JP4918378B2 - Construction method of trapezoidal CSG dam - Google Patents

Description

  The present invention relates to an improvement in a method for constructing a trapezoidal CSG dam constructed by CSG.

  CSG means natural rocks obtained at the dam construction site (including the vicinity) as a material (locally generated material), a small amount of cement added to this locally generated material, and mixed. CSG (Cemented Sand and Gravel).

  In CSG, materials can be procured in the vicinity of the dam site, and the procurement cost and transportation cost of the material can be suppressed. Therefore, the construction cost can be easily reduced. In addition, cement procurement costs can be reduced by minimizing the amount of cement.

On the other hand, there are various types of dams, including trapezoidal dams having a trapezoidal cross section. A construction method for constructing this trapezoidal dam with CSG is known (for example, see Patent Document 1).
Japanese Patent Laying-Open No. 2005-163283 (FIGS. 11 and 12)

Patent document 1 is demonstrated based on the following figure.
FIG. 7 is a diagram for explaining the basic principle of the prior art. First, as shown in FIG. 7A, a first layer 101 of CSG is placed. Next, the precast formwork 102 is installed as shown in FIG. The precast formwork 102 has a height that is twice the height (thickness) of the first layer 101. Next, as shown in (c), a second layer 103 of CSG is placed on the first layer 101. The upper surface of the second layer 103 and the upper surface of the precast formwork 102 have the same height. Therefore, protective concrete 104 is placed between the precast formwork 102 and the first and second layers 101 and 103. This completes one construction cycle.

If (a) and (b) take one day and (c) and (d) take one day, one construction cycle is completed in two days. By repeating such a construction cycle, a dam with the required height is completed.
For example, if the total height of the first and second layers 101 and 103 is 1 m and the height of the dam is 50 m, the construction cycle may be repeated 50 times, and the dam will be completed in 100 days in calculation. Become.

  Since the conventional technique is constructed by CSG, it has the advantage that the construction cost of the dam can be reduced and the construction cycle is clear, so that the construction period can be easily calculated. However, when actually constructed, it was found that there were the following problems.

FIG. 8 is a front view of the trapezoidal CSG dam, and the trapezoidal CSG dam 110 is a weir that dams the Tanigawa 111, and thus has a substantially inverted triangular shape when viewed from the upstream side (or downstream side) of the Tanigawa 111.
FIG. 9 is a cross-sectional view taken along line 9-9 of FIG. 8, that is, a cross-sectional view cut from upstream to downstream. The trapezoidal CSG dam 110 has a trapezoidal cross section with a narrow upper part and a wide lower part.

  FIG. 10 is a simplified view of a trapezoidal cross section. As shown in FIG. 10A, the trapezoidal CSG dam has an inverted triangle with a base length a and a height h as seen from the upstream side. 113. As shown in (b), the shape of the cross section cut from the upstream to the downstream can be regarded as a triangle 114 having a base length of b and a height of h.

  In contrast to the “triangle” where the vertex of the triangle is higher and the base is lower, the “inverted triangle” is the upper base and the vertex is lower. Say what you are.

  When the vertical line rising perpendicularly from the horizontal line passing through the apex of the inverted triangle 113 and the base of the triangle 114 is taken as the x axis, x changes from 0 to h. The lengths of the line segments cut by the horizontal line 115 passing through arbitrary x are a1 and b1, respectively. Assuming that the area of the surface cut by the horizontal line 115 is y, the area y is represented by a rectangle with a1 in the vertical direction and b1 in the horizontal direction, as shown in (c). That is, y = a1 × b1.

In the inverted triangle 113 in (a), a proportional relationship of a1: a = x: h is established, and can be arranged as a1 = (ax / h).
In the triangle 114 in (b), a proportional relationship of b1: b = (h−x): h is established, and can be arranged as b1 = b (h−x) / h.
a1 × b1 is (ax / h) · b (h−x) / h = x (h−x) · (ab / h ² ). Since (ab / h ² ) is a constant, it is replaced with a constant α.

As a result, the area y is a quadratic function represented by y = αx (h−x) = − αx ² + αhx. The secondary function, x = 0 and x = h at y = 0, and the sign of x ² is negative (-) because it is, as shown in FIG. 11, the quadratic function curve convex upward.

