Sunflower Oil as a Renewable Resource for Polyurethane Foams: Effects of Flame-Retardants

Asare, Magdalene A.; Kote, Prashant; Chaudhary, Sahilkumar; Souza, Felipe M. de; Gupta, Ram K.

doi:10.3390/polym14235282

Cited by 21 publications

(11 citation statements)

References 54 publications

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“…The plasticizing effect of DMMP could have led to this transition. Asare et al 18 reported similar morphological changes with the incorporation of DMMP at different concentrations into the sunflower oil-based RPUFs.…”

Section: Surface Morphologymentioning

confidence: 68%

Bio‐based rigid polyurethane foam composites reinforced with flame retardants: From synthesis to performance evaluation

Akdogan,

Erdem,

Kaynak

et al. 2024

J of Applied Polymer Sci

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The building and construction industry is under increasing pressure to make insulation materials greener, more sustainable, and less flammable. In this study, sugar beet pulp was liquified under the optimized liquefaction conditions and used as the source of bio‐polyol (SBpol) in the production of bio‐based rigid polyurethane foam (sPUF). In order to improve the flame retardancy, sPUF composites were prepared with the addition of flame retardants; expandable graphite (EG) and/or dimethyl methyl phosphonate (DMMP). The bio‐polyol was used at a fixed ratio of 50 php in sPUF composites whereas the total ratio of flame retardants was fixed at 20 php. The effects of the ratio of EG and/or DMMP on the morphological, physicomechanical, thermal, and flame retardant properties of sPUF composites were evaluated. Although the thermal conductivity values of flame retardant added sPUF composites were increased in comparison to the petroleum‐based foam, the compressive strength values were decreased as the amount of DMMP increased in the flame retardant formulation. Thermogravimetric analysis showed that the onset of decomposition of 20 php DMMP‐containing sPUF composite decreased to 168.3°C. Although the limiting oxygen index (LOI) value of the petroleum‐based PUF was as low as 19.7%, the LOI value of the sPUF/10E/10D foam increased to 24.9% (by about 26%). According to the cone calorimeter results, the peak heat release rate (pHRR) of sPUF was much higher than the petroleum‐based foam. The incorporation of both DMMP and EG could further improve the flame retardant properties. The pHRR value of sPUF/10E/10D was 28.1% lower than that of sPUF. The results have shown that flame retardancy of sPUF composites could be improved by the addition of EG which acts in the condensed phase and DMMP, which acts mainly in the gas phase during burning. Flame retardant incorporated sPUF composites are considered as promising materials for use in insulation applications.

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Section: Surface Morphologymentioning

confidence: 68%

Bio‐based rigid polyurethane foam composites reinforced with flame retardants: From synthesis to performance evaluation

Akdogan,

Erdem,

Kaynak

et al. 2024

J of Applied Polymer Sci

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“…The retention time for SO, ESO, and SOP was observed to be about 32.06, 32.31, and 32.04 min, respectively. In addition, a shoulder appeared at the retention time of around 30.38 min for SOP, which may have resulted from dimers formed as a byproduct of the reaction from ESO to SOP 22 . The molecular weights and polydispersity index (PDI) of the compounds can be estimated using a calibration curve in GPC.…”

Section: Resultsmentioning

confidence: 99%

Role of crosslinkers on the properties of bio‐based wood adhesives

Patel,

Chaudhari

et al. 2024

Polymer Engineering & Sci

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As people became more conscious of the risks associated with pollution in the early 21st century, eco‐friendly adhesives made from plant oil began to be used. Bio‐based adhesives are widely used due to their low price, easy accessibility, and high biodegradability; however, their low adhesive strength is an issue. This work incorporates three natural crosslinkers: tannic acid (TA), sorbitol (SR), and cellulose (CL) to address the drawbacks of bio‐based adhesives, such as low adhesive strength, inferior output in humidity and longer curing time that result from excess water. Methylene diphenyl diisocyanate (MDI) was used to react with soybean oil‐based polyol (SOP) plus the crosslinkers to make bio‐based polyurethane adhesives. The maximum bonding strength of the soybean‐based adhesive containing 10 wt.% of SR (SR‐10%) was measured at 6.19 MPa which is about 44% higher than the sample without SR. The higher strength is due to the crosslinking ability of SR. The effect of crosslinking is also observed in the study of polar protic and polar aprotic solvents used to dissolve the adhesive. As compared with the polar aprotic solvent tetrahydrofuran, TA‐containing adhesive samples showed a maximum tensile strength of 3.69 MPa in methanol; a polar protic solvent that can participate in further hydrogen bonding to form a higher crosslinked complex. The glass transition temperature (Tg) increases with the increase in crosslinker amount. The observed increase in Tg may be attributable to an increase in crosslinking density, which reduces polymer chain flexibility and causes a stronger material.Highlights Bio‐adhesives based on soybean oil and diisocyanate were synthesized. Natural crosslinking agents such as tannic acid, sorbitol, and cellulose were used. The effect of crosslinking using polar protic and aprotic solvents was studied. The glass transition temperature increases with the increase in crosslinker amount.

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“… 101 Additionally, Asare et al prepared a polyol from sunflower oil, reacted it with methylene diphenyl diisocyanate to produced rigid polyurethane foams. 102 Fig. 18 displays the image of sunflower seeds and the chemical structure of the oil.…”

Section: Case Studies On Vegetable Oil Derived Nipumentioning

confidence: 99%

A review on vegetable oil-based non isocyanate polyurethane: towards a greener and sustainable production route

Rayung,

Ghani,

Hasanudin

2024

RSC Adv.

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Sunflower Oil as a Renewable Resource for Polyurethane Foams: Effects of Flame-Retardants

Cited by 21 publications

References 54 publications

Bio‐based rigid polyurethane foam composites reinforced with flame retardants: From synthesis to performance evaluation

Bio‐based rigid polyurethane foam composites reinforced with flame retardants: From synthesis to performance evaluation

Role of crosslinkers on the properties of bio‐based wood adhesives

A review on vegetable oil-based non isocyanate polyurethane: towards a greener and sustainable production route

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