KR100978468B1 - Reinforced massive soil body making use of arching effect and method constructing by it - Google Patents

Abstract

PURPOSE: A self-supported earth retaining wall structure using an arching effect and an excavating method using the same are provided to efficiently resist earth pressure and to easily perform an excavating work even in a narrow space. CONSTITUTION: A self-supported earth retaining wall structure using an arching effect is composed as follows. H-piles with longitudinal H-pile insertion parts are vertically installed in the ground at B intervals. The H-piles insertion parts are connected by inserting sheet panel protruded parts. The sheet panel protruded parts are inserted into sheet panel insertion parts. The sheet panel insertion parts are coupled by inserting compression support plate protruded parts.

Description

Reinforced massive soil body making use of arching effect and method constructing by it}

The present invention relates to a reinforced self-supporting earth retaining structure using an arching effect and an underground excavation construction method using the same. More specifically, the present invention relates to supporting a self-supporting earth retaining structure formed by the arching effect of the backing earth pressure caused by vertical excavation. will be.

Reinforced self-supporting earth retaining structure using the arching effect is installed in the back of the excavation space, so it does not interfere with the excavation work, so the excavation work is efficient. Therefore, it is not only possible to form a self-supporting soil structure, but also a new concept for continuous sheet walls because the self-weight of the self-supporting structure supports the back soil pressure.

The present invention does not interfere with the excavation work because the reinforced self-supporting earth retaining structure is installed behind the excavation space, so the excavation space is wide, and the excavation work is easy and efficient in the small space in the downtown where the high-rise buildings are concentrated.

The upper and lower fasteners firmly fix the joints of the seat panel to form a composite cross section, which not only increases rigidity, but also makes the fastening and dismantling easy because of the simple structure of the upper and lower fasteners. It is easy.

Existing tentative earthquake construction method to prevent the collapse of excavated back soil during excavation work for underground structure construction is a method of reinforcing the insufficient support capacity of thumb pile against excavated back ground pressure with external force.

Typical methods for this are the strut method and the sheet-pile method.

A) Strut method

The strut method is a method of excavating the ground in a top-down manner while reinforcing the insufficient horizontal support force of the thumb pile 10 against the excavation back ground pressure by the strut 20 (FIG. 1). Reference)

Excavation back earth pressure is a horizontal force and the thumb pile 10 is a vertical member.

It is impossible in structural mechanics to support horizontal forces with only vertical members without horizontal members. The strut 20 serves as a horizontal member with respect to the thumb pile 10 which is a vertical member.

The strut 20 is perpendicular to the thumb pile 10. The strut 20 is supported by two support points.

Both support points of the strut 20 are usually the thumb piles 10 installed at positions opposite to each other.

Since the struts 20 are installed toward the thumb piles 10 facing each other, the struts in the horizontal direction and the struts in the vertical direction cross each other on the same plane.

The struts in the horizontal and vertical directions are the obstacles to narrowing the work space for excavating and entering the equipment for excavation work.

In particular, since the high-rise buildings are built around the excavation space in the downtown area, struts are more closely installed for structural safety.

On the other hand, since the struts are temporary facilities, after the excavation space is provided, the struts must be removed sequentially with the installation of the permanent structure. The construction of the permanent structure is constructed step by step starting from the bottom and upwards in a bottom-up manner.

As a result, strut removal is also performed step by step.

For example, if the basement floor is called B1, the struts installed on the B1 floor must be removed first to construct the B1 floor of the permanent structure.

At this time, although the strut of the B1 layer was removed, the struts of the upper layers B2, B3, and B4 ..... layer are supporting the earth pressure as it is installed.

The struts removed from the B1 layer must be pulled out, and the struts in the horizontal and vertical directions will interfere with the excavation work.

In addition, for the construction of the B1 floor, materials such as concrete mortar and reinforcing bar must descend to the B1 floor through the struts of the B2, B3, B4 ..... floor. The strut installed in the upper layer interferes with the material supply, which is a problem of lowering work efficiency.

Even in the construction of B2, B3, B4 ..... floors, these problems remain.

Therefore, the strut method has a problem that the work space for the excavation work and the excavation work is narrowed because the strut should be installed in the excavation space toward the thumb pile, and since the strut is a temporary facility, the construction of the permanent structure is performed sequentially. Since the construction must be performed while removing the struts, there is a problem in that the work efficiency is lowered due to the remaining struts, which interferes with the construction of the sequential permanent structures.

B) Sheet-File Method

The prior art Patent Publication No. 2008-45182, "Structure of Sheet-Pile Wall Structure," will be described.

3 of invention 2008-45182 is an invention for solving the problem of the interlock 446 (448) of US 6,715,964 B2 shown in FIG.

As shown in FIG. 2, the soil anchor 444 is coupled by the first interlock 446 of the first sheet 440 and the second interlock 448 of the second sheet 442. Soil Failure Plane is the T _max -line under which the main earth pressure is applied.

The action force 450 is a tensile force applied to the small fracture surface. Soil anchor 444 resists this.

Publication No. 2008-45182 discloses a problem with US 6,715,964 B2 that the connection connecting the seat-pile wall compartment to the anchorage is under extremely high tension due to the earth pressure (earth pressure) of the ground, which is in particular retained again from the surrounding area. The problem is that the purpose of the present invention is to develop a structure that can withstand extremely high tension without disconnecting the connecting portion, that is, the connecting portion where the first interlock 446 and the second interlock 448 engage. It can be confirmed from the specification.

The purpose of the Patent Publication No. 2008-45182 is in the configuration of the structure capable of withstanding extremely high tension without the connection portion 16 is separated, the structure is the core configuration is entirely in the shape and structure of the connection portion 16 have.

Reference numeral 12 in FIG. 3; Sheet-pile wall compartment, 14; First anchorage, 16; Connection, 18 is an open cell, 22; Flattened assembly, 24; support wall, 26; Welds, 28; It is a double-T carrier.

