JP5441616B2 - Tunnel lining formwork and lining method - Google Patents

Description

  The present invention relates to a formwork for placing secondary lining concrete in a tunnel and a method for placing and lining concrete using the formwork.

  The construction of the tunnel consists of (1) drilling with tunnel excavators such as ground, (2) primary lining with sprayed concrete to suppress and stabilize loosening of the ground, etc. (3) final As a typical lining, it is composed of three work processes called secondary lining to place cast-in-place concrete. In addition, in order to prevent water leakage from the natural ground, a waterproof sheet attachment work may be performed after the primary lining with sprayed concrete.

  In the work process, the secondary lining is performed using a movable arch-shaped formwork that supports the concrete following the primary lining. This mold is an arch-shaped movable mold having a length of around 10 m and is called a centle. The center has a foam panel that faces the concrete surface sprayed by the primary lining and has a surface that has a curvature that is almost the same as the curvature of the tunnel tunnel. The foam panel is spaced a certain distance from the sprayed concrete surface. Thus, a space is formed between the foam panel and the sprayed concrete surface, and the secondary lining concrete can be placed in the space.

  The foam panel is provided with a plurality of windows in place so that concrete can be driven from each window and compacted. The secondary lining is performed over the entire length of the tunnel by placing the concrete for secondary lining while moving the centle in the tunnel axial direction.

  When placing concrete for secondary lining while moving the center in the direction of the tunnel axis, place it so that there is no gap between the placed concrete and the next placed concrete. Must.

  When placing so as to overlap, a part of the foam panel is pressed against the already placed concrete so that the next placed concrete does not leak, but the already placed concrete has sufficient compressive strength. If not, the cracks are likely to occur. For this reason, the lining method for making sufficient compressive strength express reliably is proposed (refer patent document 1).

  In this method, a centle provided with a heater on the inner surface of the foam panel is used so that the overlapped end of the already placed concrete can be heated. Thus, by supplying heat to concrete itself, sufficient compressive strength can be expressed in a short time.

  In addition, as a method of shortening the curing time of lining concrete, the temperature of the closed working space formed inside the cart called centruform that supports the formwork is adjusted with an air conditioner to obtain an appropriate curing temperature. A method has been proposed (see Patent Document 2). In addition, when sufficient curing cannot be performed, the strength development of concrete is delayed, and it takes time to remove the formwork (hereinafter referred to as “demolding”), and as a result, the process may be delayed. . Furthermore, when the mold is removed, due to insufficient strength, concrete may adhere to the outer surface of the foam panel and peel off.

JP 2001-123794 A JP 2008-31715 A

  In the conventional method, using a heater, an air conditioner or the like, heat is applied to the placed concrete to promote the hydration reaction of the cement, so that a predetermined compressive strength is developed at an early stage. For this reason, it does not take time to demold, and the work process can be protected.

  However, when using heaters, air conditioners, etc., there is a problem that equipment costs are required, a separate power source is required, and heating increases the temperature of the work place in the center, and the work environment deteriorates especially in summer. is there.

  The foam panel is provided with I-shaped steel having an I-shaped cross section and H-shaped steel having an H-shaped cross section at regular intervals in order to support concrete by the foam panel. A heater cannot be attached to the part to which such shape steel is joined, and even if the temperature is adjusted with an air conditioner, the heat transfer between the part and the part with only the foam panel is large. In contrast, there is a problem that unevenness occurs in the expression of compressive strength. Therefore, it is difficult for the method of heating to express the compressive strength of the entire cast concrete early and uniformly.

  Therefore, it has been desired to provide a centle that can be provided at a low cost with a simple configuration without causing such problems, and a lining method using the centle.

  In view of the above problems, the present invention installs a panel made of plastic resin and having excellent heat insulation properties (hereinafter referred to as “heat insulation panel”) between the shape steels supporting the foam panel. The concrete placed is kept warm by air (air heated through the foam panel by the heat of hydration reaction of the cement) existing in the space formed by the shape steel and the foam panel.

  The I-shaped steel or the H-shaped steel has a flat plate-shaped first flange having a first bonding surface bonded to the foam panel, and a flat plate-shaped web that is continuous with the first flange and extends perpendicularly to the first bonding surface. And a flat plate-like second flange having a second joint surface continuous to the web and parallel to the first joint surface. For this reason, the heat insulation panel can be installed by being fitted between the second flanges and adjacent to the webs on both sides. Moreover, it is also possible to fix by joining to the back surface of the 1st joint surface of a 1st flange, or the back surface of the 2nd joint surface of a 2nd flange.

