Development of an artificial neural network model for prediction of bubble point pressure of crude oils

Aref Hashemi Fath; Abdolrasoul Pouranfard; Pouyan Foroughizadeh

doi:10.1016/j.petlm.2018.03.009

Petroleum ›› 2018, Vol. 4 ›› Issue (3) :281 -291. DOI: 10.1016/j.petlm.2018.03.009

research-article

Development of an artificial neural network model for prediction of bubble point pressure of crude oils

Author information +

History +

PDF

Abstract

Bubble point pressure is one of the most important pressure-volume-temperature properties of crude oil, and it plays an important role in reservoir and production engineering calculations. It can be precisely determined experimentally. Although, experimental methods present valid and reliable results, they are expensive, time-consuming, and require much care when taking test samples. Some equations of state and empirical correlations can be used as alternative methods to estimate reservoir fluid properties (e.g., bubble point pressure); however, these methods have a number of limitations. In the present study, a novel numerical model based on artificial neural network (ANN) is proposed for the prediction of bubble point pressure as a function of solution gas-oil ratio, reservoir temperature, oil gravity (API), and gas specific gravity in petroleum systems. The model was developed and evaluated using 760 experimental data sets gathered from oil fields around the world. An optimization process was performed on networks with different structures. Based on the obtained results, a network with one hidden layer and six neurons was observed to be associated with the highest efficiency for predicting bubble point pressure. The obtained ANN model was found to be reliable for the prediction of bubble point pressure of crude oils with solution gas-oil ratios in the range of 8.61-3298.66 SCF/STB, temperatures between 74 and 341.6 °F, oil gravity values of 6-56.8 API and gas gravity values between 0.521 and 3.444. The performance of the developed model was compared against those of several well-known predictive empirical correlations using statistical and graphical error analyses. The results showed that the proposed ANN model outperforms all of the studied empirical correlations significantly and provides predictions in acceptable agreement with experimental data.

Keywords

Artificial neural network / Bubble point pressure / Empirical correlation / Statistical analysis

Cite this article

Download citation ▾

Aref Hashemi Fath, Abdolrasoul Pouranfard, Pouyan Foroughizadeh. Development of an artificial neural network model for prediction of bubble point pressure of crude oils. Petroleum, 2018, 4(3): 281-291 DOI:10.1016/j.petlm.2018.03.009

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	T. Ahmed, Hydrocarbon Phase Behavior, Gulf Publishing, Houston, 1989.

[2]	W.D. McCain, The Properties of Petroleum Fluids, PennWell Books, 1990.

[3]	W.D.J. McCain, R.B. Soto, P.P. Valko, T.A. Blasingame, Correlation of bubblepoint pressures for reservoir oils-a comparative study, in: SPE Eastern Regional Meeting, Pittsburgh, Pennsylvania, 1998.

[4]	R. Gharbi, A.M. Elsharkawy, Predicting the bubble-point pressure and formation-volume-factor of worldwide crude oil systems, J. Pet. Sci. Technol 21 (2003) 53-79.

[5]	A.M. Elsharkawy, Modeling the properties of crude oil and gas systems using RBF network, in: SPE Asia Pacific Oil and Gas Conference and Exhibition, Society of Petroleum Engineers Inc, Perth, Australia, 1998.

[6]	E.A. Osman, O.A. Abdel-Wahhab, M.A. Al-Marhoun, Prediction of oil PVT properties using neural networks, in: SPE Middle East Oil Show Society of Petroleum Engineers, 2001.

[7]	S. Shahin Rafiee-Taghanaki, M. Arabloo, A. Chamkalani, M. Amani, M.H. Zargari, M.R. Adelzadeh, Implementation of SVM framework to estimate PVT properties of reservoir oil, Fluid Phase Equilib 346 (2013) 25-32.

[8]	M. Standing, A pressureevolumeetemperature correlation for mixtures of California oils and gases, Drilling and Production Practice (1947) 275-287.

[9]	J. Lasater, Bubble point pressure correlation, J. Petrol. Technol. 10 (1958) 65-67.

[10]	M. Vazquez, H.D. Beggs, Correlations for fluid physical property prediction, J. Pet. Technol 32 (1980) 968-970.

[11]	O. Glasø, Generalized pressureevolumeetemperature correlations, J. Pet. Technol 32 (1980) 785-795.

[12]	D.A. Obomanu, G.A. Okpobiri, Correlating the PVT properties of Nigerian crudes, J. Energy Resour. Technol. Trans. 109 (1987) 214-217.

[13]	M. Al-Marhoun, PVT correlations for Middle East crude oils, J. Pet. Technol 40 (1988) 650-666.

[14]	R.M. Labedi, Use of production data to estimate the saturation pressure, solution GOR, and chemical composition of reservoir fluids, in: SPE Latin America Petroleum Engineering Conference, Rio de Janeiro, Brazil, 1990.

[15]	S. Macary, M. El-Batanoney, Derivation of PVT correlations for the Gulf of Suez crude oils, Sekiyu Gakkai shi 36 (1993) 472-478.

[16]	M.E. Dokla, M.E. Osman, Correlation of PVT properties for UAE crudes, SPE Form. Eval. 7 (1992) 41-46.

[17]	F. Frashad, J. LeBlanc, J. Garber, J. Osorio, Empirical PVT correlations for Colombian crude oils, in: SPE Latin America/Caribbean Petroleum Engineering Conference, Port-of-Spain, Trinidad, 1996.

[18]	M.I. Omar, A.C. Todd,Development of new modified black oil correlations for Malaysian Crudes, in:SPE Asia Pacific Oil and Gas Conference, Singapore, 1993.

