JP6802646B2 - Wall body, wall body construction method and formwork combined wall member - Google Patents

Description

The present invention relates to a wall body, a method for constructing the wall body, and a wall member that also serves as a formwork.

Most of the construction of reinforced concrete walls (hereinafter referred to as "RC walls") is by the wooden formwork method. In this construction method, an RC wall is constructed by performing a vertical bar assembly process, a horizontal bar assembly process, a wooden formwork installation process, and a concrete placing process. Since the wooden formwork has poor formwork rigidity, a large number of support members for holding the formwork have been arranged. Therefore, the wooden formwork requires a lot of time and effort for assembly and disassembly work, which may hinder the shortening of the construction period.
On the other hand, Patent Document 1 discloses a construction method for shortening the construction period by using a highly rigid precast concrete residual formwork. Since the precast concrete residual formwork has higher rigidity than the wooden formwork, the support members can be simplified and the formwork dismantling work becomes unnecessary. Therefore, according to the construction method of Patent Document 1, the construction efficiency can be improved and the construction period can be shortened.

Japanese Unexamined Patent Publication No. 6-10363

However, even if the residual formwork disclosed in Patent Document 1 is used, it is not possible to simplify the labor required for the work of arranging the vertical and horizontal bars. In particular, when the wall reinforcements are arranged in two rows (double reinforcements), even if the remaining formwork is used, the reinforcement work requires a great deal of time and effort.
From such a viewpoint, it is an object of the present invention to provide a wall body having a structure capable of simplifying the labor required for arranging the wall reinforcements and a method for constructing the wall body, and further, when constructing the wall body. An object of the present invention is to provide a wall member that also serves as a formwork that can simplify the work of arranging the wall reinforcements.

In order to solve the above problems, the wall body of the present invention is formed on a main body made of cast-in-place concrete, a surface part made of a plurality of precast concrete plates arranged side by side along the main body, and the precast concrete plate. Some include retained vertical and horizontal streaks, at least one of the vertical and horizontal streaks having a base along the precast concrete plate and a wrap portion overhanging the precast concrete plate. The boundary portion between the base portion and the wrap portion has a step processed so that the wrap portion is separated from the surface portion from the base portion, and is held by one of adjacent precast concrete plates. It is characterized in that the lap portion of the vertical bar or the horizontal bar and the base portion of the vertical bar or the horizontal bar held on the other side are connected by a lap joint.

According to such a wall body, at least one of the vertical and horizontal bars is held by the precast concrete plate, so that the arrangement of one or both of the vertical and horizontal bars is completed at the same time as the precast concrete plate is placed. Therefore, it is possible to omit or reduce the labor of bar arrangement work at the site.
Further, since the reinforcing bars held by the adjacent precast concrete plates are connected by the lap joint, the tensile force can be transmitted even at the boundary portion between the PCa plates.

The wall body may be formed so that a pair of the surface portions face each other with the main body portion interposed therebetween, or a surface portion may be formed on only one of the main body portions.
Further, if a part or all of the surface portion functions as a structure integrally with the main body portion, the wall body can be thinned.
It has truss reinforcements arranged so as to intersect the vertical reinforcements or the horizontal reinforcements, a part of the truss reinforcements is embedded in the main body portion, and the remaining portion is embedded in the precast concrete plate. For example, the wall body can be further thinned, and the surface portion can be prevented from falling off from the main body portion.
If a joint filled with concrete is formed between the adjacent precast concrete plates, the construction error can be absorbed by the gap between the precast concrete plates, and the construction speed can be improved.
If prestress is applied to the wall body via a tension material embedded along the vertical direction or the horizontal direction of the main body portion, the wall thickness can be further reduced and the seismic performance can be improved. It can be improved. When the main body is formed in a cylindrical shape, prestress may be applied via a ring-shaped tensioning material embedded in the main body.

Further, the method for constructing a wall body of the present invention is a method for constructing a wall body including a vertical streak and a horizontal streak intersecting the vertical streak, and a plurality of methods for holding at least one of the vertical streak and the horizontal streak. A PCa plate arranging step in which precast concrete plates are arranged side by side and a placing step in which concrete is placed on the back side of the plurality of precast concrete plates are provided, and the vertical streaks or the horizontal streaks held by the precast concrete plates are A base portion along the precast concrete plate and a wrap portion protruding from the precast concrete plate are provided, and the wrap portion is formed from the precast concrete plate rather than the base portion at a boundary portion between the base portion and the wrap portion. It has a step processed so as to be separated, and in the PCa plate arranging step, it is held by the lap portion of the vertical streak or the horizontal streak held by one of the adjacent precast concrete plates and the other. It is characterized in that the vertical bar or the base portion of the horizontal bar is connected by a lap joint.
According to the method of constructing the wall body, since the precast concrete plate that holds at least one of the vertical and horizontal bars is used, it is possible to omit or reduce the labor of the bar arrangement work at the site. Further, since the precast concrete plate is used as the weir plate, the number of support members such as crosspieces, single pipes, and separators can be reduced or omitted. Furthermore, since it is not necessary to remove the precast concrete plate, the formwork dismantling work becomes unnecessary.

