KR200183409Y1 - Precast concrete segment for arch type culvert - Google Patents

Abstract

The present invention is to provide a precast arched passageway construction material that is excellent in the resistance to earth pressure in the construction of underground buried waterways or passages, and can easily shorten the air due to the ease of construction and improve the construction quality. The arched passage is divided into a precast wall material 1 and a ceiling plate 2 so as to be assembled. The partitioned end of the wall material 1 has a ceiling plate 2 on which a support step 3 is to be seated. The ceiling plate 2 is provided with a hooking jaw 4 placed on the pedestal 3 as a connection part, and on the connection part, connection holes 7 and 9 are formed, and at the lower end of the wall material 1 in the width direction. It is a precast arched passage building material in which the parallel ground part 5 was formed.

Description

Precast concrete segment for arch type culvert}

The present invention, in particular, in constructing underground buried waterways or passages (hereinafter, abbreviated as passages), has a high resistance to earth pressure and is easy to construct, which can significantly shorten the air and contribute to maintaining construction quality. It relates to a precast arched passage building material.

In the case of constructing a passage structure embedded in the basement, when concrete is used as a material, a small passage having a diameter of 1,500 mm or less as shown in FIG. In general, a larger passage, and a passage larger than 1.5 x 1.5 m, is constructed by a method of placing a box in a square box-like passage (b) as shown in FIG.

However, there are many attempts to build a factory to improve this point because the method of concrete-casting aisles involves many problems in quality control and process control.

Since the box-type aisle can be manufactured in a factory and transported and installed in the field, it is too large to be realistic and thus a method of dividing and manufacturing into several members can be considered. However, since the moment, which is the main element of the cross-sectional decision of the embankment load buried underground, is difficult to find an appropriate splitting point as shown in FIG.

On the other hand, as shown in Fig. 4, the arched structure is structurally stable in terms of displacement, axial force, shear force, and moment, and thus is one of the structural forms that has been widely adopted since ancient times because of its beauty of ideal and unique curves. Conventionally, many arch arch structures are constructed using only rocks having superior resistance to compression as tension as arch bridge materials to maintain their function for a long time.

Arching the underground passageway structure with concrete as the main material is more economical than the square box-shaped passageway structure, and it is possible to build a more stable structure while showing the beauty of the exposed cross section. Nevertheless, the concrete archway has been a major cause of the extreme reluctance of archway passage due to the various difficulties associated with the construction and installation of formwork necessary for placing concrete on site.

The present invention is a precast agent that can easily build an archway by easily transporting ready-made products to the site by focusing on the difficulty of manufacturing a box-type passage as a structure at the factory and various difficulties caused by on-site casting of the arch structure. To provide archway construction.

The present invention divides the arched passage into precast wall material and ceiling plate, and assembles it.The partitioned end of the wall material has a ceiling plate on which the seat is seated. In this connection portion, a connection cavity for forming a connection hole for strengthening the connection with a connection root is provided, and at the lower end of the wall member, a precast arc-shaped passage building material having a ground portion parallel to the width direction is provided.

1 is a cross-sectional view of the underground buried circular passage

2 is a cross-sectional view of the box-shaped passageway

3 is a moment diagram of the box-shaped passageway

4 is displacement, axial force, shear force and moment diagram of an arch structure

Figure 5 is an exploded view of the precast arched passage building material according to an embodiment of the present invention

6 is an example of the longitudinal connecting portion of the wall material and the longitudinal connecting portion of the ceiling plate;

7 is a front view of a wall material according to another embodiment;

Figure 8 is an exploded perspective view of the precast arched passage building material according to another embodiment

9 is a front view of the wall material upright using the bracket

10 is a partial cutaway front view of an archway constructed with a basic archway construction material;

11 is a cross-sectional view illustrating a seam structure between walls and ceiling plates.

12 is a schematic planar view of a wall and a ceiling plate

FIG. 13 is a partial cutaway front view of an arched passageway constructed of a wall and a ceiling plate with a grate on the connection between the wall and the ceiling plate; FIG.

14 is a construction example of the bottom plate in a special ground

15 is an example of the multiple arched passageway

<Explanation of symbols for main parts of the drawings>

1: wall material 2: ceiling board

3: base jaw 4: base jaw

5: grounding portion 6: pin hole

7,9: connection muscle 8: back muscle

15,16 Slaughter 17,18 Bolting Ball

24: connection bar 25: floor cast iron

26: power muscle 27: floor concrete

29: Bolt

In Fig. 5, the arched passage constructing material provided in the present invention is composed of all of the precast wall material 1 and the ceiling plate 2, regardless of the embodiment. The wall material 1 and the ceiling plate 2 are manufactured using a mold and a manufacturing machine that can be repeatedly manufactured in a factory production or a site.

