KR101223265B1 - Precast high-strength concrete columns and constructing method thereof - Google Patents

Abstract

PURPOSE: A precast high-strength concrete column and a construction method thereof are provided to prevent the horizontal displacement of a high-strength concrete column and to reduce construction time. CONSTITUTION: A precast high-strength concrete column(100) comprises an upper column(110), a lower column(120), a connection member(130), a filling member, and a finishing member(150). The upper and lower columns comprise upper and lower circular rings(111,111a,121,121a), axial reinforcing bars(112,122), and concrete layers(113,123). Reinforcing bar coupling holes are formed in the upper and lower circular rings in a radial direction. The axial reinforcing bars are coupled to the reinforcing bar coupling holes. The concrete layers are formed by placing high-strength concrete in the gaps between the upper and lower circular rings. The connection members connect the axial reinforcing bars protruded to the lower circular ring of the upper column and the axial reinforcing bars protruded to the upper circular ring of the lower column to each other. The space between the lower circular ring of the upper column and the upper circular ring of the lower column is filled with the filling member. The finishing member surrounds the bottom end of the upper column and the top end of the lower column to finish the filling member.

Description

Precast high-strength concrete columns and constructing method

The present invention relates to a precast high-strength concrete column, and more specifically, a high-strength concrete column made of a certain length factory made of high-strength concrete with a compressive strength of 100 MPa or more, easy to move as well as pre-boring by connecting with a coupling (Pre- The present invention relates to a precast high-strength concrete column and its construction method that prevents the transverse displacement of the high-strength concrete column by forming an expanded foundation while easily installing the soft rock by the boring method.

In general, the bridge piers constructed in the bridge construction is a site-cast concrete structure, after foundation work in the field, after the concrete is laid in the state in which the reinforcing bar and formwork is laid and cured for a period of time to form a foundation, the foundation portion After installing the reinforcing bars and formwork, concrete is formed by placing and curing, which takes a lot of time to install and dismantle the formwork, there was a problem that the air and construction costs increase.

In order to solve the above problems, the prefabricated piers and column structures and construction methods thereof have been registered as Korean Patent No. 10-099113.

The pre-registered patent has a cross-sectional area of spherical, circular and elliptical shape, and the pillars are made of a plurality of precast units according to the height, and are configured in a convex shape at the lower end of the upper unit, and concave at the upper end of the corresponding lower unit. It is configured to assemble, and the shear key for shearing the compression or tensile force, the axial force, the shear force from the bending moment acting on the upper unit at different positions is formed in the block portion and the concave portion.

However, the pre-registered patent, there is an advantage to solve the conventional problems because it is manufactured and moved to a plurality of precast units, but the manufacturing process of each unit through the formwork, as well as lifting the precast unit of concrete material Since more units have to be manufactured in weight, there is a problem in that productivity and economy are inferior.

This is made in view of the conventional problems as described above, the object of the present invention, the high-strength concrete column made of a certain length factory made of high-strength concrete with a compressive strength of 100MPa class or more, so easy to move as well as coupling by pre-boring Precast high strength concrete pillars can be easily installed to soft rock by forming pre-boring method to form translating foundations in the middle of columns to prevent lateral displacement of high strength concrete columns and shorten construction period. To provide a construction method thereof.

In addition, another object of the present invention is to produce a high-strength concrete column made of high-strength concrete, so less porosity, less dense and uniform structure, more durable than pier or prefabricated piers formed of cast-in-place concrete, axial and transverse The present invention provides a precast high-strength concrete column and its construction method that can prolong the life of a product by resisting directional force.

Precast high strength concrete column of the present invention,

The upper and lower circular rings are spaced apart by a predetermined interval while the reinforcing holes are radially penetrated, and are provided with axial reinforcing bars protruding into the lower circular rings while being coupled to the reinforcing bars of the upper and lower circular rings. An upper column having a concrete layer formed by pouring high-strength concrete between the circular rings;

The upper and lower circular rings are spaced apart at regular intervals while the reinforcing bars are radially penetrated, and are provided with axial reinforcing bars protruding into the upper circular rings while being coupled to the reinforcing bars of the upper and lower circular rings. A lower column having a concrete layer formed by pouring high-strength concrete between the circular rings;

It characterized in that it comprises a connecting member for connecting the axial reinforcement protruding into the lower circular ring of the upper column and the axial reinforcement protruding into the upper circular ring of the lower column.

