KR101196461B1 - Arch structure construction method using polygon arch block - Google Patents

Abstract

PURPOSE: A manufacturing method of an arched block assembly using polygonal unit concrete blocks is provided to improve structural efficiency by easily connecting multiple precast block assemblies in a longitudinal direction. CONSTITUTION: A manufacturing method of an arched block assembly using polygonal unit concrete blocks is as follows. Connectors integrated with upper connecting concrete are arranged in each housing spaces of a mold. Multiple unit concrete blocks are continuously formed by placing concrete inside the mold and curing the placed concrete. Unit concrete block connectors are installed on the top surfaces of the unit concrete blocks. An arched block assembly(100) is formed by placing and curing concrete to bury the connectors integrated with upper connecting concrete and the unit concrete block connectors therein. Crack guide joints are formed on the top surface of the upper connecting concrete. The mold is removed. [Reference numerals] (AA) Inner surface; (BB) Outer surface; (CC,DD) Corrugated connection

Description

ARCH STRUCTURE CONSTRUCTION METHOD USING POLYGON ARCH BLOCK}

The present invention relates to an arch block assembly manufacturing method using a polygonal unit concrete block. More specifically, in order to increase the longitudinal connection performance of the plurality of unit concrete blocks, the shape of the unit concrete block is formed into a polygon, and the upper portion of the unit concrete block is connected to each other with an upper connection concrete to manufacture an arch block assembly, and the arch The present invention relates to a method for manufacturing an arch block assembly in which a block assembly is engaged with each other through a corrugated connection to enhance shear connection performance.

Conventional arch structures are used to construct structures such as bridges, but when the arch structure is made in a curved shape in advance and fixed in a truck, it is very difficult to carry several arch structures simultaneously due to the curved shape. do.

Thus, the arch structure may be divided into a plurality of segments such as two segments or three segments, and each segmented block may be precast, and each of the blocks may be transported to the site to construct the arch structure through on-site assembly.

An example of installing the arch structure without using a copper bar is illustrated in FIG. 1A. That is, the connecting member 30 extending in the length direction in a state in which a plurality of precast blocks 11 having a curved shape having an outer surface length longer than that of the inner surface are arranged in a line so as to form an arch structure. A, integrally coupled to the curved outer surface of the precast block 11 corresponding to the upper surface of the arch structure to form one assembly, in the state before forming the arch structure, the plurality of precast block bodies (A) It is arranged in a line and has a flat configuration.

When the curved outer surface of the precast block assembly A is lifted to be an upper surface as shown in FIG. 1B, the precast block assembly A at both ends is erected to be supported by both supporting structures, and the precast block as shown in FIG. 1C. Arch structures 10 using a precast block assembly A made of a plurality of precast blocks 11 and a connecting member 30 while the respective blocks of the assembly A are pressed in the axial direction by contacting each other with each other. This is introduced.

At this time, it can be seen that the precast block assembly (A) is constructed so as to contact each other in the longitudinal direction, there is a problem that this longitudinal connection is not easy. That is, the construction is complicated, such as the use of other means for connecting the precast block assembly (A) in the longitudinal direction, there is a problem that it is not easy to ensure the shear connection performance in this case.

In the arch block assembly construction method in which the precast block assembly (A) is connected by installing in the longitudinal direction, the structural efficiency while making the longitudinal connection more easily (long distance and possible according to the improvement of shear connection performance) An object of the present invention is to provide an arch block assembly construction method using a polygonal concrete block capable of constructing the improved arch block assembly.

In order to achieve the above technical problem, the present invention forms a unit concrete block constituting the precast block assembly A in the longitudinal connection by forming the outer and inner surfaces of the precast block assembly A as a corrugated connection in a polygonal manner. It is produced under the formed one.

In this case, the unit concrete block of the precast block assembly (A) uses a polygonal concrete block, but the corrugated connection is naturally formed by the shape of the polygonal concrete block.

According to the present invention, in the construction of the arch block assembly, the precast block assembly (A) is constrained to each other in the longitudinal direction by the polygonal concrete block while making longitudinal connection easier. Long time can be achieved.

The scope of the present invention is shown by the following claims rather than the above description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

Figure 1a is a perspective view of a precast block assembly using a conventional connecting member,
Figure 1b is a lifting perspective view of the arch structure using a precast block assembly using a conventional connecting member,
Figure 1c is a construction of the arch structure using a precast block assembly using a conventional connection member,
Figure 2a and 2b is a production example of the precast block assembly (A) of the present invention,
3A, 3B, 3C, 3D, 3E and 3F are precast block assemblies A and combined perspective views according to the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

[Arch block assembly 100 manufacturing method of the present invention]

Arch block assembly 100 according to the present invention is largely divided into a method using an integrated mold and a method using an individual mold.

