JPS6337247A - Apparatus for evaluating air in room - Google Patents

Abstract

PURPOSE:To synthetically evaluate the state quantity of plural kinds of factors exerting effect on the contamination of air in a room and to simply grasp the purifying degree of air in the room, by providing a plurality of sensors, an operation means and a display means. CONSTITUTION:An oxygen sensor 1A, a humidity sensor 1B and a dust sensor 1C are provided and state quantity data of various factors detected by said sensors 1A-1C are successively read in an operation apparatus 2 in predetermined timing. The apparatus 2 is equipped with a memory storing a constant etc. given from an input apparatus 3. The differences between the data detected by the sensors 1A-1C are the standard values of various factors are calculated as the number of steps to be displayed on a display device 4. Subsequently, the number of steps of each data is multiplied by the weighing coefficient of each factor to calculate contamination frequency at every factor, and the sum of the contamination frequencies is subtracted from a reference value to calculate an evaluation index which is, in turn, displayed on the display device 4. Next, when the evaluation index is below reference point, an alarm signal is outputted and, when data are out of a tolerant limit, the signal corresponding thereto is outputted for a definite time.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an indoor air evaluation device that displays the cleanliness or pollution level of indoor air. Specifically, the present invention relates to a system that comprehensively evaluates state quantities of multiple factors that affect indoor air pollution, such as carbon dioxide, humidity, dust, etc., and displays this as an indoor air evaluation index.

[Background technology and its problems]

BACKGROUND ART In recent years, indoor air quality has become a problem due to the increase in the density of housing, the occurrence of condensation, mold, dust mites, etc., and the increase in allergic diseases caused by pollen.

In general, air contamination factors include carbon dioxide, humidity, dust, odor, fungi, and toxic gases, and indoor air contamination factors include carbon dioxide, humidity, dust, and odor.

BACKGROUND ART Conventionally, devices for measuring the cleanliness or pollution level of indoor air include a No. J, an oxygen concentration meter, a humidity d1, a dust needle, and the like. However, these display oxygen concentration, humidity, dust amount, etc. in Chinese and German terms, so they can be used as a guide to judge the quality of each factor. It is not possible to comprehensively display the degree of contamination.

Therefore, when a resident performs ventilation using these state quantities as a guide, it is extremely troublesome because he or she must check all the meters. Moreover, even if ventilation is performed when the state quantity of one of the factors exceeds the permissible limit, the degree to which it affects human safety or causes discomfort varies depending on the factor. It is not possible to determine a permissible limit, and leaving this up to each resident is particularly burdensome for the elderly and children.

[Purpose of the invention]

The purpose of the present invention is to eliminate such conventional drawbacks, to comprehensively evaluate the amount of B of multiple factors that affect indoor air pollution, and to display this as an indoor air evaluation index. Therefore, it is an object of the present invention to provide an indoor air evaluation device that allows anyone to easily grasp the cleanliness of indoor air.

[Means and effects for solving the problem] The present invention includes a plurality of sensors that each detect state quantities of a plurality of factors that influence indoor air pollution, and a state quantity detected by each of these sensors. The air conditioner includes a calculation means for calculating an evaluation index of indoor air based on the calculation means, and a display means for displaying the evaluation index calculated by the calculation means. Here, the display means is
In addition to visually displaying the evaluation index determined by the calculation means, it also includes means for expressing it as sound.

The calculation means calculates the difference between the state quantity detected by each sensor and the standard value of each factor as the number of steps, and multiplies each step number by the weighting coefficient of each factor to obtain the degree of contamination for each factor. , the sum of these contamination degrees is subtracted from the reference value to obtain an indoor air evaluation index, and this is displayed on the display means.

Therefore, anyone can easily grasp the cleanliness of the indoor air from the evaluation index displayed on the display means.

〔Example〕

An embodiment of the evaluation device according to the present invention will be described below with reference to the drawings. 1fflUsually, -e Indoor air contamination factors include the aforementioned carbon dioxide, humidity, dust, and odor, but since the increase in carbon dioxide is approximately proportional to the decrease in oxygen, it is difficult to measure the amount of oxygen. Can be substituted. Furthermore, since the main sources of odor in a general room are the human body or cigarettes, they can be replaced by carbon dioxide and dust. In this example, oxygen, humidity, dust,
An indoor air evaluation index is calculated based on three factors: dust caused by cigarettes and other smoke.

FIG. 1 shows an overall block diagram of this embodiment. In the same figure, IA is an oxygen sensor, IB is a humidity sensor, I
C is a dust sensor. Incidentally, since cigarette smoke accounts for a large proportion of dust in a general room, it is preferable that the dust sensor IC is capable of sensing this, and for example, a miscellaneous gas sensor or a CO sensor can be used. Each of these sensors IA-I
The state quantity data of each factor detected in C is sequentially read into the arithmetic unit 2 at a predetermined timing.

