KR200324464Y1 - Apparatus for measurement of ground condition in embankment - Google Patents

Abstract

In the present invention, the lower end penetrates through the settling layer work hole 21 vertically drilled into the settling layer 20 and is fixed to the floating layer 30, and the upper part is exposed through the opening of the settling layer work hole 21. A reference point rod 100 installed to be; The lower end is inserted into the settlement layer work hole 21 and is installed at a predetermined position of the settlement layer 20 by the filling means 22 filling the work hole 21, and the upper end portion opens the opening of the work hole. A sinking rod 200 installed to be exposed through; A through hole 311 is formed in the core portion so as to penetrate the settlement layer work hole 21, and a settlement layer ground surface contact mechanism having a settlement plate 310 formed at an edge thereof in surface contact with the surface of the settlement layer 20. 300; A relative settlement amount measuring means (400) for measuring a relative difference value of the settlement amount of each of the reference point rod (100), the settlement rod (200), and the settlement layer ground surface contact mechanism (300); By presenting the soil measuring device for the construction work and maintenance, it is possible to measure ground settlement, floor settlement and pore water pressure or surface settlement and water pressure in one system, while reducing the risk of damage to the measuring device. Make sure you get a more accurate measurement.

Description

Ground measuring equipment for land works and maintenance {APPARATUS FOR MEASUREMENT OF GROUND CONDITION IN EMBANKMENT}

The present invention relates to a ground measuring apparatus, and more particularly, to a system that enables the integrated measurement of changes in surface settlement, layer settlement, pore water pressure, and water pressure during settlement.

In the case of landfill work in various civil works, the consolidation phenomenon of the ground due to the change of pore water pressure inevitably occurs due to the load of the landfill layer, so that a floating layer (also called a support layer) does not occur from the bottom of the landfill layer. The part located up to the upper part of the assumed part (hereinafter referred to as the subsidence layer) causes the settlement to occur not only on the surface of the subsidence layer but also in the central part of the subsidence layer.

Since such settlement occurs unevenly throughout the settlement layer, it is necessary to clearly measure the change of surface settlement, layer settlement and pore water pressure of the settlement layer for the mechanical analysis of the ground.

7 is a cross-sectional view showing the structure of a conventional floor settling system, the construction and measurement method of the floor settling system of such a structure will be described as follows.

After drilling the work hole 21 to penetrate the settlement layer 20 to the support layer 30, and inserting the non-magnetic guide pipe 41 to the bottom surface, the support layer as the lower end of the guide pipe 41 The reference point magnet 42 is installed in the portion corresponding to (30).

Thereafter, the spider magnet 43 is lowered along the work hole 21 so that the inner surface of the deep through hole of the spider magnet 43 is in surface contact with the outer surface of the guide pipe 41, and stops at the position where the measurement of the layered settlement is necessary. And grouting (22a) to the remaining space of the work hole (21).

After a predetermined time has elapsed, the probe 44 is inserted into the guide pipe 41 and lowered. When the probe 44 reaches the position of the spider magnet 43, the indicator 45 gives a predetermined signal. Therefore, by measuring the relative displacement difference with the reference point magnet 42, it is possible to calculate the layered settlement amount of the settlement layer in which the spider magnet 43 is located.

However, such a conventional layered sedimentation system has the following problems.

First, in order to obtain a clear reaction between the probe 44 and the spider magnet 43, the guide pipe 41 should be formed by a nonmagnetic material such as PVC, which is fragile and therefore has a high risk of breakage. In this case, not only can the reference point be lost, but the work can be closed, making the measurement impossible.

Second, the settlement of the ground continuously occurs over a long period of time, the conventional measurement method is cumbersome because the measurement must be carried out by introducing the probe 44 through the guide pipe 41 every time the measurement.

Third, since it takes a configuration that measures only the layered sedimentation amount irrespective of the measurement of the surface sedimentation amount of the sedimentation layer, it is inconvenient to install a separate sedimentation plate on the ground surface of the sedimentation layer and measure the sedimentation amount. .

On the other hand, Figure 8 is a cross-sectional view showing the structure of a conventional hydraulic pressure (piezometer), the construction and measuring method of the hydraulic pressure gauge of such a structure will be described as follows.

The work hole 21 is drilled in the settlement layer 20, the pressure gauge tip 51a connected to the hydraulic pressure cable 52 is lowered, and stopped at a position requiring measurement of the pore water pressure. The sand layer 53 is formed around the system tip 51a.

Bentonite layer 54 is formed on top of sand layer 53 to prevent leakage of water pressure, and when there is another position that requires measurement of pore water pressure, another hydrometer tip 51b Install it and repeat the above operation.

After completing the above operation, the grouting 55 is applied to the top of the bentonite layer 54, and the positions at which the hydraulic pressure tips 51a and 51b are installed by the indicator 56 connected to the upper end of the hydraulic pressure cable 52 are installed. Measure pore water pressure of.

However, such a conventional hydraulic pressure gauge had the following problems.

First, since the hydraulic pressure cable 52 is directly exposed to the bentonite layer 54 and the grouting 55, damage is likely to occur.

Second, the method of measuring the pore water pressure is based on the premise that the hydraulic pressure gauge 51 is continuously positioned exactly at the first installed position, but basically, the ground on which the hydraulic pressure gauge 51 is positioned is a settlement layer in which settlement occurs ( 20), therefore, it is impossible to accurately measure the pore water pressure and to analyze the mechanical behavior of the ground.

Third, for the landfill construction, all the measurement values related to the surface subsidence, the floor subsidence, the excess pore water pressure, and the water pressure for measuring the water level are all required. A separate working hole for each measurement must be drilled, and measurement values cannot be integrated and managed, and it is difficult to maintain the measuring device in view of the characteristics of the ground subsidence that occurs continuously for a long time. It is very difficult to get accurate measurements.

The present invention solves the above problems, while it is possible to collectively measure the surface settlement, the layered settlement and the pore pressure or the surface settlement and the hydraulic pressure in one system, while reducing the risk of damage to the measuring device, and more accurate measurement value The purpose of the present invention is to provide a soil measuring device and method for landfill construction and maintenance.

1 to 6 show an embodiment of the present invention,

1 is a cross-sectional view showing the overall configuration

2 is a cross sectional view of a first embodiment of a measuring device;

3 is a cross-sectional view of the sheath fixture

4 is a cross sectional view of a second embodiment of a measuring device;

5 is a cross sectional view of a third embodiment of a measuring device;

6 is a cross sectional view of a hydraulic pressure gauge tip fitting;

Figure 7 is a cross-sectional view showing the structure of a conventional layered sedimentation system

Figure 8 is a cross-sectional view showing the structure of a conventional hydraulic pressure gauge

** Description of the symbols for the main parts of the drawings **

10: fill layer 11: fill layer workers

20: sinking layer 21: sinking layer worker

22: charging means 22a: grouting

22b Sand layer 30 Passive layer

100: reference point rod 101: hydraulic pressure cable protector

102: hydraulic gauge cable through hole 110: wing portion for earth pressure increase

120: staff mounting part 200: sinking rod

201: hydraulic pressure cable protection unit 202: hydraulic pressure cable through hole

210: wing portion for increasing earth pressure 220: staff mounting portion

300: settlement layer ground surface contact mechanism 310: settlement plate

311 through hole 320 protective tube

320a: foundation sheath 320b, 320c: connection sheath

330: spacer 331: rod through hole

332: spacer support jaw 340: sheath fixture

341: Sheath connecting screw 342: Upper fixing screw

343: lower fixing screw 350: sheath

360: transverse displacement prevention tube 370: staff mounting portion

380: connection socket 400: relative settlement measurement means

410: level meter 411,412,413: staff

420: sensor holder 421: sensor mounting hole

422 reference point sensor 423 measurement sensor

424: Settlement calculator 425: Settlement calculation value transmitter

430: sensor holder 431: measuring needle through hole

432: dial gauge mounting portion 433: dial gauge for the reference point rod

434 dial dial 500 for sinking rod surface contact mechanism protector

510: earth protection tube 510a: foundation earth protection tube

510b: connection mud protection tube 520: mud protection tube support

521: tripod 522: wing portion for earth pressure increase

530: connection socket 600: hydraulic pressure gauge tip mounting hole

601: water hole 602: anchor portion

610: hydraulic gauge tip 611: hydraulic gauge cable

620: sand bag 630: hydraulic pressure gauge

700: hydraulic leakage prevention means 710: hydraulic pressure gauge connection mechanism

