2 discloses a fan that calculates a discomfort index from the temperature detected by the temperature sensor and the humidity detected by the humidity sensor, and controls the air volume based on the discomfort index.

JP 2012-97625 A JP 2011-122550 A

  However, the fans disclosed in Patent Documents 1 and 2 control the air volume based on the temperature of the installation location of the fan itself, and reproduce the air volume based on the environmental state of the place where the user wants to reproduce. Is not disclosed.

  That is, no system is disclosed that measures an environmental condition at a location desired by a user and reproduces the wind speed at the location in real time or afterwards based on the measured environmental condition.

  An object of the present invention is to reproduce an environmental measurement device capable of measuring an environmental condition of a place desired by a user and a wind speed of the place in real time or afterwards based on the environmental condition measured by the environmental measurement apparatus. The purpose is to provide a blower system and the like. Another object of the present invention is to provide an environment for reproducing a unique wind pattern desired by a user by editing an existing wind speed information file with a portable terminal or a personal computer and transmitting the file to a fan or the like.

  In order to solve the above-mentioned problem, a blower system according to one aspect of the present invention is a blower system in which an environment measurement device that collects environmental data, a mobile terminal, and a fan are connected so as to be able to communicate with each other. The measurement device includes at least a measurement unit that measures a wind speed at an installation location, an encoding unit that converts a wind speed signal measured by the measurement unit into wind speed data, a file generation unit that generates a file including the wind speed data, A first communication unit that transmits the file to a portable terminal or a fan, and the portable terminal includes a second communication unit that communicates with the environment measurement device and the fan, and a file from the environment measurement device. A main control unit that controls to transmit the file to the electric fan, and the electric fan communicates with the environmental measurement device and the portable terminal. And a drive unit for driving the fins, a data extraction unit for extracting wind speed data from a file including the wind speed data, and a control unit for controlling the rotational speed of the drive unit based on the wind speed data. It is characterized by that. In addition, it has a function of editing an existing wind speed information file (such as a file including wind speed data related to environmental data) with a portable terminal or a personal computer according to the user's preference.

According to the first and second aspects of the present invention, the wind speed of the place can be measured in real time or afterwards based on the environmental state measured by the environmental measuring device capable of measuring the environmental state of the place desired by the user. A reproducible air blowing system can be provided. In addition, according to the invention according to claim 3 , an existing wind speed information file (such as a file including wind speed data related to environmental data) is edited with a mobile terminal or a personal computer according to the user's preference, By transmitting to, it is possible to provide an environment for reproducing a unique wind pattern desired by the user.

It is a block diagram of the ventilation system which concerns on 1st Embodiment of this invention. It is a block diagram of an environmental measurement apparatus. It is a block diagram of a portable terminal. It is a block diagram of an electric fan. It is a block diagram of a server. It is a block diagram of a control apparatus. It is a figure which shows the relationship between wind speed data and an applied voltage pattern. It is a figure which shows the relationship between wind speed data and an applied voltage pattern. It is a figure which shows the flow of a process between an environmental measurement apparatus, a portable terminal, and an electric fan. It is a figure which shows the flow of a process between an environmental measurement apparatus and an electric fan. It is a figure which shows the flow of a process between a server apparatus, a portable terminal, and an electric fan. It is a figure which shows the example of a screen structure. It is a figure which shows the example of a screen structure. It is a figure which shows the example of a screen structure. It is a figure which shows the example of a screen structure. It is a figure which shows the flow of a process between a server apparatus, a portable terminal, and a control apparatus. It is a figure which shows the structural example of the electric fan employ | adopted by 2nd Embodiment of this invention. It is a figure which shows the structural example of the air conditioner employ | adopted by 3rd Embodiment of this invention. It is a figure which shows the structural example of the remote control apparatus employ | adopted by 2nd Embodiment of this invention. It is a flowchart explaining the correction function which concerns on the improvement example of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)

(Fan system)
In FIG. 1, the structure of the ventilation system which concerns on 1st Embodiment of this invention is shown and demonstrated.
As shown in the figure, the blower system 100 according to the first embodiment is configured by any one of the following combinations.
・ Environmental measurement device 1, portable terminal 10, electric fan 20
・ Environmental measurement device 1, electric fan 20
-Server device 30, portable terminal 10, electric fan 20
-Environment measuring device 1, portable terminal 10, control device 50, and electric fan 40
・ Environmental measurement device 1, control device 50 and electric fan 40
Server device 30, mobile terminal 10, control device 50, and electric fan 40

  The environment measuring apparatus 1 includes a wind speed measuring unit 3a, a temperature measuring unit 3b, a humidity measuring unit 3c, and an illuminance measuring unit 3d, and can be switched ON / OFF by a power switch 9. In addition, environmental data obtained by measurement can be displayed on the display unit 4. The environment measuring device 1 can communicate with the mobile terminal 10, the electric fan 20, and the server device 30 via a network 60 such as the Internet. In an environment where communication is possible, a plurality of devices can be installed remotely from the electric fan 20 or the like. The environment measuring device 1 converts the environment data obtained by the measurement into a file and transmits the file to the mobile terminal 10, the server device 30, and the like. Or environment measuring device 1 can also transmit wind speed data obtained by measurement to electric fan 20 in real time.

  The mobile terminal 10 includes, for example, a mobile phone, a smartphone, a tablet terminal, a notebook personal computer (hereinafter abbreviated as PC), and the like. The mobile terminal 10 receives a file related to the environmental data from the environment measuring device 1 and transmits the file to the electric fan 20. Or the file which concerns on environmental data from the server apparatus 30 is received, and the said file is transmitted to the electric fan 20. The portable terminal 10 holds a plurality of files related to environmental data, makes it possible to select a file desired by the user from among the files, and can transmit the file selected by the user to the electric fan 20. Note that a desktop PC can be used instead of the mobile terminal 10. In that case, the desktop PC functions in the same manner as the mobile terminal 10. This also applies to second to fourth embodiments described later. When the portable terminal and the desktop PC are collectively referred to as an operation terminal.

When the electric fan 20 receives the file related to the environmental data, the electric fan 20 extracts the wind speed data from the environmental data, and executes the rotational speed control of the motor based on the wind speed data.
There are the following types of motors.
-Brush motor-DC motor-AC motor-Brushless motor-Brushless DC motor-Switched reluctance motor-Stepping motor-Ultrasonic motor

  Currently, there are brushless DC motors in addition to DC / AC brush motors as motors used to drive fans of electric fans, air conditioners, and car air conditioners. Since a microprocessor is used to control the brushless DC motor, it is also called a digital motor by some manufacturers. Although the rotational speed control method differs depending on the motor type, the purpose of this embodiment is to control the wind speed experienced by the user, and therefore the rotational speed of the motor itself is controlled by various methods.

