KR20210032634A - Truss composite precast deck plate and construction method using it - Google Patents

Abstract

The present invention relates to a precast deck plate and a bridge slab construction method using the same. A coupling groove is formed in a lower portion of a concrete panel, and the precast deck plate is synthesized with a truss structure through the coupling groove.

Description

Truss composite precast deck plate and construction method using it}

The present invention relates to a precast deck plate and a slab construction method using the same, and more particularly, to a precast deck plate on which a composite structure of a truss is formed and a method of constructing a slab for a bridge using the same.

In recent years, in the slab construction of a bridge, it is easy to see the slab construction method using a deck plate that acts as a form without using a copper bar and a formwork. This is a method of using a deck plate as a permanent formwork for slab concrete pouring. By installing a deck plate prepared in advance using a crane and pouring slab concrete using it as a formwork, the deck plate is composited with the slab concrete, and there is an advantage that a separate formwork does not need dismantling.

A method of using a conventional precast concrete panel as a deck plate is disclosed in Patent No. 10-0635137. The deck plate is completely synthesized with the slab concrete to conform to the structural behavior of the slab, while its rigidity is large so that it is easy to secure safety during concrete pouring.

On the other hand, in a bridge using a truss-type girder, there are many prior art related to a composite truss girder. "Truss" refers to the assembling of several straight steel members into a continuous triangular frame structure within one plane, and is widely used because of its simple and easy to understand mechanically. The straight member of the truss mainly uses steel, but when it receives a large compressive force depending on the member, it is combined with concrete to reinforce the steel, and this is called a composite truss.

When constructing a bridge deck slab on a truss structure or a girder of a composite truss structure, a formwork can be installed to place the slab on site or use a precast deck plate. However, there is a deficiency in terms of safety and efficiency of construction, and the necessity of a precast deck plate or construction method to improve this is recognized.

Registered Patent Publication No. 10-0978882 (published on May 18, 2009) Registered Patent Publication No. 10-0635137 (published on May 11, 2006) Registered Patent Publication No. 10-0794444 (published on November 9, 2006)

An object of the present invention is to provide a precast deck plate synthesized with a truss structure capable of increasing construction convenience and efficiency of the precast deck plate and reducing material costs, and a slab construction method using the same.

The present invention for achieving the above object is, in a rectangular precast deck plate, as a truss structure located under the concrete panel and a coupling groove formed as a groove or hole along a regular interval on the lower surface of the concrete panel, the vertical horizontal A truss member in which a plurality of vertical members are fixed side by side between the upper chords and the lower chords arranged in such a manner that a plurality of yarns are obliquely fixed between the vertical members and the upper chords are formed to protrude vertically upward, and the coupling groove It includes a connecting member formed at the same interval as the interval, and the connecting member is inserted into the coupling groove.

Alternatively, in a rectangular precast deck plate, a coupling groove formed as a groove or a hole along a predetermined distance on the lower surface of the concrete panel and a truss structure located under the concrete panel, wherein a plurality of bottom chords are arranged side by side. A truss member in which horizontal members of the truss member are fixed side by side, a plurality of vertical members are fixed to the lower chord, and a plurality of thread members are inclinedly fixed between the vertical members, and a connecting member formed vertically upwardly protruding from the vertical member of the truss member, The connecting member is inserted into the coupling groove.

Preferably, the coupling groove is formed as a hole through the concrete panel, and the connecting member includes a shape capable of binding, and the lifting operation of the precast deck plate by binding a wire to the connecting member at the top of the concrete panel This is possible.

In addition, preferably, it further comprises a support plate formed horizontally between the vertical member and the connecting member, to stably support the weight of the concrete panel.

And, preferably, the concrete panel is embedded with a reinforcing material, the reinforcing material is exposed inside the coupling groove, a fastener is formed in the exposed portion of the reinforcing material, and the fastener is inserted into the coupling groove and It is fastened and fixed.

Alternatively, in the method of constructing a slab for a bridge using a precast deck plate, the steps of (a) integrally manufacturing the precast deck plate and (b) mounting the precast deck plate of step (a) on an alternating or pier Includes steps.

Alternatively, in the method of constructing a slab for a bridge using a precast deck plate, (a) separately manufacturing a concrete panel and a truss member, and (b) mounting the truss member of the step (a) on an alternating or pier And (c) mounting the concrete panel of step (a) on the truss member of step (b).

