JP6296935B2 - Forming apparatus for lining concrete and method for lining concrete - Google Patents

Description

  The present invention relates to a formwork device for lining concrete to be applied to an inner wall of a tunnel and a method for lining concrete.

  The lining concrete will be constructed on the inner wall of the tunnel that has been completed until the secondary spraying. When constructing the lining concrete, for example, a horseshoe-shaped mold frame held by a gantry or the like is pressed against the inner wall. In this state, concrete is placed in the mold, and then protected (also referred to as “curing”) for a predetermined time until the concrete is dried and hardened, and then released.

  As shown in Patent Documents 1 and 2, there is known a formwork device that is used to perform mold release smoothly. In this type of formwork apparatus, a plurality of formwork members are connected by a hinge structure, and a lowermost formwork member (hereinafter, “ Can be folded inward (reduced diameter). Further, for example, in the formwork apparatus described in Patent Document 1, a hydraulic jack is used as a mechanism for reducing the diameter. Further, the hydraulic jack is extended to hold the formwork member at a predetermined position on the inner wall, and the concrete is placed. Appropriate protection is provided after installation.

JP 2008-308855 A JP2013-87514A

  However, when the present inventors diligently studied the present technology, a gap was formed between the invert foam and the inner wall even though the hydraulic foam jack held the side foam and the invert foam in a predetermined position. Although it itself is very small (about several mm), it has been found that in fact, this gap may cause insufficient protection (curing) of concrete and affect the quality after mold release.

  The present invention aims to solve the above-described problems, and provides a formwork apparatus that can prevent a gap from being generated between the lining concrete and the invert foam and prevent quality degradation, and a method for constructing the lining concrete. The purpose is to provide.

  When the present inventors diligently investigated the cause of the above problem, the following knowledge was obtained. In other words, the invert foam is connected to the side foam by a hinge structure so that the invert foam can be expanded and contracted, and therefore can swing around the hinge structure as a fulcrum. A means (for example, a hydraulic jack) for holding the invert foam and the side foam at a predetermined position in the deployed state can follow this swing, and the deployed state also changes in relation to the inner wall. Some play is needed to absorb the changes. This play is also present in the hinge structure. The inventors focused on these play and found that there is a possibility that the invert foam is slightly displaced by the combined action and a gap is generated even if each play is slight. Furthermore, the inventors have conducted an extensive study based on this finding, and found that while allowing the play with the means for stretching and holding the inverted form or the like, another means for applying a tensile force opposite to the tensile force by this means is provided. By installing the means, it was found that the inverted form can be firmly held at a predetermined position, and the present invention has been conceived.

  That is, the present invention is a formwork apparatus for lining concrete to be constructed on the inner wall of a tunnel, comprising a group of foams having a plurality of foams joined together, a first form and a second form adjacent to each other. A hinge structure to be joined, and a deployment holding portion that is joined to the first foam and the second foam and is stretchable and capable of imparting a tension force to the first foam and the second foam; It is connected to the first foam and the second foam and can be expanded and contracted, and a tensile force can be applied to the first foam and the second foam in a state where a tensile force is applied by the development holding portion. And a tension member.

  In the present invention, the tensile force is applied to the tension portion in the reverse direction while the unfolding holding portion imparts a tensile force to hold the unfolded state of the first foam and the second foam. That is, the hinge which joins the 1st foam and the 2nd foam, or the joined part of the 1st foam and the 2nd foam by making a tensile force and a pulling force interact mutually. Even if there is play in the structure, the relative positional relationship between the development holding portion, the first foam, and the second foam is firmly held, and the relative displacement between them is suppressed. As a result, while the first foam and the second foam are deployed to protect the lining concrete, the first foam and the second foam are separated from the lining concrete to create a gap. Can be prevented, and deterioration of the quality of the lining concrete can be prevented.

  Further, it is preferable that the first form of the above-mentioned formwork apparatus is a side form and the second form is an inverted form. Since the inverted form is positioned at the lower end of the foam group, the inverted form receives the weight of the entire foam group, and as a result, the inverted form tends to be displaced from the side foam in the unfolded state. That is, according to the above configuration, the invert foam is prevented from being separated from the lining concrete while the invert foam is deployed to protect the lining concrete, so that a gap is generated. It is superior in that it can prevent quality degradation.