711: Internal connection screw 712: Hydraulic gauge mounting groove

720: polygon wrench 730: rubber ring

In order to achieve the object as described above, the lower end portion is penetrated through the settlement layer work hole 21 vertically drilled into the settlement layer 20 and inserted into the floating layer 30, and the upper portion is the settlement layer. A reference point rod 100 installed to be exposed through the opening of the work hole 21; A lower end portion is inserted into the settlement layer work hole 21 and is installed at a predetermined position of the settlement layer 20 by filling means 22 for filling the work hole 21. A sinking rod 200 installed to be exposed through the opening of the ball; A through hole 311 is formed in the core portion so as to penetrate the settlement layer work hole 21, and a settlement layer ground surface contact mechanism having a settlement plate 310 formed at an edge thereof in surface contact with the surface of the settlement layer 20. 300; A relative settlement amount measuring means (400) for measuring a relative difference value of each settlement amount of the reference point rod (100), the settlement rod (200) and the settlement layer ground surface contact mechanism (300); We present soil measuring equipment for landfill construction and maintenance.

Here, the settlement plate ground contact mechanism 300 is drilled perpendicularly to the fill layer 10 so as to be inserted into the fill layer work hole 11 formed to penetrate the settlement layer work hole 21, the settlement plate It is preferable to take the structure further provided with the protection tube 320 extended upward from the through-hole 311 of the 310.

In addition, the protection tube 320 of the settlement layer ground surface contact mechanism 300 includes a basic protection tube 320a fixed to the settlement plate 310; A plurality of connection protection tubes 320b and 320c connected to an upper end of the base protection pipe 320a by a connection socket 380; It is desirable to take a structure that includes.

In addition, the settlement layer ground surface contact mechanism 300 has a rod through hole 331 of the reference point rod 100 and the settlement rod 200 at the core portion, and a spacer 330 provided on the inner circumferential surface of the protective tube 320. ); It is preferable to take a further structure.

In addition, the spacer 330 is a base spacer 330a which is supported upward by a spacer support jaw 332 formed on the inner circumferential surface of the base protective tube 320a; A connection spacer 330b having a gap support 333 formed on a bottom surface thereof so as to be coupled to an upper surface of the base spacer 330a; It is desirable to take a structure that includes.

In addition, the settlement layer ground surface contact mechanism 300 includes a sheath fixture 340 installed in the rod through hole 331a of the foundation spacer 330a; A sheath 350 that is connected to the sheath fixture 340 and extends downward and covers and covers the reference point rod 100 and the settlement rod 200; It is preferable to take a further structure.

In addition, the sheath fixture 340 and the sheath connecting screw 341 is connected to the upper end of the sheath 350; An upper fixing screw 342 fixed to an upper opening of the rod through hole 331a of the foundation spacer 330a and fixing the sheath connecting screw 341; A lower fixing screw 343 fixed to the lower opening of the rod through hole 331a of the foundation spacer 330a and covering and protecting the sheath 350; It can take the structure containing.

In addition, the settlement layer ground surface contact mechanism 300 extends downward from the through hole 311 of the settlement plate 310 to the transverse displacement preventing tube 360 inserted into the settlement layer work hole 21. It is preferable to take a further structure.

In addition, the outer surface of the settlement layer ground surface contact mechanism 300, the earth protection tube 510 installed around the outer surface of the protective tube 320 so as to be in surface contact with the inner circumferential surface of the fill layer work hole 11; An earth protection tube support 520 for supporting the earth protection tube 510; It is preferable to take the structure further provided with a ground surface contact mechanism protector 500 to include.

In addition, the earth protection tube 510 is a basic earth protection tube 510a supported by the earth protection tube support 520; A connecting earth protection pipe 510b connected to an upper end of the basic earth protection pipe 510a by a connection socket 530; It is desirable to take a structure that includes.

In addition, the earthen protective tube support 520 is a tripod 521 extending from the outer surface of the earthen protective tube 510 to the ground surface of the settlement layer 20; A earth pressure increasing wing portion 522 extending in a direction perpendicular to the core portion of the tripod 521; It is desirable to take a structure that includes.

In addition, it is preferable that the lower end of the reference point rod 100 has a structure further provided with the earth pressure increasing wing 110 formed to extend to the outside of the outer peripheral surface.

In addition, the relative settlement amount measuring means 400 and the staff mounting portion 120 formed on the upper end of the reference point rod 100; Staff mounting part 220 formed on the upper end of the sinking rod 200; A staff mounting part 370 formed on an upper end of the connection protection pipe 320c installed at the top of the plurality of connection protection pipes 320b and 320c of the settlement layer ground surface contact mechanism 300; A plurality of staffs (411, 412, 413) mounted on the staff mounting parts (120, 220, 370) so as to project vertically upwardly above the ground surface of the fill layer (10) through the fill layer work hole (11); A level measuring instrument (410) installed on the ground surface of the fill layer (10) to measure the staff (411, 412, 413); It can take the structure containing.

In addition, the relative settlement amount measuring means 400 has a plurality of sensor mounting holes 421 is formed in the core, and is located at the top of the plurality of connection protection tubes 320b and 320c of the settlement layer ground surface contact mechanism 300. A sensor holder 420 installed at an upper end of the connection protection tube 320c; A reference point sensor 422 mounted to the sensor mounting hole 421 to measure a distance from an upper end of the reference point rod 100; A measurement sensor 423 mounted to the sensor mounting hole 421 to measure a distance from the upper end of the settlement rod 200; A settlement amount calculator 424 which receives the measured values of the reference point sensor 422 and the measurement sensor 423 and calculates the settlement amount; It may take a structure to include.

In addition, it is preferable that the relative settlement amount measuring unit 400 further includes a settlement amount calculation value transmitter 425 for transmitting the output value of the settlement amount calculator 424 to a measurement receiver.

In addition, the relative settlement amount measuring means 400 preferably takes the structure further provided with a solar power supply unit 426 for supplying power to the settlement amount calculator 424 and the settlement calculation value transmission unit 425.

In addition, the relative settlement amount measuring means 400 has a plurality of measuring needle through hole 431 is formed in the core portion, dial gauge mounting portion 432 is formed on the upper side of the through hole 431, and the settlement layer A sensor holder 430 installed at an upper end of the connection protection pipe 320c positioned at the top of the plurality of connection protection pipes 320b and 320c of the ground contact mechanism 300; A dial gauge 433 for a reference point rod mounted on the dial gauge mounting portion 432 to measure a distance from an upper end of the reference point rod 100; A dial gauge 434 for the sink rod mounted on the dial gauge mounting portion 432 to measure a distance from the upper end of the sink rod 200; It may take a structure to include.

In addition, the filling means 22 may have a structure that is a grouting (22a).

In addition, the lower end of the sinking rod 200, it is preferable to take a structure further provided with the earth pressure increasing wing portion 210 formed to extend to the outside of the outer peripheral surface.

In addition, it is installed on the lower end of the sinking rod 200, a hydraulic pressure tip mounting space is formed therein, a plurality of water holes 601 is formed on the outer circumferential surface, the hydraulic pressure tip formed with an anchor portion 602 at the lower end A mounting hole 600; A hydraulic pressure gauge tip 610 mounted to a core of the hydraulic pressure tip mounting space; A sandbag 620 mounted inside the hydraulic tip mounting space to cover and protect the hydraulic tip 610; A hydrometer cable protection unit 201 formed to protect the cable 611 of the hydrometer tip 610 in the inner space of the settlement rod 200; A hydraulic pressure cable through-hole (202) formed at the upper end of the sinking rod (200) so that the cable (611) of the hydraulic pressure tip (610) is discharged; A hydraulic pressure gauge 630 connected to the hydraulic pressure gauge cable 611 through the hydraulic pressure gauge cable through hole 202; Hydraulic leakage prevention formed at the connection portion of the hydraulic pressure tip mounting port 600 and the hydraulic pressure tip 610 to prevent the hydraulic pressure of the hydraulic pressure tip mounting space is leaked through the hydraulic pressure cable protection unit 201 Means 700; It is preferable to take a further structure.

