KR102347820B1 - Port mega foundation structure construction method based on temporary installation structure for automation construction of mega grade port logistics - Google Patents

Abstract

The present invention relates to a port foundation structure construction method for automation of mega port logistics, which can safely, efficiently, and economically build a large-scale foundation structure in a smart container terminal, for port logistics including relatively large-scale logistics, thereby efficiently implementing the loading and transport of container logistics in a smart automation environment. The port foundation structure construction method for building a port foundation structure for the loading and transport of port container logistics comprises: a column structure installation step; a superstructure assembly step; a temporary tower structure installation step; a superstructure lifting preparation step; a superstructure lifting step; a superstructure horizontal movement step; a superstructure fixing installation step; and a temporary tower structure dismantling step, and further comprises a truss structure-girder structure fixing step.

Description

{PORT MEGA FOUNDATION STRUCTURE CONSTRUCTION METHOD BASED ON TEMPORARY INSTALLATION STRUCTURE FOR AUTOMATION CONSTRUCTION OF MEGA GRADE PORT LOGISTICS}

The present invention relates to a method for constructing a mega-class port infrastructure installed in a smart container terminal, and more particularly, to efficiently implement the loading and transport of container logistics in a port logistics handling relatively large-scale logistics in a smart automation environment. It relates to a method of constructing a port foundation structure for mega-level port logistics automation, which can safely, efficiently and economically build a large-scale foundation structure.

The logistics industry is developing and the amount of trade between countries is increasing. Countries around the world are expanding or constructing new container port terminals to handle the increasing volume of trade. It is located at the interface between sea and land, and is used as a place for container unloading, storage, receiving by land transport agencies, container equipment, repair and cleaning. The main structure of the container terminal is as follows <Table 1>.

In general, a container terminal is a connection point between sea transport and land transport in the maritime container transport system, and is integrated with container ships, unloading equipment, transport vehicles, container yards, and rear warehouses to facilitate cargo distribution. say

In order to understand the technical background of the present invention, a general structure of a container terminal for a port wharf will be described with reference to FIG. 1 . 1 is a structural diagram of a general container terminal for a port wharf.

Referring to Figure 1, a typical container terminal is a container ship unloading crane (1), yard unloading crane (2), yard transfer equipment (truck or trailer) (3), yard yard for loading cargo in the terminal (4) (5) )(6)(7), control center (8), gate entry/exit (9)(10) for loading/unloading container cargo, and other facilities in the port such as maintenance center (11). At this time, a crane is a device that can lift a container, which is a large cargo carrier of a certain standard, using power and move it using a certain section.

A container crane for transporting containers in a port is a loading and unloading facility for loading and unloading containers between a ship and a dock.

Conventional unloading facilities used in ports include, for example, crawler cranes or facilities including temporary towers and strand jacks. There is a problem in that economic feasibility is lowered in preparation for logistics efficiency. In particular, in the case of a facility including a temporary tower and a strand jack, there is a problem in that horizontal movement is limited at high altitude.,

In addition, as the amount of container handling in the port increases rapidly, rapid logistics work is required, and accordingly, research and development of structures capable of fast and stable port logistics work in a large-scale and smart environment are required.

Republic of Korea Registration Number Publication 10-0289765 (2001.11.30. Announcement) Republic of Korea Patent Publication No. 10-1709743 (2017.02.23. Announcement) Republic of Korea Patent Publication No. 10-1883219 (2018.07.31. Announcement) Republic of Korea Patent Publication No. 10-1474554 (2014.12.22. Announcement) Republic of Korea Patent Publication No. 10-2015-0016312 (published on February 11, 2015)

Therefore, the present invention for solving the above problems of the prior art, a large-scale base structure safely and efficiently to efficiently implement the loading and transport of container logistics in a port logistics handling a relatively large-scale logistics in a smart automation environment The purpose of this is to provide a method of constructing the basic structure of a port based on a temporary structure for the economical construction of mega-class port logistics automation.

The problems to be solved of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

According to one aspect of the present invention for achieving the above objects and other features of the present invention, as a method for constructing a mega-class port infrastructure for transport and loading of port container logistics, the transport and loading of port container logistics A method for constructing a harbor foundation structure for a port, comprising: a column structure installation step of installing each of a pair of column structures having intervals in the width direction with intervals in the longitudinal direction orthogonal to the width direction; After the column structure installation step, an upper structure assembly step of assembling an upper structure fixedly installed on the upper end of the pair of column structures on the ground; A temporary tower structure installation step of installing a temporary tower structure configured to be movable forward and backward with respect to the column structure on one side of each of the column structures; The upper structure lifting preparation step of preparing the lifting of the upper structure by connecting the upper structure and the lifting device installed at the upper end of the temporary tower structure; After completion of the preparation step for lifting the upper structure, the upper structure lifting step of lifting the upper structure to a position higher than the upper end of the column structure using the lifting device; Horizontal movement of the upper structure by horizontally moving the lifted upper structure to a position higher than the upper end of the column structure to position the upper structure at the upper position of the column structure; After completion of the horizontal movement of the upper structure, the upper structure fixed installation step of fixing the upper structure to the upper end of the column structure; and a temporary tower structure dismantling step of dismantling and removing the temporary tower structure after completion of the superstructure fixing installation step; is provided.