In addition, the construction method of the precast high-strength concrete pillar of the present invention,

The upper and lower circular rings are spaced apart by a predetermined interval while the reinforcing holes are radially penetrated, and are provided with axial reinforcing bars protruding into the lower circular rings while being coupled to the reinforcing bars of the upper and lower circular rings. An upper column having a concrete layer formed by pouring high-strength concrete between the circular rings; The upper and lower circular rings are spaced apart at regular intervals while the reinforcing bars are radially penetrated, and are provided with axial reinforcing bars protruding into the upper circular rings while being coupled to the reinforcing bars of the upper and lower circular rings. A connecting member connects the lower pillar with a concrete layer formed by pouring high-strength concrete between the circular rings, and the axial reinforcement protruding by the lower circular ring of the upper pillar and the axial reinforcement protruding by the upper circular ring of the lower pillar. Forming a high strength concrete column;

Forming a hole in the ground to insert the high-strength concrete column;

Injecting cement milk into the drilling hole;

Inserting a high-strength concrete column into the drilled hole into which the cement milk is injected, and pressing and striking it to install on the soft rock;

It is characterized in that it comprises a step of curing so as to harden the shimen milk.

According to the present invention, a high-strength concrete column made of high strength concrete with a compressive strength of 100MPa or more is produced at a certain length of the factory, so it is easy to move, and is connected to the coupling, and easily installed to soft rock by a pre-boring method. By forming an expansion base in the middle of the column to prevent lateral displacement of the high-strength concrete column, it can have the advantage of improving the economics by shortening the construction period and reducing the construction cost than the pillar formed by placing concrete in the field. It is.

In addition, according to the present invention, since the high-strength concrete pillars are made of high-strength concrete, the voids are small and the structure is dense and uniform. It can resist the resistance to extend the life of the product can have the advantage that the user can improve the reliability of the product.

1 is an exploded perspective view
2 is a cross-sectional view of FIG.
3 is a perspective view of another embodiment of the present invention
Figure 4 is a cross-
5 to 6 is a perspective view of another embodiment of the present invention
Figure 7 is a cross-sectional view of another embodiment of the present invention

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. 1 is an exploded perspective view of the present invention, Figure 2 is a cross-sectional view of FIG.

Precast high-strength concrete pillars 100 of the present invention, the upper and lower circular ring 111 (111a) is spaced apart by a predetermined interval while the reinforcing bar (111 ') (111a') is radially penetrated, the upper, While being coupled to the reinforcing bar (111 ') (111a') of the lower circular ring (111) (111a) is provided with an axial reinforcement (112) protruding into the lower circular ring (111a), the upper and lower circular ring ( The upper pillar 110 is provided with a concrete layer 113 formed by pouring high-strength concrete between the 111 and 111a, and the reinforcing bars 121 'and 121a' are radially penetrated and spaced apart from each other. The upper and lower circular rings 121 and 121a are provided, and the upper and lower circular rings 121 and 121a are coupled to the reinforcing coupling holes 121 'and 121a' of the upper and lower circular rings 121 and 121a. A protruding axial reinforcement 122 is provided, the lower column 120 is provided with a concrete layer 123 is formed by pouring high-strength concrete between the upper, lower circular ring 121, 121a It is configured to connect the axial reinforcement 112 protruding to the lower circular ring 111a of the upper column 110 and the axial reinforcement 122 protruding into the upper circular ring 121 of the lower column 120 It is configured to include a connecting member 130, which will be described in more detail as follows.

The connection member 130 is preferably any one of coupling or welding.

Charging to fill between the lower circular ring 111 'of the upper column 110 and the upper circular ring 121 of the lower column 120 connecting the axial reinforcement 112, 122 with the connecting member 130 It is further configured to include a member 140, it is preferable that the filling member 140 is made of super hard concrete.

It further comprises a closing member 150 surrounding the lower end of the upper pillar 110 and the upper end of the lower pillar 120 to close the filling member 140, the closing member 150 is a carbon sheet desirable.

The high-strength concrete is cement, general sand, fine yarn, filler, silica fume, blast furnace slag, water reducing agent, blended water, steel fiber or plastic fiber, the blending weight ratio thereof is 1: 0.5 to 1.1: 0.3 to 1.1: 0.3 to 0.8 : 0.1 ~ 0.3: 0.1 ~ 0.3 : 0.2 ~ 0.4: 0.02 ~ 0.1: 0.05 ~ 0.2

In addition, as shown in Figures 3 to 4, the high-strength concrete pillar 100 is configured to further include an expansion base 160 formed on the high-strength concrete pillar 100 to prevent lateral displacement.

In addition, as shown in Figures 5 to 7, further comprising a reinforcement pile 170 embedded in the ground to reinforce the enlarged foundation 160, the reinforcement pile 170, PHC pile, steel pipe It is preferable that it is either a file or a microfile.

The following describes the manufacturing and construction process of the present invention configured as described above.

