KR20130134558A - Structure using pre-cast panel - Google Patents

Abstract

The present invention relates to construction, civil engineering fields, more specifically, to a structure using a precast panel which is assembled in a construction site after manufactured in a factory. The present invention can suggest a structure using a precast panel that includes: a plurality of external wall members (10) that are abutted and installed so as to form an external wall, have a girder supporting part (14) formed on the inner side surface of the entire or one part, and that have a girder seating groove (14a) which is opened from an upper side to a lower side in the girder supporting part (14) and is penetrated along the inner and outer directions of the external wall; a plurality of column members (20) that are installed to be spaced apart each other in a room space (R) formed by the external wall and in which a girder seating groove (14a) which corresponds to the girder seating groove (14a) of the external wall member (10) is formed; a plurality of girder members (30) that include a girder main body part (32) which is installed on the upper side of the girder supporting part (14) of the external wall member (10) or the column member (20) so as to be hanged between the column members (20) or between the column member (20) and the girder supporting part (14) of the external wall member (10), and that include a girder protrusion part (34) which protrudes on the lower side surface of the girder main body part (32) downward and is inserted into the girder seating groove (14a) of the external wall member (10) or the girder seating groove (24a) of the column member (20); and a plurality of slab members (40) which are hanged between the girder members (30) so as to form a surface with the girder member (30).

Description

{Structure using pre-cast panel}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a construction and civil engineering field, and more particularly, to a structure using a precast panel that is manufactured at a factory and assembled at a construction site.

Construction and civil engineering structures can be constructed by placing concrete on site, or by assembling them in the form of panels in advance in the factory and assembling them in the field. The panel of the latter construction method is called precast panel.

The structure using the latter precast panel is manufactured in advance at the factory so that the quality can be controlled uniformly and the frequency of defects and maintenance is remarkably lowered. In addition, the construction can be carried out in winter and at night, The curing period is not necessary and the construction period is short. Therefore, it has a very good advantage compared with the electronic installation method.

However, when constructing a structure using such a precast panel, the following points should be considered.

First, since precast panels are manufactured at the factory and transported to the site, they must be easily manufacturable at factories, can be transported from the factory to the site, and must be able to be installed by a crane in the field.

Second, although precast panels are divided, they can be constructed by a crane because of its size and weight, and it takes considerable time, so precision work is required to prevent rework.

Third, the precast panels must be tightly bonded so that they are assembled at precise locations and not vulnerable to form an integral structure as a whole.

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a precast panel which can be easily manufactured, transported, and constructed, can secure sufficient structural stability, The purpose is to provide a structure.

In order to solve the above problems, the present invention is installed spaced apart from each other, a plurality of pillar members 20 formed with a beam fixing groove (24a); Protruding downward from the lower surface of the beam main body portion 32 and the beam main body portion 32 installed above the pillar member 20 so as to span between the pillar member 20 and the pillar member 20. A plurality of beam members 30 including beam protrusions 34 fitted into the beam fixing grooves 24a of the pillar member 20; A plurality of slab members (40) spanning between the beam member (30) and the beam member (30) to form a surface with the beam member (30); It can present a structure using a precast panel characterized in that it comprises a.

The beam fixing groove 14a and the beam protrusion 34 may be formed in a shape that gradually narrows from the upper side to the lower side.

The beam main body portion 32 of the beam member 30 includes a first beam main body portion 32a provided on the column member 20 or the beam receiving portion 14, And a second beam main body 32b protruding upward from the first beam main body 32a so as to be sandwiched between the slab members 40 provided on the upper side of both edges of the first beam main body 32a.

Slab member fitting protrusions 32c which can be fitted into the upper and lower through holes 40a formed in the slab member 40 so as to pass through the upper and lower through holes 40a may be respectively provided at both edges of the first beam main body portion 32a.

The beam protrusion 34 may be formed over the entire length of the beam member 30.

The beam member 30 protrudes downward from the lower surface of the beam main body portion 32 and extends along the longitudinal direction (arrow A) of the beam member 30 to the column fixing portion 24 of the column member 20 And may further include a latching jaw 36 for latching.

The beam protrusion 34 is formed at the center along the width direction (arrow B) of the beam member 30, and the locking jaw 36 may be formed at both sides of the beam protrusion 34.

The locking jaw 36 may be connected to the beam protrusion 34 along the width direction (arrow B) of the beam member 30.

The fixing surface 36a of the latching jaw 36 which contacts the column member 20 is inclined along the longitudinal direction (arrow A) of the beam member 30 with respect to the vertical direction, May be formed so as to be in surface contact with the fixing surface (36a) of the latching jaw (36).

