KR200193344Y1 - Assembly tensioning steel girder beam - Google Patents

Abstract

It is suitable for bridge beams of road bridges and sidewalks, and can be used as beams or roofs of other buildings, as well as steel or steel sheets or structures that form skeletons of various machines. An assembly tensioning steel girder beam (ATOM) using prestressing with improved bending strength is disclosed. The disclosed prefabricated tensile steel beams are tensioned by the reinforcing members 14 and 14 'on both sides of the web 11 of the fabrication beam 10 of the T-beam, which is the structural body, and fixed at both ends thereof by the fasteners 15 and 15', respectively. The support member 16 is installed to support the tensioned reinforcing member 14, 14 'in a bow shape. The tension-strengthening member 14, 14 ', which is supported by the bow, pulls both ends of the structural body inward to exert compression and tensile stress. The fabrication beam 10 has a bending strength reinforced by the compressive and tensile stress acting according to the tension of the reinforcing members 14 and 14 ', thereby significantly reducing the thickness or height of the material itself. . Therefore, the material cost can be reduced, and the volume and weight can be reduced, so that the transportation and construction can be handled very easily and the long span can be secured.

Description

Prefabricated Tensile Steel Beam {ASSEMBLY TENSIONING STEEL GIRDER BEAM}

The present invention is suitable for beams of bridges such as road bridges and sidewalks, and is a prefabricated tensile steel beam that can be used as steel or steel sheets or frameworks that form the beams or roofing structures of other buildings and skeletons of various machines. The present invention relates to an assembly tensioning steel girder beam (ATOM), and more particularly, to a prefabricated tensile steel beam using prestressing in which compressive and tensile stresses are applied to improve bending strength against external force.

Bridge beams such as road bridges and sidewalks, such as rolled steel having a certain cross-section, or a built-up beam or a built-up beam, in which the section steel and / or steel sheet are made of joint materials box beam is used.

These beams for bridges are constructed on bridges or bridges that are constructed at intervals, and are supported by vehicles moving on the road while supporting a fixed dead weight corresponding to the total weight of concrete structures and road structures paved on the concrete structures. It supports the live load of pedestrians. Therefore, the beam for bridge should consider dead load and live load acting on it. Especially, if the central part between the bridge and the bridge is bent downward due to the vertical load, the whole bridge may collapse. It needs to be designed to have sufficient bending strength.

In order to increase the strength of the bridge beam, the height of the material itself has been increased in the direction in which the thickness or the vertical load acts, or the reinforcing ribs have been welded to the portion where the load is concentrated.

According to the method of increasing the thickness or height of the material itself as described above or the method of welding the reinforcing rib, not only the material cost increases but also the weight and volume increase, making it difficult to handle during transportation and construction, thereby increasing the logistics cost and construction cost. It becomes a factor.

In addition, there is a limit to the strength that can be increased by increasing the thickness or height of the material itself or by welding the reinforcing ribs. Therefore, when a large load is required, the beam length must be shortened or a separate structure must be constructed. Therefore, in this case, the number of piers must be increased and additional structures must be added, resulting in a large increase in construction costs.

These problems will be the same for the slab beams not only in the beams for bridges but also in the steel structures that make up the framework of various buildings and machines, and also in the case of columns or walls with lateral loads or shear forces in one direction. to be.

The purpose of the present invention is to increase the thickness or height of the material itself or to further increase the strength beyond the limit of reinforcement by the conventional method of welding the reinforcement ribs, and to easily control and design the strength according to the structure specification, It is to provide a prefabricated tensile steel beam using prestressing to improve the bending strength against external force by a method of prestressing to pre-act the compressive stress from the outside.

Another object of the present invention is to provide prefabricated tensile steel beams using prestressing that are bulky, light and especially slim or have long span while retaining sufficient strength.

Figure 1 is a perspective view showing a prefabricated tensile steel beam to be applied to the present invention (built-up beam) of T-shaped steel (built-up beam).

Figure 2 is a perspective view showing a prefabricated tensile steel beam that is applied to the present invention H-shaped steel or I-shaped steel.

Figure 3 is a perspective view showing a prefabricated tensile steel beam that is applied to the present invention H-shaped steel or I-shaped steel in a different structure from FIG.

Figure 4 is a perspective view showing a prefabricated tensile steel beam to be applied to the present invention structural steel sheet.

Figure 5 is a perspective view partially separated prefabricated tensile steel beam to be applied to the assembly box-shaped beam for the present invention.

