KR102777954B1 - Seismic Hollow PC column with double confinement of core concrete - Google Patents

Abstract

The present invention relates to an earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete, and more specifically, to an earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete, which is configured with a formwork steel plate having a formwork function between angles and a through hole for arranging a penetrating-type hoop reinforcing bar penetrating the inside of the hollow portion, so as to facilitate pouring of concrete for the outer perimeter and installation of hoop reinforcing bar, and in which the through hole formed in the formwork steel plate is burred to impart in-plane shear strength with the outer perimeter concrete when pouring concrete on site.
A preferred embodiment of the present invention comprises: a formwork steel plate having a plurality of through holes formed by burring and punching to form a shear key portion by connecting adjacent angles to form a square frame shape; a through-bar formed to penetrate the through holes of the formwork steel plate; and an outer perimeter concrete formed integrally by covering the outside of the angle, the formwork steel plate, and the through-bar with a predetermined thickness.

Description

Seismic Hollow PC Column with Double Confinement of Core Concrete

The present invention relates to an earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete, and more specifically, to an earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete, which is configured with a formwork steel plate having a formwork function and through-holes for arranging penetrating-type band reinforcement penetrating the interior of the hollow portion between angles, so as to enable pouring of outer perimeter concrete and free installation of horizontal, vertical, and inclined penetrating band reinforcement, and in which the through-holes formed in the formwork steel plate are burred to impart in-plane shear strength with the outer perimeter concrete when pouring on-site concrete.

In general, in the case of PC columns, since each floor's PC column weighs more than 25 tons, it must be segmented into 1 to 3 sections per floor during on-site construction, and this segmentation has led to the inevitable problem of on-site joints. In addition, most existing hollow PC columns have no internal penetrating sash reinforcement due to manufacturing difficulties, and the outer perimeter is wrapped with concrete. However, in this case, the sash reinforcement spacing criteria specified in the existing RC standards are not satisfied, and in this case, separate verification is unavoidable, which is a problem.

In addition, SRC columns are columns that are composites of steel and reinforced concrete structures and are mainly used in high-rise buildings. Reinforced concrete structures have good fire resistance but heavy self-weight, and as the height increases, the columns become thicker, so the effective area decreases, and on the other hand, steel structures have light self-weight but poor fire resistance, so they require expensive fire-resistant coating. Therefore, steel framed reinforced concrete construction (SRC) structures that complement these shortcomings and have good fire resistance, light self-weight, and are useful for high-rise buildings have been developed and used.

The construction is done by constructing a frame with steel members and surrounding the steel members with reinforced concrete. This requires a considerable construction period, and especially as the building gets taller, the air tends to increase exponentially. To improve this problem, precast concrete (PC) is being introduced, which can simplify on-site work.

The background technology of the present invention is Patent Registration No. 2480861, “Technology for manufacturing a precast concrete earthquake-resistant hollow column capable of preventing slipping occurring at the interface between cast-in-place concrete and precast concrete” (Patent Document 1).

The above background art proposes a 'precast concrete earthquake-resistant hollow column having a hollow portion formed inside, comprising: a stud unit including angles installed longitudinally at each inner corner and having an L-shaped horizontal cross-section; studs formed longitudinally at intervals on the inner and outer sides of the angle; and hoops transversely surrounding the outer side of the angle at the longitudinal intervals; a reinforcing bar unit including main reinforcing bars arranged longitudinally at intervals on the outer side; and precast concrete formed by pouring between the inner and outer sides after formwork is installed on the outer side; characterized in that at least one fixing member connecting the ends of the studs formed on the outer side of the angle and the main reinforcing bars is formed on the upper and lower sides of the angle, so that the hollow portion can be effectively formed even when the studs protrude from the hollow portion.

However, the above background technology had problems such as difficulty in penetrating the reinforcing bars into the hollow portion and difficulty in installing corner reinforcement braces to prevent deformation such as twisting. In order to maintain the square column shape made up of four corner angles before pouring concrete, the hoop reinforcing bars surrounding the angles transversely were either joined and fixed to the angles (or studs), or a separate additional joining method was required.

