KR102184900B1 - Temporary retaining wall structure using circular steel pipe and construction method thereof - Google Patents

Abstract

The present invention relates to a temporary retaining wall structure using a round steel pipe and a construction method thereof. A temporary retaining wall structure using a round steel pipe according to an embodiment of the present invention comprises: two rows of guide beams installed parallel to each other at a first set interval along a boundary line of an earth retaining wall; a plurality of spacing maintaining members positioned to be spaced apart from each other at a second set interval in a longitudinal direction of the two rows of guide beams and assembled by crossing the second rows of guide beams; a plurality of round steel pipes which are constructed along the retaining boundary line through the space between the first set interval between the two rows of guide beams and the second set interval between the plurality of spacing maintaining members; and a circular steel pipe restraining member inserted through the two rows of guide beams and the round steel pipe, and connecting and fixing the second rows of guide beams and the round steel pipe in a horizontal direction. The guide beam can replace the role of a head fixing device only by connecting the guide beam and the round steel pipe, such that work efficiency can be increased.

Description

Temporary earth barrier structure using circular steel pipe and its construction method {TEMPORARY RETAINING WALL STRUCTURE USING CIRCULAR STEEL PIPE AND CONSTRUCTION METHOD THEREOF}

The present invention relates to a temporary wall structure using a circular steel pipe and a construction method thereof.

The earth protection method is aimed at resisting side pressures such as earth pressure and water pressure on the back surface during excavation, and to settle the surrounding ground and protect adjacent structures.

In general, the retaining method is classified in various ways according to the type of the retaining wall and the type of structural support.

For example, H-beam + earth plate (i.e., wood and steel), sheet pile, CIP (Cast In Place), SCW (Soil Cement Wall), and Slurry Wall. Etc.

In addition, self-standing, self-supporting + tie-back, ground anchor and back hitting support are introduced in the form of supporting such a wall. In recent years, a support type and an anchor type are widely used in Korea.

Briefly, H-beam + earth plate (i.e., wood and steel) is a construction method in which the H-beam is rebuilt after pre-drilling, and then the earth plate is installed using wood or steel during excavation, and then excavated.

In this method, the stiffness of the wall is weak, and a separate order method is required in the ground with groundwater level. In addition, since this method has the possibility of soil leakage, a separate prevention countermeasure method should be used in combination with soft ground where there is a concern about subsidence of the surrounding ground due to the overbreak of the soil plate and the ground, and there is a risk of heaving. In addition, this method can be reused by pulling out H-beams after installation of the structure, but it has a disadvantage of using a lot of temporary materials according to the support due to its weak rigidity.

Sheet pile is a construction method used for soft ground or sandy ground. It is often used in ground with high water level, and U-shaped steel piles are typed in the ground with hydraulic and vibration hammers to form a retaining wall.

This method has a drawback of excellent water-repellency but weak stiffness, and is not suitable for downtown, but also has disadvantages that it is difficult to construct in the ground and in dense sandy or rock layers. In addition, this method can be reused by pulling out the gangway pile after the installation of the structure, but it is weak in rigidity, the structure and the combined wall cannot be constructed, and there are many limitations in construction depending on the ground.

CIP (Cast In Place) uses a rotary boring machine (e.g. auger drilling machine, etc.) to drill the ground along the excavation boundary, insert H-beam and reinforcing bars into the drilling hole, and then place cement mortar or concrete on-site. To form the wall.

However, due to the rigid wall structure, there is a disadvantage in that the construction method frequently constructed in urban areas or the connection between the pillars is poor, and the verticality decreases as it goes down the ground, and the gap between the pillars widens. Recently, a construction method that is frequently used for the construction of a barrier wall that requires rigidity, but the construction cost is high because both materials and materials are president, and a separate tip fixing device is required.

S.C.W (Soil Cement Wall) uses single-axis and three-axis rotary boring machines to drill the ground and when it reaches a predetermined depth, cement mortar is injected to form a mixed column of soil and cement in the ground.

This construction method has a disadvantage in that it is superior to steel piles but inferior in order, because H-beams are inserted at regular intervals to form a wall. In addition, this method has a disadvantage that it is difficult to construct in a gravel layer or a rock layer, and in particular, intensive leakage may occur in a ground where there are many gravel layers and the groundwater level is high.

Underground continuous wall (Slurry Wall) uses a slurry stabilizer to maintain the hollow wall, and after excavation by a panel drilling machine, reinforced reinforcing bars and underwater concrete are poured to form a continuous wall.

This method has excellent rigidity, can excavate in large cities, and can expect a good effect in the order of magnitude. However, this construction method has the disadvantages that the construction cost is expensive, it is difficult to construct in the dead or amber stone layer, special equipment is required in the rock layer, and the construction speed is significantly lowered.

