WO2019177010A1 - Offshore working facility and construction method thereof - Google Patents

Abstract

The present invention provides an offshore working facility enabling stable work even in a deep sea region and capable of improving work efficiency. The offshore working facility has three columns 10, a deck 20 liftably supported with respect to the columns 10, and a crane 30 mounted on the deck 20. The deck 20 is configured as a floating structure and has a main deck part 21 and a first extending part 22 formed so as to extend from the main deck part 21. The crane 30 is mounted on the first extending part 22. The offshore working facility is configured by adding the first extending part 22 and the crane 30 to a jack-up drilling rig removed of a drilling facility and a cantilever. The first extending part 22 is added to the main deck part 22 with use of a supporting structure of the cantilever.

Description

Offshore work equipment and manufacturing method thereof

The present invention relates to an offshore work facility that can be used for the construction of an offshore facility such as an offshore wind power generation facility and a method of manufacturing the same.

”Offshore wind power generation is attracting attention from the viewpoint of effective use of natural energy.

For construction of offshore wind power generation facilities, offshore work facilities such as self-elevating work platform ships (SEP) are often used. A self-elevating work platform ship usually has a plurality of pedestals and a deck supported by these pedestals so as to be movable up and down (Patent Documents 1 and 2). A work crane is mounted on the deck, and offshore wind power generation equipment is assembled using this crane. The deck can also be used as a cargo handling space for various parts of offshore wind power generation facilities.

Patent Document 1: Japanese Patent Laid-Open No. 2015-37925 Patent Document 2: Japanese Patent Laid-Open No. 2016-215937

In recent years, offshore wind power generation facilities with high output of, for example, 6 MW or more have been developed as offshore wind power generation facilities, and accordingly, the size of the offshore wind power generation facilities itself has increased, and in addition to the landing type, a floating type Equipment is being developed and put to practical use. As described above, the offshore work equipment deck is equipped with a working crane and is also used as a cargo handling space for various parts. Therefore, in order to construct a large offshore wind power generation facility, an offshore work facility having a larger deck is required. In addition, in order to construct a floating wind power facility, an offshore work facility that can work stably even in a sea area where the water depth exceeds 90 m is required.

Since there is nothing that can be used with existing self-lifting work platform boats in offshore construction where the water depth exceeds 90 m, usually a large floating crane is used, but it is easily affected by waves, and the work waiting period Work efficiency is likely to decrease. On the other hand, an offshore work facility having a large deck causes a reduction in towing speed from a port to the sea area where the offshore facility is constructed. The decrease in towing speed will cause the construction period of offshore facilities to be prolonged.

Therefore, an object of the present invention is to provide an offshore work facility capable of performing stable work even in the deep sea area and capable of improving work efficiency, and a manufacturing method thereof.

The offshore work facility of the present invention is
3 or more pedestals,
A deck configured as a floating structure and supported so as to be movable up and down with respect to the pedestal;
A crane mounted on the deck;
Have
The deck is an offshore work facility having a main deck portion on which the pedestals are arranged, and an overhang portion formed to overhang from the main deck portion,
The offshore work facility is configured by adding the overhang portion and the crane to an existing jack-up excavation rig having the main deck portion and the pedestal,
The overhang portion is added to the main deck portion using a cantilever support structure for onboard drilling equipment mounted on the existing jack-up type drilling rig,
The crane is mounted on the overhanging portion.

The manufacturing method of the offshore work facility of the present invention is:
Three or more pedestal columns, the pedestal column is disposed, and a main deck portion supported to be movable up and down with respect to the pedestal column, a cantilever supported on the main deck portion via a support structure, and the cantilever Preparing a jack-up type drilling rig having a drilling facility,
Removing the cantilever and the drilling equipment from the jack-up drilling rig;
Adding an overhang formed by protruding from the main deck to the main deck using the support structure, and installing a crane on the overhang.

According to the present invention, it is possible to provide an offshore work facility capable of working stably and efficiently even in the deep sea area. Moreover, according to the manufacturing method of the offshore work facility of this invention, the said offshore work facility can be manufactured in a short period of time and low cost.

It is a schematic side view of the offshore work facility by one Embodiment of this invention. It is a schematic plan view of the offshore work facility shown in FIG. It is a figure which shows the internal structure of a deck in the offshore work equipment shown in FIG. It is a figure explaining the work range of a crane at the time of arranging a crane in the field surrounded by a pedestal. It is a schematic side view of the offshore work facility by the other form of this invention which made the deck a multilayer structure. It is a figure explaining an example of the utilization form of the offshore work facility shown in FIG.