Further, the formwork-combined wall member of the present invention is a member that constitutes a part of a wall body of a reinforced concrete structure, and is lateral between a pair of precast concrete plates facing each other at intervals and the precast concrete plates. It includes a erected connecting member and a wall reinforcement held by the precast concrete plate, and the wall reinforcement has a base along the precast concrete plate and a wrap portion overhanging from the precast concrete plate. The boundary portion between the base portion and the wrap portion is characterized by having a step processed so that the lap portion is separated from the precast concrete that holds the wall reinforcement than the base portion.
Since the wall member that also serves as a formwork functions as a formwork for the wall body, the labor required for disassembling the formwork can be omitted. In addition, the connecting member functions as a separator and contributes to ensuring rigidity as a reinforcing material.

The formwork-combined wall member may have a guide member interposed between the precast concrete plates. The guide member protrudes from the upper end of the precast concrete plate and is inserted between the precast concrete plates of other formwork-combining wall members arranged directly above the pair of precast concrete plates. In this way, positioning when stacking the wall members that also serve as formwork becomes easy, and workability is improved.

According to the present invention, the labor required for the bar arrangement work can be simplified. Further, according to the present invention, since the formwork dismantling work becomes unnecessary, cost reduction and shortening of the construction period can be expected. Furthermore, since the wall reinforcement held by the precast concrete plate can contribute to the rigidity of the wall body, the total cost can be reduced.

It is a perspective view which shows the wall body which concerns on 1st Embodiment. It is a figure which shows the wall member which also serves as a formwork, (a) is a perspective view, (b) is a side view. It is a perspective view which shows the wall streak held by the precast concrete plate. (A) is a perspective view showing a guide member, (b) is a side view showing a state in which a connecting member is mounted on the guide member, and (c) is a view taken along the line AA of (b). It is a front view which shows the construction situation of a wall body. (A) and (b) are perspective views which show the construction state of the wall body which concerns on 2nd Embodiment. It is a perspective view of the tank which concerns on 3rd Embodiment. It is a top view which shows the wall member which also serves as a formwork. It is a perspective view which shows the construction state of a wall body, (a) is a PCa board arrangement process, (b) is a bar arrangement process. It is a perspective view which shows the casting process. (A) is a casting process, and (b) is a PCa plate arranging process following (a). It is a perspective view which shows the PCa plate arrangement process which follows FIG.

<First Embodiment>
In the first embodiment, the reinforced concrete wall body 1 will be described.
As shown in FIG. 1, the wall body 1 includes a main body portion 2 and surface portions 3 and 3 formed on the front and rear surfaces of the main body portion 2.
The main body 2 is formed of cast-in-place concrete. Wall bars 4 (vertical bars 41 and horizontal bars 42) are embedded in the main body 2 as reinforcing materials (see FIG. 2).

In the wall body 1 of the present embodiment, a pair of surface portions 3 and 3 face each other with the main body portion 2 interposed therebetween.
The pair of surface portions 3, 3 are formed by connecting a plurality of wall members 5, 5, ... For both formwork, vertically and horizontally.
As shown in FIGS. 2A and 2B, the formwork-combined wall member 5 is laid horizontally between a pair of precast concrete plates 51, 51 facing each other at intervals and between the precast concrete plates 51. It includes a plurality of connecting members 52, 52, a guide member 53 interposed between the precast concrete plates 51, and wall bars 4 (vertical bars 41 and horizontal bars 42) held by the precast concrete plates 51. .. That is, the surface portion 3 is formed of a plurality of precast concrete plates 51, 51, ... Arranged in parallel along the main body portion 2.

The precast concrete plate 51 is formed of a concrete plate having a rectangular shape when viewed from the front. The shape and dimensions of the precast concrete plate 51 are not limited.
As shown in FIG. 1, a gap (joint) is formed between the precast concrete plates 51 adjacent to each other in the vertical and horizontal directions. The joints between the precast concrete materials are filled with concrete. The joint material is not limited to concrete, and may be, for example, mortar.
Wall reinforcements 4 are arranged on the inner surface side of the precast concrete plate 51. In the present embodiment, the vertical bars 41, the horizontal bars 42, and the truss bars 43, 44 (see FIG. 3) are arranged as the wall bars 4. The configuration of the wall bar 4 is not limited.