First, the method of using the integrated mold is, for example, as shown in Figure 2a,

By the arch curvature adjusting wedge plates 221 and 222 spaced apart from each other on the upper surface of the lower plate 210, the mold 200 having a plurality of spaced apart receiving spaces S having a box shape is installed.

Next, the upper connection concrete integrated connection member 120 is disposed in the upper portion of the mold 200 so that the upper portion of the upper connection concrete integrated connection member 120 is exposed to the upper mold 200. Placing and curing in the mold 200 to form a plurality of unit concrete blocks 110 in a row.

Next, the unit concrete block connecting member 140 is installed on the upper surfaces of the unit concrete blocks 110.

Next, the arch block connected to each other by the upper connection concrete 150 by placing and curing the concrete so that the upper connection concrete integrated connection member 120 and the unit concrete block connection member 140 is embedded The assembly 100 is formed, and the arc-shaped retaining crack-inducing joint 151 is formed on the upper connection concrete 150, and the mold 200 is demolded. As a result, it can be seen that the final arch block assembly 100 is formed in such a manner that the top is connected to each other.

At this time, the height h1 of the arch curvature adjusting both wedge plate 221 is formed to be larger than the height h2 of the arch curvature adjusting intermediate wedge plate 222 formed between the arch curvature adjusting both side wedge plate and the arch curvature adjusting both sides The height h2 of the wedge plates 222 is to maintain the same height.

As such, the reason why the height difference h1> h2 of the both sides of the arch curvature adjustment and the middle wedge plates 212 and 222 is to be suspended by the upper connection concrete integrated connection member 120 is installed. In this case, the arch curvature adjusting intermediate wedge plate 222 is manufactured and installed so that the curvature of the arch block assembly 100 can be easily adjusted without uniformly manufacturing the form as a form of lower light reciprocation.

At this time, the curvature may be referred to to adjust the gap between the sides of the unit concrete block 110 as an arch structure when the arch block assembly 100 is installed after lifting the arch curvature adjusting intermediate wedge plate ( 222 is prepared so that the width and height (h2) of the different things are prepared to be detachable to the lower plate 210 of the mold (200).

Next, the method of using the individual mold is as shown in Figure 2b,

An individual mold 300 having a box-shaped divided accommodation space S is formed on the lower plate.

Next, the upper connection concrete integrated connection member 120 is disposed on the individual mold 300 in the accommodation space (S) so that the upper portion of the upper connection concrete integrated connection member 120 is exposed to the individual mold 300 above the concrete. After pouring and curing in the individual mold 300 to demould the individual mold 300 to produce a unit concrete block 110.

Next, a combination of a plurality of the unit concrete block 110 is set,

The unit concrete block connecting member 140 is installed on the plurality of unit concrete blocks 110 set above, and the concrete is poured and cured so that the upper connection concrete integrated connecting member 120 and the unit concrete block connecting member 140 are embedded. The upper portions of the unit concrete blocks 110 are connected to each other by the upper connection concrete 150 to form a continuous arch block assembly 100.

Also, the arch block assembly 100 is formed by forming the arc-shaped retaining joint 151 on the upper surface of the upper connection concrete 150.

As such, the reason for using the individual mold is to enable the setting of various arch block assemblies to enable more efficient arch block assembly production and construction.

At this time, the unit concrete blocks 110 are generally formed uniformly in the form of a trapezoidal cross section, since the mold production and operation costs are low when the shape of the mold is constant.

However, only the shape of the unit concrete block 110 is limited to the effective arch block assembly 100 longitudinal connection.

Accordingly, the present invention is to provide the arch block assembly 100 by the polygonal unit concrete block 110 according to the three embodiments as follows.

[Architectural Fabrication Method Using Polygonal Unit Concrete Block of the Present Invention]

First, the combination of the arch block assembly using the polygonal unit concrete block in the longitudinal direction (shear connection) will be referred to simply as the precast block assembly (A).

Precast block assembly (A) according to Examples 1, 2 and 3 below is produced by shearing the arch block assembly 100 longitudinally with each other, each unit concrete block 110 constituting the arch block assembly 100 ) Is a combination of these forms of polygons. All of these archblock assemblies 100 are to secure the shear connection performance through the effective longitudinal connection to enable the construction of the arch structure between the long and long.

