KR100771471B1 - Structure of retaining wall used precast concrete blocks in the strengthening soil and method making the retaining wall of using it - Google Patents

Abstract

The present invention is to construct the front wall of the retaining wall block to be a gradient of 2-3 degrees, but to build an integrated structure instead of a stepped construction, the vertical reinforcement to reinforce the horizontal force of the upper and lower retaining wall block and constant construction of the integrated construction In order to have a function of inducing a gradient at the same time, it is easy to demould the retaining wall block and to make the construction of the retaining wall block efficient and economical.

In order to achieve the above object, cone-shaped insertion holes are formed in the upper and lower portions of the retaining wall block, and the vertical reinforcement with the fixing nut is inserted while the cone-shaped insertion holes of the upper and lower retaining wall blocks correspond to each other. It is a structure which has the structure which induces and fixes a gradient to a retaining wall by the integral construction method by the thickness of the retaining wall cork which seals the latter part of the gap of a retaining wall block, and the wedge provided in the front half of a clearance.

Unit retaining wall block, step, vertical reinforcement, spiral, fixing nut, inclined nut, cone insert hole, wedge, retaining wall cork

Description

Structure of retaining wall used precast concrete blocks in the strengthening soil and method making the retaining wall of using it

1a is a perspective view of a precast concrete block structure for a reinforced soil retaining wall using a round bar of the present invention

Figure 1b A-A cross section of Figure 1a

Figure 2 is a cross-sectional view showing the dimensions of the precast concrete block structure for reinforcement earth retaining wall using the present invention bar for convenience of description

3a-3g cross-sectional view showing the construction step of the reinforced earth retaining wall using a precast concrete block structure for reinforcement earth retaining wall using the round bar of the present invention

4 is a state diagram of the construction of the reinforced soil retaining wall constructed using a precast concrete block structure for a reinforced soil retaining wall using a round bar of the present invention

<Description of main parts of drawing>

10; Unit retaining wall block 12; First half step

14; Late stage 16; Link

20; Vertical stiffeners 22; Spiral

24; Fixing nut 26; Tilt Nut

30; Conical insertion hole 32; Small diameter cross section

34; Large diameter cross section 40; wedge

50; Cork 60 for retaining wall; Geo grid

62; Steel bar

The present invention relates to a precast concrete block structure for a reinforced soil retaining wall using a round bar and a retaining wall construction method using the same.

In general, the retaining wall is divided into various types of retaining walls according to the method of supporting the horizontal earth pressure on the rear surface. Examples are gravity retaining walls and reinforced earth retaining walls.

Gravity retaining wall is a method of supporting the horizontal earth pressure of the back surface by the weight of the retaining wall, and reinforcement soil retaining wall is a method of supporting the horizontal earth pressure of the back surface by the friction force between the geogrid and the reinforcement soil.

Reinforced soil retaining wall is constructed with retaining wall blocks. Retaining wall blocks are precast concrete products. Retaining wall blocks have their geogrids connected to their backs and are inserted into well-reinforced soils. The geogrid is embedded in the reinforcement soil to support the horizontal earth pressure by the frictional force between the geogrid and the reinforcement soil.

As such, the retaining wall block is not a structural member supporting the horizontal earth pressure because the horizontal earth pressure is supported by the reinforcement soil and the geogrid. It acts as an exterior material to protect the exterior of the reinforced earth.

If the retaining wall block is a structural member supporting horizontal earth pressure, the retaining wall constructed with the unit retaining wall block is very weak against horizontal earth pressure.

However, even if the frictional force of reinforcement soil and geogrid fully supports the horizontal earth pressure, if the construction is inaccurate or the load increases, the frictional force of the geogrid will not be able to cope with it, and the increased horizontal force will act on the retaining wall block. . As a result, the retaining wall part is partially full.

In order to prevent overloading, the retaining wall block is usually retracted by 2-3 degrees. In order to prepare for the phenomenon of full load on the horizontal load by predicting the above problems in advance. Another reason for building retaining walls with a 2-3 degree gradient is to provide stability. Retaining walls built vertically feel heavy and anxious. In retaining wall construction, a gradient of 2-3 degrees is known to give the most stability.

However, the gradient of the retaining wall until now has been due to the so-called stepped construction, which gradually builds by retaining the retaining wall block slightly back. Stepped construction makes rainwater penetrate into the gap between the retaining wall block and the retaining wall block, which causes the durability of the reinforcement soil located on the back wall retaining block. This is because the frictional force of the geogrid is given by the compacted reinforcement soil. In particular, acid rain is a cause of deterioration of the concrete retaining wall block. As such, the infiltration water penetrated into the gap is a problem of terraced construction.

