Enhanced Thermal Properties of Rigid PVC Foams Using Fly Ash
PVC foam-fly ash composites (PVC-FA) are
characterized for their structural, morphological, mechanical and
thermal properties. The tensile strength of the composites increased
modestly with higher fly ash loading, while there was a significant
increase in the elastic modulus for the same composites. On the other
hand, a decrease in elongation at UTS was observed upon increasing
fly ash content due to increased rigidity of the composites. Similarly,
the flexural modulus increased as the fly ash loading increased,
where the composites containing 25 phr fly ash showed the highest
flexural strength. Thermal properties of PVC-fly ash composites were
determined by Thermo Gravimetric Analysis (TGA). The
microstructural properties were studied by Scanning Electron
Microscopy (SEM). SEM results confirm that fly ash particles were
mechanically interlocked in PVC matrix with good interfacial
interaction with the matrix. Particle agglomeration and debonding
was observed in samples containing higher amounts of fly ash.
[1] Sreekanth MS, Bambole VA. Effect of Particle Size and Concentration
of Flyash on Properties of Polyester Thermoplastic Elastomer
Composites. J Miner Mat CharacEng, 2009; 8(3): 237-48.
[2] Matsunaga T, Kim JK, Hardcastle S, Rohatgi PK, Crystallinity and
selected properties of fly ash particles. J Mat SciEng, 2002: 333-43.
[3] White SC, Case ED. Characterization of fly ash from coal-fired power
plants. J Mat Sci, 1990; 25: 5215-19.
[4] Das A, Satapathy BK, Structural, thermal, mechanical and dynamic
mechanical properties of cenosphere filled polypropylene composites. J
Mat Des, 2011; 32: 1477–84.
[5] Labella M, Zeltmann SE, Shunmugasamy VC, Gupta N, Rohatgi PK.
Mechanical and thermal properties of fly ash/vinyl ester syntactic foams.
J. Fuel, 2014; 121: 240–49.
[6] Senapati AK, Bhatta A, Mohanty S, Mishra PC, Routra BC, An
Extensive Literature Review on the Usage of Fly Ash as a Reinforcing
Agent for Different Matrices. Int J InnovSci Mod Eng, 2014; 2(3); 4-9.
[7] Qiao J, Amirkhizi AV, Schaaf K, Nemat-Nasser S. Dynamic Mechanical
Analysis of Fly Ash Filled Polyurea Elastomer. J. Eng Mat Tech,
2011;133: 110161-7.
[8] Anandhan S, Sundar SM, Senthil T, Mahendran AR, Shibulal GS.
Extruded poly(ethylene-co-octene)/fly ash composites-value added
products from an environmental pollutant. J Polym Res, 2012; 9840-51.
[9] Deepthi MV, Sharma M, Sailaja RRN, Anantha P, Sampathkumaran P,
Seetharamu S, Mechanical and thermal characteristics of high density
polyethylene–fly ash Cenospheres composites. J Mat Des, 2010;
31:2051–60.
[10] Doddamani MR, Kulkarni SM. Dynamic response of fly ash reinforced
functionally graded rubber composite sandwiches- a Taguchi approach.
Int J EngSci Tech, 2011; 3(1):166-82.
[11] Nath DCD, Bandyopadhyay S, Yu A, Zeng Q, Das T, Blackburn D,
White C. Structure–property interface correlation of fly ash–isotactic
polypropylene composites. J Mater Sci, 2009; 44:6078–89.
[12] Nath DCD, Bandyopadhyay S, Yu A, Blackburn D, White C. Novel
observations on kinetics of nonisothermal crystallization in fly ash filled
isotactic-polypropylene composites. J Appl Poly Sci. 2010;115:1510–17.
[13] Nath DCD, Bandyopadhyay S, Yu A, Blackburn D, White C, Varughese
S. Isothermal crystallization kinetics of fly ash filled iso-polypropylene
composite-and a new physical approach. J Therm Anal Calorim. 2010;
99:423–29.
[14] Nath DCD, Bandyopadhyay S, Boughton P, Yu A, Blackburn D, White
C. High‐strength biodegradable poly(vinyl alcohol)/fly ash composite
films. J ApplPolymSci, 2010117:114–21.
[15] Nath DCD, Bandyopadhyay S, Yu A, Blackburn D, White C. High
strength bio-composite films of poly(vinyl alcohol) reinforced with
chemically modified-fly ash. J Mater Sci, 2010;45:1354–60.
[16] Vijaykumar HK, Prashanth M, Saheb S, Nayak V. Experimental
Investigation of the Tensile strength and Compressive strength of Fly
Ash Core Sandwiched Composite Material. J Int org Sci Res, 2014; 4(6):
1-10.
