KR102609015B1 - Hollow-core slab and degradation slab smart modular construction method of building structures - Google Patents

Abstract

The present invention relates to a smart modular construction method for hollow-core slab and low-load slab building structures.
Specifically, it is a technology for expanding the modular construction method to special industrial plant (battery, etc.) buildings and general buildings in addition to semiconductor production facilities. It is a MEP module rack (heavy object) manufactured as a structural beam fixed type rather than the existing slab fixed type module rack. ) type, it is about a smart modular construction method for hollow-core slab and low-load slab building structures to shorten the construction period and ensure stability during field installation.

Description

Smart modular construction method of hollow-core slab and low-load slab building structures {Hollow-core slab and degradation slab smart modular construction method of building structures}

The present invention relates to a smart modular construction method for hollow-core slab and low-load slab building structures.

Specifically, it is a technology for expanding the modular construction method to special industrial plant (battery, etc.) buildings and general buildings in addition to semiconductor production facilities. It is a MEP module rack (heavy object) manufactured as a structural beam fixed type rather than the existing slab fixed type module rack. ) type, it is about a smart modular construction method for hollow-core slab and low-load slab building structures to shorten the construction period and ensure stability during field installation.

In the case of hollow core pc slab architectural structures, the rigidity of the slab was lower than that of the existing deck slab due to the empty interior of the hollow core pc slab, making it difficult to apply the modularization method to heavy materials.

In particular, when installing a MEP module rack, special methods or materials are used to secure the MEP module rack to the hollow core slab, such as a method of additional reinforcement by installing a through-type suspension bolt on the PC slab, or a special screw anchor or chemical anchor construction. do.

However, even if special methods or materials were used, it was difficult to install heavy module racks. In addition, due to the installation of separate fixing devices for each MEP module rack type, a large number of installation points occurred, which lowered economic feasibility. When installing the MEP module rack in a high-altitude section, the MEP module rack must be placed on a table lift for people to lift and then installed by a person, or a separate scaffold must be installed and then installed by manpower. In some cases, MEP module racks were installed either by installing winches or chain blocks as temporary structures, which reduced site safety due to the risk of falls, tipping over, and constriction, and the construction period took a long time.

Accordingly, the present applicant combined ASL (AGV (Auto Guide Vehicle) Smart Lift) equipment and the MEP modular rack construction method to pre-manufacture each MEP module rack in a Hollow Core Pc Slab building structure at an external factory, bring it to the site, and then bring in the ASL (AGV Smart Lift) equipment. Lift) is used to lift and install MEP module racks (heavy objects) up to the high-altitude installation section. Embed plates are pre-installed on the structural beams to enable configuration of MEP module racks between structural beams. Therefore, there is no need to install separate special anchors or scaffolding methods to fix the MEP module rack. By pre-manufacturing the MEP module rack at an external factory, the construction period is shortened and the construction quality of the MEP module rack is improved. ASL is used to separate heavy materials. We propose a technology that can shorten the construction period and improve site safety by eliminating the need to install facilities for lifting. In addition, we present a type of MEP module rack that can be installed in Hollow Core Pc Slab building structures according to site conditions.

As a related technology, Patent Registration No. 10-1466590 describes a pre-piped rack module and a clean room construction method using the same.

The above technology relates to a pre-plumbed rack module and a clean room construction method using the same. A rack is manufactured in a factory, then various piping and auxiliary facilities are installed in advance, and the manufactured pre-plumbed rack module is transported to the site and connected. By assembling, a basic piping line can be constructed simply and efficiently, and a hook-up line can also be efficiently constructed from this, making it easy to maintain the required quality and dramatically shortening the construction period. In addition, the facility frame and piping can be standardized and installed compactly, reducing the space occupied and significantly improving the efficiency of construction and maintenance work.

Additionally, Registered Patent Publication No. 10-1691489 describes a piping module and a method of installing the piping module.

The technology includes a piping module (A) for piping construction in a building, including a piping 100; A frame 200 on which the pipe 100 is mounted; A pipe fixing part 300 formed on the frame 200; And a lift connection part 500 for connection with the lift line 2 for lifting the piping module (A). A piping module is provided, characterized in that it is constructed by combining a plurality of piping modules (A). do.

