JP2017166290A - Construction method of concrete member and concrete cure form - Google Patents

Abstract

PROBLEM TO BE SOLVED: To propose a construction method of a concrete member and a concrete cure form capable of uniformly supplying a cure liquid to a surface of concrete, by using an inexpensive form.SOLUTION: A construction method of a concrete member comprises a placing process of placing concrete C on the inside of a form 1 and a cure process of curing the concrete in the form 1, and in the construction method of the concrete member, the form 1 comprises a sheathing board 2 and a water supply part 3 interposed between the concrete C and the sheathing board 2, and the water supply part 3 is composed of woven fabric or nonwoven fabric, and in the cure process, water is supplied to the whole water supply part 3 by forming a water-filling part 5 in an upper part of the form 1 so that an upper end part of the water supply part 3 contacts with the water.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a concrete member construction method and a concrete curing mold.

It is known that curing concrete in water is suitable for increasing the strength, compactness, crack resistance and durability associated with the concrete.
Therefore, conventionally, a curing method for preventing drying during curing of concrete and creating an environment close to underwater curing has been adopted. Further, from the viewpoint of suppressing temperature cracking, it is also effective to reduce the temperature difference between the inside and outside of the concrete.

  As such a curing method, for example, there is a method of watering the concrete surface after demolding. However, sprinkling curing can create an environment close to underwater curing with respect to the horizontal surface such as the top surface of concrete, but it is difficult to maintain water evenly on vertical surfaces such as side surfaces and slopes.

Therefore, the present applicants have developed a large number of concrete molds having water retention, and have been put to practical use.
For example, Patent Document 1 includes a weir plate, a water retaining portion that covers the inner surface of the weir plate, and a surface portion that covers the inner surface of the water retaining portion. A concrete curing formwork has been disclosed that makes it possible to discharge water and cure underwater after setting.
Further, in Patent Document 2, in a concrete mold having a siding plate provided with a plurality of core materials and face materials laminated on both surfaces of the core material, a plurality of penetrations are made in the face material on the concrete placing surface side. A curing method is disclosed in which holes are formed and the curing solution is stored in the gaps between the cores to supply the curing solution directly from the through holes to the surface of the concrete.

Japanese Patent No. 5565921 JP 2013-238044 A

Since the water retention part of the concrete curing mold of Patent Document 1 has water retention and needs to be formed of a material having sufficient strength against the pressure of the cast concrete, It was expensive.
Further, the concrete-curing formwork of Patent Document 2 is also expensive as a formwork material because it is necessary to form a permeable plate with a material having sufficient strength against the pressure of the cast concrete. Met.
From such a point of view, the present invention has an object to propose a concrete member construction method and a concrete curing formwork capable of supplying a curing solution uniformly to the concrete surface using an inexpensive formwork. And

In order to solve the above-mentioned problems, a concrete member construction method according to the present invention includes a placing step of placing concrete in a mold and a curing step of curing the concrete in the mold. It is a construction method, wherein the mold is provided with a dam plate and a water supply portion that covers the inner surface of the dam plate and faces the concrete placed in the mold, and the water supply portion is woven or non-woven fabric. The curing step is characterized in that a curing solution is supplied to the entire water supply unit by forming a flooding unit so that the upper end of the water supply unit is in contact with the upper part of the formwork.
According to the concrete member construction method, the curing solution can be supplied to the concrete without requiring an expensive formwork material. In addition, since the curing solution is supplied to the water supply unit by infiltrating water and the like from the flooded unit, the work is simple and requires a minimum amount of water.
The flooded part is formed by allowing the upper end of the siding plate to protrude above the upper surface of the concrete and storing the curing solution in a portion surrounded by the upper surface of the concrete and the upper end of the damming plate. can do.
It is desirable to perform water stop by filling a joint material at least at the upper end of the connecting portion between the weir plates.