1 to 3, an offshore work facility 1 according to an embodiment of the present invention having a pedestal 10, a deck 20 supported by the pedestal 10, and a crane 30 mounted on the deck 20 is shown. Has been. This offshore work facility 1 can be used for construction of offshore facilities such as offshore wind power generation facilities. The deck 20 is configured as a floating structure, and when the offshore work facility 1 is constructed using the offshore work facility 1, the offshore work facility 1 is towed to the sea area where the offshore facility is constructed by a towing vessel such as a tug boat. .

The pedestal 10 supports the deck 20 above the sea surface during offshore work by the offshore work facility 1. Therefore, the pedestal 10 has such a length that the deck 20 can be supported above the sea level with the lower end of the pedestal 10 bottomed on the seabed. The offshore work facility 1 has three or more pedestals 10 to stably support the deck 20. The structure of the pedestal 10 may be arbitrary as long as the pedestal 10 can perform the above-described function. For example, the pedestal 10 is used for a self-lifting work platform ship or a jack-up type drilling rig which is a kind of the offshore work facility 1. A known structure such as a structure of a pedestal to be used can be employed. The length of the pedestal 10 is not particularly limited. For example, the pedestal 10 has a length that allows the pedestal 10 to be bottomed and stably constructed without being affected by the waves even during construction in a sea area exceeding 90 m. It is preferable. The cross-sectional shape of the pedestal 10 is not particularly limited, and may be any shape such as a circle or a polygon.

The deck 20 is supported so as to be movable up and down with respect to the pedestal 10 by an elevating mechanism (not shown). Any mechanism such as a rack and pinion mechanism can be used as the lifting mechanism. When the offshore work facility 1 is towed, the lifting mechanism is operated to raise the pedestal 10 with respect to the deck 20 so that the pedestal 10 does not bottom. Since the deck 20 is configured as a floating structure, the offshore work facility 1 floats on the sea surface by raising the pedestal 10, and the offshore work facility 1 can be towed in this state.

The deck 20 has a top wall 20a, a bottom wall 20b, and an outer peripheral wall 20c, whereby the deck 20 is configured as a floating structure in which a closed internal space is formed. As shown in FIG. 2A, the internal space of the deck 20 is divided into a plurality of sections by at least one partition wall 20d that is a strength member. Sufficient mechanical strength is secured for use as a space.

As shown in FIG. 2, the deck 20 includes a main deck portion 21, a first overhang portion 22, and a second overhang portion 23. In the illustrated form, the deck 20 has two first overhang portions 22 and two second overhang portions 23, but the number of the first overhang portions 22 and the number of the second overhang portions 23 are arbitrary. Good. Of these main deck portion 21, first overhang portion 22 and second overhang portion 23, the main deck portion 21 is a portion having the largest area when viewed from above, and the pedestal 10 is an outer edge portion of the main deck portion 21. Is arranged. Therefore, most of the upper surface of the main deck portion 21 can be used as a work space and a part mounting space for offshore facilities to be constructed. When the offshore facility is an offshore wind power generation facility, the deck 20 preferably has a space in which, for example, a part for one offshore wind power generation facility can be mounted. The planar shape of the main deck portion 21 may be arbitrary.

The first projecting portion 22 can have a shape projecting in a convex shape from the main deck portion 21 with respect to the side connecting the two adjacent pillars 10 when viewed from above. Further, it is preferable that the upper surface of the first projecting portion 22 is configured to be on the same plane as the upper surface of the main deck portion 21. Thereby, the work space on the upper surface of the deck 20 and the part mounting space can be substantially enlarged.

The crane 30 is mounted on the first overhang portion 22. The crane 30 may be a fixed type or a crawler type. However, since the work is often performed without moving on the first overhanging portion 22, the fixed crane 30 is substantially sufficient. The fixed crane 30 is also advantageous in that it occupies a smaller area on the deck 20 than the crawler crane and can secure a larger space on the deck 20.

By mounting the crane 30 on the first overhang portion 22, the crane 30 is positioned outside the region surrounded by all the pedestals 10 (three pedestals 10 in this embodiment) that support the deck 20. Become.

