KR20200065789A - Precast concrete block for arch structure construction and arch structure using the block and its construction method - Google Patents

Abstract

Disclosed are a precast concrete block for arch structure construction, an arch structure using the same, and a construction method thereof. According to the present invention, the precast concrete block for arch structure construction comprises: a pair of sidewalls protruding upwards from both ends in the longitudinal direction of a floor plate formed in a rectangular panel shape to be integrally formed side by side to face each other to form a groove to be filled with poured concrete therebetween; a shear key arranged on the outer surface of the sidewalls; and at least one connection member for a hinge function installed on the upper end of the sidewalls. A wall plate is installed on the front and back of a block assembly formed by longitudinally connecting a plurality of the precast concrete blocks while coming in contact with each other to fill an upper portion with a filler while both ends of an arch structure are installed to be supported on a bridge post to construct a bridge or a tunnel. According to the present invention, a unit precast concrete block having a weight reduced by forming a groove can be used as a base material to effectively secure rapid construction efficiency and economic efficiency by handling ease by weight reduction and manufacturability improvement.

Description

Precast concrete block for arch structure construction and arch structure using the block and its construction method

The present invention relates to an arch structure constructed for use as an arched bridge or a medium-sized open-ended tunnel, and more particularly, to a precast concrete block for building an arch structure and an arch structure using the block and a construction method therefor will be.

In general, an arch-type concrete structure, which is mainly constructed for use as an open-type tunnel such as a medium-sized or small-scale river bridge or an ecological tunnel, is effectively used considering the structural mechanical advantages and aesthetic aspects of the arch. It is expanding the field of application by adding the advantages of concrete and bonding technology.

On the other hand, prefabricated precast methods that are applied to existing arch structures have been used in large-scale ramen-type structures on short-span bridges because economical efficiency is ensured when the span is more than a certain length. In this type of construction, processes such as formwork installation, rebar assembly, on-site casting and curing are performed directly on site, so strict process control and safety management are required more strictly during construction.

In short, in the case of the existing arch structure, the emphasis is on the method of manufacturing the block, the lateral reinforcement method when mounting, and the reinforcing material for arch formation during lifting, but among the fabrication methods of the block, the reinforced plastic elastomer is reinforced to the hinge part to provide screed concrete Due to the additional introduction method and the method of using steel materials, construction efficiency and economic efficiency are deteriorated as an additional upper casting process is required.

In addition, since the existing arch structure is manufactured with a width per unit length, concrete is placed and connected in the field to increase the stiffness in the transverse direction when multiple rows are arranged in the throttle direction. In addition to being complicated, the steel used for arching during lifting is structurally unnecessary, and therefore, it is preferable in terms of durability to exclude the use of a reinforcing material.

Therefore, in recent years, a more economical and efficient precast concrete arch construction system is required by reducing the use of reinforcing bars while simultaneously improving the limitations in transportation of existing precast concrete arch structures to minimize rapid construction and environmental damage. have.

The present invention has been derived under the technical background as described above, and the above-mentioned problems of the background art are contents that the applicant has possessed for the derivation of the present invention or learned in the derivation process of the present invention, and must be applied for the present invention. It cannot be said that it was previously known to the public.

Republic of Korea Registered Patent Publication No. 10-1852083 Republic of Korea Registered Patent Publication No. 10-1735039 Republic of Korea Registered Patent Publication No. 10-1662036 Republic of Korea Registered Patent Publication No. 10-1524238 Republic of Korea Registered Patent Publication No. 10-1196461 Republic of Korea Registered Patent Publication No. 10-1157638 Republic of Korea Registered Patent Publication No. 10-1099885 Republic of Korea Registered Patent Publication No. 10-0943044

The present invention was created to improve this in view of the problems and limitations of the arch structure and its construction method using a conventional precast concrete block under the technical background as described above, and the object of the present invention is to improve the lightweight structure. It is intended to provide a precast concrete block for constructing an arch structure capable of economical and efficient rapid construction by improving the ease and efficiency of transport and handling in construction by the self-weight reduction, and an arch structure using the block and its construction method.

Another object of the present invention is the arch structure capable of more economical and efficient rapid construction by effectively securing stability and assembling workability by concrete composite structure according to the provision of the formwork function and role of the block itself, excluding the operation and reinforcement of complex formwork. It is to provide a precast concrete block for construction and an arch structure using the block and a construction method therefor.

