JP2019076525A - Indoor environment control system - Google Patents

Abstract

To provide a comfortable indoor environment appropriately by effectively using an environment device installed in an indoor space.SOLUTION: An indoor environment control system includes: environment information acquisition means 1 for acquiring environment information of an indoor space R to be a control object; constituent information acquisition means 2 for acquiring constituent information of the indoor space R, and equipment 3 including at least an environmental device 3a or 3b, installed in the indoor space R; and control means 4 having an airflow analysis part 5 for analyzing airflow patterns capable of being generated in the indoor space R, on the basis of the environment information and constituent information acquired from the information acquisition means 1, 2, and controlling an installation position and an operation condition of at least the environmental device 3a or 3b so as to obtain target airflow patterns on the basis of an analysis result by the airflow analysis part 5.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an indoor environment control system that appropriately provides a comfortable indoor environment when installing environmental devices such as an air cleaner and an air conditioner in an indoor space.

For example, Patent Documents 1 and 2 have been known as conventional indoor environment control systems of this type.
According to Patent Document 1, a gaseous or suspended particulate factor substance that affects the human body, which is contained in air before the cleaning process as a capture target different from the cleaning process target by the cleaning member, is out of the allowable range. And a capture member, the capture member being removably mounted on the cleaner body and disposed separately from the cleaning member for cumulatively collecting the gaseous or suspended particulate matter material An air cleaning member which is a collecting member and is temporarily removed from the main body of the cleaning apparatus when qualitatively and quantitatively determining a factor substance collected in the collecting member in a state where the cleaning processing by the cleaning member can be performed. An air cleanliness monitoring system is disclosed that includes an apparatus and an information monitoring apparatus that manages factor material information captured by a capture member and monitors how the managed factor material information is.
Patent Document 2 discloses a recovery unit for recovering pollutants, processing agent supply means for supplying a processing agent for processing contaminants existing in the living space outside the recovery unit or in the recovery unit, and processing agent supply In the state that the treatment agent is supplied by the means, an air flow toward the recovery device is formed in the living space, and the treatment agent and the contaminants attached are put on the air flow so as to be collected in the recovery device. An airflow forming means for conveying contaminants in the living space to the recovery unit; and a disposal means for discarding the contaminants attached to the processing agent recovered by the recovery unit on the airflow formed by the airflow forming means outside the recovery unit And an air purification and maintenance system using the same.

Patent No. 5905850 (Mode for carrying out the invention, FIG. 1) JP-A-2014-110857 (Mode for carrying out the invention, FIG. 1)

  The technical problem to be solved by the present invention is to effectively use environmental equipment installed in an indoor space to appropriately provide a comfortable indoor environment.

  According to a first technical feature of the present invention, there is provided environmental information acquisition means for acquiring environmental information of an indoor space to be controlled, configuration information of equipment including the indoor space and at least environmental equipment installed in the indoor space. It has an air flow analysis unit for analyzing an air flow pattern that can be generated in the indoor space based on the configuration information acquisition means to be acquired and the environment information and the construction information acquired from the information acquisition means, and the air flow analysis unit An indoor environment control system comprising: control means for controlling at least an installation position of the environmental device and an operating condition so as to obtain a target air flow pattern based on an analysis result.

A second technical feature of the present invention is the indoor environment control system having the first technical feature, wherein the environmental information acquisition means includes at least air quality and temperature and humidity of air as environmental information of indoor space. It is an indoor environment control system characterized by things.
According to a third technical feature of the present invention, in the indoor environment control system provided with the first or second technical feature, the configuration information acquiring unit is configured as the configuration information of the indoor space, such as the shape and volume of the indoor space. And the physical and chemical characteristics of the used building materials, and at least the location and performance information of the environmental equipment as the configuration information of the equipment installed in the indoor space, and the location and occupied area information for the equipment other than the environmental equipment It is an indoor environment control system characterized by including.
According to a fourth technical feature of the present invention, in the indoor environment control system having the third technical feature, the configuration information acquisition means is capable of three-dimensional imaging in acquiring the shape and volume of the indoor space. An indoor environment control system comprising an imaging tool and a scale for specifying dimensions installed on a reference plane of an indoor space.

According to a fifth technical feature of the present invention, in the indoor environment control system provided with any one of the first to fourth technical features, the environmental device contains at least a medicine suitable for cleaning filter and contaminants in the indoor space. The control means may include, as specifications of the air cleaning device, in addition to determining the position where the target air flow pattern can be generated and the contents of the operation control program, the air cleaning device having a drug supply mechanism to supply. The indoor environment control system is characterized in that the specification of the cleaning filter and the specification of the medicine supply mechanism are also determined.
A sixth technical feature of the present invention is an indoor environment control system comprising any of the first to fourth technical features, comprising: a plurality of environmental devices capable of communicating with each other in the indoor space; The means is an indoor environment control system characterized in that a condition under which a plurality of environmental devices cooperate with each other is determined in advance, and the plurality of environmental devices communicate with each other and are operated in cooperation with each other.
According to a seventh technical feature of the present invention, in the indoor environment control system having any one of the first to fourth technical features, the indoor space includes one or more environmental devices, and the environmental devices The environmental information acquisition means capable of acquiring environmental information in real time is mounted, and the control means real-time at least the operating conditions of the environmental device based on a change in environmental information from the environmental information acquisition means mounted in the environmental device. It is an indoor environment control system characterized by controlling by.
According to an eighth technical feature of the present invention, in the indoor environment control system having any one of the first to seventh technical features, the control means acquires the environmental information acquisition means and the configuration information acquisition means. The main control device executes the analysis by the air flow analysis unit based on the respective information, and determines the position and the operating condition of the environmental device based on the analysis result by the air flow analysis unit, and the main control device Indoor environment control characterized by receiving specification information including at least an installation position of the environmental device and operating conditions, and installing an operation control program based on the specification information into the corresponding environmental device. It is a system.
According to a ninth technical feature of the present invention, in the indoor environment control system having the eighth technical feature, the indoor space includes one or more environmental devices, and the environmental devices obtain environmental information in real time And the operation control program installed in the environmental device is updated based on a change in environmental information from the environmental information acquisition means mounted in the environmental device. It is an indoor environment control system.

