KR101150794B1 - The deepened sheet plate - Google Patents

Abstract

PURPOSE: A high-depth prefabricated temporary earth retaining structure is provided to maintain structural stability by preventing horizontal displacement generation of an earth retaining wall body. CONSTITUTION: A first row multistage H type steel material is consecutively welded and connected to first row basic H type steel materials(24) which are vertically or horizontally installed in the ground to a design depth. A multistage steel sheet is vertically inserted in the ground with the design depth by being consecutively connected to a basic steel plate(13) vertically inserted in the ground between the first row multistage H type steel materials. A second row basis H type steel material(25) is vertically installed into the ground. An H type steel-combined reinforcing material(21) is welded between the first row basis H type steel material and the second row basis H type steel material.

Description

Prefabricated Tempered Block Structure {The deepened sheet plate}

In general, when a basement is constructed, an earth block is a temporary structure installed in an excavated underground space in order to prevent the ground from collapsing. It is widely used for the construction of basement floors.

However, the current retaining method is not only economical and difficult to secure a work space due to the use of a large number of struts, but also structurally inefficient, there is a fear of settlement of the surrounding ground.

In the case of the conventional clamding method, the H-shaped steel is installed on the site at regular intervals, and at the same time as the excavation, the earthen board is interposed between the earthen boards, and then the retaining wall is installed to support the retaining wall.

This construction is relatively simple, economical and short in air, and can act as a soil wall as a rigid body. However, due to the soil condition, the order effect cannot be expected, so the displacement of the upper head is relatively large. Occurs.

In addition, it is difficult to select the order grout method that meets the soil conditions, the possibility of leakage phenomenon at the connection part is high, and the order effect is not expected.

According to the construction unit price of the earthquake method, the cheapest is to install the wood earth plate in H type steel, followed by the use of metal plate steel, the use of metal earth plate, the CIP method using reinforced concrete, and the reverse drilling method (BRD method). Construction costs increase in order.

In addition, there is a variety of reinforcement methods, such as the cheapest wooden shoring, steel shoring replaced with H-type steel, earth anchor, strut installation, etc. have.

In particular, the earth anchor construction method drills holes at regular intervals in the excavation surface to improve the safety of underground excavation work, inserts wires or reinforcing bars, specially produced anchors, etc. into the drilling holes, and then inserts an expansion agent (filler). As a method of reinforcing the finished slope, this earth anchor construction method increases the resistance to tensile stress, shear stress, and bending moment of the constructed ground, thereby improving stability against slope failure during excavation and after completion of excavation. It is a kind of ground reinforcement method for the purpose of various types from simple wire to special earth anchor, and construction cost also varies depending on the type and construction method of earth anchor, but incurs expensive construction cost.

Conventional earth anchor construction method generally comprises a step of forming a hole by drilling a hole in the excavation surface that needs to be reinforced; After the drilling operation process, the step of inserting the stranded wire into the drilling hole and the step of adding an expanding agent; and the process of closing the inlet of the drilling hole to finish the process.

1. It should be possible to warn of the danger by the self-feeding method due to the deformation of the earth block structure due to the structural deformation and earthquake caused by earth pressure.

2. Simple construction of permanent concrete structure retaining wall by placing reinforced concrete between two or more rows of retaining structures.

3. Minimize the installation of formwork by using the earthen structure to cast concrete.

4. Construct the building with minimum distance from the land boundary.

5. Minimize the number of reinforcing steels (H type steel, sheet steel) used in addition to the number of existing H type steels used for retaining walls.

6. Relatively economical and costly materials and labor costs, such as earth anchor method, applied as a method of reinforcement after the installation of retaining walls.

7. The use of a rack does not narrow the workspace.

8. It blocks the inflow of groundwater and at the same time has the dual effect of strengthening the durability of the retaining wall.

9. As far as possible, no environmental pollutants should be used as a result of the recovery and ordering (waterproofing) of the materials used.

10. When earth pressure rises in a part of the retaining wall, the entire structure of the retaining wall has structural stability by dispersing the force.

In addition to the basic construction cladding structure consisting of steel plates inserted between the first row H-shaped steel vertically poured into the ground, steel plates are inserted between two or more rows of H-type steel and two or more H-shaped steels vertically poured into the ground. After the first row of H-type steel and the second row of H-type steel is connected to the H-type steel joint reinforcement is a temporary earthquake structure reinforced by welding.

In addition, as an example, the c-type steel is inserted into the ground at an angle to the top of the earthen wall H-shaped steel, and then the H-type and the c-type steel are welded and combined, and then the metal plate steel is inserted between the c-type steel to be inserted into the ground. It is integrated and has structural stability on the retaining wall, in particular by earth pressure acting on the sheet steel.

Insert the c-type steel into the ground at an intermediate end of the H-wall steel, which requires additional reinforcement for depth excavation, weld the H-type and c-type steel joints, and insert the metal plate between the c-type steels to insert the underground. The sheet steel and the H-shaped steel are integrated, and in particular, the earth wall has structural stability due to earth pressure acting on the sheet steel.

If groundwater flows in during construction of the earthen wall using wood earthen board or metal earthen board, insert c-type steel at the top of the earthen-wall H-type steel part into which underground water flows, and then weld H-type and c-type steel after welding Metal plate steel is sandwiched between steels to block underground water, and at the same time, the plate steel and H type steel are integrated, and the earthquake wall has structural stability due to earth pressure acting on the plate steel.

As a new construction method that allows construction of buildings as close as possible to the boundary of the site, the earthenware fixture itself is directly cast in place of one formwork, which is superior in comparison with any existing construction methods in terms of construction cost and construction time.

The use of minimal steel reduces labor costs by reducing material costs and maximum mechanized construction, and has the dual effect of blocking the inflow of groundwater and enhancing the durability of the retaining wall.

In particular, the horizontal displacement of the retaining wall hardly occurs, and structural stability can be maintained. The principle of the present invention can be compared with that of a steel plate, such as a webbed of an aquatic organism. Comparable with the difference of the missing finger, it is the first time that the earthquake construction method which responds to earth pressure structurally effectively in civil engineering work.

In addition, because it does not need to install a crutch, it is possible to reduce the air shortening and construction costs due to the increase in construction, and excellent structural safety and economic efficiency.

In addition, by reinforcing the reinforced concrete between two or more layers of earthen structures, a permanent concrete structure retaining wall is simply constructed.