Patent Registration No. 2480861 "Technology for manufacturing precast concrete earthquake-resistant hollow columns capable of preventing slipping at the interface between cast-in-place concrete and precast concrete"

The present invention is to solve the above problems, and the purpose of the present invention is to provide a hollow PC column capable of freely installing horizontal, vertical, and inclined penetrating sash reinforcing bars penetrating the inside of a hollow portion, wherein the penetrating sash reinforcing bars in the form of corner braces prevent twisting and deformation during lifting, transportation, movement, assembly, and concrete pouring of the hollow column, and wherein the formwork steel plate is welded to an angle to provide a dual function of maintaining shape and horizontal confinement of concrete during concrete pouring of the outer perimeter, and at the same time, to provide in-plane shear strength with the outer perimeter concrete during on-site concrete pouring.

The present invention provides an earthquake-resistant hollow composite PC column with internal concrete doubled laterally confined, characterized by comprising: a formwork steel plate having a plurality of through holes formed by burring and punching to form a shear key portion by connecting adjacent angles to form a square frame shape; a through-bar formed to penetrate the through holes of the formwork steel plate; and an outer perimeter concrete formed integrally by covering the outside of the angle, the formwork steel plate, and the through-bar with a constant thickness.

In addition, the present invention aims to provide an earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete, characterized in that the penetrating saddle reinforcing bars are formed with hooks at each end and simultaneously penetrate the saddle reinforcing bars' penetration holes in opposing formwork plates, and the hooks are configured to protrude outward from each of the formwork plates.

In addition, the present invention aims to provide an earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete, characterized in that the penetrating sash reinforcing bar is configured to penetrate the sash reinforcing bar penetration hole of the formwork steel plate so that a hook is formed at one end and the hook is positioned on the outside.

In addition, the present invention aims to provide an earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete, characterized in that the penetrating reinforcing bar is formed in a U shape so that both ends simultaneously penetrate a pair of reinforcing bar penetration holes of a formwork steel plate.

In addition, the formwork steel plate is formed with penetration holes at regular intervals at regular heights, and the formwork steel plate is formed with a belt reinforcing bar installation part in which the penetration holes are formed, and a column belt reinforcing bar part between the belt reinforcing bar installation parts, and the column belt reinforcing bar part is welded and connected to an angle, thereby providing an earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete.

In addition, it is intended to provide an earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete, characterized in that corner reinforcement is formed in an inclined direction on the inner side of a cross-sectional corner by penetrating a belt reinforcing bar penetration hole of a formwork steel plate adjacent to each end.

In addition, the present invention aims to provide a seismic hollow composite PC column with double horizontal confinement of internal concrete, characterized by a penetration hole formed as a horizontally long hole.

In addition, the present invention provides an earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete, characterized in that a cement paste leakage prevention member having a size larger than the penetration hole is attached to the penetration hole and a penetrating belt reinforcing bar penetrates the cement paste leakage prevention member.

In addition, the present invention aims to provide a seismic hollow composite PC column with double horizontal confinement of internal concrete, characterized in that the cement paste leakage prevention member is composed of an elastic material including synthetic resin and natural resin.

In addition, the cement paste leakage prevention member is intended to provide an earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete, characterized by the formation of a horizontal cutting portion.

In addition, the present invention aims to provide an earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete, characterized in that the cement paste leakage prevention member is formed with a vertical linear cross-section or a circular penetration hole that penetrates the horizontal cut section in a circular manner so as to intersect the cut section at a specific location of the horizontal cut section.

In addition, the cement paste leakage prevention member is configured with a fixed installation part including an insertion part that protrudes horizontally from the upper and lower parts of the back surface of the cement paste leakage prevention member at positions corresponding to the upper and lower parts of the penetration hole, respectively, and a catch part that is formed by bending upward and downward at the outer ends of the insertion part, respectively, and the insertion part penetrates the penetration hole and the catch part is caught and fixed at the outer ends of the penetration hole that have been burred, thereby providing an earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete.

In addition, the present invention aims to provide an earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete, characterized in that the cement paste leakage prevention member is formed by a fixing part attached to the outside of a penetration hole and a penetration part formed by cutting or attaching a portion corresponding to the penetration hole into a plurality of rib shapes.

The earthquake-resistant hollow composite PC column with internal concrete double-cross-confined is configured with a formwork steel plate having through holes for the arrangement of penetrating-type hoop reinforcement penetrating the interior of the hollow portion and for the space between angles to function as a formwork, so as to facilitate pouring of concrete for the perimeter portion, and the through holes are installed at regular intervals so as to comply with the standards for arrangement of RC hoop reinforcement, so as to facilitate the installation of hoop reinforcement with standard hooks at both ends, and the through holes formed in the formwork steel plate are burred to implement a shear key portion protruding a certain height (4 mm) or more from the formwork steel plate in the direction of the hollow portion, so that in-plane shear strength can be imparted to the perimeter concrete when pouring concrete on-site, and the hollow portion can be used to reduce the weight of the column, thereby achieving the effect of implementing a column without segments.