As shown in FIG. 3, the vertical bars 41 and the horizontal bars 42 are arranged along the inner surface of the precast concrete plate 51.
The vertical bars 41 are arranged at a predetermined pitch along the longitudinal direction of the precast concrete 51. The bar arrangement pitch and the reinforcing bar diameter of the vertical bar 41 are not limited and may be appropriately designed.
The vertical bar 41 has a length larger than the height of the precast concrete plate 51, and has a base portion 41a along the precast concrete plate 51 and a wrap portion 41b protruding from the upper end of the precast concrete plate 51. .. The vertical bar 41 has a step at the boundary between the base portion 41a and the wrap portion 41b. The wrap portion 41b of the vertical bar 41 is processed so as to be separated from the precast concrete plate 51 rather than the base portion 41a. The wrap portion 41b of the vertical bar 41 is inserted between the precast concrete plates 51, 51 of the other formwork-combined wall member 5 arranged above, and the vertical bar 41 of the other formwork-combined member 5 is inserted. It is attached to the inside of the base 41a of the.

The horizontal bars 42 are arranged at a predetermined pitch along the height direction of the precast concrete 51. The horizontal streaks 42 intersect the vertical streaks 41. The reinforcing bar arrangement pitch and the reinforcing bar diameter of the horizontal reinforcing bars 42 are not limited, and may be appropriately designed.
The horizontal bar 42 has a length larger than the width of the precast concrete plate 51, and has a base portion 42a along the precast concrete plate 51 and a wrap portion 42b protruding from the precast concrete plate 51. That is, in the formwork-combined wall member 5 of the present embodiment, both the vertical bars 41 and the horizontal bars 42 project from the ends of the precast concrete plate 51.
An inclined portion 42c is formed between the base portion 42a and the wrap portion 42b of the lateral bar 42. The inclined portion 42c is inclined so as to be separated from the precast concrete plate 51 from the base portion 42a toward the lap portion 42b. The wrap portion 42b is farther from the precast concrete plate 51 than the base portion 41a. The wrap portion 42b of the horizontal bar 42 is inserted between the precast concrete plates 51, 51 of the other formwork-combined wall member 5 adjacent to the side, and the base portion 42a of the horizontal bar 42 of the other formwork-combined member 5 is inserted. It is attached to the inside of.

As shown in FIG. 3, truss reinforcements 43 and 44 are arranged on the inner surface of the precast concrete plate 51 (the surface on the side of the other precast concrete plate 51). A part of the truss bars 43 and 44 is embedded in the main body portion 2, and the remaining portion is embedded in the precast concrete plate 51.
In the present embodiment, the truss muscle (horizontal truss muscle) 43 arranged so as to intersect the vertical muscle 41 and the truss muscle (vertical truss muscle) 44 arranged so as to intersect the horizontal muscle 42 are provided. There is. The horizontal truss bars 43 and the vertical truss bars 44 may be arranged as needed and may be omitted. Further, only one of the horizontal truss reinforcement 43 and the vertical truss reinforcement 44 may be arranged on the precast concrete plate 51.

The horizontal truss bar 43 holds the vertical bar 41. In the present embodiment, the vertical bar 41 is inserted into the space surrounded by the horizontal truss bar 43 and the precast concrete plate 51, and the vertical bar 41 is fixed to the horizontal truss bar 43. The method of fixing the vertical bar 41 is not limited, but for example, the vertical bar 41 and the horizontal truss bar 43 may be bound or welded by a binding line.
The vertical truss bar 44 holds the horizontal bar 42. In the present embodiment, the horizontal bar 42 is inserted into the space surrounded by the vertical truss bar 44 and the precast concrete plate 51, and the horizontal bar 42 is fixed to the vertical truss bar 44. The method of fixing the horizontal bar 42 is not limited, but for example, the horizontal bar 42 and the vertical truss bar 44 may be bound or welded by a binding line.

As shown in FIG. 2B, the connecting member 52 is laid horizontally between the precast concrete plates 51 to maintain a distance between the precast concrete plates 51.
The connecting member 52 of the present embodiment is made of a concave steel material (grooved steel). The connecting member 52 is provided so that the opening portion faces upward. The material constituting the connecting member 52 is not limited, and for example, L-shaped steel may be used. Further, the connecting member 52 may be provided so that the opening portion is on the lower side, and the orientation of the connecting member 52 is not limited.
In the present embodiment, the upper and lower two-stage connecting members 52, 52 are arranged in a plurality of rows at intervals in the longitudinal direction of the precast concrete plate 51, but the number and arrangement of the connecting members 52 are not limited. However, it may be set appropriately.
Fixing portions 52a are integrally formed at both ends of the connecting member 52. The fixing portion 52a is a plate material fixed to the inner surface of the precast concrete plate 51, and is welded to the end portion of the connecting member 52. The method of fixing the connecting member 52 is not limited. Further, the method of forming the fixing portion 52a is not limited.

