JPS63193049A - Moisture control system using heat conductivity meter - Google Patents

Abstract

PURPOSE:To automate the title system, by calculating the heat conductivity of an object to be controlled from the signal issued from a thermal probe and sending out a required control signal according to the moisture content calculated from the heat conductivity and operating an control action apparatus on the basis of the control signal. CONSTITUTION:A heat conductivity meter 11 is provided. A current is supplied to the heater in a thermal probe 5 for a predetermined time and the temp. during said time is measured by a temp. sensor to allow the meter to calculate that conductivity. Further, soil that is an object to be measured is preliminarily sampled to calculate the correlation between the moisture content and heat conductivity of the soil. For example, the probe 5, a sprinkler 2 and a solenoid valve 4 controlling the feed of water of piping 3 are arranged to the green 1a of a golf course 1; water content is calculated from the temp. detected by the probe 5 through a heat conductivity meter 11 and the valve 4 is controlled by a control apparatus 12. By this method, moisture control is programmed and can be automated.

Description

DETAILED DESCRIPTION OF THE INVENTION "Field of Industrial Application"
This invention relates to a moisture management system using a thermal conductivity meter, in which the moisture content of the object to be managed is determined from the thermal conductivity of the object to be managed, and the moisture content of the object to be managed is automatically managed according to the moisture content. It is something.

"Conventional technology" Conventionally, for example, in the management of soil water molecules 1 (water content), a part of the soil to be controlled is sampled each time, and the water content of the sample is measured in a laboratory. It was common practice for humans to measure water and control, for example, the valves of a sprinkler system, based on the values obtained from the measurements.

In addition, in the moisture content measurement stage of management, R1 (radioisotope:
A method is sometimes taken in which the amount of water contained in the embankment is determined by applying a radioactive isotope (radioactive isotope) from the ground surface of the measurement site and determining the amount of water contained in the embankment based on a count that changes depending on the amount of water in the ground.

``Problems to be Solved by the Invention'' By the way, when measuring the moisture content of a controlled object whose moisture content is controlled using a sample, it takes time and effort to sample each time the measurement is made, and it is difficult to calculate the value. It took a very long time to get it out.

Furthermore, manual control based on the measurement results has the problem of constraining the person H and making it difficult to achieve highly accurate control.

In addition, in the moisture measurement stage of moisture management, RI
However, the equipment used is very expensive, costing several hundred square yen per unit, and can only measure the moisture content in the surface layer, which is several tens of centimeters below the ground surface, making it difficult to understand the cost. From this point of view, it was unreasonable.

The present invention has been made in view of the above circumstances, and allows moisture measurement to be carried out on-site by extremely simple means by determining it from thermal conductivity, as well as control based on the measurement results. It is an object of the present invention to provide a moisture management system that can be automatically performed by a control device that works with a moisture measuring device.

[Means for solving the problems] The moisture management system using the thermal conductivity meter according to the present invention has the following features:
A thermal probe embedded in a controlled object whose moisture content is to be controlled; a thermal conductivity meter that determines the thermal conductivity of the controlled object from a signal from the thermal probe; It is characterized by comprising a control device that sends a required control signal according to the moisture content of the object to be managed calculated from the thermal conductivity, and a management action device that operates based on the control signal, and further includes: The object to be managed is soil, and the management device is a water supply m of a watering device.
This includes electromagnetic valves that control or alarm equipment.

"Operation" The moisture management system according to the present invention calculates the moisture content of an object whose moisture is to be managed, based on the thermal conductivity of the object. Thermal conductivity can be easily measured using a thermal probe.
Moisture content is extremely easy to determine. Moreover, moisture management according to this moisture m is automatically performed by the control device.

"Embodiment" A first embodiment of the present invention will be described below with reference to FIGS. 1 to 4.

FIG. 1 shows an example in which the moisture management system according to the present invention is applied to moisture management of soil E (object to be managed) at a golf course. In the figure, the reference numeral 1 indicates a golf course, and the reference numeral 1a indicates a green. The green lala is equipped with a sprinkler (watering bag RTL) 2 for spraying water on the lawn of the green la. Water is supplied to the sprinkler 2 through a pipe 3 buried in the soil E. The piping 3 has the sprinkler
A solenoid valve (management device) 4 is provided that can supply and stop water to the tank 2. Also, Gooleen 1a
A so-called thermal probe, indicated by the reference numeral 5, is buried in the soil E below. This thermal probe 5 is as shown in FIG. 2, and has a heater 7 made of, for example, a constancouple, and a copper-constancouple (copper-constancouple) inside a small-diameter sealed stainless steel protective tube 6.
CG) or platinum (r't), etc., are provided in pairs. The heater 7 is configured to generate heat by receiving power from a constant current power source (not shown). In addition, the temperature detected by Temperature Centimeter 8 is
Momohabako I installed on the ground via centimeter cable 9
It is read by a thermal conductivity meter 11 housed in the chamber (FIG. 1).