The above construction method is currently widely constructed in Korea, and the method is determined according to the ground conditions, construction purpose, and type.

In the design of the retaining wall, displacement occurs due to earth pressure, overhead load, and water pressure, and construction methods other than rigid walls have a problem that a rise phenomenon occurs.

In addition, in the case of the rigid wall, the piles are arranged in a main row type, but since the piles are not connected to each other, the individual piles independently resist earth pressure, etc., so there was inconvenience of installing a separate head fixing device at the top.

Further, construction materials such as cement, section steel, reinforcing bars, and ready-mixed concrete are dead, and there is a problem that construction cost increases as well as construction speed is delayed.

As a prior art related to the present invention, there is a Republic of Korea application number 2018-0074762 (2018.06.28. filing date), and the prior document discloses a method of constructing a pile for a retaining wall.

It is an object of the present invention to install a prefabricated guide beam, and to provide a temporary earth retaining wall structure with improved work efficiency and a construction method thereof, since the guide beam can replace the role of the head fixing device only by connecting the guide beam and the circular steel pipe.

Another object of the present invention is to provide a temporary wall structure and a construction method thereof capable of forming a rigid wall through a lower construction cost and a shorter construction period compared to the existing construction method.

Another object of the present invention is to provide an eco-friendly temporary wall structure and a construction method thereof, as well as cost reduction by reusing guide beams and circular steel pipes.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention that are not mentioned can be understood by the following description, and will be more clearly understood by examples of the present invention. In addition, it will be easily understood that the objects and advantages of the present invention can be realized by the means shown in the claims and combinations thereof.

According to an aspect of the present invention, there is provided a temporary wall structure using a circular steel pipe.

The temporary wall structure using a circular steel pipe according to an embodiment of the present invention comprises two rows of guide beams installed in parallel at a first set distance apart from each other along the boundary line of the soil barrier of the ground; A plurality of spacing members positioned to be spaced apart from each other at a second set distance along the longitudinal direction of the two rows of guide beams, and assembled to cross the two rows of guide beams; A plurality of circular steel pipes are constructed along the boundary line of the soil barrier through the space between the first set distance between the two rows of guide beams and the second set distance between the plurality of space maintaining members; And a circular steel pipe constraining member inserted through the two rows of guide beams and the circular steel pipe, and connecting and fixing the two rows of guide beams and the circular steel pipe in a horizontal direction.

Each of the two rows of guide beams includes a plate-shaped horizontal body arranged in the horizontal direction, a plate-shaped first vertical body connected in a vertical direction by crossing the horizontal body at a position far from the circular steel pipe based on the position of the circular steel pipe, It includes a plate-shaped second vertical body connected in a vertical direction by crossing the horizontal body at a position close to the circular steel pipe based on the position of the circular steel pipe.

A first coupling groove is formed at the upper end of the first vertical body by cutting to a predetermined depth at a set interval, and a size corresponding to the first coupling groove corresponding to the position of the first coupling groove at the upper end of the second vertical body The second coupling groove is formed. The first and second coupling grooves are grooves in which the gap-holding members cross and fit into two rows of guide beams.

The first and second coupling grooves are spaces in which the spacing member is fitted, and a contact reinforcing portion may be provided with a predetermined thickness to reinforce a contact portion therebetween. The contact reinforcement unit may be made of a material having superior structural strength and rigidity compared to the first and second vertical bodies, and has the advantage of suppressing abrasion or damage even when repetitive bonding and releasing operations are performed.

In addition, the first and second coupling grooves may further include a concave concave in a rounded shape on the inner side of the groove, and a convex convexly protruding lateral surface may be further provided in the spacing member corresponding to the location of the concave portion. I can. Through this, it is possible to prevent separation after the gap maintaining member is coupled, and there is an advantage in selecting the bonding position of the gap maintaining member.

Round steel pipes can be installed in a main column type along the boundary of the site to be excavated.

In addition, a structural and rigidly reinforced tip reinforcing member may be provided at the lower end (ie, the tip) of the circular steel pipe. The tip reinforcing member includes a circular first reinforcing portion formed at a lower end of the circular steel pipe and structurally reinforced, and a second reinforcing portion including a plurality of protruding bodies protruding from the lower portion of the first reinforcing portion. Through such a tip reinforcing member, it is possible to suppress damage or damage to the tip of the circular steel pipe that can be reused, and it is possible to increase work efficiency when drilling the circular steel pipe. For example, as a circular steel pipe, a spiral steel pipe having high rigidity may be used.