In addition, by attaching a cement paste leak prevention member made of elastic material such as PVC or rubber to the through hole before pouring concrete on the outer perimeter, it is possible to prevent cement paste from leaking into the hollow interior through the through hole when pouring concrete on the outer perimeter.

The following drawings attached to this specification illustrate preferred embodiments of the present invention and, together with the detailed description of the invention, serve to further understand the technical idea of the present invention; therefore, the present invention should not be interpreted as being limited to the matters described in the attached drawings.
Figure 1 is a perspective view of a seismic hollow composite PC column with double horizontal confinement of internal concrete of the present invention.
Figure 2 is a cross-sectional view of a seismic hollow composite PC column with double horizontal confinement of internal concrete according to the present invention.
Figure 3 is a cross-sectional view along line AA of Figure 2.
Fig. 4 is a front view illustrating one embodiment of a cement paste leakage prevention member of the present invention.
Figure 5 is a cross-sectional view of Figure 4 above.
FIG. 6 is a front view and a side cross-sectional view along line BB of another embodiment of a cement paste leakage prevention member of the present invention.
FIG. 7 and FIG. 8 are diagrams illustrating another embodiment of the cement paste leakage prevention member of the present invention.

Below, the present invention is described in detail with reference to embodiments presented in the attached drawings, but the presented embodiments are exemplary for a clear understanding of the present invention and the present invention is not limited thereto.

The technical configuration of the present invention is described in detail according to the following preferred embodiments.

FIG. 1 is a perspective view of a double-layered earthquake-resistant hollow composite PC column with internal concrete laterally confined according to the present invention, FIG. 2 is a cross-sectional view of a double-layered earthquake-resistant hollow composite PC column with internal concrete laterally confined according to the present invention, and FIG. 3 is a cross-sectional view taken along line A-A of FIG. 2.

The earthquake-resistant hollow composite PC column (1) with double horizontal confinement of internal concrete of the present invention must be configured as a permanently embedded formwork because it is difficult to remove the formwork inside the hollow portion (150) for pouring the outer perimeter concrete (140) when arranging the penetrating belt reinforcing bars (130). Accordingly, angles (110) are installed at the four corners and used as structural materials for the main frame and main reinforcement of the formwork, and the space between the angles (110) and the angles (110) is formed of a formwork steel plate (120) having a through hole (121) for the role of the formwork and the placement of penetrating belt reinforcement (130) penetrating the inside of the hollow portion (150), and the formwork steel plate (120) and the penetrating belt reinforcement (130) are covered with a certain thickness on the outside to form an outer perimeter concrete (140) integrally.

Angles (110) are arranged to have an L-shaped cross section at each corner of a square, and adjacent angles (110) are connected to each other with a plate-shaped formwork steel plate (120) to create a square frame shape.

At this time, as shown in Fig. 2, the formwork steel plate (120) forms through holes (121) at regular intervals, and the through holes (121) are punched by burring processing so that they protrude outward (in the opposite direction of the hollow (150)) to form a shear key portion (122).

Burring is a process of making a hole in a flat plate and inserting a punch with a diameter larger than the hole to create a flange in the hole. As shown in the drawing, the flange portion becomes a shear key portion (122), so that in-plane shear strength can be imparted to the outer perimeter concrete when pouring concrete on site.

In general, it is realistically very difficult to dismantle or remove the formwork forming the boundary between the outer perimeter concrete and the hollow section, so it is desirable to use the formwork as a built-in permanent formwork. In addition, there is a concern that slipping at the boundary, etc. may occur because a cold joint is inevitably formed at the boundary between the outer perimeter concrete manufactured in a factory and the hollow section poured on site.

Accordingly, in the present invention, by using the formwork steel plate (120) as a permanent formwork and forming a through hole (121) by burring, it is possible to provide in-plane shear strength with the outer perimeter concrete when pouring concrete on site.