According to the present invention, since the precast deck plate and the truss structure can be synthesized and mounted on an alternating or pier, the efficiency of construction is increased. In addition, if the truss girder is installed first, it can be installed by inserting the concrete panel into the connecting member formed on the girder, so it is convenient and safe to mount. In addition, since the concrete panel can replace the top chord of the truss structure, the use of steel is reduced, so there is an advantage of saving material cost.

1A and 1B show side and top views of the precast deck plate according to the first embodiment of the present invention, respectively.
2A and 2B show a longitudinal side portion and a transverse side portion of a precast deck plate according to a second embodiment of the present invention, respectively.
3 is a cross-sectional view of a coupling groove of the precast deck plate according to the first embodiment.
4A and 4B show a side cross-sectional view and an upper view of the coupling groove portion of the precast deck plate according to the third embodiment of the present invention, respectively.
Figure 5 shows the construction method according to the present invention in order.
6 is a diagram illustrating another construction method according to the present invention in sequence.

Specific structural or functional descriptions presented in the embodiments of the present invention are exemplified only for the purpose of describing the embodiments according to the concept of the present invention, and the embodiments may be implemented in various forms according to the concept of the present invention. In addition, it should not be construed as limited to the embodiments described herein, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

The terms used in the present specification are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

Hereinafter, the present invention will be described with reference to the accompanying drawings. In describing the present invention, when it is determined that a description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted.

1A and 1B illustrate side and upper plane views of the precast deck plate 100 according to the first embodiment of the present invention, respectively. For convenience of explanation, the concrete panel 110 and the lower truss structure are separated and illustrated.

The precast deck plate 100 has a concrete panel 110 and a coupling groove 111 formed under the concrete panel 110, and may include a truss member 120 connected to the lower portion of the concrete panel 110. . The concrete panel 110 and the truss member 120 are connected to each other by inserting a connecting member 130 into the coupling groove 111.

Referring to FIG. 1B, the concrete panel 110 is a precast concrete product, and the overall shape is formed in a rectangular shape, but the thickness may be variously formed according to the thickness of the slab. The coupling groove 111 formed on the lower surface of the concrete panel 110 may be formed as a wedge-shaped groove or hole. Since the coupling groove 111 becomes a connection part connecting the concrete panel 110 and the truss member 120, the position of the coupling groove 111 may be different depending on the structure of the truss member 120.

1A, the truss member 120 is inclined between a plurality of vertical members 123 and the vertical members 123 fixed in parallel between the upper chord 122 and the lower chord 121 disposed vertically. It includes a plurality of fixed yarns 124. A connecting member 130 protruding in the vertical direction is formed on the upper part of the upper current 122.

In addition, a plurality of upper chords 122 and lower chords 121 may be formed in parallel under the concrete panel 110, and the plurality of upper chords 122 and lower chords 121 may be horizontal or inclined It can be connected to each other by means of sand to form a structure.

The truss member 120 is a steel material such as a pipe or H-beam having a high section modulus and excellent rigidity, and may be connected to each other by welding or bolting.

The connecting member 130 is inserted into the coupling groove 111 to connect the concrete panel 110 and the truss member 120. Accordingly, it has an appropriate shape according to the shape of the coupling groove 111, and a plurality of them are formed at regular intervals according to the truss structure. In addition, the connecting member 130 is formed in a portion where the upper chord 122 and the vertical member 123 meet in order to stably support the load of the concrete panel 110.

2A to 2B illustrate a precast deck plate 200 according to a second embodiment of the present invention from a longitudinal side and a transverse side, respectively. For convenience of explanation, the concrete panel 210 and the lower truss structure are separated and illustrated.

2A, the truss member 220 of the precast deck plate 200 includes a lower chord 221 and a plurality of vertical members 223 and the vertical members 223 fixed to the lower chord 221 at regular intervals. It includes a sand material 224 fixed to be inclined between the.

The coupling groove 211 formed in the concrete panel 210 is connected to the connecting member 230 formed in the truss member 220. Instead of having a top chord in the truss member 220, a support plate 231 is formed to support the load of the concrete panel 210 in a large area.

The base plate 231 is formed under the connecting member 230 and includes a shape suitable for supporting the weight of the slab. Unlike the precast deck plate 100 of the first embodiment, the precast deck plate 200 of the second embodiment does not have a top chord in the truss member 220, and instead, the concrete panel 210 replaces the top chord. The concrete panel 210 has the compressive strength or tensile strength required in the design to replace the top chord.

