KR102684491B1 - Weight-bar assembly for cog adjustment for eccentric lifting of offshore structure and eccentric lifting method using this - Google Patents

Abstract

The present invention relates to a center-adjusted heavy beam assembly for eccentric lifting of marine structures and an eccentric lifting method using the same, and more specifically, to eccentric lifting of marine structures that can increase the convenience of work while reducing the number of unnecessary equipment and parts. It relates to a center-adjustable heavy beam assembly and an eccentric lifting method using the same.
The center-adjusting heavy beam assembly for eccentric lifting of an offshore structure according to the present invention includes: a salvage object having a first center of gravity at a position higher than the liftable height of a marine crane; A salvage point formed on one side of the salvage object; And a weight-bar unit including a lower end that is detachably coupled to the lifting point and both ends that are caught by the marine crane, and that forms a second center of gravity in the salvage object at a lower position than the first center. It is characterized by including.

Description

Center-adjusted heavy beam assembly for eccentric lifting of marine structures and eccentric lifting method using the same {WEIGHT-BAR ASSEMBLY FOR COG ADJUSTMENT FOR ECCENTRIC LIFTING OF OFFSHORE STRUCTURE AND ECCENTRIC LIFTING METHOD USING THIS}

The present invention relates to a center-adjusted heavy beam assembly for eccentric lifting of marine structures and an eccentric lifting method using the same, and more specifically, to eccentric lifting of marine structures that can increase the convenience of work while reducing the number of unnecessary equipment and parts. It relates to a center-adjustable heavy beam assembly and an eccentric lifting method using the same.

Many floating cranes are used at offshore construction sites to lift cargo. When lifting cargo using a marine crane, the lifting load on each crane is determined by the weight of the cargo and the location of the center of gravity.

According to the “Eccentric Lifting and Mounting Method of Offshore Structures” (hereinafter referred to as “prior art”) of Patent No. 10-1577806, which the present applicant has previously applied for and received, the lifting point of the salvaged object is moved to be positioned lower than the center of gravity. , a series of tasks are performed to rotate the salvaged object using a marine crane and load it onto an object provided on an offshore structure.

Here, the prior art provides a tipping prevention device to prevent the lifting object from falling when the lifting object is rotated after moving the lifting point. Looking at this falling prevention device in more detail and detail, as shown in FIG. 8 equipment will be used.

A spreader (35) is used to connect the hooks (43, 43) of the two cranes to one lifting point (21), and a weight block (30) is installed to move the center of gravity to lift the object (10). The problem of lifting height has been solved by moving the lifting point 21 to be located lower than the center of gravity of the lifting object 10.

However, in the prior art, as shown, a pair of fixing devices 31, 31, 32, and 32 are provided at both upper and lower ends of the weight 30 in order to install the weight 30 on the salvage object 10. It is installed on the salvage object (10), and in order to dismantle the fixing devices (31, 31, 32, 32) after completing the work, additional work must be performed to remove or separate the relevant fixing part, such as welding, riveting, and bolting. It was a hassle.

In particular, the prior art is a hook 42a connecting the wire rope 41a connected to both ends of the spreader 35 to the lifting point 21 of the salvage object 10, as well as a connection with the crane hooks 43 and 43. In addition to the auxiliary wire rope (41b) and the auxiliary hook (42b) mounted on the installation lug (35a), auxiliary lugs (33, 33, There was a problem that there were unnecessarily many work points that required installation, fastening, and disassembly after completion of the work, such as the auxiliary hook (42c) and the auxiliary wire rope (41c) fixed by 33).

In addition, the prior art had the problem of increasing the burden of overall costs, such as manufacturing, installing, dismantling, and storing two heavy objects such as the weight 30 and the spreader 35.

In addition, in the prior art, there was a problem that there was a risk of safety accidents due to work at heights when installing or dismantling the weight 30.

In other words, there was the inconvenience of having to install and remove the weight 30 using a separate crane and taking the risks associated with working at heights.

Republic of Korea Patent No. 10-1577806 (published on December 8, 2015)

The present invention was invented to improve the above problems, and provides a center-adjusting heavy beam assembly for eccentric lifting of marine structures that reduces the number of unnecessary equipment and parts and increases work convenience, and an eccentric lifting method using the same. It is intended to provide.

