JPS6383319A - Excavation surface reinforcing construction for bedrock - Google Patents

Abstract

PURPOSE:To stabilize an excavation surface, by setting lock bolts arranged along the excavation surface formed along with the excavation of a bedrock prior to the excavation of the bedrock, and by reinforcing the excavation surface. CONSTITUTION:As arranged along an excavation surface 3 formed along with the excavation of a bedrock G, lock bolts 4, 5 are driven-in from the surface 1 into the ground. After that, the bedrock G is excavated by every approx. 1-2m, and spray concrete 6 is sprayed on the excavation surface 3 formed along with the excavation. Then, lock bolts 7 are driven-in to penetrate the spray concrete 6 and to be arranged to be orthogonal to the lock bolts 4, 5, and the bedrock G is excavated to the level of a floor surface 2. Thereby, the bedrock can be excavated in a state that the loosening of the bedrock is suppressed to its max. possible.

Description

DETAILED DESCRIPTION OF THE INVENTION "Field of application in the trL industry" The present invention is applicable to earth excavation surfaces suitable for use in mountain retaining work in excavation work, or primary lining and secondary lining of tunnels and underground cavities. Regarding reinforcement methods.

``Conventional technology'' Conventionally, as one of the construction methods for reinforcing the excavation surface of a tunnel or underground cavity, shotcrete is sprayed onto the excavation surface, and then concrete is applied to the ground around the excavation surface, perpendicular to the excavation surface. A method of reinforcing the excavated surface by driving rock bolts and integrating the shotcrete and the ground through the rock bolts (NAT)
M method... New Austrian Tun
The rock bolt is also applied to a construction method for reinforcing excavated surfaces such as slopes in cut-and-cover construction, in which shotcrete is applied to the excavated surface and By driving rock bolts into the ground so as to be substantially orthogonal to each other, the rock bolts and shotcrete form a pseudo retaining wall on the surface of the excavated surface, thereby reinforcing the excavated surface.

The action of rock bolts in these construction methods is as shown below.

■Fixing rock masses that are likely to loosen to the ground where there is no risk of loosening (suspension action).

■By driving rock bolts through horizontal stratified rock, these layers are connected to form an integrated beam (beam forming action).

■Rock bolts are driven into a block of rock that has a discontinuous surface, and this rock acts like a keystone in a masonry arch, stabilizing the entire excavation surface (keystone effect).

■Suppresses the progression of brittle fracture or plastic deformation of overstressed rock and prevents the rock from separating and falling off (reinforcing action).

"Problems to be solved by the invention" However, in the conventional excavation surface reinforcement method,
Since the rock bolts were installed almost perpendicular to this excavation surface, this rock bolt driving work could only be done after the excavation of the tunnel or slope surface, etc. However, there was a problem in that a considerable amount of loosening occurred in the ground around the excavation surface.

Furthermore, when a rock bolt is driven with the expectation of the effects described in (1) and (2) above, it is necessary to secure the rock bolt to a bedrock where there is no risk of loosening or destruction. The range of the loosened area of the rock around the excavation was determined using the finite element method (F, E, M
Although it can be calculated through analysis, etc., its value is extremely uncertain.

Therefore, in actual construction of rock bolts, the rock bolts have to be installed with a sufficient length, which is uneconomical.

Furthermore, none of the above-mentioned actions of rock bolts (■ to ■) are based on the viewpoint of stabilizing the excavation surface by actively utilizing the strength of the ground surrounding the excavation surface. However, the concept of the NATM method was not fully developed.

The present invention was made in view of the above-mentioned problems, and it suppresses the loosening of the rock around the excavation surface, enables economical construction of rock bolts, and further utilizes the strength of the ground around the excavation surface. The purpose is to provide an excavation surface reinforcement method that can stabilize the excavation surface of a lever.

"Means for solving the problem" The first invention of the present invention is to
A ground excavation surface reinforcement method is configured in which rock bolts or ground anchors extending along the excavation surface formed as a result of the excavation of the ground are driven prior to the excavation of the ground. It solves the problem.