In order to achieve the above object, the precast concrete block for constructing an arch structure according to the present invention is a bottom plate made of a rectangular panel shape, and protrudes upward on both side ends along the longitudinal direction of the bottom plate to be parallel to each other. A pair of sidewalls integrally formed to face each other and provided with grooves to allow filling of pour concrete to be formed therebetween, a shear key provided on an outer surface of the sidewalls, and an upper end of the sidewalls It characterized in that it comprises at least one connecting member for the hinge function installed on.

And, in order to achieve the above object, the arch structure using the precast concrete block according to the present invention is connected to the front side of the block assembly formed in the longitudinal direction in a state where the side walls of the plurality of unit precast concrete blocks are in contact. In the arch structure constructed to be built into a bridge or a tunnel by filling a filling material on the upper part in a state where each wall plate is installed at the rear and both ends of the arch structure formed by lifting are supported to alternately, the precast concrete block is , The bottom plate made of a rectangular panel shape, and protrudes upward on both side ends along the longitudinal direction of the bottom plate so as to be integrally formed to face each other in a parallel state so that a recess portion allowing filling of pour concrete is formed therebetween. It comprises a pair of sidewalls provided, a shear key provided on each side of the sidewalls, and at least one connection member for a hinge function installed on the top of the sidewalls, the hinge function connection When the block assembly is formed, the member is bound in a connected state by a binding member, and the shear key is coupled to fit complementarily when forming the arch structure by lifting the block assembly. .

In addition, the construction method of the arch structure using the precast concrete block according to the present invention to achieve the above object, forming a block assembly by connecting a plurality of precast concrete blocks in the longitudinal direction so that the side walls are in contact Wow; Installing both end portions of the arch structure formed by lifting the block assembly so as to be supported and mounted on alternate grounds; Installing wall plates on the front and rear of the block assembly, respectively; And filling a filling material on an upper portion of the block assembly.

In the precast concrete block for building an arch structure according to the present invention having the configuration as described above, and the arch structure using the block and the construction method thereof, the side wall of the precast concrete block has an inner wall surface from the top to the bottom. It is preferable to have a haunch that is formed to be thicker to form a gradual inclined surface toward the longitudinal central axis of the bottom plate.

In addition, it is preferable that the haunch of the precast concrete block is provided such that the connecting portions of the upper end of both sides of the bottom plate and the inner wall of the side wall are formed in a rounded curved surface.

In addition, the shear key of the precast concrete block is a complementary structure formed with a protruding structure (凸) and a groove structure (凹) selectively on one of the outer wall surface and the other of the outer wall surface of the side wall It is preferably provided.

According to an aspect of the present invention, it is preferable that the connecting member for the hinge function is formed of a handle or a ring shape in which a reinforcing bar or a steel bar is installed in the form of a bridge on the top of the side wall to cross the recess.

According to another aspect of the present invention, the connecting member for the hinge function may have a configuration in which pin members that are independently installed to face each other on the upper end of the side wall and are arranged side by side at a corresponding position are provided.

According to another aspect of the present invention, the bottom plate may have a configuration in which reinforcing bar seating grooves formed so that reinforcing bars are seated and excreted when concrete is placed are further provided.

According to one aspect of the present invention, it is preferable that the binding member is formed of a corrugated ring having a “∽” shape structure that is formed to be staggered at the fixed ends of the connecting member for the hinge function, respectively.

According to another aspect of the present invention, the binding member is wound to cross each other at a fixed end of the connecting member for the hinge function, a belt member connected in a closed curve state, and a "∽" shape installed to connect both ends of the belt member It may have a structure including a corrugated ring of the structure.

According to the precast concrete block according to the present invention and the arch structure using the block and its construction method, the following operational effects can be obtained.

First, as the precast concrete block of light weight unit can be used as the base material by the formation of the recess, the efficiency and rapid economic efficiency of rapid construction is effective by improving the ease of transport and handling in construction through the improvement of productivity and self-weight reduction. Can be secured.

Second, when forming the arch structure, the cross-section structure in which the upper part of the precast concrete block is formed as an open groove part effectively constructs a wall that can effectively secure the fluidity and effectively respond to the axial force when pouring topping concrete. can do.

Third, while having sufficient resistance to the tensile force acting on the arch structure, it is possible to fundamentally prevent the phenomenon from occurring in the longitudinal direction, thereby securing structural stability.