2B shows a side surface of the precast deck plate 200 in the transverse direction. A plurality of bottom chords 221 are formed in parallel with each other under the concrete panel 210, and the plurality of bottom chords 221 are connected by a horizontal member 225, and between the plurality of vertical members 223 are sand material 224 It is connected to.

Preferably, in the truss member of the present invention, one end of the yarn material may be fixed to the middle of the vertical material, and the other end may include a downwardly inclined yarn material that is fixed to the lower chord. In addition, one end of the sand material may include an upwardly inclined sand material having one end fixed to the middle of the vertical material, inclined upward, and having a connecting material at the other end.

That is, an upwardly inclined yarn and a downwardly inclined yarn are respectively connected to a middle portion of the vertical material, and a symmetrical structure may be formed based on the vertical material. Therefore, in this truss structure, each configuration of the truss can form a “*” shape at the center of the vertical member.

3 shows a cross-section of the coupling groove 111. The coupling groove 111 of the present invention may include a groove or a hole, but FIG. 3 shows a case where the coupling groove 111 penetrates the concrete panel 110 and is formed as a hole. The connecting member 130 is inserted into the coupling groove 111 to connect the truss member 120 and the concrete panel 110.

The connecting member 130 may be formed in a form capable of binding to raise a heavy object. The connecting member 130 may include a shape such as a hook hook or hook, and may be bound to a shackle or a clasp connected to the wire end of the crane.

Therefore, when the precast deck plate 100 is raised and mounted on a bridge or pier, the wire of the crane can be directly bound to the connector 130 through the coupling groove 111. This allows the precast deck plate 100 to be integrally lifted, and there is an effect that it is not necessary to separately make a binding tool on the concrete panel 110 or the truss member. After the installation work is finished, the empty space of the coupling groove 111 is filled with concrete or mortar to finish.

4A to 4B are side cross-sectional views and an upper portion of the precast deck plate 300 according to the third embodiment of the present invention, respectively. In the truss member according to the third embodiment, a top chord is omitted, but a reinforcing material 322 may be embedded in the concrete panel 310 as reinforcement for this. The reinforcing member 322 is made of a steel material such as a pipe or H-beam having a high section modulus and excellent rigidity, and may be formed in plural. The reinforcing material 322 is embedded in concrete, but is exposed in the coupling groove 311 and includes a fastener 340 in the exposed portion.

The fastener 340 is formed in a form capable of being coupled to the connector 330. When the concrete panel 310 and the truss member 320 are coupled, the fastener 340 and the connecting member 330 are fastened. In FIGS. 4A to 4B, the fastener 340 is represented by a member having a hole, and the connector 330 is inserted into the hole, but a known method may be used in consideration of construction efficiency. . Includes those that can be appropriately modified by a person of ordinary skill in the technical field to which the present invention pertains (hereinafter, also referred to as “a person skilled in the art”).

The reinforcing member 322 is combined with the truss member to serve as a top chord. Concrete is strong in compressive force, but weak in tensile force, and since the reinforcement material 322 is strong in tensile force, the weakness of concrete can be compensated. The compressive force or tensile force generated in the truss structure is transmitted to the reinforcing member 322.

Referring to FIG. 4B, a top view of the precast deck plate 300 can be seen, and a structure in which a plurality of reinforcing members 322 are combined is shown. The reinforcement material 322 may be embedded in the concrete panel 310 in an appropriate structure according to the design.

5 to 6 are sequential views illustrating a method of constructing a slab of a bridge using the precast deck plate of the present invention. For convenience of explanation, the precast deck plate 100 according to the first embodiment is expressed and illustrated.

The bridge slab construction method according to the present invention uses the precast deck plate of the present invention. However, in the construction method, a precast deck plate in which a concrete panel and a truss member are combined may be integrally manufactured, or a concrete panel and a truss member may be separated and manufactured separately.

Figure 5 shows the sequence of the bridge slab construction method according to the present invention, manufactured in step (a) and the step (a) in which the precast deck plate according to the present invention is integrally manufactured in a factory and transported to the site. It includes the step (b) of mounting the precast deck plate on the pier or the abutment.

