KR101174906B1 - Shear Test Apparatus for soil - Google Patents

Abstract

The present invention relates to a soil shear test apparatus that can determine the shear strength of forest soil, the soil is filled with a soil filling box, a seating plate extending in a horizontal direction in a horizontal direction from the open upper edge of the soil filling box, A frame having a pair of guide rails provided to face each other on an upper surface of the seating plate; A transfer plate disposed on an upper surface of the seating plate so that the soil is filled with a shear box connected to an open upper portion of the soil filling box so as to slide in a horizontal direction along the pair of guide rails; A one-side shear test unit having a first driving motor connected to one side of the transfer plate and a first load cell to slide the seat plate; And a simple shear test part disposed on the seating plate and connected to both side plates of the shear box via a second load cell, and having a second driving motor for rotating both side plates in left and right directions. The one-sided shear or simple shearing shear test is added to the soil through the one-sided shear test unit and the simple shear test unit, respectively, characterized in that it is performed individually or simultaneously.

Description

Soil Shear Test Apparatus {Shear Test Apparatus for soil}

The present invention relates to a soil shear test apparatus that can determine the shear strength of forest soil, and more particularly, one-side shear or simple shear simultaneously by sharing a shear box filled with soil similar to the actual forest soil The present invention relates to a soil shear test apparatus capable of accurately testing and evaluating the physical characteristics of forest soils that are actually operated in the field.

In order to analyze the mechanism of landslides occurring on mountain slopes, soil samples are taken from mountain areas, etc., and various soil properties are measured using shearing devices to measure soil strength in forest soils and to strengthen soil roots in tree root systems. The mechanism is being identified.

As described above, in order to measure soil strength in forest soil, a shear shear test and a force generated in a transverse direction, which measure shear force generated between layers stacked vertically and vertically, as shown in FIG. Simple shear test is performed to measure the amount of deformation caused.

Soil shear test apparatus for measuring the shear strength of the soil generated during single-sided shear or simple shearing can test only one-sided shearing or simple shearing individually, but can simultaneously perform one-sided shearing and simple shearing on soil. There is no device.

In order to confirm the exact shear strength of the forest soil, it is very important to check the shear strength applied to the soil in the environment where the single shear and simple shear are applied as well as the individual shear and simple shear. This is required.

The present invention is to solve the above problems, and to provide a soil shear test apparatus that can perform one-side shear test and simple shear test individually or simultaneously by sharing one shear box.

In order to achieve the above object, the present invention provides a soil-filling box filled with soil, a seating plate extending in a horizontal direction in a horizontal direction from an open upper edge of the soil-filling box, and facing each other on an upper surface of the seating plate. A frame having a pair of guide rails provided to be provided; A transfer plate disposed on an upper surface of the seating plate so that the soil is filled with a shear box connected to an open upper portion of the soil filling box so as to slide in a horizontal direction along the pair of guide rails; A one-side shear test unit having a first driving motor connected to one side of the transfer plate and a first load cell to slide the seat plate; And a simple shear test part disposed on the seating plate and connected to both side plates of the shear box via a second load cell, and having a second driving motor for rotating both side plates in left and right directions. The one-sided shear or simple shearing shear test is added to the soil through the one-sided shear test unit and the simple shear test unit, respectively, characterized in that it is performed individually or simultaneously.

Preferably, the control unit for outputting the operation signal to the first drive motor and the second drive motor and analyzing the signals input from the first load cell and the second load cell to calculate the shear force added to the soil filled in the shear box It may be further included.

Preferably, both side plates of the shear box may be connected to the seating plate via a hinge to allow left and right rotation by the second driving motor, and may be simultaneously connected to each other via a link unit. .

Preferably, the shear box is provided with a cover plate at an upper portion open to apply vertical stress to the soil filled therein, the vertical stress portion formed in the link structure is connected to the third drive motor, while the vertical stress portion is third It may be connected in a vertical direction with the cover plate via a load cell.

Preferably, the soil filling box is connected to the water supply means through the first tube may be supplied water to the soil filled therein.

Preferably, the soil filling box is connected to the manometer through the second tube to determine whether the water supplied from the water supply means is in the flow state or equilibrium in the soil.

Preferably, after inserting the root or the mock root system of the vegetation in the shear box can be measured by the pull out test for the root or mock root system of the vegetation.

