KR100346947B1 - The SEN Retaining Wall - Google Patents

Abstract

The present invention relates to a structure for reinforcing an existing masonry using an inverted triangular pyramid made of concrete, and to a method of constructing the same. The present invention relates to a method of reinforcing existing stone slabs to increase bearing capacity.

The present invention is to plant the support pile 12 through the foundation (2) of the existing stone shaft (1), so that the concrete inverted triangular pyramid (11) that the pile 12 is a vertex to be integrated with the existing stone shaft (1) It provides a method of reinforcing the existing masonry consisting of the step of forming.

In addition, the present invention, when excavating the retaining wall bottom hard ground (3a) is provided with the base 2 while leaving the inclined surface intact, and installs the inclined surface retaining wall 30 having an inverted triangular pyramid 31, the hard ground (3a) When the upper surface of the soft ground (3b) is reached, the slope is smoothly arranged, and the bearing concrete 32 is installed on the rear surface of the inclined surface retaining wall. It also provides a method of constructing a new retaining wall that is being constructed to complete the retained slope retaining wall.

Description

Masonry reinforcement and retaining wall construction method {The SEN Retaining Wall}

The present invention relates to a method for reinforcing an existing stone shaft using an inverted triangular pyramid made of concrete. More specifically, the present invention relates to a method of reinforcing a stone shaft to install a concrete inverted triangular pyramid in the existing stone shaft and to increase the bearing capacity of the existing stone shaft using the property of the weight of the concrete inverted triangular pyramid toward the existing stone shaft.

1 is a cross-sectional view of an existing stone shaft.

A stone shaft (1) is a structure that prevents the collapse of earth and sand by stacking vertebral and kerbstones on the slope of the slope as an axis made of stone. At the lower end of the stonework, a foundation 2 is installed and stones are stacked thereon to withstand the earth pressure of the ground 3.

The piled-up stacks that fill the back of the cantilever with cement mortar or concrete can play some role as gravity retaining walls, but the stacked stacks that fill the back of the cantilever with soil or rubble have little ability to support earth pressure. As such, the conventionally stacked masonry itself cannot be expected to have a very large structural strength, so it is expected to play a role of a surface protection material that prevents washing or weathering when the surface of the hard ground inclinedly cut is exposed to rainwater.

The inclination angle for stacking stones depends on the type of ground, and if it is stacked at the same inclination angle of soil, there is no danger of collapse. At risk, they tend to stick to steep slopes, so there is a high risk of collapse.

In recent years, the cost of constructing stone stocks has risen, so it is hard to build new ones, but it is not easy to repair old masonry. Therefore, there is a need for a new retaining wall technology to be applied to the slopes to reinforce or expand existing masonry. There is also a need for retaining wall technology that can take advantage of the erosion of the earth due to the slope of the stonework.

The inventors have developed an existing masonry reinforcement method that can increase the stability of the existing masonry and increase the utilization of the site.

In addition, the inventors have developed a method for constructing a new retaining wall that can reduce the amount of earthworks by increasing the inclination angle of the new retaining wall.

It is an object of the present invention to provide a method for reinforcing an existing stonework.

Another object of the present invention is to provide a construction method of a new retaining wall to reinforce the inclined surface.

Still another object of the present invention is to provide a method of utilizing an existing stone top space.

1 is a cross-sectional view of an existing stone shaft.

2 is a conceptual diagram of a structure for reinforcing existing stone masonry with the present invention

3 is a reinforcement drawing of a structure for reinforcing an existing masonry with the present invention.

4 is a cross-sectional view taken along line A-A of FIG.

5 is a cross-sectional view of a new retaining wall as a modification of the present invention.

Description of the major signs

1: existing stonework 2: foundation

3: Soil 11: Concrete Inverted Triangular Pyramid

12: pile 13: concrete slab

21: pillar 22: frame

23: tie beam 24: horizontal rebar

25: S-shaped rebar 26: Rib Lath

30: new retaining wall

31: concrete inverted triangular pyramid 32: bearing concrete

33: retaining wall upper slab 34: key

The present invention will be described in detail with reference to the accompanying drawings.

2 is a conceptual diagram of a structure for reinforcing existing stone masonry with the present invention.

In the reinforcing structure of the present invention, the slope of the existing stone shaft 1 is used as a reference plane. In the original stone shaft, the angle of inclination is essential, and the size of the angle depends on the soil quality and the height of the stone. Therefore, the inverted triangle wedge (C ₀ -C ₁ -B ₀ -A ₀ , C ₁ -C ₂ -B ₁ -A _{1, ....} ) If manufactured and attached to the heavy mass of the heavy body with the will increase the safety of the existing masonry.