Figure 6 is a longitudinal cross-sectional view showing an installation state of the assembly box for beams shown in FIG.

Explanation of symbols on the main parts of the drawings

10: manufacturing beam of T-shaped steel 11: web

14,14 ': Kang Hyun member 15,15': Fixture

16: support member 20,30: H-shaped steel or I-shaped steel

40: steel plate structure 50: assembly box beam

In order to achieve the above object, the present invention uses a steel wire such as steel wire, steel rod, wire rope, angle, etc. to the main body of various steel structure materials used as a steel beam structure for a bridge beam or a building or various machines. It is possible to increase the bending strength by applying compressive stress and tensile stress so as to counter the deformation direction of bending caused by external load.Concerning the structural body and both ends of the structural body in the longitudinal direction fixedly connected to both ends thereof At least one reinforcement member tensioned so that the sides are pulled inward from each other, and support means for supporting the at least one reinforcement member in its tensioned state in a bow shape, against external forces exerted on one side between its ends. Prefabricated tensile steel beams are constructed by using pre-stressing with compressive and tensile stresses to increase bending strength. The.

The structural member main body may use a built-up beam of a steel or steel plate such as the existing T-shaped steel, H-shaped steel or I-shaped steel as it is, or may be connected to the steel or steel plate or manufactured beam. Assembly beams or box-shaped beams assembled from materials can be used.

As the supporting means, a separate supporting member may be fixed to the structural member main body to support the reinforcing member in the shape of a bow or may be directly fixed to the structural member main body in the same manner as both ends of the reinforcing member.

Prefabricated tensile steel beam using prestressing according to the present invention has a compressive and tensile stress by the reinforcing member is applied, it has a bending strength reinforced corresponding to the tension (Tension) of the reinforcing member. In other words, the material (structural body) can have a much higher strength than the thickness or height of the material itself, so that the volume and weight can be reduced based on the same load, and in particular, slim and long span ) Is possible.

Referring to the drawings with respect to the prefabricated tensile steel beam using the prestressing according to the present invention as described in the preferred embodiments as follows. 1 to 4 of the accompanying drawings shows various forms of prestressing structures for applying compression and tensile stress to each of the sections in order to construct a prefabricated tensile steel beam using prestressing using a variety of section steel as the structural body.

1 is an embodiment in which the fabrication beam 10 of T-shaped steel is used as the structural body. The T-beams originally consist of a web 11 and an upper flange 12 continuous on top of the web 11. In the present invention, corresponding to the upper flange 12 of the upper end of the web 11 of the T-shaped steel to form a flange-like seating portion (13, 13 ') for seating and connecting, for example, piers, etc. Both strands of reinforcing members 14 and 14 'are equally tensioned on the front and back sides of the web 11 adjacent to the inner end portions of the seating portions 13 and 13', respectively, and the fasteners 15 at both ends thereof. Fix it by fastening or welding. In the center of the web 11, a cutout (not shown) is formed in the board-shaped support member 16, the cutout is fitted, and then fixed by welding or the like, and the reinforcing members 14, 14 'are formed at the ends thereof. Support it.

As the reinforcing members 14 and 14 ', a long wire such as a steel wire or a wire rope braided with a plurality of steel wires, or a steel bar or an angle is used. The reinforcing members 14 and 14 'are tensioned with tensions that can act on compressive and tensile stresses to compensate for bending strength in consideration of dead and live loads acting on the fabrication beam 10 that is the structural body. That is, the fabrication beam 10, which is a structural body, is prestressed by the tension of the tensioned reinforcing members 14, 14 ', and the compressive and tensile stresses by the tension of the reinforcing members 14, 14' are applied. It has reinforced bending strength corresponding to the applied compressive and tensile stresses. The bending strength is adjustable in accordance with the tension of the reinforcing members 14 and 14 ', for example in accordance with the height of the support member 16. The supporting member 16 can be installed in two or more places according to the length of the fabrication beam 10.

2 shows an embodiment using an H-beam or an I-beam. Unlike the T-beams, the H-beams or I-beams 20 have upper and lower flanges 22 and 23 continuously formed at the upper and lower ends of the web 21. The fasteners 25 and 25 'of the reinforcing members 24 and 24' are respectively fixed to upper and lower flanges 22 and 23 of the H-shaped steel and the I-shaped steel 20 at both ends of the lower flange 23, and the lower flanges respectively. A board-shaped support member 26 is provided at the central portion of 23 to support the reinforcing members 24 and 24 '. The support member 26 can be installed in two or more places according to the length of the H-beam or I-beam 20.