Further, the concrete curing form of the present invention includes a slat plate and a water supply part provided on the inner side surface of the swash plate, the water supply part is made of woven fabric or non-woven fabric, and the swash plate is placed. It has a height that protrudes upward from the upper end of the concrete.
According to such a concrete curing mold, it is possible to form a flooded layer surrounded by a slat on the upper surface of the concrete, and to supply the curing solution uniformly from the flooded layer to the side of the concrete through the water supply unit. can do.

  According to the concrete member construction method and the concrete curing form of the present invention, it is possible to provide an environment close to underwater curing by supplying the curing liquid uniformly and inexpensively to the surface of the concrete.

It is a perspective view which shows the concrete curing formwork which concerns on embodiment of this invention. (A) is a perspective view which shows the formwork formation process of the construction method of the concrete member of this embodiment, (b) is the elements on larger scale of (a). (A) is a perspective view which shows the placement process, (b) is a perspective view which shows a water storage process. It is sectional drawing which shows the outline of the concrete curing formwork which concerns on another form.

In the present embodiment, a concrete member construction method using the concrete curing mold 1 will be described.
As shown in FIG. 1, the concrete curing mold 1 includes a plurality of slats 2 and a water supply unit 3 and is formed so as to surround an outer surface of a concrete member (concrete C). In addition, the shape of the concrete curing mold 1 is appropriately formed according to the shape of the concrete member to be constructed.

The dam plate 2 is made of a wooden, resin or steel plate material having strength and rigidity that is not deformed against the pressure (side pressure) of the cast concrete C. In this embodiment, four slats (only three are displayed in FIG. 1) forming the side surface of the concrete member are combined in a rectangular shape in plan view. In addition, what is necessary is just to determine suitably arrangement | positioning of the dam plate 2 according to the shape of a concrete member.
The dam plate 2 of the present embodiment is made of a flat plate and has a height that protrudes upward from the upper end of the cast concrete C. In addition, the protrusion length of the upper part of the weir board 2 is not limited, and determines suitably. Moreover, the dam plate 2 does not necessarily need to be a flat plate, For example, you may have an unevenness | corrugation.

The water supply unit 3 is a part that supplies water W (curing solution) necessary to form an environment close to underwater curing to the concrete C when curing the concrete C.
The water supply part 3 of this embodiment is stuck (adhered) to the dam plate 2 so as to cover the inner surface of the dam plate 2. The water supply part 3 is comprised with the sheet-like material which accept | permits the passage of a water | moisture content and can suppress passage of a cement particle. The water supply part 3 of this embodiment consists of a woven fabric or a nonwoven fabric. Although the material which comprises the water supply part 3 is not limited, For example, the woven fabric and nonwoven fabric which included the water absorbing polymer other than the woven fabric and nonwoven fabric of a natural organic fiber or a synthetic fiber can be used. Moreover, the fixing method of the water supply part 3 to the dam plate 2 is not limited, For example, it fixes by latching to the latching member (needle etc.) projected on the inner surface of the dam board 2. Also good.
The water supply unit 3 of the present embodiment has a height equal to or higher than the concrete C placement height (concrete member height), and the concrete supply is placed in the concrete curing mold 1 to supply water. It is comprised so that the upper end surface of the part 3 may be exposed to external air. In addition, the water supply part 3 may cover the whole inner surface of the dam plate 2.
In addition, the thickness of the water supply unit 3 of the present embodiment is in the range of 0.1 to 5 mm so as to be suppressed to the extent that the shape of the concrete member is not affected even if it is deformed by the pressure of the cast concrete. .

The concrete member construction method of the present embodiment includes a mold forming process, a placing process, a water storage process, a curing process, and a demolding process.
As shown in FIG. 2A, the mold forming process is a process of forming the concrete curing mold 1 by combining a plurality of slats 2. In the present embodiment, four plates (only three are shown in FIG. 2A) are combined in a rectangular shape in plan view.
On the inner surface (surface on the concrete C side) of the weir plate 2, a water supply unit 3 is pasted in advance. The water supply unit 3 may be attached to the inner surface of the weir plate 2 after combining the weir plate 2.
When the weir plates 2 are combined, the joint material 4 is filled in the connecting portions between the weir plates 2 (corner portions of the concrete curing mold 1). In the present embodiment, the joint material 4 is filled into the upper end portion of the dam plate 2 (the portion protruding upward from the upper surface of the placing concrete C). The joint material 4 may be filled in the entire connecting portion (over the entire height) of the dam plate 2. The material constituting the joint material 4 is not limited as long as the water W can be stopped.

