KR101347367B1 - Clamp for pipeline installation in subsea - Google Patents

Abstract

A subsea pipeline mounting clamp is disclosed. Subsea pipeline installation clamp according to an embodiment of the present invention includes one end and the other end, the body which opens in both directions; A fixed bar coupled to the first housing provided at one end of the body; And a fixing pin coupled to the second housing provided at the other end of the body, wherein the fixing pin is fixed to the fixing bar to fasten the body to the pipeline, and reaches a certain depth to move in one direction by water pressure to fix the fixing bar. By releasing the body to be released from the pipeline, the inner peripheral surface of the body may be provided with a cushioning member having an elastic force.

Description

CLAMP FOR PIPELINE INSTALLATION IN SUBSEA}

The present invention relates to a subsea pipeline mounting clamp.

A pipe installation ship (hereinafter referred to as a "ship") moves a coastal or deep sea and lays a pipeline in which a plurality of pipes are connected to the sea floor using a pipe installation system provided in the hull. For example, S-lay, J-lay, Reel-lay, Flex-lay and the like are used according to the method of installing the pipeline on the sea floor.

Among them, for example, the S-lay method is a method in which the pipeline is installed on the sea floor while obliquely descending the pipeline in an S-shape by a stinger of the ship which prevents deformation of the pipe. While the S-lay method is fast to install, the working depth is limited to shallow and medium depth due to the limitation of the working method. At this time, in order to extend the working depth, the length of the stinger to support the load of the pipeline should be increased, or a means for reducing the load of the pipeline to a certain depth should be fastened to the pipeline.

However, since the stinger is usually installed at the stern of the ship, when the length of the stinger is extended, the ship may be balanced by the load of the pipeline. In addition, since the structure of the existing vessel to be designed differently depending on the length or the installation position of the stinger, there may be a cost accordingly.

U.S. Patent No. 4,974,995 describes a method of reducing the load of the pipeline by fastening the pipeline obliquely, such as S-lay, to the pipeline, which is connected to the negative, to the pipeline which is lowered underwater. The technology has been published. This reduces the load on the pipeline and extends the working depth to the deep sea.

However, this conventional technique is difficult to recover and reuse the negative and the fastening means since the negative means are still attached to the pipeline by the fastening means when the negative water is broken.

Patent Document 1: US Patent No. 4,974,995 (December 4, 1990 registration date)

The embodiment of the present invention is connected to the pipeline installed on the seabed to reduce the load of the pipeline by inadvertent, when reaching a certain depth is released from the pipeline to extend the working depth of the subsea pipeline installation To provide an installation clamp.

It is also an object of the present invention to provide a subsea pipeline installation clamp that facilitates recovery and reuse of the negatives and clamps by allowing the clamps to float on the surface with the negatives when released into the pipeline.

According to an aspect of the invention, the body including one end and the other end, open in both directions; A fixing bar coupled to the first housing provided at one end of the body; And a fixing pin coupled to a second housing provided at the other end of the body, wherein the fixing pin fixes the fixing bar to fasten the body to the pipeline, and reaches a certain depth in one direction by water pressure. The fixed bar is moved to release the body so that the body is released from the pipeline, and an inner buffer surface having an elastic force may be provided on the inner circumferential surface of the body.

The buffer member may be formed in a predetermined pattern on the inner circumferential surface of the body.

The shock absorbing member may be formed in a curved shape with a portion in contact with the pipeline.

The cushioning member may be provided in a form in which a curved first buffer member and a second buffer member face each other to form a predetermined pattern.

The fixing pin is coupled to penetrate through the second housing and provided to be in contact with the inside of the second housing, and may be connected to a moving plate that moves the fixing pin in one direction by water pressure when a predetermined depth is reached.

The fixing pin may provide a through hole into which the fixing bar is inserted, and the fixing bar may be inserted through the through hole formed in the fixing pin to be fixed to the lower portion of the fixing pin.

Subsea pipeline installation clamp according to an embodiment of the present invention is fastened to the pipeline to be installed on the seabed to reduce the load of the pipeline by inadvertent, when it reaches a certain depth is released from the pipeline to the work of the subsea pipeline installation You can extend the depth.