On the other hand, as a means for preventing unexpected horizontal loads acting on the retaining wall block, a means of giving a gradient of 2-3 degrees to the retaining wall, and a means of connecting and reinforcing vertical stiffeners at the upper and lower ends of the retaining wall block are also used.

The vertical stiffener is inserted into the insertion hole formed in the retaining wall block. Since the insertion hole is formed by the mold in the process of manufacturing the retaining wall block, if the mold of the insertion hole is not detached, the retaining wall block is damaged and, if severely, the retaining wall block cannot function properly as the retaining wall block.

The present invention is to solve the above problems in the reinforcement earth retaining wall constructed by the retaining wall block.

Accordingly, an object of the present invention is to construct a front wall of the retaining wall block to have a gradient of 2-3 degrees backward, but to build an integrated structure instead of a stepped construction, and to facilitate the construction of the gradient of the retaining wall front wall by performing an integrated construction. In addition to preventing the infiltration water, there is another purpose, and the other purpose is that the vertical reinforcement has the function of reinforcing the horizontal force of the retaining wall block and at the same time inducing a constant gradient, and the construction of the retaining wall block is efficient and economical. There is another purpose to this.

Reinforced soil retaining wall block structure for this purpose should have at least the following four requirements.

(1) The construction of the retaining wall is an integral construction method, The front wall of the retaining wall should have a gradient of 2-3 degrees.

The 90-degree vertical wall makes a person feel pressured and insecure.

In retaining wall construction, the slope of 2-3 degrees is known to give the most stability. An angle of inclination of 2-3 degrees is necessary to prevent the full wall from filling. This is because the horizontal force is applied to the retaining wall due to the floor load or the horizontal load, resulting in a full stomach phenomenon.

Gradient of the retaining wall block is formed by an integral construction method.

In the integrated method, the front wall is constructed so as to have an inclination angle of 2-3 degrees while the unit retaining wall block is not snapped backward and the front position of the retaining wall block is matched. The integrated method prevents water from penetrating into the gap between the retaining wall block and the retaining wall block and enhances the appearance. By preventing the penetration of acid rain, the strength of the reinforcement soil is not lowered, so the durability of the reinforcement soil is maintained as it is.

   (2) Vertical reinforcement is to be inserted in the state that the insertion hole of the retaining wall block corresponds to the upper and lower ends.

It is very vulnerable to horizontal earth pressure if only the retaining wall block is considered without considering the geogrid. The geogrid installed on the back of the retaining wall block supports the horizontal earth pressure, but the geogrid is loaded horizontally when the reinforcement soil is partially compacted or the geogrid is badly installed or the load becomes temporarily larger than the design load. You will not fully support it. The remaining horizontal load, which cannot be supported, is applied to the retaining wall block. The horizontal load acting on the retaining wall block is the cause of the full load of the retaining wall block.

Vertical stiffeners serve as stiffeners to support horizontal loads.

In addition, the vertical reinforcement along with the gradient of the retaining wall block serves to prevent the full stomach phenomenon.

  (3) The insertion hole of the retaining wall block is to have a structure that facilitates detachment from the mold.

In order for the insertion hole of the retaining wall block to be easily detached from the mold, the insertion hole should be conical in shape. The diameter of the upper and lower end faces of the retaining wall block is the largest and gradually decreases toward the inside. The mold is pulled out to the upper and lower end surfaces of the retaining wall block, thereby facilitating detachment.

  (4) The retaining wall gradient is to be induced by vertical stiffeners and insertion holes.

The vertical reinforcement consists of a round bar and is inserted into the insertion hole. The length of the vertical stiffener is equal to the depth of the insertion hole of the upper and lower retaining wall blocks. When sealing the gap between the retaining wall block and the retaining wall block with the retaining wall cork to prevent the penetration of water, the length of the vertical stiffener is the sum of the thicknesses of the filled cork. Retaining wall cork is a mixture of cork and pitch and is excellent in flexibility and sealing property.

Vertical reinforcement is a support member for supporting a horizontal force. Since the vertical stiffener is inserted into the insertion hole of the upper and lower retaining wall blocks, the length of the vertical stiffener is equal to twice the depth of the insertion hole of the unit retaining wall block.