On the other hand, Patent Publication No. 2008-45182 or US Pat. No. 6,715,964 B2 has the same basic concept of the equilibrium relationship between earth pressure and force.

The basic concept of the Earth Retaining System by the seat pile is shown in FIG. 4 is shown in US Pat. No. 6,715,964 B2, which is also incorporated herein by reference.

Looking at the basic concept of the Earth Retaining System by Figure 4 as follows.

Reference numeral 200 is a unit cell structure of a typical sheet file. The unit cell structure 200 is U-shaped. The curved portion of the U-shaped sheet pile is 210, and the straight portion of the sheet pile is 220. Curved portion 210 is closed and straight portion 220 is open. The unit cell structure 200 is installed vertically.

4 is a plan view of a unit cell structure 200. The unit cell structure 200 is a structure in which the unit cell structure 200 supports the back ground pressure P transmitted through the soil filled therein.

A structure such as a road is constructed on the unit cell structure 200.

P is the back earth pressure using the U-shaped unit cell structure 200 as the boundary condition.

Referring to Figure 7, the back ground pressure P is located on the back. In FIG. 4, this back soil pressure is acting on the curved portion 210 of the sheet pile.

The force balance in Fig. 4 is a concept in which the frictional force F = μN corresponds to the back ground pressure P.

The directions of action are balanced by P and F which are opposite to each other.

N is a vertical force acting on the straight portion 220 of the sheet pile.

The basic concept of the prior art according to FIG. 4 can be summarized as the earth pressure P acting on the curved portion 210 of the unit cell structure 200 to be balanced with the frictional force F. FIG.

The present invention uses the arching effect generated by the frictional force between the granules and the seat panel to form a self-supporting ingot of reinforcement soil method, and reinforces a new concept to resist the earth pressure acting as an excavation space by the weight of the independence ingot. Its purpose is to provide a self-supporting earthquake structure.

Reinforced self-supporting soil structure using the arching effect is located on the back of the excavation space, so it is not obstructed to excavation work, so that the excavation space can be used widely. Has a different purpose,

Seats embedded after completion of construction while making the connection and connection of the seat panel connection easy by the upper and lower fasteners to increase the rigidity by making the joints of the seat panel into a composite section and the simple structure of the upper and lower fasteners. Another object is to facilitate recovery of the panel.

Since the present invention relates to a reinforced self-supporting soil structure using the arching effect, first, a general outline of the arching effect will be described, and then the arching effect will be described in terms of soil mechanics.

A) general overview of the arching effect;

 A general outline of the arching effect will be described with reference to FIG. 5.

 Opening a hole of diameter d formed in the lower bottom plate while sand is accumulated in an open hexahedron with the top cover plate open, the sand is discharged downward through the hole of diameter d. [See Fig. 5 (a)].

 However, although the hole of diameter d is open, sand is not discharged continuously and its discharge stops. When the discharge of sand is stopped, the shape of the sand shows the arc shape of the arc.

 The sand piled up without opening of diameter d is supported by the bottom plate, and when the hole of diameter d is opened, the accumulated sand is discharged to some extent by the weight of sand W, and then the sand discharge stops while forming an arc of arc shape. do.

The phenomenon in which the sand weight W is no longer discharged and is supported by an arc-shaped arch formed on a hole of diameter d is called an arching effect.

 The arching effect is caused by the balance between the force of sand to be discharged by the sand weight W and the force of sand to be discharged by the friction force in contact with the four vertical planes of the cube.

 The arching effect is a state in which sand is in balance with the frictional force generated due to the force close to the four vertical planes of the cube with respect to the force that sand tries to discharge into the hole of diameter d.

 Therefore, the arching effect occurs only when the magnitude of the friction force and the size of the diameter d are appropriate. If the diameter d becomes too large for the magnitude of the frictional force, the arching effect does not occur because sand continues to be discharged through the holes of the diameter d.

 Opening the hole of diameter d causes the magnetic weight W of sand to act toward the hole of diameter d, and sand is discharged through the hole of diameter d by the applied force W. This does not mean that sand is continuously discharged. As shown in Fig. 5 (b), the sand does not discharge any more and forms a circular arc shape.

 Inter shear stress is generated between the sand to be discharged through the hole of diameter d and the sand particles to suppress the sand to be discharged. Thus, the force W acting on the mutual shear stress generated is supporting the arc in the shape of an arc.

The arc shape of the arc is rearranged by the shear stress generated between the sand to be discharged and the sand particles to suppress the sand to be discharged.

 The arch form is characterized in that an arc is formed in an upward direction with respect to the action direction of the sand weight W as shown in FIG.

The sand weights W are supported by the arcuate arch shape in Fig. 5B.

B) Arching effect from the point of view of soil dynamics

 Referring to Fig. 7, the arching effect of the continuous sheet wall will be described in terms of soil mechanics.

  The stability problem of the earth structure is a three-dimensional problem, but it is usually interpreted in two dimensions. This is because ordinary earth structures with longer widths (B) and lengths (L) than excavation heights (H) have almost two-dimensional boundary conditions.

  Even in three-dimensional analysis, due to the so-called arching effect, the main earth pressure is significantly reduced compared to the two-dimensional state, and the passive earth pressure is inversely increased, rather the safety side results are obtained rather than the two-dimensional analysis.

  FIG. 7 is a two-dimensional plan view of the width B and the length L of FIG. 6A.

  The earth pressure p represents the earth pressure at the same excavation height (H), so the magnitude is the same.

  B is the width between the seat panel and the seat panel, and L is the length of the seat panel provided continuously.

Friction force F = μP ₀ . μ is the coefficient of friction and P _O is the static earth pressure. The direction of action of P _O is perpendicular to the seat panel.

