KR20190060246A - Mobile type steep slope collapse simulation apparatus - Google Patents

Abstract

The present invention relates to a mobile steep slope collapse simulation apparatus, including: a frame in which a wheel is installed and which is movable; a chamber structure installed on the frame to be inclined and tramping soil after the soil fills therein; an artificial rain device installed on the frame and spraying water downwards toward the soil tramped in the soil structure; and a water tank supplying water to the artificial rain device and having the wheel on a floor so as to be movable, thereby providing an advantage of being possible to exactly identifying movement of the soil generated in a steep slope of a real natural environment during rain.

Description

[0001] The present invention relates to a moving type steep slope collapse simulation apparatus,

The present invention relates to a moving type steep slope failure simulator, and more particularly, to a moving steep slope failure simulator capable of accurately analyzing the slope behavior of a steep slope during a rainfall.

In Korea, there are a lot of slopes depending on the geographical features with many mountainous areas. In addition, slope collapse frequently occurs due to the climate characteristic that about two-thirds of the annual average rainfall is concentrated at one time.

Although the collapse of sloping land causes enormous damage to national security and property, the disaster of the slope collapse due to the weather change has been increasing in spite of efforts to reduce the damage caused by it. Due to topographical and climatic characteristics, it is not easy to forecast and prevent slope collapse accidents due to heavy rainfall such as heavy rainfall and typhoon every summer.

In recent years, researches have been conducted to reduce damages to slope collapse by providing a device or system capable of detecting the behavior of slopes on the slope. However, it is difficult to establish an environment similar to the slopes of the natural environment, It is difficult to grasp accurate information about the behavior.

Application No.: 10-2015-0160405 (Registration No.: 10-1688067, entitled "

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a method and apparatus for accurately detecting the behavior of a soil material generated in a steep slope of a natural environment during a rainfall, The present invention provides a mobile steep slope collapse simulation apparatus.

According to another aspect of the present invention, there is provided a moving type steep slope collapse simulation apparatus comprising: a frame having wheels installed therein; A to-be-construed structure provided on the frame so as to be inclined, and filled with soil after being filled therein; A slider that moves along the frame in a state in which the lower side of the to-be-construed structure is supported; An artificial rainfall apparatus installed in the frame and spraying water downward toward the compaction soil within the soil structure; A groundwater replenishing device for spraying water upwards from the bottom of the compaction soil within the soil structure through the bottom surface of the soil structure; And a water tank for supplying water to the artificial rainfall device and the groundwater replenishing device and having a wheel installed on the floor.

Here, the to-be-construed structure may include a first to-be-installed vertically movable on the frame; A second toe having one end thereof pivotally connected to an end of the first toe; A third resonator having one end connected to the other end of the second resonator so as to be rotatable; And a fourth torsion having one end connected to the other end of the third torsion so as to be rotatable.

The first toto is moved vertically by a hydraulic cylinder installed in the frame, and the third to fourth torsion is rotated by a hydraulic cylinder installed to be rotatable on the slider.

In addition, the canopy structure is provided with a transparent window on a side surface thereof.

In addition, a plurality of pipes, each having a discharge hole, are protruded from a bottom surface of the toaster structure so as to be perpendicular to an inclination direction of the toaster structure, and the pipes are connected to the groundwater replenishing device, And discharged through the discharge hole.

In the moving type steep slope collapse simulation apparatus of the present invention constructed as described above, artificial rainfall is sprayed on the slope to reproduce a steep slope so that the behavior of the slope can be easily understood, There is an advantage that the behavior of the soil can be precisely deduced.

In addition, it is possible to minimize the limitation of the space in the experiment by providing the wheels in the frame and the water tank, thereby making it possible to carry out experiments easily in a narrow place when the size is made small There is an advantage.

