KR20150131904A - Tension for both steel and precast concrete structures and its production and construction methods - Google Patents

Abstract

The present invention is to provide a channel segment structure for precast concrete grating by using steel materials having tension, and a production method and a construction method thereof. To achieve this, the channel segment structure according to the present invention comprises: steel materials having tension; sheath pipes spaced apart at predetermined intervals from the steel materials having tension; front-end key grooves formed to be recessed in a predetermined shape; front-end keys formed to protrude in a predetermined shape; connection grooves formed to be recessed by a predetermined thickness; fixing protrusions formed to be cut at a predetermined height; and gratings fixated and installed.

Description

TECHNICAL FIELD [0001] The present invention relates to a prefabricated concrete segment grating,

The present invention relates to a water channel segment structure for precast concrete grating using a tension steel, and a method of manufacturing and constructing the same. More particularly, the present invention relates to a concrete channel, The pre-cast concrete structure for a precast concrete grating is fabricated by casting concrete in a longitudinal direction in parallel with the backing in a formwork and by pouring and curing the concrete in the case of manufacturing the precast concrete segmenting structure for precast concrete grating And a water channel segment for precast concrete grating using the pre-cast concrete segment grating for precast concrete grating, which is constructed by connecting the segment structures of the precast concrete grating to the segment structures by using connecting pins in the field. It relates to a tree structure and its manufacturing method and construction method.

Generally, in establishing a concrete culvert by connecting multiple precast concrete culvert segments longitudinally together, the most important point is a solid connection at the junction of precast concrete culvert segments.

A general method of joining the precast concrete culvert segments in the longitudinal direction is to form concave joining grooves on adjacent joining surfaces of adjacent precast concrete culvert segments and to form joining grooves in a state of joining surfaces facing each other And a filler such as non-shrinkable mortar is injected into the space to form a joint.

As shown in FIG. 1, in a state where a precast concrete culvert is constructed by connecting a plurality of precast concrete culvert segments in the longitudinal direction so as to have a joint of such a structure, the vibration of the surroundings, In case of settlement, a bending moment acts on precast concrete culvert.

Also, bending moment acts on the box precast concrete culvert when the vertical load acts on the top of precast concrete culvert.

This bending moment causes a flexural tensile force to be applied to the joints of the precast concrete culvert segments. When the flexural tensile force exceeds the tensile strength of the filler of the joint, cracks are generated in the filler, There is a problem that a leakage phenomenon occurs.

Therefore, it is very important that the joints of precast concrete culvert segments are sufficiently resistant to flexural tensile forces at the joints caused by vertical stiffness and anisotropic load in establishing precast concrete culvert by bonding precast concrete culvert segments Do.

For this purpose, conventionally, a through hole is formed in a prong portion of a precast concrete culvert segment so that a tension member is installed to penetrate a plurality of precast concrete culvert segments in the longitudinal direction, and a tensioning force is applied.

In addition, an eye bolt is provided on the vertical wall portion on both side joint surfaces of the precast concrete culvert segment, and the hole of the eye bolt is made to communicate with each other, and then the fastening rod is passed perpendicularly to the hole of the eyebolt Respectively.

As described above, the joining structure using the eyebolts has a large tensile strength. Therefore, it is very effective as a precast concrete culver segment joint structure. However, since the joining rod must be penetrated, the application site is a vertical wall section of the precast concrete culvert segment There is a problem that it is limited only.

In addition, when excavating the ground to install precast concrete culvert segments, since only the minimum ground is excavated in the lateral direction of the precast concrete culverts, the neighboring precast concrete culvert segments This is because it is impossible to insert the fastening bar in the horizontally installed state and penetrate the hole of the eye bolt.

Therefore, inevitably, conventionally, the eye bolt was installed only in the vertical wall portion, and the fastening bar was inserted only in the vertical direction.

However, when uneven settlement occurs in the vertical direction of the precast concrete culvert or vertical load is applied, the bending tensile force generated by the bending moment acts most on the top plate or the bottom plate of the precast concrete culvert segment.

In contrast, since the joining structure using the eyebolts exhibiting a large flexural tensile strength can be applied only to the vertical wall portion, the top plate and the bottom plate of the precast concrete culvert segment, to which the greatest flexural tensile force is applied, .

Therefore, it is desired to increase the flexural tensile strength of the upper plate and the lower plate of the precast concrete culvert segment.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a water channel segment structure for pre-cast concrete grating, A concrete structure is constructed by casting concrete with a tensile strength in the longitudinal direction in parallel with the reinforcing steel reinforcement and casting the precast concrete by grinding and curing the concrete and then forming the water channel segment structure for the precast concrete grating By connecting the water channel segment structures for precast concrete grating by using the fastening pins, the rigidity of the joints between the channel segment structures for precast concrete grating is increased, and the rigidity of the channel segments for precast concrete grating is increased. To provide a simple after the production of the garment structure, and the construction, material stress is produced precast channel segment structure for a concrete grating with a steel tension combine to allow the construction method thereof, a method and it is an object.

In order to accomplish the above object, there is provided a pre-cast concrete grating water channel segment structure using a torsional steel material according to the present invention, comprising at least two channel segments for precast concrete grating, Wherein the pre-cast concrete grating water channel segments are embedded in the upper and lower portions of the pre-cast concrete in a longitudinal direction, respectively; A sheath tube spaced apart from the steel sheet at a predetermined interval and buried in longitudinal portions at upper and lower portions; A shear key groove formed on one side of the channel segment for precast concrete grating so as to be formed in a constant shape from top to bottom; A shear key formed on the other side of the precast concrete channel segment corresponding to the shear-key groove so as to protrude from the upper part to the lower part with a predetermined shape; A connection groove recessed and formed at a predetermined depth and a predetermined thickness from the upper end to the lower end of the shear-key groove; A fixing jaw being cut out at a predetermined height inside the channel segment for precast concrete grating; And a grating fixedly installed across the fixed jaw.

According to another aspect of the present invention, there is provided a method of manufacturing a channel segment structure for precast concrete grating using a torsional steel material, the method comprising the steps of: providing a precast using a torsional steel material according to any one of claims 1 to 17; A method of manufacturing a water channel segment structure for a concrete grating, comprising the steps of: placing reinforcing bars in a formwork, installing a tension steel and a sheath pipe around the reinforcing bars, pouring and curing the concrete in the formworks to form precast concrete grating segments And the like.

In order to accomplish the above object, there is provided a method of constructing a channel segment structure for precast concrete grating using a torsional steel material according to the present invention, comprising the steps of: preparing a precast concrete using the torsional steel material according to any one of claims 1 to 17; CLAIMS What is claimed is: 1. A method of constructing a waterway segment structure for grating, comprising: transporting a waterway segment for precast concrete grating to a location adjacent to an installation site; Mounting the conveyed pre-cast concrete grating water channel segment in a longitudinal direction using a heavy equipment at an installation site; Inserting a shear key of a channel segment for precast concrete grating on the other side into the shear-key groove of the channel segment for precast concrete grating on one side, Inserting and fastening a fastening pin between the steel sheets which serve as a tension between the adjacent channel segments for the precast concrete grating; Filling and curing the mortar between the shear key groove of the one-side precast concrete grating water channel segment and the shear key of the water channel segment for the other precast concrete grating on the other side, installing a water swellable index material on the hardened mortar, Filling the index material with a caulking material and connecting the same; And inserting and tightening the wire rope into the sheath tube of the channel segment for precast concrete grating.

As described above, the water channel segment structure for precast concrete grating using the torsional steel according to the present invention, the method of manufacturing the same, and the method of constructing and installing the precast concrete segment grindstones according to the present invention are constructed by connecting a plurality of water channel segment structures for precast concrete grating in the longitudinal direction The method for manufacturing precast concrete grating according to any one of the preceding claims, wherein the pre-cast concrete structure is manufactured by burying a torsional steel material in the longitudinal direction in parallel with the reinforcing steel reinforcement, The pre-cast concrete grating water channel segment structure is connected to the water channel segment for pre-cast concrete grating by using a fastening pin in the field, The rigidity of the joints between the buildings is increased, and the segment structure for the precast concrete grating is easily manufactured, and there is an advantage that the reinforcement can be performed after the construction.