According to the first technical feature of the present invention, environmental equipment installed in the indoor space can be effectively used to appropriately provide a comfortable indoor environment.
According to the second technical feature of the present invention, it is possible to obtain necessary and sufficient environmental information in controlling the indoor environment optimum for the person staying in the indoor space.
According to the third technical feature of the present invention, when selecting a target air flow pattern in an indoor space, necessary configuration information of the indoor space and configuration information of equipment installed in the indoor space are acquired. be able to.
According to the fourth technical feature of the present invention, it is possible to obtain the shape and volume information of the indoor space with high accuracy, as compared with the case of imaging only with a three-dimensional imaging tool.
According to the fifth technical feature of the present invention, in installing the air purification device in the indoor space, in addition to the target air flow pattern, the indoor environment which can more effectively realize the improvement of the air quality in the indoor space. Can be provided.
According to the sixth technical feature of the present invention, in a mode in which a plurality of environmental devices are installed in an indoor space, by linking a plurality of environmental devices as compared with a method of individually controlling a plurality of environmental devices Efficient indoor environmental control can be realized.
According to the seventh technical feature of the present invention, after setting the optimum position and operating conditions of the environmental device in the indoor space, even if the environmental change occurs, the indoor environmental control by the environmental device according to the environmental change Can be realized in real time.
According to the eighth technical feature of the present invention, in controlling the position and operating condition of the environmental device in the indoor space, the main control device and the individual terminal share the processing by the control means, which is appropriate. The indoor environment can be provided quickly.
According to the ninth technical feature of the present invention, after installing the operation control program in the environmental device in the indoor space, even if the environment in the indoor space changes, the operation control program is updated correspondingly. It is possible to easily create an indoor environment according to changes in the environment.

BRIEF DESCRIPTION OF THE DRAWINGS It is explanatory drawing which shows the outline | summary of embodiment of the indoor environment control system to which this invention was applied. FIG. 1 is an explanatory view showing an entire configuration of an indoor environment system according to a first embodiment. FIG. 2 is an explanatory view showing a configuration example of an air purifier (air purifier) used in the first embodiment. FIG. 2 is an explanatory view showing an example of a filter configuration of an air purifier used in Embodiment 1. (A) is explanatory drawing which shows the structural example 1 of the chemical | medical agent supply mechanism used in Embodiment 1, (b) is explanatory drawing which shows the structural example 2 of the chemical | medical agent supply mechanism. (A) is explanatory drawing which shows an example of the three-dimensional imaging method of indoor space used by Embodiment 1, (b) is explanatory drawing which shows the principal part. (A) is explanatory drawing which shows an example of the method of measuring the air quality of the indoor space used in Embodiment 1, (b) is explanatory drawing which shows the extraction process of the cartridge for analysis. FIG. 6 is an explanatory view showing control step (1) of the indoor environment control system according to the first embodiment. (A) is an explanatory view showing an example of an air flow pattern obtained under the condition that an air purifier is installed at a corner of an indoor space by air flow analysis in control step (1) shown in FIG. 8; (b) is the same air flow It is explanatory drawing which shows the example of an air flow pattern obtained by the conditions by which analysis was installed in the center part of one side of indoor space by the air cleaner. FIG. 6 is an explanatory view showing a control step (2) of the indoor environment control system according to Embodiment 1. FIG. 6 is an explanatory view showing control step (3) of the indoor environment control system according to the first embodiment. (A)-(c) is an explanatory view showing an example of various functions of an individual terminal used in a 1st embodiment. FIG. 8 is an explanatory view showing the main parts of an indoor environment control system according to a second embodiment. FIG. 14 is an explanatory view showing the main parts of an indoor environment control system according to a third embodiment. FIG. 18 is an explanatory view showing the main parts of an indoor environment control system according to a fourth embodiment. (A) is explanatory drawing which shows the example of a utilization to the health check of the person who stays in indoor space in the form 4-1 of the deformation | transformation of Embodiment 4, (b) is suffering from a disease with some people staying in indoor space. It is an explanatory view showing an example of acquisition of living body information in case. (A) is an explanatory view showing a configuration example of the indoor environment control system according to the fifth embodiment, (b) is an enlarged explanatory view of a portion B in (a), and (c) is an indoor space in the fifth embodiment. It is explanatory drawing which shows the state which installed the air cleaner and the auxiliary fan appropriately. (A) is a schematic diagram of the airflow control experiment performed with respect to the indoor environment control system which concerns on Example 1, (b) is explanatory drawing which shows the result of the airflow control experiment, (c) is a result of (b) It is explanatory drawing which shows the example of the air flow pattern which speed vector analyzed with respect to. (A) is a schematic view of another airflow control experiment performed on the indoor environment control system according to the first embodiment, (b) is an explanatory view showing the result of the airflow control experiment, (c) is (b) It is explanatory drawing which shows the airflow pattern example which speed-vector-analyzed with respect to the result of these.

Overview of Embodiment FIG. 1 shows an overview of an embodiment of an indoor environment control system to which the present invention is applied.
In the figure, the indoor environment control system includes environmental information acquisition means 1 for acquiring environmental information of the indoor space R to be controlled, the indoor space R, and at least environmental devices 3a or 3b installed in the indoor space R. Airflow analysis for analyzing an air flow pattern that can be generated in the indoor space R based on the configuration information acquisition unit 2 for acquiring configuration information of the fixture 3 and the environment information and configuration information acquired from the respective information acquisition units 1 and 2 A control unit 4 for controlling at least the installation position of the environmental device 3a or 3b and the operating condition so as to obtain the target airflow pattern based on the analysis result by the airflow analysis unit 5; It is.

In such technical means, as long as the environmental information acquisition means 1 acquires environmental information (typically air quality, temperature and humidity, etc.) of the indoor space R, an aspect of automatically acquiring by a sensor, or Alternatively, a capture member capable of capturing an agent substance contained in the air may be removably installed, and the agent material captured by the capture member may be obtained by analysis with another analysis device.
The configuration information acquisition means 2 may be any one as long as it acquires configuration information of at least one of the indoor space R and the environmental devices 3a and 3b installed in the indoor space R. The “configuration information of the indoor space R” mentioned here includes the indoor shape as physical configuration information, the indoor capacity, and the material properties of the used building materials (interior materials) for partitioning the indoor space, etc. The configuration information of the equipment 3 installed in the indoor space includes the positions of the environmental devices 3a and 3b as the configuration information of the environmental devices 3a and 3b (for example, air conditioners, air cleaning devices, humidifiers, dehumidifiers, and ventilation devices) Performance information is included, and further, the position and occupied area information of equipment 3c (bed, desk, table, etc.) other than the environmental device is included.

Furthermore, the air flow analysis unit 5 is an element of the control means 4, and as the air flow analysis unit 5, analysis software or the like as long as it analyzes an air flow pattern that can be generated based on the acquired environment information and configuration information. It may be selected appropriately. The air flow pattern referred to herein changes depending on various parameters such as the positions of the environmental devices 3a and 3b and the blowing intensity.
In addition, as long as the control means 4 controls at least the optimum layout and operating conditions of the environmental devices 3a and 3b in order to obtain a target air flow pattern, a control program for realizing this is appropriately selected. No problem. The layout of equipment 3c other than the environmental equipment may be controlled if the position can be made variable.

