KR20230055613A - Box-type CFT column with high-strength self-compacting concrete guide plate to reduce material separation and manufacturing method thereof - Google Patents

Abstract

The present invention relates to a CFT column in which concrete is poured inside a box-shaped steel plate. The present invention relates to a box-type CFT column equipped with a high-strength self-filling concrete pouring guide plate that reduces material separation and a construction method thereof in which a vertical internal diaphragm is welded and fixed to the inside of a box-shaped steel plate column, an inner part of the vertical internal diaphragm is formed to be inclined downward at a certain inclination angle, guide plates formed in zigzags are installed at regular intervals, facing each other in the longitudinal direction of the box-shaped steel plate column, and high-strength self-filling concrete with reduced material separation is poured through the guide plate, thereby capable of providing a function of easily and stably fixing the guide plate to the vertical diaphragm while reinforcing stress on the CFT column.

Description

Box-type CFT column with high-strength self-compacting concrete guide plate to reduce material separation and manufacturing method thereof}

The present invention is a material separation-reduced high-strength self-filling concrete in which the high-strength self-filling concrete is tightly filled by pouring the material separation-reduced high-strength self-filling concrete using a guide pipe welded and fixed to the vertical inner diaphragm inside the box-shaped steel plate column. It relates to a box-shaped CFT column equipped with a casting guide plate and a manufacturing method thereof.

CFT (Concrete Filled Steel Tube) column is a structure in which concrete is filled inside a plate formed of steel plate. Concrete is very strong against compressive force but vulnerable to tensile force, and steel plate is strong against both tensile and compressive force, but is vulnerable to local buckling. It is a combination of complementary material properties. In CFT columns, the steel plate constrains lateral deformation to increase the compressive capacity of the concrete, and the concrete significantly increases the capacity without increasing the cross section by reducing the local buckling of the plate. . Such a CFT column has the advantage of being structurally excellent because it does not require a separate formwork because the steel plate serves as a permanent formwork, and the steel plate firmly restrains the concrete filled inside.

However, since the steel plate column used in the CFT column as described above is assembled by welding four sides of the steel plate, torsion may occur during manufacture, so a separate hardware is required to prevent this. In the prior art, anti-torsion steel was used to facilitate manufacturing, but it did not play a structural role, and diaphragms were installed inside and outside separately in order to have the structural function of the CFT column.

In addition, for CFT columns, the thickness of the steel plate gradually becomes thinner for economical design, and since the concrete poured inside the steel plate uses high-flow concrete, there may be a case of fullness due to lateral pressure during placement, which poses a safety problem. In particular, when concrete is poured on a CFT column, material separation occurs as the concrete falls freely. To prevent this, the concrete pouring height was set. Registered Patent Publication No. 2056259, 'Rectangular CFT column equipped with internal diaphragm and concrete guide tube', in which concrete is cast inside a steel plate column forming a CFT column using an induction pipe without free fall, has been applied for and registered. The selection name is to install a horizontal internal diaphragm on the inside of the CFT column where the CFT column and the beam are combined, and install a concrete guide pipe at the corner of the internal diaphragm, so that the concrete cast in the guide pipe is an open inclined pipe and the following It is filled from the bottom through the closed straight pipe, and the poured concrete flows down the open inclined pipe and then enters the closed straight pipe and flows down, so the flow speed is not constant, and the open inclined pipe and the closed straight pipe There is a problem that the concrete being poured at the part where the pipes meet is stagnant and clogged. In particular, the internal diaphragm reinforced inside the CFT column to which the beam is connected is formed in a horizontal '+' shape and blocks most of the inner horizontal part of the CFT column, acting as a factor that interferes with the concrete being placed on the CFT column. It acts as a factor that lowers the filling ability.

In addition, when concrete is placed on a steel plate column that forms an elongated CFT column, a funnel portion is formed at the top instead of an induction pipe, and a tremie pipe having a pipe portion coupled under the funnel portion is used. Since it rotates and moves to the lower part, the air pressure inside the pipe part is minimized and discharged to the end discharge port of the pipe part, but as the concrete discharge proceeds, the lower part of the pipe part is buried in concrete at a certain depth or more, and when it is buried at least about 2 m, the pipe part There is a problem that the pressure is applied to the inside and clogged. Accordingly, in order to solve this problem, concrete pouring had to be carried out while sequentially raising and cutting the tremie pipe in the vertical direction. In order to raise the tremie pipe, heavy equipment such as service cranes and pump cars had to be used, so steel plate charging using the tremie pipe The economic feasibility of the work is reduced, the work time is long, and as the construction progresses, the equipment movement space is limited, resulting in many inconveniences.

