KR20230031866A - umbilical cable for deep sea - Google Patents

Abstract

An umbilical cable for a deep sea is disclosed. According to the present invention, an umbilical cable for a deep sea has a structure such that it is possible to effectively respond to the hydrostatic pressure of the deep sea by increasing the adhesion of the wire rods inside the core, it is possible to prevent sinking by increasing the resistance capacity and internal bearing capacity of the umbilical cable against the high hydrostatic pressure of the deep sea, and it is possible to improve the ability to maintain an original shape.

Description

Umbilical cable for deep sea

The present invention relates to an umbilical cable for deep sea use, and more particularly, a center support member can be effectively seated inside a core, and when the core is united, the union can be smoothly achieved by overcoming the difference in stiffness between the lines. It relates to a deep-sea umbilical cable that can prevent sinking by increasing resistance to high hydrostatic pressure and internal bearing capacity, and can increase circular retention.

Recently, as energy shortages and high oil prices continue due to the increase in energy demand in rapidly growing emerging countries and the depletion of land resources, exploration of deep-sea oil fields and subsea resources is becoming increasingly active. Against this backdrop, demand for umbilical cables, which are cables for marine engineering, is also gradually increasing.

‘Umbilical’ implies an umbilical cord, and umbilical cables play a diverse and important role in the field of marine engineering.

In general, umbilical cables are used as a common name for composite cables used in offshore engineering, and are largely divided into geological exploration, oil drilling, and ROV, and are connected to offshore equipment to supply power to or control equipment and monitor equipment. plays a role in transmitting the signal of

These umbilical cables must have the stability to function effectively in complex environments such as high hydrostatic pressure, currents and waves in the deep sea, structural design technology to withstand and balance the load caused by vertical laying, and data analysis and manufacturing technology. can be developed and produced.

In particular, in the case of deep sea, very high hydrostatic pressure, such as 200 times the atmospheric pressure at a depth of 2,000 m, for example, arises.

Umbilical cables are designed to have resistance to hydrostatic pressure by realizing a wet condition with a structure that allows seawater to permeate from the seabed, but it is difficult to implement a perfect wet condition because they are deployed over a very long area in the actual sea area. many.

In addition, since there are many air gaps in the internal structure of the umbilical cable, a collapse phenomenon due to high hydrostatic pressure may occur in a state where a completely wet condition is not implemented.

Referring to an example of an existing umbilical cable through drawings, FIG. 1 is a cross-sectional view of a conventional deep-sea umbilical cable 1, in which a core 10 having three inner tubes 12 is located at the center thereof. Located. Also, four signal lines 22 are provided outside the core 10 .

The inner tube 12 functions by being divided into a hydraulic line and a chemical line, and the signal line 22 has a quad structure having four signal lines in which a plurality of core wires are twisted.

Various types of fillers are provided to fill the voids on the outside and inside of the core 10, and the center support 14 is combined with the inner tube 12 at the center of the core 10.

However, since the conventional deep-sea umbilical cable 1 as described above does not come into close contact with the inner tube 12 between the central support 14 and the peripheral components, in particular, an air gap occurs, so that the bearing capacity against the high hydrostatic pressure described above is weakened. there is a problem.

In addition, since the signal line 22 is disposed outside the core 10, the bending stress applied to the signal line 22 in a harsh bending environment is large, so that the signal line included in the signal line 22 may be disconnected. There are possible problems.

In addition, by applying various types of fillers, material costs and processing costs increase, and there is a burden of providing various facilities.

In addition, when the core 10 is united, when there is a difference in stiffness between the line materials constituting the core 10, the line having a relatively small stiffness may not take its place during the association process and may depart, so that the association is not well achieved and adherence to each other is not achieved. If it does not work well, the shape may be broken and the roundness may not be maintained.

Therefore, by solving the above problems, the central support can be effectively seated inside the core, and when the core is united, the union can be smoothly achieved by overcoming the difference in stiffness between the lines, and the ability to resist the high hydrostatic pressure of the deep sea and the internal bearing capacity The need for a deep-sea umbilical cable that can prevent sinking and increase circular retention by increasing the

Embodiments of the present invention are intended to effectively seat the central support inside the core by closely contacting other components inside the core.

