JP2021155292A - Covering material, manufacturing method of covering material, concrete molded body, tubular molded body, manufacturing method of tubular molded body, and, slurry - Google Patents

Abstract

To provide a covering material or the like capable of imparting sulfuric acid resistance to a concrete molded body.SOLUTION: The covering material comprises a cement-based hydraulic material, the cement-based hydraulic material contains a blast furnace slag fine powder and a fly ash, the content ratio of the blast furnace slag fine powder in the cement-based hydraulic material is over 50 mass% and 90 mass% or less, the content ratio of the fly ash in the cement-based hydraulic material is over 5 mass% to 25% or less, and the total content ratio of the blast furnace slag fine powder and the fly ash in the cement-based hydraulic material exceeds 65 mass%.SELECTED DRAWING: None

Description

The present invention relates to a covering material, a method for producing a covering material, a concrete molded body, a tubular molded body, a method for manufacturing a tubular molded body, and a slurry.

Conventionally, a tubular molded body is manufactured by supplying concrete to a mold for centrifugal molding and compacting it by centrifugal force.

Such a tubular molded body is used as a water pipe (particularly a sewer pipe) for circulating water inside.
Conventional sewer pipes may be deteriorated by sulfuric acid contained in sewage (such as sulfuric acid generated due to hydrogen sulfide in sewage).
For this reason, a tubular molded body provided with a tubular molded body made of concrete and a covering material containing a resin by covering the inner peripheral surface of the tubular molded body has been produced (for example, a patent). Document 1).
By covering the inner peripheral surface of the tubular molded body with a covering material, the tubular molded body has excellent sulfuric acid resistance.

Japanese Unexamined Patent Publication No. 8-150613

However, further coating materials have not been sufficiently studied so far.
Further, not only a tubular molded body made of concrete but also other concrete molded bodies can be required to have a covering material capable of imparting sulfuric acid resistance.

Therefore, an object of the present invention is to provide a coating material capable of imparting sulfuric acid resistance to a concrete molded body, and a slurry provided with the coating material.

As a result of diligent research by the present inventor, the covering material is provided with a cement-based hydraulic material, and the cement-based hydraulic material contains blast furnace slag fine powder and fly ash in an appropriate blending ratio to make concrete. We have found that it is possible to impart sulfuric acid resistance to a molded product, and have come up with the present invention.

The covering material according to the present invention includes a cement-based hydraulic material, and is provided with a cement-based hydraulic material.
The cement-based hydraulic material contains blast furnace slag fine powder and fly ash.
The content ratio of the blast furnace slag fine powder in the cement-based hydraulic material is more than 50% by mass and 90% by mass or less.
The content ratio of the fly ash in the cement-based hydraulic material is more than 5% by mass and 25% by mass or less.
The total content ratio of the blast furnace slag fine powder and the fly ash in the cement-based hydraulic material exceeds 65% by mass.

Here, in one aspect of the coating material according to the present invention, the total content ratio of the blast furnace slag fine powder and the fly ash in the cement-based hydraulic material is 90% by mass or less.

Another aspect of the covering material according to the present invention further comprises a fine aggregate.

Further, the method for producing a coating material according to the present invention is a method for producing a coating material, wherein the coating material is produced.
The coating material is prepared by mixing the blast furnace slag fine powder and the fly ash.

Further, the concrete molded body according to the present invention includes a concrete molded body formed of concrete and a coating layer formed by covering the surface of the concrete molded body with the covering material.

Further, the tubular molded body according to the present invention includes a tubular molded body made of concrete and a coating layer formed by covering the inner peripheral surface of the tubular molded body with the covering material.

Further, the method for producing a tubular molded product according to the present invention is a method for producing a tubular molded product, which produces a tubular molded product.
The tubular molded body includes a tubular molded body made of concrete and a coating layer formed by covering the inner peripheral surface of the tubular molded body with a covering material.
Centrifugal molding step of obtaining the tubular molded body by centrifugal molding from concrete, and
A coating layer forming step of forming the coating layer by supplying the coating material according to any one of claims 1 to 3 to the inner peripheral surface of the tubular molded body is provided.

Further, one aspect of the method for producing a tubular molded product according to the present invention is at least one of the shavings exuded from the inner peripheral surface side of the tubular molded body after the centrifugation step and before the coating layer forming step. A removal step for removing the portion is further provided.