Here, the hydraulic leakage preventing means 700 is connected to the lower end of the settlement rod 200 by an internal connection screw 711, and the mounting portion of the earth pressure increasing wing 210 is formed on the outer circumferential surface, the lower end A hydraulic pressure gauge connecting mechanism 710 formed on the outer circumferential surface of the hydraulic pressure tip mounting hole 600 and a hydraulic pressure gauge mounting groove 712 formed on an inner circumferential surface of the lower end portion; A plurality of multi-angle wrench (720) through the through-hole formed in the lower end of the hydraulic pressure gauge connecting mechanism 710, the pressing end of the hydraulic pressure gauge tip 610 mounted in the hydraulic pressure gauge mounting groove 712 in the side To; It is desirable to take a structure that includes.

In addition, the hydraulic leakage preventing means 700 has a structure further comprising a plurality of rubber rings 730 mounted on the outer peripheral surface of the upper end of the hydraulic pressure gauge tip 610 to be compressed with the hydraulic pressure gauge mounting groove 712. desirable.

In addition, it is installed on the lower end of the reference point rod 100, the hydraulic pressure tip mounting space is formed therein, a plurality of water holes 601 is formed on the outer circumferential surface, the hydraulic pressure tip formed with an anchor portion 602 at the lower end A mounting hole 600; A hydraulic pressure gauge tip 610 mounted to a core of the hydraulic pressure tip mounting space; A sandbag 620 mounted inside the hydraulic tip mounting space to cover and protect the hydraulic tip 610; A hydraulic pressure meter cable protector 101 configured to protect the cable 611 of the hydraulic pressure tip 610 in an inner space of the reference point rod 100; A hydraulic pressure cable through-hole (102) formed at the upper end of the reference point rod (100) so that the cable (611) of the hydraulic pressure tip (610) is exposed; A hydraulic pressure gauge 630 connected to the hydraulic pressure gauge cable 611 through the hydraulic pressure gauge cable through hole 202; Hydraulic leakage prevention formed at the connection portion of the hydraulic pressure gauge tip mounting hole 600 and the hydraulic pressure gauge tip 610 to prevent the hydraulic pressure of the hydraulic pressure tip mounting space from leaking through the hydraulic pressure gauge cable protector 101 Means 700; It is also possible to take a further structure.

In addition, the hydraulic leakage preventing means 700 is connected to the lower end of the reference point rod 100 by an internal connection screw 711, and the mounting portion of the earth pressure increasing wing 110 is formed on the outer peripheral surface, the lower end A hydraulic pressure gauge connecting mechanism 710 formed on the outer circumferential surface of the hydraulic pressure tip mounting hole 600 and a hydraulic pressure gauge mounting groove 712 formed on an inner circumferential surface of the lower end portion; A plurality of multi-angle wrench (720) through the through-hole formed in the lower end of the hydraulic pressure gauge connecting mechanism 710, the pressing end of the hydraulic pressure gauge tip 610 mounted in the hydraulic pressure gauge mounting groove 712 in the side To; It is desirable to take a structure that includes.

In addition, the hydraulic leakage preventing means 700 has a structure further comprising a plurality of rubber rings 730 mounted on the outer peripheral surface of the upper end of the hydraulic pressure gauge tip 610 to be compressed with the hydraulic pressure gauge mounting groove 712. desirable.

In addition, the filling means 22 may have a structure of a sand layer 22b.

In this case, the hydraulic rod is installed on the lower end of the sinking rod 200, a pressure gauge tip mounting space is formed therein, a plurality of water holes 601 are formed on the outer circumferential surface, and an anchor part 602 is formed on the lower end thereof. A tip mount 600; A hydraulic pressure gauge tip 610 mounted to a core of the hydraulic pressure tip mounting space; A hydrometer cable protection unit 201 formed to protect the cable 611 of the hydrometer tip 610 in the inner space of the settlement rod 200; A hydraulic pressure cable through-hole (202) formed at the upper end of the sinking rod (200) so that the cable (611) of the hydraulic pressure tip (610) is discharged; A hydraulic pressure gauge 630 connected to the hydraulic pressure gauge cable 611 through the hydraulic pressure gauge cable through hole 202; It is preferable to take a further structure.

In addition, it is preferable to take a structure further provided with a sand bag 620 mounted inside the hydraulic tip mounting space to cover and protect the hydraulic tip 610.

In addition, it is installed on the lower end of the reference point rod 100, the hydraulic pressure tip mounting space is formed therein, a plurality of water holes 601 is formed on the outer circumferential surface, the hydraulic pressure tip formed with an anchor portion 602 at the lower end A mounting hole 600; A hydraulic pressure gauge tip 610 mounted to a core of the hydraulic pressure tip mounting space; A hydraulic pressure meter cable protector 101 configured to protect the cable 611 of the hydraulic pressure tip 610 in an inner space of the reference point rod 100; A hydraulic pressure cable through-hole (102) formed at the upper end of the reference point rod (100) so that the cable (611) of the hydraulic pressure tip (610) is exposed; A hydraulic pressure gauge 630 connected to the hydraulic pressure gauge cable 611 through the hydraulic pressure gauge cable through-hole 102; It is preferable to take a further structure.

In addition, it is preferable to take a structure further provided with a sand bag 620 mounted inside the hydraulic tip mounting space to cover and protect the hydraulic tip 610.

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

1 to 6 show an embodiment of the invention, Figure 1 is a cross-sectional view showing the overall configuration, Figure 2 is a cross-sectional view of a first embodiment of the measuring device, Figure 3 is a cross-sectional view of the sheath fixture, Figure 4 is a measurement 5 is a cross sectional view of a third embodiment of the measuring device, FIG. 6 is a cross sectional view of a hydraulic pressure gauge tip fitting.

The present invention is largely presented as an embodiment of the soil measuring device for the construction work and maintenance, the first embodiment is the integrated measurement system of the surface sedimentation, floor sedimentation, pore water pressure, the second embodiment is the surface sedimentation, It is an integrated measurement system of water pressure.

First, a description will be given of an integrated measurement system of surface settlement amount, layer settlement amount, and pore water pressure, which is the first embodiment.

As shown, the first embodiment of the ground measurement device for land works and maintenance according to the present invention is basically a reference point rod 100, settlement rod 200, settlement layer surface contact mechanism 300, relative settlement measurement means It is constituted by 400.

The reference point rod 100 has a lower end penetrated through the settlement layer work hole 21 vertically drilled into the settlement layer 20 and is inserted into the floating layer 30, and an upper end thereof is an opening of the settlement layer work hole 21. Installed to be exposed through.

The settlement rod 200 has a lower end portion inserted into the settlement layer work hole 21 and fixed to a predetermined position of the settlement layer 20 by grouting 22a, and the upper end portion is exposed through the opening of the work hole. Is installed.

The subsidence layer ground contact mechanism 300 has a through hole 311 formed in the core portion so as to penetrate the subsidence layer work hole 21, and the subsidence plate 310 formed so that the edge portion is in surface contact with the ground surface of the subsidence layer 20. Take a structure provided with).

The relative settlement amount measuring means 400 takes a configuration for measuring a relative difference value of each settlement amount of the reference point rod 100, the settlement rod 200, and the settlement layer ground surface contact mechanism 300.

That is, since the lower end of the reference point rod 100 is inserted and fixed to the floating layer 30, the reference point rod 100 becomes a reference for all measured values, and the lowering rod 200 is provided to the settlement layer 20 on which the lower end is assumed to be settled. Since it is located, by measuring the relative displacement of the sinking rod 200 with respect to the reference point rod after the fill operation, it is possible to easily measure the floor settling amount.