In addition, an iron plate (hereinafter, a welded iron plate) may be attached to the upper end of the circular steel pipe through welding. Through this, the welded steel plate can be used when the circular steel pipe is in and out of the pipe.

In addition, the circular steel pipe can be constructed in a main column type along the boundary line of the earth barrier through a grid accommodation space of a set size formed between the first set interval between the two rows of guide beams and the second set interval between the plurality of space holding members. have. Through this, a plurality of circular steel pipes can be accurately constructed by finding the correct depth of field at a set position.

The circular steel pipe constraining member includes a plurality of first perforated portions formed at the upper ends of each of the two rows of guide beams, and a plurality of second perforated portions formed at the upper end of the circular steel pipe in a direction facing each other. It can be a steel rod.

In addition, the circular steel pipe constraining member has a length longer than the sum of the width length of the guide beams of the two rows and the diameter length of the circular steel pipe, and a male thread is formed at one end of the circular steel pipe constraining member, and the circular steel pipe constraining member The other end of the member may be formed with an expansion protrusion limiting the insertion of the circular steel pipe constraining member.

In addition, the circular steel pipe constraining member is inserted through the two rows of guide beams and the circular steel pipe using the first and second perforations, and one end of the circular steel pipe constraining member is fastened with a fastening nut to the male thread. It is fixed to one of the two rows of guide beams, and the other end of the circular steel pipe restraining member may have the expansion protrusion in close contact with the other one of the two rows of guide beams by the fastening force of the fastening nut.

According to another aspect of the present invention, there is provided a method of constructing an earthen wall structure using the temporary earthen wall structure using the circular steel pipe.

A method of constructing a wall structure according to an embodiment of the present invention is a method of constructing a temporary wall structure using a circular steel pipe, wherein (a) the guide beams of the two rows are arranged along the boundary line of the ground by a first set interval in the width direction. Installing so as to be spaced apart and in parallel; (b) installing and fixing the plurality of spacing members in the second row of guide beams by spaced apart by a second set interval along the length direction of the two rows of guide beams; (c) constructing the circular steel pipe prepared between the two rows of guide beams and the plurality of spacing members; (d) inserting through the circular steel pipe restraining member prepared in the two rows of guide beams and the circular steel pipe; And (e) fastening the fastening nut to the male screw portion formed at one end of the circular steel pipe constraining member to connect and fix the two rows of guide beams and the circular steel pipe in a horizontal direction using the circular steel pipe constraining member. Include.

After the step (e), (f) constructing a filling material in the inside of the circular steel pipe in which the two rows of guide beams and upper ends are connected and fixed in a horizontal direction by the circular steel pipe restraining member.

Here, as the filler, cement mortar or sand may be used.

After the step (f), (g) by releasing the fastening nut formed at one end of the circular steel pipe constraining member and releasing the insertion of the circular steel pipe constraining member, the circular steel pipe constraining member and the two rows of guide beams are removed. Storing for reuse after being separated and taken out; And (h) drawing the circular steel pipe upward and storing it for reuse after being separated and taken out.

Accordingly, the retaining wall is constructed as a rigid circular steel pipe and can be designed in a self-supporting manner, and when support is installed depending on the situation, there is no need for separate construction since the two rows of guide beams serve as the upper strip. Furthermore, the construction period can be shortened by widening the support interval, and construction cost can be greatly reduced.

According to the present invention, there is an advantage that the work efficiency can be improved because the guide beam can replace the role of the head fixing device only by installing the prefabricated guide beam and connecting the guide beam and the circular steel pipe.

Specifically, according to the present invention, the retaining wall can be constructed as a rigid circular steel pipe, and thus there is an advantage in that a self-standing design is possible.

In addition, when the support is installed depending on the situation, there is an advantage that a separate construction is not required because the guide can serve as an upper belt.

In addition, there is an advantage of shortening construction cost and reducing construction cost because the support interval can be widened.

In addition, it is possible to use ready-made products that are not cast in the field, so that construction quality is excellent, eco-friendly, and various problems that may occur depending on the site situation can be prevented in advance.

In addition, it is possible to reuse guide beams and circular steel pipes, thereby reducing cost as well as being eco-friendly.

As described above, according to the present invention, after the construction of the temporary earthen wall structure is completed, the guide beam and the circular steel pipe required for the construction are dismantled and drawn to have the advantage of reusable. Accordingly, there is an advantage that can significantly reduce the construction cost.

In addition to the above-described effects, specific effects of the present invention will be described together while describing specific details for carrying out the present invention.