Further, in the coating layer forming step of another aspect of the method for producing a tubular molded product according to the present invention, the coating by supplying the coating slurry containing the coating material and water to the inner peripheral surface of the tubular molded body. Form a layer.

Further, the slurry according to the present invention includes the covering material and water.

According to the present invention, sulfuric acid resistance can be imparted to a concrete molded product.

FIG. 5 is a schematic cross-sectional view showing a state in which an outer portion of the tubular molded body is formed by a mold for centrifugal molding in the method for manufacturing a tubular molded body according to the present embodiment. FIG. 5 is a schematic cross-sectional view showing a state in which slag is accumulated on the inner peripheral surface of the tubular molded body in the method for manufacturing a tubular molded body according to the present embodiment. Schematic cross-sectional view of a tubular molded article according to this embodiment. The figure which shows the shape and size of the specimen for the sulfuric acid aqueous solution immersion test.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

The covering material according to the present embodiment includes a cement-based hydraulic material.
Further, it is preferable that the covering material according to the present embodiment further includes a fine aggregate.
Further, the covering material according to the present embodiment may further include an admixture.

The cement-based hydraulic material contains blast furnace slag fine powder and fly ash.
Further, the cement-based hydraulic material contains cement.
Further, the cement-based hydraulic material may contain silica fume, an expanding material, gypsum and the like.

The cement contained in the cement-based hydraulic material is hydraulic cement.
Examples of the hydraulic cement include various Portland cements such as ordinary, early-strength, ultra-fast-strength, white, sulfate-resistant, moderate heat, and low heat.
Examples of the hydraulic cement include blast furnace cement, fly ash cement, silica cement, and alumina cement.

The cement-based hydraulic material may contain blast furnace slag fine powder by containing blast furnace cement. Further, the cement-based hydraulic material may contain a blast furnace slag fine powder different from the blast furnace slag fine powder contained in the blast furnace cement.
Further, the cement-based hydraulic material may contain fly ash by containing fly ash cement. Further, the cement-based hydraulic material may contain fly ash different from the fly ash contained in the fly ash cement.

The blast furnace slag fine powder is a blast furnace slag fine powder specified in JIS A 6206: 2013 “Blast furnace slag fine powder for concrete”.
Examples of the blast furnace slag fine powder include blast furnace slag fine powder 3000, blast furnace slag fine powder 4000, blast furnace slag fine powder 6000, and blast furnace slag fine powder 8000.

Content ratio of the blast furnace slag fine powder in the cement-based water-hard material (total content ratio of the blast furnace slag fine powder contained in the blast furnace cement and the blast furnace slag fine powder different from the blast furnace slag fine powder contained in the blast furnace cement). ) Is more than 50% by mass and 90% by mass or less, and is preferably 55 to 80% by mass, more preferably 55 to 70% by mass.

The fly ash is a fly ash specified in JIS A 6201: 2015 “Fly ash for concrete”.
Examples of the fly ash include fly ash I, fly ash II, fly ash III, and fly ash IV.
As the fly ash, fly ash type I and fly ash type II are preferable from the viewpoint of easy availability.

The content ratio of the fly ash in the cement-based water-hard material (the total content ratio of the fly ash contained in the fly ash cement and the fly ash different from the fly ash contained in the fly ash cement) is 5% by mass. It is important that it exceeds 25% by mass and is 25% by mass or less, preferably 10 to 25% by mass, and more preferably 10 to 20% by mass.

It is important that the total content ratio of the blast furnace slag fine powder and the fly ash in the cement-based water-hard material exceeds 65% by mass, preferably 70% by mass or more, and more preferably 75% by mass or more.
The total content of the blast furnace slag fine powder and the fly ash in the cement-based hydraulic material is preferably 90% by mass or less, more preferably 85% by mass or less.

Examples of the silica fume include silica fume specified in JIS A 6207: 2016 “Silica fume for concrete”.

Examples of the expansion material include expansion materials specified in JIS A6202: 2017 “Expansion material for concrete”.

The gypsum is not particularly limited, and examples of the gypsum include anhydrous gypsum, dihydrate gypsum, and hemihydrate gypsum.

The covering material according to the present embodiment preferably further includes a fine aggregate from the viewpoint that the cement-based hydraulic material and water are difficult to separate when mixed with water.
Examples of the fine aggregate include those specified in "Annex A (Regulation) Aggregate for ready-mixed concrete" of JIS A 5308: 2019 "Ready-mixed concrete".
The fine aggregates include natural fine aggregate (sand made from rock by natural action), crushed aggregate (crushed sand) obtained by crushing natural aggregate, slag fine aggregate, artificial lightweight fine aggregate, and recycled aggregate (recycled aggregate). Recycled concrete waste material).
Examples of the slag fine aggregate include blast furnace slag fine aggregate, ferronickel slag fine aggregate, copper slag fine aggregate, electric furnace oxidized slag fine aggregate and the like.

