KR20230067089A - Apparatus, System and Method for measuring soil surface static electricity using a capacitive structure, and a recording medium recording a computer readable program for executing the method - Google Patents

Abstract

Disclosed are a soil surface static electricity measurement device using a capacitive structure, a system, a method, and a recording medium recording a computer readable program for executing the method. A soil surface static electricity measuring device using a capacitive structure includes a bottom part, a plurality of electrodes, and a capacitance calculating part. The bottom part is formed so that soil can be accumulated on the upper side, and a plurality of electrodes are in contact with the soil accumulated on the bottom part and are separated from each other, and a capacitance calculation unit for calculating the capacitance of the soil using current and voltage from the plurality of electrodes include According to this configuration, it is possible to effectively directly detect static electricity on the soil surface by inserting the soil into the probe having an empty dielectric space and detecting a change in permittivity.

Description

Apparatus, System and Method for measuring soil surface static electricity using a capacitive structure, and a recording medium recording a computer readable program for executing the method a recording medium recording a computer readable program for executing the method}

The present invention relates to a technology related to measuring soil properties, and more particularly, to a system and method for measuring static electricity on a soil surface.

In analyzing and exploring local topography in extreme environments such as high-concentration radioactive areas, confined spaces, and space environments, robot-type probes including communication equipment and various measurement equipment are used throughout the industry. A probe composed of countless electronic devices is very vulnerable to mechanical, chemical, and electrical shocks, and the technology to protect the probe from these external influences is a very important technology for analyzing extreme environments.

In particular, in abandoned buildings that used high-voltage facilities, abandoned nuclear power plants with high radiation concentration, or space environments, environments that cause electric shocks due to static electricity between structures such as local soil and probes are scattered, and damage prevention techniques are essential. am.

On the other hand, the evaluation of electrical properties of soil has been developed for the purpose of grounding construction during building construction. In general, a 4-point probe method that observes resistance change using a probe-type probe according to the depth from the soil surface, or underground burial It is installed on the surface of the tube to measure the induced current.

However, this method is not a method of measuring the soil surface, but a method of measuring changes in the content of water in the ground, etc., and has limitations in that it is somewhat complicated and expensive in installation and construction.

In Korea, the main method is to measure the resistance change according to the water content using a probe type probe to evaluate the electrical characteristics of soil. Therefore, there is a need for a method for directly detecting static electricity on the soil surface.

KR 10-2143685 B1

The present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to provide a system and method capable of directly detecting static electricity on a soil surface.

In order to achieve the above object, an apparatus for measuring soil surface static electricity using a capacitive structure according to the present invention includes a bottom part and a probe part including a plurality of electrodes and a capacitance calculating part. The bottom part is formed so that soil can be accumulated on the upper side, and a plurality of electrodes are in contact with the soil accumulated on the bottom part and are separated from each other, and a capacitance calculation unit for calculating the capacitance of the soil using current and voltage from the plurality of electrodes include

According to this configuration, by inserting soil into the probe having an empty dielectric space and detecting a change in permittivity, it is possible to effectively directly detect static electricity on the soil surface.

In this case, a Wheatstone bridge circuit unit connected between the plurality of electrodes and the capacitance calculating unit may be further included. According to this configuration, clear detection characteristics can be obtained even when fine static electricity is generated.

In addition, it may further include a capacitance storage unit for storing a calculated value of the capacitance of the soil. According to this configuration, it is possible to grasp the temporal variation of the capacitance by using the stored past information together.

In addition, an initial value correction unit for correcting an initial value of the capacitance storage unit when soil is accumulated on the upper side of the bottom unit may be further included. According to this configuration, by setting the initial value, the perception of the temporal variation of the capacitance can be more clearly recognized.

In addition, a communication unit for transmitting the calculated capacitance value to the outside may be further included. According to this configuration, it is possible to monitor the occurrence of static electricity in the target soil even in a remote place.

In addition, a danger signal output unit may be further included to output a danger signal when the amount of change in the calculated capacitance exceeds a preset reference range. According to this configuration, a user or a robot can take immediate countermeasures against static electricity fluctuations in a dangerous situation.

In addition, the soil surface static electricity measurement system using the capacitive structure according to the present invention is a system including a plurality of soil surface static electricity measurement devices that communicate with different soil surface static electricity measurement devices disposed adjacent to each other. The static electricity measuring device calculates the capacitance of the soil using a bottom portion formed so that soil can be accumulated on the upper side, a plurality of electrodes separated from each other and in contact with the soil accumulated on the bottom portion, and current and voltage from the plurality of electrodes. It includes a capacitance calculation unit.

According to this configuration, it is possible to simultaneously monitor soil surface static electricity in a wide area by installing a plurality of modularized static electricity measuring devices in a grid form.

