JPH0754307B2 - Soil moisture content measurement method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Field of Industrial Application) The present invention relates to a method for measuring the water content in soil, and more specifically, it has a high measurement accuracy and can be repeatedly measured, and the soil The present invention relates to a method for measuring soil water content, which can easily determine whether the water content is optimum at the time of backfilling.

(Prior Art) It is well known that the degree of compaction of backfilled soil, that is, the degree of compaction is an important factor in cultivated land, river areas, building construction sites, and the like. It is also known that soil compaction degree is greatly influenced by soil type and water content.

Conventionally, as a means to measure the compaction degree of backfilled soil,
There is a sand replacement method of JISA1214, etc., to measure the water content of the backfilled soil is known, but what was used for the means of measuring the water content at that time is to dry the sample according to JIS A1203. This is a method of obtaining the water content. On the other hand, as a means for easily measuring the water content of soil, sand, etc. used for backfill soil on site, an infrared moisture meter as a commercial product and the applicant previously proposed it as Japanese Patent Application No. 61-189582. A specific heat type simple water content measuring device is known.

(Problems to be solved by the invention) The drying method according to JISA1203 is a method in which a sample is taken from the site, dried in a dryer at 110 ° C. until a constant weight is obtained, and the water content is measured from the weight difference, The infrared type is
It utilizes that infrared rays of a specific wavelength are absorbed according to the amount of water contained in the subject. Therefore, such a drying method cannot easily measure water content directly on site,
Further, the drying method has a drawback that it takes a long time to dry and the measurement result cannot be obtained on the spot.

On the other hand, the specific heat type simple moisture content measuring device is a device that directly inserts the sensor into the soil to generate heat and detects the water content in the soil from the amount of heat escape, so it is possible to work directly at the site. is there.

However, since this sensor has a structure in which metal is connected with resin, it is fragile and there is a risk of wire breakage especially when trying to insert it into the compacted soil used for backfilling. , When embedded, it causes an error in measurement,
There was a drawback that the accuracy fell.

Further, since the heat used for the measurement once remains, the sensor needs to be left until it can be used next time, and it has a drawback that it cannot be repeatedly used continuously.

The present invention has been made to solve the above-mentioned conventional drawbacks.

[Structure of Invention]

 (Means for Solving the Problems) Means in the present invention are as follows.

(1) A method of measuring a water content of a soil in which a sensor is inserted into the soil and the amount of heat emitted from the sensor escapes into the soil to measure a water content in the soil. After inserting the pin made into the soil and pushing away the soil to make a guide hole, insert the sensor into the hole and push the soil further to bring the sensor into close contact with the soil and use this sensor. A method for measuring soil water content, which comprises measuring the water content in the soil.

(2) The sensor for which the measurement of the soil water content is completed is put in a cooling container, the sensor is cooled to the original temperature in a short time, and then the sensor is again used for moisture measurement. Method for measuring soil water content.

(3) The cooling container has a water-holding substance sufficiently containing water therein, and is configured to cool the sensor to the original temperature in a short time. Method for measuring soil water content.

(4) A sensor is electrically connected to a computing unit that determines whether or not the water content of the backfilled soil is appropriate to reach a predetermined compaction degree or more after backfilling. The method for measuring soil water content according to claim (1), claim (2) or claim (3).

(Operation) In the invention according to claim 1, (a) the sensor can be easily inserted into the compacted soil by making a guide hole with a pin. (B) For this guide Since the hole in the is opened by pushing the soil away, and the sensor will push this hole further, this sensor will stick to the soil as if it was inserted into the soil from the state without the hole. can do.

Therefore, as compared with the case of digging a hole by removing the soil and inserting the sensor into this hole, there is very little room for an air layer to enter between the sensor and the soil and the surrounding soil, so It is possible to accurately measure the true water content.

Further, in the invention according to claim 2, (c) the sensor whose measurement of the water content of the soil is completed can be cooled to the original temperature in a short time by the cooling container, so that the water content of different positions is measured. Even in that case, the time interval can be shortened.

Furthermore, in the invention according to the third aspect, (d) the water is contained in the water-retaining substance, so that the water in the cooling container can be stably retained.

Further, in the invention according to claim 4, since the sensor is connected to the arithmetic unit, the degree of compaction of the soil after backfilling with the soil is determined from the water content of the soil. Whether or not the value is reached can be immediately determined.

In the present invention, it is a sensor that directly senses moisture, and the structure and operation of this sensor will be described with reference to the drawings.

FIG. 1 is a sectional view of the sensor.
It consists of a cylindrical container made by connecting 3'and the resin parts 4, 4 ', and one side of which is projectingly closed. A heater 1 and a temperature sensor 2 are provided therein in contact with the metal portion 3 at the tip, and a temperature sensor 2'for reference is provided in contact with the metal portion 3 '.
Are provided, which are electrically connected by a lead wire 5 and fixed by a rubber cap 6.

