JP5461867B2 - Curing method for tunnel lining concrete - Google Patents

Description

The present invention relates to a method for curing tunnel lining concrete.

  In order to prevent drying of the lining concrete of the tunnel, the lining concrete is cured. Conventionally, there is a curing device for curing the lining concrete that includes a cart that can be raised and lowered, a frame that is fixed to the cart, and a water-permeable mat that is supported by the frame (Patent Document 1). reference).

  When curing the lining concrete, first, the curing device is placed in the tunnel. Next, the cart is raised so that the water-permeable mat is in close contact with the lining concrete. Thereafter, the water-permeable mat is connected to a water supply source, and water is supplied from the water supply source to the water-permeable mat. Thereby, water can be given to the lining concrete from the water-permeable mat, and drying of the lining concrete can be prevented.

  After curing the lining concrete, water supply to the water permeable mat is stopped, and the connection of the water permeable mat to the water supply source is released. Next, the cart is lowered so that the tight adhesion of the water-permeable mat to the lining concrete is released. Thereafter, the carriage is moved in the axial direction of the tunnel so that the water-permeable mat is moved to the face side. Thereafter, the lining concrete is cured on the face side of the already-cured lining concrete. In this way, the movement of the water-permeable mat and the curing of the lining concrete are repeated.

JP 2007-231517 A

  By the way, if water supply to the water-permeable mat is stopped during the curing of the lining concrete, the water-permeable mat is dried and water cannot be supplied from the water-permeable mat to the lining concrete. For this reason, water supply to the water-permeable mat must be continued during curing of the lining concrete. By continuing the water supply to the water permeable mat, a large amount of water drips from the water permeable mat. For this reason, a lot of cost is required to discharge the water dripping from the water-permeable mat to the outside of the tunnel.

  Since the water supply to the water permeable mat must be continued during the curing of the lining concrete, the water permeable mat must be connected to the water supply source every time the water permeable mat is moved. For this reason, much labor and time are required to connect the water-permeable mat to the water supply source, and the lining concrete cannot be cured efficiently.

  It is an object of the present invention to reduce the cost required to discharge water dripping from a water-permeable mat for curing the lining concrete of a tunnel to the outside of the tunnel, and to the water supply source of the water-permeable mat It is possible to reduce the labor and time required for the connection of the lining concrete and enable efficient curing of the lining concrete.

  In the present invention, a water absorbing material is disposed inside the water-permeable mat, and the water-absorbing material absorbs water when water is supplied to the water-permeable mat so that the water-permeable mat can retain water therein. Even if water supply to the water-permeable mat is stopped, water can be supplied from the water-permeable mat to the lining concrete. Thereby, the amount of water dripping from the water-permeable mat is reduced, and the cost required for discharging the water dripping from the water-permeable mat to the outside of the tunnel is reduced. In addition, it is not necessary to connect the water-permeable mat to the water supply source every time the water-permeable mat moves, and the labor and time required to connect the water-permeable mat to the water supply source are reduced.

When curing the lining concrete, first, a curing device is placed in the tunnel . The curing device includes a carriage that is movable in the axial direction of the tunnel, a frame that can be moved up and down on the carriage, and a water-permeable mat that is supported by the frame and has a water absorbing material disposed therein. . Next, the frame is raised so that the water-permeable mat is in close contact with the lining concrete. Thereafter, the water-permeable mat is connected to a water supply source, and water is supplied from the water supply source to the water-permeable mat. Thereafter, water supply to the water-permeable mat is stopped, and the water-permeable mat is kept in close contact with the lining concrete.

  After the water supply to the water-permeable mat is stopped, the water-permeable mat starts to dry over time. When the water-permeable mat starts to dry, water is discharged from the water absorbing material. Thereby, even after the water supply to the water permeable mat is stopped, the water permeable mat can be maintained in a wet state, and water can be supplied from the water permeable mat to the lining concrete. Drying of concrete can be prevented. By stopping the water supply to the water permeable mat, the amount of water dripping from the water permeable mat can be reduced, and the cost required for discharging the water dripping from the water permeable mat to the outside of the tunnel is reduced. be able to.

  After curing the lining concrete, the connection of the water-permeable mat to the water supply source is released. Thereafter, the frame is lowered so that the permeable mat is released from the lining concrete, and the carriage is moved in the axial direction of the tunnel so that the permeable mat is moved to the face side. Let Thereafter, the lining concrete is cured on the face side of the already-cured lining concrete. In this way, the movement of the water-permeable mat and the curing of the lining concrete are repeated.

  Since water can be supplied from the water-permeable mat to the lining concrete even after the water supply to the water-permeable mat is stopped, the water-permeable mat is connected to the water supply source each time the water-permeable mat is moved. There is no need to do. For this reason, the effort and time required for the connection of the water-permeable mat to the water supply source can be reduced, and the lining concrete can be cured efficiently.

  The water-permeable mat has two first parts spaced apart in a first horizontal direction, and a second part between the first parts, and the first part is disposed inside the second part. A pipe extending in a second horizontal direction orthogonal to the horizontal direction is disposed, and the pipe has at least one water discharge through hole provided in each side portion of the pipe.

  The tunnel lining concrete curing method according to the present invention includes a first step of preparing a water permeable mat having a water absorbing material disposed therein, and a second step of closely attaching the water permeable mat to the lining concrete. A third step of supplying water to the water permeable mat, a fourth step of stopping water supply to the water permeable mat, and a fifth step of maintaining adhesion of the water permeable mat to the lining concrete.