1 is a side view showing a state where a differential settlement occurs in a conventional precast concrete culvert,
FIG. 2 is a perspective view showing a precast concrete culvert segment using a torsional steel material according to the present invention, FIG.
3 (a) is a front view showing a precast concrete culvert segment using a torsional steel material according to the present invention, FIG. 3
FIG. 3 (b) is a cross-sectional view showing a precast concrete culvert segment using a steel material for a tension according to the present invention,
FIG. 4 is a plan view showing precast concrete culvert segments using a torsional steel material according to the present invention, FIG.
FIG. 5 is a perspective view of a pre-cast concrete culvert segment joining state using a torsional steel material according to the present invention,
6 is a sectional view taken along line AA in Fig. 5,
Fig. 7 is a sectional view taken along line BB of Fig. 5,
FIG. 8 is a detailed view showing an enlarged view of a state of engagement between a shear key and a shear-key groove of the precast concrete culvert segment of FIG. 5;
FIG. 9 is a perspective view showing a state of engagement between precast concrete culvert segments using a torsional steel material according to the present invention,
10 is a sectional view taken along the line AA in Fig. 9,
11 is a sectional view taken along line BB of Fig. 9,
FIG. 12 is a detailed view showing an enlarged view of a state of engagement between a shear key and a shear-key groove of the precast concrete culvert segment of FIG. 9;
13 (a), 13 (b) and 13 (c) are views showing an example of a composite steel sheet for use in precast concrete culvert segments using a steel sheet having a tensile strength according to the present invention,
14 (a), 14 (b) and 14 (c) are views showing a fastening pin of a precast concrete culvert segment using a steel material with a tension according to the present invention,
15 (a), 15 (b) and 15 (c) are views showing a state in which a precast concrete culvert segment using a steel material having a tensile strength according to the present invention is connected between a steel material and a fastening pin,
16 is a perspective view showing a pre-cast concrete opening culvert segment using a steel material having a tensile strength according to the present invention,
FIG. 17 (a) is a front view showing a precast concrete opening cowling segment using a torsional steel material according to the present invention, FIG. 17
FIG. 17 (b) is a cross-sectional view showing a pre-cast concrete opening culvert segment using a steel sheet for a tension according to the present invention,
FIG. 18 is a plan view showing precast concrete open culvert segments using the steel for combined use according to the present invention, FIG.
FIG. 19 is a perspective view showing a state of engagement between precast concrete open culvert segments using a torsional steel material according to the present invention,
20 is a sectional view taken along the line AA in Fig. 19,
Fig. 21 is a sectional view taken along line BB of Fig. 19,
FIG. 22 is a detail view showing an enlarged view of the state of engagement between the shear key and the shear-key groove of the precast concrete opening culvert segment of FIG. 19;
FIG. 23 is a perspective view showing a state of engagement between precast concrete open culvert segments using a torsional steel material according to the present invention,
24 is a sectional view taken along the line AA in Fig. 23,
25 is a sectional view taken along line BB of Fig. 23,
FIG. 26 is a detailed view showing an enlarged view of the state of engagement between the shear key and the shear-key groove of the precast concrete opening culvert segment of FIG. 23;
27 (a), (b), and (c) are views showing an example of a steel material having both the torsional rigidity of the precast concrete opening culvert segment using the steel material for tension according to the present invention,
28 (a), (b) and (c) are views showing a fastening pin of a precast concrete opening culvert segment using a steel material for tension according to the present invention,
29 (a), 29 (b) and 29 (c) are views showing a state in which precast concrete apertured culvert segments using a steel material having a tensile strength according to the present invention are connected to each other by means of a tension-
FIG. 30 is a perspective view of a precast concrete channel segment using a steel sheet having a tensile strength according to the present invention,
31 (a) is a front view of a precast concrete waterway segment using a steel material for tensions according to the present invention. Fig. 31
31 (b) is a cross-sectional view showing a precast concrete waterway segment using a steel material having a tensile strength according to the present invention,
FIG. 32 is a plan view showing precast concrete waterway segments using the steel material for tensions according to the present invention, and FIG.
FIG. 33 is a perspective view showing a state of engagement between precast concrete waterway segments using a torsional steel material according to the present invention, and FIG.
34 is a sectional view taken along the line AA in Fig. 33,
Fig. 35 is an enlarged detail view of the state of engagement between the shear key and the shear-key groove of the precast concrete waterway segment of Fig. 33;
Fig. 36 is an enlarged detail view of the state of engagement between the shear key and the shear-key groove of the precast concrete waterway segment of Fig. 33. Fig.
FIG. 37 is a perspective view of a precast concrete channel segment using a torsional steel material according to the present invention,
38 (a) is a front view of a precast concrete waterway segment using a steel material for a tension according to the present invention,
38 (b) is a cross-sectional view of a pre-cast concrete channel segment using a tie-cast steel according to the present invention,
FIG. 39 is a plan view showing precast concrete channel segments using the steel material for tensions according to the present invention, and FIG.
40 is a perspective view showing a state of engagement between precast concrete waterway segments using a torsional steel material according to the present invention,
41 is a sectional view taken along the line AA in Fig. 40,
42 is an enlarged detail view 1 showing a state of engagement between a shear key and a shear-key groove of the precast concrete waterway segment of FIG. 40;
Fig. 43 is an enlarged detail view of the state of engagement between the shear key and the shear-key groove of the precast concrete waterway segment of Fig. 26;
44 (a), 44 (b) and 44 (c) are views showing an example of a composite steel sheet for a precast concrete channel segment using a steel sheet with a tension according to the present invention,
45 (a), 45 (b) and 45 (c) are views showing a fastening pin of a precast concrete channel segment using a steel sheet for a tension according to the present invention,
46 (a), 46 (b), and 46 (c) are views showing a state in which a precast concrete channel segment using a steel material having a tensile strength according to the present invention is connected between a steel material and a fastening pin,
FIG. 47 is a perspective view showing a waterway segment for precast concrete grating using the steel material for comfort according to the present invention,
Figure 48 (a) is a front view of a waterway segment for precast concrete grating using a torsional steel according to the present invention.
48 (b) is a cross-sectional view of a waterway segment for precast concrete grating using the steel material for tensions according to the present invention,
FIG. 49 is a plan view 1 of a waterway segment for precast concrete grating using a steel material for comfort according to the present invention, FIG.
FIG. 50 is an exploded perspective view 1 showing a waterway segment for precast concrete grating using a steel material having a tensile strength according to the present invention, FIG.
FIG. 51 is a perspective view showing a state of engagement between waterway segments for precast concrete grating using a torsional steel material according to the present invention; FIG.
Fig. 52 is a cross-sectional view taken along line AA of Fig. 51,
Fig. 53 is an enlarged detail view of the state of engagement between the shear key and the shear-key groove of the waterway segment for precast concrete grating in Fig. 51. Fig.
FIG. 54 is a detail enlarged view of FIG. 51 showing a state of engagement between a shear key and a shear key groove of a waterway segment for precast concrete grating;
55 (a), (b) and (c) are views showing an example of a steel sheet for use in tensioning of a waterway segment for precast concrete grating using a steel sheet with a tension according to the present invention,
56 (a), (b) and (c) are views showing a fastening pin of a waterway segment for precast concrete grating using a torsional steel material according to the present invention,
57 (a), 57 (b) and 57 (c) are views showing a state in which a channel segment for precast concrete grating using a steel material having a tensile strength according to the present invention is connected between a steel material and a fastening pin,
58 is a perspective view of a waterway segment for precast concrete grating using a steel material for a tension according to the present invention,
FIG. 59 (a) is a front view of a waterway segment for precast concrete grating using a steel material with a tension according to the present invention. FIG. 59
FIG. 59 (b) is a cross-sectional view showing a waterway segment for precast concrete grating using the steel material for combined use according to the present invention,
FIG. 60 is a plan view showing a waterway segment for precast concrete grating using a torsional steel material according to the present invention,
FIG. 61 is an exploded perspective view 2 showing a waterway segment for precast concrete grating using a steel material having a tensile strength according to the present invention, FIG.
FIG. 62 is a perspective view 2 showing a state of engagement between waterway segments for precast concrete grating using a torsional steel material according to the present invention, FIG.
Fig. 63 is an enlarged detail view of the state of engagement between the shear key and the shear-key groove of the waterway segment for precast concrete grating in Fig. 62;
Fig. 64 is a detail enlarged view of Fig. 62 showing a state of engagement between a shear key and a shear-key groove of a waterway segment for precast concrete grating; Fig.
FIGS. 65 (a), 65 (b) and 65 (c) are views showing an example of a steel sheet used for tensioning a channel segment for precast concrete grating,
Figs. 66 (a), 66 (b) and 66 (c) are views showing the fastening pins of the channel segment for precast concrete grating using the steel material for tension according to the present invention,
67 (a), 67 (b), and 67 (c) are views showing a state in which a channel segment for precast concrete grating using a steel material having a tensile strength according to the present invention is connected between a steel material and a fastening pin,
68 is a perspective view of a precast concrete retaining wall segment using a steel material for a tension according to the present invention,
69 (a) is a front view showing a pre-cast concrete retaining wall segment using a steel material having a tensile strength according to the present invention, Fig. 69
69 (b) is a sectional view (1) showing a precast concrete retaining wall segment using a steel material having a tensile strength according to the present invention,
FIG. 70 is a plan view 1 of a precast concrete retaining wall segment using a steel material for comfort according to the present invention, FIG.
71 is a perspective view showing a state of engagement between pre-cast concrete retaining wall segments using a torsional steel material according to the present invention,
72 is a sectional view taken along the line AA in Fig. 71,
Fig. 73 is an enlarged detail view of the state of engagement between the shear key and the shear-key groove of the precast concrete retaining wall segment of Fig. 71;
FIG. 74 is a detail enlarged view of FIG. 71 showing a state of engagement between a shear key and a shear key groove of the precast concrete retaining wall segment; FIG.
75 (a), 75 (b), and 75 (c) illustrate examples of a steel material serving as a tension of a precast concrete retaining wall segment using a steel material for a tension according to the present invention,
76 (a), (b) and (c) are views showing a fastening pin of a precast concrete retaining wall segment using a steel material for a tension according to the present invention,
FIGS. 77 (a), (b) and (c) are views showing a state in which a precast concrete retaining wall segment using a steel material having a tensile strength according to the present invention is connected to a steel material and a fastening pin,
78 is a perspective view showing a pre-cast concrete retaining wall segment using a steel material having a tensile strength according to the present invention,
79 (a) is a front view of a precast concrete retaining wall segment using a steel material for a tension according to the present invention,
79 (b) is a sectional view (2) showing a precast concrete retaining wall segment using a steel material having a tensile strength according to the present invention,
80 is a plan view showing a precast concrete retaining wall segment using a steel material having a tensile strength according to the present invention,
81 is a perspective view 2 showing a state of engagement between precast concrete retaining wall segments using the steel material for comfort according to the present invention,
82 is a sectional view taken along the line AA in Fig. 81,
Fig. 83 is an enlarged detail view 1 showing a state of engagement between a shear key and a shear-key groove of the precast concrete retaining wall segment of Fig. 81;
FIG. 84 is a detail enlarged view of the state of engagement between the shear key and the shear key groove of the precast concrete retaining wall segment of FIG. 81;
FIGS. 85 (a), (b) and (c) are views showing an example of a composite steel sheet for use in a precast concrete retaining wall segment using a composite steel sheet according to the present invention,
FIGS. 86 (a), 86 (b) and 86 (c) are views showing a fastening pin of a precast concrete retaining wall segment using a steel material for a tension according to the present invention,
FIGS. 87 (a), 87 (b) and 87 (c) are views showing a state in which a precast concrete retaining wall segment using a steel material having a tensile strength according to the present invention is connected to a tension steel material and a fastening pin,
88 is a perspective view showing a sleeve nut of a precast concrete structure using a steel material for a tension according to the present invention,
89 is an exemplary view showing a state in which a sleeve nut is provided on the outer peripheral surface of a steel bar or a steel wire;