In this way, by mounting the crane 30 on the first overhanging portion 22 and positioning it outside the region surrounded by the pedestal 20, as shown in FIG. 2, the work range θ1 of the crane 30 (the turning center of the crane 30) The rotation range around O) can be expanded to a range exceeding 180 °. On the other hand, when the crane 30 is mounted on the main deck portion 21 as shown in FIG. 3, the pedestal 10 is usually disposed at the corner of the main deck portion 21, so that the crane 30 includes two cranes 30. It will be located in the region sandwiched between the pedestals 10. Therefore, the work range θ2 of the crane 30 is less than 180 °. By expanding the work range of the crane 30, the degree of freedom of work by the crane 30 can be improved.

If the entire deck 20 is configured as a floating structure, the first projecting portion 22 itself may be configured as a floating structure or may not be configured as a floating structure. When the 1st overhang | projection part 22 is comprised as a floating body structure, the 1st overhang | projection part 22 has the top wall, bottom wall, and outer peripheral wall which form internal space in the 1st overhang | projection part 22 like the main deck 21. Can do. The 1st overhang | projection part 22 may have a partition further as needed.

The second projecting portion 22 is formed to project from the main deck 21 in a shape that does not exceed the width of the main deck portion 21 at a position different from the first projecting portion 22. Similarly to the first overhanging portion 21, the second overhanging portion 22 may have a shape protruding from the main deck portion 21 with respect to the side connecting the two adjacent pillars 10 as viewed from above. Moreover, the 2nd overhang | projection part 22 is comprised as a floating body structure. Accordingly, like the main deck portion 21, the second overhang portion 22 can have a top wall, a bottom wall, and an outer peripheral wall that form an internal space in the second overhang portion 23. The 2nd overhang | projection part 23 may further have a partition as needed.

By adding the second overhanging portion 23 to the main deck portion 21, the space on the deck 20 is expanded, and at the same time, the stability of the offshore work facility 1 during towing can be improved. Moreover, since the 2nd overhang | projection part 23 is a shape which does not exceed the width | variety of the main deck part 21, it is suppressed that resistance becomes large at the time of towing. As a result, the offshore work facility 1 can be towed efficiently, such as a reduction in the towing speed is suppressed. In order to further suppress the resistance during towing, when the offshore work facility 1 is configured to be towed in the direction of the white arrow shown in FIG. 2A, the second overhanging portion 23 is connected to the main deck portion 21 and the second deck. It is preferable that the shape combined with the overhanging portion 23 is a shape in which the width is widened from the bow side toward the stern side.

Although the case where the deck 20 has a single layer structure has been described above, the deck 20 may have a multilayer structure. FIG. 4 shows a schematic side view of an offshore work facility having a multi-layer deck. In the following description of the offshore work facility shown in FIG. 4, the same reference numerals as those in FIG.

In the offshore work facility 1 shown in FIG. 4, the deck 20 has a second top wall 120a disposed above the top wall 20a and spaced from the top wall 20a, and the second top wall 120a is spaced from the top wall 20a. It has the 2nd outer peripheral wall 120c and the 2nd partition (not shown) which are opened and supported, and, thereby, the deck 20 is made into 2 layer structure. The structure disposed above the top wall 20a by the top wall 20a, the second top wall 120a, the second outer peripheral wall 120c, and the second partition wall is a floating structure in which an internal space divided into a plurality of sections is formed. Configured as Therefore, even if structures such as the second ceiling wall 120a, the second outer peripheral wall 120c, and the second partition wall are added on the ceiling wall 20a, the deck 20 has a buoyancy necessary to enable towing the offshore work facility. Secured.

The second top wall 120a and the second outer peripheral wall 120c are at least the main deck portion 21 of the main deck portion 21 (see FIG. 2), the first overhang portion 22 (see FIG. 2), and the second overhang portion (see FIG. 2). It can arrange | position in the position corresponding to. That is, the entire deck 20 does not need to have a two-layer structure. However, in order to effectively use the upper surface of the deck 20, the second top plate is formed so that all regions of the main deck portion 21, the first overhang portion 22 and the second overhang portion 23 have a two-layer structure. It is preferable to arrange 120a and the second outer peripheral wall 120c.

As described above, by making the deck 20 have a two-layer structure, the mechanical strength of the deck 20 can be improved, and a heavy object can be mounted on the deck 20. As a result, when carrying parts from the construction yard for offshore equipment construction to the sea area that is the construction site, offshore work equipment can be used to carry more or more heavy parts. Although the case where the deck 20 has a two-layer structure has been described here, the deck 20 may be configured with three or more layers.

Next, a method for constructing an offshore facility using the offshore work facility 1 according to the present embodiment will be described by taking as an example a case where the offshore facility is an offshore wind power generation facility.

