KR100956880B1 - bearing power reinforce method by casing exclusion type step grouting of microfile - Google Patents

Abstract

The present invention, in the micropile method, is installed from the ground surface to a rock layer through a solid soil layer or a sand layer having a certain supporting force, such as to prevent the depression of the drilling hole during operation to prevent the grout hole in the casing to maintain the grouting hole At the same time as the grouting operation, the grout material is pulled out sequentially according to the height at which the grouting is formed on the ground having a certain supporting force such as a solid soil layer or a sand layer, and the pressurized grout material is integrally formed with a ground layer having a constant supporting force such as a solid soil layer or a sand layer. Casing-removable step grouting micropile which removes the casing made of steel pipes from the ground by digging into the ground, and grinds into a ground layer with a certain supporting force such as a solid soil layer or a sand layer, and is united together to secure more ground support. The method relates to a rock layer in order to prevent the grouting hole from filling up due to the collapse of the soft layer in the micropile construction method for obtaining a tensile and compressive force in a deep soil such as a solid soil layer or a sand layer. Geodetic perforation process having a certain supporting force, such as a solid soil layer or a sand force layer to sequentially insert the grouting hole by using a variety of perforator and to connect a plurality of casings without ejection holes by coupling to the depth to the depth, and the solid soil layer Or a rock punching process for drilling a grouting hole to match a casing in a rock layer formed in a lower layer having a certain supporting force, such as a sand force layer, and a casing and rock drilling, which are installed in a ground drilling process having a certain supporting force such as the solid soil layer or a sanding layer. In the grouting hole formed in the process A tread bar insertion step of installing a tread bar of micropile, a rock bed grouting step of filling grout into a grouting hole of a rock bed layer in which a micropile tread bar is inserted through a casing in the tread bar insertion step, and grouting of the rock layer The grout, which has completed the internal filling of the hole, is filled in the strata with a certain supporting force, such as a solid soil layer or a sand layer, and at the same time, in a grouting hole of a strata with a certain supporting force, such as a solid soil layer or a sand layer, which was held as a casing while removing casings. Filling the grout with a certain pressure so that the grout penetrates through the strata with a certain supporting force, such as a solid soil layer or a sand layer, and binds it with a solid soil layer or a sand layer with a solid soil layer or a sand layer with a certain supporting force such as a sand layer. Carried by resin grouting process having a power, or when the to be constructed soil layer is deep soil with a resin layer having a predetermined supporting force supporting layer, such as embedded and sediments and solid tosacheung or force layer do not have the predetermined force that does not have the constant force In the landfill and sedimentary layers, the grout that remains without removing the casing and is pressurized with a constant pressure penetrates only the layers having a certain supporting force, such as a solid soil layer or a sand layer, to be united with a layer having a certain supporting force such as a solid soil layer or a sand layer. By dispersing and absorbing the tensile and compressive forces acting on the micropile not only in the rock layer but also in the solid soil layer or the sanding layer, it satisfies the tensile and compressive stress required in the field while the construction depth of the micropile is short. To be a novel invention that can achieve a direct effect of the reinforcement to be reducing the cost of the construction more stable than the resin layer having a predetermined force, such as force or solid tosacheung layer recycle.

Rock layer, casing, coupling, micropile, acupressure plate, reinforced concrete footing, grout, perforator, grout injector

Description

Bearing power reinforce method by casing exclusion type step grouting of microfile

The present invention is a micropile construction method, which is installed to the rock layer through the ground layer having a certain supporting force, such as a solid soil layer or a sand force layer from the ground surface to prevent grind hole in the casing to prevent the depression of the drilling hole during the operation to drill the grout hole in the casing The grout is pulled out sequentially according to the height at which the grouting is formed on the strata having a constant supporting force such as a solid soil layer or a sand layer at the same time as the grouting operation, and the pressurized grout is integrally formed with a layer having a constant supporting force such as a solid soil layer or a sand layer. Removed casings made of steel pipes from the ground by forming them, and micropile casing-removing steps that grouted into solid soil layers or sand layers having a certain supporting force, such as a sanding layer, and united together to secure more ground support. Lau It relates to the force by the reinforcing method.

