Analysis of Relationship between Temperature and Relaxation Time of Polymer Solution depending on Polymer Concentration and Salinity for Enhanced Oil Recovery

Yeong-Gyu Kim; Pan-Sang Kang; Jong-Se Lim

doi:10.12972/ksmer.2017.54.5.512

All Issue

2017 Vol.54, Issue 5 Preview Page Next Page

Research Paper

Analysis of Relationship between Temperature and Relaxation Time of Polymer Solution depending on Polymer Concentration and Salinity for Enhanced Oil Recovery 석유회수증진용 폴리머 용액의 농도와 염도에 따른 완화시간과 온도 관계 분석

31 October 2017. pp. 512-520

PDF XML

Abstract

Polymer flood which is one of enhanced oil recovery technology has been used for mobility control by injecting viscous polymer solution into the reservoir. Viscoelasticity of polymer solution contributes to increase in displacement efficiency of remaining oil. Since viscoelastic properties are affected by temperature, it is necessary to consider relationship between temperature and viscoelasticity for designing the polymer flood. Relaxation time is used as a major parameter to quantify the viscoelasticity of the polymer solution. In this paper, dynamic moduluses were measured using rheometer and relaxation time was determined using cross-over point method. Relaxation time showed positive correlation with polymer concentration and negative correlations with salinity (NaCl) and temperature. In addition, a correlation for estimation of relaxation time depending on temperature was suggested using WLF (William-Landel-Ferry) model.

Keywords

Polymer flood

Relaxation time

Temperature

Salinity

WLF model

폴리머 주입법은 점도가 높은 폴리머 용액을 저류층에 주입해 유동도를 제어함으로써 석유회수를 증진시키는 방법으로 석유회수증진용 폴리머 용액의 점탄성은 저류층 내부에 남아있는 석유의 치환효율을 향상시켜 석유 회수에 기여한다. 저류층의 온도에 따라 폴리머 용액의 점탄성이 달라지기 때문에 이를 고려한 폴리머 주입법 설계가 필요하며 폴리머 용액의 점탄성을 정량화하는 주요 요소로 완화시간이 사용되고 있다. 이 연구에서는 레오미터로 폴리머 용액의 동적 탄성률을 측정하고 교차점 기법을 이용해 완화시간을 결정하였으며 다양한 폴리머 농도, 염도(NaCl) 조건에서 온도에 따른 완화시간 변화를 측정하였다. 그 결과 완화시간은 폴리머 농도와 양의 상관관계를 보였으며, 염도 및 온도와는 음의 상관관계를 보였다. 또한, WLF 모델을 이용해 온도에 따른 폴리머 용액의 완화시간 추정 관계식을 제안하였다.

키워드

폴리머 주입법

완화시간

온도

염도

WLF 모델

References

Choi, S.K., 2008. pH Sensitive Polymers for Novel Conformance Control and Polymer Flooding Applications, PhD Thesis, The University of Texas at Austin, USA, p.4-5.

Clarke, A., Howe, A.M., Mitchell, J., Staniland, J., and Hawkes, L.A., 2015. How Viscoelastic Polymer Flooding Enhances Displacement Efficiency. SPE 27487 presented at the SPE Enhanced Oil Recovery Conference, Kuala Lumpur, Malaysia, August 11-13.

10.2118/174654-MS

Delamaide, E., Zaitoun, A., Renard, G., and Tabary, R., 2013. Pelican Lake Field: First Successful Application of Polymer Flooding in a Heavy Oil Reservoir. SPE 165234 presented at the SPE Enhanced Oil Recovery Conference, Kuala Lumpur, Malaysia, July 2-4.

Delshad, M., Kim, D.H., Magbagbeola, O.A., Huh, C., Pope, G.A., and Tarahhom, F., 2008. Mechanistic Interpretation and Utilization of Viscoelastic Behavior of Polymer Solutions for Improved Polymer-Flood Efficiency. SPE 113620 presented at the SPE Improved Oil Recovery Symposium, Tulsa, Oklahoma, USA, April 20-23.

10.2118/113620-MS

Douglas, C.M., Montgomery, E.A., Peck, G., and Geoffrey, V., 2015. Introduction to Linear Regression Analysis (4th Ed.), Wiley, New York, USA, p.20-30.

Durst, F., Haas, R., and Interthal, W., 1982. Laminar and turbulent flows of dilute polymer solutions: a physical model. Rheologica Acta, 21(4), 572-577.

10.1007/BF01534350

Ferry, J.D., 1980. Viscoelastic Properties of Polymers (3rd Ed.), Wiley, New York, USA, 352p.

Green, D.W. and Willhite, G.P., 1998. Enhanced Oil Recovery (4th Ed.), Society of Petroleum Engineers, Texas, USA, p.117-118.

9512341

Gupta, R.K., 2000. Polymer and Composite Rheology (2nd Ed.), CRC Press, New York, USA, p.141-142.

Hagan, E.W.S., Charalambides, M.N., Young, C.R.T., and Learner T.J.S., 2015. The effects of strain rate and tempera-ture on commercial acrylic artist paints aged one year to decades. Applied Physics A, 121(3), 823-835.