According to this, it is possible to easily construct piping in the field using modularized individual piping modules pre-worked at the factory. Specifically, the piping module is constructed with a frame that supports multiple piping and piping such as air conditioning piping and water supply piping. This is a technology that manufactures in a factory, brings multiple factory-made piping modules to the site, and assembles them. This simplifies the complex piping assembly process, thereby shortening the process time.

Publication of Patent No. 10-2020-0051313 describes a modular construction method of a pipe rack structure.

The technology includes a plurality of pillars 10 formed at equal intervals, an upper coupling part 100 formed on the pillars 10, and a pipe rack module unit 200 coupled to the upper coupling part 100. In the modular construction method of a rack structure, the pillars 10 are formed at equal intervals along the horizontal direction (a) and the vertical direction (b), and the upper coupling portion 100 is formed along the horizontal direction (a). It includes a cross beam 110 connecting the neighboring pillars 10 formed and a vertical beam 120 connecting the neighboring pillars 10 formed along the longitudinal direction (b), wherein the pillar 10 and the A first step (S100) of forming the upper coupling portion 100; By inserting the pipe rack module unit 200 into the space (c) between the neighboring pillars 10 formed along the horizontal direction (a), the neighboring pillars 10 formed along the vertical direction (b) ) A second step (S200) of positioning the pipe rack module unit 200 in the space (d) between them; A third step (S300) of moving the pipe rack module unit 200 to the lower part of the upper coupling part 100 where the pipe rack module unit 200 is to be coupled; And a fourth step (S400) of lifting the pipe rack module unit 200 and coupling it to the stringer 120. A modular construction method of a pipe rack structure is described, including a.

Additionally, Publication Patent Publication No. 10-2020-0119057 describes a method of constructing a high-load module within a building.

The above technology relates to a method for constructing a high-load module such as a piping module within a building. The unit module transported to the external assembly site of the building is placed on the upper part of the base that can be placed at a certain height or more from the ground to form a first A first step of assembling a module assembly provided with a fixing part; A second step of installing the first fixing part of the module assembly and the second fixing part in which bolts are assembled to the structure within the building; A third step in which a lifting transport device enters the bottom of the base and transports the module assembly to an installation location in the building; A fourth step of lifting the module assembly by the lifting transport device at the installation position of the module assembly, adjusting the position in the horizontal and vertical directions, and fixing the first fixing part and the second fixing part by bolting each other. Includes.

Registered Patent Publication No. 10-1466590 (announced on November 28, 2014) Registered Patent Publication No. 10-1691489 (announced on December 30, 2016) Public Patent Publication No. 10-2020-0051313 (2020.05.13.) Public Patent Publication No. 10-2020-0119057 (2020.10.19.)

The purpose of the present invention is a technology for expanding the modular construction method to special industrial plant (battery, etc.) buildings and general buildings in addition to semiconductor production facilities. MEP modular rack manufactured as a structural beam fixed type rather than the existing slab fixed type module rack. The purpose is to provide a smart modular construction method for hollow-core slab and low-load slab building structures to shorten the construction period and ensure stability during field installation when installing (heavy material) types.

The smart modular construction method of hollow-core slab and low-load slab building structures according to the present invention, which was devised to achieve the above-mentioned purpose, includes the steps of installing a support rack between structural beams; Transporting the MEP module rack to the installation site using ASL; Stepping the MEP module rack onto the support rack through the lifting operation of the ASL lift; Characterized in that it includes the step of lowering the ASL lift.

At this time, the MEP module rack installed using the ASL equipment is composed of section steel and lightweight steel frame, and the vertical frame for connecting to the support rack is configured to protrude upward, and the pipe, duct, and cable tray are seated. It is characterized by

According to the smart modular construction method for hollow-core slab and low-load slab building structures according to the present invention, when applying MEP modular rack to hollow core PC slab building structures, it is used as a structural beam fixed type rather than the existing slab fixed type modular rack. When installing the manufactured MEP module rack (heavy object) type, it has the advantage of shortening the construction period and ensuring stability during field installation.