Next, a representative aspect or a preferable aspect of the indoor environment control system according to the present embodiment will be described.
First, as a preferable embodiment of the environmental information acquisition means 1, as environmental information of the indoor space R, one including at least air quality and temperature and humidity of the air can be mentioned. In this example, any material that acquires at least air quality (presence or absence of pollutants) and temperature and humidity of air as environmental information may be detected by a corresponding sensor, and air quality may be detected. A part of the air sample or the interior material may be collected as a test piece and analyzed.
Moreover, as a preferable aspect of the configuration information acquisition means 2, the configuration information of the indoor space R includes the shape and volume of the indoor space R and the physical and chemical characteristics of the used building materials, and the fixtures 3 installed in the indoor space R The configuration information includes information on the position and / or performance of at least one of the environmental devices 3a and 3b, and the equipment 3c other than the environmental device includes information on the position and the occupied area. The present example shows a preferable aspect as configuration information of the indoor space R and configuration information of the fixture 3 (at least the environmental device 3a or 3b is essential) installed in the indoor space R.
Here, the physical and chemical characteristics of the used building materials are used as a consideration in determining the target air flow pattern because some materials require measures against a thick house. Moreover, it is preferable to use the position and performance information mainly affecting the generation of the air flow in the indoor space R as the configuration information of the environmental devices 3a and 3b, and the configuration information of the fixture 3c other than the environmental devices is the indoor It is preferred to use position and occupancy area information that primarily affects the path of the air flow in space.
Furthermore, as a preferable aspect of the configuration information acquiring means 2, an imaging tool capable of three-dimensional imaging (for example, a digital camera capable of three-dimensional imaging) and a reference plane of the indoor space R upon acquiring the shape and volume of the indoor space R The aspect provided with the scale for the dimension specification installed is mentioned.

In a preferred application of the indoor environment control system, the environmental device 3a or 3b supplies a drug suitable for at least a clean filter (not shown in FIG. 1) and contaminants in the indoor space R (FIG. 1). (Not shown), and the control means 4 cleans in addition to determining the position of the target air flow pattern and the content of the operation control program as the specification of the air cleaner. There is also an aspect that also determines the specifications of the filter and the specifications of the drug supply mechanism. This example shows an example of indoor environment control specialized for an air purification device.
Furthermore, as another preferable application example of the indoor environment control system, the indoor space R is provided with a plurality of environmental devices 3a and 3b that can communicate with each other, and the control unit 4 is a condition under which the plurality of environmental devices 3a and 3b cooperate. In this embodiment, the plurality of environmental devices 3a and 3b are linked and operated while communicating with each other. In this embodiment, in a mode having a plurality of environmental devices 3a and 3b in the indoor space R, energy saving control by cooperation of the environmental devices 3a and 3b can be performed by communicably connecting each other using known communication means. This is an aspect that is realized.
Furthermore, as another preferable mode of the indoor environment control system, the indoor space R is provided with one or more environmental devices 3a and 3b, and environmental information can be acquired in real time in the environmental devices 3a and 3b. The control unit 4 is mounted with the means 1, and the control means 4 controls at least the operating conditions of the environmental devices 3a, 3b in real time based on the change of the environmental information from the environmental information acquisition means 1 mounted in the environmental devices 3a, 3b. Be This example is an aspect in which the indoor environment control is performed in real time by the environmental devices 3a and 3b in a mode in which one or more environmental devices 3a and 3b are provided in the indoor space R.

Further, as a preferable mode of the control means 4, the analysis by the air flow analysis unit 5 is executed based on each information acquired from the environment information acquisition means 1 and the configuration information acquisition means 2, and the analysis result by the air flow analysis unit 5 is Receives specification information including at least the installation position and operating conditions of the environmental devices 3a and 3b determined by the main controller, and determines the specification information on the main controller for determining the positions and operating conditions of the environmental devices 3a and 3b; And a separate terminal capable of installing the operation control program based on the corresponding environmental device 3a, 3b. In this example, the main controller executes a process of determining specifications (installation position and operating conditions) of each environmental device 3a, 3b based on analysis processing and analysis by the airflow analysis unit 5, and the determined specification information is It is transferred to the individual terminal, and the individual terminal installs the operation control program based on the specification information in the corresponding environmental device 3a, 3b. Here, the operation control program may be downloaded from the main control device to the individual terminal, or may be processed by an AI program installed in the individual terminal.
Furthermore, as a preferable aspect of the operation control program, the indoor space R is equipped with one or more environmental devices 3a and 3b, and the environmental devices 3a and 3b are equipped with environmental information acquisition means 1 capable of acquiring environmental information in real time. The operation control program installed on the environmental devices 3a and 3b is updated based on the change of the environmental information from the environmental information acquisition unit 1 mounted on the environmental devices 3a and 3b. This example is an aspect in which the operation control program installed in the environmental devices 3a and 3b is automatically updated based on the change of the environmental information.

Hereinafter, the present invention will be described in more detail based on the embodiments shown in the attached drawings.
実 施 Embodiment 1
-Overall configuration of indoor environment control system-
FIG. 2 is an explanatory view showing the entire configuration of the indoor environment control system according to the first embodiment.
In the figure, when the indoor environment control system installs the air cleaner (air cleaning device) 20 as an environmental device in the indoor space R, the air quality of the indoor space R and the temperature of the air as environmental information of the indoor space R. The humidity is acquired, and as the configuration information of the indoor space R, the three-dimensional shape of the indoor space R, the volume (for example, in the case of a hollow rectangular parallelepiped indoor space, the dimensions x of two pieces of a floor surface or a top surface intersecting with each other) The calculation can be performed based on y and the height dimension z), the position of the air cleaner 20 installed in the indoor space R, performance information is acquired, and the acquired information is taken into the control device 100. The space determination unit 101 determines the environment and configuration of the indoor space R, and the air flow analysis unit 102 of the control device 100 analyzes the air flow pattern AP generated in the indoor space R, and the specifications of the control device 100. It is to determine the specification information of the air cleaner 20 at tough 103.

-Configuration of air cleaner-
In this example, as shown in FIG. 3, for example, the air cleaner 20 has a substantially box-shaped clean case 21 which is vertically elongated in the vertical direction, and one side of the clean case 21 which is directed to the indoor space R For example, a substantially rectangular intake port 22 is opened below the unit, and a substantially rectangular outlet 23 is opened at the top of the clean housing 21, and the clean housing 21 is opened from the intake port 22. A substantially L-shaped bent air flow passage 24 communicating with the discharge port 23 is formed.
Then, a louver 25 is disposed at a portion facing the intake 22 of the clean case 21, and a plurality of filter base materials including a dust filter is provided inside the louver 25 facing the intake 22 In the example, a cleaning filter 40 made of a filter substrate for removing various contaminants present in the indoor space R is detachably disposed.

