KR200400109Y1 - Arch-shaped precast panel for building arch-type slab - Google Patents

Abstract

        The present invention uses the arched precast panel to install the slab in the arch shape so that the tensile force does not occur and only the compressive force is generated, and the arched precast panel is installed without the use of additional formwork when installing the bridge and the concrete is poured. Arched slab bridge installation method to be integrated with the slab.

Description

Arch-shaped precast panel for building arch-type slab}

        The present invention installs a plurality of prestressing composite beams to form the width of the bridge in the upper part of the pier, and the shear key and steel wire in the center of the slab by mounting a unit arched precast panel on the upper casing concrete of the prestressing composite beams installed on both sides After installing the arched precast panel that can install the slab in the arch shape by forming the connection part by the concrete, and after forming the casting part in which the concrete mortar is poured between the vertical part of the arched precast panel and the abdomen of the prestressing composite beam It is a method of installing the arched slab bridge in which the arched precast panel and the slab are integrally installed by pouring concrete to form the slab as a whole.

        The unit arcuate precast panel has a vertical portion formed on one side, and installs an arch portion formed by crossing a plurality of protrusions and groove portions at regular intervals from the upper portion of the vertical portion, and has a length corresponding to the intermediate length of the arch portion of the bridge to be installed. The arch portion is provided as much as possible, and on the surface of the end portion of the arch portion, protrusions and grooves or grooves and protrusions are respectively formed to form shear keys for interlocking with each other when the unit arc-shaped precast panels are connected to each other at the center, and the panel body of the connection portion. Through the wires to form a connection to be connected to each other using a steel wire.

        In order to install the lower part of the slab in arch shape, the present invention manufactures the arch precast panel in advance as a substitute for the formwork and mounts it on the site, and then installs the arch to form the arched slab bridge.

       The synthesized beam of the present invention refers to a preplex synthesized beam and all other synthesized beams which are commonly used as using a synthetic beam having prestressing introduced therein.

        The purpose of the installation of the arched slab bridge as described above is to install the slab in an arch shape, so that it is not necessary to introduce a separate compressive force to the arched precast panel, and to the arch theory (σ = P / A) that the compressive force acts on the arched slab. As the design is possible, the shear surface of the slab is an effective cross-section, which is structurally very stable, and it is simple to install without the need for introducing a separate compressive force. In order to enable the installation of the arch to use the factory-made arched precast panel as a substitute for the form of the slab to be installed in the concrete when the slab is to be installed integrally with the arched precast panel.

       Conventionally, as shown in (a), (b) and (d) of FIG. 1, (a) after a plurality of preplex composite beams 18 are installed on the bridge 11 to correspond to the width of the bridge, B) After the precast 15 having the haunches 17 is installed on the lower casing concrete 23 of the composite beam 18, (c) to introduce a compressive force into the precast 15. After the concrete is poured while tensioning the precast with a steel wire, when the steel wire is released, a compression force introduction part 16 is installed to allow the compressive force to be introduced into the precast, and the slab concrete 14 is poured into D) forming the slab 12 in which the hunt portion 17 is installed and installing the bridge 10 by installing the necessary facilities for bridges such as curbs 13 thereon,

         In another conventional method, as shown in (a) (b) and (d) of FIG. 2, (a) a plurality of preflex composite beams 18 are installed on the bridge 11 to correspond to the width of the bridge. Afterwards, (b) after installing the formwork 32 having the haunches 17 installed on the lower casing concrete 23 of the composite beam 18 by using the copper club 31, (c) the slab concrete ( 14) after the casting, and (d) to form the slab (12) on which the hunt unit (17) is installed and the necessary facilities for bridges, such as curb (13), to install the bridge.

        1 and 2 of the prior art, so that the slab 12 is installed using the precast 15 having the haunches 17 installed thereon, or the haunches 17 may be installed in the form 32. The slab 12 with the haunch 17 is manufactured and only the concrete placed on the neutral shaft by plate theory (σ = ± M / Z) is effective for the slab 12 with the haunch 17. The concrete placed in the cross section and placed in the lower part of the neutral shaft is not recognized as an effective cross section, and it is by structural calculation to reinforce the rebar to compensate for this and to bear the tensile force in the lower part of the neutral shaft by the rebar, as shown in FIG. Even if the slab 12 is installed using the cast 15, if there is a haunting unit 17, it is necessary to separately go through the step of introducing a compressive force to the precast 15, and as shown in FIG. Of over-design to install the tensile reinforcement to receive a cross-sectional view tension problems have been raised.