The vertical stiffener has a spiral section. Helical portion has a fixed nut and the tilt adjustment nut is inserted. Lock nut is fixed to the large-diameter end face of the upper conical insertion hole, the inclination adjustment nut It is inserted into the vertical reinforcement inserted into the lower conical insertion hole.

If the retaining wall gradient is induced by the vertical stiffener and the insertion hole as follows.

For convenience of description, FIG. 2 specifically shows the dimensions of the retaining wall block. Let's explain.

First, the relationship between the gradient and the unit retaining wall block constructed in an integral manner will be described. It is assumed that 20 retaining wall blocks with a height of 567 mm are constructed in an integral manner such that the retaining wall height is h = 11.3 m, and the front wall has a gradient of d = 5 cm away from the vertical wall (see Fig. 2).

As shown in FIG. 2, one retaining wall block must be constructed by pushing back 2.5 mm in order to make the front wall have d = 5 cm with 20 retaining wall blocks. (50 mm / 20 pieces = 2.5 mm / piece)

If 40 retaining wall blocks are constructed so that the height of the retaining wall is h = 22.6m and d = 5cm, one retaining wall block should be constructed by pushing back 1.25mm.

Next, the conical insertion hole and the dimensions of the vertical reinforcement and their fixed relationship are as follows.

The small diameter of the conical insertion hole is 30mm, the large diameter is 35mm and the depth is 150mm. The diameter of the vertical stiffener is 25mm. Of fixing nut inserted in vertical reinforcement The outer diameter is 35mm. The outer diameter of the fixing nut is the same as the large diameter of the conical insertion hole, 35 mm. Of the tilt adjusting nut inserted in the vertical reinforcement The outer diameter is 30mm. Thereby firmly secure the lock nut in a larger diameter of the insertion hole on the cone. Apply a small impact to the fixing nut and fix it to the large diameter of the conical insertion hole.

In order to maintain the gradient while inducing the gradient of the retaining wall block, the vertical stiffener must be fitted in the insertion hole. In other words, the length of vertical stiffeners should be twice the depth of the insertion hole.

Therefore, the length of vertical stiffener is 150mm x 2 = 300mm.

The mechanism of giving a gradient while integrally constructing the upper and lower retaining wall blocks having the above shapes and dimensions will be described below.

First, the vertical reinforcement inserted into the insertion hole of the upper retaining wall block is inserted into the fixing nut fixed to the large diameter of the conical insertion hole while being in contact with the small diameter cross section. By inserting the fixing nut, the vertical stiffener forms one body with the upper retaining wall block.

When the upper retaining wall block is inclined, the vertical stiffener is in the same inclined relationship.

Second, the vertical reinforcement is fixed to the upper retaining wall block is inserted extending into the insertion hole of the lower retaining wall block. Extended vertical stiffeners are not restricted in the insertion hole of the lower retaining wall block. It is only in contact with the small diameter cross section of the insertion hole of the lower retaining wall block.

If the vertical stiffener is lifted slightly up from the small diameter cross section of the folded bottom retaining wall block, the vertical stiffener is free to move in the horizontal direction.

Third, the means for lifting the upper retaining wall block is made by the wedge and the retaining wall cork.

If the upper retaining wall block is lifted up about 5mm using the retaining wall cork and the wedge in the gap between the upper retaining wall block and the lower retaining wall block, the end of the vertical stiffener is lifted 5mm upward from the small diameter cross section of the lower retaining wall block insertion hole. (See Fig. 3)

The 5mm raised above allows the vertical reinforcement to move horizontally within the bottom retaining wall insert. Since the movement in the horizontal direction is free, when the top retaining wall block is inclined, the vertical reinforcement is also inclined by the same size.

Fourth, it is assumed that if the inclination of the unit retaining wall block is 2.5 mm, it is equal to the design gradient of the retaining wall body.

If the top retaining wall block is sloped 2.5mm, the vertical reinforcement is also sloped 2.5mm.

The 2.5mm slope of the top retaining wall block is converted to the 2.5mm slope of the vertical reinforcement.

Fifth, the converted vertical stiffeners should be firmly fixed by the upper and lower retaining wall blocks at the inclination angle. If the vertical reinforcement flows in the insertion hole of the upper and lower retaining wall blocks, there is no binding force to catch the gradient of the upper and lower retaining wall blocks, and thus the retaining wall gradient cannot be achieved.

The fixed vertical stiffeners can be lowered 5mm upwards.

