JP4851428B2 - Tunnel segment - Google Patents

Description

  The present invention relates to a segment constituting a tunnel lining.

  A tunnel segment used in a shield tunnel or the like is required to have a strength capable of withstanding the pressure in the tunnel axial direction by a propulsion jack as well as withstanding earth pressure and groundwater pressure.

Conventionally, many tunnel segments are made of reinforced concrete. In such a tunnel segment, the thickness of the tunnel segment is increasing for the purpose of increasing the strength of the tunnel segment as the tunnel cross-section increases.
However, as the thickness of the tunnel segment increases, the material cost increases due to an increase in the amount of concrete and the amount of reinforcing bars, the handling of the tunnel segment during transportation and assembly becomes complicated, and the tunnel excavation is interrupted. There were problems such as the construction cost being increased due to the increased area.

  Therefore, structural performance such as the strength of the tunnel segment and the time of construction can be reduced by mixing fibers into the concrete for the purpose of reducing the main bars and distribution bars and reducing the thickness of the tunnel segment members. In some cases, the thickness is reduced by improving the resistance to corner chipping.

  For example, Patent Document 1 discloses a tunnel segment formed of fiber-reinforced high-fluidity concrete having a circular cross section with a length of 20 to 60 mm, a diameter of 0.3 to 0.9 mm, and an aspect ratio of 30 to 100. A steel short fiber in which a mixing rate of 0.4 to 2.0% by volume with respect to concrete is mixed is disclosed.

  However, although the effect of increasing the strength of the tunnel segment can be obtained by containing short steel fibers, there is a problem that it is difficult to reduce the cost by using a steel material equivalent to a reinforcing bar.

Therefore, by replacing part of the fibers from steel fibers to organic fibers, the material cost may be reduced and the manufacturing cost of the tunnel segment may be reduced.
For example, Patent Document 2 discloses a concrete segment made of a cured product of a cement, pozzolanic fine powder, fine aggregate having a particle diameter of 2 mm or less, a water reducing agent, metal fibers and organic fibers having a circular cross section, and water. Has been. In such a concrete segment, steel fibers having a diameter of 0.01 to 1.0 mm and a length of 2 to 30 mm as metal fibers, vinylon fibers having a diameter of 0.005 to 1.0 mm and a length of 2 to 30 mm as organic fibers, polypropylene One or more kinds of fibers selected from fibers, polyethylene fibers, aramid fibers, and carbon fibers are mixed.

Patent Document 3 discloses a tunnel segment in which a steel fiber having a circular cross section and a polypropylene fiber are mixed, and a steel fiber having a diameter of 35 to 45 kg / m ³ per unit amount of the tunnel segment (diameter 0.6 mm, A tunnel segment is disclosed in which a polypropylene fiber (diameter: 48 μm, length: 20 mm) mixed with a length of 30 mm) and 0.4 to 2.0 kg / m ³ is disclosed.

JP 2004-232258 A JP 2001-207794 A JP 2006-16900 A

  However, for the purpose of increasing the strength of the tunnel segment, if the length of the organic fiber having a small cross-sectional area is increased (30 mm or more), a fiber ball is generated, and the concrete is mixed. May be an obstacle. In addition, increasing the amount of fibers mixed with respect to the volume of the concrete also causes the generation of fiber balls, which sometimes hinders the mixing of the concrete. Therefore, in order to further increase the performance such as the strength of the tunnel segment, it is necessary to increase the member thickness of the tunnel segment, and it is difficult to reduce the thickness of the tunnel segment.

  The present invention has been made in order to solve such problems, and has excellent structural performance and workability, and can reduce the labor and cost of tunnel construction. It is an issue to provide a segment for use.

In order to solve the above problems, for tunnel segments of the present invention, with respect to the total volume of the fibers 0. A segment for tunnel manufactured by fiber reinforced concrete obtained by mixing 3% to 2.0%, wherein the fiber includes metal fiber and organic fiber, and the organic fiber has a rectangular cross-sectional shape. and the length is 30Mm～60mm, yet, it is characterized in that the cross-sectional area is ^{78 × 10 -6 mm 2 ~0.78mm 2} .

According to such a tunnel segment, since the cross-sectional area of the organic fiber is rectangular, the adhesion area to the concrete is increased as compared with the organic fiber having a conventional circular cross section. Therefore, even when organic fibers having the same volume as the conventional fiber reinforced concrete are mixed, the bending toughness of the tunnel segment is improved by increasing the adhesion stress.
Therefore, the tunnel segment can be thinned and the excavation cross-sectional area can be reduced, so that workability and economy can be improved.

