JP2011026849A - Board for embedded form - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a board for an embedded form hardly causing the damage of protrusions and recesses provided on one side. <P>SOLUTION: The board 1 for the embedded form is made of a hardened body of a mixture containing cement, fine powder with a BET specific surface area of 3-25 m<SP>2</SP>/g, fine aggregate, water, a water reducing agent and aramid fiber with a diameter of 0.02-0.2 mm and a length of 1-30 mm. In the board 1 for the embedded form, (i) the whole surface of one side of the board 1 is almost uniformly provided with a plurality of protrusions 3 with a height of 3 mm or more and a plurality of recesses with a depth of 3 mm or more, (ii) the cut surface area of the protrusions 3 or recesses is 10-80% to the projected area of the one side having the protrusions 3 or recesses, and (iii) the area ratio (S1/S2) of the whole surface area (S1) of the one side to the projected area (S2) of the one side having the protrusions 3 or recesses is 1.2-7.0. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an embedded formwork board made of a cementitious hardened body, which is a unit member constituting the embedded formwork.

  An embedded mold that is used as a formwork for forming a concrete structure, and remains integrated with post-cast concrete without being removed even after post-cast concrete is placed and cured in the mold. A frame is conventionally known. The embedded formwork is assembled into a desired shape such as a beam by appropriately combining various embedded formwork boards that are constituent members thereof.

From the viewpoint of the durability of concrete structures, the embedded formwork board should have increased durability of the embedded formwork board itself, as well as increased adhesion and shear strength between the embedded formwork board and the post-cast concrete. Is desired.
Conventionally, as an embedded formwork board having such a performance, for example, Patent Document 1 proposes an embedded formwork having a specific shape, and Patent Document 2 discloses a precast product having a specific shape. Buried formwork has been proposed. That is, the embedded formwork of Patent Document 1 is a concrete made of gravel, sand, a net-like body, etc. on one side of a formwork body composed of a panel-like core material and surface reinforcing layers formed on both sides of the core material. The fixing protrusions are arranged. The embedded form of Patent Document 1 has improved durability by providing surface reinforcing layers formed of glass fiber reinforced plastic on both surfaces of a core material formed of resin mortar. In addition, the precast embedded formwork disclosed in Patent Document 2 has a configuration in which a cone-shaped projection (regular polygonal pyramid shape or regular polygonal frustum shape) is provided on substantially the entire surface that is in close contact with the post-cast concrete. The precast embedded formwork of Patent Document 2 is formed on the one side surface that comes into contact with the post-cast concrete without forming a gap, thereby forming a regular polygonal pyramid projection with a continuous bottom surface, The contact area with the post-cast concrete is increased to increase the adhesion between them.

JP 2000-45432 A JP-A-7-52133

However, the embedded form of Patent Document 1 is formed so that a plurality of concrete fixing protrusions are concentrated on the central part of one side of the embedded form and the frame-like plane part remains around it. Therefore, the adhesive force between the frame-like plane portion of the embedded mold and the post-cast concrete is reduced, and peeling is likely to occur in the plane portion. When such peeling occurs, water easily enters the interface between the embedded formwork and the post-cast concrete, and there is a problem that the durability of the concrete structure is lowered.
Furthermore, the embedded form of Patent Document 1 is manufactured by bringing a surface reinforcing layer made of glass fiber reinforced plastic into close contact with both sides of a resin mortar core, and heating and pressing from both sides. Therefore, there is a problem that it takes time to manufacture.

Since the shape of the projection of the precast embedded form of Patent Document 2 is a cone shape (regular polygonal pyramid shape or regular polygonal frustum shape), during transportation or construction of the precast embedded formwork, There is a problem that the tip portion of the protrusion is easily damaged, and requires care in handling. For example, when the tip of the protrusion of the precast embedded mold is damaged, the expected adhesive force and shear strength may not be obtained.
In addition, since the precast embedded formwork of Patent Document 2 is provided with a cement mortar layer on the concrete surface, and a cone-shaped projection is produced on the cement mortar layer with a dedicated formwork, it is troublesome to produce. There is also a problem of this.
Therefore, the present invention is less prone to breakage of convex portions or concave portions provided on one side, has excellent adhesion and shear strength with post-cast concrete, has high shielding properties and durability, has high mechanical strength, and is manufactured. It is an object to provide an embedded formwork board that is easy.

As a result of intensive studies to solve the above-mentioned problems, the inventors have made a cemented hardened body containing a specific material and have a convex portion or a specific shape on the surface that comes into contact with the post-cast concrete. The present invention has been completed by finding that the above problems can be solved by a buried formwork board having a concave portion.
That is, the embedded formwork board of the present invention is cement, fine powder having a BET specific surface area of 3 to 25 m ² / g, fine aggregate, water, water reducing agent, and monofilament having a diameter of 0.02 to 0.2 mm and a length of 1 to 30 mm. Embedded board made of a cured product of a compound containing aramid fibers of the type, and (i) a plurality of protrusions having a height of 3 mm or more substantially uniformly over the entire surface of one side of the embedded form board (Ii) a cut surface at a height of 3 mm of the convex portion or a depth of 3 mm of the concave portion (provided that the height of the convex portion is 3 mm) Or, when the depth of the concave portion is 3 mm, the area of the surface area) is 10 to 80% with respect to the projected area of one side having the convex portion or the concave portion, and (iii) the convex portion or The surface between the total surface area (S1) of one side having the concave portion and the projected area (S2) of the single side having the convex portion or the concave portion. A board for buried mold, characterized in that the ratio (S1 / S2) is 1.2 to 7.0.

