JP6433808B2 - Method for constructing structure and method for protecting bedrock - Google Patents

Description

  The present invention relates to a method for constructing a structure constructed on a rock mass and a method for protecting the rock mass.

When building a structure such as a dam body, in order to avoid the effects of crustal deformation such as earthquakes and to maintain the structure stably over a long period of time, the ground is excavated until the bedrock (foundation ground) is exposed. A structure may be built on top. In order to prevent the rock surface from deteriorating due to climate change, such as rainfall and temperature changes, after excavating the ground and exposing the rock, and before constructing the structure, for example, the surface of the rock is sprayed with sprayed mortar. A covering method may be employed. Such a construction method is disclosed in Non-Patent Document 1.
On the other hand, Patent Document 1 discloses that a clay or gravel soil material is solidified and hydrophobized using a chemical containing an alkali metal silicate and an alkali metal siliconate.

JP 2000-109833 A

Dam Technology Center, "Construction of Multipurpose Dam", 2005 edition, Volume 6, Construction

  However, when the above-mentioned structure is made of concrete and is rocked on the rock surface, it is necessary to remove the above-mentioned sprayed mortar prior to the construction of the structure. In removing this sprayed mortar, it was necessary to manually remove the mortar using a breaker, pick hammer, etc. so as not to damage the rock surface, and this removal work required much labor and labor. .

  In view of such a situation, an object of the present invention is to reduce a work load when removing mortar or concrete covering a rock surface from the rock surface for protecting the rock surface.

Therefore, in the first aspect of the present invention, as a construction method of the structure, a step of applying a chemical to the rock surface exposed to the outside, a step of further applying mortar or concrete on the rock surface to which the chemical has been applied, and mortar Alternatively, a step of removing concrete from the rock surface, a step of excavating the rock surface from which mortar or concrete has been removed to a predetermined thickness, and a step of constructing a structure on the excavation surface, Including. The chemical reduces the adhesion of the mortar or concrete to the rock surface. The rock surface to which the drug is applied has water repellency.

In the second aspect of the present invention, as a method for constructing a structure, a step of applying a chemical to a rock surface exposed to the outside, a step of further applying mortar or concrete on the rock surface to which the chemical has been applied, Removing the concrete from the rock surface and building a structure on the rock surface from which the mortar or concrete has been removed. The chemical reduces the adhesion of the mortar or concrete to the rock surface. The rock surface to which the drug is applied has water repellency.

In the third aspect of the present invention, the method for protecting a rock mass includes a step of applying a chemical to the rock surface exposed to the outside, and a step of further applying mortar or concrete on the rock surface to which the chemical is applied. The chemical reduces the adhesion of the mortar or concrete to the rock surface. The rock surface to which the drug is applied has water repellency.

  According to the present invention, prior to applying mortar or concrete onto the rock surface, the agent for reducing the adhesion force of the mortar or concrete to the rock surface is applied to the rock surface. This reduces the adhesion of the mortar or concrete covering the rock surface to the rock surface to protect the rock surface, so that when removing the mortar or concrete from the rock surface, the mortar or concrete can be easily peeled off from the rock surface. In turn, the work load when removing mortar or concrete from the rock surface can be reduced.

The flowchart which shows the construction method of the dam dam body in 1st Embodiment of this invention. Diagram showing excavation plan surface, cover lock and mortar Diagram showing the reaction between potassium methylsiliconate and carbon dioxide The figure which shows the effect by applying the medicine on the rock surface The flowchart which shows the construction method of the dam body in 2nd Embodiment of this invention The figure which shows an excavation plan surface, the 1st excavation surface, and mortar

  Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a flowchart showing a construction method of a dam dam body in the first embodiment of the present invention. FIG. 2 is a diagram illustrating the excavation plan surface, the cover lock, and the mortar.
In this embodiment, the construction method for a structure according to the present invention will be described below by taking a construction method for a dam bank as an example, but the structure according to the present invention is not limited to a dam bank.
Moreover, although this embodiment demonstrates below that a dam dam body is a product made from concrete (namely, a dam dam body is a dam body of a concrete dam), the structure of a dam dam body is not restricted to this.

A dam body (not shown) is a hydraulic structure having a function of blocking water.
The dam body is constructed on the bedrock after excavation of the bedrock as the foundation ground.

  While excavation of this rock mass requires a large amount of soil and rock to be excavated in a short period of time, it is necessary to prevent damage to the rock mass near the excavation plan surface α (see FIG. 2). Therefore, in general, excavation up to the excavation plan surface α is performed by being divided into rough excavation (step S1 described later) and finish excavation (step S6 described later).

As shown in FIG. 1, in the construction method of a dam dam body, first, rough excavation (foundation excavation) of the ground is performed in step S1. By this rough excavation, the first excavation surface 1 (see FIG. 2) which is the rock surface (surface of the foundation ground) is exposed to the outside. That is, the first excavation surface 1 is formed by excavating the ground.
For rough excavation, explosive excavation using explosives is used when the ground is hard rock, and mechanical excavation using bulldozers, rippers, etc. is used when it is topsoil, soft rock, weathered rock, etc. .

  In rough excavation, a rock mass of a predetermined thickness t1 is left up to the excavation plan surface α. That is, the rough excavation is performed so that the distance (thickness) between the first excavation surface 1 and the excavation plan surface α becomes the predetermined thickness t1. Here, a portion of the bedrock corresponding to the predetermined thickness t1 is referred to as a cover lock C. The predetermined thickness t1 is set in advance so as to cover and protect the excavation plan surface α. The predetermined thickness t1 is, for example, about 50 cm.