  The frictional force F is generated by the back soil pressure p, and the shear stress τ is distributed as shown in Fig. 1 or 8 due to the frictional force F. The shear stress τ becomes smaller toward the center O.

Figure-1

 Since the arc-shaped arch form formed in FIG. 5 (b) is a state in which sand particles are rearranged, this will be described in terms of soil mechanics.

When the stress-strain problem of soil is treated as a two-dimensional problem, if stress is applied to an element of soil as shown in Fig. 2 (a), only normal stress (σ ₁ , σ ₃ ) is applied to the element and shear stress There are two orthogonal planes which are zero, that is, planes I-I and III-III. The normal stresses (σ ₁ , σ ₃ ) acting on orthogonal planes (planes I-I and III-III) are called principal stresses. σ ₁ is the maximum principal stress and σ ₃ is the minimum principal stress.

Shear stress τ must be applied to planes other than the main stress plane (ie planes I-I and III-III) in addition to vertical stress σ as shown in Fig. 2 (b).

The vertical stress σ and the shear stress τ on the aa plane inclined counterclockwise by α in the I-I plane are represented by the τ-α relationship, resulting in the point a in Fig. 2 (c), and the angle α is 0 to 180 °. Rotation of a draws Mohr's stress source C with both ends of diameter I and I representing maximum stress σ ₁ centered on one point A on the σ axis and point III representing minimum principal stress σ ₃ , respectively. Can be.

From the stress source C of Mohr, the vertical stress σ and shear stress τ at point a are obtained.

σ = 1/2 (σ ₁ + σ ₃ ) + 1/2 (σ ₁ -σ ₃ ) cos2α -------- ①

τ = 1/2 (σ ₁ -σ ₃ ) sin2α -------------------- ②

In the α = 90 ° becomes _{τ = 0, σ = σ 1} .

  In this way, when the torrent rotates, the shear stress τ at point a becomes zero, and only the main stress is received.

  The arcuate arch shape of FIG. 5 (b) formed by rearrangement of sand particles is a state in which the shear stress τ is zero, that is, only the main stress is received.

Figure-2

  Now, a circular arc shape exhibited by the action of the back ground pressure p will be described with reference to FIG.

   When the back soil pressure p acts, the earth stress is rearranged while the main stress direction is rotated under the influence of the friction force F with the seat panel.

   As shown in FIG. 5 (b), when the shear stress τ = 0 due to the rearrangement of the sand particles, that is, the main stress direction is connected to each other in a state where only the main stress is received, an arc-shaped arch is formed.

   The ingot on the same arc acts as a beam supporting the earth pressure in an arc shape.

It is also due to this role of the arch shape that the arcuate arch shape in Fig. 5 (b) bears the upper sand load (W).

  In Fig. 8 1, No. 2, No. 3, No. 4, ............ No. n is an arc-shaped arch with a certain interval. No. In 1, the back soil pressure p is most supported, and the degree of support gradually decreases. No. No n is subjected to back soil pressure. No. The back ground pressure p = 0 in the area A of n. Since the earth plate is located in the area A, the earth pressure plate does not have a back ground pressure p.

  The earth pressure plate does not have a back soil pressure p in the area A of the earth plate, so the earth plate has no role as a structural material supporting the earth pressure, and is merely a protective material to protect the soil from flowing down.

On the contrary, since the curved portion 210 of the unit cell structure 200, which is a conventional technology corresponding to the earth plate, is a structural material that must support the back ground pressure p unlike the present invention, the curved portion 210 of the earth plate and the unit cell structure 200 of the present invention. ) Has completely different structural and mechanical characteristics.

 Due to the arching effect, the back soil pressure p is arch arc no. 1, No. 2, No. 3, ............ No. As the back soil pressure p gradually decreases toward n, the back soil pressure p becomes 0 in the area A in front of the earth plate 30, so that the soil in the sheet panels arranged in parallel forms a lump, and the lump is a self-supporting structure with respect to the back soil pressure p. Function as.

  The self-supporting structure by the arching effect is shown in FIG. 9A.

  The balance of force between the self-supporting structure and the back soil pressure p is similar to that of the reinforced soil. In other words, the back ground pressure p is a concept that is supported by the self-weight W of the ingot of the self-supporting structure.

  The concept of the self-supporting structure by the arching effect is a new concept completely different from that of the U-shaped unit cell structure 200 of FIG.

Now, the configuration of the present invention reinforced self-supporting soil structure of the new concept using the arching effect is as follows.

The present invention is installed vertically on the ground at a distance B to the thumb pile 10 formed integrally with the thumb pile insertion portion 14a in the longitudinal direction on one flange 12 of the thumb pile 10 is inserted into the earth plate 30 And inserting and connecting the sheet panel projection part 22a to the thumb pile insertion part 14a, and subsequently inserting the sheet panel projection part 22a into the sheet panel insertion part 22a 'and then inserting the sheet panel projection part 22a'. The compression support plate projection 46a is inserted into and coupled thereto, but the length of the continuous sheet panel 20 in the range of the internal friction angle of soil Φ = 10 to 34 ° and the adhesion force C = 0.0 to 5.0 (ton / m2). Reinforced self-supporting soil barrier using the arching effect, characterized in that the distance B between the L and the seat panel 20 is 0.5 ≤ L / B ≤ 3.0 so that the back soil pressure is not acted on the front earth plate by the arching effect. Structure structure.

Herein, the range of 0.5 ≤ L / B ≤ 3.0 is calculated by the Rankine earth pressure equation with the internal friction angle Φ of soil and adhesive force C as variables.

If L / B exceeds 3.0 at 0.5 ≤ L / B ≤ 3.0, the length becomes longer, resulting in uneconomical installation, and there is a risk of borderline disputes in urban areas, and the recovery of the seat panel 20 becomes difficult.

