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Abstract

Recently, bio-based polyols are gaining significant attention as sustainable alternatives to petroleum-based polyols for polyurethane (PU) foam production, promoting eco-friendly processing, renewable resource utilization, and reduced CO₂ emissions during polyol synthesis. This report considered fabrication of flexible thermoset PU foam by partially replacing a conventional polyol with a recycled and bio-based polyol from different spent coffee grounds. To resemble properties like cream time, gel time, tack-free time, density, height, and other physical traits of the original foam, different experimental designs have been set up using the design of experiment (DOE) and statistical analysis considering different catalyst and surfactant contents. The effects of silicone surfactant and gelling catalyst with different contents on the physico-mechanical properties of modified with 10 parts by weight (pbw) recovered bio-polyol and unmodified PU foams were investigated. With the desire for higher compressive strength and lower heat shrinkage, the formulations of the bio-polyol-based foams are optimized with 0.75 pbw of catalyst and 1.2 pbw of surfactant amounts. Consequently, at optimized condition, the PU foam displays a compressive strength of 62 gf/cm² and the lowest heat shrinkage rate (2.26%). Furthermore, the fabricated foam with unique cellular morphology shows a higher sound absorption coefficient at the lower and higher frequencies than the original foam, signifying its applicability in electric vehicles. Thus, owing to their impressive mechanical and acoustic characteristics, the developed bio-foams could serve as viable alternatives to traditional flexible PU foams for minimizing vibrations and noise pollution.

Keywords

Spent coffee grounds bio-polyol flexible polyurethane foam sound absorption statistical analysis

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References

Sung

Choe

Choi

, et al. Morphological, acoustical, and physical properties of free-rising polyurethane foams depending on the flow directions. Korean J Chem Eng 2018; 35: 1045–1052.

Lee

Zeng

Cao

, et al. Polymer nanocomposite foams. Compos Sci Technol 2005; 65: 2344–2363.

Khan

Acar

Aydin

, et al. A review on recent advances in sandwich structures based on polyurethane foam cores. Polym Compos 2020; 41: 2355–2400.

Schäfer

Nestler

Kroll

. Quasi-static and fatigue properties of thermoset sandwiches with 3D continuous fibre reinforced polyurethane foam core. Materials 2022; 15: 764.

Bhavsar

Bhave

Webb

. Solving the plastic dilemma: the fungal and bacterial biodegradability of polyurethanes. World J Microbiol Biotechnol 2023; 39: 122.

Singh

Hui

Singh

, et al. Recycling of plastic solid waste: a state of art review and future applications. Compos B Eng 2017; 115: 409–422.

Belsare

Nandi

. Sustainable polyurethane foam formulation with bio-polyol blends for automotive seating applications. Ind Crop Prod 2025; 226: 120672.

Kurańska

Prociak

. The influence of rapeseed oil-based polyols on the foaming process of rigid polyurethane foams. Ind Crop Prod 2016; 89: 182–187.

Kurańska

Aleksander

Mikelis

, et al. Porous polyurethane composites based on bio-components. Compos Sci Technol 2013; 75: 70–76.

10.

Prociak

Malewska

Kurańska

, et al. Flexible polyurethane foams synthesized with palm oil-based bio-polyols obtained with the use of different oxirane ring opener. Ind Crop Prod 2018; 115: 69–77.

11.

Gama

Silva

Carvalho

, et al. Sound absorption properties of polyurethane foams derived from crude glycerol and liquefied coffee grounds polyol. Polym Test 2017; 62: 13–22.

12.

Bernardini

Cinelli

Anguillesi

, et al. Flexible polyurethane foams green production employing lignin or oxypropylated lignin. Eur Polym J 2015; 64: 147–156.

13.

Sung

Lee

, et al. Sound damping of a polyurethane foam nanocomposite. Macromol Res 2007; 15: 443–448.

14.

Lee

Chen

Sendijarevic

, et al. Effect of morphology on sound attenuation of flexible polymeric foams. J Cell Plast 1991; 27: 135–142.