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

[Precast Concrete Culvert Segment]

FIG. 2 is a perspective view showing a precast concrete culvert segment using a torsional steel material according to the present invention, FIG. 3 (a) is a front view showing a precast concrete culvert segment using a torsional steel material according to the present invention, and FIG. 3 (b) is a cross-sectional view of a precast concrete culvert segment using a torsional steel according to the present invention, and Fig. 4 is a plan view showing a precast concrete culvert segment using a torsional steel according to the present invention.

As shown in these drawings, a precast concrete culvert segment structure using a torsional steel material according to the present invention is a precast concrete culvert having at least two or more precast concrete culvert segments connected in the longitudinal direction, The concrete culvert segment (100) includes a tension steel (120) buried in a longitudinal direction at an inner peripheral portion (110); A sheath pipe (130) spaced apart from the steel sheet (120) by a predetermined distance and buried in the longitudinal section (110) in the longitudinal direction; A pre-cast concrete culvert segment (100); And a shear key 150 protruding in a predetermined shape on the other side of the outside of the precast concrete culvert segment 100 corresponding to the shear key groove 140.

That is, the precast concrete culvert segment structure using the torsional steel according to the present invention comprises precast concrete culvert segment 100, torsion bar 110, torsion bar 120, sheath tube 130, 140 and a shear key 150 are organically coupled to each other.

The precast concrete culvert segment 100 is formed in a box shape in a cross section and is composed of at least two or more precast concrete culvert segments 100. The precast concrete culvert segments 100 are connected longitudinally to form a pre- Construct cast concrete culvert.

The concrete part 110 is formed in a triangular shape with a corner where the surface of the precast concrete culvert segment 100 meets the surface.

The tension steel member 120 is composed of a steel bar or a steel wire 122 having a predetermined length and a fastening groove 123 formed by winding both ends of the steel bar or steel wire 122 around the fastening groove 123 The R-type fastening pin 160 is inserted.

The tension steel member 120 includes a steel bar or a steel wire 122 having a predetermined length and a male screw portion 124 having threads at both ends of the steel bar or steel wire 122, And a T-shaped fastening pin 170 is inserted into the fastening groove 126. The T-shaped fastening pin 170 is inserted into the female threaded portion 125, The T-shaped fastening pin 170 has a T-shape as a whole and includes a body 172 having a through hole 174 formed at a lower portion thereof and a fixing pin 174 inserted into the through hole 174 of the body 172. [ (176).

The tension steel member 120 is composed of a steel bar or steel wire 122 having a predetermined length and a protruding protrusion 127 protruding at a predetermined thickness at both ends of the steel bar or steel wire 122, An N-type coupling pin 180 is inserted into the coupling pin 127, and the N-type coupling pin 180 is formed in a hexahedron shape with a bottom wall as a whole; An insertion groove 184 is formed in a predetermined shape on two surfaces of the main body in the same direction.

88 and 89, a sleeve nut 920 is provided on the outer circumferential surface of the steel rod or steel wire 122. The sleeve nut 920 has a thread 922 formed on the inner circumferential surface thereof, Sectional shape.

The sleeve nut 920 is provided to enhance the adhesion between the steel bar or the steel wire 122 with the concrete.

The sheath tube 130 is a kind of hollow tube for protecting the wire rope inserted therein.

Here, the wire rope is a steel material disposed on the sheath pipe 130 to give a prestress to the precast concrete culvert 100.

The shear-key groove 140 is formed on the outer side of the precast concrete culvert 100 so as to have a predetermined shape.

The shear key 150 is formed on the other side of the precast concrete culvert 100 so as to correspond to the shear-key groove 140,

The shear key 150 protrudes from the precast concrete culvert 100 and has a middle portion of the shear key groove 140 coupled to the shear key 150.

The shear key 150 protrudes from the precast concrete culvert 100 and has an upper portion of the shear key groove 140 coupled to the shear key 150.

Meanwhile, the shear key 150 is provided with a water inflating index material 200 at an upper portion thereof, and the caulking material 210 is provided at an upper portion of the water inflating index material 200.

In particular, the water extensible index material 200 is installed on the connection surface of the precast concrete culvert segment 100, so that leakage of water leaking out of the precast concrete culvert segment 100, .

As shown in FIGS. 16 to 18, an opening groove 220 is formed at a predetermined position on the upper surface of the precast concrete culvert segment 100, and a grating 230 is installed in the opening groove 220 do.

Hereinafter, the production of the precast concrete culvert segment structure using the torsional steel according to the present invention will be described.