Figure 1 shows ASL (Auto Guide Vehicle (AGV) Smart Lift) equipment that performs the smart modular construction method of hollow-core slab and low-load slab building structures according to the present invention.
Figure 2 shows an example in which ASL (Auto Guide Vehicle (AGV) Smart Lift) equipment, which performs the smart modular construction method of hollow-core slab and low-load slab building structures according to the present invention, combines a MEP modular rack with a support rack. will be.
FIG. 2A shows an example taken in another direction of FIG. 2.
Figure 3 shows an example of an MEP modular rack made of section steel and lightweight steel being placed on ASL (Auto Guide Vehicle (AGV) Smart Lift) equipment that performs the smart modular construction method of hollow-core slab and low-load slab building structures according to the present invention. It is shown.
Figure 4 shows a state in which ASL (Auto Guide Vehicle (AGV) Smart Lift) equipment, which performs the smart modular construction method of hollow-core slab and low-load slab building structures according to the present invention, is seated on a MEP module rack made of section steel and lightweight steel frame. This shows an example of use.

Terms or words used in this specification and claims should not be construed as limited to their ordinary or dictionary meanings, and the inventor may appropriately define the concept of terms in order to explain his or her invention in the best way. It must be interpreted as meaning and concept consistent with the technical idea of the present invention based on principles.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and do not represent the entire technical idea of the present invention, and various equivalents can be substituted for them at the time of filing the present application. It should be understood that there may be variations.

Hereinafter, before explaining with reference to the drawings, matters that are not necessary to reveal the gist of the present invention, that is, known configurations that can be easily added by a person skilled in the art, are not shown or described in detail. Let's keep it clear.

The present invention relates to a smart modular construction method for hollow-core slab and low-load slab building structures.

Specifically, it is a technology for expanding the modular construction method to special industrial plant (battery, etc.) buildings and general buildings in addition to semiconductor production facilities. It is a MEP module rack (heavy object) manufactured as a structural beam fixed type rather than the existing slab fixed type module rack. ) type, it is about a smart modular construction method for hollow-core slab and low-load slab building structures to shorten the construction period and ensure stability during field installation.

Below, ASL (Auto Guide Vehicle (AGV) Smart Lift) equipment for performing the smart modular construction method of hollow-core slab and low-load slab building structures according to the present invention is shown in the attached drawing.

Figure 1 shows ASL (Auto Guide Vehicle (AGV) Smart Lift) equipment that performs the smart modular construction method of hollow-core slab and low-load slab building structures according to the present invention.

In addition, Figure 2 shows an example in which ASL (Auto Guide Vehicle (AGV) Smart Lift) equipment, which performs the smart modular construction method of hollow-core slab and low-load slab building structures according to the present invention, combines MEP modular rack, Figure 2a shows an example of combining MEP module racks using lightweight steel frames.

In addition, Figure 3 shows an example of an MEP module rack being mounted on ASL (Auto Guide Vehicle (AGV) Smart Lift) equipment that performs the smart modular construction method of hollow-core slab and low-load slab building structures according to the present invention. 4 shows an example in which ASL (Auto Guide Vehicle (AGV) Smart Lift) equipment, which performs the smart modular construction method of hollow-core slab and low-load slab building structures according to the present invention, is used with the MEP module rack seated.

The smart modular construction method according to the present invention involves transporting and installing a MEP module rack that includes an ASL on the lower side, a support rack on the upper side, and on which pipes, ducts, and cable trays are seated using section steel and lightweight steel frame. do.

For the lift, reference may be made to the high-load, high-displacement self-driving transportation lifting device and construction method using the device in Registered Patent Publication No. 10-2351056, to which the present applicant has the rights.

In addition, the support part can also refer to this prior art, but as shown in Figure 1 of the attached drawing, a frame having a predetermined shape is formed using a frame on the upper side of the lift, and a plurality of vertical frames are installed in a vertical direction from the frame. It can be configured to protrude.

For further details on these lifts, refer to [Table 1].

According to [Table 1], the spiral lift included in the lift for vertical transport in the up/down direction has a stainless steel band configured in a spiral shape and has a configuration that allows 360° rotation in all directions.

In addition, by utilizing ASL's equipment-to-equipment synchronization control function, one ASL can lift and install a unit module, or more than one ASL can simultaneously lift and install multiple unit modules by lifting them to the same height through synchronization control.

