The present invention relates to an underwater trenching system, and more particularly, to a trench making equipment that enlarges an underwater trench for burying a pipeline.
Many oil and gas production sites require installation of miles of pipelines for delivery of the produced material to a refinery or other destination. Often times, the pipelines are laid underwater, especially in shallow coastal waters. The pipes are usually buried at the bottom of a waterway, such as a river, marsh, or sea. In some locations, the pipes are simply laid along the bottom of a waterway and left exposed, to be buried by the action of the currents. In other uses, a trenching tool, such as a water jet, a cutter head, or a scoop, or clam shell digger digs a trench around the pipe, which then settles into the trench.
The bottom sediment eventually settles around the pipe although a large portion of it is carried to other areas of the waterway. The time when the sediment remain in suspension varies although it is known to have a potential for creating serious environmental damage to plants, animals, marine life, and the water. Over time, the sediment has a tendency to shift the pipeline, which causes it to rise from the bottom or from the trench. Current governmental regulations prohibit disturbing the waterway bottom for the second time, such that digging out the original trench for adjusting position of the pipeline is not a viable option. As a consequence, the only viable alternative is to excavate the side of the trench near the bottom and cause the pipeline to drop into the new indentation in the soil.
In short, all currently known equipment and methods for underwater trenching create large clouds of silt and debris that remain in suspension for a long time and seriously disrupt the ecology of the waterway. Reforming the trench by additional excavation of the bottom is not allowed.
There exists therefore a need for an underwater trenching system that avoids bottom trenching, while achieving the goal of lowering the pipeline into a trench without excavating the bottom of the trench.
It is therefore an object of the present invention to provide an underwater trenching system that is capable of evacuating sediment from a side of the trench without substantially disturbing the soil.
It is another object of the invention to provide an underwater trenching system that allows the pipe to settle back into the trench.
It is a further object of the present invention to reduce the time and cost of trenching by omitting the necessity to employ underwater divers.
These and other objects of the invention are achieved through a provision of an underwater trenching apparatus for repairing a trench formed in a bed of a waterway, within which a pipeline is located. The trenching apparatus comprises an elongated boom assembly having a proximate end configured for hingedly securing to a side of a floating vessel, such as a barge. A trenching unit is secured to a distal end of the boom assembly and moves between an above-water position and an underwater position with the help of a lifting means positioned on the deck of the barge, such for instance a lifting crane, a cable of which is detachably secured to the boom assembly.
The trenching unit comprises a pair of spaced-apart opposing sparge assemblies that deliver water and air under pressure to the trench where the pipeline is located. The water and air disturb the underwater formation and move the disturbed sediment or loose formation away from the pipeline in the trench. An elongated conduit admits the sediment through a bottom inlet opening and discharges the sediment through an upper outlet opening. An airlift unit mounted inside the tubular member is connected to an above-water air supply. The airlift unit creates turbulence inside the tubular member, causing sucking of the sediment into the tubular member and lifting the sediment and water toward the discharge opening.
Reference will now be made to the drawings, wherein like parts are designated by like numerals, and wherein
Turning now to the drawings in more detail, the system of the present invention is designated by numeral 10. The system 10 comprises an elongated boom assembly 12, a proximate end 14 of which is secured to a barge 16 or other suitable vessel. Conventional trenching equipment is usually centered on the barge. The system 10, in contrast, is positioned on a side of the barge, with the boom assembly 12 secured to the starboard 20 of the barge 16. Of course, the boom assembly 12 may be also secured to the port of the barge hull, depending on the location of the pipeline in the waterway. In
The proximate end 14 boom assembly 12 is hinged to a hinge plate 18, which can be formed from a length of an I-beam, attached to the starboard 20. The hinge plate 18 extends substantially horizontally, transversely to the starboard 20 and suspends the boom assembly 12 off the side of the barge 16. The boom assembly 12 can move up and down in relation to the hinge plate 18. A support bracket 22 supports the hinge plate 18 from below and absorbs some of the vertical and horizontal forces applied to the hinge plate 18 when the boom assembly 12 moves between a transport position shown in
A distal end 26 of the boom assembly 12 is selectively secured to a lifting means 30, which can be a deck crane, positioned on the deck 32 of the barge 16. A lifting cable 34 detachably secures the boom assembly 12 to the lifting crane 30 to raise and lower the boom assembly 12. The distal end 26 of the boom assembly 12 carries a trenching unit 40 that is lowered below the waterline 42 to reach the mud line 46.
The boom assembly 12 comprises a pair of elongated beams 48, 50 which are spaced from each other and are retained in a substantially parallel relationship by a plurality of transverse braces 54 and diagonal braces 56. A mesh walkway 60 is secured between the beams 48, 50, allowing operators to access the trenching unit 40 and to measure the depth, at which the pipeline 62 extends below the mud line 46. The depth measuring can be conducted using conventional devices that are well known in the industry and are not part of the instant invention.
