KR101178737B1 - Continuous structure of composite psc girder using prestress at section changing girder height of lower center as straight steel and construction method thereof - Google Patents

Abstract

PURPOSE: A continuous structure of a PSC composite girder having a prestressed cross section which changes the height of a center bottom and a construction method thereof are provided to reduce the discharged amount of carbon by reducing the use of equipment. CONSTITUTION: A continuous structure of a PSC composite girder having a prestressed cross section which changes the height of a center bottom is composed as follows. High-contraction PSC composite girders(50) are consecutively installed on an abutment(11) and a pier(12). An upper continuation device(70) is installed on the tops of the PSC composite girders, and/or a lower continuation device(80) is installed on the bottoms of the PSC composite girders. Cast-in-place horizontal beams are installed on the side surfaces of the PSC composite girders. Bearings(13) are installed on the connection parts of the PSC composite girders and the upper and lower continuation devices to support the PSC composite girders.

Description

Continuous structure of composite PSC girder using prestress at section changing girder height of lower center as straight steel and construction method }

In the present invention, the primary steel wire is installed on both ends of the girder in a parabolic shape, and the mold height at the lower part of the girder is reduced compared to the mold height at the bottom of the center part, or the girder height at the bottom of the center part is smaller than the mold height at the lower part of the girder end, PSC composite girder with prestressed steel in the bottom of the girder and pre-stressed steel wire is installed with another straight steel, and the PSC composite girder is constructed by using the PSC composite girder. Girder continuous bridge is installed to secure a larger margin and construction limit than existing girder bridges, and at the same time, the upper and lower continuous devices or upper and lower continuous devices are installed on the upper and lower parts that connect the girder and the girder, PSC has a tensile stress in the upper part and a compressive stress in the upper part, and the prestress is introduced into the slab installed at the upper part of the connecting part. The support which is installed to support the girders in the piers while installing the girder continuous bridges is also pre-stressed with straight steel on the cross section of the lower part of the center where the girders are supported by one supporting device to form the actual continuous bridges. The present invention relates to a continuous structure of a PSC composite girder and a construction method thereof.

In the present invention, the upper and lower continuous devices are installed in the upper and lower continuous devices selectively installed in the upper, lower continuous device, or both upper and lower continuous devices, respectively, for installation of the continuous bridge. It is installed a continuous bridge.

In addition, to install the cross beam connecting the girders and girders from the side in the field, the cross beams are installed by using the pre-fabricated reinforcing cages and formwork to improve the workability and make economic construction method. Reinforcement of the reinforcing bars was made by applying the method of binding the studs at the end of the connecting reinforcement with the loop strip reinforcement and the fixing reinforcing bars to have the integrity with the pour concrete section.

Conventionally, as shown in FIG. 1, when the PSC composite girder 30 is mounted on alternating and pier or piers and piers, and the slab 16 is poured, the stress caused by all the loads is installed on the PSC composite girder 30. 33) by introducing prestress into the girder only to offset the use of the steel wire necessary for the introduction of the prestressing force, the increase in the cross section of the girder 30 and the primary steel wire 33 all according to the curved installation. As losses due to friction loss and creep have increased, the use of uneconomical cross sections and steel materials has been caused by the introduction of excessive tension.

The cross section of the girder 30 manufactured in such a situation is excessively flexible, and when applied to the bridge by using the girder manufactured with the excessive cross section, flexibility in securing the construction limit or the free height formed in the lower longitudinal direction of the girder Due to this shortage, it is true that the girder made of the excessive cross section and the construction limit or spare height have been reduced due to the above-mentioned when applied to rivers, roads and railway bridges, and thus, many difficulties have been obtained to secure the necessary construction limit and spare height.

In case of applying the conventional PSC composite girder 30, it is necessary to raise the end plan of roads, complexes, or railways in order to secure construction limits or free space. As a result, construction cost increases, carbon amount increases due to excessive use of equipment, and construction period. There have been problems of non-environmental and non-terrestrial-friendly aspects due to increase and complaints.

In addition, when installing crossbeams, since the installation of copper bars and formwork at the site, excessive manpower and risks have emerged, and as a way to replace them, crossbeams or precast crossbeams by steel have been applied. It is difficult to reduce the workability due to the construction and the size and adjustment of the precast product, and therefore, the construction cost increases and the construction period increases.

On the other hand, conventionally, when installing a continuous bridge by sequencing the PSC composite girder, the secondary sequential steel wire (32) installed for continuity is in the state of introducing the prestress by connecting only the girder, the prestress is not introduced into the installed slab. The slab has a separate continuous reinforcing bar 18, which is not only economical and troublesome due to construction problems, but also due to the continuous structure instead of the complete continuous bridge structure, there is no moment redistribution phenomenon. It causes the increase, and there is a problem in that there is a partial lack of stability due to degradation of the flexible structure.

In addition, the second sequential steel wire 32 has a large curvature installed when connecting the girder 30 and the girder 30, and the length is long, so that the sheath and frictional loss are excessive to introduce the designed prestress amount to the girder. As a matter of fact, it is difficult and economical construction is being made to compensate for insufficient prestress by installing additional steel.

In addition, when the secondary continuous steel wire 32 is installed on the girder 30, the secondary continuous steel wire 32 installed by installing the fixing block 59 for installing the secondary continuous steel wire 32 on the outside of the girder is external. There is a problem that hurts aesthetics by being exposed to.

Thus, when the girder 30 and the girder 30 are continuous by the secondary sequential steel wire 32, substantial continuity is not achieved, so that the piers support the respective girders, and prestress is not introduced into the slab. It is not economical due to the fact that it is impossible to install a continuous bridge and redistribution of moments to loads only at a partial stage without moment redistribution of all loads applied in stages. The problem of installing bridges has existed to this day.

The present invention is proposed to improve the above problems.

In other words, the building limit, which is a condition required for each bridge, is divided into the case of the bridges installed in railways, complexes, roads and rivers, so as to ensure adequate margin. Each was produced.

In addition, a secondary straight steel was installed in the center lower part of the girder to introduce prestress into the girder.

In addition, by applying an upper continuous device for substantially continuous girder on the upper part where the girder and the girder are successively arranged on the pier, the compressive stress is introduced at the upper part of the girder and the tensile stress is introduced at the lower part, and thus prestress is applied to the slab. Introduced,

Alternatively, pre-stress is applied to the slab installed by applying the compressive stress on the upper part of the girder and the tensile stress on the lower part by applying the lower continuous device to substantially continuous the girder on the lower part where the girder and the girder are successively installed on the pier. Introduced,

Alternatively, the upper and lower continuous devices may be applied to the upper and lower parts of the upper and lower parts in which the girder and the girder are continuously installed on the pier to compress the stress at the upper part of the girder and the tensile stress at the lower part thereof. Prestress is also introduced to the slab so that the actual continuous bridge is installed, and one-point support base is used to support the girders at the bridge.

In addition, the cross beams connecting the girders and the girders on the side are installed using reinforcing cages and formwork pre-fabricated in the field, so that the precast crossbeams installed on the abdomen of the girders are free to have the integrity of the concrete section that is cast in place. By applying the method of mutually binding the studs of the end of the connecting rebar extending from the side of the cast gabor and the loop strip reinforcement and the fixing reinforcing bar, the construction of the reinforcing bar is improved by improving the joint strength.

In addition, by installing a lower continuous device provided with a high-strength steel in the lower part of the girder as a method for introducing prestress to the slab which is a prerequisite of the continuous structure, the high-strength steel is press-fitted into a buckling shape and then settled under the girder. Pressing stress is introduced to the upper part of the stress and the upper part to offset the stress caused by external force, and the upper continuous device is applied to the upper part of the girder by applying a high-strength steel. It is introduced so that a substantial continuous bridge is installed by a method of canceling stress caused by external force.

In the existing bridges, girder is designed with an excessive cross section, and there have been many difficulties in securing sufficient construction limits or clearances at the lower part of the bridge.

Accordingly, the present invention is to ensure a sufficient construction limit and spare height of the lower space of the girder which is suffering a lot of difficulties in the existing bridge by making the girder according to the conditions to which the bridge is applied.

In addition, in the present invention, the amount of prestress designed by the existing primary steel and the secondary continuous steel is not sufficiently introduced into the girder. In the present invention, the secondary linear steel which introduces the prestress into the girder by installing the steel in a straight line in the lower center of the girder. Is installed.