In addition, early warning is possible in the event of abnormal displacement of the retaining structure.

1 is a simplified construction plan view for understanding of the present invention
Figure 2 is a simplified view of constructing the H-shaped steel for understanding of the present invention
Figure 3 is a simplified diagram illustrating the brief decomposition and insertion of the H-type steel and c-type steel by inserting the steel sheet in the ground between the c-type steel by inserting the steel plate in the groove between the c-type steel
Figure 4 is a simplified diagram for understanding the force vector when combining the steel sheet in the middle to strengthen the structure of the retaining wall
5 is a simplified view of inserting the steel plate in the ground by combining the c-type steel on the top of the H-type steel
Figure 6 is a simplified construction showing the waterproofing effect on the structure of the retaining wall and the groundwater inlet
Figure 7 is a simplified view for understanding of the c-shaped steel guide frame including the c-type steel insert
8 is a simplified view of the present invention to further construct and construct the H-shaped steel
Figure 9 is a simplified view for understanding the cross-welded coupling guide of the present invention
10 is an imaginary view of the side wall of the H-type steel and the steel plate inserted into the ground
Figure 11 is a simplified embodiment of making a permanent concrete structure using the H-type steel and steel plate inserted in the ground
Figure 12 is an embodiment of briefly making a permanent concrete structure using the H-type steel and steel sheet inserted into the ground
13 is a simplified view of one embodiment of reinforced concrete poured to the floor

An embodiment of the present invention, H-type steel placing step of placing the H-type steel 15 to the ground so that the H-type steel 15 is vertically placed in the ground; C-type steel guide frame coupling step of inserting the c-type steel guide frame 11 into the H-type steel between the H-type steel exposed to the top of the H-type steel inserted into the ground; C-type steel insertion step in which the c-type steel 14 is inserted into the ground while penetrating the c-type steel insertion hole 10 therein; Steel plate insertion step of inserting the steel sheet in the ground by sandwiching the steel sheet 13 between the c-shaped steel (14); A drawing step of removing the c-shaped steel guide frame (11) and drawing the c-shaped steel (14); Steel plate welding step of welding the H-type steel and the steel plate 13 as a coupling reinforcement medium; While excavating the excavation region (1), excavation and earth plate installation step of installing the earth plate between the H-shaped steel; relates to a temporary earthquake structure and its installation method comprising a.

If only three of the most important features of the present invention and different technologies and implicitly as follows.

First, the principle of the present invention can be compared to the role of the steel sheet to the role of the water web of the aquatic organisms, it can be compared with the difference between the finger with the web and the finger without the web so that the earthquake construction method that effectively responds to earth pressure First time.

Second, the present invention does not necessarily have to be symmetric in the number of steel plates installed on each side of the retaining wall. The reason is that if the retaining wall is stabilized by earth pressure, no force is applied to any steel sheet.

That is, only when displacement occurs due to earth pressure on a part of the retaining wall, the force is applied to the steel plate installed on the retaining wall of the side. Secondly, the force is distributed to the steel plate of the entire retaining wall, and thus, the overall structural stability is achieved. This is because the equilibrium point is eliminated by the displacement.

Third, as a result of the above-described effects of the present invention, it is possible to confirm that the entire wall is structurally stable compared to the existing method, and that the wall is not suddenly collapsed. By reinforcing the steel plate in addition to the site where the force is increased, the steel plate is used to construct the reinforcement work for the part where the most moment of force is concentrated before collapse.

Referring to Figures 4 and 5, when a force acts on the H-shaped steel by earth pressure, the steel plate 13 prevents deformation (falling) of the H-shaped steel by generating a drag at a vertical displacement.

In addition, referring to Figure 1 when the force acts on the steel plate A fixed to the H-shaped steel inserted obliquely in the ground, the reaction occurs in the dispersion and reaction of the force and the opposite side B, the entire structure is quite stable by the action and reaction It becomes the dispersion structure of.

Hereinafter will be described in detail through an embodiment.

As shown in Fig. 2, the wall structure is placed on the ground so that the H-type steel 15 is vertically placed in the ground by an auger crane, a vibrohamma, a drawing machine, etc. (H-type steel placing step) )

3 and 7, the c-shaped steel guide frame 11 is inserted into the H-shaped steel between the H-type steel exposed to the top of the H-type steel inserted into the ground. (C type steel guide frame coupling step)

Insert the c-type steel 14 into the ground while passing the c-type steel (14) through the c-type steel insertion hole 10 inside the c-type steel guide frame (c-type steel insertion step).

Insert the steel sheet into the ground by inserting the steel sheet 13 between the c-shaped steel (14).

Remove the c-type steel guide frame (11) and draw (pull out) the c-type steel (14) with a drawing machine.

The H-type steel 15 and the steel plate 13 are welded to the H-type steel 15 and the steel plate 13 with a reinforcing material as a medium (between). (Steel plate welding step)

3 is an embodiment in which the coupling reinforcement is welded and fixed to the coupling reinforcement 16 between the two H-shaped steel 15, and then welds the steel plate 13 to the coupling reinforcement 16 to fix the structure. After fixing the short coupling reinforcement 12 to one H-type steel 15 by welding, an embodiment of welding the C-type steel 14 to the coupling reinforcement 12 is possible.

Next, while excavating the excavation region (1), the earth plate is installed between the H-type steel. (The excavation and earth plate installation step) It is a method of installing a temporary block structure, characterized in that it comprises a.

In one embodiment, the H-type steel is placed on the ground so that the H-type steel is vertically placed in the ground.

The c-shaped steel guide frame 11 is inserted into the H-type steel between the H-type steel exposed on the top of the H-type steel inserted into the ground. (C type steel guide frame coupling step)

The c-type steel 14 is inserted into the ground while penetrating the c-type steel insertion hole 10 therein. (C-type steel insertion step)

After dismantling the c-shaped steel induction frame (11), the c-shaped steel (14) and the H-type steel are welded using a coupling reinforcement medium (H-type steel welding step).

Insert the steel sheet into the ground by inserting the steel sheet 13 between the c-shaped steel (14).

Welding the c-shaped steel 14 and the steel plate 13 (steel plate welding step)

While excavating the excavation area 1, the earth plate is installed between the H-type steels (the excavation and the earth plate installation step).

