Research Article
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Year 2020, Volume: 21 Issue: 1, 114 - 127, 31.03.2020
https://doi.org/10.18038/estubtda.712003

Abstract

References

  • [1] Abubakar A, Al-Wahaibi T, Al-Wahaibi Y, Al-hashmi AR & Al-Ajmi A. Drag reduction with polymer in oil-water flow in relatively large pipe diameter. International Journal of Advanced and Applied Science. 2016; 2(12): 1–6.
  • [2] Al-Wahaibi T, Al-Wahaibi Y, Al-Ajmi A, Yusuf N, Al-Hashmi AR, Olawale AS & Mohammed IA. Experimental investigation on the performance of drag reducing polymers through two pipe diameters in horizontal oil-water flows. Experimental Thermal and Fluid Science. 2013; 50: 139–146.
  • [3] Edomwonyi-Otu LC & Angeli P. Effects of Polymer Addition on Pressure Drop and Interfacial Waves in Horizontal Oil-Water Flows. Petroleum Technology Develoment Journal. 2014 July;(2): 41–48.
  • [4] Al-Sarkhi A. Drag reduction with polymers in gas–liquid/liquid–liquid flows in pipes: a literature review. Journal of Natural Gas Science and Engineering. 2010; 2: 41–48.
  • [5] Magit KD, Edomwonyi-Otu LC, Yusuf N, & Abubakar A. Effect of temperature variation on the effectiveness of partially hydrolyzed polyacrylamide. Research Journal of Engineering and Environmental Sciences (RJEES). 2019; 4(2): 569-577
  • [6] Ting RY & Little RC. Characterization of drag reduction and degradation effects in the turbulent pipe flow of dilute polymer solutions. Journal of Applied Polymer Science. 1973; 17(11): 3345– 3356.
  • [7] Virk PS, Merrill EW, Mickley HS, Smith KA, & Mollo-Christensen EL. The Toms phenomenon: turbulent pipe flow of dilute polymer solutions. Journal of Fluid Mechanics. 1967; 30(2): 305–328.
  • [8] Dosumu AI, Edomwonyi-Otu LC, Yusuf N, & Abubakar A. Guar gum as flow improver in single phase and liquid-liquid flows. Arabian Journal of Science and Engineering (AJSE). 2020. doi.org/10.1007/s13369-020-04429-2
  • [9] Edomwonyi-Otu LC, Simeoni M, Angeli P & Campolo M. Synergistic Effect Of Drag Reducing Agents In Pipes of Different Diameters. Nigerian Journal of Engineering. 2016; 22: 1- 5.
  • [10] Abdulbari HA, Shabirin A & Abdurrahman HN. Bio-polymers for improving liquid flow in pipelines. Journal of Industrial and Engineering Chemistry. 2014; 20(4): 1157–1170.
  • [11] Brostow, W. Drag reduction in flow: Review of applications, mechanism and prediction. Journal of Industrial and Engineering Chemistry. 2008; 14(4): 409 – 416.
  • [12] Marmy RMS, Hayder AB and Rosli MY. Improving the flow in pipelines by Cocos nucifera fiber waste. International Journal of Physical Science. 2012; 7(26): 4073–4080
  • [13] Edomwonyi-Otu LC&Adelakun DO. Effect of Heavy Molecular Weight Polymer on Quality of Drinking Water. Materials Today Communications. Elsevier Publication. 2018; 15: 337-343.
  • [15] Deshmukh SR & Singh RP. Drag reduction characteristics of graft copolymers of xanthan gum and polyacrylamide. Journal of Applied Polymer Science. 1986; 32: 6163–6176.
  • [16] Singh RP. Advanced Turbulent Drag Reducing and Flocculating Materials Based on Polysaccharides. Polymers and Other Advanced Materials. 1995; 75: 227–249.
  • [17] Nour AH, Nuraffini K & Hayder AS. Grafted Natural Polymer as New Drag Reducing Agent : An Experemental Approach. Chemical Industry and Chemical Engineering Quarterly. 2012; 18(3): 361–371.
  • [18] Al-Wahaibi T, Smith M & Angeli P. Effect of drag-reducing polymers on horizontal oil-water flows. Journal of Petroleum Science and Engineering. 2007; 57(3-4): 334–346.
  • [19] Al-Yaari M, Soleimani A, Abu-Sharkh B, Al-Mubaiyedh U & Al-Sarkhi A. Effect of drag reducing polymers on oil–water flow in a horizontal pipe. International Journal of Multiphase Flow. 2009; 35: 516–524.
  • [20] Omer A, Pal R. Pipeline flow behavior of water-in-oil emulsions with and without a polymeric additive. Chemical Engineering Technology. 2010; 33(6): 983–992.
  • [21] Yusuf N, Al-Wahaibi T, Al-Wahaibi Y, Al-Ajmi A, Al-Hahmi AR, Olawale AS. Mohammed IA. Experimental study on the effect of drag reducing polymer on flow patterns and drag reduction in a horizontal oil–water flow. International Journal of Heat and Fluid Flow. 2012; 37: 74–80.
  • [22] Langsholt M. An Experimental Study on Polymeric Type DRA used in Single- and Multiphase Flow with Emphasis on Degradation, Diameter Scaling and the Effects in Three-phase Oil–Water– Gas Flow. Institute for Energy Technology (IFE), Norway, 2012.
  • [23] Edomwonyi-Otu LC. Distortion of velocity profiles of water flow with heavy molecular weight polymers. Transfer Phenomenon in Fluid and Heat Flows VII in Journal of Defect and Diffusion Forum (DDF). Trans Tech Publications, Switzerland. 2019; 392: 228-238
  • [24] Edomwonyi-Otu LC, Chinaud M & Angeli P. Effect of drag reducing polymer on horizontal liquidliquid flows. Experimental Tharmal and Fluid Science. 2015; 1–27.
  • [25 Bari HAA, Letchmanan K & Mohd YR. Drag Reduction Characteristics Using Aloe Vera Natural Mucilage: An Experimental Study. Journal of Applied Science. 2011; 11(6): 1039–1043.
  • [26] Bozzi A, Perrin C, Austin S. Quality and Authenticity of Commercial Aloe Vera Gel Power. Food Chemistry. 2007; 103: 22-30.
  • [27] Davis RH. Aloe Vera-A Scientific, Approach. Vantage Press Inc., New-York, USA: 1997. pp. 290- 306.
  • [28] Reddy GV & Singh RP. Drag reduction effectiveness and shear stability of polymer-polymer and polymer-fibre mixtures in recirculatory turbulent flow of water. Rheologica Acta. 1985; 24: 296– 311
  • [29] Malhotra JP, Chaturvedi PN, & Singh RP. Drag Reduction by Polymer-Polymer Mixtures. Journal of Applied Polymer Science. 1988; 36: 837–858.
  • [30] Edomwonyi-Otu LC & Angeli P. Separated Oil-Water Flows With Drag Reducing Polymers. Experimental Thermal and Fluid Science Journal. 2019; 102: 467-478
  • [31] Dingilian G & Ruckenstein E. Positive and Negative Deviations from Additivity in Drag Reduction of Binary Dilute Polymer Solutions. AlChE Journal. 1974; 20(6): 1222–1224.

