JPH08271292A - Measuring equipment for environmental assessment based on mold index - Google Patents

Abstract

PURPOSE: To provide a measuring equipment for environmental assessment which makes possible quantitative measurement of the degree of gathering of mold and executes measurement and display automatically as to the environmental assessment regarding living properties based on a mold index. CONSTITUTION: This equipment is constituted of a probe 20 equipped with a humidity sensor and a temperature sensor, a measuring main body 10 equipped with a display window 12 displaying one or more measured numeric values of temperature, humidity and mold index being measured and a connecting cord 18 connecting the probe 20 and the measuring main body 10 electrically. An analog temperature and humidity detecting part which outputs detection signals of the humidity sensor and the temperature sensor as output signals corresponding to relative humidity and temperature respectively, an analog-to- digital converter respectively, an arithmetic element for calculating the mold index corresponding to the measured temperature and relative humidity, which comprises an ROM storage unit, an RAM storage unit and a microprocessor, and a power source part supplying a DC power are provided in either the measuring main body 10 or the probe 20.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a measuring device capable of quantitatively evaluating an environmental condition relating to habitability based on a fungus index which indicates the degree of mold development and reproduction.

[0002]

2. Description of the Related Art There are places in a house where mold is likely to occur. For example, a place related to water supply such as a kitchen, a washroom, and a bathroom. In addition, the susceptibility of mold to the mold depends on the location of the building itself. For example, in a place where the installation site is a swamp or where the sunlight is extremely short, most rooms in the house are prone to mold. The prevention of mold is not only important for the habitability of people who live, but also extremely important for quality control and storage of various items, equipment, foods, and the like.

As an evaluation method for quantitatively measuring the susceptibility of mold or easiness of mold growth to judge, a method already proposed by the present applicant in Japanese Patent Application Laid-Open No. 5-38296 is known. Has been. This evaluation method is very easy to understand because it uses only one display index, but it is not widely used yet. In many cases, the indoor environment is expressed only by physical and chemical environmental factors such as humidity, temperature, radiant heat, and CO ₂ concentration, and the measured quantities that take into account biological environmental factors such as mold are not used. Therefore, the easiness of mold development or the quality of mold reproduction is only empirically determined.

[0004]

SUMMARY OF THE INVENTION The object of the present invention is based on the mold index, which can quantitatively, reliably and easily measure the degree of mold growth based on the measuring method disclosed in Japanese Unexamined Patent Publication No. 5-38296. It is to provide an environment evaluation measuring device.

[0005]

According to the present invention, there is provided an environment-evaluating and measuring apparatus for measuring temperature and relative humidity of a place and numerically obtaining a fungus index indicating a degree of mold development and reproduction. Yes, humidity sensor 30 and temperature sensor 3
1 and a measurement main body 10 having a display window 12 for displaying a measured value of any one or more of measured temperature, humidity and mold index, and a humidity sensor 30 and a temperature sensor. An analog temperature / humidity detecting section that outputs the detection signals detected by 31 as output signals corresponding to relative humidity and temperature, and an analog / digital converter that converts the analog output signals of the analog temperature / humidity detecting section into digital values, respectively. Calculate the mold index corresponding to the measured temperature and relative humidity based on the analog-digital conversion functional elements consisting of 36 and 37, and the data of mold index previously obtained under various temperatures and relative humidity. ROM storage 45 and RAM storage 46 for
The measurement main body 10 and the probe 20 are provided with a calculation function element including a microprocessor 44 and a power supply unit that supplies the DC power required from the battery 40 to each circuit element.
It has been solved by preparing for either.

Other advantageous configurations according to the invention are described in the dependent claims.

[0007]

The basis of the environment evaluation measuring apparatus according to the present invention is, as described above, to use the mold index proposed in Japanese Patent Laid-Open No. 5-38296. The mold index is used as a measure of the degree of growth and reproduction of mold, and can be experimentally determined from temperature and relative humidity. That is, the mold index is the mold (J-183) in a specific medium (water containing a proper amount of gelatin and glucose) under a specific temperature and specific relative humidity.
The growth rate (actually the length of fungal hyphae) of the strain is measured, and it is used as a reference environmental condition (temperature 25 ℃, relative humidity 9
2.5%, the same mold and medium are used).

