KR102389100B1 - A sensor apparatus of pile-type and sensor fixing-type this is able to amplify sensing signal for diagnosing integrity of facilities - Google Patents

Abstract

The present invention relates to a pile-type sensor apparatus for diagnosing a health of a sensor fixed-type facility capable of amplifying a sensing signal. According to the present invention, the pile-type sensor apparatus for diagnosing the health of the sensor fixed-type facility capable of amplifying the sensing signal of the present invention is installed to a certain depth inside facilities such as slopes, buried pipes, dams and buildings to detect waves generated by structural displacement inside the facility. In addition, the pile-type sensor apparatus for diagnosing the health of the sensor fixed-type facility capable of amplifying the sensing signal amplifies an electrical waveform signal and provides a detection signal to the outside so that the health of the facility can be evaluated. Therefore, the structural displacement of the facility can be detected in advance before a serious structural displacement or collapse accident of the facility occurs, so that casualties and accidents can be prevented in advance. The pile-type sensor apparatus for diagnosing the health of the sensor fixed-type facility capable of amplifying the sensing signal comprises: an iron-type pile unit (100); a sensing unit (200); and an amplification unit (300).

Description

A sensor apparatus of pile-type and sensor fixing-type this is able to amplify sensing signal for diagnosing integrity of facilities}

The present invention relates to a file-type sensor device for diagnosing the health of a sensor-fixed facility capable of amplifying a sensing signal, and more particularly, is installed to a certain depth inside a facility such as a slope, an underground buried pipe, a dam, or a building, so that the structural displacement inside the facility Pile type that detects the wave generated according to It is a technology related to the sensor device.

Korea has a narrow land and more mountainous regions compared to plains. Due to the climatic features of four distinct seasons, high temperature and high humidity and heavy rainfall in summer, natural disasters such as floods, landslides, and typhoons occur, and low temperature and dry climate in winter. As a result, cold waves and heavy snows are occurring.

Due to these four seasons climatic characteristics, in summer, collapse accidents of facilities such as slopes occur due to natural disasters such as floods, landslides, and typhoons. Accidents in which apartments and houses are sunk often occur.

In addition, during thawing seasons such as spring, facilities such as underground burial pipes, dams, and buildings undergo a phenomenon of accelerated aging or cracking earlier than their actual design life due to the freezing and thawing process, leading to collapse accidents in severe cases.

In addition, facilities such as slopes, buried pipes, dams, and buildings are destroyed by external impacts caused by earthquakes, which occur frequently recently, or structural displacement occurs inside, which often puts them in a dangerous situation.

In addition, when facilities such as slope slopes, underground burial pipes, dams and buildings are destroyed or structural displacement occurs inside, waves (elastic waves, sound waves, ultrasonic waves, etc.) are generated according to the structural displacement. Waves generated by structural displacement inside facilities such as buried pipes, dams and buildings are difficult to measure due to weak signal strength. In reality, signal loss occurs, making signal analysis difficult.

Therefore, the present invention is installed to a predetermined depth inside facilities such as slope slopes, underground buried pipes, dams, and buildings to detect waves (elastic waves, sound waves, ultrasonic waves, etc.) We would like to propose a technology to amplify the signal immediately upon sensing and provide it to the outside to evaluate the health of the facility. The following are prior art related to this.

1. Republic of Korea Patent Publication No. 10-0505388 Slope Collapse Detection Alarm Method 2. Republic of Korea Patent Publication No. 10-0943166 Fiber optic displacement gauge and slope safety monitoring system using the same 3. Republic of Korea Patent Publication No. 10-1618328 Slope Collapse Pre-Detection Device

The present invention is installed to a certain depth inside facilities such as slope slopes, underground burial pipes, dams, and buildings to detect waves generated according to structural displacement inside the facility, and amplify the electrical waveform signal to provide a detection signal to the outside The purpose of this is to enable evaluation of the soundness of the facility.

In order to achieve the above object, a file-type sensor device for diagnosing the health of a sensor-fixed facility capable of amplifying a sensing signal of the present invention,

an iron-type pile unit 100 inserted into the facility;

It is installed inside the iron-type pile unit 100, detects an elastic wave transmitted from inside the facility to detect the structural displacement of the facility, generates an electrical waveform signal corresponding to the sensed elastic wave, and provides it to the amplifying unit 200 a sensing unit 200 and;

It is installed inside the iron-type pile unit 100, and includes an amplifying unit 300 that amplifies the electrical waveform signal provided by the sensing unit 200 and provides it to the outside,

The sensing unit 200 and the amplifying unit 300 are coupled to each other, and the sensing unit 200 so that the mutually coupled sensing unit 200 and the amplifying unit 300 are not drawn out of the iron-type pile unit 100. It is characterized in that it is fixedly installed inside the iron-type pile part 100 .