        The present invention has been proposed to improve the above problems, by installing the slab in the arch shape, so that the compressive force is introduced into the arched slab without introducing a separate compressive force to the arched precast panel to the effective cross section of the slab It is structurally very stable and simple to install and economical construction is possible because there is no need for additional tensile rebar.

       Arch type slab which is integrated with slab when slab concrete is poured by using the factory-made arch type precast panel as a substitute for the formwork so that the slab can be installed in a curved arch shape without the haunch part using the arch type precast panel as described above. To provide a bridge installation method.

        The present invention provides a plurality of pre-stressing composite beam 20 to form a width of the bridge on the top of the pier 11 and unit arch-shaped free on top of the lower casing concrete 23 of the pre-stressing composite beam 20 installed on both sides An arched precast panel 50 through which the slab 12 can be installed in an arch shape by forming the connection portion 70 by the shear key 71 and the steel wire 73 in the center of the slab 12 by passing through the cast panel 60. After installing the slab, the slab part in which concrete mortar is poured is formed between the vertical part 54 of the arcuate precast panel 50 and the abdomen 22 of the prestressing composite beam 20. It is a method of installing the arched slab bridge 40 in which the concrete 14 is cast so as to form 12, and the arcuate precast panel 50 and the slab 12 are integrally installed.

        The unit arcuate precast panel 60 forms a vertical portion 54 on one side and cross-produces a plurality of protrusions 58 and grooves 57 at regular intervals from the upper portion of the vertical portion 54. To install the tooth 51, the arch portion 51 is installed to the length corresponding to the middle length of the arched slab of the bridge to be installed, and the projections 58 and the groove ( 57 or the grooves 57 and the protrusions 58, respectively, to form a shear key 71 to be engaged with each other when the unit arcuate precast panel 60 is connected to each other at the center, and the unit arch type precast panel It is characterized in that the connection portion 70 is formed so as to penetrate the steel wire 73 to the panel 60 body of the portion where the 60 is connected to each other to interconnect with the adjacent panel and the steel wire.

        Hereinafter, the configuration and operation of the present invention in detail by the accompanying drawings as follows.

        Figure 3 (a) (b) (c) (d) is a view showing the installation process of the arched slab bridge in which the arched slab is installed using the arched precast panel of the present invention, (a) is the A plurality of prestressing composite beams 20 are installed to form the width of the bridge on the upper part, and (b) unit arc-shaped precast panels (top) of the lower casing concrete 23 of the prestressing composite beams 20 installed on both sides. 60) to form the connection portion 70 by the shear key 71 and the steel wire 73 in the center of the arched slab to install the arcuate precast panel 50 that can install the slab 12 in the arch after,

(C) The slab (the entirety of the arcuate precast panel 50 and the vertical part 54 and the abdomen 22 of the prestressing composite beam 20) is formed as a whole, The concrete 14 is poured to form 12, and (d) the slab 12 is integrally installed with the arcuate precast panel 50, and the slabs 12 are formed at both ends of both widths of the bridge. It is an arched slab bridge 40 provided with a curb 13.

        In the figure (c), a casting part 42 in which concrete mortar is poured is formed between the vertical part 54 of the arcuate precast panel 50 and the abdomen 22 of the prestressing composite beam 20. The slab 12, which is arched by the slab concrete, which is poured in the future while placing the mortar between the abdomen 22 and the vertical portion 54 while directing the vertical portion 54 to the inner side, that is, the interior of the bridge. The compressive force is automatically introduced into the arch so that only the compressive force can be applied to the arch so that the entire section of the slab becomes an effective cross section, thereby increasing the cross-sectional force and reducing the amount of tensile rebar, while the vertical portion 54 accurately lowers the concrete (23). This is to fix the position so that it is installed above.

       It is also possible to use a method of fabricating the formwork in an arch form without using an arch precast panel on the upper casing concrete of the prestressing composite beam, and then installing slab concrete to install an arch slab bridge. Introduced.

        4 is a view showing an arched precast panel in which the unit arch type precast panel of the present invention is assembled. The unit having a predetermined width as interconnecting the unit arch type precast panel 60 to install the arcuate slab 12 is shown in FIG. The arcuate precast panel 60 is installed in the longitudinal direction of the bridge and is to install the arcuate slab 12 by pouring concrete.