Further, the second invention constitutes a method for reinforcing a ground excavation surface, in which a ground anchor is placed around the ground while excavating the ground. This solves the above problems.

Here, in both of the above inventions, it is preferable that while excavating the ground, rock bolts or ground anchors that are substantially perpendicular to the direction in which the rock bolts etc. extend are driven around the ground.

Further, if necessary, shotcrete may be applied to the excavated surface.

"Function" In the present invention, the rock bolts, etc., which extend forward in the direction of movement of the excavated surface, are used as reinforcing bars around the excavated surface that is formed as a result of excavating the earth, and the surroundings of the rock bolts, etc. A pseudo-reinforced concrete wall is created by imitating the ground of concrete.

"Example" Hereinafter, a method for reinforcing a ground excavation surface, which is an example of the first aspect of the present invention, will be described with reference to FIGS. 1 and 2.

The rod IM caught -7 oil snow 11 and climbed to λn 籟Tji 111
It is a diagram showing the ground on which retaining works have been constructed. In FIG. 1, reference numeral G denotes a ground, and this ground G has been excavated from the ground surface 1 to the flooring surface 2 so that the excavated surface 3 thereof extends in the vertical direction. Moreover, shotcrete 6 is sprayed to a certain thickness on the surface of this excavated surface 3. Rock bolts 4. are attached to the ground G along the excavation surface 3.
5 is driven vertically, and this lock bolt 4
．． A plurality of rock bolts 7 are cast through the shotcrete 6 so as to be substantially perpendicular to the shotcrete 5 .

The tip of the lock bolt 4.5 extends to a position deeper than the floor surface 2. Then, by driving these rock bolts 4.5.7 into the ground G and setting them,
A pseudo retaining wall 8 is formed on the ground G around the excavation surface 3, thereby reinforcing and stabilizing the excavation surface 3.

・Next, referring to Figures 1 and 2, we will explain this ground excavation surface reinforcement method in the order of steps.
Prior to excavation, rock bolts 4.5 are driven into the ground from the ground surface l along the excavation surface 3 that is to be formed with the excavation of this ground G.
．． Inject mortar paste etc. between 5 and the ground G,
Attempt to adhere rock bolt 4.5 to the ground G. The rock bolt 4.5 used in this example is preferably a so-called fully bonded type rock bolt that has been conventionally used, but whether or not to introduce prestress before and after this bonding depends on the geology, etc. It may be taken into consideration as appropriate depending on the construction conditions, etc. In addition, the number of rock bolts 4.5 and their driving positions may be determined appropriately depending on the construction conditions, etc., but from the viewpoint of forming the above-mentioned pseudo retaining wall 8 with these rock bolts 4.5. As can be seen, it is preferable that a plurality of rock bolts be driven in the thickness direction of the pseudo retaining wall 8, and that the tips of the rock bolts 4.5 extend deeper than the floor attachment surface 2. preferable.

Next, this ground G is excavated by 1 to 2 R each, and shotcrete 6 is sprayed on the excavated surface 3 formed by this excavation, and the shotcrete 6 is further penetrated and the rock bolts 4. A rock bolt 7 is driven so as to be approximately perpendicular to the rock bolt 5, and then, as described above, it is bonded to the ground G using mortar paste etc. This shotcrete 6 is applied to the excavated surface 3 to prevent small rock masses from falling off. However, depending on the condition of the ground G, it is not necessarily essential; in other words, the ground G may be excavated without applying the shotcrete 6.

Then, by repeating the above steps, the ground G is excavated up to the flooring surface 2, and the heaping is carried out as shown in FIG.

As explained above, the ground excavation surface hlf strong construction method, which is an embodiment of the first invention, uses rock bolts 4.5.7 and shotcrete 6 to provide pseudo-reinforcement to the ground G around the excavation surface 3. This is a construction method in which a wall 8 is formed, thereby reinforcing and stabilizing the excavation surface 3.