If the foundation or ground of the existing masonry is weak, there is a fear that the foundation sinks due to the weight of the wedge. Therefore, if the weight of the rigid body is directly transferred to the hard ground by using the support means, there is no fear of sinking, and the horizontal component generated by the rigid body lying on the inclined surface is burdened by the support.

In the present invention, a concrete inverted triangular pyramid (11) is formed as a rigid body, and it is solved by installing a pile (12) as a supporting means through the foundation (2) of the existing stone shaft (1) at the vertex of the inverted triangular pyramid.

The stone masonry is laid with an inclination angle, so safety is ensured when the pressing force of the soil on the back side is greater than the sliding force of the soil on the back side of the stone. Therefore, it is natural that there is room for the stonework as much as it is pushed when the stonework slope is pressed when the stonework is standing and not falling down.

In the method of pressing the stone slabs, the entire retaining wall can be covered with concrete with a triangular cross-section, but the amount of concrete is high and the efficiency is low. To increase efficiency (ie moment), the center of gravity should be as far from the A ₀ -B ₀ line as possible based on the A ₀ point. And because the retaining wall is generally monotonous, it is necessary to consider that it does not fit with the surrounding landscape. In terms of efficiency and aesthetics, the concrete inverted triangular pyramid is derived in the most optimal form.

If it has an inverted triangular pyramid shape, the concrete amount is 1/3 compared to the continuous triangular prism shape, but the moment is 2/3, so the efficiency is doubled. In addition, by changing the texture of the surface of the concrete inverted triangular pyramid or by changing the color, it also brings a molding effect.

And by forming the floor as a concrete slab 13 on the top of the inverted triangular pyramid also provides a means to expand and utilize the lack of land on the stonework.

Figure 3 is a reinforcement drawing of the structure to reinforce the existing masonry with the present invention, Figure 4 is a cross-sectional view A-A of FIG. With reference to FIG. 3 and FIG. 4, a reinforcement structure and its construction method are demonstrated.

It penetrates through the foundation (2) on which the existing stone shaft (1) is installed and drills at a suitable interval (core boring) to the hard ground. Put the cement mortar in the perforated hole, put the support pile (12) and extend the pillar (21).

On the inclined surface of the existing stone shaft (1) to install a steel frame, such as steel pipe, square tube, section steel, channel so that the pillar 21 and the triangular pyramid and connect the end of the frame with a triangular tie beam (23). The horizontal reinforcing bar 24 is placed on the inclined plane of the triangular pyramid made of the pillar 21, the frame 22, and the tie beam 23. Horizontal rebar may be drilled at regular intervals in steel and fixed to the frame using bolts and nuts. Cross the horizontal reinforcement and reinforce the vertical reinforcement (not shown).

Ribbed lath (26, Rib Lath) is placed on the S-shaped reinforcing bar 25 by placing the S-shaped reinforcing bar 25 on the triangular pyramid surface made of the pillar 21, the frame 22 and the tie beam 22. Install).

A rib lath 26 is attached to another inclined surface other than the triangular pyramid surface from which the pillar 21, the frame 22, and the tie beam 23 are made.

The rib lath is formed on the inclined surface to which the rib lath 26 is attached to form a concrete between the inclined surface and the rib lath.

Rib lath (26, Rib Lath) is placed on the S-shaped reinforcement bar 25 by reinforcing the S-shaped reinforcing bar 25 on the triangular pyramid surface from which the pillar 21, the frame 22, and the tie beam 22 are made. The concrete is installed by placing the rib lath as a formwork on the site where) is installed to form a concrete inverted triangle pyramid (11).

Shotcrete is shot on an inclined surface different from the surface of the concrete inverted triangular pyramid 11, and the surface is treated with color if necessary.

If the concrete slab 13 is further made at the upper end of the inverted triangular pyramid 11, that is, the retaining wall, the limited land is used, and the self-load and the loading load of the slab 13 contribute to the stabilization of the masonry.

Although the reinforcing method of the present invention has been described by the specific examples, the inverted triangular pyramids formed in the present invention are characterized by the inclination of the column not in the vertical direction when the inclination angle of the stone shaft is too small (that is, when it is gentle) according to the inclination, ground state, etc. of the existing stone shaft. It can be installed to have visual stability and reduce the amount of concrete used. In addition, when the height of the existing stone shafts cannot be formed at one time, a triangle pyramid may be constructed.

5 is a cross-sectional view of a new retaining wall as a modification of the present invention.

Unlike the reinforcement method, which adds safety to existing masonry, this modification is a method of actively adding load to the retaining wall in addition to the load of the inverted triangular pyramid concrete mass and the upper slab.

