KR20130109298A - Joint structure of pc column with non-sleeve - Google Patents

Abstract

PURPOSE: A PC column joint structure with upper and lower parts into one set using a non-sleeve joint structure is provided to improve constructability and workability using the joint block of an upper column corresponding to the direct joint groove of a lower column to insert and assemble the upper column to the lower column. CONSTITUTION: A PC column joint structure with upper and lower parts into one set using a non-sleeve joint structure comprises the following steps: forming a stepped part (120) to mount a PC girder on the outer side of the top of a column body (110) and forming a direct joint groove (130) in the center of the stepped part; and joining the upper column to a PC girder using cast-in-place concrete by forming a joint block (220) to correspond to and be inserted into the direct joint groove at the bottom of the column body (210) of the upper column and assembling the main bar of the lower column to a fastening part (230) at each corner of the bottom of the column body.

Description

Joint structure of PC column with non-sleeve joint structure {Joint structure of PC column with Non-Sleeve}

In the present invention, in the construction of various buildings having a multi-storey structure including a storage tank and an underground parking lot, a conventional sleeve (SLEEVE) for connecting the upper and lower pillars is omitted, but the lower pillar is directly connected to the non-shrink mortar. The upper pillar is provided with a joint block corresponding to the direct connection groove, respectively, so that the precision workability and workability are greatly improved by a simple fitting assembly structure when assembling, and the lower pillar and the upper pillar are non-shrink mortar. Due to the filling high strength bonding, it is possible to assemble PC of the upper layer in parallel with the placing of lower concrete, and it is formed to secure the continuity of PC assembly. Meanwhile, the PC girder seated on the lower jaw of the lower pillar is stable by a separate binding muscle. At the same time, the upper root is connected to the upper hole through the coupling to allow the concrete to be cast and cured, so that the connection structure of the upper and lower tanks is secured and solidity is maintained. The present invention relates to a connection structure of a pair of upper and lower pairs of pillars for a building having a non-sleeve coupling structure, which is characterized in that workability, precision workability, durability, and building quality are greatly improved.

In general, as shown in Patent Application No. 10-2005-0077681, the PC compounding method means that some or all of the major structural members such as reinforced concrete columns, beams, and slabs are manufactured in a factory, assembled and installed in the field, and joints and slabs between the members are manufactured. Refers to a method of integrating a structure by pouring field concrete on top.

Such a construction method is a complex construction method combining a factory production method and an on-site construction method, has a joint structure by a wet joint system, and is characterized by industrial construction by factory production and on-site assembly construction.

Therefore, this method is manufactured at the factory and assembled on site, so the structure is of good quality, easy to construct, and the construction work can be completed early, resulting in a shorter construction period. There is an advantage.

On the other hand, when the construction of the building by the above-described method, as shown in Figure 7, the building more than two stories, so as to connect the lower side and the upper side of the upper surface and the lower surface abutting to each other in order to connect the conventional rib As a result of the structural calculations, these ribs are installed in the corresponding column connection parts and then assembled, thus causing excessive material costs, and the workers are not productive due to cumbersome workmanship, but also due to productivity decrease. There is a delay in the construction period, and in particular, the problem of deteriorating the building quality due to the inaccurate building construction.

The present invention is to solve the above-described problems, the technical gist of the construction of a variety of buildings having a multi-storey structure including a storage tank, underground parking, so that the conventional sleeve (SLEEVE) for the connection of the upper and lower pillars is omitted. In the lower column, there is a direct connection groove filled with non-contraction mortar, and the upper column is provided with a joint block corresponding to the direct connection groove, respectively. In addition, the lower column and the upper column can be assembled to the PC of the upper layer in parallel with the pouring of the lower concrete due to the non-contraction mortar-filled high-strength bonding to provide a continuity of the PC assembly There is this.