In one embodiment, in the c-type steel inserting step, the c-type steel insertion hole 10 is made of an inclination angle between 30 degrees to 60 degrees while the c-type steel 14 passes through the c-type steel insertion hole 10 to 30 degrees to Temporary earthquake structure installation method characterized in that the c-type steel inserting step is inserted into the ground at 60 degrees.

In one embodiment, in the c-type steel inserting step, the c-type steel inserting hole 10 has an inclination angle of 45 degrees and the c-type steel 14 is inserted into the ground while the c-type steel 14 is inserted into the ground 45 degree angle inserting step 10 Temporary earthquake structure installation method characterized in that.

In one embodiment, the H-type steel placing step of placing the H-type steel on the ground so that the H-type steel in the ground vertically; C-type steel guide frame coupling step of inserting the c-type steel guide frame 11 into the H-type steel between the H-type steel exposed to the top of the H-type steel inserted into the ground;

C-type steel insertion step in which the c-type steel 14 is inserted into the ground while penetrating the c-type steel insertion hole 10 therein; H-type steel welding step of welding the c-type steel and H-type steel using a reinforced reinforcing medium after the c-type steel induction frame (11); Steel sheet insertion step of inserting the steel sheet in the ground by sandwiching the steel sheet (13) between the c-shaped steel; Steel plate welding step of welding the c-shaped steel (14) and the steel sheet (13); Excavation and earth plate installation step of installing the earth plate between the H-type steel while excavating the excavation area (1);

In the excavation and earth plate installation step, referring to Figure 6 in any situation that requires structural security of the inflow or grounding structure of the groundwater, additional 'c-type steel induction frame coupling step, c-type in the middle of the H-type steel Repeat the steel insertion step, H-type steel welding step, and steel plate insertion step to weld the newly inserted steel plate and H-type steel in the ground with the medium of reinforcing materials, and then excavate the excavation area (1) again. Reinforcement step to install the earth plate; characterized in that the installation method of the temporary earthquake structure to construct while reinforcing the soft ground or groundwater inflow area.

In one embodiment, the first stage H-type steel (24) placing step of placing the H-type steel on the ground so that the H-type steel in the ground vertically; A second-row H-type steel placing step of placing H-type steel on the ground so that the second-row H-type steel 25 is vertically placed after the first-row H-type steel 24; The first-row H-type steel 24 and the second-row H-type steel 25 between the first-row H-shaped steel 24 and the second-row H-shaped steel 25 through the H-type steel joint reinforcing material 21 as a medium. Weld between).

In the welding joining step, referring to FIG. 8, the H-type steel reinforcing reinforcement 21 is formed of box-type steel, steel sheet, H-type steel, U-type steel, T-type steel, etc., and the first row H-type steel 24. It is for structural coupling through welding coupling between two rows of H-shaped steels 25 and is not limited to a specific shape of coupling reinforcement.

Steel sheet insertion step of inserting the steel sheet 13 in the ground between the H-shaped steel; The excavation step of excavating the excavation area (1); is a method of installing a temporary crust structure.

In an embodiment, in the second row H-type steel 25 in the pouring step; The number of second-row H-shaped steels 25 is less than half of the number of first-row H-shaped steels 24.

Referring to FIG. 8, the number of first-row H-type steels is 20 and the second-row H-type steel is eight, for example, using only 50% or less of H-type steels compared to the first-row H-type steels. Has sufficient effect.

In one embodiment, the H-shaped steel interior is a temporary earthquake structure, characterized in that it comprises a coupling guide welded alternately.

Referring to Figure 9, the coupling guides 22, 23 welded alternately inside the H-shaped steel is manufactured through the minimum welding processing process using a minimum of the coupling guide steel, the coupling guide welded across the H-shaped steel When inserting the steel sheet 13 into the empty space of the underground serves as the insertion guide of the steel sheet.

In one embodiment, the fixing by welding is a method of installing a temporary earthquake structure, characterized in that the assembly is fixed by a fastener, the fastener is a clamp, a bolt, a nut and the like fixed by tightening a nut to a bolt through a drilled hole It is not specified in the present invention to be fixed through a known fixture of.

In one embodiment, the earth plate installation step is a temporary earthquake structure installation method characterized in that the excavation of the excavation area (1) after inserting the steel plate between the H-shaped steel.

In one embodiment, the H-type steel 15 is poured into the ground vertically; A steel sheet 13 inserted into the ground; Coupling stiffener welded to the H-shaped steel 15 and the steel plate 13 through the coupling stiffener; Temporary earth block structure, characterized in that the earth plate is installed between the H-shaped steel (15).

In one embodiment, the H-shaped steel 15 and the steel plate 13 inserted into the ground vertically placed in the ground is a temporary soil structure, characterized in that the steel plate is inserted at an angle between 30 degrees to 60 degrees relative to the ground to be.

As an example, the H-type steel 15 and the steel plate 13 inserted into the ground vertically placed in the ground is a temporary soil structure, characterized in that the steel plate is inserted at an angle of 45 degrees relative to the ground.

In one embodiment, the H-type steel 15 is poured into the ground vertically; A steel plate 13 inserted into the ground from an upper end of the H-shaped steel 15; Joining reinforcing material welded to the upper portion of the H-type steel 15 and the steel plate 13 by the coupling reinforcing material; Steel plate 13 inserted into the ground between the top and bottom H-shaped steel 15; Coupling stiffener welded to the steel plate (13) inserted between the top and bottom of the H-shaped steel 15 by the medium of the coupling stiffener; Temporary earth block structure, characterized in that the earth plate is installed between the H-shaped steel (15).

In one embodiment, the first row H-shaped steel 24 is placed vertically in the ground; A second row H-type steel 25 placed in the ground vertically; A steel plate 13 inserted into the ground between the H-shaped steels; It is a temporary soil block structure characterized by the H-type steel joint reinforcing member 21 welded between the first-row H-type steel 24 and the second-row H-type steel 25 via the H-type steel coupling reinforcement 21. .

In one embodiment, the H-shaped steel interior is a temporary earthquake structure, characterized in that it comprises a coupling guide welded alternately.

The coupling guides 22 and 23 welded alternately inside the H-shaped steel are manufactured through the minimum welding processing process using the minimum coupling guide steel, and the steel plates are formed in the empty space of the coupling guides welded alternately between the H-shaped steels. 13) serves as an insertion guide for steel sheets when inserted into the ground.

