KR101426897B1 - Device for measuring sediment entrainments by debris flows - Google Patents

Abstract

The present invention relates to a device for measuring a landslide sediment floating amount. The device for measuring a landslide sediment floating amount according to the present invention includes a flume portion that is configured to have a bottom portion and side surface portions formed on both sides of the bottom portion and is arranged at an angle so that a first soil body can be slid; a frame portion in which frames are arranged in a lattice shape in a horizontal, vertical, and height directions in the flume portion across an upper portion to a lower portion of the flume portion to match in shape with a previously set landslide surface; cell portions that are configured to have bottom plates, side surface plates, and front surface plates which are inserted into and supported by the plurality of frames arranged in the lattice shape and form a space accommodating a second soil body with the bottom plates, the side surface plates, and the front surface plates; and an impact amount measuring unit that is arranged below the flume portion to measure impact amounts of the first soil body slid through the flume portion and the second soil body; or a movement amount measuring unit that measures moving distances of the first soil body and the second soil body.

Description

[0001] The present invention relates to a device for measuring sediment entrainments by debris flows,

TECHNICAL FIELD The present invention relates to a natural disaster mitigation technique related to a landslide, and more particularly, to an experimental apparatus capable of measuring a sediment entrainment of a landslide sediment, which is an important factor in evaluating the flow characteristics and risks of landslides.

The landslide occurs due to various causes such as heavy rains and vibration, and it can cause great damage to residential facilities as well as industrial facilities and national infrastructure, as in the recent 'Woomyunsan' landslide. . Especially in recent years, heavy rainfall frequently occurs due to climate change and the frequency of landslides is increasing, so precise studies and measures are required for landslides.

Studies on landslides need to be done in two aspects. One is prediction of the occurrence of landslides and the timing of occurrence of landslides. Another is to predict the extent of landslide spread and minimize the damage of civil facilities caused by landslides when landslides occur. will be.

The first research topic is predicting landslides through analysis of the causes of landslides, and reducing damages through construction of forecasting system when landslide risk conditions are formed. For example, the study of the occurrence of landslides due to the rise of groundwater level due to heavy rainfall or the increase of the pore pressure due to the saturation of the soil layer, the construction of an alarm system by predicting the occurrence time of landslides, the occurrence of landslide early, This is the case with the study of the behavior of the tots up to the process of reaching. Research on the cause of the landslide occurrence and the forecasting system is actively carried out.

The second research topic is about the disaster prevention measures that can predict the extent of impacts when landslides occur and minimize damage to civilian facilities. Research on this is not yet active.

The second research topic is to study the extent of landslide impact. In other words, studies should be conducted on the amount of sediment (floatation amount of sediments), the movement and spreading distance of sediments, and the amount of impact of sediments flowing down when a landslide occurs. If residential complexes or industrial facilities are adjacent to landslide-prone areas, it is very important to ensure that they are within the range of landslide impacts (extent of sediment dispersion). It is also important to understand the impact of the sediment. To do this, research and prediction of landslide impacts should be essential.

However, to date, there have been few researches on 'sediment floods' such as the distance, spread range, and the amount of impact of sediments due to landslides in Korea.

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made in an effort to solve the above problems, and an object of the present invention is to provide an experimental apparatus capable of measuring the impact load and the moving distance of sediments depending on the amount of sediment floating when landslides and / .

In order to accomplish the above object, according to the present invention, there is provided an apparatus for measuring the floating amount of a landslide deposit, comprising: a floor portion; a side portion formed on both sides of the bottom portion; A frame part in which a plurality of frames are arranged in a lattice pattern in a horizontal direction, a vertical direction and a height direction in the inside of the plume part from the upper part to the lower part of the plume part according to the shape of the predetermined landslide surface; A side plate, and a front plate, each of which is sandwiched and supported between the plurality of frames arranged in a lattice pattern, Cell portion; And an impact amount measuring unit disposed at a lower portion of the plume unit and measuring an impact amount of the first and second slopes, which are slid through the plume unit, Or a moving distance measuring unit for measuring the moving distance of the first and second glazing bodies.