In order to achieve the above object, the present invention provides a salvage object having a first center of gravity at a position higher than the liftable height of a marine crane; A salvage point formed on one side of the salvage object; And a lower part that is detachably coupled to the lifting point, and both ends that are caught by the marine crane, and includes a weight-bar unit that forms a second center of gravity at a lower position than the first center in the salvage object. It is possible to provide a center-adjusted heavy beam assembly for eccentric lifting of marine structures, characterized in that.

Here, the weight of the heavy beam unit is characterized in that it can increase or decrease in response to the salvage object.

At this time, the lifting point is characterized by including a lifting fastening hinge that is integrally formed or detachably coupled to one side of the lifting object.

In addition, the weight beam unit includes a first bar extending to a certain length, a second bar formed integrally with or detachably coupled to the first bar, and formed on the upper surface of the first bar with a length shorter than or equal to that of the first bar. The first bar is perpendicular to an imaginary line passing through the salvage object, both ends caught by the marine crane are formed at both ends of the upper surface of the first bar, and a lower end detachably coupled to the lifting point is connected to the first bar. It is characterized by being formed in the lower center of.

In addition, the heavy beam unit is configured to fix a lifting fastening hinge that is detachably coupled to the lifting point at the center of the lower end of the first bar and a hook on which the lifting wire rope of the marine crane is fixed. It is characterized in that it further includes at least one lifting lug installed on both ends of the upper surface of the.

In addition, the heavy beam unit further includes a guide fastening hinge protruding from the center of the upper end of the second bar, and a locking pin fixed through an end of the guide fastening hinge, and lifting the salvage object to the locking pin. It is characterized in that the upper guide engaging hook formed on the upper side of the point is engaged and fixed.

In addition, the heavy beam unit is characterized in that it further includes a guide groove that is recessed along the center of the opposing surface of the first bar and the second bar facing the salvage object and guides the salvage object.

Meanwhile, in the present invention, after lifting and rotating a salvage object with a marine crane and placing it on a stand with an inclined surface provided on a marine structure, the lifting point of the mounted salvage object is moved so that the salvage point is located lower than the center of gravity of the salvage object. In the eccentric lifting method of fastening to the marine crane, using the marine crane, a first beam unit is hung with a wire rope on both ends of a heavy beam unit orthogonal to an imaginary line passing through the salvaged object and brought close to the salvaged object. step; A second step of detachably fastening the lower center of the heavy beam unit to the lifting point of the salvage object; And a third step of finally fixing the upper side of the heavy beam unit, the lower center of which is fixed to the lifting point, to the salvage object, wherein the salvage object to which the heavy beam unit is fastened is rotated by the marine crane. It is also possible to provide an eccentric lifting method using a center-adjusted weight beam assembly for eccentric lifting of an offshore structure, which is then mounted on an object provided on the offshore structure.

Here, the second step further includes a process of fitting and seating the salvage object in a guide groove recessed along the center of the opposing surface of the heavy beam unit facing the salvage object.

At this time, the third step is a process of rotating the lower center of the heavy beam unit fastened to the salvage object as a rotation axis and bringing the upper center of the heavy beam unit close to the salvage object, and the weight beam unit Characterized in that it further comprises a process of fixing the guide fastening hinge provided at the upper center of the upper guide hook formed on the upper side of the lifting point of the salvage object.

According to the present invention configured as described above, the following effects can be achieved.

First, the present invention provides a salvage object having a first center of gravity at a position higher than the liftable height of a marine crane; A salvage point formed on one side of the salvage object; And a lower part that is detachably coupled to the lifting point, and both ends that are caught by the marine crane, and includes a weight-bar unit that forms a second center of gravity at a lower position than the first center in the salvage object. This makes it possible to increase the convenience of work while reducing the number of unnecessary equipment and parts, such as spreaders and weights.

In particular, compared to the prior art, the present invention only needs to perform a series of tasks such as managing, designing, installing, and dismantling only one heavy beam unit, so it will be possible to reduce overall costs by reducing the number of management units.

In addition, compared to the prior art where there is a risk of safety accidents due to the installation and disassembly of the weight, the present invention does not require separate disassembly of the weight from the salvaged object, so compared to the prior art where additional work at height was required for disassembly. This makes it possible to prevent safety accidents in advance.

Figure 1 is an exploded perspective view showing the overall configuration of a center-adjusting heavy beam assembly for eccentric lifting of an offshore structure according to an embodiment of the present invention;
Figure 2 is a block diagram showing an eccentric lifting method using a center-adjusted heavy beam assembly for eccentric lifting of an offshore structure according to an embodiment of the present invention;
3 to 6 are conceptual diagrams sequentially showing an eccentric lifting method using a center-adjusted weight beam assembly for eccentric lifting of an offshore structure according to an embodiment of the present invention;
Figure 7 is a conceptual diagram showing a state in which a salvage object equipped with a heavy beam unit of the present invention is mounted on an object of a marine structure;
Figure 8 is an exploded perspective view showing the overall structure of the fall prevention device used in the existing lifting method.