In addition, it is intended to provide a structure in which the union can be smoothly achieved by overcoming the difference in stiffness between the lines when the core is united.

In addition, it is intended to effectively respond to the hydrostatic pressure of the deep sea by increasing the adhesion of the inner lines of the core.

In addition, it is intended to prevent sinking by increasing the resistance capacity and internal bearing capacity of the umbilical cable against the high hydrostatic pressure of the deep sea, and to increase the original retaining power.

In addition, it is intended to ensure stable signal transmission by minimizing bending stress even in a harsh bending environment by arranging a signal line with relatively low rigidity as a core as much as possible.

According to one aspect of the present invention, a core including at least one signal line and a fluid transmission line, and a central support located in the center of the core and contacting and supporting the signal line and the fluid transmission line, the central support comprising the above A center portion located at the center of the core, and a plurality of extension portions extending from the center portion between the signal line and the fluid transmission line, and between a length R from the center of the core to an end of the extension portion and a combined outer diameter D of the core. A deep-sea umbilical cable can be provided, characterized in that the relationship of R ≥ α × tan (β / D) × D, α = 0.7, β = 0.64 is established.

A curvature formed by the central portion and the plurality of extensions may be identical to that of a signal line or a fluid transmission line in contact with each other.

According to another aspect of the present invention, a core including at least one signal line and a fluid transmission line, a central part located at the center of the core, and a plurality of extensions extending from the central part between the signal line and the fluid transmission line And a central support, wherein the central support comprises a first seating part for surrounding and supporting at least a part of the signal line, and a second seating part for surrounding and supporting at least a part of the fluid transmission line. An umbilical cable may be provided.

The first seating part may be formed between any two adjacent extension parts among the plurality of extension parts, and may be formed stepwise with respect to the two extension parts so as to cover at least a part of the signal line.

The second seat portion may be formed between any two adjacent extension portions among the plurality of extension portions, and may be formed stepwise with respect to the two extension portions so as to cover at least a portion of the fluid transmission line.

The length of the groove formed by the first seating part may be longer than the length of the groove formed by the second seating part.

According to another aspect of the present invention, a core having two types of lines having different bending stiffness, and a central support located in the center of the core and contacting and supporting the two types of lines, The central support may be provided with a deep-sea umbilical cable, characterized in that it has a central portion located at the center of the core and a plurality of extensions extending from the central portion between the signal line and the fluid transmission line.

The difference in bending strength between the two types of lines may be 5 times or more.

The deep-sea umbilical cable according to the present invention may further include a filler that is filled to fill the void inside the core to relieve external shock.

The deep-sea umbilical cable according to the present invention is provided outside the core and further includes a core sheath surrounding the core to maintain the shape of the core, and the plurality of extension parts may extend to the core sheath.

The deep-sea umbilical cable according to the present invention may further include a plurality of fluid transmission lines disposed outside the core sheath.

The deep-sea umbilical cable according to the present invention may further include a plurality of pillars disposed between a plurality of fluid transmission lines disposed outside the core sheath.

The deep-sea umbilical cable according to the present invention may further include an inner sheath provided outside the plurality of fluid transmission lines and absorbing 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 a double-structured outer armor provided outside the inner sheath to protect the inner structure and reinforce tensile strength.

The deep-sea umbilical cable according to the present invention may further include an outer sheath provided outside the outer armor and protecting the inside from external impact or corrosion.

Embodiments of the present invention can effectively seat the central support inside the core by closely contacting other components inside the core.

In addition, it is possible to provide a structure in which the union can be smoothly achieved by overcoming the difference in stiffness between the lines during core union.

In addition, it is possible to effectively respond to the hydrostatic pressure of the deep sea by increasing the adhesion of the inner lines of the core.

In addition, it is possible to prevent a sinking phenomenon by increasing the resistance capacity and internal bearing capacity of the umbilical cable against high hydrostatic pressure in the deep sea, and to increase the original retaining force.