  Moreover, in this formwork apparatus, the tension part is rotatably pin-bonded to the first foam and the second foam, and the development holding part is one of the first foam and the second foam. One end joined to the other and the other end joined to the foam, one end rigidly joined to one foam, and the other end is in surface contact with the other foam during expansion It is preferable that the other foam is supported so that it can be detached from the other foam when retracted.

  Since the one end part of the expansion | deployment holding | maintenance part which concerns on the said structure is rigidly joined to one form, there is substantially no play. Further, the other end portion is supported while being in surface contact with the other foam when it is extended, that is, in the expanded state of the second foam. In the case of surface contact, since the frictional force increases more than the point contact state due to the pulling force applied by the tension part, the occurrence of displacement (displacement) can be suppressed, and the stability is increased, so the expanded state of the second foam can be changed. Can protect properly. As a result, it is further advantageous in that a gap is prevented from being generated between the second foam and the lining concrete to prevent deterioration of the quality of the lining concrete. Further, since the other end portion can be detached from the other foam at the time of contraction, the other end portion can be detached when the diameter of the second foam is reduced. As a result, the second form follows the swing of the second foam. It becomes easy to let. Moreover, since the tension | pulling part is rotatably pin-joined with the 1st foam and the 2nd foam, it is easy to follow the rocking | fluctuation of a 2nd foam.

  Moreover, in this formwork apparatus, it is preferable that the other end portion of the development holding portion is in surface contact with the other foam on a surface intersecting the pulling direction of the tension portion. The surface contact on the surface intersecting the pulling direction is effective for effectively applying and stabilizing the frictional force, and it is more advantageous especially on the surface orthogonal to the pulling direction.

  In the above-mentioned formwork device, the extension / contraction direction of the tension part may be the same as the extension / contraction direction of the development holding part, or may be matched in the intersecting direction.

  Further, in the above-described formwork apparatus, it is preferable that the tension portion is arranged in parallel with the development holding portion in the length direction of the tunnel in which the lining concrete is constructed. After placing the lining concrete, the formwork device remains in place and plays a role of protecting the lining concrete, so that it is advantageous to be lightweight. Here, if the tension portion and the development holding portion are arranged so as to overlap in the width direction of the tunnel, a load (weight) applied to the foam group partially increases, which may be disadvantageous. On the other hand, the above-described configuration in which the tension portion and the deployment holding portion are provided side by side in the length direction of the tunnel is advantageous in that it is easy to reduce the weight.

  Further, in the above-described formwork apparatus, the unfolding holding part can be a journal jack, and the tension part can be a bar jack.

  In addition, the present invention is a method for constructing lining concrete using the above-mentioned formwork device, and includes a protection process in which the formwork device is placed in a state where the lining concrete is placed inside the foam group, In the protection step, the development holding unit applies a tensile force to hold the second foam in a developed state with respect to the first foam, and the tension unit applies a tensile force to provide the development holding unit, the first foam, And maintaining the relative positional relationship of the second form.

  According to the present invention, the second foam is separated from the lining concrete to create a gap while the second foam is expanded with respect to the first foam to protect the lining concrete. Can be prevented and deterioration of the quality of the lining concrete can be prevented.

  Also, in this method of lining concrete, the first foam is a side foam, the second foam is an invert foam, and is installed on the inner wall of the tunnel by a gantry and this installed state is maintained. After the placing process of placing the lining concrete inside the foam group of the formwork apparatus, a protection process is performed. In the protection process, the gantry is detached from the formwork apparatus and the lining concrete is hardened. It is also possible to provide a mold release step in which the formwork device is allowed to remain until it is stabilized, and when the protection process is completed, the moldwork device is detached from the lining concrete with a gantry.

  According to this construction method, while the invert foam is deployed to protect the lining concrete, the invert foam is prevented from being separated from the lining concrete to form a gap, and the quality of the lining concrete is deteriorated. Can be prevented.

  According to the present invention, it is possible to prevent a gap from being generated between the lining concrete and the invert foam, and to prevent deterioration in quality.

