KR200345792Y1 - P.S.C-Ibeam by steel bracket - Google Patents

Abstract

The present invention relates to a P.S.C-I beam made of steel brackets. In the related art, two beams cannot be structurally continually constructed. As the slab is continuously constructed after filling and connecting concrete between the beams again, the running of the vehicle is quite good, but the complete concrete structure is not possible, so the filling concrete between each beam as well as the upper slab concrete are Cracks gradually occur, degrading structural stability and usability.

The present invention integrates the end fixing plate 4 and the steel bracket 6 with a plurality of anchor bolts 7 and nuts 13 at the points of the P.S.C-I beam 1 as shown in FIG. And the lower end of the steel bracket (6) by welding with the lower connecting plate (8) and the bracket connecting plate (9) is padded on both sides of the steel bracket (6) bolt 10 and the nut (10 ') The upper connection bracket 11 is installed on the upper end of the end fixing plate 4, and the upper connection PC steel bar 12 is supported on the upper connection bracket 11 so as to be fixed as a nut 21 and the upper PC at the same time. In the state in which the strand 20 is additionally placed, the filling concrete 15 between the beam and the beam is to be poured.

Description

P.S.C-Ibeam by steel bracket

The present invention relates to the structure of the PSC-I beam (PSC-I Beam), more specifically, the end fixing plate and the steel bracket and the upper PC steel bar fixed between the beam and the beam anchor bolt and nut or The rigid connection by the upper PC strands allows the P.S.C-I beams of each span independently manufactured on the ground to be continuously combined more effectively over more than two spans.

Conventionally, as shown in FIG. 1A, in constructing a P.S.C-I beam bridge having two or more spans, the P.S.C-I beam 1 is independently prepared in advance on the ground, and a simple beam structure is provided over each span. After constructing them independently, construct them by continuously combining only the slab concrete 16 on the I beams without structurally connecting the I beams of each span, or as shown in FIG. When prefabricated, the rebar 17 is pre-exposed to the end of each beam to be hypothesized on each pier 2, and then the pre-exposed rebar 17 is overlapped, and the concrete is again between the beam of the point 4 and the beam. After filling and connecting the slab concrete 16 on the I beam there is a method of construction by combining.

Each of the above methods is independent of the P.S.C-I beams, which are independently manufactured on the ground, and thus are not structurally continuous. Therefore, the bridge supports (3) on each bridge (2) are each beam. Each bridge pier must use two bridge arrangements (3), and the concrete (15) refilled between the beams and beams is not completely attached at the interface and is cut off. Cracking may occur gradually due to the vibration load continuously generated each time it passes, and it is inevitable that the slab concrete 16 on the I-beam also cracks due to the parent part of the point.

In addition, since two bridge devices (3) are used on each bridge for the same reason as above, two bridge devices (3) cannot be divided by half between two bridge devices (3) on the bridge (2). One of the teaching device 3 has a disadvantage that the reaction force is generated and the other of the teaching device 3 excessively the reaction force acts excessively the capacity of the teaching device (3).

The present invention does not rely only on the reinforcing bar 17 or concrete 15 in connecting the beams and beams, but also has end fitting plates and steel brackets having superior structural durability than reinforcing bars or concrete brackets, and bolts. By firmly coupling with PC steel rods, the structural rigidity of the connection is made larger than the rigidity of the P.S.C-I beam itself. The purpose is to improve the usability and perfect structural safety in constructing two or more continuous P.S.C-I beam bridges by arranging them continuously over the span.

