KR101109724B1 - A slope territory or heat of city level ground road construction work method - Google Patents

Abstract

PURPOSE: A covered road construction method for a slope area or a city level ground area is provided to construct a covered road with a minimized cut area, thereby reducing a construction period. CONSTITUTION: A covered road construction method for a slope area or a city level ground area is as follows. In a covered road area, the ground is excavated in a stepwise manner along a slope from an end where an upper slab is installed. Holes are bored along width edges of the covered road area, CIP bulbs are inserted in the holes, and concrete is placed and cured(S10). Wall foundation excavating work is implemented from the inner side of the CIP bulbs and earth anchors are formed outward from the CIP bulbs(S20). A column part is formed vertically upward from a lower girder and a supporting part for supporting upper slabs is formed on the top of the column part(S30). The upper slabs are installed in crossing directions on the top of the supporting part(S40). A ventilation tower is installed through a selected area of the upper slabs in order to circulate and discharge air inside covered ground to outside(S50). Lower slab bars are assembled after the foundation cured, concrete is placed and cured, asphalt is placed, and lower slabs are installed(S60).

Description

Method of constructing open road in slope existence area or urban plain area {A SLOPE TERRITORY OR HEAT OF CITY LEVEL GROUND ROAD CONSTRUCTION WORK METHOD}

The present invention relates to a method of construction of the open road, and more particularly, to a method of constructing the open road for constructing a road to an area of a section having a slope while a feature such as a mountain exists.

When constructing a road in a section where a feature such as a mountain exists, especially when constructing a road that covers a mountain waist or an area below the mountain, a stepped cut from the construction area of the road toward the top of the mountain is generally performed. Will be built.

In the case of the conventional road construction method, the cut soil is formed at an angle from the end of the road width to the left upward or right upward direction, and after the completion of the road, the uncut soil is not completely recovered. The environment is, of course, the cause of ecosystem destruction.

The present invention is to solve the above problems, such as, when constructing a road formed on a terrain feature, such as mountains, so that the road construction can be made while minimizing the area of the soil so as to significantly reduce the air due to the construction of the road Its purpose is to protect the environment and the ecosystem by making it possible to cover the necessary parts of the soil that is laid off after road construction.

The present invention for achieving the above object,

Earth excavation and CIP drilling step (S10), wall unit installation step (S20), column installation step (S30), upper slab installation step (S40), ventilation tower installation step (S50), lower slab installation process (S60) Is done through.

According to the present invention, when constructing a road formed on a terrain feature such as a mountain, it is possible to significantly reduce the air due to the road construction by minimizing the area to be cut off, as well as after the road construction It is possible to cover the necessary areas of the areas to be protected, thereby protecting the environment and the ecosystem.

1 is a block diagram illustrating a process flow diagram of the present invention.
FIG. 2 is a view schematically illustrating a process of excavating earthworks to excavate a slope in an oblique direction from an area forming a road so that an upper area where a road is formed is exposed; FIG.
3 is a schematic diagram showing the interior of the CIP group;
4 is a view showing a state in which the trench work of the wall portion is made;
5 is a view showing that after the completion of the wall unit installation step, the pillar portion is constructed by digging the central portion constituting the abdominal road
FIG. 6 is an exploded perspective view illustrating a detached state of the pillar part according to FIG. 5. FIG.
7 is a schematic cross-sectional view of the upper slab is installed
8 to 9 are schematic views showing a state in which the upper slab is covered and the lower slab is installed after the upper slab and the ventilation tower are installed.
FIG. 10 is an enlarged view of a portion “A” of FIG. 9; FIG.
FIG. 11 is a view showing a central connection part for connecting a portion formed by contacting an end portion between an upper slab and an upper slab.
Figure 12 is an enlarged view showing an embodiment for fixing the connection between the upper slab and the CIP bulb and the wall contacting
13 to 14 are enlarged views showing that the hinges can be connected to each other by connecting the upper slab, the CIP bulb, and the contact portion between the walls.
FIG. 15 is an enlarged view of a portion connecting the side surfaces of the upper slab 300 as described above.
FIG. 16 is an enlarged view of a portion of the upper slab contacting the upper slab side in FIG. 15.
17 is an exploded perspective view showing a state in which the upper slab is separated
18 is a perspective view illustrating a state where the covered underpass is completed;