Next, in step S <b> 2, a medicine is applied on the first excavation surface 1. This chemical | medical agent has the function to reduce the adhesive force to the 1st excavation surface 1 of the mortar 5 or concrete (not shown) mentioned later. When this agent is applied on the first excavation surface 1 before the mortar 5 or concrete is applied on the first excavation surface 1, the mortar 5 or concrete is applied to the first excavation surface 1. Attaching force (in other words, affinity) is reduced as compared with the case where mortar 5 or concrete is directly applied to first excavation surface 1.
The first excavation surface 1 to which this chemical is applied has water repellency. Since the portion having water repellency is interposed between the mortar 5 or concrete and the first excavation surface 1, the adhesion force of the mortar 5 or concrete to the first excavation surface 1 is reduced.
The details of this drug will be described in the first to sixth examples of the drug described later.

  Next, in step S3, the first mortar 5 is applied on the first excavation surface 1 to which the medicine has been applied (that is, on the portion of the first excavation surface 1 to which the medicine has been applied). Excavation surface 1 is covered with mortar 5 (see FIG. 2). Here, the thickness t2 of the mortar 5 is, for example, about 5 cm. In the present embodiment, the first excavation surface 1 is covered with the mortar 5 by applying the mortar 5 on the first excavation surface 1. Instead, the concrete is applied to the first excavation surface 1. The first excavation surface 1 may be covered with concrete. Also, applying the mortar 5 or concrete on the first excavation surface 1 may include spraying the mortar 5 or concrete on the first excavation surface 1.

  Next, in step S4, basic processing is performed. In this basic process, for example, construction of an audit gallery is performed. In this basic treatment process, for example, a neglect period of several months to several years may occur. When the basic processing step is completed, the process proceeds to step S5.

  In step S5, the mortar 5 is removed from the first excavation surface 1. In addition, when the 1st excavation surface 1 is covered with concrete in above-mentioned step S3, concrete is removed from the 1st excavation surface 1 in this step S5.

Next, in step S6, finish excavation is performed. In finish excavation, the cover lock C is removed and the planned excavation surface α is exposed to the outside. In other words, in step S6, the second excavation surface 2 is formed by excavating the first excavation surface 1 coated with the medicine by a predetermined thickness t1. Here, the second excavation surface 2 corresponds to the excavation plan surface α.
In finishing excavation, careful excavation by human power or breakers is performed without using explosives.
Excavation generated by finishing excavation can be used for construction of embankments and the like.

  Next, in Step S7, the second excavation surface 2 is cleaned (rock cleaning). In this process, in order to improve the adhesion between the concrete and the rock mass constituting the dam body, the second excavation surface 2 is washed with a water jet or the like to remove the deposits on the second excavation surface 2 and the like. .

When the cleaning of the second excavation surface 2 is completed, a dam dam body is constructed in step S8. In this embodiment, the concrete which comprises a dam dam body is laid in step S8. This dam body is constructed on the second excavation surface 2 and is attached to the rock.
In this way, the dam body is constructed.

  In this embodiment, the concrete dam bank is constructed in step S8. Alternatively, a fill dam bank may be constructed. In the case where the dam body of the fill dam is constructed in step S8, the soil and rocks constituting the dam body are raised in step S8.

Next, the 1st example of the chemical | medical agent in this embodiment is demonstrated.
In this example, the drug contains water as a solvent and alkali metal silicate and alkali metal siliconate. Examples of the drug in this example include a trade name “WACKER BS (registered trademark) Drysoil” (manufactured by Wacker Chemie) or a trade name “SILRES (registered trademark) 501 DRY SOIL” (supplier: Asahi Kasei Wacker Silicone Co., Ltd.) ). Hereinafter, these products are simply referred to as “DRY SOIL”.

The alkali metal silicate that can be used in this example is any alkali metal silicate, such as sodium silicate and potassium silicate. The sodium salt and potassium salt of silicic acid are also called water glass.
The alkali metal silicates that can be used in this example are SiO ₂ to alkali metal oxides, in particular Na ₂ O or K ₂ O in a weight ratio of 2.3 to 3.5, a density of 1240 to 1535 kg / m ³ and a viscosity of 5 It is advantageous to have ˜850 mPa · s (20 ° C.).
In this example, the 1st excavation surface 1 can be solidified by the silica gel formation from the silicate component in a chemical | medical agent, and the drying of the 1st excavation surface 1. FIG.

The alkali metal siliconates that can be used in this example are in particular the formula:
R _a (R ¹ O) _b (M ⁺ O ⁻ ) _c SiO _{(4-a-b-c) / 2} (I)
[Wherein R may be the same or different and each represents a monovalent SiC-bonded organic group, and R ¹ may be the same or different and represents a monovalent substituted or unsubstituted hydrocarbon group. M ⁺ may be the same or different and represents an alkali metal ion or ammonium ion, in particular Na ⁺ or K ⁺ , a is 0, 1, 2 or 3, preferably 1, b is 0 , 1, 2 or 3, preferably 1 or 2, and c is 0, 1, 2 or 3, preferably 1, wherein the sum of a, b and c is 3 or less per molecule At least one group (assuming that at least one group (M ⁺ O ⁻ ) is present).