In one embodiment, the temporary earthquake structure is characterized in that the steel plate 13 inserted into the ground water inflow point is welded with the H-type steel through the medium of the coupling reinforcement.

In one embodiment, the fixing by welding is to be assembled and fixed by the fixture

Temporary earthquake structure characterized in that.

Hereinafter, the claims will be described in detail.

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The first row constructed by vertically placing the ground to the design depth while continuously welding one or more rows to the first row foundation H-shaped steel 24 placed in the ground and the first row foundation H-shaped steel placed in the ground. It is a multi-stage H type steel.

In other words, the length of the steel plate is limited, and the depth of the earthwork construction also varies depending on the construction site. Therefore, for the construction of the high-definition temporary earthquake, the foundation H-type steel, which is the foundation, is placed in the ground and then welded the H-type steel. If the H-type steel is not poured to the design depth, the H-type steel is poured to the design depth by repeating one or more consecutive castings and welding connection pouring until the design depth is reached.

Through the above-described process is a first row H-stage steel of the first row of H-type steel composed of multiple stages.

It is a multi-stage steel sheet configured to be inserted into the ground vertically to the design depth while continuously welding one or more to the base steel sheet 13 inserted vertically into the ground between the first row multi-stage H-shaped steel.

That is, a multi-stage steel sheet inserted into the ground while connecting one or more steel sheets by welding to insert the steel sheet to the design depth in the same principle as the configuration of the multi-stage H-shaped steel.

A second row H-shaped steel 25 and a steel sheet vertically poured into the ground are inserted vertically.

That is, the basic steel sheet of the second row is inserted after the first row on the same principle as the first row.

The H-type steel joint reinforcing member 21 welded between the first-row multi-stage H-type steel and the second-row base H-type steel upper end portion through the H-type steel joint reinforcing material 21 as a medium.

An H-shaped steel joint reinforcing member 21 is formed by welding a coupling reinforcement 21, which is an H-type steel, between a first row multi-stage H-shaped steel and a second row H-shaped steel upper end.

When explaining the coupling relationship between the components in detail, the first row multi-stage H-shaped steel and the multi-stage vertically placed in the ground to the design depth while continuously connecting one or more first-row basic H-shaped steel placed vertically in the ground In addition to the basic temporary earthquake structure consisting of a multi-stage steel sheet inserted between H-type steels, excavation after welding the second-row basic H-type steel and the first-tier multi-stage H-shaped steel upper end of H-type steel joint reinforcement It is a high-depth prefabricated construction block structure, characterized in that excavating the region (1).

The excavation area can be regarded as the excavation area as the space inside the polygon surrounded by the first row H-type steel.

First-tier multi-stage H type constructed by vertically pouring into the ground to the design depth while continuously welding one or more rows to the first-row basic H-shaped steel placed in the ground and the first-row basic H-shaped steel placed in the ground Steel;

A multi-stage steel sheet configured to be inserted vertically into the ground to a design depth while continuously welding one or more consecutively connected to the base steel sheet vertically inserted into the ground between the first row multi-stage H-shaped steels;

A second row base H-type steel and steel sheet vertically placed in the ground;

A third row base H-shaped steel and steel sheet vertically placed in the ground;

It consists of H type steel joint reinforcement welded by H-steel joint reinforcement between first row multi-stage H type steel, second row basic H type steel, and third row basic H type steel upper end.

A base consisting of a first-stage multi-stage H-steel placed vertically in the ground and a multi-stage steel sheet inserted between the first-stage multistage H-shaped steel and the multi-stage H-shaped steel vertically poured into the ground to the design depth while continuously welding one or more continuous In addition to the temporary cladding structure, the upper part of the second-row H-steel, the third-row H-steel, and the first-stage multi-stage H-steel, which are placed vertically in the ground, are connected to the H-type steel joint reinforcement and then excavated the excavation area. It is a high-depth prefabricated temporary construction structure.

The first row multi-stage H type steel, the second row basic H type steel, the third row basic H type steel and the steel sheet are inserted.

First-tier multi-stage H type constructed by vertically pouring into the ground to the design depth while continuously welding one or more rows to the first-row basic H-shaped steel placed in the ground and the first-row basic H-shaped steel placed in the ground Steel;

Second row multi-stage H type constructed by vertically laying in the ground to the design depth while continuously welding at least one continuous connection to the second-row basic H-shaped steel placed in the ground and the second-row H-shaped steel placed in the ground Steel;

A multi-stage steel sheet configured to be inserted vertically into the ground to a design depth while continuously welding one or more welded base metal sheets inserted vertically into the ground between the H-shaped steels;

It consists of H type steel joint reinforcement welded by H-type steel joint reinforcement between the first row multi-stage H type steel and the second row multi-stage H type steel,

First row multi-stage H-shaped steel laid vertically to the ground to the design depth while continuously connecting one or more continuous H-steels vertically cast into the ground, and second row foundations vertically cast into the ground. The first row multistage H type steel and the second row after inserting the multi-stage steel sheet between the second row multi-stage H type steel and the multi-stage H type steel which are placed vertically in the ground to the design depth while continuously welding one or more H type steels together. It is a high-depth prefabricated temporary construction structure, characterized in that excavation excavation area (1) after connecting the H-shaped steel joint reinforcement to the upper end of the thermal multi-stage H-type steel.

The first row multi-stage H-shaped steel, the second row multi-stage H-shaped steel and a steel sheet is inserted.

First-tier multi-stage H type constructed by vertically pouring into the ground to the design depth while continuously welding one or more rows to the first-row basic H-shaped steel placed in the ground and the first-row basic H-shaped steel placed in the ground Steel;

Second row multi-stage H type constructed by vertically laying in the ground to the design depth while continuously welding at least one continuous connection to the second-row basic H-shaped steel placed in the ground and the second-row H-shaped steel placed in the ground Steel;

A third-row base H-shaped steel vertically poured into the ground;

A multi-stage steel sheet configured to be inserted into the ground vertically to a design depth while continuously welding at least one continuous steel plate inserted vertically into the ground between the first row multi-stage H-shaped steel and the second row multi-stage H-shaped steel;

It consists of H type steel joint reinforcement welded between the first row multi-stage H type steel, the second row multi-stage H type steel, and the third row basic H type steel by the coupling reinforcement at the upper end of the H type steel.

