KR20200124422A - Module lifting system utilizing of a strand jack, and method for vertical transportation of a heavy module using of the same - Google Patents

Abstract

The present invention relates to a method to move a heavy module such as a pipe module installed on a basement floor from a ground floor to an installation position of the basement floor. The method comprises: a first step of loading a transport object (10) onto a transport device (20) to transport the transport object into a building to transport the transport object to an underground inlet port designated on the ground floor of the building; a second step of moving from the ground floor to the basement floor by a module lifting system temporarily installed on the underground inlet port while the transport object is loaded on the transport device (20); and a third step of allowing the transport device moved to the basement floor to directly transport to an installation position of the basement floor while the transport object is loaded thereon. The module lifting system comprises: four support frames (110) having a plurality of horizontal beams connecting the gap between columns in the building and supported on the horizontal beams around the underground inlet port provided on the ground floor of the building to be temporarily installed; a plurality of strand jacks (120) fixed on the support frames (110), respectively; a platform (130) connected to the strand jacks (120) via strands to ascend and descend along the underground inlet port by driving of the strand jacks (120); and a control board (140) to cooperatively control the strand jacks (120) to control an ascent and a descent of the platform (130).

Description

A module lifting system using a strand jack and a method for carrying in the basement floor of a high-load module using the same {Module lifting system utilizing of a strand jack, and method for vertical transportation of a heavy module using of the same}

The present invention relates to a method for carrying a high-load module such as a piping module from a ground floor to an installation location on a basement floor of a building, and a module lifting system for the same.

In general, in piping facilities such as plants and factories, when piping such as air conditioning piping and water supply piping is installed, a support to support the piping is installed and the piping is installed.At this time, some of the piping supports are installed and air conditioning piping. And the process of assembling pipes such as water supply pipes to the support is repeated to complete the piping facility. This piping facility procedure has a problem in that the process time is long and work efficiency is deteriorated because the piping is sequentially installed after the support is installed.

In addition, scaffolds installed for conventional pipe rack installation work have a high risk of an accident due to a fall during work, and there is a problem in that the cost of installing and dismantling the scaffolding increases and the construction period increases.

In order to improve this problem, Registration Patent Publication No. 10-1691489 and Registration Patent Publication No. 10-1826011 propose a method of installing an integrated piping module in which piping is constructed by assembling in the field using individual piping modules modularized in a factory. Are doing.

1A to 1E are field photos briefly showing a method of carrying a pipe module into the basement according to the prior art.

Referring to FIG. 1, the piping module 10 is loaded onto the first transport device 20 and moved (a) from the manufacturing site to the ground entrance, and then a crane 30 is installed at the ground entrance to transport the first. After getting off the piping module 10 from the device 20, the piping module 10 is brought in through the inlet (b) (c) (d). In the basement floor, the piping module 10 carried in by the crane 30 is loaded onto the second transportation device 40 (e), and the piping module 10 carried in the basement level is then carried by the second transportation device 40. It is transported and moved to the installation location for installation.

In this way, the transfer of the conventional piping module to the basement floor is carried out using a crane, and thus other processes such as installation of a girder of the above-ground structure that may interfere with the crane operation are inevitable to delay the delivery of the piping module. . In addition, since a transport device for transporting the piping module must be prepared on the ground floor and the basement floor, there is a problem that a lot of equipment and manpower must be mobilized to carry in the basement floor of the piping module, and the construction period is lengthened.

Registered Patent Publication No. 10-1691489 (announcement date: 2016.12.30.) Registered Patent Publication No. 10-1826011 (Notification date: 2018.02.06.)

An object of the present invention is to provide a module lifting system using a strand jack capable of efficiently carrying a high-load module installed in a basement floor in a building into the basement floor, and a method for carrying in the basement floor of a high-load module using the same.

In order to achieve this object, the method for carrying in the basement floor of the high-load module according to the present invention includes a first step of loading a packaged material on a transportation device and transferring it to the inside of a building to a designated underground transfer port on the ground floor of the building; A second step of moving a packaged material from the ground floor to the basement floor while being loaded onto the conveying device through the module lifting system installed at the underground entrance; The transport device moved to the basement floor includes a third step of directly transporting the packaged goods to the installation location of the basement floor while the cargo is loaded, and the module lifting system includes a plurality of horizontal beams connecting the pillars in the building to the ground floor of the building. Four support frames supported by the horizontal beams and installed around the provided underground entrance; A plurality of strand jacks fixed to each of the support frames; A platform that is connected to the strand jack and the strand so as to be elevated along the underground entrance by driving the strand jack; And a control panel configured to control the elevation of the platform by synchronizing and controlling the strand jacks.