1 is a perspective view briefly showing a temporary earth wall structure using a circular steel pipe according to an embodiment of the present invention.
Figure 2 is a plan view briefly showing a temporary wall structure using a circular steel pipe according to an embodiment of the present invention.
Figure 3 is a schematic cross-sectional view showing a temporary wall structure using a circular steel pipe according to an embodiment of the present invention.
Figure 4 is a perspective view briefly showing the arrangement structure of the circular steel pipe constituting the temporary earth wall structure using a circular steel pipe according to an embodiment of the present invention.
5 is a cross-sectional view schematically showing the arrangement structure of a circular steel pipe constituting a temporary wall structure using a circular steel pipe according to an embodiment of the present invention.
6 is a perspective view schematically showing an arrangement structure of two rows of guide beams constituting a temporary earth wall structure using a circular steel pipe according to an embodiment of the present invention.
7 is an exploded perspective view briefly showing a circular steel pipe constraining member constituting a temporary earth wall structure using a circular steel pipe according to an embodiment of the present invention.
Figure 8 is a reference diagram showing the construction state of the temporary earth wall structure using a circular steel pipe according to an embodiment of the present invention.
9 is a flow chart briefly showing a method of constructing a temporary wall structure using a circular steel pipe according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings so that those skilled in the art can easily implement the present invention. The present invention may be implemented in various different forms, and is not limited to the embodiments described herein.

In order to clearly describe the present invention, parts irrelevant to the description have been omitted, and the same reference numerals are assigned to the same or similar components throughout the specification. Further, some embodiments of the present invention will be described in detail with reference to exemplary drawings. In adding reference numerals to elements of each drawing, the same elements may have the same numerals as possible even if they are indicated on different drawings. In addition, in describing the present invention, when it is determined that a detailed description of a related known configuration or function may obscure the subject matter of the present invention, a detailed description thereof may be omitted.

In describing the constituent elements of the present invention, terms such as first, second, A, B, (a), (b) may be used. These terms are only for distinguishing the component from other components, and the nature, order, order, or number of the component is not limited by the term. When a component is described as being "connected", "coupled" or "connected" to another component, the component may be directly connected or connected to that other component, but other components between each component It is to be understood that is "interposed", or that each component may be "connected", "coupled" or "connected" through other components.

In addition, in implementing the present invention, components may be subdivided and described for convenience of description, but these components may be implemented in one device or module, or one component may be a plurality of devices or modules. It can also be implemented by being divided into.

In the drawings, FIGS. 1 to 3 are a perspective view, a plan view, and a cross-sectional view briefly showing a temporary wall structure using a circular steel pipe according to an embodiment of the present invention. 4 and 5 are a perspective view and a cross-sectional view briefly showing an arrangement structure of a circular steel pipe constituting a temporary wall structure using a circular steel pipe according to an embodiment of the present invention. 6 is a perspective view schematically showing an arrangement structure of two rows of guide beams constituting a temporary earth wall structure using a circular steel pipe according to an embodiment of the present invention, and FIG. 7 is a circular steel pipe according to an embodiment of the present invention. It is an exploded perspective view briefly showing a circular steel pipe constraining member constituting the temporary earthen wall structure using. 8 is a view showing a construction state of a temporary earth wall structure using a circular steel pipe according to an embodiment of the present invention.

As shown, according to one aspect of the present invention provides a temporary earthen wall structure 1000 using a circular steel pipe.

The temporary wall structure 1000 using a circular steel pipe according to an embodiment of the present invention includes a guide beam 100 of two rows, a circular steel pipe 200, a gap maintaining member 300, a circular steel pipe constraining member 400 do.

The two-row guide beams 100 are installed in parallel with each other at a first set distance (L1, see Fig. 6) along the boundary line of the ground.

The plurality of spacing members 300 are positioned to be spaced apart from each other at a second set distance (L2, see Fig. 6) along the length direction of the two rows of guide beams 100, and are assembled to cross the two rows of guide beams. Can be.

The circular steel pipe 200 includes a first set distance (L1, see FIG. 6) between the two rows of guide beams 100, and a second set distance (L2, see FIG. 6) between the plurality of spacing members 300 ) Through the space (hereinafter referred to as a grid accommodation space 600, see FIG. 6), a plurality of soil barriers are constructed along the boundary line. At this time, a gap (g, see FIG. 3) may be formed between the circular steel pipes 200 arranged in a main row corresponding to the thickness of the gap maintaining member 300 (t, see FIG. 3 ).

The circular steel pipe restraining member 400 is inserted through the two rows of guide beams 100 and the circular steel pipe 200, and connects and fixes the two rows of guide beams 100 and the circular steel pipe 200 in a horizontal direction. Let it.

Specifically, each of the two rows of guide beams 100 includes a horizontal body 110, a first vertical body 120, and a second vertical body 130.

The horizontal body 110 refers to a plate-shaped rigid member disposed in the horizontal direction.

