JP2002005488A - Indoor environment control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an indoor environment control system not to change given environment in a room. SOLUTION: The indoor environment control system not to change given environment in a room comprises an indoor environment regulating device; an indoor environment measuring means to measure indoor environment to be controlled and output measurement data; an outdoor environment measuring means to measure outdoor environment of a room to be controlled and output the measurement data; and a control means to control the indoor environment regulating device. The indoor environment control system is featured that the control means receives measurement data from the indoor environment measuring means, measurement data from the outdoor environment measuring means, area meteorological observation data, and area meteorological forecast data, environment forecasted data in a room is determined from the data, and based on the indoor environment predicated data, the indoor environment regulating device is controlled such that the given environment in the room is not changed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention generally relates to an indoor environment control system, and more particularly to a system for actively controlling the environment in a vegetable factory.

[0002]

2. Description of the Related Art Conventionally, in a vegetable factory, an air conditioner, an illuminance controller, and a solar radiation controller for controlling the temperature, humidity, and the amount of carbon dioxide in the factory in order to maintain the inside of the factory in a predetermined environment. Equipment, ventilation control equipment, etc. were provided.

When various environments in the factory, such as room temperature, deviate from the values (ranges) suitable for cultivation and growth of vegetables, the above-mentioned various control devices return the various environment values to the appropriate values. (For example, to return the room temperature that has dropped to 23 degrees to the appropriate temperature of 25 degrees), is controlled manually, or based on measurement data from various indoor environment sensors installed in the factory. It is automatically controlled by a control signal output from a control device.

[0004]

However, any of the above-mentioned control methods is a passive control system in which the indoor environment deviates from the appropriate numerical value and then returns to the appropriate numerical value. It took some or considerable time to return the indoor environment to the proper values, depending on the factory volume. In addition, in the method of manually controlling the adjustment device, forgetting control toward an appropriate numerical value,
Alternatively, there is a fear that the control may be forgotten after the return to the appropriate numerical value.

In both manual control and automatic control,
The time lag from the departure of the aptitude value to the return to the aptitude value may adversely affect the vegetables to be grown, and may have a fatal adverse effect especially on delicate vegetables that require strict temperature control etc. .

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and has as its object to provide an indoor environment control system for preventing a room from deviating from a predetermined environment.

[0007]

In order to achieve the above object, an indoor environment control system according to the present invention is an indoor environment control system for preventing a predetermined environment in a room from changing. An indoor environment measuring means for measuring the indoor environment to be controlled and outputting the measurement data, and an outdoor environment measuring means for measuring the outdoor environment of the room to be controlled and outputting the measured data, Having control means for controlling the indoor environment adjustment device, the control means, measurement data from the indoor environment measurement means, measurement data from the outdoor environment measurement means, regional weather observation data, Receiving the local weather forecast data, obtaining environmental prediction data in the room from these data, and determining the predetermined environment in the room based on the indoor environment prediction data so that the predetermined environment in the room does not change. Controlling the boundary adjustment device, characterized in that.

According to the indoor environment control system having the above-mentioned configuration, the control means controls the measurement data from the indoor environment measurement means, the measurement data from the outdoor environment measurement means, the regional weather observation data, and the local weather forecast data. Thus, indoor environment prediction data is obtained, that is, a future indoor environmental change is predicted. Next, the control means controls the indoor environment adjustment device based on the indoor environment prediction data so that a predetermined (that is, desired or appropriate) environment in the room does not change. By such active control, a change in the indoor environment itself as in the conventional passive control method of control after a change in the indoor environment can be avoided in advance.

Further, in the present invention, the control means compares the local weather observation data with the measurement data from the outdoor environment measurement means at the same time as the local weather observation data, so that both data are obtained. Obtain a correlation and apply the correlation to the regional weather forecast data to obtain outdoor weather prediction data, and compare the measurement data from the indoor environment measurement unit with the measurement data from the outdoor environment measurement unit. By calculating the correlation between the two data, the correlation between the measurement data of the indoor environment measurement means and the measurement data of the outdoor environment measurement means, by applying to the weather forecast data,
Preferably, the indoor environment prediction data is obtained, and a control signal is output to the indoor environment control device based on the indoor environment prediction data so that the predetermined environment in the room does not change.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the accompanying drawings. In this embodiment, the present invention is applied to an environment control system of a vegetable factory F for growing vegetables indoors.