By lowering 5mm, the vertical reinforcement is firmly fixed while being in contact with the small diameter cross section of the insertion hole of the upper and lower retaining wall blocks.

5 mm is given by the wedge and retaining wall cork, so remove it.

Since the retaining wall cork is a soft material, the retaining wall cork is naturally compressed by the weight of the upper retaining wall block.

The state where both ends of the vertical reinforcement are firmly in contact with the small diameter cross section of the insertion hole of the upper and lower retaining wall blocks is the final state in which the upper and lower retaining wall blocks are gradientd.

On the other hand, in order to incline the upper retaining wall block by 2.5mm or 1.25mm, it is easy to set the gradient by adjusting the gap by the inclined adjusting nut inserted into the spiral portion of the vertical stiffener extended and inserted into the insertion hole of the lower retaining wall block.

For example, in order to give a 1.25mm incline, the distance between the inclination adjustment nut and the insertion hole may be adjusted to be 1.25mm.

The process of forming the design gradient by the specific dimensions from the viewpoint of the gradient setting mechanism described above is as follows. (See Fig. 3)

The dimensions are assumed as follows.

The small diameter of the conical insertion hole is 30mm, the large diameter is 35mm and the depth is 150mm. The diameter of the vertical stiffener is 25mm. Of fixing nut inserted in vertical reinforcement The outer diameter is 35mm. Of fixing nut The outer diameter is the same as the large diameter of the conical insertion hole, 35 mm. Of the tilt adjusting nut inserted in the vertical reinforcement The outer diameter is 30mm.

Fixing nut It is firmly fixed to the large-diameter cross-section of the upper conical insertion hole, and the inclination adjustment nut is inserted into the vertical reinforcement inserted into the lower conical insertion hole.

If the permanent thickness of the retaining wall cork sealed in the gap between the unit retaining wall block and the unit retaining wall block is 10 mm, first consider the weight of the retaining wall block Should be sealed to a thickness of 15 mm. This is because the gap becomes 10 mm when the gap is compressed by the weight of the upper portion. The retaining wall cork is sealed only at the rear end of the retaining wall block gap.

If the permanent thickness of the retaining wall cork is 10mm, the length of vertical stiffener is 310mm.

If the thickness of the retaining wall cork is 15mm If the permanent thickness of retaining wall cork is subtracted 10mm, the vertical reinforcement is 5mm above the small diameter cross section of the lower retaining wall block insertion hole.

In this state, if the retaining wall blocks are constructed so that the retaining wall height is h = 11.3m and the gradient is d = 5cm (see Fig. 4), the unit retaining wall blocks may be inclined backward 2.5 mm. If you build 40 retaining wall blocks so that the retaining wall height is h = 22.6m and have a gradient of d = 5cm, the unit retaining wall blocks can be inclined backward 1.25mm. 2.5mm or 1.25mm means horizontal distance.

If the upper retaining wall block is moved backward 2.5 mm, the end of the vertical stiffener inserted into the insertion hole of the lower retaining wall block is the same as that moved forward 2.5 mm.

The movement of 2.5 mm is given by the wedge inserted into the retaining wall block gap (see Fig. 3e).

The end of the vertical stiffener inserted into the insertion hole of the lower retaining wall block by the movement of 2.5mm is moved forward by 2.5mm.

In this state where the vertical stiffener reaches the design gradient, the floating 5mm is to be lowered. The wedge is removed and the retaining wall cork is compressed by the weight of the upper retaining wall block. This is the final state where the grade is given to the upper and lower retaining wall blocks.