In addition, it can be configured to enable autonomous driving by referring to the high-load, high-displacement self-driving transportation lifting device and construction method using the device in Registration Patent Publication No. 10-2351056 filed by the present applicant.

In detail, the smart modular construction method of hollow-core slab and low-load slab building structures according to the present invention includes the steps of installing support racks between structural beams; Transporting the MEP module rack to the installation site using ASL; Installing the MEP module rack on the support rack through the lifting operation of the ASL lift; It includes: lowering the ASL lift.

In addition, before performing the step of installing a support rack using multiple vertical frames, it includes the process of measuring the construction site and constructing a production drawing, then manufacturing, assembling, and shipping the frame, vertical frame, and connecting beam. can do.

At this time, drawings used in manufacturing frames, vertical frames, and connecting beams can be used in both 2D and 3D, and interference in the structural aspect can be reviewed in advance at the actual construction site.

To elaborate, as shown in [Table 2], the construction site is measured using a 3D scanner, the production drawings are corrected and final decisions are made, and the upper support rack is manufactured as shown in [Table 3].

Afterwards, as shown in [Table 3], when assembly is completed by installing pipes, ducts, and cable trays on the MEP module rack made of section steel and lightweight steel, quality inspection is performed by pre-installing the support rack and MEP module rack. Let it be done.

The frame structure manufactured in this way is brought into the construction site using a tower crane (T/C) or hydro crane, etc. When brought into the site, it is moved and aligned using the ASL lift described above. .

That is, as described above, installing a support rack between structural beams; Transporting the MEP module rack to the installation site using ASL; Installing the MEP module rack on the support rack through the lifting operation of the ASL lift; Perform the step of lowering the ASL lift. In this case, installation is based on bolting.

This can be referred to [Table 4].

At this time, the ASL lift may be equipped with a number of hydraulic lifts on the upper surface as shown in [Table 5] in order to seat the MEP module rack, and these hydraulic lifts can be used when the ground is not flat or there are sections, steel frames, etc. If the height of the unit module is different, or if the height is somewhat insufficient compared to the height of the ASL lift due to problems with the ceiling, fine adjustment of the height can be made using an extension or hydraulic lift. You can.

Meanwhile, a roller may be configured on one side of the support plate of a frame on which a unit module is seated, such as an MEP module rack made of section steel or lightweight steel, and the roller may be configured to cross in a direction perpendicular to the direction in which the unit module is seated. there is.

These rollers may be configured to rotate about an axis, for example, by connecting an axis between vertical frames and configuring the roller to rotate about the axis. This can be referred to [Table 6].

By including this roller configuration, pipes, members, and MEP module racks can be pushed and seated as shown in [Table 7], and by being pushed and installed at the construction site, the worker's work efficiency can be increased. there is.

According to the smart modular construction method of hollow-core slab and low-load slab building structures according to the present invention described above, when applying MEP modular rack to hollow core pc slab and low-load slab building structures, the existing slab fixed type modular rack is used. When installing an MEP modular rack (heavy object) type manufactured as a structural beam fixed type, it has the advantage of shortening the construction period and ensuring stability during field installation.

The above description using the drawings describes only the main points of the present invention, and as various designs are possible within the technical scope, it is obvious that the present invention is not limited to the configuration of the drawings.

Claims (4)

Installing a support rack between structural beams;
Transporting the MEP module rack to the installation site using ASL;
Installing the MEP module rack on the support rack through the lifting operation of the ASL lift;
In the smart modular construction method of hollow-core slab and low load slab building structures, including the step of lowering the ASL lift,
The MEP module rack installed using the ASL equipment is,
A vertical frame for connection to the support rack is configured to protrude upward,
Piping, ducts, and cable trays made of section steel and lightweight steel are installed,
At least one extension structure is provided on the upper surface of the ASL lift on which the MEP module rack is seated, thereby enabling additional height adjustment in addition to the height adjustment by the ASL lift,
The ASL is,
A roller for pushing the MEP module rack or members (individual piping, individual duct) is configured on one side of the upper support plate,
A plurality of hydraulic lifts are configured on one side of the upper surface of the support plate,
As multiple hydraulic lifts can be individually adjusted, hollow-core slabs and Smart modular construction method for low-load slab building structures. delete delete delete