KR20150111653A - umbilical cable for deep sea - Google Patents

Abstract

A deep sea umbilical cable is disclosed. The deep sea umbilical cable according to the present invention can prevent the depression phenomenon by increasing the resistance ability and the internal supporting force of the umbilical cable to a high hydrostatic pressure and the filler and other lines are in surface contact inside the umbilical cable Structural stability can be achieved through design changes that can be made.

Description

Umbilical cable for deep sea}

The present invention relates to a deep sea umbilical cable, and more particularly, to a deep sea umbilical cable, which is capable of preventing the deep water from having a high hydrostatic pressure resistance and an internal supporting force to prevent a depression phenomenon, In the case of a cable,

Due to the recent increase in energy demand in emerging economies and the depletion of land resources, energy shortage and high oil prices are continuing and exploration of deep-sea oil fields and seabed resources is becoming more and more active. In this context, the demand for umbilical cables, marine engineering cables, is also increasing.

'Umbilical' implies the umbilical cord, which is why Umbilical Cable plays a vital role in marine engineering.

Generally, umbilical cable is used as the name of composite cable used in marine engineering. It is mainly divided into geological exploration, oil drilling, and ROV. It is connected to submarine equipment to supply or control the equipment, Lt; / RTI > signal.

These umbilical cables must have the stability to function effectively in complex environments such as hydrostatic pressure, algae, and waves in the deep sea, structural design technology to ensure load balance by vertical installation, data analysis and manufacturing technology Development and production are possible.

Especially, in case of deep sea, very high hydrostatic pressure occurs, for example, at 200,000m depth and 200 times of atmospheric pressure. Such high pressure causes a problem of circular maintenance of umbilical cable.

Although the umbilical cable is designed to have a resistance to hydrostatic pressure by implementing a wet condition, it is difficult to implement a complete wet condition because it is placed over a very long area in the sea area many.

In addition, since there are many pores in the inner structure of the umbilical cable, a collapse phenomenon due to high hydrostatic pressure may occur when a complete wet condition is not implemented.

1 is a cross-sectional view of a conventional deep sea umbilical cable 1 in which a core 20 having three signal lines 21 is positioned at a central portion do. The signal line 21 has a three-pair structure including a pair of signal lines 21a in which seven core wires 21b are connected to each other and a center pillar 20a is provided at a center portion adjacent to the three signal lines.

The voids in the core 20 are filled with a PE (polyethyene) filled extruded layer 24 so as to simultaneously perform a role of armor bedding while maintaining a compact shape and high roundness.

A core armature 25 is provided on the outer side of the core armature 25 to protect the inside of the core 20 and enhance the tensile strength. A core sheath 26 may be provided outside the core armor 25.

A fluid transmission line including a hydraulic line 11 and a chemical line 12 is provided outside the core 20 and an outer armor 15 and an outer sheath 16 Are provided to protect the internal structure.

However, in order to prevent the depression phenomenon described above, a circular string filler 13 is inserted into the deep sea umbilical cable 1. In the string filler 13, There is a problem in that it is structurally unstable because it is in line contact with the core 20 and the fluid transmission line inside the deep sea umbilical cable 1 and is vulnerable to depression at the above-mentioned high hydrostatic pressure.

Therefore, by solving the above problems, it is possible to prevent the depression phenomenon by increasing the resistance ability against the high hydrostatic pressure of the deep water and the inner supporting force, to improve the circular holding force, to improve the structural stability, The need for curled cables is emerging.

Embodiments of the present invention increase the resistance of the umbilical cable to high hydrostatic pressure in deep water and the internal bearing capacity to prevent the depression phenomenon.

In addition, the filler and other lines inside the umbilical cable increase the contact area through design changes to achieve surface contact, thereby achieving circularity and maintaining structural stability even in the absence of a complete wet condition.

According to an aspect of the present invention, there is provided a method of manufacturing a semiconductor device, comprising: a core including at least one signal line; at least one hydraulic line provided around the core for transmitting fluid and transmitting oil for hydraulic operation; A plurality of fluid transmission lines disposed between the core and the fluid transmission line and in contact with the core and the fluid transmission line, wherein the core and the fluid transmission line correspond to an outer circumferential surface of the core, There is provided a deep sea umbilical cable including at least one filler having an inner peripheral surface formed in surface contact with the core.

The filler may be provided such that an inner circumferential surface contacting the core is in surface contact with the core and an outer circumferential surface contacting the hydraulic line is in line contact with the hydraulic line.

The filler may be configured such that a length of an arc formed by an outer circumferential surface contacting the hydraulic line is longer than a length of an arc formed by an inner circumferential surface contacting the core.

The filler may be formed to have a constant thickness in the radial direction of the cable.

The filler may be provided in surface contact with the hydraulic line.

The deep sea umbilical cable according to the present invention may further include an inner sheath which is provided outside the hydraulic transmission line and absorbs an external shock to protect the inner core and the fluid transmission line.

The deep sea umbilical cable according to the present invention may further include an outer armor having a double structure provided on the outer side of the inner sheath to protect the inner structure and reinforce the tensile strength.

