KR20160000710U - Subsea pipeline installation spool distance measuring device - Google Patents

Abstract

The present invention relates to a submarine pipeline spool installation distance measuring device, and more particularly, to a submarine pipeline spool installation distance measuring device for easily and accurately measuring the distance and angle between pipelines for installing a spool on the seabed. .
For this purpose, a submarine pipeline consisting of a flange and a pipe is formed, and a gap is formed between the submarine pipelines and the other submarine pipelines to form spools. A pair of submarine pipeline spool installation distance measuring devices respectively installed in the submarine pipelines facing each other for measuring the interval, the coupling device comprising: a coupling portion coupled to the flange of the submarine pipeline, A horizontal table having a horizontal surface and a slit formed at a distal end thereof, a hinge coupled to a distal end of the horizontal table and pivoted in an upward and downward direction, and an arc- And at a position inwardly spaced from the printed angle, An angle indicating member that flows along the angle measuring hole and directs toward an angle, and is fixed to the rotating table and is moved upward and downward through the slit by rotation of the rotating table, A vertical angle member formed in an arc shape along the rotation radius of the rotary table and having an angle printed thereon, a sheave provided on any one of the pair of horizontal tables facing each other, the wire being wound, Wherein the wire is fixed to another pivot table after being connected to the angle indicating member of another pivot table through an angle indicating member of the pivot table.

Description

{Subsea pipeline installation spool distance measuring device}

The present invention relates to a submarine pipeline spool installation distance measuring device, and more particularly, to a submarine pipeline spool installation distance measuring device that can easily and accurately measure distances and angles between pipelines for spool installation.

Natural gas or crude oil mined from the seabed is transported to a landfill, marine platform or floating storage facility (SPM or CALM Buoy) via pipelines installed on the sea floor.

Subsea pipelines are installed to connect to landfill, marine platforms or floating storage facilities, and are available in lengths ranging from tens to hundreds of kilometers.

At this time, the submarine pipeline as described above is formed by combining tens of thousands of unit pipes of about 12 m, and each unit pipe is sequentially welded and extended on the barge.

For example, in a conventional method for installing a submarine pipeline, a relatively short length pipe manufactured on the land is moved to the sea using a sea operation line (laying line, laying line), welded to a short length pipe, The lay barge method is a typical method in which the pipeline is submerged while moving the line.

On the other hand, pipelines installed on the sea floor and pipelines connected to onshore refineries, marine platforms or floating storage facilities such as riser pipes, tie-in spools, jumper pipes, etc. It is a matter of course to measure the distance between the pipelines of the seabed as shown in Fig.

In order to measure the distance of the installation section between pipelines, a diver can directly measure the installation section distance of the pipeline by using a hand tool such as a tape measure, a piano cord, a steel wire, In deep water depths, the ROV (Remotely-Operated Vehicle) measures the distance using an underwater sounding instrument LBL (Long Base Line).

Thereafter, the length of the pipeline installation section can be known by measuring the length of the hand tool after lifting the hand tool with the land.

Thereafter, a spool suitable for the length of the pipeline installation section is manufactured, the produced spool is lowered to the sea floor by using a floating crane or a winch, and then the pipeline is connected to the pipeline.

However, the conventional method of measuring the spool installation section length between the pipelines has the following problems.

In low-lying shallow seas, the diver directly measures the distance between the pipes by using hand tools such as tape measure, piano wire, steel wire, etc., in order to prevent the diver from pulling the string or measuring the weight of the string itself, The distance measurement using the LBL for underwater acoustic wave measuring instruments takes a long time to calibrate the physical characteristics (water temperature, salinity) of the seawater, There has been a problem that a measurement error occurs according to the correction value.

In addition, there is a method of measuring the distance between pipelines by taking the coordinates on the seabed using GPS, but this also causes a problem that the accuracy of measured values is lowered due to the occurrence of errors.

If an error in distance measurement occurs, the spool must be made longer or shorter than the length of the spool to be actually manufactured.

If the spool having the incorrect dimension is installed as described above, there is a problem that the gas or crude oil leaks from the connection portion. If the spool is newly manufactured, the pipeline construction period is increased, There is a problem that economical efficiency is low.

Republic of Korea Publication No. 10-2013-0004679

It is an object of the present invention to provide a submarine pipeline spool distance measuring device for easily and accurately measuring distances and angles between pipelines for installing a spool on the sea floor .