  Examples of groups R include alkyl groups such as methyl-, ethyl-, n-propyl-, iso-propyl-, n-butyl-, iso-butyl, t-butyl-, n-pentyl, iso-pentyl-, Neo-pentyl-, t-pentyl-group, hexyl group such as n-hexyl group, heptyl group such as n-heptyl group, octyl group such as n-octyl group and iso-octyl group such as 2,2,4- Trimethylpentyl, nonyl, such as n-nonyl, decyl, such as n-decyl, dodecyl, such as n-dodecyl and octadecyl, such as n-octadecyl, cycloalkyl, such as cyclopentyl, cyclohexyl , Cycloheptyl and methylcyclohexyl groups, aryl groups such as phenyl-, naphthyl-, anthryl- and Nansuriru groups, alkaryl groups, for example o-, m-, p-tolyl group, xylyl radicals and ethylphenyl radicals and aralkyl groups such as benzyl group, include α- and β- phenylethyl.

The radical R is preferably a hydrocarbon group having 1 to 12 carbon atoms, in particular methyl, ethyl and propyl, in particular methyl.
Examples of the group R ¹ include the examples of the group R described above. Here, the radical R ¹ is preferably hydrogen, a hydrocarbon group having 1 to 6 carbon atoms, in particular a hydrogen atom, a methyl and ethyl group, in particular a hydrogen atom.

Preferred alkali metal siliconates that can be used in this example are those that are at least partially soluble in water at room temperature.
The alkali metal siliconate that can be used in this example is particularly advantageous as an aqueous solution of potassium alkyl siliconate. The potassium alkyl siliconate has a function of imparting hydrophobicity (water repellency) to the first excavation surface 1. When hydrophobicity is imparted to the first excavation surface 1, absorption of water in the rock mass is suppressed, so that long-term load resistance, stability, and freeze resistance are imparted to the rock mass. In FIG. 3, potassium methyl siliconate (potassium methyl silicate) is shown as an example of potassium alkyl siliconate.

Here, the hydrophobization of the 1st excavation surface 1 which uses potassium methyl siliconate is demonstrated using FIG.
FIG. 3 shows the reaction of potassium methylsiliconate with carbon dioxide.
When potassium methylsiliconate is applied to the first excavation surface 1, the potassium methylsiliconate reacts with carbon dioxide in the air around the first excavation surface 1, resulting in methylsilicone resin and potassium carbonate. Is generated. Thereby, the crosslinkable network by the methyl silicone resin is formed on the 1st excavation surface 1 and its inside. Hydrophobicity is imparted to the first excavation surface 1 by arranging the methyl groups constituting the crosslinkable network like umbrellas.

  In this example, alkali metal silicate and alkali metal siliconate can be used in any proportion. The weight ratio of alkali metal silicate to alkali metal siliconate is advantageously 10: 1 to 1:10, particularly 1: 1.

  In this example, among 100 liters of chemicals (that is, a total amount of water, alkali metal silicate and siliconate of 100 liters), the water content is preferably 10 to 95 liters, and the water content is 70 to 90 liters. Further preferred.

For the drug, the weight ratio of SiO ₂ to alkali metal oxide is 2.46 to 2.64 (SiO ₂ 19.7 to 20.7%), density 1240 to 1250 kg / m ³ and viscosity 20 to 20 ° C. Manufactured by mixing 15 liters of potash water glass having 40 mPa · s, 15 liters of potassium methylsiliconate of average formula: CH ₃ —Si (OH) ₂ O ^— K ⁺ as a 42% solution in water and 70 liters of water. obtain.

Or, for the drug, the weight ratio of SiO ₂ to alkali metal oxide is 2.46 to 2.64 (SiO ₂ 19.7 to 20.7%), density 1240 to 1250 kg / m ³ and viscosity at 20 ° C. 10 liters of potassium water glass having 20 to 40 mPa · s, an average formula as a 42% solution in water: 10 liters of potassium methylsiliconate of CH ₃ —Si (OH) ₂ O ^— K ⁺ and 80 liters of water are mixed. Can be manufactured.

Or, for the drug, the weight ratio of SiO ₂ to alkali metal oxide is 2.46 to 2.64 (SiO ₂ 19.7 to 20.7%), density 1240 to 1250 kg / m ³ and viscosity at 20 ° C. It can be produced by mixing 10 liters of potash water glass with 20-40 mPa · s, 5 liters of potassium methylpropyl siliconate as an approximately 40% solution in water and 75 liters of water.

Accordingly, in this example, the drug contains water as a solvent and alkali metal silicate and alkali metal siliconate. The drug may also contain a silicone having a hydrophobic group.
Moreover, in this example, the 1st excavation surface 1 to which the chemical | medical agent was apply | coated has water repellency.
About the above-mentioned "DRY SOIL", 20-30 weight% potassium methyl silicate and 70-80 weight% water and another component may be contained.

Next, the 2nd example of the chemical | medical agent in this embodiment is demonstrated.
In this example, the drug contains water as a solvent and a silane / siloxane water repellent material. This drug has one feature in that it advantageously combines a silane-based water repellent material having a property of being easily penetrated but easily volatilized, and a siloxane-based water repellent material having a property of being hardly volatilized but difficult to penetrate. is there. As a chemical | medical agent in this example, a brand name "Magical Repeller (trademark)" (supplier: Kajima Renovate Corporation) can be mentioned, for example.