In addition, by arranging a signal line with relatively low rigidity as much as possible in a core, it is possible to perform stable signal transmission by minimizing bending stress even in a severe bending environment.

1 is a cross-sectional view of a conventional deep sea umbilical cable
2 is a cross-sectional view of an umbilical cable for deep sea according to an embodiment of the present invention
3 is a perspective view of an umbilical cable for deep sea according to an embodiment of the present invention
4 is a cross-sectional view showing a core union structure of an umbilical cable for deep sea according to an embodiment of the present invention.
5 is a configuration diagram showing a point where a twist of a central support member occurs when the cores of an umbilical cable for deep sea according to an embodiment of the present invention are united.
6 is a cross-sectional view of an umbilical cable for deep sea according to another embodiment of the present invention
7 is a perspective view of an umbilical cable for deep sea according to another embodiment of the present invention
8 is a cross-sectional view showing a center support structure according to another embodiment of the present invention
Figure 9 is a cross-sectional view showing a center support structure 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 and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosed content will be thorough and complete, and the spirit of the present invention will be sufficiently conveyed to those skilled in the art. Like reference numbers indicate like elements throughout the specification.

2 is a cross-sectional view of an umbilical cable for deep sea use according to an embodiment of the present invention, FIG. 3 is a perspective view of an umbilical cable for deep sea use according to an embodiment of the present invention, and FIG. 4 is an embodiment of the present invention. It is a cross-sectional view showing the core union structure of the deep sea umbilical cable according to the example. 5 is a configuration diagram showing a point where a twist of a central support member occurs when the cores of an umbilical cable for deep sea according to an embodiment of the present invention are united.

2 to 5, a deep sea umbilical cable 1000 according to an embodiment of the present invention includes a core including at least one signal line 210 and fluid transmission lines 110 and 120. 200 and a center support 220 located at the center of the core 200 and contacting and supporting the signal line 210 and the fluid transmission lines 110 and 120.

In this embodiment, the core 200 is provided with two signal lines 210 to serve as an electric cable for transmitting a control signal to the drilling equipment provided on the seabed, while the two fluid transmission lines 110 and 120 ) is further included.

In this way, if the signal line 210 having relatively low rigidity is disposed as a core as much as possible, the bending stress applied to the signal line is minimized even in a severe bending environment, and stable signal transmission is possible.

Here, the fluid transmission lines 110 and 120 located inside the core 200 may be formed of a chemical line 120 that transmits a chemical injected to lower the viscosity of crude oil. The chemical line 120 serves to transmit chemicals to reduce viscosity by spraying crude oil, that is, crude oil. For example, ethylene glycol or alcohol may be used as a chemical that is transferred to be injected into crude oil.

The chemical line 120 is made of a steel tube, and the two chemical lines 120 may have the same outer diameter. Meanwhile, the steel tube may be a tube made of Super Duplex Stainless Steel (SDSS).

The signal line 210 may have a quad structure including four signal lines 212 in which a plurality of core wires 214 are twisted. Insulation of the signal lines 212 may be made of XLPE (Cross Linking-Polyethylene) material.

The four signal lines 212 may be combined by surrounding the outside of the combined beading 213. The combined bedding 213 may be made of HDPE (High Density Polyethylene) having excellent abrasion resistance, corrosion resistance, and UV protection.

A shielding layer 215 made of copper is formed outside the combined bedding 213 to serve as a shield for smooth signal transmission of the signal line 212 .

A signal line inner sheath 216, a signal line armor 217, and a signal line outer sheath 218 may be sequentially formed outside the shielding layer 215. Here, the signal line inner sheath 216 and the signal line outer sheath 218 may be made of the same HDPE material as the combined bedding 213.

A center support 220 is provided at the center of the core 200, and the two signal lines 210 and the two chemical lines 120 are symmetrically arranged around the center support 220.

The central support 220 is located in the center of the core 200 and serves to contact and support the signal line 210 and the fluid transmission lines 110 and 120 . The central support body 220 includes a center portion 222 located at the center of the core 200, and a plurality of extension portions 224 extending from the center portion 222 between the signal line 210 and the chemical line 120. ) can be provided.

