عنوان

An experimental and theoretical investigation of asphaltene precipitation and aggregation kinetics in model oil systems

Number

TL48672

.Language of Text, Soundtrack etc

انگلیسی

Title Proper

An experimental and theoretical investigation of asphaltene precipitation and aggregation kinetics in model oil systems

General Material Designation

[Thesis]

First Statement of Responsibility

Afra Ali Al Meraikhi

Subsequent Statement of Responsibility

Banat, Fawzi

Name of Publisher, Distributor, etc.

The Petroleum Institute (United Arab Emirates)

Date of Publication, Distribution, etc.

2015

Specific Material Designation and Extent of Item

112

Text of Note

Committee members: Al Hassan, Saeed; Al Shoaibi, Ahmed; Kirparissides, Costas; Mittal, Vikas

Text of Note

Place of publication: United States, Ann Arbor; ISBN=978-1-339-52781-9

Dissertation or thesis details and type of degree

M.S.

Discipline of degree

Chemical Engineering

Body granting the degree

The Petroleum Institute (United Arab Emirates)

Text preceding or following the note

2015

Text of Note

Asphaltenes are the heaviest and most complex fraction of crude oil with the highest aromaticity and polarity. They can precipitate at any point of oil production or transportation as a result of changes in temperature, pressure or/and composition. The precipitation and deposition of asphaltenes during oil production and processing can lead to serious problems including plugging of pipelines and production facilities, reduction of storage capacity, equipment fouling, etc. Thus, it can have a serious economic impact on petroleum production and processing. Because of the chemical complexity of asphaltenes, their molecular structure, natural state, association, aggregation etc. are a subject of continuous debate and research efforts. To unravel the key parameters that govern asphaltenes precipitation, numerous studies have been carried out over the past fifty years. It has been shown that the onset of asphaltenes precipitation is a thermodynamic driven process due to asphaltene solubility variation as a result of pressure, temperature and compositional changes [1]. The present Thesis deals with the kinetic investigation of asphaltene precipitation/aggregation from model oils using photon correlation spectroscopy as the detection technique. The asphaltenes used in this study was the pentane insoluble asphaltenes fraction extracted from field deposits. npentane was used as precipitant for inducing asphaltene destabilization and precipitation from model asphaltenes-toluene systems. A series of experiments were carried out with different initial asphaltene concentrations in model oil systems (i.e. 10, 20, 40, 60, and 120 mg of asphaltenes/Liter of toluene) and different toluene/pentane volume ratios. The onset of asphaltene precipitation and dynamic evolution of the effective hydrodynamic diameter of asphaltene aggregates as well as the asphaltene nanoaggregates size distribution were monitored at discrete time intervals with the aid of NanoBrook 90Plus Zeta Particle Size Analyzer instrument for different asphaltene concentrations and n-pentane volume fractions from 50 to 95.24%. The experimental results revealed that as the n-pentane concentration increased the measured effective diameter of asphaltene aggregates exhibited a concave type of functional dependence with respect to the n-pentane volume fraction. In particular, the effective diameter of asphaltene aggregates initially increased with the n-pentane concentration up to a maximum size followed by a decrease in size beyond a critical value of n-pentane concentration (~85-83 % C5). This is a clear indication that depending on the precipitant concentration (i.e. asphaltene and solvent solubility parameters) the contribution of the various asphaltene association/aggregation forces (i.e. Acid-base and hydrogen bonding interactions, formation of metal coordination complexes, steric interactions, π-π stacking interactions, etc.) to the overall asphaltene interaction potential vary leading to the formation of more or less dense assemblies of asphaltene nanoaggregates.

Chemical engineering

Subject Term

Applied sciences;Aggregation and precipitaion kinetics;Asphaltene;Model oil systems;Modeling

Banister, Mustafa

Banat, Fawzi

Subdivision

Chemical Engineering

The Petroleum Institute (United Arab Emirates)

Call Number

1771924240; 10027583

Electronic name

p

[Thesis]

276903

a

Y