The present disclosure relates to a detachable mooring system for an offshore structure. More particularly, the present disclosure relates to a detachable mooring system for an offshore structure, the detachable mooring system being capable of easily performing mooring of an offshore structure and of quickly and safely performing relocation of the moored offshore structure in emergency situations such as port movement requirements for emergency maintenance or typhoons.
In the case of offshore structures, such as offshore wind turbines, they are inevitably affected by waves and currents due to their location on the sea.
Therefore, when an offshore structure moves due to the effects of waves and currents, the offshore structure may not only be lost due to excessive movement, but also be damaged by collapse.
Various mooring devices or mooring systems, such as those disclosed in Korean Patent Application Publication No. 10-2014-0126022, are used to secure an offshore structure to a point on the sea.
At this point, since an offshore structure such as an offshore wind turbine has a significant size and load, a mooring device for the offshore structure also has a significant size and load. Therefore, not only is it difficult to manufacture an offshore structure, but installation thereof also requires considerable time, manpower, and equipment, which causes a problem of reducing the efficiency of installation work.
Furthermore, a conventional mooring device for an offshore structure has a complex structure because it includes, for example, multiple links. When relocation of an offshore structure is required in emergency situations such as port movement requirements for emergency maintenance or typhoons, respective connection of the multiple links should be disconnected to remove binding between the offshore structure and the mooring device. At this time, the disconnection inevitably requires more time, manpower, and equipment, and therefore, relocation of the offshore structure cannot be performed quickly. There may be problems of damage caused due to delayed maintenance and serious damage to the offshore structure due to the effects of typhoons, etc.
For the above reasons, in this field, attempts are being made to develop mooring systems for offshore structures that can facilitate mooring of an offshore structure and can quickly and safely relocate a moored offshore structure in emergency situations such as port movement requirements for emergency maintenance or typhoons, but satisfactory results have not been obtained to date.
The present disclosure has been made keeping in mind the above problems occurring in the related art, and the present disclosure is intended to propose a mooring system for an the offshore structure, the mooring system being capable of easily performing mooring of an offshore structure and of quickly and safely performing relocation of the moored offshore structure in emergency situations such as port movement requirements for emergency maintenance or typhoons.
In order to achieve the above objective, the present disclosure proposes a detachable mooring system for an offshore structure.
The detachable mooring system for an offshore structure includes: a first tension adjuster connected to an offshore structure to be a moored object, and configured to block advance of a pulling chain, which is inserted through an inlet of a body and is discharged out through an outlet, in a direction from the outlet toward the inlet; a second tension adjuster connected to one end of the pulling chain connected to an outer portion of the inlet of the first tension adjuster, and configured to block advance of the pulling chain, which is inserted through an inlet of a body and is discharged out through an outlet, in a direction from the outlet toward the inlet; a mooring chain having a first longitudinal end connected to any one surface of the body of the second tension adjuster, and a second longitudinal end connected to an anchor settled on the sea bed; a first lead rope having one longitudinal end, which is connected to one end of the pulling chain discharged out through the outlet of the first tension adjuster; and a second lead rope having one longitudinal end connected to the body of the second tension adjuster.
According to the present disclosure, the detachable mooring system for an offshore structure includes the first tension adjuster, the second tension adjuster, the mooring chain, the first lead rope, and the second lead rope. Therefore, the detachable mooring system has a relatively simple structure, thereby facilitating manufacturing and installation thereof.
Furthermore, the detachable mooring system for an offshore structure of the present disclosure is configured such that the pulling chain extending from the first tension adjuster is connected to the second tension adjuster and the mooring chain extending from the anchor is connected to the second tension adjuster, so that mooring of the offshore structure to be a moored object can be simply completed. Therefore, mooring of the offshore structure can be easily performed, thereby improving efficiency of mooring work of the offshore structure.
Furthermore, the detachable mooring system for an offshore structure according to the present disclosure is configured such that one end of the pulling chain extending from the first tension adjuster on the water is pulled or one end of the pulling chain extending from the second tension adjuster in the water is pulled, so that tension adjustment in a moored state can be performed. Therefore, the moored state of the offshore structure can be stably maintained by the tension adjustment.