In this embodiment, four extension parts 224 are provided, and one signal line 210 or chemical line 120 is disposed between each extension part 224 . Specifically, the two signal lines 210 are disposed at symmetrical positions with respect to the central portion 222, and the two chemical lines 120 are also disposed at symmetrical positions with respect to the central portion 222. can be placed.

Here, the central support 220, the signal line 210, and the chemical line 120 undergo an association process while passing through dies.

At this time, in order to overcome the difference in stiffness between the signal line 210 and the chemical line 120 made of a steel tube, the center support 220 guides the signal line 210 and the chemical line 120 so that they are well seated while in close contact. It is necessary to determine the length of the extension part 224 of the support member 220, that is, the radius of the central support member 220 to an appropriate value.

Referring to the specific details with reference to Figures 4 and 5, first, A is the twist occurrence point of the center support 220, a ₁ is the distance from the end of the die (die) on the union center line to the point A, a ₂ is It is the vertical distance between point A and the center line of the signal line 210. The design variables including the aforementioned variables are summarized as follows.

* Point A: The twisting point of the central support

* a ₁ : Distance from the end of the dies on the union center line to point A

* a ₂ : Vertical distance between point A and the center line of the signal line

* R: Central support radius (length from the center of the core to the end of the extension)

* t: minimum thickness of extension

* a: Cross-section design variable Distance between fluid transmission lines

* b: Distance between cross-sectional design variable signal lines

* d _S : outer diameter of signal line

* d _T : outer diameter of fluid transmission line

In order to overcome the difference in stiffness between the signal line 210 and the fluid transmission line 120 made of a steel tube and to facilitate the union, the radius R of the central support 220 is set to be greater than or equal to the a ₂ value measured at Point A. It is desirable to form

The point A is a point where each line is seated by the center support 220 as a result of confirmation in the actual joint work process. By defining (R≥a ₂ ), it is possible to improve the support function of the central support body 220 and increase the adhesion between the signal line 210 and the fluid transmission line 110 and 120, thereby increasing the bonding force of the association.

However, since the derived formula R≥a ₂ is a parameter confirmed in the manufacturing facility and associated process, converting it into a geometric parameter relationship derived from the actual umbilical cable itself using experimental values is as follows.

Referring to FIGS. 4 and 5, D is the combined outer diameter, assuming that the experimental value applied to the actual product is x, and at this time, a ₁ assumes that the experimental value is y, and the signal line 210 dies It is assumed that the experimental value of the angle θ entering toward is z. Here, since a ₂ = a ₁ × tanθ, R ≥ a ₂ can be expressed as R ≥ a ₁ × tanθ. The process of converting the above formula to the relationship between R and D using the above experimental values is as follows.

First, since a ₁ increases as D increases, the relationship between a ₁ and D can be expressed as follows.

a ₁ : D = y : x ∴ a ₁ = (y/x) × D

And since θ decreases as D increases, the relationship between θ and D can be expressed as follows.

θ : (1/D) = z : x ∴ θ = (z/x) × (1/D)

Substituting a ₁ and θ derived in this way into the above-mentioned R ≥ a ₁ × tanθ and combining the formulas

R ≥ (y/x) × tan ((z/x) × (1/D)) × D

The above formula can be derived, and if it is more generalized by calculating the average value of the experiment through several experiments, it can be expressed as follows.

R ≥ α × tan(β/D) × D, α=0.7, β=0.64

As described above, by converting the functional relationship between R and a ₁ , a ₂ into a functional relationship between R and D, the formula expressed as a parameter applied in the manufacturing facility and associated process can be converted into the actual deep-sea umbilical cable 1000 itself. The derived geometrical parameters can be converted into equations applied.

In addition, by applying this to the product, the length of the extension 224 of the central support 220, that is, the radius R of the central support 220 is determined to satisfy the above formula in relation to the combined outer diameter D of the core 200. It is possible to improve the support function of the 220 and increase the adhesion between the signal line 210 and the fluid transmission lines 110 and 120 to increase the bonding force of the union. As shown in FIGS. 2 and 6 , the extension part 224 preferably extends to the core sheath 250 to improve the support function of the central support 220 and to ensure structural stability.

