KR101118757B1 - Ground layer sinking volume measurement apparatus and measurement system using the smae - Google Patents

Abstract

The present invention relates to a measurement device 100 is inserted into the drilling hole 10 of the underground to measure the amount of settlement of each floor, the portion inserted into the drilling hole 10 is substantially maintained in the upright state, the drilling hole 10 A segmented rod 110 formed by the combination of a plurality of fragment rods 111, 112, and 113 such that the portion exposed to the opening of the portion is refracted and laid down; By presenting the floor settling measurement device 100 comprising a; sensor 120 is installed to measure the relative displacement of the ground and the segmented rod 110, it is possible to continuously fill and measure after the occurrence of the settlement, Automated measurements are possible even at several meters.

Settlement, Measurement, Segmentation

Description

Floor settling measuring device and measuring device using same {GROUND LAYER SINKING VOLUME MEASUREMENT APPARATUS AND MEASUREMENT SYSTEM USING THE SMAE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the field of construction metrology, and more particularly, to an apparatus and a system for measuring floor subsidence.

In the case of landfill work in various civil works, consolidation of the ground will inevitably occur due to the load of the landfill layer. The submerged portion (hereinafter referred to as subsidence layer) is settled not only on the surface of the subsidence but also in the central portion of the subsidence.

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

1 and 2 are cross-sectional views schematically showing the structure of a conventional floor settling measurement apparatus.

The rod 20 is inserted into the drilling hole 10 formed in the ground 1, the lower end of the rod 20 is fixed to the support layer 11, and the sensor 30 is the ground to be measured in the ground 1. It is installed underground to measure the relative displacement of the layer and the rod 20.

This conventional measuring device had the following problems.

In the case of large-scale landfill works, a very large settlement occurs, sometimes reaching several meters.

Therefore, even if the rod 20 is installed such that the upper end of the rod 20 is only slightly exposed to the upper portion before the settlement occurs, as shown in FIG. 2 after the massive settlement occurs, as shown in FIG. A significant portion of the top of the) protrudes above the surface.

In this way, when the upper end of the rod 20 of the settlement measurement device protrudes above the surface of the ground, since it is impossible to compact the equipment passing therethrough, it will cause enormous obstacles to the subsequent filling work. It was a reality to give up and proceed with fill work.

The present invention was derived to solve the above problems, and an object of the present invention is to provide a sedimentation amount measuring device and a measuring instrument using the same to enable continuous filling and measuring operations even after occurrence of settlement.

In order to achieve the object as described above, the present invention, in the measurement device 100 is inserted into the underground hole 10 to measure the amount of settlement per floor, the portion inserted into the drilling hole 10 is substantially upright A segmented rod (110) formed by the combination of a plurality of fragment rods (111, 112, 113) so as to maintain a state and the portion exposed to the opening of the drilling hole (10) is refracted and laid down; Presented floor settlement measuring device 100 comprising a; sensor 120 is installed to measure the relative displacement of the ground and the segmented rod (110).

The plurality of piece rods (111, 112, 113) is preferably hinged to each other.

It is preferable to further include a guide member 130 for guiding the portion of the segmented rod 110 exposed to the opening of the drilling hole 10 to be deflected in a predetermined direction.

The guide member 130 is preferably installed above the opening of the drilling hole 10, the bottom surface preferably includes an upper guide member 131 of a curved structure.

The center of curvature of the bottom surface of the upper guide member 131 is preferably biased in the direction of refraction of the segmented rod 110 from the drilling hole 10.

The guide member 130 is preferably installed at the opening side of the drilling hole 10, the upper surface preferably further includes a lower guide member 132 of a curved structure.

The guide member 130 may further include a linear guide member 133 formed to guide the portion of the segmented rod 110 guided by the lower guide member 132 laterally in a straight line shape.

The sensor 120 includes a rotating shaft 121 installed to be integral with the ground; A rotor (122) installed to rotate when the segmented rod (110) is driven up and down about the rotation shaft (121); It is preferable to include; measuring unit 123 for measuring the amount of rotation of the rotor (122).

