KR20150024204A - Roundness Maintaining Device of Large Cylindrical Structure and Manufacturing Method Thereof - Google Patents

Abstract

The present invention relates to a device for maintaining roundness of a large cylindrical structure for offshore structures, comprising: a pair of fixating plates having predetermined height and width; a curved plate vertically fixated to a space between the pair of fixating plates; and an adjustment unit for adjusting the roundness of the curved plate. Therefore, the device for maintaining roundness of a large cylindrical structure for offshore structures can maintain the roundness of a large cylindrical structure having a large diameter using the curved plate and the multiple fixating plates fixated at a regular angle; can maintain the roundness of a large cylindrical structure using the curved plate; and has a light body by simplifying the structure.

Description

Technical Field [0001] The present invention relates to a device for maintaining the roundness of a large cylindrical structure for an offshore structure,

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

In general, an offshore structure refers to structures installed on the sea or under the sea, and is mainly used for exploration and extraction of energy sources such as oil and natural gas.

These offshore structures include fixed platforms, complaint piled towers, semi-submersible type platforms, TLP (Tension leg platforms), spar platforms (marine structures) And ocean structures (FPSO).

Minimizing this disturbance has emerged as an important challenge in many types of offshore structures, since these offshore structures can suffer considerable damage due to unexpected disturbances (eg, sea breezes, waves or ocean currents) .

For example, a ship-type offshore structure (referred to as 'floating oil production storage facility, FPSO') can be seen. These ship-type offshore structures are equipped with various turret constructions on the hull to rotate the bow angle in the approach direction of disturbance or to return to itself in order to minimize the influence from disturbance, so that damage caused by extreme disturbance have.

The turret, on the other hand, consists of an upper gantry, a lower gantry, a manifold, a collar structure, and a lower turret, And includes a bogie support structure.

It is very important to maintain the roundness and / or straightness of the large cylindrical structure constituting the view supporting structure, the diameter of which is approximately 22,000 mm and the height thereof is approximately 6,500 mm. The circularity of such a large cylindrical structure should be 22,000 mm in diameter and its tolerance should be kept within ± 5 mm.

1 is a cross-sectional view of a large cylindrical structure installed on an offshore structure. As shown in FIG. 1, the large cylindrical structure is installed as a part of the turret in the middle or at the bow of the offshore structure, so that the offshore structure is moored safely.

Such a large cylindrical structure is divided into a lower structure in which the adherent is not mounted on the outer surface and a superstructure in which the adherend is mounted on the outer surface.

2 is a view schematically showing a manufacturing process of a large cylindrical structure. As shown in Fig. 2A, the large-sized cylindrical structure makes the auxiliary assembly 1 in the shape of an arc. The auxiliary assembly 1 is formed into an arc shape having the same length by dividing the large-sized cylindrical structure at an equal angle.

As shown in FIG. 2B, a donut-shaped stringer 2 is fixed on a table (not shown), and then the welding operation is performed while maintaining the roundness of the auxiliary assembly 1. FIG. At this time, a ten-dimensional (ten) -shaped stiffener 3 is fixed to the upper surface of the stringer 2. The stiffener 3 is formed of a H-beam or a pipe and is fixed to maintain the roundness of each auxiliary assembly 1 when the auxiliary assembly 1 is assembled.

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

2d and 2e, a pre-fabricated auxiliary assembly 1 is welded to the upper surface of the circularly fixed auxiliary assembly 1, and at this time, the other auxiliary stiffeners 3 are fixed .

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

In the manufacturing of such a large-sized cylindrical structure as described above, it is difficult to work while maintaining the roundness at the position where the reinforcing material is not fixed, and the material is used more than necessary. After the large cylindrical structure is completed, There is a problem that the work is difficult and deformation of the welded portion occurs during the demolishing work of the stiffener.

For example, a 'turret device' is disclosed in Patent Document 1 below.

The turret device of Patent Document 1 described below includes an upper turret installed in a vertical opening formed through a hull and a lower turret coupled to a lower portion of the upper turret and provided with a lower bearing assembly rotatably supporting the hull. The lower bearing assembly is coupled to a lower bearing provided on an outer circumferential surface of the lower turret and an outer wall of a hull forming the vertical opening. And an independent sliding pad slidably in contact with the lower bearing, wherein the independent sliding pad has a plurality of slit plates formed with at least one slit.

Korean Patent Publication No. 10-2012-0097746 (published on September 5, 2012)

However, the outer turret structure of the conventional cylindrical structure according to the prior art has a problem in that it can not be applied to the fabrication of a large cylindrical structure although the slide pad is fixed to rotate smoothly.

