KR20200008914A - Backfill load reduction method with multilayer lightweight block and the structure thereby - Google Patents

Abstract

The present invention relates to a new construction method which maximizes an effect of reducing an upper load of an underground structure and a structure for reducing an upper load of an underground structure thereby. In particular, the method for reducing an upper load of an underground structure comprises: a step of constructing an underground structure; a step of burying the underground structure; a step of locating an upper high-compression lightweight member at an upper portion of the underground structure; and a step of burying the upper high-compression lightweight member. Therefore, earth pressure applied to the underground structure is alleviated, and a seismic wave can be counteracted. The method further comprises: a step (1) of constructing a side pressure reducing unit, in which a side surface high-compression lightweight member comes in contact to be located, in order to respond to a side surface horizontal pressure; a step (2) of locating a base unit high-compression lightweight member on the outside of a base unit where an upper structure of the underground structure and the ground meet, in order to supplement the base unit; and a step (3) of allowing at least one of the layers of a multi-layer high-compression lightweight member to have an elastic coefficient different from that of other layers. Therefore, a load at the upper portion of the underground structure can be reduced, while counteracting a dynamic load such as a seismic wave.

Description

BACKFILL LOAD REDUCTION METHOD WITH MULTILAYER LIGHTWEIGHT BLOCK AND THE STRUCTURE THEREBY}

The present invention relates to reducing the earth pressure applied to the underground structure by using a high-compression lightweight member, for example 'geofoam'. In the present specification, 'underground structure (地 中 構造物)' may also be referred to as an underground structure, a generic term for those that are built or installed under the surface. For example, a concrete structure of a ramen structure or an arch structure used as a roadway, a sidewalk or an ecological passage under a road, a box-shaped culvert, various structures using corrugated pipes, various conduits, and also flexible pipes Anything that is under earth pressure if called underground is called underground structure. Although the present specification shows and illustrates an arch structure (tunnel shape) as an example among the various underground structures mentioned above, the technical idea of the present invention is to be applied to any earthquake load in case of an earthquake load and an earthquake while being located underground. Can be.

More specifically, the present invention relates to a new concept construction method that maximizes the effect of reducing the upper load of underground structures, and to a structure of lowering the upper load of underground structures.

Recently, as the interests in solving the land shortage problem, restoring the living culture, and improving the quality of life of the citizens have been concentrated on the methods of urban regeneration, eco-friendly ecological parks and the utilization of underground spaces, fundamental solutions and concrete methods for the stable structure and construction of underground structures An application plan is needed.

In addition, the social awareness due to the recent earthquake is increasing. There is a consensus that the Republic of Korea is not an earthquake safe zone and that active response is needed. Under seismic loads, the underground structures are greatly affected by the surrounding ground displacements, and when the earthquake damages the underground structures, it is difficult to recover them. Nevertheless, unlike steel structures, there is a lack of review on seismic materials and seismic structural design for underground structures. Above all, it is not easy to improve the seismic resistance of the already constructed underground structures. The present invention is to prevent the damage to the underground structure when the earthquake occurs by forming a buffer for absorbing seismic waves in the underground structure already constructed.

When an earthquake occurs, a dynamic load is generated on the underground structure. The dynamic load is a structurally very bad effect on the underground structure as a moving load in which the load action point moves and a variable load with repeated impacts. There is a need to protect the underground structure by dissipating or dissipating such a dynamic load to some extent. Specifically, according to the present invention described later, it becomes possible to cope with such a dynamic load such as seismic waves.

For example, in the construction and maintenance of various roads such as highways and local roads, in some cases, high backfill may be required on the underground structure, and in this case, the high backfill portion may have a fatal effect on the underground structure. It may be done. Most of the arches and underground structures that are buried under the ground are reinforced concrete structures so that they can receive enough earth pressure and loads. There is a difficulty with technology. In addition, when a dynamic load such as an earthquake occurs, it is not easy to respond.

In order to increase the length of the underground structures, the design and construction technologies are needed to secure the earth pressure and load, and to secure economic feasibility and safety.