The rotating shaft 121 and the rotor 122 are preferably installed at both sides of the segmented rod 110.

The lower end of the segmented rod 110 is embedded in the rock layer 11, the sensor 120 is preferably installed in a plurality in the vertical direction in the ground.

The lower end of the segmented rod 110 is embedded in the ground layer to be measured, the sensor 120 is preferably installed above the opening of the drilling hole (10).

The housing 120 is installed on the upper end of the drilling hole 10 to be moved together with the ground surface, and further includes a housing 140 having a through hole 141 of the segmented rod 110 formed on the bottom surface thereof. It is preferable that the housing 140 is installed to be integrated with the housing 140.

The present invention is a measuring instrument using the layered settlement amount measuring device 100, a plurality of segmented rod 110 is inserted into the drilling hole 10, the lower end of the plurality of segmented rod 110 is different The layered settlement meter, which is fixed to the ground layers 1a and 1b of depth, is presented together.

It is preferable that a plurality of through holes 141a and 141b are formed in the bottom surface 140 of the enclosure so that the plurality of segmented rods 110 pass therethrough.

A fixing hole 201 is formed to fix a lower end of one segmented rod of the plurality of segmented rods 110, a through hole 202 is formed to penetrate another segmented rod, and a side surface of the segmented rod 110 is formed. It is preferable that the fixing member 200 is further provided to fix the layers 1a and 1b.

The present invention provides a continuous sedimentation work and measurement work even after the occurrence of settlement, and provides a floor-level settlement measurement device and a measuring instrument using the same to enable automatic measurement even when the settlement amount reaches a few meters.

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

As shown below in FIG. 3, the present invention relates to a measuring device 100 inserted into a drilled hole 10 in the ground to measure the amount of settlement of each floor, and a portion inserted into the drilled hole 10 is substantially upright. A segmented rod (110) formed by the combination of the plurality of fragment rods (111, 112, 113) so that the portion exposed to the opening of the drilling hole (10) is refracted and laid down; And a sensor 120 installed to measure the relative displacement of the ground and the segmented rod 110.

That is, instead of using the rod 20 having a simple linear structure as in the prior art, and using the segmented rod 110 capable of both an upright state and a refractive state, it is exposed to the opening of the punched hole 10 by settlement of the ground. The part is made to lie down by refraction (Figs. 4 and 5).

Therefore, since it does not interfere with the subsequent filling work, it is possible to proceed smoothly in the construction, and when a free space for the upper portion of the segmented rod 110 is secured is secured, continuous measurement is possible even if the filling continues. The effect can be obtained.

In addition, in the past, in the case of soft ground reaching 4 ~ 5m or more in the settlement had to actually give up the automatic measurement, in the case of applying the configuration of the present invention, this effect is added.

The segmented rod 110 is formed by the combination of a plurality of pieces of rods 111, 112, and 113, and may be any structure that can convert the upright state and the refractive state described above, but as illustrated in FIGS. 3, 6, and 7. Likewise, when the plurality of pieces of rods 111, 112, and 113 are hinged to each other by the coupling pin 110a or the like, there is an advantage that the above-described structure can be easily converted.

The exposed portion of the segmented rod 110 through the opening of the drilled hole 10 is naturally refracted, and when the structure having the guide member 130 for guiding it in a predetermined direction is taken, the exposed segmented rod The advantage is that the top of 110 can be more easily managed.

When the upper guide member 131 having a curved bottom surface is installed above the opening of the drilling hole 10, the protruding segmented rod 110 may be naturally refracted to one side, and the upper guide member 131 In the case where the center of curvature of the bottom surface of the c) is deflected from the drilling hole 10 in the direction of refraction of the segmented rod 110, the advantage of determining the direction of refraction is added (FIGS. 3 and 8).

When the lower guide member 132 having a curved upper surface is installed on the side of the opening of the drilling hole 10, the upper part of the segmented rod 110 refracted downward can be stably laid down. have.