When the L / B is less than 0.5, the rigidity of the member, such as the seat panel 20 is reduced, there is a disadvantage that the member force is insufficient.

According to Figure 3, the smaller the size of L / B in the range of 0.5 ≤ L / B ≤ 3.0, the more economical the construction is. For this purpose, it is preferable to divide the range of 0.5 ≦ L / B ≦ 3.0 into the range of 0.5 ≦ L / B ≦ 1.5 and the range of 1.5 ≦ L / B ≦ 3.0.

In the range of 0.5 ≦ L / B ≦ 1.5, the internal friction angle Φ of the soil is in the range of 14 to 22 °, and the adhesion force C is in the range of 0.0 to 5.0 (ton / m 2).

In the range of 1.5 ≦ L / B ≦ 3.0, the internal friction angle Φ of soil is in the range of 10 to 14 °, and the adhesion force C is in the range of 0.0 to 5.0 (ton / m 2).

On the other hand, the sheet panel insertion part 22a 'is formed in one side of the sheet panel 20, and the sheet panel protrusion part 22a is formed in the other side. In another embodiment, the S-shaped bent portion 22b is formed on one side of the sheet panel 20, and the S-shaped inverted portion 22b 'is formed on the other.

Since the seat panel 20 is connected between the thumb pile 10 and the compression support plate 40, the shape of the connection portion of the thumb pile 10 and the compression support plate 40 depends on the shape of the connection portion of the seat panel 20.

For example, when the seat panel projection 22a and the thumb pile 10 are connected to the seat panel insertion portion 22a 'and the compression support plate 40, the shape of the connection portion of the thumb pile 10 is that the thumb pile insertion portion 14a is formed. And, the shape of the connecting portion of the compression support plate 40 should be the compression support plate projection (46a). On the contrary, the shape of the connection part of the thumb pile 10 should be the shape of the thumb pile protrusion 14a 'and the connection part of the compression support plate 40 should be the compression support plate insertion part 46a'.

Since the thumb pile protrusion 14a 'and the compression support plate insert 46a' vary depending on the form of the connection portion of the seat panel 20, the thumb pile protrusion 14a 'and the compression support plate insert 46a' are shown in the drawing. It will be omitted and replaced by the thumb pile insertion portion 14a and the compression support plate projection 46a at the same position instead.

In addition, when the S-shaped bent portion 22b and the thumb pile 10 of the seat panel 20 is connected to the compression support plate 40 when the S-shaped reverse bent portion 22b 'of the seat panel 20 is connected to the compression support plate 40 The connecting portion of 10) should be an S-shaped reverse bent portion 14b ', and the connecting portion of the compression support plate 40 should be an S-shaped bent portion 46b.

On the contrary, the shape of the connection portion of the thumb pile 10 should be an S-shaped bent portion 14b, and the shape of the connection portion of the compression support plate 40 should be an S-shaped reverse bent portion 46b '.

Since the S-shaped inverted portion 14b 'depends on the form of the connection portion of the seat panel 20, the illustration of the S-shaped inverted portion 14b' is omitted in the drawing, and instead, the S-shaped inverted portion 14b '( 14b) to replace it.

As such, the connection form of the thumb pile 10 and the compression support plate 40 changes according to the left and right connection forms of the seat panel 20. For convenience of description, the seat panel protrusion 22a and the seat panel insertion portion 22a 'are used here. I will explain it as a representative of the connection form.

The connection form of the thumb pile 10 is a thumb pile insertion portion 14a or a thumb pile protrusion 14a 'or an S-shaped bent portion 14b or an S-shaped inverted portion 14b'.

The connection form of the compression support plate 40 is a compression support plate projection 46a, or a compression support plate insertion portion 46a ', or an S-shaped bent portion 46b or an S-shaped reverse bent portion 46b'. Since the S-shaped bent portion 46b and the S-shaped reverse bent portion 46b 'are selected according to the left and right connection form of the seat panel 20, the illustration of the S-shaped reverse bent portion 46b' is omitted in the drawings and instead. The S-shaped bent portion 14b in the same position will be replaced.

In order to increase the cross-sectional secondary moment I and the rigidity of the seat panel 20, the seat panel connection portion 22 is firmly fixed by the upper and lower fasteners 50a and 50b.

The connection part of the seat panel 20 is firmly fixed by the upper and lower fasteners 50a and 50b, but the upper fastener 50a is attached to both sides of the seat panel 20 by the attachment pad 52a and the fastening plate 54a. It is fixed by the fastening bolt 56a penetrating the seat panel 20, the attachment pad 52a and the fastening plate 54a in the order of, and the lower fastener 50b is the first cutout 52b. And a second cutout 56b, an upwardly inclined surface 524b and a locking jaw 526b on the first cutout 52b, and a rotating plate 54b and a spring 59b on the second cutout 56b. ) Is formed and the upper inclined surface 542b at the upper end of the rotating plate 54b rotated about the hinge axis 58b, the lower rotating groove 546b at the lower end thereof, and the vertical insertion groove 544b at the vertical surface thereof. The spring 59b, which is formed and is inserted into the spring insertion groove 548b, is connected to and fixed to the spring hanger 562b.

The rotating plate 54b formed on the second cutout 56b is rotated about the hinge shaft 58b provided at the pivot point 582b by the elastic force of the spring 59b, so that the top inclined surface 542b of the rotating plate 54b is rotated. The locking jaw 526b of the first cutout 52b is caught.

The lower rotating groove 546b of the rotating plate 54b is formed so deep that the rotating plate 54b is smoothly rotated without being caught by the lower end of the seat panel 20.

The lower fixture 50b is configured to be connected to each other by the first cutout 52b and the second cutout 56b while being installed at the connection portion of the two seat panels 20. The first cutout 52b is formed in one seat panel 20, and the second cutout 56b is formed in the other seat panel 20, and is fixed and coupled to each other by the action of the rotating plate 54b. do.

