KR100627103B1 - a structure transportation means and precast structure installation method using the same - Google Patents

Abstract

The present invention is to bring the precast structure, such as precast concrete retaining wall, culvert, etc. manufactured in the factory and then install the precast structure on the site, even if the installation site is narrow or accessible to the crane by other obstacles, etc. The present invention relates to a structure moving means capable of easily and quickly installing a precast structure when the precast structure cannot be installed by the same, and a method of installing the precast structure using the same.

Rail member, single end, precast structure

Description

Structure transport means and precast structure installation method using the same}

Figures 1a and 1b is a plan view of the induction furnace and the structure moving means of the present invention and the state when moving the retaining wall and in cross-sectional view.

Figure 2a shows a structure transfer means installed in the induction furnace of the present invention, Figure 2b shows a case where the structure coupling means is formed in the structure transfer means of the present invention,

2c and 2d illustrate a case in which the other structure moving means of the present invention is installed in the induction furnace.

3a and 3b schematically show the installation state of the induction furnace in the case where the induction road to which the fabricated precast structure is moved is formed in a curved or stepped manner.

Figures 4a and 4b is a cross-sectional view and a plan view of the structure coupling means is formed when the precast structure factory manufacturing of the present invention.

<Explanation of symbols for main parts of drawing>

100: cast concrete 200: induction road (rail member)

300: structure transfer means 310: bearing member

320: moving member 400: structure coupling means

500: jack-up device

The present invention relates to a structure moving means and a method of installing a precast structure using the same. More specifically, when the precast structures (retaining walls, culverts, etc.) manufactured at the factory are installed in the field and interfere with obstacles (bridges, pedestrian bridges, houses, etc.) The present invention relates to a structure moving means capable of easily installing a precast structure easily in a narrow and narrow space without being disturbed by factors, and a method of installing a precast structure using the same.

Conventionally, when a precast structure, such as a precast retaining wall or a culvert, is continuously installed at a predetermined position by a lifting device such as a crane, the weight of the precast structure is excessive. This was difficult and there was a problem that requires a lot of effort and time in the setting work.

An object of the present invention is to provide a means to facilitate the quality control air management construction management of the block joint by easily and easily installed in any work conditions when precast structure site installation.

Another object of the present invention is to provide a means that can easily move the precast structure along the induction furnace, and can easily construct the coupling or connection between the precast structures to be installed.

It is still another object of the present invention to provide a means for enabling a faster transport and installation of precast structures by allowing structural coupling means to be formed on the precast structures in advance to facilitate the setting of the precast structures.

The most preferred embodiment of the present invention will be described in detail with reference to Figs.

Precast structure installation method using the structure moving means of the present invention,

In the work site where the precast structure is to be installed, the guideway is installed along the position where the precast structure is to be installed, the structure moving means moving along the guideway is installed, and the precast structure is installed on the structure moving means. After the installation, move the precast structure at a predetermined position along the induction furnace, remove the induction furnace and the structure moving means installed by raising the precast structure, and then lower the raised precast structure again to induce the induction furnace. According to the present invention, the precast structure is continuously installed. The precast structure to be installed and moved is based on the retaining wall having a predetermined height and width in the factory. .

Retaining wall is a structure that supports the backing soil formed on the back, and various types of retaining wall are installed. As shown in FIG. 1A, the discarded concrete 100 is first placed and cured on the ground with a predetermined thickness, and then the upper part thereof. It is usually installed in.

The discarded concrete may be referred to as a concrete support plate that is formed in advance to secure the flatness on the ground while allowing the load of the retaining wall to be evenly transmitted to the ground while preventing uneven settlement of the retaining wall.

When the discarded concrete 100 is formed with a predetermined width, length, and height on the work site on which the retaining wall is to be installed, two guideways 200 are installed at predetermined intervals in the direction in which the discarded concrete 100 is formed. do. In some cases, two or more may be installed.

Specific examples of the induction furnace are shown in Figs. 2A to 2D.

2A and 2B illustrate a case of using a U-shaped cross-section or a channel member having a U-shaped cross-section as an induction path 200, in which a bearing for accommodating the bearing member 310 constituting the structure transfer means 300 is provided. If the member accommodating space 250 is formed, a shape steel or a channel member having an H-shaped cross section may be used as shown in FIG. 2C, or a rail member having a triangular protrusion as shown in FIG. 2D may be used. Induction path of the present invention will be referred to as a rail member that serves as the movement path of the structure moving means 300 including a bearing member, according to the selection of the bearing member 310 constituting the structure transfer means 300 to be described later A rail member having a protrusion or a channel having a U-shaped and H-shaped cross section is used.