In addition, the 'recessed pouring pipe for pouring pillar', published in Publication No. 2021-0016759, is a mesh-type tremie pipe composed of a net with the top and bottom of the charging column open in the longitudinal direction of the column member within the column formwork. The embedded type pouring pipe must be equipped with a separate mesh-type tremie pipe when manufacturing the column, and a separate hopper that can be poured by being connected to the ready-mixed concrete chute is required during pouring. And 'Pipe-embedded charging column for concrete pouring', which is published in Publication No. 2017-0132559, is difficult to install a pipe for concrete pouring when the charging column is small, and if the above makes the pipe for concrete pouring smaller, the charging column It is possible to bury it in, but it has a high possibility of blockage during concrete pouring.

On the other hand, the applicant of the present application is a self-filling high-flow concrete composition in which fluidity is high, material separation is suppressed, and tight filling is performed by the weight of the concrete without separate compaction in the formwork in which the concrete is poured, in order to build an underwater structure or foundation. In order to apply it to the installed caisson, we have applied for and registered Patent Registration No. 1862168, 'Self-filling High Flow Concrete Composition' and Patent Registration No. 2011377, 'Self-filling concrete for normal strength using mixture for adjusting viscosity', When the concrete composition mixed as described above is poured and applied inside the steel plate column forming the CFT column, various stress reinforcing materials such as the diaphragm installed inside the steel plate column and high viscosity of high-strength concrete impede the sealing of the concrete due to poor filling. In the case of a concrete composition applied to a high-strength CFT column due to concerns about acting as a factor, a separate mix for material separation-reducing type high-strength self-filling concrete is required.

Republic of Korea Patent Registration No. 2056259 Republic of Korea Patent Publication No. 2021-0016759 Republic of Korea Patent Publication No. 2017-0132559 Republic of Korea Patent Registration No. 1862168 Republic of Korea Patent Registration No. 2011377

Accordingly, the present invention has been proposed to solve the above conventional problems, and the present invention installs a vertical inner diaphragm on the inner side of a box-shaped steel plate column to which a CFT column and a beam are coupled to reinforce the stress on the CFT column while providing vertical It provides a function to easily and stably fix the guide plate to the inner diaphragm.

In addition, the present invention reinforces stress by increasing the height of the vertical inner diaphragm installed on the inner side of the joint between the CFT column and the beam where the stress concentration is high, and the vertical inner diaphragm installed in the area where the stress concentration is not high It serves to increase the economic feasibility of installing a vertical internal diaphragm by reducing the height and catching the twist of the CFT column.

In addition, the present invention provides that the concrete to be poured naturally descends without clogging because the inclined guide plates fixed to the vertical inner diaphragm are all open, thereby increasing the concrete filling of the CFT column.

In addition, the present invention adjusts the distance between the vertical inner diaphragm and the vertical inner diaphragm in connection with the inclination angle of the guide plate so that all the concrete poured on the guide plate naturally flows into the guide plate without leaving the guide plate installed on the opposite side below. It is in providing something that goes down and recharges.

In addition, the present invention provides to reduce material separation and improve filling performance of concrete to be cast by mixing material separation-reducing high-strength self-filling concrete.

The present invention relates to a box-shaped CFT column equipped with a material-separation-reduced high-strength self-filled concrete pouring guide plate, in which concrete is poured inside a box-shaped steel plate in which a lower plate, left and right side plates and an upper plate are combined, the lower plate, A vertical internal diaphragm to which four vertical steel plates having a certain height are welded and fixed to the center of the left and right side plates and the upper plate; It is fixed to the upper end of the vertical steel plate and the inside of the vertical steel plate on both sides to induce the concrete to be poured, and is formed inclined downward with a certain inclination angle, facing each other in the downward direction in the longitudinal direction of the box-shaped steel plate column, and zigzag at regular height intervals. Guide plate formed of; It is characterized in that the material separation-reducing high-strength self-filling concrete is poured on the box-shaped steel plate column in which the vertical inner diaphragm and the guide plate are installed.