The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various different forms.

The examples herein are provided to make the disclosure of the present invention complete and to fully inform those skilled in the art of the scope of the invention. And the present invention is only defined by the scope of the claims.

Accordingly, in some embodiments, well-known components, well-known operations and well-known techniques are not specifically described in order to avoid ambiguous interpretation of the present invention.

In addition, the same reference numerals refer to the same components throughout the specification, and the terms used (mentioned) in the specification are for explaining embodiments and are not intended to limit the present invention.

In this specification, the singular also includes the plural unless specifically stated in the phrase, and elements and operations referred to as 'including' or 'comprising' do not exclude the presence or addition of one or more other elements and operations. .

Unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used with meanings that can be commonly understood by those skilled in the art to which the present invention pertains. Additionally, terms defined in commonly used dictionaries are not interpreted ideally or excessively unless they are defined.

Hereinafter, preferred embodiments of the present invention will be described with reference to the attached drawings.

First, Figure 1 is an exploded perspective view showing the overall configuration of a center-adjusting heavy beam assembly for eccentric lifting of an offshore structure according to an embodiment of the present invention.

And, Figure 2 is a block diagram showing an eccentric lifting method using a center-adjusted weight beam assembly for eccentric lifting of an offshore structure according to an embodiment of the present invention.

Meanwhile, Figures 3 to 6 are conceptual diagrams sequentially showing an eccentric lifting method using a center-adjusting heavy beam assembly for eccentric lifting of an offshore structure according to an embodiment of the present invention.

In addition, Figure 7 is a conceptual diagram showing a state in which a salvage object equipped with a heavy beam unit of the present invention is mounted on an object of a marine structure.

As shown in FIG. 1, the present invention includes a salvage object 100 having a first center at a position higher than the liftable height of the marine crane 400 (see FIG. 7), and a salvage object formed on one side of the salvage object 100. It can be seen that the structure includes a lifting point 200 and a weight-bar unit 300.

Here, the heavy beam unit 300 includes a lower end that is detachably coupled to the lifting point 200 and both ends that are caught by a marine crane, and a second center is formed in the salvage object 100 at a lower position than the first center. will be.

At this time, it should be noted that the first center and the second center are in a relative positional relationship and can be formed at the top or bottom, respectively, depending on the position at which the salvage object 100 is lifted.

The present invention can be applied to the above-mentioned embodiments, and of course, it is also possible to apply the following various embodiments.

First, the lifting point 200 may be a lifting fastening hinge 210 that is integrally formed or detachably coupled to one side of the lifting object 100.

On the other hand, the heavy beam unit 300 includes a first bar 310 extending to a certain length, and is formed integrally with or detachably coupled to the first bar 310 and has a first bar ( It may include a second bar 320 that is shorter than or has the same length as 310.

Here, the first bar 310 is approximately perpendicular to the virtual line ℓ passing through the salvage object 100, and both ends caught by the marine crane 400 are formed at both ends of the upper surface of the first bar 310, It can be clearly seen that the lower end that is detachably coupled to the point 200 is formed in the lower center of the first bar 310.

At this time, the weight of the above-described heavy beam unit 300 is adjusted to correspond to the salvage object 100 by forming the second bar 320 integrally with or detachably coupled to the first bar 310 as described above. Of course, it can be changed.

This heavy beam unit 300 may further include a lifting fastening hinge 330 that is detachably coupled to the lifting point 200 at the center of the lower end of the first bar 310.

In addition, the heavy beam unit 300 has at least one lifting lug installed on both ends of the upper surface of the first bar 310 to fix the hook 420 on which the lifting wire rope 410 of the marine crane is fixed. (340) may be further provided.

Here, the heavy beam unit 300 may further be provided with a pair of seating stones 311, 311 that protrude from the upper surface of the first bar 310 and are spaced apart, and the pair of seating stones 311 described above , 311), the second bar 320 may be seated and fixed between them.

At this time, the lifting lug 340 is formed on the upper surface of the first bar 310 and the upper surface of the seating stone steps 311 and 311, respectively, so that the heavy beam unit including the first and second bars 310 and 320 When lifting 300 through the wire rope 410, it can help to stably move closer to the salvage object 100 while reducing the left and right shaking with respect to the salvage object 100 to some extent.