In order to achieve the above object, the present invention proposes a submarine pipeline consisting of a flange and a pipe, forming a channel through which crude oil and natural gas mined from the sea bed are transferred, A pair of subsea pipeline spool installation distance measuring devices formed at intervals for installing the spools and respectively installed in the subsea pipelines facing each other for measuring the spacing, the apparatus comprising: a coupling unit coupled to a flange of a submarine pipeline, respectively; A horizontal table formed on each of the coupling parts and having a horizontal surface with the sea bottom pipeline and having a slit at the front end thereof, a hinge coupled to a distal end of the horizontal table to rotate upward and downward, ) Is formed at an angle with respect to a position spaced inward from the angle at which the angle is printed and printed along the leading edge An angle indicating member that flows along the angle measuring hole and directs toward an angle, an angle indicating member which is fixed to the rotating table, and which is rotated by the rotation of the rotating table, A vertical angle member which is formed in an arc shape along the rotation radius of the rotary table and moves downwardly and on which an angle is printed, a vertical angle member installed on a horizontal table among the pair of facing horizontal tables, Wherein the wire is connected to the angle indicating member of another pivot table through an angle indicating member of the pivot table, and then fixed to another pivot table.

The engaging portion may include a first engaging portion that is bolted to the flange and a second engaging portion that surrounds a portion of the body and guides the engaging position of the first engaging portion.

The angle indicating member may include an arrow indicating an angle printed on the rotary table and a split bolt penetrating the arrow through the angle measuring hole and being moved along the angle measuring hole. It is preferable to form the dividing holes by dividing into both sides so that the through holes can pass.

The pair of pivot tables facing each other preferably further include a guide member for guiding the wire passing the pivot table and a fixing member for fixing the wire to the pivot table.

The apparatus for measuring the installation distance of a subsea pipeline spool according to the present invention has the following effects.

The distance between the pipelines for installing the spool can be easily measured, thereby improving the workability.

In particular, the accuracy of the distance measurement between pipelines can be increased, so that spool manufacture and construction can be completed at once.

Accordingly, it is possible to prevent the occurrence of air delay due to the reinstallation operation and to reduce the increase in the operation cost, thereby improving the economical efficiency.

1 is a conceptual diagram showing a state in which a distance and an angle for installing a spool are measured between subsea pipelines
2 is a perspective view showing a state in which a submarine pipeline spool installation distance measuring apparatus according to a preferred embodiment of the present invention is installed in a submarine pipeline;
3 is a plan view showing a state in which a submarine pipeline spool installation distance measuring apparatus according to a preferred embodiment of the present invention is installed in a submarine pipeline;
4 is a side view showing a state in which a submarine pipeline spool installation distance measuring device according to a preferred embodiment of the present invention is installed in a submarine pipeline;

It is to be understood that the words or words used in the present specification and claims are not to be construed in a conventional or dictionary sense and that the inventor can properly define the concept of a term in order to best describe its own design in the best way It should be construed as meaning and concept consistent with the technical idea of the invention.

Hereinafter, a submarine pipeline spool installation distance measuring apparatus (hereinafter referred to as 'measuring apparatus') according to a preferred embodiment of the present invention will be described with reference to FIGS. 2 to 4 attached hereto.

The measuring device has a technical feature that it is possible to easily and accurately measure the distance between the pipelines in order to install a spool between the pipelines installed in the sea bed.

The measuring device is provided in a pair so that it can be used in each of the opposing pipelines and includes a coupling part 100, a horizontal table 200, a rotation table 300, an angle indicating member 400, An angle member 500, and a pulley 600. [

The coupling unit 100 constitutes a part of the measurement apparatus, and the measurement apparatus is coupled to the pipeline 10.

The coupling part 100 includes a first coupling part 110 which is bolted to the flange 11 of the pipeline 10 and a second coupling part 120 which is disposed on the pipe body 12 of the pipeline 10 .

The first engagement piece 110 is a portion that is coupled to the flange 11 through bolts and nuts as shown in Fig.

The second engaging piece 120 is disposed on the tubular body 12 to guide the engaging position of the first engaging piece 110 and is formed to cover a part of the upper portion of the tubular body 12.