In particular, the through holes (121) of the formwork steel plate (120) are configured at a constant width-wise interval at a constant height, so that the formwork steel plate (120) can have a reinforcing bar installation part (120a) in which the through holes (121) are formed, and a column reinforcing bar part (120b) repeatedly formed between the reinforcing bar installation part (120a) and the reinforcing bar installation part (120a). The reinforcing bar installation part (120a) and the column reinforcing bar part (120b) can be formed integrally or manufactured separately and then joined for use.

At this time, the column sash reinforcing bar (120b) acts as a sash reinforcing bar that wraps around four angles (110), and has a structure similar to that of angles (110) installed vertically and sash reinforcing bars arranged at regular intervals in the height direction of the angles (110).

Such a column sash reinforcing bar part (120b) is welded to the angle (110) so that only the column sash reinforcing bar part (120b) can serve as a structural member. If welding is performed up to the sash reinforcing bar installation part (120a), deformation of the through hole (121) may occur, so that the sash reinforcing bar installation part (120a) cannot serve as a structural member. Therefore, it is preferable to only weld the column sash reinforcing bar part (120b) to the angle (110).

In addition, the through hole (121) may be formed in a circular shape as in FIG. 3b, but may be formed as a horizontally long hole as in FIG. 3a. This means that when a standard hook (131) is formed at both ends of the through-type reinforcing bar (130), the standard hook (131) is fixed to the reinforcing bar (141) that is arranged in the outer concrete (140). At this time, the through hole (121) is formed as a horizontal hole of a certain width (70 mm) or more so that the standard hook (131) can penetrate, and is formed at a certain interval so as to comply with the RC reinforcing bar arrangement standards.

As shown in Fig. 2a, the penetrating belt reinforcing bar (130) is configured such that hooks (131) are formed at each end and simultaneously penetrate the belt reinforcing bar penetration holes (121) of the facing formwork steel plate (120), and the hooks (131) protrude outwardly from the formwork steel plate (120), so that the hooks (131) can be fixed to the reinforcing bar (141) arranged in the outer perimeter concrete (140).

In addition, as in Fig. 2b, the penetrating belt (130) may be configured to have a hook (131) formed at one end and to penetrate the belt penetration hole (121) of the formwork steel plate (120) so that the hook (131) is positioned on the outside, or the penetrating belt (130) may be formed in a U shape so that both ends simultaneously penetrate a pair of belt penetration holes (121) of the formwork steel plate (120).

By configuring the penetrating belt reinforcing bar (130) in this way, reinforcement can be arranged while maintaining the horizontal height of the penetrating belt reinforcing bar (130) at a constant interval, and after the penetrating belt reinforcing bar (130) is installed in this way, the angle (110), the formwork steel plate (120), and the penetrating belt reinforcing bar (130) are covered with a constant thickness on the outside so that the outer perimeter concrete (140) is formed integrally.

Most existing hollow PC columns are wrapped with concrete around the outer periphery without internal penetrating sash reinforcement due to manufacturing difficulties. However, in this case, the sash reinforcement spacing criteria specified in the existing RC standards are not satisfied, and in this case, separate verification is inevitable. However, the present invention arranges penetrating sash reinforcement (130) through a penetration hole (121) in accordance with the current RC standards (RC sash reinforcement arrangement criteria: All corner axial reinforcements and axial reinforcements located one across must be laterally supported by the corners of sash reinforcement bent at an angle of 135° or less (additional sash reinforcement is arranged when the instantaneous spacing of axial reinforcements is 150 or more)), thereby enabling reinforcement to be arranged according to the principle while complying with the sash reinforcement arrangement spacing.

In particular, a corner reinforcement (190) can be formed in an inclined direction on the inner side of the cross-sectional corner by penetrating the belt reinforcing bar penetration hole (121) of the side of the formwork steel plate (120) where both ends are adjacent to each other.

In the present invention, to prevent cement paste from leaking into the hollow (150) through the through hole (121) when pouring the outer perimeter concrete (140), a cement paste leakage prevention member (20) made of an elastic material including a synthetic resin such as PVC or a natural resin such as rubber is attached to the outer end of the through hole (121), particularly the shear key portion (122) protruding from the through hole (121), and a penetrating belt reinforcing bar (130) may be configured to penetrate the cement paste leakage prevention member (20).

At this time, the cement paste leakage prevention member (20) may be made to have a size that is a certain size larger than the through hole (121) and may be attached to the periphery of the through hole (121) using various adhesive means such as double-sided tape or adhesive. The cement paste leakage prevention member (20) may be pressed into the through hole or the through hole may be formed in advance so that the belt reinforcing bar (130) penetrates the through hole before pouring concrete to form the outer perimeter concrete (140) but cement paste does not flow in.