As shown in FIG. 3 (b), a method for manufacturing precast concrete culvert segment structures using a torsional steel material according to the present invention comprises the steps of: placing reinforcing bars 900 on a formwork (not shown) A plurality of precast concrete culvert segments 100 are manufactured by installing a tension steel 120 and a sheath pipe 130 and placing and curing concrete in the formwork.

17 (b), it is also possible to form the opening groove 220 and the grating 230 in a predetermined portion of the precast concrete culvert segment.

Hereinafter, the construction of precast concrete culvert segment structure using the above-described fabricated steel material according to the present invention will be described.

5 is a perspective view 1 showing a state of engagement between precast concrete culvert segments using a torsional steel material according to the present invention, FIG. 6 is a sectional view taken along line AA of FIG. 5, FIG. 7 is a sectional view taken along the line BB of FIG. And FIG. 9 is a perspective view showing a state of engagement between precast concrete culvert segments using a tension steel material according to the present invention, and FIG. 9 is a perspective view showing a state of engagement between precast concrete culvert segments of a precast concrete culvert segment of FIG. 9 is a sectional view taken along the line AA in Fig. 9, Fig. 11 is a sectional view taken along line BB in Fig. 9, Fig. 12 is a detail view showing a state in which a precast concrete culvert segment in Fig. 14 (a), 14 (b) and 14 (c) are views showing an example of a steel sheet for use in a precast concrete culvert segment using a torsional steel according to the present invention, Using steel Figs. 15 (a), (b) and (c) are views showing the connection between the pre-cast concrete culvert segments using the tension-resistant steel material according to the present invention, FIG. 5 is a perspective view 1 showing a pre-cast concrete cement combined state using a torsional steel material according to the present invention, FIG. 6 is a sectional view taken along the line AA in FIG. 5, and FIG. 7 is a cross- And FIG. 9 is a view showing a state of joining precast concrete cullets using the steel for combined use according to the present invention. FIG. 9 is a cross-sectional view taken along the line BB of FIG. 9 is a perspective view of the precast concrete culvert of FIG. 9, and FIG. 12 is a detail view showing an enlarged view of a state of engagement between a shear key and a shear key groove of the precast concrete culvert of FIG. (a) 14 (a), (b) and (c) are views showing an example of a steel sheet for use in a precast concrete culvert using a torsional steel according to the present invention, and Figs. 14 15 (a), 15 (b) and 15 (c) are views showing the connecting pin of a pre-cast concrete culvert using a combined tension steel, And a connecting pin.

As shown in these drawings, a method of constructing a precast concrete culvert segment structure using a torsional steel material according to the present invention comprises the steps of: transporting a precast concrete culvert segment 100 to a vicinity of an installation site; Mounting the conveyed precast concrete culvert segment (100) in a longitudinal direction using a heavy equipment at an installation site; Inserting the shear key 150 of the precast concrete culvert segment 100 on the other side into the shear-key groove 140 of the precast concrete culvert segment 100 on one side, Inserting and fixing fastening pins (160, 170, 180) between the steel plates (120) serving as the tension between the closely adhered precast concrete culvert segments (100); The mortar 910 is filled and cured between the shear key groove 140 of the precast concrete culvert segment 100 on one side and the shear key 150 of the precast concrete culvert segment 100 on the other side and the cured mortar 910 Providing a water swellable index material (200) on the water swellable index material (200), filling and connecting the caulking material (210) to the water swellable index material (200) And inserting and tightening the wire rope into the sheath pipe 130 of the precast concrete culvert segment 100.

That is, the precast concrete culvert segment structure construction method using the torsional steel according to the present invention is characterized in that after the precast concrete culvert segment 100 is transported to the vicinity of the installation site, The shear key 150 of the precast concrete culvert segment 100 on the other side is inserted into the shear key groove 140 of the precast concrete culvert segment 100 on the one side to be closely contacted, 170 and 180 are inserted between the concrete culvert segments 100 and the reinforcement members 120 between the concrete culvert segments 100 and then fixed to the shear key groove 140 of the one precast concrete culvert segment 100 and the free The mortar 910 is filled and cured between the shear keys 150 of the cast concrete culvert segment 100 and the water expansion index The wire rope is inserted into the sheath tube 130 of the precast concrete culvert segment 100 after the caulking material 210 is filled and connected to the water expandable index material 200, So that the pre-cast concrete culvert is constructed.

It is to be noted that the precast concrete culvert can be constructed by forming the opening groove 220 and installing the grating 230 as shown in FIGS. 19 to 29 (c).

[Precast Concrete Channel Segment]

FIG. 30 is a perspective view 1 and 31 (a) of a precast concrete waterway segment using a tie-breaking steel material according to the present invention. FIG. 30 is a front view of a precast concrete waterway segment using a tie- 31 (b) is a cross-sectional view showing a pre-cast concrete channel segment using a torsional steel material according to the present invention. Fig. 1 and Fig. 32 are plan views 1 and 2 showing a precast concrete channel segment using a torsional steel material according to the present invention 37 is a perspective view 2 and 38 (a) showing a precast concrete channel segment using a torsional steel material according to the present invention, and FIG. 38 is a front view showing a precast concrete channel segment using a torsional steel material according to the present invention. 38 (b) are sectional views 2, 39 (a) and 39 (b) showing a precast concrete channel segment using a torsional steel according to the present invention 2 is a plan view showing the pre-cast concrete channel segment using a Combine tension steel material according to the invention.

As shown in these figures, the pre-cast concrete channel segment structure using the torsional steel according to the present invention is a precast concrete channel in which at least two precast concrete channel segments are connected in the longitudinal direction, The concrete channel segment 300 includes a tensile steel material 320 which is longitudinally buried in the upper and lower peripheral portions 310, respectively; A sheath pipe (330) spaced apart from the steel sheet (320) by a predetermined distance so as to be buried in the longitudinally extending portions (310) of the upper and lower portions; A pre-cast concrete channel segment (300) formed on one side of the pre-cast concrete channel segment (300) with a predetermined shape from top to bottom; A shear key 350 protruding from the upper part to the lower part of the precast concrete channel segment 300 in a predetermined shape on the other side of the shear key groove 340; And a connection groove 360 which is recessed and formed at a predetermined depth from the upper end of the shear key groove 340 to the lower end at a predetermined thickness.

That is, the precast concrete channel segment structure using the torsional steel according to the present invention includes the precast concrete channel segments 300, the torsion bar 310, the torsion bar 320, the sheath pipe 330, the shear key groove 340 , A shear key 350 and a connection groove 360 are organically coupled to each other.

The precast concrete channel segments 300 are formed in the shape of an opening in a cross section and include at least two or more precast concrete channel segments 300. The precast concrete channel segments 300 are connected in the longitudinal direction, Construct a cast concrete channel.

In addition, the pre-cast concrete section 110 is formed in a triangular shape as a corner where the surface of the precast concrete channel segment 100 meets the surface.

The tensile steel member 320 is composed of a steel bar or a steel wire 322 having a predetermined length and a fastening groove 323 formed by winding both ends of the steel rod or steel wire 322 in an annular shape. The R-type fastening pin 370 is inserted.

In addition, the tension steel member 320 includes a steel bar or a steel wire 322 having a predetermined length, a male screw portion 324 having threads at both ends of the steel bar or steel wire 322, And a T-shaped coupling pin 380 is inserted into the coupling groove 326. The T-shaped coupling pin 380 is inserted into the coupling groove 326. The coupling hole 326 is formed in the female threaded portion 325, The T-shaped coupling pin 380 has a T-shape as a whole and includes a body 382 having a through hole 384 formed at a lower portion thereof and a fixing pin 382 inserted into the through hole 384 of the body 382. [ (386).

The tensile steel member 320 is composed of a steel bar or steel wire 322 having a predetermined length and a protruding protrusion 327 protruding at a predetermined thickness from both ends of the steel bar or steel wire 322, An N-type locking pin 390 is inserted into the locking hole 327, and the N-type locking pin 390 is formed in a hexahedron shape having a generally bottom wall; An insertion groove 394 is formed in two surfaces of the main body 392 in the same direction.

88 and 89, a sleeve nut 920 is provided on the outer circumferential surface of the steel bar or the steel wire 322. The sleeve nut 920 has a thread 922 formed on the inner circumferential surface thereof, Sectional shape.