Next, the horizontal table 200 is formed on the coupling portion 100 and forms a horizontal surface with the pipeline 10.

At this time, it is preferable that the horizontal table 200 has a rectangular shape.

A slit 210 is formed at the distal end of the horizontal table 200 in a straight line from the distal end toward the horizontal surface of the horizontal table 200.

The slit 210 is a space in which a vertical angle member 500 (to be described later) is disposed and can move upward and downward.

Next, the rotation table 300 allows the horizontal and vertical angles of the pipeline 10 to be measured and is hinged to the distal end of the horizontal table 200.

That is, the rotation table 300 can be rotated in the upward and downward directions about the distal end of the horizontal table 200.

At this time, it is preferable that a rotation guide part 310 for guiding the rotation of the rotation table 300 is further formed on both sides of the horizontal table 200 and the rotation table 300.

The rotation guide unit 310 controls the rotation angle of the rotation table 300 to suppress excessive rotation of the rotation table 300.

A guide hole 312 through which the rotation protrusion 311 formed in the rotation table 300 is moved is formed in the circular rotation guide unit 310 and the guide hole 312 is formed in the circular guide unit 310, Only in half.

The tip of the rotation table 300 is formed in an arc shape, and an angle is printed on the surface of the rotation table 300 along the arc.

The curvature of the arc is a curvature corresponding to a half circle.

An angle measuring hole 320 is formed in a portion of the pivot table 300 that is spaced inward from the printed angle.

The angle measuring hole 320 is a space through which the angle indicating member 400 can be moved along the printed angle to measure the horizontal angle of the pipeline 10, And is formed with a curvature that can be moved along the printed angle.

A guide member 330 or a fixing member 340 is further provided on the rotation table 300.

The guide member 330 is installed in an angle type on a rotation table 300 of a measurement device (hereinafter, referred to as a 'first measurement device') A coupled to a pipeline 10 of the opposing pipeline 10 .

The fixing member 340 is installed in an angle type on a rotation table 300 of a measurement device (hereinafter, referred to as a 'second measurement device B') coupled to another pipeline 10, And the wire passed from the apparatus A is fixed.

Next, the angle indicating member 400 serves to indicate the horizontal angle between the opposing pipelines 10 and is coupled to the angle measuring hole 320 formed in each of the rotation tables 300.

The angle indicating member 400 indicates the angle printed on the tip of the rotation table 300 while moving along the angle measuring hole 320 according to the movement of the wire in accordance with the horizontal angle between the pipelines 10.

The angle indicating member 400 is composed of an arrow 410 indicating a printed angle and a split bolt 420.

The split bolt 420 is nut-coupled at the upper side of the arrow 410 through the bottom surface of the arrow 410 and is also engaged with the wire so that it can be engaged with the wire.

At this time, the split bolts 420 are divided on both sides to form the split holes 421 so that the wires can pass through the split bolts 420.

That is, since the nut and the split bolt 420 are engaged in a state that the wire passes through the split hole 421 of the split bolt 420, the angle indicating member 400 is also interlocked with the movement of the wire.

Next, the vertical angle member 500 serves to measure the vertical angle between the pipelines 10, and is fixed to each of the pivot tables 300.

The vertical angle member 500 moves upward and downward through the slit 210 formed in the horizontal table 200 while interlocking with the rotation of the rotation table 300.

At this time, the vertical angle member 500 also has an arc shape along the rotation radius of the rotation table 300, and an angle is printed on the surface of the vertical angle member 500.

Next, the pulley 600 is a structure in which a wire for measuring the distance and angle between the pipelines 10 is wound, and is installed in the horizontal table 200 of the first measurement apparatus A. [

The wire wound around the pulley 600 as shown in Figure 2 passes through the split bolts 420 of the angle indicating member 400 through the guide member 330 and then passes through the split bolts 420 of the angle indicating member 400, And is fixed to the fixing member 340 through the member 400.

Meanwhile, the pulley 600 is preferably provided with a handle 610 for facilitating winding of the wire.

Hereinafter, the process of measuring the distance and angle between the pipelines for installing the spool between the submarine pipelines using the measuring apparatus having the above-described configuration will be described.

A pipeline 10 is provided on both sides of the space in which the spool is to be installed,

The diver submits to couple the first measurement device A to any pipeline 10A and the second measurement device B to the other pipeline 10B.