The length of the organic fiber in the segment for the tunnel for a 30Mm～60mm, than conventional segment tunnel length of the fiber was 2 mm to 30 mm, because the fixing performance is improved and better structure It is possible to provide a tunnel segment having performance.

The cross-sectional dimension the cross-sectional area is ^{78 × 10 -6 mm 2 ~ 0.78mm} 2 (the diameter when regarded sectional shape as the circle becomes 0.01 mm (10 [mu] m) ~ 1 mm of the organic fibers in the segment for the tunnel since) is, as compared with the conventional segment tunnel, by the incorporation of comparable fibers, that Do is possible to provide a tunnel for segments having excellent structural performance.

  According to the tunnel segment of the present invention, it has excellent structural performance and can reduce the labor and cost of tunnel construction.

  Hereinafter, preferred embodiments of the present invention will be described.

Tunnel segment according to the present embodiment is to total volume 0. It is manufactured by curing fiber reinforced concrete obtained by mixing 3% to 2.0% of fibers into concrete into a predetermined shape.

  In this embodiment, steel fibers (metal fibers) and organic fibers are used as the fibers in a ratio of 1: 1. The ratio of steel fiber to organic fiber is not limited and can be set as appropriate.

  Concrete contains cement, admixture such as pozzolanic fine powder and / or blast furnace slag fine powder, fine aggregate, coarse aggregate, admixture such as water reducing agent, and water as necessary. Consists of a blend. In addition, the material which comprises concrete, the mixing | blending of each material, etc. can be set suitably.

A steel fiber having a circular cross section with a diameter of 0.3 mm to 0.9 mm and a length of 30 mm to 60 mm is used.
In addition, the shape dimension of steel fiber is not limited to this, It is possible to set suitably. Moreover, in this embodiment, although steel fiber shall be used, it is also possible to use another well-known metal fiber instead of steel fiber.

The organic fiber is made of polypropylene fiber and has a cross-sectional shape of a rectangular shape with a length of 30 mm to 60 mm.
The organic fiber has a cross-sectional dimension of 78 × 10 ⁻⁶ mm ^{2 to} 0.78 mm ² , that is, a cross-sectional dimension of 10 μm to ¹ mm when the cross-sectional shape is regarded as a circle.

In this embodiment, polypropylene fiber is used as the organic fiber, but the material that can be used as the organic fiber is not limited thereto, and examples thereof include polyethylene fiber, polyvinyl alcohol fiber, and vinylon fiber. Organic fibers can be used.
In the present embodiment, the organic fiber having a rectangular cross-sectional shape is used, but the cross-sectional shape of the organic fiber is not limited as long as it is a rectangular shape, and may be a square, for example. .

  The tunnel segment according to the present embodiment is manufactured by a kneading process, a placing process, and a curing process.

  The kneading process is generated by cement, admixture such as pozzolanic fine powder and / or blast furnace slag fine powder, fine aggregate, coarse aggregate, admixture such as water reducing agent and water as required. This is done by mixing steel fiber and polypropylene fiber into concrete.

  In the kneading step according to the present embodiment, a dry kneading step in which the powder portion of the concrete is kneaded, a wet kneading step in which the liquid portion is put into the powder portion kneaded in the dry kneading step and kneaded, and a wet kneading step And a fiber kneading step in which fibers are put into the kneaded concrete and kneaded.

  In the drying and kneading step, cement, pozzolanic fine powder, and fine aggregate, which are concrete powder parts, are kneaded in a dry state. The method and means for kneading each material in the dry kneading step are not limited, and may be appropriately selected from known methods and means.

  In the wet kneading step, after the mixing of the powder portion of the concrete is completed, water, a water reducing agent, and the like, which are liquid portions of the concrete, are added and mixed to cause the concrete to exhibit a predetermined fluidity. The kneading method and means in the wet kneading step are not limited, and may be appropriately selected from known methods and means.

In the fiber kneading step, fibers are mixed and further kneaded into the concrete having a predetermined fluidity obtained by the wet kneading step. The kneading method and means in the fiber kneading step are not limited. The mixing timing of the fibers can be changed, and it is appropriately selected from known methods and means that can produce concrete having a predetermined performance. Select and do.
In the fiber kneading step, the steel fiber and the polypropylene fiber are in a ratio of 1: 1, and the volume ratio with respect to the entire fiber reinforced concrete (the sum of the concrete and the fiber) is 0.00 . It inputs so that it may become in the range of 3%-2.0%.