Fourth, due to the structure advantageous for load distribution, it is possible to secure durability according to the exclusion of the reinforcing material while effectively minimizing maintenance costs.

Fifth, the method of forming the hinge structure for connecting the blocks to form the arch structure is simple and easy to secure economical construction efficiency.

Sixth, it is possible to effectively secure construction efficiency and economic efficiency by excluding the operation of complex formwork and the use of structurally unnecessary steel.

1 is a schematic perspective view showing a precast concrete block for building an arch structure according to the present invention.
Figure 2 is a schematic cross-sectional view taken along line II-II of Figure 1;
Figure 3 is a schematic cross-sectional view showing an exemplary type for the haunch (haunch) shape structure of the precast concrete block for building an arch structure according to the present invention.
Figure 4 is a schematic cross-sectional view showing another embodiment in which the main part of the precast concrete block according to the present invention is modified.
Figure 5 is a schematic cross-sectional view showing another embodiment in which the main part of the precast concrete block according to the present invention is modified.
Figure 6 is a schematic perspective view showing a precast concrete block according to another embodiment of the present invention.
7 is a perspective view schematically showing an arch structure using a precast concrete block according to the present invention.
8 is a front view schematically showing a construction structure for each type of arch structure using a precast concrete block according to the present invention.
9 is a schematic perspective view showing an enlarged main part of an arch structure using a precast concrete block according to the present invention.
10 to 12 are schematic process flow charts shown to explain a construction method of an arch structure using a precast concrete block according to the present invention.

Hereinafter, a precast concrete block for building an arch structure according to the present invention and an arch structure using the block and a construction method thereof will be described in detail with reference to the accompanying drawings. The following description and the accompanying drawings are only preferred embodiments of the present invention, and the precast concrete block for building an arch structure according to the present invention described in the claims and the arch structure using the block and the construction method thereof are limited. no.

1 is a schematic perspective view showing a precast concrete block for building an arch structure according to the present invention, and FIG. 2 is a schematic cross-sectional view taken along line II-II of FIG. 1.

1 and 2, the precast concrete block 100 for building an arch structure according to the present invention includes a bottom panel 110 formed in a rectangular panel shape and along the longitudinal direction of the bottom plate 110. A pair of sidewalls 120 and the sidewalls 120 which are formed to be integrally formed to face each other in a state of protruding upward on both side ends so as to form grooves 101 allowing filling of pour concrete therebetween. ) Is configured to include a shear key 130 provided on the outer surface of each and at least one hinge function connecting member 140 installed on the upper side of the side wall 120.

According to the present invention, the side wall 120 has an inner wall surface toward the bottom from the top to the bottom of the longitudinal center axis (C) of the bottom plate 110 to form a gradual inclined surface to form a thicker hatch (haunch) 102 is provided.

In addition, the outer wall surface of the side wall 120 is formed to form a gradually inclined surface toward the longitudinal center axis C of the bottom plate 110 as it goes from the top to the bottom. Accordingly, the precast concrete block 100 according to the present invention, the gap between the side wall 120 with the other precast concrete block 100 disposed to be adjacent to the lower end, the smaller the gap between the "∧" shape (Fig. 10 and 11A).

Figure 3 is a schematic cross-sectional view showing an exemplary type (a) to (d) for the shape of the haunch (haunch) shape of the precast concrete block for building an arch structure according to the present invention. Here, the same reference numerals as those in the above-described drawings denote the same components, and detailed descriptions of the components will be omitted.

Referring to FIG. 3, the heonchibu 102 is the distribution of the stress concentration and the effective length of the cross-section due to the smooth stress transmission to the connecting portion of the inner wall surface of the side wall 120 and both side ends of the upper surface of the bottom plate 110. It is preferable to be formed to form a rounded curved surface for augmentation, etc., for example, it can be designed and manufactured in various shape structures according to construction conditions or environments. Accordingly, the precast concrete block 100 for building an arch structure according to the present invention can effectively adjust the weight to an appropriate state, thereby effectively obtaining a self-weight reduction effect during transportation or construction.

