KR102045025B1 - Roundness Maintaining Device of Large Cylindrical Structure and Manufacturing Method Thereof - Google Patents

Abstract

An apparatus for maintaining a roundness of a large cylindrical structure for offshore structures, comprising: a pair of fixed plates formed at a predetermined height and width, curved plates fixed vertically between the pair of fixed plates, and adjusting means for adjusting the roundness of the curved plate. It is possible to maintain the roundness of a large cylindrical structure with a large diameter by providing a plurality of fixed plates and curved plates fixed at an isometric angle, and to maintain the roundness of a large cylindrical structure by a curved plate. Obtained.

Description

Roundness Maintaining Device of Large Cylindrical Structure and Manufacturing Method Thereof}

The present invention relates to a device for maintaining the roundness of a large cylindrical structure for offshore structures and a method for manufacturing the same, and more particularly, to maintain the roundness and / or straightness of a large cylindrical structure used for a turret of an offshore structure. The present invention relates to a roundness maintaining device for a large cylindrical structure for an offshore structure and a method of manufacturing the same.

Generally, a marine structure is a general term for a structure installed on the sea or undersea, and is mainly used for exploration and extraction of energy sources such as petroleum and natural gas.

These offshore structures include fixed platform, compact piled tower (CPT), semi-submersible type platform (TLP), tension leg platform (SLP), spar platform and ship type. Offshore structures (FPSO).

Since these marine structures can be damaged by unexpected disturbances (for example, sea breeze, waves, currents, etc.), minimizing such disturbances has emerged as an important challenge in many types of marine structures. .

For example, a ship-type offshore structure (in this case 'floating crude oil production storage facility, FPSO') can be examined. In order to minimize the impact from the disturbance, such marine type marine structures are equipped with various turret structures on the hull that rotate the bow angle in the direction in which the disturbance is approaching or rotate on their own. have.

On the other hand, the turret consists of upper structures, upper gantry, lower gantry, manifold, collar structure, and lower turret. A bogie support structure.

The large cylindrical structure constituting the bogie support structure is a large structure of approximately 22,000 mm in diameter and approximately 6,500 mm in height, and maintenance of roundness and / or straightness is very important. The roundness of such a large cylindrical structure should be maintained within a diameter of 22,000 mm and its tolerance within ± 5 mm.

1 is a cross-sectional view of a large cylindrical structure is installed on the offshore structure. As shown in Figure 1, the large cylindrical structure is installed in the middle or bow portion of the offshore structure as part of the turret to safely moor the offshore structure.

Such a large cylindrical structure is divided into a lower structure in which no additives are mounted on the outer surface and an upper structure in which the additives are mounted on the outer surface.

2 is a view briefly illustrating a manufacturing process of a large cylindrical structure. As in FIG. 2A, the large cylindrical structure fabricates the auxiliary assembly 1 in an arc shape. This auxiliary assembly 1 is manufactured in an arc shape having the same length by dividing the large cylindrical structure into equal angles.

In addition, as shown in FIG. 2B, a donut-shaped stringer 2 is fixed on a surface plate (not shown), and then welding is performed while maintaining the roundness of the auxiliary assembly 1. At this time, the upper surface of the stringer (2) is fixed to the reinforcement (3) of the shape of ten (twist). The reinforcement 3 is made of a H-beam or a pipe, and is fixed to maintain the roundness of each auxiliary assembly 1 when assembling the auxiliary assembly 1.

As in FIG. 2C, the secondary assembly 1 is sequentially welded and fixed along the circle of the stringer 2.

As shown in Fig. 2d and 2e, the prefabricated subassembly 1 is fixed to the upper surface of the subassembly 1 fixed in a circle by welding, while maintaining the roundness by another reinforcing material 3. Done.

When the assembling of the auxiliary assembly 1 is completed as described above, the attachment 4 is fixed to the outer surface of the large cylindrical structure by welding.

In the manufacture of such a conventional large cylindrical structure, it is difficult to work while maintaining the roundness in a position where the reinforcement is not fixed, and the material is used more than necessary. Difficult to work, there was a problem that the deformation of the welding portion occurs during the removal of the reinforcement.

For example, Patent Document 1 discloses a 'turret device'.

The turret device of the following Patent Document 1 includes a top to bottom installed in a vertical opening formed through the hull, and a bottom to be coupled to a lower portion of the top from the top and provided with a lower bearing assembly rotatably supporting the hull. The lower bearing assembly is coupled to a lower bearing provided on the outer circumferential surface of the lower part and a hull outer wall forming the vertical opening. And an independent sliding pad in slidable contact with the lower bearing, wherein the independent sliding pad includes a plurality of slit plates having at least one slit.