It is a front view of the formwork apparatus concerning the embodiment of the present invention. It is a side view which shows the jack for fixation and the tension | tensile_strength jack of the formwork apparatus which concerns on this embodiment. It is a figure which expands and shows the jack for fixation, and is sectional drawing along the III-III line of FIG. It is a figure which expands and shows a tension rod jack, and is sectional drawing along the IV-IV line of FIG. FIG. 5 is a schematic sectional view taken along line VV in FIG. 3. FIG. 6 is a schematic cross-sectional view showing a modified example corresponding to FIG. 5. It is a figure explaining the expansion / contraction direction of a fixing jack and a tension rod jack, and (a) is related to this embodiment, and the expansion / contraction direction of the fixation jack and the expansion / contraction direction of the tension rod jack are the same direction. (B) is explanatory drawing which shows the case where the expansion-contraction direction of the jack for fixation and the expansion-contraction direction of a tension | tensile_strength jack cross | intersect according to a modification. The process from casting of lining concrete to mold release of a formwork apparatus is shown, (a) is a casting process, (b) is a protection process, and (c) is an explanatory view showing a mold release process.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

  As shown in FIG. 1, the formwork apparatus 1 according to the present embodiment is used when lining concrete C is applied to an inner wall Ta of a tunnel T where concrete has been sprayed. Specifically, the formwork apparatus 1 is installed on the inner wall Ta of the tunnel T, and an area surrounded by the foam group 2 serving as the mold and the inner wall Ta of the tunnel T (hereinafter referred to as “inside” of the foam group 2). The concrete for lining is placed on the surface, and the state is maintained for a predetermined time to protect the lining concrete C (also referred to as “curing”). In addition, the length direction D (refer FIG. 2) of the tunnel T makes the area | region which installs a lining concrete and installs a cover frame etc. as a closed area for convenience.

  The foam group 2 includes at least a top form 3, a side form 4, and an inverted form. The foam group 2 has an inverted U-shape (horse-shoe shape) and is open at the bottom. The top end form 3 is disposed on the ceiling portion of the tunnel T, and a pair of side foams 4 are joined to the left and right lower ends of the top end form 3. Invert foam 5 is joined to the lower end of each side foam 4. The length in the length direction D of the tunnel T of the foam group 2 is, for example, about 10.5 m or 12 m, and there are a plurality of lengths along the length direction of the tunnel T at the connection portion between the side foam 4 and the invert foam 5. A hinge structure 6 is provided at a location (for example, 6 locations or 7 locations). In the present embodiment, the side form 4 corresponds to the first form, and the inverted form corresponds to the second form.

  By the hinge structure 6, the invert form 5 can swing with respect to the side form 4 and can be folded inward. Here, a state where the invert form 5 is opened and connected to the side form 4 is referred to as an unfolded state of the invert form 5, and a state where the inverted form 5 is folded is referred to as a reduced diameter state of the invert form 5.

  The invert form 5 can maintain the unfolded state to some extent by its own weight. Conversely, when the diameter is reduced, the invert form 5 needs to be pulled up by another opening / closing means. In the present embodiment, the hydraulic jack 8 that connects the side foam 4 and the invert foam 5 is illustrated as an opening / closing means, but various other modes can be assumed as the opening / closing means, for example, a crane mechanism that pulls by connecting wires. Or a chain block.

  As shown in FIG. 2, the formwork apparatus 1 includes a fixing jack (deployment holding portion) 10 connected to the side foam 4 and the invert foam 5, and a tension bar jack (tensioning portion) 20. Yes. One jack unit is formed side by side in the length direction (tunnel axis direction) D of the tunnel T. The fixing jack 10 and the tension bar jack 20 constituting the jack unit are arranged so as to sandwich the hinge structure 6. For example, the interval between the fixing jack 10 and the tension bar jack 20 is about 20 mm to 800 mm. . In addition, a plurality of jack units are appropriately arranged along the length direction D of the tunnel T. As a result, the fixing jack 10 and the tension bar jack 20 constituting the jack unit are arranged in the length direction of the tunnel T. It is the aspect arrange | positioned alternately along D. FIG.

  The purpose of this jack unit is essentially different from that of the aforementioned opening / closing means (hydraulic jack 8). Therefore, for example, there are two opening / closing means (hydraulic jack 8) for the length in the length direction D of the tunnel T (for example, about 10.5 m or 12 m), whereas the fixing jack 10 and the tension rod The jack unit including the jack 20 is arranged at six locations.

  As shown in FIG. 3, the fixing jack 10 is a mechanical jack such as a journal jack, and plays a role of maintaining the deployed state of the inverted form 5 by stretching. The fixing jack 10 includes a housing 11, a screw shaft 12 that can be extended and retracted by protruding and retracting from the housing 11, a handle (operation unit) 13 for expanding and contracting the screw shaft 12, and a screw shaft that receives an operation of the handle 13. 12 and a spacer 14 for adjusting the height of the housing.