In addition, the heonchibu 102 may be designed and manufactured to have a shape structure of various shapes according to the height of the side wall 120 so that the cast-in-place concrete can be compactly poured. Accordingly, the precast concrete block 100 for building an arch structure according to the present invention can provide its own formwork role and function. As a result, it is possible to secure the fluidity so that the concrete is compactly poured when pouring concrete, and at the same time, it is possible to effectively construct a concrete composite wall that can effectively respond to axial forces.

The shear key 130 is selectively on the outer wall surface of one of the side walls 120 (the right or left wall of the drawing) and the outer wall surface of the other (the left or right wall of the drawing), respectively. The protruding structure (凸) and the groove structure (구비) provided are formed integrally, and these protruding structures (凸) and the groove structure (凹) have a shape structure formed to fit complementarily.

For example, the shear key 130 is on the outer wall surface of the right side wall 120 of the precast concrete block 100 for building an arch structure according to the present invention as illustrated in FIGS. 1 and 2. The convex protruding structure (凸) is provided to be integrally formed, and a concave groove structure (凹) is provided to be integrally formed on the outer wall surface of the left side wall (120).

Therefore, the precast concrete block 100 for building an arch structure according to the present invention protrudes from the right side wall 120 of the adjacent precast concrete block 100 during longitudinal assembly in which the side walls 120 form a state in contact with each other. The structure (凸) and the groove structure (凹) of the left sidewall (120) are assembled in a complementary fit, thereby effectively acting against the shear force acting on the arch structure.

On the other hand, in the present invention, the shear key 130 illustrates an example in which a rectangular protruding structure and a groove structure are applied, but the present invention is not limited by the exemplary shape structure. , For example, it may be applied by transforming into various types of concavo-convex shape structures such as a circle or a square.

The hinge function connecting member 140 is provided to form a handle or a ring on the top of the side wall 120 so as to cross the recess 101, for example, both ends of a reinforcing bar or steel bar of a constant length However, it may have a configuration installed in the form of a bridge in a state of being bent or bent upward while being fixed to the upper end of the side wall 120.

The hinge function connecting member 140 is disposed adjacent to each other in the process of constructing an arch structure (see reference numeral 200B in FIGS. 7 and 8 and 12) using the precast concrete block 100 according to the present invention. Block assembly (FIG. 10 and FIG. 10) is connected to each other by a connecting member 140 for hinge function of a plurality of unit precast concrete blocks 100 and a binding member for reinforcement (refer to reference numeral 10 in FIG. 9), respectively. 11, reference numeral 200A), and acts as a hinge member when lifting the block assembly 200A.

According to another aspect of the present invention, the hinge function connecting member 140 may also be used for the purpose of mounting and lifting structure.

Figure 4 is a schematic cross-sectional view showing an embodiment provided in a state in which the connecting member for the hinge function of the precast concrete block according to the present invention is modified, referring to this, the hinge function connecting member 140 is the side wall ( Reinforcing bars or steel bars may be installed at the top of each 120 in the form of independent pin members 140p. Here, the same reference numerals as those in the above-described drawings denote the same components, and detailed description of the components will be omitted.

According to an aspect of the present invention, it is preferable that the hinge function connecting member 140 or the pin member 140p is installed such that one pair is disposed at the upper end of the front end and the rear end of the side wall 120, respectively.

According to another aspect of the present invention, the hinge function connecting member 140 or the pin member 140p may have a configuration that is installed as a single unit in the center of the side wall 120.

In short, the connecting member 140 or the pin member 140p for the hinge function is not limited so that the installation quantity and location are specified, and the design and the weight or thickness of the precast concrete block 100 according to the present invention and It is possible to apply various types of embodiments according to the production specifications.

On the other hand, Figure 5 is a schematic cross-sectional view showing another embodiment in which the main part of the precast concrete block according to the present invention is modified, the same reference numerals in the drawings shown above indicate the same components, the Detailed description of the components will be omitted.

Referring to Figure 5, the precast concrete block 100 according to the present invention is a reinforcement formed in a groove shape along the longitudinal direction so that the reinforcing reinforcement is seated and buried when the concrete is placed on the bottom plate 110 of the recess 101 Seating groove 111 may have a configuration that is further provided. Accordingly, the reinforcing member in the yellow direction can be selectively applied by reinforcing the reinforcing bar in the reinforcing groove 111. Such a configuration is intended to effectively secure stability for 3D behavior.

6 is a schematic perspective view showing a precast concrete block according to another embodiment of the present invention.