Repeated construction leads to the design gradient of the retaining wall.
The present invention is to solve the above problems in the reinforcement earth retaining wall constructed by the retaining wall block.
Accordingly, an object of the present invention is to construct a front wall of the retaining wall block to have a gradient of 2-3 degrees backward, but to build an integrated structure instead of a stepped construction, and to facilitate the construction of the gradient of the retaining wall front wall by performing an integrated construction. In addition to preventing the infiltration water, there is another purpose, and the other purpose is that the vertical reinforcement has the function of reinforcing the horizontal force of the retaining wall block and at the same time inducing a constant gradient, and the construction of the retaining wall block is efficient and economical. There is another purpose to this.
Reinforced soil retaining wall block structure for this purpose should have at least the following four requirements.
(1) The construction of the retaining wall is an integral construction method, The front wall of the retaining wall should have a gradient of 2-3 degrees.
The 90-degree vertical wall makes a person feel pressured and insecure.
In retaining wall construction, the slope of 2-3 degrees is known to give the most stability. An angle of inclination of 2-3 degrees is necessary to prevent the full wall from filling. This is because the horizontal force is applied to the retaining wall due to the floor load or the horizontal load, resulting in a full stomach phenomenon.
Gradient of the retaining wall block is formed by an integral construction method.
In the integrated method, the front wall is constructed so as to have an inclination angle of 2-3 degrees while the unit retaining wall block is not snapped backward and the front position of the retaining wall block is matched. The integrated method prevents water from penetrating into the gap between the retaining wall block and the retaining wall block and enhances the appearance. By preventing the penetration of acid rain, the strength of the reinforcement soil is not lowered, so the durability of the reinforcement soil is maintained as it is.
(2) Vertical reinforcement is to be inserted in the state that the insertion hole of the retaining wall block corresponds to the upper and lower ends.
It is very vulnerable to horizontal earth pressure if only the retaining wall block is considered without considering the geogrid. The geogrid installed on the back of the retaining wall block supports the horizontal earth pressure, but the geogrid is loaded horizontally when the reinforcement soil is partially compacted or the geogrid is badly installed or the load becomes temporarily larger than the design load. You will not fully support it. The remaining horizontal load, which cannot be supported, is applied to the retaining wall block. The horizontal load acting on the retaining wall block is the cause of the full load of the retaining wall block.
Vertical stiffeners serve as stiffeners to support horizontal loads.
In addition, the vertical reinforcement along with the gradient of the retaining wall block serves to prevent the full stomach phenomenon.
(3) The insertion hole of the retaining wall block is to have a structure that facilitates detachment from the mold.
In order for the insertion hole of the retaining wall block to be easily detached from the mold, the insertion hole should be conical in shape. The diameter of the upper and lower end faces of the retaining wall block is the largest and gradually decreases toward the inside. The mold is pulled out to the upper and lower end surfaces of the retaining wall block, thereby facilitating detachment.
(4) The retaining wall gradient is to be induced by vertical stiffeners and insertion holes.
The vertical reinforcement consists of a round bar and is inserted into the insertion hole. The length of the vertical stiffener is equal to the depth of the insertion hole of the upper and lower retaining wall blocks. When sealing the gap between the retaining wall block and the retaining wall block with the retaining wall cork to prevent the penetration of water, the length of the vertical stiffener is the sum of the thicknesses of the filled cork. Retaining wall cork is a mixture of cork and pitch and is excellent in flexibility and sealing property.
Vertical reinforcement is a support member for supporting a horizontal force. Since the vertical stiffener is inserted into the insertion hole of the upper and lower retaining wall blocks, the length of the vertical stiffener is equal to twice the depth of the insertion hole of the unit retaining wall block.
The vertical stiffener has a spiral section. The fixing nut and the tilt adjusting nut are inserted in the spiral part. The fixing nut is fixed to the large diameter cross section of the upper conical insert hole, and the tilt adjusting nut It is inserted into the vertical reinforcement inserted into the lower conical insertion hole.
If the retaining wall gradient is induced by the vertical stiffener and the insertion hole as follows.
For convenience of description, the dimensions of the retaining wall block will be described with reference to FIG. 2.
First, the relationship between the gradient and the unit retaining wall block constructed in an integral manner will be described. It is assumed that 20 retaining wall blocks with a height of 567 mm are constructed in an integral manner such that the retaining wall height is h = 11.3 m, and the front wall has a gradient of d = 5 cm away from the vertical wall (see Fig. 2).
As shown in FIG. 2, one retaining wall block must be constructed by pushing back 2.5 mm in order to make the front wall have d = 5 cm with 20 retaining wall blocks. (50 mm / 20 pieces = 2.5 mm / piece)
If 40 retaining wall blocks are constructed so that the height of the retaining wall is h = 22.6m and d = 5cm, one retaining wall block should be constructed by pushing back 1.25mm.
Next, the conical insertion hole and the dimensions of the vertical reinforcement and their fixed relationship are as follows.
The small diameter of the conical insertion hole is 30mm, the large diameter is 35mm and the depth is 150mm. The diameter of the vertical stiffener is 25mm. Of fixing nut inserted in vertical reinforcement The outer diameter is 35mm. The outer diameter of the fixing nut is the same as the large diameter of the conical insertion hole, 35 mm. Of the tilt adjusting nut inserted in the vertical reinforcement The outer diameter is 30mm. Fix the fixing nut firmly to the large diameter of the conical insertion hole. Apply a small impact to the fixing nut and fix it to the large diameter of the conical insertion hole.
In order to induce a gradient of the retaining wall block and to maintain the gradient, the vertical reinforcement must be fitted in the insertion hole. In other words, the length of vertical stiffeners should be twice the depth of the insertion hole.