The sleeve nut 920 is provided to enhance the adhesion between the steel bar or the steel wire 322 with the concrete.

The sheath pipe 330 is a kind of hollow tube for protecting the wire rope inserted into the sheath pipe 330.

Here, the wire rope is a steel material disposed on the sheath pipe 330 to give a prestress to the precast concrete channel segment 300.

The shear key groove 340 is a member formed by recessing the precast concrete water channel segment 300 in a predetermined shape from the upper part to the lower part.

The shear key 350 is a member protruding in a predetermined shape from the upper part to the lower part on the other side of the precast concrete channel segment 300 so as to correspond to the shear key groove 340.

The shear key 350 protrudes from the precast concrete channel segment 300 and the shear key groove 340 coupled to the shear key 550 is formed in a central portion thereof.

One side of the precast concrete channel segment 300 protrudes from the shear key 550 and one side of the precast concrete channel segment 300 is formed in the shear key groove 340 coupled to the shear key 550.

The shear key 550 is provided with a water inflating index material 410 on the upper part and the caulking material 420 is provided on the water inflating index material 410.

In particular, the water extensible index material 410 is installed on the connection surface of the precast concrete water channel segment 300, thereby functioning to catch water leakage from the water flowing out of the precast concrete water channel segment 300.

Hereinafter, the production of precast concrete channel segment structures using the tie-breaking steel according to the present invention will be described.

31 (b) and FIG. 38 (b), a method of manufacturing a precast concrete structure using a steel material for a tension according to the present invention comprises the steps of placing a reinforcing bar 900 in a formwork, And a sheath pipe 330 are installed on the concrete structure 320 and the concrete is placed and cured in the concrete mold to produce a precast concrete channel 300. [

Hereinafter, the construction of the pre-cast concrete channel segment structure using the above-described fabricated steel material according to the present invention will be described.

Fig. 33 is a perspective view 1, Fig. 34 is a sectional view taken along the line AA in Fig. 33, Fig. 35 is a sectional view of the precast concrete channel segments shown in Fig. 33, FIGS. 1 and 36 are enlarged views of the state of engagement between a shear key and a shear-key groove of the precast concrete channel segment shown in FIG. 33. FIG. 2 and FIG. 40 are views showing a state in which the shear- 40 is a cross-sectional view taken along the line AA in Fig. 40, Fig. 42 is a detail view 1, and Fig. 42 is an enlarged view showing a state of engagement between a shear key and a shear key groove of the precast concrete channel segment shown in Fig. Fig. 43 is an enlarged detail view of the state of engagement between the shear key and the shear-key groove of the precast concrete waterway segment of Fig. 40. Figs. 2, 44 (a) FIGS. 45 (a), (b) and (c) are cross-sectional views illustrating a pre-cast concrete channel segment using a torsional steel sheet according to the present invention, 46 (a), (b), and (c) are views showing the connecting pin of the channel segment, and Fig. 46 Fig.

As shown in these drawings, a precast concrete channel segment structure construction method using a torsional steel material according to the present invention comprises the steps of: transporting a precast concrete channel segment 300 to a vicinity of an installation site; Mounting the conveyed precast concrete channel segment (300) in a longitudinal direction using a heavy equipment in an installation site; Inserting the shear key 350 of the precast concrete channel segment 300 on the other side into the shear-key groove 340 of the pre-cast concrete channel segment 300 of the one fixed side; Inserting and fixing fastening pins (370, 380, 390) between the steel plates (320) serving as a tension between the adjacent precast concrete channel segments (300); The mortar 910 is filled and cured between the shear key groove 340 of the precast concrete channel segment 300 on one side and the shear key 350 of the precast concrete channel segment 300 on the other side and the cured mortar 910 Providing a water swellable index material (410) on the water swellable index material (410), filling and connecting a caulking material (420) on the water swellable index material (410); And inserting and tightening the wire rope into the sheath pipe 330 of the precast concrete channel segment 300. [

That is, the precast concrete channel segment construction method using the tie-breaking steel material according to the present invention is characterized in that after the precast concrete channel segment 300 is transported to the vicinity of the installation site, the precast concrete channel segment 300 is transported And the shear key 350 of the precast concrete channel segment 300 on the other side is inserted into the shear key groove 340 of the precast concrete channel segment 300 of the one fixed side, 380 and 390 are inserted and fixed between the steel precursory materials 320 for tension between the precast concrete channel segments 300 in close contact with each other and then the precast concrete channel segment 300 The mortar 910 is filled and hardened between the shear key groove 340 of the pre-cast concrete channel segment 300 of the other side and the shear key 350 of the precast concrete channel segment 300 of the other side A water swellable index material 410 is installed on the cured mortar 910 and a caulking material 420 is filled on the water swellable index material 410 to connect the precast concrete channel segment 300 is inserted and tightened by a wire rope in the sheath pipe 330 to construct a precast concrete channel.

[Precast Concrete Grating Waterway Segment]

FIG. 47 is a perspective view 1 and FIG. 48 (a) showing a waterway segment for precast concrete grating using a torsional steel material according to the present invention, showing a waterway segment for precast concrete grating using a torsional steel material according to the present invention 1 and Fig. 48 are sectional views (1) and (b) of a water channel segment for precast concrete grating using a torsional steel material according to the present invention. Fig. 1 and Fig. 49 are views for explaining a precast concrete grating using water- 1 and FIG. 50 are exploded perspective views 1 and 57 showing a waterway segment for precast concrete grating using a steel sheet for a tension according to the present invention. FIG. 57 is a sectional view of a precast concrete grating And FIG. 58 (a) is a perspective view of a tension joint steel according to the present invention 2 and 58 (b) are cross-sectional views showing water channel segments for precast concrete grating using a torsional steel material according to the present invention. Fig. 2 and Fig. 59 are sectional views showing the water- And FIG. 60 is an exploded perspective view 2 showing a waterway segment for precast concrete grating using a steel sheet having a tensile strength according to the present invention.

As shown in these drawings, the water channel segment structure for precast concrete grating using the torsional steel according to the present invention comprises at least two water channel segments for precast concrete grating, which are connected in the longitudinal direction to form a precast concrete grating channel , The precast concrete grating water channel segment (500) includes a tension steel material (520) embedded in the longitudinal direction at the upper and lower portions (510), respectively; A sheath pipe (530) spaced apart from the steel sheet (520) by a predetermined distance and embedded in the longitudinally extending portions (510) of the upper and lower portions, respectively; A shear key groove 540 formed on one side of the channel segment 500 for precast concrete grating so as to be formed in a constant shape from top to bottom; A shear key 550 protruding from the upper part to the lower part of the precast concrete channel segment 500 in a predetermined shape on the other side of the precast concrete channel segment 500 corresponding to the shear key groove 540; A connection groove 560 which is formed at a predetermined depth from the upper end of the shear key groove 540 to a lower end and formed to have a constant thickness inward; A fixing jaw 570 cut out at a predetermined height to the inside of the channel segment 500 for precast concrete grating; And a grating 580 fixedly installed across the fixing jaws 570.

That is, the water channel segment structure for precast concrete grating using the torsional steel according to the present invention includes a water channel segment 500 for precast concrete grating, a truncated cone portion 510, a torsion joint steel portion 520, a sheath pipe 530, A shear key groove 540, a shear key 550, a connection groove 560, a fixing jaw 570 and a grating 580 are organically coupled.

The pre-cast concrete grating water channel segments 500 are formed in the shape of an opening in a cross section, and the grill is formed in the openings. The precast concrete channel segments 500 are formed of at least two precast concrete gratings. The pre-cast concrete grating waterway segments 500 are connected longitudinally to establish a channel for precast concrete grating.

In addition, the beveled portion 510 is formed in a triangular shape as a corner where the surface of the waterway segment 500 for precast concrete grating meets the surface.

The stress-relieving steel material is a member embedded in the longitudinal direction at the upper and lower portions 510 of the channel segment 500 for precast concrete grating.