As shown in FIG. 1, an indoor environment control system generally designated by reference numeral 1 includes an indoor environment control device. This indoor environment control device includes an air conditioner 10 for controlling the temperature, humidity and / or carbon dioxide concentration inside the vegetable factory F, an illuminance control device 11 for adjusting the illuminance illuminating the factory, and , A blind opening / closing device 12 for shielding a window of a factory F, and a ventilation volume adjusting device, ie, a device 1 for opening / closing a ventilation hole of a factory F.
3 is included. When the vegetables to be grown are hydroponics, a water temperature control device, an HP control device, and a water flow control device may be further installed as an indoor environment control device.

The indoor environment control system 1 also measures an indoor environment to be controlled and outputs the measured data, and an outdoor environment sensor for measuring the outdoor environment and outputs the measured data. And

The indoor environment sensor detects the temperature in the vegetable factory F,
A first sensor 22 for measuring humidity and carbon dioxide concentration and outputting measurement data, and a second sensor (not shown) for measuring illuminance in the vegetable factory F and outputting the measurement data; It has a third sensor (not shown) for measuring the amount of sunlight in the vegetable factory F and outputting the measurement data. If necessary, various indoor environment measurement sensors other than these, for example, the above-mentioned water temperature sensor for hydroponics vegetables can be provided.

The outdoor environment sensor measures the outside air temperature and humidity near the vegetable factory F, outputs the measurement data, a fourth sensor 23, and measures the wind direction and the wind speed near the vegetable factory F. And a fifth sensor 24 for outputting the same. The outdoor environment sensor can also have various sensors for measuring the outdoor environment near the vegetable factory F other than the sensors 4 and 5 as needed.

The indoor environment control system 1 further has a control device 30 for controlling the indoor environment control device.

As shown in FIG. 2, the control device 30
Measurement data from indoor environment sensor and outdoor environment sensor,
And, regional meteorological observation data, that is, regional meteorological observation system (commonly referred to as "AMeDAS") wide-area meteorological data, and regional meteorological forecast data, that is, numerical data (GPV data) on regularly arranged grid points Based on these data, the indoor environment control devices 10 to 13 are controlled so that the room does not deviate from a predetermined appropriate environment, that is, the interior of the vegetable factory F does not deviate from an environment suitable for growing vegetables. It is supposed to.

Here, the GPV data will be briefly described. This is numerical data of weather forecast distributed from the Japan Meteorological Agency, and several menus are prepared. For example, the ground data is used for forecasting up to 51 hours ahead. It is available twice a day as hourly data. Therefore, such G
By using the PV data, it is possible to obtain predicted weather data one hour and two hours later in the area where the vegetable factory F is installed.

The control device 30 includes indoor environment control devices 10 to 10.
3, the wide area data by AMeDAS and the pinpoint measurement data at the factory installation point by the outdoor environment sensor at the same time as the AMeDAS data are compared as shown in FIG. Find the correlation. For example, when the temperature / humidity of the AMeDAS data is 25 ° C./40% in the factory installation area and the temperature / humidity of the outdoor environment sensor data is 26 ° C./45%, the latter is + 1 ° C. per temperature, A + 5% relationship with humidity is obtained.

Next, the control device 30 calculates this correlation,
By applying the data to the GPV data as the regional data, the weather (data) up to several hours ahead at the factory installation point is predicted, that is, weather forecast data up to several hours ahead at the factory installation point is obtained. For example, when the GPV data predicts that the temperature of the factory installation area after one hour is 26 ° C. and the temperature after two hours is 26.5 ° C.,
By applying (relationship that the temperature of the factory installation point is higher by 1 ° C. with respect to the wide area temperature data), the temperature one hour after the factory installation point is 27 ° C., and the temperature two hours later is predicted to be 27.5 ° C.

Then, the control device 30 compares the weather data predicted at this factory installation point (weather prediction data at the factory installation point) with the weather (environment) data at the current factory installation point by the outdoor environment sensor. With this, the tendency of the weather change at the factory installation point up to several hours ahead is predicted. For example, if the temperature one hour after the temperature of the factory
If the temperature at the factory installation point at this time by the outdoor environment sensor is 26 ° C., while the temperature is expected to be 7 ° C., it is determined that the air temperature tends to increase.

On the other hand, the control device 30 obtains a correlation between the measured data from the indoor environment sensor and the measured data from the outdoor environment sensor by comparing the two data. For example, when the outside temperature of the factory in the outdoor environment sensor measurement data is 26 ° C. and the room temperature in the factory of the outdoor environment sensor data is 28 ° C., the latter has a relationship of + 2 ° C. with respect to the former. .

Subsequently, the control device 30 applies the correlation between the indoor environment sensor measurement data and the outdoor environment sensor measurement data to the weather forecast data up to several hours ahead at the factory installation point, thereby obtaining the number of data in the factory. The environment (data) up to a point ahead is predicted, that is, indoor environment prediction data up to a few hours ahead is obtained.