Therefore, the function and effect of this pseudo retaining wall 8 will be explained in detail with reference to FIG. 3.

In FIG. 3, only the pseudo-retaining wall 8 is taken out, and a bending moment due to the sho of the ground G shown in the direction of the arrow is applied during water formation. That is, in this pseudo retaining wall 8,
With the neutral axis 9 as a boundary, a compressive strain region 10 and a tensile strain region 1
1 occurs. In the tensile strain region 11, the rock bolt 5 along the excavation surface 3 resists this bending moment, and in the compressive strain region 1O, the rock bolt 4 and the ground G in this compressive strain region 10 resist. . In other words, the ground G has a compressive strain like the concrete in a reinforced concrete wall, and the rock bolt 5 has a tensile strain like the reinforcing bars in a reinforced concrete wall to counter the bending moment acting on the pseudo retaining wall 8. It is. That is, a pseudo retaining wall 8, which is a pseudo reinforced concrete wall, is formed around the excavation surface 3 of the ground G, and the action of this pseudo retaining wall 8 serves to reinforce and stabilize the excavation surface 3.

Further, the rock bolts 7 cast so as to be substantially perpendicular to the excavation surface 3 perform the function of the conventional rock bolts described above, and are also used in conjunction with the shotcrete 6.
While preventing the growth of the ground G in the strain zone 10, the compressive strain within this compressive strain area IO is restrained, thereby increasing the apparent strength of the ground G. Further, these rock bolts 7 increase the resistance to pulling out the rock bolt 5 from the ground G within the tensile strain region 11, and increase the apparent strength of the rock bolt 5.

In other words, the ground excavation surface reinforcement method, which is an embodiment of the first invention, forms a pseudo retaining wall 8 which is a pseudo reinforced concrete wall on the ground G + around the excavation surface 3, and excavates with this pseudo retaining wall 8. Since this construction method aims at reinforcing and stabilizing the surface 3, it becomes possible to effectively and positively utilize the inherent strength of the ground G.

In addition, in this hli strong construction method, rock bolts 4.5 are driven before excavating the ground G, so excavation of the ground G can be carried out with the loosening of the ground G suppressed as much as possible. Can be done. Further, as described above, it is sufficient for the rock bolts 4.5 to be driven along the excavation surface 3 to have a length along the excavation surface 3 and a penetration length, and therefore, the lock bolts 4.5 that are driven as a whole are By shortening the bolt length, economical construction becomes possible. Therefore, if the rock loosening of the ground G around the excavation surface is suppressed, economical construction of rock bolts becomes possible, and furthermore, the strength of the ground around the excavation surface is used to stabilize this excavation surface. It is possible to realize an excavation surface reinforcement method that is possible.

Next, a method for reinforcing a ground excavation surface, which is an embodiment of the second aspect of the present invention, will be described with reference to FIGS. 4 and 5. Note that the same components as in the embodiment of the first invention are given the same reference numerals, and their explanations will be omitted.

The difference from the embodiment of the first invention is that a plurality of rock bolts 4 are driven diagonally outward of the excavation surface 3, and extend in a direction perpendicular to these rock bolts 4. The point is that a plurality of lock bolts 7 are driven into the ground G. Also, on this excavation surface 3, an earth anchor 13
is poured to stabilize the entire excavation surface 3. Note that instead of this earth anchor 13, a strut or the like may be installed to stabilize the excavation surface 3. Whether or not to install this earth anchor 13 may be determined as appropriate depending on the construction conditions, etc. Of course.

This earth excavation surface reinforcement method will be explained in the order of steps with reference to Figures 4 and 5. First, after excavating the earth G by 1 to 2 m from the ground surface 1, 3
Shotcrete 6 is sprayed onto the concrete 6, and the shotcrete 6 is further penetrated to extend diagonally outward of the excavation surface 3, that is, in the direction of movement of the excavation surface 3 (in this case, the vertical direction of the ground G). Driving the rock bolt 4 and gluing it to the ground G as shown. Then, by repeating the above steps, rock bolts 7 are driven and attached so as to be orthogonal to the rock bolts 4 and across a plurality of these rock bolts 4, resulting in a mountain as shown in FIG. Tomeko is being carried out.