The present invention is installed to a certain depth inside facilities such as slope slopes, underground burial pipes, dams, and buildings to detect waves generated according to structural displacement inside the facility, and amplify the electrical waveform signal to provide a detection signal to the outside Thus, it is possible to evaluate the soundness of the facility, and it is possible to identify the structural displacement of the facility before a serious structural displacement or collapse accident of the facility occurs, thereby providing the effect of preventing human casualties and accidents in advance.

1 is an overall configuration diagram of the present invention;
2 is an exemplary view in which the present invention is installed in a facility;
3 is a block diagram of the present invention;
4 is a detailed configuration diagram of the iron-type pile part of the present invention;
5 is a detailed configuration diagram of a sensing unit of the present invention;
6 is a detailed configuration diagram of the amplification unit of the present invention;

An embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The present inventor's sensor-fixed sensor device capable of amplifying the sensing signal (hereinafter referred to as 'the present invention') is a file-type sensor device for diagnosing the health of a facility. It is an invention that detects seismic waves generated according to the It provides the effect of preventing human casualties and accidents in advance because it is possible to identify the structural displacement of a facility before a collapse accident occurs.

The present invention (10), as shown in FIG. 1, is a sensor-fixed file-type sensor device for facility health diagnosis capable of amplifying a sensing signal is inserted to a certain depth inside a facility where internal structural displacement can occur, and is generated according to the internal structural displacement of the facility The present invention (10) is a sensor capable of amplifying a sensing signal, generating an electrical waveform signal corresponding to the detected acoustic wave, amplifying the electrical waveform signal and providing it to the outside. The facility into which the device is inserted is a structure in which internal structural displacement can occur, such as a slope slope, an underground buried pipe, a dam, a building, etc., and the present invention (10), a file-type sensor device for soundness diagnosis, is inserted and installed inside .

For example, as shown in FIG. 2A, it is installed on the slope of the facility, which detects the wave generated according to the internal structural displacement of the slope, and provides an electrical waveform signal to the outside, and as shown in FIG. 2B, the facility is underground It is installed in the ground where the buried pipe is installed, detects the wave generated according to the structural displacement of the underground buried pipe, and provides an electrical waveform signal to the outside. It is to provide an electrical waveform signal to the outside by detecting the wave generated according to the internal structural displacement.

Specifically, as shown in FIG. 3 , the sensor device for diagnosing the health of a sensor fixed facility capable of amplifying a sensing signal of the present invention is a file type sensor device,

an iron-type pile unit 100 inserted into the facility;

It is installed inside the iron-type pile unit 100, detects an elastic wave transmitted from inside the facility to detect the structural displacement of the facility, generates an electrical waveform signal corresponding to the sensed elastic wave, and provides it to the amplifying unit 200 a sensing unit 200 and;

It is installed inside the iron-type pile unit 100, and includes an amplifying unit 300 that amplifies the electrical waveform signal provided by the sensing unit 200 and provides it to the outside,

The sensing unit 200 and the amplifying unit 300 are coupled to each other, and the sensing unit 200 so that the mutually coupled sensing unit 200 and the amplifying unit 300 are not drawn out of the iron-type pile unit 100. It is characterized in that it is fixedly installed inside the iron-type pile part 100 .

The iron-type pile part 100 has an internal space, is formed to a predetermined length, and is inserted into the facility, and the sensing part 200 and the amplifying part 300 are installed in the internal space.

In particular, the sensing unit 200 and the amplifying unit 300 are coupled to each other, and the sensing unit 200 so that the mutually coupled sensing unit 200 and the amplifying unit 300 are not drawn out of the iron-type pile unit 100 . is fixedly installed inside the iron-type pile part 100 .

The iron-type pile part 100 is after drilling a hole in the facility, and then inserts the iron-type pile part 100 into the perforated hole to insert the iron-type pile part 100 into the facility, or filing without a drilling hole It can be directly hit and inserted into the facility by the equipment.