In addition, in the present invention, the prestress is introduced to the slab so that a substantial continuous bridge is installed. In the present invention, a continuous device is selectively installed at an upper portion or a lower portion of the connecting portion connecting the girder and the upper and lower portions, and a tensile stress is introduced at the continuous lower portion. At the same time, the compressive stress is introduced into the upper portion, and at the same time, prestress is also introduced into the slab section installed on the upper portion, and the support supporting the girder at the pier is also satisfied with one.

In addition, to improve the integrity of the precast section and the concrete section installed at the site while being installed in the field using the prefabricated reinforcing cage and formwork to improve the workability of the cross beam connecting the girders and the girders on the side. The method is used to bind the studs installed at the ends of connecting bars and loop band reinforcing bars and fixing bars.

According to the present invention, the girder is manufactured according to the conditions to which the bridge is applied, thereby sufficiently securing the construction limits and the spare space of the lower space of the girder, which suffers many difficulties in the existing bridge.

In addition, by installing the steel in a straight line at the center lower part of the girder, the secondary straight steel which introduces the prestress into the girder is not able to sufficiently introduce the prestress amount designed by the existing primary and secondary continuous steel wires. will be.

In addition, whether the girder and the girder is connected to the upper and lower portions of the connecting unit selectively or by installing the upper and lower continuous devices at the same time, the tensile stress is introduced in the continuous lower portion, the compression stress is also introduced at the same time Prestress is also introduced to the slab section installed on the upper part, and a substantial continuous bridge is installed to satisfy one support supporting the girder at the bridge.

In addition, in order to improve the workability of the cross beams connecting the girders and girders from the side, pre-installed reinforcing cages and formwork are installed in the field, and at the same time, studs, loop strip reinforcing bars, and fixing bars installed at the ends of connecting bars are mutually connected. The binding method is applied to improve the solidity while concise.

When applied to the bridge by using the girder of the present invention, it is possible to secure the construction limit and the spare height which are the lower space of the bridge, and thus the applicability of the bridge is diversified, and the vertical plan in the road, railway, and complex is lowered. It is an eco-friendly invention that can reduce the amount of carbon emission by reducing the amount of earthwork and reducing the economics, air shortening and equipment use.

In addition, the cross section of the over-designed girders can not be sufficiently introduced by the existing primary and secondary sequential steel wires, thereby reducing the steel materials used.

In addition, whether the girder and the girder are connected to each other by selecting a continuous device on the upper and lower portions or installing the upper and lower continuous devices at the same time, the tensile stress is introduced in the lower portion, the compressive stress is introduced in the upper portion at the same time In addition, a separate prestress is introduced to the slab section installed on the floor, so that a substantial continuous bridge is installed so that only one support supporting the girder at the bridge is sufficient. Therefore, a substantial continuous bridge can be installed. It is to be achieved.

In addition, the introduction of prestress to the upper slab removes not only the reinforcement but also the cracks mainly generated at the point, which contributes to the improvement of durability and significantly reduces the maintenance cost.

In addition, the precast gabor is used to improve the integrity of the concrete section and precast robo section that are installed in the field while using reinforcing cage and formwork pre-fabricated during the construction of horizontal beams connecting the girders to the girders from the side. The construction of the site is greatly improved by applying a method of binding the studs, the loop strip reinforcement and the fixing reinforcing rods installed at the end of the connecting reinforcement extending from the cross section, to improve the binding force and to make a simple joint.

1 is a view showing the installation of a PSC composite continuous bridge using a conventional PSC composite girder.
2 is a PSC composite having a continuous device installed on the upper and lower portions of the girder and the girder by applying an end-type high-reduced PSC composite girder to the river, which has a larger height at the bottom of the center than the height at the bottom of the girder, according to the present invention. Drawing showing the installation of girder continuous bridge.
Figure 3 is a view showing the central lower-type high-reduction PSC composite girder of the present invention to increase the height of the bottom of the center compared to the height of the bottom of the girder to install in the river.
Figure 4 (a) (b) (c) is a cross-sectional view of the point section cross-section, the central section, the secondary straight steel fixing section of Figure 3, respectively.
5 is a view showing a continuous device in which the end-type high-reduction PSC composite girder of the present invention is continuously installed on a pier, and interconnected girders are installed successively.
Figure 6 is a plan view showing a continuous device in which the end-type high-reduced PSC composite girder of the present invention in succession to the piers, interconnecting the girder installed successively.
Figure 7 (a) (b) is a view showing the cross section, the central section of the point portion of the girders provided with a continuous device interconnecting the end-type high-reduction PSC composite girder of the present invention.
Figure 8 is applied to the upper and lower girder by connecting the girder and the girder by applying a central lower-type high-reduced PSC composite girder with a lower height of the lower center than the lower height of the girder end of the present invention to the road or railway Drawing showing the installation of PSC composite girder continuous bridge.
9 is a view showing a central lower-type high-reduction PSC composite girder of the present invention having a smaller height in the lower center than the lower height in the lower end of the girder for installation on a road or a railway;
Figure 10 (a) (b) (c) is a cross-sectional view showing the cross section of the point portion, the central section, the secondary straight steel fixing unit of Figure 9, respectively.
11 is a view showing a continuous device in which the lower center high-reduced PSC composite girder of the present invention is continuously installed on a piers, and interconnected girders are installed successively.
12 is a plan view showing in detail a continuous device in which the central lower-type high-reduced PSC composite girder of the present invention is installed in succession on a piers, and interconnected successively installed girders.
Figure 13 (a) is a view showing an upper continuous device interconnecting the end-type high-compression PSC composite girder of Figure 2 and the central lower-type high-compression PSC composite girder of Figure 8 of the present invention.
Figure 13 (b) is a view showing a plane in which the upper continuous device interconnecting the end type high-density PSC composite girder of FIG.
FIG. 14 is a view showing another embodiment of the upper continuous device interconnecting the FIG. 2 end type high compression PSC composite girder of the present invention and the center lower type high compression PSC composite girder of FIG.
15 is a cross-sectional view showing the upper continuous device of FIG.
FIG. 16 is a view showing a plane in which the upper continuous device of FIG. 14 is installed;
FIG. 17 (a) is a twist provided in a plurality of bent portions at regular intervals as sheaths installed on the outside of steel materials in the lower continuous apparatus interconnecting the end-type high-speed PSC composite girder and the center-lower high-scale PSC composite girder of the present invention. Drawing showing sheath.
Figure 17 (b) is a sheath installed on the outside of the steel in the lower continuous device interconnecting the end-type high-compression PSC composite girder and the central lower-type high-compression PSC composite girder of the present invention, spaced at regular intervals in the continuous steel installed in the sheath. Figure showing a twisted sheath that attaches the ring so that the ring is in contact with the outer surface and the inner surface of the sheath.
18 is a cross-sectional view showing a site-mounted crossbeam interconnecting the end-type high-compression PSC composite girder and the central lower-type high-compression PSC girder of the present invention from the side.
19 is a view showing a method for installing the field-mounted crossbeam of the present invention between the end-type high-reduction PSC composite girder and the central lower-type high-reduction PSC composite girder.
20 is a cross-stitch reinforcing rod, end reinforcement PSC composite girder of the field installation crossbeam of the present invention and the precast girder installed in the abdomen of the central sub-type high-compression PSC girder and connecting reinforcing bars, anchored reinforcing bars and longitudinal rebars Drawing showing the method in detail.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and the working relationship of the present invention.

As shown in FIG. 2, the end-type high-reduction PSC composite girder 50 used for the bridge applied to the river is smaller than the mold height of the lower end of the girder end 54 as shown in FIG. 31) and the primary steel wire 51 is installed in a parabolic shape, while fixing fixtures 31 are installed on the end surfaces of the block-out at intervals on both sides of the central lower portion projecting outwardly from both lower end portions. An end-type high-reduction PSC composite girder 50 in which a sheath 63, a secondary linear steel 55, and a maintenance steel wire 64 are respectively fixed to 31 is manufactured, and the primary steel wire 51 and After the respective tension forces are introduced to the ends of the secondary linear steel material 55, they are fixed to the fixing tool 31 to produce a girder in which prestress is introduced into the end-type high-reduction PSC composite girder 50.

The block-out portion is finished by pouring the futa concrete (65).