  In the curing method, after the fifth step, a sixth step of investigating the amount of water contained in the permeable mat, and whether to supply water to the permeable mat according to the amount of water. A seventh step of determining whether or not to supply water to the water permeable mat in the seventh step, performing the third step to the fifth step, and the water permeable mat in the seventh step. If it is decided not to supply water, the fifth step is included.

  By the way, when almost all of the water sucked up by the water absorbing material is discharged from the water absorbing material, even if the water permeable mat is dried, water is not discharged from the water absorbing material, and the water permeable mat is in a wet state. It becomes impossible to maintain and water cannot be given to the lining concrete from the water-permeable mat. By investigating the amount of water contained in the water-permeable mat and determining whether or not to supply water to the water-permeable mat according to the amount of water, the lining concrete is made from the water-permeable mat. The water-permeable mat can be supplied with water only when a sufficient amount of water is not contained in the water-permeable mat so that water can be supplied to the water-permeable mat. Thereby, it is possible to prevent water from being supplied to the water-permeable mat excessively while preventing the water-permeable mat from being dried, and to appropriately supply water to the water-permeable mat.

  In the first step, the curing method includes a carriage that is movable in the axial direction of the tunnel, a frame that is movable up and down on the carriage, and the water-permeable mat that is supported by the frame. Preparing a device, measuring the weight of the curing device before the third step to obtain a first measurement value, after the fifth step, measuring the weight of the curing device before the sixth step. Measurement may be performed to obtain a second measurement value, and the sixth step may include obtaining a difference between the first measurement value and the second measurement value.

  By the way, generally, it is difficult for an operator to approach the water-permeable mat, and it is difficult for the worker to confirm the wet state of the water-permeable mat visually or by hand. Since the investigation of the amount of water is performed by measuring the weight of the curing device, the worker can know the wet state of the water permeable mat without approaching the water permeable mat.

  In the first step, the curing method includes a carriage that is movable in the axial direction of the tunnel, a frame that can be moved up and down on the carriage, and the water-permeable mat supported by the frame, Providing a curing device in which a portion of the water permeable mat is removable from another portion; removing the portion of the water permeable mat from the other portion prior to the third step; Measuring the weight of the portion to obtain a first measurement value, attaching the portion of the water-permeable mat to the other portion before the third step, and after the fifth step, the sixth step Removing the part of the water-permeable mat from the other part before measuring, obtaining a second measurement value by measuring the weight of the part of the water-permeable mat, in the sixth step There are can be made include determining a difference between said second measured value and the first measured value.

  The water-permeable mat has two first parts spaced apart in a first horizontal direction, and a second part between the first parts, and the first part is disposed inside the second part. A pipe extending in a second horizontal direction perpendicular to the horizontal direction is arranged, and the pipe has at least one water discharge through hole provided in each side portion of the pipe, and the curing method includes: In the second step, the water-permeable mat is brought into close contact with the lining concrete so that the first portion and the second portion are disposed on the side wall portion and the arch portion of the tunnel, respectively, in the third step, Supplying water to the pipe so that water flows from the pipe to the water-permeable mat through the through hole, and stopping water supply to the pipe in the fourth step.

  According to the present invention, since the water-absorbing material is disposed inside the water-permeable mat for curing the lining concrete, the water-absorbing material absorbs water when water is supplied to the water-permeable mat, whereby the water-permeable mat is used. Can retain water therein, and can supply water to the lining concrete from the water-permeable mat even when the water supply to the water-permeable mat is stopped. Accordingly, it is possible to reduce the amount of water dripping from the water permeable mat when curing the lining concrete, and it is possible to reduce the cost required for discharging water dripping from the water permeable mat to the outside of the tunnel. .

  In addition, when water supply to the water-permeable mat is stopped, water can be supplied from the water-permeable mat to the lining concrete. Therefore, when the movement of the water-permeable mat and the curing of the lining concrete are repeated. It is not necessary to connect the water-permeable mat to the water supply source every time the water-permeable mat moves, and the labor and time required to connect the water-permeable mat to the water supply source can be reduced. Thereby, curing of the lining concrete can be performed efficiently.

The longitudinal cross-sectional view of the curing apparatus (2nd curing apparatus) which concerns on this invention. Sectional drawing of the 1st curing apparatus in the line 2 of FIG. Sectional drawing of the 2nd curing apparatus in the line 3 of FIG. FIG. 4 is an enlarged cross-sectional view of a water permeable mat taken along line 4 in FIG. 3.

  As shown in FIG. 1, a curing facility 14 is used for curing the lining concrete 12 of the tunnel 10. The curing equipment 14 includes a curing device (first curing device) 16 that cures the lining concrete 12 without supplying water, and a curing device (second curing device) 18 that cures the lining concrete 12 by supplying water. Including. The lining concrete 12 is formed using a movable formwork 20.

  As shown in FIG. 2, the first curing device 16 includes a carriage 22 movable in the axial direction of the tunnel 10, a frame 24 fixed to the carriage, a sheet receiving base 26 fixed to the frame, And a water-impermeable sheet 28 attached to the sheet cradle.