In the state inserted into the facility, the iron-type pile unit 100 functions as a protective case that protects the sensing unit 200 and the amplification unit 300 installed therein from the external environment, and at the same time, the structure of the facility delivered inside the facility It functions as a wave transmission medium that transmits an elastic wave, which is a wave related to displacement, to the detection sensor 220 of the sensing unit 200 installed therein.

That is, the elastic wave, which is a wave related to the displacement of the structure of the facility, is transmitted in the order of the inside of the facility → the iron-type pile part 100 → the detection sensor 220, so that the iron-type pile part 100 is the facility structural displacement transmitted inside the facility. It is a collection of seismic waves, which are waves about

Specifically, as shown in FIG. 4, the iron-type pile part 100 is

The sensing surface of the sensing unit 200 of the detection sensor 220 is in surface contact, and the pile tip 110 is coupled to the pile body 120 to form the tip of the iron-type pile part 100,

One side is coupled to the file tip 110 and the other side is coupled to the closing cover 130, a cylinder of a certain length formed with a hollow 121 so that the sensing unit 200 and the amplifying unit 300 can be installed therein. A file body portion 120 of the shape and,

A closing cover 130 coupled to the inlet of the file body 120 in a detachable manner to prevent foreign substances from entering the inside of the file body 120,

In order for the second signal transmission line 350 of the amplifying unit 300 to be withdrawn to the outside, among the side surfaces of the file body 120 , the drawing groove 140 is located on one side of the side of the portion to which the closing cover 130 is coupled. It is characterized in that it includes.

Referring to FIG. 4 , the tip of the pile 110 is in contact with the sensing surface of the detection sensor 220 of the sensing unit 200 , is coupled to the pile body 120 , and is the tip of the iron-type pile part 100 . In a configuration to form, specifically, the file tip 110 is,

The iron-type pile part 100 is formed in a cone shape so that it can be easily inserted into the facility, and a tip 111 forming the tip of the iron-type pile part 100,

A pile coupling part 112 coupled to the pile body part 120, and

A flat sensor contact surface 113 formed inside the pile coupling unit 112 so that the sensing surface of the detection sensor 220 of the sensing unit 200 is in surface contact, and

The sensor housing 210 of the sensing unit 200 is formed to a predetermined depth inside the file coupling unit 112 so that it can be inserted, and there is a screw tab for coupling around the inner circumference so that the inserted sensor housing 210 can be coupled. and a sensor insertion groove 114 formed,

A flat sensor contact surface 113 is formed on the lower surface of the sensor insertion groove 114 .

The tip 111 corresponds to the front end of the iron-type pile part 100, and is formed in a cone shape, as shown in FIG. 4, so that the iron-type pile part 100 can be easily inserted into the facility.

The pile coupling part 112 is a part coupled to the pile body part 120, and a coupling thread is formed.

The sensor contact surface 113 has a flat shape as shown in FIG. 4 so that the detection surface of the detection sensor 220 of the sensing unit 200 is in surface contact, and is formed inside the file coupling unit 112 .

Specifically, it is formed on the bottom surface of the sensor insertion groove 114 to be described later formed inside the file coupling part 112 . That is, the sensor insertion groove 114 of a certain depth is formed inside the file coupling part 112 , and the sensor contact surface 113 , which is a flat flat surface, is formed on the bottom of the sensor insertion groove 114 .

The elastic wave, which is a wave generated according to the internal structural displacement of the facility, is transmitted to the iron-type pile part 100 embedded in the facility, and then on the flat sensor contact surface 113 of the pile tip 110 constituting the iron-type pile part 100. The detection surface is transmitted to the detection sensor 220 of the sensing unit 200 in surface contact, and finally the detection sensor 220 detects an elastic wave, which is a wave generated according to the displacement of the structure inside the facility.

The sensor insertion groove 114 is formed at a predetermined depth inside the file coupling unit 112 so that the sensor housing 210 of the sensing unit 200 can be inserted, and the inserted sensor housing 210 can be coupled thereto. A screw tab for coupling is formed around the inner circumference of the sensor insertion groove 114 .

That is, when a part of the sensor housing 210 is inserted into the sensor insertion groove 114 and coupled, the sensing surface of the detection sensor 220 installed inside the sensor housing 210 is a flat sensor contact surface formed on the bottom surface of the sensor insertion groove 114 . Surface contact with 113 and the sensor housing 210 is fixedly coupled to the sensor insertion groove 114, so that the surface contact state of the detection sensor 220 with respect to the sensor contact surface 113 is stably maintained inside the facility The transmitted acoustic wave signal is stably detected.