When the linear guide member 133 is installed to guide the portion of the segmented rod 110 guided by the lower guide member 132 to the side in a straight form, the upper portion of the segmented rod 110 in the lying state is stable. As a result, it is added to the advantage that the subsequent filling work and measurement work can be performed more stably.
The guide member 130 (upper guide member 131, lower guide member 132, straight guide member 133) to perform the above-described function, a drill hole (a separate structure from the segmented rod 110) As long as it is a structure provided in the vicinity of the opening of 10), it may be any.

When the lower end of the segmented rod 110 is embedded in the rock layer 11, and the sensor 120 is installed in the vertical direction in the ground, it is possible to measure the settlement amount per layer by the same method as in the prior art.

Further, when the lower end of the segmented rod 110 is embedded in the ground layer to be measured, and the sensor 120 takes the configuration provided above the opening of the drilling hole 10, the sensor 120 having a sensitive structure is It is not located in the ground, but is located on the ground surface, there is an advantage that the failure of the sensor 120 can be reduced more stable measurement (Fig. 9).

The housing 140 further includes a housing 140 in which a through hole 141 of the segmented rod 110 is formed at the bottom of the drilling hole 10 so as to behave together with the ground surface, and the sensor 120 is integral with the housing 140. In the case of taking the structure installed so that the sensor 120 is behaved in a continuous manner, the sensor 120 reliably integrally behaves with the earth's surface, thereby enabling more accurate measurement.

When such measuring apparatus 100 is applied to a plurality of ground layers 1a and 1b, a system capable of measuring the amount of settlement for each layer of each ground layer is formed.

That is, the plurality of segmented rods 110 are inserted into the drilling holes 10, and the lower ends of the plurality of segmented rods 110 are fixed to the ground layers 1a and 1b having different depths.

In this case, only one through hole 141 may be formed in the bottom surface 140 of the enclosure so that all of the plurality of segmented rods 110 may be exposed therethrough, but each of the plurality of segmented rods 110 may pass through. It is preferable to take a structure in which a plurality of through holes 141a and 141b are formed so that the lower portion of the segmented rod 110 can be guided to maintain the upright state (FIG. 10).

For this purpose, the fixing hole 201 is formed so that the lower end of one segmented rod of the plurality of segmented rods 110 is fixed, and the through hole 202 is formed to penetrate the other segmented rods. It is preferable to take the structure further provided with the fixing member 200 provided so that the side surface may be fixed to the ground layers 1a and 1b (FIG. 11).

That is, the lower part of the segmented rod 110 is guided by the through hole 141 of the enclosure 140 and the through hole 202 of the fixing member 200 to maintain the upright state.

The sensor 120 may be any structure provided to measure the relative displacement of the ground and the segmented rod 110.

12 shows, as one embodiment of the sensor 120, a rotating shaft 121 installed on the enclosure 140 to be integrated with the ground; A rotor 122 installed to rotate when the segmented rod 110 is driven up and down about the rotation shaft 121; It shows a configuration including; measuring unit 123 for measuring the amount of rotation of the rotor (122).

Here, the measuring unit 123 may be implemented by a potentio meter.

For accurate measurement, it is required that the rotor 122 and the segmented rod 110 closely adhere to each other so that the vertical drive of the segmented rod 110 is converted into the rotational drive of the rotor 122 as it is. .

To this end, it is preferable that the rotating shaft 121 and the rotor 122 are installed on both sides of the segmented rod 110 so that the rotor 122 on both sides presses the segmented rod 110 inward.

Since the above has been described only with respect to some of the preferred embodiments that can be implemented by the present invention, the scope of the present invention, as is well known, should not be construed as limited to the above embodiments, the present invention described above It will be said that both the technical idea and the technical idea which together with the base are included in the scope of the present invention.

1 and 2 are cross-sectional views of a conventional measuring device.

3 or less shows an embodiment of the present invention,

3 is a configuration diagram of a first embodiment of a measuring device.

4 and 5 are operating states of the first embodiment of the measuring instrument;

6 is a front view of the engraving rod.

7 is a partial cross-sectional view of a segmented rod.

8 is a configuration diagram of a second embodiment of a measurement apparatus.