In addition, since the angle of the soil structure can be freely adjusted, there is an advantage that the collapse experiment can be performed on slopes having various angles.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1A and FIG. 1B are perspective views of a portable steep slope collapse simulator according to the present invention.
FIG. 2A and FIG. 2B are views showing a state in which the angular constriction angle of the moving type steep slope collapse simulation apparatus shown in FIG. 1 is changed.
FIG. 3 is a view showing a state in which the sandstone is filled in the sandstone structure of the moving type steep slope collapse simulator according to the present invention. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of a moving type steep slope collapse simulation apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

FIGS. 1A and 1B are perspective views of a moving type steep slope collapse simulation apparatus according to the present invention, and FIGS. 2A and 2B are views showing a change in angle of a toe structure of the moving type steep slope collapse simulation apparatus shown in FIG. And FIG. 3 is a view showing a state in which the geosyge structure of the moving type steep slope collapse simulation apparatus according to the present invention is filled with gravel.

A moving type steep slope collapse simulation apparatus according to the present invention includes a frame 10, a tiller structure 20 provided on the frame 10, a slider 30 provided on the frame 10, An artificial rainfall apparatus 40 installed on the upper side of the earthquake-proof structure 20, a groundwater recycling apparatus 50 for supplying water into the soil structure 20 through the bottom surface of the earthquake- And a water tank (60) for supplying water to the groundwater replenishing device (40) and the groundwater replenishing device (50).

The frame 10 is fabricated by combining a plurality of steel beams or the like and supports most of the components except for the water tray 60. The frame 10 is provided with a wheel 11 so as to be movable.

One side of the structure 10 is connected to the upper side of the frame 10 and the other side of the structure 10 is positioned on the bottom side of the frame 10 so as to be inclined to the frame 10.

The canopy structure 20 has a transparent window 21 on its side and a plurality of pipes 22 on its bottom.

The transparent window 21 is made of polycarbonate so as to be able to identify the inside of the toaster structure 20. The inside of the toaster structure 20 is used to stably install various measuring equipment and to observe the experimental procedure, And the like.

Each of the tubes 22 is protruded from the bottom surface of the tiller 20 so as to be perpendicular to the tilting direction of the tiller 20. Each of the pipes 22 forms a roughness with respect to the bottom surface of the sloped soil structure 20 so as to simulate the natural condition and prevent the slip of the soil.

The toaster structure 20 includes a first toast 23, a second toast 24 connected to the first toast 23, a second toast 24 connected to the first toast 23, A third tozo 25 connected to the tozo 24 and a fourth tozo 26 connected to the third tozo 25.

The first resonator 23 is installed on the side surface of the frame 10 so as to be movable up and down. The first toothed wheel 23 is moved up and down by a hydraulic cylinder C provided in the frame 10. [

One end of the second resonator 24 is rotatably connected to the end of the first resonator 23. The lower end of the first resonator 23 and the upper end of the second resonator 24 are pin-coupled to change the inclination angle of the first resonator 23 in accordance with the upward and downward movement.

One end of the third resonator 25 is rotatably connected to the other end of the second resonator 24. The lower end of the second toothing 24 is pin-engaged with the upper end of the third toothing 25 so that the third toothing 25 rotates in accordance with the change of the inclination angle of the second toothing. The third toothed wheel 25 is rotated by the hydraulic cylinder C provided on the slider 30, and the inclination angle of the third toothed wheel 25 is adjusted.

One end of the fourth resonator 26 is rotatably connected to the other end of the third resonator 25. The lower end of the third toothing 25 is pin-engaged with the upper end of the fourth toothing 26 so that the fourth toothing 26 is rotated in accordance with the change of the inclination angle of the third toothing. The fourth toothed wheel 26 is rotated by the hydraulic cylinder C provided on the slider 30, and its inclination angle is adjusted.

A door 26a is installed at the other end of the fourth toast 26. The door 26a is closed when filling the inside of the toaster structure 20 with the soil and compaction And after the collapse simulation is completed, it is opened.

Between the first to fourth tanks 23 and 24 and between the second to fourth tumblers 24 and 25 and between the third to fourth tumblers 25 and 26, A spring steel plate 27 made of a steel plate is installed to prevent the soil from leaking out.