  The embedded formwork board of the present invention is made of a hardened cementitious material and has a convex portion or a concave portion of a specific shape substantially uniformly over the entire surface of one side. It is not easily damaged and has excellent adhesion and shear strength with post-cast concrete. The embedded formwork board of the present invention is made of a hardened cementitious material, has high mechanical strength, and has high shielding properties and durability. Moreover, the embedded formwork board of the present invention can be easily manufactured because the convex portion or the concave portion and the other portion (main body portion) can be integrally formed using the same material. Can do.

It is a perspective view which shows an example (part) of the board for embedding forms of this invention. It is sectional drawing which shows an example (part) of the board | substrate for embedment formwork of this invention. It is sectional drawing which shows an example (part) of the concrete structure containing the embedment formwork board of this invention. It is a perspective view which shows another example (part) of the board for embedding forms of this invention. It is sectional drawing which shows another example (part) of the board for embedding forms of this invention. It is a figure explaining the measuring method of adhesion strength ((a); perspective view of a test body, (b); front view of a test body (part)).

The embedded formwork board of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a perspective view showing an example (part) of an embedded formwork board according to the present invention, FIG. 2 is a cross-sectional view showing an example (part) of an embedded formwork board according to the present invention, and FIG. It is sectional drawing which shows an example (part) of the concrete structure containing an embedded formwork board.
As shown in FIGS. 1 to 3, the embedded formwork board 1 of the present invention includes a plate-like main body portion 2 made of a hardened cementitious material, and one side 4 of the main body portion 2 (on the side on which the post-cast concrete is poured). A plurality of convex portions 3 having a specific shape and formed substantially uniformly over the entire surface. The embedded formwork board 1 shown in FIGS. 1 to 3 shows an example in which a cylindrical convex portion 3 is formed on one surface 4 (reference surface) of the main body 2.
The embedded formwork board of the present invention is used, for example, in the form as shown in FIG. As shown in FIG. 3, the two embedded formwork boards 1, 1 are arranged so that the surfaces (one surface 4) on the side having the plurality of convex portions 3 are opposed to each other, and the two embedded arrangements thus arranged Post-cast concrete 6 is placed between the formwork boards 1, 1 to form a concrete structure 5. The two embedded formwork boards 1, 1 are left as constituent parts of the concrete structure 5 without being removed even after the post-cast concrete 6 is hardened.

FIG. 4 is a perspective view showing another example (part) of the embedded formwork board of the present invention, and FIG. 5 is a cross-sectional view showing another example (part) of the embedded formwork board of the present invention.
As shown in FIGS. 4 and 5, the embedded formwork board 10 of the present invention includes a plate-like main body portion 11 made of a hardened cementitious material and one side 13 of the main body portion 11 (on the side where the post-cast concrete is poured). A plurality of concave portions 12 having a specific shape and formed substantially uniformly over the entire surface. The embedded formwork board 10 shown in FIGS. 4 and 5 shows an example in which a quadrangular prism-shaped concave portion 12 is formed on one surface 13 (reference surface) of the main body 11.

Next, the cementitious hardened body constituting the embedded formwork board of the present invention will be described in detail.
The cementitious hardened body is made of cement, fine powder having a BET specific surface area of 3 to 25 m ² / g, fine aggregate, water, a water reducing agent, and a monofilament type aramid fiber having a diameter of 0.02 to 0.2 mm and a length of 1 to 30 mm. It is the hardening body of the formulation containing.

The type of cement is not particularly limited. For example, various portland cements such as ordinary portland cement, early-strength portland cement, medium heat portland cement, low heat portland cement, and mixed cements such as blast furnace cement and fly ash cement are used. be able to.
In the present invention, when trying to improve the early strength of the cured product of the blend, it is preferable to use early-strength Portland cement, and when trying to improve the fluidity of the blend, It is preferable to use heat Portland cement or low heat Portland cement.

Examples of the fine powder having a BET specific surface area of 3 to 25 m ² / g include silica fume, silica dust, fly ash, slag, volcanic ash, silica sol, precipitated silica, and limestone powder. In general, silica fume and silica dust have a BET specific surface area of 5 to 25 m ² / g and do not need to be pulverized, and thus are suitable as the fine powder of the present invention. Moreover, limestone powder is also suitable as the fine powder of the present invention from the viewpoints of pulverizability and fluidity.
The fine powder has a BET specific surface area of 3 to 25 m ² / g, preferably 7 to 15 m ² / g. When the value is less than 3 m ² / g, the compressive strength of the cured product is lowered, and the denseness and impact resistance are also lowered. On the other hand, when the value exceeds 25 m ² / g, it is difficult to obtain, the unit water amount increases, and the strength, denseness, impact resistance, etc. of the cured product may be lowered.
The blending amount of the fine powder is preferably 5 to 50 parts by mass, more preferably 10 to 40 parts by mass with respect to 100 parts by mass of cement. When the blending amount is less than 5 parts by mass, the compressive strength of the cured body is lowered, and the denseness and impact resistance are also lowered. On the other hand, when the blending amount exceeds 50 parts by mass, the unit water amount increases, and the strength, denseness, impact resistance and the like of the cured body may be lowered.