Compared to the conventional method of inserting the probe 44 into the guide pipe 41 and using the indicator 45 to measure the reaction between the probe 44 and the spider magnet 43 by using the indicator 45, the present invention Since only the reference rod rod 100 and the settlement rod 200 are placed in the antifreeze layer 20 and the settlement layer 30, respectively, and a simple and clear method of measuring the relative displacement, the risk of breakdown is significantly reduced, Long term maintenance makes it easier to get clearer measurements.

In addition, by measuring the relative displacement between the settlement layer surface contact mechanism 300 having the settlement plate 310 and the reference point rod 100, the surface settlement amount can be easily measured. It will be possible to measure and manage the level of sedimentation at the same time.

During the filling operation, since the reference point rod 100, the settlement rod 200, the settlement plate 310, etc. may be buried by the soil to be filled, the settlement layer ground surface contact mechanism 300 is perpendicular to the soil layer 10 The protective tube 320 extending upward from the through hole 311 of the settlement plate 310 to be inserted into the interior of the fill layer work hole 11 formed to be perforated to penetrate the settlement layer work hole 21. It is preferable to take a further structure.

In addition, the filling work is generally made by a predetermined height for a predetermined period, the protective tube 320 is a basic protective tube 320a fixed to the settlement plate 310; A plurality of connection protection tubes 320b and 320c connected to an upper end of the base protection pipe 320a by a connection socket 380; It is preferable to take a structure in which the height of the protective pipe 320 becomes high in accordance with the progress of the fill work by taking the structure to include.

Here, as the height of the protective tube 320 increases, the stability of the settlement layer ground surface contact mechanism 300 may decrease due to earth pressure or the like acting on the wall surface of the protective tube 320. A plurality of spacers 330 in which rod rods 331 of the rod 100 and the sinking rod 200 are formed; Spacer support jaw (332) formed on the inner circumferential surface of the base protective tube (320a) and the connection protective tube (320b, 320c) to support the spacer (330), respectively; It is preferable to take a further structure.

In addition, since the reference point rod 100 and the settlement rod 200 are preferably protected by the sheath 350 before the grouting, the settlement layer ground surface contact mechanism 300 is a spacer supporting jaw of the foundation protective pipe 320a ( Sheath fasteners 340 provided in the rod through hole 331a of the spacer 330a supported by 332a; A sheath 350 that is connected to the sheath fixture 340 and extends downward and covers and covers the reference point rod 100 and the settlement rod 200; It is effective to take a more equipped structure.

Here, the sheath fixture 340 may be any structure as long as it can secure the upper end of the sheath 350 to the spacer 330a, and FIG. 3 is a sheath connection screw 341 connected to the upper end of the sheath 350. )Wow; An upper fixing screw fixed to the upper opening of the rod through hole 331a of the spacer 330a supported by the spacer support jaw 332a of the basic protective tube 320a and fixing the sheath connection screw 341 ( 342; The lower fixing screw 343 which is fixed to the lower opening of the rod through hole 331a of the spacer 330a supported by the spacer support jaw 332a of the basic protective tube 320a and covers and protects the sheath 350. ); An example embodiment is shown.

In addition, when such a configuration is taken, the spacer 330a and the sheath 350 are fixed by the grouting 22a to behave integrally, and the settlement layer ground surface contact mechanism 300 having the settlement plate 310 is settled. With the settlement of the layer 20, the lowering of the layer 20 causes the spacer 330a and the settlement plate 310 and the protection tube 320 of the settlement layer ground contact mechanism 300 to move relative to each other in the vertical direction.

In order to reflect the relative motion such that the spacer 330 plays a predetermined role, the base spacer 330a which is supported upward by the spacer support 332 formed on the inner circumferential surface of the base protective tube 320a and ; A connection spacer 330b having a gap support 333 formed on a bottom surface thereof so as to be coupled to an upper surface of the base spacer 330a; It is desirable to take a structure that includes.

In this case, since the spacer 330 is not integrally coupled to the inner surface of the protective tube 320 of the settlement layer ground contact mechanism 300, the settlement layer ground contact mechanism 300 is caused by the settlement of the settlement layer 20. Even if it is lowered, the base spacer 330a, which behaves integrally with the grouted sheath 350, leaves the spacer support 332 and moves upward relative to the settlement layer surface contact mechanism 300. The connecting spacer 330b having the spacer support 333 coupled to the upper surface of the 330a also performs the same movement. Thus, the spacer 330 is formed of rods 100 and 200 despite deformation of the device due to settlement of the ground. ) And the settling layer surface contact mechanism 300 to play a predetermined role.

In addition, since the settlement layer ground surface contact mechanism 300 should be installed on the ground surface of the settlement layer 20 so as not to cause displacement in the lateral direction, the settlement surface below the through hole 311 of the settlement plate 310 is lowered. It is preferable to take the structure further provided with a transverse displacement preventing tube 360 extended to be inserted into the settlement layer working hole 21.

In addition, when the land fill operation is advanced and the height of the fill layer 10 is increased, the earth pressure applied by the settlement layer ground surface contact mechanism 300 increases, so that the settlement layer ground surface contact mechanism 300 is reduced. An outer wall protection tube 510 installed around the outer side of the protective tube 320 to be in surface contact with the inner circumferential surface of the fill layer work hole 11; An earth protection tube support 520 for supporting the earth protection tube 510; It is preferable to take the structure further provided with a ground surface contact mechanism protector 500 to include.

Here, since the filling work is generally performed at a predetermined height for a predetermined period, it is preferable that the ground surface contact mechanism protector 500 also has a structure capable of gradually increasing its height as in the case of the settlement surface ground contact mechanism 300. Therefore, the earth protection tube 510 is a basic earth protection tube 510a supported by the earth protection tube support 520; A connecting earth protection pipe 510b connected to an upper end of the basic earth protection pipe 510a by a connection socket 530; An example of a structure is included.

In addition, the earthen protective tube support 520 may be any structure as long as it can support the earthen protective tube 510 before and after filling work, in this embodiment, the settlement layer 20 from the outer surface of the earthen protective tube 510. A tripod 521 extending to the ground surface of the center; A earth pressure increasing wing portion 522 extending in a direction perpendicular to the core portion of the tripod 521; Present a structure to include.

Further, in order to obtain an accurate measurement value, the reference point rod 100 and the settlement rod 200 are integrally combined with the ground, so that the consolidated settlement behavior in the ground is required to be reflected as it is through the rod. At the lower end of the 100 and the sinking rod 200, it is preferable to take the structure further provided with the earth pressure increasing wing 110 formed to extend outward of the outer circumferential surface thereof.

Hereinafter, three embodiments of the relative settlement amount measuring means 400 will be described.

Fig. 2 is a cross sectional view showing the first embodiment.

As shown, the first embodiment of the relative settlement amount measuring means 400 is a staff mounting portion 120 formed on the upper end of the reference point rod 100; Staff mounting part 220 formed on the upper end of the sinking rod 200; A staff mounting part 370 formed on an upper end of the connection protection pipe 320c installed at the top of the plurality of connection protection pipes 320b and 320c of the settlement layer ground surface contact mechanism 300; A plurality of staffs (411, 412, 413) mounted on the staff mounting parts (120, 220, 370) so as to project vertically upwardly above the ground surface of the fill layer (10) through the fill layer work hole (11); A level measuring instrument (410) installed on the ground surface of the fill layer (10) to measure the staff (411, 412, 413); It is configured to include.

That is, the present invention is settled layer having a reference point rod 100 is fixed to the passivation layer 30, the settlement rod 200 installed in the settlement layer 20, the settlement plate 310 in surface contact with the ground surface of the settlement layer By measuring the relative displacement of the ground contact mechanism 300, the surface settlement amount (relative displacement of the reference point rod and the sinking plate) and the layered settlement amount (relative displacement of the reference point rod and the settlement rod) are simultaneously measured. The example is the simplest way, with the staff mounted on the upper end of the control point 320 of the reference point rod 100, the settlement rod 200 and the settlement surface contact mechanism 300, respectively, and at the ground surface of the fill layer 10. Through the level meter 410 to measure the relative displacement of the three staff.