FIG. 4 is a front view illustrating one embodiment of a cement paste leakage prevention member of the present invention, and FIG. 5 is a side cross-sectional view of FIG. 4.

As shown in Fig. 4, the cement paste leakage prevention member (20) is formed with a horizontal cut portion (221) so that the band reinforcing bar (130) can be easily penetrated, and the cement paste leakage prevention member (20) is made of an elastic member so that the space after penetration of the band reinforcing bar (130) can be restored and closed, thereby preventing the inflow of cement paste.

In particular, as shown in FIG. 4a, the cement paste leakage prevention member (20) can be formed with a vertical linear cross-cut (222) that intersects the cut (221) at a specific location of the horizontal cut (221) to facilitate penetration of the belt reinforcing bar (130), and as shown in FIG. 4b, a circular penetration portion (223) can be formed to penetrate in a circular manner on one side of the cut (221) to allow the standard hook (131) of the belt reinforcing bar (130) to penetrate through the cut (221) and the main body of the belt reinforcing bar (130) to penetrate and be positioned in the penetration portion (223).

In addition, as in Fig. 5, when installing a cement paste leakage prevention member (20) on the outer end of the shear key part (122), a groove (229) may be formed in the cement paste leakage prevention member (20) so that it can be stably installed on the end of the shear key part (122), and the outer end of the shear key part (122) may be fitted into this groove (229).

FIG. 6 is a front view and a side cross-sectional view along line B-B of another embodiment of the cement paste leakage prevention member of the present invention.

As shown in Fig. 6, a cement paste leakage prevention member (20) may have a fixed installation part (230) formed by injection molding or the like on a surface that comes into contact with the outer end of the shear key part (122) of the through hole (121) so that the cement paste leakage prevention member (20) can be easily fixed to the through hole (121).

To this end, the fixed installation part (230) of the cement paste leakage prevention member (20) is formed by an insertion part (231) that protrudes horizontally from the upper and lower parts of the back surface of the cement paste leakage prevention member (20) at positions corresponding to the upper and lower parts of the through hole (121) in correspondence with the through hole (121), and a catch part (232) that is formed in a hook shape by bending upward and downward at the outer end of the insertion part (231), so that the insertion part (231) penetrates the through hole (121) at the outer end of the shear key part (122) and the catch part (232) is caught and fixed at the outer end of the through hole (121).

FIGS. 7 and 8 are front views of another embodiment of the cement paste leakage prevention member of the present invention.

As shown in Fig. 7, the cement paste leakage prevention member (20) may be configured with a fixing member (241) attached to the outside of the through hole (121) and a penetration member (242) in which a portion through which the belt reinforcing bar (130) penetrates is cut or attached in a plurality of rib shapes corresponding to the through hole (121) and configured in a shape similar to a brush shape, thereby facilitating penetration of the belt reinforcing bar (130).

In addition, as in Fig. 8a, when installing a cement paste leakage prevention member (20) on the outer end of the shear key portion (122), as in Fig. 8b, a fixing member (241) attached to the outer side of the through hole (121) can be fixed by being adhered to the protruding outer surface of the shear key portion (122).

The earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete of the present invention as described above is composed of a formwork steel plate having through holes for the arrangement of penetrating belt reinforcement penetrating the interior of the hollow portion and the space between the angles acting as a formwork, so as to facilitate pouring of the outer perimeter concrete, and the through holes are installed at regular intervals so as to comply with the standards for arrangement of RC belt reinforcement, so as to facilitate the installation of belt reinforcement with standard hooks at both ends, and the through holes formed in the formwork steel plate are burred to implement a shear key portion protruding a certain height (3 mm) or more in the direction of the hollow portion from the formwork steel plate, so that it has the effect of imparting in-plane shear strength to the outer perimeter concrete when pouring concrete on site. In addition, by attaching a cement paste leak prevention member made of elastic material such as PVC or rubber to the through hole before pouring concrete on the outer perimeter, it is possible to prevent cement paste from leaking into the hollow interior through the through hole when pouring concrete on the outer perimeter.

Although the present invention has been described in detail with reference to the presented embodiments, those skilled in the art will be able to make various modifications and variations without departing from the technical spirit of the present invention by referring to the presented embodiments. The present invention is not limited by such modifications and variations, but is only limited by the claims attached below.