Example 1

First, the embodiment 1 is a combination of the arch block assembly by combining the unit concrete block 110 polygonal, for example, hexagonal unit concrete block 111, hexagonal and octagonal unit concrete blocks 112 and 113 and the end unit concrete block 114 100: 100a, 100b, 100c, and 100d) and the archblock assemblies 100 are longitudinally connected to each other to produce a precast block assembly (A), which will be described with reference to FIGS. 3A and 3B.

First, as shown in FIG. 3a, four types of A, B, C, and D arch block assemblies 100a, 100b, 100c, and 100d are prepared. Each of these arch blocks 100a, 100b, 100c, and 100d is an integrated mold or It can be produced using an individual mold.

In this case, the A-type arch block assembly 100a may be manufactured integrally with each other by arranging nine hexagonal unit concrete blocks 112 between 10 rectangular unit concrete blocks 111 as shown in FIG. 3A.

Since the arch block assembly 100a of the A type is disposed on one outer surface of the precast block assembly A as shown in FIG. 3B, the outer surface is the same so that the respective unit concrete blocks 111 and 112 do not protrude while forming a step with each other. Located on the plane, the inner side is arranged so that the hexagonal polygonal unit concrete block 112 protrudes outward more than the rectangular unit concrete block 111. The inner side is formed with a corrugated connection portion to be engaged with the corrugated connection portion of the adjacent B-type archblock assembly (100b).

As a result, the A and B arch block assemblies 100a and 100b meshed with each other can be easily connected to each other in the longitudinal direction, while ensuring sufficient shear connection performance.

Next, the B-type arch block assembly 100b is made of 9 octagonal unit concrete blocks 113 between 9 hexagonal unit concrete blocks 111 as shown in FIGS. 3B and 3B to be integrally manufactured. .

In this case, the hexagonal unit concrete blocks 114 at both ends are connected to the end hexagonal unit concrete blocks 114 to be engaged with the A-type arch block assembly 100a.

B-type arch block assembly such that the end hexagonal unit concrete block 114 and the octagonal unit concrete block 112 protrude inward and outward with respect to the inner and outer surfaces of the rectangular unit concrete block 111. It can be seen that (100b) is formed so that both the outer surface and the inner surface is formed with a corrugated connection.

At this time, the outer surface corrugated connector is engaged with the A-type arch block assembly 100a described above, and the inner surface corrugated connector is engaged with the corrugated connectors of the adjacent C-type arch block assembly 100c and sheared.

Next, the C-type arch block assembly 100c may be manufactured integrally with each other by arranging nine octagonal unit concrete blocks 113 between 10 rectangular unit concrete blocks 111 as shown in FIGS. 3A and 3B.

By the rectangular unit concrete block 111 and the octagonal unit concrete block 113 it can be seen that the C-type arch block assembly (100c) is formed so that both the outer surface and the inner surface is formed as a corrugated connection.

At this time, the outer surface corrugated connector is engaged with the B-type arch block assembly 100b described above, and the inner surface corrugated connector is sheared by engaging with the corrugated connector of the adjacent D-type arch block assembly 100d.

Next, the D-type arch block assembly 100d is manufactured by integrally arranging eight hexagonal unit concrete blocks 112 between nine rectangular unit concrete blocks 111 as shown in FIGS. 3A and 3B. The end square unit concrete block 111 is connected to the end hexagonal unit concrete block 114 to be engaged with the C-type arch block assembly (100c).

Since the arch block assembly 100d of the D type is disposed on the other outer surface of the precast block assembly A as shown in FIG. 3B, the outer surface is positioned on the same plane so that the respective unit concrete blocks 111 and 112 do not protrude. And the inner side is arranged so that the end hexagonal and octagonal unit concrete blocks 113 and 114 protrude.

The inner side is formed with a corrugated connection is to be engaged with the corrugated connection of the adjacent C-type arch block assembly (100c).

As a result, the first embodiment combines the 4, 6, octagonal archblock assembly (111, 112, 113) and the end hexagonal archblock assembly 114 corresponding to the corrugated connection to produce the arch block assembly (100a, 100b, 100c, 100d) It can be seen that by using these corrugated connectors to be engaged with each other in the longitudinal direction to ensure sufficient longitudinal shear connection performance.

[Example 2]

First embodiment 2 is an arch block assembly by combining a unit concrete block 110 polygonal, for example, end 6, octagonal unit concrete block 115, 116, octagonal unit concrete block 117 and octagonal unit concrete block 118 (100: 100a, 100b, 100c, and 100d) and the arch block assemblies 100 are longitudinally connected to each other to produce a precast block assembly (A), which will be described with reference to FIGS. 3C and 3D.