As such, when the upper and lower fasteners 50a and 50b are firmly fixed to the upper and lower portions of the connection portion of the seat panel 20, the two seat panels 20 become one composite section to increase the cross-sectional secondary moment. With stiffness increases.

Next, the relationship between the space | interval B between two sheet panels 20 which cause an arching effect, and the length L of the continuous sheet panel 20 is demonstrated as follows.

If p is the back earth pressure per unit area acting on the space B between the sheet panels 20, the force P of the earth pressure is P = p * B.

P = p * B --------------- (1)

That is, the earth pressure P of the formula (1) is the earth pressure acting on the collapse between the continuous sheet panels 20. If the weight of the lump is W, W is resisting P.

The back soil pressure p per unit area can be obtained by Rankine pressure equation (2).

or

The earth pressure p in the equation (2) has a functional relationship with the adhesive force (C) and the internal friction angle (Φ).

Where Ka is the Rankine dynamic pressure coefficient Ka = tan² (45 ° -Φ / 2), Φ is the internal friction angle, r is the unit weight of soil, H is the depth of excavation, and C is the adhesion.

When the frictional force between the continuous sheet panel 20 and the ingot contacted with it is F, the frictional force F is as follows.

F = 2 * L (Po * μ + C ') = 2 * L (r * H * Ko * μ + C') ------- (3).

L is the length of the continuous sheet panel 20, Po is the static earth pressure, μ is the coefficient of friction, C 'is the friction adhesion.

When the earth pressure acting on the earth wall is Pt, the relationship between the back ground pressure P and the frictional force F is as follows.

Pt = P-F ------------ (4)

In Eq. (4), Pt = 0 because the earth pressure is not applied to the arching effect in the area A of Figure 3. P-F = 0 -------- (5)

Becomes When F is equal to or greater than P (F? P) in Equation (5), due to the arching effect, the collapse in the length L of the sheet panel 20 continuous with the width B becomes independent while maintaining its own weight W.

F ≥ P -------- (6)

Substituting Eq. (3) and (2 ') into Eq. (6) is:

Equation (7) is a variable of the internal friction angle Φ and the adhesion force C.

Next, when the excavation depth H = 10m, the lower limit for L / B according to the change of the internal friction angle Φ and the adhesion force C will be obtained by equation (7).

[Condition]

Excavation depth H = 10 m, unit weight of ingot; r = 1.7 (t / m 3), coefficient of friction; μ = [tan (⅔Φ)],

Rankine kinetic pressure coefficient; Ka = tan² (45 ° -Φ / 2), Rankine dynamic pressure coefficient; Kp = tan² (45 ° + Φ / 2) Ka,

adhesiveness; C (ton / m 2), friction adhesion; C '= [⅔C] (ton / m 2),

Static earth pressure coefficient; Ko

In the graph above, and the calculation result of L / B according to equation (7) within the range of the variable internal friction angle Φ = 10 ~ 34 ° and adhesive force C = 0.0 ~ 5.0 (ton / ㎡) It looks like Figure-3.

Figure-3

Figure 3 shows the following result.

(1) The maximum and minimum values are shown with the adhesive force C = 0 and C = 5.0 (ton / m 2) as the boundary.

② When L / B exceeds 3 within the range of soil friction angle Φ = 10 ~ 34 ° and adhesive force C = 0.0 ~ 5.0 (ton / ㎡), back soil pressure is not acted on the front earth plate by arching effect. It can be seen.

③ However, if the L / B exceeds 3, the length of the continuous sheet panel must be longer, which is uneconomical, and if the L / B is less than 0.5, the rigidity of the seat panel is reduced, there is a problem that the member force is insufficient. In the above, L / B was limited to 0.5 ≦ L / B ≦ 3.0.

④ That is, the internal friction angle Φ of soil is in the range of 10 to 34 °, and the length L of the continuous sheet panel 20 and the distance B between the sheet panels 20 in the range of adhesive force C = 0.0 to 5.0 (ton / m 2). It can be seen that the back soil pressure does not act on the front earth plate by the arching effect when the relationship is 0.5 ≦ L / B ≦ 3.0.

⑤ The relationship between the length L of the continuous seat panel 20 and the distance B between the seat panels 20 in the range of the internal friction angle Φ = 14 to 22 ° of soil and the adhesion force C = 0.0 to 5.0 (ton / m 2). When 0.5 ≤ L / B ≤ 1.5 it can be seen that the back soil pressure does not act on the front earth plate by the arching effect.

⑥ The relationship between the length L of the continuous seat panel 20 and the distance B between the seat panels 20 in the range of the internal friction angle Φ = 10 to 14 ° of soil and the adhesion force C = 0.0 to 5.0 (ton / ㎡). When 1.5 ≤ L / B ≤ 3.0 it can be seen that the back ground pressure does not act on the front earth plate by the arching effect.

On the other hand, even though the L / B range satisfies the range of 0.5 ≤ L / B ≤ 3.0, in the case of urban areas, there is a general lack of free space with adjacent land boundaries or adjacent structures, so the length of continuous sheet panels There is a construction limitation that cannot be installed to meet the above range. In order to solve the limitation of the construction it is preferable to replenish by manual earth pressure by the root depth Hb as shown in Figure 14 to compensate for the insufficient length of the continuous seat panel. The root depth (Hb) should be at least 1.0m to increase wall stability and maintain freezing depth.

The present invention uses the arching effect between the granules and the seat panel to form a self-supporting soil in the earth plate which does not apply the back soil pressure to the earth plate so that the ground soil pressure acting as the excavation space can be resisted by the self-weight of the self-supporting soil. The concept is more efficient and economical than conventional sheet piles.

Reinforced self-supporting soil structure using the arching effect is located on the back of the excavation space, so the excavation work is not hindered, so the excavation space can be used widely, and the excavation work is easy and efficient in the small space of the downtown area with high-rise buildings.