Therefore, the length of vertical stiffener is 150mm x 2 = 300mm.
The mechanism of giving a gradient while integrally constructing the upper and lower retaining wall blocks having the above shapes and dimensions will be described below.
First, the vertical reinforcement inserted into the insertion hole of the upper retaining wall block is inserted into the fixing nut fixed to the large diameter of the conical insertion hole while being in contact with the small diameter cross section. By inserting the fixing nut, the vertical stiffener forms one body with the upper retaining wall block. When the upper retaining wall block is inclined, the vertical stiffener is in the same inclined relationship.
Second, the vertical reinforcement is fixed to the upper retaining wall block is inserted extending into the insertion hole of the lower retaining wall block. Extended vertical stiffeners are not restricted in the insertion hole of the lower retaining wall block. It is only in contact with the small diameter cross section of the insertion hole of the lower retaining wall block.
If the vertical stiffener is lifted slightly up from the small diameter cross section of the folded bottom retaining wall block, the vertical stiffener is free to move in the horizontal direction.
Third, the means for lifting the upper retaining wall block is made by the wedge and the retaining wall cork.
If the upper retaining wall block is lifted up about 5mm using the retaining wall cork and the wedge in the gap between the upper retaining wall block and the lower retaining wall block, the end of the vertical stiffener is lifted up 5mm from the small diameter cross section of the lower retaining wall block insertion hole. (See Fig. 3)
The 5mm raised above allows the vertical reinforcement to move horizontally within the bottom retaining wall insert. Since the movement in the horizontal direction is free, when the top retaining wall block is inclined, the vertical reinforcement is also inclined by the same size.
Fourth, it is assumed that if the inclination of the unit retaining wall block is 2.5 mm, it is equal to the design gradient of the retaining wall body.
If the top retaining wall block is sloped 2.5mm, the vertical reinforcement is also sloped 2.5mm. The 2.5mm slope of the top retaining wall block is converted to the 2.5mm slope of the vertical reinforcement.
Fifth, the converted vertical stiffeners should be firmly fixed by the upper and lower retaining wall blocks at the inclination angle. If the vertical reinforcement flows in the insertion hole of the upper and lower retaining wall blocks, there is no binding force to catch the gradient of the upper and lower retaining wall blocks, and thus the retaining wall gradient cannot be achieved. The fixed vertical stiffeners can be lowered 5mm upwards.
By lowering 5mm, the vertical reinforcement is firmly fixed while being in contact with the small diameter cross section of the insertion hole of the upper and lower retaining wall blocks. 5 mm is given by the wedge and retaining wall cork, so remove it. Since the retaining wall cork is a soft material, the retaining wall cork is naturally compressed by the weight of the upper retaining wall block. The state where both ends of the vertical reinforcement are firmly in contact with the small diameter cross section of the insertion hole of the upper and lower retaining wall blocks is the final state in which the upper and lower retaining wall blocks are gradientd.
On the other hand, in order to incline the upper retaining wall block by 2.5mm or 1.25mm, it is easy to set the gradient by adjusting the gap by the inclined adjusting nut inserted into the spiral portion of the vertical stiffener extended and inserted into the insertion hole of the lower retaining wall block.
For example, in order to give a 1.25mm incline, the distance between the inclination adjustment nut and the insertion hole may be adjusted to be 1.25mm.
The process of forming the design gradient by the specific dimensions from the viewpoint of the gradient setting mechanism described above is as follows. (See Fig. 3)
The dimensions are assumed as follows.
The small diameter of the conical insertion hole is 30mm, the large diameter is 35mm and the depth is 150mm. The diameter of the vertical stiffener is 25mm. Of fixing nut inserted in vertical reinforcement The outer diameter is 35mm. Of fixing nut The outer diameter is the same as the large diameter of the conical insertion hole, 35 mm. Of the tilt adjusting nut inserted in the vertical reinforcement The outer diameter is 30mm.
Fixing nut It is firmly fixed to the large-diameter cross-section of the upper conical insertion hole, and the inclination adjustment nut is inserted into the vertical reinforcement inserted into the lower conical insertion hole.
If the permanent thickness of the retaining wall cork sealed in the gap between the unit retaining wall block and the unit retaining wall block is 10mm, it should be sealed at the thickness of 15mm at first considering the weight of the retaining wall block. This is because the gap becomes 10 mm when the gap is compressed by the weight of the upper portion. The retaining wall cork is sealed only at the rear end of the retaining wall block gap.
If the permanent thickness of the retaining wall cork is 10mm, the length of vertical stiffener is 310mm.
If the thickness of the retaining wall cork is 15mm If the permanent thickness of retaining wall cork is subtracted 10mm, the vertical reinforcement is 5mm above the small diameter cross section of the lower retaining wall block insertion hole.
In this state, if the retaining wall blocks are constructed so that the retaining wall height is h = 11.3m and the gradient is d = 5cm (see Fig. 4), the unit retaining wall blocks may be inclined backward 2.5 mm. If you build 40 retaining wall blocks so that the retaining wall height is h = 22.6m and have a gradient of d = 5cm, the unit retaining wall blocks can be inclined backward 1.25mm. 2.5mm or 1.25mm means horizontal distance.
If the upper retaining wall block is moved backward 2.5 mm, the end of the vertical stiffener inserted into the insertion hole of the lower retaining wall block is the same as that moved forward 2.5 mm.
The movement of 2.5 mm is given by the wedge inserted into the retaining wall block gap (see Fig. 3e).
The end of the vertical stiffener inserted into the insertion hole of the lower retaining wall block by the movement of 2.5mm is moved forward by 2.5mm.
In this state where the vertical stiffener reaches the design gradient, the floating 5mm is to be lowered. The wedge is removed and the retaining wall cork is compressed by the weight of the upper retaining wall block. This is the final state where the grade is given to the upper and lower retaining wall blocks. Repeated construction leads to the design gradient of the retaining wall.

