JPH09100524A - Development method of fill dam - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make it possible to use effectively a soil material as a core material even if the soil material involves some problems as for impervious performance and rigidity and develop a fill dam which is excellent in the impervious properties and stability of a dam bank. SOLUTION: The top of a base rock F of a scheduled development area of a fill dam is graded. On this base rock G, there is developed a dam bank D, whose height is H having a specified gradient slope surface on the upstream and downward sides comprising a core zone 1, a filter zone 2 outside and a rock zone 3 outside. After the development, when the deformation, which includes compression settlement of the dam bank D comes to substantially an end, the area from the top of the core zone 1 to the base rock G is excavated. A proper amount of cement is injected to the earth material thus excavated and mixed, thereby forming a soil cement-made impervious wall 4 which extends in the direction of the axis of the dam and whose lower end 4a is encroached in the base rock G inside the core zone 1.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is in the field of dam construction technology, and more particularly to a fill dam constructed by raising soil material, gravel or rock mass.

[0002]

2. Description of the Related Art Fill dams include a rock fill dam having a relatively large construction scale and a uniform fill dam having a relatively small construction scale. Of these, the former rock-fill dam basically has a core zone 1 for ensuring water-tightness of the dam, and a filter zone 2 formed on the upstream side and the downstream side of the core zone 1, as shown in FIG. , And the lock zone 3 formed on the upstream side and the downstream side thereof. In the core zone 1 which is required to have excellent water impermeability, a soil material such as cohesive soil having low water permeability is used as a core material,
A homogeneous filter material such as sand is used in the filter zone 2 which is interposed between the core zone 1 and the lock zone 3 to mitigate abrupt changes in particle size and rigidity and to prevent the core material from flowing out. A gravel or rock mass having a large strength and rigidity is used in the lock zone 3 located outside of the rock zone 3 for stabilizing the dam body. Further, in the latter uniform type fill dam, a dam bank body is constructed by raising a single soil material such as cohesive soil having low water permeability used in the core zone 1.

[0003]

Among the above-mentioned conventional fill dams, the rock fill dam having a large construction scale has different zones 1 to 1 due to the difference in rigidity between the core material to be piled up, the filter material, and the gravel or rock mass. 3. There is a difference in settlement and deformation characteristics. That is, in general, the riser material has higher rigidity as the water permeability is higher, and therefore, the rock zone 3 composed of gravel or rock mass having high water permeability hardly causes subsidence or deformation. In the core zone 1 in which soil material such as soil is raised, subsidence or deformation due to consolidation is likely to occur. Therefore, steps and cracks due to the discontinuity of deformation occur at the boundaries between the zones 1 to 3, and this tendency is particularly remarkable around the core zone 1. If such a step or a crack is generated, there is a problem that the resistance of the dam bank body against the stored water pressure is lowered, or water leakage easily occurs.

Further, in a small-scale uniform type fill dam, a single soil material provides the water blocking performance and the stability of the dam levee body. However, for the above-mentioned reason, the soil material having the excellent water blocking performance is provided. When using, the rigidity of the dam dam body decreases, and when using a material with high rigidity, the water impermeability tends to decrease. Therefore, in reality, it is unavoidable to use a soil material having a problem in both the water impermeability and the rigidity. In order to sufficiently satisfy the water impermeability and stability with such materials, the water permeability should be increased (the width of the dam embankment should be large) and the slope of the dam embankment slope should be adjusted according to the strength of the soil material. There is a problem that the volume of the dam body is large relative to the scale of the dam, that is, a large amount of soil material is required, which is uneconomical.

When cohesive soil with low water permeability is used to build up core material in rock fill dams and dam levee bodies in uniform fill dams, it is necessary to adjust particle size and water content to satisfy the soil characteristics. There was a need to secure a large site for a stockyard for that work.

The present invention has been made under the above circumstances, and its technical problem is that even a soil material having a problem of water impermeability and rigidity has a core material or a uniform type in a rock fill dam. It is intended to be able to effectively construct a fill dam that can be effectively used as an embankment material for dam dam bodies in fill dams and that has excellent water impermeability and stability.

[0007]

The above-mentioned technical problems are as follows.
This can be effectively solved by the present invention. That is, in the method of constructing a fill dam according to the present invention, in the case of a rock fill dam consisting of a plurality of zones in which the dam dam body has an appropriately water-blocking soil material as a core zone, a dam dam body consisting of the plurality of zones is formed on a base. After heaping up, from the top of the core zone to the upper surface of the base, the impermeable wall made of soil cement solidified by adding cement and water to the soil material of the core zone and consolidating it was continuously along the dam axis. To form.

The same applies to the case where the dam bank is a uniform type fill dam made of a single soil material having an appropriate water blocking property, that is, after the dam bank is made of a single soil material. , From the top of the dam levee to the upper surface of the foundation, a water impermeable wall made of soil cement solidified by adding cement and water to the soil material and mixing is formed continuously along the dam axis. is there.