According to the present invention as described above, by sharing a single shear box, the single shear test and the simple shear test can be performed individually or simultaneously to measure and analyze the exact shear strength applied to the actual forest soil.

1 is a conceptual diagram showing a simple shear and one-sided shear
Figure 2 is a schematic diagram showing the overall configuration of the soil shear test apparatus according to the present invention.
3 is a perspective view showing a soil shear test apparatus applied to FIG.
Figure 4 is a plan view of Figure 3;
5 is a cross-sectional view of FIG. 3.
6 is a longitudinal cross-sectional view of FIG.
7 is a view showing a manometer applied to FIG.
8 is a view showing a mobile drawing tester applied to FIG.
9 is a view showing a state in which FIG. 8 is applied to FIG.

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

In order to facilitate understanding of the present invention, the same reference numerals will be used to denote the same constituent elements even if they are shown in different drawings.

Soil shear test apparatus 100 according to a preferred embodiment of the present invention, as shown in Figures 2 to 6, sharing a single shear box 130 filled with soil to simultaneously perform one-side shear test and simple shear test Or to be performed separately, the frame 110, one-side shear test unit, a simple shear test unit and the control unit 200.

The frame 110 is a place where the one-side shear test unit and the simple shear test unit is installed, as shown in Figures 3 to 6, the interior space is formed inside the soil is filled with soil for the shear test The box 112 is provided.

That is, in the center region of the frame 110 is provided with a soil filling box 112 of the upper body is open and the lower surface is sealed enclosure shape to fill the soil required for the shear test through the open upper surface. It is.

On the other hand, the soil filling box 112 is arranged so that the open upper side as shown in Figure 5 and 6 protrudes a predetermined height from the upper surface of the frame 110, the lower portion into the interior of the frame 110 The side is arranged to extend a certain length.

Then, the seating plate 114 is provided to extend a predetermined length in the horizontal direction from the open upper edge of the soil filling box 112.

A pair of guide rails 116 are provided on the upper surface of the seating plate 114 to allow the one-side shear test part to move horizontally along the pair of guide rails 116.

In this case, as shown in Figure 2, the soil filling box 112 may be connected to the water supply means 300 and the manometer 400 via the first, second tube (118a, 118b).

That is, the water supply means 300 supplies water to the soil filled in the soil filling box 112 to maintain the moisture conditions of the soil constant by the moisture of the soil filled in the soil filling box 112 of the shear tester The content can be adjusted to the actual water content of the forest soil.

In addition, by adjusting the height of the lower end on which the water supply means 300 is placed to adjust the water level supplied into the soil filling box 112 of the soil filled in the soil filling box 112 to obtain data By adjusting the moisture content, it is possible to measure the shear stress generated in the soil under various moisture conditions.

Then, the soil filling box 112 is connected to the manometer 400 via the second tube 118b to supply the moisture to the soil filling box 112 by the water supply means 300, It is possible to check whether the water supplied from the soil filled in the soil filling box 112 is in a flow state or an equilibrium state.

This means that the water supplied to the soil filling box 112 through the water supply means 300 flows in the soil for a predetermined time, and when the measurement is made in a state in which the water flows in the soil, accurate experimental results are not obtained. Because.

Such a manometer 400 has a structure in which a plurality of hollow tubes 420 connected to the second tube 118b are vertically disposed on one surface of the body 410 as shown in FIG. 7. When the water level of the water filled in the tube 420 is the same can be confirmed that the equilibrium state without the flow of water in the soil filled in the soil filling box (112).

The one-side shear test part is installed on the upper surface of the seating plate 114 to measure the shear stress in the horizontal direction generated when moving along the guide rail 116, the transfer plate 122, the first The load cell 124, the shear box 130 and the first drive motor 126 is composed of.

The transfer plate 122 is provided with a shear box 130 of a predetermined height in communication with the soil filling box 112 in the center area is filled with the soil to be tested, coupled with the pair of guide rails 116 It is connected via the part 123 to allow the driving force to move along the guide rail 116.

In addition, one side of the transfer plate 122 is connected to the first driving motor 126 seated and installed on the upper surface of the frame 110 via the first load cell 124 to the first driving motor 126. To be moved along the guide rail 116 by the driving force added during the operation of.