The reason why the height of the lower part of the center is larger than that of the lower part of the end of the end-type high-reduction PSC composite girder 50 applied to the river as described above is that the calculation of the communication surface of the river is performed by the support 13 installed on the shift 11. Since the height from the lower surface to the surface of the river is calculated by the height 20, the lower height of the end of the end-type high-reduction PSC composite girder is smaller than the height of the lower part of the center, so that the height of the smaller girder end is reduced (20). ) Increases, eventually increasing the cross section of the entire river bridge.

In addition, the end-type high-compression PSC composite girder 50 manufactured as described above is installed in the shift 11 and the pier 12, respectively, and the end-type high-compression PSC composite girder 50 is successively installed in the bridge 12. Afterwards, the upper continuous device 70 is installed on the upper part of the continuous high end type reduced PSC composite girder 50, or the lower continuous device 80 is installed on the lower part, or the upper, lower part, The lower continuous device (70, 80) is installed, and on the side of the end-type high-compression PSC composite girder 50 and the end-type high-compression PSC composite girder (50) is installed on-site casting robot (100), The end-type high-speed PSC composite girder 50 is provided by installing one support 13 under the connection part of the end-type high-speed PSC composite girder 50 in which the upper and lower continuous devices 70 and 80 are installed selectively or in parallel. ) Is installed in the piers (12) to support.

Another method of application is to install the central lower compact PSC composite girder 90 in the river, and install the central lower compact PSC composite girder 90 in the alternating 11 and the piers 12, respectively. 12) after the central lower high compression PSC composite girder (90) is installed in succession, the upper continuous device (70) is installed in the upper portion of the central lower high compression PSC composite girder (90) installed in series to introduce a tension force Prestress is introduced to the slab installed while the tensile stress is introduced at the lower part and the compressive stress is introduced at the upper part thereof.

Alternatively, the lower continuous device 80 is installed in the lower portion of the centrally-type high-compression PSC composite girder 90 which is installed in succession to introduce a tension force, so that a tensile stress is provided at the lower portion of the connecting portion, and a compressive stress is introduced at the upper portion of the slab. Prestress is introduced,

Alternatively, the upper and lower continuous apparatuses 70 and 80 are installed on the upper and lower portions of the centrally-type high-density compact PSC composite girder 90 which are installed in succession to introduce tension to the lower portion of the connecting portion, and compressive stress to the upper portion. Prestress is introduced to the slab installed while being installed, and the site lowering robo 100, which is installed in the field, is installed on the sides of the central lower type high compression PSC composite girder 90 and the central lower type high compression PSC composite girder 90, , The lower portion of the central high-density compact PSC composite girder 90, which selectively or simultaneously installed the lower continuous device (70, 80) by installing one support (13) in the lower portion of the central high-density compact PSC composite girder (90) It is provided in the pier 12 to support it.

As shown in FIG. 5, the lower continuous device 80 connected to each other at the bottom of the continuously installed end type high reduction PSC composite girder 50 is provided with lower flanges at both ends of the end type high reduction PSC composite girder 50 installed in succession. (62) After block-out for the installation of the press-fit block 56 in which the fixing unit 31 is installed at the portion where the upper part and the abdomen 61 meet, the fixing unit 31 is provided inside the pressing block 56 installed. After the fixing unit 31 face each other, the twist sheath 67 and the high-strength steel 58 is inserted between the fixing unit 31 installed on both sides and fixed to the fixing unit, the high-strength steel fixed to the fixing unit After passing through 58 the indentation block 56, an indentation cylinder 66 as shown in FIG. 6 is installed at the end of the high strength steel.

The stroke is applied to the press-fit cylinders 66 provided on both sides to push the high-strength steels 58 therebetween so that the high-strength steels 58 are twisted with the compressive force introduced. In FIG. 17, after the buckling deformation is performed so that the compressive force is introduced into the high-strength steel 58, the high-strength steel 58 is fixedly fixed to the fixing unit 31 facing each other inside the indentation block 56.

As described above, when the high-strength steel 58 is fixed to the anchorage and the press-in cylinder is removed to remove the compressive stress of the press-in cylinder, the steel 58 acts as a pre-stress tensile force to the end-type high-compression PSC composite girder 50. While the tensile stress is applied to the lower portion, at the same time the top of the end-type high-compression PSC composite girder 50 is prestressed to the cross section of the slab 53 which is installed at the same time as the compressive stress is introduced to install a substantially continuous bridge.

Block out the front of the indentation block to install the indentation block 56, and fix the high-strength steel 58 over each of the fixing holes 31 installed inside the indentation blocks on both sides, and the compression force is introduced. After finishing, the block-out portion is finished with futa concrete (65).

Another lower serialization method is the lower continuous device 80 interconnected at the bottom of the successive lower centralized high compression PSC composite girder 90, as shown in FIG. After blocking out the front for the installation of the fixing block 59 in the cross section where the central lower end section of the 90 is reduced, the fixing unit 31 is installed on the outside of the installed fixing block 59 in a pair of right and left. 12, a pair of left and right anchoring fixtures are also installed on the girders on the other side, and the twist sheath 67 and the high-strength steel ( 58) are respectively settled, but in the area where the central lower-type high-compression PSC composite girder 90 and the central lower-type high-compression PSC composite girder (90) meet, install the high-strength steel (58) to face at regular intervals, and face the above Installed high strength An acupressure plate 83 is disposed to face the ends of the ash 58 and the twist sheath 67, a hydraulic cylinder 81 is provided between the acupressure plates 83, and the acupressure plate of the hydraulic cylinder 81 is bolted up and down. Tighten with nut (85).

A stroke is applied to the hydraulic cylinders 81 installed between the pressure plate to push the high strength steel 58 to the left and right to introduce a compressive force to the high strength steel 58, so that the high strength steel 58 is twisted within the twist sheath 67. After the buckling deformation as described in 17 (a) (b) to allow the compressive force to be introduced into the high strength steel 58, the stroke of the hydraulic cylinder is stopped, and the bolt nuts fastened to the upper and lower parts of the pressure plate are completely fixed and fixed. The high strength steel 58 is fixed and fixed to the fixing tool 31 provided outside the block 59.

When the high-strength steel 58 is fixed to the anchorage as described above, and the hydraulic cylinder is removed, the compressive stress introduced into the steel 58 is acted as a prestressed tensile stress, so that the lower portion of the central lower-type high-compression PSC composite girder 90 At the same time as the tension is applied, the compressive force is introduced to the upper part of the girder, and in the future, the prestress is introduced to the installed slab.

As described above, two continuous apparatuses mentioned above are used as a continuous device in the lower portion of the end-type high-compression PSC composite girder 50 or the central lower-type high-compression PSC composite girder 90 used for the bridge applied to the river. Apply.

In addition, the high-strength diaphragm 73 is provided in a portion where the end-type high-compression PSC composite girder 50 and the end-type high-compression PSC composite girder 50 face each other.

On the other hand, the upper continuous device 70 is installed on the upper end of the high-end reduction PSC composite girder 50 and the end-type high-compression PSC composite girder 50 is provided in succession.

In the future, the upper continuous apparatus 70 is applied to the same apparatus when the girder 90 of the bridges installed in the roads, complexes and railways described in FIG.

The upper continuous device 70 is as shown in Figure 13 (a) (b), the detailed device is spaced on the upper flange 60 of the end-type high-reduction PSC composite girder 50 installed facing each other. After the fixing unit 31 is installed on the outer surface of the fixing block 59 blocked out, the sheath 63 and the high-strength steel 58 are installed between the fixing unit 31 and fixed to the fixing unit 31, respectively. After the introduction of the tension force at the end of the high-strength steel 58, the high-strength steel is fixed and fixed to the fixing unit 31, while placing the slab on the top, and at the same time filling the block-out part to install the slab as a whole Allow prestress to be introduced into the slab.

In addition to the upper continuous device 70 of FIG. 13 is another embodiment as shown in Figures 14, 15 and 16, the detailed apparatus is the upper flange of the end-type high-compression PSC composite girder 50 installed facing each other ( The cross section is partially enlarged on both sides of the 60 and installed as shown in FIG. 16, and the fixing unit 31 is installed on the outside of the fixing block 59 provided on the enlarged cross section installed on both sides, and the fixing unit 31 is installed on both sides. After fixing the sheath 63 and the high-strength steel 58 in the fixing unit 31, respectively, after the tension force is introduced at the end of the high-strength steel 58, the high-strength steel to the fixing unit 31 It is fixedly fixed and prestress is introduced into the installed slab by pouring the slab on the upper part.

