Abstract
When crude oil is transported via sub-sea pipeline, the temperature of the pipeline decreases at a deep depth which causes a difference in temperature with the crude oil inside. This causes the crude oil to dissipate its heat to the surrounding until thermal equilibrium is achieved. This is also known as the cloud point where wax begins to precipitate and solidifies at the walls of the pipeline which obstruct the flow of fluid. The main objective of this review is to quantify the factors that influence wax deposition such as temperature difference between the wall of the pipeline and the fluid flowing within, the flow rate of the fluid in the pipeline and residence time of the fluid in the pipeline. It is found the main factor that causes wax deposition in the pipeline is the difference in temperature between the petroleum pipeline and the fluid flowing within. Most Literature deduces that decreasing temperature difference results in lower wax content deposited on the wall of the pipeline. The wax content increases with rising flow rate. As for the residence time, the amount of deposited wax initially increases when residence time increases until it reaches a peak value and gradually decreases. Flow-loop system and cold finger apparatus were used in literature investigations to determine the trends above. Three new models are generated through a regression analysis based on the results from other authors. These new models form a relationship between temperature difference, flow rate, residence time and Reynolds number with wax deposition. These models have high values of R-square and adjusted R-square which demonstrate the reliability of these models.
Highlights
The wax deposition has always been one of the most challenging and long-standing issues faced by petroleum industry when transporting crude oil via sub-sea pipelines
It can be seen that at any residence time, wax deposition decreases at the nearly consistent rate when there is an increase in differential temperature across the pipeline wall and the fluid
This, in turn, causes the wax to precipitate and deposit at the wall of the pipeline. Since this experiment was conducted in a close-loop system, there is no continuous supply of fresh sample causing a depletion in a wax deposition at longer residence time
Summary
The wax deposition has always been one of the most challenging and long-standing issues faced by petroleum industry when transporting crude oil via sub-sea pipelines. For the wax to precipitate, the crude oil has to be at a temperature lower than WAT. This temperature is similar to the freezing point where a liquid or fluid begins to solidify[1, 2]. This causes a shrinkage in flow area of the pipeline deposited wax becomes thicker. The oil droplets eventually lose their flowability, causes blockage in the pipeline and can result in pressure rise Pipelines at an ocean floor experiences temperature of about 4°C and wax molecules begin to precipitate on the pipeline walls due to the cooling of crude
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