In addition, the soil surface static electricity measurement method using the capacitive structure according to the present invention is a soil surface static electricity measurement method performed by the soil surface static electricity measurement device, wherein the initial value correction unit detects static electricity when soil is accumulated on the upper side of the bottom part. Correcting the initial value of the capacitance storage unit, calculating the capacitance of the soil by using the current and voltage from the plurality of electrodes by the capacitance calculator, and storing the calculated value of the capacitance of the soil by the capacitance storage unit. , and outputting, by the danger signal output unit, a danger signal when the amount of change in the calculated capacitance exceeds a preset reference range.

In addition, a recording medium recording a computer readable program for executing the method is disclosed together.

According to the present invention, by inserting soil into a probe having an empty dielectric space and detecting a change in permittivity, it is possible to effectively directly detect static electricity on a soil surface.

In addition, it has clear detection characteristics even when fine static electricity is generated.

In addition, it is possible to grasp the temporal variation of the capacitance by using the stored past information together.

In addition, by setting the initial value, the recognition of the temporal variation of the capacitance can be more clear.

In addition, it is possible to monitor the occurrence of static electricity in the target soil even in a remote location.

In addition, in a dangerous situation, a user or a robot can take immediate countermeasures to static electricity fluctuations.

In addition, by installing a plurality of modularized static electricity measurement devices in a grid form, soil surface static electricity can be simultaneously monitored in a wide area.

1 is a schematic block diagram of a soil surface static electricity measuring device using a capacitive structure according to an embodiment of the present invention.
FIG. 2 is a diagram schematically illustrating an example of an actual implementation of the probe unit of FIG. 1;
FIG. 3 schematically illustrates a measurement concept of the Wheatstone bridge circuit of FIG. 1; FIG.
4 is a schematic diagram for explaining the concept of data measurement and data transmission of a soil surface static electricity measuring system using a capacitive structure according to an embodiment of the present invention.
5 is a diagram schematically illustrating a measurement algorithm in a method for measuring soil surface static electricity using a capacitive structure according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a schematic block diagram of a soil surface static electricity measuring device using a capacitive structure according to an embodiment of the present invention, and the soil surface static electricity measuring device using a capacitive structure in FIG. 1 is a probe unit 110 ), a capacitance calculation unit 120, a wheatstone bridge circuit unit 130, a capacitance storage unit 140, an initial value correction unit 150, a communication unit 160, and a danger signal output unit 170, , The probe unit 110 includes a bottom portion 112 and a plurality of electrodes 114 again.

The bottom portion 112 is formed so that soil can be accumulated on the upper side, and the plurality of electrodes 114 come in contact with the soil accumulated on the bottom portion 112 and are separated from each other. FIG. 2 is a diagram schematically illustrating an example of an actual implementation of the probe unit of FIG. 1 .

In FIG. 2, the soil surface electrostatic measuring device has a simplified structure by utilizing a multilayer structure capacitance probe, and the dielectric space is empty in the multilayer structure capacitance probe, and as the soil is inserted, the permittivity change through It has static electricity detection characteristics.

The capacitance calculation unit 120 calculates the capacitance of the soil using the current and voltage of the plurality of electrodes 120 . According to this configuration, it is possible to effectively directly detect static electricity on the soil surface by inserting the soil into the probe having an empty dielectric space and detecting a change in permittivity.

The wheatstone bridge circuit unit 130 is connected between the plurality of electrodes 120 and the capacitance calculator 130 . According to this configuration, clear detection characteristics can be obtained even when fine static electricity is generated. FIG. 3 is a diagram schematically illustrating a measurement concept of the Wheatstone bridge circuit of FIG. 1 .

That is, the change in the capacitance value of the probe applied to the present invention causes the change in output current and voltage, and the output electrical signal can be finely detected through the wheatstone bridge (W.B.).

The capacitance storage unit 140 stores the calculated value of capacitance of the soil. According to this configuration, it is possible to grasp the temporal variation of the capacitance by using the stored past information together.

The initial value correction unit 150 corrects the initial value of the capacitance storage unit 140 when soil is accumulated on the upper side of the bottom part 112 . According to this configuration, by setting the initial value, the perception of the temporal variation of the capacitance can be more clearly recognized.

In other words, the present invention is designed to correct the initial value with the starting point of the time when the soil is included in the dielectric layer in the capacitive detection probe, and the capacitance value is have changing characteristics.

The communication unit 160 transmits the capacitance calculation value to the outside. According to this configuration, it is possible to monitor the occurrence of static electricity in the target soil even in a remote place.

The danger signal output unit 170 outputs a danger signal when the amount of change in the calculated capacitance exceeds a preset reference range. According to this configuration, a user or a robot can take immediate countermeasures against static electricity fluctuations in a dangerous situation.

The soil surface static electricity measurement device using the capacitive structure of FIG. 1 can be applied as a system capable of monitoring electrical characteristics of the soil surface under various environmental conditions. 4 is a schematic diagram for explaining the concept of data measurement and data transmission of a soil surface static electricity measurement system using a capacitive structure according to an embodiment of the present invention.