Conventional general retaining walls must prevent wedge-shaped soil from slipping between the back of the retaining wall and the angle of repose of the soil, so an inverted T or L retaining wall fills the soil on the foundation to offset the earth pressure by its weight. Therefore, the inverted T-shaped retaining wall or L-shaped retaining wall becomes safer as the foundation length increases, and there is a side effect of increasing the amount of dirt excavated on the back of the retaining wall. In addition, if the foundation length is long, the moment value is increased, the cross section is increased, and there is a disadvantage in that the construction cost is added.

In order to solve the above shortcomings and obtain a good effect, the new retaining wall 30 is constructed with the slope intact when excavating the hard ground 3a at the bottom of the retaining wall. Then, the reinforced concrete foundation and slab is attached to the rear surface of the inclined concrete retaining wall to be used as a load bearing concrete (32). This is the same principle as the fork tray, so it is not necessary to install a separate formwork, so construction is easy. The slab and the soil it fills up are far from the support point A, which is very effective in ensuring safety.

In the present modified example, the formation of the concrete inverted triangular pyramid 31 is the same as the reinforcement method, and in the case of the new construction method, since the size of the foundation can be appropriately designed from the beginning, it is not necessary to install a separate pile 12, but the size of the foundation You can install a pile to reduce it.

In the present modification, it is essential to install the slab 33 on the top of the retaining wall, but since it is a new structure, additional key 34 on the opposite side of the retaining wall of the slab 33 further ensures the safety of the retaining wall. If the key 34 is used as a part of the new structure on the retaining wall, it contributes to the safety of the retaining wall until the load of the structure.

The present invention can effectively reinforce the existing masonry by forming an inverted triangular pyramid of concrete on the existing masonry. Existing stone masonry is usually difficult to demolish and re-install because the building is dense and the site is narrow, it can be easily reinforced using the present invention. In addition, the existing stone masonry or retaining wall has a flat shape, which does not give a good aesthetic appearance, while the shape of the present invention has a triangular pyramid shape, which has a sense of protrusion and texture, and each surface can be treated in various colors, thereby improving the aesthetic appearance of the city. . It also provided a means to utilize the upper part of the retaining wall as a site.

The modifications applied to the new retaining wall can significantly reduce the amount of excavation, increase the utilization of the land at the top of the retaining wall, and make the retaining wall economically by utilizing the load of the structure installed on the retaining wall.

Claims (8)

Planting the support pile 12 through the foundation 2 of the existing stone shaft 1; Forming a concrete inverted triangular pyramid (11) at which the pile (12) is a vertex to be integrated with the existing stone stack (1); Reinforcement method of the existing masonry, characterized in that consisting of. 2. The method according to claim 1, further comprising a concrete slab (13) covering the upper end of the existing stone (1) and the concrete inverted triangular pyramid (11). In claim 1, the concrete inverted triangular pyramid (11) is installed on the inclined surface of the existing stone shaft (1), the pillar 21 and the frame 22 is installed by connecting the end of the steel 12 with a tie beam (23) Forms an inverted triangular pyramid; Reinforcing horizontal and vertical rebars on the inclined plane of the inverted triangular pyramid made of the pillars 21, the frames 22 and the tie beams 22; Projecting and reinforcing the S-shaped reinforcement 25 on the surface of the inverted triangular pyramid from which the pillar 21, the frame 22, and the tie beam 23 are made; Installing a rib lath (26) on the S-shaped rebar (25); And Placing concrete in an inner space in which the S-shaped rebar 25 is disposed; Reinforcement method of the existing stonework, characterized in that to form a concrete inverted triangular pyramid (11). A rib lath (26) is attached to an inclined surface other than the inclined surface on which the pillar (21), the frame (22) and the tie beam (23) are made on the inclined surface of the existing stone shaft (1); And Type concrete between the rib laths (26) on the inclined surface to which the rib laths (26) are attached; Reinforcement method of the existing stonework, characterized in that it further comprises. The method according to claim 3 or 4, further comprising the step of shooting shotcrete (Shotcrete). When excavating the retaining wall lower end hard ground 3a, the foundation 2 is provided with the slope intact; An inclined retaining wall 30 having an inverted triangular pyramid 31 is installed; When the hard ground (3a) is reached to the soft ground (3b) to gently clean up the inclined surface; Attaching reinforced concrete foundation and slab to the rear surface of the inclined retaining wall to install the bearing concrete (32); Adjusting the inclined surface with rubble or soil on the bearing concrete (32); Completing an inclined retaining wall having the inverted triangular pyramid (31); Construction method of new retaining wall characterized in that constructing by. The method of claim 6, wherein the slab (33) is further provided on the top of the retaining wall (30) having the inverted triangular pyramid (31). 8. The method for constructing a new retaining wall according to claim 7, further comprising a key (34, key) on the opposite side of the retaining wall of the slab (33).