3 shows another form of pre-stressing structure for H-shaped steel or I-shaped steel 30. The fasteners 35, 35 'at both ends of the reinforcing members 34, 34' are provided with upper and lower flanges of the web 31. As shown in FIG. It is fixed by shifting to a position close to the upper flange 32 of (32, 33), and in the center of the web 31 and the lower flange 33, two auxiliary fixtures (36, 36 ') instead of a separate support member It is biased and fixed at a position close to the flange 33 to fasten the reinforcing members 34 and 34 'to the auxiliary fixtures 36 and 36' so as to be supported. Auxiliary fixtures 36, 36 'can be increased in the installation place according to the length of the H-beam or I-beam (30).

Next, FIG. 4 shows an embodiment using the steel plate structure material 40 continuous with a constant thickness and width. The steel plate structural member 40 is fastened to fastening portions 45 and 45 'at both ends of the reinforcing member 44 at both end portions of the side portions 41 corresponding to the width direction to a portion near the upper surface portion 42 of the side portions 41. In addition, in the center portion of the side portion 41, instead of a separate support member, the auxiliary fixtures 46 and 46 'are fixed to a portion adjacent to the lower surface portion 43 to support the reinforcement member 44. The auxiliary fixtures 46 and 46 'can increase the installation place according to the length of the steel plate structural material 40.

Prestressing prefabricated tensile steel beams using the single beams or fabricated beams according to FIGS. 1-4 described above will be suitable for bridge beams, as well as other structural structures and steel structures that form the skeleton of various machines.

Next, Figures 5 and 6 shows an embodiment applied to the assembly box-shaped bridge beam as the structural body. In these figures, the code | symbol 50 points out the assembly box beam which is a structural material main body. The assembly box-shaped beam 50 includes a lower support plate 51 made of a steel plate material having a constant width using a steel plate material, and a web plate welded to surround the lower support plate 51 at a predetermined height. ), A plurality of diaphragms 53 welded at regular intervals in the longitudinal direction on the lower support plate 51 in the web plate 52, and each compartment divided by the web plate 52 and the diaphragm 53. It consists of a plurality of top cover plates 57 welded to cover the openings. Here, the plurality of upper cover plates 57 may be provided as a single body made of a continuous steel plate material, such as the lower support plate 11, and also one size of the upper cover plate 57 occupies two or more compartments May be

In order to increase the strength of the assembly box-shaped beam 50, the present invention uses a steel wire or a wire rope braided with a plurality of steel wires, or a steel member 54 made of a long member such as a steel bar or an angle. Tension is applied to both ends of the bottom surface of the lower support plate 51 by fixing fixtures 55 and 55 ', respectively, and at the middle of the lower support plate 51, the rod-shaped support member 56 is placed directly downward. By supporting the central portion of the reinforcing member 54 in the form over the end of the support member 56, the reinforcing member 54 was installed in a tense state. The reinforcement member 54 acts on the compressive and tensile stresses to compensate for the bending strength in consideration of the dead weight of concrete structures and road pavements placed on the assembly box beam 50 and the moving loads by vehicles or pedestrians that will move on them. It is tensioned with tension that can be made. In other words, the assembly box-shaped beam 50 is applied to the compressive stress and tensile stress by the tension of the steel member 54 installed under the lower support plate 51 to correspond to the compressive stress and tensile stress applied to the reinforced bending strength Hold. The bending strength is adjustable according to the tension of the reinforcing member 54, for example, the height of the support member 56.

The reinforced box-type beam 50 reinforced as described above may have a slimmer or longer span that is thinner or significantly reduced in height compared to the thickness of the steel sheet used in the existing assembly box-shaped beam based on the same intensity. Here, the reinforcing member 54 may be installed in one or two or more depending on the width of the assembly box-shaped beam (50). In addition, two or more support members 56 may be provided depending on the length of the assembly box beam 50.

This embodiment shows a structure in consideration of the assembly workability of the slim assembly box beam 50. That is, the web plate 52 and the diaphragm 53 together with the reinforcing member 54 and the support member 56 under the lower support plate 51 are assembled at the factory, and the lower support plate 51 structure is primarily assembled. After transporting the site to the site, using a crane, etc. to be installed on the piers (58, 58 '). Both ends of the hypothesized lower support plate 51 may be fixed to the piers using a conventional scissor device or the like. In addition, the upper cover plate 57 is transported together when transporting the lower support plate 51 to be assembled on the site, that is, on the lower support plate 51 structure hypothesized on the piers (58, 58 ') by welding from the outside.