The first row multi-stage H type steel that is placed vertically in the ground to the design depth while continuously welding one or more columns of the first row H type steel that is placed in the ground and then continuously welded to the first row basic H type steel placed in the ground. Two-stage H-steels placed in the ground and placed vertically in the ground and inserted into the ground vertically to the design depth while continuously welding one or more foundation steel sheets inserted vertically into the ground between the multi-stage H-shaped steels One or more continuous steel plates inserted vertically into the ground between the second row multi-stage H type steel and the multi-stage H type steel, which are placed vertically in the ground to the design depth while continuously welding one or more second row basic H type steels continuously Multi-stage steel sheet constructed by inserting vertically into the ground to the design depth while welding connection by means of In the H type steel, high depth prefabricated hypothesis, which is constructed by welding H type steel joint reinforcement between first row multi-stage H type steel, second row multi-stage H type steel and third row basic H type steel. It is an earth block structure.

The first row multi-stage H type steel, the second row multi-stage H type steel, the third row basic H type steel and the steel sheet is inserted.

One or more post-heat H-type steels constructed by vertically placing the H-type steel in the first row and the H-type steel in the first row placed in the ground vertically in the ground;

Inserting a steel plate perpendicular to the ground between the H-shaped steels in at least one of the first-row H-shaped steels or one or more post-heated H-shaped steels;

It consists of H type steel joint reinforcement welded between H type steel in the first row and at least one H type steel upper end by H type steel joint reinforcement,

In the one or more post-heat H-steels in which one or more post-heat H-type steels are placed vertically in the ground after the first-row H-type steels are placed in the ground and the first-row H-steels are placed in the ground. Insert a steel plate perpendicular to the ground between H type steel in any one or more of H type steel or at least one post heat H type steel, and then connect H type steel in the first row and one or more post H type steel upper ends. It is a high-depth prefabricated temporary construction structure characterized in that the coupling reinforcing material is constructed by welding.

The first row of H-shaped steel, followed by one or more post-row H-shaped steel constitutes a row, characterized in that the steel sheet is inserted.

A first row H-type steel placing step of placing H-type steel on the ground so that H-type steel is vertically placed in the ground;

A post heat H-type steel pouring step of placing the H-type steel on the ground so that at least one post-heat H-type steel is vertically placed behind the first row H-type steel;

A welding joint step of welding between the first row H type steel and the at least one post row H type steel by using an H type steel joint reinforcing material between the first row H type steel and the upper part of the post row H type steel;

1. At least one post-heat H-steel comprising a first row, comprising: a steel sheet inserting step of inserting a steel sheet in at least one row;

An excavation step of excavating an excavation area between the first row H-type steels facing each other;

H-shaped steel upper part of the first row H-type steel and the post-row H-shaped steel, which are configured through the foundation frame and the one or more post-heat H-steels, which are additionally reinforced, by the first-row H-type steel placing step Reinforced through the excavation step of excavating the excavation area in the construction of the temporary earthquake structure formed by inserting the steel plate between the one or more thermal H-type steel in the basic frame composed of the welding joint step of connecting and welding the joint reinforcement. High-depth prefabricated temporary cladding structure and installation method characterized by the temporary cladding structure.

It is characterized by a high-depth prefabricated temporary scaffolding structure and installation method comprising a row of H-type steels in the first row and one or more post-heat H-steels, followed by excavation of the excavation area after the steel sheet is inserted.

A first row H-type steel placing step of placing H-type steel on the ground so that H-type steel is vertically placed in the ground;

A post heat H-type steel pouring step of placing the H-type steel on the ground so that at least one post-heat H-type steel is vertically placed behind the first row H-type steel;

A welding joint step of welding between the first row H-type steel and the at least one post-heat H-type steel via the H-type steel joint reinforcing material between the first row H-type steel and the post-row H-type steel;

Steel sheet insertion step of inserting the steel sheet in one or more rows between the H-shaped steel;

An excavation step of excavating an excavation area between the first row H-type steels facing each other;

Reinforced concrete pouring step of constructing formwork and placing concrete after inserting the reinforcing structure into the empty space spaced by the design distance for one retaining wall composed of the first row H-type steel and steel sheet;

A drawing step of drawing the H-type steel and the steel sheet and removing the formwork after the reinforced concrete curing;

H-shaped steel upper part of the first row H-type steel and the post-row H-shaped steel, which are configured through the foundation frame and the one or more post-heat H-steels, which are additionally reinforced, by the first-row H-type steel placing step Reinforced through the excavation step of excavating the excavation area in the construction of the temporary earthquake structure formed by inserting the steel plate between the one or more thermal H-type steel in the basic frame composed of the welding joint step of connecting and welding the joint reinforcement. In addition to the temporary earthquake structures, after inserting the reinforcing structures apart from the design wall and inserting the formwork, placing concrete, and curing the H-shaped steel and steel plates after curing, Prefabricated temporary cladding structure and installation method.

It is a method that can make a permanent reinforced concrete retaining structure (retaining wall) at a much lower cost than the conventional method of making a concrete permanent blocking structure by drilling the ground through a perforator.

When the retaining wall is formed using the first-row H-type steel and the post-heat H-steel and the steel sheet, and the H-steel and the steel sheet cannot be recovered until the basic structure is completed, the turnover of the material decreases. As a result, the permanent reinforced concrete retaining wall structure is made, and the expensive H-type steel and steel sheet are recovered to improve the material turnover rate.

A first row H-type steel placing step of placing H-type steel on the ground so that H-type steel is vertically placed in the ground;

A second row H-type steel placing step of placing the H-type steel on the ground so that the second-row H-type steel is vertically placed after the first-row H-type steel;

Steel sheet insertion step of inserting the steel sheet between the H-shaped steel;

A reinforced concrete structure step of curing a permanent reinforced concrete structure by inserting a steel structure into an empty space from which the soil between the H type steels of the first row and the second row H type steel is removed, and then pouring concrete;

An excavation step of excavating an excavation area between the temporary row wall formed of the first row H-type steel and the steel sheet;

A pull-out step of removing the H-type steel and steel sheet; is a high-depth prefabricated temporary construction structure and installation method.

It is a high-depth prefabricated temporary block structure and installation method that excavates excavation area after creating permanent reinforced concrete structure.