Referring to FIG. 6, the precast concrete block 100A according to another embodiment of the present invention protrudes upward on both side ends along the longitudinal direction of the bottom plate 110 made of a rectangular panel shape so as to face each other in a parallel state. The concave groove is formed by connecting a pair of side walls 120 and a front end portion and a rear end portion of the side wall 120 to be formed integrally to form a concave groove portion 101 that allows filling of pour concrete between them. It has a configuration further provided with a front end wall 121 and a rear end wall 122 provided to close both front and rear openings of the 101. According to this configuration, it is possible to secure an effective fluidity when pouring concrete because it has a cross-section effective for axial force during the formation of the arch structure and the groove portion 101 is opened on the upper side by being surrounded by walls on all sides. Here, the same reference numerals as those in the above-described drawings denote the same components, and detailed description of the components will be omitted.

7 is a perspective view schematically showing an arch structure using a precast concrete block according to the present invention. And Figure 8 is a front view schematically showing the construction structure of each type of arch structure using a precast concrete block according to the present invention.

7 and 8, the arch structure 200 using a precast concrete block according to the present invention is a plurality of units such that the unit precast concrete block 100 as described by FIGS. 1 to 6 are adjacent to each other. Arranged in the direction, the side ends of the arch structures 200B formed by lifting the center portion of the block assembly 200A formed by connecting the side walls 120 to face each other are alternately constructed with base plates on the ground, respectively. 211) The wall plate 200C is installed at the front and rear of the block assembly 200A in a state mounted to be supported on the 212, so that the filling material 220 is filled at the top and is constructed as a bridge or tunnel.

The block assembly 200A has an arch structure in which each side wall 120 faces each other so that the unit precast concrete blocks 100 are adjacent to each other as illustrated in FIGS. 10 and 11A. 200B) in the state arranged in the longitudinal direction, the hinge function connecting member 140 is bound to be connected by the binding member 10. Accordingly, each side wall 120 of the unit precast concrete block 100 is connected so that the upper end is in contact with it, and at the same time, the lower end is formed so that a gap “s” in the form of “∧” that opens slightly as it goes down.

9 is a schematic perspective view showing an enlarged view of a main part of an arch structure using a precast concrete block according to the present invention, and shows a state in which the binding member 10 binds the hinge function connecting member 140 It seems.

Referring to FIG. 9(a), the binding member 10 is formed of, for example, a wavy ring having a “고리” shape structure having openings symmetrically positioned, and each opening is a connecting member 140 for the hinge function. It is preferable to be installed so as to be staggered on both sides of the fixed end.

According to one aspect of the present invention, it is preferable that the corrugated ring of the "∽" shape structure as described above is made of, for example, a metal or rubber material having a certain elasticity.

Referring to (b) of FIG. 9, the binding member 10 is wound around a fixed end of the connecting member 130 for the hinge function, so as to alternately cross each other, a belt member (B) connected in a closed curve state of an “∞” shape structure ) May have a configuration that is installed to connect the both ends of the corrugated ring. At this time, the belt member (B), for example, a string or a string or a wire having elasticity and toughness, such as a rubber band, may be employed.

In other words, the binding member 10 is provided to form a hinge portion made to enable high elasticity at the junction of the block assembly 200A, and acts to form an arch by itself when lifting the block assembly 200A.

The wall plate 200C is installed on the front and rear surfaces of the block assembly 200A, respectively, to form a wall that closes both front and rear openings of the recess 101 of the unit precast concrete block 100. do. Accordingly, the upper side of the recess 101 of the unit precast concrete block 100 is maintained in an open state, respectively.

On the other hand, according to another aspect of the present invention, according to another embodiment of the present invention described by FIG. 6, the front end wall 121 and the rear end wall 122 to close both front and rear openings of the recess 101 In the case of a block assembly in which a plurality of precast concrete blocks 100A having a connection are connected, the installation of the wall plate 200C may be omitted.

The arch structure 200B of the block assembly 200A through a lifting jig frame J and a rope using, for example, a crane (not shown), as illustrated in FIGS. 10 and 11 (a). When the central portion is lifted, the connecting member 130 for the hinge function by the binding member 10 functions to perform a hinge function in a state of being constrained to have a constant play. Accordingly, as each unit precast concrete block 100 sags downward at both sides of the lifting center due to its own weight, the gap s in the form of “∧” formed between adjacent sidewalls 120 is completely narrowed and interviewed. In the projecting structure (凸) constituting the shear key (130) and the groove structure (결) are formed to form an arch by being bound to complementarily fit. Accordingly, it is possible to effectively prevent the sliding due to the shear force between the precast concrete blocks of each unit during bulk lifting for forming the arch of the block assembly 200A and connect them in a solidly integrated state.