This not only makes construction and measuring work simpler than the prior art, but also enables the surface settlement and floor settlement to be measured by one system, and since there is little risk of breakage, it is possible to accurately measure the settlement of soil over a long period of time. Therefore, it has an advantageous effect not only in the case of landfill construction but also in its maintenance.

Fig. 4 is a cross sectional view showing the second embodiment.

As shown, in the second embodiment of the relative settlement amount measuring means 400, a plurality of sensor mounting holes 421 are formed in the core portion, and a plurality of connection protective tubes 320b of the settlement layer ground surface contact mechanism 300 are provided. A sensor holder 420 installed at an upper end of the connection protection pipe 320c positioned at the top of the 320c; A reference point sensor 422 mounted to the sensor mounting hole 421 to measure a distance from an upper end of the reference point rod 100; A measurement sensor 423 mounted to the sensor mounting hole 421 to measure a distance from the upper end of the settlement rod 200; A settlement amount calculator 424 which receives the measured values of the reference point sensor 422 and the measurement sensor 423 and calculates the settlement amount; It is configured to include.

That is, in the present embodiment, a reference point sensor for installing the sensor holder 420 on the upper end of the protective tube 320 of the settlement surface ground contact mechanism 300 and measuring the relative displacement with the reference point rod 100 on the holder 420. 422 and the measuring sensor 423 for measuring the relative displacement between the sinking rod 200 is installed, the measuring method using the same is as follows.

Here, the reference point sensor 422 and the measurement sensor 423 is installed on the sensor holder 420 and integrally behaves with the settlement layer ground surface contact mechanism 300 having the settlement plate 310. Since the inserted reference point rod 100 does not generate displacement, the value measured by the reference point sensor 422 integrally behaving integrally with the settlement plate 310 becomes the surface settlement amount.

In addition, since the value measured by the measuring sensor 423 reflects not only the settlement displacement of the settlement rod 200, but also the surface settlement displacement of the settlement plate 310 which is integral with the measurement sensor 423, the actual floor settlement amount. Is a difference between the value measured by the measuring sensor 423 and the value measured by the reference point sensor 422.

In addition, the relative settlement amount measurement means 400 of the present embodiment may take a structure further comprising a settlement amount calculation value transmission unit 425 for transmitting the output value of the settlement amount calculator 424 to the measurement value receiver.

Here, the measured value receiver may be a main computer installed in a site office of a landfill construction, or may be a personal terminal (PDA) carried by a person in charge of measurement.

With this structure, it is possible to continuously check the amount of settlement of the ground even if there is no action or action in the place where the measured value receiver is installed, which is a beneficial effect in the structural analysis of the behavior of the ground where settlement occurs continuously for a long time. Will have.

In addition, although the settlement amount calculator 424 and settlement settlement value transmitter 425 need to supply power, it does not require a large amount of power, and the ground measuring apparatus according to the present invention requires long-term measurement work. Therefore, it is preferable to take a structure capable of continuously supplying stable power by the solar power supply device 426 rather than by a general power supply means.

Fig. 5 is a cross sectional view showing the third embodiment.

As shown, in the third embodiment of the relative settlement amount measuring means 400, a plurality of measuring needle through holes 431 are formed in the core portion, and dial gauge mounting portions 432 are respectively located above the through holes 431. And a sensor holder 430 installed at an upper end of the connection protection pipe 320c positioned at the top of the connection protection pipes 320b and 320c of the settlement layer ground surface contact mechanism 300; A dial gauge 433 for a reference point rod mounted on the dial gauge mounting portion 432 to measure a distance from an upper end of the reference point rod 100; A dial gauge 434 for the sink rod mounted on the dial gauge mounting portion 432 to measure a distance from the upper end of the sink rod 200; It is configured to include.

That is, in the present embodiment, the reference point rod 100, the settlement rod 200, and the settlement layer ground surface using dial gauges 433 and 434 which measure the behavior of the measurement object through the fine movement of the measurement needle in contact with the measurement object. It is the structure which measured the relative displacement of the contact mechanism 300. FIG.

Here, the dial gauge 433 for the reference point rod and the dial gauge 434 for the settlement rod are installed on the sensor holder 430 to be integrated with the settlement layer ground surface contact mechanism 300 having the settlement plate 310. Since the reference point rod 100 inserted and fixed in the antifreeze layer 30 is assumed not to cause displacement, the value measured by the reference gauge rod dial gauge 433 behaving integrally with the needle plate 310 is determined by the surface settlement amount. do.

In addition, the value measured by the sinking rod dial gauge 434 is not only the sinking displacement of the sinking rod 200, but also the ground sinking displacement of the sinking plate 310 which behaves integrally with the sinking rod dial gauge 434. Since it is reflected, the actual floor settling amount is a difference value between the value measured by the settling rod dial gauge 434 and the reference point rod dial gauge 433.

On the other hand, the present embodiment proposes an embodiment in which not only the surface settlement amount and the layer settlement amount, but also the pore water pressure can be measured in one system by using the rods 100 and 200 installed in the past.

That is, as shown in Figures 1 and 6, is installed on the lower end of the sinking rod 200, the hydraulic pressure tip mounting space is formed therein, a plurality of water holes 601 is formed on the outer peripheral surface, the lower end A hydraulic pressure gauge tip mounting hole 600 having an anchor portion 602 formed therein; A hydraulic pressure gauge tip 610 mounted to a core of the hydraulic pressure tip mounting space; A sandbag 620 mounted inside the hydraulic tip mounting space to cover and protect the hydraulic tip 610; A hydrometer cable protection unit 201 formed to protect the cable 611 of the hydrometer tip 610 in the inner space of the settlement rod 200; A hydraulic pressure cable through-hole (202) formed at the upper end of the sinking rod (200) so that the cable (611) of the hydraulic pressure tip (610) is discharged; A hydraulic pressure gauge 630 connected to the hydraulic pressure gauge cable 611 through the hydraulic pressure gauge cable through hole 202; Hydraulic leakage prevention formed at the connection portion of the hydraulic pressure tip mounting port 600 and the hydraulic pressure tip 610 to prevent the hydraulic pressure of the hydraulic pressure tip mounting space is leaked through the hydraulic pressure cable protection unit 201 Means 700; It is a more equipped structure.

The hydraulic pressure gauge tip 610 is mounted on the hydraulic pressure tip mounting hole 600 installed at the lower end of the sinking rod 200, and the hydraulic pressure cable protection part 201 and the hydraulic pressure cable through hole ( The hydraulic pressure gauge cable 611 is observed through 202 to measure the pore water pressure of the ground portion on which the hydraulic pressure gauge tip 610 is mounted by the hydraulic pressure gauge 630 installed on the ground surface of the fill layer 10. .

In such a configuration, the following effects can be obtained.

First, since the hydraulic pressure cable is directly exposed to the bentonite layer and grouting, there is a problem that damage is likely to occur, but in the present invention, since the hydraulic pressure gauge cable 611 is protected by the settlement rod 200, Concerns diminish.

Second, since the position of the hydraulic pressure gauge that changes according to the settlement of the ground is not known, there was a problem that accurate measurement of the pore water pressure according to the position of the hydraulic pressure tip was impossible, but in the present invention, the hydraulic pressure gauge 610 is used. It is integrally coupled to the lower end of the sinking rod 200, and the sinking amount of the sinking rod 200 is accurately measured by the relative settlement amount measuring means 400, even if settlement of the sinking layer 20 occurs, the hydraulic pressure tip Since the position change of 610 can be continuously detected, more accurate measurement of the pore water pressure is possible.

Third, in the related art, since each of the three measurement methods related to the surface settlement, the layer settlement, and the pore water pressure has a totally independent configuration, a separate work hole for each measurement must be drilled, and the measured values are also integrated. There is a problem that it is very difficult to obtain a precise measurement value through the measuring device because it is difficult to maintain and maintain the measuring device in view of the characteristics of the ground subsidence that occurs continuously for a long time, but the present invention integrates them all Because it can be measured in one system, the operation is simple, integrated management of the measured value and easy maintenance make it possible to obtain more reliable measured value.