In the method for carrying in the basement floor of the high-load module according to the present invention, after installing a module lifting system that moves up and down between the ground floor and the basement floor using a strand jack at the basement entrance, the transport device in which the high-load module is loaded is directly installed. By moving from the ground floor to the basement floor, the work of carrying in the basement floor of the basement installation structure can be quickly and conveniently performed.In particular, in contrast to the carrying-in method used by the conventional crane, the work space required for carrying-in construction is secured and interference with other constructions due thereto It has the effect of minimizing the load and reducing the cost and time of carrying in and out.

Figure 1 (a) to (e) are site photos briefly showing a method for bringing in a basement module according to the prior art,
2 is a plan configuration diagram of a module lifting system according to an embodiment of the present invention,
3 is a side view of the configuration of the main parts of the module lifting system according to an embodiment of the present invention
4 is a perspective view of a platform according to an embodiment of the present invention,
5 is a perspective configuration diagram of a module lifting system according to an embodiment of the present invention,
6 is a side view schematically showing a process of carrying in the basement floor of the piping module using the module lifting system according to an embodiment of the present invention
7 to 12 are views briefly showing the installation process of the module lifting system according to the present invention.

Specific structural or functional descriptions presented in the embodiments of the present invention are exemplified only for the purpose of describing the embodiments according to the concept of the present invention, and embodiments according to the concept of the present invention may be implemented in various forms. In addition, it should not be construed as being limited to the embodiments described in the present specification, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

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

2 is a plan configuration diagram of a module lifting system according to an embodiment of the present invention.

Referring to FIG. 2, the module lifting system of this embodiment includes four support frames 110 installed around an underground entrance provided on the ground floor of a building; A plurality of strand jacks 120 fixed to each of the support frames 110, a platform 130 supported by the strand jack 120 and elevating along the underground entrance, and the strand jacks 120 are synchronized to control the platform ( It includes a control panel 140 that controls the elevation of the 130).

Preferably, the underground entrance includes a horizontal beam 102 connecting the pillars 101 of the building, and in the present embodiment, the underground entrance has four pillars 101 constituting each corner and two adjacent pillars It shows that a pair of horizontal beams 102 connecting 101 horizontally are provided side by side in the entry direction of the conveying device. On the other hand, for such an underground entrance, the uncast slab section of one span above the ground may be utilized.

The support frame 110 is constructed to be symmetrically vertically around the underground entrance, and preferably, each support frame 110 is provided on the top of the horizontal beam 102.

The strand jack 120 is fixed to each support frame 110, and the strand of each strand jack 120 is connected to the platform 130, and the platform 130 is vertically arranged along the underground entrance by the strand jack 120. Elevation takes place. On the other hand, the four strand jacks 120 are synchronously controlled by the control panel 140 so that the lifting operation of the platform 130 can be stably performed. Preferably, a pressure sensor may be added to each strand jack to monitor the load, and a stroke sensor may be installed to check the movement of each strand jack.

3 is a side configuration diagram of a configuration of a main part of a module lifting system according to an embodiment of the present invention.

Referring to Figure 3, the support frame 110 of the present embodiment, a first vertical frame 111 that is supported by a horizontal beam 101 made of H-beam and vertically erected, and vertically erected on the ground floor 103 The second vertical frame 112 is fixed horizontally with respect to the first vertical frame 111 and the second vertical frame 112, and a horizontal frame 113 in which the strand jack 120 is seated and fixed at the top of one side , It includes a strand guide 114 fixed to a predetermined height of the horizontal frame 114.

The first vertical frame 111 and the second vertical frame 112 are installed vertically on the horizontal beam 101 and the ground-side floor 103, respectively, and after carrying the package to the basement, within the range of easy removal. It is installed on the horizontal beam 101 and the ground-side floor 103. For example, the first vertical frame 111 is simply mounted and fixed on the top of the horizontal beam 101, and the second vertical frame 112 can be fixed by the basement floor 103 and a plurality of through bolts. In this case, as the strand jack 120 is installed adjacent to the first vertical frame 111, the first vertical frame 111 can be fixed upright to the horizontal beam 101 by acting on a considerable load.

The strand guide 114 is supported by a bar 114a fixed to the upper end of the horizontal frame 113 and is provided at the upper end of the strand jack 120 to guide the strand 121.

4 is a perspective view of a platform according to an embodiment of the present invention.

As illustrated in Figure 4, the platform 130 is made of a square structure consisting of a steel structure of an H-beam and a plurality of top plates, a plurality of lifting lugs 131 for fixing the strand, and provided to be freely rotatable It may include a plurality of guide rollers (132).

The guide roller 132 is provided on the upper end of the platform 130 and freely rotates in contact with the pillar constituting the underground entrance during the elevation of the platform 130 to guide the vertical movement of the platform 130.