As shown in FIG. 2B, the guide member 53 is fixed to the upper part of the precast concrete plate 51. The upper part of the guide member 53 protrudes from the upper end of the precast concrete plate 51, and the lower part of the guide member 53 is fixed to the inner surface of the precast concrete plate 51 (the surface on the other precast concrete plate 51 side). The method of fixing the guide member 53 to the precast concrete plate 51 is not limited, but is bolted in the present embodiment.

As shown in FIG. 4A, the guide member 53 includes a pair of vertical members 53a, 53a, a pair of vertical members 53b horizontally laid on the pair of vertical members, and a pair of vertical members 53a, 53a and 53b. It is provided with a pair of diagonal members 53c and 53c that connect the members. The configuration of the guide member 53 is not limited. The guide member 53 is fixed to the precast concrete plate 51 by bolts B penetrating the lower part of the vertical member 53a. The method of fixing the guide member 53 is not limited.
The upper portion of the guide member 53 (the portion protruding from the upper end of the precast concrete plate 51) is inserted between the precast concrete plates 51 and 51 of the other formwork-combined wall member 5 arranged directly above. On the guide member 53, a connecting member 52 of the formwork-combining wall member 5 arranged above is placed.

As shown in FIG. 4B, the upper portion of the vertical member 53a is inclined so that the width becomes smaller toward the upper end. In this way, the guide member 53 can be easily inserted into the other formwork-combined wall member 5 adjacent to the upper side.
A pedestal 53d is formed at the upper end of the vertical member 53a. The pedestal 53d is formed by fixing (for example, welding) a concave steel material to the upper end of the vertical member 53a. As shown in FIGS. 4 (b) and 4 (c), the pedestal 53d can insert the connecting member 52 of the upper formwork / wall member 5 when the formwork / wall member 5 is stacked one above the other. It has a possible shape. The receiving material 53d does not necessarily have to be a concave steel material, and may be, for example, a flat plate. Further, when the upper end of the vertical member 53a is processed so that the connecting member 52 can be mounted, or when it is not necessary to mount the connecting member 52 on the guide member 53, the receiving member 53d is omitted. You may.

Next, a method of constructing the wall body of the present embodiment will be described.
The method of constructing the wall body includes a PCa plate arranging step and a placing step.
As shown in FIG. 5, the PCa plate material arranging step is a step of arranging a plurality of precast concrete plates 51, 51, ... In parallel. In the present embodiment, the precast concrete plates 51 are arranged side by side by arranging the formwork and wall members 5 side by side for each stage.
Since the vertical bars 41 and the horizontal bars 42 are held by the precast concrete plate 51, when the formwork-combined wall member 5 is arranged, the necessary wall bars 4 are arranged. The wall bars 4 held by the adjacent formwork-combined wall members 5 are connected to each other by a lap joint between the lap portions 41b and 42b and the base portions 41a and 42a.

When the formwork / wall member 5 is placed on the existing formwork / wall member 5, a gap is formed between the precast concrete plates 51 by the guide member 53. Further, since the guide member 53 and the joining member 52 are engaged with each other, the positioning of the formwork / wall member 5 in the lateral direction (left and right in FIG. 5) is completed at the same time. Joints (gap) are formed between the precast concrete plates 51 adjacent to each other on the upper and lower sides and between the precast concrete plates 51 adjacent to each other on the left and right sides. The joints 6 may be formed as needed, and the precast concrete plates 51 may be in contact with each other.

The placing step is a step of placing concrete between the surface portions 3 (opposing precast concrete plates 51). The concrete is placed in a state where a formwork (not shown) is installed in the gap between the precast concrete plates 51. The concrete is cast so as to involve the wall reinforcement 4.
After curing the concrete, the formwork is removed and the joint 6 is filled with concrete.
The concrete may be cast for each stage of the formwork / wall member 5, or the formwork / wall member 5 may be assembled in a plurality of stages and then put together.

As described above, according to the wall body 1 and the construction method of the wall body of the first embodiment, since the vertical bars 41 and the horizontal bars 42 are held by the precast concrete plate 51, the formwork and wall member 5 is arranged at the same time. Reinforcement of wall reinforcement 4 is completed. Further, since the vertical bars 41 and the horizontal bars 42 are continuous by the lap joints using the lap portions 41b and 42b protruding from the precast concrete plate 51, the tensile force is transmitted even at the boundary portion between the formwork and wall members 5. can do. Therefore, the labor of bar arrangement work at the site can be significantly reduced, and by extension, the wall body 1 having a desired yield strength can be easily constructed.