  The lower end (one end) 10 a of the fixing jack 10, that is, the lower end of the spacer 14 is joined to the invert form 5. The invert form 5 is provided with a rib 5a extending perpendicular to the length direction D of the tunnel T, and the rib 5a is provided with a seat portion 5b for receiving the lower end of the spacer 14. The spacer 14 is bolted to the seat portion 5b. As a result, the spacer 14 is firmly fixed without displacement, so that substantial rigid joining is realized. Since the spacer 14 is only bolted to the seat portion 5b, it can be removed by loosening the bolt.

  The tip end of the screw shaft 12 that becomes the upper end portion (the other end portion) 10 b of the fixing jack 10 is joined to the side foam 4. A plate-like (flat plate) pressing portion 15 is fixed to the tip of the screw shaft 12. The side foam 4 is provided with a rib 4a on an extension line of the rib 5a so as to correspond to the rib 5a of the inverted foam 5 in the unfolded state, and a receiving part 4b for receiving the pressing part 15 is bolted to the rib 4a. And is detachably fixed. The receiving part 4b is formed with a recessed part 4c (see FIG. 5) corresponding to the shape of the pressing part 15, and the pressing part 15 is inserted into the recessed part 4c. When the screw shaft 12 extends, the pressing portion 15 is inserted into the recessed portion 4c and comes into surface contact with the receiving portion 4b. The pressing portion 15 is in surface contact with the recessed portion 4c on the surface P intersecting the pulling direction Dp of the tension bar jack 20. In the present embodiment, an orthogonal plane is exemplified as an aspect intersecting with the pulling direction Dp. However, the plane is not limited to the orthogonal plane, and may be a plane inclined with respect to the orthogonal plane.

  The lower part of the fixing jack 10 is fixed to the invert form 5. Therefore, when the screw shaft 12 is extended, the side foam 4 is pressed so that the pressing portion 15 which is the upper end portion 10b of the fixing jack 10 is stretched. As a result, a tension force is applied to the invert foam 5 and the side foam 4. Thus, the developed state of the inverted form 5 is maintained. Further, since the pressing portion 15 is merely joined to the receiving portion 4b by surface contact, the pressing portion 15 is detached from the receiving portion 4b when the screw shaft 12 is retracted, that is, the protrusion amount with respect to the housing 11 is reduced. To do. Therefore, if the fixing jack 10 is removed from the invert form 5 in a state where the pressing part 15 is detached from the receiving part 4 b, the fixing jack 10 can be easily detached from the invert form 5 and the side form 4.

  In addition, the press part 15 and the receiving part 4b are not limited to the form shown by FIG. 5, For example, the form which concerns on the modification shown by FIG. 6 may be sufficient. That is, the pressing portion 15A according to the modified example may have a convex curved surface shape, specifically a spherical shape, and the receiving portion 4b may have a concave curved portion 4x corresponding to the pressing portion 15A. . In this modification, the pressing portion 15 and the receiving portion 4b are in surface contact on the curved surface, and it is easy to maintain the surface contact state. This curved surface corresponds to an example of a surface that intersects the pulling direction Dp of the pull rod jack 20.

  Also, as shown in FIG. 4, the tension bar jack 20 is a mechanical bar jack. Although a hydraulic jack can be used as the tension bar jack 20, a mechanical bar jack will be described below as an example. The tension bar jack 20 includes a cylindrical body portion 21 and a pair of shaft portions 22 and 23 that can be protruded and retracted from both ends of the body portion 21. The shaft portion 22 according to this embodiment is screwed to the body portion 21 with a right screw, and the shaft portion 23 is screwed to the body portion 21 with a left screw. However, the direction of this screw may be reversed.

  The tension rod jack 20 rotates the body portion 21 so that the shaft portions 22 and 23 are projected and retracted. As a result, a stretchable configuration is realized. One shaft portion 22 is rotatably pin-joined to a bracket portion 5 f provided on the invert form 5, and the other shaft portion 23 is rotatably pin-joined to a bracket portion 4 f provided on the side foam 4. . The pins 22a and 23a of these pin joints are arranged substantially in parallel, and are arranged so that the axial direction of the pins 22a and 23a is along the length direction D of the tunnel T (see FIG. 2). .

  When the invert form 5 is expanded and contracted, the invert form 5 swings with respect to the side form 4. Since the tension bar jack 20 is rotatable to the invert form 5 and the side form 4, it can move following the swinging movement.