In addition, the first vertical body 120 refers to a plate-shaped rigid member that is connected in a vertical direction by crossing the horizontal body 110 at a position far from the circular steel pipe 200 based on the position of the circular steel pipe 200.

In addition, the second vertical body 130 refers to a plate-shaped rigid member that is connected in a vertical direction by crossing the horizontal body 110 at a position close to the circular steel pipe 200 based on the position of the circular steel pipe 200.

Preferably, the first and second vertical bodies 120 and 130 may have the same height, whereby each of the guide beams 100 may have an H-shaped cross-sectional structure.

In addition, a first coupling groove 121 is formed on the upper end of the first vertical body 120 by cutting to a predetermined depth at a set interval.

In addition, a second coupling groove 131 having a size corresponding to the first coupling groove 121 (see FIG. 2) corresponding to the position of the first coupling groove 121 (see FIG. 2) at the upper end of the second vertical body 130, 2) is formed.

The first and second coupling grooves 121 and 131 (see Fig. 2) are grooves in which the gap maintaining member 300 is intersected and coupled to the guide beams 100 in two rows, and corresponds to the thickness of the gap maintaining member 300. It can have a size and shape.

As described above, the first and second coupling grooves 121 and 131 (see FIG. 2) are spaces in which the gap maintaining member 300 is fitted, and therefore, the contact reinforcing part 132, FIG. 6) may be provided with a predetermined thickness.

As shown in FIG. 6, the contact reinforcing part 132 may be made of a material having superior structural strength and rigidity compared to the first and second vertical bodies 120 and 130.

Accordingly, even when the coupling and release of the gap maintaining member 300 is repeatedly performed for a long period of time for reuse, abrasion, damage, breakage, etc. at the coupling portion can be suppressed.

Further, the first and second coupling grooves 121 and 131 (see FIG. 6) may further include a concave portion 133 (see FIG. 6) recessed in a rounded manner.

Meanwhile, a convex portion 303 (see FIG. 6) protruding roundly and convexly may be further provided on the side of the gap maintaining member 300 (see FIG. 6) corresponding to the position of the concave portion 133 (see FIG. 6 ). .

Accordingly, after fitting and coupling the gap maintaining member 300 to the guide beams 100 in two rows, it is possible to prevent the position of the gap maintaining member 300 from being disengaged or disengaged, unlike the intention of the operator. There is an advantage in selecting the coupling position of the holding member 300.

Specifically, a plurality of circular steel pipes 200 may be installed in a main column type along the boundary surface of the site to be excavated.

For example, referring to FIG. 4, a tip reinforcing member 230 that is structurally and rigidly reinforced may be provided at the lower end (ie, the tip) of the circular steel pipe 200.

The tip reinforcing member 230 is formed at the lower end of the circular steel pipe and includes a structurally reinforced circular first reinforcing portion 231 and a plurality of protruding bodies protruding from the lower portion of the first reinforcing portion 231. It includes a reinforcement part 233.

Through the tip reinforcing member 230, it is possible to prevent damage or damage to the tip of the circular steel pipe 200 that can be reused, and it may be helpful for excavation of the circular steel pipe 200.

For example, the circular steel pipe 200 may use a spiral steel pipe having high rigidity, but is not limited thereto, and various steel pipes that are self-evident to a person skilled in the art may be used.

In addition, an iron plate (hereinafter, referred to as welded iron plate 220) may be previously attached to the upper end of the circular steel pipe 200 through welding.

The welded steel plate 220 refers to a welded steel plate to the upper part of the circular steel pipe 200 in advance in a factory or workshop prior to installation and construction of the circular steel pipe 200. , It is used when drawing the circular steel pipe 200 for reuse, so as to prevent damage to the circular steel pipe 200.

As shown in FIG. 6, the prepared circular steel pipe 200 has a first set distance L1 between the guide beams 100 in two rows, and a second set distance L2 between the plurality of spacing members 300. It is constructed through the lattice accommodation space 600 of a set size formed between, and a plurality of soil barriers may be constructed in a main column type along the boundary line. As a result, the plurality of circular steel pipes 200 can be accurately constructed by finding the correct depth of field at a set position.

Specifically, the circular steel pipe restraining member 400 has a plurality of first perforated portions 150 formed on the upper ends of each of the two rows of guide beams 100, and the circular steel pipe 200 in a direction facing each other. It may be manufactured by using a circular steel rod 410 (see FIG. 7) sequentially inserted through the formed second perforated portions 290 (see FIG. 4) as a body.

The circular steel pipe constraining member 400 has a length longer than the sum of the width and length of the two rows of guide beams 100 and the diameters of the circular steel pipes 200.