According to the present invention, the side plate is a screen plate in which a plurality of holes are formed so that the second glazing body can flow out sideways, and the size of the holes may be formed differently for each screen plate.

The bottom plate is impermeable to prevent water from leaking out of the second glazing, and a load cell may be installed on the bottom plate so that the load of the second glazing received in the plurality of cell portions can be measured .

In an embodiment of the present invention, it is preferable that some of the float portions are disposed in a curved shape so that the curl amount and the curved shape in the curved portion can be measured.

In the present invention, the impact amount measuring unit may include: a blocking plate disposed on a path of the first and second goggles sliding along the flume and colliding with the first and second goggles; And a load cell for measuring the amount of impact applied to the plate.

The movement amount measuring unit may include a scale unit disposed at a lower portion of the plume unit to measure a movement distance and a diffusion distance of the first and second goggles sliding along the flume unit.

Since the apparatus for measuring the floating amount of landslide deposits according to the present invention can reflect the phenomenon that the time after the occurrence of the initial landslide is increased by the erosion caused from the surrounding terrain in the course of the landslide, the actual landslide in the natural environment can be accurately The advantage is that it can be reproduced.

In addition, by measuring the amount of impact and movement distance of the increased sediments during the landslide process, it is possible to grasp the extent of influence and influence of the landslide on the infrastructure. Can be provided.

According to the present invention, the terrain condition, the soil condition, and the rainfall conditions of the landslide slope can be variously adjusted, and various dangerous landslides can be reproduced. Therefore, there is an advantage that the experiment can be performed by specifying the area and conditions.

1 is a schematic perspective view of a device for measuring a landslide levitation amount according to an embodiment of the present invention.
2 is a schematic plan view of the apparatus for measuring the landslide levitation amount shown in Fig.
3 is a schematic side view of the apparatus for measuring the landslide levitation amount shown in Fig.
4 is a schematic perspective view for explaining a cell unit including a frame, a bottom plate, a side plate, and a front plate of the apparatus for measuring a landslide levitation amount shown in FIG.
5 is a schematic cross-sectional view for explaining the configuration of the uppermost cell portion among a plurality of cell portions.
Fig. 6 is a schematic cross-sectional view and a partial enlarged view of the line aa in Fig. 1;
7 is a schematic cross-sectional view and partially enlarged view of line bb in Fig.
8 and 9 are schematic cross-sectional views of a device for measuring a landslide levitation amount according to another embodiment.

One of the greatest features of landslides is that the total accumulated amount of accumulated landslide increases by 1 ~ 40 times compared with that at the time of landslide occurrence. That is, in the landslide occurrence part, the size of the toshee is small, but the size of the toshe is very large in the sediment part in the lower part of the valley because the toshee slides along the slope.

Impact loads due to the occurrence of debris can cause considerable damage to the infrastructure in the vicinity of the deposits. However, most of the modeling devices developed to date have been limited to evaluating the flowability of debris flow by free-falling debris flow materials, which are debris flow materials, on the bottom of the rectangular flume of a laboratory plate. That is, the conventional experimental apparatus has a disadvantage in that it can not accurately predict the impact load and the travel distance of the earth rock.

In the actual landslide, the area where the debris flow occurs is not only the straight section but also the various terrain features in which the straight section and the curved section are repeatedly mixed, and the sediment entrainment is increased due to the erosion of the surrounding soil, The amount of soil erosion depends on the soil composition (clay, silt, sand, gravel, etc.)

However, in the existing experimental system, it was not possible to measure and experiment with the amount of sediment flood by reflecting various terrain condition and soil condition. Therefore, systematic approach to sediment flood due to soil sediment and the impact load of soil stone could not be achieved.

In order to solve the above problems, the present invention is an experimental apparatus for grasping and predicting various terrain conditions and the degree of impact of sediments depending on landslides in soil conditions, that is, the moving distance and the amount of impact of sediments.