The deep sea umbilical cable according to the present invention is further provided on the outer side of the outer armor and further comprises an outer sheath for protecting the inside from external impact or corrosion.

Embodiments of the present invention can prevent the depression phenomenon by increasing the resistance capability and the internal supporting force of the umbilical cable against the high hydrostatic pressure of the deep sea.

In addition, by changing the design of the filler and other lines within the umbilical cable, the contact area can be increased by making design changes, thereby enabling circularity maintenance and achieving structural stability even without a complete wet condition.

1 is a cross-sectional view of a conventional deep sea umbilical cable
2 is a cross-sectional view of a deep sea umbilical cable according to an embodiment of the present invention;
3 is a perspective view of a deep sea umbilical cable according to an embodiment of the present invention;
4 is a cross-sectional view of a deep sea umbilical cable according to another embodiment of the present invention

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein but may be embodied in other forms. Rather, the embodiments disclosed herein are provided so that the disclosure can be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Like reference numerals designate like elements throughout the specification.

FIG. 2 is a sectional view of a deep sea umbilical cable according to an embodiment of the present invention, FIG. 3 is a perspective view of a deep sea umbilical cable according to an embodiment of the present invention, and FIG. Sectional view of a deep sea umbilical cable according to an example.

2 to 4, a deep sea umbilical cable 1000 according to an embodiment of the present invention includes a core 200 including at least one signal line 210, And a filler 130 disposed between the core 200 and the fluid transmission line. The fluid transmission line may include a plurality of fluid transmission lines provided around the core 200 and transmitting fluid, and a filler 130 provided between the core 200 and the fluid transmission line.

The core 200 is provided with three signal lines 210 in the present embodiment as an electric cable, and can transmit a control signal to a drilling rig installed on the seabed. The signal line 210 may have a three-pair structure including a pair of signal lines 212 in which seven core wires 214 are twisted.

The center pillar 201 is provided at the center of the core 200 and the three signal lines 210 are arranged symmetrically with respect to the center pillar 201.

The voids in the core 200 are filled with a PE (polyethyene) filled extruded layer 24 so as to simultaneously perform a role of armor bedding while maintaining a compact shape and high roundness.

A core armature 250 is provided outside the PE faithful extrusion layer 240 to protect the inside of the core 200 and to reinforce tensile strength and a core sheath 260 outside the core armor 250 .

Meanwhile, the PE filled extrusion layer 240 may be replaced with a double tube extruded layer having a polyvinyl chloride (PVC) layer on the inside and a high density polyethylene (HDPE) layer on the outside. In this case, ) And the double tube extruded layer can be filled with a string filler and a yarn.

A plurality of fluid transmission lines are disposed around the core 200. The fluid transmission lines include at least one hydraulic line 110 for transferring oil for hydraulic operation and a chemical transfer agent for lowering the viscosity of the crude oil At least one chemical line (120).

The hydraulic line 110 forms a passage through which oil flows so as to transmit hydraulic pressure to a hydraulic driving apparatus such as a hydraulic cylinder. The hydraulic line 110 may be made of a nylon material on the inner side and an aramid yarn yarn on the inner side of the hydraulic line 110. The outermost layer may be made of a polyurethane material.

The hydraulic lines 110 may be grouped into three groups of three around the core 200. The chemical lines 120 may be disposed between the three sets of the hydraulic lines 110 to form a total of three chemical lines 120 may be disposed.

The chemical line 120 injects crude oil, that is, crude oil, to transfer the compound to lower the viscosity. As the compound to be sprayed onto the crude oil, glycol alcohol can be used, for example.

Inside the chemical line 120, a carcass structure made of stainless steel is formed so as to withstand the hydrostatic pressure and maintain flexibility, and a nylon material is formed on the carcass structure. Then, it may be made so that the braid sphere of the aramid yarn surrounds it. And the outermost side may be made of nylon, which can be perforated for the aeration of the transferred chemical.

The number, size, and arrangement of the fluid transmission lines including the hydraulic line 110 and the chemical line 120 are not limited to the examples shown in FIGS. 2 to 4, and may be variously modified according to the needs of the user .

Meanwhile, a filler 130 may be provided between the core 200 and the fluid transmission line to provide surface contact with at least one of the core 200 and the fluid transmission line.

As described above, conventionally, a circular string filler is disposed inside an umbilical cable. Since such a string filler is in line contact with other lines, it is structurally unstable and is vulnerable to depression at high hydrostatic pressure There was a problem.

Alternatively, the filler 130 applied to the deepwater ebullient cable 1000 according to the present invention may have a surface contact with at least one of the core 200 and the fluid transmission line, thereby enhancing the internal supporting force and improving the structural stability. have.

Specifically, the filler 130 is provided between the core 200 and the fluid transmission line and is in contact with the core 200 and the fluid transmission line, and has an inner circumferential surface corresponding to the outer circumferential surface of the core 200, And may be configured to make surface contact with the core 200.