In general, the casing operation of inserting a casing made of steel pipe to the depth reaching the rock layer to prevent the filling of the perforated hole of the soft ground during the micro pile construction, and after the casing operation to the rock layer through the inside of the casing Punching work to grout the grouting hole using a variety of punching machines, Microfile inserting work to insert the microfile in the hole drilled in the drilling work, and grouting work to inject grouting liquid using the grouting mixer into the punching site where the microfile is inserted Is done in the order of.

The grouting liquid injected by the above operation is filled up to the rock layer in the casing and the lower part and hardened integrally with the ground together with the tread bar.

The micropile construction method is performed as a means for obtaining tensile and compressive forces in a deep support layer of the ground, which is a method of resisting tensile and compressive forces in consideration of the main surface frictional force of the rock layer by tread bars and grouting.

Therefore, until now, the focus is on fixing the micropile on the rock in order to obtain the required compressive and frictional forces in the structure. By buried the casing made of steel pipes in the ground, it is not possible to secure the support of the strata with constant support such as grout and solid soil layer or sand layer, so that the tensile and compressive forces should only depend on the frictional stress of the micropile inserted into the rock layer. By laying the casing in the ground after construction, the waste of resources and the casing oxidizing for a long time became a cause of rock instability.

The present invention provides a constant support force such as a solid soil layer or a sand layer in the micropile method, which has been performed as a means for obtaining tensile and compressive forces in a deep ground or a layer having a constant support force such as a solid soil layer or a sand layer described above. The steel pipe casing installed to maintain the grouting hole of the strata is buried as it is, so that the bond between the grout and the solid soil layer or sand layer has a certain supporting force, and at the same time, wastes resources and causes ground instability due to oxidation. In order to solve the problem that causes the problem of grouting, removing the casing to maintain the grouting hole of the strata with a certain supporting force, such as a solid soil layer or a sand layer, to reduce the waste of resources and a layer with a constant bearing force, such as grout and a solid soil layer or a sand layer Unity is improved The purpose is to make the construction more stable by reinforcing the tensile and compressive strength of the micropile by perfect construction.

The present invention for achieving the above object, in the micropile construction method in which the support layer was performed as a reinforcing means for obtaining tensile and compressive force in the deep ground, to reach the rock layer in order to prevent the perforation of the hole due to the collapse of the soil Using a variety of perforators to drill the grouting hole to the depth to be able to connect a plurality of casings without blow holes at the same time by a solid soil layer or a sand layer layer having a certain supporting force, such as a solid soil layer or a sand layer to insert sequentially, and the solid A rock drilling process for drilling grouting holes to match the casing in the rock layers formed in the lower layers of the soil layer having a constant supporting force such as the soil layer or the sanding layer, and the casings and rocks installed in the layered drilling process having the constant supporting force such as the solid soil layer or the sand layer. Tread bar is installed in the grouting hole formed in the drilling process A tread bar insertion process, a rock layer grouting process for filling grout into a grouting hole of a rock bed layer installed through a casing in the tread bar insertion process, and a grout having a solid soil layer or mortification that has completed internal filling of the grouting hole of the rock layer. The soil layer or sand layer with solid grout is filled by filling the grout in the grouting hole of the ground layer with a certain supporting force such as a solid soil layer or a sand layer, which is maintained as a casing while being filled up and removing casings sequentially while filling the strata with constant support such as layers. Solid soil layer or solid sand layer grouting through the strata with constant support force and solid soil layer or sand layer to be united with the soil layer with constant support force such as solid soil layer or dead sand layer. When the supporting layer is composed of a layer which has a certain supporting force such as a sand layer or a sand layer and a buried or sedimentary layer which does not have a constant support force, the grout is left in the landfill and sediment layer which does not have the constant support force without removing the casing and pressurized with a constant pressure. It penetrates only the layers with certain supporting force such as solid soil layer or sand layer to bond with the layers with certain supporting force such as solid soil layer or sand layer, so that the tension and compressive force acting on the tread bar can be rock layer as well as solid soil layer or sand force. The present invention relates to a casing-removing step grouting ground reinforcing method that allows the micropile to have a short depth of construction and to efficiently recycle resources by dispersing and absorbing even in a layer having a constant supporting force such as a layer.