The silane / siloxane-based water repellent material is an alkylalkoxysilane whose general formula is represented by “R—Si— (OR ′)” (where R is an alkyl group having 1 to 15 carbon atoms, R ′ is 1 to 1 carbon atoms). 6 represents a polyorganosiloxane represented by the general formula “R ¹ _a R ² _b R ³ _c SiO _{(4-abc) / 2} ” (where R ¹ is a methyl group) , R ² represents an aminoalkyl group, R ³ represents a hydroxyl group or an alkoxy group, and has a relationship of 0 <a + b + c <3). The weight ratio of alkylalkoxysilane to polyorganosiloxane is preferably 2: 1 to 10: 1. The silane / siloxane water repellent material may contain a small amount of a surfactant. It is preferable that the chemical | medical agent in this example contains 75 weight% or more of silane siloxane type water repellent materials.

  When the chemical | medical agent in this example is apply | coated on the 1st excavation surface 1, the water in a chemical | medical agent and the water | moisture content in a rock will react with the alkyl alkoxysilane in a chemical | medical agent, and will discharge | release alcohol, and the 1st excavation surface 1 will be carried out. It is three-dimensionally cross-linked to a silicone resin that is chemically fixed to the resin to form an impregnated coating film (silicone coating film) having water repellency.

Accordingly, in this example, the drug contains water as a solvent and a silane / siloxane water repellent material. The silane / siloxane water-repellent material contains alkylalkoxysilane and polyorganosiloxane. The drug may also contain a silicone having a hydrophobic group.
Moreover, in this example, the 1st excavation surface 1 to which the chemical | medical agent was apply | coated has water repellency.
The aforementioned “Magical Repeller®” is composed of a silicone emulsion and may contain 75-85 wt.% Organosilane silicone, 15-25 wt.% Water and other components.

Next, the 3rd example of the chemical | medical agent in this embodiment is demonstrated.
In this example, the drug is composed of a silicone emulsion containing water as a solvent and octyltriethoxysilane. As a chemical | medical agent in this example, brand name "SILRES BS 45" (supplier: Asahi Kasei Wacker Silicone Co., Ltd.) can be mentioned, for example.
In this example, the drug may contain a silicone having a hydrophobic group. The agent can also contain a surfactant.
Moreover, in this example, the 1st excavation surface 1 to which the chemical | medical agent was apply | coated has water repellency.
The aforementioned “SILRES BS 45” may contain 3 to 5% by weight of octyltriethoxysilane and 95 to 97% by weight of silicone, water and other components.

Next, the 4th example of the medicine in this embodiment is explained.
In this example, the drug is composed of a silicone emulsion containing water as a solvent, silicone having a hydrophobic group, and silica. As a chemical | medical agent in this example, brand name "POWERSIL 570 PLUS" (supplier: Asahi Kasei Wacker Silicone Co., Ltd.) can be mentioned, for example.
In this example, the 1st excavation surface 1 to which the chemical | medical agent was apply | coated has water repellency.
The aforementioned “POWERSIL 570 PLUS” may contain 35 to 45% by weight of water, 5 to 15% by weight of silica, 45 to 55% by weight of silicone and other components.

Next, the 5th example of the medicine in this embodiment is explained.
In this example, the drug is composed of a silicone emulsion containing water as a solvent, silicone having a hydrophobic group, and poly (oxyethylene) = sodium dodecyl ether sulfate. As a chemical | medical agent in this example, brand name "P2003" (supplier: Asahi Kasei Wacker Silicone Co., Ltd.) can be mentioned, for example.
In this example, the drug may contain a surfactant.
Moreover, in this example, the 1st excavation surface 1 to which the chemical | medical agent was apply | coated has water repellency.
As for the aforementioned “P 2003”, 40 to 50% by weight of water, 1 to 6% by weight of poly (oxyethylene) = sodium dodecyl ether sulfate ester, 45 to 50% by weight of silicone, surfactant and others And ingredients.

Next, a sixth example of the medicine in this embodiment will be described.
In this example, the drug is composed of a silicone emulsion containing water as a solvent, silicone having a hydrophobic group, and polyoxyethylene alkyl ether (alkyl group having 12 to 15 carbon atoms). . As a chemical | medical agent in this example, brand name "SILICONE FLUID EMULSION C 800" (supplier: Asahi Kasei Wacker Silicone Co., Ltd.) can be mentioned, for example.
In this example, the drug may contain a surfactant.
Moreover, in this example, the 1st excavation surface 1 to which the chemical | medical agent was apply | coated has water repellency.
Regarding the above-mentioned “SILICONE FLUID EMULSION C 800”, 15 to 25% by weight of water, 3 to 8% by weight of polyoxyethylene alkyl ether (the alkyl group having 12 to 15 carbon atoms), 70 to 80 % By weight of silicone and other ingredients.

Next, the effect when the first to sixth examples of the above-described chemicals are applied on the first excavation surface 1 (rock surface) will be described with reference to FIG. 4 in addition to FIG.
FIG. 4 shows the results of confirming the effect of reducing the adhesion performance of the mortar 5 to the first excavation surface 1 with respect to the first to sixth examples of the above-described drug.