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

The present invention is earth excavation and CIP drilling step (S10), wall unit installation step (S20), pillar installation step (S30), upper slab installation step (S40), ventilation tower installation step (S50), lower slab installation step (S60) )

Earth excavation  And CIP  Drilling Steps- S10

In this step, as shown in Figure 2, excavation of the slope in an oblique direction from the area forming the road to be excavated to expose the upper area where the road is formed.

When excavating the slope from the side of the road in the road area, the amount of earthwork work is considerable, in the present invention was to be excavated from the end where the upper slab is installed in the covered underpass area, to reduce the amount of earthwork.

As described above, in order to form a road in the area passing through the slope where the mountain exists, the hole 101 in which the CIP bulbs 100 can be inserted at both ends corresponding to the width of the covered underpass after excavation in the slope direction is performed. Perforated) to be formed into an inner wall.

Formed as an inner wall using the CIP bulb 100 in the present invention, the wall of the central portion is to be realized through a separate configuration, a description thereof will be described later.

On the other hand, the cast-in-place pile (CIP) bulb 100 is a plurality of reinforcement 110 is arranged in a spherical shape as shown in Figure 2 to have a rectangular shape surrounding the outer peripheral side of the reinforcement 110 The band reinforcing bars 120 are formed at equal intervals.

By placing and curing concrete in the interior of the CIP bulb 100, it is possible to form a cylindrical CIP bulb 100 consisting of a single unit, otherwise the hole 101 for the CIP bulb 100 is inserted ) And then insert the CIP bulb 100 into the hole 101 and then pour concrete to obtain a finished CIP bulb 100.

In this case, when the bedrock layer is high, the CIP bulb 100 may be formed only in the soil layer, and when the bedrock layer is higher, the CIP bulb 100 may not be formed.

Wall  Facility Level- S20

In this step, when the insertion of the CIP bulb 100 is completed through the earth excavation and the CIP drilling step S10, the wall part is excavated in the inward direction of the CIP bulb 100.

Figure 4 is a view showing a state in which the above-mentioned wall excavation work is made, after completing the wall excavation work to form an Earth Anchor from the CIP bulb 100 to the outward direction from the outer direction of the CIP bulb 100 Make sure to withstand the earth pressure provided.

Reference numeral 102 denotes a wall and is cured into a concrete structure inward of the above-described CIP bulb 100.

In this case, as described above, when the bedrock layer is high, the cancer may be cut off by the cancer of the CIP bulb 100 or less and the wall may be installed.

Column  Facility Level- S30

In this step, after the wall part facility step S20 is completed, the pillar part 200 may be constructed by digging the central part constituting the abdominal road.

5, the lower girder 210 is cured in the lower portion, as shown in FIG. 5, and the pillar 200 is cured vertically from the lower girder 210.

The pillar part 200 may be formed in a wall or in the form of a circular or spherical column, which may be selectively installed depending on work site conditions.

The support part 220 for supporting the upper slab 300 is configured inside the pillar part 200.

The support 220 may be implemented as shown in FIG. 6, which is formed in a cross-section “○” and has a hollow shape to have a shape in which a pair of fixing members 221 are opposed to each other and have a shape that is open. 200 to be fixed to the inner surface, and between the fixing member 221 and the fixing member 221 to be connected and fixed using a PC steel bar 222.

Using the PC steel bar 222, connecting the fixing member 221 and the fixing member 221 to be tensioned, the upper slab 300 is made of a pair of fixed in the form of a "Y" When the mounting member 221 is seated on the upper surface of the upper slab by the weight of the upper slab 300, the fixing member 221 gradually widens the opening angle to prevent phenomena such as fracture or breakage, and the stable support of the upper slab 300 To make it possible.