To this end, the present invention is to provide a structure for replacing a predetermined amount of existing ground with a geofoam (geofoam) on top of the underground structure. This can be called 'Soft Material Zone' in comparison with the existing ground.

On the other hand, when substituting some geoforms for ground arches or ground structures, the theoretical and empirical studies are needed to investigate the effects of soft structures on arch structures such as arch structures. Related studies have been conducted by some scholars in the United States and Canada, but specific response structures have not been disclosed.

The present invention is to provide a new type of technology that can reduce the large earth pressure acting on the underground structure by up to 80% by using a high-pressure compressive geofoam surrounding the entire underground structure. The inventor of the present invention refers to this as 'ETI technology', which expresses 'Embedded Trench Installation'.

The present invention further proposes an empirical test method for the ETI technique according to the present invention using the underground arch structure. According to the present invention, it is possible to propose material optimization and design guidelines of the high-compression lightweight member of the ETI technique.

In response to such a problem, a method of replacing a portion of the upper portion of the underground structure with a lightweight member has been proposed, which may be referred to as using the ITI method. 'ITI' in the 'ITI' method stands for 'Imperfect Trench Installation', which forms part of the backfill space as a lightweight member layer in the 'trench installation' method of installing pipes below the ground surface. .

To present in more detail the related prior art Republic of Korea Patent Publication No. 0462529 relates to the 'covering method of underground structure using waste styrofoam particles'. This prior art provides a lightweight soil material applied with soil and waste styrofoam generated at the construction site without bringing backfill materials such as retaining walls and cover material of underground structures from the outside, and the structure backfill method and underground structure cover method using the same. .

Republic of Korea Patent Publication No. 0462529 (2004. 12. 17.)

The present invention reduces the load of the upper of the underground structure by substituting a part of the cover of the upper part of the underground structure with a high-pressure compressive lightweight member, and can respond to dynamic loads such as seismic waves, but provides a means for supplementing the foundation of the base, which can be called a weak part The construction method is proposed.

 The present invention intends to propose an underground structure corresponding to the increasing earth pressure in the ground structure and its construction method.

The present invention is to propose a structure of a geoform to increase the effect more in using a high-compression lightweight member block, such as geofoam (geofoam).

In order to solve the above problems, the present invention, the construction of the underground structure, the step of embedding the underground structure, the step of placing the upper high-compression lightweight member on the underground structure, the step of embedding the upper high-compression lightweight member To reduce the earth pressure to be loaded on the underground structure, including, and propose a method for reducing the upper load of the underground structure corresponding to the seismic wave.

The present invention may further include a side pressure reducing part construction step of closely contacting and positioning the side high-compression lightweight member in a side portion of the underground structure, and may be characterized in that it corresponds to the side horizontal pressure.

In addition, the present invention includes the step of forming an opening by attaching the upper ground of the existing underground structure, positioning the upper high-pressure compressive lightweight member on the opening which is the upper of the underground structure, the step of filling the opening Therefore, to reduce the earth pressure applied to the underground structure and propose a method for reducing the upper load of the underground structure corresponding to the earthquake wave.

The present invention may further include a side pressure reducing part construction step of closely contacting and positioning the side high-compression lightweight member in a side portion of the underground structure, and may be characterized in that it corresponds to the side horizontal pressure.

The high-compression lightweight member of the present invention may be characterized in that the geofoam (geofoam).

The upper high-pressure compressive lightweight member and the side high-pressure compressive lightweight member of the present invention may form a front (high-side) high-pressure compressive lightweight member may be characterized in that the structure surrounding the entire underground structure.

The front high-compression lightweight member of the present invention is pre-fabricated corresponding to the outer surface of the underground structure, two or more injection holes in the form of a drilled hole is formed, the front high-compression lightweight member by injecting a soft urethane into the injection hole It may further comprise the step of uniformly adhering to the underground structure.

The present invention is constructed by the above-described underground structure upper load reduction method, and also discloses an underground structure upper load reduction structure, characterized in that the upper and side portions of the underground structure are surrounded by a highly compressible lightweight member.