Furthermore, a louver 28 is disposed at a portion facing the outlet 23 of the clean case 21, and a heat exchange unit 29 for cooling and heating is disposed midway along the air flow passage 24 of the clean case 21. The fan 30 is disposed between the louver 28 and the heat exchange unit 29 in the air flow passage 24 to form an air flow Af from the inlet 22 to the outlet 23 in the air flow passage 24. It has become.
Furthermore, a contaminant discrimination sensor 35 for discriminating contaminants existing in the indoor space R is provided on the side of the clean casing 21 on the side facing the indoor space R. An environmental sensor 36 is provided to measure the temperature and humidity of Af.
A control unit 32 is disposed in the clean case 21. The control unit 32 controls the heat exchange unit 29 and the fan 30 as normal air cleaning process in conjunction with an operation switch (not shown). When the contaminant discrimination sensor 35 detects a contaminant, the chemical solution supply mechanism 50 is controlled based on the detection signal to selectively supply the chemical solution as the treatment agent according to the contaminant. In addition, the fan 30 is started to be driven as the contaminant processing. Of course, the heat exchange unit 29 may be operated simultaneously at the time of contaminant treatment.

<Cleaning filter>
In this example, as shown in FIG. 4, the cleaning filter 40 includes, in order from the inlet 22 of the air flow passage 24, the prefilter 41, the microorganism removal filter 42, the medium performance filter 43, the gas removal filter 44, and the HEPA filter ( A High Efficiency Particulate Air Filter 45 is provided.
In the present embodiment, each of the filters 41 to 45 is detachably mounted to the airflow passage 24.
(1) Pre-filter 41
This is a coarse mesh filter that mainly captures coarse dust and the like, and is formed into a non-woven fabric using, for example, metal mesh, metal fibers, carbon fibers and the like.
(2) Microorganism removal filter 42
It mainly captures microbial particles such as bacteria, fungi and viruses, but it can also capture pollen particles similar to microbial particles and allergen particles such as mites and their feces.
(3) Medium performance filter 43
This is a mesh-like filter finer than the pre-filter 41 and mainly captures medium-sized dust and the like. For example, a metal mesh, metal fibers, carbon fibers and the like are used to form a non-woven fabric It is molded.
(4) Gas removal filter 44
This is a filter for removing gaseous pollutants of odorous substances and chemical substances, and a configuration using an adsorbent such as activated carbon, zeolite, ceramics, etc. which adsorbs odorous substances is adopted.
(5) HEPA filter 45
This is a finer mesh-like filter than the medium performance filter 43, for example, for capturing fine powder of activated carbon used in the gas removal filter 44, for example, metal mesh, metal fiber, carbon fiber Etc. and it shape | molds in the shape of a nonwoven fabric.

<Chemical solution supply mechanism>
In this example, the cleaning filter 40 is a gaseous contaminant such as, for example, microbial particles, odorous substances, chemical substances (for example, VOC: abbreviation of Volatile Organic Compounds) to be removed from the microbe removal filter 42 and the gas removal filter 44. And a chemical solution supply mechanism 50 capable of supplying a chemical solution (including a deodorant and the like) corresponding to.
As shown in FIGS. 3 and 4, the chemical solution supply mechanism 50 is a deodorant as a chemical solution corresponding to the removal of odorous substances and chemical substances (for example, a chemical solution Sa corresponding to ammonia, a chemical solution Sm corresponding to methyl mercaptan, Alternatively, mixed chemical solutions Sx corresponding to a plurality of odor substances and chemical substances including these, and a chemical solution Sw corresponding to the removal of microorganisms such as influenza virus (for example, a bactericide corresponding to sterilization of microorganisms, for preventing the growth of microorganisms And the corresponding antimicrobial agent).
Then, these chemical solutions are dispensed, for example, into the respective corresponding chemical solution bottles 51, 52, and as shown in FIGS. 3 and 5A, a constant amount of the chemical solution from each chemical solution bottle 51, 52 is pumped by the pump unit 53. It sucks and is periodically sprayed from the nozzle 54.
As shown in FIG. 5B, the supply principle of the chemical solution by the chemical solution supply mechanism 50 is such that the air supplied from the air pump 55 is throttled to a predetermined flow rate by the flow rate adjustment valve 56 and the flow meter 57 There is no problem even if it is introduced into the chemical solution in the chemical solution bottles 51 and 52 and sprayed periodically from the nozzle 54.

In the cleaning filter 40 according to the present embodiment, assuming that dust A, pollen B, fungus C, bacteria D, virus E, chemical substance F, and odor substance G are present as contaminants in air, dust A is Mainly captured by the prefilter 41, medium performance filter 43, HEPA filter 45, fungus C, bacteria D, virus E are mainly captured by the microbe removal filter 42, and further chemical F, odorant G are mainly degassed It is captured by the filter 44. The pollen B is captured by the microbe removal filter 42 or the medium performance filter 43.
Here, in the indoor environment control system according to the present embodiment, the operation of the chemical solution supply mechanism 50 will be described based on a more specific example.
In the indoor space R (see FIG. 2), for example, when a person infected with influenza virus is present near the air cleaner 20, the contaminant discrimination sensor 35 of the air cleaner 20 detects microbial particles consisting of influenza virus as a contaminant. . Then, in the air cleaner 20, the chemical solution supply mechanism 50 supplies the microorganism removal filter 42 with the chemical solution Sw corresponding to the influenza virus.
In this state, when the air purifier 20 is operated, the suction action of the fan 30 in the air purifier 20 forms an air flow Af indicated by an arrow in the indoor space R, as shown in FIG. At this time, in the vicinity of the air cleaner 20, the influenza virus is scattered in the air from the infected person of the influenza virus, but the influenza virus gets on the air flow Af described above and distributes air from the intake port 22 of the air cleaner 20. It is sucked into the passage 24. Then, the sucked influenza virus is captured by the microbe removal filter 42 impregnated with the drug solution. For this reason, clean air is released from the air purifier 20, and the influenza virus is removed from the indoor space R, and clean air spreads around.
As described above, in the present embodiment, the air cleaner 20 doubles as the contaminant recovery function, and by forming the desired air flow Af in the indoor space R, the contaminants existing in the indoor space R can be made efficient. It is possible to remove it.