In addition, as shown in Figure 6 it is preferable to be connected and fixed between the set of fixing members 221 and another set of fixing members 221 which are spaced apart from the side using the cross-connection steel pipe 223.

As described above, the connecting steel pipe 223 is spaced apart from the fixing member 221 in the lateral direction, that is, the opening direction, and the other fixing member 221 fixed to the upper surface of the support part 220 of the pillar part 200. To this end, the transverse connection steel pipe 223 is fixed to the part in contact with the fixing member 221 and the fixing member 221 by welding or bolting.

The upper slab 300 is seated on the fixing member 221 by fixedly connecting between the set of the fixing member 221 and the other set of the horizontal connecting steel tube 223 spaced apart laterally by the transverse connecting steel pipe 223. After the construction will be able to prevent the phenomenon that the fixing member 221 is twisted by the weight of the upper slab 300 in advance.

On the other hand, provided with a flat plate 224 discontinuously to the end side of the other fixing member 221 which is laterally spaced apart from the fixing member 221, the transverse connecting steel pipe 223 described above on the lower side of the flat plate 224. The flat plate 224 is configured to support the upper surface of the upper plate 224, and the non-shrink pad 225 is provided on the upper surface of the flat plate 224, so that the stable support when contacting the upper slab 300 is supported. It is preferable to configure so that it is possible.

Upper slab installation steps- S40

This step is an upper slab 300 made of unit material as the upper surface of the fixing member 221 is spaced at equal intervals on the upper surface of the support portion 220 of the pillar portion 200 and installed along the advancing underpass. As in the step means to settle.

The upper slab 300 is to be installed in a state in contact with each other by using a structure having an arc shape as a concrete curing structure consisting of a plurality of unit ubiquitous, so that the upper slab 300 consisting of the unit ubiquitous staggered mutually installed However, it is preferable to be configured to be in contact with each other. (See Figs. 15 and 17 to 18).

In addition, a configuration for connecting the upper slabs 300 with the wall 102 on each side is required, as shown in FIG. 16, between the upper slab 300 and the upper slab 300 sides between the reinforcing bars 310 and 320. To connect.

The reinforcing bars 310 and 320 are bent end portions of the reinforcing bar 310 protruding in a straight line from one side of the upper slab 300 to form a bent portion 311, and the corresponding reinforcing bar 320 is the other upper slab. After forming the groove 330 on the side of the 300 to be formed in a vertical state, the bent portion 311 of the reinforcement 310 to hold the reinforcement 320, and then inside the groove 330 By mortar treatment it is possible to firmly fix the side portions of the upper slab (see Figs. 15 to 16).

In addition, it is preferable to block the water flowing through the upper slab 300 by using a waterproof sheet and a watertight sheet as the upper surface of the upper slab 300 and the upper slab 300 contact.

On the other hand, the upper slab 300 and the upper slab 300 is formed in an arc shape, the center connecting portion 340 for connecting the center portion is in contact with each other is configured as shown in Figure 11, the center connecting portion 340 ) Forms a fixed block 342 cured with concrete in a portion between the upper slab 300 and the connection between the fixed block 342 and the upper slab 300 using a fastener 343, the Mortar 344 is processed on the upper end side of the fixture 343.

As described above, the central portion in contact with the upper slab 300 and the upper slab 300 is fixedly connected to each other by the central connecting portion 340. As described above, the upper slab 300 is installed to be in contact with each other. Therefore, the center connecting portion 340 is to be formed over the entire upper portion of the upper slab 300, that is, the direction of travel to the open road.

On the other hand, the upper side of the upper slab 300 and the wall 102 should be in contact with and fixed.

The method of interconnecting the upper slab 300 and the upper end of the CIP bulb 100 and the wall 102 can be implemented by dividing the fixed and hinged, Figure 12 is the upper slab 300 and the CIP bulb 100 and A fixed connection method of the wall 102 is illustrated, and FIGS. 13 to 14 illustrate a hinged connection method of the upper slab 300, the CIP bulb 100, and the wall 102.