An object of the present invention is to provide an apparatus for maintaining the roundness of a large-sized cylindrical structure for an offshore structure and a method of manufacturing the same, in which the roundness and / or the straightness are easily maintained when the large- .

Another object of the present invention is to provide an apparatus for maintaining the roundness of a large cylindrical structure for a marine structure and a method of manufacturing the same, which maintain the roundness and / or the straightness of the lower structure by using a lightened roundness maintaining apparatus.

In order to achieve the above object, the present invention provides a circularity maintaining apparatus for a large cylindrical structure for an offshore structure, comprising: a pair of fixed plates having a predetermined height and width; a curved plate vertically fixed between the pair of fixed plates; And an adjusting means supported so as to maintain the curved plate in a vertically fixed state.

The fixing plate is formed in an arc shape having a predetermined length and is provided with a reinforcing plate for supporting the fixing plate.

A plurality of first eye plates fixed to the upper surface of the base on which the fixing plate and the curved plate are fixed, a second eye plate fixed to the upper end of the curved plate, wires fixed between the first eye plate and the second eye plate, .

And the wire is fixed symmetrically with respect to the curved plate.

And the wire is provided with a lever block for adjusting the length and tension of the wire.

The adjusting means includes a auxiliary support vertically fixed to the outside of the curved plate, and a jack fixed to the auxiliary support and vertically holding the curved plate.

According to another aspect of the present invention, there is provided a method of manufacturing a large cylindrical structure for an offshore structure, comprising the steps of: (a) fixing a fixing plate at an equal angle; (b) inserting a curved plate into the fixing plate; (c) adjusting the tension of the wire fixed to the curved plate to set roundness or straightness, (d) fixing the adjusting means on one side of the curved plate, (e) And welding the plate.

In the step (a), the fixing plate may include a pair of circular arcs having a predetermined length, and fixing the reinforcing plate to one surface of each of the pair of fixing plates to stably support the fixing plate. do.

(C1) fixing the first eye plate to the base, (c2) fixing the second eye plate to the top of the curved plate, (c3) fixing the first eye plate to the second eye plate, (C4) adjusting the length and tension of the wire so that the curved plate is held vertically.

After the step (c4), the curved plate is held in a vertical state by adjusting the tension of the wire.

In the step (d), the adjusting unit includes vertically fixing the auxiliary struts having a predetermined length, and fixing the jack supporting the curved plate to one surface of the auxiliary strut.

As described above, according to the circularity maintaining apparatus for a large-sized cylindrical structure for an offshore structure according to the present invention, it is possible to maintain the roundness of a large-sized cylindrical structure having a large diameter by a plurality of fixed plates fixed at an equal angle, The straightness of the plate can be maintained, and the effect of being made simple and lighter can be obtained.

According to the method for manufacturing a large-sized cylindrical structure for an offshore structure according to the present invention, it is possible to manufacture the lower structure and to easily install the roundness maintaining device, so that the manufacturing cost is low and the roundness maintaining device can be reused, .

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

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, a circularity maintaining apparatus for 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.

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

The apparatus for maintaining the roundness of a large cylindrical structure for an offshore structure according to a preferred embodiment of the present invention includes a pair of fixed plates 10 formed with a predetermined height and width, a curved plate 20 fixed vertically between the fixed plates 10, And adjustment means (30) for adjusting the roundness and / or straightness of the plate (20).

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

As shown in FIGS. 3 to 5, the fixing plate 10 is a plate having a predetermined size, and is formed of arcs having a certain height and width and having a predetermined length when viewed in a plan view. The fixing plate 10 is provided in a pair to stably fix the curved plate 20.

4 and 5, the pair of fixing plates 10 are fixed at a distance corresponding to the thickness of the curved plate 20, and a reinforcing plate 11 for supporting the fixing plate 10 is formed on one surface of each fixing plate 10, . The fixing plate 10 and the reinforcing plate 11 are welded to the upper surface of the base 12.

On the other hand, since the lower structure of the large cylindrical structure also has a diameter of approximately 22,000 mm, the base 12 is a steel plate or a yard flat concrete which is horizontally fixed to a separate assembly site (also referred to as a shop) Face. That is, the base 12 is not made separately but uses a plurality of steel plates or yards of flat concrete floor fixed horizontally on the floor of the assembly floor.

The reinforcing plate 11 is formed in the shape of a letter 'A' so that one side is fixed to the base 12 and the other side is fixed to one side of the fixing plate 10. So that the fixing plate 10 is vertically and stably fixed by the reinforcing plate 11. [

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

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

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

The thicknesses of the fixed plate 10 and the curved plate 20 are respectively set to appropriate thicknesses. It is sufficient that the thickness of the fixing plate 10 is made thick enough to support the curved plate 20, and the curved plate 20 has a thickness that satisfies design conditions.