1: Hollow PC column
110 : Angle
120 : Steel sheet for formwork
121 : Penetration
122 : Shear key
130: Penetrating belt reinforcement
140 : Outer concrete

Claims (13)

Angles (110) of L-shaped cross-section placed at each corner of the square;
A formwork steel plate (120) configured with a plurality of through holes (121) formed by connecting adjacent angles (110) to form a square frame shape and protruding to one side by burring and forming a shear key portion (122);
A penetrating belt reinforcing bar (130) configured to penetrate a penetration hole (121) of a formwork plate (120);
An earthquake-resistant hollow composite PC column characterized by having an inner concrete double-cross-confined, characterized in that it is formed integrally by covering the outer side of an angle (110), a formwork plate (120), and a penetrating belt reinforcing bar (130) with a certain thickness; In claim 1,
A double-layered earthquake-resistant hollow composite PC column with internal concrete confined laterally, characterized in that the penetrating reinforcing bar (130) has hooks (131) formed at each end and simultaneously penetrates the reinforcing bar penetration holes (121) of the opposing formwork steel plate (120), and the hooks (131) are configured to protrude outward from each of the formwork steel plates (120). In claim 1,
A double-layered earthquake-resistant hollow composite PC column with internal concrete confined laterally, characterized in that a penetrating reinforcing bar (130) is formed with a hook (131) at one end and is formed by penetrating a reinforcing bar penetration hole (121) of a formwork steel plate (120) so that the hook (131) is positioned on the outside. In claim 1,
A seismic hollow composite PC column with double horizontal confinement of internal concrete, characterized in that the penetrating reinforcing bar (130) is formed in a U shape so that both ends simultaneously penetrate a pair of reinforcing bar penetration holes (121) of a formwork steel plate (120). In claim 1,
The penetration holes (121) of the formwork plate (120) are configured at regular intervals at regular heights.
The formwork steel plate (120) is composed of a belt reinforcement installation part (120a) in which a through hole (121) is formed, and a column belt reinforcement part (120b) between the belt reinforcement installation part (120a) and the belt reinforcement installation part (120a).
An earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete, characterized in that a column belt reinforcing bar (120b) is welded and joined to an angle (110). In claim 1,
An earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete, characterized in that corner reinforcement (190) is formed in an inclined direction on the inner side of a cross-sectional corner by penetrating a belt reinforcing bar penetration hole (121) of a side of a formwork plate (120) whose two ends are adjacent to each other. delete In claim 1,
An earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete, characterized in that a cement paste leakage prevention member (20) having a size larger than the penetration hole (121) is attached to the penetration hole (121) and a penetrating belt reinforcing bar (130) penetrates the cement paste leakage prevention member (20). In claim 8,
A double-layered, earthquake-resistant hollow composite PC column characterized in that the cement paste leakage prevention member (20) is composed of an elastic material including synthetic resin and natural resin. In claim 8,
A double-layered earthquake-resistant hollow composite PC column characterized by a cement paste leakage prevention member (20) having a horizontal cutting portion (221) formed therein. In claim 8,
A double-layered earthquake-resistant hollow composite PC column with internal concrete, characterized in that a cement paste leakage prevention member (20) is formed with a vertical linear cross-section (222) that intersects the horizontal cut portion (221) at a specific location of the horizontal cut portion (221) or a circular penetration portion (223) that penetrates the cut portion (221) in a circular shape. In claim 8,
The cement paste leak prevention member (20) is configured with a fixed installation member (230) including an insertion part (231) that is formed by protruding horizontally on the upper and lower sides of the back surface of the cement paste leak prevention member (20) at positions corresponding to the upper and lower sides of the through hole (121) in correspondence with the through hole (121), and a catch part (232) that is formed by bending upward and downward at the outer end of the insertion part (231), respectively.
An earthquake-resistant hollow composite PC column with double horizontal confinement of internal concrete, characterized in that an insertion portion (231) penetrates a through hole (121) and a catch portion (232) is caught and fixed on the outer end of the through hole (121) that has been burred. In claim 8,
A double-layered earthquake-resistant hollow composite PC column with internal concrete, characterized in that the cement paste leakage prevention member (20) is composed of a fixing member (241) attached to the outside of a through hole (121) and a through hole (242) formed by cutting or attaching a portion corresponding to the through hole (121) in a plurality of rib shapes.

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