The fixing surface 36a of the latching jaw 36 can be inclined toward the column member 20 in which the latching jaw 36 is hooked from the lower side to the upper side.

All or a part of the latching jaw 36 along the longitudinal direction (arrow A) of the beam member 30 may be formed thicker toward the pillar member 20 in which the latching jaw 36 is hooked.

The lower side 36b of the locking jaw 36 may be formed in an arc shape symmetrically in the longitudinal direction (arrow A) of the beam member 30.

A plurality of joints are installed so as to form an outer wall, and the beam support part 14 protrudes from the inner side of all or a part of the beam member 30 together with the pillar member 20 so as to support the beam support part 14. The outer wall member 10 may further include a plurality of outer wall members 10 formed at an upper side and a lower side thereof and having a beam fixing groove 14a penetrating along the inner and outer directions of the outer wall body.

The outer wall member 10 may have a slab support portion 16 protruding from the inner wall of the outer wall member 10 to support the slab member 40.

According to the present invention, it is possible to quickly and easily construct the structure in a precast-casting manner by the outer wall member as a precast panel, the column member, the beam member, and the slab member. It can be organically bound.

The present invention relates to a structure using a precast panel,
1 to 3 are plan views showing a state in which an outer wall member, a column member, a beam member, and a slab member are sequentially installed as a construction example.
4 is a perspective view illustrating a state in which an outer wall member, a column member, and a beam member are separated from each other.
FIG. 5 is a perspective view of the combined state of FIG. 4; FIG.
6 is a front view of the mating state of the column member and the beam member.
Fig. 7 is a side view of the mating state of the column member and the beam member. Fig.
Fig. 8 is a side view of a combined state of the column member and the beam member of another embodiment; Fig.
FIG. 9 is a bottom perspective view of the beam member of FIG. 8;
10 is a perspective view showing a state in which the outer wall member, the beam member, and the slab member are separated.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In the following description of the present invention, a detailed description of known functions and configurations will be omitted so as not to obscure the gist of the present invention.

1 to 10, the structure using the precast panel according to the present invention is constructed in a plurality of outer wall member 10 to form an outer wall and the interior space (R) formed by the outer wall to form a column A plurality of pillar members 20 to be formed, a plurality of beam members 30 installed on the pillar member 20 and the outer wall member 10 so as to be supported by the pillar member 20 and the outer wall member 10, Along with the beam member 30 may include a plurality of slab members 40 and the like to form a surface (that is, the bottom surface, the ceiling surface).

The outer wall member 10 basically includes a wall body portion 12 as a divided portion when a plurality of outer wall bodies are divided (preferably equally divided) along the circumferential direction of the outer wall body, So that the outer wall body can be formed to form the indoor space. Each of the outer-wall member 10 may be manufactured in a single structure as shown in FIG. 1, and may be further subdivided into a plurality of outer-wall members 10 in a vertical direction as necessary.

All or a part of the plurality of outer wall member 10 is supported on the inner side surface of the wall body portion 12 so that the bolt member 14 can be supported with the pillar member 20 And may be formed to protrude toward the inside. In this case, not only the beam member 30 is firmly supported by the beam receiving portion 14, but also the outer-wall member 10 and the beam member 30 can be tightly adhered to each other.

The support member 14 may protrude from only the upper side of the outer wall member 10 or may protrude from the inner side surface of the outer wall member 10 in the vertical direction like a column.

The support member 14 may have any structure as long as it can support the beam member 30 and preferably has the same or similar shape as the support member 30 so as to support the beam member 30 To the column fixing portion 24 that supports the beam member 30 of the first embodiment. Unlike the pillar member 20, the pillar member 20 does not support the two pillar members 30 connected thereto but only one pillar member 30 to be installed at the end is supported. Therefore, the pillar member 30 Of the column fixing portion 24 of the column member 20 along the longitudinal direction (arrow A) That is, the beam support portion 14 basically opens a predetermined depth from the upper side to the lower side so that the fitting can be made while supporting the beam member 30, and the beam fixing groove 14a penetrated along the inner and outer directions of the outer wall is formed. Can be. A more specific feature of the resilient supporting portion 14 can be referred to the column fixing portion 24 of the column member 20 to be described later, and a description overlapping with the column member 20 is omitted.

All or a part of the plurality of outer wall member 10 is attached to the outer wall member 10 so that the last slab member 40 can be closely attached to the slab member 40, The slab support portion 16 may be formed to protrude from the side surface of the wall body portion 12. The slab support portion 16 may be formed only on the upper side of the outer wall member 10 or on the outer wall member 10 in the vertical direction. The slab support portion 16 may be any structure as long as it can support the slab member 40. The slab support portion 16 may be formed as a concavo-convex structure with the slab member 40 in accordance with the structural feature of the slab member 40 For example, the upper surface may be formed as a horizontal step.