  FIG. 12 is a diagram for explaining the area of the flat cross section of the trapezoidal CSG dam. The triangle 114 shown in (a) is accompanied by the graph shown in (b). In this graph, since the horizontal axis is the y-axis and the vertical axis is the x-axis, the quadratic function curve is convex to the right.

This quadratic function curve corresponds to the area of each layer when the trapezoidal CSG dam is divided by a horizontal line, and represents the amount of CSG to be placed on each layer.
The amount of CSG placement is maximized at a height of h / 2 on the vertical axis.

Therefore, two CSG supply facilities that can cover the area of Y / 2 marked on the horizontal axis were prepared. This is because the area of Y can be covered with two units.
Then, on the vertical axis, only one CSG supply facility is operated in the range of height 0 to P1. In the range of the heights P1 to P2, two CSG supply facilities are operated. In the range of the heights P2 to h, only one CSG supply facility is operated. By efficiently suspending one CSG supply facility, the efficiency of the facility can be improved.

However, in the hatched portions 116, 117, 118, and 119, the CSG supply facility is wasted, and the operation efficiency rate of the facility is reduced. As a result, the construction cost of the trapezoidal CSG dam increases.
It is desirable that the shaded portions 116, 117, 118 and 119 can be compressed or made zero.

  This invention makes it a subject to provide the construction method of the dam which can improve the operation | use effective rate of a CSG supply facility in construction of a trapezoidal CSG dam.

The invention according to claim 1 is a construction for constructing a dam made of a material called CSG in which the shape viewed from the upstream side approximates an inverted triangle and the cross-sectional shape cut from the upstream to the downstream has a trapezoidal shape. A method,
In order to construct a dam by sequentially placing CSG layers with a height of 500 mm to 1000 mm, a CSG supply facility for supplying a constant amount of CSG per hour is prepared. Prepare a precast formwork of height, prepare a protective concrete material to be poured between the two CSG layers and the precast formwork,
Arbitrary CSG layers are n layers, CSG layers placed on the n layers are (n + 1) layers, and CSG layers placed on the (n + 1) layers are many layers such as (n + 2) layers. the turn call, the n layer is applied by a plurality of work area, the (n + 1) layer and (n + 2) layers are also applied by a plurality of work area as well, the construction also several of the precast mold and the protective concrete material When it is constructed in the work area ,
A mold installation step for installing the precast mold, and
When the construction of the first section of this formwork installation process is completed, an n-layer CSG placement process in which a constant amount of CSG is supplied per hour to continuously place the n-layer CSG layer;
Subsequent to the n-layer CSG placement step, the (n + 1) -layer CSG placement step is performed by receiving a constant amount of CSG per hour and continuously placing the (n + 1) -layer CSG layers;
After the completion of the first section of the (n + 1) layer CSG placing process, the concrete placing process for placing the protective concrete material between the two CSG layers and the precast formwork is performed. By applying, the CSG placing step is continuously performed.

According to inventions described in claim 1, it enabled the continuous implementation of about C SG strokes設工. The CSG placement process is continuously performed with a constant amount of CSG supplied per hour.
There is no worry of excessive CSG supply. As a result, the CSG supply facility can be utilized to the maximum extent, and the construction cost of the trapezoidal CSG dam can be reduced.

The best mode for carrying out the present invention will be described below with reference to the accompanying drawings. The drawings are viewed in the direction of the reference numerals.
FIG. 1 is a plan sectional view of a certain layer, and is a diagram showing the planar sectional shape of a certain layer (for example, n layer) of a trapezoidal CSG dam in a simplified form of a rectangle having a length of a1 and a width of b1. Establishing the 1st to 4th work zones as the work proceeding from left to right in the figure. In addition, although the number of construction zones is arbitrary, it was set to 4 here for convenience.

FIG. 2 is a construction process diagram of the trapezoidal CSG dam according to the present invention, and the horizontal axis is the time axis. The first line below the time axis shows the formwork (precast formwork installation process), the second line shows the CSG work (CSG placement process), and the third line shows the concrete work (protective concrete placement process).
The construction state at the time T1 to T8 attached to the time axis will be described in detail with reference to FIG.