It should be noted that the arched structure embedded in the basement has the least moment (??) on both sides of the top of the arch as shown in the moment diagram of FIG. 4. Of course, the position varies little by little depending on the upper overload, that is, the fill level, but if the hinge is placed at a certain point in the vicinity, there is no moment at the hinge position and only shear force is generated. Therefore, the wall material 1 and the ceiling plate 2 are separately manufactured by taking this position.

On the upper end of the wall material 1, which is manufactured in accordance with the above standard, a support jaw 3 is formed at the top of the ceiling plate 2, and a stepped jaw 4 is formed at both ends of the ceiling plate 2 to the connection portion. do.

The wall material 1 needs to stabilize an upright posture when it is cured, transported by a source by a vehicle, temporarily mounted near a site, and arranged at a construction site. Therefore, the grounding portion 5 parallel to the width direction of the passage is formed inside and outside the lower end of the wall 1 to increase the grounding force. And the pin hole (6) for fitting the upper pin of the upright posture support bracket at the approximately middle height of the wall is also formed. The pin hole 6 also has a sufficient value as a hook hole for hooking ropes or hooks when carrying out operations such as movement, vehicle storage, getting off and installation using a crane.

In addition, at the upper part of the wall 1, a connecting root 7 is formed to face the ceiling plate in a diagonal direction, and the grounding part 5 is formed with a bottom reinforcement hole 8 penetrating the ground part in the width direction, and is formed along the arched passage. It is possible to maintain the gap between the grounding parts of the facing wall material (1) and to pass through the rebar or PC steel wire for floor concrete.

At both end portions of the ceiling plate 2, the connecting pores 9 corresponding to the connecting pores 7 of the wall material 1 are formed. These connection roots (7, 9) are centered on a vertical line when the ceiling plate (2) is placed between the walls (1) on both sides of the wall by inserting connection bars such as reinforcing bars or PC steel wire and filling with mortar ) And the ceiling plate (2) to maintain the combined state and strength after construction.

FIG. 6 illustrates a fitting element for facilitating connection between the wall materials 1 and the ceiling plate 2, and the support jaw 10 at one end of the wall material 1 and the ceiling plate 2. ) And the other step of forming a stepping jaw (11) corresponding to the support jaw 10 at the other end, and the connecting groove 12 at one end and the connecting projection 13 corresponding to the connecting groove 12 at the other end The method of granting can be assumed.

In FIG. 7, the grounding portion 5 of the wall material 1 has a connecting root 14 protruding inward. The connecting rod 14 is to be connected to the main reinforcing bar reinforcement on the floor, it is easy to connect with the floor main reinforcing bars.

In FIG. 8, the outside of the connection portion of the wall material 1 and the ceiling plate 2 is provided with a reinforcement 15, 16 to increase the strength of the connection portion, and both sides of the reinforcement 15, 16 have a bolt hole 17 whose center coincides with each other. , 18) to be used to stabilize the original assembly with a bolt. If the thickness of the wall (1) and the ceiling plate (2) is maintained in the mutually coupled state itself, but if the thickness of the wall (1) and the ceiling plate (2) is thin, the assembly strength between them will be low. In this case, the decay (15, 16) plays a big role.

In FIG. 9, when the cured wall material 1 is placed upright in a factory, a vehicle, a site near a site, and a construction site, it is safe to use the bracket 20. The bracket 20 is attached to the pin hole (6) to the pin hole (6) on the top of the frame having a height enough to reach the pin hole (6) on the ground or the foundation and the bottom root hole (8) of the ground portion (5) It is attached to the pin 22 to be inserted into, or the tube pin to be inserted into the connecting muscle (14).

In Fig. 10, excavating a place to build an arched passageway, cast concrete (c) of about 10 cm thick on the bottom and flatten the surface to be solidified, and hold the correct position in the vicinity of both sides of the upper bracket (20) Erect the wall (1) using. At this time, the base jaw (3) facing each other facing the wall (1). And the optimum distance between the facing wall (1) is a suitable interval to assemble the top plate (2).

When the wall materials 1 are to be connected to each other, the connection grooves 13 formed on the front surface of the wall material to be built up are connected to the connection grooves 12 formed on the rear surface of the wall material 1, as shown in FIG.

In this way, the ceiling plate (2) is placed on the wall (1) facing each other. At this time, the base of the ceiling plate to be assembled following the connecting groove 12 formed on the back of the ceiling plate 2, which is placed on the base plate 3 of the wall plate 1, while the base plate 2 of the ceiling plate 2 is placed. Proceed by inserting the connecting projection 13 given in the.