Since the surface portion 3 is integrally formed with the main body portion 2 via the truss bars 43, 44 and the like, the surface portion 3 functions as a structure integrally with the main body portion 2. Therefore, the wall thickness of the entire wall body 1 can be reduced, which is economical.
Further, since the truss bars 43 and 44 are arranged so as to straddle the main body portion 2 and the surface portion 3, the precast concrete plate 51 is prevented from falling off.
Since the joints 6 are formed between the precast concrete plates 51, even if a construction error should occur, the joints 6 can absorb the joints 6.

Since the precast concrete plate 51 is used as a weir plate, support members such as crosspieces, single pipes, and separators can be reduced or omitted. Further, since the formwork dismantling work is not required, the workability is excellent.
Since the wall member 5 that also serves as a formwork is used, the formwork may be arranged only at the joints. Therefore, the labor required for formwork can be reduced. That is, by arranging the formwork-combined wall members 5 in parallel, the formwork can be installed at a desired position. Further, since it is not necessary to remove the wall member 5 that also serves as a formwork, the labor required for removing the formwork can be omitted. Since the formwork-combined wall member 5 has the guide member 53, the formwork-combined wall member 5 can be easily positioned.

<Second embodiment>
In the second embodiment, the wall body 1 formed between the columns 7 and 7 will be described.
As shown in FIGS. 6A and 6B, the wall body 1 is formed by stacking formwork-combining wall members 5 and 5 between the left and right columns 7 and 7.
The formwork-combined wall member 5 includes a pair of precast concrete plates 51, 51 facing each other at intervals, and a plurality of connecting members 52, 52 horizontally laid between the precast concrete plates 51 (see FIG. 2B). ) And wall bars 4 (vertical bars 41 and horizontal bars 42) held by the precast concrete plate 51. A guide member is arranged on the formwork-combined wall member 5 as needed.

The precast concrete plate 51 becomes the surface portion 3 of the wall body 1. Since the details of the precast concrete plate 51 are the same as those shown in the first embodiment, detailed description thereof will be omitted.

The vertical bars 41 and the horizontal bars are arranged along the inner surface of the precast concrete plate 51.
The vertical bars 41 are arranged at a predetermined pitch along the longitudinal direction of the precast concrete 51. The bar arrangement pitch and the reinforcing bar diameter of the vertical bar 41 are not limited and may be appropriately designed.
The vertical bar 41 has a length larger than the height of the precast concrete plate 51, and has a base portion 41a along the precast concrete plate 51 and a wrap portion 41b protruding from the upper end of the precast concrete plate 51. .. The vertical bar 41 has a step at the boundary between the base portion 41a and the wrap portion 41b. The wrap portion 41b of the vertical bar 41 is processed so as to be separated from the precast concrete plate 51 with respect to the base portion 41a. The wrap portion 41b of the vertical bar 41 is inserted between the precast concrete plates 51, 51 of the other formwork-combined wall member 5 arranged above, and the vertical bar of the other formwork-combined wall member 5 is inserted. It is attached to the inside of the base 41a of 41.

The horizontal bars 42 are arranged at a predetermined pitch along the height direction of the precast concrete plate 51. The horizontal streaks 42 are orthogonal to the vertical streaks 41. The horizontal bar 42 has a length that fits within the width dimension of the precast concrete plate 51. That is, in the formwork-combined wall member 5 of the present embodiment, only the vertical streaks project from the end of the precast concrete plate 51. The reinforcing bar arrangement pitch and the reinforcing bar diameter of the horizontal reinforcing bars 42 are not limited, and may be appropriately designed. Further, truss reinforcements may be arranged on the inner surface of the precast concrete plate 51 as needed.
The connecting member 52 is laid horizontally between the precast concrete plates 51 to maintain a distance between the precast concrete plates 51 (see FIG. 2B). Since the details of the connecting member 52 are the same as those shown in the first embodiment, detailed description thereof will be omitted.

Next, a method of constructing the wall body of the present embodiment will be described.
The method of constructing the wall body includes a PCa plate arranging step and a placing step.
The PCa plate material arranging step is a step of arranging a plurality of precast concrete plates 51, 51. In the present embodiment, the precast concrete plate 51 is arranged by inserting the formwork and wall member 5 between the left and right columns 7 and 7.
Since the vertical bars 41 and the horizontal bars 42 are held by the precast concrete plate 51, when the formwork-combined wall member 5 is arranged, the necessary wall bars 4 are arranged. The vertical bars 41 held by the vertically adjacent formwork-combined wall members 5 are connected to each other by a lap joint with a base portion 41a and a wrap portion 41b.