When the tension force is introduced into the high-strength steel 58 as described above, the compressive force is introduced into the slab 53 provided on the upper end of the continuous high-scaling PSC composite girder 50 installed in succession, connecting only the conventional girder and the girder and prestressing Since the introduction of the pre-stress is not introduced into the slab to improve the disadvantage of disposing a separate continuous reinforcing bar to compensate for this, the prestress is introduced to the slab 53 to be installed is the end-type high-compression PSC composite girder 50 is connected By the method of installing the upper and lower continuous device (70, 80) at the same time or selectively install the portion of the end type high-scaling PSC composite girder (50) is made of the number of the supporting base to be installed in the pier (12) It can be supported by a one-point stand to support a continuous girder by installing one.

A detailed description of the twist sheath 67 applied to FIG. 5 is shown in FIGS. 17A and 17B.

The twist sheath 67 of FIG. (A) is a tube in which a plurality of nodes are formed by forming bent portions 68 at regular intervals, and a high-strength steel 58 is installed in the tube, and as shown in FIG. When the high-strength steel 58 is compressed using a cylinder, the inside of the bent portion is narrowed at regular intervals of the twist sheath 67, while the inside of the normal cross section forms a wider space to receive a high-strength steel ( The high strength steel 58 is buckled into an S-shape as shown in the drawing while the compression is introduced into the high-strength steel while passing through the inside of the bent portion and the inner end surface of the bent portion.

Another twist sheath 67 is a hydraulic cylinder, as shown in Fig. 5, after inserting a high-strength steel 58 with a plurality of circular rings 78 inserted into the pipe at regular intervals, as shown in (b). When compressive force is applied at both ends of the high strength steel 58, the high strength steel inserted into the tube is bent in the space between the ring 78 and the ring 78, and the compressive force is introduced into the high strength steel while buckling and deforming in an S shape. It was made possible.

After the compression force is introduced into the two twist sheaths, grouting 69 is performed.

The end-type high-compression PSC composite girder 50 and the end-type high-compression PSC composite girder 50 are installed on the site by the site casting robot 100 is connected to each other.

The cast-in-place robot 100 forms a cut portion 79 which cuts the width of both upper flanges 60 of the end-type high-compression PSC composite girder 50 continuously installed as shown in FIG. Match the width of the flange and the width of the lower flange 62, and cut the cut portion 79 and the horizontal portion 110 of the L-shaped support plate 109 on both ends of the formed upper flange 60 to temporarily fix the bolt nut While fixing to the 108, the lower portion of the vertical portion 111 is in contact with the side of the girder end, while installing a plurality of loop strip reinforcing bars 105 in a loop shape in contact with the vertical portion 111 In the corner of the loop strip reinforcing 105, as shown in FIG. 20, the loop strip reinforcing 105 is installed in close contact with the stud 104 installed at the end of the connecting reinforcement 103 protruding inwardly from the precast robo 102. The fixing reinforcement 106 is in close contact with the top and bottom of the connecting reinforcement 103 between the stud 104 and the stud 104. In other parts, the stud 104 of the connecting reinforcement 103 and the longitudinal reinforcing bar 107 intersect with the left and right sides of the loop band reinforcing bar 105, but is installed in close contact with each other. Fixing reinforcement 106 is installed close to the top and bottom of the loop strip reinforcing bar 105 between the studs 104 installed on the left and right, the loop strip reinforcement 105 and the stud 104, the fixing reinforcement 106 and longitudinal transverse reinforcement 107 18) is to be adhered tightly as shown in Fig. 18, so that, after installing concrete, the cross beam is installed on the site.

At this time, the width of the upper flange is cut to a certain portion because the width of the upper flange and the width of the lower flange is different so that the width of the upper flange to match the width of the lower flange.

Figure 4 (a) shows the cross section of the point portion of the end-type high-reduction PSC composite girder, it can be seen that the primary steel wire is installed as a parabola, Figure 4 (b) shows a cross section in the center, the lower flange 2 It can be confirmed that the primary linear steel 56, the primary steel wire 51 and the maintenance steel wire 64 are installed by the sheath.

4 (c) is a cross-sectional view that the primary steel wire 51 is installed in the abdomen 61 and the maintenance steel wire 64 and the secondary linear steel 56 are installed in the lower flange 62 as a straight steel, respectively. You can check it.

6 shows a state in which the lower continuous device 80 is installed in a plane, and it can be seen that the indentation cylinder 66 is installed in the high-strength steel 58 in front of the indentation block 56, and the indentation block 56 By installing the fixing unit 31 on the inner side so that the fixing unit is facing each other so that the compressive force introduced into the high-strength steel 58 is transmitted to the end type high-compression PSC composite girder 50.

After block-out in front of the inner shaft of the press-fit block and installing the anchorage, the compressive force is introduced into the high-strength steel, and then the futa concrete is poured into the blocked out portion.

Figure 7 (a) shows the cross section of the point of the girder 50, it can be confirmed that the primary steel wire 51 is installed as a parabola, the lower portion is installed a steel wire for maintenance 64 as a straight steel, The lower continuous device 80 in which the high strength steel 58 is installed in the twist sheath 67 can be confirmed.

Figure 7 (b) shows a cross section of the end-type high-reduction PSC composite girder 50, the primary steel wire 51, the secondary linear steel 55 and the maintenance steel wire 64 in the lower flange 62 It can be confirmed that the sheath 63 is installed, the twist sheath 67 and the high-strength steel 58 in the indentation block 56 at the portion where the lower flange 62 and the abdomen 61 meets the fixing hole 31 It can be seen that it is fixed by and grouted inside.

The twist sheath 67 is also grouted.

On the other hand, as shown in Fig. 8, the central lower-type high-reduction PSC composite girder 90 used for the bridge applied to the road, complex or railway as shown in Fig. 9, the lower profile height of the girder end 54 is larger than the central height While installing the fixing unit 31 at both ends and installing the primary steel wire 51 in a parabolic shape, block out both sides of the center portion which has entered the inner side of the lower end of the girder, and install the fixing unit 31 at the end face. 31) to produce a central lower cross-sectional reduced PSC girder 90, the sheath 63, the secondary linear steel 55 and the maintenance steel wire 64 is fixed, respectively, the primary steel wire 51 and secondary After each of the tension forces is introduced into the end portions of the straight steel 55, the girders are fixed to the fixing tool 31 to introduce a prestress into the girder.

The block-out part is to be poured to finish the futa concrete (65).

The reason why the lower height of the lower part of the center is smaller than the height of the lower part of the end of the central lower type high reduction PSC composite girder 90 applied to the road, the complex or the rail as described above is the margin of latitude which is the building limit 23 of the road or railway. Since the height of the lower part of the girder and the roadbed of the road, complex or railway is calculated by the margin of construction (20), the height of the lower part of the center is smaller than the height of the lower part of the girder, so (20) is increased so that the building limit (23) of the whole road, complex or railway bridge is increased.

In addition, the central lower-type high-compression PSC composite girder 90 manufactured as described above is installed on the shift 11 and the pier 12, respectively, and the central lower-type high-compression PSC composite girder 90 is successively installed on the pier 12. After that, the upper continuous device 70 is installed in the upper portion of the central lower-type high-compression PSC composite girder successively installed to introduce a tension force, and a tensile stress is installed at the lower portion of the connecting portion, and a compressive stress is introduced at the upper portion thereof. Prestress is introduced into the slab,

Alternatively, the lower continuous device 80 is installed in the lower portion of the centrally-type high-compression PSC composite girder 90 which is installed in succession to introduce a tension force, so that a tensile stress is provided at the lower portion of the connecting portion, and a compressive stress is introduced at the upper portion of the slab. Allow prestress to be introduced,

Alternatively, the upper and lower continuous apparatuses 70 and 80 are installed on the upper and lower portions of the centrally-type high-density compact PSC composite girder 90 which are installed in succession to introduce tension to the lower portion of the connecting portion, and compressive stress to the upper portion. The prestress is introduced to the slab installed while being installed, and the site lowering robot 100 installed on the site is installed on the side of the central lower type high compression PSC composite girder 90 and the central lower type high compression PSC composite girder 90, The central lower type high compression PSC composite girder 90 is provided by installing one support 13 in the lower part of the connection part of the central lower type high compression PSC composite girder 90 which selectively or simultaneously installs the upper and lower continuous devices 70 and 80. It is installed on the pier 12 to support the.