Also, as shown in FIG. 3C, four types of A, B, C, and D arch block assemblies 100a, 100b, 100c, and 100d are prepared. Each of these arch blocks 100a, 100b, 100c, and 100d is integrated as described above. What is necessary is just to manufacture using a mold or an individual mold.

In this case, the A-type arch block assembly 100a has eight octagonal unit concrete blocks 116 connected to each other as shown in FIG. 3C, and one end hexagonal unit concrete block 115 is disposed at one end to each other. It is made in one piece.

Since the A-type arch block assembly 100a is disposed on one outer surface of the precast block assembly A as shown in FIG. 3D, the outer surface is the same so that the respective unit concrete blocks 115 and 117 do not protrude while forming a step with each other. On the plane, the inner side is the end hexagonal unit concrete block 115 and the octagonal polygonal unit concrete block 117 are arranged in succession so that the inner side is formed with a corrugated connection to the adjacent B-type arch block assembly ( Mesh with the corrugated connection of 100b).

Next, the B-type arch block assembly 100b has eight octagonal unit concrete blocks 118 connected to each other in succession to each other, as shown in FIGS. 3C and 3D, and at one end of the octagonal unit concrete block 116 1. The dogs are arranged to be integrated with each other.

B-type arch block assembly 100b by allowing the end hexagonal unit concrete block 117 and the octagonal unit concrete block 119 to protrude outward from each other based on the inner and outer surfaces of the unit concrete blocks 116 and 118. ) Can be seen that both the outer surface and the inner surface is formed as a corrugated connection.

At this time, the outer surface corrugated connector is engaged with the A-type arch block assembly 100a as described above, and the inner surface corrugated connector is sheared by engaging with the corrugated connector of the adjacent C-type arch block assembly 100c.

Next, the C type arch block assembly 100c has eight octagonal unit concrete blocks 118 continuously connected to each other in the same side as the B type arch block assembly 100b as shown in FIGS. 3C and 3D. One end of the hexagonal unit concrete block 116 is arranged to be produced integrally with each other.

That is, one end hexagonal unit concrete block 116 is disposed on the opposite side of the B-type arch block assembly 100b (to face each other in the longitudinal direction).

Next, the D-type archblock assembly 100d is manufactured to be identical to the A-type archblock assembly 100a as shown in FIG. 3D, but is disposed to face each other.

Accordingly, the arch block assembly 100d of the D type also has eight octagonal unit concrete blocks 117 connected to each other, and one end hexagonal unit concrete block 115 is disposed at one end to be integrally manufactured. The inner surface is formed in the corrugated connection portion is meshed with the corrugated connection portion of the adjacent C-type arch block assembly (100c).

Finally, Example 2 combines the 8,12 octagonal archblock assemblies 117,118 and the end hexagonal octagonal archblock assemblies 115,116 corresponding to the corrugated connections to form the archblock assemblies 100a, 100b, 100c, 100d. It can be seen that by using these corrugated connectors to be engaged with each other in the longitudinal direction to ensure sufficient longitudinal shear connection performance.

[Example 3]

In the third embodiment, the unit concrete blocks 110 are combined with polygons, for example, quadrangular unit concrete blocks 111, to produce arch block assemblies 100: 100a, 100b, 100c, and 100d, and the arch block assemblies 100 are formed. The longitudinal connection is made to each other to produce a precast block assembly (A) will be described with reference to Figures 3e and 3f.

Also, as shown in FIG. 3E, four types of A, B, C, and D arch block assemblies 100 a, 100 b, 100 c, and 100 d are prepared. Each of these arch blocks 100 a, 100 b, 100 c, and 100 d is integrated as described above. What is necessary is just to manufacture using a mold or an individual mold.

At this time, the A-type arch block assembly (100a), as shown in Figure 3e is to be connected to each other side of the 13 rectangular unit concrete blocks (111a, 111b) to form a corrugated connection on the inner side.

Since the arch block assembly 100a of the A type is disposed on one outer surface of the precast block assembly A as shown in FIG. 3F, the outer surface does not protrude while each unit concrete block 111a and 111b forms a step with each other. In order to be located on the same plane, the inner surface is arranged so that the quadrilateral unit concrete block 111b alternately protrudes from each other so that the inner surface is formed with a corrugated connection, the corrugated connection of the adjacent B-type arch block assembly (100b) And interlock with each other.

Next, as shown in FIGS. 3E and 3F, the B-type arch block assembly 100b has 13 hexagonal unit concrete blocks 111b continuously connected to each other, and the inner and outer surfaces of the hexagonal unit concrete blocks 111b. It can be seen that the B-type arch block assembly 100b is continuously arranged to alternately protrude from each other with respect to the side so that both the outer side and the inner side are formed as corrugated connections.

