SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4319603182> ?p ?o ?g. }

Showing items 1 to 100 of ±162 with 100 items per page.

W4319603182 endingPage "211522" @default.
W4319603182 startingPage "211522" @default.
W4319603182 abstract "During ultra-deep oil and gas exploration and development, overflow can easily occur when drilling in high-temperature (≤473.15 K) and high-pressure (≤150 MPa) reservoirs. The invaded methane gas is more soluble in the drilling fluid under high temperature and pressure, and the concealment is enhanced. Low temperature and pressure at the wellhead cause rapid expansion and precipitation of the dissolved gas, thereby increasing the risk of blowout. Therefore, the safe development of the ultra-deep oil and gas drilling process is critical to accurately determine the solubility of natural gas under alternating high- and low-temperature and high-pressure conditions in ultra-deep drilling wellbores. In this study, considering the presence and absence of hydrates at low temperature, and the conditions of high temperature and high pressure, the phase equilibrium prediction fugacity–fugacity model of methane and the aqueous solution is established. At the same time, the solubility experimental data of existing CH4 in aqueous solution are counted. The prediction model is established according to the particle swarm optimization support vector machine (PSO–SVM) algorithm. The new thermodynamic fugacity–fugacity model can be applied to predict the methane solubility and water content in the gas phase under the following ultra-deep drilling conditions: temperature from 273.15 to 473.15 K, pressure up to 150 MPa, and salinity from 0 to 5.4 mol kg−1. The prediction errors for the presence and absence of hydrate at 273.15–293.15 K and 273.15–473.15 K are within 8%. The calculation error from the PSO–SVM machine learning model for the interactive solubility of methane and water is maintained within 10%, but the prediction error at atmospheric pressure exceeds 10%. The machine learning model strongly depends on abundant statistical experimental data. The prediction of gas dissolution in ultra-deep oil and gas development should be based on thermodynamic models." @default.
W4319603182 created "2023-02-09" @default.
W4319603182 creator A5010508884 @default.
W4319603182 creator A5014809179 @default.
W4319603182 creator A5074798587 @default.
W4319603182 creator A5087585921 @default.
W4319603182 creator A5089966362 @default.
W4319603182 creator A5091143353 @default.
W4319603182 date "2023-04-01" @default.
W4319603182 modified "2023-10-14" @default.
W4319603182 title "Prediction method for methane solubility in high-temperature and high-pressure aqueous solutions in ultra-deep drilling" @default.
W4319603182 cites W1656388686 @default.
W4319603182 cites W1966409448 @default.
W4319603182 cites W1969523857 @default.
W4319603182 cites W1971649105 @default.
W4319603182 cites W1972807145 @default.
W4319603182 cites W1974315408 @default.
W4319603182 cites W1977481991 @default.
W4319603182 cites W1978316095 @default.
W4319603182 cites W1978830188 @default.
W4319603182 cites W1979043629 @default.
W4319603182 cites W1981825707 @default.
W4319603182 cites W1982733509 @default.
W4319603182 cites W1987873485 @default.
W4319603182 cites W1990536516 @default.
W4319603182 cites W1991198786 @default.
W4319603182 cites W1992171359 @default.
W4319603182 cites W1992691508 @default.
W4319603182 cites W1994310840 @default.
W4319603182 cites W1994358809 @default.
W4319603182 cites W2000568246 @default.
W4319603182 cites W2001294202 @default.
W4319603182 cites W2003042858 @default.
W4319603182 cites W2007877890 @default.
W4319603182 cites W2010198346 @default.
W4319603182 cites W2010344523 @default.
W4319603182 cites W2011563303 @default.
W4319603182 cites W2012881143 @default.
W4319603182 cites W2013345815 @default.
W4319603182 cites W2014514140 @default.
W4319603182 cites W2015318422 @default.
W4319603182 cites W2017182107 @default.
W4319603182 cites W2019231063 @default.
W4319603182 cites W2020807353 @default.
W4319603182 cites W2021304100 @default.
W4319603182 cites W2022666327 @default.
W4319603182 cites W2024796433 @default.
W4319603182 cites W2027900489 @default.
W4319603182 cites W2028929133 @default.
W4319603182 cites W2030242308 @default.
W4319603182 cites W2032709929 @default.
W4319603182 cites W2033365163 @default.
W4319603182 cites W2045175011 @default.
W4319603182 cites W2057905177 @default.
W4319603182 cites W2060308713 @default.
W4319603182 cites W2065236035 @default.
W4319603182 cites W2068604894 @default.
W4319603182 cites W2074159087 @default.
W4319603182 cites W2075417531 @default.
W4319603182 cites W2077990965 @default.
W4319603182 cites W2083118609 @default.
W4319603182 cites W2083463148 @default.
W4319603182 cites W2083976914 @default.
W4319603182 cites W2086081942 @default.
W4319603182 cites W2087599586 @default.
W4319603182 cites W2087959943 @default.
W4319603182 cites W2088228478 @default.
W4319603182 cites W2088957237 @default.
W4319603182 cites W2090884527 @default.
W4319603182 cites W2092181124 @default.
W4319603182 cites W2094818470 @default.
W4319603182 cites W2094983097 @default.
W4319603182 cites W2127041725 @default.
W4319603182 cites W2129288307 @default.
W4319603182 cites W2130706941 @default.
W4319603182 cites W2139212933 @default.
W4319603182 cites W2158870701 @default.
W4319603182 cites W2166603099 @default.
W4319603182 cites W2257277565 @default.
W4319603182 cites W2323549983 @default.
W4319603182 cites W2325506961 @default.
W4319603182 cites W2334462412 @default.
W4319603182 cites W2560700522 @default.
W4319603182 cites W2606559572 @default.
W4319603182 cites W2738424286 @default.
W4319603182 cites W2751697921 @default.
W4319603182 cites W2904712937 @default.
W4319603182 cites W2937401074 @default.
W4319603182 cites W2969585231 @default.
W4319603182 cites W3004452394 @default.
W4319603182 cites W3048108064 @default.
W4319603182 cites W3122723814 @default.
W4319603182 cites W3206377643 @default.
W4319603182 doi "https://doi.org/10.1016/j.geoen.2023.211522" @default.
W4319603182 hasPublicationYear "2023" @default.
W4319603182 type Work @default.
W4319603182 citedByCount "0" @default.
W4319603182 crossrefType "journal-article" @default.