In addition, the present invention promotes significant labor savings due to the omission of the ribs, and reduces the cost due to air shortening, while the PC girder seated on the stepped jaw of the lower column while ensuring a stable fastening by a separate binding muscle At the same time, after the upper part is connected to the upper hole through the joint, the concrete is cast and cured, so that the connection structure of the upper and lower one-piece PC columns ensures solid integrity and continuity, as well as workability and precision workability. And to provide that the durability and building quality are greatly improved.

In order to achieve the above object, the pillar pillar connection structure of the present invention extends outward on the top of the columnar body 110 having a square body having a length up and down, and the stepping rod 120 is formed to seat the PC girder 300. A direct connection groove 130 is formed at the center on the surface of the hooking jaw 120, and the main root 140 embedded from the inside of the column body 110 branches and protrudes upward on the outer circumferential surface of the direct connection groove 130. Lower pillar 100 and; A joint block 220 is formed at a lower end of the pillar body 210 having a length up and down so as to correspond to the direct connection groove 130, and a lower end of the pillar body 210 contacting the joint block 220. When each corner fastening portion 230 of the lower column is assembled through the fixing hole 232 of the fixing bracket 231, fastening by the upper fixing nut 233 and the lower height adjustment nut 234 After being fixed, the upper pillar 200 to be combined with the PC girder 300 by the site concrete (C); .

Thus, the lower pillar 100 is formed so that the non-contraction mortar 150 is filled in the direct connection groove 130, the upper pillar 200 is that the uneven surface 240 on the outer peripheral surface of the joint block 220 desirable.

In addition, the joint block 220 of the upper pillar 200 has a connection hole 250 penetrated in one direction and the other direction on one side on the surface, so that the upper root 310 extending from the PC girder 300 passes through without interference. After being placed, it is formed so that it can be cast by the site concrete (C), the joint block 220 is precast concrete integrally formed with the pillar body 210 or H-beam, L-shaped steel, C-shaped steel, T It is preferred to be formed of any one of the section steel.

In this case, the lower column 100 is formed with a binding muscle 260 to ensure structural integrity with the PC girder 300 on the upper jaw (120) when assembled with the upper pillar 200, the binding muscle ( 260 is one end is embedded in one side of the pillar body 110, the other end is branched to the upper surface of the stepping jaw 120 is assembled groove formed in the bottom surface of the compound groove 320 of the PC girder 300 After passing through the 330 is fastened by the assembly nut 340 it is preferable to be synthesized by the field concrete (C).

In addition, the lower column 100 has a plurality of pillar connecting muscles 160 are formed on the outer peripheral surface of the direct connection groove 130 of the hooking jaw 120 to support the lower outer surface of the lower column of the upper pillar when assembling the upper pillar 200. It is desirable to ensure that.

Thus, in the present invention, in the construction of various buildings having a multi-storey structure including a storage tank and an underground parking lot, the conventional sleeve (SLEEVE) for connecting the upper and lower columns is omitted, but the non-shrink mortar is filled in the lower column. It is provided with a direct connection groove, the upper column is provided with a joint block corresponding to the direct connection groove, respectively, when assembling to improve the precision workability and workability by the simple fitting assembly structure, as well as the lower column and the upper column Due to the non-shrink mortar-filled high-strength bonding, it is possible to assemble the PC of the upper layer in parallel with the pouring of the lower concrete, thereby securing the continuity of the PC assembly.

In addition, the present invention promotes significant labor savings due to the omission of the ribs, and reduces the cost due to air shortening, while the PC girder seated on the stepped jaw of the lower column while ensuring a stable fastening by a separate binding muscle At the same time, after the upper part is connected to the upper hole through the joint, the concrete is cast and cured, so that the connection structure of the upper and lower one-piece PC columns ensures solid integrity and continuity, as well as workability and precision workability. In addition, durability and building quality are greatly improved.