The slider 30 slides along the frame 10 while supporting the lower side of the toaster structure 20. The slider 30 is provided with a hydraulic cylinder C for adjusting the inclination angles of the third to fourth tongs 25 and 26 on the upper surface thereof, A pivot 31 is provided on the upper surface so as to move forward or backward along the longitudinal direction of the frame 10 in this state. This slider 30 corresponds to the forward and backward movement in accordance with the change of the inclination angle of the toaster structure 20.

The artificial rainfall apparatus 40 includes a plurality of nozzles for spraying water. The artificial rainfall apparatus 40 is installed in the frame 10 to spray water downward toward the compaction soil within the soil structure 20. [

The groundwater replenishing device 50 injects water upward from below the compaction soil within the soil structure 20 through the bottom surface of the soil structure 20. [ In other words, the groundwater reproducing apparatus 50 has one side penetrating the bottom surface of the toaster structure 20, and the penetrating portion is connected to the bottom surface of the toaster structure 20. At this time, discharge holes 22a are formed in the respective pipes 22 at predetermined intervals, and the water supplied from the groundwater replenishing device 50 is discharged through the discharge holes 22a. Accordingly, the water supplied from the lower side of the compaction soil within the soil structure 20 serves as groundwater.

The water tank 60 supplies water to the artificial rainfall apparatus 40 and the groundwater replenishing apparatus 50. The water tank 60 is provided with a wheel 61 on the floor and is movable. Therefore, the water tray 60 not provided in the frame 10 is moved separately from the frame 10.

The controller 70 is installed in the frame 10 to automatically control the hydraulic cylinder C, the artificial rainfall apparatus 40 and the groundwater reproducing apparatus 50, Adjust the simulation conditions, the angle of the steep slope, and the pressure of the hydraulic pressure.

In addition, the present invention further comprises a soil material storage device (not shown) capable of collecting and storing various types of soil material. Soil storage equipment is equipped with constant temperature and humidity function, so that it can be stored in optimum conditions.

10: Frame 11: Wheel
20: constriction 21: transparent window
22: Each pipe 23: First tojo
24: second tozo 25: third tozo
26: Fourth toe 26a: Door
27: steel plate member 30: slider
31: District 40: Artificial rainfall device
50: Groundwater reproducing device 60: Water tank
61: wheel 70: controller
C: Cylinder

Claims (7)

A frame (10) on which a wheel (11) is installed and movable;
A to-be-construed structure 20 inclined to the frame 10 and filled therein with the gravel after compaction;
An artificial rainfall apparatus 40 installed in the frame 10 for spraying water downward toward the compaction soil within the soil structure 20;
And a water tank (60) capable of supplying water to the artificial rainfall apparatus (40) and having a wheel (61) installed on the floor.
The method according to claim 1,
And a groundwater replenishing device (50) for spraying the water supplied to the water tank (60) upward through the bottom surface of the soil water tank structure (20) from below the compaction soil in the soil water tank structure A moving type steep slope failure simulator.
The method according to claim 1,
Wherein the frame (10) is provided with a slider (30) that moves along the frame (10) in a state of supporting the lower side of the toaster structure (20).
The method of claim 3,
The toaster structure 20 includes a first toothing 23 installed on the frame 10 so as to be movable up and down;
A second resonator 24 having one end connected to the end of the first resonator 23 so as to be rotatable;
A third resonator 25 having one end connected rotatably to the other end of the second resonator 24;
And a fourth torsion (26) rotatably connected to the other end of the third torsion (25) at one end of the third torsion (25).
The method of claim 4,
The first toothed wheel 23 moves up and down by a hydraulic cylinder C provided in the frame 10,
Wherein the third torsion bar (25) and the fourth torsion bar (26) are pivoted by a hydraulic cylinder (C) rotatably mounted on the slider (30).
The method according to claim 1,
Wherein the toaster structure (20) is provided with a transparent window (21) on a side surface thereof.
The method of claim 2,
A plurality of pipes 22 each having a discharge hole 22a formed on the bottom surface of the toh-sher structure 20 are protruded so as to be perpendicular to the oblique direction of the to-be constricting body 20,
Wherein the each pipe (22) is connected to the underground water reproducing device (50) and discharges the water supplied from the ground water reproducing device (50) through the discharge hole (22a).

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