  For example, in a DC / AC brush motor, an applied voltage pattern corresponding to wind speed data is obtained, the applied voltage pattern is decoded, and the applied voltage to the motor is controlled, so that the measured voltage is measured by the environment measuring apparatus 1 or the like. It is also an example to reproduce the blowing at the wind speed.

  On the other hand, if the electric fan 2 has a configuration in which the fins are rotated by a brushless DC motor using a pulse modulation method (PWM), after extracting the wind speed data from the file related to the environmental data, The brushless DC motor performs a step operation in which it is converted into an electric pulse signal and mechanically interrupted by the electric pulse signal, thereby realizing reproduction of a predetermined air volume. Since the rotational speed of the brushless DC motor is proportional to the frequency of the input electric pulse signal, a wide range of rotational speeds can be realized. The brushless DC motor can be accurately controlled in an open loop by an electric pulse signal. Further, when a brush DC motor is employed, the brush DC motor is configured using a permanent magnet as a stator and a rotor, that is, a coil as an armature. Since it has a feature of generating a rotational force by switching the direction of the current flowing through the rotor, it is possible to control the rotational speed of the motor by switching the energization pattern based on the wind speed data.

  The server device 30 registers a file related to environment data transmitted from the environment measurement device 1 at a predetermined timing determined in advance or at an arbitrary timing desired by a user or a contractor in a database (hereinafter abbreviated as DB). Then, the file related to the environmental data transmitted from the mobile terminal 10 is registered in the DB. Further, when there is a file download request related to environmental data or the like from the mobile terminal 10, the requested file is read from the DB and transmitted to the mobile terminal 10. The server device 30 holds files from a plurality of environment measuring devices 1 installed at a plurality of locations in a selectable manner. At this time, a plurality of files may be classified into predetermined categories and held so as to be selectable by category.

  Control device 50 is for enabling utilization as a ventilation system concerning this embodiment also to common electric fan 40 marketed. That is, the control device 50 receives a file related to environmental data from the mobile terminal 10 or the like. Then, the wind speed data is extracted from the file to obtain the corresponding applied voltage pattern, the applied voltage pattern is decoded, and the supply voltage to the fan 40 connected to the plug (power supply terminal) is controlled. Thereby, the wind speed reproduction | regeneration by the electric fan 40 connected to the control apparatus 50 is attained. The control device 50 can control a fan that employs either a brush motor or a brushless motor. The controller 50 extracts wind speed data from a file related to environmental data, and based on the wind speed data. The number of rotations of the motor will be controlled.

  Hereinafter, the detailed configuration of each device will be further described.

(Environmental measurement device 1)
FIG. 2 shows and describes the configuration of the environment measuring apparatus 1 according to the embodiment of the present invention.

  As shown in the figure, the environment measuring apparatus 1 includes a control unit 2 that controls the whole, a measurement unit 3, a display unit 4, an operation unit 5, a communication unit 6, a storage unit 7, a power supply 8, and a power switch ( SW) 9. The control unit 2 functions as the main control unit 2a, the encoding unit 2b, the file generation unit 2c, and the display control unit 2d by reading and executing the control program stored in the storage unit 7. The measurement unit 3 includes various sensors for environmental measurement, and includes a wind speed measurement unit 3a, a temperature measurement unit 3b, a humidity measurement unit 3c, and an illuminance measurement unit 3d.

  In such a configuration, in the measurement unit 3, the wind speed measurement unit 3 a measures the wind speed and sends a wind speed signal to the control unit 2. The temperature measuring unit 3 b measures the temperature and sends a temperature signal to the control unit 2. The humidity measuring unit 3 c measures the humidity and sends a humidity signal to the control unit 2. The illuminance measuring unit 3d measures the illuminance and sends an illuminance signal to the control unit 2. In the control unit 2, when these analog signals are received, the encoding unit 2b encodes (digitizes) the signals and converts them into wind speed data, temperature data, humidity data, and illuminance data, respectively. Then, the file generation unit 2c collects the wind speed data, temperature data, humidity data, and illuminance data as one environment file. The main control unit 2a transmits a file related to the environmental data to the mobile terminal 10 or the like via the communication unit 6. Alternatively, the main control unit 2 a transmits only the wind speed data to the electric fan 20 or the control device 50 via the communication unit 6. When the transmission destination address of the file related to the environmental data is set, the main control unit 2a can also control the address to transmit the file at a predetermined timing or the wind speed data in real time. .

  Each part of the environment measuring apparatus 1 is supplied with power from a power source 8 and can be switched ON / OFF by a power switch 9. The display control unit 2d controls the display unit 4 to display measurement values and the like related to environmental data. In addition, the operation unit 5 performs various operations such as selecting a measurement target from the units 3 a to 3 d of the measurement unit 3. The selected content may be displayed on the display unit 4 under the control of the display control unit 2d.

  The communication unit 6 is connected to the mobile terminal 10 by various communication methods including Bluetooth (registered trademark) (IEEE802.151), Wi-Fi (IEEE802.11), Ethernet (registered trademark) (IEEE802.3), and the like. And communication with the server device 30, the control device 50, and the electric fan 20.

(Mobile terminal 10)
FIG. 3 shows and describes the configuration of the mobile terminal 10 according to the embodiment of the present invention.

  As shown in the figure, the mobile terminal 10 includes a control unit 11 that controls the entire terminal, a communication unit 12, an operation unit 13, a display unit 14, and a storage unit 15. The control unit 11 functions as the main control unit 11a, the file registration / acquisition unit 11b, the reproduction unit 11c, and the display control unit 11d by reading and executing the control program stored in the storage unit 15. The operation unit 13 and the display unit 14 may be integrally configured with a touch panel.

  In such a configuration, when the communication unit 12 receives a file related to environmental data sent from the environmental measurement device 1, in the control unit 11, the main control unit 11 a sends the file to the electric fan 20 via the communication unit 12. Alternatively, it is transferred to the control device 50. The file registration unit / acquisition unit 11 b uploads a file related to environment data sent from the environment measurement device 1 to the server device 30. The file registration unit / acquisition unit 11 b downloads a desired file from files related to a plurality of environment data managed by the server device 30. When a file related to a plurality of environment data is already stored in the storage unit 15, a file name or the like is displayed on the display unit 14 so as to be selectable, and when one is selected by the operation of the operation unit 13, the playback unit 11 c The file is selected from the storage unit 15, and the main control unit 11 a transmits the file to the electric fan 20 or the control device 50 via the communication unit 12.

  The communication unit 12 uses the various types of communication methods including Bluetooth (registered trademark) (IEEE802.151), Wi-Fi (IEEE802.11), Ethernet (registered trademark) (IEEE802.3), etc. Communication with the control device 50 and the electric fan 20 is possible.