The configuration of the present invention from the above point of view will be described in detail with reference to the accompanying drawings.
The shape of the retaining wall block 10 of the present invention is one third the size of a conventional retaining wall panel. The width of the upper and lower surfaces of the contact portion to be constructed was widened. In the upper and lower surfaces of the contact portion, the first half step 12 and the second half step 14 are formed around the middle part.
The shape of the retaining wall block front may be any. It doesn't matter if it's oval or square.
The connecting ring 16 is formed at the rear of the retaining wall block 10. The geogrid 60 is connected to the connecting ring 16. The geogrid 60 is connected in a zigzag form between the connecting ring 16 and the steel bar 62.
Precast concrete block structure for a reinforced earth retaining wall of the present invention Conical insertion holes 30 are formed at the same position in the upper and lower portions of the retaining wall block 10 having the stepped 12 and 14 formed therein, and the cone-shaped insertion holes of the upper and lower retaining wall blocks 10 and 10 ( The vertical reinforcement 20 having the spiral portion 22 formed therein is inserted into the insertion holes 30 and 30 formed by the upper and lower retaining wall blocks 10 and 10 in a state in which the 30 is corresponded to each other. ) Both ends of the top Small diameter cross section 32 and bottom of retaining wall block 10 The fixing nut 24 fitted into the spiral portion 22 while being in contact with the small diameter end face 32 of the retaining wall block 10 is attached to the large diameter end face 34 of the insertion hole 30 of the upper retaining wall block 10. The vertical reinforcement 20 is firmly fixed and inserted into the insertion hole 30 of the lower retaining wall block 10 to be in contact with the small diameter end face 32 of the insertion hole 30 of the lower retaining wall block 10. It is a composition.
In addition, the rear half step 14 seals the retaining wall cork 50 in the gap formed by the upper and lower retaining wall blocks 10 and 10, and the wedge 40 is installed in the front end step 12 of the gap, and the rear half step It is a structure which forms the retaining wall gradient by integral construction by the thickness of the retaining wall cork 50 of (14), and the thickness of the wedge 40. FIG.
The permanent thickness of the retaining wall cork 50 is preferably about 10 mm. To induce the gradient, the initial thickness of the retaining wall cork 50 is 15 mm.
Considering the permanent thickness of the retaining wall cork 50, the length of the vertical stiffener 20 should be the length of the insertion hole 30 plus 10mm.
The inclined adjustment nut 26 may be inserted into the spiral portion 22 of the vertical reinforcement 20 inserted into the insertion hole 30 of the lower retaining wall block 10. To easily adjust the horizontal distance for the draft.
Referring to the construction method of the reinforced soil retaining wall construction to guide and fix the gradient of the retaining wall using the precast concrete block structure for the reinforced soil retaining wall configured as described above.
Installing a lower retaining wall block 10 having a conical insertion hole 30 formed therein; Fastening the fixing nut 24 to the large diameter end face 34 of the insertion hole 30 of the upper retaining wall block 10; Insert the vertical reinforcement 20 having a length that is twice the depth of the insertion hole 30 of the retaining wall block 10 and the permanent thickness 10 mm of the retaining wall cork 50 into the fixing nut 24, and 20 to make the upper end of the small diameter end face 32 of the insertion hole 30 of the upper retaining wall block 10; Inserting the tilt adjusting nut 26 into the spiral portion 22 of the vertical reinforcing material 20 extended and inserted into the insertion hole 30 of the lower retaining wall block 10; The rear end step 14 of the gap formed by the upper and lower retaining wall blocks 10 is sealed by a retaining wall cork 50 having a thickness of about 15 mm, and the wedge 40 is installed on the front step step 12 of the gap. Making a gradient; Removing the wedge 40 while the retaining wall cork 50 has a permanent thickness of 10 mm; By repeating these steps, it is a configuration that enables the integrated construction.