The arch structure 200B is constructed so that the filling material 220 is filled in the upper part in a state where both ends are installed to be supported by the alternations 211 and 212, respectively, so that the arch structure using the precast concrete block 100 according to the present invention 200 is built as a bridge or tunnel.

10 to 12 are schematic process flow charts shown to explain a construction method of an arch structure using a precast concrete block according to the present invention.

10 and 11, the construction method of the arch structure 200 using the precast concrete block according to the present invention is first illustrated in the state diagram shown in solid line in FIG. 10 and FIG. 11 (a). Likewise, the plurality of precast concrete blocks 100 are connected in the longitudinal direction to form a state where the sidewalls 120 face each other to form the block assembly 200A.

The precast concrete block 100 protrudes upward at both end portions along the longitudinal direction of the bottom plate 110 and the bottom plate 110 in the form of a rectangular panel, as described with reference to FIGS. 1 to 6. A pair of sidewalls 120 which are integrally formed to face each other in a side-by-side state and are formed to form grooves 101 allowing filling of pour concrete therebetween, and each of the sidewalls 120 on the outer surface of the sidewalls 120 It has a configuration consisting of a shear key (shear key) 130 and at least one connection member for hinge function 140 is installed on the top of the side wall 120.

According to the present invention, in the step of forming the block assembly (200A), the precast concrete block (100) is adjacent to each other, and each side wall (120) is arranged in the longitudinal direction so as to face each other. 140) is connected by binding with the binding member (10). Accordingly, each side wall 120 of the unit precast concrete block 100 is connected so that the upper end is in contact with it, and at the same time, a gap s having a “∧” shape is formed which spreads slightly as the lower end goes down.

In the next process, referring to the state diagram indicated by the dotted line in FIG. 10 and FIG. 11(b), the block assembly 200A through the lifting jig frame J and the rope using a crane (not shown) at the construction site Connect and salvage. At this time, in order to properly distribute the load when lifting the block assembly 200A, as illustrated in the drawing, the lifting jig frame J and the rope will cover the center of the block assembly 200A over a certain area. It is desirable to be connected as possible.

That is, when the block assembly 200A is lifted through a lifting jig frame J and a rope by using a crane (not shown) or the like, the connecting member 130 for the hinge function by the binding member 10 Will function as a hinge in the restrained state to have a constant play. Accordingly, as each unit precast concrete block 100 sags downward on both sides of the lifting center due to its own weight, the gap “s” in the form of “∧” formed between each adjacent side wall 120 is completely narrowed and interviewed In the projecting structure (凸) constituting the shear key (130) and the groove structure (결) are bound to complementarily fit to form an arch structure (200B). At this time, by the action of the shear key 130, it is possible to effectively prevent slipping due to the shear force between each unit precast concrete block and be connected in a solidly integrated state.

In the next step, as shown in (c) of FIG. 12, alternating ends 211 and 212 of both ends of the arch structure 200B formed by lifting of the block assembly 200A are respectively used as base plates on the ground. ) And installed in a mounted state.

Subsequently, as illustrated in FIG. 12D, wall plates 200C are installed at the front and rear of the block assembly 200A constituting the arch structure 200B, respectively. Accordingly, the upper side of the recess 101 of the unit precast concrete block 100 is maintained in an open state, respectively.

As a final step, as illustrated in (e) of FIG. 12, the filling material 220 is filled in the upper portion of the unit precast concrete block 100 to prepare the precast concrete block according to the present invention such as an arched bridge or a tunnel. Construction of the used arch structure 200 is completed.

The present invention is not limited to the specific preferred embodiments described above, and various modifications can be made to any person skilled in the art to which the invention pertains without departing from the gist of the invention as claimed in the claims , And such changes are within the scope of the stated claims.