As shown in FIG. 11, the lower continuous device 80 interconnected with the lower portion of the central lower type high compression PSC composite girder continuously installed as shown in FIG. 11, the lower portion of the central lower type high compression PSC composite girder 90 installed at both sides. After block-out the front for the installation of the fixing block 59 in the cross section is reduced in cross-section, the fixing unit 31 is installed on the outside of the installed fixing block 59, and installed in a pair from side to side, Similarly, a pair of left and right anchorages may be installed on the other girders, and the twist sheaths 67 and the high strength steels 58 may be fixed to the anchorages 31 installed on the central lower-type high-compression PSC composite girders 90 on both sides. At the portion where the central lower type high compression PSC composite girder 90 and the central lower type high compression PSC composite girder 90 meet, the high strength steels 58 are installed to face each other at regular intervals, and the high strength steels 58 facing each other are installed. And twist sheath (67) Between the installation to face the jiappan 83 to the end portion, and the jiappan 83 has the oil pressure cylinder 81, and tightening the upper and lower jiappan of the hydraulic cylinder 81 by a bolt nut (85).

A stroke is applied to the hydraulic cylinder 81 provided between the pressure plate to push the high strength steel 58 to the left and right, so that a compressive force is introduced into the high strength steel 58, so that the high strength steel 58 is formed within the twist sheath 67. After the buckling deformation as described in 17 (a) (b) allows the compressive force to be introduced into the high-strength steel 58, the stroke of the hydraulic cylinder is stopped, and the bolt nuts fastened to the upper and lower parts of the pressure plate are completely fixed and fixed. The high strength steel 58 is fixed and fixed to the fixing tool 31 provided outside the block 59.

When the high-strength steel 58 is fixed to the anchorage as described above, and the hydraulic cylinder is removed, the compressive stress introduced into the steel 58 acts as a prestress tensile stress, so that the lower portion of the central lower-type high-compression PSC composite girder 90 As the tensile force is applied, a compressive force is introduced at the same time as the upper part of the girder, and in the future, prestress is introduced to the installed slab.

In this way, when compressive force and tensile force are introduced to the upper and lower portions of the girder connecting the girder and the girder, and prestress is introduced to the slab, the tensile force generated at the center point of the continuous bridge can be canceled, and at the same time, the girder is substantially continuous. There is also an advantage that can be achieved.

In order to install the fixing block 59, the front end is blocked out, the high-strength steel 58 is fixed to the fixing unit 31, and after the introduction of the compressive force is completed, the blocked out portion of the futa concrete 65 To the end.

As another lower continuous device, when the end-type high-speed PSC composite girder 50 is applied to a road, a complex, or a railroad, the end-type high-speed PSC composite girder 50 is continuously connected to the bottom of the girder and the girder. As shown in FIG. 5, the lower continuous device 80 includes a fixing unit 31 at a portion where the upper portions of the lower flange 62 and the abdomen 61 of both ends of the end-type high-compression PSC composite girder 50 are installed in series. After block-out for the installation of the press-fit block 56 to be installed, the fixing unit 31 is installed on the inner side of the installed pressing block 56 so that the fixing unit 31 faces the fixing unit 31 installed on both sides. After the twist sheath 67 and the high-strength steel 58 are inserted and fixed to the fixing unit, the high-strength steel 58 fixed to the fixing unit penetrates through the press-in block 56, and then the At the end, a press-fit cylinder 66 as shown in FIG. 6 is installed.

The stroke is applied to the press-fit cylinders 66 provided on both sides to push the high-strength steels 58 therebetween so that the high-strength steels 58 are twisted with the compressive force introduced. In FIG. 17, after the buckling deformation is performed so that the compressive force is introduced into the high-strength steel 58, the high-strength steel 58 is fixedly fixed to the fixing unit 31 facing each other inside the indentation block 56.

As described above, when the high-strength steel 58 is fixed to the anchorage and the press-in cylinder is removed to remove the compressive stress of the press-in cylinder, the steel 58 acts as a pre-stress tensile force to the end-type high-compression PSC composite girder 50. While the tensile stress is applied to the lower portion, at the same time the top of the end-type high-compression PSC composite girder 50 is prestressed to the cross section of the slab 53 which is installed at the same time as the compressive stress is introduced to install a substantially continuous bridge.

Block out the front of the indentation block to install the indentation block 56, and fix the high-strength steel 58 over each of the fixing holes 31 installed inside the indentation blocks on both sides, and the compression force is introduced. After finishing, the block-out portion is finished with futa concrete (65).

As described above, the above-mentioned two devices mentioned above are continuous in the lower portion of the central lower-type high-compression PSC composite girder 90 or the end-type high-compression PSC composite girder 50 used for bridges applied to roads, complexes or railways. The continuous device of applies.

In addition, a high-strength diaphragm 73 is provided at a portion where the central lower type high compression PSC composite girder 90 and the central lower type high compression PSC composite girder 90 face each other.

Meanwhile, the upper continuous device 70 is installed on the upper part of the girder in which the central lower type high compression PSC composite girder 90 and the central lower type high compression PSC composite girder 90 are successively installed.

The upper continuous device 70 is the same device is applied even when the girder 50 of the river bridge described in FIG.

The upper continuous device 70 is as shown in Fig. 13 (a) (b), the detailed device is settled block-out at intervals to the upper flange 60 of the girder (50, 90) facing each other After the fixing unit 31 is provided on the outer surface of the block 59, the sheath 63 and the high strength steel 58 are installed between the fixing unit 31 and fixed to the fixing unit 31, respectively. After introducing the tension force at the end of 58, the high-strength steel is fixed and fixed to the fixing unit 31, and the slab is placed on the upper part, and at the same time the block-out part is also filled to install the slab as a whole to prestress the slab installed. To be introduced.

Other embodiments of the upper continuous device 70 of FIG. 13 are shown in FIGS. 14, 15, and 16, and the detailed device is provided on both sides of the upper flange 60 of the girder 50, 90 facing each other. 16 is partially enlarged in cross section and installed as shown in FIG. 16, and a fixing unit 31 is installed outside the fixing block 59 provided at the enlarged end surfaces provided at both sides, and the fixing unit 31 is installed at both sides. After the sheath 63 and the high-strength steel 58 are installed in between and fixed to the fixing unit 31, the high-strength steel is fixed to the fixing unit 31 after the tension force is introduced from the end of the steel bar 58. Then, prestress is introduced into the installed slab by pouring the slab on the upper part.

When the tension force is introduced into the high strength steel 58 as described above, the compressive force is introduced into the slab 53 provided on the upper part of the girder 50, 90 successively installed, so that only the girder and the girder are connected and prestress is introduced. There is no prestress is introduced to improve the disadvantage of arranging a separate continuous reinforcing bar to compensate for this, and the prestress is also introduced to the slab 53 is installed in the upper and lower continuous device (Girder 50, 90) is connected to the part ( Substantially continuous girder (50, 90) is made by the method of installing 70, 80 at the same time or selectively installed to support the continuous girder by installing the number of the supporting base installed in the piers 12 as one It can be supported by point bearings.

A detailed description of the twist sheath 67 applied to FIG. 5 is shown in FIGS. 17A and 17B.

The twist sheath 67 of FIG. 17 (a) is a tube in which a plurality of nodes are formed by forming bent portions 68 at regular intervals, and a high-strength steel 58 is installed in the tube, as shown in FIG. When the high-strength steel 58 is compressed using a hydraulic cylinder, the inside of the bent portion is narrowed at regular intervals of the twist sheath 67, while the inside of the normal cross section forms a wider space and receives a high-strength steel (58) is bent so that the high-strength steel (58) is buckled into the S-shape as shown in the drawing while passing between the inside of the unbent portion and the inner end of the bent portion to simultaneously introduce a compressive force to the high-strength steel .

Another twist sheath 67 is shown in Figure 17 (b), after inserting a high-strength steel 58 with a plurality of circular rings 78 at regular intervals into a circular sheath tube having a diameter, Figure 5 As described above, when a compressive force is applied at both ends of the high strength steel 58 by using a hydraulic cylinder, the high strength steel inserted into the pipe is bent in the space between the ring 78 and the ring 78 and buckled into an S shape. As it is intended to introduce a compressive force to the high-strength steel.

After the compression force is introduced into the two twist sheaths, grouting 69 is performed.

The girder (50, 90) and the girder (50, 90) will be interconnected by installing a site-pouring robot 100 that is installed in the field from the side.