It is expected that the design conditions and data for establishing the disaster prevention facilities for landslides can be constructed by grasping the influence of landslides under various conditions through the experimental apparatus according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

2 and 3 are a schematic plan view and a side view, respectively, of the apparatus for measuring a landslide levitation amount, and FIG. 4 is a schematic plan view and a side view of the apparatus for measuring a landslide levitation amount according to an embodiment of the present invention. And a cell unit including a bottom plate, a side plate, and a front plate.

The apparatus 100 for measuring a floating sludge deposit according to the present invention includes a float portion 10, a frame portion 20, a plurality of cell portions 30, an impact amount measuring portion 40, and / Respectively.

The float portion 10 is provided to incline slopes or valleys where a landslide occurs and is inclined from the upper side to the lower side. 3, the plumb portion 10 is divided into an upper layer portion 11, an middle layer portion 12 and a lower layer portion 13 so as to reduce the inclination from the upper layer portion 11 to the lower layer portion 13 do.

However, in other embodiments, it may be provided at the same inclination angle from the upper layer portion to the lower layer portion, and the inclination angle may be variously changed according to the experiment condition, for example, the middle layer portion may be installed lower than the lower layer portion.

The length of the plumb portion 10 may vary, but may be as short as 1 to 3 m, but may be as long as about 100 m.

The pleat portion 10 is composed of a bottom portion 15 and both side portions 16 formed upward from both sides of the bottom portion 15 and has an upper surface opened. A plurality of leg portions (19) are provided under the plumb portion (10) to support the plumb portion (10).

Referring to FIG. 2, in the present embodiment, the plumb portion 10 is not arranged in a straight line but takes a curved shape that curves at an intermediate portion. Although the present invention does not exclude that the float portion 10 is formed as a straight line, in a natural environment, a slope is dominant in a curve shape, and therefore, it is formed in a curved shape to reflect this. When the pillar portion 10 has a curved shape, it is easy to grasp the amount of irregularity in the curved region when the gravel body flows down.

A frame portion (20) is provided inside the plum portion (10). The frame portion 20 is for reproducing a terrain such as a valley or a slope in which a landslide occurs in the inside of the plumb portion 10. The section of the slope where the landslide occurs is in various forms such as the letter 'U' shape, 'V' shape. The frame unit 20 reproduces the terrain condition of the slope to be tested using a plurality of frames.

Figs. 5 to 7 are views for explaining the cell portion 30 formed by the frame portion 20 and the frame portion 20. Fig.

Referring to the drawings, the frame portion 20 is composed of a horizontal frame 21, a vertical frame 22, and a height direction frame 23, and is installed over the entire length of the flight portion 10. As shown in Fig. 4, a frame portion 20 in the form of a lattice is formed in the pleat portion 10 by the transverse direction frame 21, the longitudinal direction frame 22 and the height direction frame 23. The front plate 24, the side plate 25 and the bottom plate 26 are coupled between the frames 21, 22 and 23 so as to be able to receive the second lens group s2, (30).

Here, when expressed as the horizontal direction frame 21, the vertical direction frame 22, and the height direction frame 23, the width, length, and height are not limitedly limited to directions orthogonal to each other, It should be understood broadly as the concept of a member acting as a skeleton.

 In general, the cell portion 30 formed by the frames 21, 22, and 23 is formed in a rectangular parallelepiped shape as shown in FIG. 4, so that the expression horizontal, vertical, 5, the cell portion formed on the upper side of the frame portion 20 has various shapes such as a triangular shape, arc shape, and the like. It should be understood that the frames 21, 22, and 23 in the horizontal, vertical, and height directions are arranged so that the cell portions 30 are continuously arranged to form a lattice shape.

