KR200223113Y1 - A structure preventing for bulging of retaining wall - Google Patents

Abstract

The present invention uses the retaining wall to compensate for the front block loading during compaction construction, which is a problem of the existing block-type reinforced soil retaining wall by using EPS compressed blocks that are effectively used as lightweight fill material for roads and shifts. The prevention structure is related.

That is, the present invention is the front block 10 is stacked at a predetermined distance from the cut-off slope 40 is required retaining wall, and the crushed stone 60 is introduced into the back of the front block 10 in a predetermined width, the crushed stone 60 In the general retaining wall structure in which the geogrid 30 is installed at regular intervals between the input portion of the cutting edge and the cut slope 40, and the ground layer 20 is formed by filling with a backfill material such as earth and sand, the fill layer 20 ) When compacting construction with compaction equipment such as a roller 80, the crushed stone (60) which is inserted into the rear surface of the hole 70 and the front block 10 formed in the front block 10 to prevent the loading of the retaining wall Instead of the front block 10 is characterized in that the adhesive (EPS) compression block (1) having a thickness of about 2 ~ 10cm on the back surface by bonding to a certain thickness and laminated.

Description

A structure preventing for bulging of retaining wall}

The present invention relates to a structure for preventing the load of the retaining wall, and more specifically, the compaction construction, which is a problem of the existing block-type reinforcement soil retaining wall by using an EP compression block that is effectively used as a lightweight fill material for roads and shifts. It relates to a full load preventing structure of the retaining wall to supplement the full load of the city front block.

In general, the front block generally used at the site of reinforcement soil retaining wall in the civil engineering field is constructed by using natural aggregate such as crushed stone as drainage and filling material.

That is, as shown in Figures 1a and 1b, the conventional block-shaped reinforcement earth retaining wall structure is a front block 10 stacked on the concrete foundation 50 in front of the cut slope 40, and then to the front block 10 Inject the crushed stone 60 into the back of the formed hole 70 and the front block 10 in a width of about 20 cm to impart shear stress, and fill the backfill material such as earth and sand on the back of the crushed stone 60 20) to form a bar, in which the geogrid 30, which is a geosynthetic material, is placed in the fill layer 20 so as to reinforce the fill layer 20.

By the way, the conventional block-type reinforcement earth retaining wall structure, as shown in Figure 2a, when the compaction construction of the fill layer 20 with compaction equipment such as roller 80, the problem often occurs when the filling phenomenon There was this.

In other words, the bulging phenomenon of the block-type reinforced earth retaining wall is a phenomenon in which the upper and lower blocks of the block cannot secure a relative position in design at an arbitrary block height, and the relative position of the front block is generally the front end of the front wall. It is held by (friction) resistance.

In this front block, the shear resistance of the wall is the working earth pressure, the connection strength and vertical spacing of the stiffeners, and the shear resistance of the front block. Are affected.

At this time, the shear force of the front block is changed according to the height of the wall of the front block, as shown in Figure 2 (b), the analysis of the load of the reinforced soil retaining wall is analyzed as a continuous beam under continuous distribution load (earth pressure) (United States Steel, 1972).

This analytical method presents a shear force diagram in which the maximum shear resistance as shown in FIG. 2 (b) is generated at the reinforcement laying surface, and the shear force diagram is a reinforcement laying surface which progresses from the top end of the reinforced soil retaining wall to the bottom end ( It is created by the sum of the unbalanced horizontal forces at the top points.

At this time, the laying surface of the reinforcement The unbalanced horizontal force at point) should be addressed by the shear resistance at that height.

The maximum shear force exerted on any face is therefore the difference between the horizontal force above the face under consideration and the tension of the stiffener available.

Here, the shear resistance of the front block in any plane shown in Figure 2 (c) Is calculated by equation (2.5).

Shear resistance ) Is determined by the weight of the front block by the hinge height concept.

(2.5)

here, : Ultimate cohesion by block friction test (t / m)

: Indicates the ultimate friction angle (。) by connection strength test.

At this time, the safety factor of the horizontal activity and the shear resistance is the safety factor of the horizontal activity ( ) And shear resistance ) To reflect the calculation of resistance to full stomach.

Here, each safety factor should apply at least 1.5.

Safety factor of shear resistance Is calculated by the following equation (2.6).