  The placing step is performed by pouring the fiber reinforced concrete kneaded in the kneading step into a mold having a desired shape.

  In the curing process, first, after the fiber reinforced concrete is placed, primary curing is performed in a predetermined temperature environment for 18 hours to 48 hours. After the primary curing, when a predetermined strength is developed, the mold is removed and a secondary curing is performed in a predetermined temperature environment. The secondary curing is not limited to the thermal curing described above, and air curing at room temperature or underwater curing performed with conventional concrete may be employed. Moreover, the curing method of the fiber reinforced concrete is not limited to the above method.

  According to the tunnel segment according to the present embodiment, since the cross-sectional shape of the organic fiber is formed in a rectangular shape, the surface area (circumference) when the cross-sectional area is the same as that of the conventional circular cross-sectional organic fiber. Because the length is large, the adhesion area with concrete increases. Therefore, when compared with a tunnel segment manufactured by mixing the same volume of conventional organic fibers having a circular cross section, the tunnel segment of the present embodiment exhibits higher bending toughness.

  In addition, since organic fibers having a rectangular cross section are used, it is difficult to produce fiber balls. Therefore, workability of concrete mixing is improved, and the manufacturing cost of the tunnel segment can be reduced. Moreover, while the length of the organic fiber used in the conventional fiber reinforced concrete was 30 mm or less, it became possible to use a longer one of 30 mm to 60 mm. In addition, by using organic fibers with a length of 30 mm to 60 mm, the fixing length of organic fibers is long, the bending toughness of the tunnel segment is improved, and a tunnel segment with excellent durability is provided. It becomes possible to do.

As described above, since the tunnel segment according to the present embodiment can improve the bending toughness as compared with the conventional tunnel segment, the tunnel segment can be thinned. Therefore, the amount of concrete can be reduced and the amount of tunnel excavation can be reduced, so that drastic cost reduction can be achieved as tunnel construction.
In addition, the thinning of the tunnel segment facilitates handling with the tunnel segment, and can improve workability.
Moreover, since relatively inexpensive polypropylene fibers are used as the organic fibers, it is possible to reduce the manufacturing cost of the tunnel segment.

In addition, the fiber reinforced concrete according to the present embodiment can ensure fluidity even when the amount of water mixed is small compared to the case of using only steel fibers by using half of the fibers as polypropylene fibers. Is possible. Furthermore, since a high fluidity concrete is comprised by mixing the water reducing agent, it is excellent in the productivity of the segment for tunnels.
In addition, by reducing the moisture content of the fiber reinforced concrete that constitutes the tunnel segment, it is possible to prevent a sudden increase in water vapor pressure due to a sudden rise in temperature due to a fire, etc. A tunnel segment is configured.

  Here, when the cross-sectional areas are the same, the relationship between the circumferences of the rectangular cross section, the square cross section, and the circular cross section is as follows: rectangular cross section> square cross section> circular cross section.

When the long side of the rectangle is α, the short side is β, the square piece is a, and the radius of the circle is r, the circumference of each cross section is as follows.
Rectangular perimeter = 2 (α + β)
Square perimeter = 4a
Circle circumference = 2πr
Here, αβ = a ² = πr ²

  Therefore, it has been proved that by making the cross-sectional shape of the organic fiber rectangular, the surface area of the organic fiber is increased and the adhesion area with the concrete is increased as compared with the conventional circular cross-section. Therefore, the tunnel segment according to the present embodiment has a segment strength superior to that of the conventional tunnel segment.

The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and it goes without saying that the above-described constituent elements can be appropriately changed in design without departing from the spirit of the present invention.
For example, in the tunnel segment according to the present invention, when the shear strength is ensured by mixing steel fibers and organic fibers, the shear reinforcing bars can be omitted or the amount can be reduced.

  Further, in the tunnel segment according to the present embodiment, when the force is sufficiently transmitted to the main bar by the fiber, the distribution bar can be reduced or omitted. Furthermore, when sufficient strength is expressed, the main muscles can be reduced or omitted.

  Hereinafter, a description will be given of the results of a demonstration experiment conducted for confirming the effect of improving the toughness of the tunnel segment by the tunnel segment according to the present invention.

  In this demonstration experiment, a tunnel segment according to the present invention was manufactured and a bending toughness test was performed, and the effect was confirmed by comparing with a tunnel segment constituted by a conventional fiber-reinforced concrete.