-Three-dimensional measurement example of indoor space-
In this example, in order to obtain the shape and volume information of the indoor space R, a method of three-dimensionally measuring the indoor space R is employed.
In this measurement method, as shown in FIG. 6A, a support pipe 71 having a circular cross section, which is bent at an acute angle with respect to the vertical direction, near the approximate center of the floor of the indoor space R to be measured. And a pair of scales 75 serving as a reference rule on the floor surface sandwiching the support pipe 71, and as shown in FIGS. 6 (a) and 6 (b), the support pipe 71 is near the floor surface. Several measurement points P (specifically, P1... Pn) of different height dimensions are set from the top toward the top, and at each measurement point P, targets 72 are installed at three points on the outer periphery, and as a three-dimensional imaging tool The digital camera 73 is positioned on each target 72, and the indoor space R is photographed from each target 72.
As a result, by the digital camera 73 positioned on each target 72 of the support pipe 71, images of the entire area of the indoor space R can be obtained as a plurality of photographs in a state of being divided from various positions and directions.

-Analysis of air quality-
In the present embodiment, for analysis of air quality in the indoor space R, for example, as shown in FIG. 7A, in the cleaning filter 40, the particulate matter is formed in a part of filter material of the microorganism removal filter 42 or the medium performance filter 43. An analysis cartridge 81 in which the substance Wr is captured is detachably installed, and an analysis cartridge 82 in which the gaseous substance Wg is captured is detachably installed in part of the gas removal filter 44 functioning as a deodorizing filter. After a predetermined time has elapsed from the installation of the analysis cartridges 81 and 82, as shown in FIG. 7 (b), the analysis cartridge 81 from the microorganism removal filter 42 or the medium performance filter 43 is The analysis cartridge 82 is removed from the removal filter 44, and the particulate matter Wr and the gaseous matter W captured by the respective analysis cartridges 81 and 82 are removed. Was analyzed by known analytical methods, it is sufficient to diagnose the pollutants contained as air quality in the indoor space R.
Here, as a well-known analysis method, a gas chromatograph, a gas chromatograph mass spectrometer, a high performance liquid chromatograph, an ion chromatograph, etc. are adopted.

-Configuration example of control device-
In this example, as shown in FIGS. 2 and 8, the control device 100 includes a dedicated information input PC (Personal Computer) 110 and a dedicated small terminal 120.
<PC for information input>
In this example, the user inputs air quality diagnosis information and temperature / humidity information from the environment sensor 36 of the air purifier 20 based on the air quality diagnosis result to the dedicated information input PC 110.
In addition, the user takes in a dedicated information input PC 110, and takes in the shape of the indoor space R and photographic data obtained by three-dimensional measurement as volume information. Moreover, the performance information of the air cleaner 20 is taken in by inputting a model about the air cleaner 20. FIG.
In this example, the dedicated information input PC 110 includes the indoor space determination unit 101 and the air flow analysis unit 102, and the indoor space determination unit 101 can easily input three-dimensional information such as photographic data (for example, three-dimensional information) CAD software is installed, automatically analyzed by this input application, and saved as three-dimensional CAD data. Thereby, when fixtures, such as a shape of indoor space R, volume, or furniture which becomes an airflow obstruction factor, are installed, the said fixture is distinguished as a part of shape of indoor space.

In addition, an airflow analysis application is installed in the airflow analysis unit 102, and the airflow pattern AP with respect to an arbitrary installation position of the air cleaner 20 is analyzed based on the information of the shape and volume of the indoor space R. Here, the air flow pattern AP changes depending on the air blowing intensity of the air cleaner 20 and the air blowing direction from the outlet 23, and also changes depending on the installation position of the furniture such as the air flow inhibiting factor. As a result, the optimum position of the air cleaner 20 is not determined uniformly by the information on the shape and volume of the indoor space R, but is determined depending on the operating conditions of the air cleaner.
FIGS. 9A and 9B show an example of the air flow pattern AP.
Both figures also, the size of the indoor space R x × y × z: 2700 × 3600 × 2400 (mm), Equipment air volume: 400m ³ / h. Airflow velocity: 12.5 m / s, temperature: 23 ° C., relative humidity: 50%, (a) shows the air flow distribution at the installation position of the air cleaner 20 at the corner, (b) shows air purification The installation position of the machine 20 shows the airflow distribution in the central part of the side along the y direction of the floor surface.
Therefore, in analysis of the air flow pattern AP, data of various air flow patterns AP are generated depending on the presence or absence of equipment which changes the shape of the indoor space R and the operating condition of the air cleaner 20, and the shape of the indoor space R Depending on the conditions, the operating conditions of the air purifier 20, it is stored reproducibly.

<Small terminal>
In addition, the dedicated small terminal 120 has a specification determination unit 103, and a artificial intelligence program (AI program) is installed in the specification determination unit 103, and as shown in FIG. Communication with the PC 110 is enabled by communication means such as Bluetooth (registered trademark). Here, the AI program includes information input to the information input PC 110, for example, information on air quality diagnosis results, sensors installed in the air cleaner 20 (contaminant detection sensor 35, environment sensor 36), power consumption Of the dust collection filter suitable for the air purifier 20, deodorization filter, etc., type of chemical solution in the chemical solution supply mechanism 50, supply amount, supply interval, etc. A maintenance method or the like of the air cleaner 20 is determined and displayed on the display 121 (see FIG. 11).
As described above, the specification, the operating condition, the installation position, and the management content of the air purifier 20 are determined by the dedicated information input PC 110 and the dedicated small terminal 120.

In this example, for example, as shown in FIG. 10, the following items are determined.
(1) Pre-filter specification: A saran net type is determined based on air quality diagnosis results (fiber components, oil components such as tar).
(2) Dust collection filter (fiber type) specifications: Determination of HEPA (High Efficiency Particulate Air Filter) or quasi-HEPA based on air quality diagnosis results (particle diameter, type of environmental allergen, acid / basic gas), fiber material (Glass, PRE, olefin, nylon, ...) determination, determine the suitability of the electrostatic filter (electret).
(3) Dust collection filter (electrostatic collection type) specifications: Based on air quality diagnosis results, the propriety, charging voltage, dust collection voltage, etc. are determined by comparison with the fiber type.
(4) Deodorizing filter specifications: Based on air quality diagnosis results, determine the type and amount of activated carbon, pellet size, type of adhesive, amount of adhesive used, and presence or absence of dust prevention treatment.
(5) Chemical solution supply mechanism specifications: Based on the air quality diagnosis result, the selection of the liquid solution (chemical solution) (liquid agent suitable for air pollutants), the supply amount, the supply timing, the supply interval, ... is determined.
(6) Operation control program content: Based on air quality diagnosis results, indoor air flow formation by device air volume, outlet angle, etc., continuous / intermittent operation, energy saving operation, low noise operation, presence / absence of specific pollutant response operation such as pollen, etc. decide.
(7) Equipment installation method: Based on air quality diagnosis results, room shape (plane + cross section), airflow obstruction factors such as furniture, ventilation routes, installation status of other equipment (environmental equipment, equipment outside environmental equipment), etc. The installation position of the ideal air purifier in the indoor space R is determined and determined by the airflow analysis and the AI program.
(8) Equipment maintenance method: Based on the air quality diagnosis result, the maintenance content of the prefilter, the dust collection filter, the deodorizing filter, or the chemical solution supply mechanism is determined.