10: binding member
100: precast concrete block
101: recess
102: haunch
110: bottom plate
120: sidewall
121: shear wall
122: rear wall
130: shear key
140: connecting member
140p: pin member
200A: block assembly
200B: arch structure
200C: Wall plate
220: Chaeumjae
J: lifting jig frame

Claims (27)

A bottom plate 110 made of a rectangular panel shape;
A pair of protrusions protruding upwards on both side ends along the longitudinal direction of the bottom plate 110 so as to be integrally formed to face each other in a parallel state, and provided with a groove 101 that allows filling of pour concrete between them. Sidewall 120 of the;
A shear key 130 provided on an outer surface of the sidewall 120, respectively; And
Precast concrete block for building an arch structure, characterized in that it comprises;; at least one or more hinge function connecting member (140) installed on the upper side of the side wall (120). According to claim 1,
The side wall 120 is characterized in that the inner wall surface has a haunch (102) that is formed to be thicker to form a gradual inclined surface toward the longitudinal central axis of the bottom plate (110) toward the bottom. Precast concrete blocks for building arch structures. According to claim 2,
The haunch (102) is a precast for the construction of an arch structure, characterized in that the connecting portion of the inner wall surface of the upper side of both sides of the bottom plate 110 and the inner wall surface of the side wall 120 is formed as a rounded curved surface. Concrete blocks. According to claim 1,
The shear key (130) is provided with a projecting structure (凸) and groove structure (凹) formed to complementarily fit on one of the outer wall surface of the side wall 120 and the other of the outer wall surface selectively Characterized in that the precast concrete block for building an arch structure. According to claim 1,
The hinge function connecting member 140 is an arch structure construction characterized in that a rebar or a steel bar is installed in the form of a bridge in the form of a handle or a ring at the top of the side wall 120 so as to cross the recess 101. Precast Concrete Blocks. According to claim 1,
The hinge function connecting member 140 is a precast concrete for arch structure construction, characterized in that a pin member which is independently installed to face each other on the upper end of the side wall 120 is disposed side by side at a corresponding position. block. The method according to any one of claims 1 to 6,
Precast concrete block for building an arch structure, characterized in that the bottom plate 110 is further provided with a reinforcing bar seating groove 111 formed so that the reinforcing bar is seated and excreted when the concrete is placed. The bridge is filled with a filling material on the upper part in a state where both end portions of the arch structure formed by lifting the central portion of the block assembly formed by connecting in the longitudinal direction with the side walls of the plurality of unit precast concrete blocks in contact are respectively supported by the shifts In the arch structure is constructed to be built into the tunnel or,
The precast concrete block 100,
A bottom plate 110 made of a rectangular panel shape;
A pair of protrusions protruding upwards on both side ends along the longitudinal direction of the bottom plate 110 so as to be integrally formed to face each other in parallel, and provided with a concave groove 101 allowing filling of pour concrete therebetween. Sidewall 120 of the;
Shear keys (130) provided on the outer surface of the side wall (120), respectively; And
It comprises at least one or more hinge function connecting member 140 installed on the upper side of the side wall 120;
The connection member 140 for the hinge function is bound in a state connected by the binding member 10 when forming the block assembly,
The shear key (130) is an arch structure using a precast concrete block characterized in that it is coupled to fit complementarily when forming the arch structure by lifting the block assembly. The method of claim 8,
The side wall 120 is characterized in that it has a haunch (102) that is formed to be thicker to form a gradual inclined surface toward the longitudinal central axis of the bottom plate (110) as the inner wall surface goes from top to bottom. Arch structure using precast concrete blocks. The method of claim 8,
The haunch (102) is a precast concrete block using a precast concrete block characterized in that it is provided so that the connecting portion of the inner wall surface of the upper side and the side wall 120 of the bottom plate 110 is formed in a rounded curved surface Arch structure. The method of claim 8,
The shear key (130) is provided with a projecting structure (凸) and groove structure (凹) formed to complementarily fit on one of the outer wall surface of the side wall 120 and the other of the outer wall surface selectively Arch structure using a precast concrete block, characterized in that. The method of claim 8,
The hinge function connecting member 140 is a precast concrete characterized in that the rebar or steel bar is installed in the form of a bridge in the form of a handle or a ring on the top of the side wall 120 so as to cross the recess 101. Arch structure using blocks. The method of claim 8,
The hinge function connecting member 140 is an arch using a precast concrete block, characterized in that a pin member which is independently installed to face each other on the upper end of the side wall 120 is disposed side by side at a corresponding position. structure. The method of claim 8,