The curved plate 20 is sandwiched between a pair of spaced apart fixing plates 10. The curved plate 20 is sandwiched between the pair of fixing plates 10 to maintain the circularity and to be held in a vertically fixed state.

The curved plate 20 includes a first eye plate 21 fixed to the base 12, a second eye plate 22 fixed to the upper end of the curved plate 20, a first eye plate 21, And a wire (23) connected between the plates (22).

The first eye plate 21 is fixed to the table 12 and the second eye plate 22 is welded to the upper end of the curved plate 20. [ The first eye plate 21 can be fixed by welding to a predetermined position of the surface plate 12 or fixed to a circular pile or the like fixed with the first eye plate 21 and fixed in a buried state on the concrete floor surface.

 Between these eye plates 21 and 22, a wire 23 for holding 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. So that the curved plate 20 is held in a vertically fixed state. The wire 23 and the lever block 24 can vertically adjust the curved plate 20 when the curved plate 20 is not standing vertically.

The adjusting means 30 includes a auxiliary strut 31 fixed vertically and a jack 32 fixed to the auxiliary strut 31 and supporting the curved plate 20.

It is preferable that the auxiliary strut 31 is vertically fixed to the outside of the curved plate 20 and the auxiliary strut 30 uses a H-beam having strong stiffness. This is because the curved plate 20 must maintain sufficient strength to maintain a vertically fixed state.

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

Further, the jack 30 can use a screw jack or a hydraulic jack which can be adjusted in length.

As shown in Fig. 4, the fixing plate 10 and the adjusting means 30 are fixed at an angle of 15 DEG, 20 DEG and 30 DEG, respectively. This is to make it possible to more accurately maintain the roundness of the curved plate 20 during the assembling operation of the curved plate 20 and also to confirm the straightness of the curved plate 20 at more places.

The following is a detailed description of the engagement relationship of the roundness maintaining apparatus for a large cylindrical structure for an offshore structure according to a preferred embodiment of the present invention.

A pair of fixing plates 10 are fixed to the steel plate by welding or embedded in the concrete floor. At this time, a plurality of fixing plates 10 are arranged at equal angles of 15 °, 20 °, and 30 °, and are fixed in a round shape to maintain a predetermined diameter. That is, a plurality of the fixing plates 10 are arrayed and fixed so as to maintain the roundness.

Also, the fixing plate 10 is fixed by welding or embedded in the concrete floor so that the fixing plate 10 is held in a more firmly fixed state.

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

The first eye plate 21 is fixed to the base 12 by welding or embedding in positions symmetrical with respect to the base plate 10, respectively. A 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 confirms the straightness of the curved plate 20 in the state that the wire 23 is installed. The wire 23 vertically adjusts the length of the wire 23 to fix the curved plate 20 vertically if the curved plate 20 is fixed at an angle other than vertical. Therefore, the curved plate 20 is fixed while maintaining roundness and straightness.

In addition, the adjusting means 30 is fixed to the outside of the curved plate 20. The auxiliary struts 31 of the adjustment means 30 are fixed perpendicular to the table 12 and the auxiliary struts 31 are fixed to a weld or a foundation. On one side of the auxiliary strut 31, the jack 32 is fixed by welding in advance.

On the other hand, the jack 32 is brought into close contact with the curved plate 20 to prevent deformation or warping of the curved plate 20. Accordingly, even if there is warping or deformation, the curved plate 20 can maintain the vertical roundness by the fixing plate 10 and the straightness by the jack 32.

6, a method of manufacturing a large-sized cylindrical structure for an offshore structure according to a preferred embodiment of the present invention will be described in detail.

FIG. 6 is a process diagram for explaining steps of a method for manufacturing a large-sized cylindrical structure for an offshore structure 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 equal angle of 15 °, 20 °, or 30 ° (S10). The pair of fixing plates 10 are fixed apart by the thickness of the curved plate 20, and these fixing plates 10 are formed in an arc shape having a predetermined length.

That is, the fixing plate 10 is fixed so as to maintain the same amplitude as the diameter of the lower structure. The reinforcing plate 11 is welded or embedded in the outer surface of the fixing plate 10 to reinforce the strength of the fixing plate 10.

Each of the fixing plates 10 is fixed by sandwiching the curved plate 20 therebetween (S20). The first eye plate 21 is fixed to the base 12 at symmetrical positions with respect to the fixing plate 10 and the second eye plate 22 is fixed to the upper end of the curved plate 20.