The impermeable wall made of soil cement continuously formed along the dam axis inside the dam bank is a solidified body in which soil particles of a soil material are bonded via cement. Since the water permeability is significantly reduced (improved in water impermeability) compared to the soil material before addition, the core zone of the rock dam dam dam body or the dam dam of the uniform fill dam has a certain degree of water permeability. However, the passage of water is completely blocked by the impermeable wall, and the problem of water leakage does not occur. Therefore, a soil material having water permeability can be used, and generally, a soil material having high water permeability has a large rigidity, and therefore, by using such a soil material, long-term settlement or deformation of the core zone or dam dam body can be effectively performed. Can be prevented. Therefore, a stable fill dam is constructed without using a large amount of soil material.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION Preferred embodiments in which the method for forming a fill dam according to the present invention is applied to the formation of a rock fill dam will be described below in the order of steps with reference to FIGS.

First, as shown in FIG. 1, the foundation ground or bedrock G (hereinafter simply referred to as the foundation G) of the site where the fill dam is planned to be constructed.
Groove a for leveling the upper surface of the core zone and for preventing water from easily passing through the boundary between the lower end of the core zone and the base G in correspondence with the lower end position of the core zone described later.
Are formed in the direction of the dam axis (direction orthogonal to the cross section shown in the drawing).

Next, as shown in FIG. 2, a core zone 1 ₁ corresponding to the position of the groove a of the base G, a filter zone 2 ₁ on the outer side (upstream side and downstream side) thereof, and Appropriate layer thickness ΔH consisting of the outer lock zone 3 ₁
The first layer, D ₁ , is layered. The core material to make serving the core zone 1 _1, but soil material somewhat smaller water permeability is selected, need not be small enough cohesive soil water permeability used in the conventional fill dam. Further, sand is used in the filter zone 2 ₁ as in the conventional case, and gravel or rock masses having high strength and rigidity are used in the lock zone 3 ₁ .

After the formation of the _first rise layer D ₁ , as shown in FIG. 3, a core zone 1 ₂ continuous above the _first core zone 1 ₁ is formed by the same steps as described above.
A second layer layer having a layer thickness ΔH composed of a filter zone 2 ₂ continuous above the first layer filter zone 2 ₁ and a lock zone 3 ₂ continuous above the first layer lock zone 3 _1. Raise the standing layer D ₂ . By repeating such a process n times to build up to the _n-th build-up layer D _n , the height H (= n · ΔH) having slopes with a predetermined gradient on the upstream side and the downstream side is obtained. Create dam dam body D.

When the deformation including the consolidation settlement of the dam dam body D thus constructed is almost completed, the vertical shaft 1a is reached inside the core zone 1 of the dam dam body D from its top to the foundation G by using the excavating machine M. Is continuously excavated in a direction (direction of the dam axis) orthogonal to the cross section shown in the drawing, and the admixture is poured into the vertical shaft 1a while mixing an appropriate amount of cement and water with the excavated core material. The added and mixed cement is
The core material hardens with time due to a hydration reaction with the water in the soil material or with the injected water to consolidate the soil particles. As a result, as shown in FIG. 5, an impermeable wall 4 made of soil cement having a predetermined thickness is formed inside the core zone 1 and extending along the direction of the dam axis, and the lower end 4a bites into the base G. .

According to the central core type rockfill dam constructed by the above-mentioned method, the water W stored in the upstream side of the dam body D is the gap between the gravel or rock mass forming the rock zone 3 on the upstream side. Through the gap between the sand particles forming the inner filter zone 2 and the gap between the soil particles forming the inner core zone 1 and the soil material to reach the upstream surface of the impermeable wall 4 made of soil cement. However, it cannot pass through the impermeable wall 4 to the downstream side of the dam bank D. Further, since the lower end portion 4a of the impermeable wall 4 cuts off the boundary between the core zone 1 and the base G and penetrates into the base G from the bottom of the groove a, it does not flow to the downstream side through the boundary.

In the above embodiment, the impermeable wall 4 is formed in the core zone 1 after the subsidence / deformation of the dam dam D that has been formed is completed. If the rigidity of soil cement is made to be about the same as the surrounding core material by adjusting the mixing ratio of cement, this impermeable wall 4 can be deformed following the subsidence / deformation of dam dam body D, thus causing cracks. It is possible to maintain the water impermeability.
Therefore, in this case, the impermeable wall 4 may be formed before the settlement / deformation of the dam levee D converges, and the construction period can be shortened.

In order to obtain a more reliable water-blocking effect, FIG.
As shown in (2), it is effective to form a plurality of water shield walls 4 made of soil cement (two layers in the illustrated example) in the core zone 1. A core material layer 1 ′ having an appropriate thickness made of a core material is interposed between each water shield wall 4.

When the impermeable wall 4 made of soil cement is formed in the core zone 1, as shown in FIG.
If necessary, a reinforcing member 5 made of H-shaped steel or sheet pile, the lower end 5a of which reaches the inside of the base G, may be driven into the inner portion of the base material at appropriate intervals. As a result, the strength of the impermeable wall 4 against the horizontal deformation force due to water pressure or the like can be improved.