Accordingly, the circular steel pipe restraining member 400 sequentially penetrates the first perforated portion 150 of the two rows of guide beams 100 and the second perforated portion 290 (see FIG. 4) of the circular steel pipe 200 to horizontally When simultaneously connected and fixed in the direction, both ends of the circular steel pipe constraining member 400 may have a shape protruding a predetermined length to the outside of the two rows of guide beams 100.

At this time, a male screw portion 420 may be formed at one end of the circular steel pipe constraining member 400. Further, an expansion protrusion 430 may be formed at the other end of the circular steel pipe constraining member 400 to limit insertion of the circular steel pipe constraining member 400.

Accordingly, the circular steel pipe restraining member 400 is inserted through the two rows of guide beams 100 and the circular steel pipe 200 using the first and second perforated portions 150 and 290, and then the circular steel pipe One end of the constraining member 400 is fixed to one of the two rows of guide beams 100 by fastening a fastening nut 500 to the male screw part 420. In addition, the other end of the circular steel pipe constraining member 400 is closely fixed to the other end of the two rows of guide beams 100 by the fastening force of the fastening nut 500.

As a result, the circular steel pipe restraint member 400 is inserted and fixed between the two rows of guide beams 100 and the circular steel pipe 200 while the operator does not intentionally disengage the fastening nut 500 to firmly support them in the horizontal direction. Can do it.

In this way, the temporary earthen wall structure 1000 according to an embodiment of the present invention is a circular steel bar 200 which is installed in a main column along the boundary line of the ground 10 as shown in FIG. 8 to form an earthen wall. And, two rows of guide beams 100 for supporting and fixing the upper part of the circular steel bar 200 in two rows, and two rows of guide beams 100 and circular steel bars 200 through the horizontal direction, and then inserted into the fastening nut 500 Using a circular steel pipe constraining member 400 that is firmly coupled through ). For this reason, the occurrence of displacement at the top of each circular steel bar 200 can be suppressed as much as possible, and since it itself serves as a belt, it can significantly shorten the construction period compared to the existing construction method and significantly reduce the construction cost. There is a beneficial advantage.

Next, a description will be given of a method of constructing an earthen wall structure using a temporary earthen wall structure using a circular steel pipe according to an embodiment of the present invention.

9 is a flow chart briefly showing a method of constructing a temporary wall structure using a circular steel pipe according to an embodiment of the present invention. Referring to FIG. 9, a method of constructing a temporary wall structure using a circular steel pipe according to an embodiment of the present invention includes a parallel installation step of two rows of guide beams (S100), a plurality of spacing member installation steps (S200), and a circular steel pipe construction. Step (S300), circular steel pipe constraining member insertion step (S400), circular steel pipe constraining member fixing step (S500), circular steel pipe inner filler construction step (S600), circular steel pipe constraining member disengagement step (S700), guide beams in two rows Installation and disassembly step (S800), and a circular steel pipe drawing and carrying out step (S900) for reuse. 1 to 8 will be referred to in parallel for explanation of each step.

Parallel installation step of two rows of guide beams (S100)

This step is a step of installing two rows of guide beams in parallel, and in this step, the two rows of guide beams 100 are spaced apart by a first set interval (L1, see Fig. 6) in the width direction along the boundary line of the ground. Install to achieve.

Step of installing a plurality of gap maintaining members (S200)

This step is a step of installing a plurality of spacing members, and in this step, the plurality of spacing members 300 are moved by a second set distance (L2, see FIG. 6) along the length direction of the two rows of guide beams 100. It is installed and fixed to the guide beams 100 of the two rows by being spaced apart.

Round steel pipe construction step (S300)

This step is a circular steel pipe construction step. In this step, the circular steel pipe 200 prepared between the two rows of guide beams 100 and the plurality of spacing members 300 is constructed. In this way, the circular steel pipe 200 is accurately constructed through the grid receiving space 600 (refer to FIG. 6) provided between the guide beams 100 in two rows and a plurality of spacing members 300 coupled in a direction intersecting thereto. As a result, the ability to maintain accurate depth and verticality can be strengthened.

In addition, if the ground water level is high, the circular steel pipes 200 are arranged in a main column type, and there is a risk of soil leakage due to groundwater leakage between each of the circular steel pipes 200, so additional grouting construction between the circular steel pipes 100 is added. Apply. Thus, it is possible to prevent soil leakage and leakage.

Round steel pipe constraining member insertion step (S400)

This step is a step of inserting a circular steel pipe constraining member. In this step, the circular steel pipe constraining member 400 prepared in the two rows of guide beams 100 and the circular steel pipe 200 is inserted through.