9 is a sectional view of a second embodiment of a measuring instrument.

10 is a perspective view of the enclosure;

11 is a perspective view of the fixing member.

12 is a configuration diagram of a sensor.

DESCRIPTION OF REFERENCE NUMERALS

1,1a, 1b Ground 10: Hole drilled

11: support layer 100: measuring device

110: segmented rod 111,112,113: fragment rod

120: sensor 121: rotation axis

122: rotor 123: measuring unit

130: guide member 131: upper guide member

132: lower guide member 133: straight guide member

140: enclosure 141,141a, 141b: through hole

200: fixing member 201: fixing hole

202: through hole

Claims (15)

delete delete In the measuring device 100 is inserted into the underground drilling hole 10 to measure the amount of settlement by floor, By inserting the plurality of pieces rods 111, 112, and 113 so that the portion inserted into the drilling hole 10 remains substantially upright and the portion exposed to the opening of the drilling hole 10 is refracted and laid down. Formed segmented rod 110; A sensor (120) installed to measure the relative displacement of the ground and the segmented rod (110); A guide member 130 for guiding a portion of the segmented rod 110 exposed through the opening of the drilling hole 10 to be deflected in a predetermined direction; Floor settling measurement device characterized in that it comprises a. The method of claim 3, The guide member 130 is Floor settlement amount measuring device 100, which is installed on the upper side of the opening of the drilling hole 10, the bottom surface includes a curved upper guide member (131). 5. The method of claim 4, The center of curvature of the bottom surface of the upper guide member (131) is settled floor level measurement apparatus 100, characterized in that located in the deflection direction of the segmented rod 110 from the drilling hole (10). 5. The method of claim 4, The guide member 130 is Floor settlement amount measuring device 100, which is installed on the opening side of the drilling hole 10, the upper surface further comprises a lower guide member 132 of a curved structure. The method of claim 6, The guide member 130 is Floor settling measurement device 100, characterized in that it further comprises a linear guide member 133 formed to guide the portion of the segmented rod 110 guided by the lower guide member 132 in a straight direction laterally. . The method of claim 3, The sensor 120 is A rotating shaft 121 installed to be integral with the ground; A rotor (122) installed to rotate when the segmented rod (110) is driven up and down about the rotation shaft (121); Measuring unit 123 for measuring the amount of rotation of the rotor 122; Floor settling measurement device characterized in that it comprises a. The method of claim 8, The rotary shaft (121) and the rotor (122) is settled amount measurement device for each floor, characterized in that installed on both sides of the segmented rod (110). The method according to any one of claims 3 to 9, The lower end of the segmented rod (110) is embedded in the rock layer (11), the sensor 120 is settled amount measurement device for each floor, characterized in that a plurality is installed in the vertical direction in the ground. The method according to any one of claims 3 to 9, The lower end of the segmented rod (110) is embedded in the ground layer to be measured, the sensor 120 is settled amount measurement device for each floor, characterized in that installed on the upper side of the opening of the drilling hole (10). The method of claim 11, The housing 140 is installed on the upper end of the drilling hole 10 to behave together with the ground surface, and further includes a housing 140 having a through hole 141 of the segmented rod 110 at the bottom thereof. The sensor 120 is settled amount measurement device for each floor, characterized in that installed to be integrated with the enclosure 140. As a measuring instrument using the layered settlement measurement device of claim 12, A plurality of segmented rods 110 are inserted into the drilling holes 10, and lower ends of the plurality of segmented rods 110 are fixed to ground layers 1a and 1b of different depths, respectively. Floor Settlement Meter. The method of claim 13, The bottom surface 140 of the enclosure has a plurality of through-holes (141a, 141b) is formed so that the plurality of segmented rods (110) penetrates the floor settled amount gauge. The method of claim 13, A fixing hole 201 is formed to fix a lower end of one segmented rod of the plurality of segmented rods 110, a through hole 202 is formed to penetrate another segmented rod, and a side surface of the segmented rod 110 is formed. Settlement level meter for each floor characterized in that it further comprises a fixing member (200) installed to fix the layers (1a, 1b).

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