Republic of Korea Patent Publication No. 10-2012-0097746 (published September 5, 2012)

However, the outer turret structure of the cylindrical marine structure according to the prior art has the advantage that the rotation is smoothly fixed by the slide pad, there was a problem that can not be applied to the production of a large cylindrical structure.

An object of the present invention is to solve the problems as described above, to provide a roundness maintenance device and a manufacturing method of a large cylindrical structure for offshore structure to easily maintain the roundness and / or straightness when manufacturing a large cylindrical structure. .

Another object of the present invention is to provide a roundness maintaining device for a large cylindrical structure for an offshore structure that maintains the roundness and / or straightness of a lower structure by using a lightened roundness maintaining device and a manufacturing method thereof.

In order to achieve the object as described above, the roundness maintaining device of a large cylindrical structure for offshore structures according to the present invention is a pair of fixed plate formed of a predetermined height and width, a curved plate fixed vertically between the pair of fixed plates, It characterized in that it comprises an adjustment means which is supported to maintain the curved plate vertically fixed state.

The fixing plate is formed in an arc shape having a predetermined length, characterized in that the reinforcing plate for supporting the fixing plate is provided.

A plurality of first eye plates fixed to an upper surface of the surface plate to which the fixing plate and the curved plate are fixed, a second eye plate fixed to an upper end of the curved plate, and a wire fixed between the first eye plate and the second eye plate It is characterized by including.

The wire is characterized in that it is fixed symmetrically based on the curved plate.

The wire is characterized in that the lever block for adjusting the length and tension of the wire is provided.

The adjustment means is characterized in that it comprises a secondary support which is fixed to the outside of the curved plate vertically, the jack is fixed to the auxiliary support and maintains the curved plate vertically.

In addition, in order to achieve the object as described above, the manufacturing method of a large cylindrical structure for offshore structures according to the present invention comprises the steps of (a) fixing the fixed plate at an equal angle, (b) inserting the curved plate on the fixed plate, ( c) setting the roundness or straightness by adjusting the tension of the wire fixed to the curved plate, (d) fixing the adjusting means to one surface of the curved plate, (e) another curved surface adjacent to the curved plate Welding the plate.

In the step (a), the fixing plate is made of a pair of circular arcs of a predetermined length, characterized in that it comprises the step of stably supporting the fixing plate by fixing the reinforcement plate on one surface of each of the pair of fixing plate do.

In the step (c), (c1) fixing the first eye plate on the surface plate, (c2) fixing the second eye plate on the top of the curved plate, (c3) the first eye plate and the second Binding the wire provided with the lever block between the eye plates; and (c4) adjusting the length and tension of the wire so that the curved plate is maintained vertically.

After the (c4), the curved plate is characterized in that it is maintained in a vertical state by the tension control of the wire.

In the step (d), the adjusting means is characterized in that it comprises the step of vertically fixing the auxiliary support having a predetermined length, fixing the jack for supporting the curved plate on one surface of the auxiliary support.

As described above, according to the apparatus for maintaining roundness of a large cylindrical structure for offshore structures according to the present invention, the roundness of a large cylindrical structure having a large diameter can be maintained by a plurality of fixing plates fixed at an equal angle, and the curved surface is caused by the tension of the wire. The straightness of the plate can be maintained, and the simple structure makes it possible to reduce the weight.

According to the manufacturing method of the large cylindrical structure for offshore structures according to the present invention, the manufacturing cost of the lower structure and the installation of the roundness maintaining device is easy, the manufacturing cost is low, and the roundness maintaining device can be reused and can be used semi-permanently. Obtained.

1 is a cross-sectional view showing a state in which a conventional large cylindrical structure is installed.
2 is a view sequentially showing a process of manufacturing a conventional large cylindrical structure.
Figure 3 is a cross-sectional view showing a roundness maintaining apparatus of a large cylindrical structure for offshore structures according to an embodiment of the present invention.
4 is a plan view of FIG. 3.
5 is a partially enlarged cross-sectional view of FIG. 3.
6 is a process diagram illustrating a step-by-step method of manufacturing a large cylindrical structure for offshore structures according to a preferred embodiment of the present invention.

Hereinafter, a roundness maintaining device of a large cylindrical structure for an offshore structure according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 is a cross-sectional view showing a roundness maintaining apparatus of a large cylindrical structure for offshore structures according to a preferred embodiment of the present invention, Figure 4 is a plan view of Figure 3, Figure 5 is a partially enlarged cross-sectional view of FIG.