Examples of the fine aggregate include river sand, land sand, sea sand, crushed sand, silica sand, and the like, or a mixture thereof. In the present invention, as the fine aggregate, the maximum particle size is 2 mm or less, more preferably 1.5 mm or less, from the fluidity of the composition, the strength of the cured product, the denseness, the impact resistance, etc. preferable. From the viewpoint of fluidity and workability, the proportion of particles having a size of less than 0.15 mm in the fine aggregate is preferably 5.0% by mass or less.
The amount of fine aggregate blended is 100 parts by mass of cement from the viewpoint of fluidity and workability of the blend, the strength of the cured body, and further from the viewpoints of reducing self-shrinkage and drying shrinkage, and reducing the amount of heat generated by hydration. Is preferably 50 to 250 parts by mass, more preferably 80 to 180 parts by mass.

As water, tap water or the like can be used.
In the present invention, the water / cement ratio is preferably 10 to 30% by mass, and preferably 15 to 25% by mass, from the fluidity and workability of the blend, the strength, durability, denseness and impact resistance of the cured product. More preferred.

As the water reducing agent, a lignin-based, naphthalenesulfonic acid-based, melamine-based, or polycarboxylic acid-based water reducing agent, an AE water reducing agent, a high-performance water reducing agent, or a high-performance AE water reducing agent can be used. Among these, it is preferable to use a polycarboxylic acid-based high-performance water reducing agent or a high-performance AE water reducing agent. By blending the water reducing agent, the fluidity and workability of the blend, the denseness and strength of the cured body, and the like are improved.
The blending amount of the water reducing agent is preferably 0.1 to 4.0 parts by mass in terms of solid content with respect to 100 parts by mass of cement from the aspects of fluidity and separation resistance of the formulation, denseness and strength of the cured body, cost, etc. 0.1-2.0 mass parts is more preferable, and 0.1-1.0 mass part is especially preferable.

The aramid fiber used in the present invention has a diameter of 0.02 to 0.2 mm (preferably 0.03 to 0.2 mm, more preferably 0.04 to 0.2 mm) and a length of 1 to 30 mm (preferably 3 to 20 mm, more preferably 5 to 16 mm). This is a monofilament type fiber. When the diameter of the aramid fiber is less than 0.02 mm, the fluidity and workability of the blend are lowered, and the compressive strength of the cured product is also lowered. On the other hand, it is difficult to obtain an aramid fiber having a diameter exceeding 0.2 mm as a monofilament type fiber. In addition, when convergent aramid fibers having a diameter of more than 0.2 mm are used, the number of fibers with the same blending amount decreases, so that bending strength and fracture energy may be reduced. If the length of the aramid fiber is less than 1 mm, it is difficult to obtain and the bending strength and fracture energy may be lowered. On the other hand, when the length exceeds 30 mm, the fluidity and workability of the blend are extremely lowered, and the compressive strength of the cured product is also lowered.
The blending amount of the aramid fiber is preferably 0.5 to 3.0% of the volume of the blend, and more preferably 0.8 to 2.0%. When the blending amount is less than 0.5% of the volume of the blending, bending strength and breaking energy, particularly breaking energy may be lowered. On the other hand, if the blending amount exceeds 3.0%, the fluidity and workability of the blend are extremely lowered and the cost is increased.

In the present invention, it is preferable to use an aramid fiber having a water content of 5 to 50% by mass from the viewpoint of fluidity and workability of the composition, strength of the cured product, denseness and impact resistance, and the like. More preferably, 30% by mass is used. If the moisture content of the aramid fiber is less than 5% by mass, the aramid fiber may become lumpy or the fluidity and workability of the blend may be reduced. On the other hand, if the water content exceeds 50% by mass, strength development may be reduced, and the denseness and impact resistance of the cured product may be reduced.
In the present invention, the moisture content of the aramid fiber is a value calculated from a mass reduction amount when heated at 105 ° C. for 24 hours.

In the present invention, the formulation may contain an inorganic powder having a Blaine specific surface area of 350,000 to 10,000 cm ² / g. By containing the inorganic powder, the fluidity of the blend, the strength development of the cured product, the denseness, and the like can be improved.
Examples of the inorganic powder include slag, limestone powder, feldspar, mullite, alumina powder, quartz powder, fly ash, volcanic ash, silica sol, carbide powder, and nitride powder. Of these, slag, fly ash, limestone powder, and quartz powder are preferably used in terms of cost and quality stability of the cured product.
Blaine specific surface area of the inorganic powder is preferably 3500~10000cm ² / g, more preferably ^{4000~9000cm 2 / g, 5000~9000cm 2 /} g is particularly preferred. If the Blaine specific surface area of the inorganic powder is less than 3500 cm ² / g, the strength, denseness, impact resistance and the like of the cured product are unfavorable. On the other hand, when the value exceeds 10000 cm ² / g, the fluidity may be lowered, and the strength, denseness, impact resistance, etc. of the cured product may be lowered. In this case, the cost also increases.
The blending amount of the inorganic powder is preferably 55 parts by mass or less, more preferably 10 to 50 parts by mass with respect to 100 parts by mass of cement. If the blending amount exceeds 55 parts by mass, the fluidity may decrease, and the strength, denseness, impact resistance, etc. of the cured product may decrease.