A control device 12 is further installed inside the box 10 to receive an output signal from the thermal conductivity meter 11. The control device 12 sends a control signal S1 to the electromagnetic valve 4 via a control cable 13 in accordance with a moisture content value calculated based on the thermal conductivity of the soil E measured by the thermal conductivity meter 11. It is Party B who sends the.

The moisture management system according to this embodiment has these solenoid valves 4,
It comprises a thermal probe 5, a thermal conductivity meter 11 and a control device 12.

-Next, the operation of the moisture management system using a thermal conductivity meter having the above configuration will be explained.

The heater 7 of the thermal probe 5 is energized for a predetermined time T, and the temperature during that time is measured by the temperature sensor 8. Here, the relationship between time and temperature when a constant amount of heat is applied to a certain object for a certain period of time exhibits a certain correlation as shown in FIG.
att/am), set the sensor temperature at time t1 to 0.
+(”C), the sensor temperature at time t! is O,(”
C), the thermal conductivity λ can be obtained by the following formula, [CGS units] (MKS units).In other words, by performing the above calculation, the thermal conductivity of the soil 2 in which the temperature sensor 8 is buried is calculated as follows. Therefore, the rate can be calculated.

By the way, it has been found that there is a clear correlation between the water content m contained in the soil and the thermal conductivity, as shown in FIG. 4, for example. The figure shows the relationship between sandy soil (line diagram A),
and silt (diagram B). In other words, from the thermal conductivity of the soil,
This makes it possible to determine the moisture content of the soil. However, here, the correlation between moisture content and thermal conductivity is unique to the soil type.
Since it is necessary to understand the correlation between the water content ratio and thermal conductivity of the soil to be measured, the relationship must be determined in advance by sampling the soil to be measured. As a result, the thermal conductivity meter 11 measures the thermal conductivity λ
Once calculated, the water content ratio can be determined.

In this way, the moisture content of the soil E in the portion forming the green 1a is measured by the thermal probe 5. Information regarding the moisture content of the soil E is then sent to the control device 12. The control device 12 is programmed to send a control signal S to the solenoid valve 4 based on the information, and if the moisture content measurement result is insufficient for the required moisture content, the solenoid valve H is The sprinkler 2 is opened by the control signal S, and water is sprinkled from the sprinkler 2. At this time, even during watering, the moisture content of soil E is intermittently measured using the above method, and it is green! When the upper limit of the optimum moisture content range for a is reached, the solenoid valve 4 is closed by the control signal Sl.

Then, when the water reaches the lower limit of the Qili water content range as the water evaporates, the solenoid valve 4 is opened again and water is sprayed.

In this way, the above moisture management system measures the moisture (moisture content) of the soil E by measuring the thermal conductivity of the soil E.
Based on this data, the control device 12 performs ON10 FF control of the solenoid valve 14 based on the data;
In other words, the water content of soil E is adjusted. Soil B, that is, the younger sister volume of the managed object, can be immediately determined by measuring the thermal conductivity once the relationship between the thermal conductivity and moisture content of the managed object is understood.
Moisture measurement can be performed easily and in real time. Furthermore, since the control device 12 automatically adjusts the moisture content according to the measured value, it is possible to realize reliable moisture management without requiring any human intervention.

Note that the relationship between the thermal conductivity of the object to be managed and the moisture content determined by the thermal conductivity meter 11 can be expressed by a relational expression (mathematical expression), so depending on the parameter settings, it can be expressed directly from the thermal conductivity, It is also possible to activate the control bag &212.

FIG. 5 is a second embodiment of the present invention, which is an example in which the moisture management system according to the present invention is applied to predicting slope collapse due to rainfall.

In the figure, reference symbol E indicates soil, and the soil E forms a step surface 14. On the flat land located below the slope 14, that is, on the low-lying side, there is a system to issue a warning to people living in or passing through the low-lying area when there is a risk of the slope 14 collapsing. An alarm device (alarm equipment; management action device) 15 is provided. By the way, code 1
6 represents a road, and numeral 17 represents a railway. And slope 14
In the soil E whose side surface is
In the illustrated example, they are embedded in two rows). These thermal probes 5 are each connected to a thermal conductivity meter 11 installed on the ground via a sensor cable 9. The thermal conductivity meter 11 is a temperature sensor 8 provided in the thermal probe 5.
The temperature is measured over time, and the thermal conductivity of the soil E around the thermal probe 5 is calculated from the relationship between the measured time and the measured temperature. In the vicinity of this thermal conductivity meter 11, a control signal S is sent to the alarm via a control cable 13 according to the moisture content calculated based on the thermal conductivity calculated by the thermal conductivity meter 11. Control device 1 to send to 5
2 is installed.