The arithmetic device 2 includes a memory (not shown) for storing constants and various numerical values given from the input device 3, and executes the processing shown in FIG. 3 according to a preset procedure. First, the difference between each data detected by each sensor IA to IC and the standard value of each factor, here 21% oxygen, 50% humidity, and Omg/m3 of dust, is determined as the number of steps, and this is displayed on the display device 4. do. Next, multiply the number of steps of each data by the weighting coefficient of each factor to find the degree of contamination for each factor.
The total sum of contamination degrees is subtracted from the reference value to obtain an evaluation index, which is displayed on the display device 4. Finally, it is determined whether the evaluation index is below the reference point or not, and if it is not below the reference point, the process returns to the beginning. On the other hand, if the evaluation index is below the reference point, a warning 1 signal is output, and then it is determined in turn whether each data is outside the allowable limit for each factor, and if it is outside the allowable limit, take appropriate action. outputs a ventilation command signal, humidity improvement command signal, and purification command signal for a certain period of time.

The display device 4 includes an oxygen data display 5 that displays oxygen data, a humidity data display 6 that displays humidity data, and a dust data display 7 that displays dust data, as well as an evaluation index that digitally displays an evaluation index. A display 8 is provided. In addition, the evaluation index display 8 indicates the air cleanliness from 1 to 1.
It can be displayed as an index up to 0. For example, index 9
~10 is "comfortable", 8 is "adequate", 7 is "somewhat poor", 6
5 means "poor" and 5 or less means "unsuitable".

As shown in FIG. 2(A), the oxygen data display 5 has 10
Light emitting diodes D1 to DIG are arranged in a row, and the oxygen concentration is 0.15% or more and 19.65% or less.
Each percentage can be displayed in 10 steps. That is, when the oxygen concentration is 21% or more, only diode D is lit, and each time the oxygen concentration decreases by 0.15% from 21%, diodes D2 to D10 are lit in order. At this time, diodes D1 to D3 are green, diodes D4 to D7 are yellow,
Since the diodes D s = D Io are each color-coded red, evaluation can be made based on which color region the lit diode belongs to.

As shown in FIG. 2(B), the humidity data display 6 has 10
A number of light emitting diodes DI-D Io are arranged in a line, and it is possible to display the humidity range from IO% or less to 90% or more in 10 steps in 10% increments.

In other words, at 50% humidity, the diode D5. D6 lights up, and each time the humidity rises by 10% with respect to 50%, the diodes D7 to DI0 turn on, and each time the humidity drops by 10%, the diode D turns on.
4 to D1 light up in order. In this case, diode D
s, D6 is green, diodes Dx, Da, D
? , De turns yellow, diode-FD+ , Dz , Dq
, D+o are color-coded in red, so this color-coding can be used as a guide for evaluation.

As shown in FIG. 2(C), the dust data display 7 has 10
Light-emitting diodes DI-D Io are arranged in a row, and the dust content is 10.05 mg/m3 or less to 0.05 mg/m3 or less.
The range of 45 mg/nf or higher can be displayed in 10 steps in increments of 0.05 aw/rrr. In other words, the amount of dust is 0.05■/d
Below, only diode D1 lights up and the amount of dust is O■/
0.05mg/n with d as a reference (each time it increases, diodes D2 to D+ light up in order. Note that the diode DI
” The color coding of D Io is the same as that of the humidity data display 5.

Next, the operation of this embodiment will be explained.

In the calculation device 2, first, the oxygen data X detected by the oxygen sensor A is read, and the difference between the oxygen data
%) to find the number of steps S8, and the oxygen is displayed according to this number of steps SN. That is, the diodes D2 to D1 of the oxygen data display 5 are sequentially turned on by the number of steps Sx. Therefore, the number of dimends D1 to DI0 that light up increases or decreases depending on the oxygen concentration, so the oxygen state can be confirmed by checking their length.

Next, read the humidity data Y detected by humidity sensor B, and calculate the number of steps SV by dividing the difference between the humidity data Y and the standard value (50%) by the preset steering knob width (10%). , the humidity is displayed in accordance with this step number 87. That is, if the number of steps 87 is ten, the diodes D7 to D1° are sequentially turned on by the number of steps 87, and if the number of steps Sv is -, the diodes D4 to D1 are sequentially turned on by the number of steps SY. Therefore, the humidity is 50
If it is high based on %, the diode D7~I)IO is
If the temperature is low, the diodes D, ~D, will light up, so the humidity condition can be determined by the lighting direction and number of the diodes D1~D, o! can be approved.

Next, read the dust data Z detected by the dust sensor IC, and divide the difference between the dust data Z and the standard value (0■/if> by the step width (0,05■/rd) to find the step number Sz. The dust data is displayed according to the number of steps 82.In other words, the dust data is displayed as many times as the number of steps 82.
t 7 diodes D2-D,. lights up. Therefore, the diode DI that lights up depending on the amount of dust
Since the number of +a increases or decreases, the dust condition can be confirmed by its length.