  The carriage 22 is a pair of horizontal members spaced in the first horizontal direction (left-right direction in FIG. 2), each extending in a second horizontal direction (depth direction in FIG. 2) perpendicular to the first horizontal direction. 22a and a plurality of wheels 22b attached to each horizontal member at intervals in the second horizontal direction. The carriage 22 is movable in the second horizontal direction. A bottom concrete 30 is provided on the lining concrete 12 in the invert portion 10a of the tunnel 10, and is spaced on the bottom concrete in the width direction of the tunnel 10, each in the axial direction of the tunnel 10. A pair of extending rails 32 is installed. Wheels 22b attached to one horizontal member 22a of the carriage 22 are arranged on one rail 32, and wheels 22b attached to the other horizontal member 22a are arranged on the other rail 32, respectively.

  The frame 24 includes a plurality of frame members 34 that are disposed on the carriage 22 at intervals in the second direction and are each coupled to the carriage 22. Each frame member 34 has a pair of columns 34 a spaced apart in the first horizontal direction and a beam 34 b connecting the columns, and one column 34 a is connected to one horizontal member 22 a of the carriage 22. The other column 24 b is coupled to the other horizontal member 22 a of the carriage 22. Each frame member 34 is attached to each column 34a at an interval in the vertical direction. Each of the frame members 34 extends from the column 34a outward in the first horizontal direction, and the first horizontal to the beam 34b. And a plurality of vertical members 34d, which are spaced apart in the direction and each extend upward from the beam 34b.

  The sheet cradle 26 has a shape corresponding to the surface shape of the lining concrete 12. The sheet cradle 26 has a plurality of upwardly projecting arch members 26a that are spaced in the second horizontal direction and are parallel to each other, and each of them is orthogonal to the arch member 26a and attached to the arch member 26a. And a plurality of girders 26b parallel to each other. Each arch member 26a is coupled to a column 34a, a horizontal member 34c, and a vertical member 34d of the frame member 34. The water-impermeable sheet 28 is disposed on the sheet receiving base 26 and is secured to the arch member 26a or the girder 26b. The water-impermeable sheet 28 can be a vinyl sheet. The water-impermeable sheet 28 is supported on the frame 24 via the sheet receiving base 26.

  As shown in FIG. 1, the first curing device 16 is disposed between one end portion of the water-impermeable sheet 28 in the second horizontal direction and the sheet receiving base 26, and the one end portion of the water-impermeable sheet 28. The first blocking means 36 that blocks the gap between the lining concrete 12 and the other horizontal end of the water-impermeable sheet 28 in the second horizontal direction and the sheet receiving base 26, and the water-impermeable sheet 28. And a second closing means 38 for closing a gap between the other end portion and the lining concrete 12. Each of the first closing means 36 and the second closing means 38 is made of an inflatable rubber balloon. The first closing means 36 is fixed to one outermost arch member 26 a of the sheet receiving table 26, and the second closing means 38 is fixed to the other outermost arch member 26 a of the sheet receiving table 26.

  As shown in FIGS. 3 and 4, the second curing device 18 includes a carriage 40 that is movable in the axial direction of the tunnel 10, a frame 42 that can be moved up and down on the carriage, and supported by the frame. And a water-permeable mat 46 in which a water-absorbing material 44 is disposed.

  The carriage 40 has a pair of horizontal members 40a spaced in the first horizontal direction, each extending in the second horizontal direction, and a plurality of carriages attached to the horizontal members at intervals in the second horizontal direction. Wheel 40b. The carriage 40 is movable in the second horizontal direction. The wheel 40b attached to one horizontal member 40a of the carriage 40 is arranged on one rail 32, and the wheel 40b attached to the other horizontal member 40a is arranged on the other rail 32, respectively.

  The frame 42 includes a plurality of frame members 48 that are disposed on the carriage 40 at intervals in the second direction and are each coupled to the carriage 40. Each frame member 48 has a pair of columns 48a spaced apart in the first horizontal direction and a beam 48b connecting the columns, and one column 48a is connected to one horizontal member 40a of the carriage 40. The other column 48 a is coupled to the other horizontal member 40 a of the carriage 40. Each frame member 48 is attached to each column 48a, and is attached to the beam 48b with a horizontal member 48c extending outward from the column in the first horizontal direction. Has a plurality of vertical members 48d extending upward from the beam 48b.

  The second curing device 18 has a mat cradle 50 attached to the frame 42. The mat cradle 50 has a shape corresponding to the surface shape of the lining concrete 12. The mat cradle 50 has a shape corresponding to the shape of the top portion 52 having a shape corresponding to the shape of the arch portion 10b of the tunnel 10 and one side wall portion 10c of the tunnel 10 pivotally attached to one end of the top portion. It has a first side portion 54 and a second side portion 56 that is pivotally attached to the other end of the top portion 52 and has a shape corresponding to the shape of the other side wall portion 10 c of the tunnel 10. When viewed in a plane perpendicular to the second horizontal direction, the first side portion 54 of the mat base 50 is rotatable with respect to the top portion 52 around the one end of the top portion 52, and the second side of the mat base 50. The side portion 56 is rotatable with respect to the top portion 52 around the other end of the top portion 52. The top 52 of the mat cradle 50 is fixed to the frame 42.

  The mat cradle 50 includes a plurality of upwardly projecting arch members 50a that are spaced apart in the second horizontal direction and are parallel to each other, each orthogonal to the arch member 50a and fixed to the arch member. And a plurality of girders 50b parallel to each other. Each arch member 50a is coupled to a column 48a, a horizontal member 48c, and a vertical member 48d of the frame member 48 at the top 52 of the mat base 50.

