Decline curve based models for predicting natural gas well performance

Arash Kamari , Amir H. Mohammadi , Moonyong Lee , Alireza Bahadori

Petroleum ›› 2017, Vol. 3 ›› Issue (2) : 242 -248.

PDF
Petroleum ›› 2017, Vol. 3 ›› Issue (2) :242 -248. DOI: 10.1016/j.petlm.2016.06.006
research-article
Decline curve based models for predicting natural gas well performance
Author information +
History +
PDF

Abstract

The productivity of a gas well declines over its production life as cannot cover economic policies. To overcome such problems, the production performance of gas wells should be predicted by applying reliable methods to analyse the decline trend. Therefore, reliable models are developed in this study on the basis of powerful artificial intelligence techniques viz. the artificial neural network (ANN) modelling strategy, least square support vector machine (LSSVM) approach, adaptive neuro-fuzzy inference system (ANFIS), and decision tree (DT) method for the prediction of cumulative gas production as well as initial decline rate multiplied by time as a function of the Arps' decline curve exponent and ratio of initial gas flow rate over total gas flow rate. It was concluded that the results obtained based on the models developed in current study are in satisfactory agreement with the actual gas well production data. Furthermore, the results of comparative study performed demonstrates that the LSSVM strategy is superior to the other models investigated for the prediction of both cumulative gas production, and initial decline rate multiplied by time.

Keywords

Decline curve / Production / Rate / Model / Gas well

Cite this article

Download citation ▾
Arash Kamari, Amir H. Mohammadi, Moonyong Lee, Alireza Bahadori. Decline curve based models for predicting natural gas well performance. Petroleum, 2017, 3(2): 242-248 DOI:10.1016/j.petlm.2016.06.006

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]

H.H. Khanamiri, A non-iterative method of decline curve analysis, J. Pet. Sci. Eng. 73 (2010) 59-66.
[2]

B. Xu, M. Haghighi, X. Li, D. Cooke, Development of new type curves for production analysis in naturally fractured shale gas/tight gas reservoirs, J. Pet. Sci. Eng. 105 (2013) 107-115.
[3]

D. Zhang, L. Zhang, Y. Zhao, J. Guo, A composite model to analyze the decline performance of a multiple fractured horizontal well in shale reservoirs, J. Nat. Gas Sci. Eng. 26 (2015) 999-1010.
[4]

J. Fanchi, M. Cooksey, K. Lehman, A. Smith, A. Fanchi, C. Fanchi, Probabilistic decline curve analysis of Barnett, Fayetteville, Haynesville, and Woodford gas shales, J. Pet. Sci. Eng. 109 (2013) 308-311.
[5]

J. Arps, Analysis of decline curves, Trans. AIME 160 (1945) 228-247.
[6]

A. Kamari, A. Bahadori, A.H. Mohammadi, On the determination of crude oil salt content: application of robust modeling approaches, J. Taiwan Inst. Chem. Eng. 55 (2015) 27-35.
[7]

A. Kamari, M. Arabloo, A. Shokrollahi, F. Gharagheizi, A.H. Mohammadi, Rapid method to estimate the minimum miscibility pressure (MMP) in live reservoir oil systems during CO2 flooding, Fuel 153 (2015) 310-319.
[8]

A. Kamari, A. Bahadori, A.H. Mohammadi, S. Zendehboudi, Evaluating the unloading gradient pressure in continuous gas-lift systems during petroleum production operations, Pet. Sci. Technol. 32 (2014) 2961-2968.
[9]

A. Kamari, A.H. Mohammadi, A. Bahadori, S. Zendehboudi, Prediction of air specific heat ratios at elevated pressures using a novel modeling approach, Chem. Eng. Technol. 37 (2014) 2047-2055.
[10]

A. Bahadori, Analysing gas well production data using a simplified decline curve analysis method, Chem. Eng. Res. Des. 90 (2012) 541-547.
[11]

R.W. Gentry, Decline-curve analysis, J. Pet. Technol. 24 (1972) 38-41.
[12]

T. Ahmed, Reservoir Engineering Handbook, Access Online via Elsevier, 2006.
[13]

R. Zabihi, M. Schaffie, H. Nezamabadi-Pour, M. Ranjbar, Artificial neural network for permeability damage prediction due to sulfate scaling, J. Pet. Sci. Eng. 78 (2011) 575-581.
[14]

P.S. Hegeman, C. Dong, N. Varotsis, V. Gaganis,Application of artificial neural networks to downhole fluid analysis, in:International Petroleum Technology Conference, 2007.
[15]

N. Al-Bulushi, M. Araujo, M. Kraaijveld, Predicting water saturation using artificial neural networks (ANNS), Neural Netw. 549 (2007) 57.
[16]

M. Rafiq, G. Bugmann, D. Easterbrook, Neural network design for engineering applications, Comput. Struct. 79 (2001) 1541-1552.
[17]

G. Arulampalam, A. Bouzerdoum, A generalized feedforward neural network architecture for classification and regression, Neural Netw. 16 (2003) 561-568.
[18]