  In this confirmation, two types of tests were performed: (1) impact test and (2) mortar suspension test. In these two tests, “No. 0” shown in FIG. 4 refers to the case where the mortar 5 is directly applied on the first excavation surface 1 without applying the drug on the first excavation surface 1. Show. “No. 1” shown in FIG. 4 refers to the first excavation where the drug is applied after the stock solution of “DRY SOIL” corresponding to the first example of the drug is applied on the first excavation surface 1. The case where the mortar 5 is apply | coated on the surface 1 is shown. “No. 2” shown in FIG. 4 means that after the stock solution of “Magical Repeller (registered trademark)” corresponding to the second example of the above-described drug is applied on the first excavation surface 1, the drug is applied. The case where the mortar 5 is applied on the first excavation surface 1 is shown. “No. 3” shown in FIG. 4 means that the first solution on which the drug is applied after the stock solution of “SILRES BS 45” corresponding to the third example of the drug is applied on the first excavation surface 1. The case where the mortar 5 is apply | coated on the excavation surface 1 is shown. “No. 4” shown in FIG. 4 means that the first solution to which the drug is applied after the stock solution of “POWERSIL 570 PLUS” corresponding to the above-described fourth example of the drug is applied on the first excavation surface 1. The case where the mortar 5 is apply | coated on the excavation surface 1 is shown. “No. 5” shown in FIG. 4 refers to the first excavation in which a stock solution of “P 2003” corresponding to the fifth example of the above-described medicine is applied on the first excavation surface 1 and then the medicine is applied. The case where the mortar 5 is apply | coated on the surface 1 is shown. “No. 6” shown in FIG. 4 means that after the stock solution of “SILICONE FLUID EMULSION C 800” corresponding to the above-described sixth example of the drug is applied on the first excavation surface 1, The case where the mortar 5 is apply | coated on 1 excavation surface 1 is shown. Here, in these two tests, the application thickness of the mortar 5 was about 1 cm, and the curing period after the application of the mortar 5 was about one week. As the mortar 5, a commercially available premix early strong mortar was used.

(1) Blow test In the blow test, a 1.5 kg weight is dropped 100 times from a height of 20 cm to each of the aforementioned “number 0” to “number 6”, and the mortar 5 is the first excavation. It was confirmed whether or not the surface 1 was peeled off. The result of this test is shown in FIG. 4, and in all of “No. 0” to “No. 6”, the mortar 5 did not peel from the first excavation surface 1.

(2) Mortar suspended test In the mortar suspended test, the mortar 5 adhered on the first excavation surface 1 was suspended using a chisel for each of the aforementioned "number 0" to "number 6". It was. The results of this test are shown in FIG.
Regarding “No. 0”, the mortar 5 was firmly attached to the first excavation surface 1, so the first excavation surface 1 was broken in the middle of holding the mortar 5. That is, with “No. 0”, it was very difficult to separate the mortar 5 from the first excavation surface 1.

  As for “No. 1”, since the adhesion force of the mortar 5 to the first excavation surface 1 is greatly reduced as compared with “No. 0”, the mortar 5 was able to be attached very easily ( That is, the mortar 5 could be separated very easily). Moreover, about the location which put the mortar 5 among the 1st excavation surfaces 1, most of the chemical | medical agent (DRY SOIL) applied to the location had adhered to the isolate | separated mortar 5. FIG. Therefore, by using the first example of the above-described drug, in the above-described step S5 (see FIG. 1), the drug can be removed from the first excavation surface 1 together with the mortar 5 while the drug is attached to the mortar 5. .

  Regarding “No. 2”, since the adhesion force of the mortar 5 to the first excavation surface 1 is reduced as compared with “No. 0”, the mortar 5 can be easily attached (that is, the mortar 5). Could be easily separated). In addition, in the portion where the mortar 5 is held in the first excavation surface 1, most of the medicine (Magical Repeller (registered trademark)) applied to the portion remains on the first excavation surface 1. It was.

  With respect to “No. 3”, since the adhesion force of the mortar 5 to the first excavation surface 1 is reduced as compared with “No. 0”, the mortar 5 can be easily attached (that is, the mortar 5 Could be easily separated). Moreover, about the location which stuck the mortar 5 among the 1st excavation surfaces 1, most of the chemical | medical agent (SILRES BS 45) applied to the location had adhered to the isolate | separated mortar 5. FIG. Therefore, by using the third example of the above-described medicine, in the above-described step S5 (see FIG. 1), the medicine can be removed from the first excavation surface 1 together with the mortar 5 while the medicine is attached to the mortar 5. .

  As for “No. 4”, since the adhesion force of the mortar 5 to the first excavation surface 1 is reduced as compared with “No. 0”, the mortar 5 can be easily attached (that is, the mortar 5). Could be easily separated). Further, in the portion where the mortar 5 was put on the first excavation surface 1, most of the medicine (POWERSIL 570 PLUS) applied to the portion remained on the first excavation surface 1.

  As for “No. 5”, the adhesion force of the mortar 5 to the first excavation surface 1 is greatly reduced as compared to “No. 0”, so that the mortar 5 can be very easily attached ( That is, the mortar 5 could be separated very easily). Moreover, about the location which stuck the mortar 5 among the 1st excavation surfaces 1, most of the chemical | medical agents (P2003) applied to the location had adhered to the isolate | separated mortar 5. FIG. Therefore, by using the fifth example of the above-described medicine, in the above-described step S5 (see FIG. 1), the medicine can be removed from the first excavation surface 1 together with the mortar 5 while the medicine is attached to the mortar 5. .

  As for “No. 6”, the adhesion force of the mortar 5 to the first excavation surface 1 is greatly reduced as compared with “No. 0”, so that the mortar 5 could be very easily attached ( That is, the mortar 5 could be separated very easily). In addition, in the portion where the mortar 5 was put on the first excavation surface 1, most of the medicine (SILICONE FLUID EMULSION C 800) applied to the portion was attached to the separated mortar 5. . Therefore, by using the sixth example of the above-described medicine, in the above-described step S5 (see FIG. 1), the medicine can be removed from the first excavation surface 1 together with the mortar 5 while the medicine is attached to the mortar 6. .