As described above, if the detection sensor 220 in surface contact with the flat sensor contact surface 113 formed inside the iron-type pile part 100 fails to maintain the surface contact state, the elastic wave cannot be detected, and the surface contact state is maintained. If it moves while moving, the seismic wave sensing efficiency decreases. Since the sensor housing 210 is fixedly coupled to the sensor insertion groove 114, the surface contact state of the detection sensor 220 with respect to the sensor contact surface 113 is stably maintained, Accordingly, the detection sensor 220 stably detects the acoustic wave signal transmitted from the inside of the facility.

In addition, for ease of coupling with the pile body 120 , the pile tip 110 has a friction surface 115 having a certain roughness around the side of the pile tip 110 between the tip 111 and the pile coupling part 112 . ) and at least two or more flat surfaces 116 formed on the friction surface 115 .

When the pile tip part 110 is coupled to the pile body part 120, it is coupled by turning it manually or by using equipment (wrench, etc.) (111).

The cone-shaped tip 111 is inconvenient to touch with a hand or equipment due to its shape, and this may make it inconvenient to couple the pile tip 110 to the pile body 120 .

Therefore, when the pile tip part 110 is coupled to the pile body part 120 , for ease of coupling, a friction surface having a certain roughness around the side surface of the pile tip part 110 between the peak part 111 and the pile coupling part 112 . At least two or more flat surfaces 116 are formed on the 115 and the friction surface 115 .

By bringing a hand or equipment into contact with the friction surface 115 or the flat surface 116 , the file tip part 110 can be rotated to be easily coupled to the file body part 120 .

Referring to FIG. 4 , the pile body part 120 has one side coupled with the pile tip part 110 and the other side with the closing cover 130 , but the sensing part 200 and the amplifying part 300 are installed therein. It is a configuration of a cylindrical shape of a certain length in which the hollow 121 to be able to be formed.

The pile body 120 may be configured by combining a plurality of cylinders, or may be configured as a single cylinder (in FIG. 4, an example in which the pile body 120 is configured as a single cylinder is shown), inside The hollow 121 formed in the space provides a space in which the sensing unit 200 and the amplifying unit 300 can be installed.

The connection between the pile body part 120 and the pile tip part 110 may exist in various embodiments. For example, the file coupling part 112 of the pile tip part 110 is formed with a screw thread for coupling, and a coupling thread is formed inside the pile body part 120 to form the pile tip part 110 and the pile body part 120. Directly coupled by a screw coupling method, or after forming the pile coupling part 112 of the pile tip part 110 with a coupling thread and forming a coupling thread on the surface of the pile body part 120, the pile of the pile tip part 110 The connection flange is positioned between the coupling part 112 and the pile body part 120, and the pile coupling part 112 and the pile body part 120 of the pile tip part 110 are coupled to the connection flange in a screw coupling method, respectively. The pile body part 120 and the pile tip part 110 may be indirectly connected.

However, in the present invention, the connection method between the pile body part 120 and the pile tip part 110 is not limited to the above example, and any configuration that can connect and couple the pile body part 120 and the pile tip part 110 may be used. It does not matter, in FIG. 4, the pile coupling part 112 of the pile tip part 110 is formed with a screw thread for coupling, and a coupling thread is formed inside the pile body part 120 to form the pile tip part 110 and the pile body part 120 ) is shown as an example of direct screw coupling.

Referring to FIG. 4 , the closing cover 130 is configured to be coupled to the inlet of the pile body 120 in a detachable manner (eg, screw coupling method) to prevent foreign substances from flowing into the pile body 120 .

Referring to FIG. 4 , the withdrawal groove 140 is a side surface of the file body 120 so that the second signal transmission line 350 of the amplifying unit 300 can be drawn out, and the closing cover 130 is coupled thereto. It is a configuration formed on one side of the side of the part.

The electric waveform signal amplified by the preamplifier board 320 of the amplifying unit 300 is transmitted to the outside through the second signal transmission line 350 of the amplifying unit 300. For external transmission of the amplified electric waveform signal, The second signal transmission line 350 should be drawn out of the iron-type pile part 100 , and the configuration for this is the drawing-out groove 140 .

The reason for forming the lead-out groove 140 for taking out the second signal transmission line 350 to the outside is on one side of the side of the side of the pile body 120, to which the closing cover 130 is coupled, the iron type into the inside of the facility. This is to prevent damage to the second signal transmission line 350 when the file unit 100 is inserted.