On the other hand, it is preferable that the minimum thickness t of the extension part 224 is made of 2 mm or more. The minimum thickness of the extension part 224 should be at least a thickness that can maintain the shape to support the union despite the shape change due to compression during the extrusion process. As a result of confirming the thickness change in the actual process, the value is 2mm figured out

At this time, the distance (b) between the signal lines 210 and the distance (a) between the fluid transmission lines 110 and 120 may be arranged after being determined in consideration of the roundness of the core 200 based on the thickness of the extension part 224. there is.

And, as shown in FIG. 2, the curvature formed by the central portion 222 and the plurality of extension portions 224 is the same as that of the signal line 210 or the fluid transmission lines 110 and 120 in contact with each other. desirable.

By forming the curvature of the center 222 and the plurality of extensions 224 as above, the occurrence of air gaps between the center support 220, the signal line 210, and the fluid transmission lines 110 and 120 is minimized and a simple structure This can reduce material and processing costs.

In addition, the resistance to high hydrostatic pressure of the deep sea and the internal bearing capacity are increased to prevent sinking, and the adhesion between the signal line 210 and the fluid transmission lines 110 and 120 is increased to effectively respond to the hydrostatic pressure of the deep sea.

A filler 240 may be provided to fill a gap between the central support 220, the signal line 210, and the fluid transmission lines 110 and 120. Yarn filling is applied as the filler 240 to maintain roundness of the core 200 and to mitigate external impact. In addition, the core sheath 250 is applied to the outside of the core 200 to maintain the shape of the entire core 200 union.

A plurality of fluid transmission lines 110 and 120 are additionally disposed around the core 200, and the fluid transmission lines 110 and 120 outside the core 200 are hydraulic lines for transmitting oil for hydraulic operation ( 110). The hydraulic line 110 forms a passage through which oil flows so that hydraulic pressure can be transmitted to equipment for hydraulic drive, such as a hydraulic cylinder.

In this embodiment, all of the fluid transmission lines including the chemical line 120 and the hydraulic line 110 described above are made of steel tubes, and their outer diameters may also be made of the same size. Meanwhile, the steel tube may be a tube made of Super Duplex Stainless Steel (SDSS). In addition, eight hydraulic lines 110 may be provided around the outside of the core 200 , and two chemical lines 120 may be disposed inside the core 200 .

The number, size, shape and arrangement of the fluid transmission lines 110 and 120 composed of the hydraulic line 110 and the chemical line 120 are not limited to the examples shown in FIGS. It can be variously modified and implemented according to. For example, FIGS. 2 and 3 show an embodiment in which the hydraulic line 110 is provided outside the core and the chemical line 120 is provided inside the core, but on the contrary, the hydraulic line 110 is provided inside the core. In addition, various arrangements such as the chemical line 120 being provided on the outside of the core are possible.

The deep-sea umbilical cable 1000 according to the present invention is provided between the fluid transmission lines 110 and 120 provided outside the core 200, and the fluid transmission lines 110 and 120 and the core 200 ) and at least one filler 130 forming surface contact may be further included.

The filler 130 is provided between the fluid transmission lines 110 and 120 provided outside the core 200, that is, between the hydraulic lines 110, and the core 200 as well as the fluid transmission lines 110 and 120 It is formed to make surface contact to uniformly transmit high hydrostatic pressure to the core 200 and prevent local stress concentration in the inner core 200.

Conventionally, various types of fillers have been placed inside the umbilical cable as shown in FIG. 1, but these existing fillers are structurally unstable because they do not make surface contact with other lines but make line contact, and are susceptible to sinking at high hydrostatic pressure. There was a weak problem.

Unlike this, the filler 130 applied to the deep-sea umbilical cable 1000 according to the present invention forms surface contact with the core 200 and the fluid transmission line, ultimately supporting the deep-sea umbilical cable 1000. and improve structural stability.

In this embodiment, eight pillars 130 are provided between the hydraulic lines 110, and the specific number, size, and arrangement of the pillars 130 may be modified as needed.