The roundness maintaining device of a large cylindrical structure for an offshore structure according to a preferred embodiment of the present invention is a pair of fixed plate 10 formed in a predetermined height and width, the curved plate 20 and the surface is fixed vertically between the fixed plate 10 And adjusting means 30 for adjusting the roundness and / or straightness of the plate 20.

Meanwhile, the large cylindrical structure of the present invention refers to the lower structure among the upper structure and the lower structure. That is, the lower structure of the large cylindrical structure is manufactured according to the present invention, and the upper structure is manufactured separately. These substructures and superstructures are manufactured, respectively, and then are integrally manufactured by a separate manufacturing process.

3 to 5, the fixed plate 10 is a plate having a predetermined size, and has a predetermined height and width and consists of a circular arc having a predetermined length when viewed in a plan view. The fixing plate 10 is for stably fixing the curved plate 20 and is provided in pairs.

As shown in FIGS. 4 and 5, the pair of fixing plates 10 are fixed apart by the thickness of the curved plate 20, and a reinforcing plate 11 supporting the fixing plate 10 on one surface of each fixing plate 10. Is fixed. The fixing plate 10 and the reinforcing plate 11 is fixed to the upper surface of the surface plate 12 by welding.

On the other hand, since the lower structure of the large cylindrical structure is also approximately 22,000 mm in diameter, the surface plate 12 is flat steel plate or yard flat concrete fixed horizontally in a separate assembly site (also called a shop). Refers to cotton. That is, the surface plate 12 is not manufactured separately, but uses a flat concrete bottom surface of a plurality of steel sheets or yards fixed horizontally to the bottom surface of the assembly plant.

The reinforcement plate 11 is formed in a '-' shape so that one side is fixed to the surface plate 12, the other side is fixed to one surface of the fixing plate (10). The fixing plate 10 is fixed vertically stable by the reinforcing plate (11).

As shown in FIG. 3, the curved plate 20 has a predetermined height and thickness (width), and has a predetermined length (arc length). That is, the vertical direction in FIG. 3 is set to height, the circular arc in FIG. 4 is set to length, and the horizontal direction in FIG. 5 is set to thickness (width).

That is, the fixing plate 10 and the curved plate 20 is formed of a three-dimensional shape having a height, a length, and a thickness, respectively. On the other hand, the fixing plate 10 is to fix the curved plate 20 in the garden (roundness), the height and length is made of approximately 200 ~ 400mm. The curved plate 20 is made of a height of 3,000 to 5,000 mm and a length of 2,500 to 6,000 mm.

On the other hand, the fixed plate 10 may be changed by increasing or decreasing its size as necessary.

The thicknesses of these fixing plates 10 and the curved plate 20 are made of appropriate thicknesses, respectively. The thickness of the fixing plate 10 is sufficient to be made of a thickness having a strength capable of supporting the curved plate 20, the curved plate 20 is made of a thickness that meets the design conditions.

The curved plate 20 is sandwiched between a pair of spaced fixing plates 10. The curved plate 20 is sandwiched between the pair of fixing plates 10 to maintain roundness, and to maintain a vertically fixed state.

Meanwhile, the curved plate 20 includes a first eye plate 21 fixed to the surface plate 12, a second eye plate 22 fixed to an upper end of the curved plate 20, a first eye plate 21 and a second eye. A wire 23 connected between the plates 22.

The first eye plate 21 is fixed to the surface plate 12, and the second eye plate 22 is fixed to the upper end of the curved plate 20 by welding. The first eye plate 21 may be fixed by welding at a predetermined position of the surface plate 12 or may be fixed to a circular pile in which the first eye plate 21 is fixed and embedded in the concrete floor.

 Between these eye plates 21 and 22, a wire 23 for maintaining the curved plate 20 in a vertically fixed state is connected.

The wire 23 also includes a lever block 24 for adjusting the length of the wire 23. The lever block 24 is provided with a tension by adjusting the length of the wire 23 to be long or short. Accordingly, the curved plate 20 is maintained in a vertically fixed state. In addition, the wire 23 and the lever block 24 may adjust the curved plate 20 vertically when the curved plate 20 is not standing vertically.

The adjusting means 30 comprises an auxiliary strut 31 fixed vertically and a jack 32 fixed to the auxiliary strut 31 to support the curved plate 20.

The auxiliary support 31 is fixed perpendicularly to the outside of the curved plate 20, and the auxiliary support 30 preferably uses a H-beam having strong rigidity. This is because the curved plate 20 must maintain sufficient strength to maintain the vertically fixed state.

The auxiliary strut 31 is fixed to the jack 32 is adjustable in length. In FIG. 3, one jack 32 is fixed, but a plurality of jacks 32 may be fixed to compensate for the straightness of the curved plate 20.

