EN
TR
Determination of the Production Rate and Cumulative Production in the “No Flow” Boundary Condition Utilizing the Finite Element Method
Öz
The No Flow outer boundary condition also known as the PSEUDO-STEADY STATE occurs When reservoirs outside boundary lines are all closed boundaries in the late time region. This condition is relevant to bounded reservoirs. In this research, we employed the well the rate of production and cumulative production in a circular reservoir adopting the Finite Element Method (FEM). The FEM was used to analyze the diffusivity equation (governing equation). The reservoir was divided into fragments, which is referred to finite element. These components were examined and then put together to create the reservoir's domain. The research was conducted under the presumption that the pressure in the reservoir was uniformly distributed prior to the well starting production. Due to the nature of the diffusivity equation, dimensional analysis was carried out to make the equation dimensionless. The dimensionless results indicate a linear increase in cumulative production over time. Thereafter, the dimensionless cumulative production becomes asymptotically constant with a very slight increase as the dimensionless time increases. This continues throughout this flow regime. The results indicate a decline in the production rate of the reservoir over time. The rate of decrease at the initial stage is high and later in the regime, becomes steady. The finding of this study was juxtaposed with the obtained results of Christine. The comparison reveals that the two approaches have a high positive correlation, with an overall percentage error of 1.5512 & 0.0891 and a minimal percentage error of 0.0001 & 0.0111 produces the dimensionless cumulative production & the dimensionless production rate, respectively. Again, Christine solutions only stated the reservoir's production rate and cumulative production at certain times, but this work estimates the reservoir's overall production rate and cumulative output simultaneously.
Anahtar Kelimeler
Destekleyen Kurum
University of Benin, Benin City, Nigeria.
Etik Beyan
The authors have declared that there is no conflict of interest of whatsoever.
Teşekkür
My appreciation goes to the Chief editor and the entire board members of International Journal of Engineering Technologies IJET for given me the platform to publish this paper.
Kaynakça
- [1] T. Ahmed, and P. McKinney, Advanced reservoir management engineering, Gulf Professional Publishing, Oxford, 2nd ed., 2011, ISBN: 9780123855480.
- [2] H.S. Carslaw, and J.C. Jaeger Conduction of Heat in Solids, Oxford: Clarendon Press, 522 pages ISBN: 9780198533689, 1986.
- [3] W.J. Lee, and R.A. Wattenbarger Gas reservoir engineering, SPE Textbook Series, 5. Society of Petroleum Engineers, p. 349, 1996.
- [4] C. Chakrabarty, S. Ali and W. Tortike Analytical solutions for radial pressure distribution including the effects of the quadratic gradient term. Water Resour Res, 29(4), p. 1171–1177, 1993.
- [5] W.J. Lee, “Pressure transient testing part 9. Production engineering methods”, In: Development Geology Reference Manual. AAPG Methods in Exploration No. 10, Tulsa, OK, p. 477–481, 1992.
- [6] A. Van Everdingen, “The skin effect and its influence on the productive capacity of a well”, J Petrol Techn., 5(06) p. 171–176, 1953.
- [7] S. Braeuning, T.A. Jelmert, and S.A. Vik, “The effect of the quadratic gradient term on variable-rate well-tests”, J. Petrol Sci. Eng., 21(3) p. 203–222, 1998.
- [8] Y. Wang, and M.B. Dusseault, “The effect of quadratic gradient terms on the borehole solution in poroelastic media”, Water Resour Res 27(12) p. 3215–3223, 1991.
Ayrıntılar
Birincil Dil
İngilizce
Konular
Rezervuar Mühendisliği
Bölüm
Araştırma Makalesi
Erken Görünüm Tarihi
3 Mart 2026
Yayımlanma Tarihi
3 Mart 2026
Gönderilme Tarihi
11 Aralık 2025
Kabul Tarihi
9 Şubat 2026
Yayımlandığı Sayı
Yıl 2025 Cilt: 10 Sayı: 4
APA
Otamere, B., & Erhunmwun, I. D. (2026). Determination of the Production Rate and Cumulative Production in the “No Flow” Boundary Condition Utilizing the Finite Element Method. International Journal of Engineering Technologies IJET, 10(4), 58-68. https://doi.org/10.19072/ijet.1835756
AMA
1.Otamere B, Erhunmwun ID. Determination of the Production Rate and Cumulative Production in the “No Flow” Boundary Condition Utilizing the Finite Element Method. IJET. 2026;10(4):58-68. doi:10.19072/ijet.1835756
Chicago
Otamere, Blessing, ve Iredia Davis Erhunmwun. 2026. “Determination of the Production Rate and Cumulative Production in the ‘No Flow’ Boundary Condition Utilizing the Finite Element Method”. International Journal of Engineering Technologies IJET 10 (4): 58-68. https://doi.org/10.19072/ijet.1835756.
EndNote
Otamere B, Erhunmwun ID (01 Mart 2026) Determination of the Production Rate and Cumulative Production in the “No Flow” Boundary Condition Utilizing the Finite Element Method. International Journal of Engineering Technologies IJET 10 4 58–68.
IEEE
[1]B. Otamere ve I. D. Erhunmwun, “Determination of the Production Rate and Cumulative Production in the ‘No Flow’ Boundary Condition Utilizing the Finite Element Method”, IJET, c. 10, sy 4, ss. 58–68, Mar. 2026, doi: 10.19072/ijet.1835756.
ISNAD
Otamere, Blessing - Erhunmwun, Iredia Davis. “Determination of the Production Rate and Cumulative Production in the ‘No Flow’ Boundary Condition Utilizing the Finite Element Method”. International Journal of Engineering Technologies IJET 10/4 (01 Mart 2026): 58-68. https://doi.org/10.19072/ijet.1835756.
JAMA
1.Otamere B, Erhunmwun ID. Determination of the Production Rate and Cumulative Production in the “No Flow” Boundary Condition Utilizing the Finite Element Method. IJET. 2026;10:58–68.
MLA
Otamere, Blessing, ve Iredia Davis Erhunmwun. “Determination of the Production Rate and Cumulative Production in the ‘No Flow’ Boundary Condition Utilizing the Finite Element Method”. International Journal of Engineering Technologies IJET, c. 10, sy 4, Mart 2026, ss. 58-68, doi:10.19072/ijet.1835756.
Vancouver
1.Blessing Otamere, Iredia Davis Erhunmwun. Determination of the Production Rate and Cumulative Production in the “No Flow” Boundary Condition Utilizing the Finite Element Method. IJET. 01 Mart 2026;10(4):58-6. doi:10.19072/ijet.1835756