And, as shown in FIGS. 2 and 3 , the length of the arc formed by the outer circumferential surface of the pillar 130 may be longer than the length of the arc formed by the inner circumferential surface in contact with the core 200 .

Of course, the specific shape of the filler 130 can be variously modified according to the number, size, shape, and arrangement of the core 200 and the fluid transmission line.

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

An outer armor 150 may be provided outside the inner sheath 140 . In this embodiment, the outer armor 150 has a double structure, and serves to protect the inner structure and reinforce the tensile strength of the deep-sea umbilical cable 1000.

An outer sheath 160 may be provided outside the outer armor 150 . The outer sheath 160 is provided at the outermost part of the deep-sea umbilical cable 1000 to protect the deep-sea umbilical cable 1000 from external impact or corrosion. The outer sheath 160 may use a raw material such as HDPE having excellent abrasion resistance, corrosion resistance, and UV protection.

6 is a cross-sectional view of an umbilical cable for deep sea according to another embodiment of the present invention, FIG. 7 is a perspective view of an umbilical cable for deep sea according to another embodiment of the present invention, and FIG. 8 is another embodiment of the present invention. It is a cross-sectional view showing the central support structure according to the example.

The structure of the deep sea umbilical cable 1000 according to another embodiment of the present invention will be described with reference to FIGS. 6 to 8 . The deep sea umbilical cable 1000 according to this embodiment also includes a core 200 including a signal line 210 and fluid transmission lines 110 and 120, and a signal line ( 210) and a central support 320 that contacts and supports the fluid transmission lines 110 and 120.

As in the previous embodiment, the signal line 210 may have a quad structure including four signal lines 212 in which a plurality of core wires 214 are twisted. Insulation of the signal lines 212 may be made of XLPE material.

The four signal lines 212 may be united by surrounding the outside of the combined bedding 213. The combined bedding 213 may be made of HDPE as in the previous embodiment.

A signal line filler 211 may be provided between the signal lines 212 to fill the air gap to increase the circular retaining force. The signal line filler 211 is a selectable component, and a union can be formed only with the combined bedding 213 outside the signal line 212.

A shielding layer 215 made of copper is formed outside the combined bedding 213 to serve as a shield for smooth signal transmission of the signal line 212 .

A signal line inner sheath 216, a signal line armor 217, and a signal line outer sheath 218 may be sequentially formed outside the shielding layer 215. Here, the signal line inner sheath 216 and the signal line outer sheath 218 may be made of the same HDPE material as the combined bedding 213.

Also, the center support 320 is located at the center of the core 200 and serves to contact and support the signal line 210 and the fluid transmission lines 110 and 120 . The central support body 320 includes a center portion 322 located at the center of the core 200, and a plurality of extension portions 324 extending from the center portion 322 between the signal line 210 and the chemical line 120. ) is provided.

However, unlike the previous embodiment, in this embodiment, the central support 320 includes a first seating part 326 that surrounds and supports at least a portion of the signal line 210, and at least one of the fluid transmission lines 110 and 120. It includes a second seating part 328 that surrounds and supports a part.

Specifically, as shown in FIGS. 6 to 8, the first seating portion 326 is formed between any two extensions 324 adjacent to each other among the plurality of extensions 324, and the signal line It may be formed stepwise with respect to the two extension parts 324 so as to cover at least a part of 210 .

In the previous embodiment, as shown in FIGS. 2 and 3, the extension 224 of the central support 220 extends smoothly to the core sheath 250 and the signal is transmitted to the space between the extensions 224 adjacent to each other. The line 210 and the chemical line 120 are seated.

However, in this embodiment, the first seating portion 326 is formed so that the signal line 210 is seated between the extension portions 324 adjacent to each other. Specifically, as shown in FIG. 8 , the first seating portion 326 is formed in a grooved shape based on a stepped point S located at a certain portion of the extension portion 324, and the signal line 210 A grooved shape surrounding a part of may be formed to extend to the neighboring extension part 324 .