In addition, the present invention is characterized in that the height of the vertical inner diaphragm installed on the inner side of the box-shaped steel plate column in the portion where the CFT column and the beam are installed is greater than the height of the vertical inner diaphragm installed in the portion where the CFT column and the beam are not coupled. to be

In addition, the present invention is characterized in that the guide plate is composed of an inclined plate and a guide plate.

In addition, the present invention is characterized in that a through hole is formed in the guide plate to reduce the buoyancy of the concrete being poured and to secure integrity with the concrete.

In addition, the present invention is characterized in that the lower end of the guide plate is formed so that the inclined line formed by the inclination angle of the guide plate passes through the center of the box-shaped steel plate column and is positioned to pass inside the upper end of the guide plate facing each other in a downward direction. to be

In addition, the present invention is characterized in that the size of the inclination angle of the guide plate is set in association with the height between the vertical inner diaphragm and the vertical inner diaphragm installed directly below.

In addition, in the present invention, in the material separation reduction type high-strength self-filling concrete is mixed with mixing water, cement-containing binder, fine aggregate, coarse aggregate and water reducing agent, the binder is 50 to 60% by weight of one type of ordinary Portland cement, blast furnace slag fine powder It is composed of 10 to 30% by weight and 20 to 30% by weight of fly ash, and the total amount of powder constituting the binder is the mass included in the unit volume, and is composed of high-strength concrete with a compressive strength of 40MPa or more at 28 days of age in the range of 450 to 580kg / ㎥ characterized by

In addition, the present invention relates to a method for manufacturing a box-shaped CFT column equipped with a material-separation-reduced high-strength self-filled concrete pouring guide plate, comprising the steps of: a) positioning a lower plate forming a box-shaped steel plate column on a horizontal surface; b) positioning a corner of the vertical inner diaphragm to be welded and fixed to a prefabricated guide plate at the inner center of the lower plate using a temporary support, and then welding and fixing the corner of the vertical inner diaphragm to the lower plate; c) positioning both side plates at both ends of the lower plate in the width direction, welding the lower plate and both side plates, and welding and fixing corner portions of the vertical inner diaphragm closely attached to inner centers of the both side plates; d) After positioning the top plate at the upper end of the both side plates, the both side plates and the top plate are welded together, and the top plate and the vertical inner diaphragm are welded to the welding groove formed to weld the corner portion of the top plate and the vertical inner diaphragm. Welding and fixing the corner of the; e) It is characterized in that the box-shaped steel plate column in which the vertical internal diaphragm and the guide plate are installed is erected and then material separation-reducing high-strength self-filling concrete is poured through the guide plate.

The present invention has the effect of easily and stably fixing the guide plate to the vertical inner diaphragm while reinforcing the stress on the CFT pillar by installing the vertical inner diaphragm on the inner side of the box-shaped steel plate pillar forming the CFT pillar.

In addition, the present invention provides a role of increasing economic efficiency according to the installation of the vertical internal diaphragm by adjusting the size according to the height of the vertical internal diaphragm according to the position where the vertical internal diaphragm is installed.

In addition, in the present invention, since all of the inclined guide plates fixed to the vertical inner diaphragm are open, the concrete to be poured naturally rises from the bottom to the top of the box-shaped steel plate column without material separation, improving the concrete filling of the CFT column. Height works.

In addition, the present invention adjusts the height between the vertical inner diaphragm and the vertical inner diaphragm or the height between the guide plate and the guide plate, so that all of the concrete poured on the guide plate flows into the guide plate without leaving the guide plate installed on the opposite side below. It goes down naturally and has the effect of tightly filling the box-shaped steel plate column.

In addition, the present invention has the effect of reducing material separation and improving the filling performance of concrete by mixing the material separation-reduced high-strength self-filling concrete.