Particularly, in the present embodiment, since the plumb portion 10 is formed in a curved shape instead of a straight line, it should be understood that the horizontal direction and the vertical direction are relative directions, not a specific direction. That is, the longitudinal direction of the flume portion 10 (the direction changes because it is a curved shape) is set as the longitudinal direction, the direction perpendicular to the longitudinal direction can be set as the lateral direction, and the height direction can be the gravity direction. Further, the height direction may be set to a direction perpendicular to both the horizontal direction and the vertical direction.

That is, in the present invention, the frame portion 20 should be understood as a skeleton for continuously forming a plurality of cell portions 30 accommodating the second glazing element s2, It is to be interpreted that the frames 21, 22, and 23 are arranged corresponding to the shapes of the various cell portions 30.

The front plate 24, the side plate 25 and the bottom plate 26 are coupled to the frame portion 20 provided in the designed design shape over the entire length of the plumb portion 10, . The cell part (30) is filled with various soil materials such as clay, sand, and gravel by reflecting the soil condition of the test area. Different soil may be accommodated for each cell unit 30, and various sizes of soil may be incorporated into one cell unit 30. The types and sizes of the gravels contained in the cell part 30 are changed according to the experimental conditions.

The front plate 24 and the side plate 25 are composed of a screen plate in which a plurality of holes h are formed so that the gravel can pass through. The size of the hole h can be variously selected for each screen plate. For example, fluid can freely pass through a hole in the screen plate. In addition, when the soil particle size is classified according to the particle size, only the soil particles having a silt size (0.075 mm) or less can be passed through the clay, or only the sand having the sand size (0.075 to 0.4 mm) or the gravel (> 2 mm) Can be set differently.

Since the front plate, the side plate, and the bottom plate coupled to the frame can be replaced, it is possible to vary the hole size of the screen plate or to combine the impermeable plate according to the experimental conditions.

When the landslide test is performed while lowering the first slope body s1 on the upper side of the plumb portion 10 under the rainfall condition using the present measuring apparatus 100, the second slack body s2 inside the cell portion 30 It flows out through the hole h from the cell portion 30 due to the erosion action of the first slug body s1 flowing out through the hole h or descending. In the actual landslide process, the initial amount of the toe slides at the upper portion is very small, but the soil can be moved through the side plate and the front plate of the cell portion 30 in order to reproduce the phenomenon that the size of the bottom portion is increased.

However, in the case of the bottom plate 26, it is made of an impermeable plate through which soil and water can not pass. A load cell (not shown) is installed on the bottom plate 26 to measure the weight of the second lens group s2 accommodated in the cell unit 30. [ That is, the weight of the second glazing member s2 in the cell portion 30 is measured in the initial state, and after the landslide simulation, the second glazing member s2 remaining in the cell portion 30 after the glaze caused by erosion, rainwater, ) Can be measured to determine the change in soil intake.

However, as shown in Fig. 5, the plate coupled to the upper surface of the cell portion 30 disposed at the uppermost position among the plurality of cell portions 30 is provided with a screen plate. That is, since this portion is an area directly contacting the descending first slope body s1, the first slope body s1 and the first slope body s1 can be accurately positioned in order to accurately reflect the erosion action occurring at the time of descending the first slope body s1 A condition must be created such that the second soil body s2 accommodated in the cell portion 30 can be washed away.

On the other hand, in the measuring apparatus 10 according to the present invention, the distance (movement amount) that the debris (sediment) moving from the lower side of the slope is moved and the intensity of the impulse due to the load of the sediment is measured Is an important technical task. The impact of sediment migration and impact on social infrastructure can be grasped.

To this end, the measuring apparatus 10 according to the present invention includes an impact amount measuring unit 40 and / or a movement amount measuring unit.

The impact amount measuring unit 40 is for measuring the amount of impact according to the loads of the first and second bodies s1 and s2 that are discharged through the plumb portion 10. [ For example, it is to measure the amount of impact that will be applied when a landing stone descends along a slope in a Woomyunsan landslide colliding with an apartment and a house.