A formwork layer corresponding to two layers consisting of n layers and (n + 1) layers of the CSG layer is defined as A layer, and a formwork corresponding to two layers consisting of (n + 2) layers and (n + 3) layers Is defined as layer B.
In the first-line formwork, precast formwork installation in the 1st to 4th districts in the A layer is carried out starting from the time axis T0.

  At the time when the first section (formwork) of the A layer in the first row is completed, in the CSG process in the second row, CSG placement in the first to fourth sections in the n layer is started. It is desirable to set idle time Id1 next to the 4th section of the n layer. The idle time Id1 is determined for the purpose of forwarding a heavy machine such as a bulldozer or a vibrating roller from the 4th ward to the 1st ward and absorbing a delay generated during construction in the 1st to 4th wards. However, the idle time Id1 is set to a time as short as possible because it leads to a decrease in construction efficiency. For the same reason, it is desirable to set the idle time Id1 next to the four sections of the (n + 1) layer and the (n + 2) layer.

After the idle time Id1, CSG placement in the 1st to 4th districts in the (n + 1) layer is performed.
In addition, in the CSG construction in the second row, it is possible to construct the n layer from T0, but preferably, it starts when the first section of the A layer in the first row is completed. If the work zones are overlapped and adjacent, interference between heavy machinery and heavy machinery and workers will be a problem, but if the A-layer work zone and the n-layer work zone are different as in this example, Handling of heavy machinery becomes easier and is preferable from the viewpoint of occupational safety.

In the concrete work in the third row, the layer of protective concrete placement corresponding to the A layer in the first row is defined as a layer, and the layer of protection concrete placement corresponding to the B layer is defined as layer b.
In the concrete work in the third row, the concrete placement of the a layer can be performed if the (n + 1) layer in the second row starts. However, it preferably starts when the first section of the (n + 1) layer in the second row is completed. If the work zones overlap and are adjacent, the interference between heavy machinery and the interference between heavy machinery and workers will be a problem. However, as shown in this example, the (n + 1) -layer work zone and the a-layer work zone may be different. This makes it easier to handle heavy machinery and is favorable for occupational safety.

In CSG construction in the second row, CSG placement for 1st to 4th districts at (n + 1) layer was carried out, and after 1st idle period Id1, CSG placement for 1st to 4th districts at (n + 2) layer was conducted However, the formwork of the 1st row of the B layer in the 1st row can be completed before the CSG placement of the (n + 2) layer is completed. Implement the installation.
Then, in the second row, CSG placement of 1st to 4th districts in the (n + 2) layer is performed, and after the idle time Id1, CSG placement of 1st to 4th districts in the (n + 3) layer is performed. .

  In the concrete work in the third row, the concrete placement of the b layer starts when the first section of the (n + 3) layer in the second row is completed.

Next, the state of the construction site corresponding to T1 to T8 in FIG. 2 will be described.
In FIG. 2, at T1, only the formwork is carried out, and the construction has progressed to the middle of the first section of the A layer. The construction state at this time is as shown in FIG.
In FIG. 2, at T2, the formwork has progressed to the middle of the second section of the A layer. In parallel with this, CSG is progressing to the middle of the 1st section of the n layer. The construction state at this time is as shown in FIG. According to FIG. 3 (c), which is a view taken in the direction of arrow C in FIG. 3 (b), left and right A layers (precast formwork) with predetermined intervals L and L on both sides of the n layer (CSG layer). Is installed.

In FIG. 2, at T3, the ASG layer of the CSG craft has finished, and the CSG craft has advanced to the 4th section of the n-layer. The construction state at this time is as shown in FIG.
In FIG. 2, at T4, the CSG process is progressing to the middle of the second section of the (n + 1) layer. In addition, the concrete work is progressing partway through the first section of the a layer. The construction state at this time is as shown in FIG. According to FIG. 4 (c), which is a C arrow view of FIG. 4 (b), the CSG process for two layers from the n layer and the (n + 1) layer, and the left and right A layers (precast formwork) A layer (protective concrete) is placed between them.

In FIG. 2, at T5, the CSG craft has finished placing the (n + 1) layer, and the formwork has progressed partway through the first tier of the B layer. In addition, the concrete works are progressing halfway through the 4th section of the a layer. The construction state at this time is as shown in FIG.
In FIG. 2, at T6, the formwork is progressing to the middle of the second section of the B layer. In parallel with this, CSG is progressing to the middle of the first section of the (n + 2) layer. The construction state at this time is as shown in FIG. According to FIG. 5 (c), which is a view taken in the direction of arrow C in FIG. 5 (b), the left and right B layers (precast type) are placed at predetermined intervals L and L on both sides of the (n + 2) layer (CSG layer). Frame) is installed.