The forming method according to the present invention can be similarly applied to the formation of a uniform type fill dam. That is, first, as shown in FIG. 1, the upper surface of the base G of the fill dam construction site is leveled to form a groove a, and then a predetermined centering on the groove a is formed on the base G as shown in FIG. In the region of, the first embankment layer D ′ ₁ having a layer thickness ΔH is embossed by using an embankment material composed of the same soil material as the above-mentioned core zone 1, and the same steps are repeated on it. 'by standing prime to _m, the height H of the upstream and downstream with a slope of a predetermined gradient' prime fresh layer D of the m-th layer to construct a dam D 'of (= m · ΔH). Then, when the deformation including the consolidation settlement of the dam levee D'is almost converged, from the top of the dam, in the same manner as the above-mentioned process,
The lower end 4a forms the water-impervious wall 4 made of soil cement having a predetermined thickness and biting into the base G.

Also in the case of this uniform type fill dam, as in FIG. 6, a plurality of impermeable walls 4 are formed, or in the same manner as in FIG.
An embodiment in which it is reinforced with H-section steel or sheet pile 5 can be adopted.

[0021]

According to the fill dam construction method of the present invention, the following effects are realized. (1) Since a soil material with insufficient water impermeability can be used as the core material of the rock fill dam or the embankment material of the dam levee body of the uniform fill dam, the soil material can be easily procured. (2) Soil materials with insufficient water impermeability (high water permeability)
Generally, since the rigidity and strength are large, it becomes possible to use such a soil material, so that a fill dam having a small amount of deformation and excellent stability can be formed. (3) Impermeable walls made of soil cement are easy to construct because they are formed by adding cement to the core material of rock fill dams or the embankment material of dam dam bodies in uniform fill dams. (4) Impermeable walls made of soil cement have a higher water impermeability than the core material of rock fill dams or the embankment material of dam dam bodies of uniform fill dams, so the width of the core zone and the uniform fill dam can be reduced. Alternatively, the core zone can be eliminated. (5) It can be constructed even when a large amount of cohesive soil for the core material or dam embankment material cannot be secured. (6) When a core material made of cohesive soil is used, it is not necessary to have a large work site for stockyards, which was conventionally required to adjust the soil quality.

[Brief description of the drawings]

FIG. 1 shows a method for forming a fill dam according to the present invention,
It is explanatory drawing which shows the process of leveling the upper surface of the foundation of a fill dam construction planned site.

FIG. 2 is a view showing a method of forming a fill dam according to the present invention,
It is explanatory drawing which shows the process which raises the raising layer of the 1st layer on a base.

FIG. 3 is a view showing a method for forming a fill dam according to the present invention,
It is explanatory drawing which shows the state which completed the formation of the dam bank body of a rock fill dam by raising up to the n-th layer raising layer.

FIG. 4 is a view showing a method for forming a fill dam according to the present invention,
It is explanatory drawing which shows the process of forming the impermeable wall which consists of soil cement inside a core zone.

FIG. 5 is an explanatory view showing a rock fill dam in which a water impermeable wall made of soil cement is formed inside the core zone by the fill dam construction method according to the present invention.

FIG. 6 is an explanatory view showing a rock fill dam in which a plurality of layers of impermeable walls made of soil cement are formed inside the core zone by the fill dam construction method according to the present invention.

FIG. 7 is an explanatory diagram showing a rock fill dam in which a water-impermeable wall made of soil cement and reinforced with H-shaped steel or sheet pile is formed inside the core zone by the fill dam construction method according to the present invention.

FIG. 8 is an explanatory view showing a uniform type fill dam in which a water barrier made of soil cement is formed inside the core zone by the fill dam construction method according to the present invention.

FIG. 9 is an explanatory diagram showing a conventional rock fill dam.

[Explanation of symbols]

 1 Core Zone 2 Filter Zone 3 Lock Zone 4 Impermeable Wall 5 H-Shaped Steel or Sheet Pile D, D'Dam Bank G Base

Claims (4)

[Claims] 1. The earth material of the core zone is formed on the base material from the top of the core zone to the upper surface of the base material after a dam dam body composed of a plurality of zones having an appropriately water-impervious soil material as the core zone is piled up. A method for constructing a fill dam, which comprises continuously forming along a dam axis an impermeable wall made of soil cement obtained by adding cement and water to and mixing and solidifying. 2. A dam dam body made of a single soil material having an appropriate water-blocking property is raised on the foundation, and cement and water are added to the soil material from the top of the dam dam body to the upper surface of the foundation. A method for constructing a fill dam, which comprises continuously forming a water-impervious wall made of soil cement by adding and mixing and solidifying along the dam axis. 3. The method for constructing a fill dam according to claim 1, wherein a plurality of layers of impermeable walls made of soil cement are formed. 4. Construction of a fill dam according to claim 1 or 2, characterized in that a required number of reinforcing agents, the lower end of which reaches the inside of the foundation, are driven into the impermeable wall made of soil cement at appropriate intervals. Method.