In the present invention, the column structure installation step is made by fixing the lower end of the column structure to a concrete block having a steel pipe pile buried and fixed in the ground, and the upper structure assembling step includes the longitudinal size of the entire column structure A girder structure having a larger size is formed by fixing a truss structure to the upper surface of the girder structure in a state where a pair of column structures are located in the facing inner space, and the girder structure of the upper structure is parallel It consists of a plurality of main frames and a plurality of support frames connecting the main frames, and the truss structure of the upper structure includes a parallel lower frame and an upper frame, and the upper frame has a shorter length than the lower frame. A pair of parallel frames, a plurality of support frames connecting and supporting the lower frame and the upper frame, a vertical frame extending from both ends of the lower frame toward an upper surface, and one end fixed to the vertical frame and the other end being fixed to the vertical frame It may include an inclined frame fixed to the end of the upper frame.

In the present invention, the temporary tower structure installation step, a pair of tower structures having a predetermined interval so that the column structure can be positioned between the intervals is installed movably back and forth with respect to the column structure, the temporary tower structure installation step The temporary tower structure installed in the column structure includes a skid frame installed on the ground on both sides of each column structure, a pair of tower structures having a lower end slidably provided on each of the skid frames, and an upper end of the pair of tower structures. A working platform that is connected and fixed, a cross beam provided in the longitudinal direction of the working platform, a lifting device movably provided along the cross beam, and a cross beam provided to slide the lifting device back and forth It may include a push-pull drive device.

In the present invention, the preparation step for lifting the superstructure includes moving the tower structure from one end to the other end of the skid frame, and the lifting of the superstructure includes both ends of the truss structure of the temporary tower structure In a state located on the side of the column structure, it consists of lifting the upper structure to a position higher than the upper end of the column structure while synchronizing the lifting devices of each of the temporary tower structures, and the horizontal movement of the upper structure is the push-pull By sliding the lifting device by driving the driving device, both ends of the truss structure of the upper structure may be positioned at the upper end of the column structure.

In the present invention, the lifting of the upper structure comprises receiving a detection signal from an object detection sensor provided with an interval in the longitudinal direction in at least one of the column structure and the tower structure to lift while controlling the lifting height of the girder structure. can

In the present invention, the fixing installation step of the upper structure consists of fixing the girder structure of the upper structure to the column structure by bolting and welding, one end of a pair of fixed wire ropes on both ends of the truss structure The connection is fixed, and the other end of the pair of fixed wire ropes may further include being fixed to the ground.

In the present invention, the superstructure assembling step further includes; the truss structure and the girder structure of the upper structure are fixed to the truss-girder structure by the truss-girder fixing means, and the truss-girder fixing means further includes; One end of the truss structure is fixed to the first position and the second position having a gap on one surface of the upper frame, respectively, and the other end is fixed to the main frame at a third position and a fourth position separated by a predetermined distance from the upper frame, respectively. A pair of first and second inclined fixtures, and a third inclined fixture having one end fixed to a fifth position on one surface of the upper frame and the other end fixed to a sixth position further away from the upper frame than the third position; and a fourth inclination fixture having one end fixed to a seventh position on one surface of the upper frame, and the other end fixed to an eighth position further away from the upper frame than the fourth position.

In the present invention, the first inclined fixture to the fourth inclined fixture may be located within the width range of the main frame of the girder structure when viewed in a plan view.

In the present invention, the first inclined fixture to the fourth inclined fixture is configured on both sides of the truss structure symmetrically with respect to the truss structure when the truss structure is viewed in a plane, the first inclined fixture and the third The inclined fixture, the second inclined fixture, and the fourth inclined fixture may be configured to be symmetrical with respect to a central line in the longitudinal direction of the main frame.

In the present invention, the third position of the first inclination fastener and the sixth position of the second inclination fastener are located on the same line along the longitudinal direction of the main frame, and the fourth position of the second inclination fastener and the An eighth position of the third inclination fixture may be located on the same line in the longitudinal direction of the main frame.

In the present invention, the first and third positions of the first inclination fastener and the sixth position of the second inclination fastener are located on the same line along the longitudinal direction of the main frame, and the second position of the second inclination fastener The second position, the fourth position, and the eighth position of the third inclination fixture may be located on the same line in the longitudinal direction of the main frame.

In the present invention, the fixing installation step of the superstructure consists of fixing both ends of the truss structure of the upper structure to the upper end of the column structure by bolting and welding, and a pair of fixing wires on both ends of the truss structure One end of the rope is connected and fixed, and the other end of the pair of fixed wire ropes may further include being fixed to the ground.

According to the method of constructing a temporary structure based on a temporary structure for the mega-class port logistics automation construction according to the present invention, the following effects are provided.

First, the present invention is a smart automation environment for loading and transporting container logistics in a port dealing with relatively large-scale logistics by constructing a soccer field-sized structure safely and effectively at a height of about 10 floors and connecting it with a container crane. It has the effect of allowing it to be implemented efficiently in

Second, the present invention can extend the horizontal transport distance compared to the horizontal transport distance of existing port logistics, such as a crawler crane or a facility including a temporary tower and a strand jack, so that more efficient and effective logistics operations can be performed. there is

Third, the present invention is large-scale compared to existing port logistics facilities such as a crawler crane or a facility including a temporary tower and a strand jack, and can shorten the construction time and reduce the construction cost, thereby securing economic feasibility. It works.