Round steel pipe constraining member fixing step (S500)

This step is a step of fixing the circular steel pipe constraining member. In this step, the fastening nut 500 is fastened to the male threaded portion 420 formed at one end of the circular steel pipe constraining member 400. Accordingly, the two rows of guide beams 100 and the circular steel pipes 200 are connected and fixed in a horizontal direction using the circular steel pipe restraining member 400.

Round steel pipe inner filling material construction step (S600)

This step is a step of constructing a filling material inside the circular steel pipe, and in this step, the two rows of guide beams 100 and upper ends are connected and fixed in a horizontal direction by the circular steel pipe restraining member 400 in the inside of the circular steel pipe 200 Install the filling material. At this time, cement mortar or sand may be used as the filling material. According to the use of such a filling material, the cross-sectional area of the earthing wall can be expanded, and when the circular steel pipe is drawn out, the pulling of soil can be prevented.

Detachment of the constraining member of the circular steel pipe, installation and disassembly of the guide beams in two rows, and the steps of drawing out and reusing circular steel pipes (S700, S800, S900)

These steps are steps to release the fastening of the circular steel pipe constraining member, install and dismantle the two rows of guide beams, and take out the circular steel pipes for drawing and reuse. First, the fastening in the male screw part 420 formed at one end of the circular steel pipe constraining member 400 The tightening of the nut 500 is released. Subsequently, the insertion of the circular steel pipe constraining member 400 is released. Subsequently, the circular steel pipe restraining member 400 and the two rows of guide beams 100 are sequentially separated and taken out. Accordingly, there is an advantage in that the circular steel pipe constraining member 400 and the two rows of guide beams 100 can be reused. Next, the circular steel pipe 200 is pulled upward and separated and taken out, after which the circular steel pipe 200 may be stored and reused.

Accordingly, the retaining wall is constructed as a rigid circular steel pipe and can be designed in a self-supporting manner, and when support is installed depending on the situation, there is no need for a separate construction because the two rows of guide beams 100 serve as the upper strip. Furthermore, the construction period can be shortened by widening the support interval, and construction cost can be greatly reduced.

As described above, according to the configuration and operation of the present invention, the guide beam can replace the role of the head fixing device only by installing the prefabricated guide beam and connecting the guide beam and the circular steel pipe, so that work efficiency can be improved.

Specifically, the retaining wall may be constructed as a rigid circular steel pipe, and thus there is an advantage that a self-standing design is possible. In addition, when the support is installed depending on the situation, there is an advantage that a separate construction is not required because the guide can serve as an upper belt. In addition, there is an advantage of shortening construction cost and reducing construction cost because the support interval can be widened. In addition, it is possible to use ready-made products that are not cast in the field, so that construction quality is excellent, eco-friendly, and various problems that may occur depending on the site situation can be prevented in advance. In addition, it is possible to reuse guide beams and circular steel pipes, thereby reducing cost as well as being eco-friendly.

As described above, according to the present invention, after the construction of the retaining wall structure is completed, the guide beam and the circular steel pipe required for the construction are dismantled and drawn to have an advantage that can be reused. Accordingly, there is an advantage that can significantly reduce the construction cost.

As described above with reference to the drawings illustrated for the present invention, the present invention is not limited by the embodiments and drawings disclosed in the present specification, and various by a person skilled in the art within the scope of the technical idea of the present invention. It is obvious that transformation can be made.

S100: Steps for parallel installation of two rows of guide beams
S200: Step of installing a plurality of gap maintaining members
S300: Round steel pipe construction stage
S400: Round steel pipe constraining member insertion step
S500: Step of fixing the circular steel pipe constraining member
S600: Round steel pipe inner filling material construction stage
S700: Round steel pipe constraining member disengagement step
S800: Steps for disassembling the installation of two rows of information beams
S900: Round steel pipe drawing and take-out step for reuse
100: guide
110: horizontal body
120: first vertical body
121: first coupling groove
130: second vertical body
131: second engagement groove
132: contact reinforcement part
133: recess
150: first perforated portion
200: round steel pipe
210: tubular body
211: internal hollow
220: welded iron plate
230: tip reinforcing member
231: first reinforcement part
233: second reinforcement part
290: second perforation
300: gap maintaining member
303: convex portion
400: circular steel pipe constraining member
410: round steel bar
420: male thread
430: expansion protrusion
500: tightening nut
600: grid accommodation space
1000: Temporary earth barrier structure using circular steel pipes

Claims (7)