Figure 1 is an exploded perspective view showing a coupling state of the lower column and the upper column of the upper, lower one tank type cylinder according to the present invention,
Figure 2 is a longitudinal cross-sectional view showing a coupling state of Figure 1,
Figure 3 is an enlarged perspective view of the main portion showing the lower column according to the present invention,
Figure 4 is an enlarged perspective view of the main portion showing the upper column according to the present invention,
5 to 6 are exemplary plan views showing that the PC girder is coupled in one direction or two directions to the PC pillar according to the present invention;
Figure 7 is an exemplary view showing a conventional double layer PC pillar connection structure.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the accompanying drawings.

First, the present invention relates to the connection structure of the vertical column 1 set of PC pillars, as shown in Figures 1 to 6, it is largely composed of a lower column having a direct groove and an upper column having a joint block.

Thus, the lower pillar 100 is extended to the outside on the top of the columnar body 110 of the rectangular tetrahedral body having a length up and down to form a stepping step 120 so that the PC girder 300 is seated, the stepping step 120 The direct connection groove 130 is formed on the center of the plane, and the main root 140, which is embedded from the inside of the column body 110, is branched to protrude upwards on the outer circumferential surface of the direct connection groove 130.

In this case, as shown in Figure 5, as shown in Figure 5, the length is long in one direction or as shown in Figure 6, it may be formed of any one having a square surface, the one-way or two-way construction of the It is desirable to make all possible.

At this time, the direct groove is shown as a square groove etched toward the inside of the pillar body from the stepped surface, the direct groove is a joint block of the upper column to be described later H-beam, L-shaped steel, c-shaped steel, T-shaped steel It is preferable to be provided in a corresponding shape as formed in any one of.

In addition, the main root 140 is preferably a screw thread is formed on the branched side end side to be assembled with the fixing nut and the height adjustment nut of the fastening portion to be described later.

On the other hand, the upper column 200 is formed with a joint block 220 to be inserted in correspondence with the direct connection groove 130 at the lower end of the pillar body 210 of the rectangular body having a length up and down, the joint block 220 When the main root 140 of the lower column is assembled through the fixing hole 232 of the fixing bracket 231 to each corner fastening portion 230 of the lower end surface of the pillar body 210 in contact with the upper body, the upper fixing nut 233 and the lower side After being fastened and fixed by the height adjusting nut 234, it is configured to be combined with the PC girder 300 by the field concrete (C).

At this time, the joint block 220 is preferably formed of any one of precast concrete or H-beam, L-shaped steel, c-shaped steel, T-shaped steel integrally formed with the pillar body (210). That is, to enable a variety of variations by design.

Thus, the lower pillar 100 is formed so that the non-contraction mortar 150 is filled in the direct connection groove 130, the upper pillar 200 is that the uneven surface 240 on the outer peripheral surface of the joint block 220 desirable.

That is, the non-shrink mortar is formed in the direct groove, the embossed or other concavo-convex surface is formed on the outer peripheral surface of the joint block to increase the bonding surface area during synthesis (pouring and curing) to greatly improve the synthesis efficiency to be.

In addition, the fastening part is to fix the main root of the lower column, and when the joint block of the upper column is first inserted into the direct connection groove of the lower column to be fixed to the girder using the support brass (BRACE) first, and then the fastening part The main root penetrating the fixing bracket fixing hole is formed at the end, the fixing nut is formed on the upper side and the height adjusting nut is formed on the lower side based on the fixing bracket to form the height and fixing at the same time by screwing.

In addition, the joint block 220 of the upper pillar 200 has a connection hole 250 penetrated in one direction and the other direction on one side on the surface, so that the upper root 310 extending from the PC girder 300 passes through without interference. It is preferable that it is formed so that it can be poured by on-site concrete (C) after being placed.

That is, the connecting hole is to ensure the structural integrity and continuity of the PC pillar by allowing the upper root to continue after passing through the upper pillar without interference in order to secure the integrity with the PC girder.