The covering material according to the present embodiment includes 100 parts by mass of the cement-based hydraulic material, preferably 50 to 250 parts by mass, and more preferably 75 to 200 parts by mass.

Examples of the admixture include an AE agent, a water reducing agent, an AE water reducing agent, a high-performance water reducing agent, a high-performance AE water reducing agent, a fluidizing agent, a thickener, an antiseptic agent, a hardening accelerator, and a setting retarder. ..

The method for producing the covering material according to the present embodiment is a method for producing the covering material according to the present embodiment.
In the method for producing a coating material according to the present embodiment, the coating material is produced by mixing the blast furnace slag fine powder and the fly ash.
More specifically, in the method for producing a covering material according to the present embodiment, the covering material is prepared by mixing the blast furnace slag fine powder, the fly ash, the cement, and the fine aggregate. do.

The coating slurry according to the present embodiment includes the coating material and water according to the present embodiment.

The coating slurry according to the present embodiment comprises 100 parts by mass of the water, preferably 30 to 60 parts by mass, and more preferably 40 to 60 parts by mass with respect to 100 parts by mass of the cement-based hydraulic material.

The concrete molded body according to the present embodiment includes a concrete molded main body made of concrete and a coating layer formed by covering the surface of the concrete molded main body with the covering material according to the present embodiment.

The concrete contains cement, fine aggregate, coarse aggregate, and water.

The cement contained in the concrete is hydraulic cement.
Examples of the hydraulic cement include various Portland cements such as ordinary, early-strength, ultra-fast-strength, white, sulfate-resistant, moderate heat, and low heat.
Examples of the hydraulic cement include blast furnace cement, fly ash cement, silica cement, and alumina cement.

Examples of the fine aggregate contained in the concrete include those specified in "Annex A (Regulation) Aggregate for ready-mixed concrete" of JIS A 5308: 2019 "Ready-mixed concrete".

Examples of the coarse aggregate contained in the concrete include those specified in "Annex A (Regulation) Aggregate for ready-mixed concrete" of JIS A 5308: 2019 "Ready-mixed concrete".

The concrete contains cement at preferably 300 kg / m ³ or more and 600 kg / m ³ or less, more preferably 350 kg / m ³ or more and 540 kg / m ³ or less.

The concrete contains fine aggregate at preferably 700 kg / m ³ or more and 1000 kg / m ³ or less, more preferably 750 kg / m ³ or more and 900 kg / m ³ or less.

The concrete contains coarse aggregate at preferably 850 kg / m ³ or more and 1150 kg / m ³ or less, more preferably 900 kg / m ³ or more and 1100 kg / m ³ or less.

In the concrete, the water-cement ratio (mass of water / mass of cement) (W / C) is preferably 25% or more and 55% or less, and more preferably 30% or more and 50% or less.

The concrete may contain an admixture.
Examples of the admixture contained in the concrete include an AE agent, a water reducing agent, an AE water reducing agent, a high-performance water reducing agent, a high-performance AE water reducing agent, a fluidizing agent, a thickener, an antiseptic agent, a hardening accelerator, and a setting retarder. And so on.

Examples of the concrete molded body according to the present embodiment include a tubular molded body.

The tubular molded body according to the present embodiment includes a tubular molded body made of concrete and a coating layer formed by covering the inner peripheral surface of the tubular molded body with the covering material according to the present embodiment. ..

Examples of the tubular molded body include a tubular molded body in which concrete is centrifugally molded.

The size of the tubular molded product is not particularly limited. For example, the inner diameter of the tubular molded product is preferably 200 mm or more and 900 mm or less, and more preferably 400 mm or more and 800 mm or less. The outer diameter of the tubular molded body is preferably 300 mm or more and 1000 mm or less, and more preferably 500 mm or more and 1000 mm or less. The length of the tubular molded body is preferably 300 mm or more, more preferably 2000 mm or more and 3000 mm or less, and particularly preferably 2000 mm or more and 2500 mm or less.

The method for producing a tubular molded product according to the present embodiment is to produce a tubular molded product.
The tubular molded body includes a tubular molded body made of concrete and a coating layer formed by covering the inner peripheral surface of the tubular molded body with a covering material.