First, various parts such as wind turbine members of the offshore wind power generation equipment and the offshore work equipment 1 are moved from the construction yard to the sea area that is the construction site. The offshore work facility 1 is moved by raising the legs 10 with respect to the deck 20 and towing the offshore work facility 1 with a towing vessel in a state where the deck 20 floats on the sea surface. At this time, the components of the offshore wind power generation facility are mounted on the deck 20. If the deck 20 has a space for mounting components for one offshore wind power generation facility and has mechanical strength, a ship for transporting the components is necessary to move the components of the offshore wind power generation facility. Absent.

When the movement of the offshore wind power generation equipment parts and the offshore work equipment 1 is completed, the pedestal 10 of the offshore work equipment 1 is lowered with respect to the deck 20, and the pedestal 10 is landed on the seabed. At this time, as shown in FIG. 1, the pedestal 10 is lowered until the deck 20 is positioned away from the sea surface. Thereby, an offshore wind power generation facility can be constructed without being affected by sea conditions.

After landing the pedestal 10 on the sea floor, the parts on the deck 20 are suspended by the crane 30 and the offshore wind power generation equipment is assembled by the crane 30. Since the crane 30 is mounted on the first overhanging portion 22 and the work range of the crane 30 is further expanded, smooth assembly is possible.

After assembling the offshore wind power generation equipment, the pedestal 10 is raised again with respect to the deck 20, and the offshore work equipment 1 is returned to the construction yard by a towed vessel.

It is also possible to connect a plurality of offshore equipment 1 and use it as a construction yard for offshore equipment construction for cargo handling and assembly of offshore equipment parts. FIG. 5 shows a plan view of a construction yard using a plurality of offshore work facilities 1.

The construction yard shown in FIG. 5 is one in which three offshore working facilities 1 are connected so that offshore equipment parts can be handled and assembled on the deck 20. Since the crane 30 is mounted on the first overhang portion 22, a wider deck space can be secured. Moreover, even if it is a case where the several crane 30 is operated simultaneously by arrange | positioning the offshore work equipment 1 so that the crane 30 may be located alternately, it is suppressed that it mutually interferes.

A construction yard can be set up for each project. By using the offshore work facility 1 as a construction yard, when the yard work is completed, the offshore work facility 1 can be moved to the construction area of the offshore equipment and the offshore equipment can be constructed. The construction yard can also be used as a permanent facility. Thus, by using the offshore work facility 1 as a construction yard, it becomes a substitute for the harbor facility for offshore facilities, and the construction yard can be installed at low cost and in a short period of time.

In the above, the present invention has been described by taking the representative embodiment as an example. The offshore work facility 1 according to the present invention has a first overhanging portion 21 and a crane 30 for an existing offshore work facility such as a self-lifting work table ship or a jack-up excavation rig having a main deck portion 21 and a pedestal 10. It can be configured by adding and further adding a second overhang 23 as required. The “existing offshore work facility” means an offshore work facility that has already been assembled so as to have the intended function of the offshore work facility. The offshore work equipment can be modified and configured.

In general, a conventional offshore work facility such as a self-lifting work platform ship and a jack-up type drilling rig has a self-lifting pedestal and a platform supported so as to be able to move up and down with respect to the pedestal (the above-described offshore of this embodiment). Corresponding to the main deck portion 21 in the work facility 1.

Therefore, the offshore work facility is used (modified) to form the offshore work facility according to the present invention, and the pedestal 10 and the main deck portion are respectively utilized using the pedestal and platform of the existing offshore work facility structure. 21 can be configured. Thereby, an offshore work facility can be obtained more easily and in a short construction period, and as a result, a significant cost reduction of the offshore work facility is achieved. In particular, by using the existing jack-up type drilling rig to construct the offshore work facility 1, the pedestal is settled down at the time of offshore construction in the sea area where the water depth exceeds 90m, and it is stable without being affected by waves. It is possible to obtain an offshore work facility that can be constructed in a simpler and shorter construction period.

Also, the jack-up type drilling rig has an on-board drilling facility so that oil and natural gas drilling work can be carried out in a state where it has landed offshore. The onboard drilling equipment is mounted on a cantilever installed on the platform. However, the cantilever moves on the platform by the drive mechanism and performs excavation work at the position where the cantilever gets out of the platform. In order to support such a load of the entire cantilever including the drive mechanism and the onboard excavation equipment, the platform has a strength member such as a partition wall having a necessary strength inside as a support structure.