[17] Guhanathan S, Sarojadevi M. Studies on interface in polyester/fly-ash
particulate composites. J Comp Interface, 2004; 11:43–66
[18] Bishoyee N, Dash A, Mishra A, Patra S, Mahapatra SS. A Grey-Based
Taguchi Approach for Characterization of Erosive Wear Phenomenon of
Glass–Polyester Fly Ash Filled Composites. J Polym Environ, 2010;
18:177–87
[19] N. Usta. Investigation of Fire Behavior of Rigid Polyurethane Foams
Containing Fly Ash and Intumescent Flame Retardant by Using a Cone
Calorimeter. J ApplPolymSci, 2012; 124, 3372–82.
[20] Chow JD, Chai WL, Yeh CM, Chuang FS. Recycling and Application
Characteristics of Fly Ash from Municipal Solid Waste Incinerator
Blended with Polyurethane Foam. J Environ EngSci, 2008; 25(4): 461-
71.
[21] Guptaa N, Woldesenbetb E, Mensah P. Compression properties of
syntactic foams: effect of cenosphere radius ratio and specimen aspect
ratio. J Composites: Part A, 2004;35: 103–11.
[22] Rabinovich EB, Isner JD, SIDOR JA, Wiedl D J. Effect of Extrusion
Conditions on Rigid PVC Foam. J Vin Add Tech, 1997; 3(3): 210-15.
[23] Thomas NL. Rigid PVC Foam, Formulating for sustainability, Blowing
agent and foaming process. 2004.
[24] Eaves D. Handbook of Polymer Foams. 2004.
[25] Thomas NL. Blowing agent and foaming process. 2004.
[26] Gupta N, Woldesenbet E. Characterization of Flexural Properties of
Syntactic Foam Core Sandwich Composites and Effect of Density
Variation. J Comp Mat, 2005; 39 (24):2197-212.
[27] Purushothama HL, Hyatt J. Co-firing high-sulfur with refuse-derived
fuel. J ThermochimicaActa. 1996; 284: 161-177.
[28] Lodi PC, Souza BBD. Thermo-gravimetric Analysis (TGA) after
Different Exposures of High Density Polyethylene (HDPE) and Poly
Vinyl Chloride (PVC) Geomembranes. Elec J GeotechEng,
2012;17:3339-49.
[1] Sreekanth MS, Bambole VA. Effect of Particle Size and Concentration
of Flyash on Properties of Polyester Thermoplastic Elastomer
Composites. J Miner Mat CharacEng, 2009; 8(3): 237-48.
[2] Matsunaga T, Kim JK, Hardcastle S, Rohatgi PK, Crystallinity and
selected properties of fly ash particles. J Mat SciEng, 2002: 333-43.
[3] White SC, Case ED. Characterization of fly ash from coal-fired power
plants. J Mat Sci, 1990; 25: 5215-19.
[4] Das A, Satapathy BK, Structural, thermal, mechanical and dynamic
mechanical properties of cenosphere filled polypropylene composites. J
Mat Des, 2011; 32: 1477–84.
[5] Labella M, Zeltmann SE, Shunmugasamy VC, Gupta N, Rohatgi PK.
Mechanical and thermal properties of fly ash/vinyl ester syntactic foams.
J. Fuel, 2014; 121: 240–49.
[6] Senapati AK, Bhatta A, Mohanty S, Mishra PC, Routra BC, An
Extensive Literature Review on the Usage of Fly Ash as a Reinforcing
Agent for Different Matrices. Int J InnovSci Mod Eng, 2014; 2(3); 4-9.
[7] Qiao J, Amirkhizi AV, Schaaf K, Nemat-Nasser S. Dynamic Mechanical
Analysis of Fly Ash Filled Polyurea Elastomer. J. Eng Mat Tech,
2011;133: 110161-7.
[8] Anandhan S, Sundar SM, Senthil T, Mahendran AR, Shibulal GS.
Extruded poly(ethylene-co-octene)/fly ash composites-value added
products from an environmental pollutant. J Polym Res, 2012; 9840-51.
[9] Deepthi MV, Sharma M, Sailaja RRN, Anantha P, Sampathkumaran P,
Seetharamu S, Mechanical and thermal characteristics of high density
polyethylene–fly ash Cenospheres composites. J Mat Des, 2010;
31:2051–60.
[10] Doddamani MR, Kulkarni SM. Dynamic response of fly ash reinforced
functionally graded rubber composite sandwiches- a Taguchi approach.
Int J EngSci Tech, 2011; 3(1):166-82.
[11] Nath DCD, Bandyopadhyay S, Yu A, Zeng Q, Das T, Blackburn D,
White C. Structure–property interface correlation of fly ash–isotactic
polypropylene composites. J Mater Sci, 2009; 44:6078–89.