[19]	G.E. Petrosky Jr., F. Farshad, Pressure-volume-temperature Correlations for Gulf of Mexico Crude Oils. SPE Annual Technical Conference and Exhibition, Society of Petroleum Engineers, Texas, 1993.

[20]	T. Kartoatmodjo, Z. Schmidt, Large data bank improves crude physical property correlations, Oil Gas J. 92 (1994).

[21]	M. Khairy, S. El-Tayeb, M. Hamdallah, PVT correlations developed for Egyptian crudes, Oil Gas J. (1998) 114-116.

[22]	B. Dindoruk, P. Christman, PVT properties and viscosity correlations for Gulf of Mexico Oils, SPE Reservoir Eval. Eng. 7 (2004) 427-437.

[23]	A. Naseria, M. Nikazarb, S.A. Mousavi Dehghani, A correlation approach for prediction of crude oil viscosities, J. Petrol. Sci. Eng. 47 (2005) 163-174.

[24]	R.P. Sutton, F.F. Farshad, Evaluation of empirically derived PVT properties for Gulf of Mexico crude oils, SPE. Res. Eng (1990) 79-86.

[25]	A.M. Saleh, I.S. Mahgoub, Y. Assad, Evaluation of empirically drived PVT properties for Egyptian crudes, in: Middle East Oil Show, Society of Petroleum Engineers, 1987.

[26]	A.M. Elsharkawy, A.A. Elgibly, A.A.Alikhan, Assessment of the PVT correlations for predicting the properties of Kuwaiti crude oils, J. Pet. Sci. Eng 13 (1995) 219-232.

[27]	M.A. Al-Marhoun, Evaluation of empirically derived PVT properties for Middle East crude oils, J. Petrol. Sci. Eng. 42 (2004) 209-221.

[28]	S. Dutta, J.P. Gupta, PVT correlations for Indian crude using artificial neural networks, J. Pet. Sci. Eng 72 (2010) 93-109.

[29]	A.H. Fath, Application of radial basis function neural networks in bubble point oil formation volume factor prediction for petroleum systems, Fluid Phase Equilib 437 (2017) 14-22.

[30]	R.B. Gharbi, A.M. Elsharkawy,Neural network model for estimating the PVT properties of Middle East crude oils, in:Middle East Oil Show and Conference Society of Petroleum Engineers, 1997.

[31]	M.A. Al-Marhoun, New correlations for formation volume factors of oil and gas mixtures, J. Can. Pet. Technol. 31 (1992) 22-26.

[32]	A.M. Malallah, R. Gharbi, M. Algharaib, Accurate estimation of the world crude oil PVT properties using graphical alternating conditional expectation, Energy Fuels. 20 (2006) 688-698.

[33]	A.R. Moghadassi, F. Parvizian, S.M. Hosseini, A.R. Fazlali, A new approach for estimation of PVT properties of pure gases based on artificial neural network model, Brazil, J. Chem. Eng. 26 (2009) 199-206.

[34]	R. Perry, H. Green, Perry's Chemical Engineers' Hand Book, seventh ed., McGraw-Hill New York, 1999.

[35]	W.S. McCulloch, W.A. Pitts, Logical calculus of ideas immanent in nervous activity, Bull. Math. Biophys. 5 (1943) 115-133.

[36]	D.O. Hebb, The Organization of Behavior: a Neuropsychological Approach, John Wiley & Sons, 1949.

[37]	F. Rosenblatt, The perceptron: a probabilistic model for information storage and organization in the brain, Psychol. Rev. 65 (1958) 386.

[38]	J. Zupan, J. Gasteiger, Neural networks: a new method for solving chemical problems or just a passing phase? Anal. Chim. Acta 248 (1991) 1-30.

[39]	I.A. Basheera, M. Hajmeer, Artificial neural networks: fundamentals computing, J. Microbiol. design, and application, Methods 43 (2000) 3-31.

[40]	J.R.M. Smits, W.J. Melssen, L.M.C. Buydens, G. Kateman, Using artificial neural networks for solving chemical problems: part I. Multi-layer feed-forward networks, Chemom. Intell. Lab. Syst 22 (1994) 165-189.

[41]	O.O. Bello, K.M. Reinicke, P.A. Patil, Comparison of the performance of empirical models used for the prediction of the PVT properties of crude oils of the Niger Delta, Petrol. Sci. Technol. 26 (2008) 593-609.

[42]	M.A. Mahmood, M.A. Al-Marhoun, Evaluation of empirically derived PVT properties for Pakistani crude oils, J. Petrol. Sci. Eng. 16 (1669) 275-290.

[43]	G. De Ghetto, F. Paone, M. Villa, Reliability analysis on PVT correlations, in: SPE European Petroleum Conference, London, United Kingdom, 1994.

[44]	J.N. Moghadam, K. Salahshoor, R. Kharrat, Introducing a new method for predicting PVT properties of Iranian crude oils by applying artificial neural networks, Petrol. Sci. Technol. 29 (2011) 1066-1079.

[45]	G. Cybenko, Approximation by superpositions of a sigmoidal function, Math. Control. Signals. Syst 2 (1989) 303-314.

[46]	K. Hornik, M. Stinchcombe, H. White, Multilayer feedforward networks are universal approximators, Neural Netw 2 (1989) 359-366.

[47]	A. Al-Shammasi,Bubble point pressure and oil formation volume factor correlations, in:SPE Middle East Oil Show & Conference, 1999, pp. 241e256.

[48]	G. Chen, K. Fu, Z. Liang, T. Sema, C. Li, P. Tontiwachwuthikul, R. Idem, The genetic algorithm based back propagation neural network for MMP prediction in CO 2-EOR process, Fuel 126 (2014) 202.