M. Aikman scite author profile

Starosud

et al. 2001

A fast and accurate method for the group analysis of crude oils in porous media that describes petroleum components (especially heavy fractions) has been developed. NMR structure group analysis is used as the tool for the characterization of crude oils. This method is proposed as an alternative to existing complicated and laborious methods of characterization of extracted oil samples. Currently, group analysis of heavy fractions of crude oils is being investigated by means of chromatographic methods, such as the SARA (saturates-aromatics-resinsasphaltenes) test. These methods are usually expensive, and require considerable work from qualified personnel. Furthermore, these methods cannot be used for estimating the oil components in situ. The basis of determining crude oil components using NMR is the difference of the nuclei mobility in the different hydrocarbons during the NMR testing period. A combination of solvent extraction, NMR testing and data processing gives a series of NMR terms that are then used to specify hydrocarbon mixtures and their components both in the bulk phase and in unconsolidated porous media. Introduction NMR logging tools are currently used for determining reservoir properties such as porosity(1, 2), permeability(1-4), as well as mobile and immobile fluids(5-7). Recent developments in NMR research offer tools for separating water, oil, and gas from the combined NMR signal(7, 8). Very little is known about the use of NMR logging tools for the in situ characterization of crude oils(1). With respect to heavy oil and bitumen formations, NMR logging has not been very successful in characterizing crude oil. The reason for the lack of such success is the fact that the NMR logging tools cannot detect the spectra from most heavy oil and bitumen formations. It should be noted that high field NMR technology has solved such problems in the past, but such technology cannot be used downhole. A fundamental objective of the research performed in our laboratory is to extend the use of NMR logging tools to all heavy oil and bitumen formations. To this end, the NMR characteristics of heavy oils in porous media were investigated(9, 10). The objective of our work is to isolate the oil signal from the combined NMR spectrum of the formation, and then shift it towards the relaxation time range that can be detected by the conventional NMR logging tools. Once this goal is achieved, NMR logs of heavy oil and bitumen formations can become successful in the analysis of oil downhole. This objective was accomplished in the material presented in this paper through a series of experiments that addressed the following issues:Relaxation interactions in mixtures of simple organic liquids with water.Relaxation interactions in mixtures of simple organic liquids. Relaxation interactions in mixtures of simple organic liquids with solvents.Relaxation times of conventional crude oils with and without solvents present.Relaxation times of heavy crude oils and bitumen with and without solvents present.Relaxation times of heavy crude oils and bitumen with and without solvents in unconsolidated sands and with variable connate water saturation.

Experimental Work on the Behaviour of Synthetic Soils Contaminated with Light Hydrocarbon, and Subsequent Remediation Thereof

Aikman

Mirotchnik³

2002

The contamination of soil by light hydrocarbons is one of the most frequently encountered environmental problems. Leakage from underground storage tanks at refueling stations is the most common source, but others are refineries or production facilities. Research at the University of Calgary has been examining the application of proven petroleum reservoir engineering methods to address this issue. By use of horizontal boreholes, and cyclic water and gas injection, the contaminant can be recovered in situ. Laboratory work has been ongoing to determine basic data on the contamination and remediation aspects of the process. In this paper, we report work that has been done to characterize the saturations during the contamination and remediation processes. Sand that typifies the grain shape and distribution of native soil was used. This sand was strongly water wet. To examine the impact of the humic acid from topsoil loam, humic acid was extracted and plated onto the sand. Characterization of the sand has been performed to demonstrate that the humic acid has bound to the surface of the sand grain, and has altered the surface wettability. Results of coreflooding also demonstrated that the performance of the organic coated sand, and the untreated sand, will lead to different contamination and remediation results. It appears that the treated sand exhibits hysteresis, for if it was originally in contact with water, it behaves as if water wet. If, instead, it was originally in contact with kerosene, it behaves as if oil wet. Introduction In our industrial world, one of the consequences of economic and technologic development is the discharge of undesirable materials into the environment. Of the many compounds released to the environment, the volume of petroleum related products released is very large. The importance of petroleum as the primary source of energy for our society is the main reason for this, reflecting the widespread usage of petroleum. The main discharge site for liquid hydrocarbons is at commercial refueling stations, from underground storage tanks ("UST") that hold gasoline. Small holes in these tanks can result from corrosion or material stress. Further locations for possible leakage are at pipe connections or flanges, where shifting soil can lead to a compromise in the integrity of the connection. It has been estimated (1) that of the roughly 1.6 million underground storage tanks in the United States, about 20% are or have discharged gasoline or diesel into the surroundings. Furthermore, conservative estimates of the cost to clean up these UST sites are around $37 billion U.S. dollars (year 2000 value). If all sites that have been contaminated by light hydrocarbons are included, such as refineries and airport tank farms, remediation is a multibilliondollar per year industry. For Canada, scaling the $37 billion (U.S.) clean up cost estimate by population and currency differences leads to an estimate of $5 billion Canadian (year 2000 value) for the clean up of contaminated sites in Canada. A significant fiscal incentive therefore exists to improve both the cost effectiveness, and also the process efficiency, of remediation.

The application of petroleum engineering methods for in-situ remediation of light hydrocarbon contaminated soil: experimental and numerical simulation studies

Aikman¹

2001

A New Method For Group Analysis of Petroleum Fractions In Unconsolidated Porous Media

Stratosud

Mirochinik³

et al. 1998

A fast and accurate method for ihe group analysis of crude oils in porous media that describes petroleum components (especially heavy f;ocrions) has been developed NMR structure group anabsis is used as ihe tool for the characterization of crude oils. This method is proposed as an alternative io existing complicated and laborious methods of characterization of extracted oil samples. Currenily, group analysis of heavy fractions of crude oils is being investigated by means of chromatographic method such as the SARA (saturates-aromatics-resins-asphaltenes) test These methods are usualb expensive and require considerable work from qualzified personnel. Furthermore, these metho& cannot be used for estimating the oil components in-situ.

Characteristics of Soil Under Variations In Clay Content And Overburden Pressure

Aikman

Mirotchnik³

et al. 1999