Because the upper and lower fasteners make the connection part of the seat panel a composite section, not only the rigidity is increased but also the structure of the upper and lower fasteners is simple, so it is easy to attach and dismantle the seat panel connection part and the sheet which is embedded after completion of construction. It is a useful invention that the panel is easy to recover and its construction and recovery are efficient and economical.

1 is a front view showing the underground excavation of the top-down method by the conventional strut method
Figure 2 is a state diagram showing the connection state of the sheet pile joint by the conventional sheet pile method
3 is a plan view showing a connection state of the sheet pile joint by the conventional sheet pile method
4 is a basic conceptual view showing the relationship between the back soil pressure and the frictional force by the sheet pile method of FIGS.
5 is a state showing the state of the arch stopped by the arching effect after exiting a certain amount through a small hole drilled in the bottom plate of the sand filled with hexahedron
FIG. 6a is a perspective view of the present invention showing a state in which soil is filled in a seat panel connected to a thumb pile
6B is a perspective view showing a state in which soil is removed in FIG. 6A
FIG. 7 is a unit plan view showing an action state of a force balanced against the back earth pressure of FIG. 6A
8 is a state diagram showing the shear stress distribution shown in the unit plan view of FIG. 7 with respect to the back ground pressure, the arching effect and the back ground pressure not acting on the A region.
Figure 9a is a perspective view showing the relationship between the ingot (W) formed by the arching effect and the back soil pressure
FIG. 9B is a balance of forces showing the relationship of FIG. 9A in a two-dimensional plane
10 is a cross-sectional view showing the shear stress distribution when the ingot is not formed
Figure 11a is a perspective view showing the form of the connection portion of the thumb pile and the seat panel of the present invention
11B is a state diagram showing a state where the upper fixture is installed at the connection portion of the seat panel of the present invention;
12A is another embodiment showing the shape of a connection portion between the thumb pile and the seat panel of the present invention;
12B is a state diagram showing a state where the upper fixture is installed in the connecting portion of FIG.
12c is another embodiment showing the form of the connection between the thumb pile and the seat panel of the present invention
13A is an exploded perspective view of a lower fixture installed in a connection portion of a seat panel of the present invention;
Figure 13b, 13c] a state diagram showing the process and the installed state of the lower fixture of the present invention installed
14 is a cross-sectional view showing a state in which the thumb pile 10 and the seat panel 20 of the present invention are installed deeper by the indentation portion Hb than the design ground to receive manual earth pressure.

Referring to the ground excavation construction method using the reinforced self-supporting earth retaining structure of the present invention in detail as follows.

Placing the thumb pile 10 on the ground of the boundary to be excavated to a vertical depth H, which is the design ground to be the distance B;

엄지 Insert and connect the thumb pile insertion portion 14a and the seat panel projection portion 22a formed on the flange 12 of the thumb pile 10, and then insert the sheet panel projection portion 22a into the seat panel insertion portion 22a '. Insert and couple the compression support plate projection 46a to the seat panel insert 22a 'as the year goes by, but the internal friction angle of soil Φ = 10 to 34 °, and the adhesion force C = 0.0 to 5.0 (ton / ㎡). Connecting so that the relationship between the length L of the continuous seat panel 20 and the distance B between the seat panel 20 is 0.5 ≦ L / B ≦ 3.0;

굴 excavating to a predetermined depth (h ₁ ) while gradually drilling the ground from the ground, and then inserting the earth plate 30 from the upper end of the thumb pile 10;

굴 proceeding with the excavation of a predetermined depth (h ₂ ) in the state of excavation of a predetermined depth (h ₁ ) and inserting the earth plate 30 into the thumb pile 10 from the upper end;

⒠ repeating the 와 step and ⒟ step to complete the underground excavation; underground excavation construction method using a reinforced self-supporting earth retaining structure characterized in that it comprises a.

In addition, in step ⒝, the internal friction angle of soil Φ = 14 to 22 ° and the adhesion force C = 0.0 to 5.0 (ton / m2) in the range between the length L of the seat panel 20 and the seat panel 20 The relationship between the intervals B is 0.5 ≦ L / B ≦ 1.5. In the step 간의 between the length L of the continuous sheet panel 20 and the sheet panel 20 in the range of the internal friction angle Φ = 10 ~ 14 ° of the soil, and the adhesive force C = 0.0 ~ 5.0 (ton / ㎡) The relationship between the intervals B is 1.5 ≦ L / B ≦ 3.0.

In the case of urban areas, there is a lack of free space with adjacent land boundary lines or construction structures exist adjacent to each other, and thus, there is a construction limitation in that the length of the continuous sheet panel cannot be installed to fit the above range. In this case, as shown in FIG. 14, it is preferable to install the thumb pile 10 and the root indentation portion Hb of the seat panel 20 to receive manual earth pressure deeper than the vertical depth H, which is the design ground. This is to increase the stability to the activity and conduction of the reinforced self-supporting masonry structure. In this case, if the proper L / B is not satisfied, the earth pressure acts on the front earth plate 30, so the thickness must be determined by calculating the structure.

On the other hand, the seat panel 20, the mounting pad 52a and the fastening plate 54a in the state in which the mounting pad 52a and the fastening plate 54a are positioned on both sides of the upper end of the connection part of the seat panel 20 in the step ⒝. The upper fastener 50a fastened and fixed by the fastening bolt 56a penetrating through it, and a rotating plate 54b formed at the second cutout 56b at the lower end thereof is hinged by the elastic force of the spring 59b. The top inclined surface 542b of the rotating plate 54b is rotated around the 58b so that the top inclined surface 542b of the rotating plate 54b is caught by the locking jaw 526b of the first cutout 52b. The lower rotating groove 546b is formed at the lower end thereof, and the lower fixture 50b is formed at the vertical plane thereof with the vertical insertion groove 544b formed thereon.