The outer wall member 10 further includes a wall base portion 18 protruding toward the interior space R from the lower end of the wall body portion 12 so as to form a bottom surface when the floor surface is formed by site casting can do. The wall foundation 18 may be manufactured with reinforcing bars 18a protruding outwardly for placement in the field.

The plurality of column members 20 are mutually dispersedly installed in the indoor space R formed by the outer wall body along the length of each of the beam members 30 and the like. Particularly, the plurality of pillar members 20 together with the pawl receiving portion 14 of the outer wall member 10 can support one beam member 30 at both ends along the longitudinal direction (arrow A) And one column member 20 can be manufactured and installed so as to simultaneously support two beam members 30 connected to each other along the longitudinal direction (arrow A) of the beam member 30. [

The column member 20 includes a vertically long column main body 22 which is basically a skeleton of the column member 20. The column main body 22 has a column fixing portion 22 for supporting the beam member 30 above the column main body portion 22, (24) may be formed. The column member 20 has a column base portion 26 in which a reinforcing bar is buried under the column main body portion 22 for the bottom surface construction by field installation such as the wall base portion 18 of the outer wall member 10 . The column main body 22 and the column fixing part 24 can be directly connected to each other so that the column main body 22 and the column fixing part 24 can be structurally and stably connected. A column connecting portion 28 may be further formed between the body portion 22 and the column fixing portion 24. [

The column main body portion 22 of the column member 20 can be formed relatively thin like a bottleneck structure between the column fixing portion 24 and the column base portion 26. [

The pillar fixing part 24 of the pillar member 20 corresponds to the beam fixing groove 14a of the beam supporting part 14 so that the fitting may be made while supporting the beam member 30 like the beam supporting part 14. The beam fixing groove 24a may be formed. The column fixing portion 24 of the column member 20 must support the two beam members 30 so that the two bolster members 14 along the longitudinal direction (arrow A) of the beam member 30 ) Are sequentially formed.

The column fixing portion 24 of the column member 20 will be described in more detail as follows.

The beam fixing groove 24a of the pillar member 20 is formed so that the beam protrusion 34 of the beam member 30 can be shaped like a concave-convex structure that is paired with the beam protrusion 34 of the beam member 30 fitted thereto. Of course, it takes a shape corresponding to. However, the beam fixing groove 24a of the pillar member 20 is formed to a predetermined depth, and gradually increases from the upper side to the lower side so that the beam member 30 can be easily inserted from the upper side to the lower side of the pillar member 20. It may be formed into a narrowing structure. That is, the beam fixing groove 24a of the pillar member 20 may have a parallelogram in cross section along the longitudinal direction (arrow A) of the beam member 30.

The pillar fixing unit 24 may have a square or rectangular cross section along the longitudinal direction (arrow A) of the beam member 30, or may have a parallelogram shape corresponding to the beam fixing groove 24a of the pillar member 20.

In addition, the column fixing unit 24 has a longitudinal section along the longitudinal direction (arrow A) of the beam member 30 from the lower side to the upper side according to the organic coupling relationship with the locking projection 36 of the beam member 30 to be described later. Increasingly, the width along the longitudinal direction (arrow A) of the beam member 30 may be a balanced quadrangle. (See FIGS. 7 and 8)

The column connecting portion 28 can take a shape that the width gradually decreases from the upper side to the lower side so as to stably connect the column fixing portion 24 and the column body portion 22 having a different size.

The beam member 30 extends between the pillar member 20 and the pillar member 20 or between the pillar member 20 and the pillar receiving member 14 of the outer wall member 10 and basically extends along the direction between them And may be formed into a long and relatively narrow straight shape.

More specifically, the beam member 30 includes a beam main body portion 32 which is provided on the pillar member 20 or the upper side of the beam receiving portion 14 of the outer wall member 10 and supports the slab member 40 can do.

The beam main body 32 is supported by the column member 20 or the beam receiving portion 30 so as to support the slab member 40 on both sides of the beam member 30 along the width direction (arrow B) The first beam main body 32a and the first beam main body 32a are sandwiched between the first beam main body 32a and the slab member 40 provided on both sides of the first beam main body 32a, And a second beam main body 32b protruding upward from the second beam main body 32b. That is, the first beam main body portion 32a is wider than the second beam main body portion 32b along the width direction (arrow B) of the beam member 30, and is disposed at the center of the first beam main body portion 32a A step can be formed between the first and second main body portions 32a and 32b by the second main body portion 32b being protruded.