For reference, conventional box-shaped beams are not easy to be transported and installed at once because their weight and volume are considerable compared to the case of using a single beam or fabricated beam. In general, considering the weight and volume that can be transported and lifted, two or more are separated and manufactured in the longitudinal direction, and the separated manufactured beams are assembled by bolting on site. Therefore, in order to enable the fastening work, the box height of the beam must be at least 700 mm, and this has not reduced the weight and volume.

On the contrary, since the height of the present invention has been greatly slimmed down through the embodiments as shown in FIGS. 1 and 2, the lower support plate 51 can be integrally formed, and thus the transport and construction are easy and structurally stable. This has the advantage of greatly improving the appearance.

In the present embodiment, the plurality of upper cover plates 57 may be formed as a single body, and the assembly box-shaped beam 50 having a reduced volume and a slim box height is separately manufactured in the longitudinal direction, and then assembled by bolts, and then, a diaphragm. The upper cover plate 57 separated between the diaphragm and the diaphragm 53 can be welded and then minimized to further minimize its weight and volume.

On the other hand, although not illustrated in the drawings, the assembly box-shaped beam 50, which is the structural member body of the present embodiment, of the assembly box-shaped beam 50 as shown in the embodiment of FIG. 4 without tensioning the reinforcing member 54 on the lower support plate 51. The lateral side web plate 52 may be directly tensioned using a fixture and an auxiliary fixture.

As described in the above embodiments, according to the present invention, the bending current against the external force is increased by applying compressive and tensile stresses to the steel beams of bridge beams or various structures, thereby increasing the bending strength against external forces. While the thickness and height can be greatly reduced, the same thickness and height can provide a structural material or a structure that can secure a long span while having much higher strength.

Therefore, according to the present invention, it is possible to reduce the material cost of the steel frame structure and at the same time provides an easy effect of handling for transport and construction through the reduction of volume and weight. In particular, the present invention is to provide a slim bridge bridge beam can be lowered the height of the three-dimensional intersection, etc. is to provide a significant reduction in construction costs.

On the other hand, if the basis of the thickness and height of the same structural material body has a much higher strength to increase the stability of the structure, as well as to extend the length of the bridge beam can be reduced the number of bridges This will drastically reduce construction costs.

Claims (7)

A structural member body, at least one reinforcing member fixedly connected to both end portions in the longitudinal direction of the structural member main body and tensioned such that both ends thereof are pulled inward from each other, and a support supporting the central portion of the at least one reinforcing member in the shape of a bow; A prefabricated tensile steel beam including a means, in which compression and tensile stress by prestressing are pre-acted to increase bending strength against external forces applied to one side of the structural body. The prefabricated tensile steel beam as claimed in claim 1, wherein the supporting means stands a separate supporting member on the structural member main body to support the reinforcing member at the end of the supporting member. The prefabricated tensile steel beam as claimed in claim 1, wherein the support means directly fixes the support member to the structural body. The method according to claim 1, wherein the structural structural body is welded at regular intervals in a longitudinal direction on a lower support plate which is continuous in a constant width and a web plate welded to surround the lower support plate at a predetermined height, and a lower support plate in the web plate. Assembled with a plurality of diaphragm beams consisting of a plurality of diaphragm and a plurality of upper cover plate welded to the web plate and the top of the diaphragm, the compression and tensile stress by the reinforcing member is applied under the lower support plate of the assembling box beam Prefabricated tensile steel beam characterized by. The method according to claim 1, wherein the structural structural body is welded at regular intervals in a longitudinal direction on a lower support plate which is continuous in a constant width and a web plate welded to surround the lower support plate at a predetermined height, and a lower support plate in the web plate. Assembled with a plurality of diaphragm beam consisting of a plurality of diaphragm and a web plate and a plurality of upper cover plate welded to the upper end of the diaphragm, the compression and tensile stress by the reinforcing member is applied to the web plate of the assembling box beam Prefabricated tensile steel beam characterized by. The structural structural body according to claim 1, wherein the structural structural body is any one of T-beam H-beam I-beam, or fabrication beam, and compressive and tensile stress by the reinforcement member is applied on the web of each steel or fabrication beam. Prefabricated tensile steel beam characterized by. 2. The prefabricated tensile steel beam as claimed in claim 1, wherein the structural structural body is a steel sheet material having a constant thickness and width, and compressive and tensile stress by the reinforcing member is applied to the side portion of the steel sheet material.