(2.6)

here, : Horizontal earth pressure acting on the front block (t / m)

: Tensile force induced by stiffener (t / m)

When the shear force value acting on the front block 10 designed in the above manner is out of the design value when the compaction layer 20 is compacted by equipment such as the roller 80, a batch phenomenon occurs.

On the other hand, reportedly surveyed in Korea Aggregate Association, the annual domestic aggregate demand is currently about 100 million 6 10 million m ³ in 1995, which reached about 3 trillion.

Such domestic aggregate supply and demand is becoming difficult to procure natural aggregate after raising awareness of environmental conservation.

As described above, the conventional front block 10 has a disadvantage in that the front block 10 is caused by the compaction construction after the construction, causing a phenomenon of swelling, and by using the crushed stone 60 for compaction, when the rainfall is completed after construction is completed. There was a problem of generating structural defects caused by soil loss of the backfill layer.

In addition, the existing retaining wall structure is required to more effectively compensate for structural defects such as destruction of the natural environment due to the construction of crushed stone, uneconomical efficiency, soil loss due to rain.

The present invention was devised to supplement the above problems, the object of the present invention is the problem of drainage using natural aggregates, such as the above-mentioned crushed stone, damage of natural landscape, uncomfortable construction, loss of soil by rain, rain In order to improve the economics, and to supplement the loading phenomenon of the retaining wall structure at the time of compaction, it is to provide a load preventing structure of the retaining wall reinforced with the back surface of the front block by using the EPS compression block capable of manpower construction.

1a and 1b is a partial cutaway perspective view and side cross-sectional view showing a conventional retaining wall structure,

Figure 2a is a side cross-sectional view showing a full stomach phenomenon occurring during compaction construction in a conventional retaining wall structure,

Figure 2b is a shear force diagram and earth pressure distribution diagram shown in a conventional retaining wall structure,

Figure 2c is a free body diagram for the full load phenomenon occurring in the conventional retaining wall structure,

Figure 3 is a first embodiment showing the structure of preventing the full load of the retaining wall using the CS compression block according to the present invention,

Figure 4 is a second embodiment showing a load preventing structure of the retaining wall using the CS compression block according to the present invention.

* Description of the symbols for the main parts of the drawings *

1,1a: EP compression block 1b: Insertion protrusion

10: front block 20: fill layer

30: geogrid 40: cut slope

50: concrete foundation 60: crushed stone

70: hole

The present invention for achieving the object of the present invention as described above is a front block that is laminated at a certain distance from the slope required the retaining wall, the crushed stone is put on the back of the front block, the geogrid between the input site and the slope of the crushed stone In the general retaining wall structure to form a fill layer by laying with a backfill material such as earth and sand while laying at regular intervals, when the ground layer is compacted by compacting equipment such as a roller, the retaining wall is prevented from being filled. Instead of the hole formed in the front block and the front block backing the crushed stone is characterized in that the adhesive block (EPS) compression block having a thickness of about 2 ~ 10cm on the front block back to a certain thickness and laminated.

At this time, the EP compression block is manufactured to have the same size as the height of the front block and at the same time the insertion protrusion protruding in the upper portion of one side of the EP compression block is formed, the insertion groove which can be fixed by inserting the insertion protrusion It is formed on the front block, the EP compression block may be attached to the front block through the fitting coupling.

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

At this time, in the structure of the retaining wall according to the present invention described in the embodiment for the same components as the prior art the same name and the detailed description thereof will be omitted.

Accompanying drawings, Figure 3 is a first embodiment showing the structure of the retaining wall using the CS compression block according to the present invention, Figure 4 is a load preventing structure of the retaining wall using the CS compression block according to the present invention Fig. 2 shows the second embodiment.

As shown in FIG. 3, the retaining wall structure according to the present invention is constructed in the form of a retaining wall by stacking the front block 10 on the concrete foundation 50 in close proximity to the cut slope 40, and the front block 10. EPS compression block 1 having a thickness of about 2 ~ 10cm along the back side is bonded to a certain thickness and laminated structure.

At this time, a much smaller amount of crushed stone 60 is introduced into the rear of the CS compression block 1 than before, and then the fill layer 20 that is filled with backfill material using earth and sand as in the prior art. At the same time, the geogrid 30, which is a geotextile material, is inserted and placed in a predetermined layer to reinforce the fill layer 20.