Referring to the installation and removal method of the upper and lower fixtures as follows.

Inserting the seat panel protrusion 22a (or the S-shaped bent portion 22b 'of the seat panel into the S-shaped bent portion 14b of the thumb pile) from the top to the thumb pile insertion portion 14a provided on the ground, Subsequently, the sheet panel 20 is inserted and assembled, and then the compressed support plate protrusion 46a is inserted into the sheet panel inserting portion 22a 'to install.

The lower fixture 50b should first install the seat panel 20 in which the first cutout 52b is formed, and then install the seat panel 20 in which the second cutout 56b is formed.

The same procedure applies to the removal of the seat panel 20 provided. That is, it is necessary to first remove the sheet panel 20 on which the first cutout 52b is formed, and then remove the sheet panel 20 formed on the second cutout 56b. If the order is different, it can not be installed or removed.

Referring to the binding and dismantling of the lower fixture (50b) as follows.

First, the binding action of the lower fixture 50b will be described.

The sheet panel protrusion 22a of the sheet panel 20 in which the second cutout 56b is formed in the sheet panel inserting portion 22a 'of the sheet panel 20 having the first cutout 52b embedded in the ground When inserted, the rotating plate 54b rotated about the hinge axis 58b is vertically guided by the vertical sheet panel inserting portion 22a 'so that the vertical state is maintained. (See Figure 12a)

The hinge shaft 58b is inserted at the axial point 582b.

As soon as the rotating plate 54b, which has been maintained in the vertical state, comes into contact with the first cutout 52b, the rotating plate 54b is formed by the springs of the spring 59b fixed to the spring hook 562b as shown in Fig. 12B. The upper inclined surface 542b of the rotating plate 54b is caught by the locking jaw 526b of the first cutout 52b while being rotated toward the first cutout 52b.

At this time, the vertical insertion groove 544b of the rotary plate 54b inserted into the second cutout 56b of the seat panel 20 and the lower rotary groove 546b inserted into the lower end of the second cutout 56b are also rotated. With the rotation of 54b).

In particular, since the rotary plate 54b must be rotated about the hinge axis 58b, the lower rotary groove 546b of the rotary plate 54b is not hindered by the rotation by the second cutout 56b of the seat panel 20. It is formed to a depth that is not enough.

In this way, the top inclined surface 542b of the rotating plate 54b is firmly fixed.

The spring 59b is fixed to the spring hook 562b while being inserted into the spring insertion groove 548b of the rotary plate 54b.

Next, the dismantling action of the lower fixture 50b will be described.

In order to disassemble the upper inclined surface 542b of the rotating plate 54b by the locking jaw 526b of the first cutout 52b, the seat panel 20 having the first cutout 52b is first placed upward. When lifted up, the rotating plate 54b is vertically guided by the vertical sheet panel inserting portion 22a 'to be in a vertical state. While removing the seat panel 20 having the first cutout 52b, the vertical insertion groove 544b and the lower rotary groove 546b of the rotating plate 54b are again maintained while keeping the rotating plate 54b vertical. It is inserted into the second cutout 56b of 20). As described above, since the rotary plate 54b is not disturbed while the sheet panel 20 having the first cutout 52b is pulled up, the sheet panel 20 having the first cutout 52b is easily dismantled. .

Since the structure of the lower fixture 50b is simple and easy to bind and dismantle, the binding and dismantling work and the rigidity increase are efficient.

10; Thumb pile
12; flange
14a; Thumb pile insert
14b; S-shaped bend,
20; Seat panel
22a; Sheet panel projection, 22a '; Seat panel insert
22b; Sigmoidal bend, 22b '; S-shaped inverted bend
30; Earth plate
40; Compressed support plate
42; Vertical section
44; Horizontal section
46a; Compression support plate protrusion
46b; S-shaped bend
50a; Upper fixture
52a; Attachment pad
54a; Fastener
56a; Tightening Bolt
50b; Lower fixture
52b; First incision, 524b; Upward slope, 526b; Jam
54b; Swivel plate, 542b; Top slope, 544b; Vertical insertion groove, 546b; Bottom revolving groove,
548b; Spring insertion groove
56b; Second incision, 562b; Spring hanger
58b; Hinge axis, 582b; Axis
59b; spring
B; Width between seat panel and seat panel
L; Seat length of seat panel

Claims (10)