Furthermore, each of the first tension adjuster and the second tension adjuster of the detachable mooring system for an offshore structure according to the present disclosure includes the pulling member and the wireless controller. Therefore, the pulling member may lock and unlock the restrictor of the first tension adjuster and the second tension adjuster manually. Additionally, the wireless controller may lock and unlock the restrictor of the first tension adjuster and the second tension adjuster automatically. Accordingly, tension adjustment using the first tension adjuster and the second tension adjuster can be easily performed.
Hereinbelow, the present disclosure will be described in detail with reference to accompanying drawings.
As shown in
The first tension adjuster 10 of the present disclosure is connected to an offshore structure 100 to be a moored object, and blocks advance of a pulling chain 200, which is inserted through an inlet 11a of a body 11 and is discharged out through an outlet 11b, in a direction from the outlet 11b toward the inlet 11a.
At this point, as shown in
At this point, the restrictor 13 may use any known structures and methods as long as it can restrict uni-directional rotation of the pulley 12 as locking of the restrictor 13 is performed, and detailed description of the restrictor 13 will be omitted.
In addition, the first tension adjuster 10 includes a pulling member 14, the pulling member 14 being configured to remove the locked state by pulling the restrictor 13. Accordingly, when the pulling member 14 is pulled manually, the locked state of the restrictor 13 is removed and the pulling chain 200 can be moved forward from the outlet 11b toward the inlet 11a.
In addition, the first tension adjuster 10 includes a wireless controller 15 configured to lock and unlock the restrictor 13 in response to a control signal from a remote location. Accordingly, the locked state of the restrictor 13 is removed according to control of the wireless controller 15, and the pulling chain can be moved forward from the outlet 11b toward the inlet 11a.
At this point, the wireless controller 15 may use any known structures and methods as long as it can lock and unlock the restrictor 13 according to a control signal of a remote location, and detailed description of the wireless controller 15 will be omitted.
Meanwhile, the first tension adjuster 10 is connected to the offshore structure 100 from the start while being coupled with the pulling chain 200 and, specifically is connected to any one bollard (without reference numeral) constituting the offshore structure 100. Accordingly, as shown in
The second tension adjuster 20 of the present disclosure is connected to one end of the pulling chain 200 connected to an outer portion of the inlet 11a of the first tension adjuster 10. The second tension adjuster 20 blocks the advance of the pulling chain 200, which is inserted through the inlet 11a of a body 21 and is discharged out through an outlet 21b, in a direction from the outlet 21b toward the inlet 21a.
At this point, as shown in
At this point, the restrictor 23 may use any known structures and methods as long as it can restrict uni-directional rotation of the pulley 22 as locking of the restrictor 23 is performed, and detailed description of the restrictor 23 will be omitted.
In addition, the second tension adjuster 20 includes a pulling member 24, which is configured to remove the locked state by pulling the restrictor 23. Accordingly, when the pulling member 24 is pulled manually, the locked state of the restrictor 23 is removed and the pulling chain 200 can be moved forward from the outlet 21b toward the inlet 21a.
In addition, the second tension adjuster 20 includes a wireless controller 25 configured to lock and unlock the restrictor 23 in response to a control signal from a remote location. Accordingly, the locked state of the restrictor 23 is removed according to control of the wireless controller 25, and the pulling chain 200 can be moved forward from the outlet 21b toward the inlet 21a.
At this point, the wireless controller 25 may use any known structures and methods as long as it can lock and unlock the restrictor 23 according to a control signal of a remote location, and detailed description of the wireless controller 25 will be omitted.
In addition, the second tension adjuster 20 includes a link member 26 arranged at one surface of the body 21. Accordingly, as the second lead rope 50 is bound to the link member 26, connection of the second lead rope 50 to the second tension adjuster 20 may be achieved.
In addition, the second tension adjuster 20 includes a binding member 27 arranged at one surface of the body 21. Accordingly, the mooring chain 30 extending from an anchor 31 is bound to the binding member 27, and accordingly the mooring chain 30 may be connected to the second tension adjuster 20.