In addition, the jack 30 may use a screw jack or a hydraulic jack that is adjustable in length.

As shown in FIG. 4, the fixing plate 10 and the adjusting means 30 are fixed at an angle of 15 °, 20 °, and 30 °, respectively. This is to maintain the roundness of the curved plate 20 more accurately during the assembling operation of the curved plate 20, as well as to check the straightness of the curved plate 20 at more locations.

Next will be described in detail the coupling relationship of the roundness maintaining device of a large cylindrical structure for offshore structures according to an embodiment of the present invention.

The pair of fixing plates 10 are fixed by welding to steel sheets or by embedding in a concrete floor. At this time, the fixing plate 10 is fixed in a plurality of arrays at an isometric angle of 15 °, 20 °, 30 °, fixed in a round shape to maintain a predetermined diameter. That is, a plurality of fixing plates 10 are arranged and fixed in a form to maintain roundness.

In addition, the fixing plate 10 is fixed to the reinforcement plate 11 by welding or embedded in the concrete floor surface to maintain a more firmly fixed state.

The curved plate 20 prepared in advance in a predetermined size is sandwiched between the fixing plates 10 and fixed vertically. In addition, the second eye plate 22 is fixed to the upper end of the curved plate 20 by welding. That is, the curved plate 20 is fixed between the first eye plate 22 and then the fixing plate 10.

At the same time, the first eye plate 21 is fixed to the surface plate 12 by welding or embedding at positions symmetrical with respect to the fixing plate 10. The wire 23 is bound between the first eye plate 21 and the second eye plate 22. The wire 23 is provided with a lever block 24 for adjusting the length of the wire 23.

On the other hand, the operator is to check the straightness of the curved plate 20 in the wire 23 is installed. The wire 23 is fixed to the curved plate 20 vertically by adjusting the length of the wire 23, if the curved plate 20 is fixed at an angle rather than vertical. Therefore, the curved plate 20 is fixed while maintaining roundness and straightness.

In addition, the adjustment means 30 is fixed to the outside of the curved plate 20. The auxiliary support 31 of the adjusting means 30 is fixed perpendicularly to the surface plate 12, and the auxiliary support 31 is fixed to the welding or foundation structure (foundation). The jack 32 is fixed in advance to one surface of the auxiliary support 31 by welding.

On the other hand, the jack 32 is in close contact with the curved plate 20 to prevent deformation or warpage of the curved plate 20. Accordingly, even if the curved plate 20 is bent or deformed, it is possible to maintain the vertical roundness by the fixing plate 10 and the straightness by the jack 32.

Next, with reference to Figure 6 will be described in detail a manufacturing method of a large cylindrical structure for offshore structures according to an embodiment of the present invention.

6 is a process diagram illustrating a step-by-step method of manufacturing a large cylindrical structure for offshore structures according to a preferred embodiment of the present invention.

The fixing plate 10 is fixed to the surface plate 12 at equal intervals so as to maintain an isometric angle of 15 °, 20 ° or 30 ° (S10). A pair of fixing plate 10 is fixed apart by the thickness of the curved plate 20, these fixing plate 10 is made of an arc shape having a predetermined length.

That is, the fixing plate 10 is fixed to maintain the roundness equal to the diameter of the lower structure. In addition, the reinforcing plate 11 is fixed to the outer surface of the fixed plate 10 by welding or buried respectively to reinforce the strength of the fixed plate 10.

Each of these fixing plates 10 is fitted with a curved plate 20 to be fixed (S20). The first eye plate 21 is fixed to the surface plate 12 at positions symmetrical with respect to the fixing plate 10, and the second eye plate 22 is fixed to the upper end of the curved plate 20.

Meanwhile, the curved plate 20 may be fixed in a state where the second eye plate 22 is fixed in advance.

In addition, the wire 23 is bound between the first eye plate 21 and the second eye plate 22. The wire 23 is provided with a lever block 24 for adjusting the length of the wire 23, by adjusting the length or tension of the wire 23 by the lever block 24 to adjust the straightness of the curved plate 20. Set (S30).

Therefore, the curved plate 20 is fixed vertically by adjusting the length of the wire 23, thereby the curved plate 20 is adjusted to have a vertical straightness. The straightness of the curved plate 20 adjusts the length or tension of the wire 23 by increasing or decreasing the length of the wire 23 symmetrically connected to each other. When the curved plate 20 is not fixed vertically, the curved plate 20 can be adjusted vertically.