In the present invention, the blend may contain fibrous particles or flaky particles having an average particle size of 1 mm or less. Here, the particle size of the particle is the size of the maximum dimension (particularly, the length of the fibrous particle). By containing the fibrous particles or flaky particles, the toughness after curing can be increased.
Examples of fibrous particles include wollastonite, bauxite, mullite, and examples of flaky particles include mica flakes, talc flakes, vermiculite flakes, and alumina flakes.
The blending amount of the fibrous particles or flaky particles is preferably 35 parts by mass or less, more preferably 0.1 to 5 parts by mass with respect to 100 parts by mass of cement, from the fluidity and workability of the blend, toughness of the cured body, and the like. .
In addition, it is preferable to use a fibrous particle having a needle-like degree represented by a length / diameter ratio of 3 or more from the viewpoint of increasing the toughness of the cured body.

  In the present invention, the kneading method of the compound is not particularly limited, and a usual method can be used. Moreover, the apparatus used for kneading is not particularly limited, and an omni mixer, a pan-type mixer, a biaxial kneading mixer, a tilting cylinder mixer, and the like are used.

  By molding, curing, and curing the kneaded mixture, the embedded formwork board of the present invention can be manufactured. The molding method is not particularly limited, and a conventional molding method such as casting can be employed. Further, the curing method is not particularly limited, and normal temperature curing, steam curing, or the like may be performed.

The embedded formwork board of the present invention comprises a hardened cementitious material, and (i) a plurality of convex portions or depths having a height of 3 mm or more substantially uniformly over the entire surface of one side of the embedded formwork board. (Ii) a cut surface at a height of 3 mm of the convex portion or a depth of 3 mm of the concave portion (provided that the height of the convex portion is 3 mm or equivalent to the concave portion) When the depth is 3 mm, the area of the surface area) is 10 to 80% with respect to the projected area of the one side having the convex part or the concave part, and (iii) one side having the convex part or the concave part The area ratio (S1 / S2) of the total surface area (S1) and the projected area (S2) of one side having the convex part or the concave part is 1.2 to 7.0.
The embedded formwork board of the present invention has a convex part or a recessed part of the embedded formwork board by having a convex part or a recessed part of a specific shape substantially uniformly over the entire surface of one side of the embedded formwork board. The adhesion strength between the single-sided surface and post-cast concrete can be improved to 1 N / mm ² or more, and the shear strength can also be improved to 1 N / mm ² or more.

  The convex portion or the concave portion can be integrally formed using the same material as the main body portion. As a method of forming the convex portion or the concave portion, for example, a specific concave shape or convex shape is placed in a mold having an inner bottom surface, and a composition constituting the main body portion is placed and cured. A method of forming a convex portion or a concave portion on one side of the cementitious hardened body by demolding is mentioned. As another method, after placing the compound in a normal mold having a flat bottom surface, a pressing mold having a specific concave shape or convex shape is placed on the upper surface of the compound after casting. To form a convex part or a concave part on one side of the cementitious hardened body.

(i) The height of the convex portion 3 formed on one side 4 of the embedded formwork board 1 or the depth of the concave portion is 3 mm or more from the one side 4 (reference surface) of the embedded formwork board 1; From the viewpoint of the strength and cost of the embedded formwork board, it is preferably 3 to 10 mm, more preferably 4 to 9 mm (see FIG. 1).
If the height of the convex part or the depth of the concave part is less than 3 mm, the adhesive strength between the embedded formwork board and the post-cast concrete decreases, and it is difficult to obtain an adhesion strength of 1 N / mm ² or more. Further, it is difficult to obtain a shear strength of 1 N / mm ² or more. Even if the height of the convex portion or the depth of the concave portion exceeds 10 mm, the adhesion and shear strength between the embedded formwork board and the post-cast concrete are not improved so much. In addition, if the height of the convex portion exceeds 10 mm, the convex portion is likely to be chipped during transportation or installation at a construction site. On the other hand, when the depth of the concave portion exceeds 10 mm, it is necessary to increase the thickness of the member (main body portion) in order to maintain the strength of the embedded formwork board, resulting in an increase in cost.
In addition, if the adhesion strength is less than 1 N / mm ² , although depending on the thickness of the post-cast concrete, the post-cast concrete may be peeled off, which is not preferable. Even if the shear strength is less than 1 N / mm ² , it is not preferable because post-cast concrete may be peeled off.