In order to accurately measure the pore water pressure at the position where the hydraulic pressure tip 610 is mounted, the hydraulic pressure at the position should be prevented from leaking through the hydraulic pressure cable protection part 201 formed in the inner space of the settlement rod 200. A hydraulic leakage preventing means 700 is formed at a connection portion of the hydraulic pressure gauge tip mounting hole 600 and the hydraulic pressure tip 610.

In Figure 6 as an embodiment of the hydraulic leakage preventing means 700, and connected to the lower end of the settlement rod 200 by an internal connection screw 711, the outer circumferential surface of the wing portion 210 for increasing the earth pressure A hydraulic pressure gauge connecting mechanism 710 having a mounting portion formed therein, and a mounting portion of the hydraulic pressure gauge tip mounting hole 600 formed on an outer circumferential surface of a lower end portion, and a hydraulic pressure gauge mounting groove 712 formed on an inner circumferential surface of the lower portion; A plurality of multi-angle wrench (720) through the through-hole formed in the lower end of the hydraulic pressure gauge connecting mechanism 710, the pressing end of the hydraulic pressure gauge tip 610 mounted in the hydraulic pressure gauge mounting groove 712 in the side To; It presents a structure to include.

In addition, in order to obtain a more stable hydraulic leakage effect, it is preferable to take a structure in which a plurality of rubber rings 730 is mounted on the outer circumferential surface of the upper end of the hydraulic pressure gauge tip 610 to be compressed with the hydraulic pressure gauge mounting groove 712.

On the other hand, in some cases, it is necessary to measure not only the settlement layer 20 but also the amount of change in the pore water pressure of the passivation layer 30. In this case, the same structure as described above may be applied to the reference point rod 100 as it is. .

That is, the pressure gauge tip is installed at the lower end of the reference point rod 100, a hydraulic pressure tip mounting space is formed therein, a plurality of water holes 601 are formed at the outer circumferential surface, and the hydraulic part tip having the anchor part 602 formed at the lower end thereof. A mounting hole 600; A hydraulic pressure gauge tip 610 mounted to a core of the hydraulic pressure tip mounting space; A sandbag 620 mounted inside the hydraulic tip mounting space to cover and protect the hydraulic tip 610; A hydraulic pressure meter cable protector 101 configured to protect the cable 611 of the hydraulic pressure tip 610 in an inner space of the reference point rod 100; A hydraulic pressure cable through-hole (102) formed at the upper end of the reference point rod (100) so that the cable (611) of the hydraulic pressure tip (610) is exposed; A hydraulic pressure gauge 630 connected to the hydraulic pressure gauge cable 611 through the hydraulic pressure gauge cable through hole 202; Hydraulic leakage prevention formed at the connection portion of the hydraulic pressure gauge tip mounting hole 600 and the hydraulic pressure gauge tip 610 to prevent the hydraulic pressure of the hydraulic pressure tip mounting space from leaking through the hydraulic pressure gauge cable protector 101 Means 700; What is necessary is just to have the structure further equipped.

Here, the hydraulic leakage preventing means 700 is connected to the lower end of the reference point rod 100 by an internal connection screw 711, the mounting portion of the wing 110 for increasing the earth pressure is formed on the outer peripheral surface, the lower end A hydraulic pressure gauge connecting mechanism 710 formed on the outer circumferential surface of the hydraulic pressure tip mounting hole 600 and a hydraulic pressure gauge mounting groove 712 formed on an inner circumferential surface of the lower end portion; A plurality of multi-angle wrench (720) through the through-hole formed in the lower end of the hydraulic pressure gauge connecting mechanism 710, the pressing end of the hydraulic pressure gauge tip 610 mounted in the hydraulic pressure gauge mounting groove 712 in the side To; It is preferable to take the configuration as described above, and further provided with a plurality of rubber rings 730 mounted on the outer peripheral surface of the upper end of the hydraulic pressure gauge tip 610 to be compressed with the hydraulic pressure gauge mounting groove 712 The above is also effective to take the structure.

Hereinafter, an integrated measurement system of the surface subsidence and the water pressure, which is the second embodiment of the present invention, will be described.

Basically, the ground measuring apparatus according to the present embodiment is the same as the first embodiment in that it is constituted by the reference point rod 100, the settlement rod 200, the settlement ground surface contact mechanism 300, and the relative settlement amount measurement means 400. However, there is a difference in that the filling means 22 for filling the working hole 21 of the settlement layer 20 to fix the settlement rod 200 is constituted by the sand layer 22b.

That is, in the first embodiment, since the settlement rod 200 installed in the settlement layer 20 is fixed by the grouting 22a and behaves integrally with the settlement layer 20 ground, the settlement rod 200 is mounted. In the second embodiment, since the settlement rod 200 is installed in the sand layer 22b and does not act integrally with the ground, the measurement value as described above can be obtained. There is no.

However, since such a change in the configuration does not affect the behavior of the reference point rod 100 and the subsidence surface contact mechanism 300, the contents of the measurement of the surface subsidence are the same as those of the first embodiment. When the hydraulic pressure tip 610 is installed at the upper end of the 200, the water pressure at the portion where the hydraulic pressure tip 610 is installed can be measured under the situation where the pore water flows freely by the sand layer 22b. Integrated measurement of water level is possible.

In addition, in the first embodiment, as a specific embodiment of the relative settlement amount measuring means 400, three methods have been presented. The second embodiment is also the same, but there are differences in the following effects.

That is, in the case of the first embodiment, since the settlement rod 200 is fixed to the settlement layer 20 by the grouting 22a and behaves integrally, the amount of layer settlement can be calculated by measuring the displacement of the settlement rod 200. Since the position of the hydraulic pressure gauge tip 610 provided at the lower end of the sinking rod 200 can be grasped, it enables accurate measurement of the pore water pressure.

In contrast, in the second embodiment, since the sand layer 22b is formed in the settlement layer work hole 21 to measure the hydraulic pressure, the settlement rod 200 is not fixed to the settlement layer 20, so that the amount of layer settlement is obtained. Although not possible, the position of the hydraulic pressure gauge tip 610 installed at the lower end of the sinking rod 200 is the same as in the first embodiment.

Therefore, since the position at which the hydraulic pressure gauge tip 610 is installed can be accurately measured, it is possible to accurately measure the hydraulic pressure at the position.

On the other hand, the hydraulic pressure measuring means according to the present embodiment will be described.

That is, the hydrostatic tip is installed at the lower end of the sinking rod 200, a hydraulic pressure tip mounting space is formed therein, a plurality of water holes 601 are formed at the outer circumferential surface, and the anchor part 602 is formed at the lower end. A mounting hole 600; A hydraulic pressure gauge tip 610 mounted to a core of the hydraulic pressure tip mounting space; A hydrometer cable protection unit 201 formed to protect the cable 611 of the hydrometer tip 610 in the inner space of the settlement rod 200; A hydraulic pressure cable through-hole (202) formed at the upper end of the sinking rod (200) so that the cable (611) of the hydraulic pressure tip (610) is discharged; A hydraulic pressure gauge 630 connected to the hydraulic pressure gauge cable 611 through the hydraulic pressure gauge cable through hole 202; It is a more equipped structure.

Basically, in the first embodiment, the configuration for measuring the pore water pressure is substantially the same as that of the case, and the difference is that a separate hydraulic pressure leakage preventing means 700 is not necessary. This is because the hydraulic pressure to be measured in the second embodiment is the hydraulic pressure under the situation where the flow of the pore water is freed by the sand layer 22b.

In this structure, the sand of the sand layer 22b is introduced through the water hole 601 formed on the outer circumferential surface of the hydraulic pressure gauge tip mounting hole 600, so that the hydraulic pressure tip mounting space inside the hydraulic pressure tip mounting hole 600 is introduced. Surrounding the hydraulic pressure gauge tip 610 is mounted on, and then to measure the pressure of the hydraulic pressure of the mounting portion of the hydraulic pressure tip 610, in order to achieve a more stable structure, the hydraulic pressure tip 610 is covered and protected It is preferable to take a structure further provided with a sand bag 620 mounted inside the hydraulic pressure tip mounting space.