The mold index under various environmental conditions is a contour line as shown by the solid line in FIG. 1 when the horizontal axis represents relative humidity (%) and the vertical axis represents temperature (° C.).
20, 40, 80, 160 represent the mold index at that time. S in the figure
C is a standard climate with a mold index of 168 (24 x 7). Black circles, squares, and black triangle marks indicate spore germination 1
Shown on days, 2-7 days, and 8-30 days. Moreover, the-marked area indicates that germination was not observed in the culture for 30 days. In the standard environmental conditions, the mold index shows the highest value of 179.

According to the present invention, the data of the mold index shown in FIG. 1 is stored in a table in a memory, and the mold index under the measured environment (that is, the temperature T and the relative humidity H at the location) is stored.
A can be calculated by interpolation from the stored mold index close to the environment, or a formula for the mold index that best fits the data in Fig. 1 can be obtained in advance, and the desired temperature can be calculated from this formula.
Determine the mold index A under T (° C) and relative humidity H (%). The calculation formula that fits the data in Fig. 1 can be approximately expressed as A = a T ² H ³ + b T ² + K (1). Where a = (589 ± 2) x 10 ^-9 b = (185 ± 2) x 10 ^-3 K = constant determined by the error accuracy of the temperature / humidity sensor.

In addition, the mold index is a predetermined discrete value, for example,
2, 4, 6, ····················· is limited to 160, and the range of temperature T and relative humidity F corresponding to each discrete value is determined in advance,
There is also a method of determining the mold index depending on the range to which the measured temperature T and relative humidity F belong.

[0011]

EXAMPLES The present invention will now be described in more detail based on examples. FIG. 2 is a schematic perspective view showing the overall configuration of the environment evaluation measuring device according to the present invention. This environment evaluation measuring device includes a measuring main body 10, a probe 20, and both 10,
It is composed of a flexible connection cable 18 that connects between 20. The probe 20 includes a tip portion 24 and a probe body 22, and has a lightweight structure that allows the probe body 22 to be held with one hand. Inside the tip portion 24, there are provided a temperature sensor and a humidity sensor (not shown in FIG. 2) for detecting the temperature and humidity of the outside air. Further, the tip 24
Is provided with a plurality of notches 26 and open holes 28 so that both sensors are constantly exposed to the outside air. The measurement main body 10 includes a display window 12 for displaying measured values, a main power switch 14, a display changeover switch 15, and a connector receiver 16 for connecting a connection cable 18. The display window 12 displays the measured temperature, relative humidity, and the mold index obtained from the measured temperature and relative humidity based on the mold index data described above by an interpolation formula or a predetermined equation (1) in digital or analog form. it can. A liquid crystal display as the display window 12,
An LED display, a plasma display, etc. can be used, and the measured values of the above three types can be displayed simultaneously or by switching. The display changeover switch 15 is used for this changeover.

FIG. 3 shows functional blocks of electric circuits provided inside the measurement main body 10 and the probe 20. In the case of this embodiment, the humidity sensor 30 in the probe 20 is composed of a substrate having two electrodes sandwiching a high molecular polymer moisture sensitive film, and the temperature sensor 31 is composed of a thermistor. Both sensors 30 and 31 are oscillating circuit bodies 32 and 3 respectively.
And 3 form one RC oscillation circuit. After the oscillating circuit bodies 32 and 33, frequency / voltage converters 34 and 35 for converting the oscillating frequency into corresponding voltages are connected, respectively. Further, the output signals of the frequency / voltage converters 34 and 35 are supplied to the measurement main body 10 via the conductors L _{1 and} L _{2 ,} respectively, and the probe 2 from the measurement main body 10 via the conductor L _3.
The DC power supply β is supplied to each circuit element in 0. Conductor L _1,
L _2, L ₃ constitutes the connection cable 18 Fig.

Next, both frequency / voltage converters 34, 35 in the probe 20 convert the analog output voltages of these frequency / voltage converters into digital values, so that the measurement main unit 1
The analog-to-digital converters 36 and 37 in 0 are followed respectively. In addition to this, the DC power supply α supplied from the power supply of the battery 40 to each circuit element in the measurement main body through the distributor 41 and the voltage of the DC power supply β supplied to each circuit element in the probe 20 described above. An analog-to-digital converter 38 for converting the voltage of the DC power supply into a digital value is also provided in the measurement body 10 for the purpose of monitoring, that is, after all, the voltage of the battery 40.