First, to form a form forming the upper pillar 110 and the lower pillar 120 of the high-strength concrete column 100, the formwork should be formed in the upper, lower formwork, the upper, lower inside both ends of the lower formwork After the upper and lower circular rings 111, 111a, 121, 121a of the pillars 110, 120 are seated, respectively, the upper, lower circular rings 111, 111a, 121, 121a The axial reinforcing bars 112 and 122 are respectively coupled to the reinforcing bars 111 ', 111a', 121 ', and 121a'.

Here, of course, the axial reinforcing bars 112 and 122 protrude into the lower circular ring 111a of the upper column 110 and the upper circular ring 121 of the lower column 120, the upper column 110 of course. Although the upper circular ring 111 and the lower circular ring 121a of the lower column 120 of the axial reinforcement 112, 122 can be combined to protrude, but axial reinforcement 112 (122) than the circular ring It is preferable that) does not protrude.

When the axial reinforcement 112, 122 is reinforced to the upper, lower circular ring 111 (111a) of the upper column 110 and the upper, lower circular ring 121 (121a) of the lower column 120, respectively Cement, general sand, fine thread, filler, silica fume, blast furnace slag, water reducing agent, blended water, steel fiber or plastic fiber in the form of seating the upper formwork in the lower formwork and fixed with a separate fixing member. 1.1: 0.3 ~ 1.1: 0.3 ~ 0.8: 0.1 ~ 0.3: 0.1 ~ 0.3: 0.2 ~ 0.4: 0.02 ~ 0.1: 0.05 ~ 0.2 The high-strength concrete mixed with the mixing ratio is poured and the hot steam cured concrete layer 113 (123) After forming a), the upper and lower dies are dismantled to complete the manufacture of the upper and lower pillars 110 and 120.

A space 110 ′ may be further formed at the upper end of the upper pillar 110 to connect with the coping.

The upper and lower columns 110 and 120 respectively manufactured by the above process are lower circular rings 111a of the upper column 110 according to the depth of the drilling hole 10 in the state of moving to the installation site using the vehicle. Connecting the axial reinforcing bar 112 and the axial reinforcing bar 122 protruding into the upper circular ring 121 of the lower column 120 to the connecting member 130, the connecting member 130 is the upper The pillars 110 and the lower pillars 120 may be fixed by welding or coupled by coupling with the axial reinforcing bars 112 and 122.

The coupling is composed of any one of the configuration surrounding the axial reinforcement 112, 122 and the configuration for fastening the axial reinforcement 112, 122.

When the axial reinforcing bars 112 and 122 are connected and fixed by the connecting member 130, a space is formed between the upper pillar 110 and the lower pillar 120 by the length of the minimum connecting member 130. Filling the filling member 140 is made of superhard concrete in the space and the carbon member finishing member 150 at the lower end of the upper pillar 110 and the upper end of the lower pillar 120 to prevent the filling member 140 from being separated. After finishing with a separate fixing member (not shown), while the filling member 140 is cured is to form a high-strength concrete pillar 100.

When the high-strength concrete pillar 100 is formed by the above process, the drilling hole 10 is formed on the ground into which the high-strength concrete pillar 100 is to be inserted into the drilling equipment (not shown), and the cement is formed in the drilling hole 10. After inserting the high-strength concrete pillar 100 in a state in which milk (not shown) is inserted, the lower pillar 120 of the high-strength concrete pillar 100 is installed in the soft rock by pressing and striking the upper pillar 110 on the ground. Make it protrude more.

When the high-strength concrete pillars 100 are installed in soft rock, the cement milk is cured so as to cure, and the reinforcing bars are accommodated to accommodate the high-strength concrete pillars 100 at a position lower than the ground to prevent lateral displacement of the high-strength concrete pillars 100. And spreading and curing concrete to form an enlarged foundation 160, before forming the enlarged foundation 160, any one of the PHC file, steel pipe pile, micro-pile supporting the enlarged foundation 160 After the phosphorus reinforcement pile 170 is buried in the ground facing each other, the reinforcement pile 170 may be installed so as to be connected to the expansion foundation 160.

Coping is formed in the high-strength concrete column 100 reinforced with the reinforcement pile 170 and the expansion foundation 160 by the above process, so that the reinforcing bar of the coping is embedded in the space 110 ′ of the upper column 110. After that, by pouring and curing concrete will be able to form a high-strength concrete pillar 100 and coping integrally.

As described above, the present invention, although described by the limited embodiments and drawings, terms or words used in the present specification and claims are not limited to the ordinary or dictionary meanings and should not be interpreted, the technical spirit of the present invention It must be interpreted to mean meanings and concepts. Therefore, the configuration shown in the embodiments and drawings described herein are only one embodiment of the present invention, and do not represent all of the technical spirit of the present invention, various changes within the scope of the claims of the present invention It should be understood that there may be equivalents and variations.

