Development of Asphaltenes-Triggered Two-Layer Waxy Oil Gel Deposit under Laminar Flow: An Experimental Study

Yang, Fei; Cai, Jinyang; Cheng, Liang; Li, Chuanxian; Ji, Zhongyuan; Zhao, Yu-Guo; Zhang, Guangzheng

doi:10.1021/acs.energyfuels.6b01482

Cited by 48 publications

(43 citation statements)

References 59 publications

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“…And the relationship between the thickness of deposition layer and time was explored. Chuanxian et al , studied the influence mechanism of asphaltene on the gelation and deposition behavior using the Couette deposition experimental device. It was found that the associated particles of asphaltene could accumulate in the inner wax deposition layer through Brownian motion and participate in the process of wax crystallization and precipitation, which would improve the waxy crystals’ structure and result in the higher structural strength of the inner deposition layer than that of the outer layer.…”

Section: Introductionmentioning

confidence: 99%

Molecular Dynamics Simulation of Waxy Crude Oil Multiphase System Depositing and Sticking on Pipeline Inner Walls and the Micro Influence Mechanism of Surface Physical–Chemical Characteristics

et al. 2021

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For ensuring the safe and stable operation of waxy crude oil pipeline transportation, in this research, the molecular dynamics model was established to characterize the deposition and wall sticking behavior of waxy crude oil multiphase system pipeline transportation. The equal density interpolation fitting method was proposed to determine the wall contact angle of simulation results. Through verification, the error between the simulation results and the experimental results measured by Dos Santos et al. (2006) was less than 5%, which showed that the established model was accurate and reliable. Using the established model, the deposition and wall sticking behavior of waxy crude oil nucleated clusters was simulated. It was found that the nucleated clusters would first adhere to the wall surface to form the solidified oil layer. Then, the wax and asphaltene molecules would diffuse to the deposit layer, and the oil molecules in the solidified oil layer reverse diffused to the direction of the oil flow. With the adhering and spreading degree of clusters on the wall surface increasing, the deposit layer gradually aged, and the gelled deposit layer with a higher density and hardness would form. On this basis, the micro influence mechanism of the surface free energy was studied. It was found that the higher the surface free energy, the more hydrophilic the pipeline wall was, and the higher the adhesion degree would be. Moreover, based on the ABF sampling and the potential of mean force calculations, the selective deposition process of waxy crude oil deposited on the sedimentary layer was studied. The micro information on the deposition sites, the binding conformation, and the binding energy of different molecules in clusters deposited on different molecules in sedimentary layer were analyzed. The investigations in this study could provide theoretical support for paraffin removal and control, which could ensure the safe and stable operation of the waxy crude oil production system.

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Section: Introductionmentioning

confidence: 99%

Molecular Dynamics Simulation of Waxy Crude Oil Multiphase System Depositing and Sticking on Pipeline Inner Walls and the Micro Influence Mechanism of Surface Physical–Chemical Characteristics

et al. 2021

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“…[18,72] 4.4 | A model for deposit aging: shear deformation of a cubical cage A number of studies have reported that, with time and under shear stress, the incipient gel-like structure undergoes compositional changes through a process called deposit aging. [33,50,54,[75][76][77][78]93,[129][130][131][132][133] During deposit aging, the concentration of lighter paraffins in the deposit decreases with time and that of the heavier paraffins increases. Experimental results have shown that a harder deposit, with a lower fraction of the entrapped oil, is formed under higher shear rates.…”