Analog / digital converters 36, 37, 3
The digital output signals of 8 are introduced into the first interface 47 and connected to each other via the bus line 48.
It is introduced into a computer system including a memory 45, a RAM memory 46 and a microprocessor 44. ROM memory 4
5 stores the procedure of the arithmetic processing, and the relationship between the mold index relating to the temperature and the relative humidity described above in the form of a table or the equation (1) described above. The RAM storage device 46 is for temporarily storing the numerical values being processed by the microprocessor 44. In this computer system, based on the equations (1) of the output signals from the analog / digital converters 36 and 37 and the mold index or the table of data, the microprocessor 44 determines the location based on the temperature and relative humidity under the measured conditions. Calculate the mold index of.

The calculated mold index and the measured values of temperature and relative humidity are supplied to the display section 42 corresponding to the display window 12 (FIG. 1) via the second interface 43,
Three kinds of measurement data can be displayed there simultaneously or individually. In this embodiment, since the individual display is adopted, the data is switched by using the display changeover switch 15.

In addition to digital display, bar level display (analog display) using LED elements or bar color display is also possible. For example, a three-stage display indicating the degree of mold generation, which does not occur, is likely to occur, and is extremely likely to occur, is displayed in different colors (red, blue, and yellow). If necessary, it is possible to display the measured numerical value or the degree of susceptibility by voice.

As the temperature sensor 31, other than the thermistor element, a thermocouple such as a copper constantan or iron constantan element can be used. Furthermore, in addition to the humidity sensor 30 composed of electrodes sandwiching the polymer layer,
An inorganic material humidity sensor composed of a dielectric layer and a gold vapor deposition film can also be used. In any case, it is necessary that the heat capacity be as small as possible so that the equilibrium value can be reached immediately by directly contacting the outside air.

When the probe 20 is replaced by the failure of the humidity sensor 30 or the temperature sensor 31, or only the failed sensor is replaced, the characteristics of the RC oscillation circuit may be deviated. To compensate for this shift, a circuit configuration as shown in FIG. 4 can be considered. That is, it is conceivable that some or all of the resistors and capacitors of the oscillation circuit bodies 32 and 33 are variably adjusted. That is, in the case of FIG. 4, one or both of the variable resistors R _{1 and} R ₂ and the trimmer capacitors C _{1 and} C ₂ are adopted for the resistors and the capacitor elements in the oscillation tank circuit.

In addition to the mold index measuring mode, the environment evaluation measuring device of the present invention also has a mode for monitoring malfunctions of the device itself. That is, the arithmetic processing procedure is determined such that the mold index measurement period and the malfunction monitoring period are automatically repeated alternately for a specific period at a predetermined timing. In the mold index measurement period, the mold index described above is obtained from the measured temperature and relative humidity. In the malfunction monitoring period, first, it is checked whether the voltage of the DC power supply is below a predetermined value, and then the measured temperature is the lower limit value _TL. It is inspected whether the temperature is below (for example -10 ° C) or below, and then the measured temperature is above the upper limit value _TH (for example + 60 ° C). Finally, check whether the measured relative humidity is above the upper limit relative humidity (eg 99.9%). If any of these inspections deviates from the specified range, it means that these malfunctions or malfunctions have been detected, and a corresponding malfunction message is displayed on the display of the display window 12 or, in some cases, malfunction display. The alarm lamp (not shown in this embodiment) may be turned on.

Finally, the internal structure of the environment evaluation measuring device according to the present invention can be configured differently from the embodiment described above. In the above embodiment, the actual temperature and humidity are respectively converted into the corresponding resonance frequencies of the resonance circuit having the temperature sensor and the humidity sensor as the resonance circuit elements, and these frequencies are extracted as the output signals of the corresponding temperature and humidity. Adopted circuit method. However, a constant DC or AC voltage (or current) is applied to the temperature sensor and humidity sensor, respectively, and the current (or voltage) generated at that time is measured, which is finally output as an analog output signal corresponding to temperature and humidity. It is also possible to take out a circuit system. that time,
When using a DC applied power supply, differential amplification using a well-known operational amplifier is adopted, and when using an AC applied power supply, a modulation / demodulation circuit or a rectification circuit (detection amplification) is used. . Furthermore, in this case, it is also necessary to consider the circuit technology similar to that of FIG. 4 for compensating the nonuniformity of the characteristics of the temperature and humidity sensors. This can be easily conceived by a person skilled in the art and will not be described further here.

Furthermore, unlike the circuit arrangement described above on the basis of the exemplary embodiment, the analog-digital converters 36, 37, 38 provided in the measuring body 10 can also be moved into the measuring probe 22. Furthermore, the ROM storage device 45, the RAM storage device 46, and the microprocessor 44, which are computer systems provided in the measurement main body 10, may also be moved into the measurement probe 22. Of course, in addition to the RC oscillator circuit, another oscillator circuit, such as an LC oscillator circuit, can be used. In any case, it goes without saying that all the device configurations defined in the claims belong to the scope of the present invention.