On the other hand, the heavy beam unit 300 includes a guide fastening hinge 350 protruding from the center of the upper end of the second bar 320, and a locking pin 352 fixed through the end of the guide fastening hinge 350. More can be provided.

The upper guide hook 220 formed on the upper side of the lifting point 200 of the lifting object 100 is caught on the locking pin 352, so that the upper part of the heavy beam unit 300 is fixed to the lifting object 100.

In addition, the heavy beam unit 300 allows workers to visually check the exact center alignment of the heavy beam unit 300 with respect to the salvage object 100 and guides and moves the heavy beam unit 300 to the salvage object 100. To help, a guide groove 360 may be further provided.

That is, the guide groove 360 is depressed along the center of the opposing surfaces of the first bar 310 and the second bar 320 facing the salvage object 100 to guide the salvage object 100.

Hereinafter, an eccentric lifting method using a center-adjusted heavy beam assembly for eccentric lifting of an offshore structure according to an embodiment of the present invention will be described.

The eccentric lifting method according to an embodiment of the present invention involves lifting and rotating the salvage object 100 with a marine crane 400 and placing it on a stand (not shown hereinafter) having an inclined surface provided on the marine structure 600. , relates to a method of fastening the lifting point 200 of the mounted salvage object 100 to the marine crane 400 by moving the lifting point 200 so that the lifting point 200 is located lower than the center of gravity of the salvage object 100.

First, the worker uses the marine crane 400 to place the two ends of the heavy beam unit 300 perpendicular to the virtual line (ℓ, hereinafter referred to as FIG. 1) penetrating the salvage object 100, as shown in FIGS. 3 and 4. The work of hanging the wire rope 410 and approaching the salvage object 100 as shown in FIG. 5 is performed (S1: first step).

Thereafter, the worker operates the marine crane 400 and detachably fastens the lower center of the heavy beam unit 300 to the lifting point 200 of the salvage object 100 as shown in FIG. 6 (S2: second step) ), the upper side of the heavy beam unit 300, the lower center of which is fixed to the lifting point 200, is finally fixed to the salvage object 100 as shown in FIGS. 6 and 7 (S3: third step ).

Here, the salvage object 100 to which the heavy beam unit 300 is fastened is rotated by the marine crane 400 and then mounted on the mounting object 610 provided on the marine structure 600 as shown in FIG. 7.

At this time, in the second step (S2), the worker installs a heavy beam unit 300 facing the salvage object 100 in order to increase the accuracy of the work and ensure that the heavy beam unit 300 is accurately guided to the salvage object 100. ) may additionally be performed to seat the salvaged object 100 in the guide groove 360 recessed along the center of the opposing surface.

In addition, in the third step (S3), the upper center of the heavy beam unit 300 is rotated around the lower center of the heavy beam unit 300 fastened to the salvage object 100 as a rotation axis. Additional work can be performed to approximate .

In addition, in the third step (S3), the guide fastening hinge 350 provided at the upper center of the heavy beam unit 300 is connected to the upper guide engaging hook formed on the upper side of the lifting point 200 of the salvage object 100. Of course, the additional work of fixing the jam at (220) can also be performed.

Therefore, the present invention can increase the convenience of work while reducing the number of unnecessary equipment and parts, such as spreaders and weights.

In particular, compared to the prior art, the present invention only needs to perform a series of tasks such as managing, designing, installing, and dismantling only one heavy beam unit 300, so overall costs can be reduced by reducing the number of management units.

In addition, compared to the prior art where there is a risk of safety accidents due to the installation and disassembly of the weight, the present invention does not require separate dismantling of the weight beam unit 300 from the salvage object 100, so work at height is required for dismantling. Compared to prior technologies that required additional technology, there is no risk of safety accidents occurring.

As described above, the basic technical idea of the present invention is to provide a center-adjusted heavy beam assembly for eccentric lifting of marine structures and an eccentric lifting method using the same, which can reduce the number of unnecessary equipment and parts and increase the convenience of work. can be seen.

And, of course, many other modifications and applications are possible for those skilled in the art within the scope of the basic technical idea of the present invention.