Effects of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a structural diagram of a container terminal for a general port wharf.
2 is a flowchart illustrating steps of a method for constructing a temporary structure-based port foundation for mega-level port logistics automation construction according to the present invention.
3 is a view schematically showing a column structure installation step included in the method for constructing a harbor foundation structure based on a temporary structure according to the present invention.
4 is a view showing the upper structure assembling step included in the temporary structure-based harbor foundation construction method according to the present invention, and is a schematic side view showing the assembly step of the upper truss structure constituting the upper structure.
5 is a view showing an upper structure assembling step included in the method for constructing a harbor foundation structure based on a temporary structure according to the present invention, and is a side view schematically illustrating a state in which the upper structure is assembled.
6 is a view showing the upper structure assembling step included in the temporary structure-based harbor foundation construction method according to the present invention, and is a schematic plan view showing the assembled state of the upper structure.
7 is a diagram illustrating a state in which a temporary tower structure included in the method for constructing a harbor foundation structure based on a temporary structure according to the present invention is completed.
8 is a perspective view schematically illustrating the preparation step for lifting the superstructure included in the method for constructing a temporary structure-based harbor foundation according to the present invention.
9 is a side view schematically illustrating the preparation step for lifting the superstructure included in the method for constructing a temporary structure-based harbor foundation according to the present invention.
10 is a schematic perspective view illustrating the configuration of a temporary tower structure used in a method for constructing a harbor foundation structure based on a temporary structure according to the present invention.
11 is a front view showing an upper end of a temporary tower structure to explain the configuration of a temporary tower structure used in the method for constructing a harbor foundation structure based on a temporary structure according to the present invention.
12 is a plan view showing an upper end of a temporary tower structure to explain the configuration of a temporary tower structure used in a method for constructing a harbor foundation structure based on a temporary structure according to the present invention.
13 is a perspective view schematically illustrating the lifting step of the superstructure included in the method for constructing a temporary structure-based harbor foundation according to the present invention.
14 is a side view schematically showing the lifting step of the superstructure included in the method for constructing a temporary structure-based harbor foundation according to the present invention.
15 is a front view schematically showing the lifting step of the superstructure included in the method for constructing a temporary structure-based harbor foundation according to the present invention.
16 is an enlarged perspective view showing a part of a schematic diagram of a lifting step of an upper structure included in a method for constructing a harbor foundation structure based on a temporary structure according to the present invention.
17 is a side view schematically illustrating a state in which the upper structure has been lifted in the upper structure lifting step included in the temporary structure-based harbor foundation construction method according to the present invention.
18 is a view showing the horizontal movement step of the superstructure included in the method for constructing a harbor foundation structure based on a temporary structure according to the present invention, schematically showing a state in which the upper structure is moved to the upper side of the column structure.
19 is a view showing the horizontal movement step of the superstructure included in the method for constructing a temporary structure-based harbor foundation structure according to the present invention, and is an enlarged perspective view showing some components in the parallel movement step of the upper structure.
20 is a diagram schematically illustrating an upper structure fixing installation step included in the temporary structure-based harbor foundation construction method according to the present invention.
21 is a view showing a state in which the temporary tower structure is dismantled in the temporary tower structure dismantling step included in the temporary structure-based port foundation construction method according to the present invention and the port foundation structure is constructed.
22 is a front view showing the harbor foundation in a state in which the truss structure-column structure fixing step further included in the method of constructing the harbor foundation structure based on the temporary structure according to the present invention is completed.
23 is a plan view showing the harbor foundation in a state in which the truss structure-column structure fixing step further included in the method of constructing the harbor foundation structure based on the temporary structure according to the present invention is completed.
24 is a side view showing the harbor foundation in a state in which the truss structure-column structure fixing step further included in the method of constructing the harbor foundation structure based on the temporary structure according to the present invention is completed.

Additional objects, features and advantages of the present invention may be more clearly understood from the following detailed description and accompanying drawings.

Prior to the detailed description of the present invention, the present invention can make various changes and can have various embodiments, and the examples described below and shown in the drawings are not intended to limit the present invention to specific embodiments. No, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

When an element is referred to as being “connected” or “connected” to another element, it is understood that it may be directly connected or connected to the other element, but other elements may exist in between. it should be On the other hand, when it is said that a certain element is "directly connected" or "directly connected" to another element, it should be understood that the other element does not exist in the middle.

The terms used herein are used only to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present specification, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

In addition, terms such as "...unit", "...unit", "...module", etc. described in the specification mean a unit that processes at least one function or operation, which includes hardware or software or hardware and It can be implemented by a combination of software.