The first load cell 124 connects the first drive motor 126 and the transfer plate 122 to each other, and the load added from the first drive motor 126-more specifically, is added in the horizontal direction. Shear stress is to measure the one-side shear strength generated in the soil filled in the shear box 130.

The first load cell 124 and the first driving motor 126 are provided to measure the shear strength of one side of the soil filled in the shear box 130, and electrically connected to the controller 200 via a cable. The measured data and signals are transmitted to the controller 200.

On the other hand, the shear box 130 is composed of a front plate 131, a rear plate 132 and both side plates 133 so that the upper portion is opened to a central area of the transfer plate 122 and have a predetermined height.

That is, the front plate 131, the rear plate 132 and both side plate 133 is formed by the upper and lower portions of the inner space (S ₂ ) to open the soil is filled through the open top and the bottom of the soil filling box Connected with the open top of the 112 to allow the soil to be continuously filled from the bottom surface of the soil filling box 112 to the top surface of the shear box 130.

In other words, the inner space (S ₁ , S ₂ ) of the shear box 130 and the soil filling box 112 is connected to each other so that the soil filled in the shear box 130 and the soil filling box 112 is It is to be filled continuously without being separated from each other.

Therefore, the driving force is transmitted through the first driving motor 126 to move the transfer plate 122 in the horizontal direction to apply shear stress to the soil filled in the shear box 130.

At this time, the front plate 131 and the rear plate 132 of the shear box 130 is installed to be fixed to the transfer plate 122, while the side plate 133 is hinged to the lower end to the transfer plate 122 142 is connected via a media so that the upper portion can be rotated in the left and right directions about the hinge 142.

In addition, the side plates 133 are connected to each other by a link unit 144 formed in a link structure so that both side plates 133 may be integrally operated even when a load is applied from one side thereof, so that both side plates 133 are loaded. Try to rotate at the same time.

Both side plates 133 integrally behaved by the link unit 144 may include a second driving motor 146 and a second load cell having one side of the link unit 144 provided on one side of the transfer plate 122. 148 is connected to the left and right directions about the hinge 142 by the driving force added during the operation of the second drive motor 146.

That is, when a load is added by the second driving motor 146, both side plates 133 of the shear box 130 are operated in the shape of "//" in the shape of "?".

As described above, both side plates 133 of the shear box 130 are connected to the second driving motor 146 via the second load cell 148 to constitute a simple shear test unit, thereby providing a shear test apparatus 100 according to the present invention. ) Can be measured individually through one tester as well as one-side shear applied to the soil by using the same shear box 130.

In addition, the simple shear test unit is installed on the transfer plate 122 of the one-side shear test unit to transfer the transfer plate 122 through the first drive motor 126 to apply a simple shear and at the same time the second drive motor 146 By allowing both side plates 133 to pivot, the information on the one-side shear and the simple shear is simultaneously applied to the soil.

The second load cell 148 connects the second driving motor 146 and the link unit 144 to each other, and the load added from the second driving motor 146-more specifically, is added in the horizontal direction. Simple shear strength generated in the soil filled in the shear box 130 by the shear stress is measured.

The second load cell 148 and the second driving motor 146 are provided to measure the simple shear strength of the soil filled in the shear box 130, and electrically connected to the control unit 200 via a cable. The measured data and signals are transmitted to the controller 200.

On the other hand, the soil shear test apparatus 100 of the present invention is provided with a cover plate 134 covering the open upper surface of the shear box 130 during one-side shear test and simple shear test.

The cover plate 134 is connected to the vertical stress unit 150 through the third load cell 154 to apply vertical stress to the soil side filled in the shear box 130.

In this case, the vertical stress unit 150 is formed in a link structure so as to be connected to the third driving motor 152 installed in the frame 110, and is operated vertically by the third driving motor. The upper portion of the cover plate 134 is pressed.

This is to create the same conditions as the soil located in the deep layer portion as well as the surface layer of the mountain in the actual forest by transferring the load in the direction perpendicular to the soil filled in the shear box 130.

Therefore, the soil shear test apparatus 100 of the present invention is able to accurately measure the shear strength generated in the soil located in the deep portion of the mountain as well as the surface layer.

As described above, the control unit 200 operates by driving the first and second driving motors 126 and 146 or analyzes the signals measured by the first and second load cells 124 and 148 and is filled in the shear box 130. To calculate the shear force added to the soil, as shown in Figure 1 is composed of a data logger 210 and a computer 220.