That is, the first seating portion 326 is a portion that surrounds a portion of the signal line 210, and is bent with a portion of the extension portion 324 that does not enclose the signal line 210 based on the stepped point (S). It is formed in a single step. The first seating parts 326 are formed to face each other based on the central portion 322, and accordingly, the two signal lines 210 can be seated on the first seating parts 326 so that they are symmetrical to each other.

Meanwhile, the second seating portion 328 is formed between any two extension portions 324 adjacent to each other among the plurality of extension portions 324, and wraps at least a portion of the fluid transmission lines 110 and 120. It may be formed to be stepped with respect to the two extension parts 324 so as to be able to do so.

Specifically, in this embodiment, two second seating parts 328 may be formed to face each other between the first seating parts 326 . The second seating part 328 is also formed in a grooved shape based on the stepped point S located at a certain portion of the extension part 324, and has a grooved shape surrounding a part of the chemical line 120. It may be formed to extend to the neighboring extension part 324 .

The second seating portion 328 is also a portion that surrounds a portion of the chemical line 120, and is bent and stepped with the portion of the extension portion 324 that does not cover the chemical line 120 based on the step point (S). will be formed

Here, the length of the groove formed by the first seating part 326 is longer than the length of the groove formed by the second seating part 328 . The radius of the signal line 210 is not only larger than the radius of the chemical line 120, but also the signal line 210, which has a relatively small rigidity, is tightly and widely wrapped to increase structural stability.

On the other hand, a central support structure according to another embodiment of the present invention is shown in FIG.

The first seating portion 326 surrounds a portion of the signal line 210 and is formed in a grooved shape, and may be smoothly connected to a portion of the extension portion 324 that does not surround the signal line 210 .

Similarly, the second seating part 328 is also formed in a grooved shape surrounding a part of the chemical line 120, and can be smoothly connected to a part of the extension part 324 that does not cover the chemical line 120.

As shown in the present embodiment, as long as the seating portion is formed in a grooved shape, various types of embodiments in which the stepped point S does not exist may be applied.

As described above, the central support 320 guides the signal line 210 and the chemical line 120 by overcoming the difference in stiffness between the signal line 210, which is a general electric cable, and the chemical line 120 made of a steel tube. It is an important task to ensure that the alliance can be smoothly established by closely adhering to it.

The difference in stiffness between the signal line 210 and the fluid transmission lines 110 and 120 may be expressed as bending stiffness, and the difference in bending stiffness between the two types of lines may be 5 times or more.

When the signal line 210 includes the signal line armor 217 that increases the bending strength, the difference in bending strength is reduced to nearly five times, but when the signal line armor 217 is not present, the difference in bending strength is larger. will lose

As in the embodiment of the present invention, when the signal line 210 and the chemical line 120 made of a steel tube are provided together inside the core 200, the difference in bending strength is 5 times or more, and at this time, the central support ( 320), the first seating portion 326 and the second seating portion 328 overcome the difference in bending strength or rigidity to perform a role of enabling smooth union.

When the difference in bending strength is less than 5 times, the outer diameter of the signal line 210 is increased or the armor ( 217), there is a problem in that a compact structure cannot be implemented because the total outer diameter of the cable increases, and the manufacturing cost may increase.

Since the first seating part 326 and the second seating part 328 are formed in a stepped shape between the extension part 324 and provided in a state of closer contact to the signal line 210 and the chemical line 120, An optimal structure for solving the above problems can be achieved. That is, the structural stability of the core 200 including the signal line 210 and the fluid transmission lines 110 and 120 having such a difference in bending strength or rigidity can be increased.

In addition, the first seating portion 326 and the second seating portion 328 more stably surround the signal line 210 and the fluid transmission lines 110 and 120 while maintaining unity within the core, and maintaining roundness and shape bearing capacity. can play a role in increasing

Since the outer structure of the core 200 of the deep-sea umbilical cable 1000 according to this embodiment is the same as that described in the previous embodiment, a detailed description thereof will be omitted.

The deep-sea umbilical cable according to the embodiments of the present invention described so far can be effectively seated inside the core by closely contacting the central support with other components inside the core, and overcomes the difference in stiffness between the lines when the core is united. Thus, it is possible to provide a structure in which the union can be smoothly formed.