In the pillar 7, a plurality of fixing members 71, 71, ... Are pre-planted on the surface of the wall member 5 that also serves as a formwork. The configuration and forming method of the fixing member 71 are not limited. For example, when constructing the column 7, the fixing member 71 may be formed by projecting a reinforcing bar from the side surface, or the fixing member 71 may be formed by planting a reinforcing bar or the like on the side surface of the column 7 by post-construction. You may.
When the formwork-combined wall member 5 is arranged between the columns 7, the fixing members 71, 71, ... Are inserted between the front and rear precast concrete plates 51, 51, and the fixing members 71, 71, ... Are horizontal streaks. It is connected to 42, 42, ... By a lap joint.

The placing step is a step of placing concrete between the surface portions 3 (precast concrete plates 51, 51 before and after facing each other). The concrete is cast so as to involve the wall reinforcement 4 and the fixing member 71.
The concrete may be cast for each stage of the formwork / wall member 5, or the formwork / wall member 5 may be assembled in a plurality of stages and then put together.

As described above, according to the wall body 1 and the construction method of the wall body of the second embodiment, since the vertical bars 41 and the horizontal bars 42 are held by the precast concrete plate 51, the formwork and wall member 5 is arranged at the same time. Reinforcement of wall reinforcement 4 is completed. Further, since the vertical bars 41 are continuous by the lap joint using the lap portion 41b protruding from the precast concrete plate 51, the tensile force can be transmitted even at the boundary portion between the formwork and wall members 5. Therefore, the labor of bar arrangement work at the site can be significantly reduced, and by extension, the wall body 1 having a desired yield strength can be easily constructed.
Since the wall body 1 is joined to the pillar 7 via the fixing member 71, it functions as a building frame together with the pillar 7.

Since the precast concrete plate 51 is used as a weir plate, support members such as crosspieces, single pipes, and separators can be reduced or omitted. Further, since the formwork dismantling work is not required, the workability is excellent.
Since the wall member 5 that also serves as a formwork is used, the time and effort required for installing and removing the formwork can be omitted. That is, by arranging the formwork-combined wall members 5 in parallel, the formwork can be installed at a desired position. Further, since it is not necessary to remove the wall member 5 that also serves as a formwork, the labor required for removing the formwork can be omitted.

<Third embodiment>
In the third embodiment, the case where the wall body 1 of the tank T shown in FIG. 7 is formed will be described.
The wall body 1 is formed in a cylindrical shape. The shape of the wall body 1 is not limited to a cylindrical shape, and may be, for example, a square cylinder shape.
Prestress is introduced into the wall body 1 through a tension material embedded along the lateral direction. In addition, a tension material may be embedded in the wall body 1 along the vertical direction.

In the wall body 1 of the present embodiment, a pair of surface portions 3 and 3 face each other with the main body portion 2 interposed therebetween (see FIG. 10).
The pair of surface portions 3, 3 are formed by connecting a plurality of wall members 5, 5, ... For both formwork, vertically and horizontally.
As shown in FIG. 8, the formwork-combined wall member 5 includes a pair of precast concrete plates 51, 51 facing each other at intervals, and a plurality of connecting members 52, 52 horizontally laid between the precast concrete plates 51. , ... And the horizontal streaks 42 held by the precast concrete plate 51. That is, the surface portion 3 is formed of a plurality of precast concrete plates 51, 51, ... Arranged in parallel along the main body portion 2. A guide member is provided on the formwork-combined wall member 5 as needed.
In the formwork combined wall member 5, the gap between the left and right adjacent precast concrete plates 51 on the inner air side of the tank T is smaller than the gap between the left and right adjacent precast concrete plates 51 on the outside of the tank T. Arrange.
Since the details of the precast concrete plate 51 are the same as those shown in the first embodiment, detailed description thereof will be omitted.

Wall reinforcements 4 are arranged on the inner surface side of the precast concrete plate 51. In the present embodiment, the lateral muscle 42 and the truss muscle 43 are arranged as the wall muscle 4. The configuration of the wall bar 4 is not limited.
The horizontal bars 42 are arranged at a predetermined pitch along the height direction of the precast concrete 51. The reinforcing bar arrangement pitch and the reinforcing bar diameter of the horizontal reinforcing bars 42 are not limited, and may be appropriately designed.

The horizontal bar 42 has a length larger than the width of the precast concrete plate 51, and has a base portion 42a along the precast concrete plate 51 and a wrap portion 42b protruding from the precast concrete plate 51. An inclined portion 42c is formed between the base portion 42a and the wrap portion 42b of the lateral bar 42. The inclined portion 42c is inclined so as to be separated from the precast concrete plate 51 from the base portion 42a toward the lap portion 42b. The wrap portion 42b is farther from the precast concrete plate 51 than the base portion 41a. The wrap portion 42b of the present embodiment is bent toward the inner air side of the tank T according to the shape of the cylindrical wall body 1. That is, the wrap portion 42b is inclined with respect to the base portion 42a (precast concrete plate 51).
As shown in FIG. 9A, the wrap portion 42b of the horizontal bar 42 is inserted between the precast concrete plates 51, 51 of the other formwork-combining wall member 5 adjacent to the side, and the other mold is inserted. It is attached to the inside of the base portion 42a of the horizontal bar 42 of the frame-combined wall member 5. That is, the formwork-combined wall member 5 of the present embodiment holds in advance only the horizontal streaks 42 in a state of protruding from the end portion of the precast concrete plate 51.