As described above, the present invention provides that the grouting hole is filled by the collapse of the soil in the grouting method, in which the strata having a constant supporting force such as a solid soil layer or a sand layer or a supporting layer of the strata are performed as reinforcing means for obtaining tensile and compressive forces in the deep soil. In order to prevent it from being inserted into the casing that is inserted into the ground layer having a certain supporting force such as a solid soil layer or a sand layer without having a drill hole, the grout has a certain supporting force such as a solid soil layer or a sand layer by being pulled out and removed sequentially. Grout by dispersing and penetrating the strata to unite with a layer of constant support such as a solid soil layer or a sand layer to disperse the tensile force acting on the micropile not only in a rock layer but also in a layer with constant support such as a solid soil layer or a sand layer. Of By maximizing the abrasion and distributing the tensile force acting on the tread bar from the ground, the micropile has a short construction depth and effectively resists the ground, minimizing the length of the tread bar while satisfying the required tensile and compressive strength in the field while recycling the casing. It is a novel invention that can reduce the cost of construction and obtain a direct effect to more stably reinforce the strata with a certain supporting force, such as a solid soil layer or a sand layer.

Example 1

Referring to Fig. 1 illustrates a micropile construction method for obtaining tensile and compressive forces in a layer having a certain supporting force, such as a solid soil layer or a sand layer.

First step: Geotechnical perforation process with constant bearing capacity, such as solid soil layer or sand layer.

 In order to prevent the grouting hole from sinking due to the collapse of the soil, the grouting hole is drilled using a variety of perforators 70 to the depth that can reach the rock layer 20 and at the same time, a plurality of casings 30 having no ejection holes are coupled. Connected to the ring 31 is inserted sequentially until the rock layer 20 comes out.

At this time, there is no fear of invasion of foreign matter or groundwater into the casing 30 during operation since the spray holes are not formed in the casing 30, and the durability of the casing 30 is also large.

In this case, the blow holes are not drilled in the casing 30 because the casing 30 is pulled out and removed.

Second process: rock drilling process.

The grouting hole is drilled in the rock layer 20 formed in the lower layer of the ground layer 10 having a predetermined supporting force such as the solid soil layer or the sand layer to extend in line with the casing 30.

Step 3: insert the tread bar into the micro pile

The tread bar of the micropile 40 is inserted into the grouting hole formed in the rock drilling process so as to extend in line with the casing 30 installed in the ground drilling process having a certain supporting force such as the solid soil layer or the sand layer.

In this case, reinforcing bars or other reinforcing materials may be used in place of the tread bars of the micropile 40, but it is important to construct the absorbent to cope with most tensile and compressive stresses in the rock layer 20.

4th step: rock layer grouting process.

In the tread bar insertion process of the micropile, the grout 60 is filled by using the grout injector 80 into the grouting hole of the rock layer 20 in which the tread bar of the micropile is inserted through the casing 30. The grout 60 of the tread bar 40 and the rock layer 20 are integrally bound together.

5th process: Stratification grouting process which has a certain supporting force, such as a solid soil layer or a sand layer.

 The grout 60, which has completed the internal filling of the grouting hole of the rock layer 20, is filled in the ground layer 10 having a certain supporting force, such as a solid soil layer or a sand layer, and at the same time, the casing 30 is pulled out and removed to remove casing. The grout 60 filled by pressing and filling the grout 60 into the grouting hole of the ground layer 10 having a certain supporting force such as a solid soil layer or a sand layer, which was maintained at 30, has a constant supporting force such as a solid soil layer or a sand layer. Drill through the weak part of (10) and bind it with the ground layer 10 having a certain supporting force such as a solid soil layer or a sand layer, so that the construction depth is short and the construction depth is effectively resisted.