In the present invention, unlike the conventional structure in which the crushed stone 60 is put into the hole 70 formed in the front block 10, the crushed stone 60 does not need to be put into the hole 70 of the front block 10.

This is because the EP compression block 1 attached to the back of the front block 10 sufficiently corresponds to the earth pressure of the fill layer 20 acting on the front block 10.

Here, the EP compression block (1) is made of a block by compressing EPS (Expanded Poly-Styrene), which is a porous lightweight material commonly referred to as 'Valfoschiropol', the EP is granulated A foamed resin is obtained by adding a blowing agent to a polystyrene resin in the form, followed by heating and softening, and simultaneously foaming a gas.

The PS compression block 1 having such a material property is made of a compression block having a square shape of about 2 to 10 cm in thickness and about 120 to 160 cm and attached to the rear surface of the front block 10, When the crushed stone 60 is inserted into the hole 70 and the rear surface of the conventional front block 10, the load burden acting on the front block 10 is reduced as well as the crushed stone is stacked on the side surface thereof. 60) and when filling the fill layer 20, the PS compression block (1) is distributed to support the load it is possible to prevent the full stomach phenomenon.

In addition, it is possible to greatly reduce the load burden of the front block 10 contributes to the stability of the building (retaining wall).

On the other hand, Figure 2 shows a second embodiment according to the present invention.

In the second embodiment of the present invention, when attaching the PS compression block (1a) to the front block 10, it has been proposed as a way to improve the workability than in the first embodiment.

That is, in the second embodiment of the present invention, unlike the first embodiment, the PS compression block 1a having the same size as the height of one front block (approximately 20 cm) is manufactured and the PS compression block ( It characterized in that the insertion projection (1b) protruding in one side upper end portion of 1a).

At this time, in order to attach the above-described compression compression block (1a) to the front block 10, the insertion projection (1b) formed in the compression compression block (1a) is inserted on the front block 10 that can be fitted. It is a natural structural feature that the grooves must be formed first.

As such, when the insertion grooves and the insertion protrusions 1b are formed in the front block 10 and the EP compression block 1a, respectively, the EP compression block 1a is attached to the front block 10 before the retaining wall construction. Not only can the retaining wall construction be in a state, but even if the PS compression block 1a is attached to the front block 10 during the retaining wall construction, the attaching operation can be performed more smoothly, and thus the construction property is greatly improved.

In this way, when the soil is deposited on the rear surface of the retaining wall, the compression characteristics of the EPS compression block (1,1a), which is in the limelight by the soft ground road construction method, is prevented to prevent the filling by the compaction equipment. By using the EPS compression blocks 1 and 1a to accommodate the deformation of the soil due to the compaction, the deformation of the front block 10 (batch phenomenon) is suppressed.

In addition, the present invention can significantly reduce the amount of crushed stone 60 by using the EP compression block.

As described above, according to the present invention, unlike the existing block, the use of crushed wastewater does not use, and thus, complaints related to the damage of natural landscape, which is a problem of drainage using natural aggregates such as crushed stone, transportation and compaction, etc. are caused. They can reduce their possessions and effectively cope with sensitive environmental problems.

In addition, the present invention can prevent the filling of the front block caused by the compaction of equipment due to the compressibility of the EPS material, as well as improve the stability of the structure according to the earth pressure of the front block reduced There is a characteristic to let.

Claims (2)

The front block stacked at a certain distance from the slope where the retaining wall is needed, the crushed stone that is put on the back of the front block, and the geogrid is laid at regular intervals between the input site and the slope of the crushed stone In a general retaining wall structure intended to form a layer, When compacting the fill layer with compaction equipment such as a roller, the thickness of the front block is 2 to 10 cm in place of the crushed stone that was put in the front block and the hole formed in the front block to prevent the filling of the retaining wall. Retaining wall prevention structure of the retaining wall, characterized in that to laminate by bonding a certain thickness of the EP compression block having a certain thickness. The method of claim 1, The EP compression block is manufactured to have the same size as the height of the front block, and at the same time, a protruding insertion protrusion is formed at an upper portion of one side of the EP compression block, and the insertion protrusion may be inserted and fixed. Grooves are formed in the front block, the retaining wall of claim 2, characterized in that the EP compression block is attached to the front block through the fitting coupling.