The operation of the moisture management system according to this embodiment will be described below.

The moisture content of soil E is measured in the same manner as in the first embodiment. That is, first, the relationship between the water content ratio and the thermal conductivity of soil E, which is the measurement target (management target), is determined in advance using a sample.

Then, the heater 7 of the thermal probe 5 is heated with a constant current for a certain period of time T, and the thermal conductivity λ of the soil E is calculated from the relationship between the time 'r and the degree of temperature rise using the thermal conductivity meter 11. do. As a result, the moisture content of the soil E is calculated, slope stability analysis is performed based on the moisture content, and the information is transmitted to the control device ■2. When the safety factor according to the analysis reaches the collapse danger area of the slope 14, the control device 1
2 sends out a control signal SI, and the alarm device 15 issues an alarm. Here, the control device 12 does not simply send out one type of signal when the moisture content reaches a dangerous area, but the alarm 15 responds to the moisture m, that is, as the moisture content increases. By sending out different signals in stages and issuing different warnings depending on the situation at the time, residents of low-lying areas and passersby can be provided with more detailed information about the condition of the slope 14. You can also get it. In addition, as alarm equipment,
In addition to the above-mentioned alarm 15, it may be used as a traffic light, an emergency barrier, or an electric warning board, etc. By doing so, it is possible to prevent traffic such as the road 16 or railway 17 in the collapse danger area of the building E. It is also possible to implement automatic restrictions such as:

Since the moisture management system according to the present invention calculates the moisture content of soil etc. by measuring its thermal conductivity, as described above, the thermal probe 5
It is only necessary to measure the thermal conductivity, and as in this embodiment, it is also possible to easily measure the water content in the deep layer of the soil E.

In addition, by creating correlation graphs like the one shown in Figure 4 above for various types of soil in advance, it is possible to avoid the need to actually sample the ±(management target) to be measured. Once the soil quality is known,
An approximation can also be made from the graph, and in such a case, the effort of sampling and calculating the relationship between thermal conductivity and water content using samples can be saved.

In addition, in these examples, the target of moisture management is described as soil, but when the target of moisture management is soil in this way, in addition to the above, for example, farms, sports grounds, etc. Applications to etc. are also stored. Further, the moisture management system according to the present invention is not limited to soil as a management target, and can of course be applied to moisture management of other materials such as feed and raw materials.

"Effects of the Invention" As explained above, the moisture management system according to the present invention measures the thermal conductivity of the object whose moisture is to be managed using a thermal probe and a thermal conductivity meter, and The moisture content of the object to be managed is calculated from the water content, and the control device is controlled and driven by the control device based on the calculated moisture content, making it possible to fully automate the moisture management of the object to be managed using a program. Moreover, highly accurate control (management) can be achieved accordingly. Moreover, on-site moisture measurement is possible as long as the thermal conductivity of the object to be managed can be measured, so if the object to be managed is soil, for example, it is possible to measure the amount of moisture in the deep layer of the soil. This method has excellent effects such as being able to easily manage moisture even in deep layers.

[Brief explanation of the drawing]

FIG. 1 explains a first embodiment of the present invention, and is a side sectional view showing a moisture management system according to the present invention together with a golf course. FIG. 2 is a sectional view, not showing a thermal probe for measuring thermal conductivity according to the present invention. FIG. 3 is a diagram showing an example of the relationship between heating time and temperature of a thermal probe. Figure 4 is a diagram showing the relationship between soil moisture content and thermal conductivity. FIG. 5 shows a second embodiment of the present invention,
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side sectional view showing the water-distribution system according to the present invention together with soil having a slope.

Claims (1)

[Scope of Claims] 1) A thermal probe embedded in an object whose moisture content is to be controlled; a thermal conductivity meter that measures the thermal conductivity of the object from a signal from the thermal probe; A control device that sends a necessary control signal according to the moisture content of the object to be managed calculated from the thermal conductivity determined by a thermal conductivity meter, and a management action device that operates based on the control signal. A moisture management system using a thermal conductivity meter that is characterized by: 2) A moisture management system using a thermal conductivity meter according to claim 1, wherein the object to be managed is soil. 3) A moisture management system using a thermal conductivity meter according to claim 1 or 2, wherein the management device is a solenoid valve that controls the amount of water supplied to a water sprinkler. 4) A moisture management system using a thermal conductivity meter according to claim 1 or 2, wherein the management action device is an alarm facility.