In FIG. 2, at T7, the B layer of the formwork is finished, and the CSG method is progressing to the middle of the first section of the (n + 3) layer. The construction state at this time is as shown in FIG.
In FIG. 2, at T8, the CSG process has progressed to the middle of the second section of the (n + 3) layer. In addition, the concrete work is progressing to the middle of the 1st section of the b layer. The construction state at this time is as shown in FIG. According to FIG. 6 (c), which is a C arrow view of FIG. 6 (b), CSG work for two layers from the (n + 2) layer and the (n + 3) layer, and the left and right B layers (precast formwork) In between, a b layer (protective concrete) is placed.

  In FIG. 2, the first layer, the second layer, the third layer,... The mth layer of the CSG are generalized by describing the n layer, the (n + 1) layer, the (n + 2) layer, and the (n + 3) layer. In other words, CSG works continuously. As a result, the CSG supply facility can be operated continuously, and the first layer, the second layer, the third layer,. As a result, the hatched portions indicated by reference numerals 116 to 119 in FIG. Therefore, there is no worry of excessive CSG supply. As a result, the CSG supply facility can be utilized to the maximum extent, and the construction cost of the trapezoidal CSG dam can be reduced.

  The present invention is suitable for a trapezoidal CSG dam constructed by CSG.

It is plane sectional drawing of a certain layer. It is a construction process figure of trapezoid CSG dam concerning the present invention. FIG. 3 is a construction state diagram corresponding to T1 and T2 in FIG. 2. FIG. 3 is a construction state diagram corresponding to T3 and T4 in FIG. 2. FIG. 3 is a construction state diagram corresponding to T5 and T6 in FIG. 2. FIG. 3 is a construction state diagram corresponding to T7 and T8 in FIG. 2. It is a figure explaining the basic principle of the prior art. It is a front view of a trapezoid CSG dam. FIG. 9 is a sectional view taken along line 9-9 in FIG. 8. It is the figure which simplified the trapezoid cross section. It is an upward convex quadratic function curve diagram. It is a figure explaining the area of the plane cross section of a trapezoid CSG dam.

Explanation of symbols

  110 ... Trapezoid CSG dam, 111 ... Tanikawa, 113 ... Inverted triangle, 114 ... Triangle, n layer, (n + 1) layer, (n + 2) layer, (n + 3) layer ... CGS layer, A layer to B layer ... Precast formwork, Layers a to b ... Protective concrete.

Claims (1)

It is a construction method when building a dam with a shape viewed from the upstream side that approximates an inverted triangle and the shape of the cross section cut from the upstream to the downstream has a trapezoidal shape with a material called CSG,
In order to construct a dam by sequentially placing CSG layers with a height of 500 mm to 1000 mm, a CSG supply facility for supplying a constant amount of CSG per hour is prepared. Prepare a precast formwork of height, prepare a protective concrete material to be poured between the two CSG layers and the precast formwork,
Arbitrary CSG layers are n layers, CSG layers placed on the n layers are (n + 1) layers, and CSG layers placed on the (n + 1) layers are many layers such as (n + 2) layers. the turn call, the n layer is applied by a plurality of work area, the (n + 1) layer and (n + 2) layers are also applied by a plurality of work area as well, the construction also several of the precast mold and the protective concrete material When it is constructed in the work area ,
A mold installation step for installing the precast mold, and
When the construction of the first section of this formwork installation process is completed, an n-layer CSG placement process in which a constant amount of CSG is supplied per hour to continuously place the n-layer CSG layer;
Subsequent to the n-layer CSG placement step, the (n + 1) -layer CSG placement step is performed by receiving a constant amount of CSG per hour and continuously placing the (n + 1) -layer CSG layers;
After the construction of the first section of the (n + 1) layer CSG placing process is completed, a concrete placing process for placing the protective concrete material between the two CSG layers and the precast formwork is performed. Thus, the trapezoidal CSG dam construction method, wherein the CSG placing step is continuously performed.

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