In this demonstration experiment, as shown in Table 1, the mixing amount of the fiber with respect to the entire volume of the fiber-reinforced concrete was made with a tunnel segment manufactured with 0.5% steel fiber and 0.5% polypropylene 2 (Example) A bending toughness test was performed on A).
In addition, as a comparative example with the test of Example A, the mixing amount of the fiber with respect to the entire volume of the fiber-reinforced concrete is 1.0% for steel fiber (Comparative Example 1) and 0.5% for steel fiber (Comparison) Example 2) Five types of fibers including 0.5% steel fiber, 0.5% polypropylene 1 (Comparative Example 3), 0.5% steel fiber and 0.5% Polyethylene (Comparative Example 4) Each tunnel segment made of reinforced concrete was subjected to a bending toughness test and compared.
Here, the physical properties of the fibers used in this demonstration experiment are as shown in Table 2.

  FIG. 1 shows the test results of Example A. In the drawing, the vertical axis represents the load, and the horizontal axis represents the vertical displacement. FIG. 1 shows the test results of Comparative Example 1 and Comparative Example 2 together with the test results of Example A.

  As shown in FIG. 1, since Comparative Example 1 can handle a larger load than Comparative Example 2 as a whole, the amount of vertical displacement decreases by increasing the amount of steel fibers mixed in. Proved.

  Moreover, when Example A and Comparative Example 1 are compared, it can be seen that Example A bears a larger load than Comparative Example 1. That is, in the case where half of the fibers mixed with 1% of the total volume are made of polypropylene fibers having a long rectangular cross section (polypropylene 2) and the other half are steel fibers (Example A). It was proved that it was possible to handle a larger load than when all the fibers were steel fibers (Comparative Example 1). This is because the toughness of the tunnel segment is improved by using polypropylene fibers having a large adhesion area and a long fixing length.

  FIG. 2 shows the test results of Comparative Examples 1 to 3. In the drawing, the vertical axis represents the load, and the horizontal axis represents the vertical displacement.

As shown in FIG. 2, the comparative example 3 which mixed the organic fiber (polypropylene 1) and 0.5% of steel fiber with a short length with a circular cross section of 0.5% with respect to the whole volume, and steel fiber only When compared with Comparative Example 2 in which 0.5% is mixed, both show substantially the same linearity, and the bending toughness strength is lower than that in Comparative Example 1 in which only 1.0% of steel fibers are mixed. became.
That is, almost no effect is seen by introducing polypropylene 1 from the relationship between comparative example 3 and comparative example 2, and by replacing some of the steel fibers with polypropylene 1 from the relationship between comparative example 3 and comparative example 1. It has been demonstrated that the strength of the tunnel segment is reduced.

  FIG. 3 shows the test results of Comparative Examples 1, 2, and 4. In the drawing, the vertical axis represents the load, and the horizontal axis represents the vertical displacement.

  As shown in FIG. 3, the comparative example 4 which mixed the organic fiber (polyethylene) and 0.5% steel fiber with a short length with a 0.5% circular cross section with respect to the whole volume, and only steel fiber are mixed. Comparing Comparative Example 1 containing 1.0% and Comparative Example 2 containing only 0.5% steel fiber, Comparative Example 4 is disposed between Comparative Example 1 and Comparative Example 2. That is, although a slight increase in bending toughness strength can be seen by mixing polyethylene with a short cross-section and a short length due to the relationship between Comparative Example 4 and Comparative Example 2, the steel from the relationship between Comparative Example 4 and Comparative Example 1 is seen. It has been demonstrated that the bending toughness of the segment is reduced by replacing the fiber with a short section of polyethylene with a circular cross section.

  Based on the above results, it has been demonstrated that the toughness of the tunnel segment can be improved by making the cross-sectional shape of the organic fiber a rectangular cross-section and increasing the length of the organic fiber to 30 mm or more. It was done.

It is a graph which shows the test result of Example A. It is a graph which shows the test result of a comparative example. It is a graph which shows the test result of a comparative example.

Claims (1)

A tunnel segment manufactured by fiber reinforced concrete obtained by mixing 0.3% to 2.0% of fibers with respect to the entire volume,
The fibers include metal fibers and organic fibers,
The organic fibers, in cross section rectangular, and a length 30Mm～60mm, yet, segment tunnel, wherein the cross-sectional area is 78 × ¹⁰ -6 ^{mm 2} ~0.78mm 2 .

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