JP5753524B2 - Film for curing concrete structures - Google Patents

Description

  The present invention relates to concrete structures such as concrete bridges and box culverts incidental to road construction, or various concrete surfaces such as concrete rising parts in buildings, particularly upright walls, inclined walls, and side surfaces of beam members. The present invention relates to a curing film used to prevent the volatilization of moisture from the concrete surface in order to sufficiently harden the concrete when placing a concrete structure having a bottom surface or the like.

  When setting concrete floors such as airport pavements, roads, tunnel pavements, plazas, factory pavements, and concrete walls and floors of concrete bridges, various concrete structures or buildings, the concrete must be fully cured. Usually, mat watering curing is performed. This can be done by placing a mat made of woven or non-woven fabric of natural fiber or synthetic fiber, or synthetic resin mat such as open-cell urethane foam, and then laying it down after the surface water has disappeared, and spraying water on it. In addition to preventing the volatilization of the moisture of the concrete, it is intended to supply the sufficient moisture to allow the concrete to harden well.

The reaction of the concrete is a hydration reaction, and a normal reaction is performed due to the presence of sufficient moisture. Therefore, if the moisture is not retained, there is a possibility that sufficient strength cannot be obtained due to insufficient reaction, resulting in inferior concrete. In addition, a wide concrete pavement such as an airport pavement may be difficult to maintain uniform moisture due to direct sunlight and strong wind conditions. In order to prevent this, curing mats such as a curing mat and a curing cover are used (Patent Document 1).
In addition to curing mats, synthetic resin emulsions such as acrylic resin and EVA resin are sprayed on the concrete surface after placement to form a film of this synthetic resin on the concrete surface. There is also a type of “film curing material” that shields from sunlight and wind and prevents the volatilization of moisture in concrete.
After the concrete surface is placed, if there is no floating water on the surface, the surface starts to dry rapidly due to heating by irradiation of direct sunlight and air flow by wind, causing dry cracks.
Curing materials used to prevent this are important building materials, and curing is an indispensable process in concrete structures that are placed in harsh environments.

  However, unlike flat concrete surfaces such as roads, rising surfaces of concrete walls such as bridge piers, railings and box culverts, concrete dams, waterways, retaining walls, and other concrete structures That is, it is very difficult to lay the above-mentioned curing mats on the entire surface and spray water on the upright wall surface, the steeply inclined wall surface, the side surface and the bottom surface of the beam member, etc. For this reason, it is often forced to leave the mold without leaving the curing itself after watering with the mold still installed.

After placing the concrete, if the formwork is left as it is, there will be almost no moisture dissipation from the formwork surface, but for reasons of construction process and cost, remove the formwork as soon as possible to proceed to the next process. Is often necessary.
In recent years, a method of using a shielding material called a “water retaining tape” made of a film that prevents the diffusion of moisture has also been reported. However, it takes time and effort to affix this material to the entire surface, and the water retaining tape is removed after the mold is removed. The problem remains that the concrete surface dries before the tape application is completed.
In addition to this, there is a conventional method in which curing mats are installed after removing the frame to perform wet curing, but it is difficult to install the mats in close contact with the concrete surface which is a vertical surface, and the bottom surface (the back surface) ), It is almost impossible to install it on the ceiling or under the floor, and it is also problematic that the drying progresses after the frame is removed and before the curing mat is installed.
However, there is a widespread understanding that curing is important for extending the life of concrete as described above, and various means for curing the concrete surface of such structures have been studied. It is the actual situation.

JP 2010-255251 A

The present invention relates to concrete curing on a concrete bridge such as a pier of a concrete bridge, a wall of a rail or a box culvert, a concrete wall such as a concrete dam, a waterway, a retaining wall, a wall of a building, a beam member or the like. It solves the following problems.
(1) A curing film such as a synthetic resin film is attached to concrete such as a rising surface, and this film layer can block the concrete surface from the atmosphere, confine moisture, and sufficiently promote the hydration reaction. Work such as watering is unnecessary.
(2) Curing film can be applied to the formwork in advance, so that the curing material can be applied at the same time as the concrete is placed, eliminating the need to apply it after curing the concrete, and later The film for curing should be attached and adhered to a place where it cannot be attached by human hands.