  The second curing device 18 is configured such that the first side portion 54 of the mat cradle 50 is attached to the first side portion 54 of the mat cradle 50 and the other end portion is attached to the frame 42. A first rotating means 58 for rotating, and a second side portion 56 of the mat base 50 having one end portion attached to the second side portion 56 of the mat base 50 and the other end portion attached to the frame 42, respectively. And a second rotation means 60 for rotating the rotation. Each of the first rotating means 58 and the second rotating means 60 is a jack. The first rotating means 58 and the second rotating means 60 are used for bringing the water-permeable mat 46 into close contact with the lining concrete 12 or releasing the close contact.

  The second curing device 18 has lifting means 62 attached to the carriage 40 for raising and lowering the carriage. The lifting / lowering means 62 includes a plurality of jacks 62a attached to the horizontal members 40a of the carriage 40 at intervals in the second horizontal direction. Each jack 62 a has an upper end fixed to the horizontal member 40 a and a lower end directed to the bottom concrete 30. The lifting / lowering means 62 is used together with the first rotating means 58 and the second rotating means 60 to bring the water-permeable mat 46 into close contact with the lining concrete 12 or release the close contact.

  The water permeable mat 46 is disposed on the mat base 50 and is fixed to the mat base. The water permeable mat 46 is fixed to the mat base 50 by, for example, a fixing means (not shown) such as a clamp. The water permeable mat 46 is supported by the frame 42 via the mat cradle 50. The water permeable mat 46 includes two first portions 64 spaced apart in the first horizontal direction, and a second portion 66 located between the first portions. One first portion 64 is fixed to the first side portion 54 of the mat base 50 and the other first portion 64 is fixed to the second side portion 56 of the mat base 50. The second portion 66 is fixed to the top portion 52 of the mat base 50.

  A pipe 68 extending in the second horizontal direction is disposed inside the second portion 66 of the water permeable mat 46. The pipe 68 has at least one water discharge through-hole 72 provided on each side 70 of the pipe (FIG. 4). A plurality of through holes 72 spaced in the second horizontal direction may be provided in each side portion 70 of the tube 68, and one through hole 72 is provided in each side portion 70 of the tube 68. It may be. The pipe 68 is used for supplying water to the water-permeable mat 46. A plate material 74 such as a plywood is disposed under the water-permeable mat 46. A water-impermeable sheet (not shown) that prevents water from entering the plate material may be disposed between the water-permeable mat 46 and the plate material 74, and the water-impermeable sheet 46 is disposed between the water-permeable mat 46 and the plate material 74. The water-permeable mat 46 may be in contact with the plate material 74 without the disposing sheet.

  The water permeable mat 46 is made of a nonwoven fabric. The nonwoven fabric is, for example, a long fiber polyester nonwoven fabric or a short fiber polyester nonwoven fabric. The thickness of the water permeable mat 46 is, for example, in the range of 1 cm to 3 cm. The water absorbing material 44 is made of a water absorbing resin. Examples of the water-absorbent resin include polyacrylic acid resins, starch resins, poval resins, and cellulose resins. The water-absorbing resin may be a temperature-sensitive water-absorbing and draining resin (thermogel) (trade name, manufactured by Kojin Co., Ltd.) having high water retention and temperature sensitivity. The water-absorbent resin can be Aqualic CS-6 (trade name, manufactured by Nippon Shokubai Co., Ltd.), which has a high water retention and excellent salt resistance, and has a modified acrylic crosslinked polymer as a main component. The water-absorbent resin can be Aquaric CS-7 (trade name, manufactured by Nippon Shokubai Co., Ltd.) having excellent heat resistance. The water-permeable mat 46 is manufactured by, for example, injecting a liquid obtained by dissolving a powdery water-absorbing resin in water into a mat made of nonwoven fabric.

  In the example shown in FIG. 1, the length 76 of the first curing device 16 is equal to the length of the movable mold 20 and is 10.5 m, and the length 78 of the second curing device 18 is the first curing device 18. It is twice the length 76 of 16 and is 21.0 m. The second curing device 18 has a first half 80 and a second half 82 having the same length. The rear half 80 is connected to the front half 80 by a connecting member 84.

  When curing the lining concrete 12, first, a first curing device 16 and a second curing device 18 are prepared. Next, as shown in FIG. 1, the 1st curing apparatus 16 is arrange | positioned in the back (left side of drawing) of the mobile formwork 20, and it connects with the mobile formwork 20 by the connection means 86 like a wire rope. . Thereafter, the movable mold 20 is placed inside the first region of the tunnel 10, and the lining concrete 12 is formed by the movable mold 20 in the first region, and then demolded. Thereafter, the mobile mold 20 is moved forward (to the right in the drawing) by a distance corresponding to the length of the mobile mold 20 so that the first curing device 16 is disposed inside the first region of the tunnel 10. Move. Thereby, the carriage 22 of the first curing device 16 is moved in the axial direction of the tunnel 10, and the water-impermeable sheet 28 of the first curing device 16 is moved to the face side. Thereafter, the lining concrete 12 of the tunnel 10 is cured by the first curing device 16 in the first region.