The placing step is a step of placing concrete C inside the concrete curing mold 1 as shown in FIG.
The surplus water including the breathing water generated after placing the concrete C stays in the water supply unit 3 and can be used as a curing liquid supplied to the surface of the concrete C in the curing process. In addition, it is not necessary to use surplus water for the curing solution of a curing process.

The water storage step is a step of supplying water (curing solution) W to the upper surface of the concrete C as shown in FIG. The water W is supplied to the upper surface of the concrete C after the concrete C is condensed.
When the water W is supplied to the upper surface of the concrete C, the water W is stored in a portion surrounded by the upper surface of the concrete C and the upper end portion of the dam plate 2, and the flooded portion 5 is formed.
Since the upper end portion of the water supply unit 3 faces the water supply unit 5, the water W of the water supply unit 5 penetrates into the water supply unit 3. The water W that has permeated the water supply unit 3 penetrates the entire water supply unit 3 by capillary action and gravity, and the water (curing solution) W is supplied to the entire side surface of the concrete C.

  In this embodiment, water (tap water etc.) W is used as a curing solution. In addition, as a liquid used for the curing solution, in addition to water W, a calcium hydroxide (saturated) solution, a silica-based impregnating agent, a penetrating rust preventive agent, and the like are used, so that the hardened body of concrete C is more dense. It may be formed to improve durability. If these liquids are used, the active ingredient will be additionally supplied from the outside, and the hydration reaction will be accelerated or the amount of hydrated product will be increased from the viewpoint of mass conservation. Easy continuous voids can be blocked more effectively, and in addition to the curing effect, additional functions such as a water repellent effect and a rust preventive effect can also be imparted.

The curing process is a process of curing concrete C in the concrete curing mold 1 as shown in FIG.
The upper end surface of the concrete C is in contact with the water W of the flooded part 5, and the side surface of the concrete C is in contact with the water W supplied via the water supply part 3. Therefore, curing of concrete C is performed in an environment close to underwater curing.

The demolding step is a step of demolding the concrete curing mold 1.
The demolding of the concrete curing mold 1 is performed by curing the concrete C for a predetermined period, and after the predetermined strength has been developed in the concrete C, the piling board 2 (water supply unit 3) is removed from the surface of the hardened body of the concrete C. Do.

As described above, according to the concrete curing mold 1 and the concrete member construction method of the present embodiment, water (curing solution) is supplied to the concrete C by the simple and inexpensive concrete curing mold 1 constituted by the dam plate 2 and the water supply unit 3. ) W can be supplied.
In addition, according to the concrete curing form 1, it is possible to realize underwater curing on-site, prevent the dissipation of moisture during the concrete curing, and actively supply moisture to the concrete C. Can improve the quality.

Since the water W is uniformly supplied to the entire surface of the concrete C through the water supply unit 3, it is possible to form an environment close to underwater curing, and compared with the conventional concrete curing method, Hydration is promoted, and a denser concrete hardened body can be formed.
The supply of the curing solution to the water supply unit 3 is performed by infiltrating the water W from the flooded unit 5, so that the work is simple and a minimum amount of water is required.

Moreover, since the water supply part 3 is arrange | positioned in the contact surface of the concrete C and the concrete curing formwork 1, the surplus water and air bubble of the surface layer part of the concrete C can be excluded, and the aesthetics of the concrete surface improves. At the same time, the strength and proof stress of the concrete surface are improved.
Since the flooded part 5 is formed using the dam plate 2, a separate container or the like is not required. Moreover, since the joint material 4 is filled with the joint material 4, the water of the flooded part 5 does not leak out.