The present invention for realizing the above object is previously embedded in the concrete of the I-beams in the concrete of the I-beams, as shown in Figure 2 when inserting the upper PC strand when each I-beams independently on the ground, the connecting end of each beam An end fixing plate having a through hole through which a sheath pipe penetrates at the same time as protruding two steel brackets is securely attached to the beam by a plurality of anchor bolts and nuts which are pre-embedded in the concrete of the I beam. After installation, the lower connecting plate and the two steel brackets pre-installed on the staircase are joined together by welding, and the two steel brackets longitudinally adjacent to each other protrude from the end fixing plate between the beams and the beams. And bolt as the nut and the upper connection PC steel rod is supported on the upper connection bracket fixed to the top of the end fixing plate. At the same time, the upper connection sheath pipe is assembled and the upper PC strand is inserted and arranged continuously over all the spans, and the slab can be continuously installed while the filling concrete is placed between each beam. I would have done it.

1A is a front schematic view of a state in which a conventional P.S.C-I beam is constructed by a simple beam structure system so that only slab concrete is continuous;

1B is a schematic front view of a state in which a conventional P.S.C-I beam is constructed with a simple beam structure and filled with reinforced concrete between beams and beams, and then constructed so that slab concrete is continuous;

Figure 2 is a longitudinal cross-sectional view of a state in which the sheath pipe for inserting the upper PC strand in advance when manufacturing each beam independently from the ground according to the present invention,

Figure 3 is a cutaway perspective view of the end fixing plate protruding from the steel bracket on one or both ends of the P. C-I beam according to the present invention is fixed to the beam by an anchor bolt and a nut embedded in concrete,

Figure 4a is a front view of a state in which the bottom of the steel bracket is in close contact with the lower connecting plate on the bridge device by installing a P.S.C-I beam according to the present invention on a temporary support pre-installed on the bridge,

4B is a cross-sectional view taken along the line A-A of FIG. 4A;

5 is an exploded perspective view before connecting the connecting pipe and the bracket connecting plate to the connecting portion of the P. S. C-I beam according to the present invention,

Figure 6a is a perspective view of the separation before connecting the upper connection PC steel bar on the top of the steel bracket after coupling the connection bracket of the P.S.C-I beam connecting plate and the steel bracket between each beam with a bolt and nut according to the present invention ,

6B is a cross-sectional view taken along the line B-B in FIG. 6A;

FIG. 7 is a cross-sectional view taken along line CC of FIG. 6B of a P.S.C-I beam according to the present invention, wherein a connecting sheath pipe is installed between each beam to continuously penetrate the sheath pipe previously embedded in each beam; FIG. After that, the cross-sectional view of the state in which the upper PC strand is continuously inserted into and the upper connecting PC steel bar is assembled,

8 is an exploded perspective view of the connection portion of the P. C-I beam according to the present invention,

Figure 9 after the completion of the coupling connection of the steel bracket and the lower connecting plate and the upper connecting PC steel bar in the connection portion of the P.S.C-I beam according to the present invention of the filling concrete between the beam and the beam Partial incision perspective,

10 is a schematic longitudinal cross-sectional view showing the arrangement of the connection portion and the upper PC strand of the three-span continuous bridge using the P.S.C-I beam according to the present invention.

* Description of the symbols for the main parts of the drawings *

1-P.S.C-I Beam, 2-Pier,

3-chair, 4-end plate,

5-through hole, 6-steel bracket,

7-anchor, 8-lower connecting plate,

9-bracket connection plate, 10-connection bolt,

10 '-nut, 11-upper connection bracket,

12-PC connection steel rod, 13-anchor fixing nut,

14-temporary support, 15-filled concrete,

16-slab concrete, 17-rebar,

18-Sheathpipe, 19-Sheathpipe,

20-Upper PC Strand, 21-Upper Connection PC Steel Bar Nut,

22-Support bracket for upper connection bracket.

The present invention, when manufacturing the P.S.C-I beam (1) from the ground in advance as shown in Figure 2 and Figure 3, the sheath pipe 18 to insert the upper PC strand 20 in the concrete of the I beam. Of the P.S.C-I beam (1) by the anchor bolt (7) and the nut (13), which is pre-filled and the end fixing plate (4) is prefilled in the concrete of the I beam at one or both ends of the beam. It can be combined with the end concrete to produce a P.S.C-I beam. At this time, the end fixing plate 4 has two steel brackets 6 protruding by welding coupling with the end fixing plate 4, and a through hole 5 through which the sheath pipe 18 can penetrate at the upper center thereof. It should be formed, and a number of bolt holes should be drilled in advance in the steel bracket 6 so that the bolt 10 and the nut 10 'may be fastened by the connecting plate 9.