  When curing the lining concrete 12 by the first curing device 16, first, the gap between the one end portion of the water-impermeable sheet 28 and the lining concrete 12 and the other end portion of the water-impermeable sheet 28 and the lining concrete. 12 is closed by the first closing means 36 and the second closing means 38, respectively. At this time, the balloon of the first closing means 36 presses the one end portion of the water-impermeable sheet 28 and the balloon of the second closing means 38 presses the other end portion of the water-impermeable sheet 28 against the lining concrete 12. Thus, air is injected into each of the balloons of the first closing means 36 and the second closing means 38.

  Thereafter, a plurality of weights 88 are placed on each side of the water-impermeable sheet 28 so that a gap between each side of the water-impermeable sheet 28 and the lining concrete 12 is closed (FIG. 2). The weight 88 is made of, for example, wood. In this way, the lining concrete 12 is covered with the water-impermeable sheet 28, and the lining concrete 12 is cured without applying water. Thereby, the temperature of the lining concrete 12 can be gradually lowered while preventing the lining concrete 12 from being dried. Thereby, generation | occurrence | production of the crack of the covering concrete 12 by the rapid cooling of the covering concrete 12 can be prevented. The time for curing the lining concrete 12 without applying water is preferably within a range of 24 hours to 96 hours.

  During the curing of the lining concrete 12 by the first curing device 16, the lining concrete 12 is formed by the movable formwork 20 in the second region located on the face side of the first region of the tunnel 10, Demold. Thereafter, the curing of the lining concrete 12 by the first curing device 16 is terminated, and the movable mold 20 is moved to the face side so that the first curing device 16 is disposed inside the second region of the tunnel 10. Let Thereafter, the second curing device 18 is arranged inside the tunnel 10 so that the front half 80 of the second curing device 18 is located inside the first region of the tunnel 10. Thereafter, the lining concrete 12 is cured by the second curing device 18 in the first area while the lining concrete 12 is cured by the first curing apparatus 16 in the second area.

  The arrangement of the second curing device 18 inside the tunnel 10 is such that the jacks of the first rotating means 58 and the second rotating means 60 are shrunk so that the first side portion 54 and the second side portion 56 of the mat receiving base 50 are arranged. Each of these is rotated inward with respect to the top 52, and each jack 62a of the elevating means 62 is contracted and the carriage 40 is lowered. When curing the lining concrete 12 by the second curing device 18, first, the carriage 40 is raised by the lifting means 62. At this time, a pedestal 90 having an inverted U-shaped longitudinal section is disposed between each jack 62a of the elevating means 62 and the bottom concrete 30 so that the pedestal straddles the rail 32, and then each jack 62a. Each jack 62a is extended so as to receive a reaction force from the bottom concrete 30 through the base 90. As the carriage 40 is raised, the frame 42 is raised, and the second portion 66 of the water-permeable mat 46 is brought into close contact with the lining concrete 12.

  Thereafter, the first rotating means 58 rotates the first side portion 54 of the mat cradle 50 outwardly with respect to the top portion 52, and the second rotating means 60 causes the second side portion 56 of the mat cradle 50 to be moved outside thereof. Rotate relative to the top 52. At this time, the jacks of the first rotating means 58 and the second rotating means 60 are extended. The first portions 64 of the water-permeable mat 46 are brought into close contact with the lining concrete 12 by the rotation of the first side portion 54 and the second side portion 56 of the mat receiving base 50. Thus, the entire permeable mat 46 is brought into close contact with the lining concrete 12 by the rising of the carriage 40 and the rotation of the first side portion 54 and the second side portion 56 of the mat receiving base 50. Thus, the 1st part 64 and the 2nd part 66 of the water-permeable mat 46 are arrange | positioned at the side wall parts 10c and 10d of the tunnel 10, and the arch part 10b, respectively.

  After the water permeable mat 46 adheres to the lining concrete 12, the water permeable mat 46 is connected to the water supply source by connecting the pipe 68 and a water supply source (not shown) by another pipe (connecting pipe). . Thereafter, water is supplied from the water supply source to the pipe 68 through the connecting pipe. At this time, water flows from the pipe 68 to the water-permeable mat 46 through the through hole 72. In this way, water is supplied to the water-permeable mat 46. Since the water absorbing material 44 is disposed inside the water permeable mat 46, when water is supplied to the water permeable mat 46, a part of the water is absorbed by the water absorbing material 44, and the other part of the water is It is given to the lining concrete 12 from the water-permeable mat 46. When the water absorbing material 44 absorbs water, the water-permeable mat 46 can hold water therein. By providing water to the lining concrete 12 from the water permeable mat 46, the hydration reaction of the lining concrete 12 is promoted, and the lining concrete 12 is cured. For this reason, sufficient strength can be exerted on the lining concrete 12.

  Since the first portion 64 and the second portion 66 of the water permeable mat 46 are respectively disposed on the side wall portions 10 c and 10 d and the arch portion 10 b of the tunnel 10, the second portion 66 of the water permeable mat 46 is more than the first portion 64. When the water is supplied to the pipe 68, the water that has flowed from the pipe to the water-permeable mat 46 flows down from the second portion 66 of the water-permeable mat 46 to the first portions 64. Thereby, water is supplied to the whole water-permeable mat 46, and water is given to the lining concrete 12 from the whole water-permeable mat 46. For this reason, even if it does not arrange | position the other pipe | tube (not shown) for water supply to the water-permeable mat 46 inside the 1st part 64 of the water-permeable mat 46, water is given to the whole lining concrete 12 be able to.