H-type steel placing step of placing H-type steel on the ground so that H-type steel is vertically placed in the ground;

Steel sheet insertion step of inserting the steel sheet between the H-shaped steel;

An excavation step of digging an excavation area between the H-shaped steel and the earthen wall formed of the steel sheet;

A formwork step of constructing wall formwork after inserting and fixing the reinforcing structure, the underground wall piping, and the system box in an empty space separated by the design wall;

Reinforced concrete pouring step of pouring concrete;

After the reinforced concrete is cured, the drawing step to remove the H-shaped steel and steel sheet and formwork; high-depth prefabricated temporary construction clamshell structure and installation method.

When building the building as close to the land boundary as possible, it is a construction method that can be installed in close contact with the land boundary than any existing construction methods.

In other words, when constructing a new building between buildings, the existing construction method should construct an underground structure as close as possible to the earth wall after constructing the earth wall. In addition, a work space is needed to make the underground structure away from the retaining wall.

The present invention is in close contact with the earth boundary, placing the H-type steel and inserting the steel plate to construct the earthquake structure, and excavation of the excavation area by using the earthquake wall (H-type steel + steel plate) as one formwork wall to construct the rebar structure After inserting and fixing the pipes, boxes, and anchors that are inserted into the reinforcing structures, the molds are built and poured directly, and the underground building structure as close as possible to the land boundary is poured.

After curing the concrete, the steel plate and H-type steel are drawn out and then cast on the floor, and then the basement is poured. If the basement is two or more floors, it is poured up by floor as shown in the right wall of FIG.

H-type steel placing step of placing H-type steel on the ground so that H-type steel is vertically placed in the ground;

Steel sheet insertion step of inserting the steel sheet between the H-shaped steel;

An excavation step of digging an excavation area between the H-shaped steel and the earthen wall formed of the steel sheet;

Reinforced concrete placing step of constructing wall formwork and placing concrete after inserting reinforcing bar in space far away from design wall;

After the reinforced concrete is cured, the drawing step to remove the H-shaped steel and steel sheet and formwork; high-depth prefabricated temporary construction clamshell structure and installation method.

First and second rows of H-type steels formed by vertically placing a second row of H-type steels into the ground after the first-row H-type steels and a first row of H-type steels placed in the ground;

Inserting a steel plate perpendicular to the ground between the first and second row H-shaped steels;

Inserting the steel structure into the empty space from which the soil between the first and second columns of H-type steel and the steel sheet is removed, and then pouring concrete to cure the permanent reinforced concrete structure, and then removing the H-type steel and the steel sheet;

After the reinforced concrete is cured, it is separated from the one-sided temporary structure and the underground concrete structure, which is generated by drawing and removing the H-type steel and the steel plate, by the design distance. Temporary cladding structure and underground concrete structure in which reinforced concrete is placed on the floor after excavating soil between both temporary cladding structures and underground concrete structures after construction.

The earth block structure is necessary not only for the earth block structure for constructing the building but also for the construction of water pipes of reinforced concrete structures.

That is, the soil wall formed by digging the soil between the first row and the second row is used as a formwork, so it is convenient to construct the water and sewage reinforced concrete pipe as shown in FIG.

In detail,

First and second rows of H-type steels formed by vertically placing a second row of H-type steels in the ground after the first-row H-type steels and a first row of H-type steels placed in the ground;

Inserting a steel plate perpendicular to the ground between the first and second row H-shaped steels;

After inserting the steel structure into the empty space between the H-type steel and the steel plate in the first and second rows, the concrete is poured to cure the permanent reinforced concrete structure, and then the H-type steel and the steel plate are removed to remove the water and sewage When constructing the concrete pipe, if you install the remaining water and sewage reinforced concrete pipe in the same way as above, it is possible to efficiently construct the reinforced concrete water and sewage pipe when placing the reinforced concrete on the floor.

Placing H-type steel on the ground so that H-type steel is vertically placed in the ground;

Inserting a steel sheet between the H-shaped steels;

Excavating the excavation area between the retaining wall composed of the H type steel and the steel plate;

Constructing the wall formwork by the design distance to the earthen wall created by the excavation step;

Reinforcement structures, underground wall piping and system boxes are inserted in the space far away from the design wall, and the wall formwork is installed, concrete is poured and cured, and then the H-shaped steel and steel plate are removed and removed. Structure and underground concrete structure.

Placing H-type steel on the ground so that H-type steel is vertically placed in the ground;

Inserting a steel sheet between the H-shaped steels;

Excavating the excavation area between the facing wall of the H-shaped steel and the steel plate;

Inserting the reinforcing structure into the space away from the wall and designing the wall formwork and placing concrete;

Temporary cinder structure and underground concrete structure produced by drawing and removing formwork of H-type steel and steel plate after reinforced concrete is cured.

Placing H-type steel on the ground so that H-type steel is vertically placed in the ground;

Placing H-type steel on the ground so that at least one post-heat H-type steel is vertically placed behind the first-row H-type steel;

Welding between the first row H type steel and the at least one post row H type steel via an H type steel joint reinforcing material between the first row H type steel and the post row H type steel;

Inserting a steel sheet in one or more rows between the H-shaped steels;

Excavating an excavation area between the first row H-type steels facing each other;

Inserting the reinforcing structure into an empty space spaced by a design distance with respect to one retaining wall composed of the first row H-type steel and the steel sheet, and constructing wall formwork and placing concrete;

After reinforced concrete curing, it consists of H-shaped steel and steel plate, which is made of earth block structure composed of drawing and removing formwork,

In one or more post-heat H-type steel further reinforced to the basic frame composed of the first-row H-type steel, the first row H-type steel and the post-heat H-type steel upper end portion is connected by welding the H-type steel joint reinforcement After excavating the excavation area in the temporary earthquake structure constructed by inserting steel plates between one or more thermal H-type steels in the basic frame, and inserting the reinforcement structure after placing the reinforcing structure and placing concrete It is a high-depth prefabricated temporary cladding structure characterized by permanent reinforced concrete structure produced by drawing out the H-type steel and steel plate after curing.

The following description focuses on the dependent claims.

In one embodiment, for inserting the steel sheet between the first row H-shaped steel, the high depth, characterized in that replaced by sandwiching the wood earth plate between the first row H-shaped steel while excavating the excavation area instead of the steel sheet It is a prefabricated temporary structure.

After the second row, a steel plate is inserted between the post-heat steels to improve the stability of the structure of the retaining structure by acting as a webbed, and in the case of the first row, excavation area of the polygonal interior surrounded by the first row H-type steel is excavated. While inserting the wood earth plate between the H-shaped steel, the earth excavation is formed by forming the wood earth plate wall.