  Next, the interaction between the fixing jack 10 and the tension bar jack 20 with respect to the inverted form 5 will be described with reference to FIGS. 2, 3, and 4. The deployed state of the invert form 5 is basically maintained by the extension of the fixing jack 10. Here, the invert form 5 can swing with respect to the side form 4 for expansion and contraction, and the inflated state of the invert form 5 slightly changes according to the inner wall Ta of the tunnel T. Therefore, since fine adjustment according to each deployment state is required, a slight play for absorbing the change in the deployment state is required at the joint portion between the fixing jack 10 and the side foam 4. Therefore, when the pressing portion 15 of the fixing jack 10 is received by the receiving portion 4b of the side foam 4, it is slightly slidable and provided with substantial play (see FIG. 5). The hinge structure 6 that connects the invert form 5 and the side form 4 also has play for smooth rotation.

  Inverted foam 5 and side foam 4 are held in place in a state where fixing jack 10 is extended. However, the invert form 5 and the side form 4 may move slightly due to the combined action of the above-described plurality of plays, and the relative positional relationship with the fixing jack 10 may be shifted. This deviation causes the invert form 5 that should have been in close contact with the lining concrete C to be detached from the lining concrete C, and a slight gap is generated. If such a gap exists, the protection (curing) of the lining concrete C is adversely affected, and the quality of the lining concrete C may be impaired.

  Therefore, in this embodiment, the tension bar jack 20 is provided so as to be aligned with the fixing jack 10. The tension bar jack 20 applies a tensile force to the side foam 4 and the invert foam 5 in a state in which a tensile force is applied by the fixing jack 10, that is, in a developed state of the invert foam 5. As a result, the relative positional relationship between the invert form 5 or the side form 4 and the fixing jack 10 can be firmly held, and the gap between the lining concrete C and the invert form 5 caused by a plurality of play. Can be prevented.

  In addition, after placing the lining concrete C, the mold apparatus 1 remains in a fixed position as it is and plays a role of protecting the lining concrete C, so that the lighter weight is more advantageous. Here, if the fixing jack 10 and the tension rod jack 20 are arranged so as to overlap in the width direction of the tunnel T, the load (weight) applied to the foam group 2 partially increases, which may work disadvantageously. On the other hand, in the formwork apparatus 1 according to the present embodiment, the fixing jack 10 and the tension bar jack 20 are arranged in parallel in the length direction D of the tunnel T, which is advantageous in that it is easy to reduce the weight.

  Moreover, in the formwork apparatus 1 which concerns on this embodiment, as shown to Fig.7 (a), the expansion / contraction direction Da of the fixing jack 10 and the expansion / contraction direction Da of the tension rod jack 20 are the same direction. However, as shown in FIG. 5B, the fixing jack 10 and the tension bar jack 20 are arranged so that the expansion / contraction direction Da of the fixing jack 10 and the expansion / contraction direction Db of the tension bar jack 20 intersect each other. Can also be arranged.

  Next, with reference to FIG. 1 and FIG. 8, the construction method of the lining concrete C using the formwork apparatus 1 which concerns on said embodiment is demonstrated.

  When placing the lining concrete C, the mold apparatus 1 is transported by the gantry 50 to a predetermined position on the inner wall Ta of the tunnel T. The gantry 50 is detachably connected to the portal-type movable carriage 51 that can run on the rails laid along the length direction D of the tunnel T, corresponding to the shape of the foam group 2 of the formwork device 1. And a plurality of jack portions 53 that connect the movable carriage unit 51 and the wall 52, press the wall 52 against the mold apparatus 1, and support the wall 52 detachably from the mold apparatus 1. ing. In this embodiment, the gantry 50 that supports the formwork apparatus 1 through the wall 52 is illustrated, but a gantry that does not have the wall 52 and the jack portion 53 supports the formwork apparatus 1 may be used. .

  As shown in FIG. 8A, the gantry 50 that supports the formwork device 1 is disposed in a predetermined position on the inner wall Ta where the concrete has been sprayed in the tunnel T. The gantry 50 is installed on the inner wall Ta in a state where the foam group 2 of the formwork apparatus 1 is expanded through the wall 52. While maintaining this installation state, concrete for lining is filled into the foam group 2 of the mold apparatus 1 through the piping, and lining concrete C is placed (placement process).