The data logger 210 is electrically connected to the first, second, and third driving motors 126, 146, 152 and the first, second, and third load cells 124, 148, 154, and various operation panels are provided to drive the first, second, and third drives. When driving the motors 126, 146, 152, the appropriate stresses satisfying the conditions to be tested are added to the soil side filled in the shear box 130, and various data measured by the first, second, and third load cells 124, 148, 154 are collected. After that, it is delivered to the computer 220.

In addition, the computer 220 is installed with a program that can analyze the data to analyze the data transmitted from the data logger 210 so that the user can easily identify the shear strength generated in the soil under various conditions on the screen To help.

On the other hand, the soil shear test apparatus 100 of the present invention is provided with a separate mobile drawing tester 500 as shown in Figure 8 may measure the pull tension acting on the root or mock root system of vegetation.

At this time, the cover plate 134 covering the open top of the shear box 130 is formed with an insertion hole 135 to insert the root or mock root system of vegetation.

That is, the drawing tester 500 is provided with a drawing frame 110 is provided with a moving means 512 such as a wheel at the bottom, the fourth driving motor 520 is installed on the upper side of the drawing frame 110 And a gripping part 530 operated by the fourth driving motor 520 to connect the gripping part 530 and the fourth driving motor 520 to the fourth load cell 540.

Meanwhile, the fourth driving motor 520 and the fourth load cell 540 are also connected to the controller 200 via a cable.

The drawing test machine 500 is located in the shear box 130 of the present invention to measure the root or mock root system of the vegetation to be measured in the shear box generated in the root or mock root system of the vegetation and filling the soil By operating the four-drive motor 520 to lift the roots or roots of the vegetation through the gripping portion 530 to measure the pull tension of the roots or roots.

Thus, the soil shear test apparatus 100 of the present invention, as shown in Figure 9, when the pull-out test of the root is required to move the drawing frame 110 so that the gripping portion 530 of the shear box 130 By being located on the upper side, the shear box 130 of the present invention used for the one-side shear test and the simple shear test can be easily shared by simply testing.

Hereinafter, the use process of the soil shear test apparatus 100 according to the present invention will be described.

First, after filling the soil in the shear box 130 and the soil filling box 112 covers the open top with a cover plate 134.

Thereafter, the water supply means 300 supplies water to the soil filling box 112 through the first tube 118a, checks the water level in the manometer 400, and the water flows in the soil. Check whether it is or is in equilibrium.

When the moisture of the soil is in equilibrium, the third driving motor 152 is operated to apply vertical stress to the cover plate 134 through the vertical stress unit 150.

In this state, by operating the control panel provided in the data logger 210 by applying a shear stress to the soil filled in the shear box 130 to measure the shear strength of the soil.

That is, when the one-side shear test is to be performed, the shear box 130 is moved by moving the transfer plate 122 by operating the first driving motor 126 to slide the transfer plate 122 in the horizontal direction. The soil filled in it is subjected to one-sided shear stress in the horizontal direction.

At this time, the data measured in the first load cell 124 is transmitted to the data logger 210 and the computer 220 so that the user is shear shear strength of the soil generated during simple shearing in the soil filled in the shear box 130 You can check.

When the simple shear test is to be performed, the second drive motor 146 is operated to rotate both side plates 133 of the shear box 130 in the "//" direction or the "＼＼" direction. Soil filled in the box 130 is subjected to a simple shear stress.

This simple shear stress is measured through the second load cell 148 and then transmitted to the data logger 210 and the computer 220 so that the user is generated when one side shear in the soil filled in the shear box 130 The shear strength of the soil can be checked.

On the other hand, if you want to check the shear strength when the one-side shear and simple shear is simultaneously operated in the soil filled in the shear box 130, as described above the first drive motor 126 and the second drive motor ( By 146) to operate at the same time through the above-described process the user can check the shear strength generated in the soil.

And, if you want to do a drawing test, the roots or mock root system of vegetation is placed in the shear box 130 and the soil is filled, the roots or mock root system of vegetation inserted into the shear box 130 the gripping portion The mobile drawing tester 500 is moved to be gripped at 530.