When this sensor 10 is inserted into the soil and the heater 1 is caused to generate heat, the heat is transferred to the temperature sensor 2 and at the same time escapes into the soil in contact with the periphery of the metal part 3. This amount of heat escape (absorption) depends on the water content in the soil, so if the calorific value is kept constant, the water content can be known from the amount of heat escape.

Further, FIG. 2 shows an example of another sensor. The sensor 10 includes a heater 1, a temperature sensor 2, a heater 1 ', and a reference temperature sensor 2'at the tip of a container in which a metal is coated with a heat resistant resin. Are sequentially connected by the lead wire 5 and housed therein, and the periphery thereof is filled with a temperature loss body 7 such as polybutadiene. In the case of this example, since the temperature sensor 2 is sandwiched by the two heaters 1 and 1 ', the temperature sensor 2 is suitable for measuring the water content of soil with a large amount of water, that is, the soil with a large amount of heat escape.

(Example) Hereinafter, the Example of this invention is described.

FIG. 3 is a schematic diagram showing a water content measuring device, in which four sensors 10 are fixed to a mounting plate 12 with nuts 13, and a level 19 and a shaft rod 18 project upward in the center of the mounting plate 12. Has been done.

On the other hand, the lead wire 5 from the sensor 10 is connected to a calculation determination unit (calculator) 14. The calculation determination unit 14 includes a select switch 16, a determination LED display unit 17, and a display unit 20.

FIG. 4 is a schematic view of a guide jig used in the present invention. The shape is almost the same as the sensor of the moisture content measuring device, but the part projecting below the mounting plate 12 is arranged at the same interval as the sensor 10. The metal pin 11 is stronger than the sensor 10.
And each pin 11 is made slightly thinner than the sensor 10.

FIG. 5 is a block diagram showing the operation of the computer and the determination mechanism by the computer in the operation determination unit 14.

FIG. 6 is a diagram of a sensor cooling container. That is, a plastic cooling container 15 is filled with a water-containing coolant (water-holding substance) 22, and a lid 21 having a hole 23 is formed.

Next, an example of implementing the present invention will be shown.

Here, an example is shown in which improved soil is used as an embedding material and the judgment value of the water content necessary for achieving a predetermined compaction degree after backfilling is standardized. First, the improved soil that passed through the 4.75 mm sieve was backfilled in two layers in a mold with a diameter of 15 cm and a height of 12 cm.
A disk weighing 5 kg was struck on each layer from the height of 5 cm 10 times to compact the entire surface, and then the pin 11 of the guide jig shown in Fig. 4 was inserted perpendicularly to the compacted surface, and the sensor The measurement position was decided. At this time, the soil is pushed away by the pin 11,
A hole is formed. Next, the guide jig was pulled out, and the sensor of the water content measuring device shown in FIG. 3 was carefully inserted into the hole previously drilled. At this time, the hole formed by the guide jig is one turn thinner than the sensor 10. Therefore, the sensor 10 can push the soil further,
From the beginning, it sticks to the soil as if it was inserted only with the sensor 10. However, the sensor 10 could be easily inserted with much less force than it was by itself with holes already drilled. 7 and 8 are calibration curves of improved soil and sea sand, and FIG. 7 shows the difference in sensor output-water content curve depending on whether or not a guide jig is used. From the figure, the measurement is performed three times at each measurement point, but obviously the variation is smaller when the guide jig is used.
Also, it can be seen that the calibration curve is stable. According to JIS A1210, the relationship between soil dry density and water content Figures 9 and 10 show the compaction characteristics as shown in FIG. From Fig. 9, when the specified soil was compacted,
It can be seen that when the water content is 8 to 20%, the compaction degree is 90% or more, and further, in the range of 9.3 to 17.3%, the compaction degree is 95% or more. When this is replaced with the moisture content measuring instrument of the present invention, as shown in Table 1, the compaction degree of 90% or more is 0.
The range is 79 to 1.20V, and the compaction degree of 95% or more is 0.86.
It will be ~ 1.14V.