SYNERGISTIC EFFECT OF POLYMER-POLYMER MIXTURES AS DRAG REDUCING AGENTS ON OIL-WATER FLOWS

Year 2020, Volume: 21 Issue: 1, 114 - 127, 31.03.2020
https://doi.org/10.18038/estubtda.712003

Abstract

The synergistic effect of natural and synthetic polymers as drag reducing agents in water phase during horizontal oil-water flows was studied in 12 mm internal diameter (ID) unplasticised polyvinylchloride (uPVC) pipe. Partially hydrolyzed polyacrylamide (HPAM; trade name as magnafloc 1011 or Separan), polyethylene oxide (PEO; trade name as Polyox WSR 310), Aloe Vera mucilage (AVM; as Aloe barbadensis miller), mixture of partially hydrolyzed polyacrylamide and Aloe Vera mucilage and polyethylene oxide and Aloe Vera mucilage (HPAM-AVM and PEO-AVM) were used. Mixture Reynolds number of 62923, master solution of 2000 ppm and 20000 ppm, and total concentration (TC) of 30 ppm and 400 ppm were investigated using diesel oil (ρ = 832 kg/m3, µ = 1.66 cP) and water (ρ = 1000 kg/m3, µ = 0.89 cP) as test fluids. The results show that the drag reduction (DR) of 65.39 and 69.23%, and 69.23 and 70.77% were obtained for HPAM-AVM and PEO-AVM mixtures respectively, at mixing ratios of 3:1 and 1:19, for 25% oil input fraction and water phase Reynolds number (Rew) of 47192. These values were found to be higher than the DR obtained by individual polymer alone at the same conditions. Drag reduction decreased with increase in the oil input fraction due to the decrease in the water phase Reynolds number. The result implies drag reduction efficiency can be enhanced by combining natural and synthetic polymers.