  By the way, if the pipe 68 is disposed on the water-permeable mat 46, the water that comes out of the pipe 68 is directly given to a part of the lining concrete 12. For this reason, the said part of the lining concrete 12 may be cooled rapidly, and the lining concrete 12 may generate | occur | produce a crack. Further, since the pipe 68 is disposed on the water-permeable mat 46, the pipe 68 may hit the lining concrete 12 and damage the lining concrete. On the other hand, when the pipe 68 is disposed inside the water permeable mat 46, the water discharged from the pipe 68 is reliably supplied to the lining concrete 12 through the water permeable mat 46. For this reason, it is possible to prevent a portion of the lining concrete 12 from being rapidly cooled and cracking in the lining concrete 12. Further, since the pipe 68 is disposed inside the water-permeable mat 46, the pipe 68 does not hit the lining concrete 12 and damage the lining concrete.

  After the water supply to the water permeable mat 46, the water supply to the water permeable mat 46 is stopped by stopping the water supply to the pipe 68. Thereafter, the adhesion of the water-permeable mat 46 to the lining concrete 12 is maintained. After the water supply to the water permeable mat 46 is stopped, the water permeable mat 46 starts to dry over time. When the water-permeable mat 46 starts to dry, water is discharged from the water absorbent material 44. For this reason, even if water supply to the water-permeable mat 46 is stopped, the water-permeable mat 46 can be maintained in a wet state for a long time, and water can be supplied from the water-permeable mat 46 to the lining concrete 12. it can. By stopping the water supply to the water permeable mat 46, the amount of water dripping from the water permeable mat 46 can be reduced, and the cost required for discharging the water dripping from the water permeable mat 46 out of the tunnel 10 can be reduced. Can do.

  While curing the lining concrete 12 by the first curing device 16 in the second area, and curing the lining concrete 12 by the second curing apparatus 18 in the first area, the first of the tunnel 10 is performed. In the third region located on the face side of the two regions, the lining concrete 12 is formed by the movable mold frame 20, and demolded. Thereafter, the curing of the lining concrete 12 by each of the first curing device 16 and the second curing device 18 is finished, and the mobile curing mold is arranged so that the first curing device 16 is disposed inside the third region of the tunnel 10. The frame 20 is moved to the face side. Then, the 2nd curing device 18 is moved to the face side so that the front half part 80 and the latter half part 82 of the 2nd curing device 18 may be arranged inside the 2nd field of the tunnel 10, and the 1st field, respectively. At this time, the carriage 40 of the second curing device 18 is moved in the axial direction of the tunnel 10 so that the water-permeable mat 46 of the second curing device 18 is moved to the face side.

  Before the movement of the second curing device 18, the connection between the pipe 68 and the water supply source is released to release the connection of the water permeable mat 46 to the water supply source. Thereafter, the adhesion of the water-permeable mat 46 to the lining concrete 12 is released. At this time, the jack of the first rotating means 58 is shrunk and the first side portion 54 of the mat receiving base 50 is rotated inward with respect to the top 52, and the jack of the second rotating means 60 is shrunk to receive the mat. The second side 56 of the pedestal 50 is rotated inward relative to the top 52. Thereby, the adhesion of the first portions 64 of the water-permeable mat 46 to the lining concrete 12 is released. Thereafter, the jacks 62a of the lifting means 62 are contracted to lower the carriage 40. Thereby, the frame 42 is lowered, and the adhesion of the second portion 66 of the water-permeable mat 46 to the lining concrete 12 is released. The movement of the second curing device 18 may be self-propelled, or may be caused by towing the second curing device 18 on a vehicle (not shown) such as a truck. It may be connected to the first curing device 16 and the movable mold 20 may be moved.

  After the movement of the second curing device 18, the lining concrete 12 by the second curing device 18 is cured in the second region and the first region while curing the lining concrete 12 by the first curing device 16 in the third region. Caring for. In this way, the movement of the first curing device 16 and the second curing device 18 and the curing of the lining concrete 12 by the first curing device 16 and the second curing device 18 are repeated.

  After the second curing device 18 is moved, the permeable mat 46 is brought into close contact with the lining concrete 12 when the lining concrete 12 is cured by the second curing device 18. Thereafter, the water-permeable mat 46 is kept in close contact with the lining concrete 12 without supplying water to the water-permeable mat 46. While maintaining the tight adhesion of the water-permeable mat 46 to the lining concrete 12, the water-permeable mat 46 begins to dry over time. When the water-permeable mat 46 starts to dry, water is discharged from the water absorbent material 44. For this reason, water can be supplied from the water-permeable mat 46 to the lining concrete 12 without supplying water to the water-permeable mat 46. Thereby, it is not necessary to connect the water permeable mat 46 to the water supply source every time the second curing device 18 is moved, and it is possible to reduce the labor and time required to connect the water permeable mat 46 to the water supply source. The lining concrete 12 can be cured efficiently.

  After the water-permeable mat 46 is kept in close contact with the lining concrete 12, the amount of water contained in the water-permeable mat 46 is investigated, and water is supplied to the water-permeable mat 46 according to the amount of water. Decide whether or not. As a result of the investigation of the amount of water, if the water-permeable mat 46 does not contain a sufficient amount of water to the extent that water can be supplied from the water-permeable mat 46 to the lining concrete 12, the water-permeable mat 46 Decide to supply water. On the other hand, if the water-permeable mat 46 contains a sufficient amount of water to the extent that water can be supplied from the water-permeable mat 46 to the lining concrete 12, it is determined not to supply water to the water-permeable mat 46. .