It is also possible to facilitate recovery and reuse of the negatives and clamps by allowing the clamps to float above the water with the negatives when released into the pipeline.

Figure 1 shows a vessel for installing the pipeline on the seabed using a subsea pipeline installation clamp according to an embodiment of the present invention.
2 is a perspective view of a subsea pipeline installation clamp according to an embodiment of the present invention.
3 is an exploded perspective view of the clamp of FIG. 2.
4 illustrates a state in which the clamp of FIG. 2 is fastened to a pipeline.
5 illustrates a state in which the clamp fixing bar of FIG. 2 is released from the fixing pin.
6 illustrates a state in which the clamp of FIG. 2 is released from a pipeline.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 shows a vessel for installing the pipeline on the seabed using a subsea pipeline installation clamp according to an embodiment of the present invention.

Referring to Figure 1, the subsea pipeline installation clamp (hereinafter referred to as "clamp") 100 according to an embodiment of the present invention is fastened to the pipe (line) (P) pipeline (P) which is lowered into water Can reduce the load. At this time, the pipeline P is lowered obliquely through the stinger 2 of the ship 1 is installed on the seabed. Hereinafter, the S-lay method will be described as an example of the subsea pipeline installation method, but is not necessarily limited thereto.

In the case of the S-lay method, in order to extend the working depth to the deep sea, it is necessary to reduce the load of the pipeline P to a certain depth where the load of the pipeline P is heavily loaded on the stinger 2. Clamp 100 according to an embodiment of the present invention is connected to the negative (B) to reduce the load of the pipeline (P) which is lowered into the water by the buoyancy of the negative (B). Through this, the working depth of the pipeline can be extended, so that the pipeline can be effectively installed by the S-lay method to the deep sea.

In addition, when the predetermined depth is reached, the clamp 100 is released from the pipeline P and floated to the surface by the negative B. This facilitates the recovery and reuse of the clamp 100 and the negative B. In addition, at a predetermined depth or more, the pipeline P can be installed on the sea floor by its own load, thereby increasing the efficiency of the pipeline P installation. Hereinafter, the clamp 100 described above will be described in detail with reference to FIGS. 2 and 3.

2 is a perspective view of a subsea pipeline installation clamp according to an embodiment of the present invention. 3 is an exploded perspective view of the clamp of FIG. 2.

2 and 3, the subsea pipeline installation clamp according to an embodiment of the present invention is a clamp body 101 (hereinafter referred to as the 'body') that opens in both directions and one end portion 102 of the body 101 It includes a fixing bar 10 coupled to the first housing 110 provided and a fixing pin 20 coupled to the second housing 120 provided at the other end 103 of the body 101.

Body 101 includes one end 102 and the other end 103. The body 101 may be configured to surround the pipeline by one end 102 and the other end 103. Body 101 is provided in a form that is opened in both directions by the coupling member 101a for coupling the one end portion 102 and the other end 103. By the two-way opening of the body 101, the end coupling of the one end 102 and the tartan 103 can be released from the pipeline. At this time, the coupling member 101a may include a hinge or the like. As another example, when the body 101 is provided to have buoyancy, the negative part B may be omitted.

Here, a buffer member 104 having an elastic force is provided on the inner circumferential surface of the body 101. The buffer member 104 may be provided in a form that is variable when the body 101 is fastened to the pipeline P or released from the pipeline P. The buffer member 104 may be formed in a predetermined pattern on the inner circumferential surface of the body 101, and may be fixed by welding or the like.

For example, the shock absorbing member 104 may be fixed to the inner circumferential surface of the body 101 in a form in which a curved first buffer member 104a and a second buffer member 104b face each other and form a predetermined pattern. At this time, the first buffer member (104a) and the second buffer member (104b) is provided with a curved portion of the portion in contact with the pipeline (P).

However, the present invention is not limited thereto. For example, the shock absorbing member 104 may include only the first shock absorbing member 104a or the second shock absorbing member 104b and may be fixed to the inner circumferential surface of the body 101 in a predetermined pattern. In addition, it is obvious that the shock absorbing member 104 may be provided in various shapes. The buffer member 104 may be implemented with a leaf spring or the like.