  In the above configuration, the heat escapes through the flat web, but the cross-sectional area of the web on the foam panel is extremely small compared to the area of the heat insulation panel covering the foam panel. Therefore, it is possible to prevent the temperature of the concrete from lowering, accelerate the development of the strength of the concrete necessary for demolding, and protect the work process without requiring time until demolding. Such heat retention can be carried out while keeping the concrete temperature substantially constant in the cover thickness direction, and can promote the development of compressive strength throughout the placed concrete, so that deterioration of the quality of the concrete can also be prevented. .

  In consideration of strength, workability, hermeticity, heat retention, and the like, the heat insulating panel can be, for example, a panel made of polypropylene having a predetermined size and thickness. Moreover, since the I-shaped steel or H-shaped steel web extends perpendicularly to the first joint surface by a predetermined length, it is joined to either the first flange side or the second flange side. For example, the heat insulation panels to be installed on both side walls of the arch-shaped tunnel are installed on the first flange side in accordance with the installation position of the centle scaffolding, and installed near the top of the tunnel The heat insulation panel to be installed can be installed on the second flange side in terms of workability. After installing the insulation panel on the centle, it is possible to attach a material made of, for example, foamed polyethylene with cushioning and sealing effect to the end face of the insulation panel for the purpose of preventing the gap between it and the centle. included.

Moreover, since the centle is a movable formwork, it is equipped with a carriage for enabling movement in the tunnel axis direction.

  Moreover, in the present invention, besides the centle provided with the above-described heat insulating panel, a lining method can be provided in which lining is performed while shortening the curing time using this centle. Specifically, a step of placing a centle in which a plastic resin heat insulation panel is installed between the shape steels supporting the foam panel at a predetermined position, the heat insulation panel, the heat insulation panel, the shape steel, and the foam panel is formed. Holding the cast concrete with air (air heated through the foam panel by the heat of hydration of the cement) present in the space to be placed.

The front view which illustrated the place which arranged the centre in which the heat insulation panel was installed in the tunnel mine, and laid the lining concrete. The figure which illustrated the longitudinal section and the heat insulation panel of the lining concrete cut | disconnected by cutting line AA, and a foam panel. The perspective view of the lining concrete cut | disconnected by the cutting line BB, a foam panel, an eye beam, and a heat insulation panel. The perspective view of the lining concrete cut | disconnected by the cutting line CC, a foam panel, an eye beam, and a heat insulation panel.

  FIG. 1 is a front view illustrating a place where a centle provided with a heat insulating panel is placed in a tunnel mine and lining concrete is placed. The tunnel 10 is formed by excavating a natural ground or underground using a tunnel excavator such as a shield machine in which cutter bits as a plurality of cutting members are attached to the tip. After the excavation, the primary lining is performed by spraying concrete immediately so that the surface does not collapse. In addition, before this primary lining, a steel support work may be performed.

  After the loosening of the natural ground is suppressed and stabilized by the primary lining, the centle 20 which is an arch-shaped movable formwork is placed in the tunnel mine. The center 20 is provided with a foam panel 21 having a surface facing the inner wall surface in the circumferential direction of the tunnel 10, and a plurality of panels that are arranged on the back surface of the surface of the foam panel 21 at regular intervals and support the foam panel 21. The I-shaped steel, the carriage 22 for supporting the foam panel 21 and the plurality of I-shaped steels so as to be movable in the tunnel axis direction, and adjusting the distance to set the foam panel 21 at a constant distance from the inner wall surface of the tunnel And a plurality of jacks 23 for the purpose. The tunnel axis direction is the tunnel excavation direction.

  The carriage 22 includes wheels so that it can run on rails laid on the bottom of the tunnel, for example. The carriage 22 can be equipped with a discharge pipe, an exhaust fan, or the like that discharges dust or the like flowing inside the tunnel mine to the outside of the mine. As the jack 23, a jack using hydraulic pressure or water pressure can be used.

  The foam panel 21 is an arch-shaped steel plate having a surface having the same curvature as the circumferential curvature of the inner wall surface of the tunnel 10, and matches the cross-sectional shape of the tunnel 10 from the side wall toward the bottom surface. The portion 21a disposed in the plate is a plate having a surface with a curvature different from the above curvature. Specifically, only the lower edge portion of the portion 21a close to the tunnel bottom surface has a surface with a curvature smaller than the above curvature, and the other has a surface with a curvature larger than the above curvature. . In addition, the foam panel 21 can be moved in the radial direction of the tunnel 10 by the jack 23 connected to the I-shaped steel, and the distance from the inner surface of the tunnel lining which is primary lining is adjusted.