  By the way, when almost all of the water sucked up by the water absorbing material 44 is discharged from the water absorbing material 44, water is not discharged from the water absorbing material 44 even when the water permeable mat 46 is dried, and the water permeable mat 46 is brought into a wet state. It becomes impossible to maintain, and water cannot be given to the lining concrete 12 from the water-permeable mat 46. By investigating the amount of water contained in the water-permeable mat 46 and determining whether or not to supply water to the water-permeable mat 46 according to the amount of water, the lining concrete 12 Water can be supplied to the water-permeable mat 46 only when a sufficient amount of water is not contained in the water-permeable mat 46 so that water can be supplied to the water-permeable mat 46. Thereby, it is possible to prevent the water-permeable mat 46 from being excessively supplied while preventing the water-permeable mat 46 from drying.

  When it is determined to supply water to the water-permeable mat 46, the water-permeable mat 46 is supplied with water. Thereafter, water supply to the water-permeable mat 46 is stopped, and the water-permeable mat 46 is kept in close contact with the lining concrete 12. Thereafter, the amount of water contained in the water-permeable mat 46 is examined again, and it is determined whether or not to supply water to the water-permeable mat 46 according to the amount of water. On the other hand, when it is determined not to supply water to the water permeable mat 46, the water permeable mat 46 is kept in close contact with the lining concrete 12 without supplying water. Thereafter, the amount of water contained in the water-permeable mat 46 is examined again, and it is determined whether or not to supply water to the water-permeable mat 46 according to the amount of water.

  Prior to the examination of the amount of water, the weight of the second curing device 18 is measured before water supply to the water permeable mat 46 to obtain a first measurement value, and after water supply to the water permeable mat 46, After maintaining close contact with the lining concrete 12, the weight of the second curing device 18 is measured to obtain a second measured value. When investigating the amount of water, the difference between the first measured value and the second measured value is obtained. Thereby, the amount of water contained in the water-permeable mat 46 can be known, and the wet state of the water-permeable mat 46 can be confirmed. In this case, for example, an instrument (not shown) for measuring the weight of the second curing device 18 is disposed in the vicinity of the lifting means 62 and attached to the carriage 40. The meter measures the weight of the second curing device 18 before supplying water to the water-permeable mat 46 and after maintaining the tight adhesion of the water-permeable mat 46 to the lining concrete 12. The weight of the second curing device 18 may be measured by measuring the entire weight of the second curing device 18 or by measuring the weight of a part of the second curing device 18. .

  The investigation of the amount of water is carried out by measuring the weight of the mat base 50 and the water-permeable mat 46 disposed on the mat base instead of the above-mentioned example that is performed by measuring the weight of the second curing device 18. Also good. In this case, for example, an instrument for measuring the weight of the mat cradle 50 and the water permeable mat 46 is disposed in the vicinity of the mat cradle 50 and attached to the frame 42. The mat holder 50 and the water permeable mat 46 may be measured by measuring the total weight of the mat holder 50 and the water permeable mat 46, or a part of the mat holder 50 and the water permeable mat 46. It may be by measuring the weight of.

  By the way, in general, it is difficult for an operator to approach the water-permeable mat 46, and it is difficult for the worker to confirm the wet state of the water-permeable mat 46 by visual observation or by hand. By examining the amount of water by measuring the weight of the second curing device 18 using the meter, the worker can know the wet state of the permeable mat 46 without approaching the permeable mat 46. it can.

  Instead of the above-described example in which the amount of water is measured by measuring the weight of the second curing device 18, a part of the water-permeable mat 46 is extracted as a sample, and the weight of the part of the water-permeable mat 46 is measured. May be performed. In this case, the part of the water permeable mat 46 can be detached from the other part of the water permeable mat 46. Prior to examining the amount of water, before supplying water to the water permeable mat 46, the portion of the water permeable mat 46 is removed from the other portion, and the weight of the portion of the water permeable mat 46 is measured to obtain a first measured value. Get. Then, before supplying water to the water permeable mat 46, the part of the water permeable mat 46 is attached to the other part. Thereafter, after the water-permeable mat 46 is maintained in close contact with the lining concrete 12, the part of the water-permeable mat 46 is removed from the other part, and the weight of the part of the water-permeable mat 46 is measured to obtain the second measured value. obtain. When investigating the amount of water, the difference between the first measured value and the second measured value is obtained. Thereby, the amount of water contained in the part of the water-permeable mat 46 can be known, and the wet state of the water-permeable mat 46 can be confirmed.

  In addition, after maintaining the adhesion of the water-permeable mat 46 to the lining concrete 12, the amount of water contained in the water-permeable mat 46 is investigated, and water is supplied to the water-permeable mat 46 according to the amount of the water. Instead of the above example for determining whether or not to perform, water supply to the water permeable mat 46 is determined in advance after the water supply to the water permeable mat 46 is stopped, and then the water supply to the water permeable mat 46 is determined. After stopping, water may be supplied to the water-permeable mat 46 when a predetermined time elapses.