While the curved plate 20 can be fixed with the second eye plate 22 fixed in advance,

Further, a 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 and the straightness of the curved plate 20 is adjusted by controlling the length or tension of the wire 23 by the lever block 24 (S30).

Thus, the curved plate 20 is fixed vertically by adjusting the length of the wire 23, so that the curved plate 20 is adjusted to have a vertical straightness. The straightness of the curved plate 20 increases or decreases the length of the wire 23 symmetrically connected to each other to adjust the length or tension of the wire 23. If the curved plate 20 is not vertically fixed, the curved plate 20 can be vertically adjusted.

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

The auxiliary strut (31) uses H-shaped steel having high strength so as to maintain a state of being vertically fixed to external force. Further, the jack 32 uses a screw jack or a hydraulic jack for adjusting the length.

When the installation of the circularity maintaining device of the fixing plate 10 and the adjusting means 30 is completed as described above, the roundness and vertical roundness of the curved plate 20 can be confirmed since the circularity is fixed when viewed in plan.

On the other hand, when the curved plate 1 is not fixed in the vertical straight line, the jack 32 installed on one side of the curved plate 20 is adjusted to press the curved plate 20. That is, the jack 32 presses the curved plate 20.

Since the curved plate 20 is fixed to each other by welding while maintaining the roundness and straightness of the curved plate 20, the curved plate 20 is assembled while maintaining the roundness and straightness of the large-diameter lower structure (S50).

The constructed substructure is moved by a crane or the like. For this purpose, the wire 23 is released from the second eye plate 22. The lower structure is moved by hooking a crane hook or the like to the second eye plate 22.

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

On the other hand, when another lower structure is manufactured, the curved plate 20, which is made to have a predetermined length, is fixed to the fixing plate 10. At this time, the second eye plate 22 is welded together with the curved plate 20. The fixing plate 10 maintains the roundness of the curved plate 20.

Further, the curved plate 20 holds the wire 23 between the first eye plate 21 and the second eye plate 22 to maintain the straightness of the curved plate 20. In this manner, the lower structure can be manufactured while maintaining the roundness and the straightness of the other lower structure.

Although the present invention has been described in detail with reference to the above embodiments, it is needless to say that the present invention is not limited to the above-described embodiments, and various modifications may be made without departing from the spirit of the present invention.

10: fixing plate 11: reinforcing plate
12: Plate 20: Curved plate
21: first eye plate 22: second eye plate
23: wire 24: lever block
30: adjusting means 31: auxiliary holding
32: Jack

Claims (11)

A pair of fixed plates formed with a predetermined height and width,
A curved plate vertically fixed between the pair of fixed plates,
Wherein the curved plate is supported so as to maintain the curved plate in a vertically fixed state. The method according to claim 1,
Wherein the fixing plate is formed in an arc shape having a predetermined length,
And a reinforcing plate for supporting the fixing plate is provided on the inner surface of the large cylindrical structure. The method according to claim 1,
A plurality of first eye plates fixed to the upper surface of the base,
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. The method of claim 3,
Wherein the wire is fixed symmetrically with respect to the curved plate. ≪ RTI ID = 0.0 > 8. < / RTI > The method of claim 3,
Wherein the wire is provided with a lever block for adjusting the length and tension of the wire. The method according to claim 1,
Wherein the adjusting means comprises an auxiliary support vertically fixed to the outside of the curved plate,
And a jack fixed to the auxiliary strut and vertically holding the curved plate. (a) fixing the fixing plate at a constant angle,
(b) fitting a curved plate into the stationary plate,
(c) adjusting the tension of the wire fixed to the curved plate to set roundness or straightness,
(d) fixing the adjusting means on one side of the curved plate,
(e) welding a curved plate adjacent to the curved plate to another curved plate adjacent to the curved plate. 8. The method of claim 7,
In the step (a), the fixing plate has a pair of circular arcs of a predetermined length,
And fixing the reinforcing plate to one surface of each of the pair of fixing plates to stably support the fixing plate. 8. The method of claim 7,
In the step (c), (c1) fixing the first eye plate to the base,
(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,
(c4) adjusting the length and tension of the wire so that the curved plate is held vertically. 10. The method of claim 9,
Wherein the curved plate is maintained in a vertical state by adjusting the tension of the wire after the step (c4). 8. The method of claim 7,
In the step (d), the adjusting means vertically fixes the auxiliary support having a predetermined length,
And fixing a jack supporting the curved plate to one surface of the auxiliary strut. ≪ RTI ID = 0.0 > 21. < / RTI >

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