The method for manufacturing a tubular molded body according to the present embodiment is a centrifugal molding step of obtaining the tubular molded body by centrifugation from concrete, and supplying a covering material according to the present embodiment to the inner peripheral surface of the tubular molded body. The coating layer forming step for forming the coating layer is provided.

More specifically, the method for producing a tubular molded product according to the present embodiment includes a centrifugal molding step of obtaining the tubular molded body from concrete by centrifugal molding, and after the centrifugal molding step and before the coating layer forming step. The coating is performed by removing at least a part of the glue exuded from the inner peripheral surface side of the tubular molded body and supplying the coating slurry according to the present embodiment to the inner peripheral surface of the tubular molded body. It includes a coating layer forming step of forming a layer.
The slag is a slurry-like substance (consisting of cement, water, etc.).

In the centrifugal molding step, the concrete is centrifugally molded once or in a plurality of times.
Specifically, in the centrifugal molding step, as shown in FIG. 1, a reinforcing bar (not shown) embedded in the tubular molding body is arranged in the tubular mold X for centrifugal molding. , The concrete is supplied to the inside of the formwork X while rotating the formwork X. And low speed (centrifugal force 4-8G, time: 5 minutes-7 minutes), medium speed (centrifugal force 10-25G, time: 3 minutes-5 minutes), high speed (centrifugal force 30-55G, time: 4 minutes- Centrifugal molding is performed by changing the rotation speed in the order of 6 minutes) (first centrifugal step). As a result, the outer portion 1a of the tubular molded body is formed.
Next, the concrete is supplied to the inside of the outer portion 1a while rotating the formwork X. And low speed (centrifugal force 4-8G, time: 5 minutes-7 minutes), medium speed (centrifugal force 10-25G, time: 3 minutes-5 minutes), high speed (centrifugal force 30-55G, time: 4 minutes- Centrifugal molding is performed by changing the rotation speed in the order of 6 minutes) (second centrifugal step). As a result, a tubular molded body is formed.
Then, when the rotation of the mold X is stopped after performing the centrifugal molding step, as shown in FIG. 2, the glue 1c exuded from the tubular molding main body 1b is in a state of being accumulated inside the tubular molding main body 1b.

In the removing step, at least a part of the slag 1c exuded from the inner peripheral surface side of the tubular molding body 1b is removed after the centrifugation step and before the coating layer forming step.

In the coating layer forming step, the coating slurry is supplied to the inner peripheral surface of the tubular molding body, and the coating layer is formed by centrifugal molding.
Specifically, in the coating layer forming step, as shown in FIG. 3, the coating slurry is supplied to the inner peripheral surface of the tubular molding body 1b in the mold X while rotating the mold X at a low speed. Then, the coating slurry is leveled with a rod-shaped member (so-called finishing rod or the like) to form the coating layer 1d by centrifugation.
Instead of the rod-shaped member, a plate-shaped member (for example, a spatula or the like), a brush, or the like may be used.

The thickness of the coating layer is preferably 3 mm or more and 15 mm or less, and more preferably 5 mm or more and 10 mm or less.

The tubular molded body produced as described above is preferably taken out of the mold after being steam-cured. In steam curing, the temperature of the environment in which the tubular molded body is placed together with the mold is 30 ° C. A step of raising the temperature at a rate of / hour or less (heating step) and after the raising step, the temperature of the environment in which the tubular molded body is placed together with the mold is maintained at 65 ± 10 ° C. for 2 hours or more. It is preferable that a step of performing the process (temperature holding step) and a step of lowering the temperature of the environment in which the tubular molded body is arranged together with the mold to room temperature (temperature lowering step) are performed after the temperature holding step.
Further, it is preferable that the tubular molded product taken out from the mold after steam curing is air-cured until a predetermined age (7 days or more from the production of the tubular molded product).

The covering material, the method for producing the covering material, the concrete molded body, the tubular molded body, the manufacturing method for the tubular molded body, and the slurry according to the present invention are not limited to the above embodiments. Further, the covering material, the method for producing the covering material, the concrete molded body, the tubular molded body, the manufacturing method for the tubular molded body, and the slurry according to the present invention are not limited by the above-mentioned effects. Further, the covering material, the method for producing the covering material, the concrete molded body, the tubular molded body, the manufacturing method for the tubular molded body, and the slurry according to the present invention can be variously changed without departing from the gist of the present invention. be.