In this case, the lower column 100 is formed with a binding muscle 260 to ensure structural integrity with the PC girder 300 on the upper jaw (120) when assembled with the upper pillar 200, the binding muscle ( 260 is one end is embedded in one side of the pillar body 110, the other end is branched to the upper surface of the stepping jaw 120 is assembled groove formed in the bottom surface of the compound groove 320 of the PC girder 300 After passing through the 330 is fastened by the assembly nut 340 it is preferable to be synthesized by the field concrete (C).

In addition, the lower column 100 has a plurality of pillar connecting muscles 160 are formed on the outer peripheral surface of the direct connection groove 130 of the hooking jaw 120 to support the lower outer surface of the lower column of the upper pillar when assembling the upper pillar 200. It is desirable to ensure that.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

100 ... lower pillar 110 ... column body
120 ... step 130 ... direct groove
140 ... Main root 150 ... Anhydrous mortar
160 ... column connecting muscle 200 ... upper column
210 ... pillar body 220 ... joint block
230 ... fastening part 231 ... fixing bracket
232 ... fixing hole 233 ... fixing nut
234 ... Height adjusting nut 240 ... Uneven surface
250 ... 260 Binding ...
300 ... PC girder 310 ... upper root
320 ... Composite groove 330 ... Assembly groove
340 ... Assembled Nut

Claims (5)

A stepping rod 120 is formed to extend to the outside on the top of the pillar body 110 having a vertical body having a length up and down so that the PC girder 300 is seated, and a direct connection groove 130 is formed on the center of the stepping rod 120. A lower pillar 100 formed on the outer circumferential surface of the direct connection groove 130 and having the main root 140 embedded from the inside of the pillar body 110 branched to protrude upward;
A joint block 220 is formed at a lower end of the pillar body 210 having a length up and down so as to correspond to the direct connection groove 130, and a lower end of the pillar body 210 contacting the joint block 220. When each corner fastening portion 230 of the lower column is assembled through the fixing hole 232 of the fixing bracket 231, fastening by the upper fixing nut 233 and the lower height adjustment nut 234 After being fixed, the upper pillar 200 to be combined with the PC girder 300 by the site concrete (C);
The connection structure of the upper and lower one-piece PC pillar for the building having a non-sleeve combined structure, characterized in that made. According to claim 1, wherein the lower pillar 100 is formed so that the non-contraction mortar 150 is filled in the direct connection groove 130, the upper pillar 200 is an uneven surface on the outer peripheral surface of the joint block 220 ( 240) is a connection structure of the upper and lower one-piece PC pillar for buildings having a non-sleeve coupling structure. The upper block 310 of claim 2, wherein the joint block 220 of the upper pillar 200 has a connection hole 250 penetrated in one direction and the other direction on one side of the plane and extends from the PC girder 300. After being penetrated and reinforced without interference, the joint block 220 is formed of precast concrete or H-beam, L-shaped steel, which is integrally formed with the pillar body 210. Connection structure of the upper and lower one-piece PC pillar for buildings having a non-sleeve coupling structure, characterized in that it is formed of any one of c-beam, T-beam. According to claim 3, The lower column 100 is the binding column 260 is formed so as to ensure the structural integrity with the PC girder 300 on the upper step 200 when assembled with the upper pillar 200, The binding muscle 260 is one end is embedded in one side of the column body 110, the other end is branched to the upper surface of the stepping jaw 120, the bottom surface of the compound groove 320 of the PC girder 300 The upper and lower one-piece set for buildings having a non-sleeve combined structure, characterized in that after passing through the assembly groove 330 formed in the fastening by the assembly nut 340 is synthesized by the field concrete (C) Connection structure of PC pillar. According to claim 4, The lower column 100 is formed on the outer peripheral surface of the direct connection groove 130 of the hooking jaw 120 a plurality of column connecting muscles 160 are formed at the bottom of the upper column when assembling the upper column 200 Connection structure of the upper and lower one-piece PC pillar for the building having a non-sleeve coupling structure, characterized in that to secure a support force to the outer peripheral surface.

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