The present inventors have devised concrete curing materials and construction methods suitable for rising surfaces and the like in order to solve the conventional problems through intensive studies.
In other words, it is a curing material that can be attached to the concrete surface by removing the concrete formwork rather than attaching it to the concrete surface after curing. As a result, there is no time lag from removing the formwork to applying the curing material, and the concrete surface can be prevented from drying out during this time. As soon as the formwork is removed from concrete, moisture on the surface will fly and the color will turn white. If it is exposed to direct sunlight or strong winds, the moisture in the surface layer will drop rapidly, leading to cracking. However, with the method of the present invention, the curing material covers the concrete even when the mold is removed, and the hydration reaction can be sufficiently continued without being exposed to the outside air.

The curing material of the present invention, that is, the curing film is a film substrate having a function of preventing the evaporation of moisture such as a plastic film, an adhesive applied to both surfaces of the substrate, and both surfaces or one surface of the adhesive layer. It has a configuration in which a release sheet such as a release paper or a release film is attached.
The curing film of the present invention can be used by peeling off the release sheet at the work site and affixing it to the formwork. it can. Therefore, the present invention also relates to a mold with a curing film.
In the present invention, the work sheet or the like peels off the release sheet that covers one side of the curing film and attaches it to the mold, performs a predetermined frame using the mold, and then the other side. The present invention relates to a curing film construction method comprising peeling a release sheet, placing concrete, hardening the concrete, and removing the formwork to leave the curing film on the concrete surface.

As described above, the present invention can bring about the following effects.
(1) When placing concrete, it is only necessary to affix a curing film to the formwork in advance, and it does not take time and effort to affix it to the concrete surface after placing.
(2) Compared with the type in which concrete is pasted after curing, the concrete surface after placement does not touch the outside air, so the surface does not dry and the effect of trapping moisture is high.
(3) After the concrete is hardened, it can be applied to places and cases that cannot be pasted by human hands, such as high upright surfaces, ceiling surfaces, under floor surfaces, and the like.
(4) By using a rework type (re-adhesive type) adhesive, both the mold surface and the concrete surface can be reattached even if they are once peeled off.
(5) Since the curing film is bonded with an adhesive, the effect of suppressing the occurrence of cracks in the concrete is increased by maintaining the optimum curing state, and the generation of cracks can be minimized.
(6) Since the state of the surface of the concrete is known during the curing of the concrete by making the film transparent, it is possible to take measures such as repairing the portion in advance.

The cross-sectional schematic diagram which shows the structure of the film for curing of this invention. The cross-sectional schematic diagram of the film for curing of this invention which stuck the release sheet on both surfaces. The cross-sectional schematic diagram of the film for curing of this invention which stuck the double-sided release type release sheet on the single side | surface. Outline diagram explaining the test method

  Several examples of the present invention will be described below with reference to the drawings, but the present invention is not limited thereto.

FIG. 1 is a schematic cross-sectional view showing the structure of the curing film of the present invention. The curing film is provided with a mold-side pressure-sensitive adhesive (2) on one side of the film substrate (1) and each coating layer of the concrete-side pressure-sensitive adhesive (3) on the other side.
The film substrate can be selected from various substrates such as PET resin, polyethylene, and polypropylene. This selection is made based on the tensile strength and tear strength of the film itself, and data such as water vapor barrier properties and gas barrier properties. Moreover, even if welding sparks or spatter flies in the middle of construction and may come into contact with the film, it is preferable to have a property that does not spread. The film substrate is usually colorless and transparent, but may be colored white so that it reflects direct sunlight when applied to concrete.
The substrate is not limited to a plastic film, and may be a non-woven fabric, a synthetic resin-impregnated paper, a plastic laminated paper, or the like as long as it has a function such as barrier properties.

