Dynamic‐mechanical study of water‐blown rigid polyurethane foams with and without soy flour

Chang, Li-Chung; Xue, Yu; Hsieh, Fushing

doi:10.1002/app.1635

Cited by 31 publications

(20 citation statements)

References 15 publications

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“…Here δ is the phase angle between stress and strain, and E ′ and E ″ are the elastic storage modulus and the elastic loss modulus respectively. As a result, tanδ is an important parameter characterizing material's viscoelasticity 25, 26. From Figure 10, we can see that the values of tanδ increase first and then decrease with the temperature increasing, which means that the increase in E ′ is slower than that in E ″ when the temperature is under the glass transition temperature ( T g ), but the case is reversed when the temperature increases to over T g .…”

Section: Resultsmentioning

confidence: 98%

Flame‐retardant and mechanical properties of high‐density rigid polyurethane foams filled with decabrominated dipheny ethane and expandable graphite

Meng

Liu

et al. 2008

J of Applied Polymer Sci

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ABSTRACT:The article reported the flame-retardant and the mechanical properties of expandable graphite (EG), an intumescent type, and decabrominated dipheny ethane (DBDPE), a gas-phase type of flame-retardant-containing high-density rigid polyurethane foams (RPUF) with a constant density of 0.5g/cm 3 . The results indicated that both EG and DBDPE could effectively interdict the burning of RPUF, besides, the EG exhibited more effective flame retardancy than the DBDPE. When the flame-retardant loadings were 20 wt %, the LOI value of DBDPE-filled RPUF increased to 33 vol %, while, surprisingly, the EGfilled RPUF reached 41 vol %. Unfortunately, when they were both simultaneously added into RPUF, there was not any flame-retardant synergistic effect. Although EG had outstanding flame retardancy, the compressive strength and modulus of 20 wt % EG-filled RPUF dropped to only 9.1MPa and 229.7MPa respectively, which were lower than those of DBDPE (12.4 MPa and 246.8 MPa). The phenomena were ascribed to the different flame-retardant mechanisms of EG and DBDPE, which were verified by scanning electronic microscope (SEM) observation of the burned surfaces. Besides, the dynamical mechanical analysis (DMA) demonstrated that the additions of EG and DBDPE made the glass transition temperature shift to the high temperatures, and the EG-filled RPUF had the higher storage modulus.

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Section: Resultsmentioning

confidence: 98%

Flame‐retardant and mechanical properties of high‐density rigid polyurethane foams filled with decabrominated dipheny ethane and expandable graphite

Meng

Liu

et al. 2008

J of Applied Polymer Sci

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“…Studies have been conducted to determine the effects of water content and soy flour content, added into rigid polyurethane foam formulation, on the physical and dynamic-mechanical properties of the water-blown foam [27,28]. In this study, we used a typical formulation to determine the effects of different isocyanate indices (NCO: OH ratio) on the physical properties of the foam ( Table 1).…”

Section: Resultsmentioning

confidence: 99%

Rigid Polyurethane Foam Production from Palm Oil‐Based Epoxidized Diethanolamides

Lee

Ooi

Chuah

et al. 2007

J Americ Oil Chem Soc

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A new type of rigid polyurethane foam was produced by incorporating oxazolidone heterocyclic rings on to polyurethane backbones. Epoxidized diethanolamides were synthesized by reacting palm oil blends of epoxidized palm olein and refined bleached deodorized palm kernel olein with diethanolamine to produce rigid polyurethane foams. Epoxides, retained in the diethanolamides, reacted with isocyanate during foam production in the presence of AlCl 3 -THF complex catalyst to form oxazolidone linkages in the polyurethane network. The carbonyl stretch of oxazolidone was identified at 1,750 cm -1 through Fourier Transform Infra Red analysis. Chemical modifications of the polyurethane network also improved the thermal and mechanical properties of the foams. In addition, isocyanate index 1.4 was determined to be the most suitable in the production of foams from this newly synthesized epoxidized diethanolamides.

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“…Thermal degradation of polyurethanes was usually described as a complicated process involving the dissociation of the initial polyol and isocyanate components. Thermal decomposition can lead to the formation of amines, small transition components, and carbon dioxide 2, 3, 19…”

Section: Resultsmentioning

confidence: 99%

Polyurethane foams derived from liquefied mountain pine beetle‐infested barks

Zhao

Yan

Feng

2011

J of Applied Polymer Sci

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In this study, lodgepole pine (Pinus contorta Dougl.) bark infested by the mountain pine beetles (Dendroctonus ponderosae hopkins) was liquefied using either polyethylene glycol (PEG) or polyethylene glycol/glycerol (PEG/G) as the solvent. It was found that the addition of glycerol to PEG reduced the residue ratio during bark liquefaction. The liquefied bark fraction obtained by using PEG/G had a slightly higher hydroxyl number than that obtained by using PEG. The residue from PEG/G liquefaction contained less lignin and more cellulose than the residue from PEG liquefaction. Various polyurethane foams containing liquefied bark fractions were made, and it was found that the weight ratios of liquefied bark to pMDI used in foam formulation and bark liquefaction solvents affected the density, gel content, thermal stability, mechanical properties, and the cell structure of the resulting foams.

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Dynamic‐mechanical study of water‐blown rigid polyurethane foams with and without soy flour

Cited by 31 publications

References 15 publications

Flame‐retardant and mechanical properties of high‐density rigid polyurethane foams filled with decabrominated dipheny ethane and expandable graphite

Flame‐retardant and mechanical properties of high‐density rigid polyurethane foams filled with decabrominated dipheny ethane and expandable graphite

Rigid Polyurethane Foam Production from Palm Oil‐Based Epoxidized Diethanolamides

Polyurethane foams derived from liquefied mountain pine beetle‐infested barks

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