In addition, as shown in FIG. 4A, one bridge device 3 is installed on each bridge 2 in advance, and a temporary support 14 is installed to temporarily support the weight of the I beam on both sides of the bridge device 3. At the same time, the lower connecting plate (8) is installed to be fixed in advance on the seating device (3), and then each beam (1) prefabricated on the ground is installed so as to be supported on the temporary support (14), but the steel bracket (6) The lower part of the steel plate 6 and the lower connecting plate 8 is completely coupled by welding so as to be completely in contact with the lower connecting plate (8).

First, as described above, the steel bracket 6 and the lower connecting plate 8 are completely coupled by welding, and then through the through hole 5 formed in the center of the end fixing plate 4 as shown in FIG. In the two adjacent beams in the direction of the pipe sheath pipes 18, which are embedded in the connection between the pipes 19 are installed so that the two protruding steel brackets 6 between each beam connecting two brackets The plate 9 is padded on both sides to fix the connecting bolt 10 and the nut 10 'so as to be continuous.

At this time, each of the bracket connecting plates 9 drills a plurality of bolt holes in advance so as to coincide with the bolt holes of the steel bracket 6.

Through the above process, the two steel brackets 6 are completely connected by the bracket connecting plate 9, the bolt 10, and the nut 10 'between each beam and the beams, and the lower end between the beams is The lower part of the steel bracket 6 is completely connected by welding with the lower joint plate 8, and the upper end is supported by the upper connection bracket 11 previously installed on the steel bracket 6 as shown in FIG. After installing the upper connection PC steel rod 12 and fixed with a nut 21, the upper end between each beam as well as the lower end to complete the coupling.

At this time, the upper connection bracket 11 is fixed on the steel bracket (6) together with the support plate (22).

7 shows that the connecting sheath pipe 19 between the beams and the beams according to the present invention continuously connects the sheath pipes 18 previously embedded in each beam, and then inserts the upper PC strand 20 therein. Shows the installed status.

Exemplary Figure 8 is an exploded perspective view representing the entire coupling process of the present invention at the same time, each beam and beam between the steel bracket (6) and its connecting plate (9) and the lower connecting plate (8) and the upper connecting PC steel bar (12) When completely continuous, such as, Figure 9 is filled with concrete between each beam and the beam as shown in Figure 9 to embed the steel bracket (6) and its connecting plate (9) in the concrete of the beam (15) each span is completely In addition, the temporary support 14 is removed so that one bridge device 3 supports the load, so that the P.S.C-I beam bridge of the complete continuous structure system is supported.

As described above, after the beams are completely connected to each other, the temporary support 14 is removed to support only one bridge device 3 for each bridge, and thus the continuous coupling portion that becomes the point on each bridge is used for the I beam. Parenting due to dead weight due to placing of slab concrete 16 and asphalt pavement, which are constructed after continuous coupling, is generated firstly, and parenting due to live load due to vehicle traffic is generated secondly after completing the bridge.

In the present invention, the upper connection PC steel bar 12 at the upper end of the connection part may resist both the dead load and the parent load due to the live load, and optionally, the parent load due to the dead load may be borne by the upper connection PC steel bar 12. As the parent load due to the live load, as illustrated in FIG. 7, the upper PC strands 20 are separately placed above the connection portions between the beams and the beams, or the upper PC strands 12 are entirely excluded and the upper PC strands ( 20) may be used to resist both parental loads and dead loads. At this time, in order to arrange the upper PC strand 20, when manufacturing the respective beams on the ground independently, as shown in Fig. 2, the sheath pipe 18 is embedded in the concrete of each beam in advance to the upper PC strand 20 Space must be provided for continuous insertion over each span.