At this time, each of the second coupling pieces 120 is in close contact with the tube body 12, and the first coupling piece 110 is bolted to the flange 11, so that the coupling of the measuring device to each pipeline 10 is completed do.

Next, the distance and angle between the pipelines 10 can be measured by loosening the wire wound around the pulley 600 and fixing it to the second measuring device B coupled to the opposite side.

That is, on the basis of the first measuring apparatus A provided with the pulley 600, the wire is unwound toward the left or the right toward the second measuring apparatus B as shown in Fig. 3, The split bolt 420 of the indicating member 400 is moved along the angle measuring hole 320 in the direction in which the wire is released.

At this time, the arrow 410 of the angle indicating member 400 naturally indicates the angle printed on the tip of the rotation table 300, so that the horizontal angle between the pipelines 10 can be known.

Further, as the wire is unwound toward the upper side or the lower side toward the second measuring device B, the rotation table 300 is rotated to the upper side or the lower side of the horizontal table 200 with reference to the hinge as shown in FIG. 4 The vertical angle member 500 fixed to the rotation table 300 also moves upward and downward on the slit 210 while interlocking with the rotation table 300.

At this time, the angle printed on one side of the vertical angle member 500 corresponds to the slit 210 line, so that the vertical angle between the pipelines 10 can be known.

In addition, since the wire connects the measuring devices on both sides, the distance between the pipelines 10 can be known by measuring the length of the wire loosened.

As described above, according to the present invention, the submarine pipeline spool installation distance measuring apparatus can measure the distance and angle between the fir line for installing the spool in the process of installing the pipeline on the seabed so that it can be easily and accurately measured There are technical features.

In other words, each measuring device is installed in the opposing pipeline, and the rotation table of each measuring device is turned while the wire is connected from the measuring device to the other measuring device, and the angle of the wire is naturally measured. And can be done accurately.

Accordingly, it is possible to increase the accuracy of spool manufacture and construction for installing the spool, thereby preventing the occurrence of air delay, thereby preventing the construction cost from increasing.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

100: coupling portion 110: first coupling piece
120: second coupling piece 200: horizontal table
210: Slit 300: Rotation table
310: rotation guide part 311:
312: guide hole 320: angle measuring ball
330: guide member 340: fixing member
400: angle indicating member 410: arrow
420: Split bolt 421: Split hole
500: vertical angle member 600: pulley

Claims (4)

It forms a pipeline through which crude oil and natural gas mined from the sea floor are transported, a submarine pipeline consisting of a flange and a pipe body is provided,
A pair of subsea pipeline spool installation distance measuring devices each having an interval for installing a spool between a submarine pipeline and other submarine pipelines, and each installed in a submarine pipeline facing each other for measuring the interval,
A coupling portion coupled to the flange of the subsea pipeline, respectively;
A horizontal table formed at each of the coupling parts, the horizontal table having a horizontal surface with the sea floor pipeline and having a slit at the front end;
And an arc-shaped tip portion is hingedly coupled to the distal end portion of the horizontal table and rotated in the upward and downward directions. At a position spaced inward from the printed angle at which the angle is printed along the tip portion, A rotation table having an angular measuring ball formed therein;
An angle indicating member which flows along the angle measuring hole and directs toward an angle;
A vertical angle member which is fixed to the rotation table and flows in an upward and downward direction through the slit by rotation of the rotation table, the angle being formed in an arc shape along the rotation radius of the rotation table and printed with an angle;
And a sheave provided on one of the pair of horizontal tables facing the horizontal table and wound with the wire,
Wherein the wire is fixed to another pivot table after being connected to an angle indicating member of another pivot table through an angle indicating member of the pivot table. The method according to claim 1,
The coupling portion
And a second coupling piece for guiding a coupling position of the first coupling piece while surrounding a part of the tubular body. 3. The method according to claim 1 or 2,
The angle-
An arrow indicating an angle printed on the rotation table, and a split bolt penetrating the arrow through the angle measuring hole and being nut-coupled and moved along the angle measuring hole,
Wherein the split bolt is divided on both sides so as to form a split hole so that the wire can pass therethrough. 3. The method according to claim 1 or 2,
Wherein the pair of pivot tables facing each other is further provided with a guide member for guiding the wire passing the pivot table and a fixing member for fixing the wire to the pivot table.

Images