  The I-shaped steel is a steel having an I-shaped cross section, and a taper is formed on the inner surface of the flange, that is, the surface facing the web, the thickness of the portion connected to the web is increased, and the rigidity is increased. There is an H-shaped steel as a shaped steel having a similar structure, but this is a shaped steel having a H-shaped cross section, and is not tapered as in the case of an I-shaped steel. In addition to T-shaped steel, angle steel, flat steel, grooved steel, and Z-shaped steel, the shape steel is not excellent in cross-sectional efficiency and rigidity like I-shaped steel and H-shaped steel. As a support member for appropriately supporting the member 21, I-shaped steel or H-shaped steel is preferable.

  The centle 20 is arranged at an appropriate position in the tunnel axis direction, and the wheel of the carriage 22 is stopped and stopped completely. Then, the foam panel 21 is moved in the radial direction of the tunnel 10 by the jack 23, and the primary lining is performed. It is arranged at a certain distance from the lining of the inner surface of the tunnel formed by the concrete sprayed in the above, and a space is formed between the lining and the foam panel 21, and the concrete 24 is placed in the secondary wall. Perform lining. For example, when the secondary lining is performed by placing concrete having a thickness of about 0.3 m, the jack 23 is adjusted so that the surface of the foam panel 21 comes to a position about 0.3 m away from the lining.

  The foam panel 21 is provided with a plurality of windows, and concrete can be driven from the windows and the concrete can be driven. A transparent plate such as tempered glass or acrylic plate that can be opened and closed is attached to these windows so that the concrete after pouring does not flow into the inside. This window can also be used to compact the cast concrete.

  When the concrete 24 is placed in this manner, a load is applied to the foam panel 21, but the foam panel 21 to which the load is applied is supported by the I-shaped steel, so that the concrete is cured and the centle 20 is removed. Later, an arch-shaped tunnel cross section is formed.

  Here, concrete is made of cement, aggregate, water, and an admixture, and these can be blended to obtain the target strength, durability, and workability. This strength is determined by the water sentiment ratio, and water can be reduced using a chemical admixture to obtain a high strength.

  Since concrete cannot keep its own shape until it hardens, it must be poured into the mold and cured for a predetermined time inside the mold until it begins to harden. By curing for a predetermined time, concrete having a predetermined compressive strength can be obtained.

  When placing concrete, it is necessary to ensure the uniformity of the concrete and prevent initial defects. Therefore, ventilate using a vibrator or wood to eliminate unfilled parts and prevent material separation. In addition, in order to raise concrete strength, it is also possible to arrange rebar and perform secondary lining as reinforced concrete. Curing is performed by covering the surface of the concrete so that the waterproofing of the concrete, scratches, etc. are not caused. However, in the embodiment shown in FIG. The state is maintained until it is cured.

  The foam panel 21 is made of steel because a load is applied by the cast concrete 24 and a certain degree of strength is required. If the steel foam panel 21 is left uncovered, construction in winter is particularly important. In this case, the heat of the placed concrete 24 escapes, and it takes a long time until the concrete 24 develops the compressive strength necessary for demolding. Therefore, in the present invention, a heat insulating panel 25 made of plastic resin is installed, the heat insulating panel 25 functions as a heat insulating material, and further, in a space formed by the heat insulating panel 25, the foam panel 21, and the I-shaped steel. Certain air (air heated through the foam panel by the heat of hydration reaction of the cement) also functions as a heat insulating layer to accelerate the development of the necessary compressive strength of the concrete 24 and harden the concrete 24 at an early stage.

  As shown in FIG. 2, the heat insulation panel 25 is installed without gaps between the I-shaped steels so as to cover the inner wall surface of the tunnel 10. Here, the cross section of the I-shaped steel web 26 is shown by a solid line between the heat insulating panels 25, but in this way most of the cross section of the web 26 is covered with the heat insulating panel 25. Since it is not only, sufficient heat insulation effect can be obtained.

  The heat insulating panel 25 can be made of, for example, polyethylene, polyethylene terephthalate, polyvinyl chloride, polypropylene or the like in consideration of strength, workability, airtightness, heat retention, and the like. Polypropylene is light because it has the smallest specific gravity among fibers, and it has high strength, good sealing properties, no hygroscopicity, and is strong against chemicals. It is preferable as the heat insulation panel 25 of the present invention utilized as the above. In addition, by forming a hollow structure by processing, it is possible to achieve higher heat insulation and heat insulation.