In order to further increase the connection strength between the wall material 1 and the ceiling plate 2, half of the ceiling plate 2 is placed in the middle of the length of the wall material 1 and the wall material 1 facing each other as shown in FIG. 12. There is a difference.

When the wall (1) and the ceiling plate (2) are assembled in half, inevitably the front half of the first constructed wall and the rear half of the later constructed wall are covered with a full size ceiling plate (2). The plate 2 is left half by half, so that the ball pair is rough and difficult to process, so this part covers the ceiling plate 2a manufactured in half length or cut accordingly.

After the ceiling plate 2 is placed on the wall material 1, the connection muscles 24 are inserted in each of the connection holes 7 and 9 at each position so that the wall material 1 and the ceiling plate 2 are temporarily removed. Fixing and filling the mortar in the empty space of the remaining connection hole (7,9) occupied by the reinforcing bar 24, and firmly fixed the connection state between the wall material (1) and the ceiling plate (2).

Next, the bottom main reinforcing bar (25) is penetrated between the reinforcement holes (8) of the ground part (5) of the opposite side wall material facing each other, and the mortar is injected into the remaining empty space occupied by the bottom main reinforcing bar (25), or connected thereto. The muscles 14 are connected to the floor cast iron 25 with each other, and the back muscle 26 is placed on the floor cast steel 25.

While pouring the concrete 27 on the floor to remove the crow's feet (20), the pinhole (6) from which the crow's feet (20) is removed is filled with mortar. In addition, the outside of the seams 1 and the seams of the wall 1 and all the seams of the ceiling plate 2 and the ceiling plate 2 is blocked by a water repellent material 28 such as epoxy resin as shown in FIG. Asphalt is applied to the outer surface of (1) and the ceiling plate (2) and waterproofed, and an arched passage is completed. Soil fills the surface of the arched passageway and builds it to the required height. At this time, it is suitable to pile up soil while maintaining the same height as possible on the outer surface of both wall materials 1 of the arched passage.

In Fig. 13, in the case of the wall material 1 and the ceiling plate 2, which are provided with the reinforcement 15, 16, the bolt hole 17 of the wall material 1 and the bolt ball 18 of the ceiling plate 2 are placed when placed. Insert the bolt 29 and tighten the nut on the opposite side to temporarily fix the wall material 1 and the ceiling plate 2, and then proceed in the above-described construction sequence.

The above description assumes that the ground on which the grounding part 5 is placed is based on the ground or the mat base on which general soil is chopped, and in the case of installing the precast wall material 1 and the ceiling plate 2 on the special ground, According to 14. That is, in the solid rock (d) to install the concrete (c) in the excavated ground as shown in the left figure to place the ground (5). In this case, since the rock and the ground portion 5 are integrated by the concrete (c), the reinforcement hole 8 or the connecting rod 14 for reinforcing the floor cast iron 25 is unnecessary.

In addition, when constructing an arched passageway in the soft ground (e), the hooking part (g) is installed on the pile foundation (f), the grounding part (5) is grounded, and the reinforcing bar (30) is placed in the reinforcement hole (8). Integrate by inserting and filling the concrete.

All of the above processes also apply to the multiple arched passage in FIG. 15 as it is.

As described above, the present invention can be constructed at a very economical cost by constructing an arched passageway using a wall material and a ceiling plate made by dividing the arch into several pieces, so that it can cope with the fill load with a smaller cross section than the conventional boxed passageway. The wall and ceiling panels can be manufactured and transported as a ready-made product in the factory, which ensures perfect quality control, significantly shortens the construction period, and finds the unique curved beauty of the arch type. Benefits such as being visible.

Claims (4)

The arched passage is divided into a precast wall material (1) and a ceiling plate (2) so as to be assembled.The partition end of the wall material (1) has a ceiling plate (2) mounted thereon, and a supporting step (3) to be seated on the ceiling plate. In (2), a stepped jaw (4) placed on the support step (3) is provided as a connection part, and on this connection part, connection root holes (7, 9) are formed, and the lower end of the wall material (1) is parallel in the width direction. An arched passage building material made of precast, characterized in that a ground portion (5) is formed. The precast arc-shaped passage building material according to claim 1, wherein the ground portion (5) of the wall material (1) is provided with a bottom main reinforcement bar (8) in the width direction thereof. The precast tooth passage building material according to claim 1, wherein the ground portion (5) of the wall material (1) is planted with a connecting rod (14) for connecting a bottom cast steel bar protruding therein. The free surface of claim 1, wherein an additional portion (15, 16) is added to the outer surface of the wall member (1) and the ceiling plate (2), and the bolt holes (17, 18) are drilled in these portions (15, 16). Precast archway construction.