The embedded formwork board of the present invention has a plurality of convex portions or concave portions substantially uniformly over the entire surface of one surface of the embedded formwork board. When the plurality of convex portions or concave portions are partially concentrated on one side of the embedded formwork board, or are formed so as to be biased to one side, Since the adhesive force between the convex part or the part where the concave part is not formed (planar part) and the post-cast concrete becomes small, peeling easily occurs at the interface between the embedded formwork board and the post-cast concrete in the part. It is not preferable.
In addition, the form having a plurality of convex portions or concave portions substantially uniformly on the entire surface of one side of the embedded formwork board is to divide one side having convex portions (or concave portions) into 100 cm ² (10 cm × 10 cm). The plurality of convex portions (or the number of convex portions (or concave portions) in one area and the number of the convex portions (or concave portions) in the other area are within five. (Or the concave portion) refers to a form formed on one side of the embedded formwork board. The convex portions (or concave portions) are preferably formed uniformly at equal intervals on the entire surface of one side of the embedded formwork board.

(ii) The area of the cut surface at the height of 3 mm of the convex part or the depth of 3 mm of the concave part (however, the surface area when the height of the convex part is 3 mm or the depth of the concave part is 3 mm) However, it is 10 to 80%, preferably 20 to 70%, and more preferably 30 to 65% with respect to the projected area of one side (the whole) having the convex portion or the concave portion.
If the above value is less than 10%, the adhesive strength between the embedded formwork board and the post-cast concrete decreases, and it is difficult to obtain an adhesive strength of 1 N / mm ² or more. Further, it is difficult to obtain a shear strength of 1 N / mm ² or more. When the above numerical value exceeds 80%, it is difficult to produce and the surface having convex portions or concave portions is likely to be chipped or cracked.
The cut surface at a height of 3 mm of the convex portion or a depth of 3 mm for the concave portion is 3 mm of each convex portion when the height of the convex portion is 3 mm or more or the depth of the concave portion is 3 mm or more. The total area (Ca) of the cut surfaces at a height of 3 mm or a depth of 3 mm corresponding to the concave portion. In addition, the surface area when the height of the convex portion is 3 mm or the depth of the concave portion is 3 mm is the total surface area at the height of 3 mm of each convex portion or the depth of 3 mm of the concave portion. Area (Sa).
In the present specification, for convenience, a cut surface at a height of 3 mm of the convex portion or a depth of 3 mm of the concave portion (however, the height of the convex portion is 3 mm or the depth of the concave portion is 3 mm. In this case, the ratio of the area (Ca or Sa) of the surface area to the projected area (S2) of one side (the whole) having the convex portion or the concave portion is the cross-sectional area ratio (Ca / S2 × 100%, or Sa / S2 × 100%).

(iii) The area ratio (S1 / S2) of the total surface area (S1) of one side having the convex part or the concave part and the projected area (S2) of the single side having the convex part or the concave part is 1.2 to 7.0. , Preferably 1.25 to 6.0, more preferably 1.3 to 5.0. If the area ratio is less than 1.2, the adhesive strength between the embedded formwork board and the post-cast concrete decreases, and it is difficult to obtain an adhesive strength of 1 N / mm ² or more. Further, it is difficult to obtain a shear strength of 1 N / mm ² or more. Those having an area ratio of more than 7.0 are difficult to produce, and are liable to be chipped or cracked on the surface having convex portions or concave portions.
The area ratio is a value calculated as in the following equation.
Area ratio = (total surface area of one side having convex part or concave part; S1) / (projected area of one side having convex part or concave part; S2)
In addition, the projected area (S2) of the single side | surface which has the convex part or recessed part part of the embedded formwork board is the same as the area of the single side | surface (the whole) of the embedded formwork board in case it does not have a convex part or recessed part part. .

In the present invention, when the embedded formwork board has a convex portion on one side, the convex portion has a cylindrical shape with a diameter of 4 to 25 mm or a rectangular column shape with a side length of 4 to 25 mm. It is preferable to have it. It is not preferred that the convex portion has a cylindrical shape with a diameter of less than 4 mm or a rectangular column shape with a side length of less than 4 mm, because the convex portion is likely to be chipped or cracked. On the other hand, when the convex portion has a cylindrical shape with a diameter exceeding 25 mm or a square pillar shape with one side exceeding 25 mm, the area ratio (S1 / S2) of the embedded formwork board is small. In some cases, the adhesive strength between the embedded formwork board and the post-cast concrete decreases, and an adhesion strength of 1 N / mm ² or more may not be obtained.

In the present invention, when the embedded formwork board has a concave portion on one side, the concave portion has a cylindrical shape with a diameter of 5 to 25 mm or a square column shape with a side length of 5 to 25 mm. It is preferable to have it. If the concave portion has a cylindrical shape with a diameter of less than 5 mm or a square pillar shape with a side length of less than 5 mm, it becomes difficult for post-cast concrete to enter the concave portion, Adhesive strength with post-cast concrete decreases, and it is difficult to obtain an adhesion strength of 1 N / mm ² or more. Further, it is difficult to obtain a shear strength of 1 N / mm ² or more. On the other hand, when the concave portion has a cylindrical shape with a diameter exceeding 25 mm or a square pillar shape with a side length exceeding 25 mm, the area ratio (S1 / S2) of the embedded formwork board is small. In some cases, the adhesive strength between the embedded formwork board and the post-cast concrete decreases, and an adhesion strength of 1 N / mm ² or more may not be obtained.