[12] Nath DCD, Bandyopadhyay S, Yu A, Blackburn D, White C. Novel
observations on kinetics of nonisothermal crystallization in fly ash filled
isotactic-polypropylene composites. J Appl Poly Sci. 2010;115:1510–17.
[13] Nath DCD, Bandyopadhyay S, Yu A, Blackburn D, White C, Varughese
S. Isothermal crystallization kinetics of fly ash filled iso-polypropylene
composite-and a new physical approach. J Therm Anal Calorim. 2010;
99:423–29.
[14] Nath DCD, Bandyopadhyay S, Boughton P, Yu A, Blackburn D, White
C. High‐strength biodegradable poly(vinyl alcohol)/fly ash composite
films. J ApplPolymSci, 2010117:114–21.
[15] Nath DCD, Bandyopadhyay S, Yu A, Blackburn D, White C. High
strength bio-composite films of poly(vinyl alcohol) reinforced with
chemically modified-fly ash. J Mater Sci, 2010;45:1354–60.
[16] Vijaykumar HK, Prashanth M, Saheb S, Nayak V. Experimental
Investigation of the Tensile strength and Compressive strength of Fly
Ash Core Sandwiched Composite Material. J Int org Sci Res, 2014; 4(6):
1-10.
[17] Guhanathan S, Sarojadevi M. Studies on interface in polyester/fly-ash
particulate composites. J Comp Interface, 2004; 11:43–66
[18] Bishoyee N, Dash A, Mishra A, Patra S, Mahapatra SS. A Grey-Based
Taguchi Approach for Characterization of Erosive Wear Phenomenon of
Glass–Polyester Fly Ash Filled Composites. J Polym Environ, 2010;
18:177–87
[19] N. Usta. Investigation of Fire Behavior of Rigid Polyurethane Foams
Containing Fly Ash and Intumescent Flame Retardant by Using a Cone
Calorimeter. J ApplPolymSci, 2012; 124, 3372–82.
[20] Chow JD, Chai WL, Yeh CM, Chuang FS. Recycling and Application
Characteristics of Fly Ash from Municipal Solid Waste Incinerator
Blended with Polyurethane Foam. J Environ EngSci, 2008; 25(4): 461-
71.
[21] Guptaa N, Woldesenbetb E, Mensah P. Compression properties of
syntactic foams: effect of cenosphere radius ratio and specimen aspect
ratio. J Composites: Part A, 2004;35: 103–11.
[22] Rabinovich EB, Isner JD, SIDOR JA, Wiedl D J. Effect of Extrusion
Conditions on Rigid PVC Foam. J Vin Add Tech, 1997; 3(3): 210-15.
[23] Thomas NL. Rigid PVC Foam, Formulating for sustainability, Blowing
agent and foaming process. 2004.
[24] Eaves D. Handbook of Polymer Foams. 2004.
[25] Thomas NL. Blowing agent and foaming process. 2004.
[26] Gupta N, Woldesenbet E. Characterization of Flexural Properties of
Syntactic Foam Core Sandwich Composites and Effect of Density
Variation. J Comp Mat, 2005; 39 (24):2197-212.
[27] Purushothama HL, Hyatt J. Co-firing high-sulfur with refuse-derived
fuel. J ThermochimicaActa. 1996; 284: 161-177.
[28] Lodi PC, Souza BBD. Thermo-gravimetric Analysis (TGA) after
Different Exposures of High Density Polyethylene (HDPE) and Poly
Vinyl Chloride (PVC) Geomembranes. Elec J GeotechEng,
2012;17:3339-49.
@article{"International Journal of Chemical, Materials and Biomolecular Sciences:68693", author = "Nidal H. Abu-Zahra and Parisa Khoshnoud and Murtatha Jamel and Subhashini Gunashekar", title = "Enhanced Thermal Properties of Rigid PVC Foams Using Fly Ash", abstract = "PVC foam-fly ash composites (PVC-FA) are
characterized for their structural, morphological, mechanical and
thermal properties. The tensile strength of the composites increased
modestly with higher fly ash loading, while there was a significant
increase in the elastic modulus for the same composites. On the other
hand, a decrease in elongation at UTS was observed upon increasing
fly ash content due to increased rigidity of the composites. Similarly,
the flexural modulus increased as the fly ash loading increased,
where the composites containing 25 phr fly ash showed the highest
flexural strength. Thermal properties of PVC-fly ash composites were
determined by Thermo Gravimetric Analysis (TGA). The
microstructural properties were studied by Scanning Electron
Microscopy (SEM). SEM results confirm that fly ash particles were
mechanically interlocked in PVC matrix with good interfacial
interaction with the matrix. Particle agglomeration and debonding
was observed in samples containing higher amounts of fly ash.
", keywords = "PVC Foam, Polyvinyl Chloride, Rigid PVC, Fly Ash
Composites.", volume = "9", number = "1", pages = "18-7", }