When the iron-type pile part 100 is inserted into the facility, the finishing cover 130 is hit so that the iron-type pile part 100 is inserted into the facility. If it is formed in the iron-type pile part 100, when hitting the closing cover 130 for insertion, the second signal transmission line 350 is struck and damaged. In order to prevent this, the withdrawal groove 140 is formed on one side of the side of the side of the file body 120 to which the closing cover 130 is coupled.

On the other hand, in order to prevent an external foreign substance from flowing into the pile body 120 through the lead-out groove 140 from which the second signal transmission line 350 of the amplifying part 300 is drawn out, the iron-type pile part ( 100 ) may further include an airtight member ( 141 ) fitted in the withdrawal groove ( 140 ).

In particular, the airtight member 141 has a function of preventing foreign substances from entering the inside of the file body 120 through the withdrawal groove 140 and a function of drawing out a second signal transmission line, through which a second signal transmission line passes. It is inserted into the withdrawal groove 140 in a state of being

The sensing unit 200 is fixedly installed inside the iron-type pile unit 100, detects an elastic wave transmitted from the inside of the facility to detect the structural displacement of the facility, and generates an electrical waveform signal corresponding to the detected elastic wave. It is a configuration provided to the amplification unit 200 .

Specifically, as shown in FIG. 5, the sensing unit 200

A sensor housing 210 into which the detection sensor 220 is inserted and installed;

Installed inside the sensor housing 210 to detect an elastic wave transmitted from the inside of the facility through the sensor contact surface 113, and to generate an electrical waveform signal corresponding to the sensed acoustic wave, the sensing surface of the steel-type pile part 100 A detection sensor 220 that is in surface contact with the flat sensor contact surface 113 formed on the file tip 110,

A first sensor housing coupling part 230 that is a screw hole formed in the center of the upper surface of the sensor housing 210 so that the sensor housing 210 can be coupled to the preamplifier board housing 310 of the amplifying part 300;

A second sensor housing coupling part 240 which is a screw tab formed on the lower side of the outer surface of the sensor housing 210 so that the sensor housing 210 can be coupled to the sensor insertion groove 114 of the iron-type pile part 100;

A first signal transmission line 250 for transmitting the electrical waveform signal generated by the detection sensor 220 to the preamplifier board 320 of the amplifying unit 300 is included,

When the sensor housing 210 is coupled to the sensor insertion groove 114 of the iron-type pile part 100 , the sensing surface of the detection sensor 220 is formed in the pile tip 110 of the iron-type pile part 100 . It is characterized in that the surface is in contact with the flat sensor contact surface 113 formed on the inside of the file coupling portion 112 .

Referring to FIG. 5 , the sensor housing 210 has a configuration in which the detection sensor 220 is inserted and installed, and protects the detection sensor 220 inserted and installed inside from the external environment. In particular, one side of the sensor housing 210 is open so that the detection sensor 220 can be inserted inside and the detection surface of the detection sensor 220 inserted inside can be exposed to the outside.

Referring to FIG. 5 , the detection sensor 220 is installed inside the sensor housing 210 to detect an acoustic wave transmitted from the inside of the facility through the sensor contact surface 113 , and generates an electrical waveform signal corresponding to the sensed acoustic wave. To do so, the sensing surface is configured to be in surface contact with the flat sensor contact surface 113 formed on the pile tip 110 of the iron-type pile part 100 .

When the sensor housing 210 is inserted into the sensor insertion groove 114 formed in the pile tip 110 of the iron-type pile part 100, the sensing surface of the detection sensor 220 is on the bottom surface of the sensor insertion groove 114. Surface contact with the formed flat sensor contact surface 113 . In this case, the acoustic wave detected by the detection sensor 220 is characterized in that it is an acoustic wave in a band of 1 kHz to 1 MHz.

Referring to FIG. 5 , the first sensor housing coupling part 230 is formed in the center of the upper surface of the sensor housing 210 so that the sensor housing 210 can be coupled to the preamplifier board housing 310 of the amplifier 300 . It is characterized in that it is a screw hole in which a thread is formed as a coupling means.

That is, the first sensor housing coupling part 230, which is a screw hole formed in the center of the upper surface of the sensor housing 210, and the board housing coupling part 340, which is a screw protrusion formed in the preamplifier board housing 310 of the amplifier 300, By coupling, the sensor housing 210 of the sensing unit 200 and the preamplifier board housing 310 of the amplifying unit 300 are coupled to each other.