As the pressure-sensitive adhesive provided on both surfaces of the base material, a pressure-sensitive adhesive that sufficiently adheres the curing film to the mold surface or the hardened concrete surface is selected. In the field work, the adhesive can be peeled off and attached immediately, and if it is a rework type (re-adhesion type) adhesive, it can be re-applied and there will be no failure in attaching. Have advantages.
Select the quality, coating amount, and thickness of the adhesive so that the film substrate (1) adheres to the concrete over the entire surface, preferably adheres, and is easily separated from the formwork side when the formwork is removed after the concrete is cured. To do.
The pressure-sensitive adhesive may be the same pressure-sensitive adhesive on both the concrete side and the formwork side, or may be different pressure-sensitive adhesives. Since it is necessary for the curing film to remain on the concrete surface when the formwork is removed from the concrete surface after placing, the concrete should have a greater adhesion to the concrete surface than the adhesion to the mold surface. It is preferable to increase the application amount of the adhesive on the side, or to select and use an adhesive with strong adhesive strength.

2 and 3 are schematic cross-sectional views of the product form of the curing film of the present invention.
FIG. 2 is a type in which the adhesive (2, 3) is coated on both sides of the film substrate (1), and both adhesive surfaces are covered with a release sheet (4) for handling. . A product of this type is supplied as a single product, for example, in the size of the formwork surface, and when used, the release sheet (4) of the formwork side adhesive (2) is peeled off and adhered to the formwork. After assembling such a formwork, the concrete side adhesive (3) release sheet (4) is peeled off and concrete is placed. In the case of this example, the release sheet may be a single-sided release sheet.
FIG. 3 shows an example in which a curing film is supplied as a roll (long product). The surface of the mold side adhesive (2) is covered with a double-sided release type release sheet (5) and supplied as a roll. To do. In use, the film for curing is cut into a desired size and used.
The double-sided release sheet (5) may be covered and wound only on the concrete side adhesive (3) surface.

First, the curing film of the present invention is attached to the concrete mold side. The release sheet covering the pressure-sensitive adhesive (2) layer coated on the formwork side is removed or the roll is unwound and attached to the formwork. By selecting an adhesive that can be re-applied, the adhesive can be re-applied any number of times even if it is applied by mistake.
Examples of rework-type acrylic emulsions include polyacrylic adhesives such as Polysol PSA-SE1005E (acrylic ester copolymer) or Polysol PSA SE-6101 (acrylic ester copolymer) manufactured by Showa Denko K.K. Is done. However, the present invention is not limited to this emulsion.

When concrete is placed, the curing film of the present invention is in close contact with the concrete side. The adhesion to the concrete surface is designed to be greater than the adhesive strength on the mold side, so that when the mold is removed after the concrete is cured, it will not leave the concrete with the mold. This can be achieved by selecting an adhesive having a greater adhesive strength than that on the mold side or adjusting the coating thickness.
Since the film for curing is in close contact with the concrete surface even when the formwork is removed, the concrete surface keeps moisture and does not dry. Moreover, since direct sunlight and wind can be prevented, surface cracks due to rapid drying can also be prevented. And since a water | moisture content is sealed, a hydration reaction can be advanced further.

Hereinafter, details of the present invention will be described with reference to Examples.
Example 1
The film for curing according to the present invention has the following constitution.
A PET resin film having a thickness of 50 μm was used as a substrate, and a rework type acrylic emulsion was coated on one side as an adhesive. The mold side was coated to a thickness of 5 μm, and the concrete side was similarly coated with a rework type acrylic emulsion adhesive of 50 μm thickness. Polysol PSA-SE1005E (acrylic ester copolymer) manufactured by Showa Denko KK was used as a rework type acrylic emulsion.

Curing performance was confirmed using this curing film.
As a confirmation method, since there is no standard test method for curing materials in domestic standards, the amount of moisture loss defined in ASTM C-156 was measured.
We also examined how the strength of the mortar changes with the effect of curing.
The bending strength test was based on JIS R5201 and compared the bending strength at 7 days of age with curing under conditions of a temperature of 40 ° C. and a humidity of 40%. Similarly, according to JIS R5201, the compressive strength at the age of 7 days was compared with curing under conditions of a temperature of 40 ° C. and a humidity of 40%.