  When the placing process is completed as shown in FIG. 8B, the gantry 50 is basically detached from the self-supporting formwork apparatus 1 until the lining concrete C is cured and stabilized, so that the formwork apparatus 1 is used. And protect (curing) the lining concrete C (protection process). In the protection process, the fixing jack 10 of the mold apparatus 1 applies a tension force to hold the unfolded state of the inverted foam 5 with respect to the side foam 4. Further, the tension bar jack 20 applies a tensile force to maintain the relative positional relationship of the fixing jack 10, the side foam 4, and the invert foam 5.

  When the protection process is completed, the gantry 50 is again placed inside the mold apparatus 1. Then, the gantry 50 is fixed to the mold apparatus 1, and the invert form 5 is reduced in diameter so that the mold apparatus 1 is detached from the inner wall Ta so as to be separated (mold releasing step).

  The above placement process, protection process, and mold release process are repeated, and the lining concrete C is applied to the inner wall Ta of the tunnel T.

  At the time of placing the lining concrete (placement process), since the gantry 50 supports the formwork device 1 via the plurality of jack portions 53, there is no gap between the wall 52 and the lining concrete. . However, in the protection process, in a state where the formwork apparatus 1 is detached, that is, in the middle of protecting the lining concrete C by unfolding the invert form 5, the invert form 5 is particularly at the top end form 3 or side. Due to the load of the entire foam group 2 such as the foam 4, displacement is likely to occur in the deployed state.

  On the other hand, according to the formwork apparatus 1 and the construction method of the lining concrete C according to the present embodiment, the invert foam 5 is covered while the invert foam 5 is deployed to protect the lining concrete. It is suppressed that it leaves | separates from the work concrete C and a clearance gap is produced, and the quality deterioration of the lining concrete C can be prevented.

  Moreover, since the lower end part (one end part) 10a of the fixing jack 10 according to the present embodiment is rigidly joined to the invert form 5, there is substantially no play and it is firmly fixed. Further, the upper end portion (the other end portion) 10 b is supported in a state of being in surface contact with the side foam 4. In the case of surface contact, the pulling force applied by the pull rod jack 20 increases the frictional force as compared with the point contact state, so that the occurrence of displacement (displacement) can be suppressed and the stability is increased. Can be protected properly. As a result, it is further advantageous in that the gap between the invert foam 5 and the lining concrete C is prevented and the quality deterioration of the lining concrete C is prevented. Further, since the upper end portion 10b can be detached from the side foam 4 when retracted, the upper end portion 10b can be detached when the diameter of the invert foam 5 is reduced, and as a result, it is easy to follow the swing of the invert foam 5. Become. Further, since the tension bar jack 20 is rotatably pin-connected to the side foam 4 and the invert foam 5, it is easy to follow the swing of the invert foam 5.

  Further, the pressing portion 15 of the fixing jack 10 is in surface contact with the side foam 4 on the surface P intersecting the pulling direction Dp of the tension bar jack 20. The surface contact on the plane P intersecting the pulling direction is effective for effectively applying and stabilizing the frictional force, and it is more advantageous especially on the plane perpendicular to the pulling direction.

  In addition, the fixing jack 10 according to the present embodiment exemplifies a mode in which the lower end portion 10a is rigidly joined to the invert form 5 and the pressing portion 15 that is the upper end portion 10b is fixed in a state of being in surface contact with the side foam 4. However, the same effect can be expected even in a mode in which the upper end portion 10b is rigidly joined to the side foam 4 and the lower end portion 10a is fixed in surface contact with the invert foam 5.

  In addition, as the deployment holding portion, it is possible to apply a tensile force, and the tension portion can achieve the object of the present invention as long as a tensile force can be applied. Therefore, the deployment holding portion is not limited to the above embodiment. As such, a hydraulic jack, a bar jack, or the like may be used, and a journal jack, a hydraulic jack, or the like may be used as the tension portion.

  In the above-described embodiment, the side foam is illustrated as an example of the first foam, and the inverted foam is illustrated as an example of the second foam. However, the present invention is not limited thereto, and the adjacent foams may be joined with a hinge structure. The present invention can be applied. For example, when the top form and the side form are connected by a hinge structure, the first form is the top form, the second form is the side form, and the side form is In order to prevent separation from the lining concrete, the development holding portion and the tension portion may be connected to the top end foam and the side foam.

  EXAMPLES Hereinafter, although an Example demonstrates this invention further in detail, this invention is not limited by a following example.