The binding member 10 is an arch structure using a precast concrete block, characterized in that it is made of a corrugated ring of a "∽" shape structure formed so as to be staggered to each of the fixed ends of the connecting member 140 for the hinge function. The method of claim 8,
The binding member 10 is of a "되는" shape structure installed to connect both ends of the belt member, and a belt member wound in a closed curve so as to cross each other at a fixed end of the connection member 140 for the hinge function. Arch structure using a precast concrete block, characterized in that it comprises a corrugated ring. The method according to any one of claims 8 to 15,
Arch structure using a precast concrete block, characterized in that the bottom plate 110 is provided with a reinforcement seating groove formed so that reinforcing bars are seated and excreted when concrete is poured. Forming a block assembly (200A) by connecting a plurality of precast concrete blocks (100) in the longitudinal direction such that the side walls (120) are in contact;
Installing the end portions of both sides of the arch structure 200B formed by lifting the block assembly 200A so as to be supported and mounted on alternate grounds 211 and 212, respectively; And
Filling the filling material 220 on top of the block assembly (200A); Construction method of the arch structure using a precast concrete block comprising a. The method of claim 17,
Between the step of installing the arch structure (200B) to be mounted on the alternation (211, 212), and filling the filling material (220) on top of the block assembly (200A), the front of the block assembly (200A) And a step of installing wall plates 200C on the rear, respectively, and the construction method of the arch structure using the precast concrete block. The method of claim 17,
The precast concrete block 100,
A bottom plate 110 made of a rectangular panel shape;
A pair of protrusions protruding upwards on both side ends along the longitudinal direction of the bottom plate 110 so as to be integrally formed to face each other in a parallel state, and provided with a groove 101 that allows filling of pour concrete between them. Sidewall 120 of the;
A shear key 130 provided on an outer surface of the sidewall 120, respectively; And
It comprises at least one or more hinge function connecting member 140 installed on the upper side of the side wall 120;
The hinge function connecting member 140 is bound in a state connected by a binding member 10 when the block assembly is formed,
The shear key (130) is a method for constructing an arch structure using a precast concrete block, characterized in that it is coupled to fit complementarily when forming an arch structure by lifting the block assembly. The method of claim 19,
The side wall 120 of the precast concrete block 100 has a thickness of an inner wall from the top to the bottom, so that the thickness of the bottom plate 110 is gradually thickened to form a gradual slope toward the central axis. Construction method of the arch structure using a precast concrete block, characterized in that provided with (102). The method of claim 19,
The haunch (102) of the precast concrete block (100) is characterized in that it is provided so that the connecting portion of the inner wall surface of the upper side of both sides of the bottom plate (110) and the side wall (120) is formed as a rounded curved surface Construction method of arch structure using precast concrete block. The method of claim 19,
The shear key 130 of the precast concrete block 100 has a protruding structure (凸) and a groove structure (凹) formed to fit complementarily different from any one of the outer wall surfaces of the side wall (120). Construction method of the arch structure using a precast concrete block, characterized in that it is selectively provided on one outer wall surface. The method of claim 19,
The connecting member 140 for the hinge function of the precast concrete block 100 is installed in the form of a bridge or a reinforcing bar or a steel bar at the top of the side wall 120 so as to cross the recess 101. Construction method of the arch structure using a precast concrete block, characterized in that made. The method of claim 19,
The connecting member 140 for the hinge function of the precast concrete block 100 is provided with pin members that are independently installed so as to be arranged side by side at corresponding positions, respectively, on the top of the side wall 120. Construction method of arch structure using precast concrete block. The method of claim 19,
The binding member 10 is a construction method of an arch structure using a precast concrete block, characterized in that it is made of a corrugated ring of a "∽" shape structure formed so as to be staggered on the fixed ends of the connection member 140 for the hinge function, respectively. . The method of claim 19,
The binding member 10 is of a "되는" shape structure installed to connect both ends of the belt member, and a belt member wound in a closed curve so as to cross each other at a fixed end of the connection member 140 for the hinge function. Construction method of the arch structure using a precast concrete block, characterized in that it comprises a corrugated ring. The method according to any one of claims 17 to 26,
Construction method of an arch structure using a precast concrete block, characterized in that the bottom plate 110 of the precast concrete block 100 is provided with a reinforcement seating groove formed so that reinforcing bars are seated and excreted during concrete pouring.

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