The cast-in-place robot 100 forms a cut portion 79 that cuts the width of both upper flanges 60 of the girders 50 and 90 successively installed as shown in FIG. 18, and the width of the upper flange cut and remaining. Fit the width of the lower flange 62, and cut the cut portion 79 and the horizontal portion 110 of the L-shaped support plate 109 to the both ends of the formed upper flange 60 to the temporary fixing bolt nut 108 The roof strip is fixedly installed and the lower portion of the vertical portion 111 is in contact with the side of the girder end, and a plurality of loop strip reinforcing bars 105 having a reinforcing bar shape in contact with the vertical portion 111 are provided. At the corners of the reinforcing bar 105, the loop strip reinforcing bar 105 and the stud 104 are installed in close contact with the stud 104 installed at the end of the connecting bar 103 protruding inwardly from the precast robo 102 as shown in FIG. 20. The fixing reinforcement 106 is installed in close contact with the connecting reinforcement 103 between In other portions, the studs 104 of the connecting reinforcement 103 and the longitudinal reinforcing bars 107 intersect with each other on the left and right sides of the loop strip reinforcing bar 105, but are installed on the left and right sides of the loop band reinforcing bar 105. Fixing reinforcement 106 is installed between the studs 104 on the upper and lower sides of the loop band reinforcing bar 105, so that the loop band reinforcing bar 105, the stud 104, the fixing bar 106 and the longitudinal reinforcing bar 107 are shown. As shown in 18, after being tightly bonded to prevent deviation, the concrete beam was installed at the site by pouring concrete.

At this time, the width of the upper flange is cut to a certain portion because the width of the upper flange and the width of the lower flange is different so that the width of the upper flange to match the width of the lower flange.

Figure 10 (a) shows the cross section of the point of the girder, it can be seen that the primary steel wire is installed as a parabola, (b) shows the cross section of the central portion, the secondary linear steel 56 to the lower flange It can be confirmed that the straight wire is installed in the sheath, the primary steel wire 51 is installed in the sheath, and the steel wire for maintenance 64 is installed by the sheath in a straight steel material.

13 is a plan view showing a state in which the upper continuous device 70 is installed, block out to install a fixing block in the upper flange 60, the fixing unit is installed in the installed fixing block, sheath and high-strength steel ( 58) is installed.

The block-out part is provided with a fixing fixture, and after introducing a compressive force to the high-strength steel, and finishes by pouring the futa concrete.

FIG. 15 shows a cross-sectional view of FIG. 14, in which a fixing block is installed by expanding a cross section outside the upper flange and a fixing unit is installed in the fixing block, and then the high strength steel and a sheath are installed to fix the fixing unit.

FIG. 16 illustrates a plan view of FIG. 14, in which separate cross sections are enlarged on both sides of the upper flange, and a high strength steel and a sheath are installed on the enlarged cross section to fix the cross section.

10: PSC composite continuous bridge 11: shift
12: Pier 13: Base
14: connecting slab 15: expansion joint
16: slab 17: bulkhead
18: Slab continuous rebar 19: Supporting space
20: laid back 21: river
22: Road, Rail 23: Building Limits
30: PSC composite girder 31: anchorage
32: 2nd sequential liner 33: 1st liner
40: PSC composite girder continuous bridge 50: end type high reduction PSC composite girder
51: primary liner 53: slab
54: girder end 55: secondary straight steel
56: press-fit block 57: central enlarged cross-section
58: high strength steel 59: fixing block
60: upper flange 61: abdomen
62: lower flange 63: sheath
64: Maintenance steel wire 65: Blockout and futa concrete
66: indentation cylinder 67: twist sheath
68: bend 69: grouting
70: upper continuous device 71: high strength bottom plate concrete
72: shear connector 73: diaphragm
78: ring 79: cutout
80: lower continuous device 81: hydraulic cylinder
83: acupressure plate 84: enlarged upper flange
85: Bolt nut 90: Central lower type high reduction PSC composite girder 100: Cast-in place robot 101: Reinforcing cage
102: precast crossbeam 103: connecting rebar
104: stud 105: loop belt
106: anchored bar 107: longitudinal rebar
108: Temporary fixing bolt nut 109: “A” shaped support plate
110: horizontal portion 111: vertical portion

Claims (26)

