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Founded in 1983, the last 25 years has seen Whittaker Engineering develop into a respected and reliable contributor to the North Sea oil industry. Whittaker Engineering provides in-house manufacturing, engineering design and analysis for the offshore oil and gas industry. Their highly skilled engineers are able to create innovative and unique solutions that are tailored to individual circumstances.
Many mature oil fields use compressed gas to force the oil out of the underground oil bearing strata, the gas is compressed using reciprocating piston gas compressors. The gas flows through a scrubber to remove liquids out of the gas before it enters the gas compressors and immediately before the gas compressors the gas flows through a pulsation damper to reduce the gas velocity and smooth out the flow. Whittaker Engineering was asked to design and manufacture nozzles to fit inside the damper to ensure that no liquids made their way through the damper outlets into the compressors. A drain was then fitted with an outlet pipe to a collection bottle to gather any liquids found, as liquids in a gas compressor can have serious effects to the mechanical parts of a compressor.
IDAC were contracted to verify and modify the design of the outlet nozzles by taking all the output data from the compressors and simulating the gas flow using CFD techniques. The work was carried out in two parts as follows:
The geometry of the gas damper comprises of a cylinder with two outlets at the bottom and one inlet at the side. The graphic to the left shows the half symmetry model and a typical flow path through the structure.
The geometric model was defeatured using ANSYS DesignModeler and then meshed using prisms and tetrahedral meshes. A boundary layer mesh, based on the global length scale Reynolds number was also placed on the walls. Using the volumetric mesh, a transient solve was set up in CFX-Pre using a single-phase fluid, properties of which were specifically created to model the saturated gas.
The CFD domain was set up to run with the same atmospheric pressure as when in operating conditions, with pressure and mass flow boundary conditions defined at the outlets and inlet. Other details pertinent to the analysis are listed below:
The original design showed unequal velocities and mass flow rates through each outlet. The flow was biased towards Outlet 1, rather than making it all the way to Outlet 2 as seen in the graphic above. In order to force the flow onto Outlet 2, the geometry was changed, such that each outlet protruded further into the cylinder.
On analysing the new model, it was found that both outlets were performing better in terms of 'sharing' the total fluidic loading. As seen in the images below, when each outlet is opened to its maximum flow rate condition, both situations show similar mass flow rate values exiting the gas damper.
The down time of the compressors had direct financial implications. To reach a quick and effective solution, it was decided to conduct a CFD analysis, as several models could be created, edited and run at the same time. Once the basic model had been established and verified, changing the geometry marginally, while keeping all other parameters constant meant very little time was needed for each different set-up. This meant more time was dedicated to analysis solving and post processing. The client also gained further understanding into some of the other issues surrounding the old design, such as unequal mass flow rates between the two outlets.
With both outlets performing equally in the new design the compressors downstream of the gas damper were also being stressed equally. Having met the design criteria, the redesigned gas damper is once again operational onboard a vessel in the North Sea.
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