In general, the induction furnace 200 may be installed in a straight line, but when the work plan line for installing the retaining wall is curved, it is necessary to install the overall shape to be curved. In this case, although the induction furnace itself may be designed in a curved shape, it is efficient to combine the linear induction furnaces with each other but to form a curved installation direction as the connecting member.

3a shows that the induction furnace is curved, but the straight rail member is installed in a predetermined length, but the direction is inflexible, and the wedge-shaped connecting member 210 having a curvature is inserted into the inflection portion so that the induction furnace is generally curved. The case where it is installed is shown. The wedge-shaped connecting member may be used to cut the rail member to match the curvature to bend.

3b illustrates a case in which the induction path is installed in a stepped manner in which a step is formed up and down. In the case where the working site according to the design condition is filled with a step, the taxiway should be installed with different height. In this case, the induction furnace may be provided with an induction furnace formed to be inclined upward or downward in a portion where the step is formed to maintain the continuity. Of course, instead of installing a sloped taxiway, the taxiway is first installed on the ground with the lowest step, the earth and sand are piled up to the next step, and the taxiway is installed at the next step. You can also install a taxiway in a way that fills the soil again. In some cases, the step may increase upward, but in some cases, the step may decrease downward. In this case, it is preferable to install a brake system or the like for securing safety when moving the structure.

In addition, the induction furnace is provided with a rail member continuously installed in a predetermined interval is divided into each other to enable a continuous installation with respect to the final length has the advantage of easy reuse and installation and transport later.

Figure 2a is a plan view showing the structure transfer means 300 of the present invention described later in the U-shaped rail member of the induction path 200 having a predetermined length other than the other configuration (such as discarded concrete),

The length of the divided induction furnace can be adjusted in length to facilitate transportation, installation, etc., usually about 2M is preferred. The taxiway should be formed over the entire length of the planned line where the retaining wall is to be installed, so if the taxiway is made at about 2M, a number of divided taxiways should be connected to each other in a straight or curved line. This connection is first attached to the nut member 220 on both sides of the induction furnace, and the connection member (splice, 230) formed with an elliptical hole for connecting the induction furnace by the nut member is formed on the nut member The hollow and the elliptical hole of the connection member are coincident with each other, and the induction furnace is easily mechanically coupled by tightening the connection member to the nut member with the bolt member 240. At this time, the hole of the connecting member is made into an oval and formed coaxially with the hole of the nut member to facilitate the installation of the induction furnace.

Thus, by tightening or loosening the bolt member there is an advantage that it is possible to easily install or dismantle the plurality of induction furnace connected.

In order to fix the induction furnace to the discarded concrete, an additional L-shaped additional plate may be installed using an anchor on the side of the induction furnace.

When the induction furnace 200 is installed on the discarded concrete 100, as shown in FIG. 1A, a leveling layer (mortar, sand: cement = 3: 1) is disposed at least on the bottom surface of the retaining wall. Allow to be formed at a height. The level adjustment layer serves to allow the retaining wall formed on the lower surface of the structure coupling means to be installed at a constant level while being integrated with the discarded concrete.

After the level adjustment layer is formed, the structure transfer means 300 of the present invention is installed, and the structure transfer means 300 may be formed in two ways.

FIG. 2A illustrates a case where the structure transfer means 300 and the guideway are installed in the U-shaped cross section, and FIG. 2B illustrates a case where the structure coupling means 400 is formed in the structure transfer means 300 of FIG. 2A. will be.

The structure transfer means 300 includes a bearing member 310 moving in contact with the induction path; And a receiving groove 321 into which the bearing member upper portion is inserted is formed at a lower portion thereof, and a structure is installed at the upper portion thereof so that the moving member 320 moves along the induction furnace together with the structure installed when the bearing member is moved along the induction furnace. It includes;

The bearing member 310 is located in the bearing accommodation space 250 inside the rail member, which is a U-shaped induction path 200 as shown in FIG. That is, the shape is formed so that the rail member can move along the inside can use a ball-shaped end and can be made of steel material, but is not limited thereto.

The moving member 320 serves to allow the bearing member 310, which is the ball-shaped end, to move along an induction path while being constrained with each other, and to allow the structure to be positioned on an upper surface. Position restraint function of the bearing member 310 is made by a bearing member receiving groove 321 formed on the lower surface of the moving member.