The tension steel member 520 includes a steel bar or a steel wire 522 having a predetermined length and a fastening groove 523 formed by winding both ends of the steel bar or steel wire 522 in an annular shape. And an R-shaped fastening pin 590 is inserted into the through hole 590. [

The tension steel member 520 includes a steel bar or a steel wire 522 having a predetermined length and a male screw portion 524 having threads at both ends of the steel bar or steel wire 522, And a T-type fastening pin 600 is inserted into the fastening groove 526. The fastening groove 526 is formed in the fastening groove 526. The fastening groove 526 is formed in the fastening groove 526, And the T-shaped fastening pin 600 has a T-shape as a whole and includes a body 602 having a through hole 604 formed at a lower portion thereof and a fixing pin 604 inserted into the through hole 604 of the body 602. [ (606).

The reinforcing steel member 520 is composed of a steel bar or steel wire 522 having a predetermined length and a protruding protrusion 527 protruding at a predetermined thickness from both ends of the steel bar or steel wire 522, An N-type fastening pin 610 is inserted into the through-hole 527, and the N-type fastening pin 610 is formed in a hexahedron shape with a bottom wall as a whole; An insertion groove 614 is formed in two surfaces in the same direction of the main body in a predetermined shape.

88 and 89, a sleeve nut 920 is provided on the outer circumferential surface of the steel bar or steel wire 522. The sleeve nut 920 has a thread 922 formed on the inner circumferential surface thereof, Sectional shape.

The sleeve nut 920 is provided to enhance adhesion between the steel bar or the steel wire 522 with the concrete.

The sheath tube 530 is a kind of hollow tube for protecting the wire rope inserted into the sheath tube 530.

Here, the wire rope is a steel material disposed on the sheath pipe 530 to give a prestress to the precast concrete grating water channel segment 500.

In addition, the shear key groove 540 is a member which is formed by being recessed and formed in a predetermined shape from one side of the water channel segment 500 for precast concrete grating to the other side.

The shear key 550 is a member protruding in a constant shape from the upper part to the lower part on the other side of the channel segment 500 for precast concrete grating so as to correspond to the shear key groove 540.

The shear key 550 protrudes from the channel segment 500 for precast concrete grating and the shear key groove 540 coupled to the shear key 550 has a central portion formed therein.

The shear key 550 has one side of the channel segment 500 for precast concrete grating protruding and one side of the shear key groove 540 coupled to the shear key 550 is formed.

The connection groove 560 is a member which is recessed and formed at a constant depth from the upper end of the shear-key groove 540 to a predetermined depth.

The fixing jaw 570 is cut out at a predetermined height to the inside of the channel segment 500 for precast concrete grating.

In addition, the grating 580 is made of concrete or reinforced concrete, and is fixed across the fixing jaws 570.

The shear key 550 is provided with a water inflating index material 630 at an upper portion thereof and a caulking material 640 at an upper portion of the water inflating index material 630.

In particular, the water-swellable index material 630 is installed on the connection surface of the channel segment 500 for precast concrete grating, thereby functioning to receive the water flowing out of the channel segment 500 for precast concrete grating .

Hereinafter, the construction of the channel segment structure for precast concrete grating using the torsional steel according to the present invention will be described.

As shown in FIGS. 44 (b) and 48 (b), a method of manufacturing a channel segment structure for precast concrete grating using a steel sheet for a tension according to the present invention comprises the steps of: 900 and a sheath pipe 530 are installed in the periphery of the concrete casting 500 and the concrete is placed and cured in the formwork to produce a precast concrete grating water channel segment 500.

Hereinafter, construction of the channel segment structure for precast concrete grating using the above-described fabricated steel material according to the present invention will be described.

FIG. 51 is a perspective view 1 and FIG. 52 showing a state of engagement between waterway segments for precast concrete grating using a torsional steel material according to the present invention, and FIG. 51 is an enlarged view of the state of joining between a shear key and a shear key groove of a waterway segment for precast concrete grating shown in FIG. Detailed Diagrams 1 and 52 show enlarged views of the state of engagement between a shear key and a shear-key groove of a waterway segment for precast concrete grating in FIG. 51. Detailed Diagrams 2, 54 (a), (b) 55 (a), (b), and (c) are views showing examples of a steel sheet which is used in combination with the tension of a waterway segment for precast concrete grating using a tension steel sheet according to the present invention, Figs. 56 (a), (b) and (c) are views showing a connecting pin of a water channel segment for grating, 61 is a perspective view showing a state of engagement between water channel segments for precast concrete grating using a tension steel material according to the present invention, and FIG. 61 is a perspective view showing a state in which the segments are connected by a tension- 61 is an enlarged view of the state of engagement between the shear-key groove and the shear-key groove of the precast concrete grating in Fig. 61. Fig. 1 and Fig. 63 are enlarged views of the shear- 65 (a), 65 (b) and 64 (c) are views showing an example of a steel sheet for use in tensioning of a channel segment for precast concrete grating using a steel sheet with a tension according to the present invention, (a), (b) and (c) are views showing an example of a fastening pin of a waterway segment for precast concrete grating using a steel sheet for a tension according to the present invention, Using the tension of the steel combined persons precast concrete grating is illustrated by the state connecting the channel segment in tension combined with the steel retaining pin shown for FIG.

As shown in these drawings, a method of constructing a channel segment structure for precast concrete grating using a torsional steel according to the present invention comprises the steps of: transporting a channel segment 500 for precast concrete grating to the vicinity of an installation site; Mounting the conveyed pre-cast concrete grating water channel segment (500) in a longitudinal direction using a heavy equipment at an installation site; Inserting the shear key 550 of the channel segment 500 for precast concrete grating on the other side into the shear-key groove 540 of the channel segment 500 for precast concrete grating at one side, Inserting and fixing fastening pins (590, 600, 610) between the steel sheets (520) serving as the tension between the closely spaced precast concrete grating water channel segments (500); The mortar 910 is filled and cured between the shear key groove 540 of the channel segment 500 for precast concrete grating at one side and the shear key 550 of the channel segment 500 for precast concrete grating at the other side, Providing a water swellable index material (630) on the mortar (910) and filling the water swellable index material (630) with a caulking material (640); And inserting and straining the wire rope into the sheath tube 530 of the channel segment 500 for precast concrete grating.

That is, the method for constructing the channel segment structure for precast concrete grating using the torsional steel according to the present invention is characterized in that after the precast concrete channel segment 500 for grinding concrete is transported to the vicinity of the installation site, The water channel segment 500 is installed in the installation site in the longitudinal direction using a heavy equipment, and then the pre-cast concrete grating water channel 540 of the fixed water channel 500 for the pre- The fastening pins 590, 600 and 610 are inserted and fixed between the tightening steel sheets 520 between the closely adjacent channel segments 500 for precast concrete grating after the shear keys 550 of the segments 500 are inserted and tightened. The shear grooves 540 of the channel segments 500 for precast concrete grating at one side and the free The mortar 910 is filled and cured between the shear keys 550 of the waterway segment 500 for the concrete concrete grating and the water inflating index material 630 is provided on the hardened mortar 910, And the wire rope is inserted and tightened in the sheath pipe 530 of the precast concrete grating water channel segment 500 so as to construct a precast concrete grating channel .

[Precast Concrete Retaining Wall Segment]

FIG. 67 is a perspective view 1 and FIG. 68 (a) of a precast concrete retaining wall segment using a tie-breaking steel material according to the present invention. FIG. 67 is a front view of a precast concrete retaining wall segment using a tie- 68 (b) is a sectional view (1) and (69) showing a precast concrete retaining wall segment using a torsional steel material according to the present invention, and FIG. 69 is a plan view showing a precast concrete retaining wall segment using a torsional steel material according to the present invention 77 is a perspective view 2 and FIG. 78 (a) showing a precast concrete retaining wall segment using a torsional steel according to the present invention, and FIG. 78 is a front view showing a precast concrete retaining wall segment using a torsion steel 78 (b) are sectional views 2 and 79 of a pre-cast concrete retaining wall segment using a torsional steel material according to the present invention Precast 2 is a plan view showing a concrete retaining wall segment using a Combine tension steel according to the invention.