Two rows of guide beams that are installed in parallel by being spaced apart from each other at a first set interval along the boundary line of the soil barrier of the ground;
A plurality of spacing members positioned to be spaced apart from each other at a second set distance along the longitudinal direction of the two rows of guide beams, and assembled to cross the two rows of guide beams;
A plurality of circular steel pipes are constructed along the boundary line of the soil barrier through the space between the first set distance between the two rows of guide beams and the second set distance between the plurality of space maintaining members; And
A circular steel pipe constraining member inserted through the two rows of guide beams and the circular steel pipe, and connecting and fixing the two rows of guide beams and the circular steel pipe in a horizontal direction;
Including,
Each of the two rows of guide beams includes a plate-shaped horizontal body, a plate-shaped first vertical body and a second vertical body connected in a vertical direction to the horizontal body,
The first vertical body and the second vertical body have the same height, and each of the guide beams has an H-shaped cross-sectional structure,
Meanwhile, a first coupling groove and a second coupling groove are formed at upper ends of the first vertical body and the second vertical body, respectively,
The first coupling groove and the second coupling groove further includes a contact reinforcing portion to reinforce a contact portion when the gap maintaining member is fitted,
In addition, the first coupling groove and the inner side of the second coupling groove is further provided with a concave concave round,
On the other hand, in response to the position of the concave portion, a temporary earth wall structure further provided with a convex portion protruding in a rounded convex shape on the side of the spacing member.
The method of claim 1,
The circular steel pipe constraining member,
A plurality of first perforated portions formed on the upper ends of each of the two rows of guide beams,
It characterized in that it is a circular steel bar inserted through a plurality of second perforated portions formed in a direction facing each other at the upper end of the circular steel pipe,
Temporary earth barrier structure using circular steel pipes.
The method of claim 2,
The circular steel pipe constraining member,
It has a length longer than the sum of the width and length of the two rows of guide beams and the length of the diameter of the circular steel pipe,
A male thread is formed at one end of the circular steel pipe constraining member,
Characterized in that an expansion protrusion is formed at the other end of the circular steel pipe constraining member to limit insertion of the circular steel pipe constraining member
Temporary earth barrier structure using circular steel pipes.
The method of claim 3,
The circular steel pipe restraint member is inserted through the two rows of guide beams and the circular steel pipe using the first and second perforations,
One end of the circular steel pipe constraining member is fixed to one of the two rows of guide beams by fastening a fastening nut to the male thread,
The other end of the circular steel pipe constraining member is characterized in that the expansion protrusion is closely fixed to the other one of the guide beams of the two rows by the fastening force of the fastening nut.
Temporary earth barrier structure using circular steel pipes.
As a method of constructing an earthen wall structure using a temporary earthen wall structure using a circular steel pipe,
(a) installing two rows of guide beams so that the soil barriers of the ground are parallel to each other by a first set interval along the boundary line;
(b) installing and fixing a plurality of spacing members to the second row of guide beams by spaced apart by a second set interval along the length direction of the two rows of guide beams;
(c) constructing a circular steel pipe prepared between the two rows of guide beams and the plurality of spacing members;
(d) fixing the circular steel pipes and the two rows of guide beams using the two rows of guide beams and a circular steel pipe constraining member penetrating the circular steel pipes; And
(e) fastening a fastening nut to a male thread formed at one end of the circular steel pipe constraining member to connect and fix the two rows of guide beams and the circular steel pipe in a horizontal direction using the circular steel pipe constraining member;
Including,
Each of the two rows of guide beams includes a plate-shaped horizontal body, a plate-shaped first vertical body and a second vertical body connected in a vertical direction to the horizontal body,
The first and second vertical bodies have the same height, and each of the guide beams has an H-shaped cross-sectional structure,
Meanwhile, a first coupling groove and a second coupling groove are formed at upper ends of the first vertical body and the second vertical body, respectively,
A contact reinforcing part is further provided in the first and second coupling grooves to reinforce a contact portion when the gap maintaining member is fitted,
In addition, the inner side of the first and second coupling grooves are further provided with a concave concave rounded,
On the other hand, the construction method of a temporary earthen wall structure further provided with a convex protruding roundly on the side of the gap maintaining member corresponding to the position of the concave portion.
The method of claim 5,
After step (e),
(f) constructing a filler in the inside of the circular steel pipe in which the two rows of guide beams and upper ends are connected and fixed in a horizontal direction by the circular steel pipe restraining member;
Construction method of a temporary wall structure further comprising a.
The method of claim 6,
After step (f) above,
(g) By releasing the fastening nut from the male screw portion formed at one end of the circular steel pipe constraining member and releasing the insertion of the circular steel pipe constraining member, the circular steel pipe constraining member and the two rows of guide beams are separated and carried out and reused. Storing for; And
(h) drawing the circular steel pipe upward and storing it for reuse after being separated and taken out;
Construction method of a temporary wall structure further comprising a.

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