The accommodating groove is formed as a hemispherical groove into which the upper end of the end member as the bearing member can be inserted, so that the end member as the bearing member is inserted to be moved together with the moving member when the end member moves, and according to the forming interval and the number of the accommodating grooves. The position and the number of bearing members are determined.

Figure 2a illustrates a case in which the zigzag-shaped receiving grooves are formed in the moving member so that the three end members, the bearing members can be positioned at a constant interval from each other, the formation position and number of the receiving grooves can be variously changed.

In particular, it is preferable that the forming height of the bearing member, which is a single ball, is formed to be slightly higher than the height of the rail member, which is the guideway, so that the moving member, which is a structure transfer means inserted into the bearing member, does not interfere with the upper surface of the rail member, which is the guideway. .

The moving member 320 is provided with a receiving groove 321 is inserted into the upper portion of the bearing member 310 as shown in Figure 2b and the structure is mounted on the upper surface. As a result, the structure to be installed by the structure moving means 300 can move together with a minimum of friction along the induction path. In addition, the width of the lower portion of the moving member is preferably formed to be smaller than the width of the guideway and the upper portion may be formed in a slightly larger width so that the moving member is not separated when moving from the guideway.

Means for easily installing the structure on the upper surface of the moving member is a structure coupling means 400 of the present invention and Figure 2b is a front view and a plan view when the structure coupling means 400 is formed on the structure moving means 300 It is shown.

The structure coupling means 400 is a protrusion 410 formed on the upper surface of the moving member; And a protrusion accommodating member 420 having a receiving groove into which the protrusion member is inserted.

The protrusion 410 is tapered so that the diameter of the lower part is larger than the diameter of the upper part on the upper surface of the moving member 420, the protrusion receiving member 420 is a member formed with a receiving groove for receiving the tapered protrusion on the lower surface of the structure to be. In other words, it is to be coupled to each other by the female, male coupling method, the structure is installed stably on the moving member that is the structure moving means, and the tapering can be more easily installed.

4A illustrates a case in which the protrusion receiving member 420 is installed at four corners on a lower surface of the box-shaped structure, and FIG. 4B shows the protrusion receiving member 420 at four corners on the bottom plate of the L-shaped side opening. The case where this is formed is shown. The protruding portion receiving member is set to be located at the correct part in the factory in advance when manufacturing each structure, the number and location of installation can be changed by the spacing and the shape of the bottom surface of the structure and the like.

In addition, the moving member 420 is formed on the moving member and the bearing member and the structure moving means of the structure moving means when the wire connecting portion is formed in the ring shape as shown in FIGS. Allow the structure to move along the taxiway together.

Another example of a bearing member is shown in FIGS. 2C and 2D. In the case of Figure 2c, in particular, the bearing member is accommodated in the rail member of the induction path of the H-shaped cross-section is formed so that the bearing member penetrates the rotating shaft formed in the lower portion of the movable member without being inserted into the receiving groove of the movable member. A kind of rolling method is adopted, and the width of the moving member may be formed smaller or larger than the width of the taxiway. In the case of the rolling method of the wheel, the moving member is less likely to escape when moving on the taxiway. It is important to choose a method that is stable and stable when moving.

Figure 2d is a case in which the bearing member is installed in the moving member by a rotating shaft, but the bearing member is formed in a failure shape in which the diameter of the center portion is narrow and the diameter increases toward both ends, thereby reducing the diameter of the center portion as a whole. In this case, the rail member as the guideway is made of a rail member having a triangular protrusion, unlike FIGS. 2A to 2C, so that the failed bearing member can move in the direction in which the guideway is formed in contact with the rail member. That is, in the direction other than the direction in which the induction path is formed, the movement is constrained, and thus the movement efficiency is good in its own way. In the case of FIGS. The movement is constrained in a direction other than the direction in which it is formed.

Therefore, the bearing member and the moving member which are the structure moving means of the present invention can be manufactured in various examples as shown in Figure 2a to 2d according to the shape.

When the structure moving means 300 is installed on the rail member as an induction path, the structure moving means moves so that the structure moving means can be stably moved by using the structure coupling means formed on the lower portion of each structure and the upper portion of the moving member. Install on the member.

In this case, the precast concrete structure, as well as precast concrete structures such as retaining walls, which are pre-fabricated in factories, may be applied. The protruding portion receiving member 420 constituting the above-described structure coupling means 400 may be applied to the lower surface. To form. It does not matter even if the structure coupling means is not necessarily used.

