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Petroleum testing involves quality analysis of petroleum products during upstream, midstream, and downstream production processes. Analyses include crude oil composition, crude oil fractions, analysis of fuel additives and oil contaminants.
For petroleum production, the upstream process is the exploration and production phase, which includes searching for potential underground or underwater crude oil and natural gas fields, drilling exploratory wells, and bringing the natural gas and crude oil from the well to the surface.
The midstream process involves the transportation (by pipeline, rail, barge, oil tanker, or truck), storage, and wholesale marketing of crude or refined petroleum products. Pipelines and other transport systems can be used to move crude oil from production sites to refineries and deliver the various refined products to downstream distributors.
The downstream process refers to the refining petroleum crude oil, and processing and purifying raw natural gas. These products are divided into:
Crude oil is a complex mixture of hydrocarbons, non-hydrocarbon organic compounds containing N, S, O, and organometallic (e.g., Ni, Fe, and V) compounds. The refinery process distills the crude oil mixture into different fractions and makes the final products for industrial uses of various purposes.
Distillation fractions | End products |
---|---|
Gasoline vapors, LPG | LPG |
Naphtha | Gasoline |
Kerosene | Jet fuel |
Diesel distillate | Diesel fuel |
Medium weight gas oil | LPG gasoline |
Heavy gas oil | Motor gasoline, jet fuel, diesel fuel |
Residuum | Industrial fuels, asphalt base |
Different crude oil fractions, petroleum feedstock, and finished products need different analytical tools and methods for analysis.
Saturated fractions can often be analyzed by a stand-alone gas chromatography (GC) with conventional detectors. These GC systems are limited to analyzing hydrocarbons with carbon numbers less than 35 because its lower temperature limit is about 325°C. Analysis of heavier hydrocarbons requires high temperature GC.
The aromatics fraction is hard to analyze by stand-alone GC, but can be analyzed using GC-MS because of its highly sensitive and selective detector. Heavier-cut petrochemical products such as resins and asphaltenes have higher boiling points and can be analyzed by LC-MS. These heavier-cut petrochemical products are not easily analyzed by GC because GC cannot volatize the high boiling point components.
Adding certain additives to fuels can prevent or remedy fuel delivery system problems. The function of the fuel additives include, but are not limited to:
As an example, benzene and toluene are gasoline additives that are analyzed by GC as described in ASTM D3606. The method is for analysis of benzene between 0.1 to 5% and toluene between 2 to 20%. The original method uses a packed GC column and thermal conductivity detector (TCD), but the method can be simplified using a capillary column with flame ionization detector (FID) for automated analysis of the two compounds.
Inorganic contaminants can contaminate refined fuels and cause serious problems in product quality, corrode equipment, and interfere with the catalysts necessary for the refining process.
Although it is difficult to analyze trace-level halogens and sulfur directly by ion chromatography (IC), these contaminants can be measured accurately by combustion IC, where the samples are oxidized by high heat before IC analysis. Trace metals can be routinely analyzed by ICP-OES, although organic samples are always more challenging compared to aqueous samples.
Reliable water analysis is critical to eliminating corrosion and scaling that can damage valuable industrial components and to ensure regulatory compliance. Download the infographic to learn about our solutions to the top three analytical challenges in industrial water and waste water processing.
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