As a result, the water loss was extremely low at 0.05 Kg / m ^2, and the water loss by the same test method for spray-coated film curing material for concrete paving (US ASTM standard compliant product) was 0.3 Kg / m ² . It is a good result compared to the existing one. In addition, it can be said that the US ASTM standard, that is, the standard of water loss in ASTM C-309 TYPE2 is 0.55 kg / m ^2, which is a good result. The bending strength of the mortar specimen is nearly 18% higher than that of air curing in which no curing material is applied to the mortar surface. Similarly, the result that the compressive strength increased by 50% or more was obtained.

Example 2
A PET resin film having a thickness of 100 μm was used as a substrate, and a rework type acrylic emulsion was coated on one side as an adhesive. The mold side was coated to a thickness of 5 μm, and the concrete side was similarly coated with a rework type acrylic emulsion adhesive material to a thickness of 50 μm. Polyzol PSA SE-6101 (acrylic ester copolymer) was used as the adhesive.

The adhesive film was tested for the adhesive film thus obtained.
The method for measuring the adhesive strength is as shown in Table 2.
A schematic diagram of the adhesion test is shown in FIG.
The test results of adhesive strength are as shown in Table 3.

Depending on the adhesive strength of the adhesive and the thickness of the adhesive, the adhesive strength on the mold side and the adhesive strength on the concrete side can be adjusted appropriately. The degree and thickness of this adhesive strength are not limited. . Moreover, since these adhesive forces can be changed also by changing or increasing / decreasing the crosslinking agent used for resin of an adhesive, appropriate conditions can be selected.
As a result of using the film for curing according to this example, it was possible to appropriately affix to the mold and re-apply easily. Moreover, when concrete was placed, it was in close contact with the concrete surface, and even when the formwork was removed, it did not peel off from the concrete surface. The film for curing was in close contact with the concrete and still retained a black color, confirming that moisture was retained.

1: Curing base material 2: Formwork side adhesive layer 3: Concrete side adhesive layer 4: Release sheet (single side release type)
5: Release sheet (double-sided release type)
6: Specimen 7: Stainless steel plate

Claims (5)

When constructing a concrete structure, it is a film that prevents the volatilization of moisture from the surface by adhering to the concrete surface from which the formwork was removed after placing the concrete, and the film has a thickness of 50 to 100 μm that prevents the volatilization of moisture . Rework-type acrylic system that is provided with adhesive layers on both sides of the plastic film substrate to adhere to the formwork surface and concrete surface, and can be re-applied even if the adhesive is peeled off from the surface once applied It is an emulsion adhesive and is applied at a thickness of 50 μm on the concrete surface side with respect to 5 μm on the mold surface side of the film base material. After the concrete is hardened, it will function without sticking to the concrete surface when the formwork is removed, and it will be easy to work manually after the function. A film for curing a concrete structure, which can be removed. The curing film according to claim 1, wherein the adhesive provided on both surfaces of the film substrate is a rework type acrylic emulsion adhesive, and one or both surfaces of the adhesive layer are covered with a release sheet. The film for curing according to claim 1 or 2 , wherein a release sheet is attached to one surface of the pressure-sensitive adhesive layer provided on both surfaces of the film base material to form a roll. When a concrete structure is constructed using the curing film according to claim 1, one of the release sheets covering the pressure-sensitive adhesive layers on both sides of the film substrate is peeled off and attached to the mold, A concrete structure characterized in that the curing film adheres to the concrete surface by peeling the release sheet of the adhesive layer on the concrete side, placing the concrete, and removing the formwork Curing method. A concrete mold with a curing film, wherein one adhesive layer surface of the film substrate of the curing film according to claim 1 is attached to a concrete mold surface, and the other adhesive layer surface is covered with a release sheet.

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