Hereinafter, the test result using the concrete curing mold 1 of this embodiment is shown. In this test, the degree of rebound and the air permeability coefficient were measured for concrete members formed using the concrete curing form 1 (Example). In addition, as a comparative example, the degree of rebound and the air permeability coefficient were measured for a concrete member formed using a normal formwork (only the dam plate 2) (comparative example).
The test results are shown in Table 1.

As shown in Table 1, the concrete members (examples) formed by the concrete curing mold 1 of the present embodiment have an air permeability coefficient of 0.032 to 0.093 × 10 ⁻¹⁶ m ² , and the conventional formwork Compared with the air permeability coefficient (0.355-0.450 * 10 < ^-16 > m < ² >) of the concrete member (comparative example) formed by this, it is improved significantly. Therefore, it was confirmed that the concrete curing mold 1 and the concrete member construction method of the present embodiment can form a dense concrete member that is difficult for air to penetrate.
Moreover, the concrete member (example) formed with the concrete curing mold 1 of this embodiment has an electrical low efficiency of 10.9 to 25.3 kΩ · cm, and the concrete member formed with the conventional mold (comparative example). Compared with the low electric efficiency (40.6 to 51.5 kΩ · cm), it is greatly improved. Therefore, it was confirmed that the concrete curing mold 1 and the concrete member construction method of the present embodiment can form a dense concrete member that is difficult for chloride ions to permeate.
In this demonstration experiment, concrete members having the same compressive strength (repulsion degree) were formed for the examples and comparative examples.

The embodiment according to the present invention has been described above. However, the present invention is not limited to the above-described embodiment, and the above-described components can be appropriately changed without departing from the spirit of the present invention.
For example, the concrete member manufactured by the concrete formwork 1 is not limited, and for example, any concrete member such as a box girder, a wall member, a retaining wall, a wall surface of a culvert, a floor slab concrete, a tunnel lining concrete, etc. Applicable.
In the present embodiment, the concrete curing mold 1 is used for cast-in-place concrete, but the concrete curing mold 1 may be used when forming a precast member in a factory or the like.

  Moreover, although the said embodiment demonstrated the case where the water W was supplied to the water supply part 3 by infiltrating water from the flooding part 5 formed by storing water on the upper surface of the concrete C, The method for supplying water W is not limited to this. For example, as shown in FIG. 4, water W may be supplied to the water supply unit 3 from a flooded unit (for example, a water storage tank or a water storage tank) 5 provided at a position higher than the concrete C. At this time, the upper end portion of the water supply unit 3 extends from the upper end of the weir plate 2 and is in contact with the water in the flooded unit 5. Therefore, the water W in the flooded part 5 penetrates the entire water supply part 3 due to capillary action and gravity, and is supplied uniformly to the side surface of the concrete C.

1 Concrete curing formwork (formwork)
2 Scallop 3 Water supply part 4 Joint material 5 Flooding part C Concrete W Water (curing solution)

Claims (4)

A placing process of placing concrete inside the formwork;
A curing method for curing the concrete in the formwork, and a concrete member construction method comprising:
The mold is provided with a slat, and a water supply unit interposed between the concrete placed in the mold and the slat.
The water supply unit is made of woven fabric or non-woven fabric,
In the curing process, a curing solution is supplied to the entire water supply unit by forming a flooded unit so that an upper end of the water supply unit is in contact with an upper part of the formwork. Construction method.   The upper end portion of the dam is protruded above the upper surface of the concrete, and the water filling portion is formed by storing a curing solution in a portion surrounded by the upper surface of the concrete and the upper end portion of the dam plate. The concrete member construction method according to claim 1, wherein: Comprising a mold forming step of forming a mold by combining a plurality of dams;
The construction method for a concrete member according to claim 2, wherein in the mold forming step, a joint material is filled in at least an upper end portion of the connecting portion between the dams. With a weeping board,
A concrete curing mold comprising a water supply portion provided on an inner surface of the dam,
The water supply unit is made of woven fabric or non-woven fabric,
A concrete-curing formwork, wherein the weir plate has a height protruding upward from an upper end of the cast concrete.

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