References

  • [1] Abubakar A, Al-Wahaibi T, Al-Wahaibi Y, Al-hashmi AR & Al-Ajmi A. Drag reduction with polymer in oil-water flow in relatively large pipe diameter. International Journal of Advanced and Applied Science. 2016; 2(12): 1–6.
  • [2] Al-Wahaibi T, Al-Wahaibi Y, Al-Ajmi A, Yusuf N, Al-Hashmi AR, Olawale AS & Mohammed IA. Experimental investigation on the performance of drag reducing polymers through two pipe diameters in horizontal oil-water flows. Experimental Thermal and Fluid Science. 2013; 50: 139–146.
  • [3] Edomwonyi-Otu LC & Angeli P. Effects of Polymer Addition on Pressure Drop and Interfacial Waves in Horizontal Oil-Water Flows. Petroleum Technology Develoment Journal. 2014 July;(2): 41–48.
  • [4] Al-Sarkhi A. Drag reduction with polymers in gas–liquid/liquid–liquid flows in pipes: a literature review. Journal of Natural Gas Science and Engineering. 2010; 2: 41–48.
  • [5] Magit KD, Edomwonyi-Otu LC, Yusuf N, & Abubakar A. Effect of temperature variation on the effectiveness of partially hydrolyzed polyacrylamide. Research Journal of Engineering and Environmental Sciences (RJEES). 2019; 4(2): 569-577
  • [6] Ting RY & Little RC. Characterization of drag reduction and degradation effects in the turbulent pipe flow of dilute polymer solutions. Journal of Applied Polymer Science. 1973; 17(11): 3345– 3356.
  • [7] Virk PS, Merrill EW, Mickley HS, Smith KA, & Mollo-Christensen EL. The Toms phenomenon: turbulent pipe flow of dilute polymer solutions. Journal of Fluid Mechanics. 1967; 30(2): 305–328.
  • [8] Dosumu AI, Edomwonyi-Otu LC, Yusuf N, & Abubakar A. Guar gum as flow improver in single phase and liquid-liquid flows. Arabian Journal of Science and Engineering (AJSE). 2020. doi.org/10.1007/s13369-020-04429-2
  • [9] Edomwonyi-Otu LC, Simeoni M, Angeli P & Campolo M. Synergistic Effect Of Drag Reducing Agents In Pipes of Different Diameters. Nigerian Journal of Engineering. 2016; 22: 1- 5.
  • [10] Abdulbari HA, Shabirin A & Abdurrahman HN. Bio-polymers for improving liquid flow in pipelines. Journal of Industrial and Engineering Chemistry. 2014; 20(4): 1157–1170.
  • [11] Brostow, W. Drag reduction in flow: Review of applications, mechanism and prediction. Journal of Industrial and Engineering Chemistry. 2008; 14(4): 409 – 416.
  • [12] Marmy RMS, Hayder AB and Rosli MY. Improving the flow in pipelines by Cocos nucifera fiber waste. International Journal of Physical Science. 2012; 7(26): 4073–4080
  • [13] Edomwonyi-Otu LC&Adelakun DO. Effect of Heavy Molecular Weight Polymer on Quality of Drinking Water. Materials Today Communications. Elsevier Publication. 2018; 15: 337-343.
  • [15] Deshmukh SR & Singh RP. Drag reduction characteristics of graft copolymers of xanthan gum and polyacrylamide. Journal of Applied Polymer Science. 1986; 32: 6163–6176.
  • [16] Singh RP. Advanced Turbulent Drag Reducing and Flocculating Materials Based on Polysaccharides. Polymers and Other Advanced Materials. 1995; 75: 227–249.
  • [17] Nour AH, Nuraffini K & Hayder AS. Grafted Natural Polymer as New Drag Reducing Agent : An Experemental Approach. Chemical Industry and Chemical Engineering Quarterly. 2012; 18(3): 361–371.