A slab member fitting protrusion 32c which can be fitted into the upper and lower through holes 40a formed in the slab member 40 so as to pass through the upper and lower portions may be formed at both edges of the first body portion 32a. Therefore, the beam member 30 and the slab member 40 can be integrally joined.

The beam member 30 is formed to protrude to the lower side of the beam body portion 32 to form a coupling of the concave-convex structure to the beam fixing groove 24a of the pillar member 20 or the beam fixing groove 14a of the outer wall member 10. It may further include a beam protrusion 34 to be fitted.

The beam protrusion 34 has a cross section along the longitudinal direction (arrow A) of the beam member 30 corresponding to the beam fixing groove 24a of the pillar member 20 and the beam fixing groove 14a of the outer wall member 10. It may be a parallelogram, and may be formed throughout the beam member 30 along the longitudinal direction (arrow A) of the beam member 30 to serve as a rib for structural stability of the beam member 30. have.

The beam protrusion 34 may be formed only at the center portion along the width direction (arrow B) of the beam member 30 for structural stability and avoiding structural interference with the locking projection 36 to be described later.

The beam member 30 protrudes downward from the lower surface of the beam main body portion 32 and extends along the longitudinal direction (arrow A) of the beam member 30 to the column fixing portion 24 of the column member 20, (36) which is engaged with the resilient supporting portion (14) of the main body (10). Therefore, the engaging protrusions 36 of the beam member 30 are brought into close contact with the column fixing portion 24 along the longitudinal direction (arrow A) of the beam member 30 so as to be wound around the column member 20 or the outer wall member 10 A stopper preventing effect for restricting the movement in the longitudinal direction (arrow A) of the beam member 30 may occur. Therefore, the beam member 30 and the pillar member 20 can be easily coupled with each other at an accurate position by the slip prevention effect, so that the two pillar members 20, which are installed together in one pillar member 20, Interference, collision can also be avoided.

The locking jaw 36 is a beam so that the beam protrusion 34 of the beam member 30 can be fitted into the beam fixing groove 24a of the pillar member 20 or the beam fixing groove 14a of the outer wall member 10. Along the longitudinal direction (arrow A) of the member 30, the end of the beam member 30 is spaced apart by the fitting length of the beam protrusion 34 of the beam member 30 and the beam fixing groove 24a of the pillar member 20. And formed along the longitudinal direction (arrow A) of the beam member 30, but may be formed or partially formed over the entire remaining portion except for both ends.

The locking jaw 36 protrudes downwardly along the beam protrusion 34 on the lower side of the beam main body portion 32, and both sides around the beam protrusion 34 along the width direction (arrow B) of the beam member 30. Or it may be formed on either side, in particular to be formed to interact with the column fixing portion 24 of the pillar member 20. The locking jaw 36 is preferably formed on both sides of the beam protrusion 34 for structural stability.

The catching jaw 36 may be connected to the beam main body part 32 directly rather than being spaced apart from the beam protrusion 34 by a predetermined distance along the width direction (arrow B) of the beam member 30.

A fixing surface 36a which is an end surface at both ends along the longitudinal direction (arrow A) of the beam member 30 is fixed to the fixing surface 20a of the column member 20 by a surface contacting the column member 20 of the latching jaw 36. [ Or the fixing surface 14b of the resilient supporting member 14, in particular, the fixing surface 14b of the resilient supporting member 14 is preferably formed in a direction perpendicular to the longitudinal direction, (An arrow A). More preferably, the fixing surface 36a of the latching jaw 36 can be inclined toward the pillar member 20 in which the latching jaw 36 is hooked from the lower side to the upper side. The fixing surface 36a of the locking jaw 36 and the fixing surface 20a of the pillar member 20 and the fixing surface 36a of the fixing surface 14a of the outer wall member 10 can be ensured to be wide, When the beam member 30 is installed lowered from the upper side of the column member 20 and the outer wall member 10 downwardly, the engaging protrusions 36 of the beam member 30 abut against the fixing surface 20a of the column member 20 , And can easily and smoothly ride down along the fixing surface 14a of the outer-wall member 10 without frictional resistance.

Since the stopping jaw 36 is structurally formed to have a sufficient thickness only along the longitudinal direction (arrow A) of the beam member 30, the beam member 30 may be formed to have a sufficient thickness to reinforce the beam member 30 as a whole, All or a part of each of the engaging protrusions 36 may be formed thicker toward the column member 20 in which the engaging protrusions 36 are caught along the longitudinal direction (arrow A) More preferably, in order to increase the structural stability, the lower side 36b of the locking projection 36 may be formed in an arc shape in which all or part of the beam member 30 is symmetrical in the longitudinal direction (arrow A).