As shown in FIG. 8, a truss bar 43 is planted on the inner surface of the precast concrete plate 51 (the surface on the side of the other precast concrete plate 51). A part of the truss bar 43 is embedded in the main body 2, and the remaining part is embedded in the precast concrete plate 51.
The truss muscles 43 are arranged along the lateral muscles 42. The truss reinforcement 43 may be arranged as needed, and may be omitted.
The truss bar 43 holds the vertical bar 41. In the present embodiment, the vertical bars are arranged by inserting the vertical bars 41 into the space surrounded by the truss bars 43 and the precast concrete plate 51. The method of fixing the vertical bar 41 is not limited, but for example, the vertical bar 41 and the horizontal truss bar 43 may be bound by a binding line.

The vertical bars 41 of the present embodiment are arranged at a predetermined pitch along the longitudinal direction of the precast concrete plate 51 after the formwork and wall member 5 is arranged at a predetermined position. The bar arrangement pitch and the reinforcing bar diameter of the vertical bar 41 are not limited and may be appropriately designed. The vertical 41 may be held in advance by the precast concrete plate 51.
The vertical bar 41 has a length larger than the height of the precast concrete plate 51, and as shown in FIG. 9B, the upper portion of the vertical bar 41 protrudes from the upper end of the precast concrete plate 51 when the reinforcing bars are arranged. The vertical bar 41 is inserted between the precast concrete plates 51, 51 of the other formwork-combining wall member 5 arranged above.

As shown in FIG. 8, the connecting member 52 is laid horizontally between the precast concrete plates 51 to maintain a distance between the precast concrete plates 51. Since the details of the connecting member 52 are the same as those shown in the first embodiment, detailed description thereof will be omitted.

Next, a method of constructing the wall body of the present embodiment will be described.
The wall body construction method includes a PCa plate arranging step, a tension material setting step, a bar arrangement step, a formwork step, and a placing step.
As shown in FIG. 9A, the PCa plate material arranging step is a step of arranging a plurality of precast concrete plates 51, 51, ... In parallel. Precast concrete plates 51 are arranged side by side by arranging the formwork-combined wall members 5 side by side.
Since the formwork-combined wall member 5 is held by the horizontal bars 42 via the precast concrete plate 51, when the formwork-combined wall member 5 is arranged, the necessary horizontal bars 42 are arranged. The horizontal bars 42 held by the adjacent formwork-combined wall members 5 are connected to each other by a lap joint 42b and a base 42a.

The tension material installation step is a step of arranging the ring-shaped tension material 8 between the precast concrete plates 51.
As shown in FIG. 9B, the bar arrangement step is a step of arranging the vertical bars 41. The vertical bar 41 is arranged by inserting it into the gap between the truss bar 43 and the precast concrete plate 51.
The formwork process is a process of installing the formwork 9 in the gap between the precast concrete plates 51. In addition, with the installation of the formwork 9, tension is applied to the tension member 8. The timing of applying tension to the tension member 8 is not limited.

As shown in FIG. 10A, the placing step is a step of placing concrete between the surface portions 3 (opposing precast concrete plates 51). The concrete is cast so as to involve the wall bars 4 (vertical bars 41 and horizontal bars 42).
After curing the concrete, the formwork 9 is removed and the joint 6 is filled with concrete.
Subsequently, as shown in FIG. 10B, by repeating the PCa plate arranging step, the tension material setting step, the bar arrangement step, the formwork step, and the casting step, the wall body 1 having a predetermined height 1 To form. As shown in FIG. 11, the inner precast concrete plate 51 is arranged at the portion corresponding to the end portion (fixing body 11) of the tension member 8.