In the present invention, the blocking plate 41 and the load cell 42 are provided as the impact amount measuring unit 40. The blocking plate 41 is installed below the plumb portion 10. The blocking plate 41 is disposed so as to intersect (preferably perpendicular) with respect to the longitudinal direction of the plumb portion 10, that is, the direction in which the first and second glazing bodies s1 and s2 descend, . A load cell 42 is provided on the back surface of the blocking plate 41 to measure the amount of impact of the goggles and transmits them to a control system such as a controller (not shown).

Also, in the present invention, when it is desired to test the extent of influence of sediments instead of the amount of impact, a movement amount measuring unit may be provided except for the impact amount measuring unit. The moving distance measuring unit is for measuring the moving distance of the sediments. Although not shown, it is possible to measure the distance in the longitudinal direction and the lateral direction by attaching the scale unit in the horizontal and vertical directions on the lower side of the float unit.

Hereinafter, an experimental method using the apparatus 100 for measuring the floating amount of landslide sediment will be briefly described.

For the experiment, firstly, the experimental condition, the inclination angle of the slope where the landslide occurs, the terrain condition forming the slope, the soil condition of the landslide occurrence area, and the rainfall condition are designed.

The inclination angle of the slope is adjusted by adjusting the installation angle of the plumb portion (10), and the frame portion (20) is installed in accordance with the terrain condition. As shown in Figs. 8 and 9, the landslide topography condition may be formed as a letter 'U' character or a letter 'V' in cross section, or may be formed in various curves. After the frame part is formed, the front panel 24 and the side plate 25 are installed. Then, the second glazing body s2 is filled in the cell part 30 according to the soil condition of the landslide occurrence area. In the case where the cell portion 30 is formed of a plurality of layers along the height direction, after the cell portion disposed in the lower layer is filled with the glaze, the bottom plate 26 of the cell portion disposed in the upper layer is bonded, You can fill it.

As described above, after the measurement apparatus 100 according to the present invention is installed, artificial rainfall is applied to the glacier to increase the water content and the pore water pressure of the gypsum. In general, as in the case of rainfall in a natural environment, artificial rainfall is sprayed a plurality of times to increase the water content of the soil body. In this process, each cell 30 continuously measures changes in weight of the soil and water.

The first slope body s1 is lowered on the upper side of the plumb portion 10 with the water content increased at the design level. Experiments may be conducted with artificial rainfall, or artificial rainfall may be excluded.

The first glazing body s1 descends along the plumb portion 10 to erode the second glazing body s2 accommodated in the cell portion 30. [ Also, the second glazing body s2 having increased fluidity due to the rainfall passes through the screen plate and is washed down with the first glazing body s1. More specifically, the second dead bodies s2 housed in the respective cell portions 30 are moved together with the water through the holes h of the screen plate to join the first dead bodies s1.

Particularly, in the portion where the plumb portion 10 is warped, the amount of sinking (scooping) increases, so that the amount of the dirt dropping along the plumb portion 10 can increase sharply. The longer the length of the plumb portion 10, the greater the amount of slugs that slide. The dashed lines shown in Figs. 8 and 9 indicate the appearance of the soil erosion in the cell part by the landslide test.

The first and second glazing bodies s1 and s2 pass through the plumb portion 10 and collide against the shutoff plate 41 of the impact amount measuring section 40. The load cell 42 receives an impact amount or a load Can be measured. When the movement amount measuring unit is provided instead of the impact amount measuring unit, the diffusion distance of the first and second glazing bodies s1 and s2 can be measured.

In the load cell (not shown) provided in each cell 30, the change in the weight of the soil and water in each cell 30 can be measured, and the amount of the soil and water swept along with the occurrence of the earth and stone can be measured.

However, if the fluidity of the soil is increased due to the increase of the water content of the soil in the cell part 30, the float part (s1) A landslide experiment can be started while the second glazing element s2 accommodated in the cell part 30 arranged on the upper side of the screen plate 10 flows out through the hole h of the screen plate.