(Fan 20)
FIG. 4 shows and describes the configuration of the electric fan 20 according to the embodiment of the present invention.

  As shown in the figure, the electric fan 20 includes a control unit 21 that performs overall control, a communication unit 22, a storage unit 25, an operation unit 26, a motor 23, and fins 24. The control unit 21 reads out and executes the control program stored in the storage unit 25 to thereby execute a main control unit 21a, a data extraction unit 21b, an air volume control unit 21f (a conversion unit 21c, a decoding unit 21c, and a motor drive control unit 21e). Function as.

  In such a configuration, the communication unit 22 receives a file related to environment data transmitted from the mobile terminal 10 or the like under the control of the main control unit 21a. The data extraction unit 21b extracts wind speed data from the file. The air volume control unit 21f controls the air volume by controlling the rotation speed of the motor 23 based on the wind speed data. When an AC / DC brush motor is adopted as the motor 23, the rotation speed is controlled by the applied voltage. That is, the conversion unit 21c converts the wind speed data into the applied voltage pattern with reference to the table related to the applied voltage pattern stored in the storage unit 25. The decoding unit 21e converts the digital applied voltage pattern into an analog applied voltage pattern signal. The motor drive control unit 21e controls the applied voltage to the motor 23 based on the applied voltage pattern signal. As a result, the motor 23 rotates the fins 24 at a predetermined number of rotations, and the blowing at the wind speed corresponding to the wind speed data is reproduced.

  When only the wind speed data is transmitted from the environment measuring apparatus 1 or the like, the communication unit 22 receives the wind speed data under the control of the main control unit 21a. The converter 21c converts the wind speed data into an applied voltage pattern signal. The motor drive control unit 21e controls the applied voltage to the motor 23 based on the applied voltage pattern signal. As a result, the motor 23 rotates the fins 24 at a predetermined number of rotations, and the blowing at the wind speed corresponding to the wind speed data is reproduced.

  The communication unit 22 uses various communication methods including Bluetooth (registered trademark) (IEEE802.151), Wi-Fi (IEEE802.11), Ethernet (registered trademark) (IEEE802.3), etc. Communication with the measuring apparatus 1 or the like is possible.

  When a brushless DC motor is employed as the motor 23, the conversion unit 21c converts the wind speed data into an electric pulse signal. The motor drive control unit 21e controls the rotation speed of the motor 23 based on the electric pulse signal. As a result, the motor 23 rotates the fins 24 at a predetermined number of rotations, and the blowing at the wind speed corresponding to the wind speed data is reproduced.

(Server device 30)
FIG. 5 shows and describes the configuration of the server device 30 according to the embodiment of the present invention.

  As shown in the figure, the server device 30 includes a control unit 31 that controls the entire device, a communication unit 32, a DB 33, a DB 34, and a storage unit 35. The control unit 31 functions as the main control unit 31a, the file registration unit 31b, and the file extraction unit 31c by reading and executing the control program stored in the storage unit 35.

  In such a configuration, when the communication unit 32 receives a file related to environment data uploaded from the mobile terminal 10 or the like, the file registration unit 31b of the control unit 31 registers the file in the DB 33. In the DB 33, in addition to environmental data such as temperature (° C.), humidity (%), illuminance (lux), and wind speed, data such as date and time, comments, latitude and longitude of the measurement location are also stored as a file 33a. Has been. The file format and the underlying data are not limited to this. On the other hand, when there is a download request from the mobile terminal 10 or the like, the communication unit 32 receives the request, and the file extraction unit 31c of the control unit 31 extracts the requested file from the DB 33. The main control unit 31a transmits the file to the mobile terminal 10 or the like via the communication unit 32. The DB 34 stores a file 34a related to the applied voltage pattern table. This is a table used when a general electric fan 40 is controlled via the control device 50. The table is such that an applied voltage pattern corresponding to the wind speed data can be calculated for each model of the electric fan 40.

(Control device 50)
FIG. 6 shows the configuration of the control device 50 according to the embodiment of the present invention. The control device 50 is an indirect unit that makes it possible to reproduce the air flow at the wind speed based on the environmental data measured by the environment measuring device 1 even for a general electric fan 40.

  As shown in the figure, the control device 50 includes a control unit 51 that controls the entire device, a communication unit 52, a storage unit 53, and a plug (voltage supply terminal) 54. The control unit 51 functions as a main control unit 51a, a data extraction unit 51b, a conversion unit 51c, a decoding unit 51d, and a voltage control unit 51e by reading and executing the control program stored in the storage unit 53. A power outlet of a general electric fan 40 is inserted into the voltage supply terminal 54.

  In such a configuration, when the communication unit 52 receives a file related to environmental data sent from the mobile terminal 10 or the like, in the control unit 51, the data extraction unit 51b extracts wind speed data from the file. Then, the conversion unit 51 c refers to the table stored in the storage unit 53 and converts the wind speed data into an applied voltage pattern. Subsequently, the decoding unit 51d converts the digital applied voltage pattern into an analog applied voltage pattern signal. And the voltage control part 51e controls the voltage supplied to the electric fan 40 through the plug 54 based on an applied voltage pattern signal. Thereby, in the electric fan 40, a motor is rotated by the voltage supplied via the plug 54, and the ventilation at the wind speed corresponding to wind speed data is reproduced.

  When only the wind speed data is transmitted from the environment measuring apparatus 1 or the like, the communication unit 52 receives the wind speed data. The converter 51c converts the wind speed data into an applied voltage pattern. The voltage control unit 51e controls the voltage supplied to the electric fan 40 through the plug 54 based on the applied voltage pattern signal. Thereby, in the electric fan 40, a motor is rotated by the voltage supplied via the plug 54, and the ventilation at the wind speed corresponding to wind speed data is reproduced.

  The control device 50 can control a fan that employs either a brush motor or a brushless motor. The controller 50 extracts wind speed data from a file related to environmental data, and based on the wind speed data. Controls the motor speed.

(Control of applied voltage)
Here, with reference to FIG.7 and FIG.8, the relationship between the wind speed data in an AC / DC brush motor and an applied voltage pattern is further mentioned. Due to the inertia of the fins of the electric fan 20, it takes time to rise to a desired wind speed even when a voltage is applied to the motor 23 of the electric fan 20. Similarly, even when the application of voltage to the motor 23 is stopped, it takes time until the wind speed falls.

  That is, for example, even if a voltage is applied based on the applied voltage pattern as shown in the upper part of FIG. 7, the wind speed is completely zero until the desired wind speed is reached, as shown in the lower part of FIG. There will be a time lag before falling. Therefore, in this embodiment, the applied voltage pattern is set as shown in FIG. 8 to solve the time lag problem.