In particular, in the present embodiment, (7) the device installation method requires a very high-level, high-capacity application and tends to take time for processing. Therefore, in the present example, a method is adopted in which the input such as the shape of the indoor sky and the air flow analysis are performed by the dedicated information input PC 110, and the result is displayed on the dedicated small terminal 120.
On the other hand, as for the items (1) to (6) and (8), a method of processing and displaying with the Air program in the dedicated small terminal 120 was adopted.

<Display example on a small terminal>
Further, as an example of display on the display 121 of the small terminal 120, for example, the one shown in FIG.
This is because the AI program (AI function) in the small terminal 120
Deodorizing filter, type and amount of liquid agent, spray timing, operation control program, optimal solution of maintenance method is derived and displayed on the display 121.

Next, as shown in FIG. 11, the dedicated small terminal 120 communicates with the corresponding air cleaner 20 by communication means such as Bluetooth (registered trademark), and as a result of air quality diagnosis, indoor space R The result of the study derived from the shape etc. is transmitted to the air cleaner 20, and a new operation control program is installed in the air cleaner 20. As a result, the operation of the air cleaner 20 optimum for the indoor environment is started.
Furthermore, in the present embodiment, the operation control program is updated each time according to various types of sensor information mounted on the air purifier 20.

<Other roles of small terminals>
(A) Determination of Optimal Position of Air Purifier and Display Function In this example, as described above, the small terminal 120 determines the optimal specification of the air purifier 20 and displays it on the display 121. Furthermore, in the present example, as shown by U in FIG. 12A, the optimum position of the air cleaner 20 is obtained from information such as the shape of the indoor space R and the air flow inhibition factor, and is displayed on the display 121.
(B) Display mechanism of air quality information If the dedicated small terminal 120 can receive the sensor information of the air purifier 20 via communication means such as the air purifier 20 and Bluetooth (registered trademark), real time can be obtained. It is possible to display these information at.
Here, as a sensor mounted on the air purifier 20, for example, the contaminant discrimination sensor 35 and the environment sensor 36 for measuring temperature and humidity are exemplified, but in addition to this, a sensor related to air cleanliness (scent, dust) is added By doing this, as shown in FIG. 12B, it is possible to display information on odor and dust in addition to the temperature and humidity information on the display 121 of the small terminal 120.
At this time, if the small terminal 120 is installed on the wall of a room, for example, in a wall-hanging manner, the occupant can always grasp the air quality information in the room. By using such a display function, it is also possible to emphasize the visitor of the installation facility that the facility is an air environment-friendly facility. In addition, it is also possible to determine the replacement time of consumables such as a filter from the accumulated sensor information and to display this.
(C) Remote Control Function The dedicated small terminal 120 has a function as a remote controller of the air purifier 20, as shown in FIG. 12 (c). At this time, if the display 121 of the small terminal 120 is configured by a liquid crystal touch panel that is easy to view, it can be easily operated as a remote control.

Second Embodiment
FIG. 13 shows the main part of the indoor environment control system according to the second embodiment.
In the figure, the indoor environment control system includes a plurality of environmental devices 130 (for example, an air cleaner 131, an air conditioner (air conditioner / air conditioner) 132, a cleaning robot 133, a useful substance supply device 134, etc. in the same indoor space R. ) Are mixed and installed.
As the useful material supply device 134 mentioned here, for example, the contaminants remain or the contaminants are decomposed in order to prevent the spread of the attached contaminants adhering or adhering to the surface or the inside of the interior material or the interior goods. Those which supply liquid or gaseous useful substances having characteristics, those which supply deodorants which are useful substances for deodorizing odorous substances in the indoor space R, and which are considered to be good for human health One that supplies useful substances is mentioned.
Generally, in the case where a plurality of environmental devices 130 coexist in the same indoor space R, it is extremely difficult to determine the installation position of each environmental device 130, the operation method, and the maintenance method.
Therefore, in this example, as in the first embodiment, environment information of the indoor space R, configuration information such as shape and volume, and performance information of each environmental device 130 are obtained, and based on these information The air flow pattern AP generated in the indoor space R is analyzed, and the installation position and operating condition of each environmental device 130 are controlled so as to obtain the target air flow pattern AP.

  Specifically, the installation position of the air purifier 131 and the air conditioner 132, which are environmental devices 130 that greatly affect the air flow pattern AP, and the operating conditions are selected, and the air flow pattern AP generated for the mobile cleaning robot 133 As for the useful substance supply device 134, the type of useful substance, the supply amount, the supply timing, etc. are predicted for the useful substance supply device 134, and furthermore, environmental devices 130 (air cleaners 131 to 131 Communication among the useful substance supply devices 134 is enabled using a communication means such as Bluetooth (registered trademark). For example, the operation of the air cleaner 131 based on the detection information of the dirt sensor 141 mounted on the air cleaner 131 To automatically operate each environmental device 130 in coordination with the start of operation of the air purifier, or The operation of the air conditioner 132 is automatically turned on and off based on the detection information of the environment sensor 142 mounted on the computer 132, and each environmental device 130 is operated in cooperation with the operation start of the air conditioner 132. It is intended to realize environmental control. In addition, the dust sensor 143 and the microorganism sensor 144 are mounted on the cleaning robot 133, and the operation of the cleaning robot 133 is automatically turned on / off based on the detection information of these, and in cooperation with the operation start of the cleaning robot 133 The environmental device 130 may be operated.