15.

Imai

Asano

. Studies of acoustical absorption of flexible polyurethane foam. J Appl Polym Sci 1982; 27: 183–195.

16.

Schäfer

Nestler

Kroll

. Impact compressive properties of polyurethane foams with 3D continuous fibre reinforcement. Proc Inst Mech Eng Pt L J Mater Des Appl. 2025; 239: 706–719.

17.

Patel

Stojko

. Characterising polyurethane foam as impact absorber in transport packages. Packag Transp Storage Secur Radioact Material 2010; 21: 25–30.

18.

Gama

Ferreira

Barros-Timmons

. Polyurethane foams: past, present, and future. Materials 2018; 11: 1841.

19.

Choe

Lee

Seo

, et al. Properties of rigid polyurethane foams with blowing agents and catalysts. Polym J 2004; 36: 368–373.

20.

Sung

Kim

. Sound absorption behavior of flexible polyurethane foams including high molecular-weight copolymer polyol. Polym Adv Technol 2018; 29: 852–859.

21.

Hong

Zhou

, et al. The effect of the trimerization catalyst on the thermal stability and the fire performance of the polyisocyanurate-polyurethane foam. Fire Mater 2018; 42: 119–127.

22.

Lefebvre

Bastin

Le Bras

, et al. Thermal stability and fire properties of conventional flexible polyurethane foam formulations. Polym Degrad Stabil 2005; 88: 28–34.

23.

Paria

Kim

Lee

, et al. Ecopolyols from spent coffee grounds through acid liquefaction using polyol: synthesis and its optimization. J Polym Environ 2024; 32: 1619–1630.

24.

Jin

Sahu

Kim

, et al. An insight into the recycling of waste flexible polyurethane foam using glycolysis. Elastom Compos 2023; 58: 32–43.

25.

Kairytė

Vėjelis

. Evaluation of forming mixture composition impact on properties of water blown rigid polyurethane (PUR) foam from rapeseed oil polyol. Ind Crop Prod 2015; 66: 210–215.

26.

Zhang

Chen

. The study of palm-oil-based bio-polyol on the morphological, acoustic and mechanical properties of flexible polyurethane foams. Polym Int 2020; 69: 257–264.

27.

Kraitape

Thongpin

. Influence of recycled polyurethane polyol on the properties of flexible polyurethane foams. Energy Proc 2016; 89: 186–197.

28.

Zhang

Macosko

Davis

, et al. Role of silicone surfactant in flexible polyurethane foam. J Colloid Interface Sci 1999; 215: 270–279.

29.

Ragauskas

. Kraft lignin-based rigid polyurethane foam. J Wood Chem Technol 2012; 32: 210–224.

30.

Pan

Saddler

. Effect of replacing polyol by organosolv and kraft lignin on the property and structure of rigid polyurethane foam. Biotechnol Biofuels 2013; 6: 12–110.

31.

Kreter

. Polyurethane foam physical properties as a function of foam density. J Cell Plast 1985; 21: 306–310.

32.

Alzoubia

Tanbour

Al-Waked

. Compression and hysteresis curves of nonlinear polyurethane foams under different densities, strain rates and different environmental conditions. IMECE 2011; 9: 101–109.

33.

Elliott

Windle

Hobdell

, et al. In-situ deformation of an open-cell flexible polyurethane foam characterised by 3D computed microtomography. J Mater Sci 2002; 37: 1547–1555.

34.

Frey

Stanga

. Design of a new silicone surfactant for flexible slabstock polyurethane foam. J Cell Plast 1997; 33: 55–71.

35.

Al-Moameri

Ghoreishi

Zhao

, et al. Impact of the maximum foam reaction temperature on reducing foam shrinkage. RSC Adv 2015; 5: 17171–17178.

Spent coffee ground derived bio-polyol based flexible polyurethane foam with improved mechanical and sound absorption properties

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