According to the ground excavation surface reinforcement method explained above, by forming a large number of pseudo retaining walls 8 on the ground G in the area around the excavation surface 3, it is possible to form a large pseudo retaining wall as a whole. By obtaining the same effect as the ground excavation surface reinforcement method, which is an embodiment of the invention No. 1, *7. -:, -Agono)
lh+l+ To 11th page 11 Hese Tsu lF++
) Rock bolts 4.5 are not driven prior to the excavation of the upper mountain G, but by driving the rock bolts 4 diagonally outward of the excavation surface 3, a pseudo-rock bolt is installed around the ground G to be excavated. Since the retaining wall 8 is formed, the same effect as the embodiment of the first invention can be obtained as a result.

In addition, the earth excavation surface reinforcement method of the present invention is not limited to the above embodiments. For example, the scope of application of this reinforcement method is not limited to mountain retaining work using the open cut method as in the above embodiment, but it can of course be suitably used for primary lining of excavated surfaces of tunnels, underground cavities, etc. .

In addition, although rock bolts are used in the above embodiments, ground anchors that have almost the same effect on the ground G may also be used. Any member that can form the retaining wall 8) may be appropriately selected from known means.

Furthermore, the rock bolts 7 extending in the thickness direction of the pseudo retaining wall 8 are not essential, and if the ground G is a highly self-supporting rock mass, the rock bolts 7 are unnecessary.

"Effects of the Invention" As explained in detail above, according to the ground excavation surface reinforcement method of the present invention, locks extending forward in the direction of movement of the excavated surface are formed around the excavated surface of the ground to be excavated. A pseudo-reinforced concrete wall is formed by using bolts or ground anchors as reinforcing bars, and the ground around these rock bolts as concrete, thereby effectively and proactively utilizing the natural ground strength of this ground. In addition to making it possible to excavate the ground while suppressing the loosening of the ground as much as possible, the length of the rock bolts etc. used as a whole is shortened. Economical construction becomes possible. Therefore, it suppresses the loosening of the rock around the excavation surface, and enables economical construction of rock bolts, etc.
Furthermore, it is possible to realize an excavation surface reinforcement method that can stabilize the excavation surface by utilizing the strength of the ground around the excavation surface.

[Brief explanation of the drawing]

Figures 1 and 2 are Figure 9 for explaining the ground excavation surface reinforcement method which is an embodiment of the first invention of the present invention, Figure 1 is a diagram showing the completed construction state; Fig. 2 is a diagram showing a state in the middle of construction, Fig. 3 is a diagram for explaining the effects of the present invention, and Figs. FIG. 4 is a diagram showing a completed state of construction, and FIG. 5 is a diagram showing a state in the middle of construction. G...Ground, 3...Excavation surface, 4.5.
7...Rock bolt.

Claims (4)

[Claims] (1) Driving rock bolts or ground anchors around the ground to be excavated, prior to said ground excavation, extending along the excavation surface formed as the ground is excavated, A ground excavation surface reinforcement method characterized by reinforcing the excavation surface. (2) While excavating the ground, rock bolts or ground anchors that are substantially perpendicular to the extending direction of the rock bolts, etc. are driven around the ground. The ground excavation surface reinforcement method described in Section 1. (3) While excavating the ground, install rock bolts or ground anchors around the ground that extend forward in the direction of travel of the excavation surface that is formed as the ground is excavated. A ground excavation surface reinforcement method characterized by reinforcing the excavation surface. (4) While excavating the ground, rock bolts or ground anchors that are substantially orthogonal to the extending direction of the rock bolts, etc. are driven around the ground. The ground excavation surface reinforcement method described in Section 3.