Thereafter, the water supply means 300 supplies water to the soil filling box 112 through the first tube 118a, checks the water level in the manometer 400, and the water flows in the soil. Check whether it is or is in equilibrium.

When the moisture of the soil is in equilibrium, the third driving motor 152 is operated to apply vertical stress to the cover plate 134 through the vertical stress unit 150.

In this state, by operating the control panel provided in the data logger 210, the fourth driving motor 520 is operated by operating the vegetation root or the simulation root inserted into the shear box 130 to hold the gripper 530. By adding the pulling force to the root or mock root system side of the vegetation planted through the fourth load cell 540 to collect data to measure the pull tension.

According to the present invention as described above by sharing a single shear box 130, by performing the single-sided shear test and simple shear test individually or at the same time has the effect of measuring and analyzing the exact shear strength applied to the actual forest soil have.

In addition, by having a separate mobile drawing tester 500 to share the shear box 130 used for the simple shear test and one-sided shear test has the advantage that can facilitate the drawing test of the root or mock root system of the vegetation.

Furthermore, the shear strength generated in the soil under various conditions by controlling the moisture of the soil to be tested by connecting the soil filling box 112 with the water supply means 300 and the manometer 400 via the first and second tubes. There is an effect that can be easily measured.

Although specific embodiments of the present invention have been described above in detail with reference to the drawings, the present invention is not limited to such specific structures. Those skilled in the art will be able to easily modify or change without departing from the scope of the following claims. However, all such simple design variations or modifications are clearly disclosed in advance within the scope of the present invention.

100: shear test device 110: frame
112: soil filling box 114: seating plate
116: guide rail 118a, 118b: first and second tube
122: transfer plate 123: coupling portion
124: first load cell 126: first drive motor
130: shear box 131: electric board
132: thick plate 133: side plate
134: cover plate 135: insertion hole
142: hinge 144: link unit
146: second drive motor 148: second load cell
150: vertical stress unit 152: third drive motor
154: third load cell 200: control unit
210: data logger 220: computer
300: water supply means 400: manometer
410: body 420: tube
500: mobile drawing tester 510: drawing frame
512: means of movement 520: fourth drive motor
530: gripper 540: fourth load cell

Claims (7)

Soil is filled with a soil filling box, a seating plate extending a predetermined length in the horizontal direction from the open upper edge of the soil filling box, and a pair of guide rails provided to face each other on the upper surface of the seating plate is provided frame;
A transfer plate disposed on an upper surface of the seating plate so that the soil is filled with a shear box connected to an open upper portion of the soil filling box so as to slide in a horizontal direction along the pair of guide rails; A one-side shear test unit having a first driving motor connected to one side of the transfer plate and a first load cell to slide the seat plate; And
And a simple shear test part disposed on the seating plate and connected to both side plates of the shear box via a second load cell, and having a second driving motor for rotating both side plates in left and right directions.
Soil shear test apparatus, characterized in that the one-side shear or simple shear test to be added to the soil through the one-side shear test section and the simple shear test section are performed individually or simultaneously. The method of claim 1,
The controller may further include a control unit configured to output an operation signal to the first driving motor and the second driving motor, and to analyze the signals input from the first load cell and the second load cell to calculate shear force added to the soil filled in the shear box. Soil shear test apparatus characterized in that. The method of claim 1,
Both side plates of the shear box are connected to the seating plate via a hinge to allow left and right rotation by the second driving motor, while the soil shear is connected to each other via a link unit so as to be rotated at the same time. Test equipment. The method of claim 1,
The shear box is provided with a cover plate to apply vertical stress to the soil filled therein, the vertical stress formed in the link structure is connected to the third drive motor, while the vertical stress is connected to the cover plate via the third load cell Soil shear test apparatus characterized in that connected in the vertical direction. The method of claim 1,
The soil filling box is connected to the water supply means through the first tube soil shear test apparatus, characterized in that the water supplied to the soil filled inside. 6. The method of claim 5,
The soil filling box is connected to the manometer via a second tube soil shear test apparatus, characterized in that to check whether the water supplied from the water supply means flow or equilibrium in the soil. 7. The method according to any one of claims 1 to 6,
Soil shear test apparatus, characterized in that for inserting the root or mock root system of the vegetation in the shear box and measuring the pull force to the root or mock root system of the vegetation through a mobile pull tester.

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