  That is, as shown in FIG. 8, when the slope related to the time change of the wind speed related to the wind speed data to be reproduced is a time change controlled by ON / OFF of the normal voltage, that is, the slope is steeper than the slope, A higher voltage than usual is applied for a predetermined time to speed up the wind speed. On the other hand, when it is necessary to stop the wind speed in a short time, a voltage having the opposite polarity is applied to the motor 23 and the brake is applied. In this control, the wind speed data is prefetched and the control after the present time is performed in advance. Since the data related to the applied voltage pattern corresponding to the wind speed data differs for each model depending on the motor 23 such as the electric fan 20 and the fins 24, the data is stored in the storage unit 25 for each model in a table format.

  When the control device 50 is used, the mobile terminal 10 transmits a table relating to the applied voltage pattern of the corresponding model together as a file to the control device 50. In the control device 50, a table related to the applied voltage pattern is stored in the storage unit 53 and used for conversion. The portable terminal 10 can download a table related to the applied voltage pattern for each model of the fan from the server 30. The applied voltage pattern for each electric fan model can be uploaded to a server by a trader or a user. The control of the applied electric pattern in these brush motors is similarly performed by controlling the frequency of the electric pulse signal to the motor by the microprocessor in the brushless motor.

(Processing flow related to wind speed reproduction)
Hereinafter, with reference to FIG. 9 thru | or FIG. 16, the flow of the process which concerns on the ventilation reproduction by the ventilation system of embodiment is demonstrated in detail.

  First, with reference to the flowchart of FIG. 9, the flow of processing between the environment measuring apparatus 1, the portable terminal 10, and the electric fan 20 will be described in detail.

  When this process is started, the environment measuring device 1 first performs environment measurement (S1). More specifically, in the measurement unit 3, the wind speed measurement unit 3 a measures the wind speed and sends a wind speed signal to the control unit 2. The temperature measuring unit 3 b measures the temperature and sends a temperature signal to the control unit 2. The humidity measuring unit 3 c measures the humidity and sends a humidity signal to the control unit 2. The illuminance measuring unit 3d measures the illuminance and sends an illuminance signal to the control unit 2. However, only a part of the measurement units may function.

  In the control unit 2, when these analog signals are received, the encoding unit 2b encodes these signals and converts them into wind speed data, temperature data, humidity data, and illuminance data (S2). Then, the file generation unit 2c collects the wind speed data, temperature data, humidity data, and illuminance data as environmental data into one file (S3). The main control unit 2a transmits a file related to the environmental data to the mobile terminal 10 or the like via the communication unit 6 (S4). This file always includes wind speed data, but may not include some other data.

  In the mobile terminal 10, when the control unit 11 receives a file related to the environmental data from the environmental measurement device 1 via the communication unit 12 (S 5), whether or not the main control unit 11 a uploads the file to the server device 30. Is determined (S6). For example, when uploading a file related to the environment file to the server device 30 on the predetermined screen displayed on the display unit 14 of the mobile terminal 10 (YES in S5), the file registration / acquisition unit 11b of the control unit 11 is selected. Uploads the file to the server device 30 (S7). On the other hand, when not uploading, step S7 is skipped and it progresses to step S8.

  Subsequently, the main control unit 11 of the portable terminal 10 determines whether or not the fan 20 reproduces the air at a predetermined wind speed based on the file related to the environmental data (S8). Here, for example, when the operation by the operation unit 13 is performed on a predetermined screen displayed on the display unit 14 and reproduction based on a file related to desired environment data is selected (YES in S8), the reproduction unit 11c The file is transmitted to the electric fan 20 via the communication unit 12 (S9).

  In the electric fan 20, when the communication unit 22 receives a file related to environmental data sent from the portable terminal 10 (S10), in the control unit 21, the data extraction unit 21b extracts wind speed data from the file (S11). And the conversion part 21c refers to the table memorize | stored in the memory | storage part 25, and converts wind speed data into an applied voltage pattern (S12). Subsequently, the decoding unit 21e converts the digital applied voltage pattern into an analog applied voltage pattern signal (S13). Then, the motor drive control unit 21e controls the applied voltage to the motor 23 based on the applied voltage pattern signal (S14). As a result, the motor 23 rotates the fins 24 at a predetermined number of rotations, and the blowing at the wind speed corresponding to the wind speed data is reproduced.

  When the electric fan 20 employs a brushless DC motor as the motor 23, the conversion unit 21c converts the wind speed data into an electric pulse signal instead of the above process (S12). Subsequently, the motor drive control unit 21e may control the rotational speed of the motor 23 based on the electric pulse signal (S13, S14). As a result, the motor 23 rotates the fins 24 at a predetermined number of rotations, and the blowing at the wind speed corresponding to the wind speed data is reproduced.

  With the above, a series of processes from the environment measurement by the environment measurement apparatus 1 to the wind speed regeneration in the electric fan 20 is completed.

  Next, with reference to the flowchart of FIG. 10, the flow of processing between the environment measuring apparatus 1 and the electric fan 20 will be described in detail.

  When this process is started, the environment measuring device 1 first performs environment measurement (S21). More specifically, in the measurement unit 3, the wind speed measurement unit 3 a measures the wind speed and sends a wind speed signal to the control unit 2.

  In the control unit 2, when these wind speed signals are received, the encoding unit 2b encodes these signals and converts them into wind speed data (S22). Then, the main control unit 2a transmits the wind speed data to the mobile terminal 10 or the like via the communication unit 6 (S23).

  In the electric fan 20, when the communication unit 22 receives the wind speed data transmitted from the mobile terminal 10 under the control of the main control unit 21a (S24), the conversion unit 21c of the control unit 21 is stored in the storage unit 25. The wind speed data is converted into the applied voltage pattern with reference to the table (S25). Subsequently, the decoding unit 21e converts the digital applied voltage pattern into an analog applied voltage pattern signal (S26). The motor drive control unit 21e controls the applied voltage to the motor 23 based on the applied voltage pattern signal (S27). As a result, the motor 23 rotates the fins 24 at a predetermined number of rotations, and the blowing at the wind speed corresponding to the wind speed data is reproduced.

  In addition, when the electric fan 20 employ | adopts a brushless DC motor as the motor 23, it replaces with the said process and the conversion part 21c converts wind speed data into an electric pulse signal (S25). Subsequently, the motor drive control unit 21e may control the rotational speed of the motor 23 based on the electric pulse signal (S26, S27). As a result, the motor 23 rotates the fins 24 at a predetermined number of rotations, and the blowing at the wind speed corresponding to the wind speed data is reproduced.

  With the above, a series of processes from the environment measurement by the environment measurement apparatus 1 to the blast regeneration in the electric fan 20 is completed.

  Next, with reference to the flowchart of FIG. 11, the flow of processing between the server device 30, the mobile terminal 10, and the electric fan 20 will be described in detail. Here, the description will be made with reference to the screen configuration examples of FIGS.