Therefore, the first excavation surface 1 (rock surface) of the mortar 5 is obtained with respect to the first to sixth examples of the above-mentioned chemicals by performing the above-mentioned (1) impact test and (2) the mortar suspension test. It was possible to confirm the effect of reducing the adhesion performance to
In addition, about the 1st-6th example of the above-mentioned chemical | medical agent, it replaces with the mortar 5, and even if it is a case where concrete covers the 1st excavation surface 1, the above-mentioned adhesion performance reduction effect similar to the mortar 5 is shown. The present inventors were able to confirm that this was exhibited. The confirmation result is the same as that of FIG.

  According to this embodiment, as a method for constructing a dam dam body (structure), a step of applying a chemical to the first excavation surface 1 (rock surface) exposed to the outside (step S2), and a chemical is applied The step of further applying mortar 5 or concrete on the first excavation surface 1 (step S3), the step of removing the mortar 5 or concrete from the first excavation surface 1 (step S5), and the removal of the mortar 5 or concrete. A step of forming the second excavation surface 2 by excavating the first excavation surface 1 for a predetermined thickness t1 (step S6), and a step of constructing a dam dam body on the second excavation surface 2 ( Step S8). A chemical | medical agent reduces the adhesive force to the 1st excavation surface 1 of mortar 5 or concrete (refer the 1st example-the 6th example of the above-mentioned chemical | medical agent). By applying this chemical, the adhesion force of the mortar 5 or concrete covering the first excavation surface 1 for protecting the first excavation surface 1 to the first excavation surface 1 is reduced. When removing mortar 5 or concrete from 1, the mortar 5 or concrete can be easily peeled off from the first excavation surface 1, and as a result, the work for removing the mortar 5 or concrete from the first excavation surface 1 The load can be reduced. In addition, it is possible to prevent unnecessary loosening from occurring in the bedrock deeper than the first excavation surface 1.

  Moreover, according to this embodiment, the 1st excavation surface 1 (rock surface) to which the chemical | medical agent was apply | coated has water repellency (refer the 1st example-the 6th example of the above-mentioned chemical | medical agent). Since the portion having water repellency is interposed between the mortar 5 or concrete and the first excavation surface 1, the adhesion force of the mortar 5 or concrete to the first excavation surface 1 is reduced.

Moreover, according to this embodiment, a chemical | medical agent contains the silicone which has a hydrophobic group (refer the 1st example-the 6th example of the above-mentioned chemical | medical agent). Thereby, the 1st excavation surface 1 (rock surface) to which the chemical | medical agent was apply | coated can have water repellency.
Moreover, according to this embodiment, a chemical | medical agent contains an alkali metal siliconate (refer the 1st example of the above-mentioned chemical | medical agent). Thereby, the 1st excavation surface 1 (rock surface) to which the chemical | medical agent was apply | coated can have water repellency.

Moreover, according to this embodiment, in the process (step S5) which removes the mortar 5 or concrete from the 1st excavation surface 1 (rock surface), a chemical | medical agent is the mortar 5 or a state in which the chemical | medical agent adhered to the mortar 5 or concrete. It is removed from the first excavation surface 1 together with the concrete (see the first example, the third example, the fifth example and the sixth example of the above-mentioned chemicals). Thereby, the excavation gap which does not contain a chemical | medical agent which generate | occur | produces in finish excavation can be utilized for construction of embankment etc.
Moreover, according to this embodiment, the 1st excavation surface 1 (rock surface) is an excavation surface formed by excavating the ground (step S1). By applying a chemical to the excavated surface, water repellency can be imparted to the surface of the cover lock C.

According to this embodiment, the dam body (structure) is made of concrete. Thereby, the concrete and bedrock which comprise a dam dam body can be stuck watertight.
Moreover, according to this embodiment, the structure constructed | assembled by the flowchart shown in FIG. 1 is a hydraulic structure (dam dam body). Accordingly, the rock can stably support the hydraulic structure in a state where the hydraulic structure and the rock are in close contact with each other.
Moreover, according to this embodiment, the hydraulic structure constructed | assembled with the flowchart shown in FIG. 1 is a dam dam body. Accordingly, the rock mass can stably support the dam embankment in a state in which the dam embankment and the rock mass are in close contact with each other.

  Moreover, according to this embodiment, as a rock-protecting method, the process (step S2) which apply | coats a chemical | medical agent to the 1st excavation surface 1 (rock surface) exposed outside, and the 1st excavation surface where the chemical | medical agent was apply | coated And a step of further applying mortar 5 or concrete (step S3). The chemical reduces the adhesion of the mortar 5 or concrete to the first excavation surface 1. By applying this chemical, the adhesion force of the mortar 5 or concrete covering the first excavation surface 1 for protecting the first excavation surface 1 to the first excavation surface 1 is reduced. When removing mortar 5 or concrete from 1, the mortar 5 or concrete can be easily peeled off from the first excavation surface 1, and as a result, the work for removing the mortar 5 or concrete from the first excavation surface 1 The load can be reduced.

  Further, according to the present embodiment, when the mortar 5 or concrete is removed from the first excavation surface 1 (rock surface) (step S5), the chemical is attached to the mortar 5 or concrete, and the chemical is mortar 5 or It is removed from the first excavation surface 1 together with the concrete (see the first example, the third example, the fifth example and the sixth example of the above-mentioned chemicals). Thereby, the excavation gap which does not contain a chemical | medical agent which generate | occur | produces in finish excavation can be utilized for construction of embankment etc.