In order to solve the above problems, the present invention, the construction of the underground structure, the step of embedding the underground structure, the step of placing the upper high-compression lightweight member on the underground structure, the step of embedding the upper high-compression lightweight member In the underground structure upper load reduction method to reduce the earth pressure to be loaded on the underground structure, including the earthquake wave, the underground structure is composed of an upper structure and a base for supporting the upper structure in the base, It provides a underground structure upper load reduction method characterized in that to supplement the base by further comprising the step of positioning the base high-compression lightweight member on the outside of the base where the superstructure and the base meet.

In addition, the present invention includes the step of forming an opening by adhering the upper ground of the existing underground structure, positioning the upper high-pressure compressive lightweight member on the opening that is the upper of the underground structure, including the step of filling the opening In the earth load reduction method for reducing the earth pressure applied to the structure and corresponding to the earthquake wave, the underground structure is composed of an upper structure and a base for supporting the upper structure in the base, and the upper structure and the base of the underground structure Disclosing the underground structure upper load reduction method characterized in that it further comprises the step of positioning the base high-compression lightweight member on the outside of the base meets.

Injecting a soft urethane between the base portion of the high-compression lightweight member and the underground structure of the present invention may further comprise the step of uniformly bonding the base portion of the high-compression lightweight member and the underground structure.

The height of the base portion high-compression lightweight member of the present invention is 20% of the height of the underground structure, the width of the base portion high-compression lightweight member may be characterized in that 20% of the width of the underground structure.

The present invention is constructed by the above-described underground structure upper load reduction method, and also discloses a structure for replacing the upper part of the foundation underground structure, characterized in that the high-pressure compressive lightweight member is located on the upper portion and the base portion of the underground structure.

The present invention, in order to solve the above problems, the construction of the underground structure, including the step of placing the high-pressure compressive lightweight member on the open portion of the upper portion of the underground structure, the load on the underground structure including the step of backfilling the opening In the underground structure load reduction method for reducing earth pressure and responding to seismic waves, the high-compression lightweight member is a multi-layer high pressure lightweight member having two or more layers, and at least one of the layers of the multi-layer high pressure lightweight member. Discloses a method for reducing the load on the underground structure, which has a different modulus of elasticity from other layers.

In addition, the present invention comprises the step of forming the opening to expose the underground structure by opening the ground, positioning the high-pressure compressive lightweight member on the opening that is above the underground structure, the underground structure including the step of backfilling the opening In the underground structure load reduction method for reducing earth pressure applied to the earthquake wave and responding to the seismic wave, the high-compression lightweight member is a multi-layer high-pressure lightweight member having two or more layers, and any of the layers of the multi-layer high-pressure lightweight member. At least one proposes a method for reducing the load on the underground structure, characterized in that it has a different modulus of elasticity from other layers.

The multi-layer high-pressure lightweight member of the present invention is composed of three layers in which the intermediate layer is formed, the upper layer is formed on the upper surface of the intermediate layer, the lower layer is formed on the lower surface of the intermediate layer, the intermediate layer is The upper layer and the lower layer may be characterized in that the elastic modulus is different.

The elastic modulus of the upper layer and the lower layer of the present invention is the same, the elastic modulus of the intermediate layer may be characterized in that about 90% of the elastic modulus of the upper layer and the lower layer.

The present invention is constructed by the above-described load reduction method of the underground structure using the multi-layer lightweight member, the upper part of the underground structure, characterized in that the lightweight member of the multi-layer structure including a layer having a different modulus of elasticity is located on top of the underground structure A load reduction structure is also disclosed.

According to the present invention, by replacing part of the cover of the upper part of the underground structure with a high-pressure compressive lightweight member, it is possible to reduce the load on the upper part of the underground structure and to cope with dynamic loads such as seismic waves, but a part of the backfill of the base of the base which can be called a weak part By substituting the high-compression lightweight member can complement the base.

According to the present invention, by replacing a part of the cover of the upper portion of the underground structure with a high-pressure compressive lightweight member to reduce the load of the upper portion of the underground structure, and in addition to the side portion of the underground structure further side pressure reduction portion for close contact with the high-pressure lightweight member Including, in response to the earth pressure increases to the side of the underground structure according to the substitution of the high-pressure compressive lightweight member of the top of the underground structure to complement the side of the underground structure, and can respond to dynamic loads, such as seismic waves.