For example, in the method for producing a tubular molded product according to the present embodiment, the removal step is performed, but in the method for producing a tubular molded product according to the present invention, the removal step may not be performed.
Further, in the method for producing a tubular molded product according to the present invention, the coating layer may be formed by mixing the slag and the coating slurry.
Further, in the method for producing a tubular molded product according to the present invention, the coating material may be mixed with the slag to form a coating layer without being mixed with water to form a slurry.

Next, the present invention will be described in more detail with reference to Examples, Comparative Examples, and Test Examples.

(Making a tubular molded body)
Using the following materials, concrete with the blending ratio shown in Table 1 below was prepared. In Table 1 below, "W / C" means the water-cement ratio (mass of water / mass of cement), and "s / a" is the fine aggregate ratio (volume of fine aggregate / fine bone). It means the total volume of material and coarse aggregate).
Cement (abbreviation: C): Ordinary Portland cement (manufactured by Sumitomo Osaka Cement Co., Ltd.)
Water (abbreviation: W): Tap water Fine aggregate (abbreviation: S): Mountain sand (produced in Kakegawa City, Shizuoka Prefecture)
Coarse aggregate (abbreviation: G): Hard sandstone crushed stone 2005 (produced in Sakuragawa City, Ibaraki Prefecture)
Admixture (abbreviation: AD): Naphthalene sulfonic acid-based water reducing agent (Mighty 150, manufactured by Kao Corporation)

Specifically, the admixture and water were mixed to obtain admixture-containing water.
Next, the cement, fine aggregate, and coarse aggregate are air-kneaded for 15 seconds with a forced twin-screw kneading mixer, then the admixture-containing water is added to these and kneaded with a forced twin-screw kneading mixer for 3 minutes. , Made concrete.
Then, concrete was supplied to a hollow mold having a diameter of 200 × 300 mm, and centrifugal molding was performed in the order of low speed (5G) for 2 minutes, medium speed (15G) for 2 minutes, and high speed (44G) for 7 minutes to obtain a tubular molded body. ..
Next, most of the slag that had exuded from the inner peripheral surface side of the tubular molded body was removed.

(Preparation of coated slurry)
Using the following materials, the materials were kneaded with a hovert mixer for 2 minutes so as to have the blending ratios shown in Tables 2 and 3 below to obtain a coated slurry.
Cement: Ordinary Portland cement (abbreviation: NC) (manufactured by Sumitomo Osaka Cement Co., Ltd.)
Alumina cement (abbreviation: AC) (manufactured by AGC Ceramic)
Water (abbreviation: W): Tap water blast furnace slag fine powder (abbreviation: BFS): Blast furnace slag fine powder 4000 (manufactured by Nippon Steel Slag Products Co., Ltd.)
Fly ash (abbreviation: FA): Hekinan Thermal Power Station product (manufactured by Techno Chubu Co., Ltd.)
Fine aggregate (abbreviation: S): silica sand No. 7 (manufactured by JFE Mineral Co., Ltd.)

(Preparation of tubular molded body)
While rotating the hollow mold at a low speed, the coating slurry is supplied to the inner peripheral surface of the tubular molding body in the hollow mold, and the coating slurry is leveled with a finishing rod to form a coating layer (thickness: 10 mm). Then, a tubular molded body was obtained.
Then, in the steam curing of the obtained tubular molded body, the tubular molded body was held together with the mold at room temperature for 4 hours (pre-curing step). Further, after the pre-curing step, the temperature of the environment in which the tubular molded body is placed together with the mold is raised at a rate of 30 ° C./hour or less (heating step), and the environment in which the tubular molded body is placed together with the mold. The temperature was maintained at 65 ± 10 ° C. for 2 hours or more (temperature holding step). Further, after the temperature holding step, the temperature of the environment in which the tubular molded body was placed together with the mold was lowered to room temperature (temperature lowering step).
The steam-cured tubular molded body was demolded at the age of 1 day and cured in the air until the age of 28 days. The material age here is the material age calculated from the production of the tubular molded body.