Based on the environment prediction data, the controller 30 prevents the inside of the vegetable factory F from deviating from the environment suitable for growing vegetables as described above, that is, the vegetable factory F suitable for growing vegetables. The control signals are output to the indoor environment control devices 10 to 13 so that the inside environment does not change. For example, when the room temperature of the vegetable factory F is predicted to increase by 1 ° C. after one hour, the control device 30 prevents the inside of the vegetable factory F from deviating from the current room temperature (environment) suitable for growing vegetables. That is, a control signal is output to the air conditioner 10 so that the room temperature of the vegetable factory F does not rise by 1 ° C. after one hour.

As described above, by maintaining the inside of the vegetable factory F in an environment suitable for growing vegetables at all times, the production efficiency of vegetables can be improved.

Referring to FIG. 4, a second embodiment of the present invention is schematically illustrated.

The indoor environment control system according to the second embodiment will be described with reference to FIGS. 1 to 3 except that a wind power generator 40 and / or a solar power generator 50 are provided as a power source for the entire system. This is the same as the indoor environment control system according to the first embodiment of the present invention described above. Therefore, here, the configuration and operation of the indoor environment control system of the second embodiment will not be repeatedly described. The system of the present invention includes a wind power generator 40 and / or a solar power generator 50.
By using, the running cost of the system can be significantly reduced, and the production efficiency can be further improved.

The present invention can be variously modified without being limited to the above embodiment.

For example, in the above-described embodiment, the indoor environment control system of the present invention is applied to a vegetable factory for growing vegetables, but the application of the system of the present invention is limited to the vegetable factory. Instead, the present invention can be widely applied to, for example, various manufacturing factories in which maintaining a predetermined indoor environment is strictly required, or general homes and office buildings in which it is preferable to maintain a comfortable indoor environment.

In the above-described embodiment, the control device obtains the regional weather observation data from the local weather observation system. However, the local weather observation data need not be the data from the local weather observation system. Similarly, the control device uses the GPV data as the local weather forecast data, but any other data than the GPV data can be used as the local weather forecast data.

[0030]

As described above, the present invention can provide an indoor environment control system for preventing a room from deviating from a predetermined environment.

[Brief description of the drawings]

FIG. 1 is a schematic perspective view of a vegetable factory to which an indoor environment control system of the present invention is applied.

FIG. 2 is a block diagram of the indoor environment control system of FIG. 1;

FIG. 3 is a schematic logic diagram of the control device of FIG. 2;

FIG. 4 is a schematic perspective view of a vegetable factory according to a second embodiment to which the indoor environment control system of the present invention is applied.

[Explanation of symbols]

1 indoor environment control system 10, 11, 12, 13 indoor environment control device (air conditioner,
22) Indoor environment measuring means (indoor environment sensor, first sensor) 23, 24 Outdoor environment measuring means (outdoor environment sensor, fourth
Sensor, fifth sensor) 30 Control means (control device)

Continued on the front page (72) Inventor Masaaki Fukihara 1-1-1 Wadazakicho, Hyogo-ku, Kobe-shi, Hyogo F-term in Kobe Shipyard, Mitsubishi Heavy Industries, Ltd. (Reference) 2B029 MA01 MA04 MA06 MA08 PA01 SA01 3L060 AA06 AA07 CC02 CC03 CC07 DD02

Claims (2)

[Claims] An indoor environment control system for preventing a predetermined indoor environment from changing, comprising: an indoor environment adjusting device; and an indoor room for measuring an indoor environment to be controlled and outputting the measurement data. An environment measuring means, an outdoor environment measuring means for measuring an outdoor environment of a room to be controlled and outputting the measurement data, and a control means for controlling the indoor environment adjusting device, the control means comprising: Receives the measurement data from the indoor environment measurement means, the measurement data from the outdoor environment measurement means, the regional weather observation data, and the local weather forecast data, and obtains indoor environment prediction data from these data. An indoor environment control system, wherein the indoor environment control device is controlled based on the indoor environment prediction data so that the predetermined environment in the room does not change. 2. The control means obtains a correlation between the local weather observation data and the local weather observation data by comparing the local weather observation data with measurement data from the outdoor environment measurement means at the same time, By applying the correlation to the regional weather forecast data, outdoor weather forecast data is obtained.By comparing the measured data from the indoor environment measuring means with the measured data from the outdoor environment measuring means, The correlation between data is obtained, and the correlation between the measurement data of the indoor environment measurement unit and the measurement data of the outdoor environment measurement unit is applied to the weather forecast data, thereby obtaining indoor environment prediction data. A control signal is sent to the indoor environment control device based on the environment prediction data so that the predetermined environment in the room does not change. Output to the indoor environmental control system of claim 1, wherein.