A.H. Mohammadi, D. Richon, Hydrate phase equilibria for hydrogen+ water and hydrogen+ tetrahydrofuran+ water systems: predictions of dissociation conditions using an artificial neural network algorithm, Chem. Eng. Sci. 65 (2010) 3352-3355.
[19]

A. Eslamimanesh, F. Gharagheizi, A.H. Mohammadi, D. Richon, Artificial neural network modeling of solubility of supercritical carbon dioxide in 24 commonly used ionic liquids, Chem. Eng. Sci. 66 (2011) 3039-3044.
[20]

H. Yarveicy, A.K. Moghaddam, M.M. Ghiasi, Practical use of statistical learning theory for modeling freezing point depression of electrolyte solutions: LSSVM model, J. Nat. Gas Sci. Eng. 20 (2014) 414-421.
[21]

P. Samui, D. Kothari, Utilization of a least square support vector machine (LSSVM) for slope stability analysis, Sci. Iran. 18 (2011) 53-58.
[22]

J.A. Suykens, J. Vandewalle, Least squares support vector machine classifiers, Neural Process. Lett. 9 (1999) 293-300.
[23]

B.B. Ekici, A least squares support vector machine model for prediction of the next day solar insolation for effective use of PV systems, Measurement 50 (2014) 255-262.
[24]

L.-Z. Ding, S. Liao, Approximate model selection for large scale LSSVM, in: ACML, 2011, pp. 165-180.
[25]

H. Safari, A. Shokrollahi, M. Jamialahmadi, M.H. Ghazanfari, A. Bahadori, S. Zendehboudi, Prediction of the aqueous solubility of BaSO4 using pitzer ion interaction model and LSSVM algorithm, Fluid Phase Equilib 374 (2014) 48-62.
[26]

M. Mesbah, E. Soroush, V. Azari, M. Lee, A. Bahadori, S. Habibnia, Vapor liquid equilibrium prediction of carbon dioxide and hydrocarbon systems using LSSVM algorithm, J. Supercrit. Fluids 97 (2015) 256-267.
[27]

M. Erdogan, B. Mudford, G. Chenoweth, R. Holeywell, J. Jakubson, Optimization of decision tree and simulation portfolios: a comparison,in:SPE Hydrocarbon Economics and Evaluation Symposium, Society of Petroleum Engineers, 2001.
[28]

I.K. Sethi, B. Chatterjee, Efficient decision tree design for discrete variable pattern recognition problems, Pattern Recognit. 9 (1977) 197-206.
[29]

L.R. Heinze, H.W.Winkler, J.F. Lea, Decision tree for selection of artificial lift method, in: SPE Production Operations Symposium, Society of Petroleum Engineers, 1995.
[30]

M.S. Alkhasawneh, U.K. Ngah, L.T. Tay, N.A. Mat Isa, M.S. Al-Batah, Modeling and testing landslide hazard using decision tree, J. Appl. Math. 2014 (2014).
[31]

B. Chandra, R. Kothari, P. Paul, A new node splitting measure for decision tree construction, Pattern Recognit. 43 (2010) 2725-2731.
[32]

K.-M. Osei-Bryson, Evaluation of decision trees: a multi-criteria approach, Comput. Op. Res. 31 (2004) 1933-1945.
[33]

X. Wang, X. Liu, W. Pedrycz, L. Zhang, Fuzzy rule based decision trees, Pattern Recognit. 48 (2015) 50-59.
[34]

D.G. Laughton, G. Joe, M. Paduada, M. Samis, Complete decision-tree analysis using simulation methods: illustrated with an example of Bitumen production in alberta using steam injection,in:SPE Annual Technical Conference and Exhibition, Society of Petroleum Engineers, 2006.
[35]

P. Tan, M. Steinbach, V. Kumar, Introduction to Data Mining. Classification:Basic Concepts, Decision Trees and Model Evaluation, AddisoneWesley, Boston, 2006.
[36]

A.H. Gandomi, M.M. Fridline, D.A. Roke, Decision tree approach for soil liquefaction assessment, Sci. World J. 2013 (2013).
[37]

W.Y. Loh, Classification and regression trees, Wiley Interdiscip. Rev. Data Min. Knowl. Discov. 1 (2011) 14-23.
[38]

J.-S.R. Jang, ANFIS: adaptive-network-based fuzzy inference system, systems, man and cybernetics, IEEE Trans. 23 (1993) 665-685.
[39]

I. Rahimzadeh Kivi, M. Ameri Shahrabi, M. Akbari, The development of a robust ANFIS model for predicting minimum miscibility pressure, Pet. Sci. Technol. 31 (2013) 2039-2046.
[40]

J. Kennedy, Particle swarm optimization, in: Encyclopedia of Machine Learning, Springer, 2010, pp. 760-766.
[41]

V. Fabian, Simulated annealing simulated, Comput. Math. Appl. 33 (1997) 81-94.
PDF

0

Accesses

0

Citation

Detail
Sections
Recommended

/