1a is a perspective view of a guide plate and a vertical internal diaphragm installed inside a box-shaped steel plate column forming a CFT column in the present invention;
Figure 1b is a partially cut perspective view of a guide plate and a vertical inner diaphragm installed inside a box-shaped steel plate column forming a CFT column in the present invention
Figure 1c is a cross-sectional view showing a state in which concrete is poured by installing a guide plate and a vertical internal diaphragm inside a box-shaped steel plate column forming a CFT column in the present invention
Figure 2a is a perspective view of the guide plate and the vertical inner diaphragm installed inside the box-shaped steel plate column forming a CFT column coupled to the beam in the present invention
Figure 2b is a partially cut perspective view of the guide plate and the vertical inner diaphragm installed inside the box-shaped steel plate column forming the CFT column coupled to the beam in the present invention
Figure 2c is a cross-sectional view showing a state in which concrete is poured by installing a guide plate and a vertical internal diaphragm inside a box-shaped steel plate column forming a CFT column combined with a beam in the present invention
Figure 3 is a photograph of a formwork installed to test the filling performance according to the pouring of the general high-flow concrete and the material separation-reduced high-strength self-filling concrete of the present invention
4 is a photograph of the casting process and formwork demolding of the general high-flow concrete and the material separation-reduced high-strength self-filling concrete of the present invention
Figure 5 is a surface photograph of the general high-flow concrete cured by pouring and the material separation-reduced high-strength self-filling concrete of the present invention after formwork demoulding
6 is a perspective view in which a prefabricated guide plate and a vertical internal diaphragm are placed on a lower plate of a box-shaped steel plate and welded and fixed by a temporary support
7 is a perspective view showing a state in which first one side plate of both side plates is welded to both ends of the lower plate in the width direction following FIG. 6;
Figure 8 is a perspective view showing that the top plate is welded to the upper end of the side plates on both sides following Figure 7;
9 is a perspective view illustrating welding and fixing a corner portion of a top plate and a vertical inner diaphragm through a welding groove formed in the top plate following FIG. 8;

Hereinafter, the present invention will be described in detail based on the accompanying drawings. 1a is a perspective view of a guide plate and a vertical internal diaphragm installed inside a box-shaped steel plate column forming a CFT column in the present invention, and FIG. Figure 1c is a partially cut perspective view of the installed frame, and Figure 1c is a cross-sectional view showing a state in which concrete is poured by installing a guide plate and a vertical inner diaphragm inside a box-shaped steel plate column forming a CFT column in the present invention. 2a to 2c show a state in which a beam is coupled to a box-shaped steel plate column forming the CFT column of 1a to 1c.

In the present invention, the box-shaped steel plate column 10 into which concrete is poured is a combination of a lower plate 11, left and right side plates 12 and 12', and an upper plate 13, and the lower plate 11 and the left and right side plates (12, 12 ') and the vertical inner diaphragm 20 to which four rectangular vertical steel plates (21, 21') having a certain height (D, d) are welded and fixed to the center of the top plate 13, and the cast It is welded and fixed to the upper end of the vertical steel plate 21 and the inner side of the vertical steel plate 21' on the side to induce concrete, and is formed inclined downward with a certain inclination angle (θ), and is formed downward in the longitudinal direction of the box-shaped steel plate column 10. Guide plates 30 are installed facing each other and formed in a zigzag pattern at intervals of a certain height (h). The height (D) of (20) is formed larger than the height (d) of the vertical inner diaphragm 20 installed in a region where the CFT column and beam are not coupled.

The guide plate 30 is composed of an inclined plate 31 and a guide plate 32, and when concrete flows down through the inclined plate 31 of the guide plate 30 and is filled in the box-shaped steel plate column 10, the concrete to be poured The guide plate 30 buried in the buoyancy, which is a force that acts to rise to the upper part by the buoyancy generated from the concrete to be filled, acts and reduces this buoyancy while curing the concrete to be poured. A through hole 33 is formed to secure the integrity of the

As shown in FIGS. 1b and 1c and FIGS. 2b and 2c, the inclined plate 31 constituting the guide plate 30 is formed at an inclination angle θ inclined downward, and the concrete to be poured on both sides of the inclined plate 31 The guide plate 32 is installed so that it flows down well without leaving the inclined plate 31, so that the concrete to be poured, as shown in FIGS. It naturally flows down and the concrete is filled tightly from the lower part of the box-shaped steel plate column 10.

The guide plate 30 of the present invention shows only the inclined plate 31, which is a straight flat plate, and the guide plate 32 installed on both sides of the inclined plate 31 in the drawing, but this shows one embodiment of the guide plate 30. The shape of the guide plate 30 can be diversified so that the concrete to be cast as such can naturally flow down through the inside of the guide plate 30 without leaving the side of the guide plate 30.