First, a fixed connection method between the upper slab 300 and the CIP bulb 100 and the wall 102 shown in FIG. 12 will be described.

As shown in FIG. 12, inside the CIP bulb 100, the reinforcing bar 110 provided inside the wall 102 extends upwards, and fixing and connecting the reinforcing bar 351 provided inside the upper slab 300. To the outside, the reinforcing bar 350 provided in the interior of the upper slab 300 is extended from the end side of the upper slab 300 CIP bulb main reinforcement 108 extending upward in the CIP bulb 100 And the reinforcement 350 is to be connected and fixed by welding and lap method, such as between the upper slab 300 and the upper end of the CIP bulb 100 and the wall 102 and the above CIP bulb reinforcement 108 and The spaces 130a and 130b should be configured to form the reinforcing bars 110 and 350 so as to be fixed to each other. After the fixing of the CIP bulb main reinforcing bars 108 and the reinforcing bars 110 and 350 is completed, Pouring secondary concrete.

13 to 14 are shown for the hinged connection method between the upper slab 300 and the CIP bulb 100 and the wall 102, Figure 12 is rounded so that the end side of the upper slab 300 rounded A round plate 361 is formed on the round part 360, wherein the round part 360 is formed in an arc shape.

Meanwhile, the upper surfaces of the corresponding CIP bulb 100 and the wall 102 form an arc groove 140 having an arc shape, and fix the arc plate 141 to the inner circumferential surface of the arc groove 140, thereby allowing the upper slab to be fixed. Round part 360 of the 300 and the arc groove 140 to be in contact with each other while installing the upper slab 300 to connect the central portion between the upper slab 300 and the upper slab 300 as described above When the work is made or the work to fit the center portion of the upper slab 300 can provide a range that can be rotated at a certain angle can provide the usefulness and convenience of the work.

Meanwhile, the reason why the arc plate 141 protrudes on the upper surface of the CIP bulb 100 is to prevent the external waterproof sheet 370 from being damaged and inflow of groundwater, and on the upper surface of the wall 102. The protruding arc plate 141 and the bracket 142 installed on the front surface are to prevent deformation of the upper slab 300 and to prevent the upper slab 300 from falling off.

In addition, when the upper slab 300 is rotated within a certain angle range, there is a risk that water, such as moisture from the outside through the outer surface between the upper slab 300 and the CIP bulb 100, seep, as shown in Figure 12 Comprising a waterproof sheet 370 to cover the upper side outer surface of the CIP bulb 100 from the outer surface of the slab 300, the outer end surface of the upper slab 300 and the upper end of the CIP bulb 100 The waterproof portion 370 has a bellows shape at the boundary portion of the outer portion to have flexibility when the upper slab 300 rotates.

On the other hand, it is preferable to inject a lubricant into the arc groove 140 to help the friction action between the arc plate 141 and the cover plate 161 in the arc groove 140, to prevent rust.

In addition, unlike the above method, a hinge method as shown in FIG. 14 may be adopted.

For example, as shown in FIG. 14, the semi-circular fixing member 150 is formed in a pair on the upper surface of the wall 102 and fixed to be spaced apart, and is pivotable by the hinge 381 while being sandwiched between the fixing members 150. Rotating member 380 is configured to be inserted into and fixed to the end side of the upper slab 300, the process of joining the central portion between the upper slab 300 while contacting the upper surface of the wall 102 when installing the upper slab 300 Ease of use can be secured.

Installation of ventilation tower; S50

In this step, after the installation of the upper slab 300 is completed as described above, it is preferable to install the ventilation tower 400 as shown in FIGS. 17 to 18 to discharge the cloudy air inside the covered underpass to the outside. Do.

In the case of the ventilation tower 400, it may be installed by a generally known installation method.

