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The impact of CO2 injection and pressure changes on asphaltene molecular weight distribution in a heavy crude oil: An experimental study

Sadeqimoqadam, M ; Sharif University of Technology

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  1. Type of Document: Article
  2. DOI: 10.1080/10916460903226155
  3. Abstract:
  4. This work concerns observing the pressure as well as CO2 mole percentage effects on asphaltene molecular weight distributions at reservoir conditions. A high-pressure, high-temperature asphaltene measurement setup was applied, and the amount of precipitated asphaltene at different pressures as well as CO2 mole percentage in an Iranian heavy crude oil was measured. Moreover, the asphaltene molecular weight distributions during titration of crude oil with different n-alkanes were investigated. The gel permeation chromatography (GPC) apparatus was used for characterization of asphaltene molecular weight under different conditions. It has been observed that some thermodynamic changes such as pressure depletion above the bubble point increase the average molecular weight of asphaltene and cause the asphaltene molecular weight distributions changes from a bimodal curve with two maxima to a single maxima curve. One the other hand, below the bubble point, pressure reduction causes a decrease in the average molecular weight of asphaltene and also causes the shape of asphaltene molecular weight distributions to restore, which might be due to dissolution of asphaltene aggregates. An interesting result is that asphaltene molecular weight distribution at the final step of pressure reduction tests, ambient condition, shows approximately the same trend as the distribution of asphaltene molecular weight obtained at reservoir condition. This behavior explains the reversibility of the asphaltene precipitation process under pressure depletion conditions. In the case of CO2 injection, the graphs of asphaltene molecular weight distributions always show a single modal trend and shift toward larger molecular weight values when CO2 mole percentage increases. The results of this work can be imported to thermodynamic models that use polydisperse data of heavy organic fractions to enhance their performance at reservoir conditions. The distributions obtained by this method are good indicators of asphaltene structures at reservoir conditions
  5. Keywords:
  6. Asphaltene ; Ambient conditions ; Asphaltene aggregates ; Asphaltene precipitation ; Average molecular weight ; Bubble points ; CO2 ; Experimental studies ; Heavy crude oil ; High temperature ; Iranian heavy crude oil ; Measurement setup ; Mole percentages ; n-Alkanes ; Organic fractions ; Polydisperses ; Pressure change ; pressure depletion ; Pressure reduction ; Reservoir conditions ; Single-modal ; Thermodynamic changes ; Thermodynamic model ; Chromatographic analysis ; Crude oil ; Dissolution ; Gels ; Molecular weight distribution ; Paraffins ; Polydispersity ; Precipitation (chemical) ; Water injection ; Weighing ; Asphaltenes
  7. Source: Petroleum Science and Technology ; Volume 28, Issue 17 , 2010 , Pages 1728-1739 ; 10916466 (ISSN)
  8. URL: http://www.tandfonline.com/doi/abs/10.1080/10916460903226155