FIG. 5 is a flowchart showing a method for constructing a dam body in the second embodiment of the present invention. FIG. 6 is a diagram illustrating the excavation plan surface, the first excavation surface, and the mortar.
A different point from 1st Embodiment shown in FIGS. 1-4 is demonstrated.

In the present embodiment, the dam dam body is described below as being a dam body of a fill dam, but the configuration of the dam dam body is not limited thereto.
In step S11 shown in FIG. 5, the ground is excavated. By this excavation, the first excavation surface 1 ′ (see FIG. 6), which is the rock surface (surface of the foundation ground), is exposed to the outside. That is, the first excavation surface 1 ′ is formed by excavating the ground. Here, the first excavation surface 1 ′ corresponds to the excavation plan surface α.

Next, in step S2, a chemical | medical agent is apply | coated to 1st excavation surface 1 '. About this chemical | medical agent, since it is the same as that of the above-mentioned 1st Embodiment, the description is abbreviate | omitted.
Next, in step S3, the mortar 5 is applied on the first excavation surface 1 'to which the medicine has been applied (that is, on the portion of the first excavation surface 1' to which the medicine has been applied), thereby 1 excavation surface 1 ′ is covered with mortar 5 (see FIG. 6). Since the application of the mortar 5 is the same as that in the first embodiment, the description thereof is omitted. In the present embodiment, the first excavation surface 1 ′ is covered with the mortar 5 by applying the mortar 5 on the first excavation surface 1 ′, but instead, the first excavation surface 1 ′. The first excavation surface 1 ′ may be covered with concrete by applying concrete thereon.

Next, in step S4, basic processing is performed in the same manner as in the first embodiment. When the basic processing step is completed, the process proceeds to step S5, and the mortar 5 is removed from the first excavation surface 1 ′ as in the first embodiment. In addition, when 1st excavation surface 1 'is covered with concrete in above-mentioned step S3, concrete is removed from 1st excavation surface 1' in this step S5.
If the removal of the mortar 5 is completed, it will progress to step S12 and will clean the 1st excavation surface 1 '(rock mass cleaning). In this step, the first excavation surface 1 ′ is washed with a water jet or the like to remove deposits or the like on the first excavation surface 1 ′.

When the cleaning of the first excavation surface 1 ′ is completed, a dam dam body is constructed in step S13. In the present embodiment, soil and rocks constituting the dam dam body are raised in step S13. The dam body is constructed on the first excavation surface 1 ′.
In this way, the dam body is constructed.

  In this embodiment, the dam body of the fill dam is constructed in step S13, but a dam body of a concrete dam may be constructed instead. When the concrete dam body is constructed in step S13, the concrete constituting the dam body is placed in step S13.

  In particular, according to this embodiment, as a method for constructing a dam dam body (structure), a step of applying a chemical to the first excavation surface 1 ′ (rock surface) exposed to the outside (step S2), and a chemical coating A step of further applying mortar 5 or concrete on the first excavation surface 1 '(step S3), a step of removing the mortar 5 or concrete from the first excavation surface 1' (step S5), and a mortar 5 Or a step of constructing a dam dam body on the first excavation surface 1 ′ from which the concrete has been removed (step S13). The chemical reduces the adhesion of the mortar 5 or concrete to the first excavation surface 1 '. By applying this chemical, the adhesion force of the mortar 5 or concrete covering the first excavation surface 1 ′ for protecting the first excavation surface 1 ′ to the first excavation surface 1 ′ is reduced. When removing the mortar 5 or concrete from the excavation surface 1 ′, the mortar 5 or concrete can be easily peeled off from the first excavation surface 1 ′, and thus the mortar 5 or concrete is removed from the first excavation surface 1 ′. It is possible to reduce the workload when removing from the work. In addition, it is possible to prevent unnecessary loosening from occurring in the bedrock deeper than the first excavation surface 1 '.

  Moreover, according to this embodiment, the 1st excavation surface 1 '(rock surface) to which the chemical | medical agent was apply | coated has water repellency (refer the 1st example-the 6th example of the above-mentioned chemical | medical agent). Since the portion having water repellency is interposed between the mortar 5 or concrete and the first excavation surface 1 ′, the adhesion force of the mortar 5 or concrete to the first excavation surface 1 ′ is reduced.

According to the present embodiment, in the step of removing the mortar 5 or concrete from the first excavation surface 1 ′ (rock surface) (step S <b> 5), the chemical is attached to the mortar 5 or concrete and the chemical is mortar 5. Or it removes from 1st excavation surface 1 'with concrete (refer the 1st example of the above-mentioned medicine, the 3rd example, the 5th example, and the 6th example). Thereby, the chemical | medical agent apply | coated to 1st excavation surface 1 'can be efficiently removed with the mortar 5 or concrete.
Moreover, according to this embodiment, 1st excavation surface 1 '(rock surface) is an excavation surface formed by excavating the ground (step S11). By applying a chemical | medical agent to this excavation surface, water repellency can be provided to the excavation plan surface (alpha).