In addition, it is possible to effectively respond to the hydrostatic pressure of the deep sea by increasing the adhesion of the inner lines of the core, and it is possible to prevent a sinking phenomenon by increasing the resistance capacity and internal bearing capacity of the umbilical cable against the high hydrostatic pressure of the deep sea, and to increase the retaining force of the original shape.

Although the above has been described with reference to an embodiment of the present invention, those skilled in the art variously modify and change the present invention within the scope not departing from the spirit and scope of the present invention described in the claims described below. You will be able to. Therefore, if the modified implementation basically includes the elements of the claims of the present invention, all of them should be considered to be included in the technical scope of the present invention.

1000: umbilical cable for deep sea 110: hydraulic line
120: chemical line 130: filler
140: inner sheath 150: outer armor
160: external sheath 200: core
210: signal line 220: central delay
222: center 224: extension
240: filler 250: core sheath
326: first seating portion 328: second seating portion
S: difference point

Claims (15)

a core including at least one signal line and a fluid transmission line;
A central support located in the center of the core and contacting and supporting the signal line and the fluid transmission line;
The center support has a central portion located at the center of the core and a plurality of extensions extending from the central portion between the signal line and the fluid transmission line,
Between the length R from the center of the core to the end of the extension and the combined outer diameter D of the core
R ≥ α × tan(β/D) × D, α=0.7, β=0.64
Umbilical cable for deep sea, characterized in that the relationship of According to claim 1,
The deep-sea umbilical cable, characterized in that the curvature formed by the central portion and the plurality of extensions is the same as that of the contacting signal line or fluid transmission line. a core including at least one signal line and a fluid transmission line; and
A center support having a central portion located at the center of the core and a plurality of extensions extending from the central portion between the signal line and the fluid transmission line;
The central support body comprises a first seating portion that surrounds and supports at least a portion of the signal line, and a second seating portion that surrounds and supports at least a portion of the fluid transmission line. According to claim 3,
The first seating part is formed between any two extensions adjacent to each other among the plurality of extensions, and is formed stepwise with respect to the two extensions so as to cover at least a part of the signal line. Umbilical cable. According to claim 3,
The second seating part is formed between any two extensions adjacent to each other among the plurality of extensions, and is formed stepwise with respect to the two extensions so as to cover at least a part of the fluid transmission line. umbilical cable for According to claim 3,
The deep-sea umbilical cable, characterized in that the length of the groove formed by the first seating portion is longer than the length of the groove formed by the second seating portion. A core having two types of lines having different bending strengths;
A central support located in the center of the core and contacting and supporting the two types of lines;
The umbilical cable for deep sea, characterized in that the central support body has a central portion located at the center of the core, and a plurality of extensions extending from the central portion between the two types of lines. According to claim 7,
A deep-sea umbilical cable, characterized in that the difference in bending strength between the two types of lines is 5 times or more. According to any one of claims 1 to 8,
A deep-sea umbilical cable further comprising a filler filled to fill the air gap inside the core to mitigate external shock. According to any one of claims 1 to 8,
Further comprising a core sheath provided outside the core and surrounding to maintain the shape of the core,
The plurality of extension parts extend to the core sheath, characterized in that the deep sea umbilical cable. According to claim 10,
A deep-sea umbilical cable further comprising a plurality of fluid transmission lines disposed outside the core sheath. According to claim 11,
A deep-sea umbilical cable further comprising a plurality of pillars disposed between a plurality of fluid transmission lines disposed outside the core sheath. According to claim 11,
An umbilical cable for deep seas, further comprising an inner sheath provided outside the plurality of fluid transmission lines and absorbing external impact to protect the inner core and fluid transmission lines. According to claim 13,
A deep-sea umbilical cable further comprising an outer armor of a double structure provided outside the inner sheath to protect the inner structure and reinforce tensile strength. According to claim 14,
A deep-sea umbilical cable further comprising an outer sheath provided outside the outer armor and protecting the inside from external impact or corrosion.

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