The soil surface static electricity measurement system includes a plurality of soil surface static electricity measurement devices shown in FIG. 1 communicating with other soil surface static electricity measurement devices disposed adjacent thereto. According to this configuration, it is possible to simultaneously monitor soil surface static electricity in a wide area by installing a plurality of modularized static electricity measuring devices in a grid form.

As such, since the capacitive static electricity measurement device proposed in the present invention has a very simple structure, it can be directly applied to the tip of the operating part of a robot in extreme cold regions, and can be applied to major points in the form of a single module for large-area soil surface monitoring. It can be installed in grid form.

In addition, the measured data can be directly transmitted to the probe MCU, and when a large-area grid-type measurement system is implemented, a battery and communication module are added to the rear of the module to monitor the large-area indicator with charging function and information transmission function according to static electricity. can be implemented in the system.

5 is a diagram schematically illustrating a measurement algorithm in a method for measuring soil surface static electricity using a capacitive structure according to an embodiment of the present invention. The soil surface static electricity measuring method of FIG. 5 is performed by the soil surface static electricity measuring device shown in FIG. 1 .

In FIG. 5, the initial value correction unit corrects the initial value of the capacitance storage unit when soil is accumulated on the upper side of the bottom, the capacitance calculation unit calculates the capacitance of the soil using current and voltage from a plurality of electrodes, and The capacity storage unit stores the calculated capacitance value of the soil, and the danger signal output unit outputs a danger signal when the amount of change in the calculated capacitance value exceeds a preset reference range.

In summary, the present invention relates to the detection of static electricity in soil in an extreme environment, and has a simple structure and can be applied to various fields of application, so that the stability of the probe is secured, and the measurement result is transmitted to the probe to detect static electricity according to the terrain. It can be used to collect data.

The present invention was developed for the purpose of maximizing the protection performance of electronic equipment applied in extreme cold regions, and according to the present invention, it is possible to obtain and provide data on occurrence of external static electricity.

Through the Wheatstone bridge circuit included in the present invention, it is designed to have clear detection characteristics even in the occurrence of minute static electricity, and it is possible to provide soil static electricity detection data over a large area through interactive communication between independent measurement modules.

The present invention has overall high usability in various industrial fields, especially safety management, instrumentation and system management fields, and has applicability in the field of research in extreme cold regions. In particular, it has the advantage of being applicable in the form of a very small size assembly when analyzing soil in an extreme environment where users cannot enter.

Although the present invention has been described by some preferred embodiments, the scope of the present invention should not be limited thereto, but should also extend to modifications or improvements of the above embodiments supported by the claims.

110: probe unit
112: bottom
114: multiple electrodes
120: capacitance calculation unit
130: wheatstone bridge circuit
140: capacitance storage unit
150: initial value correction unit
160: communication department
170: danger signal output unit

Claims (9)

A probe unit including a bottom portion formed to accumulate soil on the upper side, and a plurality of electrodes separated from each other and in contact with the soil accumulated on the bottom portion; and
The soil surface static electricity measuring device comprising a capacitance calculation unit for calculating the capacitance of the soil using the current and voltage from the plurality of electrodes.
The method of claim 1,
The soil surface static electricity measuring device further comprising a Wheatstone bridge circuit connected between the plurality of electrodes and the capacitance calculating unit.
The method of claim 2,
The soil surface static electricity measurement device further comprising a capacitance storage unit for storing the calculated value of the capacitance of the soil.
The method of claim 3,
The soil surface static electricity measurement device further comprising an initial value correction unit for correcting an initial value of the capacitance storage unit when soil is accumulated on the upper side of the bottom unit.
The method of claim 4,
The soil surface static electricity measuring device further comprising a communication unit for transmitting the capacitance calculation value to the outside.
The method of claim 5,
The soil surface static electricity measuring device further comprises a danger signal output unit for outputting a danger signal when the amount of change in the calculated capacitance value is out of a preset reference range.
A system including a plurality of soil surface static electricity measurement devices in communication with other soil surface static electricity measurement devices disposed adjacent to each other, the soil surface static electricity measurement devices comprising:
A bottom portion formed to accumulate soil on the upper side, a probe portion including a plurality of electrodes separated from each other and in contact with the soil accumulated on the bottom portion; and
The soil surface static electricity measurement system comprising a capacitance calculation unit for calculating the capacitance of the soil using the current and voltage from the plurality of electrodes.
A soil surface static electricity measuring method performed by the soil surface static electricity measuring device of claim 6,
correcting an initial value of the capacitance storage unit when soil is accumulated on an upper side of the floor by the initial value correction unit;
Calculating the capacitance of the soil by the capacitance calculating unit using the current and voltage in the plurality of electrodes;
storing the calculated value of the capacitance of the soil by the capacitance storage unit; and
and outputting, by the danger signal output unit, a danger signal when the amount of change in the calculated capacitance exceeds a preset reference range.
A recording medium recording a computer readable program for executing the method of claim 8.

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