        The unit arcuate precast panel 60 forms a vertical portion 54 on one side, and the protrusions 58 and the groove portion 57 at regular intervals on the upper surface of the extension portion extending from the upper portion of the vertical portion 54 by a predetermined length. ) Install a plurality of cross-sections of the arch portion 51, the arch portion 51 is installed to a length equal to the length of the arch-shaped slab 12 of the bridge to be installed, the surface of the portion where the arch portion 51 ends In order to form a shear key 71 formed with a protrusion 58 and a groove 57 or a groove 57 and a protrusion 58, respectively, the shear key 71 when the unit arcuate precast panel 60 is connected to each other in the center thereof. The protrusions 58 and the grooves 57 of the) are engaged with each other, and the unit arch type precast panel 60 penetrates the steel wire 73 through the panel body of the interconnected portion so as to be adjacent to each other. (60) to interconnect with steel wire (73) As shown in FIG. 6, the groove portion 57 and the protrusion 58 formed on the upper surface of the extension portion are closely coupled and integrally formed when the slab is installed by pouring the slab concrete 14 as shown in FIG. 6. As a shear connecting role to be able to behave with respect to the external load in addition to the method of sequentially forming the groove portion and the protrusion as described above, protruding rebar in the form of a deflector on the upper surface of the extension portion and shear Include all shear connectors to improve adhesion to the concrete being poured, such as installing multiple bolts.

        The steel frame forming the unit arch type precast panel 60 is provided with reinforcing bar 55 at the lower end of the vertical part 54, and wire mesh 56 is installed at the vertical part 54 and the arch part 51. Next, it is to make arch type slab by manufacturing and installing in advance as factory production or site production to cast concrete.

        Figure 5 is a view showing in detail the unit arch-shaped precast panel and the connection of the present invention, which is made of a length corresponding to half the slab length of the bridge to be installed, the unit arched free to form an arch later The cast panel 60 is installed to allow the unit arch type precast panel 60 to be interconnected at the center of the slab of the arch portion of the bridge to install the arcuate slab 12.

The unit arcuate precast panel 60 forms a vertical portion 54 on one side, and the protrusions 58 and the groove portion 57 at regular intervals on the upper surface of the extension portion extending from the upper portion of the vertical portion 54 by a predetermined length. ) Install a plurality of cross-sectioned arch portion 51, but installs the arch portion 51 to the length equal to the length of the arch-shaped slab 12 of the bridge to be installed, the surface of the portion where the arch portion 51 ends In order to form a shear key 71 formed with a protrusion 58 and a groove 57 or a groove 57 and a protrusion 58, respectively, the shear key 71 when the unit arcuate precast panel 60 is connected to each other in the center thereof. The protrusions 58 and the grooves 57 of the () are meshed with each other and the unit arch type precast panel 60 is connected to the panel body of the interconnected portion by a steel wire so that the adjacent interconnected panels are steel wires. Connections to Interconnect To form.

        The steel frame forming the unit arch type precast panel 60 is provided with reinforcing bar 55 at the lower end of the vertical part 54, and wire mesh 56 is installed at the vertical part 54 and the arch part 51. Next, it is to make arch type slab by manufacturing and installing in advance as factory production or site production to cast concrete.

         6 is a view showing in detail the installation of the arch arch slab bridge by installing the arch arch precast panel to the pre-stressing composite beam by assembling the unit arch type precast panel of the present invention, the concrete is installed, the bridge installed by the installation process of FIG. Shows the whole.

        A plurality of prestressing composite beams 20 are provided on the top of the bridge 11 to form the width of the bridge, and the unit arcuate precast panel is provided on the upper casing concrete 23 of the prestressing composite beams 20 provided on both sides. Arching precast panel that can install the slab 12 in an arch shape by mounting the respective 60 so that the arch 51 in the center of the slab to form a connecting portion 70 by the shear key 71 and the steel wire 73. After installing 50, a casting part 42 in which concrete mortar is poured is formed between the vertical part 54 of the arcuate precast panel 50 and the abdomen 22 of the prestressing composite beam 20. Later, concrete is formed so that the slab can be formed as a whole, the slab is integrally installed with the arcuate precast panel 50, and the slab 12 has an arch shape in which the curbstones 13 are installed at the ends of both widths of the bridge. Slab Bridge 40.

          Forming a casting part 42 in which concrete mortar is poured between the vertical part 54 of the arcuate precast panel 50 and the abdomen 22 of the prestressing composite beam 20 is perpendicular to the abdomen. While placing the mortar between the parts, the vertical part is directed to the inside, that is, the interior of the bridge, and the compressive force is automatically introduced into the arch by the slab concrete, which is poured in the future, and the slab 12 formed integrally with the arch part also has the compressive force. This is to ensure that the vertical portion 54 is accurately installed on the lower casing concrete 23 while allowing only the compressive force to be applied to the entire slab including the arch portion to be automatically introduced.