As such, the buffer member 104 is provided on the inner circumferential surface of the body 101, and when the body 101 is fastened to the pipeline P, the buffer member 104 is varied according to the diameter of the pipeline P. It can be usefully used for the installation of pipelines of various diameters (P).

In addition, when the body 101 is released from the pipeline P, the shock absorbing of the pipeline P due to the rapid release of the body 101 by the buffer member 104 to mitigate the impact on the pipeline to the seabed (P) can be installed safely.

The fixing bar 10 is rotatably coupled to the upper portion of the first housing 110 provided at one end 102 of the body 101 by the coupling member 10a. Here, the first housing 110 is provided with a puncher 30 for applying a force to the fixed bar 10 by the elastic force, and an elastic member 31 provided below the puncher 30 and applying an elastic force to the puncher 30. It is included inside. Here, the elastic member 31 may include a leaf spring or the like. The first housing 110 is formed with a locking groove 110a into which the fixing pin 20 to be described later is inserted. At this time, the puncher 30 is maintained in an isolated state by the fixing pin 20 inserted into the locking groove 110a. In addition, the puncher 30 is released when the fixing pin 20 is released from the locking groove 110a is applied to the fixing bar 10 by the elastic force.

The fixing bar 10 is inserted through the through hole 21 formed in the fixing pin 20 to be described later is fixed to the lower portion of the fixing pin 20. The fixing bar 10 may have a protrusion 11 to be caught by the fixing groove 22 provided below the fixing pin 20. The fixing bar 10 may be provided in a shape bent more than once.

In addition, the negative (B) may be connected to the upper portion of the fixing bar (10). At this time, when the body 101 is lowered by being fastened by the buoyancy force of the negative B to the fixing bar 10 fixed to the lower part of the fixing pin 20, the pipeline 101 is lowered, In spite of hydraulic pressure, the fixing bar 10 is not easily released from the fixing pin 20. By doing so, the body 101 is moved to the state coupled to the pipeline P to a certain depth, thereby effectively reducing the load of the pipeline (P), it is possible to reduce the defective rate of the product. This negative (B) causes the body 101 to rise in the upward direction when the body 101 is released from the pipeline (P). In another embodiment, the negative part B may be connected to one or more specific parts of the body 101, for example.

 The fixing pin 20 is coupled to the second housing 120 provided at the other end 103 of the body 101. Fixing pin 20 is fixed to the fixing bar 10 to fasten the body 101 to the pipeline (P). To this end, the fixing pin 20 provides a through hole 21 into which the fixing bar 10 is inserted, and the fixing bar 10 is inserted into the fixing bar 10 through the through hole 21 formed in the fixing pin 20. 10 to be fixed to the bottom of the fixing pin (20). At this time, the fixing pin 20 is provided with a fixing groove 22 in the lower, so that the projection 11 of the fixing bar 10 is caught in the fixing groove 22 to be fixed.

In addition, the fixed pin 20 is moved in one direction by water pressure when reaching a certain depth to release the fixing bar 10 to release the body 101 from the pipeline (P). The fixing pin 20 is coupled through the through hole 120a of the second housing 120. Then, the second housing 120 is provided in contact with the inside, and reaches a predetermined depth is connected to the moving plate 24 for moving the fixing pin 20 in one direction by water pressure.

Here, the inside of the second housing 120 may be filled with air in a watertight state, it may be compressed by the moving plate 24 to move by water pressure when a certain depth is reached. The fixing pin 20 moved in one direction by the moving plate 24 releases the fixing bar 10. Hereinafter, a method of fastening the clamp 100 to the pipeline P and a method of disengaging the clamp 100 from the pipeline P will be described based on FIGS. 2 and 3.

4 illustrates a state in which the clamp of FIG. 2 is fastened to a pipeline. 5 illustrates a state in which the clamp fixing bar of FIG. 2 is released from the fixing pin. 6 illustrates a state in which the clamp of FIG. 2 is released from the pipeline.

Referring to FIG. 4, in order to fasten the body 101 to the pipeline P, the fixing bar 10 is inserted through the through hole 21 formed in the fixing pin 20 to lower the fixing pin 20. Is fixed to. Here, the protrusion 11 of the fixing bar 10 is fixed to the fixing groove 22 provided in the lower portion of the fixing pin 20. At this time, the fixing pin 20 is inserted through the locking groove 110a and coupled to the first housing 110, and the puncher 30 is isolated when the fixing pin 20 is inserted into the locking groove 110a. Is maintained.