According to the present invention, the above-mentioned effect is enhanced by replacing the backfill portion with a multi-layered high-compression lightweight member including a layer having a different modulus of elasticity, and more particularly, when the dynamic load such as an earthquake load is applied. have.

1 is a conceptual view showing that the upper high-pressure compressive lightweight member according to an embodiment of the present invention is located on the underground structure.
Figure 2 is a conceptual diagram showing a load reduction structure of the upper portion of the foundation displacement underground structure according to an embodiment of the present invention.
3 is a view conceptually showing that the front high-compression lightweight member wrapped the underground structure according to an embodiment of the present invention.
4 is a view conceptually illustrating the injection of a soft urethane through an injection hole formed in the front high-pressure compressive lightweight member according to an embodiment of the present invention.
5 is a conceptual view showing that the multi-layered lightweight member according to an embodiment of the present invention is applied to an underground structure.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. The present invention is not limited to the embodiments disclosed below, but can be implemented in various different forms, only this embodiment is to make the disclosure of the present invention complete and complete the scope of the invention to those skilled in the art It is provided to inform you.

■ Load reduction method on the upper part of underground structure

The present invention may not only be applied when constructing underground structures in the first place, but may also be used as a method of improving the underground structure for maintenance of underground structures already constructed and buried in the ground.

When the present invention is applied to the construction of the first underground structure, the first step is to construct the underground structure, and then the embedded underground structure is buried, the 'upper high-compression lightweight member' is placed on top of the underground structure, Just by embedding the upper high-compression light weight member may be referred to as a method for reducing the load on the underground structure to reduce the earth pressure partly and to respond to seismic waves. The upper high-compression lightweight member is generally in the form of a block, meaning that it is in the form of a solid having a constant volume rather than a particle form such as soil. 1 is a conceptual view showing that the upper high-pressure compressive lightweight member according to an embodiment of the present invention is located on the underground structure.

When the underground structure is composed of an upper structure and a base for supporting the upper structure at the base, the present invention further includes the step of placing the base high compression lightweight member on the outside of the base where the upper structure and the base of the underground structure meet. Complement the foundation by including. The base portion refers to the footing portion at the bottom of the underground structure. This part needs to be supplemented because of the large external earth pressure.

In addition, in the case of installing a high-compression lightweight member that is a solid block on the upper part of the deeply buried structure, there may be a problem that the earth pressure of the upper portion moves to the lower portion and acts as an excessive load on the side of the structure. To this end, the present invention is to replace the back-filling portion of the side, in particular the lower end of the base with a high-pressure compressive lightweight member of the base to cope with the earth pressure and dynamic load that can act on the foundation of the structure.

Such a reduction method can be applied to existing underground structures as well as the case of applying the above-mentioned underground structures. In this case, by opening the upper ground of the existing underground structure to form an open portion, by placing an upper high-pressure compressive lightweight member in the open portion of the upper underground structure, by reducing the earth pressure applied to the underground structure by filling the opening Can respond to seismic waves. In this case, the base portion may further include a step of placing the base high-compression lightweight member on the outer side of the base portion where the superstructure of the underground structure and the base meet.

The above 'high compression lightweight member' refers to a material that is lighter, such as soil filled with backfill, and has a physical property that can be maintained to some extent in the ground. One such material is geofoam.

Geofoam, one of geosynthetics, is closely related to the construction technology of civil engineering used in the environment of sand, soil, gravel, etc. Expanded polystyrene polymers made of bulky blocks (expanded polystyrene, called 'EPS') or extruded polystyrene polymers (called 'XPS'), etc. EPS blocks are one of the most widely used geoforms, and the 'Iso Pink' brand of Byucksan Co., Ltd. is distributed as XPS blocks.

The foundation high pressure lightweight member and the underground structure should be in close contact. The present invention provides a step of uniformly bonding the base high-pressure compressive lightweight member and the underground structure by injecting a soft urethane between the base high-pressure compressive lightweight member and the underground structure.

