Demulsifying compositions for destruction of water coal tar emulsions

Demulsifying compositions for destruction of water coal tar emulsions

The task of the study was to test new demulsifying compositions for high pyrolysis coal tars originally intended for separating emulsions based on heavy petroleum oils. Coal tars with a specific gravity of 1.243-1.261 were investigated and light coal tar with a specific gravity of 1.185 was used for...

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Bibliographic Details
Published in:Petroleum science and technology Vol. 42; no. 14; pp. 1820 - 1840
Main Authors: Topilnytskyy, Petro, Romanchuk, Viktoria, Bannikov, Leonid, Karchakova, Valeria, Chuishchev, Vadim, Nyakuma, Bemgba B., Gunka, Volodymyr
Format: Journal Article
Language:English
Published: Abingdon Taylor & Francis 17-07-2024
Taylor & Francis Ltd
Subjects:
Coal tar
coking
Composition
Crude oil
demulsifier
Density
Emulsions
Fourier transforms
Functional groups
Heavy petroleum
Infrared analysis
oil
Pyrolysis
Reagents
Scientific imaging
Specific gravity
Spectrometry
Tars
water emulsion
X ray fluorescence analysis
Zinc compounds
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Summary:The task of the study was to test new demulsifying compositions for high pyrolysis coal tars originally intended for separating emulsions based on heavy petroleum oils. Coal tars with a specific gravity of 1.243-1.261 were investigated and light coal tar with a specific gravity of 1.185 was used for comparison. Demulsifying compositions for heavy media were prepared on the basis of Dissolvan (Clariant) reagents, "PM" demulsifier was used as a main indicative reagent for breaking of light coal tar emulsions. To determine the efficiency of dewatering a "bottle test" was applied, Fourier transform infrared spectroscopy analysis of the distillate residues was performed to determine the functional group of potential stabilizers. The composition of the mineralized and dispersed solid stabilizers was determined by X-ray fluorescence (XRF) spectrometry. The results showed that for the heavy coal tar emulsions, some compositions based on oxalkylated resin showed high activity and separated up to 17-19% of water, in contrast to the indicative demulsifier 0-3%. An attempt has been made to investigate the mineral composition of emulsion stabilizers transferred into the water part and remaining in the coal tar (sludge). The results of XRF spectrometry suggested that Zn-pyridine compounds are the most likely hydrophile stabilizers of heavy coal tar emulsions.
ISSN:1091-6466
1532-2459
DOI:10.1080/10916466.2022.2150776