As such, when the body 101 is fastened to the pipeline P, the buffer member 104 provided on the inner circumferential surface of the body 101 is pressed by the pipeline P. This allows the clamp 100 to be usefully used for installing pipelines P of various diameters. In a state where the body 101 is fastened to the pipeline P, the shock absorbing member 104 exerts a constant elastic force on the pipeline P.

Referring to FIG. 5, when the body 101 reaches a certain depth in a state in which the body 101 is fastened to the pipeline P, the moving plate 24 is moved in one direction by the water pressure of the seawater flowing into the second housing 120. It is pushed out. The fixing pin 20 is moved in one direction by the movement of the movable plate 24, and the fixing bar 10 is released from the fixing pin 20. Here, the protrusion 11 of the fixing bar 10 fixed to the fixing groove 22 provided in the lower portion of the fixing pin 20 is released. At this time, the puncher 30 in which the fixing pin 20 is inserted into the locking groove 110a and isolated is released by being released from the locking pin 110a. The puncher 30 exerts a force on the fixing bar 10 by the elastic force. This is to help the fixing bar 10 released from the fixing pin 20 to be quickly and completely released through the through hole 21 of the fixing pin 20.

At this time, when the fixing bar 10 is released by being released from the fixing pin 20 and then the body 101 is released from the pipeline P, a shock absorbing member that has applied a constant elastic force to the pipeline P ( 104 is to mitigate the impact the pipeline (P) due to the rapid release of the body 101. That is, when the body 101 which was reducing (supporting) the load of the pipeline P by buoyancy is released from the pipeline P, the load of the pipeline P is rapidly increased. At this time, the shock absorbing member 104 absorbs the impact (energy) received by the pipeline P by reducing the rapid increase in the load of the pipeline P by the elastic force. Through this, the pipeline (P) can be safely installed on the sea floor.

Referring to FIG. 6, when the fixing bar 10 is released from the fixing pin 20 and released, the body 101 is opened in both directions and released from the pipeline P.

Here, the body 101 is floated upward by the negative portion B connected to the fixing bar 10. Through this, the recovery and reuse of the clamp 100 that rises to the surface by the negative (B) can be effectively made.

The foregoing has shown and described specific embodiments. However, it is to be understood that the present invention is not limited to the above-described embodiment, and various changes and modifications may be made without departing from the scope of the technical idea of the present invention described in the following claims It will be possible.

10: fixing bar 20: fixing pin
30: Puncher 24: Moving Plate
100: clamp 101: body
104: buffer member 110: first housing
120: second housing B: negative
P: pipe

Claims (6)

In the subsea pipeline installation clamp is fastened to the pipeline to be installed on the seabed, and reduces the load of the pipeline by the negative,
A body including one end and the other end and opened in both directions;
A fixing bar coupled to the first housing provided at one end of the body; And
And a fixing pin coupled to the second housing provided at the other end of the body.
The second housing is provided with a moving plate connected to the fixing pin and pushed in one direction by the water pressure of the seawater flowing into the second housing when the predetermined depth is reached.
The fixing pin fastens the fixing bar to fasten the body to the pipeline, and when the water reaches a predetermined depth, the fixing pin is moved by the moving plate pushed in one direction by the water pressure to release the fixing bar to fix the body. To be released from
The inner circumferential surface of the body is in contact with the pipeline, the clamp for installation of the subsea pipeline provided with a cushioning member having an elastic force. delete The method of claim 1,
The buffer member is a subsea pipeline installation clamp consisting of a curved surface portion in contact with the pipeline. The method of claim 3,
The buffer member is a subsea pipeline installation clamp comprising a first buffer member and a second buffer member disposed to face each other on the inner peripheral surface of the body. The method of claim 1,
The fixing pin is coupled to penetrate through the second housing and provided to be in contact with the inside of the second housing. The method of claim 1,
The fixing pin provides a through hole through which the fixing bar is inserted,
The fixing bar is inserted through the through hole formed in the fixing pin is a clamp for installation of the subsea pipeline fixed to the lower portion of the fixing pin.

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