Referring to FIG. 5 , the second sensor housing coupling part 240 is located on the lower side of the outer surface of the sensor housing 210 so that the sensor housing 210 can be coupled to the sensor insertion groove 114 of the steel-type pile part 100 . As a coupling means formed in the, characterized in that the screw tab is formed with a screw thread.

That is, the coupling of the second sensor housing coupling part 240, which is a screw tab formed on the lower side of the outer surface of the sensor housing 210, and the coupling screw tab formed around the inner periphery of the sensor insertion groove 114 of the iron-type pile part 100, By this, the sensor housing 210 of the sensing unit 200 is coupled to the sensor insertion groove 114 formed in the pile tip 110 of the iron-type pile part 100 and is fixedly installed on the iron-type pile part 100 .

Referring to FIG. 5 , the first signal transmission line 250 is configured to transmit the electrical waveform signal generated by the detection sensor 220 to the preamplifier board 320 of the amplifier 300 .

The first signal transmission line 250 of which one side is connected to the detection sensor 220 is connected to the preamplifier board 320 of the amplifying unit 300 through the hollow 311 formed in the preamplifier board housing 310 of the amplifying unit 300 . ) so that the electrical waveform signal generated by the detection sensor 220 is transmitted to the preamplifier board 320 of the amplifier 300 .

The amplifying unit 300 is installed inside the iron-type pile unit 100 in a state coupled to the sensing unit 200, and an electrical waveform signal provided by the sensing unit 200 (specifically, the detection sensor 220). It is a configuration that amplifies and provides to the outside.

Specifically, as shown in FIG. 6, the amplification unit 300 is

A preamplifier board housing 310 having a cylindrical shape in which a hollow 311 is formed so that the preamplifier board 320 can be installed therein;

A preamplifier board 320 which is inserted and installed inside the preamplifier board housing 310 and designed with an amplification circuit for amplifying the electrical waveform signal transmitted from the sensing unit 200;

A slide groove 330 of a certain length formed in the hollow 311 so that the preamplifier board 320 can be inserted into the hollow 311 formed inside the preamplifier board housing 310 in a slide manner;

The board housing coupling part 340, which is a hollow screw protrusion formed at the lower end of the preamp board housing 310 so that the preamplifier board housing 310 can be coupled to the sensor housing 210 of the sensing part 200, and ,

It is characterized in that it includes a second signal transmission line 350 for transmitting the electric waveform signal amplified through the preamplifier board 320 to the outside.

Referring to FIG. 6 , the preamplifier board housing 310 has a cylindrical shape in which a hollow 311 allowing the preamplifier board 320 to be installed therein is formed.

That is, the preamplifier board housing 310 protects the preamplifier board 320 inserted and installed in the hollow 311 formed inside from the external environment. The preamplifier board 320 is designed with an amplification circuit sensitive to the external environment and must be protected from the external environment, and for this purpose, it is inserted and installed in the hollow 311 formed inside the preamplifier board housing 310 .

6, the preamplifier board 320 is inserted and installed in the hollow 311 formed inside the preamplifier board housing 310, and an amplifier circuit for amplifying the electrical waveform signal transmitted from the sensing unit 200 is provided. It is a designed boat type configuration.

Since the amplifier circuit designed on the board-type preamplifier board 320 is sensitive to the external environment, it is inserted and installed in the hollow 311 formed inside the preamplifier board housing 310 to be protected.

6, the slide groove 330 is formed in the hollow 311 so that the preamp board 320 can be inserted into the hollow 311 formed inside the preamp board housing 310 in a slide manner. It is an insertion guide groove of a certain length.

That is, the board-type preamplifier board 320 having a rectangular shape slides through the slide groove 330 and is inserted into the hollow 311 formed inside the preamplifier board housing 310 .

The board-type preamplifier board 320 on which the amplification circuit is designed should be positioned inside the preamplifier board housing 310 in a stable state for stable signal amplification. To this end, it is fitted into the slide groove 330 .

That is, the preamplifier board 320 inserted into the slide groove 330 and positioned in a stable state inside the preamplifier board housing 310 stably amplifies the electrical waveform signal transmitted from the sensing unit 200 .