In addition, in the description with reference to the accompanying drawings, the same components are given the same reference numerals regardless of the reference numerals, and the overlapping description thereof will be omitted. In describing the present invention, if it is determined that a detailed description of a related known technology may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

Hereinafter, a method for constructing a temporary structure-based port foundation for mega-level port logistics automation according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a flowchart showing the steps of a temporary structure-based port foundation structure construction method for mega-level port logistics automation construction according to the present invention, and FIG. 3 is a temporary structure-based port foundation structure construction method according to the present invention included in the method It is a view schematically showing the column structure installation step, and FIGS. 4 to 6 are views showing the upper structure assembling step included in the temporary structure-based port foundation construction method according to the present invention, and FIG. 4 is the upper structure constituting the upper structure It is a side view showing the assembly process of the upper truss structure, FIG. 5 is a side view showing the assembled state of the upper structure, and FIG. 6 is a plan view showing the assembled state of the upper structure. 7 is a view showing a state in which a temporary tower structure included in the method for constructing a temporary structure based on a temporary structure according to the present invention is completed, and FIGS. 8 and 9 are a method for constructing a temporary structure based on a harbor foundation according to the present invention. Fig. 8 is a perspective view, and Fig. 9 is a side view showing the preparation step for lifting the upper structure included in the . 10 to 12 are views for explaining the configuration of a temporary tower structure used in a method for constructing a harbor foundation structure based on a temporary structure according to the present invention, FIG. 10 is a perspective view, and FIG. 11 is a view showing the upper end of the temporary tower structure It is a front view, and FIG. 12 is a plan view showing the upper end of the temporary tower structure. 13 to 16 are views showing the lifting step of the superstructure included in the method for constructing a harbor foundation structure based on a temporary structure according to the present invention, and FIG. 13 is a perspective view, FIG. 14 is a side view, and FIG. 15 is a front view, and FIG. 16 is an enlarged perspective view showing a part enlarged. 17 is a side view showing a state in which the upper structure has been lifted. 18 and 19 are views showing the horizontal movement step of the superstructure included in the method for constructing a harbor foundation structure based on a temporary structure according to the present invention, and FIG. 18 is a view showing a state in which the upper structure has been moved to the upper side of the column structure. , Figure 19 is an enlarged perspective view showing some components of the upper structure parallel movement step in an enlarged manner. 20 is a view showing the fixed installation step of the superstructure included in the method for constructing a harbor foundation structure based on a temporary structure according to the present invention, and FIG. 21 is a temporary tower included in the method for constructing a harbor foundation structure based on a temporary structure according to the present invention. It is a drawing showing the state in which the temporary tower structure is dismantled and the port foundation structure is built in the structure dismantling stage. 22 to 24 are views showing the harbor foundation in a state in which the truss structure-column structure fixing step is completed, which is further included in the method of constructing the harbor foundation based on the temporary structure according to the present invention, and FIG. 22 is a front view, and FIG. 23 is a plan view, and FIG. 24 is a side view. In the drawing, the OS is an overhead shuttle system.

The meaning of the width direction and the longitudinal direction in the content described below is the longitudinal direction in the direction having a relatively long distance in the completed harbor foundation structure, and the direction having a relatively short distance (direction orthogonal to the longitudinal direction) in the width direction. to be defined as In addition, in the description below, the meaning of "mega" or "mega-class" is the size of a normal soccer field, that is, the length (longitudinal direction) of 90 ~ 120m, the width (width direction) of 45 ~ 90m, and the height (vertical direction) of 30 ~ 35m is defined as meaning

The method of constructing a temporary structure based on a temporary structure for automating mega-level port logistics according to the present invention is a soccer field scale, that is, a length of 90 to 120 m, a width of 45 to 90 m, and a height as a basic structure for transport and loading of port container logistics. As a method for constructing a mega-class port foundation structure of 30 ~ 35m scale, as shown in Figs. 2 to 24, a large column structure installation step (S100); superstructure assembly step (S200); Temporary tower structure installation step (S300); Superstructure lifting preparation step (S400); Superstructure lifting step (S500); Horizontal moving step of the superstructure (S600); superstructure fixed installation step (S700); and a temporary tower structure dismantling step (S800); and including, a truss structure-girder structure fixing step (S210); may further include.

Specifically, the port foundation structure construction method according to the present invention is a mega-class port foundation on the scale of a soccer field, that is, a length of 90 to 120 m, a width of 45 to 90 m, and a height of 30 to 35 m as a basic structure for transport and loading of port logistics. As a method for constructing a structure, as shown in FIGS. 2 to 24 , a column structure installation step (S100) of installing a pair of column structures 110 and 120 having a gap in the width direction with a distance in the longitudinal direction, respectively. ); The upper structure assembly step of assembling the upper structure (U) fixedly installed on the upper end of each of the pair of column structures (110, 120) installed in the column structure installation step (S100) on the ground to complete the upper structure (U) ( S200); A temporary tower structure for installing a temporary tower structure (T) configured to be movable forward and backward to lift the upper structure (U) to the upper side of the column structures (110, 120) on one side of each of the column structures (110, 120) installation step (S300); The upper structure lifting preparation step (S400) of moving the temporary tower structure (T) installed in the temporary tower structure installation step (S300) to a predetermined position, and preparing the lifting of the upper structure (U) by connecting the upper structure (U) (S400) ); After the upper structure lifting preparation step (S400) is completed, the upper structure (U) is lifted to a position higher than the upper end of the column structure by using the strand jack 400 as a lifting device provided at the upper end of the temporary tower structure (T). The superstructure lifting step (S500); Horizontal movement of the upper structure (S600) by horizontally moving the upper structure (U) lifted to a position higher than the upper end of the column structure in the lifting step (S500) of the upper structure and positioning the upper structure at the upper position of the column structure (S600); After completion of the horizontal moving step (S600) of the upper structure, the upper structure fixed installation step (S700) of fixing and installing the upper structure (U) on the upper end of the column structure; and a temporary tower structure dismantling step (S800) of dismantling and removing the temporary tower structure (U) after the upper structure fixing installation step (S700) is completed.