On the other hand, in some cases, it is necessary to measure not only the settlement layer 20 but also the amount of change in the hydraulic pressure of the passivation layer 30. In this case, the same structure as described above may be applied to the reference point rod 100 as it is.

That is, the pressure gauge tip is installed at the lower end of the reference point rod 100, a hydraulic pressure tip mounting space is formed therein, a plurality of water holes 601 are formed at the outer circumferential surface, and the hydraulic part tip having the anchor part 602 formed at the lower end thereof. A mounting hole 600; A hydraulic pressure gauge tip 610 mounted to a core of the hydraulic pressure tip mounting space; A hydraulic pressure meter cable protector 101 configured to protect the cable 611 of the hydraulic pressure tip 610 in an inner space of the reference point rod 100; A hydraulic pressure cable through-hole (102) formed at the upper end of the reference point rod (100) so that the cable (611) of the hydraulic pressure tip (610) is discharged; A hydraulic pressure gauge 630 connected to the hydraulic pressure gauge cable 611 through the hydraulic pressure gauge cable through-hole 102; It is a more equipped structure.

In addition, it is preferable to take a structure further comprising a sand bag 620 mounted inside the hydraulic pressure tip mounting space to cover and protect the hydraulic pressure tip 610.

According to the present invention, it is possible to measure surface settlement amount, layer settlement amount and pore water pressure or surface settlement amount and water pressure in one system, and to reduce the risk of breakage of the measuring device and to obtain a more accurate measurement value. It provides a ground measuring device and method for maintenance.

Claims (30)