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The effects of the present invention configured as described above are as follows.
① Integral construction method is possible, and the front wall of the retaining wall can be constructed to have a gradient of 2 to 3 degrees.
② It is easy to insert the vertical reinforcement in the state that the insertion hole of the retaining wall block corresponds to the upper and lower ends.
③ The upper and lower end diameters of the retaining wall block are the largest and the shape gradually decreases toward the inside, so the detachment of the mold is easy.

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Claims (4)

Conical insertion holes 30 are formed at the same position in the upper and lower portions of the retaining wall block having the step 12 and 14 formed on the upper and lower portions thereof, and the conical insertion holes of the upper and lower retaining wall blocks 10 and 10 are formed at the same position. The vertical reinforcement 20 having the spiral portion 22 formed therein is inserted into the cone-shaped insertion hole 30 formed by the upper and lower retaining wall blocks 10 and 10 in a state where the 30 is corresponding to each other. ) Both ends of the top Small diameter cross section 32 and bottom of retaining wall block 10 The fixing nut 24 fitted into the spiral portion 22 while being in contact with the small diameter end face 32 of the retaining wall block 10 is attached to the large diameter end face 34 of the insertion hole 30 of the upper retaining wall block 10. The vertical reinforcement 20 which is firmly fixed and inserted into the insertion hole 30 of the lower retaining wall block 10 is in contact with the small diameter end face 32 of the insertion hole 30 of the lower retaining wall block 10. Precast concrete block structure for reinforcement retaining wall using round rod The retaining wall cork 50 is sealed in the rear end step 14 in a gap formed by the upper and lower retaining wall blocks 10 and 10, and a wedge 40 is provided in the front end step 12 of the gap. The precast concrete block structure for reinforcement soil retaining wall using a round bar is formed by the retaining wall gradient by integral construction by the thickness of the retaining wall cork 50 and the thickness of the wedge 40 of the second half step 14. The inclined adjustment nut 26 of claim 1 or 2 is inserted into the spiral portion 22 of the vertical reinforcement 20 extending and inserted into the insertion hole 30 of the lower retaining wall block 10. Precast concrete block structure for reinforced earth retaining wall using round rod Installing a lower retaining wall block 10 having a conical insertion hole 30 formed therein; Fastening the fixing nut 24 to the large diameter end face 34 of the insertion hole 30 of the upper retaining wall block 10; Insert the vertical reinforcement 20 having a length that is twice the depth of the insertion hole 30 of the retaining wall block 10 and the permanent thickness 10 mm of the retaining wall cork 50 into the fixing nut 24, and 20 to make the upper end of the small diameter end face 32 of the insertion hole 30 of the upper retaining wall block 10; Inserting the tilt adjusting nut 26 into the spiral portion 22 of the vertical reinforcing material 20 extended and inserted into the insertion hole 30 of the lower retaining wall block 10; The rear end step 14 of the gap formed by the upper and lower retaining wall blocks 10 is sealed by a retaining wall cork 50 having a thickness of about 15 mm, and the wedge 40 is installed on the front step step 12 of the gap. Making a gradient; Removing the wedge 40 while the retaining wall cork 50 has a permanent thickness of 10 mm; Reinforcement earth retaining wall construction method using precast concrete block structure for reinforcement earth retaining wall using round bar, characterized in that to enable the integral construction by repeating these steps

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