This embodiment pays attention to this point, and utilizes the cantilever support structure of the existing jack-up type drilling rig when configuring the first overhanging portion 22. That is, the first projecting portion 22 is supported by the cantilever support structure and projects from the main deck portion 21. Here, the “support structure of the cantilever” is a support structure that the platform has to support the load of the entire cantilever including the drive mechanism and the on-board excavation equipment, and specifically, the cantilever. It is a strength member having a strength required to support the whole, for example, a partition wall. Thus, by using the support structure that originally exists in the jack-up type drilling rig, for example, a machine sufficient to mount a crane 30 capable of carrying a heavy structure such as a nacelle of an offshore wind power generation facility. The 1st overhang | projection part 22 which has suitable intensity | strength can be added more easily according to the strength member which has existed originally, without adding a strength member newly. As a result, significant cost reduction of offshore work facilities is achieved.

When the first overhanging portion 22 is configured using the support structure of the cantilever of the jack-up type drilling rig as described above, the support structure of the cantilever is removed by removing the cantilever and the onboard drilling equipment of the jack-up type drilling rig. The 1st overhang | projection part 22 is comprised on the top, and the crane 30 is mounted on it. Therefore, the offshore work facility 1 no longer functions as a drilling rig.

Also, when the deck 20 has a multi-layer structure in order to improve the mechanical strength of the deck 20, it is generally considered to replace the existing ceiling wall with a ceiling wall having higher mechanical strength. However, various structures such as electric wiring and water supply / drainage pipes are usually attached to the lower surface of the top wall. Therefore, when exchanging the top wall, it is necessary to exchange these structures together. Therefore, as shown in FIG. 4, by leaving the top wall 20a as it is and placing the second top wall 120a above it, it is possible to utilize existing electrical wiring, water supply and drainage pipes, etc. As a result, the construction period of the offshore work facility 1 can be shortened, and an increase in construction cost can be suppressed.

DESCRIPTION OF SYMBOLS 1 Offshore work equipment 10 Pedestal column 20 Deck 20a Top wall 20b Bottom wall 20c Outer wall 20d Bulkhead 21 Main deck part 22 1st overhang part 23 2nd overhang part 30 Crane 120a 2nd ceiling wall 120c 2nd outer wall

Claims (7)

1. 3 or more pedestals,
   A deck configured as a floating structure and supported so as to be movable up and down with respect to the pedestal;
   A crane mounted on the deck;
   Have
   The deck is an offshore work facility having a main deck portion on which the pedestals are arranged, and an overhang portion formed to overhang from the main deck portion,
   The offshore work facility is configured by adding the overhang portion and the crane to an existing jack-up excavation rig having the main deck portion and the pedestal,
   The overhang portion is added to the main deck portion using a cantilever support structure for onboard drilling equipment mounted on the existing jack-up type drilling rig,
   The crane is an offshore work facility mounted on the overhanging portion.
2. The offshore work facility according to claim 1, wherein the deck further includes a second overhanging portion configured as a floating structure.
3. The offshore work facility according to claim 2, wherein the second projecting portion is formed to project from the main deck portion so as not to exceed the width of the main deck portion.
4. The second projecting portion is formed by projecting from the projecting portion in such a shape that the shape combined with the main deck portion is a ship shape whose width is widened in a direction from the bow side toward the stern side. The offshore work facility according to 3.
5. The deck includes a top wall, a bottom wall, an outer peripheral wall, and a partition wall, and an inner space is formed in the deck by the top wall, the bottom wall, and the outer peripheral wall, and the inner space is divided into a plurality of sections by the partition wall. The offshore work facility according to any one of claims 1 to 4, which is divided.
6. The offshore of claim 5, further comprising a second ceiling wall disposed above the ceiling wall, a second outer peripheral wall and a second partition wall that support the second ceiling wall with a space from the ceiling wall. Work equipment.
7. A manufacturing method of offshore work equipment,
   Three or more pedestal columns, the pedestal column is disposed, and a main deck portion supported to be movable up and down with respect to the pedestal column, a cantilever supported on the main deck portion via a support structure, and the cantilever Preparing a jack-up type drilling rig having a drilling facility,
   Removing the cantilever and the drilling equipment from the jack-up drilling rig;
   A method of manufacturing an offshore work facility, comprising: adding an overhang portion formed by overhanging from the main deck portion to the main deck portion using the support structure; and mounting a crane on the overhang portion.

Images