In addition, in the present invention, the upper structure assembling step (S200) is a truss constituting the upper structure (U) - using the girder fixing means 500, the upper truss structure 200 and the girder structure 300 are fixed between the It may further include a truss structure-girder structure fixing step (S210). That is, the upper structure U assembled in the upper structure assembling step S200 consists of an upper structure including the truss structure 200 and the girder structure 300 fixed by the truss-girder fixing means 500 . Here, the truss structure-girder structure fixing step (S210) may be performed after the superstructure fixing installation step (S700) is completed, and in consideration of safety and work efficiency, it is performed in the superstructure assembly step (S200) desirable.

Hereinafter, each of the above steps will be described in more detail.

The column structure installation step (S100) consists of fixedly installing a pair of column structures 110 and 120 each having an interval in the width direction at intervals in the longitudinal direction.

In the present invention, in the column structure installation step (S100), the column structures 110 and 120 are fixedly installed at intervals of 28 to 30 m in the width direction and 30 to 32 m in the longitudinal direction.

In addition, in the column structure installation step (S100), the column structures 110 and 120 have a circular or polygonal body portion 101 in cross section, and the truss structure 200 constituting the upper structure U is stably seated at the upper end. It is formed with a head portion 102 of a size larger than the body 101 for this purpose.

In the column structure installation step (S100), the lower ends of the column structures 110 and 120 are fixed to a concrete block 103 (see FIGS. 4 and 5), and the concrete block 103 is a steel pipe pile 104 ) (steel pipe pile) and firmly fixed to the ground.

Next, the upper structure assembly step (S200) is fixedly installed on the upper end of each of the pair of column structures 110 and 120 installed in the column structure installation step (S100), and the upper truss structure 200 and the girder structure ( 300) by assembling the upper structure (U) on the ground to complete the upper structure (U).

The upper structure assembly step (S200) is a pair of column structures (110, 120) inner space (ie, each pair) of the girder structure 300 having a size larger than the installation lengthwise size of the entire column structure (110, 120). of the column structure (110, 120) of the truss structure (200) in which the lower side is fixed to the upper surface of the head portion 102 of the pair of column structures (110, 120) in a state located in the space) is configured to be assembled on the upper surface of the girder structure 300 .

The girder structure 300 constituting the upper structure U includes three parallel main frames 310 and a plurality of support frames 320 connecting the main frames 310 to each other.

In the present invention, the girder structure 300 has a length (longitudinal direction) of 90 to 97 m, a width (width direction) of 27 to 31 m, and a height (vertical direction) of 2 to 3 m.

In addition, the girder structure 300 may be positioned at a predetermined height from the ground by being seated on a pedestal S of a predetermined height installed on a virtual line connecting the pair of column structures 110 and 120 .

In addition, the upper truss structure 200 constituting the upper structure (U) is formed to have a solid structure.

Specifically, the upper truss structure 200 is composed of a lower frame 210 and an upper frame 220 that are parallel to each other, and the upper frame 220 is parallel frames 210 and 220 having a shorter length than the lower frame 210 . ) and a plurality of support frames 230 connecting and supporting the lower frame 210 and the upper frame 220 between the lower frame 210 and the upper frame 220 , and both ends of the lower frame 210 . a vertical frame 240 extending toward the upper surface, one end of which is fixed to the vertical frame 240 and the other end of which is fixed to the end of the upper frame 220 , the inclined frame 250 , and the inclined frame 250 . ) or is provided at both ends of the upper frame 220 and is configured to include a lifting lug 260 to which the strands of the strand jack 400 are connected and fixed.

The lower frame 210 is formed to have a length greater than the distance between the pair of column structures (110, 120).

The upper truss structure 200 is integrated with the girder structure 300 by welding and/or bolting.

Here, in the upper truss structure 200 is integrally assembled to the girder structure 300, the length of the lower frame 210 is formed to have a length greater than the distance between the pair of column structures 110 and 120. , 6 and 7, both ends of the upper truss structure 200 are assembled in a state positioned on one side of the column structures 110 and 120 to form the upper structure (U).

In the present invention, the upper truss structure 200 used in the upper structure assembly step (S200) has a length of 28 to 32m, a width of 1.5 to 2m, and a height of 7 to 7.5m is used.

Next, in the temporary tower structure installation step (S300), the temporary tower structure (T) configured to be movable forward and backward to lift the upper structure (U) to the upper side of the column structures (110, 120) is the column structure ( 110, 120) consists of being installed on one side of each.

In the temporary tower structure installation step (S300), a pair of tower structures 11 having a gap on the inside are installed to be movable back and forth with respect to the column structures 110 and 120, that is, in the width direction, and are installed at the upper end in the longitudinal direction. A structure equipped with a strand jack 400 that is movably provided as a movably consists of being installed.

Specifically, the temporary tower structure (T) installed in the temporary tower structure installation step (S300) is a skid frame (or skid beam) installed on the ground on both sides of each of the column structures (110, 120) )) (10) and a pair of tower structures 11 each having a lower end slidably provided on the skid frame 10, and a working platform connected and fixed between the upper ends of the pair of tower structures 11 A working platform 12 , a cross beam 13 provided in the longitudinal direction of the working platform 12 , and a strand jack movably provided along the cross beam 13 . ) 400 , and a push-pull driving apparatus 14 provided on the cross beam 13 and configured to slide the strand jack 400 back and forth. have.