Third Embodiment
FIG. 14 shows the main part of the indoor environment control system according to the third embodiment.
In the figure, the indoor environment control system includes a plurality of environmental devices 130 (in this example, an air purifier 131, an air conditioner 132, a cleaning robot 133, a useful substance supply device 134, and an auxiliary fan 135) in substantially the same manner as in the second embodiment. , And the humidifier 137 etc. are mixed, and further, equipment 150 (a table in this example) other than the environmental device 130 is installed.
In this example, as in the second embodiment, environment information of the indoor space R, configuration information such as shape and volume, and performance information of each environmental device 130 and position of the fixture 150 and occupied area information are acquired. Then, based on the information, the air flow pattern AP generated in the indoor space R is analyzed, and the installation position and operating condition of each environmental device 130 are controlled so as to obtain the target air flow pattern AP. It is
In the present embodiment, in particular, the dirt sensor 141 is mounted on the air purifier 131, the environment sensor 142 is mounted on the air conditioner 132, and the dust sensor 143 and the microorganism sensor 144 are mounted on the cleaning robot 133. The operating condition of each environmental device 130 is controlled in real time based on the change of the environmental information from each of the sensors 141 to 144 mounted on the vehicle and the change of the power consumption of each environmental device 130 from moment to moment. .
According to the present embodiment, in the mode in which a plurality of environmental devices 130 are mixed in the indoor space R, even if the environmental conditions of the indoor space R change with time, the operating conditions of the respective environmental devices 130 are controlled. It is possible to always set the target air flow pattern AP in the indoor space R as the optimum one.

Fourth Embodiment
FIG. 15 shows the main part of the indoor environment control system according to the fourth embodiment.
In the figure, the indoor environment control system is to make the indoor space R used as a sleeping space comfortable, for example, and an embedded air cleaner 131 is installed in the indoor space R, and further, the indoor space R is The bed 151 as equipment is installed at a part away from the air purifier 131 among them, and a humidifier 137 as an example of the environmental device 130 between the bed 151 and the air purifier 131 is a table 152 as equipment. It was installed on top.
In particular, in the present example, the inlet 161 of the air cleaner 131 is provided corresponding to the lower area of the bed 151 and the table 152, and the outlet 162 of the air cleaner 131 is the indoor space R via the duct 163. It is provided on the upper side of one side.

Also in this example, the environment information of the indoor space R, the configuration information such as the shape and the volume, and the performance information of each environmental device 130 and the position and occupancy of the bed 151 and the table 152 in substantially the same manner as the first embodiment. Region information is acquired, the airflow pattern AP generated in the indoor space R is analyzed based on these pieces of information, and each environmental device 130 (air cleaner 131, humidification, etc. is obtained so as to obtain the targeted airflow pattern AP. The installation position and operation conditions of the container 137) are controlled.
In this example, in the indoor space R, particulate matter W1, virus W2, pollen W3, mold / fungus W4, chemical substance W5, dust W6 from the duvet, fleas mites hired in the duvet, odorant W8 of the human body, etc. It is possible to identify the pollutant W in the indoor space R by analyzing the air quality.
In such a situation, it is preferable that the target air flow pattern AP circulate without stagnating air in the indoor space R, and it is preferable to select the space below the bed 151 and the table 152 as the air flow passage area. As the operating condition of the humidifier 137, it is preferable to select the specifications of the operating time and the intensity of the humidifier 137 in consideration of the humidity condition as a sleeping space.
In such a situation, comfortable indoor environment control is performed as a sleeping space.
Furthermore, in this example, for example, an active ingredient cartridge 165 containing an active ingredient (water, high concentration oxygen, aroma, enzymes, etc.) considered to be good for human health is incorporated in a part of the duct 163, It is also possible to dissipate the In this way, useful components can be arbitrarily selected according to the user's constitution and needs, and commercially available small oxygen cylinders, plant essential oils (eucalyptus, phytoncid ...), etc. can be applied, and the active components are respiratory organs, skin, etc. It is possible for the components effective for the health of the human body to be efficiently supplied locally on the air flow Af. For example, it is effective in preventing winter dry, rough skin, sore throat, cold, flu, infection with coronavirus.

形態 Modification form 4-1
In the fourth embodiment, an example is shown in which the indoor environment control is performed on the indoor space R as a sleeping space, but the present invention is not limited to this. For example, a specific work room such as an individual's work room Assuming that the person M staying in the room space R in which the person M stays suffers a disease, the disease state of the person M staying as shown in the form 4-1 of the variation of FIG. It is also possible to grasp.
In this example, the air purifier 131 is an embedded air purifier installed in advance in the indoor space R, and faces the partition wall that divides the indoor space R and the air purifier 131 from each other. While opening the air intake port 161 of the air purifier 131, the exhaust port 162 which discharges clean air from the upper side of the partition wall from the air purifier 131 via the duct 163 to near the ceiling surface of the substantially center of the indoor space R The air flow passage 164 in the air cleaner 131 is equipped with the same clean filter 40, fan 30, and heat exchange unit 29 as in the first embodiment.
In particular, in this example, in order to analyze air quality in the indoor space R, the particulate matter Wr in the filter for removing microbes 42 or the medium performance filter 43 in the cleaning filter 40 of the air purifier 131 The analysis cartridge 81 in which the gas is captured is detachably installed, and the analysis cartridge 83 in which the disease-specific gaseous substance Ws is captured is detachably installed in part of the gas removal filter 44 functioning as a deodorizing filter. It is
In this example, after a predetermined time has elapsed since the analysis cartridges 81 and 83 were installed, as shown in FIG. 16 (b), the analysis cartridge 81 is removed from the microorganism removal filter 42 or the medium performance filter 43. Also, the analysis cartridges 83 are removed from the gas removal filter 44, and the particulate matter Wr and the gaseous matter Ws captured by the respective analysis cartridges 81 and 83 are analyzed by a known analysis method. It is recommended to diagnose the contaminants contained as quality.
At this time, the air quality diagnosis result is used to perform indoor environment control of the indoor space R, but stays in the indoor space R when, for example, the amount of captured gaseous substance Ws specific to a disease is large. It turns out that the person M is suffering from a predetermined disease, which makes it possible to carry out a health check using biological information.
Also in this example, an active ingredient cartridge 165 containing an active ingredient (water, high concentration oxygen, aroma, enzymes, etc.) considered to be good for human health may be incorporated into a part of the duct 163. Of course.

形態 Embodiment 5
FIG. 17A is an explanatory view showing a state in which there is a concern that the contaminants attached to and impregnated in the surface or the inside of the building material (interior material etc.) 180 in the indoor space R may be dissipated with the construction work.
At present, although the reduction of the form materials is progressing, indoor air pollution by chemical substances such as VOCs and odorous substances such as acetaldehyde and ammonia which are not subject to regulation is still a problem on the building environment.
In construction work such as new construction and renovation work, there is a need for technology to terminate the emission of chemical substances generated from building materials such as plywood, adhesives, paints, and wax in a short time.
First, as shown in FIGS. 17 (a) and 17 (b), a chemical substance or odor attached to or impregnated in the surface or the inside of the building material 180 by giving, for example, a blowing air flow 191 from the blower 190 to the surface of the building material 180. Promote the emission of substance 192.
Then, in the present embodiment, the air flow analysis is performed in the indoor space R at the construction site, and as shown in FIG. 17C, chemical substances and odorous substances present in each indoor space R are added to the blower 190. The specifications and installation positions of the air cleaner 200 and the auxiliary fans 201 and 202 to be removed efficiently are selected, the air flow Af circulating in the indoor space R is generated, and the building is actually used through the curing process from the construction period. It is possible to provide a construction method by which the rate of emission of chemical substances and odorous substances from building materials and construction materials can be increased, and residence can be safely made as quickly as possible after construction.