Installing the thumb pile 10 formed integrally with the thumb pile insertion portion 14a in the longitudinal direction on one flange 12 of the thumb pile 10 into which the earth plate 30 is inserted, perpendicularly to the ground at an interval B, and The compression support plate is inserted into the seat panel insertion portion 22a 'while inserting and connecting the seat panel projection portion 22a to the thumb pile insertion portion 14a, and subsequently inserting the seat panel projection portion 22a into the seat panel insertion portion 22a'. Insert and combine the projections 46a, but the length L and the sheet of the continuous sheet panel 20 in the range of the internal friction angle Φ = 10 to 34 ° of the soil and the adhesion force C = 0.0 to 5.0 (ton / m 2) Reinforced self-supporting earth retaining structure using an arching effect, wherein the gap B between the panels 20 is 0.5 ≦ L / B ≦ 3.0 so that the back ground pressure is not acted on the front earth plate by the arching effect.
The method of claim 1
The relationship between the length L of the continuous sheet panel 20 and the distance B between the sheet panels 20 in the range of the internal friction angle Φ = 14 to 22 ° of the soil and the adhesion force C = 0.0 to 5.0 (ton / m2). Reinforced freestanding structure using arching effect, characterized in that 0.5 ≤ L / B ≤ 1.5
The method of claim 1
The relationship between the length L of the continuous sheet panel 20 and the distance B between the sheet panels 20 in the range of the internal friction angle Φ = 10 to 14 ° of the soil and the adhesion force C = 0.0 to 5.0 (ton / m2). Reinforced freestanding structure using arching effect, characterized in that 1.5 ≤ L / B ≤ 3.0
The method according to claim 1 or 2
The connection portion of the thumb pile 10 is formed of a thumb pile insertion portion 14a or a thumb pile protrusion 14a ', and the seat panel 20 connection portion coupled thereto is a sheet panel protrusion portion 22a or a sheet panel insertion portion ( 22a ′) reinforced self-supporting earth retaining structure using arching effect
The method according to claim 1 or 2
The compression support plate 40 is formed of a vertical portion 42 and a horizontal portion 44, while the connection portion of the compression support plate 40 has a compression support plate protrusion 46a or a compression support plate insert 46a '. Reinforced self-supporting earth retaining structure using an arching effect, characterized in that formed integrally with
The method according to claim 1 or 2
The connection part of the seat panel 20 is firmly fixed by the upper and lower fasteners 50a and 50b, but the upper fastener 50a is attached to both sides of the seat panel 20 by the attachment pad 52a and the fastening plate 54a. It is fixed by the fastening bolt 56a passing through the seat panel 20, the attachment pad 52a, and the fastening plate 54a in the order of, and the lower fixture 50b is the seat of the seat panel 20. A first cutout 52b formed on the panel inserting portion 22a 'side, and a second cutout 56b formed on the sheet panel protrusion 22a side of the sheet panel 20 corresponding thereto. The first inclined portion 52b has an upward inclined surface 524b and a locking jaw 526b, and the second cutout 56b has a spring hook 562b and an axial point 582b formed therein. And a rotating plate 54b rotatable by the hinge shaft 58b inserted into the lower rotating groove 546b of the rotating plate 54b,
An upper inclined surface 542b is formed at the upper end of the rotating plate 54b, a lower rotating groove 546b is formed at the lower end thereof, and a vertical insertion groove 544b is formed at the vertical surface thereof, and the spring 59b is formed at the vertical insertion groove ( While being inserted into the spring insertion groove 548b and the spring hook 562b formed in the 544b, the upper inclined surface 542b of the rotating plate 54b is formed by the elastic force of the spring 59b. Reinforced self-supporting earth retaining structure using an arching effect, characterized in that the locking jaw (526b) is inserted and fixed
Placing the thumb pile 10 on the ground of the boundary to be excavated to a vertical depth H, which is the design ground to be the distance B;
엄지 Insert and connect the thumb pile insertion portion 14a and the seat panel projection portion 22a formed on the flange 12 of the thumb pile 10, and then insert the sheet panel projection portion 22a into the seat panel insertion portion 22a '. Insert and couple the compression support plate projection 46a to the seat panel insert 22a 'as the year goes by, but the internal friction angle of soil Φ = 10 to 34 °, and the adhesion force C = 0.0 to 5.0 (ton / ㎡). Connecting so that the relationship between the length L of the continuous seat panel 20 and the distance B between the seat panel 20 is 0.5 ≦ L / B ≦ 3.0;
굴 excavating to a predetermined depth (h ₁ ) while gradually drilling the ground from the ground, and then inserting the earth plate 30 from the upper end of the thumb pile 10;
굴 proceeding with the excavation of a predetermined depth (h ₂ ) in the state of excavation of a predetermined depth (h ₁ ) and inserting the earth plate 30 into the thumb pile 10 from the upper end;
⒠ repeating the 와 step and ⒟ step to complete the ground excavation; underground excavation construction method using a reinforced self-supporting earthquake structure comprising a;
The method of claim 7, wherein
In step 간격, the distance between the length L of the continuous seat panel 20 and the seat panel 20 in the range of the internal friction angle Φ = 14 to 22 ° of the soil and the adhesion force C = 0.0 to 5.0 (ton / m 2) Underground excavation construction method using the reinforced self-supporting earth retaining structure, characterized in that the relation of B is 0.5 ≦ L / B ≦ 1.5
The method of claim 7, wherein
The gap between the length L of the continuous seat panel 20 and the seat panel 20 in the range of the inner friction angle Φ = 10 to 14 ° of the soil and the adhesive force C = 0.0 to 5.0 (ton / m 2) in the step Underground excavation construction method using the reinforced self-supporting earthquake structure characterized in that the relation of B is 1.5 ≤ L / B ≤ 3.0
The method according to claim 7 or 8
In the step ⒝, the seat panel 20, the attachment pad 52a, and the fastening plate 54a are positioned on both sides of the seat panel 20 in the order of the attachment pads 52a and the fastening plate 54a. An upper fastener 50a fastened and fixed by the penetrating fastening bolt 56a, and a first cutout 52b formed at the seat panel inserting portion 22a 'of the seat panel 20 at the lower end thereof; In addition, a lower fixture 50b including a second cutout 56b formed on the sheet panel protrusion 22a side of the seat panel 20 is formed, and an upwardly inclined surface 524b is formed on the first cutout 52b. And a hooking jaw 526b, and a second hook portion 56b, a spring hook 562b and an axial point 582b are formed, and the lower rotation groove 546b of the axial point 582b and the rotating plate 54b. Rotating plate 54b rotatably formed by a hinge shaft 58b inserted into the
An upper inclined surface 542b is formed at the upper end of the rotating plate 54b, a lower rotating groove 546b is formed at the lower end thereof, and a vertical insertion groove 544b is formed at the vertical surface thereof, and the spring 59b is formed at the vertical insertion groove ( While being inserted into the spring insertion groove 548b and the spring hook 562b formed in the 544b, the upper inclined surface 542b of the rotating plate 54b is formed by the elastic force of the spring 59b. Underground excavation construction method using a reinforced self-supporting earth retaining structure, characterized in that it is inserted and fixed to the locking jaw (526b)

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