  In the example shown in FIG. 1, since the length of the second curing device 18 is twice the length of the first curing device 16, the curing period of the lining concrete 12 by the second curing device 18 is the first curing. The curing period of the lining concrete 12 by the device 16 is doubled. For example, when the curing period of the lining concrete 12 by the first curing device 16 is 2 days, the curing period of the lining concrete 12 by the second curing device 18 is 4 days. Thus, the ratio between the length of the first curing device 16 and the length of the second curing device 18 is the period of curing the lining concrete 12 without applying water and the curing of the lining concrete 12 with water. It corresponds to the ratio with the period. For this reason, the ratio of the length of the 1st curing device 16 and the length of the 2nd curing device 18 is previously set to the number of days for curing the lining concrete 12 without providing water and the curing of the lining concrete 12 by supplying water. By setting the ratio to the number of days to be performed, the lining concrete 12 can be efficiently cured. The ratio between the length of the first curing device 16 and the length of the second curing device 18 is a period of curing the lining concrete 12 without supplying water and a period of curing the lining concrete 12 with water. It can be arbitrarily changed according to the ratio.

  Prior to curing the lining concrete 12 by supplying water, curing the lining concrete 12 without applying water, the temperature of the lining concrete 12 is set to a time before supplying water to the lining concrete 12. It can be lowered by applying. Thereby, when water is given to the lining concrete 12, the lining concrete 12 is not rapidly cooled by the water, and cracking of the lining concrete 12 can be prevented.

  The adhesion of the water permeable mat 46 to the lining concrete 12 and the release thereof are replaced with the first rotation means 58, the second rotation means 60, and the lifting means 62 instead of the example shown in FIG. Instead of using the rotating means 58 and the second rotating means 60, only the lifting means 62 may be used. In this case, each of the first side portion 54 and the second side portion 56 of the mat cradle 50 is rigidly coupled to the top portion 52, and the second curing device 18 does not have the first rotation means 58 and the second rotation means 60. . In the example shown in FIG. 3, a pipe for supplying water to the water permeable mat 46 is not disposed inside each first portion 64 of the water permeable mat 46. In order to increase the amount of water to be supplied, a pipe (not shown) for supplying water to the permeable mat 46 may be disposed inside each first portion 64 of the permeable mat 46.

  Instead of the example shown in FIG. 1 in which the frame 42 of the second curing device 18 is raised and lowered by raising and lowering the carriage 40, the frame 42 may be attached to the carriage 40 so as to be raised and lowered, and the frame 42 may be raised and lowered with respect to the carriage 40. . The second curing device 18 is not divided into the first half portion 80 and the second half portion 82, instead of being divided into the first half portion 80 and the second half portion 82, and is configured integrally. Also good. Instead of the example shown in FIG. 1 in which curing of the lining concrete 12 is performed using both the first curing device 16 and the second curing device 18, only the second curing device 18 is used without using the first curing device 16. May be used. The lining concrete 12 may be formed without using the mobile formwork 20 instead of the example shown in FIG. 1 formed using the mobile formwork 20.

10 tunnel 12 lining concrete 18 curing device (second curing device)
40 bogie 42 frame 44 water absorbing material 46 water permeable mat 64 first part 66 second part 68 pipe 72 through hole

Claims (4)

A method for curing tunnel lining concrete,
A first step of preparing a water-permeable mat having a water absorbing material disposed therein;
A second step of bringing the water-permeable mat into close contact with the lining concrete;
A third step of supplying water to the water-permeable mat;
A fourth step of stopping water supply to the water-permeable mat;
A fifth step of maintaining adhesion of the water-permeable mat to the lining concrete ;
After the fifth step, a sixth step of investigating the amount of water contained in the water-permeable mat;
A seventh step of determining whether to supply water to the water-permeable mat according to the amount of water;
Performing the third step to the fifth step when it is determined to supply water to the water-permeable mat in the seventh step;
A curing method comprising performing the fifth step when it is determined not to supply water to the water-permeable mat in the seventh step . In the first step, preparing a curing device including a carriage movable in the axial direction of the tunnel, a frame that can be moved up and down on the carriage, and the water-permeable mat supported by the frame. ,
Measuring the weight of the curing device before the third step to obtain a first measurement value;
Measuring the weight of the curing device after the fifth step and before the sixth step to obtain a second measurement value;
The curing method according to claim 1 , comprising obtaining a difference between the first measurement value and the second measurement value in the sixth step. In the first step, a carriage that is movable in the axial direction of the tunnel, a frame that can be moved up and down on the carriage, and the water-permeable mat supported by the frame, Providing a curing device, one part of which can be removed from the other part;
Removing the part of the water-permeable mat from the other part before the third step;
Measuring the weight of the portion of the water-permeable mat to obtain a first measurement value;
Attaching the part of the water-permeable mat to the other part before the third step;
Removing the part of the water-permeable mat from the other part after the fifth step and before the sixth step;
Measuring the weight of the portion of the water-permeable mat to obtain a second measurement value;
The curing method according to claim 1 , comprising obtaining a difference between the first measurement value and the second measurement value in the sixth step. The water-permeable mat has two first parts spaced apart in a first horizontal direction, and a second part between the first parts, and the first part is disposed inside the second part. A pipe extending in a second horizontal direction perpendicular to the horizontal direction is arranged, the pipe having at least one water discharge through hole provided on each side of the pipe;
In the second step, bringing the water-permeable mat into close contact with the lining concrete so that the first part and the second part are disposed on a side wall part and an arch part of the tunnel, respectively.
Supplying water to the pipe in the third step so that water flows from the pipe to the water-permeable mat through the through hole;
The curing method according to any one of claims 1 to 3 , comprising stopping water supply to the pipe in the fourth step.

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