  When this process is started, the mobile terminal 10 first requests the server device 30 to download a file related to environmental data (S31).

  More specifically, the mobile terminal 10 obtains predetermined authentication, accesses a Web site provided by the server device 30, receives data related to the download screen via the communication unit 12, and receives the data from the display control unit 11d. Under the control, a download screen as shown in FIG. 12 is displayed on the display unit 14. In the screen configuration example of FIG. 12, on the screen 100, an area 101 displays an image related to the reproduction environment, and an area 102 displays a file registration date and title related to the environment data. A selection button 103 for selecting a desired file is also provided. When the selection button 103 is selected by operating the operation unit 13 from this display and a desired file is selected, a detailed screen as shown in FIG. 13 is displayed. In the detail screen 110 of FIG. 13, an image relating to the selected file is displayed in the area 111, the registration date and time and the title of the selected file are displayed in the area 112, and environmental data, images, movies, sounds, etc. are displayed in the area 113. A list of downloadable files is displayed. A download button 114 for downloading a desired one of the files is provided for each file. For example, when the file download button 114 related to the environmental data is selected, the file registration / acquisition unit 11b requests the server device 30 to download the file via the communication unit 12.

  When the server device 30 receives the download request (S32), the file extraction unit 31c extracts the corresponding file from the DB 33 (S33), and the file is portable via the communication unit 32 under the control of the main control unit 31a. It transmits to the terminal 10 (S34).

  In the mobile terminal 10, when the control unit 11 receives a file related to the environmental data from the server device 30 via the communication unit 12 (S35), the main control unit 11a of the mobile terminal 10 is based on the file related to the environmental data. It is determined whether or not the fan 20 at a predetermined wind speed is regenerated by the fan 20 (S36). At this time, a screen 120 as shown in FIG. 14 may be displayed on the display unit 14 so that a desired file can be selected. That is, on this screen 120, an image relating to environmental data is displayed in the area 121, and a file registration date and title and a title are displayed in the area 122. The reproduction of a desired file can be selected by selecting the reproduction button 123.

  When an operation by the operation unit 13 is performed on the screen 120 displayed on the display unit 14 and the reproduction button 123 based on a file related to desired environment data is selected (YES in S36), the reproduction unit 11c reads the file. Then, it is transmitted to the electric fan 20 via the communication unit 12 (S37).

  In the electric fan 20, when the communication unit 22 receives a file related to the environmental data sent from the portable terminal 10 (S38), the data extraction unit 21b of the control unit 21 extracts wind speed data from the file (S39). And the conversion part 21c refers to the table memorize | stored in the memory | storage part 25, and converts wind speed data into an applied voltage pattern (S40). Subsequently, the decoding unit 21e converts the digital applied voltage pattern into an analog applied voltage pattern signal (S41). The motor drive control unit 21e controls the applied voltage to the motor 23 based on the applied voltage pattern signal (S42). As a result, the motor 23 rotates the fins 24 at a predetermined number of rotations, and the blowing at the wind speed corresponding to the wind speed data is reproduced.

  When the electric fan 20 employs a brushless DC motor as the motor 23, the converter 21c converts the wind speed data into an electric pulse signal instead of the above process (S40). Subsequently, the motor drive control unit 21e may control the rotation speed of the motor 23 based on the electric pulse signal (S41, S42). As a result, the motor 23 rotates the fins 24 at a predetermined number of rotations, and the blowing at the wind speed corresponding to the wind speed data is reproduced.

  With the above, a series of processes from file download from the server device 30 by the portable terminal 10 to wind speed reproduction on the electric fan 20 is completed.

  During the reproduction, a screen 130 as shown in FIG. 15 may be displayed on the display unit 14 of the mobile terminal 10. This is based on the assumption that the environment measuring apparatus 1 is located in the playback environment, but an image showing the file being played is displayed in the area 131 of the screen 130, and the file registration date and time and the area 132 below it are displayed. The title and current (latitude, longitude) are displayed. Further, in the lower area 134, the comparison between the data environment and the current environment is displayed for the temperature, humidity, and illuminance. By this comparison, the feasibility of reproduction can be confirmed visually. In addition, by showing such a display to the user, it is possible to prompt the user to operate another device such as an air conditioner, a lighting device, or a humidifier in order to improve reproducibility.

  Next, with reference to the flowchart of FIG. 16, the flow of processing between the server device 30, the portable terminal 10, and the control device 50 will be described in detail.

  When this process is started, the portable terminal 10 first requests the server device 30 to download a file related to environmental data and a file of an applied voltage pattern table corresponding to a change in wind speed data corresponding to the fan 40 (S51). ).

  Upon receiving the download request (S52), the server device 30 extracts the file 33a related to the corresponding environmental data from the DB 33, and extracts the file 34a related to the applied voltage pattern table from the DB 34 (S53). The main control unit 31a transmits these files to the mobile terminal 10 via the communication unit 32 (S54).

  In the portable terminal 10, when the control unit 11 receives the file 33 a related to the environmental data and the file 34 a related to the applied voltage pattern table from the server device 30 via the communication unit 12 (S 55), the main control unit 11 of the portable terminal 10. Determines whether or not to regenerate the fan 40 with a predetermined wind speed based on the file 33a relating to the environmental data (S56). When reproducing (YES in S56), the reproducing unit 11c transmits the files 33a and 34a to the control device 50 via the communication unit 12 (S57).

  In the control device 50, when the communication unit 52 receives the file 33a related to the environmental data and the file 34a related to the applied voltage pattern table transmitted from the portable terminal 10 under the control of the main control unit 51a (S58), the control unit 50 performs control. The data extraction unit 51b of the unit 51 extracts the wind speed data from the file 33a (S59). Then, the converter 51c converts the wind speed data into an applied voltage pattern with reference to the applied voltage pattern table in the file 34a (S60). The decoding unit 51d converts the digital applied voltage pattern into an analog applied voltage pattern signal (S61). The voltage control unit 51e controls the applied voltage to the electric fan 40 via the plug 54 based on the applied voltage pattern signal (S42). As a result, the motor of the electric fan 40 rotates the fins at a predetermined rotational speed, and the air blowing at the wind speed corresponding to the wind speed data is reproduced.

  When the electric fan to be controlled adopts a brushless DC motor as the motor 23, the conversion unit 21c converts the wind speed data into an electric pulse signal instead of the above process (S60). Subsequently, the motor drive control unit 21e may control the rotation speed of the motor 23 based on the electric pulse signal (S61, S62). As a result, the motor 23 rotates the fins 24 at a predetermined number of rotations, and the blowing at the wind speed corresponding to the wind speed data is reproduced.

  Thus, a series of processes from file download from the server device 30 by the mobile terminal 10 to wind speed reproduction in the electric fan 40 via the control device 50 is completed.