Reference point is installed so that the lower end penetrates the settling layer work hole 21 perpendicular to the settling layer 20 and is inserted into the floating layer 30 and the upper part is exposed through the opening of the settling layer work hole 21. A rod 100; The lower end is inserted into the settlement layer work hole 21 and is installed at a predetermined position of the settlement layer 20 by the filling means 22 filling the work hole 21, and the upper end portion opens the opening of the work hole. A sinking rod 200 installed to be exposed through; A through hole 311 is formed in the core portion so as to penetrate the settlement layer work hole 21, and a settlement layer ground surface contact mechanism having a settlement plate 310 formed at an edge thereof in surface contact with the surface of the settlement layer 20. 300; A relative settlement amount measuring means (400) for measuring a relative difference value of the settlement amount of each of the reference point rod (100), the settlement rod (200), and the settlement layer ground surface contact mechanism (300); Ground measurement device for the construction and maintenance, including. The method of claim 1, The settlement layer ground contact mechanism 300 is Perforated perpendicular to the fill layer 10 so as to be inserted into the fill layer work hole 11 formed to penetrate the settling layer work hole 21, from the through hole 311 of the settlement plate 310 to the upper side Soil construction and maintenance ground measurement device characterized in that it further comprises an extended protective tube 320. The method of claim 2, The protective tube 320 of the settlement layer ground surface contact mechanism 300 A basic protective tube 320a fixed to the settlement plate 310; A plurality of connection protection tubes 320b and 320c connected to an upper end of the base protection pipe 320a by a connection socket 380; Ground measurement device for land works and maintenance comprising a. The method of claim 3, The settlement layer ground contact mechanism 300 is A spacer 330 formed on an inner circumferential surface of the protective tube 320 and a rod through hole 331 of the reference point rod 100 and the sinking rod 200 are formed in the core portion; Ground measurement device for land works and maintenance characterized in that it further comprises. The method of claim 4, wherein The spacer 330 is A base spacer 330a supported upward by a spacer support jaw 332 formed on an inner circumferential surface of the base protective tube 320a; A connection spacer 330b having a gap support 333 formed on a bottom surface thereof so as to be coupled to an upper surface of the base spacer 330a; Ground measurement device for land works and maintenance comprising a. The method of claim 5, The settlement layer ground contact mechanism 300 is Sheath fasteners 340 installed in the rod through hole 331a of the base spacer 330a; A sheath 350 that is connected to the sheath fixture 340 and extends downward and covers and covers the reference point rod 100 and the settlement rod 200; Ground measurement device for land works and maintenance characterized in that it further comprises. The method of claim 6, The sheath fixture 340 is Sheath connecting screw 341 connected to the upper end of the sheath 350; An upper fixing screw 342 fixed to an upper opening of the rod through hole 331a of the foundation spacer 330a and fixing the sheath connecting screw 341; A lower fixing screw 343 fixed to the lower opening of the rod through hole 331a of the foundation spacer 330a and covering and protecting the sheath 350; Ground measurement device for land works and maintenance comprising a. The method of claim 2, The settlement layer ground contact mechanism 300 is Filling construction and maintenance characterized in that it further comprises a transverse displacement preventing tube 360 is formed extending from the through hole 311 of the settlement plate 310 inserted into the settlement layer work hole 21. Ground measuring device. The method of claim 2, Outside the settlement layer ground surface contact mechanism 300 An earth barrier protection tube 510 installed around the outer side of the protection tube 320 so as to be in surface contact with the inner circumferential surface of the fill layer work hole 11; An earth protection tube support 520 for supporting the earth protection tube 510; Ground measurement device for land works and maintenance, characterized in that the surface contact mechanism protector 500 further comprises. The method of claim 9, The earth protection tube 510 is A basic earth protection pipe (510a) supported by the earth protection pipe support (520); A connecting earth protection pipe 510b connected to an upper end of the basic earth protection pipe 510a by a connection socket 530; Soil construction and maintenance ground measurement device comprising a. The method of claim 9, The retainer support pipe 520 is A tripod 521 extending from the outer surface of the earthen protective tube 510 to the ground surface of the settlement layer 20; A earth pressure increasing wing portion 522 extending in a direction perpendicular to the core portion of the tripod 521; Ground measurement device for land works and maintenance comprising a. The method of claim 1, A ground measurement device for earthwork and maintenance, characterized in that the lower end of the reference point rod 100 is further provided with an earth pressure increasing wing 110 formed to extend to the outside of the outer peripheral surface. The method of claim 3, The relative settlement amount measuring means 400 A staff mounting part 120 formed at an upper end of the reference point rod 100; Staff mounting part 220 formed on the upper end of the sinking rod 200; A staff mounting part 370 formed on an upper end of the connection protection pipe 320c installed at the top of the plurality of connection protection pipes 320b and 320c of the settlement layer ground surface contact mechanism 300; A plurality of staffs (411, 412, 413) mounted on the staff mounting parts (120, 220, 370) so as to project vertically upwardly above the ground surface of the fill layer (10) through the fill layer work hole (11); A level measuring instrument (410) installed on the ground surface of the fill layer (10) to measure the staff (411, 412, 413); Ground measurement device for land works and maintenance comprising a. The method of claim 3, The relative settlement amount measuring means 400 A plurality of sensor mounting holes 421 are formed in the core portion, and a sensor holder installed on an upper end of the connection protection tube 320c positioned at the top of the connection protection tubes 320b and 320c of the settlement layer ground surface contact mechanism 300. 420; A reference point sensor 422 mounted to the sensor mounting hole 421 to measure a distance from an upper end of the reference point rod 100; A measurement sensor 423 mounted to the sensor mounting hole 421 to measure a distance from the upper end of the settlement rod 200; A settlement amount calculator 424 which receives the measured values of the reference point sensor 422 and the measurement sensor 423 and calculates the settlement amount; Ground measurement device for land works and maintenance comprising a. The method of claim 14, The relative settlement amount measuring means 400 A soil measuring device for land works and maintenance, characterized in that it further comprises a settled amount calculation value transmitting unit (425) for transmitting the output value of the settling amount calculator (424) to the measured value receiver. The method of claim 15, The relative settlement amount measuring means 400 The ground measurement device for land works and maintenance characterized in that it further comprises a solar power supply unit 426 for supplying power to the settlement amount calculator (424) and settlement settlement value transmission unit (425). The method of claim 3, The relative settlement amount measuring means 400 A plurality of measuring needle through-holes 431 are formed in the core portion, and dial gauge mounting portions 432 are formed above the through-holes 431, respectively, and a plurality of connection protection tubes of the settlement layer ground surface contact mechanism 300 are provided. A sensor holder 430 installed at an upper end of the connection protection pipe 320c positioned at the top of the 320b and 320c; A dial gauge 433 for a reference point rod mounted on the dial gauge mounting portion 432 to measure a distance from an upper end of the reference point rod 100; A dial gauge 434 for the sink rod mounted on the dial gauge mounting portion 432 to measure a distance from the upper end of the sink rod 200; Ground measurement device for land works and maintenance comprising a. The method according to any one of claims 1 to 17, The ground measuring device for land works and maintenance, characterized in that the filling means 22 is grouting (22a). The method of claim 18, A ground measurement device for earthwork and maintenance, characterized in that the lower end of the sinking rod 200 is further provided with an earth pressure increasing wing portion 210 extending to the outside of the outer peripheral surface. The method of claim 19, In addition to being installed at the lower end of the sinking rod 200, a hydraulic pressure tip mounting space is formed therein, a plurality of water holes 601 is formed on the outer circumferential surface, the hydraulic pressure tip mounting hole formed with an anchor portion 602 at the lower end 600; A hydraulic pressure gauge tip 610 mounted to a core of the hydraulic pressure tip mounting space; A sand bag 620 mounted inside the hydraulic pressure tip mounting space to cover and protect the hydraulic pressure tip 610; A hydrometer cable protection unit 201 formed to protect the cable 611 of the hydrometer tip 610 in the inner space of the settlement rod 200; A hydraulic pressure cable through-hole (202) formed at the upper end of the sinking rod (200) so that the cable (611) of the hydraulic pressure tip (610) is discharged; A hydraulic pressure gauge 630 connected to the hydraulic pressure gauge cable 611 through the hydraulic pressure gauge cable through hole 202; Hydraulic leakage prevention formed at the connection portion of the hydraulic pressure tip mounting port 600 and the hydraulic pressure tip 610 to prevent the hydraulic pressure of the hydraulic pressure tip mounting space is leaked through the hydraulic pressure cable protection unit 201 Means 700; Ground measurement device for land works and maintenance characterized in that it further comprises. The method of claim 20, The hydraulic leakage prevention means 700 is In addition to being connected to the lower end of the settlement rod 200 by an internal connection screw 711, the mounting portion of the earth pressure increasing wing 210 is formed on the outer circumferential surface, the pressure gauge tip mounting hole 600 on the outer peripheral surface of the lower end A mounting part of the hydraulic pressure gauge connecting mechanism 710 formed on the inner circumferential surface of the lower end thereof; A plurality of multi-angle wrench (720) through the through-hole formed in the lower end of the hydraulic pressure gauge connecting mechanism 710, the pressing end of the hydraulic pressure gauge tip 610 mounted in the hydraulic pressure gauge mounting groove 712 in the side To; Ground measurement device for land works and maintenance comprising a. The method of claim 21, The hydraulic leakage prevention means 700 is Soil construction and maintenance ground measurement apparatus, characterized in that it further comprises a plurality of rubber rings (730) mounted on the outer peripheral surface of the upper end of the hydraulic pressure tip (610) to be compressed with the hydraulic pressure gauge mounting groove (712). The method of claim 19, In addition to being installed at the lower end of the reference point rod 100, a hydraulic pressure tip mounting space is formed therein, a plurality of water holes 601 is formed on the outer peripheral surface, the hydraulic pressure tip mounting hole formed with an anchor portion 602 at the lower end 600; A hydraulic pressure gauge tip 610 mounted to a core of the hydraulic pressure tip mounting space; A sandbag 620 mounted inside the hydraulic tip mounting space to cover and protect the hydraulic tip 610; A hydraulic pressure meter cable protector 101 configured to protect the cable 611 of the hydraulic pressure tip 610 in an inner space of the reference point rod 100; A hydraulic pressure cable through-hole (102) formed at the upper end of the reference point rod (100) so that the cable (611) of the hydraulic pressure tip (610) is exposed; A hydraulic pressure gauge 630 connected to the hydraulic pressure gauge cable 611 through the hydraulic pressure gauge cable through hole 202; Hydraulic leakage prevention formed at the connection portion of the hydraulic pressure gauge tip mounting hole 600 and the hydraulic pressure gauge tip 610 to prevent the hydraulic pressure of the hydraulic pressure tip mounting space from leaking through the hydraulic pressure gauge cable protector 101 Means 700; Ground measurement device for land works and maintenance characterized in that it further comprises. The method of claim 23, wherein The hydraulic leakage prevention means 700 is In addition to being connected to the lower end of the reference point rod 100 by an internal connection screw 711, the mounting portion of the earth pressure increasing wing 110 is formed on the outer circumferential surface, the pressure gauge tip mounting hole 600 on the outer peripheral surface of the lower end A mounting part of the hydraulic pressure gauge connecting mechanism 710 formed on the inner circumferential surface of the lower end thereof; A plurality of multi-angle wrench (720) through the through-hole formed in the lower end of the hydraulic pressure gauge connecting mechanism 710, the pressing end of the hydraulic pressure gauge tip 610 mounted in the hydraulic pressure gauge mounting groove 712 in the side To; Ground measurement device for land works and maintenance comprising a. The method of claim 24, The hydraulic leakage prevention means 700 is Soil construction and maintenance ground measurement apparatus, characterized in that it further comprises a plurality of rubber rings (730) mounted on the outer peripheral surface of the upper end of the hydraulic pressure tip (610) to be compressed with the hydraulic pressure gauge mounting groove (712). The method according to any one of claims 1 to 17, The ground measuring device for land works and maintenance, characterized in that the filling means 22 is a sand layer (22b). The method of claim 26, In addition to being installed at the lower end of the sinking rod 200, a hydraulic pressure tip mounting space is formed therein, a plurality of water holes 601 is formed on the outer circumferential surface, the hydraulic pressure tip mounting hole formed with an anchor portion 602 at the lower end 600; A hydraulic pressure gauge tip 610 mounted to a core of the hydraulic pressure tip mounting space; A hydrometer cable protection unit 201 formed to protect the cable 611 of the hydrometer tip 610 in the inner space of the settlement rod 200; A hydraulic pressure cable through-hole (202) formed at the upper end of the sinking rod (200) so that the cable (611) of the hydraulic pressure tip (610) is discharged; A hydraulic pressure gauge 630 connected to the hydraulic pressure gauge cable 611 through the hydraulic pressure gauge cable through hole 202; Ground measurement device for land works and maintenance characterized in that it further comprises. The method of claim 27, Soil construction and maintenance ground measurement apparatus further comprises a sand bag 620 mounted inside the hydraulic tip mounting space to protect the hydraulic tip (610). The method of claim 26, In addition to being installed at the lower end of the reference point rod 100, a hydraulic pressure tip mounting space is formed therein, a plurality of water holes 601 is formed on the outer peripheral surface, the hydraulic pressure tip mounting hole formed with an anchor portion 602 at the lower end 600; A hydraulic pressure gauge tip 610 mounted to a core of the hydraulic pressure tip mounting space; A hydraulic pressure meter cable protector 101 configured to protect the cable 611 of the hydraulic pressure tip 610 in an inner space of the reference point rod 100; A hydraulic pressure cable through-hole (102) formed at the upper end of the reference point rod (100) so that the cable (611) of the hydraulic pressure tip (610) is exposed; A hydraulic pressure gauge 630 connected to the hydraulic pressure gauge cable 611 through the hydraulic pressure gauge cable through-hole 102; Ground measurement device for land works and maintenance characterized in that it further comprises. The method of claim 29, Soil construction and maintenance ground measurement apparatus further comprises a sand bag 620 mounted inside the hydraulic tip mounting space to protect the hydraulic tip (610).