Mounted on the deck 32 of the barge 16 is water and air supply units that deliver water under pressure and pressurized air to the trenching unit 40. As can be seen in
The trenching unit 40 comprises a pair of sparge units 80, 82 that are connected to a single manifold 84 that supplies water under pressure through manifold connectors 86, 88, 90, and 92. Only two manifold connectors are active at a particular time during operation of the trenching unit 40. Depending on the diameter of the pipeline 46 and the width of the desired trench, the trenching unit can be connected, through the manifold connectors to either two adjacent manifold connectors or to a pair of further spaced-apart manifold connectors. In the example illustrated in
The sparge units 80 and 82 are mirror images of each other. Each of the sparge units comprises a tubular conduit 94 that has a first inlet portion 96, 98, respectively, and a second discharge portion 102, 104, respectively. The discharge portions 102, 104 are oriented at an angle to longitudinal axes of the first inlet portions 96, 98. The outlet openings of the second discharge portions 102, 104 are oriented in opposite directions so that effluent is discharged away from the pipeline 46.
The air supply conduit 68 is secured to the side of the first inlet portion 98 for delivering pressurized air to the interior of the first inlet portion 96. Mounted inside the first inlet portion is an airlift insert 106 that has exterior dimensions slightly smaller than the interior of the first inlet portion conduit 98. The insert 106 is secured inside the conduit defined by the first inlet portion and has a flared inlet opening 108.
A plurality of openings 110 is formed in the walls of the insert 106 allowing air delivered through the air conduit 68 to enter the interior of the insert 106 and create turbulence inside the insert 106. The turbulent flow carries the sediment, as will be explained in more detail hereinafter, toward the second discharge portion 102 and ultimately—to the discharge opening 112 of the second discharge portion 102. As shown in
The openings 110 are preferably formed at an angle to the longitudinal axis of the insert 106, as shown in
Each sparge unit 80, 82 is provided with a sparge conduit 120, 122, respectively. The sparge conduits 120, 122 are connected to the manifold 84 through manifold connector flanges 124, 126. Each sparge conduit 120, 122 is provided with a plurality of discharge nozzles 128, 130 that jet pressurized water/air mixture into the waterway bed 140 in the area adjacent the pipeline 46. The nozzles 128, 130 are detachably mounted in the corresponding openings formed in the wall of the sparge conduits 120, 122.
Each nozzle has exterior threads 131 that allow the nozzle to be threaded into the opening in the wall of the sparge conduit. An inlet opening 132 of the nozzle 128 (or 130) has a generally conical configuration, as can be seen in more detail in
The disturbed sediment is sucked into the bottom opening 146 of the first inlet portion 98 and moves through the insert 106 under the force of the flow created by the incoming air flow. Some of the water moving through the sparge conduit 120 is diverted to the first inlet portion 98 below the airlift insert 106 by a pair of water hoses, or pipes 148, 150 to facilitate movement of the sediment through the trenching unit 40. The sediment can be discharged to the waterway bed 140 above the mud line 46 or, if the trench is shallow—even to the banks of the waterway.
To ensure alignment of the trenching unit 40 with the pipeline 46, the trenching unit 40 is provided with a guiding means, which comprises a plurality of rotating guiding rollers. A transverse roller 152 is secured between the sparge conduits 120, 122 at a position downstream from the inlets openings of the sparge conduits 12, 122. In the embodiment shown in
A pair of vertical guiding rollers 154, 156 is positioned in a general vertical alignment with the first inlet portion 96, and a similar pair of vertical guiding rollers 158, 160 is positioned in a general vertical alignment with the first inlet portion 98. The rollers 154, 156, 158, and 160 prevent the trenching unit 40 from significantly deviating from the dimensions created by the sides of the trench, where the pipeline 46 is located. The distance between the rollers 154, 156 and 158, 160 is selected to conserve energy and enlarge the trench 142 only as necessary for the pipeline 46.
The barge 16 can be propelled by a tug boat 170 shown in phantom line in
If desired the nozzles 128, 130 can be strategically spaced along the length of the inlet portions such that the majority of the nozzles are located closer to the bottom of the trench, while fewer nozzles are located in an area that would be approximately above the pipeline 46. The depth of the pipeline 46 embedment can be measured prior to lowering the trenching unit 40 into water.
The barge 16 is propelled along the waterway at a desired speed, allowing the sparge units 80, 82 to disturb underwater sediment and for the airlift force to lift the disturbed sediment away from the trench. The actual speed of travel depends on the condition of the waterway bed. Naturally, slower speed will be necessary where there exists clay bottom than where the bed is sandy. It is envisioned that a land vehicle may be employed for transporting the trenching apparatus of the present invention. Depending on several factors, such as the width of the waterway, the location of the pipeline and the depth, at which the pipeline is buried the land vehicle with the boom assembly mounted thereon may be employed.
Many changes and modifications can be made in the design of the present invention without departing from the spirit thereof. I therefore pray that my rights to the present invention be limited only by the scope of the appended claims.
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Number | Date | Country | |
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20090274520 A1 | Nov 2009 | US |