Here, the temporary tower structure (T) may further include a sliding drive device (not shown) that is provided on one side of each of the skid frame 10 and configured to linearly drive the tower structure 11 .

Next, the upper structure lifting preparation step (S400) moves the temporary tower structure (T) installed in the temporary tower structure installation step (S300) to a predetermined position, and the upper structure (U) of the strand jack 400 It consists in preparing the lifting of the upper structure (U) by connecting to the strand.

Specifically, the upper structure lifting preparation step (S400) moves the temporary tower structure 11 from one end of the skid frame 10 to the other end, and the upper truss structure 200 constituting the upper structure U is lifted. It consists in connecting the strands of the strand jack (400) to the lug (260). The above order may be changed. That is, it may be made by first connecting the strands of the strand jack 400 and then moving the temporary tower structure 11 .

The upper structure lifting preparation step (S400) is an initial position (a position in which the tower structure 11 is at the rear end (outward-facing end) of the skid frame 10) for stable lifting of the upper structure U). To move to the lifting position (the tower structure 11 moves along the skid frame 10 and is located at the front end of the skid frame 10 (that is, the end of the side opposite between the column structures 110 and 120)) do.

Next, the upper structure lifting step (S500) is after the completion of the upper structure lifting preparation step (S400), the upper structure (U) using a strand jack 400 provided at the upper end of the temporary tower structure (T) By lifting to a position higher than the upper end of the column structure, the upper structure (U) including the girder structure 300 having a length longer than the longitudinal length in which a pair of column structures 110 and 120 is installed is the column structure 110 , 120) consists of lifting to a higher position than the upper end.

Specifically, in the lifting step (S500) of the upper structure, the strands of the strand jack 400 provided in the cross beam 13 of the upper end of the tower structure 11 and the lifting lugs 260 of the upper truss structure 200 are In the connected state, while synchronizing the strand jacks 400 of all the tower structures 11, that is, the lifting is performed while synchronizing the lifting height of the upper structure U to be lifted.

At this time, in the upper structure lifting step (S500), the place where the lifting height of the upper structure (U) is high waits until the height of the other places becomes the same and then is lifted.

In addition, in the present invention, the column structures 110 and 120 and/or the tower structure 11 has an object detection sensor (for example, Optical sensor) is provided to detect the lifting height of the upper structure U between the pair of column structures 110 and 120 in real time and transmit it to the control panel to control the strand jack 400 so that the upper structure U is horizontal. It can be made to be lifted more stably while maintaining the state.

The upper structure (U) lifted in the upper structure lifting step (S500) is located at a position deviated to one side from the upper end of the column structures (110, 120).

Subsequently, the horizontal moving step (S600) of the upper structure is lifted to a position higher than the upper end of the column structures 110 and 120, and the upper structure U is at a position deviated from the upper end of the column structures 110 and 120 to one side. It consists of horizontally moving the positioned upper structure (U) to position it in the upper position of the column structure.

Specifically, the horizontal moving step (S600) of the upper structure is a push-pull driving apparatus for the strand jack 400 provided movably along the cross beam 13 at the upper end of the tower structure 11. By driving through (14), the upper structure (U) located at a position deviated to one side from the upper end of the column structures (110, 120) consists of locating the upper structure (U) at the upper end of the column structures (110, 120).

Next, the upper fixture fixed installation step (S700) consists of fixing and installing the upper structure (U) on the upper end of the column structure after the horizontal movement of the upper structure (S600) is completed.

Specifically, in the upper structure fixing installation step (S700), the strand jack 400 is moved horizontally to position the upper structure U at the upper positions of the column structures 110 and 120, and is securely fixed by bolting and welding. done by doing

Next, the temporary tower structure dismantling step (S800) is to disassemble and remove the temporary tower structure (U) after completion of the upper structure fixing installation step (S700) so that only the column structures 110 and 120 and the upper structure (U) remain. do.

On the other hand, in the present invention, the upper structure assembling step (S200) is a truss constituting the upper structure (U) - using the girder fixing means 500 to fix between the upper truss structure 200 and the girder structure 300 Truss structure-girder structure fixing step (S210); may further include. That is, the upper structure U assembled in the upper structure assembling step S200 consists of an upper structure including the truss structure 200 and the girder structure 300 fixed by the truss-girder fixing means 500 . Here, the truss structure-girder structure fixing step (S210) may be performed after the superstructure fixing installation step (S700) is completed, and in consideration of safety and work efficiency, it is performed in the superstructure assembly step (S200) desirable.

Specifically, the truss structure-girder structure fixing step (S210) is before the upper truss structure 200 and the girder structure 300 are welded and bolted or in a welded and bolted state, the truss-girder fixing means 500 is It may further include fixing between each of the upper truss structure 200 and the girder structure 300 through.

The truss-girder fixing means 500 has one end at a first position P1 and a second position P2 having a gap in the upper frame 220 of the upper truss structure 200, respectively, as shown in FIG. A pair of first and second ends fixed to the main frame 310 of the girder structure 300 at the third position P3 and the fourth position P4 separated by a predetermined distance from the upper frame 220, respectively A second inclined fixture (511, 512), one end is fixed to the fifth position (P5) of the upper frame 220 of the upper truss structure 200, the other end of the upper frame 220 than the third position A third inclined fixture 520 fixed to a sixth position P6 further away from, and one end is fixed to the seventh position P7 of the upper frame 220 of the upper truss structure 200, and the other end is and a fourth inclined fixture 530 fixed to an eighth position P8 further away from the upper frame 220 than the fourth position.