In the present invention, the lower end 35 of the guide plate 30 passes through the center (C-C') of the box-shaped steel plate column 10 and is formed by the inclination angle θ of the guide plate 30 (S) -S') is formed to pass inside the upper end 34 of the guide plate 30 facing each other in the downward direction, which means that the lower end 35 of the guide plate 30 is the box-shaped steel plate column 10 ) by being located through the center (C-C ') of the concrete to be poured, all concrete, including the concrete directly below, flows down to the guide plate 30 installed on the opposite side directly below the guide plate 30, and also , The inclination line (S-S') formed by the inclination angle (θ) of the guide plate 30 is placed so that it passes inside the upper end 34 of the guide plate 30 facing each other in the downward direction. This is to allow the descending concrete, which is accelerated according to the inclination angle (θ) of the guide plate 30 among the concrete, to flow down into the guide plate 30 installed on the opposite side directly below the guide plate 30.

Therefore, the size of the inclination angle (θ) of the guide plate 30 is set in association with the height (h) between the vertical inner diaphragm 10 and the vertical inner diaphragm 10 installed on the lower side, all of the concrete being poured. In order to naturally flow down through the guide plate 30, the lower end 35 of the guide plate 30 passes through the center (CC ') of the box-shaped steel plate column 10 as described above, and the guide plate 30 ) formed by the inclination angle θ of the inclination line (S-S') is formed so as to pass inside the upper end 34 of the guide plate 30 facing each other in the downward direction.

As shown in FIGS. 2A to 2C, the present invention installs the vertical internal diaphragm 20 on the inner side of the box-shaped steel plate column 10 to which the CFT column and the beam are coupled to reinforce the stress on the CFT column while the vertical internal diaphragm 30 ), the guide plate 30 can be easily and stably fixed, and the vertical inner diaphragm 20 installed on the inner side of the joint where the CFT column and beam with a lot of stress concentration increases the height D to reinforce the stress In addition, in the case of the vertical internal diaphragm 20 installed in a region with high stress concentration, the height (d) is reduced to catch the twist of the steel plate of the CFT column, thereby increasing the economic feasibility of installing the vertical internal diaphragm 20 role

In addition, in the present invention, since the inclined guide plates 30 fixed to the vertical inner diaphragm 20 are all open, the concrete to be poured naturally flows from the bottom to the top of the box-shaped steel plate column 10 without material separation. It kicks up to increase the concrete filling of the CFT column, and since the vertical inner diaphragm 20 is integrally formed with the guide plate 30 by welding and fixing, the vertical inner diaphragm 20 and the guide plate 30 reinforce stress together. It has the effect of having the function to do.

In addition, the present invention relates to the inclination angle θ of the guide plate 30 and the height h between the vertical inner diaphragm 20 and the vertical inner diaphragm 20 or the guide plate 30 and the guide plate 30 ) by adjusting the height (h) of the guide plate 30 so that all the concrete poured on the guide plate 30 naturally descends into the guide plate without leaving the guide plate 30 installed on the opposite side below and is tightly filled in the box-shaped steel plate column has the effect of

In the present invention, when the generally applied high-strength concrete is poured into the box-shaped steel plate column 10 in which the vertical inner diaphragm 20 and the guide plate 30 are installed, the high-strength concrete has high viscosity, resulting in poor filling of the concrete. Since it acts as an element that inhibits concrete from being filled tightly, the present invention reduces material separation and improves the filling performance of concrete while improving the fluidity of concrete. apply

In the material separation-reducing high-strength self-filling concrete of the present invention, mixing water, binder including cement, fine aggregate, coarse aggregate and water reducing agent are mixed,

The binder is composed of 50 to 60% by weight of one type of ordinary Portland cement, 10 to 30% by weight of blast furnace slag fine powder, and 20 to 30% by weight of fly ash, and the total powder amount constituting the binder is 450 to 450 to the mass included in the unit volume It is made of high-strength concrete with a compressive strength of 40MPa or more at 28 days of age in the range of 580kg/㎥. Comparative examples in Table 1 below are mixtures of general high-flow concrete, and examples are mixtures of material separation-reduced high-strength self-filling concrete applied to the CFT columns of the present invention.

division W/B
(%) S/a
(%) Unit volume mass (kg/㎥) Water Binder S G25 G20 comparative example 29.2 47.3 159 545 775 863 - Example 32.1 54.9 170 530 890 - 730