As shown in these drawings, a pre-cast concrete retaining wall segment structure using a torsional steel according to the present invention is a precast concrete retaining wall formed by connecting at least two or more precast concrete retaining wall segments in the longitudinal direction, The concrete retaining wall segment 700 includes a tensioned steel material 720 which is longitudinally buried in the upper portion and the shallow portion 710; A sheath pipe 730 spaced apart from the tension steel material 720 by a predetermined distance and buried in the longitudinal direction of the upper and the bezel 710; A pre-cast concrete retaining wall segment (700) having a shear key groove (740) formed on one side of the pre-cast concrete retaining wall segment (700) A shear key 750 protruding from the upper portion to the lower portion of the precast concrete retaining wall segment 700 corresponding to the shear key groove 740 in a predetermined shape; And a connection groove 760 which is recessed and formed to a predetermined depth from the upper end of the shear-key groove 740 to the lower end and a predetermined thickness inward.

That is, the precast concrete retaining wall segment structure using the torsional steel according to the present invention includes a precast concrete retaining wall segment 700, a beveling portion 710, a torsion joint 720, a sheathing tube 730, , A shear key 750, and a connection groove 760 are organically coupled to each other.

Here, the precast concrete retaining wall segment 700 is formed in an L-shape in cross section, and at least two or more precast concrete retaining wall segments 700 are connected in the longitudinal direction to construct a precast concrete retaining wall.

In addition, the relief portion 710 is formed in a triangular shape as a corner where the surface of the precast concrete retaining wall segment 700 meets the surface.

The stress-relieving steel material 720 is a member that is embedded in the longitudinal direction of the pre-cast concrete retaining wall segment 700 and the upper portion 710.

The tension member 720 is composed of a steel bar or a steel wire 722 having a predetermined length and a connecting groove 723 formed by winding both ends of the steel bar or the steel wire 722 in an annular shape. The R-shaped fastening pin 770 is inserted.

The tension member 720 includes a steel bar or a steel wire 722 having a predetermined length, a male screw portion 724 having threads at both ends of the steel bar or steel wire 722, And a T-shaped fastening pin 780 is inserted into the fastening groove 726 so as to be inserted into the female threaded portion 725 The T-shaped fastening pin 780 has a T-shape as a whole and includes a body 782 having a through hole 784 formed at a lower portion thereof and a fixing pin 782 inserted into the through hole 784 of the body 782. [ (786).

The tension member 720 is composed of a steel bar or a steel wire 722 having a predetermined length and a protruding protrusion 727 protruding at a predetermined thickness from both ends of the steel bar or steel wire 722, An N-type fastening pin 790 is inserted into the N-type fastening pin 727, and the N-type fastening pin 790 has a hexahedron-shaped main body 792 having a bottom wall as a whole; An insertion groove 794 is formed in two sides of the main body 792 in the same direction.

88 and 89, a sleeve nut 920 is provided on the outer circumferential surface of the steel bar or steel wire 722. The sleeve nut 920 has a thread 922 formed on the inner circumferential surface thereof, Sectional shape.

The sleeve nut 920 is provided to enhance the adhesion between the steel bar or the steel wire 722 with the concrete.

The sheath tube 730 is a kind of hollow tube for protecting the wire rope inserted into the sheath tube 730.

Here, the wire rope is a steel material disposed on the sheath pipe 730 to give a prestress to the precast concrete retaining wall segment 700.

In addition, the shear key groove 740 is a member formed by recessing a predetermined shape from one side of the precast concrete retaining wall segment 700 to the other.

The shear key 750 is a member protruding in a predetermined shape from the upper part to the lower part on the other side of the precast concrete retaining wall segment 700 so as to correspond to the shear key groove 740.

The shear key 750 protrudes from the precast concrete retaining wall segment 700 and the shear key groove 740 coupled to the shear key 750 is formed in a central portion thereof.

The shear key 750 is protruded from the precast concrete retaining wall segment 700 and the upper portion of the shear key groove 740 coupled to the shear key 750 is recessed.

The connection groove is a member which is recessed and formed at a predetermined depth and a predetermined thickness from the upper end of the shear key groove 740 to the lower end.

On the other hand, the shear key 750 is provided with a water expandable index material 810 at an upper portion thereof, and a caulking material 820 is provided at an upper portion of the water expandable index material 810.

In particular, the water extensible index material 200 is installed on the connection surface of the precast concrete retaining wall segment 700, so that the leakage of the water flowing out from the precast concrete retaining wall segment 700 and the groundwater introduced from the outside .

Hereinafter, the production of the pre-cast concrete retaining wall segment structure using the steel material having the above-described construction according to the present invention will be described.

As shown in FIGS. 68 (b) and 78 (b), a method of manufacturing a precast concrete retaining wall segment structure using a steel sheet for a tension according to the present invention comprises the steps of: placing reinforcing bars 900 in a formwork A tension steel 720 and a sheath pipe 730 are installed in the vicinity of the reinforcing bar 900 and the concrete is placed and cured in the formwork to produce a precast concrete retaining wall segment 700.

Hereinafter, the construction of the pre-cast concrete retaining wall segment structure using the above-described fabricated steel material according to the present invention will be described.

FIG. 70 is a perspective view 1 and FIG. 71 is a cross-sectional view taken along the line AA in FIG. 70, FIG. 72 is a cross-sectional view of the shear key of the precast concrete retaining wall segment of FIG. 71 Detail views 1 and 73 showing an enlarged view of the joining state between the shear-key grooves show detail views 2, 74 (a), (b), and (c) of FIG. 71 showing an enlarged view of the joining state between the shear- 75 (a), 75 (b) and 75 (c) are views showing an example of a steel sheet for use in a precast concrete retaining wall segment using a tension steel sheet according to the present invention, 76 (a), (b) and (c) are views showing an example of a connecting pin of a cast concrete retaining wall segment, in which a pre-cast concrete retaining wall segment using a steel sheet for a tension according to the present invention is used as a tension-FIG. 80 is a perspective view 2 showing a state of engagement between precast concrete retaining wall segments using a torsional steel material according to the present invention, FIG. 81 is a sectional view taken along the line AA in FIG. 80, Detail views 1 and 83 showing an enlarged view of a state of engagement between a shear key and a shear-key groove of a precast concrete retaining wall segment are shown in detail in FIGS. 2 and 84 (a FIGS. 85 (a), 85 (b), and 85 (c) are views showing an example of a torsion joint steel of a precast concrete retaining wall segment using a torsional steel according to the present invention, 86 (a), 86 (b) and 86 (c) are cross-sectional views showing a case where the pre-cast concrete retaining wall segment using the steel material for tension according to the present invention An illustration showing the state of connection to tension the steel combined with the retaining pin FIG.

As shown in these drawings, a method of constructing a precast concrete retaining wall segment structure using a torsional steel material according to the present invention includes the steps of: transporting a precast concrete retaining wall segment 700 to a vicinity of an installation site; Mounting the carried precast concrete retaining wall segment (700) in a longitudinal direction by using a heavy equipment at an installation site; Inserting the shear key 750 of the precast concrete retaining wall segment 700 on the other side into the shear key groove 740 of the pre-cast concrete retaining wall segment 700 on the one side, Inserting and fixing fastening pins (770, 780, 790) between the tensioned steel members (720) between the tightened precast concrete retaining wall segments (700); The mortar 910 is filled and cured between the shear key groove 740 of the one precast concrete retaining wall segment 700 and the shear key 750 of the precast concrete retaining wall segment 700 of the other side and the cured mortar 910 Providing a water swellable index material (810) on the water swellable index material (810), filling the water swellable index material (810) with a caulking material (820) and connecting the same; And inserting and tightening the wire rope into the sheath tube 730 of the precast concrete retaining wall segment 700.

That is, the method of constructing a precast concrete retaining wall segment structure using the tie-breaking steel material according to the present invention is characterized in that after the precast concrete retaining wall segment 700 is transported to the vicinity of the installation site, the precast concrete retaining wall segment 700 The shear key 750 of the precast concrete retaining wall segment 700 on the other side is inserted into the shear-key groove 740 of the precast concrete retaining wall segment 700 of the one fixed side, 780 and 790 are inserted and fixed between the adjacent precast concrete retaining wall segments 700 and the tension members 720 between the precast concrete retaining wall segments 700. The precast concrete retaining wall segments 700 The mortar 910 is filled and hardened between the shear key groove 740 of the pre-cast concrete retaining wall segment 740 and the shear key 750 of the other precast concrete retaining wall segment 700 A water swellable index material 810 is installed on the cured mortar 910 and a caulking material 820 is filled on the water swellable index material 810 and connected to the precast concrete retaining wall segment 810. [ 700 is inserted and tightened to the precast concrete retaining wall.