The first to fourth inclined fixtures 511 , 512 , 520 , and 530 are located within the width range of the main frame 310 when the main frame 310 of the girder structure 300 is viewed in a plan view.

In addition, the first to fourth inclined fixtures 511 , 512 , 520 , 530 are symmetrical with respect to the upper truss structure 200 when the upper truss structure 200 is viewed in a plan view, and the upper truss structure 200 . is configured on both sides of the first inclined fixture 511 and the third inclined fixture 520 and the second inclined fixture 512 and the fourth inclined fixture 530 in the longitudinal direction of the main frame 310 It is configured symmetrically with respect to the center line.

In addition, the third position (P3) of the first inclined fixture (511) and the sixth position (P6) of the second inclined fixture (520) are located on the same line along the longitudinal direction of the main frame (310), The fourth position P4 of the second inclination fastener 512 and the eighth position P8 of the third inclination fastener 530 are preferably located on the same line in the longitudinal direction of the main frame 310 .

More preferably, the first position (P1) and the third position (P3) of the first inclination fixture 511 and the sixth position (P6) of the second inclination fixture (520) of the main frame (310) Located on the same line along the longitudinal direction, the second position (P2) and the fourth position (P4) of the second inclination fastener 512 and the eighth position (P8) of the third inclination fastener 530 are the main Preferably, they are located on the same line in the longitudinal direction of the frame 310 .

The upper truss structure 200 and the girder structure 300 are more stably and firmly fixed through the upper fixing means 500 configured as described above.

In addition, in the present invention, one end of a pair of fixing ropes (wire ropes) (not shown) is connected and fixed on both ends of the upper truss structure 200 in the upper structure U provided in the upper structure assembly step S200. In the upper structure fixing installation step 600, the upper truss structure 200 is fixedly installed on the pair of column structures 110 and 120 upper ends (head portion 102), and then the fixing rope (fixing wire) Rope) by diagonally and further comprising fixing the other end of the fixing rope to the ground, and accordingly, the basic structure of the present invention is made of a more robust structure.

According to the temporary structure-based port base structure construction method for port logistics automation construction according to the present invention as described above, a mega structure the size of a soccer field can be safely and effectively simultaneously lifted to a height of 10 stories and connected with a container crane There is an advantage in that the loading and transport of container logistics can be efficiently implemented in a smart automation environment in port logistics that deal with relatively large-scale logistics by building it to be possible.

In addition, according to the present invention, it is possible to extend the horizontal transport distance compared to the horizontal transport distance of existing port logistics, such as a crawler crane or a facility including a temporary tower and a strand jack, so that more efficient and effective logistics work can be performed. Compared to the existing port logistics facilities, it is large-scale and has the advantage of shortening the construction time and saving the construction cost, thereby securing economic feasibility.

The embodiments described in this specification and the accompanying drawings are merely illustrative of some of the technical ideas included in the present invention. Therefore, since the embodiments disclosed in the present specification are for explanation rather than limitation of the technical spirit of the present invention, it is obvious that the scope of the technical spirit of the present invention is not limited by these embodiments. Modifications and specific embodiments that can be easily inferred by those skilled in the art within the scope of the technical spirit included in the specification and drawings of the present invention should be interpreted as being included in the scope of the present invention.

S100: Column structure installation step
S200: superstructure assembly step
S210: truss structure - girder structure fixing step
S300: Temporary tower structure installation stage
S400: Preparation for lifting the superstructure
S500: Superstructure lifting stage
S600: Horizontal moving stage of superstructure
S700: superstructure fixed installation stage
S800: Temporary tower structure dismantling stage
T: Temporary tower structure
U: superstructure
S: pedestal
10: Skid frame (skid beam)
11: Tower structure
12: Working Platform
13: cross beam
14: push-pull drive
110, 120: column structure
101: body part
102: head
103: concrete block
104: steel pipe pile
200: upper truss structure
210: lower frame
220: upper frame
230: support frame
240: vertical frame
250: inclined frame
300: girder structure
310: main frame
320: support frame
400: straight jack
500: truss-girder fixing means
511: first inclined fixture
512: second inclined fixture
520: third slope fixture
530: fourth inclined fixture

Claims (12)