Using this as the judgment standard, the judgment unit 1 in the arithmetic unit (CPU)
In addition, the third-order equation obtained from the calibration curve shown in FIG. As a result, first, when the select switch 16 of the main body is set to the improved soil, the input / output port composed of the arithmetic unit 1 and the determination unit 1 inside the CPU receives the sensor input signal. After the measurement is completed, the input signal of the sensor is calculated by the calculation unit 1 as the weight moisture content, and the process moves to the moisture content display unit 20 and the determination unit 1. The weighted water content value input to the determination unit 1 is numerically compared to determine which of the three classifications shown in Table 1 falls into, and then the determination LED display unit 17 (A, B, C) is turned on. For example, when the input signal of the sensor is 1.1V, the display of water content is
It becomes 10% and the judgment LED display section 17A lights up. The measurement principle of the sensor is a known method of knowing the amount of water by discharging a certain amount of heat from the inside of the sensor and measuring the amount of escape of that amount of heat. It takes time to measure continuously. This is a phenomenon that occurs because heat is trapped inside the sensor, and in order to improve it,
Fig. 11 shows the results of repeated tests using sea sand (water content 10%) when the sensor cooling container of Fig. 6 was used after measurement and when it was not used. From the figure, when the cooling container 15 is used after the measurement indicated by the circle, it returns to the original base temperature in about 2 minutes and shows stable reproducibility. When the sample is left to cool in the air without using, the base temperature does not return to the initial value and the measurement error occurs up to about 2 to 3% in 2 minutes.

Further, the waiting time until the next measurement took about 10 minutes when the cooling container 15 was not used, whereas it can be measured in about 2 minutes when the cooling container is used.

〔The invention's effect〕

 According to the method of the present invention, the following effects can be obtained.

In the invention according to claim 1, (a) the sensor can be easily inserted into the compacted soil by making a hole for the guide with a pin. (B) The hole for the guide is It is opened by pushing the soil away, and the sensor will push this hole further, so this sensor can be in close contact with the soil as when it was inserted into the soil from the state without holes. it can.

Therefore, as compared with the case of digging a hole by removing the soil and inserting the sensor into this hole, there is very little room for an air layer to enter between the sensor and the soil and the surrounding soil, so It is possible to accurately measure the true water content.

Further, in the invention according to claim 2, (c) the sensor whose measurement of the water content of the soil is completed can be cooled to the original temperature in a short time by the cooling container, so that the water content of different positions is measured. Even in that case, the time interval can be shortened.

Furthermore, in the invention according to the third aspect, (d) the water is contained in the water-retaining substance, so that the water in the cooling container can be stably retained.

Further, in the invention according to claim 4, since the sensor is connected to the arithmetic unit, the degree of compaction of the soil after backfilling with the soil is determined from the water content of the soil. Whether or not the value is reached can be immediately determined.

[Brief description of drawings]

FIG. 1 is a sectional view of a sensor, FIG. 2 is a sectional view of another sensor, FIG. 3 is a schematic view of a water content measuring device, FIG. 4 is a schematic view of a guide jig, and FIG. Block diagram, FIG. 6 is a plan and side view of the sensor cooler, FIG. 7 is a calibration curve of voltage and moisture content of improved soil, FIG. 8 is a calibration curve of voltage and moisture content of sea sand, FIG. 9 and FIG. 10 is a graph showing the relationship between the moisture content and the dry density of the improved soil, and FIG. 11 is a graph showing the relationship between time and temperature showing the results of repeated tests with sea sand. 1 …… Heater 2 …… Temperature sensor 5 …… Lead wire 7 …… Temperature loss body 10 …… Sensor 11 …… Pin 14 …… Calculation judgment unit (calculator) 15 …… Cooling container 21 …… Lid 22… … Coolant (water-holding substance)

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Yoshiharu Nagawa, 23 Minamikashima, Futatama-cho, Tenryu-shi, Shizuoka Prefecture, inside the Yazaki Keiki Co., Ltd. (72) Inventor, Yoshiaki Ishiguro, 23, Minamikashima, Futamata-cho, Tenryu-shi, Shizuoka (56) References JP 62-87841 (JP, A) JP 63-156110 (JP, A) JP 30-4846 (JP, B1) JP 48-35838 (JP, Y1)

Claims (4)

[Claims] 1. A method for measuring a water content of a soil, wherein a sensor is inserted into the soil, and the amount of heat emitted from the sensor escapes into the soil to measure the water content in the soil. After inserting a large metal pin into the soil and pushing out the soil to make a guide hole, insert the sensor into the hole and push the soil further to bring the sensor into close contact with the soil. A method for measuring the soil water content, which comprises measuring the water content in the soil by using. 2. The method of claim 1, wherein the sensor whose soil water content has been measured is placed in a cooling container, the sensor is cooled to the original temperature in a short time, and then the sensor is again used for moisture measurement. ) The method for measuring soil water content as described above. 3. The cooling container has a water-holding substance in which water is sufficiently contained therein, and the sensor is cooled to the original temperature in a short time. ) The method for measuring soil water content as described above. 4. A sensor is electrically connected to a computing device for determining whether or not the water content of the backfilled soil is appropriate to reach a predetermined compaction degree or more after backfilling. The method for measuring soil water content according to claim (1), claim (2) or claim (3).