As described above, according to the wall body 1 and the construction method of the wall body of the third embodiment, the arrangement of the horizontal bars 42 is completed at the same time as the formwork and wall member 5 is arranged. Further, since the horizontal bars 42 are continuous by the lap joint, the tensile force can be transmitted even at the boundary portion between the formwork and wall members 5. Therefore, the labor of bar arrangement work at the site can be significantly reduced, and by extension, the wall body 1 having a desired yield strength can be easily constructed.
Since the joints 6 are formed between the precast concrete plates 51, even if a construction error should occur, the joints 6 can absorb the joints 6.
Since the precast concrete plate 51 is used as a weir plate, support members such as crosspieces, single pipes, and separators can be reduced or omitted.
Since the wall member 5 that also serves as a formwork is used, the amount required for installation and removal of the formwork can be reduced. That is, by arranging the formwork-combined wall members 5 in parallel, the formwork can be installed at a desired position. Therefore, the formwork 9 may be installed only at the joints between the precast concrete plates 51. Further, since it is not necessary to remove the wall member 5 that also serves as a formwork, it is possible to reduce the time and effort required to remove the formwork.
Since the wall body 1 is prestressed via the ring-shaped tension member 8, it is excellent in high yield strength and earthquake resistance.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and each of the above-mentioned components can be appropriately modified without departing from the spirit of the present invention.
In each of the above embodiments, the wall body 1 in which the pair of surface portions 3 and 3 are formed so as to face each other with the main body portion 2 interposed therebetween has been described, but the wall body 1 has a surface portion only on one of the main body portions 2. 3 may be formed.
In each of the above embodiments, the case where the opposing precast concrete plates 51 and 51 have the same shape has been described, but the shapes of the opposing precast concrete plates 51 and 51 may be different. For example, when forming the cylindrical wall body 1, the width (length in the longitudinal direction) of the precast concrete plate 51 on the outer peripheral side may be larger than the width of the precast concrete plate 51 on the inner peripheral side.

1 Wall body 2 Main body 3 Surface 4 Wall reinforcement 41 Vertical reinforcement 42 Horizontal reinforcement 43,44 Truss reinforcement 5 Formwork combined wall member 51 Precast concrete plate 52 Connection member 53 Guide member 6 Joint 7 Pillar 8 Tension material

Claims (10)

The main body made of cast-in-place concrete and
A surface portion composed of a plurality of precast concrete plates arranged side by side along the main body portion,
A wall body having vertical and horizontal streaks held on the precast concrete plate.
At least one of the vertical streaks and the horizontal streaks has a base along the precast concrete plate and a wrap portion protruding from the precast concrete plate.
The boundary portion between the base portion and the wrap portion has a step processed so that the lap portion is separated from the surface portion from the base portion.
That the lap portion of the vertical bar or the horizontal bar held by one of the adjacent precast concrete plates and the base portion of the vertical bar or the horizontal bar held by the other are connected by a lap joint. The characteristic wall body. The wall body according to claim 1, wherein the pair of the surface portions face each other with the main body portion interposed therebetween. The wall body according to claim 1 or 2, wherein a part or all of the surface portion functions as a structure integrally with the main body portion. It has truss muscles arranged so as to intersect the vertical or horizontal muscles,
The method according to any one of claims 1 to 3, wherein a part of the truss bar is embedded in the main body portion and the remaining portion is embedded in the precast concrete plate. Wall body. The wall body according to any one of claims 1 to 4, wherein joints filled with concrete are formed between adjacent precast concrete plates. The wall body according to any one of claims 1 to 5, characterized in that prestress is applied via a tension material embedded along the vertical direction or the horizontal direction of the main body portion. .. The main body is formed in a cylindrical shape.
The wall body according to any one of claims 1 to 5, wherein prestress is applied via a ring-shaped tensioning material embedded in the main body. A method of constructing a wall body having vertical bars and horizontal bars intersecting the vertical bars.
A PCa plate arranging process in which a plurality of precast concrete plates holding at least one of a vertical streak and a horizontal streak are arranged side by side,
It is provided with a placing step of placing concrete on the back side of the plurality of precast concrete plates.
The vertical or horizontal streaks held on the precast concrete plate have a base along the precast concrete plate and a wrap portion overhanging from the precast concrete plate.
The boundary portion between the base portion and the wrap portion has a step processed so that the lap portion is separated from the precast concrete plate from the base portion.
In the PCa plate arranging step, the lap portion of the vertical bar or the horizontal bar held by one of the adjacent precast concrete plates and the base portion of the vertical bar or the horizontal bar held by the other are overlapped and joined. A method of constructing a wall body, which is characterized by being connected by. A wall member that also serves as a formwork that forms part of a wall body with a reinforced concrete structure.
A pair of precast concrete plates facing each other at intervals,
A connecting member laid horizontally between the precast concrete plates and
With a wall streak held on the precast concrete plate,
The wall bar has a base along the precast concrete plate and a wrap portion protruding from the precast concrete plate.
The boundary portion between the base portion and the wrap portion is characterized by having a step processed so that the lap portion is separated from the base portion by the precast concrete plate that holds the wall reinforcement. A wall member that also serves as a formwork. It is provided with a guide member that is laid horizontally between the precast concrete plates and projects from the upper end of the precast concrete plates.
The ninth aspect of the present invention, wherein the protruding portion of the guide member is inserted between the precast concrete plates of other formwork-combining wall members arranged directly above the pair of precast concrete plates. Formwork and wall member.

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