(Second Embodiment)
2nd Embodiment of this invention implement | achieves air volume reproduction by the electric fan using a brushless DC motor.

  FIG. 17 shows a configuration example of an electric fan using a brushless DC motor.

  As shown in the figure, the electric fan 70 includes a control unit 71 that performs overall control, a communication unit 72, a storage unit 75, an operation unit 76, a brushless DC motor 73, and fins 74. The control unit 71 reads and executes the control program stored in the storage unit 75, thereby functioning as a main control unit 71a, a data extraction unit 71b, and a rotation speed control unit 71c.

  In such a configuration, the communication unit 72 receives a file related to environment data transmitted from the mobile terminal 10 or the like under the control of the main control unit 71a. The data extraction unit 71b extracts wind speed data from the file. The rotation speed control unit 71c controls the rotation speed of the brushless DC motor 73 based on the wind speed data. More specifically, reproduction of a predetermined air volume is realized by converting the wind speed data into an electric pulse signal and performing a step operation mechanically interrupted by the electric pulse signal by the brushless DC motor. As a result, the brushless DC motor 73 rotates the fins 74 at a predetermined rotational speed, and air blowing at the wind speed corresponding to the wind speed data is reproduced.

  When only the wind speed data is transmitted from the environment measuring apparatus 1 or the like, the communication unit 72 receives the wind speed data under the control of the main control unit 71a. The rotation speed control unit 71c controls the rotation of the brushless DC motor 73 based on the wind speed data. As a result, the motor 73 rotates the fins 74 at a predetermined number of revolutions, and the blowing at the wind speed corresponding to the wind speed data is reproduced.

  The communication unit 72 is connected to the mobile terminal 10 or the environment by various communication methods including Bluetooth (registered trademark) (IEEE802.151), Wi-Fi (IEEE802.11), Ethernet (registered trademark) (IEEE802.3), and the like. Communication with the measuring apparatus 1 or the like is possible.

  In the case of controlling such a fan 70, in FIG. 9, instead of the process described above, the rotation speed control unit 71c controls the rotation speed of the motor 73 based on the wind speed data (S12, S13, S14). As a result, the motor 73 rotates the fins 74 at a predetermined number of revolutions, and the blowing at the wind speed corresponding to the wind speed data is reproduced.

  In FIG. 10, instead of the above-described processing, the rotation speed control unit 71c controls the rotation speed of the brushless DC motor 73 based on the wind speed data (S25, S26, S27). As a result, the brushless DC motor 73 rotates the fins 74 at a predetermined rotational speed, and air blowing at the wind speed corresponding to the wind speed data is reproduced.

  In FIG. 11, instead of the above-described processing, the rotation speed control unit 71c controls the rotation speed of the brushless DC motor 73 based on the wind speed data (S40, S41, S42). As a result, the brushless DC motor 73 rotates the fins 74 at a predetermined rotational speed, and air blowing at the wind speed corresponding to the wind speed data is reproduced.

  In FIG. 16, instead of the above-described processing, the rotation speed control unit 71c controls the rotation speed of the brushless DC motor 73 based on the wind speed data (S60, S61, S62). As a result, the brushless DC motor 73 rotates the fins 74 at a predetermined rotational speed, and air blowing at the wind speed corresponding to the wind speed data is reproduced.

(Third embodiment)
The second embodiment of the present invention realizes air volume reproduction by an air conditioner device (hereinafter abbreviated as an air conditioner).

  FIG. 18 shows an example of the configuration of an air conditioner.

  As shown in the figure, the electric fan 80 includes a control unit 81 that performs overall control, a communication unit 82, a blower unit 83, a storage unit 84, an operation unit 85, and a blower unit 83. The control unit 81 functions as a main control unit 81a, a data extraction unit 81b, and an air volume control unit 81c by reading and executing the control program stored in the storage unit 84.

  In such a configuration, the communication unit 82 receives a file related to environment data transmitted from the mobile terminal 10 or the like under the control of the main control unit 81a. The data extraction unit 81b extracts wind speed data from the file. The air volume control unit 81c controls the air volume of the air blown by the air blowing unit 83 based on the wind speed data. The air blowing at the wind speed corresponding to the wind speed data is reproduced.

  When only the wind speed data is transmitted from the environment measuring apparatus 1 or the like, the communication unit 82 receives the wind speed data under the control of the main control unit 81a. The air volume control unit 81c controls the air volume of the air blown by the air blowing unit 83 based on the wind speed data. Thereby, the ventilation at the wind speed corresponding to the wind speed data is reproduced.

  The communication unit 82 uses various communication methods including Bluetooth (registered trademark) (IEEE802.151), Wi-Fi (IEEE802.11), Ethernet (registered trademark) (IEEE802.3), etc. Communication with the measuring apparatus 1 or the like is possible.

  In the case of controlling such an air conditioner 82, in FIG. 9, instead of the process described above, the air volume control unit 81c controls the air volume of the air blown by the air blowing unit 83 based on the wind speed data (S12, S13, S14). . Thereby, the ventilation at the wind speed corresponding to the wind speed data is reproduced.

  In FIG. 10, instead of the processing described above, the air volume control unit 81 c controls the air volume of the air blown by the air blowing unit 83 based on the wind speed data (S 25, S 26, S 27). Thereby, the ventilation at the wind speed corresponding to the wind speed data is reproduced.

  In FIG. 11, instead of the above-described processing, the air volume control unit 81 c controls the air volume of the air blown by the air blowing unit based on the wind speed data (S 40, S 41, S 42). Thereby, the ventilation at the wind speed corresponding to the wind speed data is reproduced.

  In FIG. 16, instead of the processing described above, the air volume control unit 81c controls the air volume of the air blown from the air blowing unit based on the wind speed data (S60, S61, S62). Thereby, the ventilation at the wind speed corresponding to the wind speed data is reproduced.

(Fourth embodiment)
In the fourth embodiment of the present invention, a remote operation function is added to the function of the environment measurement apparatus 1 to be used as a remote operation apparatus.

  FIG. 19 illustrates a configuration example of the remote control device. The remote operation device 90 has the functions of both the environment measurement device 1 and the portable terminal 10, and is a dedicated remote control device (remote control) for each model of the electric fan.

  As shown in the figure, the remote operation device 90 includes a control unit 91 that controls the whole, a measurement unit 92, a display unit 93, an operation unit 94, a communication unit 95, a storage unit 96, a power source 97, and a power switch (SW ) 98. The control unit 91 reads out and executes the control program stored in the storage unit 96 to thereby execute a main control unit 91a, an encoding unit 91b, a file generation unit 91c, a display control unit 91d, a file registration unit 91e, and a reproduction unit 91f. Function. The measuring unit 92 includes various sensors for environmental measurement, and includes a wind speed measuring unit 92a, a temperature measuring unit 92b, a humidity measuring unit 92c, and an illuminance measuring unit 92d. Note that the remote control device 90 can also be realized with a configuration that does not include the measurement unit 92.