  Further, according to the present embodiment, as a rock protection method, a step of applying a chemical to the first excavation surface 1 ′ (rock surface) exposed to the outside (step S2), and a first excavation coated with the chemical A step of further applying mortar 5 or concrete on the surface 1 '(step S3). The chemical reduces the adhesion of the mortar 5 or concrete to the first excavation surface 1 '. By applying this chemical, the adhesion force of the mortar 5 or concrete covering the first excavation surface 1 ′ for protecting the first excavation surface 1 ′ to the first excavation surface 1 ′ is reduced. When removing the mortar 5 or concrete from the excavation surface 1 ′, the mortar 5 or concrete can be easily peeled off from the first excavation surface 1 ′, and thus the mortar 5 or concrete is removed from the first excavation surface 1 ′. It is possible to reduce the workload when removing from the work.

  Further, according to the present embodiment, when the mortar 5 or concrete is removed from the first excavation surface 1 ′ (rock surface) (step S5), the chemical is attached to the mortar 5 or concrete, and the chemical is in the mortar 5. Or it removes from 1st excavation surface 1 'with concrete (refer the 1st example of the above-mentioned medicine, the 3rd example, the 5th example, and the 6th example). Thereby, the chemical | medical agent apply | coated to 1st excavation surface 1 'can be efficiently removed with the mortar 5 or concrete.

  In the first and second embodiments described above, water repellency can be imparted to the surfaces of the first excavation surfaces 1, 1 ′ by using the first to sixth examples of the drug. Therefore, the raindrops on the first excavation surface 1, 1 ′ cooperate with the chemical applied on the first excavation surface 1, 1 ′ and the mortar 5 or concrete further applied thereon. Therefore, the thickness t2 of the mortar 5 or concrete covering the first excavation surface 1 or 1 ′ (in other words, the amount of mortar 5 or concrete used) is reduced as compared with the conventional case. can do.

  In the first and second embodiments described above, the silicone-based chemical is used as the chemical that reduces the adhesion force of the mortar 5 or the concrete to the first excavation surfaces 1, 1 ′. For example, it may be a resin-based drug.

  In the first and second embodiments described above, the dam dam body construction method has been described as an example of the hydraulic structure construction method according to the present invention. However, the hydraulic structure according to the present invention is the dam dam body construction method. It is not limited to the bank. For example, the hydraulic structure may be the body of a sluice constructed on a rock surface. Moreover, the structure to which the construction method according to the present invention is applied is not limited to the hydraulic structure described above, and may be a structure such as a nuclear power plant or a pier foundation.

  In the first and second embodiments described above, the rock protection method according to the present invention has been described by taking the method of protecting the rock as the foundation ground of the dam dam body as an example. The bedrock to which the protection method can be applied is not limited to this. In order to prevent the excavation surface from being exposed to the outside for a long period of time, the excavation surface is temporarily treated, and for protection of all rocks such that a structure is built on the excavation surface after the lapse of the period, The rock protection method according to the present invention can be applied. For example, the rock protection method according to the present invention can be applied to the protection of rocks that are to support structures such as nuclear power plants and pier foundations.

  The illustrated embodiments are merely examples of the present invention, and the present invention is not limited to those directly described by the described embodiments, and various improvements and modifications made by those skilled in the art within the scope of the claims. Needless to say, it encompasses changes.

1, 1 'first excavation surface 2 second excavation surface 5 mortar C cover lock α excavation plan surface

Claims (12)

Applying a chemical to the rock surface exposed to the outside;
A step of further applying mortar or concrete on the rock surface to which the drug is applied;
Removing the mortar or the concrete from the rock surface;
A step of excavating the rock surface from which the mortar or the concrete has been removed by a predetermined thickness to form an excavation surface;
Building a structure on the excavation surface;
Including
The agent reduces the adhesive force of the mortar or the concrete to the rock surface ,
The method for constructing a structure, wherein the rock surface to which the drug is applied has water repellency . Applying a chemical to the rock surface exposed to the outside;
A step of further applying mortar or concrete on the rock surface to which the drug is applied;
Removing the mortar or the concrete from the rock surface;
Building a structure on the rock surface from which the mortar or the concrete has been removed;
Including
The agent reduces the adhesive force of the mortar or the concrete to the rock surface ,
The method for constructing a structure, wherein the rock surface to which the drug is applied has water repellency . The method for constructing a structure according to claim 1, wherein the drug contains silicone having a hydrophobic group. The said chemical | medical agent contains the alkali metal siliconate, The construction | assembly method of the structure of any one of Claims 1-3 . In the step of removing the mortar or the concrete from the rock surface, the agent is removed from the rock surface together with the mortar or the concrete in a state where the agent adheres to the mortar or the concrete. The method for constructing a structure according to claim 4 . The method for constructing a structure according to any one of claims 1 to 5 , wherein the rock surface is an excavation surface formed by excavating the ground. The method for constructing a structure according to any one of claims 1 to 6 , wherein the structure is made of concrete. Applying a chemical to the rock surface exposed to the outside;
A step of further applying mortar or concrete on the rock surface to which the drug is applied;
Including
The agent reduces the adhesive force of the mortar or the concrete to the rock surface ,
A method for protecting a rock mass, wherein the rock surface to which the chemical is applied has water repellency . The rock protection method according to claim 8 , wherein the drug contains silicone having a hydrophobic group. The method for protecting rock according to claim 8 or 9 , wherein the agent contains an alkali metal siliconate. Wherein the mortar or the concrete when removed from the rock face, in a state in which the drug is adhered to the mortar or the concrete, the agent is removed from the rock face with the mortar or the concrete, according to claim 8 The rock protection method according to claim 10 . The rock surface protection method according to any one of claims 8 to 11 , wherein the rock surface is an excavation surface formed by excavating the ground.