In one embodiment, the number of the post-heat H-shaped steel and the number of steel sheets inserted between the H-type steel is less than the number of steel plates inserted between the first row H-shaped steel and H-type steel, characterized in that less than It is a prefabricated temporary structure.

It is not necessary to do so when a safe structure is formed even if the polygons are not completely enclosed by the second row H-type steel plate and the steel plate with a distance from the first row retaining wall of the polygonal structure surrounded by the first column H-type steel plate and the steel sheet.

On the contrary, if the safety is not satisfactory in two rows, three and more rows are added to reinforce the construction.

In one embodiment, the H-type steel interior is a high-depth prefabricated temporary construction structure, characterized in that it comprises a coupling guide 22, 23 welded alternately.

In one embodiment, the H-type steel joint reinforcing member 21 fixed by welding is a high-definition prefabricated temporary construction structure, characterized in that the assembly is fixed by any one of the clamp, bolt and nut instead of welding. .

In one embodiment, the steel structure is inserted into an empty space from which the soil between the H-type steel and the post-heat H-steel in the first row is removed, and the concrete is poured to cure the permanent reinforced concrete structure, and then the H-type steel and the steel sheet. It is a high-depth prefabricated temporary construction structure characterized in that the removal of the draw.

In one embodiment, after excavating the excavation area (1) between the H-type steel in the first row facing each other in the above wall formed by the design distance away from the earth wall created by the wall and the distance formed by the design distance away from the earth wall It is a high-definition prefabricated temporary wall structure characterized by permanent reinforced concrete retaining wall which is created after inserting reinforcing bars into the empty space between wall formwork and curing after pouring concrete and drawing and removing formwork of H type steel and steel sheet.

In one embodiment, in the H-type steel and the steel sheet is placed in the vertical to be placed in the ground,

Pour basic H-shaped steel and weld one or more H-shaped steel in series, vertically to the design depth;

It is a high-depth prefabricated construction block structure, characterized in that the basic steel plate is inserted vertically between the H-shaped steel and inserted into the ground vertically to the design depth while welding one or more consecutive steel plates.

In one embodiment, the high-depth prefabricated temporary construction structure is characterized in that a non-woven fabric or a non-woven fabric coated with a release agent is attached to any one side or both sides of the empty space spaced apart, and then the concrete is poured after the reinforcing structure is inserted.

1: excavation area
2: groundwater
10: C type steel insertion hole
11: Type C steel guide frame
12: bonding reinforcement
13: steel sheet
14: Type C steel
15: H type steel
16: Another embodiment of the bond reinforcement
17: brace
21 is another embodiment of the H-type steel joint reinforcement for welding by connecting between the first and second row H-shaped steel
22, 23: staggered welded joint guide

Claims (15)