As shown in FIGS. 2 and 3, in the present embodiment, the filler 130 has a shape in surface contact with the core 200. That is, the filler 130 has a shape in which the inner circumferential side corresponds to the outer circumferential surface of the core 200, and is in surface contact with a part of the outer circumferential surface of the core 200.

Three pillars 130 are provided between the core 200 and the hydraulic line 110. The specific number, size, and arrangement of the pillars 130 may be modified as needed.

At this time, the inner circumferential surface of the filler 130 contacting the core 200 is in surface contact with the core 200, while the outer circumferential surface contacting the hydraulic line 110 is in line contact with the hydraulic line.

2 and 3, the length of the arc formed by the outer circumferential surface contacting the hydraulic line 110 is longer than the length of the arc formed by the inner circumferential surface contacting the core 200, .

By arranging the surface contact pillar 130 as described above, the collapse resistance of the deepwater ebullient cable 1000 can be improved and the contact area between the core and the fluid transmission line can be increased to improve the structural stability have.

In addition, the use of the surface contact filler 130 makes it possible to reduce the generation of a cavity, increase the resistance to high hydrostatic pressure, and to maintain the roundness even if the wet condition is not completely achieved in the deep sea.

Meanwhile, according to another embodiment of the present invention, as shown in FIG. 4, the filler 130 'may be configured to make surface contact with the hydraulic line 110. In this embodiment, the filler 130 'has a shape in surface contact with the hydraulic line 110. That is, the outer surface of the filler 130 'has a shape corresponding to the outer circumferential surface of the hydraulic line 110 and is in surface contact with a part of the outer circumferential surface of the hydraulic line 110.

In this embodiment, one filler 130 'is brought into contact with the three hydraulic lines 110, so that the portion of the filler 130' contacting the respective hydraulic lines 110 is formed into a surface contact- .

In this embodiment, the filler 130 'has a surface contact with both the core 200 and the hydraulic line 110. However, as in the previous embodiment, the filler 130' But it is also possible to constitute only a fluid contact with the fluid transmission line such as the hydraulic line 110 or the chemical line 120.

It should be understood that the specific shape of the filler 130 can be variously modified depending on the number, size, shape, and arrangement of the core 200 and the fluid transmission lines.

The inner sheath 140 may be provided outside the fluid transmission line including the hydraulic line 110 and the chemical line 120. The inner sheath 140 serves to protect the core 200 and the fluid transmission line therein by absorbing an external impact, and thermoplastic and thermosetting raw materials such as PVC, PE, and PU can be used.

An outer armor 150 may be provided outside the inner sheath 140. In the present embodiment, the outer armor 150 has a double structure, and can protect the inner structure and enhance the tensile strength of the deep sea umbilical cable 1000.

The outer sheath 160 may be provided outside the outer armor 150. The outer sheath 160 is provided at the outermost portion of the deepwater ocularial cable 1000 to protect the deepwater ocularial cable 1000 from external impact or corrosion. The outer sheath 160 may be made of a raw material such as HDPE having excellent abrasion resistance, corrosion resistance, and UV protection.

The deep sea umbilical cable according to the embodiments of the present invention described above can prevent the depression phenomenon by increasing the resistance capability and the internal supporting force of the umbilical cable to a high hydrostatic pressure and can prevent the filler By increasing the contact area through design changes that other lines can make face contact, it is possible to maintain circularity even without a perfect wet condition, and structural stability can be achieved.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined in the appended claims. You can do it. It is therefore to be understood that the modified embodiments are included in the technical scope of the present invention if they basically include elements of the claims of the present invention.

1000: Deep sea umbilical cable 20: Core
110: Hydraulic line 120: Chemical line
130: filler 140: inner sheath
150: Outer Armor 160: Outer Sheath

Claims (8)

A core comprising at least one signal line;
A plurality of fluids comprising at least one hydraulic line provided around the core for transferring fluids and transferring oil for hydraulic operation and at least one chemical line for transferring chemicals sprayed to lower the viscosity of the crude oil, Transmission lines; And
And at least one filler disposed between the core and the fluid transmission line and in contact with the core and the fluid transmission line, the inner periphery corresponding to the outer circumferential surface of the core forming a surface contact with the core, Curl cable. The method according to claim 1,
The filler
Wherein the inner circumferential surface contacting the core is in surface contact with the core and the outer circumferential surface contacting the hydraulic line is in line contact with the hydraulic line. 3. The method of claim 2,
The filler
Wherein a length of an arc formed by an outer circumferential surface contacting the hydraulic line is longer than a length of an arc formed by an inner circumferential surface contacting the core. The method of claim 3,
Wherein the filler is formed to have a constant thickness in the radial direction of the cable. The method according to claim 1,
Wherein the filler is in surface contact with the hydraulic line. 6. The method according to any one of claims 1 to 5,
And an inner sheath provided outside the hydraulic transmission line and absorbing an external shock to protect the inner core and the fluid transmission line. The method according to claim 6,
Further comprising an outer armor of a double structure provided outside the inner sheath to protect the inner structure and to reinforce the tensile strength. 8. The method of claim 7,
Further comprising an outer sheath disposed on the outer side of the outer armor for protecting the inside from external impact or corrosion.

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