The method of installing the structure on the structure moving means uses a lifting device such as a crane. In many cases, it is not easy to bring the crane to the site and locate the place where the retaining wall should be installed because of obstacles around it. Even if the crane work is not easy due to civil complaints, in the present invention, the structure is moved to the position to be installed through the induction furnace, lifting equipment such as a crane installed in one place at the beginning of the induction furnace structure The efficiency and installation of the installation work can be improved.

After installing the structure using the lifting device on the structure moving means installed in the taxiway, the structure is first moved from the installed structure along the taxiway to a predetermined position. This movement is connected to the wire coupling portion of the moving member described above, or connected to the demoulding and installation insert pre-filled in precast concrete, and the structure moving means is guided by pulling the wire using a winch installed at a predetermined position. It may be moved along the furnace, and if possible, may be moved by manpower, or may move the structure moving means using a power means. If the induction path is inclined upward or downward, it is preferable to install the structure moving means and related systems in a brake system to prevent sudden movement of the structure moving means, and to use the power means to increase the efficiency of the moving operation. Do.

When one or two or more structures first installed arrive at a predetermined position by the structure moving means, the structures must be installed at the final position. In the case of a divided and combined route, the jack-up device may be made to be buried at the site. (500, the structure lifting and lowering means including the hydraulic jack) on both sides of the structure as shown in Figure 1b to raise the structure arrived at the final position, the pre-installed structure moving means and guideway dismantled, and the jack-up device again As it descends, it is preferable that the protrusion receiving member installed on the lower surface of the structure is embedded in the level adjusting layer, so that it can be stably installed on the discarded concrete and the upper surface.

The jack up device may use a device including a hydraulic jack that can raise the structure.

When the structure is installed on the level adjustment layer, it is desirable to finish the process using fillers such as adjusting mortars.

First, the moved structure is installed while dismantling the divided taxiway, and then the moving structure is installed to be connected with the already installed structure. Since the installation position and level of the structure are already set, the precast structure has been previously There is an advantage that can solve the problem that it is not easy to assemble integrally.

Dismantled induction furnaces can be recycled, making it possible to install more economical structures.

According to the present invention, a heavy precast block (retaining wall, culvert) can be adapted to various planar and vertical lines of a design, and there is an obstacle in the installation, so that the precast block can be installed quickly and accurately even if the crane is not accessible. In addition, even if the crane is accessible, the work can be fixed and fixed at one place without moving the crane when installing the structure according to the present invention, as well as reducing the time loss of the transportation means brought to the site from the factory, in some cases unloading the structure As the work is additionally added, the construction cost may be added, but the present invention can quickly perform the unloading and installation work of the structure at the same time, greatly reducing the air shortening and installation costs. In addition, the crane can work continuously in one place, maximizing the utilization efficiency of lifting devices such as cranes, which greatly reduces air.

Claims (16)

A bearing member moving in contact with the induction furnace; And a moving member which is formed at a lower portion of the receiving groove into which the bearing member upper part is inserted, and a structure is installed at the upper part and moves along the induction path together with the structure installed when the bearing member is moved along the induction path. The induction furnace is a rail member having a bearing member receiving space therein, and the bearing member is a single end formed in a ball shape, and the movable member has a width at a lower portion where the receiving groove is formed smaller than the width of the induction furnace. The structure moving means, characterized in that formed in the hemispherical groove so that the upper portion of the end sphere is inserted into a plurality of zigzag on the bottom of the moving member to move the bearing member along the guideway. delete delete delete According to claim 1, Structure coupling means is further formed on the moving member, The structure coupling means Protrusions formed on the upper surface of the moving member; And A protrusion accommodating member having a receiving groove into which the protrusion member is inserted; It includes, wherein the shape of the protrusions structure moving means characterized in that the tapered so that the width of the lower than the width of the upper to facilitate the coupling. delete delete delete At the work site where the precast structure is to be installed, Install the taxiway along the location where the precast structure should be installed, Install the structure moving means of claim 1 moving along the induction path, After installing the precast structure to the structure moving means to move the precast structure to a predetermined position along the guideway, After removing the guideway and structure moving means installed by raising the precast structure, the precast structure is installed, and the precast structure can be continuously installed along the guideway by lowering the raised precast structure again. Way. delete delete delete delete delete delete delete

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