Next, an indoor air evaluation index is determined. To do this, multiply S7 and S2 by the weighting coefficients A, B, and C for each factor to obtain the degree of contamination for each factor, and then calculate the sum of these contamination degrees. The evaluation index is obtained by subtracting from the reference value (10). In other words, evaluation index -10 (A SX+IB Syl+ CSz
). However, Ail, 5, B; 2) C; 1. Thereafter, the obtained evaluation index is digitally displayed on the evaluation index display 8. Therefore, the cleanliness of the indoor air can be grasped from the numerical value displayed on the evaluation index display 8.

Next, it is determined whether the evaluation index is below the reference point (6). If the evaluation index is not below the reference point, the process returns to the oxygen data reading process. On the other hand, if the evaluation index is below the reference point, an alarm signal is output and the oxygen data
%) or less, the humidity data Y is within the permissible limit range (
40% to 50%), and whether the dust data Z is outside the permissible limit (for example, 0°15 as specified by the Building Standards Act).
/b) Determine whether or not the above values are met in order, and if any of them is outside the allowable limit, output the corresponding signal for a certain period of time, that is, a ventilation command signal, a humidity improvement command signal, and a purification command signal. . Therefore, if air purification equipment is not available, an alarm signal can be used to urge residents to ventilate.
On the other hand, if you have air purification equipment, use these command signals to open ventilation doors and humidity improvement equipment (dehumidifiers and humidifiers).
By operating an air purifier, etc., the air condition can be automatically improved.

According to this embodiment, the oxygen, humidity, and dust amount in indoor air are detected, and these state quantities are comprehensively evaluated to obtain an evaluation index, which is displayed. You can comprehensively understand the cleanliness and pollution level.

Therefore, when performing ventilation, there is no need to check various instruments as in the past, so there is no hassle. This can ensure the comfort, health, and safety of residents, and can also be easily linked to air conditioning systems.

Furthermore, since the evaluation index is displayed as an index from 1 to 10, anyone can easily understand and handle it, and even the elderly and children can use it. At the same time, oxygen, humidity, and dust amount are also indexed and displayed, which can be useful for preventing dew condensation and for housing maintenance and management.

In the above example, the indoor air evaluation index was calculated based on three factors: oxygen, humidity, and dust. However, if the evaluation index is calculated by including other factors such as fungi and toxic gases, the air quality will be improved. can be evaluated accurately.

In addition, in the above embodiment, when calculating the number of steps for each data, the step width of oxygen is set to 0. 15%, humidity step width 10%, dust step width 0, 05
mmg/m 3 , but these step widths may be determined arbitrarily. However, if it is too small, the display 5
, 6.7, the display range becomes narrower, and conversely, if it is too large, it will not be possible to display slight fluctuations in each data.
It is preferable to take these points into consideration when making a decision.

In addition, when displaying each data based on the number of steps, in the above embodiment each data is displayed in 10 steps, but this may be arbitrary as long as it can display the required state quantity within a certain range. It is not limited to visual expression, but may also be expressed by sound.

In addition, when calculating the evaluation index from the number of steps for each data, the weighting coefficient for each data is not limited to the value in the above example, but also considers the degree to which each factor affects human safety and the discomfort caused to the person. It is only necessary to take this into account and decide accordingly. Furthermore, the display of the evaluation index is not limited to 10 levels as in the above embodiment, but may be arbitrary.

〔Effect of the invention〕

As described above, according to the present invention, the state quantities of multiple factors that affect indoor air pollution are comprehensively evaluated, and this is displayed as an indoor air evaluation index.
It is possible to provide an indoor air evaluation device that allows anyone to easily grasp the cleanliness of indoor air.

[Brief explanation of drawings]

The figures show one embodiment of the present invention, in which Figure 1 is a block diagram of the entire device, Figure 2 is a diagram showing each data display, and Figure 3 is a diagram showing each data display.
The figure is a flowchart. ]A~IC...sensor, 2...control device, 3...
Human power device, 4...display device.

Claims (3)

[Claims] (1) Multiple sensors that each detect the state quantities of multiple factors that affect indoor air pollution, and the difference between the state quantities detected by each sensor and the standard value of each factor as the number of steps. a calculation means for obtaining an indoor air evaluation index by multiplying each step number by a weighting coefficient for each factor to obtain a contamination degree for each factor, and subtracting the sum of these contamination degrees from a reference value; An indoor air evaluation device comprising: a display means for displaying an evaluation index determined by the means; (2) The indoor air evaluation device according to claim 1, wherein the plurality of sensors include an oxygen sensor, a humidity sensor, and a dust sensor. (3) An indoor air evaluation device according to claim 1 or 2, characterized in that the reference value is set to 10.