(Sulfuric acid aqueous solution immersion test)
The above-mentioned tubular molded body after aerial curing was cut with a wet concrete cutter to prepare a specimen shown in FIG.
Then, five surfaces other than the inner surface of the specimen (a part of the inner peripheral surface of the tubular molded product) were coated with an acryloyl-modified acrylic resin adhesive. Then, a sulfuric acid aqueous solution immersion test was performed on such a specimen to determine the mass change rate.
Specifically, a sulfuric acid aqueous solution immersion test was conducted in accordance with the "Corrosion Control Technology and Anticorrosion Technology Manual for Sewerage Concrete Structures (Published by: Sewerage Business Support Center)". The outline of the test is as follows.
First, the mass of the specimen was measured.
Next, such a specimen was immersed in an aqueous sulfuric acid solution (sulfuric acid concentration: 5% by mass) for 28 days. The mass of the specimen was measured 7 days and 28 days after being immersed in the sulfuric acid aqueous solution.
Before measuring the mass of the specimen, the sulfuric acid aqueous solution adhering to the surface of the specimen was washed away with tap water, and the water adhering to the surface of the specimen was sufficiently wiped off with a dry cloth.
Then, the mass change rate of the specimen after 7 days and after 28 days was calculated by the following formula.
Mass change rate after 7 days (%) = (mass after 7 days-mass immediately before immersion) / mass immediately before immersion x 100
Mass change rate after 28 days (%) = (mass after 28 days-mass immediately before immersion) / mass immediately before immersion x 100
The evaluation was based on the following evaluation criteria.
⊚: Although the mass change rate after 7 days and the mass change rate after 28 days are both −0.30% or more and the mass change rate after 7 days is negative, after 28 days When the mass change rate of is positive.
〇: When both the mass change rate after 7 days and the mass change rate after 28 days are -0.30% or more.
Δ: When only one of the mass change rate after 7 days and the mass change rate after 28 days is −0.30% or more.
X: When both the mass change rate after 7 days and the mass change rate after 28 days are less than -0.30%.
The results are shown in Tables 2 and 3 below.

As shown in Table 2, in the examples, it was difficult to reduce the mass of the tubular molded product as compared with the comparative example.
Further, in Examples 1 to 8 and 10 to 13, even if the mass of the tubular molded body decreased once, the mass of the tubular molded body was subsequently recovered to the original state or more. That is, Examples 1 to 8 and 10 to 13 exhibited an excellent effect of having self-healing property.

1: Tubular molded body, 1a: Outer part, 1b: Tubular molded body, 1c: Noro, 1d: Coating layer, X: Formwork.

Claims (10)

Equipped with cement-based hydraulic material,
The cement-based hydraulic material contains blast furnace slag fine powder and fly ash.
The content ratio of the blast furnace slag fine powder in the cement-based hydraulic material is more than 50% by mass and 90% by mass or less.
The content ratio of the fly ash in the cement-based hydraulic material is more than 5% by mass and 25% by mass or less.
A coating material in which the total content of the blast furnace slag fine powder and the fly ash in the cement-based hydraulic material exceeds 65% by mass. The coating material according to claim 1, wherein the total content ratio of the blast furnace slag fine powder and the fly ash in the cement-based hydraulic material is 90% by mass or less. The covering material according to claim 1 or 2, further comprising a fine aggregate. A method for producing a covering material, wherein the covering material according to any one of claims 1 to 3 is produced.
A method for producing a coating material, wherein the coating material is produced by mixing the blast furnace slag fine powder and the fly ash. A concrete molded body including a concrete molded body formed of concrete and a coating layer formed by coating the surface of the concrete molded body with the covering material according to any one of claims 1 to 3. .. A tubular body provided with a tubular molded body made of concrete and a coating layer formed by coating the inner peripheral surface of the tubular molded body with the covering material according to any one of claims 1 to 3. Molded body. A method for producing a tubular molded product, which is a method for producing a tubular molded product.
The tubular molded body includes a tubular molded body made of concrete and a coating layer formed by covering the inner peripheral surface of the tubular molded body with a covering material.
Centrifugal molding step of obtaining the tubular molded body by centrifugal molding from concrete, and
A method for producing a tubular molded product, comprising a coating layer forming step of forming the coating layer by supplying the coating material according to any one of claims 1 to 3 to the inner peripheral surface of the tubular molded body. .. The tubular according to claim 7, further comprising a removing step of removing at least a part of the glue exuded from the inner peripheral surface side of the tubular molding body after the centrifugation step and before the coating layer forming step. A method for manufacturing a molded product. The tubular molded body according to claim 7 or 8, wherein in the coating layer forming step, the covering slurry containing the coating material and water is supplied to the inner peripheral surface of the tubular molding body to form the coating layer. Production method. A coating slurry comprising the coating material according to any one of claims 1 to 3 and water.

Images