  • [18] Al-Wahaibi T, Smith M & Angeli P. Effect of drag-reducing polymers on horizontal oil-water flows. Journal of Petroleum Science and Engineering. 2007; 57(3-4): 334–346.
  • [19] Al-Yaari M, Soleimani A, Abu-Sharkh B, Al-Mubaiyedh U & Al-Sarkhi A. Effect of drag reducing polymers on oil–water flow in a horizontal pipe. International Journal of Multiphase Flow. 2009; 35: 516–524.
  • [20] Omer A, Pal R. Pipeline flow behavior of water-in-oil emulsions with and without a polymeric additive. Chemical Engineering Technology. 2010; 33(6): 983–992.
  • [21] Yusuf N, Al-Wahaibi T, Al-Wahaibi Y, Al-Ajmi A, Al-Hahmi AR, Olawale AS. Mohammed IA. Experimental study on the effect of drag reducing polymer on flow patterns and drag reduction in a horizontal oil–water flow. International Journal of Heat and Fluid Flow. 2012; 37: 74–80.
  • [22] Langsholt M. An Experimental Study on Polymeric Type DRA used in Single- and Multiphase Flow with Emphasis on Degradation, Diameter Scaling and the Effects in Three-phase Oil–Water– Gas Flow. Institute for Energy Technology (IFE), Norway, 2012.
  • [23] Edomwonyi-Otu LC. Distortion of velocity profiles of water flow with heavy molecular weight polymers. Transfer Phenomenon in Fluid and Heat Flows VII in Journal of Defect and Diffusion Forum (DDF). Trans Tech Publications, Switzerland. 2019; 392: 228-238
  • [24] Edomwonyi-Otu LC, Chinaud M & Angeli P. Effect of drag reducing polymer on horizontal liquidliquid flows. Experimental Tharmal and Fluid Science. 2015; 1–27.
  • [25 Bari HAA, Letchmanan K & Mohd YR. Drag Reduction Characteristics Using Aloe Vera Natural Mucilage: An Experimental Study. Journal of Applied Science. 2011; 11(6): 1039–1043.
  • [26] Bozzi A, Perrin C, Austin S. Quality and Authenticity of Commercial Aloe Vera Gel Power. Food Chemistry. 2007; 103: 22-30.
  • [27] Davis RH. Aloe Vera-A Scientific, Approach. Vantage Press Inc., New-York, USA: 1997. pp. 290- 306.
  • [28] Reddy GV & Singh RP. Drag reduction effectiveness and shear stability of polymer-polymer and polymer-fibre mixtures in recirculatory turbulent flow of water. Rheologica Acta. 1985; 24: 296– 311
  • [29] Malhotra JP, Chaturvedi PN, & Singh RP. Drag Reduction by Polymer-Polymer Mixtures. Journal of Applied Polymer Science. 1988; 36: 837–858.
  • [30] Edomwonyi-Otu LC & Angeli P. Separated Oil-Water Flows With Drag Reducing Polymers. Experimental Thermal and Fluid Science Journal. 2019; 102: 467-478
  • [31] Dingilian G & Ruckenstein E. Positive and Negative Deviations from Additivity in Drag Reduction of Binary Dilute Polymer Solutions. AlChE Journal. 1974; 20(6): 1222–1224.
There are 30 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Articles
Authors

Lawrence Chukwuka Edomwonyı-otu This is me 0000-0001-8317-0096

Muhammad Muhammad Gimba This is me 0000-0002-9102-0618

Yusuf Nurudeen This is me 0000-0001-6933-7064

Abdulkareem Abubakar This is me 0000-0002-8537-8488

Publication Date March 31, 2020
Published in Issue Year 2020 Volume: 21 Issue: 1

Cite

AMA Edomwonyı-otu LC, Gimba MM, Nurudeen Y, Abubakar A. SYNERGISTIC EFFECT OF POLYMER-POLYMER MIXTURES AS DRAG REDUCING AGENTS ON OIL-WATER FLOWS. Estuscience - Se. March 2020;21(1):114-127. doi:10.18038/estubtda.712003