Embeddable seepage module capable of being embedded into interface ring shear apparatus considering soil erosion

11125,667

16/507963

July 10, 2019

An embeddable seepage module capable of being embedded into an interface ring shear apparatus is disclosed, wherein: the seepage module includes an annular cylinder, a seepage pressure regulation system, a top plate and a bottom plate; the interface ring shear apparatus includes an upper shear box and a lower shear box; the annular cylinder, the top plate, the bottom plate, the upper shear box and the lower shear box form an internal pressure cavity and an external pressure cavity; the internal pressure cavity is able to realize the precise double control of the soil seepage pressure and water flow through the seepage pressure regulation system; the external pressure cavity is able to collect fine soil particles under pressure seepage. In the case of soil seepage-shear coupling, the seepage module is assembled firstly for seepage, and after completing the seepage, the external pressure cavity is removed for ring shear tests.

ZHEJIANG UNIVERSITY (Zhejiang, CN)

ZHEJIANG UNIVERSITY (Zhejiang, CN)

1. An embeddable seepage module capable of being embedded into an interface ring shear apparatus considering soil erosion, wherein: the interface ring shear apparatus comprises an upper shear box (13) and a lower shear box (14); an inner wall and an outer wall of the upper shear box (13) are made from a porous material; the seepage module comprises an annular cylinder (17), a seepage pressure regulation system (9), a top plate (15), a bottom plate (16), a water intake pipeline (3), a water discharge pipeline (4), a first valve (5), a second valve (6), a sedimentation tank (7), a filter screen (8), a water pressure sensor (10), an electromagnetic flowmeter (11) and a pore pressure sensor (12); when the seepage module is embedded into the interface ring shear apparatus, the annular cylinder (17) is arranged outside the upper and lower shear boxes, the top plate (15) is provided at a top of an inner wall of the upper shear box (13), the bottom its plate (16) is provided at a bottom of an inner wall of the lower shear box (14), in such a manner that the top plate (15), the bottom plate (16), the inner wall of the upper shear box (13) and the inner wall of the lower shear box (14) form a sealed internal pressure cavity (1); the annular cylinder (17), an outer wall of the upper shear box (13) and an outer wall of the lower shear box (14) form a sealed external pressure cavity (2); the internal pressure cavity (1) is connected with the seepage pressure regulation system (9) through the water intake pipeline (3); the water pressure sensor (10), the electromagnetic flowmeter (11) and the first valve (5) are located on the water intake pipeline (3); the external pressure cavity (2) is connected with the seepage pressure regulation system (9) through the water discharge pipeline (4); the second valve (6), the sedimentation tank (7) and the filter screen (8) are located on the water discharge pipeline (4); the pore pressure sensor (12) is located at the outer wall of the upper shear box (13) to monitor a pore pressure of soil.

2. The embeddable seepage module, as recited in claim 1 , wherein: the inner wall and the outer wall of the lower shear box (14), the top plate (15) and the bottom plate (16) are made from stainless steel.

3. The embeddable seepage module, as recited in claim 1 , wherein: the annular cylinder (17) comprises two semicircular cylinders conjoined with each other; for sealing, water-stops (19) are located at joints of the two semicircular cylinders, of the annular cylinder (17) and the upper shear box (13), and of the annular cylinder (17) and the lower shear box (14).

4. The embeddable seepage module, as recited in claim 3 , wherein: the water-stops (19) are made from rubber, multiple ribs each of which has a square cross section are located on a surface of each of the water-stops (19) and evenly spaced from each other; the water-stops (19) at the joints of the two semicircular cylinders are in a shape of groove and the water-stops (19) at the joints of the annular cylinder and the annular upper shear box (13), and of the annular cylinder (17) and the lower shear box (14) are in a shape of circular.

5. The embeddable seepage module, as recited in claim 1 , wherein: the top plate (15) is sealed with the inner wall of the upper shear box (13) through welding, and the bottom plate (16) is sealed with the inner wall of lower shear box (14) through welding.

6. The embeddable seepage module, as recited in claim 1 , wherein: the water intake pipeline (3) is communicated with the internal pressure cavity (1) at a center of the top plate (15).

7. The embeddable seepage module, as recited in claim 1 , wherein: a probe of the pore pressure sensor (12) is located in the upper shear box (13), and the pore pressure sensor (12) passes through the annular cylinder (17) for reading to monitor the pore pressure of the soil.

8. The embeddable seepage module, as recited in claim 1 , wherein: the bottom plate (16) has a drainage hole (20) which is closed when seeping and is opened after seepage for discharging water.

9. The embeddable seepage module, as recited in claim 1 , wherein: a set of standard sieves are placed in the sedimentation tank (7) to quantify a soil erosion amount, whose sieve diameters are respectively 10 mm, 5 mm, 2 mm, 1 mm, 0.5 mm, 0.25 mm, 0.1 mm and 0.075 mm from top to bottom in order to quantify the soil erosion amount.

10. The embeddable seepage module, as recited in claim 1 , wherein: four pairs of bending elements (23) are uniformly arranged along a circumferential direction of the inner wall of a middle part of the upper shear box (13) to test a shear modulus of sand before and after a seepage-shear coupling action; twelve soil pressure sensors (22) are respectively uniformly arranged along the circumferential direction of the inner wall of an upper, the middle and a bottom part of the upper shear box (13) to test a soil pressure and a distribution along a depth before and after the seepage-shear coupling action; the four soil pressure sensors arranged along the circumferential direction of the inner wall of the middle part of the upper shear box (13) and the four pairs of bending elements are uniformly alternately distributed along the circumferential direction of the inner wall of the upper shear box (13).

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