Phase Behavior Identification and Formation Mechanisms of the BZ19-6 Condensate Gas Reservoir in the Deep Bozhong Sag, Bohai Bay Basin, Eastern China

Significant developments have been observed in recent years, in the field of deep part exploration in the Bozhong Sag, Bohai Bay Basin in eastern China. The BZ19-6 large condensate gas field, the largest gas field in the Bohai Bay Basin, was discovered for the first time in a typical oil-type basin....

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Bibliographic Details
Published inGeofluids Vol. 2021; pp. 1 - 19
Main Authors Wang, Zhenliang, Xiao, Shengdong, Wang, Feilong, Tang, Guomin, Zhu, Liwen, Zhao, Zilong
Format Journal Article
LanguageEnglish
Published Chichester Hindawi 2021
Hindawi Limited
Wiley
Subjects
Basins
Block diagrams
Carbon dioxide
Condensates
Critical temperature
Crude oil
Deposition
Empirical analysis
Evaporation
Experiments
Fluids
Gases
Geology
High temperature
Hydrocarbons
Identification
Identification methods
Lithology
Metamorphic rocks
Methods
Natural gas
Natural gas reserves
Neogene
Oil
Oil and gas fields
Oil reserves
Oil reservoirs
Petroleum production
Phase diagrams
Physical properties
Reservoirs
Statistical methods
Tectonics
Temperature
Temperature range
Transition temperature
Bohai Bay
China
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Summary:Significant developments have been observed in recent years, in the field of deep part exploration in the Bozhong Sag, Bohai Bay Basin in eastern China. The BZ19-6 large condensate gas field, the largest gas field in the Bohai Bay Basin, was discovered for the first time in a typical oil-type basin. The proven oil and gas geological reserves in the deeply buried hills of the Archean metamorphic rocks, amount to approximately 3×108 tons of oil equivalent. However, the phase behavior and genetic mechanisms of hydrocarbon fluids are still unclear. In this study, the phase diagram identification method and various empirical statistical methods, such as the block diagram method, φ1 parameter method, rank number method, and Z-factor method were implemented to comprehensively identify the phase behavior types of the BZ19-6 condensate gas reservoir. The genetic mechanism of the BZ19-6 condensate gas reservoir was investigated in detail through analyses of physical properties of the fluid at high temperatures and pressures, organic geochemical characteristics of condensate oil and gas, and regional tectonic background. Consequently, this study is shown as follows: (1) The BZ19-6 condensate gas reservoir is a part of a secondary condensate gas reservoir with oil rings, formed synthetically since the Neogene period due to multiple factors, such as retrograde evaporation from deep burial and high temperature, inorganic CO2 charging from the deep mantle, and late natural gas invasion. (2) The hydrocarbon accumulation process of the BZ19-6 condensate gas reservoir is as follows: First, a large amount of oil is accumulated at the end of the lower Minghuazhen deposition (5 Ma BP); second, a large amount of natural gas is generated in the deep-source kitchen and mantle-derived inorganic CO2 charged into the early formed oil reservoirs at the end of the upper Minghuazhen deposition (2 Ma BP). As a result, the content of gaseous hydrocarbons in the hydrocarbon system of the reservoir increased, which led to large amounts of liquid hydrocarbons dissolved in gaseous hydrocarbons and significantly reduced the critical temperature of the hydrocarbon system. Therefore, existing secondary condensate gas reservoirs are formed when the critical temperature is lower than the formation temperature and it enters the critical condensate temperature range.
ISSN:1468-8115
1468-8123
DOI:10.1155/2021/6622795