A first longitudinal end of the mooring chain 30 of the present disclosure is connected to one surface of the body 21 of the second tension adjuster 20 and a second longitudinal end thereof is connected to the anchor 31 is settled on the sea bed.
At this point, the mooring chain 30 may be connected to the second tension adjuster 20 as the first longitudinal end thereof is bound to the binding member 27 provided at the second tension adjuster 20.
Meanwhile, the mooring chain 30 is connected to the second tension adjuster 20 at first. Accordingly, as shown in
A first longitudinal end of the first lead rope of the present disclosure is connected to one end of the pulling chain 200 discharged out through the outlet 11b of the first tension adjuster 10.
Therefore, towing the offshore structure 100 or tension adjustment of the pulling chain 200 may be achieved as a second longitudinal end of the first lead rope 40 is pulled using the winch arranged at the ship 300.
Meanwhile, the offshore structure 100 may be restrained from unintentionally moving while being exposed outwards as the second longitudinal end of the first lead rope 40 is bound to the offshore structure 100 in situations other than towing or tension adjustment.
A first longitudinal end of the second lead rope 50 of the present disclosure is connected to the body 21 of the second tension adjuster 20.
Accordingly, the second tension adjuster 20 and the mooring chain 30 connected to the second tension adjuster may be towed as a second longitudinal end of the second lead rope 50 is pulled using the winch arranged at the ship 300.
At this point, the second lead rope 50 may be connected to the second tension adjuster 20 as the first longitudinal end of the second lead rope 50 is bound to the link member 26 arranged at one surface of the body 21 of the second tension adjuster 20.
Meanwhile, the offshore structure 100 may be restrained from unintentionally moving while being exposed outwards as the second longitudinal end of the second lead rope 50 is bound to the offshore structure 100 in situations other than towing or tension adjustment.
Furthermore, additionally, the detachable mooring system A for an offshore structure of the present disclosure may include a connecting rope 60.
At this point, a first longitudinal end of the connecting rope 60 is connected to one end of the pulling chain 200 discharged out through the outlet 21b of the second tension adjuster 20. Accordingly, a tension of the pulling chain 200 may be adjusted as a second longitudinal end of the connecting rope 60 is pulled using the winch arranged at the ship 300.
Hereinbelow, mooring the offshore structure 100 by using the detachable mooring system A for an offshore structure of the present disclosure will be described in detail.
First, the offshore structure 100 and the mooring chain 30 are transferred to one point on the sea.
At this point, the first tension adjuster 10 is connected to the offshore structure 100, the pulling chain 200 is connected to the first tension adjuster 10, and the first lead rope 40 is connected to the first longitudinal end of the pulling chain 200 discharged out through the outlet 11b of the body 11 of the first tension adjuster 10.
The second tension adjuster 20 is connected to the first longitudinal end of the mooring chain 30, and the second lead rope 50 is connected to the body 21 of the second tension adjuster 20.
Meanwhile, the mooring chain 30 transferred to one point on the sea is located on the sea by being inserted into the sea with one end thereof connected to a buoy (without reference numeral).
At this point, the buoy is seated from the mooring chain 30 in a process in which the first tension adjuster 10 and the second tension adjuster 20 are connected to each other, so that the mooring chain 30 may be located underwater.
Next, the first tension adjuster 10 and the second tension adjuster 20 are connected to each other.
At this point, as shown in
At this point, the pulling chain 200 extending from the first tension adjuster 10 may be connected to the second tension adjuster 20 as the longitudinal end thereof is inserted through the inlet 21a of the body 21 of the second tension adjuster 20 and is discharged out through the outlet 21b.
Meanwhile, connection between the first tension adjuster 10 and the second tension adjuster 20 is performed while the second tension adjuster 20 is towed on a ship thereby minimizing underwater operation.
Next, tension adjustment is performed while the second tension adjuster 20 and the mooring chain 30 are inserted into the water.
