beginning the STU ( Subsea Tensioning Unit ) model subsea tensioners have built in lifting rings. This makes it much easier for them to be secured in place. They might be secured in a basket which is being lowered to the seabed or they might be secured on the flange itself. It will depend greatly on the task at hand. Since divers do not have the same leverage subsea as they would topside, it is important that their tools are easy to use. For model, they could be standing on a soft bottom, swimming or in an awkward position. As a leave, these built-in rings can be very handy.
Subsea tensioners besides have “ Quick Fit Pullers ”. These take the place of the standard threaded pullers. They are split into halves and lock when squeezed together. then, springs inside push the two halves apart again when a unblock is pressed. This main routine of this invention is so that the divers can eliminate the time wasted by threading standard pullers onto bolts. rather, the divers leave the two halves separated and slide it down over the gobble. When the puller gets to the right spot, the diver squeezes the two puller halves together on the abscond and gives it a unmarried turn or two in regulate to make it snug against the tensioner.
Another dispute between subsea and topside tensioners is that the subsea tensioners use holes drilled into the nuts whereas topside tensioners use addict rotating sockets. They both calm use tommy bars but this is another design with the loon in mind. By not needing nut rotating sockets, the divers have fewer components to handle which will again make the job easier. Companies like Direct Bolt and Supply have the capability to drill all sizes of nuts.
finally, the subsea tensioners besides have more stroke duration than the standard topside tensioners. This is designed with the divers and their valuable “ bottom clock time ” in mind. With longer strokes, the tensioners will require fewer actuations and will save clock time when making up the flanges.
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Attached are pictures of a pipeline facility where the subsea tensioners were utilized in the “ ignition line ” of a pipelay barge. In this situation, topside tensioners could have been used on board the gravy boat. however, the decision was made for the subsea tensioners to be used during the grapevine initiation and used for the “ tie in ” exercise arsenic well. What this means is that once the grapevine was installed on the ocean floor from the barge, the subsea tensioners would be taken from the ignition pipeline and given to the divers. The divers would then use those lapp tensioners to install the spool pieces and make the concluding connections on chopine risers. The real advantage to this type of link is to get the Pipelay barge “ off the clock ” and perform the tasks with divers and a diver digest vessel or platform support. The pipelay barge cost is the largest expense related to an initiation and should be minimized. The entirely extra piece of equipment needed to move from working on the pipelay barge to subsea was a longer main trace, high imperativeness hosiery from the pump to the first tensioner. The addition of a hose reel like the XHR1 made the organization of that hose much easier. The customer was able to reduce overall project cost substantially while maintaining schedule .