100...salvage
200...Inyang Branch
210...Hinge for lifting fastening
220...Upper guide catch hook
300...heavy beam unit
310...1st bar
311, 311...seating stone ledge
320...2nd bar
330...Hinge for lifting fastening
340... Lifting lug
350...Hinge for guide fastening
352...Latch pin
360...Guide Home
400...marine crane
410...wire rope
420...hanging hook
430...Crane hook
500...tug boat
600...offshore structures
610...Loaded object
ℓ...imaginary line
S1...First stage
S2...second stage
S3...third stage

Claims (11)

A salvage object having a first center of gravity at a position higher than the liftable height of a marine crane;
A salvage point formed on one side of the salvage object; and
A weight-bar unit including a lower end that is detachably coupled to the lifting point and both ends that are caught by the marine crane, and that causes a second center of gravity to be formed in the salvage object at a lower position than the first center. do,
The weight of the heavy beam unit is capable of increasing or decreasing in response to the salvage object. A center-adjusting heavy beam assembly for eccentric lifting of an offshore structure. delete In claim 1,
The salvage point is,
A center-adjusting heavy beam assembly for eccentric lifting of an offshore structure, characterized in that it includes a lifting fastening hinge that is integrally formed or detachably coupled to one side of the salvage object. In claim 1,
The heavy beam unit,
a first bar extending to a certain length; and,
A second bar is integrally formed with or detachably coupled to the first bar and is formed on an upper surface of the first bar with a length shorter than or equal to that of the first bar,
The first bar is perpendicular to an imaginary line passing through the salvage object,
Both ends caught by the marine crane are formed on both ends of the upper surface of the first bar,
A center-adjusting heavy beam assembly for eccentric lifting of an offshore structure, characterized in that the lower end that is detachably coupled to the lifting point is formed in the lower center of the first bar. In claim 4,
The heavy beam unit,
A lifting fastening hinge that is detachably coupled to the lifting point at the center of the lower end of the first bar;
The eccentric lifting center of the marine structure further comprises at least one lifting lug installed on both ends of the upper surface of the first bar to fix the hook on which the lifting wire rope of the marine crane is fixed. Adjustable heavy beam assembly. In claim 5,
The heavy beam unit,
It further includes a pair of seating stone protrusions protruding from the upper surface of the first bar and spaced apart,
The second bar is seated and fixed between the pair of seating stones,
The lifting lug is a center-adjusting heavy beam assembly for eccentric lifting of an offshore structure, characterized in that it is formed on the upper surface of the first bar and the upper surface of the seating stone ledge, respectively. In claim 4,
The heavy beam unit,
A guide fastening hinge protruding from the center of the upper end of the second bar;
It further includes a locking pin fixed through an end of the guide fastening hinge,
A center-adjusting heavy beam assembly for eccentric lifting of a marine structure, characterized in that an upper guide hook formed on the upper side of the lifting point of the salvage object is fixed to the locking pin. In claim 4,
The heavy beam unit,
A guide groove recessed along the center of the opposing surface of the first bar and the second bar facing the salvage object to guide the salvage object; a center adjustment weight beam for eccentric lifting of an offshore structure, characterized in that it further comprises a. assembly. After lifting and rotating the salvage object with a marine crane and placing it on a stand with an inclined surface provided on a marine structure, the lifting point of the mounted salvage object is moved so that it is located lower than the center of gravity of the salvage object and fastened to the marine crane. In the eccentric lifting method,
A first step of using the marine crane to approach the salvage object by hanging wire ropes on both ends of a heavy beam unit perpendicular to an imaginary line passing through the salvage object;
A second step of detachably fastening the lower center of the heavy beam unit to the lifting point of the salvage object; and
It includes a third step of finally fixing the upper side of the heavy beam unit, the lower center of which is fixed to the lifting point, to the salvage object,
The salvage object to which the heavy beam unit is fastened is rotated by the marine crane and then mounted on a mounting object provided on the marine structure. An eccentric lifting method using a center-adjusted heavy beam assembly for eccentric lifting of an offshore structure. . In claim 9,
The second step is,
A center-adjusting heavy beam assembly for eccentric lifting of an offshore structure, further comprising the step of seating the salvage object in a guide groove recessed along the center of the opposing surface of the heavy beam unit facing the salvage object. Eccentric lifting method used. In claim 9,
The third step is,
A process of rotating the lower center of the heavy beam unit fastened to the salvage object as a rotation axis and bringing the upper center of the heavy beam unit close to the salvage object;
Eccentric lifting of an offshore structure, characterized in that it further comprises the process of fixing the guide fastening hinge provided at the upper center of the heavy beam unit to the upper guide hook formed on the upper side of the lifting point of the salvage object. Eccentric lifting method using center-adjusted heavy beam assembly.

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