(1) In this example, as shown in FIG. 17C, the blower 190 and the air cleaner 200 are installed at the construction site by air flow analysis to reduce the indoor concentration, and the emission rate of the contaminants of the building material 180 And efficiently recover the emission material with the air cleaner 200. Furthermore, by using the auxiliary fans 201 and 202, the auxiliary fans 201 and 202 that apply the air flow to the finished surface as appropriate are used.
(2) Also, as in (1), a humidifier or a dehumidifier is used to increase the diffusion rate of building materials in hydrophilic and hydrophobic gases and shorten the construction period.
(3) In addition, as in (1) or (2), a heater may be used to increase the emission rate of the volatile component of the contaminant.
In the present embodiment, the ions (active species) 191 are given to the surface of the building material 180, but the air flow pattern AP generated by the air cleaner 200 and the auxiliary fans 201 and 202 is not given. Thus, the emission rate of the contaminants adhering to and infiltrating the building material 180 may be increased and collected in the air cleaner 200, and furthermore, a humidifier, a heater and a heater may be used in combination.

Example 1
The present example 1 shows an experiment to demonstrate the airflow analysis in the indoor environment control system according to the first embodiment, and obtains an analysis example of the airflow pattern generated in the indoor space.
In this example, as shown in FIG. 18A, in the airflow control experiment 1, the airflow generation unit 210 generates a spiral airflow Af from the smoke generating portion on the floor surface of the indoor space toward the suction portion above Shows an air flow pattern obtained when the image is taken from the top to the bottom under the conditions described above. In FIG. 18A, reference numeral 211 denotes a camera for photographing, and reference numeral 212 denotes a laser for irradiating sheet-like light to the air flow Af.
FIG. 18 (b) shows the result of the airflow control experiment in the present experiment 1, and FIG. 18 (c) shows the result of velocity vector analysis of FIG. 18 (b).
In the air flow control experiment 2, as shown in FIG. 19A, the air flow generator 210 generates a spiral air flow Af from the smoke generating part on the floor surface of the indoor space toward the suction part above. It shows the air flow pattern obtained when it is photographed from the side under certain conditions. In the figure, reference numeral 211 denotes a camera and 212 denotes a laser.
FIG. 19 (b) shows the result of the airflow control experiment in the present experiment 2, and FIG. 19 (c) shows the result of velocity vector analysis of FIG. 19 (b).
As seen from the results of velocity vector analysis in FIGS. 18C and 19C, since the spiral air flow pattern can be obtained in either case, the air flow analysis employed in the first embodiment is accurate. It is understood that there is.

  DESCRIPTION OF SYMBOLS 1 ... Environmental information acquisition means, 2 ... Configuration information acquisition means, 3 ... Equipment, 3a, 3b ... Environmental apparatus, 3c ... Equipment other than an environmental apparatus, 4 ... Control means, 5 ... Airflow analysis part, R ... Indoor space

Claims (9)

Environmental information acquisition means for acquiring environmental information of the indoor space to be controlled;
Configuration information acquisition means for acquiring configuration information of equipment including the indoor space and at least environmental equipment installed in the indoor space;
The air flow analysis unit analyzes the air flow pattern that can be generated in the indoor space based on the environmental information and the configuration information acquired from each of the information acquisition means, and the target is based on the analysis result by the air flow analysis unit. An indoor environment control system comprising: control means for controlling at least an installation position of the environmental device and an operating condition so as to obtain an air flow pattern. In the indoor environment control system according to claim 1,
The indoor environment control system, wherein the environmental information acquisition means includes at least air quality and temperature and humidity of air as environmental information of indoor space. In the indoor environment control system according to claim 1 or 2,
The configuration information acquisition means includes, as the configuration information of the indoor space, the shape and volume of the indoor space, and physical and chemical characteristics of the used building materials, and at least the environmental devices as configuration information of fixtures installed in the indoor space. An indoor environment control system comprising position and performance information of the above and including position and occupancy area information for equipment other than environmental equipment. In the indoor environment control system according to claim 3,
The configuration information acquisition means is characterized by including an imaging tool capable of three-dimensional imaging for acquiring the shape and volume of the indoor space, and a scale for specifying dimensions installed on a reference plane of the indoor space. Indoor environment control system. In the indoor environment control system according to any one of claims 1 to 4,
The environmental device includes an air cleaning device having at least a cleaning filter and a drug supply mechanism for supplying a drug suitable for contaminants in the indoor space,
The control means, as the specification of the air cleaning device, determines the specification of the cleaning filter and the specification of the medicine supply mechanism in addition to determining the position where the target air flow pattern can be generated and the contents of the operation control program. An indoor environment control system characterized by also determining. In the indoor environment control system according to any one of claims 1 to 4,
A plurality of environmental devices capable of communicating with each other in the indoor space;
An indoor environment control system characterized in that the control means determines in advance a condition under which a plurality of environmental devices cooperate with each other and makes the plurality of environmental devices communicate with each other. In the indoor environment control system according to any one of claims 1 to 4,
The indoor space is provided with one or more environmental devices, and the environmental devices are equipped with the environmental information acquisition means capable of acquiring environmental information in real time,
An indoor environment control system, wherein the control means controls in real time at least operating conditions of the environmental device based on a change in environmental information from environmental information acquisition means mounted on the environmental device. In the indoor environment control system according to any one of claims 1 to 7,
The control means executes analysis by the air flow analysis unit based on each information acquired from the environment information acquisition means and the configuration information acquisition means, and based on the analysis result by the air flow analysis unit, the position of the environmental device and A main control device for determining an operating condition, and specification information including at least an installation position of the environmental device determined by the main control device and operating conditions are received, and an operation control program based on these specification information An indoor environment control system comprising an installable individual terminal. In the indoor environment control system according to claim 8,
The indoor space is provided with one or more environmental devices, and the environmental devices are equipped with the environmental information acquisition means capable of acquiring environmental information in real time,
An indoor environment control system, wherein an operation control program installed in the environmental device is updated based on a change in environmental information from environmental information acquisition means mounted in the environmental device.