For example, after cutting the construction to penetrate the area where the ventilation tower 400 can be installed in the upper portion of the upper slab 300 formed in the longitudinal direction of the abdominal underpass, and install the ventilation tower 400 is produced separately or installed on-site Can be constructed by direct production method from.

On the other hand, the upper slab 300 corresponding to the site where the ventilation tower 400 is installed is to be cut so as to penetrate as described above, before the ventilation tower 400 is installed, the section steel 600 to cross the side of the section to be cut By installing a plurality, it is preferable to support between the upper slab 300 and the upper slab 300 formed to face each other.

After the support between the upper slab 300 is made by the section steel 600 as described above, when the connection between the top of the ventilation tower 400 and the upper slab 300 is completed according to the installation of the ventilation tower 400, the section steel 600 Should be demolished.

In addition, the upper surface side of the upper slab 300, the side connection portion between the upper slab 300 and the end portion between the upper slab 300 and the upper slab 300 is in contact with the water resistant sheet 370 and the watertight waterproofing agent, respectively. (Not shown) repeatedly performs waterproofing.

Through the above process can be completed in the form of a covered underpass.

After completing the above steps, when the upper and wall construction of the covered underpass is completed in the area where the slope exists, the upper surface side of the covered underpass is covered to return the area that was cut through to form the covered underpass in the initial construction stage. do.

At this time, in the case of the base rock layer, the cancer is cut off, and when cutting the arm, it should be excavated using no vibration or non-vibration method so as not to damage the structure, and other sidewalks after asphalt paving on the road without installing the lower slab 500. It can be finished by installing internal facilities such as railings and electricity.

Lower Slab Installation Steps- S60

When constructing the open road using the present invention, when the construction area is made of earth and sand, the lower slab should be installed.

Therefore, this step is a step for finishing by installing the lower slab 500 of the lower side of the abdominal underpass after forming the shape of the abdominal underpass when each of the above-described step is composed of earth and sand, etc. First, after the foundation floor is cured, the lower slab reinforcing bars are assembled and concrete is poured. After curing, asphalt is installed and other internal facilities (walkway, railing, electricity, etc.) can be installed to achieve a completed road. .

100; CIP bulb 101; hall
102; Wall 108; CIP Bulb Cast Iron
110; Rebar 120; Steel bars
130a, b; Space 140; Home
141; Arc plate 142; Brackets
150; Fixing member 200; Column
210; Lower girder 220; Support
221; Fixing member 222; PC steel bar
223; Transverse connecting steel pipe 224; Flat plate
225; Non-contraction pad 300; Upper slab
310, 320; Rebar 311; Bent portion
330; Groove 340; Center connection
342; Fixed block 343; Fixture
344; Mortar 350, 351; rebar
360; Round part 361; Round Plate
370; Waterproof sheet 380; Rotating member
381; Hinge 400; Ventilation tower
500; Lower slab 600; Section steel

Claims (9)