In the present disclosure, one longitudinal end of the pulling chain 200 is discharged out through the outlet 11b of the body 11 of the first tension adjuster 10, and the longitudinal end of the pulling chain 200 is connected to the first lead rope 40. As shown in
Furthermore, in the present disclosure, another longitudinal end of the pulling chain 200 is discharged out through the outlet 21b of the body 21 of the second tension adjuster 20, and the connecting rope 60 is connected to the longitudinal end of the pulling chain 200. As shown in
However, each of the first tension adjuster 10 and the second tension adjuster 20 blocks the uni-directional advance of the pulling chain 200 by restricting uni-directional rotation of the pulley 12, 22 by the restrictor 13, 23. Tension adjustment may be difficult by blocking the uni-directional advance of the pulling chain 200.
However, in the present disclosure, each of the first tension adjuster 10 and the second tension adjuster 20 includes a pulling member 14, 24. When the pulling member 14, 24 is pulled manually, locking of the restrictor 13, 23 may be removed. Accordingly, the uni-directional advance of the pulling chain 200 is released, in other words, bi-directional advance thereof may be achieved, so that tension adjustment by pulling the pulling chain 200 may be efficiently achieved.
Furthermore, in the present disclosure, each of the first tension adjuster 10 and the second tension adjuster includes a wireless controller 15, 25. Locking of the restrictor 13, 23 may be removed by control of the wireless controller 15, 25 in response to a control signal from a remote location. Accordingly, the uni-directional advance of the pulling chain 200 is released, in other words, the bi-directional advance thereof may be achieved, so that tension adjustment by pulling the pulling chain 200 may be efficiently achieved.
Meanwhile, the detachable mooring system A for an offshore structure according to the present disclosure may efficiently relocate the moored offshore structure 100 in emergency situations such as port movement requirements for emergency maintenance or typhoons.
In other words, while the offshore structure 100 is moored, one end of each of the first lead rope 40 and the second lead rope 50 of the present disclosure is bound to the offshore structure 100 to be exposed outwards. In emergency situations such as port movement requirements for emergency maintenance or typhoons, the end of the first lead rope 40 and the second lead rope 50 bound to the offshore structure 100 is unbound and connected to the winch arranged at the ship 300 and then is pulled, thereby allowing not only the offshore structure 100 to be towed but also the second tension adjuster 20 to be towed. Accordingly, connection between the first tension adjuster 10 and the second tension adjuster 20 may be simply removed as the second tension adjuster 20 is towed to the ship and the pulling chain 200 is separated therefrom.
Therefore, while connection between the first tension adjuster 10 and the second tension adjuster 20 is removed, the pulling chain 200 and the first lead rope 40 that extend from the first tension adjuster 10 is connected to the ship 300 to move the ship 300. Accordingly, the offshore structure 100 connected to the first tension adjuster 10 is transferred, thereby quickly and safely performing relocation.
At this point, the second tension adjuster 20 released from connection with the first tension adjuster 10 may maintain a previous installation location as the second tension adjuster 20 connected to the buoy is re-put into the water. Therefore, when mooring of the offshore structure 100 is required in the future, the second tension adjuster located in the water is towed and is connected to the first tension adjuster 10, and accordingly the offshore structure 100 may be re-located at the point before relocation.
The present disclosure described above is not limited to the above-mentioned embodiment and those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the present disclosure as disclosed in the accompanying claims, and the modifications, additions and substitutions are within the scope of the protection of the patent right of the present disclosure that are defined by description of the claims.
The present disclosure is configured not only to facilitate mooring of an offshore structure but also to quickly and safely relocate a moored offshore structure in emergency situations such as port movement requirements for emergency maintenance or typhoons, so that the present disclosure has industrial applicability in relation to manufacturing of a mooring system for an offshore structure.
Number | Date | Country | Kind |
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10-2021-0155932 | Nov 2021 | KR | national |
This application is a continuation of International Application No. PCT/KR2022/005159 filed on Apr. 8, 2022, which claims priority to Korean Patent Application No. 10-2021-0155932 filed on Nov. 12, 2021, the entire contents of which are herein incorporated by reference.
Number | Date | Country | |
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Parent | PCT/KR2022/005159 | Apr 2022 | US |
Child | 18403425 | US |