  In such a configuration, in the measuring unit 92, the wind speed measuring unit 92 a measures the wind speed and sends a wind speed signal to the control unit 91. The temperature measuring unit 92 b measures the temperature and sends a temperature signal to the control unit 91. The humidity measuring unit 92 c measures the humidity and sends a humidity signal to the control unit 91. The illuminance measuring unit 92d measures the illuminance and sends an illuminance signal to the control unit 91. In the control unit 91, when these analog signals are received, the encoding unit 91b encodes (digitizes) the signals and converts them into wind speed data, temperature data, humidity data, and illuminance data, respectively. Then, the file generation unit 91c collects the wind speed data, temperature data, humidity data, and illuminance data as one environment file. The main control unit 91a transmits the file related to the environmental data to the electric fan 20 via the communication unit 95. Alternatively, the main control unit 91a transmits only the wind speed data to the electric fan 20 or the like via the communication unit 95.

  When the transmission destination address of the file related to the environmental data is set, the main control unit 91a can also control the file to transmit the file at a predetermined timing or the wind speed data in real time to the address. .

  The file registration unit 91e can register a file related to the environment data generated by the file generation unit 91c in the server device 30. In addition, the playback unit 91 f can read and play a file that has already been registered from the server device 30. Here, the reproduction means that the file is transmitted to the electric fan 20 or the like, thereby realizing blowing by the air volume related to the environmental data of the file.

  Each part of the remote control device 90 is supplied with power from a power source 97 and can be switched ON / OFF by a power switch 98. The display control unit 91 controls the display unit 93 to display measurement values and the like related to environmental data. In addition, the operation unit 94 performs various operations such as selecting a measurement target from each of the units 92a to 92d of the measurement unit 92 and selecting a file related to environmental data to be reproduced by the electric fan 20 or the like. is there. The selected content may be displayed on the display unit 94 under the control of the display control unit 91d.

  The communication unit 6 uses, for example, various control methods including Bluetooth (registered trademark) (IEEE802.151), Wi-Fi (IEEE802.11), Ethernet (registered trademark) (IEEE802.3), etc. Communication with the electric fan 20 or the like is possible.

  With the above-described configuration, the remote operation device 90 measures the various environmental data, generates a file related to the environmental data, uploads the file to the server device 30, and further reproduces the file already registered in the server device 30. Realization of air blowing at 20 etc. is possible. Further, depending on the user's request, the measuring unit 92 may be excluded, and in addition to general remote control functions such as power ON / OFF of the fan and wind speed control, a format in which only transmission / reception of environmental data files is conceivable.

  As described above, according to the present invention, the environmental measurement device can collect environmental data such as wind speed at a location desired by the user, and based on the files related to the environmental data, the fan can be used at the same wind speed afterwards. Can be realized. Alternatively, if the environment measuring device is installed in the selected environment, it is possible to realize air blowing at the same wind speed as the wind speed at the installation location in real time or afterwards, while being remote. By downloading the global environmental data collected by the user to the server, it is possible to experience air blowing at the same wind speed at the desired date and time and location.

  Further, if the control device is utilized as an indirect unit, the same air regeneration can be performed even when a general commercially available fan is used. In addition, since the file related to the environmental data collected by the environmental measurement device is registered in the server device and can be downloaded by a portable terminal or the like, the user can download the file related to the environmental data in a desired place or the like. It is possible to regenerate the air based on the environmental data at any time.

  The embodiment of the present invention has been described above, but the present invention is not limited to this, and various improvements and modifications can be made without departing from the spirit of the present invention. For example, the electric fan is not limited to a type in which the fins are driven by the driving force of the motor and the air is blown by turning the fins, and the fins are driven by a motor housed in a predetermined housing. For a blower that discharges wind by the above-mentioned fin swirling from the slit of the blower section arranged at the upper part of the body, and at that time the surrounding wind also entrains the wind generated by the swirling of the fin ten times However, it is of course applicable.

  The environment measuring device may further include a function for correcting the wind speed reproduced by the electric fan. This correction function is realized as a function of the main control unit. In general, when the electric fan is disposed at a position 1 m from the position where the user is located and disposed at a position 3 m, the wind speed experienced by the fan varies depending on the rotation speed of the same motor. Therefore, by providing a correction mode in the environmental measurement device, the wind speed experienced can be made closer to the wind speed during recording.

  Hereinafter, the correction function will be further described with reference to the flowchart of FIG. Here, with reference to FIGS. 1 and 4 as appropriate, the description will be given using the same reference numerals. When the user reaches a place where he / she should be positioned in relation to the electric fan (for example, the position of a relaxing sofa), the user starts the environment measuring device 1 toward the electric fan 20 in the correction mode (S71). Then, the main control unit 2 of the environment measuring apparatus 1 continuously transmits wind speed data such that the wind speed is gradually accelerated to the electric fan 20 (S72). The electric fan receives the wind speed data in real time (S73), and performs the air volume control as described above (S74). That is, for example, if the motor is a brush DC motor, it is converted into an applied voltage pattern, the fins are rotated by the motor, and the air blowing is reproduced. On the other hand, if the motor is a brushless DC motor, it is converted into a corresponding electric pulse signal, the fins are rotated by the motor, and air is reproduced (S75). In the environment measuring apparatus 1, the wind speed measuring unit 3a measures the wind speed of the blown air (S76), and the main control unit 2a detects the current wind speed when receiving the wind speed signal (S77). If the current wind speed does not match the wind speed as the reference value, the process returns to step S72 and the above process is repeated. On the other hand, when the current wind speed matches the wind speed serving as the reference value (S78 is branched to Yes), the main control unit 2a sets the electric fan to handle the wind speed data at that time as wind speed data for realizing the reference value. A match signal is transmitted to 20 (S79). When the electric fan 20 receives this match signal (S80), the main control unit 21 stores the correspondence between the reference value and the wind speed data in the storage unit 25 as correction data (S81). Thus, the process under the correction mode is finished. Thereafter, when reproducing the wind speed, for example, if the motor is a brush DC motor, the air volume control unit 21f is stored in the storage unit 25 when the applied voltage pattern is obtained by referring to the applied voltage pattern table. Add correction data. For example, when the distance between the electric fan 20 and the user is long, the applied voltage is corrected to increase the number of rotations of the motor. Thereby, the wind speed reproduced with the electric fan 20 is adjusted so that a user's bodily sensation becomes a thing close | similar to a measured value.

  The electric fan 20 registers voltage correction values for each model in the storage unit 25 in advance for typical distances that are normally used such as 1 m, 2 m, and 3 m. When precise correction by the environment measuring device 1 is not necessary, the operation unit 26 of the electric fan 20 may be directly operated to set voltage correction for an arbitrary distance.