           The present invention has been proposed to improve the above problems, an arcuate slab in which the panel and the slab are integrally installed so that the compression force is introduced by installing an arcuate arched precast panel and pouring slab concrete thereon. As the shear surface of the arched slab does not need to introduce a separate compressive force to the arcuate precast panel, the compressive force acts, so the cross section of the slab is effective and the structure is very stable and simple to install while reducing the amount of tensile rebar. It is economical and construction to be integrated with the slab when slab concrete is laid while using the factory-made arch precast panel as a substitute for formwork so that the slab can be installed in a curved arch form without a haunch using the arch precast panel. This handy Tooth slab will bridge the installation.

        Figure 1 (a) (b) (c) is a diagram showing the installation process of the bridge to install the haunting slab using a precast conventional haunch.

        Figure 2 (a) (b) (c) (d) is a view showing the installation process of the bridge to install the haunting slab using the formwork with the haunch conventionally.

        Figure 3 (a) (b) (c) (d) is a view showing the installation process of the arched slab bridge installed the arched slab using the arched precast panel of the present invention.

        Figure 4 is a view showing an arched precast panel assembled with the unit arch type precast panel of the present invention.

        Figure 5 is a view showing in detail the connection of the unit arcuate precast panel of the present invention.

        6 is a view showing in detail the installation of the arch arch slab bridge by assembling the unit arch type precast panel of the present invention to install the arch type precast panel to the prestressing composite beam and cast concrete.

<Description of the symbols for the main parts of the drawings>

         10 bridge 11 bridge

         12: slab 13: curb

         14: Slab Concrete 15: Precast

         16: compressive force introduction portion 17: haunting portion

         18: preplex composite beam

         20: prestressing composite beam 21: H-beam

         22: abdomen 23: lower casing concrete

         30: bridge 31: dongbari

         32: formwork

         40: arched slab bridge 41: arched slab

         42: mortar of concrete mortar

         50: arch type precast panel 51: arch portion

         52: When 53: When

         54: vertical part 55: reinforcing bar

         56: wire mesh 57: groove

         58: protrusion

         60: unit arch type precast panel

         70: connection portion 71: shear key

         72: penetrating portion 73: steel wire

Claims (7)

        A plurality of prestressing composite beams are installed to form the width of the bridge on the upper part of the pier, and a unit arch-shaped precast panel is mounted on the lower casing concrete of the prestressing composite beams installed on both sides by a shear key and steel wire at the center of the slab. An arcuate precast panel connected by a connection part is installed, and a concrete mortar casting part is formed between the arcuate precast panel and the prestressing composite beam, and the concrete is poured to form a slab. Arched precast panel for arched slab installation characterized in that the slab is formed in the form of an arch.         The method of claim 1,         The unit arc-shaped precast panel has a vertical portion formed on one side, and on the upper surface of the extended portion extending a certain length from the upper portion of the vertical portion at regular intervals, a plurality of arch portions formed by cross-protruding portions and grooves are installed, The arch part is provided in bisecting lengths of the arcuate slabs, and the front end of the arch part is formed with a shear key formed with a projection part and a groove part or a groove part and a projection part respectively, and the steel wire is formed on the panel body of the part where the unit arch type precast panel is interconnected. Arched precast panel for installation of arched slabs characterized by passing through them.         The method of claim 1,         The concrete mortar casting part is to cast concrete mortar between the vertical part of the arch-shaped precast panel installed on the upper casing concrete of the prestressing composite beam and the abdomen of the prestressing composite beam, to introduce a compressive force to the arcuate slab. Arched precast panel for arched slab installation characterized by         The method of claim 1,         The connection portion is an arched precast panel for the arched slab installation characterized in that the connection by the shear key and the steel wire is made.         The method of claim 1,         The shear key is formed in the connecting portion of the arcuate precast panel that is mutually connected from the left and right, so that the projection and the groove or the groove and the projection is formed in the left and right cross-section respectively so that the projection and the groove of the shear key are connected to each other when connected to each other. Arched precast panel for arched slab installation characterized by one.         The method of claim 1,         The unit arch type precast panel is installed in the reinforcing bar at the bottom of the vertical portion, the arched precast panel for the installation of the arched slab characterized in that the concrete is made by pouring concrete after installing the wire mesh on the vertical portion and the arch portion.        The method of claim 1,        Instead of using an arched precast panel on the upper casing concrete of the pre-stressing composite beam, the arched precast panel for the installation of arched slabs characterized in that the formwork is made in the form of arches, cast slab concrete.