As such, the beams in which the sheath pipes 18 into which the upper PC strands 20 can be inserted are pre-arranged are hypothesized on each of the piers 2 through the same process as before. After completing the coupling of the lower connecting plate (8) and the combination of the steel bracket (6) and the bracket connecting plate (9) and the assembly of the upper connecting PC steel rod 12 and at the same time as shown in Figure 5 two protruding steel bracket ( 6) Assemble the connecting sheath pipe 19 for connecting the sheath pipes 18 of two beams adjacent in the longitudinal direction at the upper part of the interspace. At this time, the through hole 5 should be formed in the upper side of the end fixing plate 4 of each beam so that the sheath pipe 18 and the connecting sheath pipe 19 which are previously embedded in the I beam can be continuously assembled and assembled. do.

Through the above process, the sheath pipe 18 embedded in the beams of each span in advance is allowed to penetrate the upper PC strand 20 after all the spans of two or more spans are continuously penetrated by the connecting sheave pipes 19 between the beams. After inserting and arranging to be continuous over all spans, construct the filling concrete 15 between each beam, remove the temporary support 14, and tension the upper PC strand 20 first just before constructing the upper slab 16. After fixing or installing the upper slab (16) to be tension fixed.

Up to now, when constructing P.S.C-I beam in multi-span over 2 spans, beams of each span are independently produced on the ground and hypothesized as a simple beam structure system over each span. As shown in FIG. 1B, two slab devices are used to fill the beams and the slabs are continuously constructed by filling only the reinforced concrete with only the reinforced concrete. Therefore, it is impossible to realize a complete continuous structure system.

The present invention is completely made of the P.S.C-I beam produced independently from the ground as described above as a steel bracket and its connecting plate and lower connecting plate and upper connecting PC steel bar between the beam and the beam of each span. By continuous coupling, the structural stiffness of the connecting portion is greater than that of the P.S.C-I beam itself, so that two or more spans of P.S.C.I-beam bridges that are structurally completely continuous with only one crosslinking device are used. In addition, it is possible to construct a continuous prestressed compressive stress which can reliably resist the tensile stress in which the parent moment and the constant moment intersect continuously over all spans by additionally tensioning the upper PC strand. There is an additional effect that can be introduced.

Claims (7)

In the P.S.C-I beam, an end fixing plate 4 is provided at one end or both ends of the P.S.I-beam 1, and the end fixing plate 4 is a P.S.C-I beam. -PS beam, characterized in that it is fixed by the anchor bolt (7) and the nut (13) embedded in the concrete of the beam. The P.S.C-I beam according to claim 1, characterized in that two steel brackets (6) protrude from the end fixing plate (4). 3. The two beams of steel beams (6) adjacent to each other in the longitudinal direction are superimposed so as to surround two bracket connecting plates (9) and are coupled as a bolt (10) and a nut (10 '). PS C-I beam 3. The P.S.C-I beam according to claim 2, wherein an upper connection bracket (11) is installed at an upper end of the steel bracket (6) to connect the upper connection PC steel bar (12). 3. The lower end of the steel bracket (6) is coupled to the upper surface of the lower connecting plate (8) pre-installed on the seating device (3) of each pier (2) by welding or the like. Mr.-I beam 2. The sheath pipe 18, which can be inserted through the upper PC strand 20, is pre-embedded in the P.S.-I beam 1, and the upper portion of the center fixing plate 4 is placed in the upper portion. P. S. C.-I beam, characterized in that the through-hole 5 through which the sheath pipe 18 can pass. The method according to claim 6, characterized in that the two longitudinally adjacent sheath pipes (18) are continuously connected by assembling the connecting sheath pipes (19) through the through holes (5) of the end mounting plate (4). PS C-I beam