As a method for constructing a port foundation structure for transport and loading of port container logistics,
A column structure installation step of installing each of a pair of column structures having intervals in the width direction with intervals in the longitudinal direction orthogonal to the width direction;
an upper structure assembly step of assembling an upper structure fixedly installed on the upper end of the pair of column structures on the ground after the column structure installation step;
A temporary tower structure installation step of installing a temporary tower structure configured to be movable forward and backward with respect to the column structure on one side of each of the column structures;
The upper structure lifting preparation step of preparing the lifting of the upper structure by connecting the upper structure and the lifting device installed at the upper end of the temporary tower structure;
After completion of the preparation step for lifting the upper structure, the upper structure lifting step of lifting the upper structure to a position higher than the upper end of the column structure using the lifting device;
Horizontal movement of the upper structure by horizontally moving the lifted upper structure to a position higher than the upper end of the column structure to position the upper structure at the upper position of the column structure;
After completion of the horizontal movement of the upper structure, the upper structure fixed installation step of fixing the upper structure to the upper end of the column structure; and
Temporary tower structure dismantling step of dismantling the temporary tower structure after completion of the upper structure fixing installation step;
The column structure installation step is made by fixing the lower end of the column structure to a concrete block having a steel pipe pile fixed to the ground,
In the upper structure assembling step, the truss structure is fixed to the upper surface of the girder structure in a state in which the girder structure having a size larger than the longitudinal size of the entire column structure is located in the inner space facing the pair of column structures. consists of becoming
The girder structure of the upper structure is composed of a plurality of parallel main frames, and a plurality of support frames connecting the main frames,
The truss structure of the upper structure includes a pair of parallel frames made of a parallel lower frame and an upper frame, the upper frame having a shorter length than the lower frame, and a plurality of supporting frames connecting and supporting the lower frame and the upper frame. and a vertical frame extending from both ends of the lower frame toward the upper surface, and an inclined frame having one end fixed to the vertical frame and the other end fixed to an end of the upper frame.
How to construct a port foundation structure.
delete According to claim 1,
In the temporary tower structure installation step, a pair of tower structures having a predetermined interval are installed to be movable back and forth with respect to the column structure so that the column structures can be positioned between the intervals,
The temporary tower structure installed in the temporary tower structure installation step includes a skid frame installed on the ground on both sides of each column structure, and a pair of tower structures provided with a lower end slidably on each of the skid frames, and the pair A working platform connected and fixed between the upper ends of the tower structure of and a push-pull drive device configured to slide back and forth.
How to construct a port foundation structure.
4. The method of claim 3,
The preparation step for lifting the superstructure includes moving the tower structure from one end of the skid frame to the other end,
In the lifting step of the superstructure, in a state where both ends of the truss structure of the temporary tower structure are located on the sides of the column structure, the upper structure is lifted to a position higher than the upper end of the column structure while synchronizing the lifting devices of each of the temporary tower structures It is done by doing
The horizontal moving step of the upper structure comprises sliding the lifting device by driving the push-pull driving device so that both ends of the truss structure of the upper structure are positioned at the upper end of the column structure.
How to construct a port foundation structure.
5. The method of claim 4,
The lifting step of the superstructure,
In at least one of the column structure and the tower structure, it is characterized in that it is made to be lifted while controlling the lifting height of the girder structure by receiving a detection signal from an object detection sensor provided with an interval in the longitudinal direction.
How to construct a port foundation structure.
According to claim 1,
The upper structure fixed installation step,
It consists of fixing the girder structure of the upper structure to the column structure by bolting and welding,
One end of a pair of fixed wire ropes is connected and fixed to both ends of the truss structure, and the other end of the pair of fixed wire ropes is fixed to the ground.
How to construct a port foundation structure.
According to claim 1,
The step of assembling the superstructure further includes; a truss structure and a girder structure of the upper structure are fixed by a truss-girder fixing means to a truss structure-girder structure fixing step;
The truss-girder fixing means has one end fixed to a first position and a second position having a gap on one surface of the upper frame of the truss structure, respectively, and the other end is a third position and a fourth position separated by a predetermined distance from the upper frame, respectively. a pair of first and second inclined fixtures fixed to the main frame at a position, one end fixed at a fifth position on one surface of the upper frame, and the other end at a sixth position further away from the upper frame than the third position a third inclination fixture fixed to, and a fourth inclination fixture having one end fixed to a seventh position on one surface of the upper frame, and the other end fixed to an eighth position further away from the upper frame than the fourth position characterized by
How to construct a port foundation structure.
8. The method of claim 7,
The first inclined fixture to the fourth inclined fixture,
When the main frame of the girder structure is viewed in a plane, it is characterized in that it is located within the width range of the main frame.
How to construct a port foundation structure.
8. The method of claim 7,
The first inclined fixture to the fourth inclined fixture,
When the truss structure is viewed in a plane, it is symmetrical with respect to the truss structure and is configured on both sides of the truss structure,
The first inclined fixture and the third inclined fixture, and the second inclined fixture and the fourth inclined fixture are characterized in that they are configured symmetrically with respect to the central line in the longitudinal direction of the main frame.
How to construct a port foundation structure.
8. The method of claim 7,
The third position of the first inclined fixture and the sixth position of the second inclined fixture are located on the same line along the longitudinal direction of the main frame,
The fourth position of the second inclination fastener and the eighth position of the third inclination fastener are positioned on the same line in the longitudinal direction of the main frame
How to construct a port foundation structure.
8. The method of claim 7,
The first and third positions of the first inclined fixture and the sixth position of the second inclined fixture are located on the same line along the longitudinal direction of the main frame,
The second position and the fourth position of the second inclination fastener and the eighth position of the third inclination fastener are located on the same line in the longitudinal direction of the main frame.
How to construct a port foundation structure.
According to claim 1,
The upper structure fixed installation step,
It consists of fixing both ends of the truss structure of the upper structure to the upper end of the column structure by bolting and welding,
One end of a pair of fixed wire ropes is connected and fixed to both ends of the truss structure, and the other end of the pair of fixed wire ropes is fixed to the ground.
How to construct a port foundation structure.

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