The size of the base high compression light weight member is relative to the scale of the underground structure. Preferably, the height of the base high-pressure lightweight member is about 20% of the height of the underground structure, and the width of the base high-pressure lightweight member is preferably about 20% of the width of the underground structure. Figure 2 is a conceptual diagram showing a load reduction structure of the upper portion of the foundation substructure replacing the embodiment according to the present invention.

■ Load reduction method on the upper part of underground structure for underground pressure

The present invention not only reinforces the foundation described above, but also provides a configuration that entirely complements the side portions of the structure in response to increasing lateral earth pressure.

As described above, if the present invention is applied when constructing an underground structure, the earthquake wave may be reduced by partially placing an upper high-compression lightweight member on top of the underground structure when the underground structure is embedded. Can correspond to.

However, in spite of the positive effect of such a structure, as described above, there may occur a problem of increasing the side pressure on the underground structure, the present invention is in close contact with the side high-compression lightweight member in addition to the side portion of the underground structure It further comprises the step of positioning the pressure reducing portion to position.

As described above, the abatement method according to the present invention can be applied to existing underground structures, and forms an opening by opening the upper ground of the existing underground structure, and places an upper high-compressibility lightweight member on the opening that is the upper of the underground structure. The side portion of the pressure reduction part may be constructed by filling the opening part and placing the side high-compression lightweight member in close contact with the side part of the underground structure.

According to the present invention, since the upper high-pressure compressive lightweight member is in close contact with the upper portion of the underground structure and the high-pressure compressive lightweight member is disposed on the side, all surfaces of the underground structure, ie, the entire surface, are wrapped in a high-pressure compressive lightweight member. The upper high-pressure compressive lightweight member and the side high-pressure compressive lightweight member form a front (high-side) high-pressure compressive lightweight member to be a structure surrounding the entire underground structure. 3 is a view conceptually showing that the front high-compression lightweight member wrapped the underground structure according to an embodiment of the present invention.

For convenience of construction, the front high-compression lightweight member is preferably pre-fabricated (fabricated) according to the underground structure. According to the scale of the underground structure, the front high-compression lightweight member may be installed in two or more modules. For example, in the case of a tunnel-shaped arched underground structure, the front high-pressure compressive lightweight member is modularized into an arc shape covering an upper portion and an arc shape covering left and right sides, and can be closely adhered to the underground structure.

In addition, the pre-fabricated high pressure lightweight member should be constructed in close contact with the underground structure. It must be closely adhered to the underground structure to prevent post-disturbance such as backfilled soil after construction, and it can be appropriately dispersed when external loads or earthquake loads are applied to the underground structure through the front high-compression lightweight member. . To this end, the present invention forms an injection hole in the form of a hole drilled in the front high-pressure compressive lightweight member and injects a soft urethane between the front high-compression lightweight member and the underground structure through the injection hole to the front high-pressure compressive lightweight member A further step is provided to ensure uniform adhesion to the structure. As such, by uniformly adhering the front high-compression lightweight member to the underground structure, it is possible to maximize the dispersing effect on dynamic loads (for example, seismic waves, etc.) as well as loads placed on the underground structures. 4 is a view conceptually illustrating the injection of soft urethane through an injection hole formed in the front high-pressure compressive lightweight member according to an embodiment of the present invention.

■ Method of reducing load on underground structures using multi-layer lightweight member blocks

As described above, the present invention partially replaces the backfill portion with a high-compression lightweight member block to reduce the load on the underground structure and cope with dynamic loads such as seismic waves.

On the other hand, the high compression light weight member block preferably has a multi-layer structure. In particular, when the modulus of elasticity of several layers is different, the modulus of elasticity may be improved by the action of layers having different modulus of elasticity when dynamic load such as a floor load or seismic wave is applied. In this way, if the high-compression lightweight member has a multi-layered structure, and the high-compression lightweight member acts as a high modulus of elasticity complex than the inherent elastic modulus, the high-compression lightweight member can be made lighter and more economical. Since the action is efficient, it responds more preferably to load loads and dynamic loads.