In the continuous structure of the river bridge,
It is provided in the alternating 11 and the pier 12, and the lower mold height of the girder end 54 is smaller than the mold height of the lower part of the center, and fixing means 31 are provided in both ends, and the primary steel wire 51 is parabolic. While installing, fixing fixtures 31 are provided on the end surfaces of the central lower portion protruding outward from the lower ends of both sides at intervals, and the sheath 63 and the secondary straight steel material 55 are disposed on the fixing openings 31. ) And the maintenance steel wire 64 are respectively settled, and the tension force is introduced into the primary steel wire 51 and the secondary straight steel material 55, respectively, and then fixed to the fixing unit 31 to introduce prestress into the girder. One end-type high-compression PSC composite girder 50 and the end-type high-compression PSC composite girder 50 are successively installed in the pier 12, and the upper portion of the end-type high-compression PSC composite girder 50 is upper part. The end-type high-reduction PSC composite girder 50, which is connected to each other by installing a continuous device 70, is installed in the piers 12. Continuous structure of the PSC girder a gong is prestressed by introducing a linear steel material in its cross-section having variations of center in the lower pick. In the continuous structure of the river bridge,
It is provided in the alternating 11 and the pier 12, and the lower mold height of the girder end 54 is smaller than the mold height of the lower part of the center, and fixing means 31 are provided in both ends, and the primary steel wire 51 is parabolic. While installing, fixing fixtures 31 are provided on the end surfaces of the central lower portion protruding outward from the lower ends of both sides at intervals, and the sheath 63 and the secondary straight steel material 55 are disposed on the fixing holes 31. ) And the maintenance steel wire 64 are respectively settled, and the tension force is introduced into the primary steel wire 51 and the secondary straight steel material 55, respectively, and then fixed to the fixing unit 31 to introduce prestress into the girder. One end-type high-compression PSC composite girder 50 and the end-type high-compression PSC composite girder 50 are successively installed in the pier 12, and the lower portion of the end-type high-compression PSC composite girder 50 is lower. Specially provided with the end-type high-reduction PSC composite girder 50 connected to the pier 12 by installing a continuous device 80. The introduction of the prestressing steel material in a straight line in cross section in which variations of the center bottom of choices in the structure of the continuous PSC girders. The method according to claim 1 or 2,
The PSC girder in which prestress is introduced with a straight steel in the cross section of the upper and lower continuous gears is installed at the same time as the upper continuous device or the lower continuous device at the same time. Continuous structure. The method according to claim 1 or 2,
The end-type high-reduction PSC composite girder 50 has a lower mold height of the girder end 54 than the mold height of the lower part of the center, and a fixing unit 31 is installed at both ends to install the primary steel wire 51 in a parabolic shape. On the other hand, the fixing unit 31 is provided on both end portions of the center lower portion protruding outwardly from the lower ends of both sides at intervals, and the sheath 63 and the secondary linear steel 55 are disposed on the fixing unit 31. And each fixing steel wire 64 for maintenance, and introducing tension force to the primary steel wire 51 and the secondary linear steel material 55, respectively, and then fixing to the fixing hole 31 to introduce prestress into the girder. Continuous structure of PSC girder with prestressed by straight steel in the cross section which changed the height of the lower part of the center characterized by In the continuous structure of roads, complexes or railway bridges,
It is provided in the alternating 11 and the pier 12, and the lower mold height of the girder end 54 is larger than the mold height of the lower part of the center, and fixing means 31 are provided in both ends, and the primary steel wire 51 is installed in a parabolic shape. In the meantime, the fixing unit 31 is provided in the end surface of which both sides of the center portion which has entered inward from the lower end of the girder are cut out, and the sheath 63, the secondary linear steel 55, and the maintenance steel wire 64 are disposed on the fixing unit 31. ) And each of the primary steel wire (51) and the secondary linear steel (55) to introduce a tension force, respectively, and then fixed in the fixing hole (31), the central lower-type high-reduction PSC composite girder in which prestress is introduced into the girder (90) and the pier (12) after the central lower-type high-compression PSC composite girder 90 in succession, the upper continuous device (70) is installed on the upper portion of the central lower-type high-compression PSC composite girder (90) It is characterized in that the central lower-type high-reduction PSC composite girder (90) connected to each other is installed on the pier (12). Continuous structure of the PSC girder introducing a prestress to the linear steel material in its cross-section in which variations in the central lower part of choices. In the continuous structure of roads, complexes or railway bridges,
It is installed on the alternating 11 and the pier 12, and the lower mold height of the girder end 54 is larger than the mold height of the lower part of the center, and the fixing unit 31 is installed at both ends to install the primary steel wire 51 in a parabolic shape. And a fixing unit 31 is installed at a cross section of both sides of the center portion which is inwardly entered from the lower end of the girder, and the sheath 63 and the secondary linear steel 55 and the maintenance steel wire 64 are disposed on the fixing unit 31. And each of the primary steel wire 51 and the secondary linear steel 55, respectively, the tension force is introduced, and then fixed in the fixing hole 31, the central lower-type high-reduction PSC composite girder in which prestress is introduced into the girder ( 90) and the pier (12) after the central lower-type high-compression PSC composite girder (90) in succession, the lower continuous device (80) is respectively installed in the lower portion of the central lower-type high-compression PSC composite girder (90) The central lower-type high-reduced PSC composite girder 90 connected to each other is installed on the piers 12. Continuous structure of the PSC girder introducing a prestress to the linear steel material in its cross-section in which variations of the center in the lower pick. The method according to claim 5 or 6,
PSC girder in which prestress is introduced with a straight steel in the cross section of the upper and lower continuous gears, which is characterized in that the upper continuous device or the lower continuous device is installed at the same time on the upper or lower portion of the central lower type high reduction PSC composite girder 90 at the same time. Continuous structure. The method according to claim 5 or 6,
The lower center height-reducing PSC composite girder 90 has a lower mold height of the girder end 54 than the mold height of the lower center, and installs the fixing holes 31 at both ends to install the primary steel wire 51 in a parabolic shape. And a fixing unit 31 is installed at a cross section of both sides of the center portion which is inwardly entered from the lower end of the girder, and the sheath 63 and the secondary linear steel 55 and the maintenance steel wire 64 are disposed on the fixing unit 31. To each of the first steel wire 51 and the second linear steel (55), respectively, and then fixed to the fixing unit 31, the pre-stress is introduced to the girder, characterized in that Continuous structure of PSC girder with prestressed linear steel in the cross section with high height. 7. The method according to claim 2 or 6,
The lower continuous device 80 is the installation of the press-fit block 56, the fixing unit 31 is installed in the portion where the upper portion of the lower flange 62 and the abdomen 61 of the both ends of the high-end endless reduction PSC composite girder 50 is installed. In order to block out the front to install a press-fit block, the fixing unit 31 is installed inside the pressing block 56 so that the fixing unit 31 faces the twist sheath 67 and the twist sheath 67. And after fixing the high-strength steel 58, the press-fit cylinder 66 is installed at the end of the high-strength steel 58 fixed to the anchorage penetrating the press-in block or the center of the central lower-type high-compression PSC composite girder 90 After block-outing the front to install the fixing block 59 in the cross section of the lower cross-section, the fixing unit 31 is installed on the outside of the fixing block 59, and installed in a pair from side to side, and thus left and right A pair of anchorages are also installed on the other girders, and the anchorages 31 The shear sheath (67) and the high-tension steel (58) is to be settled, but in the part where the central lower-type high-compression PSC composite girder (90) and the central lower-type high-compression PSC composite girder (90) meet at regular intervals. It is installed so as to face each other, the pressure plate 83 is installed at the ends of the high-strength steel 58 and the twist sheath 67, respectively, the pressure plate is installed facing each other, the hydraulic cylinder 81 is installed between the pressure plate 83. And a prestressing system in which prestress is introduced with a straight steel in a cross section in which the upper and lower pressure plates of the hydraulic cylinder (81) are fixed with bolt nuts (85). 6. The method according to claim 1 or 5,
The upper continuous device 70 faces the inner side of the fixing block 59 that is cut out at intervals from the upper flange 60 of the end-type high-compression PSC composite girder or the center lower-type high-compression PSC composite girder 50, 90. After the report anchorage 31 is installed, the sheath 63 and the high-strength steel 58 are installed between the anchorage 31 and fixed to the anchorage 31, and then the tension force is introduced into the high-strength steel 58. And a continuous structure of a PSC girder in which prestress is introduced as a straight steel in a cross section of a lower portion of the center, characterized in that the high-strength steel is fixed and fixed to the fixing unit 31. 6. The method according to claim 1 or 5,
The upper continuous device 70 is provided with an enlarged end surface on both sides of the upper flange 60 of the end-type high-compression PSC composite girder or the center lower-type high-compression PSC composite girder (50, 90), the anchorage in the enlarged cross section (31), the sheath (63) and the high-strength steel (58) is provided between the fixing unit (31) and fixed to the fixing unit (31), and then after the tension force is introduced into the high-strength steel (58), A continuous structure of a PSC girder in which prestress is introduced as a straight steel in a cross section in which the shape of the lower part of the center is characterized by fixing and fixing high-strength steel to the fixing unit 31. 10. The method of claim 9,
The twist sheath 67 is a tube in which a plurality of nodes are formed by forming the bent portions 68 at regular intervals, while the inside of the bent portion is narrowed while the inside of the normal cross section forms a wider space to compress the compressive force. A continuous structure of PSC girders in which prestress is introduced as a straight steel in the cross section of the lower center of gravity, which is characterized in that the high-strength steel is subjected to bending in an uncurved section of the sheath to be bent in an S shape. 10. The method of claim 9,
The twist sheath 67 inserts a high strength steel 58 having a plurality of circular rings 78 at regular intervals into a circular sheath tube having a diameter, and then applies compressive force at both ends of the high strength steel 58. The high strength steel inserted into the tube is bent in the space between the ring 78 and the ring 78 to be bent in an S-shape. Continuous structure of one PSC girder. In the construction method of the continuous structure of the river bridge,
While the lower mold height of the girder end 54 in the alternating 11 and the pier 12 is smaller than the mold height in the lower center, the fixing holes 31 are provided at both ends to install the primary steel wire 51 in a parabolic manner. Fixtures 31 are provided on the end surfaces of the central portion protruding outwardly from the lower ends of both sides at intervals, and the sheath 63 and the secondary straight steel 55 and the retainer 63 are disposed on the end faces 31. After fixing the steel wires 64 for management, respectively, the tension force is introduced into the primary steel wires 51 and the secondary linear steels 55, respectively, and then fixed to the fixing holes 31 to introduce the prestress into the girder. A high shrinkage PSC composite girder 50 is installed, and the end type high shrinkage PSC composite girder 50 is successively installed in the pier 12, and the upper continuous portion is disposed above the end high shrinkage PSC composite girder 50. An apparatus 70 is installed and the side surfaces of the end type high shrink PSC composite girder 50 and the end type high shrink PSC composite girder 50 are removed. Pre-stressed with straight steel on the cross section of the lower part of the center characterized by the installation of the end-type high-compression PSC composite girder 50 installed on the bridge 12 in the field to install the site casting robot 100 in the field Method for constructing continuous structure of PSC girder with In the construction method of the continuous structure of the river bridge,