In the present invention, the interval between the convex portions or the concave portions is preferably 2 mm or more, more preferably 3 mm or more, and particularly preferably 4 mm or more. If the distance between convex parts or concave parts is less than 2mm, it is difficult to manufacture, and the convex parts and concave parts are likely to be chipped during manufacturing, transportation, and installation at the construction site. Become.
If the distance between the convex portions or the concave portions is too large, the adhesive strength between the embedded formwork board and the post-cast concrete is lowered, and it is difficult to obtain an adhesion strength of 1 N / mm ² or more. In addition, since it is difficult to obtain a shear strength of 1 N / mm ² or more, it is preferable that the interval between the convex portions or the concave portions is 20 mm or less.
In addition, in this specification, the space | interval of convex parts means the distance d1 (refer FIG. 2) of the space | gap between the convex part 3 and the convex part 3. FIG. Moreover, the space | interval between recessed parts means the distance d2 (refer FIG. 5) between the recessed parts 12 and the recessed parts 12. FIG.

  The dimensions of the embedded formwork board of the present invention are 0.3 to 5.0 m in length in consideration of the strength and durability of the embedded formwork board itself, as well as the trouble of manufacturing, transportation, installation on the construction site, etc. The width is preferably 0.3 to 5.0 m and the thickness is 1 to 7 cm. Here, the thickness of the embedded formwork board is opposite to the case where the convex portion is not formed from the surface of the top portion of the convex portion when the convex portion is formed on one side (reference surface). The distance to one side of the side. When the concave portion is formed on one side (reference surface), it means the distance from the one side (reference surface) where the concave portion is formed to the opposite side surface where the concave portion is not formed.

  The embedded formwork board of the present invention can have an insert hole for fixing the embedded formwork board. The embedded formwork board can be easily assembled into an arch shape, a plate shape or the like by inserting the fixing tool through the insert hole and hitting it on the slope or the ceiling.

Formulation containing cement used in the present invention, fine powder having a BET specific surface area of 3 to 25 m ² / g, fine aggregate, water, water reducing agent and monofilament type aramid fiber having a diameter of 0.02 to 0.2 mm and a length of 1 to 30 mm In the method described in "JIS R 5201 (physical test method for cement) 11. Flow test", the flow value measured without performing 15 drop motions is 200 mm or more and has excellent fluidity. Yes, it is excellent in workability such as loading into a formwork. The cured product of the blend has a compressive strength of 180 N / mm ² or more, more preferably 190 N / mm ² or more. Therefore, the embedded formwork board 1 of the present invention is extremely dense and has excellent freezing and thawing resistance, wear resistance, water impermeability and the like without performing surface treatment or the like.

EXAMPLES Next, although an Example is given and this invention is further demonstrated, this invention is not limited by these Examples.
1. Materials used The following materials were used.
(a) Cement: Low heat Portland cement (manufactured by Taiheiyo Cement Co., Ltd.)
(b) Fine powder: Silica fume (BET specific surface area 11m ² / g)
(c) Inorganic powder: Quartz powder (Blaine specific surface area 7000cm ² / g)
(d) Fine aggregate: quartz sand (particle size 0.15-0.6mm)
(e) Water reducing agent: Polycarboxylic acid-based high-performance water reducing agent
(f) Water: Tap water
(g) Aramid fiber: Monofilament fiber with diameter: 0.045mm and length: 6mm (water content 15% by mass)
(h) Polyvinyl alcohol fiber: Diameter: 0.3mm, Length: 15mm
(i) Steel fiber: Diameter: 0.2mm, Length: 15mm

2. Manufacture and evaluation of compound 1
Low heat Portland cement 100 parts by mass, silica fume 30 parts by mass, fine aggregate 120 parts by mass, water 22 parts by mass, high-performance water reducing agent 0.4 parts by mass (solid content conversion) and aramid fiber (1% of the volume of the compound) It put into the shaft kneading mixer and kneaded. The flow value of the blend was measured in the method described in “JIS R 5201 (Cement physical test method) 11. Flow test” without performing 15 drop motions. As a result, the flow value was 200 mm.
Further, the blend was poured into a mold of φ50 × 100 mm, pre-positioned at 20 ° C. for 48 hours, and then steam-cured at 90 ° C. for 48 hours to obtain cured bodies (3 pieces). The cured body had a compressive strength (average of three) of 182 N / mm ² .
The blend was poured into a 4 × 4 × 16 cm mold, pre-positioned at 20 ° C. for 48 hours, and then steam-cured at 90 ° C. for 48 hours to obtain cured bodies (3 pieces). The bending strength (average value of 3 pieces) of the cured body was 29 N / mm ² .
In the above bending strength test, the fracture energy was calculated as the value obtained by dividing the integrated value of the load-load point displacement from when the load reached the cracking load until it decreased to 1/3 by the cross-sectional area of the specimen. did. As the load point displacement, the crosshead displacement amount of a bending tester was used.
The breaking energy (average value of 3 pieces) of the cured product was 43 kJ / m ² .
Further, the blend was poured into a mold of φ50 × 100 mm, pre-positioned at 20 ° C. for 48 hours, and then steam-cured at 90 ° C. for 48 hours to obtain cured bodies (3 pieces). The water permeability coefficient of the cured body was measured by a water level permeability test method according to “Geotechnical Society Standard JGS 0231 (Soil permeability test method)”. As a result, no water penetration was observed, and the penetration depth was zero.
Further, the blend was poured into a 10 × 10 × 40 cm mold, preliminarily placed at 20 ° C. for 48 hours, and then subjected to steam curing at 90 ° C. for 48 hours to obtain cured bodies (three pieces). The freeze-thaw test of the cured product was measured according to “JIS A 6204 (Chemical Admixture for Concrete) Appendix 2 (Freeze-Thaw Test of Concrete)”. As a result, the durability index (average value of 3 pieces) was 99.8.