One surface of the curved plate 20 is fixed to the adjustment means 30 (S40). That is, the auxiliary strut 31 of the adjusting means 30 is vertically fixed, and the jack 40 is fixed to one surface of the auxiliary strut 31 to maintain the straightness even when the curved plate 20 receives an external force.

The auxiliary strut 31 uses a high strength H-shaped steel so as to remain vertically fixed even to external force. In addition, the jack 32 uses a screw jack or a hydraulic jack in which the length adjustment is made.

When the installation of the roundness maintaining device of the fixing plate 10 and the adjustment means 30 is completed in this way, since it is fixed in a circular shape when viewed in a plane, the roundness and the vertical roundness of the curved plate 20 can be confirmed.

On the other hand, when the curved plate 1 is not fixed to the vertical straightness, the curved plate 20 is pressed by adjusting the jack 32 provided on one surface of the curved plate 20. That is, the jack 32 is to press the curved plate 20.

In this way, since the curved plates 20 are fixed to each other by welding while maintaining the roundness and the straightness of the curved plate 20, the round plate 20 is assembled while maintaining the roundness and straightness of the large diameter structure (S50).

The lower structure thus manufactured is moved by a crane or the like. For this purpose, the wire 23 is released from the second eye plate 22. In addition, the lower structure is moved by hanging the hook of the crane on the second eye plate (22).

Therefore, the second eye plate 22 serves as a hook for hanging the hook or the like when moved by the crane.

Meanwhile, in the case of manufacturing another lower structure, the curved plate 20 having a predetermined length is fixed to the fixing plate 10. At this time, the second eye plate 22 is fixed to the curved plate 20 by welding. The fixed plate 10 maintains the roundness of the curved plate 20.

In addition, the curved plate 20 maintains the straightness of the curved plate 20 by hanging a wire 23 between the first eye plate 21 and the second eye plate 22. In this way it is possible to manufacture the lower structure while maintaining the roundness and straightness of the other lower structure.

As mentioned above, although the invention made by the present inventor was demonstrated concretely according to the said Example, this invention is not limited to the said Example and can be variously changed in the range which does not deviate from the summary.

10: fixed plate 11: gusset
12: surface plate 20: curved plate
21: first eye plate 22: second eye plate
23: wire 24: lever block
30: adjusting means 31: auxiliary pillar
32: Jack

Claims (11)

A pair of fixed plates formed to a certain height and width,
A curved plate fixed vertically between the pair of fixing plates,
And adjusting means supported to maintain the curved plate in a vertically fixed state,
A plurality of first eye plates fixed to an upper surface of the surface plate, a second eye plate fixed to an upper end of the curved plate, a wire fixed between the first eye plate and the second eye plate,
The wire is a roundness maintenance device of the large cylindrical structure for offshore structure, characterized in that the symmetrical fixation on the basis of the curved plate. The method of claim 1,
The fixing plate is made of an arc shape having a predetermined length,
Roundness maintenance device of a large cylindrical structure for offshore structures, characterized in that provided with a reinforcing plate for supporting the fixed plate. delete delete The method of claim 1,
The wire is a roundness maintenance device of a large cylindrical structure for offshore structures, characterized in that the lever block for adjusting the length and tension of the wire is provided. The method of claim 1,
The adjusting means is an auxiliary post fixed vertically to the outside of the curved plate,
And a jack fixed to the auxiliary support to hold the curved plate vertically. (a) securing the fixing plate at an isometric angle,
(b) inserting a curved plate into the fixing plate;
(c) setting the roundness or straightness by adjusting the tension of the wire fixed to the curved plate;
(d) fixing the adjusting means to one surface of the curved plate,
(e) welding a large cylindrical structure for offshore structures, comprising the step of welding another curved plate adjacent to the curved plate. The method of claim 7, wherein
In the step (a), the fixing plate is made of a pair of arc-shaped with a predetermined length,
And a step of stably supporting the fixing plate by fixing a reinforcement plate to one surface of each of the pair of fixing plates. The method of claim 7, wherein
In the step (c), (c1) fixing the first eye plate on the surface plate,
(c2) fixing the second eye plate to the top of the curved plate,
(c3) binding a wire provided with a lever block between the first eye plate and the second eye plate,
and (c4) adjusting the length and tension of the wire so that the curved plate is vertically maintained. The method of claim 9,
After the (c4), the curved plate is a manufacturing method of a large cylindrical structure for offshore structures, characterized in that it is maintained in a vertical state by adjusting the tension of the wire. The method of claim 7, wherein
In the step (d), the adjusting means for fixing the auxiliary strut having a predetermined length vertically,
Fixing a jack for supporting the curved plate on one surface of the auxiliary support, characterized in that for manufacturing a large cylindrical structure for offshore structures.

Images