[0022]

As described above, when the environment evaluation measuring device according to the present invention is used, the degree of mold growth can be quantitatively, reliably, and easily automatically measured, and a practical living environment evaluation and foods can be obtained. It is extremely useful for managing and storing.

[Brief description of drawings]

FIG. 1 is a graph showing the relationship between mold index (represented by contour lines) that is determined according to temperature and relative humidity.

FIG. 2 is a perspective view showing the overall configuration of the environment evaluation and measurement device according to the present invention.

FIG. 3 is a block diagram showing connections of all circuits of the environment evaluation measuring device according to the present invention.

FIG. 4 is a circuit diagram showing a configuration of an oscillation circuit having a coarse adjustment circuit element.

[Explanation of symbols]

 10 Measurement Main Body 12 Display Window 14 Power Switch 15 Display Changeover Switch 18 Connection Cable 20 Probe 22 Probe Main Body 24 Tip 26 Cutout 30 Humidity Sensor 31 Temperature Sensor 32, 33 Oscillation Circuit Main Body 34, 35 Frequency / Voltage Converter 36, 37, 38 analog / digital converter 40 battery 41 power distribution circuit 42 display 43, 47 interface 44 microprocessor 45 ROM storage 46 RAM storage

Claims (7)

[Claims] 1. A humidity sensor (30) and a temperature sensor (31) are provided in an environment evaluation measuring device that measures the temperature and relative humidity at the location and numerically obtains a mold index indicating the degree of mold generation and reproduction. A humidity sensor comprising a probe (20) provided with the measurement body (10) having a display window (12) for displaying a measured value of any one or more of measured temperature, humidity and mold index. An analog temperature / humidity detection circuit that outputs detection signals detected by (30) and the temperature sensor (31) as output signals corresponding to relative humidity and temperature, respectively, and an analog output signal output from this analog temperature / humidity detection circuit. The analog-to-digital conversion functional elements, which consist of analog-to-digital converters (36, 37) for converting into digital values respectively, are obtained in advance under various temperatures and various relative humidity. From the ROM memory (45), the RAM memory (46) and the microprocessor (44) for calculating the mold index corresponding to the measured temperature and the relative humidity based on the data of the mold index. It is characterized in that any one of the measurement main body (10) and the probe (20) is provided with a computing function element and a power supply section for supplying a DC power required from the battery (40) to each circuit element. , Environmental evaluation measuring device by mold index. 2. The mold index corresponding to the measured temperature and relative humidity is determined in advance under various temperatures and relative humidities and stored in the ROM storage device (45) in the form of a table. Calculated by interpolation using mold index data, or predetermining the range of temperature and relative humidity corresponding to the discrete mold index, and corresponding to that range based on the measured temperature and relative humidity range The mold evaluation index according to claim 1, wherein the mold index is determined and calculated. 3. The ROM storage device (45) stores an interpolation formula obtained from mold index data obtained in advance at various temperatures and various relative humidities, and stores the measured values at the relevant temperature and relative humidity. The mold evaluation index according to claim 1, wherein the corresponding mold index is calculated each time using the interpolation formula. 4. In the interpolation formula, the mold index A is A = a T ² H ³ + b T ² + K, where A = mold index T = measured temperature (° C) H = measured relative Humidity (%) a = (589 ± 2) x 10 ^-9 b = (185 ± 2) x 10 ^-3 K = It can be expressed as a constant determined by the error accuracy of the temperature / humidity sensor. Environmental evaluation and measurement device based on the mold index. 5. There are two types of calculation periods of the calculation function element, both calculation periods are alternately performed in a predetermined cycle, one calculation period is a period for calculating a mold index, and the other calculation period is 5. A period during which a malfunction of the measurement system is investigated, and the malfunction is determined by detecting a decrease in the DC power supply voltage and the infeasibility of the measured temperature and relative humidity. 2. An environment evaluation measuring device according to the mold index according to item 1. 6. The display window (12) can simultaneously display the measured temperature and relative humidity and the mold index obtained from both measured values, or can individually display the three data, temperature, relative humidity and mold index. An environment-evaluating and measuring apparatus based on the mold index according to any one of claims 1 to 5, characterized in that it has an indicator that can be used. 7. The mold according to any one of claims 1 to 6, characterized in that the display is also provided with a voice generator for transmitting measured values by voice or transmitting a required message. Environmental evaluation measuring device by index.