3. Production and evaluation of compound 2
Low heat Portland cement 100 parts by weight, silica fume 30 parts by weight, quartz powder 30 parts by weight, fine aggregate 120 parts by weight, water 22 parts by weight, high-performance water reducing agent 0.4 parts by weight (in terms of solid content) and aramid fiber (volume of the formulation) 1%) was put into a biaxial kneader and kneaded.
The flow value of the blend, the compressive strength, the bending strength, the fracture energy, the water penetration depth, and the durability index of the cured product were measured in the same manner as described above.
As a result, the flow value was 212 mm, the compressive strength was 192 N / mm ² , the bending strength was 29 N / mm ² , the fracture energy was 44 kJ / m ² , the water penetration depth was zero, and the durability index was 99.9.

4). Manufacture and evaluation of compound 3
100 parts by mass of low heat Portland cement, 30 parts by mass of silica fume, 30 parts by mass of quartz powder, 120 parts by mass of fine aggregate, 22 parts by mass of water, and 0.4 parts by mass of high-performance water reducing agent (in terms of solid content) are put into a biaxial kneader. Kneaded.
The flow value of the blend, the compressive strength, the bending strength, and the fracture energy of the cured product were measured in the same manner as described above.
As a result, the flow value is 270 mm, compressive strength 220 N / mm ^2, bending strength of 17N / mm ^2, the breaking energy was 2 kJ / m ^2.

5. Formulation and evaluation 4
Low heat Portland cement 100 parts by weight, silica fume 30 parts by weight, quartz powder 30 parts by weight, fine aggregate 120 parts by weight, water 22 parts by weight, high-performance water reducing agent 0.4 parts by weight (in terms of solid content) and polyvinyl alcohol fiber 3% of the volume) was put into a biaxial kneader and kneaded.
The flow value of the blend, the compressive strength, the bending strength, and the fracture energy of the cured product were measured in the same manner as described above.
As a result, the flow value is 260 mm, compressive strength 165 N / mm ^2, bending strength of 21N / mm ^2, the breaking energy was 32 kJ / m ^2.

6). Formulation production and evaluation 5
Low heat Portland cement 100 parts by weight, silica fume 30 parts by weight, quartz powder 30 parts by weight, fine aggregate 120 parts by weight, water 22 parts by weight, high-performance water reducing agent 0.4 parts by weight (in terms of solid content) and steel fibers (volume of the compound) 2%) was put into a biaxial kneader and kneaded.
The flow value of the blend, the compressive strength, the bending strength, and the fracture energy of the cured product were measured in the same manner as described above.
As a result, the flow value was 270 mm, the compressive strength was 200 N / mm ² , the bending strength was 45 N / mm ² , and the fracture energy was 45 kJ / m ² .

7). Evaluation of embedded formwork board 1
7-1 Manufacture of embedded formwork board A 400mm x 400mm x 30mm (thickness) formwork, the formwork with a concave shape with a depth of 6mm and a diameter of 7mm on the bottom of the formwork Pour into the surface, cure (previously for 48 hours at 20 ° C, then steam cure at 90 ° C for 48 hours), demold, and evenly on the entire surface of one side 4 with multiple heights of 6mm in height and 7mm in diameter An embedded formwork board 1 having a portion 3 was produced. The spacing between the convex portions was 4 mm, the cross-sectional area ratio was 38.5%, and the area ratio (S1 / S2) was 2.32.

7-2 Post-cast concrete placement and curing The post-cast concrete shown in Table 1 (slump 12cm, compressive strength 32N / mm ² (28 days underwater curing)) Was laid.
The materials used for post-cast concrete are as follows.
(1) Cement: Ordinary Portland cement (manufactured by Taiheiyo Cement Co., Ltd.)
(2) Fine aggregate: land from Ogasa
(3) Coarse aggregate: A mixture of Iwase No. 5 crushed stone and Iwase No. 6 crushed stone (maximum particle size 20mm)
(4) Water reducing agent; lignin sulfonic acid AE water reducing agent
(5) AE agent; alkylallylsulfone compound anionic surfactant
(6) Water ： Tap water