In addition, Figure 6 is another construction method of the bridge slab according to the present invention, the concrete panel and the truss member of the present invention produced in the step (a) and the step (a) in which the concrete panel and the truss member of the present invention are separately manufactured and transported to the site. (B) mounting the truss member on a pier or abutment, and (c) mounting the concrete panel manufactured in the (a) step on the upper portion of the truss member mounted in the (b) step.

As the deck plate is manufactured in an optimal condition in the factory with such a precast method, the quality of concrete is improved compared to the on-site construction, and construction interference is reduced because the construction is performed in a separate place rather than the construction site. In addition, it is possible to pre-fabricate, thus reducing the amount of time required.

On the other hand, a person skilled in the art to achieve optimal cost and reduction in construction time considering product production volume, production cost, production speed and quality, distance from the site, capacity of transport vehicles, and on-site crane capacity at the concrete panel production site or truss member production site. Will choose appropriately.

The precast deck plate of the present invention may be widely used in a slab for construction or civil works within a range where construction conditions are acceptable.

The concrete panel according to the present invention may be manufactured to have the same thickness as the designed bridge slab thickness, or may be manufactured to be thinner than that, and may be combined with the cast-in-place concrete later. When the concrete panel is made thin, a shear connector may be included on the upper surface for bonding strength with the cast-in-place concrete.

It will be apparent to those skilled in the art that the present invention described above is not limited by the above-described embodiments and the accompanying drawings, and various substitutions, modifications and changes are possible within the scope of the technical spirit of the present invention.

100: Precast deck plate according to the first embodiment of the present invention
110: concrete panel
111: coupling groove
120: truss member
121: Ha Hyeon
122: phase present
123: vertical material
124: Sajae
130: connector
200: Precast deck plate according to the second embodiment of the present invention
210: concrete panel
220: truss member
221: Ha Hyeon
223: vertical material
224: private material
225: horizontal material
230: connector
231: base plate
300: Precast deck plate according to the third embodiment of the present invention
310: concrete panel
320: truss member
321: Ha Hyeon
322: reinforcement
323: vertical material
324: Sajae
330: connector
331: base plate
340: fastener

Claims (7)

In the rectangular precast deck plate,
A coupling groove formed as a groove or hole along a regular interval on the lower surface of the concrete panel;
A truss structure positioned under the concrete panel, wherein a plurality of vertical members are fixed side by side between an upper chord and a lower chord arranged vertically and horizontally, and a plurality of sand members are inclinedly fixed between the vertical members; And
It is formed protruding vertically upward from the upper chord, and includes a connecting member formed at the same interval as the interval of the coupling groove,
Precast deck plate, characterized in that the connecting member is inserted into the coupling groove. In the rectangular precast deck plate,
A coupling groove formed as a groove or hole along a regular interval on the lower surface of the concrete panel;
As a truss structure located under the concrete panel, a plurality of horizontal members are fixed side by side between a plurality of bottom chords arranged side by side, a plurality of vertical members are fixed to the bottom chord, and a plurality of sand members are inclined between the vertical members. A fixed truss member; And
It includes a connecting member protruding vertically upward on the vertical member of the truss member,
Precast deck plate, characterized in that the connecting member is inserted into the coupling groove. The method according to claim 1 or 2,
The coupling groove is formed as a hole penetrating the concrete panel, the connecting member including a shape capable of binding, the precast deck, characterized in that the lifting operation is possible by binding a wire to the connecting member at the top of the concrete panel plate. The method of claim 2,
A precast deck plate, characterized in that it stably supports the weight of the concrete panel, further comprising a support plate formed horizontally between the vertical member and the connecting member. The method of claim 2,
The concrete panel is embedded with a reinforcing material, the reinforcing material is exposed from the inside of the coupling groove, a fastener is formed in the exposed portion of the reinforcing material, and the fastener is fastened with the connector inserted into the coupling groove to be fixed. Precast deck plate, characterized in that. In the slab construction method of a bridge using the precast deck plate of claim 1 or 2,
(a) integrally manufacturing a precast deck plate;
(b) mounting the precast deck plate of step (a) on an alternate or pier;
Slab construction method of a bridge using a precast deck plate comprising a. In the slab construction method of a bridge using the precast deck plate of claim 1 or 2,
(a) separately manufacturing a concrete panel and a truss member;
(b) mounting the truss member manufactured in step (a) on the bridge or pier;
(c) mounting the concrete panel produced in step (a) on the upper portion of the truss member in step (b);
Slab construction method of a bridge using a precast deck plate comprising a.

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