delete delete The first row constructed by vertically placing the ground to the design depth while continuously welding one or more rows to the first row foundation H-shaped steel 24 placed in the ground and the first row foundation H-shaped steel placed in the ground. Multi-stage H type steel;
A multi-stage steel sheet configured to be inserted into the ground vertically to a design depth while continuously welding one or more consecutively connected to the base steel sheet 13 vertically inserted into the ground between the first row multi-stage H-shaped steels;
Vertically inserting a second row base H-shaped steel 25 and a steel plate vertically poured into the ground;
It is composed of the H-type steel joint reinforcement 21 welded through the H-type steel joint reinforcement 21 between the first row multi-stage H-shaped steel and the second column H-shaped steel upper end,
A base consisting of a first-stage multi-stage H-steel placed vertically in the ground and a multi-stage steel sheet inserted between the first-stage multistage H-shaped steel and the multi-stage H-shaped steel vertically poured into the ground to the design depth while continuously welding one or more continuous In addition to the temporary earthquake structure, the excavation area is excavated after connecting the H-shaped steel joint reinforcement to the upper end of the second-row H-shaped steel and the first-row multi-stage H-shaped steel that are placed perpendicular to the ground.
Between the first row multi-stage H-shaped steel placed vertically in the ground and the top end of the second row basic H-steels placed spaced by the design distance, welded with H-type steel joint reinforcement, and multistage between the first-stage multi-stage H-shaped steel Prefabricated temporary deck structure with steel plate inserted.
First-tier multi-stage H type constructed by vertically pouring into the ground to the design depth while continuously welding one or more rows to the first-row basic H-shaped steel placed in the ground and the first-row basic H-shaped steel placed in the ground Steel;
A multi-stage steel sheet configured to be inserted vertically into the ground to a design depth while continuously welding one or more consecutively connected to the base steel sheet vertically inserted into the ground between the first row multi-stage H-shaped steels;
A second row base H-type steel and steel sheet vertically placed in the ground;
A third row base H-shaped steel and steel sheet vertically placed in the ground;
It consists of H type steel joint reinforcement welded by H-steel joint reinforcement between first row multi-stage H type steel, second row basic H type steel, and third row basic H type steel upper end.
A base consisting of a first-stage multi-stage H-steel placed vertically in the ground and a multi-stage steel sheet inserted between the first-stage multistage H-shaped steel and the multi-stage H-shaped steel vertically poured into the ground to the design depth while continuously welding one or more continuous In addition to the temporary cladding structure, the upper part of the second-row H-steel, the third-row H-steel, and the first-stage multi-stage H-steel, which are placed vertically in the ground, are connected to the H-type steel joint reinforcement and then excavated the excavation area. Characterized by
The first row multi-stage H-shaped steel placed vertically in the ground is welded by connecting the upper end of the second-row H-steel and the third-row H-steel, which are placed by a design distance and connected by H-steel joint reinforcement. High depth prefabricated temporary masonry structure with multi-stage steel sheet inserted between single row multi-stage H type steels.
First-tier multi-stage H type constructed by vertically pouring into the ground to the design depth while continuously welding one or more rows to the first-row basic H-shaped steel placed in the ground and the first-row basic H-shaped steel placed in the ground Steel;
Second row multi-stage H type constructed by vertically laying in the ground to the design depth while continuously welding at least one continuous connection to the second-row basic H-shaped steel placed in the ground and the second-row H-shaped steel placed in the ground Steel;
A multi-stage steel sheet configured to be inserted vertically into the ground to a design depth while continuously welding one or more welded base metal sheets inserted vertically into the ground between the H-shaped steels;
It consists of H type steel joint reinforcement welded by H-type steel joint reinforcement between the first row multi-stage H type steel and the second row multi-stage H type steel,
First row multi-stage H-shaped steel laid vertically to the ground to the design depth while continuously connecting one or more continuous H-steels vertically cast into the ground, and second row foundations vertically cast into the ground. The first row multistage H type steel and the second row after inserting the multi-stage steel sheet between the second row multi-stage H type steel and the multi-stage H type steel which are placed vertically in the ground to the design depth while continuously welding one or more H type steels together. It is characterized in that the excavation area (1) is excavated after connecting the H-shaped steel joint reinforcement to the upper end of the thermal multi-stage H-type steel,
The first row multi-stage H-shaped steel placed vertically in the ground and the second row multi-stage H-shaped steel placed at the distance of design distance are welded by H-bonded steel reinforcement, and the multi-stage steel sheet is inserted between the multi-stage H-shaped steels. High depth prefabricated temporary cladding structures.
First-tier multi-stage H type constructed by vertically pouring into the ground to the design depth while continuously welding one or more rows to the first-row basic H-shaped steel placed in the ground and the first-row basic H-shaped steel placed in the ground Steel;
Second row multi-stage H type constructed by vertically laying in the ground to the design depth while continuously welding at least one continuous connection to the second-row basic H-shaped steel placed in the ground and the second-row H-shaped steel placed in the ground Steel;
A third-row base H-shaped steel vertically poured into the ground;
A multi-stage steel sheet configured to be inserted into the ground vertically to a design depth while continuously welding at least one continuous steel plate inserted vertically into the ground between the first row multi-stage H-shaped steel and the second row multi-stage H-shaped steel;
It consists of H type steel joint reinforcement welded between the first row multi-stage H type steel, the second row multi-stage H type steel, and the third row basic H type steel by the coupling reinforcement at the upper end of the H type steel.
The first row multi-stage H type steel that is placed vertically in the ground to the design depth while continuously welding one or more columns of the first row H type steel that is placed in the ground and then continuously welded to the first row basic H type steel placed in the ground. Two-stage H-steels placed in the ground and placed vertically in the ground and inserted into the ground vertically to the design depth while continuously welding one or more foundation steel sheets inserted vertically into the ground between the multi-stage H-shaped steels One or more continuous steel plates inserted vertically into the ground between the second row multi-stage H type steel and the multi-stage H type steel, which are placed vertically in the ground to the design depth while continuously welding one or more second row basic H type steels continuously Multi-stage steel sheet constructed by inserting vertically into the ground to the design depth while welding connection by means of In the H type steel, characterized in that configured between the first row multi-stage H type steel, the second row multi-stage H type steel and the third row basic H type steel by welding the H type steel joint reinforcing material as a medium,
The H-type steel joint reinforcement is welded between the first-stage multi-stage H-shaped steel and the second-stage multi-stage H-steel and the third-row basic H-shaped steel which are placed by the vertical distance and vertically placed in the ground. High depth prefabricated temporary masonry structure with multi-stage steel sheet inserted between the first and second row multi-stage H type steels.
One or more post-heat H-type steels constructed by vertically placing the H-type steel in the first row and the H-type steel in the first row placed in the ground vertically in the ground;
Inserting a steel plate perpendicular to the ground between the H-shaped steels in at least one of the first-row H-shaped steels or one or more post-heated H-shaped steels;
It consists of H type steel joint reinforcement welded between H type steel in the first row and at least one H type steel upper end by H type steel joint reinforcement,
In the one or more post-heat H-steels in which one or more post-heat H-type steels are placed vertically in the ground after the first-row H-type steels are placed in the ground and the first-row H-steels are placed in the ground. Insert a steel plate perpendicular to the ground between H type steel in any one or more of H type steel or at least one post heat H type steel, and then connect H type steel in the first row and one or more post H type steel upper ends. Characterized in that the joint reinforcing material is configured by welding,
A steel joint reinforcement welded between the first row of H-shaped steel laid vertically in the ground and the one or more post-heated H-shaped steels laid vertically behind the first row of H-shaped steel, and connected to the first row of H-shaped steel or one or more High-temperature prefabricated temporary cladding structure in which a steel sheet is inserted between any one or more H-shaped steels.
The method according to any one of claims 3, 4, 5, 6, and 7,
For inserting steel sheets between the first row H-shaped steels,
A high-definition prefabricated construction block structure, characterized in that by replacing the steel earth plate between the first row H-shaped steel while excavating the excavation area instead of the steel sheet.
The method according to any one of claims 3, 4, 5, 6, and 7,
And the number of steel plates inserted between the number of post-row H-shaped steels and the H-type steel is less than the number of steel sheets inserted between the first-row H-shaped steels and the H-shaped steels.
The method according to any one of claims 3, 4, 5, 6, and 7,
H-shaped steel interior is a high-depth prefabricated temporary construction structure, characterized in that it comprises a cross-welded coupling guide (22, 23).
The method according to any one of claims 3, 4, 5, 6, and 7,
H-type steel joint reinforcing member to be fixed by welding is a high-definition prefabricated temporary construction structure, characterized in that the assembly is fixed by any one of the clamp, bolt and nut instead of welding.

The method according to any one of claims 3, 4, 5, 6, and 7,
After inserting the steel structure into the empty space from which the soil between the H-type steel in the first row and the post-heat H-type steel is removed, the concrete is poured to cure the permanent reinforced concrete structure, and then the H-type steel and the steel sheet are removed. High depth prefabricated temporary cladding structure.
The method according to any one of claims 3, 4, 5, 6, and 7,
After excavating the excavation area (1) between the H-shaped steels in the first row, construct the wall formwork by the design distance away from the created wall, and then add the reinforcing bar to the empty space between the wall formwork and the wall formwork created by the design distance. A high-definition prefabricated temporary cladding structure characterized by permanent reinforcement retaining walls, which are formed after pouring and curing concrete after insertion and removing formwork and removing formwork.
The method of claim 7, wherein
H-steels and steel sheets are to be placed vertically in the ground,
Pour basic H-shaped steel and weld one or more H-shaped steel in series, vertically to the design depth;
A high-definition prefabricated construction block structure, characterized in that the basic steel sheet is inserted vertically between the H-shaped steel and vertically inserted into the ground to the design depth while welding one or more consecutive steel plates.
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