7-3 Measurement (evaluation) of shear strength and bond strength
About the hardening body which consists of a board for embedding formwork, and post-cast concrete, shear strength and adhesion strength were measured with the following method.
(1) Method of measuring shear strength The shear strength of the cured product was measured according to "JSCE-G 553-1983 (Method for testing shear strength of steel fiber reinforced concrete)".
(2) Bond strength test method
The above-mentioned compound for post-cast concrete was poured into a mold having a bottom face of one side of a 400mm x 400mm x 30mm (thickness) embedded form board board, and was cured at 20 ° C for 24 hours. Thereafter, it was demolded, and further cured under water for 28 days and cured to obtain a test body (cured body) composed of an embedded formwork board and post-cast concrete (thickness 50 mm).
As shown in FIG. 6, parallel to the side end face 21 from the side of the embedded formwork board 20a to the inside of the post-cast concrete 20b at positions 80 mm, 200 mm, and 320 mm from one side end face 21 of the test body 20. Three cut lines 22, 23, and 24 were formed on the substrate. Three perpendicular lines 26, 27, and 28 are formed at positions 80 mm, 200 mm, and 320 mm from one side end face 25 orthogonal to the side end face 21 so as to be orthogonal to the three cuts 22, 23, and 24. 28 was formed.
As shown in FIG. 6 (b), the test body 20 is installed so that the embedded formwork board 20a is arranged on the upper side and the post-cast concrete 20b is arranged on the lower side, and the test position (A in FIG. 6 (a)) is set. A steel upper attachment 30 was attached with an epoxy resin adhesive, a weight was placed on the attachment, and the test specimen 20 was left still in a drying oven at 20 ° C. for one day. After that, the maximum load when tensile loading in the vertical direction (in the direction of the arrow in FIG. 6B) at a loading speed of 1.0 kN / mm ² is obtained through the upper tension attachment 30, and this value is obtained for the upper tension. The adhesion strength was obtained by dividing by the adhesion area of the attachment 30.
As a result, shear strength 2.6 N / mm ^2, adhesion strength was 1.3 N / mm ^2.

8). Evaluation of embedded formwork board 2
8-1 Manufacture of embedded formwork board Is a 400mm x 400mm x 30mm (thickness) formwork with a plurality of convex shapes of 10mm in height and 5mm in diameter on the bottom of the formwork An embedded mold board having a plurality of concave portions each having a depth of 10 mm and a diameter of 5 mm was manufactured almost uniformly on the entire surface of one side. The interval between the concave portions was 2.1 mm, the cross-sectional area ratio was 40.0%, and the area ratio (S1 / S2) was 4.20.

8-2 Placing, curing, and evaluation of post-cast concrete A hardened body made of buried formwork board and post-cast concrete was manufactured in the same manner as in 7. above. The shear strength of the cured product was measured in the same manner as in 7. above.
As a result, the shear strength was 1.3 N / mm ² .

9. Evaluation of buried formwork board 3
Using the formulation prepared in 5. above, 7. The embedded formwork board was manufactured in the same manner. In the same manner as in 7. above, a hardened body made of the embedded formwork board and post-cast concrete was produced. The shear strength and adhesion strength of the cured product are set as described in 7. Was measured in the same manner.
As a result, the shear strength was 1.9 N / mm ² and the adhesion strength was 1.1 N / mm ² .

10. Evaluation of embedded formwork board 4
Using the formulation prepared in 6. above, 7. The embedded formwork board was manufactured in the same manner. In the same manner as in 7. above, a hardened body made of the embedded formwork board and post-cast concrete was produced. The shear strength and adhesion strength of the cured product are set as described in 7. Was measured in the same manner.
As a result, the shear strength was 2.8 N / mm ² and the adhesion strength was 1.4 N / mm ² .

DESCRIPTION OF SYMBOLS 1 Embedded formwork board 2 Main part 3 Convex part 4 One side (reference plane) of embedded formwork board
5 Concrete structure 6 Post-cast concrete 10 Embedded formwork board 11 Main body part 12 Recessed part 13 One side (reference plane) of embedded formwork board
20 Test body 20a Embedded formwork board 20b Post-cast concrete 21 One end face 22, 23, 24 cut line of test specimen 25 One end face 26, 27, 28 test specimen 30 Cut line 30 Attachment for upper tension

Claims (5)

From a hardened body of a composition containing cement, fine powder having a BET specific surface area of 3 to 25 m ² / g, fine aggregate, water, water reducing agent and monofilament type aramid fibers having a diameter of 0.02 to 0.2 mm and a length of 1 to 30 mm An embedded formwork board,
(i) having a plurality of convex portions having a height of 3 mm or more or a plurality of concave portions having a depth of 3 mm or more substantially uniformly over the entire surface of one surface of the embedded formwork board,
(ii) The area of the cut surface at the height of 3 mm of the convex part or the depth of 3 mm of the concave part (however, the surface area when the height of the convex part is 3 mm or the depth of the concave part is 3 mm) Is 10 to 80% with respect to the projected area of one side having the convex portion or the concave portion, and
(iii) The area ratio (S1 / S2) of the total surface area (S1) of one side having the convex part or the concave part and the projected area (S2) of the single side having the convex part or the concave part is 1.2 to 7.0. Embedded formwork board characterized by that.    2. The embedded formwork board according to claim 1, wherein the convex portion has a cylindrical shape with a diameter of 4 to 25 mm or a quadrangular prism shape with a side length of 4 to 25 mm.   2. The embedded formwork board according to claim 1, wherein the concave portion has a cylindrical shape having a diameter of 5 to 25 mm or a quadrangular prism shape having a side length of 5 to 25 mm.   The embedded formwork board according to any one of claims 1 to 3, wherein an interval between the convex portions or the concave portions is 2 mm or more. Board for buried formwork according to claim 1 comprising the formulation, the inorganic powder Blaine specific surface area 3500~10000cm ² / g.

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