100: high strength concrete pillar 110: upper pillar
120: lower column 111,121: upper circular ring
111a, 121a: Lower circular ring 111 ', 111a', 121 ', 121a': Reinforcing bar
112,122: axial rebar 113,123: concrete layer
130: connecting member 140: filling member
150: finish member 160: enlarged base
170: reinforcement pile

Claims (16)

The upper and lower circular rings are spaced apart by a predetermined interval while the reinforcing holes are radially penetrated, and are provided with axial reinforcing bars protruding into the lower circular rings while being coupled to the reinforcing bars of the upper and lower circular rings. An upper column having a concrete layer formed by pouring high-strength concrete between the circular rings;
The upper and lower circular rings are spaced apart at regular intervals while the reinforcing bars are radially penetrated, and are provided with axial reinforcing bars protruding into the upper circular rings while being coupled to the reinforcing bars of the upper and lower circular rings. A lower column having a concrete layer formed by pouring high-strength concrete between the circular rings;
A connecting member connecting the axial reinforcement protruding from the lower circular ring of the upper column and the axial reinforcing bar protruding from the upper circular ring of the lower column;
A filling member for filling between the lower circular ring of the upper column and the upper circular ring of the lower column connecting the axial reinforcement to the connecting member;
Precast high-strength concrete column characterized in that it comprises a closing member surrounding the lower end of the upper column and the upper end of the lower pillar to close the filling member.
The method according to claim 1,
The connection member is a precast high strength concrete pillar, characterized in that any one of coupling or welding.
delete The method according to claim 1,
The filling member is precast high-strength concrete pillars, characterized in that the super hard concrete.
delete The method according to claim 1,
The finishing member is a precast high strength concrete pillar, characterized in that the carbon sheet.
The method according to claim 1,
The high-strength concrete is cement, general sand, fine yarn, filler, silica fume, blast furnace slag, water reducing agent, blended water, steel fiber or plastic fiber, the blending weight ratio thereof is 1: 0.5 to 1.1: 0.3 to 1.1: 0.3 to 0.8 : 0.1 ~ 0.3: 0.1 ~ 0.3: 0.2 ~ 0.4: 0.02 ~ 0.1: 0.05 ~ 0.2 The precast high strength concrete column which is composed of.
The method according to claim 1,
Precast high-strength concrete pillars, characterized in that it further comprises an enlarged foundation formed on the high-strength concrete pillars to prevent lateral displacement of the high-strength concrete pillars.
The method according to claim 8,
Precast high-strength concrete pillars, characterized in that it further comprises a reinforcement pile embedded in the ground to reinforce the expanded base.
The method according to claim 9,
The reinforcement pile is a precast high-strength concrete pillar, characterized in that any one of the PHC file, steel pipe pile, micro pile.
The method according to claim 1,
Precast high-strength concrete pillars characterized in that it further comprises a space for connecting with the coping in the upper column.
The upper and lower circular rings are spaced apart by a predetermined interval while the reinforcing holes are radially penetrated, and are provided with axial reinforcing bars protruding into the lower circular rings while being coupled to the reinforcing bars of the upper and lower circular rings. An upper column having a concrete layer formed by pouring high-strength concrete between the circular rings; The upper and lower circular rings are spaced apart by a predetermined interval while radially penetrating into the reinforcing bar, and are provided with axial reinforcing bars protruding into the upper circular ring while being coupled to the reinforcing bar of the upper and lower circular rings. A connecting member connects the lower pillar with a concrete layer formed by pouring high-strength concrete between the circular rings, and the axial reinforcement protruding by the lower circular ring of the upper pillar and the axial reinforcement protruding by the upper circular ring of the lower pillar. And filling between the lower circular ring of the upper pillar connected with the connecting member and the upper circular ring of the lower pillar with a filling member, and wrapping the lower end of the upper pillar and the upper end of the lower pillar with a finishing member to close the filling member. Forming a high strength concrete column;
Forming a hole in the ground to insert the high-strength concrete column;
Injecting cement milk into the drilling hole;
Inserting a high-strength concrete column into the drilled hole into which the cement milk is injected, and pressing and striking it to install on the soft rock;
Construction method of the precast high-strength concrete pillars, characterized in that it comprises the step of curing so as to harden the seam milk.
delete delete The method of claim 12,
A method of constructing a precast high-strength concrete pillar, characterized in that it further comprises the step of forming an expansion foundation on the high-strength concrete pillar to prevent the transverse displacement of the high-strength concrete pillar fixed to the drilling hole by the curing of the cement milk.
The method according to claim 15,
Method for constructing a precast high-strength concrete pillar, characterized in that further comprising the step of embedding a reinforcement pile on the ground to reinforce the expanded base.

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