[Example 1]
In the formwork apparatus according to the above-described embodiment, when the protective process is performed using the fixing jack 10 provided with the pressing portion 15 shown in FIG. 5 in particular, there is a gap between the invert foam and the lining concrete. Did not occur.

[Example 2]
It is a formwork apparatus concerning the above-mentioned embodiment, and when a protection process was carried out especially using jack 10 for fixation provided with press part 15A shown in Drawing 6, there is a crevice between invert foam and lining concrete. Did not occur.

[Comparative Example 1]
When the protection process was carried out using the formwork apparatus according to Comparative Example 1 provided with only the fixing bar jacks that were pin-bonded at both ends without providing the tension portion, the thickness was about 10 mm between the invert foam and the lining concrete. A gap occurred.

[Comparative Example 2]
The basic configuration of the mold apparatus according to Comparative Example 1 is the same as that of Comparative Example 2, and the protection process was performed again. As a result, a gap of about 5 mm was found between the invert foam and the lining concrete. Occurred.

  DESCRIPTION OF SYMBOLS 1 ... Formwork apparatus, 2 ... Form group, 4 ... Side form (1st form), 5 ... Invert form (2nd form), 6 ... Hinge structure, 10 ... Fixing jack (deployment holding | maintenance part), 10a ... lower end (one end), 10b ... upper end (other end), 20 ... tension bar jack (tensile part), 50 ... gantry, C ... lining concrete, D ... length direction of tunnel, Dp ... tension direction , Da, Db ... stretching direction, P ... face, T ... tunnel, Ta ... inner wall.

Claims (10)

A formwork device for lining concrete to be constructed on the inner wall of a tunnel,
A group of foams having a plurality of foams joined together;
A hinge structure for joining adjacent first foam and second foam;
A deployment holding portion that is bonded to the first foam and the second foam and is stretchable, and is capable of imparting a tensile force to the first foam and the second foam;
The first foam and the second foam are connected to the first foam and extendable and extendable, and in the applied state of the tension force by the deployment holding portion, the first foam and the second foam. A lining concrete formwork apparatus, comprising: a tension portion capable of imparting a tensile force.   The formwork apparatus for lining concrete according to claim 1, wherein the first foam is a side foam, and the second foam is an inverted foam. The tension portion is rotatably pin-bonded to the first foam and the second foam,
The deployment holding portion includes one end portion joined to one of the first foam and the second foam, and the other end joined to the foam on the other.
The one end is rigidly joined to the one foam;
3. The formwork apparatus according to claim 2, wherein the other end portion is supported in a state of being in surface contact with the other foam at the time of extension, and is detachably joined from the other foam at the time of retraction.   4. The formwork apparatus according to claim 3, wherein the other end portion of the development holding portion is in surface contact with the other foam on a surface intersecting a pulling direction of the tension portion.   The formwork apparatus according to any one of claims 1 to 4, wherein the expansion / contraction direction of the tension part is the same direction as the expansion / contraction direction of the development holding part. The formwork apparatus according to any one of claims 1 to 4 , wherein the expansion / contraction direction of the tension part is a direction intersecting with the expansion / contraction direction of the development holding part.   The formwork device according to any one of claims 1 to 6, wherein the tension part is arranged in parallel to the length direction of the tunnel in which lining concrete is constructed with respect to the development holding part.   The formwork apparatus according to any one of claims 1 to 7, wherein the development holding part is a journal jack, and the tension part is a bar jack. It is a construction method of the lining concrete using the formwork apparatus as described in any one of Claims 1-8,
A protection step of placing a formwork device in a state in which lining concrete is placed inside the foam group,
In the protection step, the unfolding holding portion applies a tensile force to hold the unfolded state of the second foam with respect to the first foam, and the pulling portion applies a pulling force to the unfolding holding portion. A method for constructing lining concrete, characterized by maintaining a relative positional relationship between the first foam and the second foam. The first form is a side form and the second form is an inverted form;
After the placing step of placing lining concrete inside the foam group of the formwork apparatus installed on the inner wall of the tunnel by the gantry and maintained in the installed state, the protection step is performed,
In the protection step, the gantry is detached from the formwork apparatus, and the formwork apparatus is allowed to remain until the lining concrete is cured and stabilized.
The method for constructing lining concrete according to claim 9, further comprising: a mold release step for releasing the formwork device from the lining concrete by a gantry when the protection step is completed.

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