Section: Modelling Of Pipeline Flow Shut-downmentioning

confidence: 99%

A review of heat‐transfer mechanism for solid deposition from “waxy” or paraffinic mixtures

et al. 2020

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Summarized in this review are a large number of experimental and modelling studies for advancing the heat-transfer-based mechanism for solid deposition from "waxy" or paraffinic oils and mixtures. This comprehensive heat-transfer approach is entirely different from a more popular molecular-diffusion mechanism. It has evolved from numerous publications, over three decades, which explored topics related to thermodynamic, rheological, crystallization, solid deposition, and shutdown and deposit-aging behaviour of prepared multicomponent paraffinic mixtures of varying compositions to simulate "waxy" crude oils. These investigations covered a wide range of compositions, temperatures, and cooling rates-under static, sheared, laminar and turbulent conditions-in both the hot and cold flow regimes. The heat-transfer mechanism for wax deposition is based on (partial) freezing or liquid-to-solid phase transformation process, for which steady-state and unsteady-state mathematical models have been developed and validated with extensive laboratory data. Furthermore, a shear-induced deformation model for the deposit aging phenomenon has been developed and validated; it is based on a partial release of the liquid phase from the incipient gel, thereby causing an enrichment of heavier alkanes and a corresponding depletion of lighter alkanes in the deposit. A successful analogy with the ice deposition process has confirmed the wax deposition process to be also controlled by heat transfer, without involving any other mechanism for wax deposition. All of these previous studies confirm that wax deposition is predominantly a thermally driven process. K E Y W O R D S aging, cold flow, heat transfer, solid deposition, waxy crude oil 1 | INTRODUCTION Crude oils are complex mixtures of hydrocarbons, including high molar mass alkanes or paraffins, which are referred to as waxes. Waxes contain carbon numbers ranging from 18-65. [1] Crude oils that contain a significant proportion of high molecular weight paraffins or waxes are referred to as paraffinic or "waxy" crude oils. Waxes tend to crystallize and deposit on cooler surfaces because of their decreased solubility in the crude oil at lower temperatures. The highest temperature at which the first crystals start to appear, upon cooling of a "waxy" crude oil, is called the wax appearance temperature (WAT), which is also referred to as the cloud point temperature (CPT). The precipitation and deposition of solids are of significant importance in the production,

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“…However, the inner deposit was very compact and hard and required sharp instruments to scrape it away. Yang et al also investigated the effect of asphaltenes on the stratification in wax deposits (Yang et al 2016). The results showed that there was interaction between asphaltenes and wax molecules, and the asphaltenes were enriched in the wax deposit layer by Brownian diffusion.…”

Section: Effects Of Asphaltenesmentioning

confidence: 99%

Multifunctional anti-wax coatings for paraffin control in oil pipelines

Bai

2019

Pet. Sci.

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Paraffin deposition is a severe global problem during crude oil production and transportation. To inhibit the formation of paraffin deposits, the commonly used methods are mechanical cleaning, coating the pipe to provide a smooth surface and reduce paraffin adhesion, electric heating, ultrasonic and microbial treatments, the use of paraffin inhibitors, etc. Pipeline coatings not only have the advantages of simple preparation and broad applications, but also maintain a long-term efficient and stable effect. In recent years, important progress has been made in research on pipe coatings for mitigating and preventing paraffin deposition. Several novel superhydrophilic organogel coatings with low surface energy were successfully prepared by bionic design. This paper reviews different types of coatings for inhibiting wax deposition in the petroleum industry. The research prospects and directions of this rapidly developing field are also briefly discussed.

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Development of Asphaltenes-Triggered Two-Layer Waxy Oil Gel Deposit under Laminar Flow: An Experimental Study

Cited by 48 publications

References 59 publications

Molecular Dynamics Simulation of Waxy Crude Oil Multiphase System Depositing and Sticking on Pipeline Inner Walls and the Micro Influence Mechanism of Surface Physical–Chemical Characteristics

Molecular Dynamics Simulation of Waxy Crude Oil Multiphase System Depositing and Sticking on Pipeline Inner Walls and the Micro Influence Mechanism of Surface Physical–Chemical Characteristics

A review of heat‐transfer mechanism for solid deposition from “waxy” or paraffinic mixtures

Multifunctional anti-wax coatings for paraffin control in oil pipelines

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