100: precast concrete culvert segment 110:
120: Strain joint steel 122: Steel rod or steel wire
123: fastening groove 124: male thread portion
125: female thread portion 126: fastening groove
127: protruding jaw 130: sheath tube
140: Flyer Keys Home 150:
160: R-shaped fastening pin 170: T-shaped fastening pin
172: main body 174: through hole
176: fixing pin 180: N-type fixing pin
182: main body 184: insertion groove
200: water expandable index material 210: caulking material
220: opening groove 230: grating
300: precast concrete channel segment 310:
320: Steel for combined tension 322: Steel rod or steel wire
323: fastening groove 324: male thread portion
325: female thread portion 326: fastening groove
327: protruding jaw 330: sheath tube
340: shear key groove 350: shear key
360: connecting groove 370: R-shaped connecting pin
380: T-shaped fastening pin 382:
384: Through hole 386: Fixing pin
390: N-type fastening pin 392:
394: insertion groove 410: water expansive index material
420: caulking material
500: Waterway segment for precast concrete grating
510: Special portion 520: Steel for combined tension
522: steel bar or steel wire 523: fastening groove
524: male thread portion 525: female thread portion
526: fastening groove 527: projecting jaw
530: Sheath tube 540: Shear-key groove
550: Shear key 560: Connection groove
570: Fixing jaw 580: Grating
590: R-type fastening pin 600: T-shaped fastening pin
602: main body 604: through hole
606: fixing pin 610: N-type fixing pin
612: main body 614: insertion groove
630: water expansive index material 640: caulking material
700: precast concrete retaining wall segment 710:
720: Steel for combined tension 722: Steel rod or steel wire
723: fastening groove 724: male thread portion
725: female thread portion 726: fastening groove
727: protruding jaw 730: sheath tube
740: Flyer Keys Home 750:
760: connection groove 770: R-shaped fastening pin
780: T-shaped fastening pin 782:
784: Through hole 786: Fixing pin
790: N-type fastening pin 792:
794: insertion groove 810: water expansive index material
820: caulking material 900: reinforcing steel
910: Mortar 920: Sleeve nut

Claims (19)

1. A precast concrete grating channel in which at least two or more precast concrete grating water channel segments are connected in the longitudinal direction,
The pre-cast concrete grating water channel segment 500 includes a tension steel material 520 buried in the upper and lower circumferential portions 510 in the longitudinal direction, respectively;
A sheath pipe (530) spaced apart from the steel sheet (520) by a predetermined distance and embedded in the longitudinally extending portions (510) of the upper and lower portions, respectively;
A shear key groove 540 formed on one side of the channel segment 500 for precast concrete grating so as to be formed in a constant shape from top to bottom;
A shear key 550 protruding from the upper part to the lower part of the precast concrete channel segment 500 in a predetermined shape on the other side of the precast concrete channel segment 500 corresponding to the shear key groove 540;
A connection groove 560 which is formed at a predetermined depth from the upper end of the shear key groove 540 to a lower end and formed to have a constant thickness inward;
A fixing jaw 570 cut out at a predetermined height to the inside of the channel segment 500 for precast concrete grating;
And a grating (580) fixedly installed across the fixing jaws (570). The prefabricated channel segment structure for precast concrete grating using the torsion joint steel. The method according to claim 1,
Wherein the predetermined portion (510) is formed in a triangular shape. The prefabricated channel segment structure for precast concrete grating using the torsional steel material. The method according to claim 1,
Wherein the tension steel member 520 comprises a steel bar or steel wire 522 having a predetermined length and a fastening groove 523 formed by winding both ends of the steel bar or steel wire 522 in an annular shape. Waterway Segment Structures for Precast Concrete Gratings. The method according to claim 1,
The tension steel member 520 includes a steel bar or a steel wire 522 having a predetermined length and a male screw portion 524 having threads at both ends of the steel bar or steel wire 522 and a male screw portion 524 screwed to the male screw portion 524 And a fastening groove (526) formed in the internal thread portion (525), wherein the fastening groove (526) is formed with a thread on the inner periphery. The method according to claim 1,
Wherein the tensile steel member 520 comprises a steel bar or a steel wire 522 having a predetermined length and a protruding step 527 protruding at a predetermined thickness from both ends of the steel bar or steel wire 522. [ Waterway Segment Structures for Precast Concrete Gratings Using. The method of claim 3,
And an R-shaped fastening pin (590) is inserted into the fastening groove (523) so as to form a channel segment structure for precast concrete grating. 5. The method of claim 4,
And a T-shaped fastening pin (600) is inserted into the fastening groove (526). The channel structure for precast concrete grating using the steel material for tension and torsion. 8. The method of claim 7,
The T-shaped fastening pin 600 has a T-shape as a whole and includes a body 602 having a through hole 604 formed at a lower portion thereof and a fixing pin 606 inserted into the through hole 604 of the body 602 Wherein the prefabricated concrete segment grating is constructed of a plurality of prefabricated concrete members. 6. The method of claim 5,
And an N-type fastening pin (610) is inserted into the protruding step (527). A channel segment structure for precast concrete grating using the strain-resistant steel material. 10. The method of claim 9,
The N-type fastening pin 610 includes a main body 612 having a hexagonal shape with a bottom wall as a whole; Wherein an insertion groove (614) is formed in two surfaces of the main body in the same direction in a predetermined shape to form a channel segment structure for precast concrete grating using the tension steel. The method according to claim 1,
And a wire rope is inserted into the sheath pipe (530). The pre-cast concrete structure for precast concrete grating using the steel material for tension and torsion. The method according to claim 1,
Wherein the shear key 550 protrudes from the channel segment 500 for precast concrete grating and the center portion of the shear key groove 540 coupled to the shear key 550 is recessed and formed. Waterway segment structures for cast concrete gratings. The method according to claim 1,
Wherein the shear key 550 is formed by protruding one side of the channel segment 500 for precast concrete grating and one side of the shear key groove 540 coupled to the shear key 550 is formed in a recessed shape. Waterway Segment Structures for Precast Concrete Gratings. The method according to claim 1,
Wherein the shear key (550) is provided with a water expandable index material (630) on the upper portion thereof. 15. The method of claim 14,
And a caulking material (640) is installed on the water expansive index material (630). The method of claim 3,
Wherein a sleeve nut (920) is provided on the outer circumferential surface of the steel bar or the steel wire (522), the sleeve nut (920) has a threaded portion (922) formed on the inner circumferential surface thereof, Waterway Segment Structures for Precast Concrete Gratings Using Steel. 5. The method of claim 4,
Wherein a sleeve nut (920) is provided on the outer circumferential surface of the steel bar or the steel wire (522), the sleeve nut (920) has a threaded portion (922) formed on the inner circumferential surface thereof, Waterway Segment Structures for Precast Concrete Gratings Using Steel. A method of manufacturing a channel segment structure for precast concrete grating using the torsion steel according to any one of claims 1 to 17, comprising the steps of: placing a reinforcing bar (900) in a formwork, And a sheath pipe (530) are installed on the concrete, and the concrete is placed and cured in the formwork to manufacture a precast concrete grating segment (500). The precast concrete Method of making a segmented structure by water for grating. A method of constructing a waterway segment structure for precast concrete grating using the torsional steel of any one of claims 1 to 17,
Conveying the pre-cast concrete grating waterway segment (500) to the vicinity of the installation site;
Mounting the conveyed pre-cast concrete grating water channel segment (500) in a longitudinal direction using a heavy equipment at an installation site;
Inserting the shear key 550 of the channel segment 500 for precast concrete grating on the other side into the shear-key groove 540 of the channel segment 500 for precast concrete grating at one side,
Inserting and fixing fastening pins (590, 600, 610) between the steel sheets (520) serving as the tension between the closely spaced precast concrete grating water channel segments (500);
The mortar 910 is filled and cured between the shear key groove 540 of the channel segment 500 for precast concrete grating at one side and the shear key 550 of the channel segment 500 for precast concrete grating at the other side, Providing a water swellable index material (630) on the mortar (910) and filling the water swellable index material (630) with a caulking material (640);
And inserting and tightening a wire rope into the sheath pipe (530) of the channel segment (500) for precast concrete grating. ≪ Desc / Clms Page number 19 >

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