6th Step: Finishing Process

The acupressure plate 41 is coupled to the ground exposed portion of the grouted micropile 40 by the above-described process, and the reinforced concrete footing 50 is integrally cured.

Example 2

Referring to FIG. 2, a micropile construction method for obtaining a tensile and compressive force in a deep soil is made of a support layer composed of a layer having a certain supporting force such as a solid soil layer or a sand layer and a layer of landfill and sedimentation layer having a constant supporting force.

First step: a ground drilling process with a deep support layer.

In order to prevent the grouting hole from decaying due to the collapse of the deep soil 11, the supporting layer composed of the weathered soil layer 12 and the landfill and sedimentation layer 13 is provided with various perforators 70 to a depth that can reach the rock layer 20. By drilling the grouting hole by using a plurality of casings (30) having no ejection hole at the same time by coupling to the coupling 31 is inserted sequentially to grout the grouting hole in the deep ground (11).

At this time, there is no fear of invasion of foreign matter or groundwater into the casing 30 during operation since the spray holes are not formed in the casing 30, and the durability of the casing 30 is also large.

In this case, the blow holes are not drilled in the casing 30 because the casing 30 is pulled out and removed.

Second process: rock drilling process.

The grouting hole is drilled so that the support layer extends coincident with the casing 30 in the rock layer 20 formed in the lower layer of the deep ground 11.

Step 3: Micropile Insertion Process

The micropile 40 is inserted into the grouting hole formed in the rock drilling process so that the support layer extends in line with the casing 30 installed in the deep ground drilling process.

At this time, the reinforcement or other reinforcing materials may be used in place of the micropile 40, but it is important to construct the absorbent to cope with most tensile stress in the rock layer.

4th step: rock layer grouting process.

In the micropile inserting process, the grout 60 is filled using the grout injector 80 into the grouting hole of the rock layer 20 in which the micropile 40 is inserted through the casing 30. And the rock layer 20 to allow the grout 60 to be integrally bound.

Fifth step: weathered soil layer grouting process.

 The grout 60, which has completed the internal filling of the grouting hole of the rock layer 20, fills the weathered soil layer 12 of the deep ground 11, and simultaneously pulls up the casing 30 and removes the casing 30. The grout 60 penetrates through the weak part of the weathered soil layer 12 by filling the grout 60 in the grouting hole formed in the weathered soil layer 12 of the deep ground 11. It is to be integrated with the ground layer having a certain supporting force such as the layer so that the construction depth can be short and effective to resist earth pressure.

Step 6: Landfill and Sediment Grouting Process.

 The grout 60 is filled in the casing 30 in a state where the casing 30 is embedded by remaining the casing 30 in the landfill and deposition layer 13 generated on the weathered soil layer 12.

At this time, the casing 30 is advantageously to maintain a part of the buried in the weathered soil layer (12).

7th Step: Finishing Process

The acupressure plate 41 is coupled to the ground exposed part of the grouted micropile 40 by one step, and the reinforced concrete footing 50 is cured integrally therewith.

The present invention can be used immediately when the grouting construction to complement the strata with a certain supporting force, such as a solid soil layer or a sand layer is immediately available for industrial use.

1 is an exemplary view showing a process execution state of the present invention.

Figure 2 is another exemplary embodiment of the process of the present invention.

* Explanation of the major symbols in the drawings *

10: Strata with a certain bearing capacity, such as a solid soil layer or a sand layer. 11: Deep support layer. 12: Weathered soil layer.

13: landfill and sedimentary layers.

20: Rock bed.

30: casing. 31: Coupling.

40: Microfile. 41: Acupressure plate.

50: reinforced concrete footing. 60: grout.

70: perforator. 80: grout injector.