A structure using such a precast panel can be constructed as follows.

The outer wall member is formed by the outer wall member 10 as shown in Fig. 1 and the pillar member 20 is provided in the inner space formed by the outer wall member 10 and then the pillar member 30 is inserted into the pillar member 20 and the pillar member 20 or between the pillar member 20 and the outer wall member 10. [ 3, a slab member 40 may be installed between the beam member 30 and the beam member 30 so that a structure having a predetermined interior space R can be constructed.

Such a structure using precast panels can be useful as a storage tank for collecting groundwater.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

10; An outer wall member 14; [0030]
20; Column member 24; The column-
24a; A fixing groove 30; Beam member
34; Beam protrusion 36; Jaw
40; Slab member

Claims (14)

A plurality of pillar members 20 spaced apart from each other and formed with beam fixing grooves 24a;
Protruding downward from the lower surface of the beam main body portion 32 and the beam main body portion 32 installed above the pillar member 20 so as to span between the pillar member 20 and the pillar member 20. A plurality of beam members 30 including beam protrusions 34 fitted into the beam fixing grooves 24a of the pillar member 20;
A plurality of slab members (40) extending between the beam member (30) and the beam member (30) so as to form a surface together with the beam member (30);
Structure using a precast panel, characterized in that it comprises a. The method according to claim 1,
The beam fixing groove (24a) and the beam protrusion 34 is a structure using a precast panel, characterized in that formed in a gradually narrowing shape from the upper side to the lower side. The method according to claim 1,
The beam main body portion 32 of the beam member 30 includes a first beam main body portion 32a provided on the column member 20 or the beam receiving portion 14, And a second beam main body part (32b) protruding upward from the first beam main body part (32a) so as to be sandwiched between slab members (40) provided on the upper side of both edges of the slab member Structures used. The method according to claim 3,
And slab member fitting protrusions 32c which can be fitted into upper and lower through holes 40a formed in the slab member 40 so as to pass through the upper and lower through holes 40a are provided on both sides of the first beam main body portion 32a, Structures using cast panels. The method according to claim 1,
The beam protrusion 34 is a structure using a precast panel, characterized in that formed over the entire length of the beam member (30). The method according to claim 1,
The beam member 30 protrudes downward from the lower surface of the beam body portion 32 to the column fixing portion 24 of the pillar member 20 along the longitudinal direction (arrow A) of the beam member 30. Structure using a precast panel, characterized in that it further comprises a locking jaw (36) to be locked. The method of claim 6,
The beam projection 34 is formed in the center along the width direction (arrow B) of the beam member 30, the locking jaw 36 is characterized in that each formed on both sides of the beam projection (34) Structure using a precast panel characterized in that. The method of claim 7,
The catching jaw (36) is a structure using a precast panel, characterized in that connected to the beam protrusion 34 in the width direction (arrow B) of the beam member (30). The method of claim 6,
The fixing surface 36a in contact with the pillar member 20 of the locking jaw 36 is inclined along the longitudinal direction (arrow A) of the beam member 30 with respect to the vertical direction, and the pillar member 20. The structure using a precast panel, characterized in that formed correspondingly to be in surface contact with the fixing surface (36a) of the locking projection (36). The method of claim 9,
The fixing surface (36a) of the locking jaw (36) is a structure using a precast panel, characterized in that inclined in the direction toward the pillar member 20, the locking jaw 36 is caught from the lower side to the upper side. The method according to any one of claims 6 to 10,
The hooking jaw 36 is formed such that all or a part of the hooking jaw 36 along the longitudinal direction (arrow A) of the beam member 30 becomes thicker toward the pillar member 20 to which the hooking jaw 36 is hooked Structures using precast panels. The method of claim 11,
Wherein the lower surface of the latching jaw (36) is formed in an arcuate shape symmetrical with respect to a longitudinal direction (arrow A) of the beam member (30). The method according to any one of claims 1 to 10,
A plurality of joints are installed so as to form an outer wall, and the beam support part 14 protrudes from the inner side of all or a part of the beam member 30 together with the pillar member 20 so as to support the beam support part 14. A structure using a precast panel, characterized in that it further comprises a plurality of outer wall member (10) which is open from the upper side to the lower side and the beam fixing groove (14a) formed through the inner and outer directions of the outer wall body. The method according to claim 13,
Wherein a plurality of outer wall member (10) is formed with a slab support portion (16) protruded to support the slab member (40) on all or part of inner side surfaces thereof.

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