W/B: water/binder, S/a: fine aggregate rate, W: water, Binder: binder, S: fine aggregate, G25: 25mm coarse aggregate, G20: 20mm coarse aggregate, Table 2 below shows the examples of Table 1 above and As a comparison with Comparative Example, viscosity and inductivity are increased by increasing the fine aggregate ratio (S/a), viscosity is increased by using a lot of fly ash (F/A), and fluidity and filling speed are improved by increasing unit quantity. In order to improve the viscosity and cohesive action of the high-performance water reducing agent, viscosity and material separation resistance were improved by adding a thickener (VMA), and the maximum size of the aggregate was reduced from 25mm to 20mm to improve rebar penetration and fluidity.

division characteristic improve performance S/a height Increased viscosity and inductivity Use F/A plenty increase in viscosity unit quantity height Improve fluidity and filling speed high performance water reducing agent Mixture for viscosity control (+VMA) Improved viscosity and material separation resistance Coarse aggregate maximum size 20mm Improving rebar passability and fluidity

Table 3 below shows the slump flow (unit mm) and the time to reach 500 mm of slump flow (T ₅₀₀ , sec) by measuring the slump flow according to KS F 2594 'Concrete Flow Test Method', and the concrete is from the center to 500 mm It measures the arrival time and indicates the viscosity and pouring speed. That is, slump flow is a liquidity evaluation method, and T ₅₀₀ is a filling speed and performance evaluation method. Examples 1 and 2 satisfied the filling evaluation T ₅₀₀ of 3 to 10 seconds in Comparative Examples 1 and 2, but as T ₅₀₀ was further shortened in Examples 1 and 2 compared to Comparative Examples 1 and 2, the fluidity and It shows that the filling performance is increased, and the water reducing agent is expressed as AD (%).

In the above, it was confirmed that the slump flow was within the target value of 600 to 700 mm, and in the plastic strength representing material separation and workability, when the plastic strength was 150 or more, the workability was poor. Examples 1 and 2 had a target value of 70 to 120 It was confirmed that the workability was good within the range. As for the compressive strength, as the 7-day compressive strength came out to be 39.7MPa and 35.6MPa, it was confirmed that the compressive strength at 28 days of age naturally came out over 40MPa according to the increase table of compressive strength according to age.

division AD
(%) Slump
flow(mm) T _-500
(SEC) air volume
(%) Rheology Compressive strength (MPa) yield strength plastic strength 3 days 7 days 28 days Example 1 1.50 680 5.1 3.2 78.2 24.1 39.7 - Example 2 1.40 645 4.0 5.6 4.5 60.5 22.9 35.6 - Comparative Example 1 0.90 655 7.4 3.0 160.8 31.0 47.9 - Comparative Example 2 1.30 640 6.2 5.8 15.8 110.7 27.5 43.5 -

In the present invention, in the polymer polymer for reducing material separation and improving filling performance, a polymer having high affinity for water capable of reacting with the mixing water and the surface of the powder was used in a weight ratio of 20 to 45 relative to the content of the water reducing agent, concrete By reducing the high viscosity of the high-strength concrete mixture through the reduction of friction between particles, the occurrence of filling defects due to excessive viscosity was prevented, and the hydrophilic polymer composition is cellulose-based, starch-based, gum, polymer, Two or more of the glycols were used in the form of polymers in which a mixture was used.

Figure 3 is a photograph of a formwork installed for a mock-up test test to test the filling performance according to the casting of the general high-flow concrete and the material separation-reduced high-strength self-filling concrete of the present invention, the left mark ① is the mixed It is a formwork in which general high-flow concrete is poured, and the middle mark ② is a formwork in which a buffer material corresponding to the guide plate 30 of the present invention is installed in the center of the formwork in placing the material separation-reduced high-strength self-filling concrete of the present invention. , Mark ③ on the right is a formwork installed to fill the material separation-reducing high-strength self-filling concrete without installing a buffer material corresponding to the guide plate of the present invention inside the formwork.

Figure 4 is a photograph of the casting process and formwork demolding of the general high-flow concrete and the material separation-reduced high-strength self-filling concrete of the present invention in the present invention, after pouring and curing the concrete with a concrete hopper in the three forms shown in FIG. This is a picture showing the front and side of the demolded specimen.