While the lower mold height of the girder end 54 in the alternating 11 and the pier 12 is smaller than the mold height in the lower center, the fixing holes 31 are provided at both ends to install the primary steel wire 51 in a parabolic manner. Fixtures 31 are provided on the end surfaces of the center portion protruding outward from the lower ends of both sides at intervals, and the sheath 63 and the secondary linear steel 55 and the retainer 63 are disposed at the end faces of the blocks. After fixing the steel wires 64 for management, respectively, the tension force is introduced into the primary steel wires 51 and the secondary linear steels 55, respectively, and then fixed to the fixing holes 31 to introduce the prestress into the girder. A high shrinkage PSC composite girder 50 is installed, and the end type high shrinkage PSC composite girder 50 is continuously installed in the pier 12, and the lower continuous PSC composite girder 50 is continuously lowered below the end type high shrinkage PSC composite girder 50. Specially provided with the end-type high-reduction PSC composite girder 50 installed on the piers 12 interconnected by installing the device 80. Construction method for PSC continuous girder structure of the introduction of the prestressing steel material in a straight line in cross section in which variations of the center in the bottom of choices. 16. The method of claim 15,
The PSC girder in which prestress is introduced with a straight steel in the cross section of the upper and lower continuous gears is installed at the same time as the upper continuous device or the lower continuous device at the same time. Construction method of continuous structure. The method according to any one of claims 14 to 16,
The end-type high-reduction PSC composite girder 50 has a lower mold height of the girder end 54 than the mold height of the lower part of the center, and a fixing unit 31 is installed at both ends to install the primary steel wire 51 in a parabolic shape. On the other hand, the fixing unit 31 is provided in the end surface of the block out at intervals on both sides of the center lower portion protruding outwardly from the lower end of both sides, and the sheath 63 and the secondary linear steel 55 in the fixing unit 31. And each fixing steel wire 64 for maintenance, and introducing tension force to the primary steel wire 51 and the secondary linear steel material 55, respectively, and then fixing to the fixing hole 31 to introduce prestress into the girder. A method of constructing a continuous structure of a PSC girder in which prestress is introduced with a straight steel in a cross section of which a section height of the center lower part is characterized by In the construction method of the continuous structure of the road, complex or railway bridge,
The girder while the lower mold height of the girder end 54 in the alternating 11 and the pier 12 is larger than the mold height in the lower center, and the fixing holes 31 are installed at both ends to install the primary steel wire 51 in a parabolic manner. The fixing unit 31 is provided in the end surface of which both sides of the center portion which went into the lower end portion are cut out, and the sheath 63, the secondary linear steel 55, and the maintenance steel wire 64 are respectively installed in the fixing unit 31. After fixing and introducing tension forces into the primary steel wire 51 and the secondary linear steel 55, respectively, the central lower-type high-compression PSC composite girder 90, which is fixed to the fixing unit 31 and introduces prestress into the girder, is fixed. After installing the pier 12, the central lower-type high-compression PSC composite girder 90 in a row, and then install the upper continuous device 70 on the upper portion of the central lower-type high-compression PSC composite girder (90) The central lower-type high-reduction PSC composite girder 90 connected to the bridge 12 is characterized in that it is installed. Construction method of the continuous structure of the PSC girder introducing a prestress to the linear steel material in its cross-section in which variations in the central lower part of choices. In the construction method of the continuous structure of the road, complex or railway bridge,
The lower girders of the girder end 54 on the alternating 11 and the piers 12 are larger than the girders of the lower part of the center, and the fixing girders 31 are provided at both ends to install the primary steel wire 51 in a parabolic manner. The fixing unit 31 is provided in the end surface of which both sides of the center portion which went into the lower end portion are cut out, and the sheath 63, the secondary linear steel 55, and the maintenance steel wire 64 are respectively installed in the fixing unit 31. After fixing and introducing tension forces into the primary steel wire 51 and the secondary linear steel 55, respectively, the central lower-type high-compression PSC composite girder 90, which is fixed to the fixing unit 31 and introduces prestress into the girder, is fixed. After the installation, and the pier 12, the central lower-type high-compression PSC composite girder 90 in a row, the lower continuous device 80 is installed in the lower portion of the central lower-type high-compression PSC composite girder 90 The central lower-type high-reduction PSC composite girder 90 connected to the bridge 12 is characterized in that it is installed. Construction method of the continuous structure of the PSC girder introducing a prestress to the linear steel material in its cross-section in which variations in the central lower part of choices. 20. The method according to claim 18 or 19,
PSC girder in which prestress is introduced with a straight steel in the cross section of the upper and lower continuous gears, which is characterized in that the upper continuous device or the lower continuous device is installed at the same time on the upper or lower portion of the central lower type high reduction PSC composite girder 90 at the same time. Construction method of continuous structure. 20. The method according to claim 18 or 19,
The lower center height-reducing PSC composite girder 90 has a lower mold height of the girder end 54 than the mold height of the lower center, and installs the fixing holes 31 at both ends to install the primary steel wire 51 in a parabolic shape. And a fixing unit 31 is installed at a cross section of both sides of the center portion which is inwardly formed from the lower end of the girder, and the sheath 63 and the secondary linear steel 55 and the maintenance steel wire 64 are disposed on the fixing unit 31. To each of the first steel wire 51 and the second linear steel (55), respectively, and then fixed to the fixing unit 31, the pre-stress is introduced to the girder, characterized in that A method of constructing a continuous structure of PSC girders in which prestress is introduced as a straight steel in a cross section with a high height. 15, 16. The method of claim 19, wherein
The lower continuous device 80 is the installation of the press-fit block 56, the fixing unit 31 is installed in the portion where the upper portion of the lower flange 62 and the abdomen 61 of the both ends of the high-end endless reduction PSC composite girder 50 is installed. In order to block out the front to install the press-fit block, the fixing unit 31 is installed on the inner side of the installed pressing block 56 so that the fixing unit 31 faces the twist sheath (67). ) And the high-strength steel 58 is fixed, a press-fit cylinder 66 is installed at the end of the high-strength steel 58 and a compressive force is introduced to the high-strength steel using a press-fit cylinder, and the press-fit cylinder is removed to compress the compressive force. When the high-strength steel 58 is removed, the tensile stress is applied to the lower portion of the connecting portion of the girder, the compressive stress is applied to the upper portion of the girder, and the prestress is introduced to the installed slab or the center of the girders 90 on both sides. Ha After block-outing the front for the installation of the fixing block 59 in the cross section of which the cross section is reduced, install the fixing holes 31 on the outside of the fixing block 59, and install them in a pair from side to side, A pair of anchorages are also installed on the other girders, and the twist sheath 67 and the high strength steels 58 are fixed to the anchorages 31, but at the portions where the girders 90 and the girders 90 meet, the high strength steels 58 are formed. Are installed to face each other at regular intervals, and the pressure plate 83 is installed at the ends of the high strength steel 58 and the twist sheath 67, respectively, and the pressure plate is disposed to face each other, and between the pressure plate 83 is a hydraulic cylinder ( 81), the upper and lower pressure plate of the hydraulic cylinder 81 is fixed with bolt nuts 85, and a stroke is generated in the hydraulic cylinder so that the pressure plate and the high strength steel are pushed out so that they are buckled in the twist sheath. after When the high-strength steel is fixed to the fixing unit, the pressure plate and the bolt nut are completely fixed, and the hydraulic cylinder is removed, prestressing tension is applied to the high-strength steel 58 so that the tensile stress is applied to the lower part of the connection part of the girder, and the upper part is compressed. A method of constructing a continuous structure of a PSC girder in which prestress is introduced with straight steel in a cross section in which a stress is introduced and prestress is introduced into a slab to be poured. The method according to any one of claims 14, 16, 18, 19,
The upper continuous device 70 faces the inner side of the fixing block 59, which is blocked out at intervals between the upper flange 60 of the end type high reduction PSC composite girder and the center lower type high reduction PSC composite girder 50 and 90. After the report anchorage 31 is installed and the sheath 63 and the high strength steel 58 are installed between the anchorage 31 and fixed to the anchorage 31, the tension force is introduced into the high strength steel 58. When the high-strength steel is fixed and fixed to the anchorage 31, the compressive stress is introduced into the upper part of the connected girder, and the tensile stress is introduced into the lower part, respectively. Construction method of continuous structure of PSC girder with prestressed with straight steel in cross section. The method according to any one of claims 14, 16, 18, 19,
The upper continuous device 70 is provided with an enlarged end surface on both sides of the upper flange 60 of the end-type high-compression PSC composite girder and the central lower-type high-compression PSC composite girder (50, 90), the fixing unit in the enlarged cross-section (31), the sheath (63) and the high-strength steel (58) is provided between the fixing unit (31) and fixed to the fixing unit (31), and then after the tension force is introduced into the high-strength steel (58), When the high-strength steel is fixed and fixed to the anchorage 31, a compressive stress is introduced into the upper part of the connected girder, a tensile stress is introduced into the lower part, and a prestress is introduced into the slab, respectively. Construction method of continuous structure of PSC girder with low prestress. The method of claim 22,
The twist sheath 67 is a tube in which a plurality of nodes are formed by forming the bent portions 68 at regular intervals, while the inside of the bent portion is narrowed while the inside of the normal cross section forms a wider space to compress the compressive force. PSC is a high-strength steel that is bent in an uncurved section of the sheath and buckled into an S-shape to introduce a compressive force into the steel. Construction method of girder continuous structure. The method of claim 22,
The twist sheath 67 inserts a high strength steel 58 having a plurality of circular rings 78 at regular intervals into a circular sheath tube having a diameter, and then applies compressive force at both ends of the high strength steel 58. The high-strength steel inserted in the sheath tube is bent in the space between the ring 78 and the ring 78 to be buckled into an S-shape to change the shape of the lower part of the center, which is characterized in that the compressive force is introduced into the steel. Construction method of continuous structure of PSC girder with prestressed with straight steel in cross section.

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