Referring to FIG. 6 , the housing coupling unit 340 is formed at the lower end of the preamp board housing 310 so that the preamp board housing 310 can be coupled to the sensor housing 210 of the sensing unit 200 . As a coupling means, it is characterized in that the hollow screw protrusion is formed.

That is, the preamplifier board housing 310 is amplified by the coupling of the board housing coupling part 340 which is a screw protrusion having a hollow formed at the lower end and the first sensor housing coupling part 230 of the sensing part 200 which is a screw hole. The preamplifier board housing 310 of the unit 300 and the sensor housing 210 of the sensing unit 200 are coupled to each other.

Referring to FIG. 6 , the second signal transmission line 350 is configured to transmit the electric waveform signal amplified through the preamplifier board 320 to the outside.

The second signal transmission line 350 of which one side is connected to the preamplifier board 320 is the file body through the hollow 121 formed inside the file body 120 and the lead-out groove 140 formed in the above-described closing cover 130 . The electric waveform signal that is drawn out and amplified by the unit 120 is transmitted to the outside for signal analysis.

On the other hand, the sensing unit 200 and the amplifying unit 300 installed in the inner space of the iron-type pile unit 100 are coupled to each other, and the mutually coupled sensing unit 200 and the amplifying unit 300 are the iron-type pile units ( 100) The sensing unit 200 is characterized in that it is fixedly installed inside the iron-type pile unit 100 so as not to be drawn out.

The detection sensor 220 of the sensing unit 200 that is in surface contact with the flat sensor contact surface 113 formed inside the iron-type pile unit 100 needs not to move.

If the detection sensor 220, which is in surface contact with the flat sensor contact surface 113 formed inside the iron-type pile part 100, does not maintain the surface contact state, it cannot detect the elastic wave, and if it moves while maintaining the surface contact state The seismic wave detection efficiency decreases.

Therefore, so that the detection sensor 220 does not move while in surface contact with the flat sensor contact surface 113 formed inside the iron-type pile part 100, the sensing part 200 is fixedly installed inside the iron-type pile part 100. . Specifically, the sensor housing 210 of the sensing unit 200 is inserted and fixed into the sensor insertion groove 114 formed in the pile tip 110 of the iron type pile unit 100 .

Although the technical idea of the present invention has been described together with the accompanying drawings in the above, this is an exemplary description of a preferred embodiment of the present invention and does not limit the present invention, the scope of the present invention is not limited to the embodiment, It will be apparent that those skilled in the art also include modifications within the scope of the technical spirit of the present invention.

10: Pile-type sensor device for facility health diagnosis
100: iron-type pile part
200: sensing unit
300: amplification unit

Claims (8)

In the file-type sensor device for diagnosing the health of a sensor-fixed facility capable of amplifying a sensing signal,
an iron-type pile unit 100 inserted into the facility;
It is installed inside the iron-type pile part 100, detects an elastic wave transmitted from the inside of the facility to detect the structural displacement of the facility, generates an electric waveform signal corresponding to the sensed elastic wave, and provides it to the amplifying unit 200 a sensing unit 200 to;
It is installed inside the iron-type pile part 100 and includes an amplifying part 300 that amplifies the electrical waveform signal provided by the sensing part 200 and provides it to the outside,

The sensing unit 200,
A sensor housing 210 into which the detection sensor 220 is inserted and installed;
Installed inside the sensor housing 210 to detect an elastic wave transmitted from the inside of the facility through the sensor contact surface 113, and to generate an electrical waveform signal corresponding to the sensed acoustic wave, the sensing surface of the iron-type pile part 100 A detection sensor 220 that is in surface contact with the flat sensor contact surface 113 formed on the tip of the file 110,
A first sensor housing coupling part 230 which is a screw hole formed in the center of the upper surface of the sensor housing 210 so that the sensor housing 210 can be coupled to the preamplifier board housing 310 of the amplifying part 300;
A second sensor housing coupling part 240 that is a screw tab formed on the lower side of the outer surface of the sensor housing 210 so that the sensor housing 210 can be coupled to the sensor insertion groove 114 of the iron-type pile part 100;
and a first signal transmission line 250 for transmitting the electrical waveform signal generated by the detection sensor 220 to the preamplifier board 320 of the amplifier 300,