  As shown in FIG. 3, the I-shaped steel has a flat plate-like first flange 27 having a first joint surface joined to the foam panel 21, and continues to the first flange 27 and is perpendicular to the first joint surface. And a flat plate-like second flange 28 having a second joint surface continuous to the web 26 and parallel to the first joint surface. For this reason, the heat insulation panel 25 can be installed by being fitted between the second flanges 28 and adjacent to the webs 26 on both sides. Therefore, no tool is required.

  The I-shaped steel has a second flange 28, which serves as a stopper, so that the fitted insulation panel 25 cannot be easily removed. Moreover, the heat insulation panel 25 is arrange | positioned adjacent to the web 26, and the up-and-down left and right edge part of the heat insulation panel 25 and one surface of the web 26 can contact | adhere, and it can prevent further removing.

  In order to completely fix the first flange 27, the first flange 27 may be installed on the rear surface of the first joint surface or the second flange 28 on the rear surface of the second joint surface. For example, it can be attached to the back surface of an adhesive made of urethane resin or epoxy resin.

  The I-shaped steel web 26 extends perpendicularly to the first joint surface by a predetermined length, and may be installed on any of the first flange 27 side, the second flange 28 side, the center portion, and the like. However, for example, as shown in FIG. 4, the heat insulating panels 25 installed on both side walls of the arch-shaped tunnel are installed on the first flange 27 side in accordance with the installation position of the scaffold of the centle 20. The heat insulation panel 25 installed near the upper part is located on the second flange 28 side as shown in FIG. 3 because it is difficult to install on the first flange 27 side because the construction position is above. it can.

When the heat insulation panel 25 is installed at the position shown in FIG. 3, in addition to the thickness of the first flange 27, the width of the web 26 becomes a position away from the foam panel 21, and the space 30 formed therebetween is sufficiently large. Therefore, a sufficient heat insulating effect can be obtained by the air inside thereof (air heated through the foam panel by the heat of hydration reaction of the cement). This is because air has a lower thermal conductivity than the steel foam panel 21 and I-shaped steel, and does not allow the heat of the cast concrete to escape into the tunnel mine. Incidentally, the thermal conductivity of iron is 84 W · m ⁻¹ · K ⁻¹ , the thermal conductivity of polypropylene is about 0.1 W · m ⁻¹ · K ⁻¹ , and the thermal conductivity of air is about 0 0.02 W · m ⁻¹ · K ⁻¹ .

  On the other hand, when the heat insulation panel 25 is installed at the position shown in FIG. 4, the space 30 is reduced because the heat insulation panel 25 is separated from the foam panel 21 only by the thickness of the first flange 27. When the fluid is in relative motion, a solid film exists between the solid and the gas, which is a very thin region where a laminar flow state is maintained at the phase boundary, and heat transfer in this region is extremely slow. In this region, the movement phenomenon of the entire system becomes rate-limiting. Since this boundary film exists at a position very close to the solid, if it is as far away as the thickness of the first flange 27, the heat transfer is very slow, and the heat does not escape easily. A sufficient heat insulating effect can be obtained.

  In addition, keeping the concrete in this way can be cured while maintaining the temperature almost uniformly in the direction of the cover thickness over the entire placed concrete, so it can be cured without causing temperature unevenness, The compressive strength can be expressed uniformly in the cover thickness direction over the entire cast concrete. That is, since the temperature distribution in the thickness direction of the placed concrete is uniform (almost the same temperature if the position is the same thickness from the concrete surface), temperature unevenness is eliminated and the strength is uniform. Moreover, deterioration of the quality of concrete can be prevented by expressing the compressive strength uniformly in this way.

  In addition, as long as sufficient space can be secured in connection with the installation position of the scaffold of the centle 20, as shown in FIG. 3, instead of installing the heat insulation panel 25 at the position shown in FIG. It is preferable to install on the side of the second flange 28, take a large space 30, and enhance the heat insulation effect.

  In the above, a simple heat insulating panel 25 made of plastic resin is used. The heat insulating panel 25 is made by attaching a heat insulating material such as polyurethane foam, phenol foam, polystyrene foam, glass wool, rock wool to a panel made of polypropylene. It is also possible to use a panel in which the above heat insulating material is sandwiched between the formed panel or two polypropylene panels. The heat insulation panel 25 is made of, for example, a material made of polyethylene foam having a cushioning property and a sealing effect on the end surface portion of the heat insulation panel 25 for the purpose of preventing a gap from being generated between the heat insulation panel 25 and the center. It can also be attached. If necessary, the exposed portion of the I-shaped steel or H-shaped steel can be covered with a heat insulating material to enhance the heat insulating effect.