The present invention discloses that the multi-layered lightweight member comprises three layers, the most efficient when the modulus of elasticity of the layer is around 90% of the modulus of elasticity of the other layer in contact with the upper and lower surfaces of the middle layer. . 5 is a conceptual view showing that the multilayer structure lightweight member according to an embodiment of the present invention is applied to the underground structure.

This can be confirmed through simulation experiments. Through the experimental data, it can be seen that the composite elastic modulus value which is more stably behaved when the middle layer modulus of the multilayer structure lightweight member having three layers is about 90% is obtained.

The present invention has been described with reference to specific embodiments, but the present invention is not limited thereto. Of course, modifications and variations are possible within the scope of the technical idea of the present invention.

10 underground structures
11 ground
12 backfill
20 High compression light weight member
40 High-compression lightweight member
50 High-compression lightweight member
51 inlet
60 Multi-layer high pressure lightweight member

Claims (12)

Constructing the underground structure,
Embedding the underground structure,
Positioning an upper high-compression lightweight member on the underground structure;
Reducing the earth pressure loaded on the underground structure, including the step of embedding the upper high-compression lightweight member and corresponding to the earthquake wave
Underground load reduction method.
According to claim 1,
In addition to the side portion of the underground structure further comprises a side pressure reducing portion construction step of placing in close contact with the side high-pressure compressive lightweight member, characterized in that corresponding to the side horizontal pressure
Underground load reduction method.
According to claim 1,
The high-compression lightweight member is a multi-layered high-compression lightweight member having two or more layers,
At least one of the layers of the multi-layer high-compression lightweight member has a different modulus of elasticity from other layers
Underground load reduction method.
Attaching the upper ground of the existing underground structure to form an open portion,
Positioning an upper high-compression lightweight member on the open portion that is above the underground structure,
Responding to earthquake waves to reduce the earth pressure loaded on the underground structure including the step of filling the opening
Underground load reduction method.
The method of claim 4, wherein
In addition to the side portion of the underground structure further comprises a side pressure reducing portion construction step of placing in close contact with the side high-pressure compressive lightweight member, characterized in that corresponding to the side horizontal pressure
Underground load reduction method.


The method of claim 4, wherein
The high-compression lightweight member is a multi-layered high-compression lightweight member having two or more layers,
At least one of the layers of the multi-layer high-compression lightweight member has a different modulus of elasticity from other layers
Underground load reduction method.
The method according to claim 2 or 5,
The upper high-pressure compressive lightweight member and the side high-pressure compressive lightweight member form a front (high-side) high-pressure compressive lightweight member is characterized in that the structure surrounding the entire underground structure
Underground load reduction method.
The method of claim 7, wherein
The front high-compression lightweight member is pre-fabricated corresponding to the outer surface of the underground structure, two or more injection holes in the form of a drilled hole is formed,
Injecting the soft urethane into the injection hole further comprises the step of uniformly adhering the front high-pressure compressive lightweight member to the underground structure
Underground load reduction method.
Constructed by the load reduction method of the underground structure of claim 2 or 4,
The upper and side portions of the underground structure is surrounded by a high-pressure compressive lightweight member
Underground structure upper load reduction structure.
The method according to claim 3 or 6,
The multi-layer high pressure lightweight member is composed of three layers, the intermediate layer is formed,
An upper layer is formed on an upper surface of the intermediate layer, and a lower layer is formed on a lower surface of the intermediate layer.
The intermediate layer is characterized in that the elastic modulus is different from the top layer and the bottom layer
Underground load reduction method.
The method of claim 10,
The elastic modulus of the upper layer and the lower layer is the same,
The modulus of elasticity of the intermediate layer is about 90% of the modulus of elasticity of the upper and lower layers.
Underground load reduction method.
Constructed by the load reduction method of the underground structure using the multi-layer high-pressure lightweight member of claim 3 or 6,
Characterized in that the lightweight member of the multi-layer structure including a layer having a different modulus of elasticity on top of the underground structure
Underground structure upper load reduction structure.

Images