5 is a photograph of the surface after mold demolding of the general high-flow concrete cured by pouring and the material separation-reduced high-strength self-filling concrete of the present invention, which is rare on the surface of the general high-flow concrete cured by pouring on the formwork marked ① in FIG. While rare small holes are formed, the surface of the material separation-reduced high-strength self-filling concrete of the present invention, which is cast and cured in the form ② and ③ of FIG. 3, is formed smoothly with almost no small holes. In particular, when it is seen that the surface of the material separation-reducing type high-strength self-filling concrete poured and cured in the form ② of FIG. 3 is formed more smoothly than the mark ③ of FIG. It was confirmed that doing so is more effective in reducing material separation than not installing a buffer material.

6 to 9 are perspective views sequentially showing a method of manufacturing a box-type CFT column equipped with a material separation-reducing high-strength self-filling concrete pouring guide plate.

6 is a perspective view in which a prefabricated guide plate 20 and a vertical internal diaphragm 20 are placed and fixed on a lower plate 11 forming a CFT column by a temporary support 40, showing the box-shaped steel plate column 10 After placing the lower plate 11 to be formed on a horizontal surface, the corner of the vertical inner diaphragm 20 coupled to the guide plate 30 pre-fabricated at the inner center of the lower plate 11 is used with the temporary support 40. After positioning, it shows the step of welding and fixing the corner of the vertical internal diaphragm 20 to the lower plate 11.

FIG. 7 is a perspective view showing a state in which first one side plate 12 of both side plates 12 and 12′ is welded to both ends of the lower plate 11 in the width direction, following FIG. 6, of the lower plate 11 After placing both side plates 12 and 12' at both ends in the width direction, the lower plate 11 and both side plates 12 and 12' are welded together, and the inner center of both side plates 12 and 12' is in close contact. It has a step of welding and fixing the corner of the vertical inner diaphragm (20).

FIG. 8 is a perspective view showing that the top plate is welded to the upper ends of both side plates following FIG. 7, and FIG. 9 is a perspective view showing that the top plate and the vertical inner diaphragm are welded and fixed through welding grooves formed in the top plate, following FIG. As such, after positioning the top plate 13 at the upper end of the both side plates 12 and 12', the both side plates 12 and 12' and the top plate 13 are welded together, and the top plate 13 and the vertical A box-shaped steel plate that forms a CFT column through the step of welding and fixing the upper plate 13 and the corner of the vertical internal diaphragm 20 by groove welding to the welding groove 50 formed to weld and fix the corner of the diaphragm 20 The installation of the vertical internal diaphragm 20 and the guide plate 30 to the pillar 10 is completed.

Finally, after the box-shaped steel plate column 10 to which the vertical internal diaphragm 20 and the guide plate 30 are installed is erected, the box-shaped steel plate column 10 installed inside the box-shaped steel plate column 10 is passed through the guide plate 30 to reduce material separation. By pouring self-filled concrete, the present invention completes the production of a box-type CFT column equipped with a high-strength self-filled concrete pouring guide plate with reduced material separation.

Although the present invention has been described in more detail by way of examples above, the present invention is not necessarily limited to these examples, and may be variously modified without departing from the spirit of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted according to the claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

10: box-shaped steel plate column 11: lower plate
12, 12 ': side plate 13: top plate
20: vertical internal diaphragm 21, 21 ': vertical steel plate
30: guide plate 31: inclined plate
32: guide board 33: through hole
34: upper end of the guide plate 35: lower end of the guide plate
40: temporary support 50: welding groove
D, d: height of the vertical inner diaphragm
h: the distance between the diaphragm in the vertical and the diaphragm in the vertical
θ: angle of inclination

Claims (9)