5 is a perspective configuration diagram of a module lifting system according to an embodiment of the present invention.

Referring to FIG. 5, a horizontal beam 102 connecting the pillar and the pillar is provided around the underground entrance (A), and the first vertical frame 111 is supported on the horizontal beam 102 And a second vertical frame 112 supported on the ground-side floor 103 is provided. A horizontal frame 113 is connected between the first vertical frame 111 and the second vertical frame 112 and a strand jack 120 is mounted and fixed at one end of the horizontal frame 113.

The horizontal frame 113 may be provided with a working scaffolding 113a on the top, and a hand rail 115 and a staircase 116 for the safety of the operator may be installed.

6 is a side view schematically showing a process of carrying in the basement floor of the piping module using the module lifting system according to an embodiment of the present invention.

Referring to FIG. 6, the modular lifting system configured as described above loads the package 10 on the transportation device 20 and transports it to the inside of the building to the underground entrance designated on the ground floor of the building, and the transportation device 20 includes the package ( 10) Moves to the platform 130 provided in the underground entrance in the loaded state.

Next, the platform 130 together with the transport device 20 on which the package 10 is loaded is moved to the basement floor by synchronized driving of each strand jack 120. After the platform 130 moves to the basement floor, the transport device 20 directly transports the package 10 to the installation location of the basement floor.

In such a method for carrying in the basement floor of the high-load module of the present invention, the transport 10 is directly transported from the ground floor to the basement floor in a state in which the transport 10 is loaded on one transport device 20 from the ground to the basement floor. Compared to the underground carrying method used, the present invention does not require a crane for moving the carrying-in underground material to the basement, and also secures a large working space generated by requiring separate carrying devices in the ground floor and the basement floor, and other construction and Interference can be minimized.

7 to 12 are views schematically showing the installation process of the module lifting system according to the present invention.

7 to 9 briefly show the installation process in the basement floor of the module lifting system, and a horizontal beam 102 is installed between two adjacent columns 101 in the unplaced slab section of one span of the ground floor. Afterwards, the steel structure 133 constituting the platform is installed on the basement level of the entrance, and the upper plate 134 is installed on the upper part of the steel structure 133 to install the platform 130.

Next, Figures 10 to 12 briefly show the installation process on the ground floor of the module lifting system, and are supported by the horizontal beam 102 installed between the two pillars 101 to install the four support frames 110, and assemble The strand jack 120 is fixed and installed on the upper end of each of the support frames 110 that have been completed. Thereafter, by connecting the strand 121 between each strand jack 120 and the platform 130, the installation of the module lifting system is completed.

On the other hand, after all the high-load modules required for the basement installation are completed, the module lifting system installed at the underground entrance is demolished and construction work is carried out later.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications and changes are possible within the scope of the technical spirit of the present invention. It will be obvious to those who have the knowledge of.

110: support frame 111: first vertical frame
112: second vertical frame 113: horizontal frame
114: strand guide 120: strand jack
121: strand 130: platform
140: control panel

Claims (4)

A first step of loading the transported material on a transport device, transporting it to the inside of the building, and transporting it to an underground entrance designated on the ground floor of the building;
A second step of moving a packaged material from the ground floor to the basement floor while being loaded onto the conveying device through the module lifting system installed at the underground entrance;
Including a third step in which the transport device moved to the basement floor directly transports the packaged material to the installation location of the basement floor from the loaded state,
The module lifting system,
Four support frames that are provided with a plurality of horizontal beams connecting the pillars in the building and are supported by the horizontal beams around an underground entrance provided on the ground floor of the building to be installed;
A plurality of strand jacks fixed to each of the support frames;
A platform that is connected to the strand jack and the strand so as to be elevated along the underground entrance by driving the strand jack;
And a control panel configured to control the lifting and lowering of the platform by synchronizing and controlling the strand jacks. The method of claim 1, wherein the support frame,
A first vertical frame supported by the horizontal beam and vertically installed;
A second vertical frame supported on the ground-side floor and vertically installed;
A method for carrying in a basement floor of a high-load module comprising a horizontal frame fixed horizontally with respect to the first vertical frame and the second vertical frame, and wherein the strand jack is mounted and fixed to an upper end of one side. The method of claim 1, wherein the underground entrance is an unplaced slab section on the ground of a building. Four support frames that are provided with a plurality of horizontal beams connecting the pillars in the building and are supported by the horizontal beams around an underground entrance provided on the ground floor of the building to be installed;
A plurality of strand jacks fixed to each of the support frames;
A platform that is connected to the strand jack and the strand so as to be elevated along the underground entrance by driving the strand jack;
A module lifting system comprising a control panel configured to control the elevation of the platform by synchronizing and controlling the strand jacks.

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