  The thickness of the heat insulation panel 25 is set so that the heat insulation panel 25 is fitted between the first flange 27 and the second flange 28 made of I-shaped steel or H-shaped steel. It is smaller than the width of the web 26, which is the distance between the two, and is fitted between adjacent I-shaped steels. Since the thermal conductivity of air is smaller than that of the heat insulating panel 25, it is preferable to make it as thin as possible and to make a wide space. However, if it is too thin, it is easy to break and the sealing performance is deteriorated, so a thickness of about 0.5 to 2 cm is preferable.

  The present invention can also provide a lining method for lining while shortening the curing time using this centle in addition to the centle having the above-described heat insulation panel installed. This lining method supports a foam panel. Placing a centle with a plastic resin insulation panel between the sections to be placed in place, the insulation panel, and the air present in the space formed by the insulation panel, the section steel and the foam panel ( Maintaining the temperature of the cast concrete with the air heated through the foam panel by the heat of hydration reaction of the cement.

  The tunnel lining form of the present invention and the lining method using the form of the present invention have been described in detail with reference to the embodiments shown in the drawings, but the present invention is limited to the above-described embodiments. However, other embodiments, additions, changes, deletions, and the like can be changed within a range that can be conceived by those skilled in the art, and as long as the operations and effects of the present invention are exhibited in any aspect, It is included in the scope of the present invention. Therefore, the installation of the heat insulation panel can be performed by fastening the second flange with a bolt and a nut in addition to the above-described bonding with the adhesive. Moreover, since the heat insulation panel can be installed simply by fitting, it can be installed by fitting it when necessary, and it can be removed otherwise.

DESCRIPTION OF SYMBOLS 10 ... Tunnel, 20 ... Centle, 21 ... Foam panel, 21a ... part, 22 ... Dolly, 23 ... Jack, 24 ... Concrete, 25 ... Thermal insulation panel, 26 ... Web, 27 ... First flange, 28 ... Second flange, 30 ... space

Claims (7)

A formwork used for placing concrete for lining on the inner wall surface of an excavated tunnel,
An arch-shaped foam panel having a surface facing the inner wall surface of the tunnel;
A plurality of support members provided to be arranged at regular intervals on the back surface of the surface, and supporting the foam panel;
A plurality of heat insulation panels installed between each of the support members and adjacent to both of the support members and spaced from the foam panel to form a space;
The concrete for lining placed between the inner wall surface of the tunnel and the foam panel by the heat insulating panel and air heated through the foam panel by heat of hydration reaction of cement existing in the space A formwork characterized by keeping warm.   The said heat insulation panel is a formwork of Claim 1 which is a panel made from a polypropylene.   The said heat insulation panel is a formwork of Claim 1 formed from the panel made from a polypropylene, and a heat insulating material.   The said formwork is further equipped with the trolley | bogie which mounts the said foam panel, these several support members, and these heat insulation panels, and makes it movable to a tunnel axial direction. The formwork described. The support member includes a first flange having a first joint surface joined to the foam panel, a second flange having a second joint surface parallel to the first joint surface, the first joint surface, and the first Two I-shaped steels or H-shaped steels, each of which is formed of a web extending perpendicularly to the joint surface and connecting the first flange and the second flange;
The said heat insulation panel is a formwork of any one of Claims 1-4 installed by inserting between the said I-shaped steel or H-shaped steel.   The said heat insulation panel is a formwork of Claim 5 further joined to the back surface in any one of the said 1st joining surface or the said 2nd joining surface of the said I-shaped steel or H-shaped steel. A lining method in which a formwork is placed on an excavated tunnel inner wall and concrete for lining is placed,
A foam panel having a surface facing the inner wall surface of the tunnel; a plurality of support members that are arranged on the back surface of the surface at regular intervals; and that support the foam panel; and between the support members, and Placing the formwork in the tunnel pit, including a plurality of thermal insulation panels that are adjacent to both of the support members and are disposed to form a space spaced from the foam panel;
Placing the lining concrete between the inner wall surface of the tunnel and the foam panel;
A method of covering, comprising: heat-insulating the placed concrete for lining by the heat insulating panel and air heated through the foam panel by heat of hydration reaction of cement present in the space.