In the CFT column in which concrete is poured inside the box-shaped steel plate 10 to which the lower plate 11, the left and right side plates 12 and 12', and the upper plate 13 are combined,
Four vertical steel plates 21 and 21' having a certain height D and d are welded and fixed to the center of the lower plate 11, the left and right side plates 12 and 12', and the upper plate 13. Fram 20;
It is fixed to the upper end of the vertical steel plate 21 and the inner side of the vertical steel plate 21' on both sides to induce the concrete to be poured, and is formed inclined downward with a certain inclination angle θ, and the box-shaped steel plate column 10 guide plates 30 facing each other in the longitudinal direction downward and formed in a zigzag pattern at intervals of a predetermined height (h);
A material separation-reduced high-strength self-filling concrete pouring guide plate is provided, characterized in that the material separation-reduced high-strength self-filling concrete is poured on the box-shaped steel plate column 10 on which the vertical inner diaphragm 20 and the guide plate 30 are installed. boxed CFT columns.
The method of claim 1,
The height (D) of the vertical internal diaphragm 20 installed on the inner side of the box-shaped steel plate column 10 at the portion where the CFT column and the beam to be installed are coupled is the vertical internal diaphragm installed in the portion where the CFT column and the beam are not coupled. A box-type CFT column equipped with a material separation-reducing high-strength self-filled concrete pouring guide plate, characterized in that it is greater than the height (d) of (20).
The method of claim 1,
The guide plate 30 is a box-shaped CFT column equipped with a material separation-reduced high-strength self-filling concrete pouring guide plate, characterized in that consisting of an inclined plate 31 and a guide plate 32.
The method of claim 1,
The guide plate 30 reduces the buoyancy of the concrete to be poured and has a through hole 33 formed to secure integrity with the concrete. .
The method of claim 1,
The lower end 35 of the guide plate 30 passes through the center of the box-shaped steel plate column 10 and the inclined line S-S' formed by the inclined angle θ of the guide plate 30 moves downward to each other. A box-shaped CFT column equipped with a material separation-reduced high-strength self-filled concrete pouring guide plate, characterized in that it is formed to pass inwardly of the upper end 34 of the facing guide plate 30.
The method of claim 5,
Material separation, characterized in that the size of the inclination angle (θ) of the guide plate 30 is set in association with the height (h) between the vertical inner diaphragm 10 and the vertical inner diaphragm 10 installed directly below A box-type CFT column equipped with a reduced-type, high-strength, self-filled concrete pour guide board.
in claim 1
In the mixing of the material separation-reducing type high-strength self-filling concrete with mixing water, binder including cement, fine aggregate, coarse aggregate and water reducing agent,
The binder is composed of 50 to 60% by weight of one type of ordinary Portland cement, 10 to 30% by weight of blast furnace slag fine powder, and 20 to 30% by weight of fly ash, and the total powder amount constituting the binder is 450 to 450 to the mass included in the unit volume A box-type CFT column equipped with a material separation-reduced high-strength self-filling concrete pour guide plate, characterized in that it is made of high-strength concrete with a compressive strength of 40 MPa or more at 28 days of age in the range of 580 kg / ㎥.
The method of manufacturing a box-type CFT column equipped with a material separation-reducing type high-strength self-filled concrete pouring guide plate,
a) positioning the lower plate 11 forming the box-shaped steel plate column 10 on a horizontal plane;
b) After positioning the corner of the vertical internal diaphragm 20 welded and fixed to the prefabricated guide plate 30 at the inner center of the lower plate 11 using the temporary support 40, perpendicular to the lower plate 11 fixing the corner of the inner diaphragm 20 by welding;
c) After placing both side plates 12 and 12' at both ends of the lower plate 11 in the width direction, the lower plate 11 and both side plates 12 and 12' are welded together, and both side plates 12 and 12 fixing by welding a corner of the vertical inner diaphragm 20 closely attached to the inner center of ');
d) After positioning the top plate 13 at the upper end of the both side plates 12 and 12', the both side plates 12 and 12' and the top plate 13 are welded together, and the top plate 13 and the vertical Welding and fixing the corner of the upper plate 13 and the vertical inner diaphragm 20 by groove welding in the welding groove 50 formed to weld the corner of the diaphragm 20;
e) After standing the box-shaped steel plate column 10 on which the vertical inner diaphragm 20 and the guide plate 30 are installed, and then pouring the material separation-reducing high-strength self-filling concrete through the guide plate 30, characterized in that A method for manufacturing a box-type CFT column equipped with a material separation-reducing type high-strength self-filled concrete pouring guide board.
The method of claim 8,
In the mixing of the material separation-reducing type high-strength self-filling concrete with mixing water, binder including cement, fine aggregate, coarse aggregate and water reducing agent,
The binder is composed of 50 to 60% by weight of one type of ordinary Portland cement, 10 to 30% by weight of blast furnace slag fine powder, and 20 to 30% by weight of fly ash, and the total powder amount constituting the binder is 450 to 450 to the mass included in the unit volume A method of manufacturing a box-type CFT column equipped with a material separation reducing type high-strength self-filling concrete pouring guide plate, characterized in that it is made of high-strength concrete with a compressive strength of 40 MPa or more at 28 days of age in the range of 580 kg / ㎥.

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