Claims (2)

In carrying out the micropile construction method to obtain tensile and compressive forces in a layer having a certain supporting force such as a solid soil layer or a sand layer, In order to prevent the grouting hole from filling up due to the collapse of the soil, the grouting hole is drilled using various perforators 70 to the depth reaching the rock layer 20 and at the same time, a plurality of casings 30 having no ejection hole are coupled ( 31) a stratified perforation process having a certain supporting force, such as a solid soil layer or a sand layer to be inserted in sequence by connecting to the; A rock drilling process for drilling a grouting hole to match the casing 30 on the rock layer 20 formed in the lower layer 10 having a certain supporting force such as the solid soil layer or the sand layer; A micropile inserting step of installing the micropile 40 inside the casing 30 installed in the boring process of the ground layer 10 having a predetermined support force such as the solid soil layer or the sanding force layer and the grouting hole formed in the rock drilling process; A rock layer grouting step of filling the grout 60 using the grout injector 80 into the grouting hole of the rock layer 20 in which the micropile is inserted through the casing 30 in the micropile inserting step;  The grout 60, which has completed the internal filling of the grouting hole of the rock layer 20, is filled in the ground layer 10 having a certain supporting force such as a solid soil layer or a sand layer, and at the same time, the casing 30 is sequentially pulled up and removed to remove the casing 30. The grout 60 is filled into the grouting hole of the ground layer 10 having a certain supporting force such as a solid soil layer or a sand layer, which is maintained at), and the grout 60 penetrates the ground layer 10 having a constant supporting force such as a solid soil layer or a sand layer. A stratum grafting process having a certain supporting force, such as a solid soil layer or a sand layer, which is soaked and united with a ground layer 10 having a certain supporting force such as a solid soil layer or a sand layer, The above process is to combine the acupressure plate 41 on the ground exposed part of the grouted micropile 40 and to cure the reinforced concrete footing 50 integrally therewith so that the construction depth is short and effectively resists earth pressure. A method of reinforcing bearing capacity by casing-removable step grouting of a micropile characterized in that the configuration. In carrying out the micropile construction method to obtain the tensile and compressive force in the deep ground of the supporting layer of the landfill and sediment layer and the weathered soil layer, In order to prevent the grouting hole from filling up due to the collapse of the deep ground 11, the supporting layer consisting of the weathered soil layer 12 and the landfill and sedimentation layer 13 uses various perforators 70 to the depth reaching the rock layer 20. A deep ground drilling process for supporting the grouting hole and simultaneously inserting a plurality of casings 30 having no ejection holes into the coupling 31 to sequentially insert the grouting holes; A rock drilling step of drilling a grouting hole in the rock layer 20 formed in the lower layer of the deep ground 11 so as to match the casing 30; A tread bar insertion process of the micropile for installing the tread bar of the micropile 40 in the casing 30 installed in the deep ground 11 drilling process and the grouting hole formed in the rock drilling process; The grout 60 is filled by using the grout injector 80 into the grouting hole of the rock layer 20 in which the tread bar of the micropile 40 is inserted through the casing 30 in the tread bar insertion process of the micropile. Rock layer 20 grouting process,  The grout 60, which has completed the internal filling of the grouting hole of the rock layer 20, fills the weathered soil layer 12 of the deep ground 11, and simultaneously pulls up the casing 30 and removes the casing 30. The grout 60 is filled into the grouting hole formed in the weathered soil layer 12 of the deep ground 11 so that the grout 60 penetrates through the weak part of the weathered soil layer 12 and binds integrally. Weathered soil layer grouting process,  A landfill and sedimentation layer filling the grout 60 in the casing 30 in a state where the casing 30 is embedded by remaining the landfill and sedimentation layer 13 formed on the weathered soil layer 12 without removing the casing 30. Grouting process, The grout 60 is a weathered soil layer 12 as a finishing process of combining the acupressure plate 41 on the ground exposed portion of the grouted micropile 40 and curing the reinforced concrete footing 50 integrally therewith. A method of reinforcing the supporting force by casing-removing step grouting of a micropile, which is configured to penetrate through the bay and unite integrally to effectively resist earth pressure while having a short construction depth.

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