  The remote control device 90 including the environment measuring device 1, the portable terminal 10 linked to the environment measuring device 1, or the measuring unit 92 is configured to set the illumination intensity, the temperature and humidity setting by the air conditioner simultaneously with the air volume of the fan 20 or the air conditioner. It is also possible to control at least one of them simultaneously using the correction function described above. That is, the main control unit of the environment measuring device 1, the portable terminal 10, and the remote control device 90 continuously outputs control signals set for each device model in which the illuminance gradually increases with respect to the illuminance control type lighting apparatus. To send. The luminaire receives these control signals in real time and increases the illuminance. The measurement unit 92 of the environment measurement device 1 and the remote control device 90 stops the control of the luminaire when the illuminance specified by the file being used is reached. On the other hand, the air conditioner blows air based on at least one of the set temperature and humidity. With this function, in addition to the air volume of the fan or air conditioner corresponding to the environmental information specified in the file, the user can experience the light emission of a predetermined illuminance by the lighting fixture and the blowing of at least one of the predetermined temperature and humidity by the air conditioner. .

  In addition, by editing a wind speed information file (such as a file containing wind speed data related to environmental data) with a portable terminal or a desktop PC, that is, an operation terminal, and transmitting it to a fan or an air conditioner, the original wind desired by the user can be obtained. It is also possible to provide a pattern reproduction environment. In this case, the blower system is a blower system in which an operation terminal and a fan or an air conditioner are communicatively connected. The operation terminal includes a first communication unit that communicates with the fan, and a wind speed information file of the environment measurement device. A main control unit that controls to transmit the edited wind speed information file to the electric fan or air conditioner, and the electric fan or air conditioner drives the fins and the second communication unit that communicates with the operation terminal. And a data extraction unit that extracts wind speed data from the wind speed information file, and a control unit that controls the rotational speed of the drive unit based on the wind speed data.

  DESCRIPTION OF SYMBOLS 1 ... Environmental measurement apparatus, 2 ... Control part, 2a ... Main control part, 2b ... Encoding part, 2c ... File generation part, 2d ... Display control part, 3 ... Measurement part, 3a ... Wind speed measurement part, 3b ... Temperature measurement Part, 3c ... humidity measuring part, 3d ... illuminance measuring part, 4 ... display part, 5 ... operation part, 6 ... communication part, 7 ... storage part, 8 ... power source, 9 ... power source SW, 10 ... portable terminal, 11 ... Control unit, 11a ... main control unit, 11b ... file registration / acquisition unit, 11c ... playback unit, 11d ... display control unit, 12 ... communication unit, 13 ... operation unit, 14 ... display unit, 15 ... storage unit, 20 ... Electric fan, 21 ... control unit, 21a ... main control unit, 21b ... data extraction unit, 21c ... conversion unit, 21d ... decoding unit, 21e ... motor drive control unit, 22 ... communication unit, 23 ... motor, 24 ... fin, 25 ... Storage unit, 26 ... Operation unit, 30 ... Server, 31 ... Control unit, 31a ... Main system , 31b ... file registration part, 31c ... file extraction part, 32 ... communication part, 33 ... DB, 34 ... DB, 40 ... electric fan, 50 ... control device, 51 ... control part, 51a ... main control part, 51b ... data Extraction unit 51c Conversion unit 51d Decoding unit 51e Voltage control unit 52 Communication unit 53 Storage unit 54 Plug

Claims (3)

An air blowing system in which an environmental measuring device that collects environmental data and a fan are connected to each other in a communicable manner,
The environmental measuring device is
A measurement unit that measures at least the wind speed of the installation location;
An encoding unit for converting the wind speed signal measured by the measurement unit into wind speed data;
A file generator for generating a file including the wind speed data;
A first communication unit that transmits the file to the fan;
A first main control unit for detecting the wind speed based on the measured value;
With
The above fan is
A second communication unit that communicates with the environmental measurement device;
A drive unit for driving the fins;
A data extraction unit for extracting the wind speed data from a file including the wind speed data;
An air volume controller that controls the rotational speed of the drive unit based on the wind speed data;
A second main control unit that stores correction data in the storage unit;
A storage unit for storing correction data;
With
The environmental measurement device continuously transmits wind speed data such that the first main control unit gradually accelerates the wind speed, and the electric fan receives the wind speed data and controls the rotational speed by the air volume control unit. The environmental measurement apparatus is configured to measure the wind speed by the measurement unit, detect the current wind speed by the main control unit, and send a match signal to the fan when the current wind speed matches the reference wind speed. And when the said fan receives the said coincidence signal, the said 2nd main control part memorize | stores the correspondence of a reference value and wind speed data in the said memory | storage part as correction data, The air blower system characterized by the above-mentioned. A blower system in which a remote control device having a function of collecting environmental data and a fan are connected to be able to communicate,
The remote control device is
A measurement unit that measures at least the wind speed of the installation location;
An encoding unit for converting the wind speed signal measured by the measurement unit into wind speed data;
A file generator for generating a file including the wind speed data;
A first communication unit that transmits the file to the fan;
A first main control unit for detecting the wind speed based on the measured value;
With
The above fan is
A second communication unit that communicates with the remote control device;
A drive unit for driving the fins;
A data extraction unit for extracting the wind speed data from a file including the wind speed data;
An air volume control unit that controls the rotational speed of the drive unit based on the wind speed data;
A second main control unit that stores correction data in the storage unit;
A storage unit for storing correction data;
With
The remote control device continuously transmits wind speed data such that the first main control unit gradually accelerates the wind speed, and the electric fan receives the wind speed data and performs rotation speed control by the air volume control unit. And the remote control device measures the wind speed by the measurement unit, detects the current wind speed by the main control unit, and sends a match signal to the fan when the current wind speed matches the reference wind speed. When the fan receives the match signal, the second main control unit stores the correspondence between the reference value and the wind speed data as correction data in the storage unit. Communication with an environmental measurement device that generates a file related to environmental data including wind speed data recorded to reproduce a wind pattern and a server device that has a database for holding the file related to environmental data collected by the environmental measurement device A blower system in which an operation terminal and a fan are connected to each other in a freely communicable manner,
The operation terminal
A first communication unit that communicates with the fan;
Acquire a file related to environmental data including wind speed data from the environment measuring device and server device, edit a file including wind speed data related to environmental data in order to realize a unique wind pattern, and A main controller that controls the file to be sent to the fan;
With
The above fan is
A second communication unit that communicates with the operation terminal;
A drive unit for driving the fins;
A data extraction unit for extracting the wind speed data from the file;
A blower system comprising: a control unit that controls the number of rotations by frequency control of an electric pulse signal to the drive unit based on the wind speed data.