In the method of excavating the undercover underpass,
Earthwork excavation is stepwise excavated along the slope from the end where the upper slab 300 is installed in the covered underpass area, and the CIP bulb 100 is inserted along both end sides forming the width of the underpass area to be formed as an inner wall. Earth excavation and CIP drilling step (S10), which drills the hole 101 so that,
When the insertion of the CIP bulb 100 through the earth excavation and CIP drilling step (S10) is completed, after the wall part dig in the inward direction of the CIP bulb 100, outward from the CIP bulb 100 Wall unit facility step (S20) to form the Earth Anchor,
The pillar 200 constitutes a vertical portion from the lower girder 210 which is cured in the lower portion, and the pillar constituting the support portion 220 for supporting the upper slab 300 inside the pillar portion 200. Secondary facility stage (S30),
The upper slab installation step to be installed in a state in contact with each other by using a structure having an arc shape as a concrete curing structure consisting of a plurality of unit pieces, the upper slab 300 made of each unit piece alternately freezing each other (S40) ),
Characterized in that it comprises a ventilation tower installation step (S50) penetrating the area selected from the upper slab 300 is installed by the upper slab installation step (S40) and circulated to discharge the air in the covered underpass to the outside Method of construction on the open road in slope area or urban flat area.
The method of claim 1,
The support portion 220 is fixed to the inner surface of the pillar portion 200 so as to have a form in which a pair of fixing members 221 having a hollow shape in a cross-section and having a “○” shape in cross section and facing each other. 221) and the method of construction in the open road in the slope presence area or the urban flat area including the fixing between the fixing member (221) using a PC steel bar (222).
The method of claim 2,
In the presence of the slope or the urban flat area comprising the connection between the fixing member 221 and the other set of fixing members 221 which are installed spaced apart from the side by using the transverse connection steel pipe 223 How to construct a road on the road.
The method according to any one of claims 2 to 3,
The discontinuous flat plate 224 is fixed on the fixing member 221 and the transverse connecting steel pipe 223 of the support unit 220, and the non-contraction pad 225 is provided on the flat plate 224. Method of construction in the open road in the slope presence area or urban flat area comprising the upper surface of the upper slab (300) in contact with the upper surface of the pad (225).
The method of claim 1,
In order to connect each side of the upper slab 300, between the upper slab 300 and the upper slab 300 side by using mutual reinforcement (310,320), but in a straight line on one side of the upper slab 300 The bent portion 311 is formed by bending an end of the reinforcing bar 310 protruding into the reinforcing bar 310, and the corresponding reinforcing bar 320 forms a recess 330 on the side of the other upper slab 300, and then protrudes. By forming in a vertical state, the bent portion 311 of the reinforcement 310 to hold the reinforcement 320, and then mortar the inside of the groove 330 to fix the side portions of the upper slab (300) A method of constructing a covered road in a slope present zone or downtown flat area comprising connecting.
The method of claim 1,
The upper slab 300 and the upper slab 300 to form a circular arc shape to connect the center portion to be in contact with each other, forming a fixed block 342 cured with concrete inside the portion between the upper slab 300 and The upper slab is connected to and fixed between the fixing block 342 and the upper slab 300 by using a fastener 343, and a central connection part 340 is formed by mortar 344 on the upper end of the fastener 343. 300) and the construction method of the open road in the slope presence area or the urban flat area comprising connecting the central portion in contact with the end side between the upper slab (300).
The method of claim 1,
In order for the end side of the upper slab 300 to be mounted and fixedly supported on the upper surface of the CIP bulb 100, the reinforcing bar 110 inside the wall 102 extends upwardly, and the upper portion It is connected to the reinforcing bar 351 provided in the slab 300, and extends from the end side of the reinforcing bar 351 provided in the upper slab 300 to the outside in the CIP bulb 100 in the upward direction After connecting and fixing the connected reinforcing bars (108) (350), the method of construction on the road in the slope presence area or urban flat area comprising the second concrete to be fixed.
The method of claim 1,
The round part 360 is formed so that the end side of the upper slab 300 is rounded, but the round part 360 is formed with a circular plate 361 which is formed in an arc shape, and the corresponding CIP bulb 100 and The upper surface of the wall 102 forms an arc groove 140 having an arc shape, and fixes the arc plate 141 to the inner circumferential surface of the arc groove 140 to form a round portion 360 of the upper slab 300. Method of constructing the open road in the slope existing area or the urban flat area, including installing the upper slab 300 so that the arc groove 140 is in contact with each other.
The method of claim 1,
The semi-circular fixing member 150 is formed in a pair on the upper surface of the wall 102 to be installed by the wall part installation step (S20) and fixed to be spaced apart, and the hinge 381 is fitted between the fixing members 150. Rotating member 380 configured to be rotatable by insertion is fixed to the end side of the upper slab 300, the center between the upper slab 300 while contacting the upper surface of the wall 102 when the upper slab 300 is installed A method of constructing a covered road in a slope present area or a downtown flat area, comprising ensuring ease of joining of parts.

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