At this time, the outer surface corrugated connector is engaged with the A-type arch block assembly 100a described above, and the inner surface corrugated connector is engaged with the corrugated connectors of the adjacent C-type arch block assembly 100c and sheared.

Next, the type C archblock assembly 100c is manufactured in the same manner as the type B archblock assembly 100b as shown in FIGS. 3E and 3F.

At this time, the outer surface corrugated connector is pre-engaged with the type B archblock assembly 100b described above, and the inner surface corrugated connector is sheared in engagement with the corrugated connector of the adjacent D type arch block assembly 100d.

Next, the D-type archblock assembly 100d is manufactured to be identical to the A-type archblock assembly 100a as shown in FIG. 3E, but disposed to face each other.

In this case, as shown in FIG. 3F, the outer surface of the precast block assembly A is disposed on the same plane so that the respective unit concrete blocks 111a and 111b do not protrude. The blocks 111a and 111b are arranged in succession so as to alternately protrude from each other so that a corrugated connection is formed on the inner side thereof so as to be engaged with the corrugated connection of the adjacent C-type arch block assembly 100c.

As a result, in Example 3, the arch block assemblies 100a, 100b, 100c, and 100d are manufactured by combining the quadrangular arch block assemblies 111a and 111b, and the longitudinal connection is performed by using the corrugated connectors to interlock with each other in the longitudinal direction. It can be seen that enough performance is secured.

Although not shown, the arch block assembly 100 according to embodiments 1, 2, and 3 is lifted and installed at both ends of the arch block assembly 100 so as to be supported by both the base structure and the wall structure, and the unit of the arch block assembly 100. The tension member is installed in the through hole formed in the lower portion of the concrete block 110 to further introduce prestress into the arch block assembly 100 to construct the final arch structure.

100: arch block assembly
110: unit concrete block
120: upper connection concrete integrated connector
130: temporary temporary material for integrated connection material
140: unit concrete block connecting member
150: upper connection concrete
151: crack induction joint

Claims (2)

On the upper surface of the lower plate 210 is installed a mold 200 is formed a plurality of spaced apart receiving space (S) of the box-shaped by the arch curvature adjustment wedge plate 220 spaced apart from each other, the upper portion on the mold 200 Connection concrete integrated connection member 120 is disposed in each of the receiving space (S) so that the upper portion of the upper connection concrete integrated connection member 120 is poured into the mold 200 and cured concrete in the mold 200 Unit concrete block 110 of the continuously formed, and the unit concrete block connecting member 140 is installed on the upper surface of the unit concrete blocks 110, the upper connection concrete integrated connection member 120 and the unit concrete block connecting member 140 ) To form and arch the concrete so that the upper portion of the unit concrete blocks 110 are connected to each other by the upper connection concrete 150 to form an arch block assembly 100, the upper edge In the arch block assembly manufacturing method of forming a concrete 150 cracks induced for holding arcuate shape on the upper surface of the joint 151, and include a demolding step of the mold 200,
The arch block assembly is coupled to each other by the adjacent arch block assembly and the corrugated connector, the corrugated connector is formed by forming the unit concrete blocks in a polygonal shape and the unit concrete blocks formed in a polygonal staggered mutually Method of manufacturing arch block assembly using polygonal unit concrete block. An individual mold 300 having a box-shaped divided receiving space S is formed on an upper portion of the lower plate, and an upper connection concrete integrated connecting member 120 is disposed in the receiving space S on the individual mold 300. The upper portion of the upper connection concrete integrated connection member 120 is cast and cured concrete in the individual mold 300 so that the upper portion of the individual mold 300, and then demolished the individual mold 300 to demolish the unit concrete block 110 Produced, and set a plurality of unit concrete block 110 in combination, install a unit concrete block connecting member 140 on the set of a plurality of unit concrete block 110, the upper connection concrete integrated connection member 120 ) And the unit concrete block connecting member 140 is placed and cured concrete so that the upper portion of the unit concrete blocks 110 are connected to each other by the upper connection concrete 150 and continuous arch Forming an arch block assembly 100 by forming a lock assembly 100 and forming an arch shape retaining crack 151 on the upper surface of the upper connection concrete 150 to form an arch block assembly 100. In
The arch block assembly is coupled to each other by the adjacent arch block assembly and the corrugated connector, the corrugated connector is formed by forming the unit concrete blocks in a polygonal shape and the unit concrete blocks formed in a polygonal staggered mutually Method of manufacturing arch block assembly using polygonal unit concrete block.

Images