When the sensor housing 210 is coupled to the sensor insertion groove 114 of the ferrous pile part 100 , the sensing surface of the detection sensor 220 is formed in the pile tip 110 of the ferrous pile part 100 . Characterized in surface contact with the flat sensor contact surface 113 formed on the inside of the file coupling part 112,
The sensing unit 200 and the amplifying unit 300 are coupled to each other, and the sensing unit 200 so that the mutually coupled sensing unit 200 and the amplifying unit 300 are not drawn out of the iron-type pile unit 100. A pile-type sensor device for diagnosing the health of a sensor fixed-type facility capable of amplifying a sensing signal, characterized in that it is fixedly installed inside the iron-type pile unit 100 .
The method according to claim 1,
The iron-type pile part 100,
The sensing surface of the detection sensor 220 of the sensing unit 200 is in surface contact, and the pile tip 110 is coupled to the pile body 120 to form the tip of the iron-type pile part 100,
One side is coupled with the file tip 110 and the other side is coupled with the closing cover 130, a cylinder of a certain length having a hollow 121 that allows the sensing unit 200 and the amplifying unit 300 to be installed therein. A file body portion 120 of the shape and,
A closing cover 130 coupled to the inlet of the file body 120 in a detachable manner to prevent foreign substances from entering the inside of the file body 120,
In order for the second signal transmission line 350 of the amplifying unit 300 to be withdrawn to the outside, among the side surfaces of the file body 120 , the drawing groove 140 is located on one side of the side of the portion to which the closing cover 130 is coupled. A file-type sensor device for diagnosing the health of a sensor fixed-type facility capable of amplifying a sensing signal, comprising:
3. The method according to claim 2,
The iron-type pile part 100,
In order to prevent foreign substances from entering the inside of the file body 120 through the lead-out groove 140 from which the second signal transmission line 350 of the amplifying unit 300 is drawn out, the second signal transmission line is passed through. A file-type sensor device for diagnosing the health of a sensor-fixed facility capable of amplifying a sensing signal, characterized in that it further comprises an airtight member (141) fitted in the withdrawal groove (140).
3. The method according to claim 2,
The file tip 110 is,
The iron-type pile part 100 is formed in a cone shape so that it can be easily inserted into the facility, and the tip 111 forms the tip of the iron-type pile part 100;
A pile coupling part 112 coupled to the pile body part 120, and
A flat sensor contact surface 113 formed inside the pile coupling unit 112 so that the sensing surface of the detection sensor 220 of the sensing unit 200 is in surface contact, and
The sensor housing 210 of the sensing unit 200 is formed at a predetermined depth inside the file coupling unit 112 so that it can be inserted, and there is a screw tab for coupling around the inner circumference so that the inserted sensor housing 210 can be coupled. and a sensor insertion groove 114 formed,
A file-type sensor device for diagnosing the health of a sensor fixed-type facility capable of amplifying a sensing signal, characterized in that a flat sensor contact surface 113 is formed on the bottom surface of the sensor insertion groove 114.
5. The method of claim 4,
The file tip 110 is,
For ease of coupling with the file body 120,
A friction surface 115 having a certain roughness formed around the side surface of the pile tip 110 between the peak part 111 and the pile coupling part 112, and;
A file-type sensor device for diagnosing the health of a sensor fixed-type facility capable of amplifying a sensing signal, characterized in that it further comprises at least two or more flat surfaces (116) formed on the friction surface (115).
delete The method according to claim 1,
The detection sensor 220,
A sensor device capable of amplifying a sensing signal, characterized in that it is a sensor that detects acoustic waves in the 1 kHz to 1 MHz band, and a file-type sensor device for diagnosing the health of a fixed-type facility.
The method according to claim 1,
The amplification unit 300,
A preamplifier board housing 310 having a cylindrical shape in which a hollow 311 is formed so that the preamplifier board 320 can be installed therein;
A preamplifier board 320 which is inserted and installed inside the preamplifier board housing 310 and designed with an amplification circuit for amplifying the electrical waveform signal transmitted from the sensing unit 200;
A slide groove 330 of a certain length formed in the hollow 311 so that the preamplifier board 320 can be inserted into the hollow 311 formed inside the preamplifier board housing 310 in a slide manner;
The board housing coupling part 340, which is a hollow screw protrusion formed at the lower end of the preamp board housing 310 so that the preamplifier board housing 310 can be coupled to the sensor housing 210 of the sensing part 200, and ,
A file-type sensor device for diagnosing the health of a sensor fixed facility capable of amplifying a sensing signal, characterized in that it includes a second signal transmission line 350 for transmitting the electric waveform signal amplified through the preamplifier board 320 to the outside.

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