As described above, according to the present invention, it is possible to reflect the phenomenon that the size of the sediment increases due to the erosion while the slope initially sliding at the time of the landslide descends along the slope, and the distance that the sediment moves after the slope descends By measuring the amount of impact, the extent and extent of damage by landslides can be predicted in advance.

In addition, it is possible to reproduce various landslide terrain conditions by adjusting the shape of the cell part, and soil condition can be reproduced by filling the soil with each cell part. In addition, it is possible not only to reproduce the erosion action by forming the surface portions of the side plate 25, the front plate 24 and the cell portion of the upper layer as screen plates, but also to change the size of the holes And various test conditions can be formed.

According to the measuring apparatus according to the present invention, it is possible to carry out the landslide experiment according to various conditions such as the terrain condition, the soil condition, and the rain condition, and in particular, it is possible to measure the impact amount and the moving distance of the soil. Experimental data obtained through experiments under various conditions are expected to be used as important data for designing facilities to reduce the damage of landslides and determining the scope of evacuation when landslides occur.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation and that those skilled in the art will recognize that various modifications and equivalent arrangements may be made therein. It will be possible. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

100 ... landslide injury measuring device 10 ... float part
11 ... upper layer portion 12 ... middle layer portion
13 ... lower layer portion 15 ... bottom portion
16 ... side face portion 19 ... leg portion
20 ... frame portion 21 ... horizontal frame
22 ... vertical direction frame 23 ... height direction frame
24 ... front plate, 25 ... side plate
26 ... bottom plate 30 ... shelf
40 ... an impact amount measuring part 41 ... a blocking plate
42 ... load cell h ... hole
s1 ... first soil body s2 ... second soil body

Claims (10)

A pillar portion comprising a bottom portion and side portions formed on both sides of the bottom portion, the pillar portion being inclinedly disposed so that the first trough body can be slid;
A frame part in which a plurality of frames are arranged in a lattice pattern in a horizontal direction, a vertical direction and a height direction in the inside of the plume part from the upper part to the lower part of the plume part according to the shape of the predetermined landslide surface;
A side plate, and a front plate, each of which is sandwiched and supported between the plurality of frames arranged in a lattice pattern, Cell portion; And
And an impact amount measuring unit disposed at a lower portion of the plume unit and measuring an impact amount of the first and second slopes sliding through the plume unit. A pillar portion comprising a bottom portion and side portions formed on both sides of the bottom portion, the pillar portion being inclinedly disposed so that the first trough body can be slid;
A frame part in which a plurality of frames are arranged in a lattice pattern in a horizontal direction, a vertical direction and a height direction in the inside of the plume part from the upper part to the lower part of the plume part according to the shape of the predetermined landslide surface;
A side plate, and a front plate, each of which is sandwiched and supported between the plurality of frames arranged in a lattice pattern, Cell portion; And
And a movement amount measuring unit disposed at a lower portion of the plume portion and measuring a moving distance of the first and second gathers slid through the plume portion. 3. The method according to claim 1 or 2,
Wherein the side plate is a screen plate in which a plurality of holes are formed so that the second gravel body can flow out sideways. The method of claim 3,
Wherein the size of the hole is different for each screen plate. The method of claim 3,
Wherein the screen plate is interchangeably coupled to the frame. 3. The method according to claim 1 or 2,
Wherein the bottom plate is impermeable to prevent water from leaking out from the second gravel body. The method according to claim 6,
Further comprising a load cell mounted on the bottom plate so as to measure a load of the second glazing housed in the plurality of cell units. 3. The method according to claim 1 or 2,
And a part of the float part is arranged in a curved shape. The method according to claim 1,
The impact-
A blocking plate disposed on a path of the first and second dunnage slides along the flume and colliding with the first dunnage and the second dunnage;
And a load cell for measuring the amount of impact applied to the blocking plate. 3. The method of claim 2,
The moving-
Wherein the scale portion is a scale portion provided at a lower portion of the plume portion to measure a moving distance and a diffusion distance of the first and second gathers sliding along the flume portion.

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