10.1007/s00339-015-9423-6

Hetzer, M. and Kee, D.D., 2008. Wood/polymer/nanoclay composites, environmentally friendly sustainable technology: A review. Chemical Engineering Research and Design, 86(10), 1083-1093.

10.1016/j.cherd.2008.05.003

Kang, P.S. and Lim, J.S., 2011. Development of artificial neural network viscosity model of pH-sensitive polymer for enhanced oil recovery. J. of the Korean Society of Mineral and Energy Resources Engineers, 48(2), 190-198.

Kang, P.S., Lim, J.S., and Huh, C., 2016. Artificial neural network model to estimate the viscosity of polymer solutions for enhanced oil recovery. Applied Sciences, 6(7), 1-15.

10.3390/app6070188

Kasapis, S., 2004. Definition of a mechanical glass transition temperature for dehydrated foods. J. of Agricultural Food Chemistry, 52(8), 2262-2268.

10.1021/jf030468w15080631

Kim, D.H., Lee, S., Ahn, C.H., Huh, C., and Pope, G.A., 2010. Development of a viscoelastic property database for EOR polymers. SPE 129971 presented at the SPE Improved Oil Recovery Symposium, Tulsa, Oklahoma, USA, April 24-28.

10.2118/129971-MS

Koh, H.S., 2015. Experimental Investigation of the Effect of Polymers on Residual Oil Saturation, PhD Thesis, The University of Texas at Austin, USA, p.59-85.

Lee, K.S., 2010. Application of horizontal injection and production wells in polymer flood processes. J. of the Korean Society of Mineral and Energy Resources Engineers, 47(3), 283-290.

10.12972/ksmer.2015.52.3.283

Lee, S.M., Kang, P.S., and Lim, J.S., 2016. Measurement for retention levels of polymer using absorbance measurement method in enhanced oil recovery. J. of the Korean Society of Mineral and Energy Resources Engineers, 53(1), 53-62.

10.12972/ksmer.2016.53.1.053

Liang, R.F. and Mackley, M.R., 1994, Rheological characterization of the time and strain dependence for polyisobutylene solutions, J. of Non-Newtonian Fluid Mechanics, 52(3), 387-405.

10.1016/0377-0257(94)85031-3

Lopez, X., Valvatne, P.H., and Blunt, M.J., 2003. Predictive network modeling of single-phase non-newtonian flow in porous media. J. of Colloid and Interface Science, 264(1), 256-265.

10.1016/S0021-9797(03)00310-2

Moré, J.J. and Sorensen, D.C., 1983. Computing a trust region step. Society for Industrial and Applied Mathematics J. on Scientific and Statistical Computing, 4(3), 553-572.

10.1137/0904038

Munoz, M., Santamaria, A., Guzman, J., and Riande, E., 2003. Enhancement of the first normal stress coefficient and dynamic moduli during shear thickening of a polymer solution, J. of Rheology, 47(4), 1041-1050.

10.1122/1.1579690

Ravindranath, S. and Wang, S., 2008. Universal scaling characteristics of stress overshoot in startup shear of entangled polymer solutions. J. of Rheology, 52(3), 681-695.

10.1122/1.2899147

Romero-Zerón, L., 2012. Introduction to Enhanced Oil Recovery (EOR) Processes and Bioremediation of Oil-Contaminated Sites, InTech, Rijeka, Croatia, p.3-4.

Saleh, L.D., Wei, M., and Bai, B., 2014. Data analysis and novel screening criteria for polymer flooding based on a comprehensive database. SPE 169093 presented at the SPE Improved Oil Recovery Symposium, Oklahoma, USA, April 12-16.

10.2118/169093-MS

Sheng, J.J., 2013. Enhanced Oil Recovery Field Case Studies, Gulf Professional Publishing, UK, 88p.

Standnes, D.C. and Skjevrak, I., 2014. Literature review of implemented polymer field projects. J. of Petroleum Science and Engineering, 122, 761-775.

10.1016/j.petrol.2014.08.024

Volpert, E., Selb, J., and Candau, F., 1998. Associating behavior of polyacrylamide hydrophobically modified with dihexylacrylamide. Polymer, 39(1), 1025-1033.

10.1016/S0032-3861(97)00393-5

Wang, D., Xia, H., Liu, Z., and Yang, Q., 2001. Study of the mechanism of polymer solution with visco-elastic behavior increasing microscopic oil displacement efficiency and the forming of steady 'oil thread' flow channel. SPE 68723 presented at the SPE Asia Pacific Oil Gas Conference, Jakarta, Indonesia, April 17-19.

Information

Publisher :The Korean Society of Mineral and Energy Resources Engineers
Publisher(Ko) :한국자원공학회
Journal Title :Journal of the Korean Society of Mineral and Energy Resources Engineers
Journal Title(Ko) :한국자원공학회지
Volume : 54
No :5
Pages :512-520
Received Date : 2017-06-23
Revised Date : 2017-10-13
Accepted Date : 2017-10-18
DOI :https://doi.org/10.12972/ksmer.2017.54.5.512

Journal of the Korean Society of Mineral and Energy Resources Engineers ISSN:2288-0291(Print) 2288-2790(Online) 한국자원공학회지

All Issue