Relation of structure to properties in polyurethanes

Cluff, E. F.; Gladding, E. K.

doi:10.1002/app.1960.070030905

Cited by 23 publications

(6 citation statements)

References 8 publications

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“…In all these cases, both hardness and tensile strength increased on crosslinking while elongation decreased as per the expectations. 22 Even though same equivalent (as per the hydroxyl content) of the crosslinking agents was used, the increase in tensile strength with castor oil is not high compared to TMP and PV A. This may be explained 23 as due to its low hydroxyl functionality of 2.…”

Section: Resultsmentioning

confidence: 99%

Preparation, Properties, and Crosslinking Studies on Polyurethane Elastomers

Kothandaraman

Venkatarao

Thanoo

1989

Polym J

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ABSTRACT:Polyurethane elastomers were prepared from structurally distinct hydroxyterminated polybutadiene and polyether-ester based prepolymers with diisocyanates such as hexamethylenediisocyanate, toluenediisocyanate, and diphenylmethanediisocyanate by the one short polymerizatiQn process. The effect of crosslinking by polyfunctional alcohols such as castor oil, trimethylolpropane, and poly(vinyl alcohol) on mechanical properties is compared in case of hydroxyterminated polybutadiene based polyurethane systems. The effect of crosslinking by trimethylolpropane on the mechanical properties was quantitatively studied in all the prepolymers based polyurethane systems. Crosslinking was also induced in the polyurethanes by taking higher NCO/OH ratio (R value) and the observations on mechanical properties are compared with those prepared with trimethylolpropane crosslinking. The thermal degradation of the polymers was studied in an oxygen atmosphere and interpreted with respect to their structure.KEY WORDS Polyurethane Elastomers / Crosslinked Polyurethanes / NCO/OH Ratio Effect / HTPB Based Polyurethanes / Copolyetherester Polyols / Polyurethanes are prepared by reacting polyols with diisocyanates. The most commonly used polyols include low molecular weight hydroxyterminated polymers of saturated and unsaturated aliphatic hydrocarbon, polyethers and polyesters. The functionality of the hydroxyl containing compounds as well as isocyanates can be increased to three or more to form branched or crosslinked polymers. Other structural changes can also be made by changing the type and molecular weight of the intervening groups. Polyurethanes are unique in their crosslinking, chain flexibility and intermolecular forces which can be varied widely. The abundance of original substances used for preparing urethane elastomers in conjunction with the wide variety of reactions taking place during their synthetic cause the highly complicated chemical structure of the resulting polyurethanes. 1 -5 Crosslinking of polyurethanes is of primary importance in controlling many of their properties. 6 The degree of crosslinking was controlled by the use of polyfunctional ingredients or by taking excess diisocyanate than that of the stoichiometric requirement. Crosslinking at higher diisocyanate ratio is reported to proceed through the formation of allophanate and isocyanurate linkages. 7 A significant change in properties by crosslinking may also be expected in the case of elastomers like polyether based polyurethanes.

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Section: Resultsmentioning

confidence: 99%

Preparation, Properties, and Crosslinking Studies on Polyurethane Elastomers

Kothandaraman

Venkatarao

Thanoo

1989

Polym J

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“…At the same C, but different an, eqs. (7) and (10) give (YO -?I/(?/ -2 ) = a n o / a n t (11) where the subscript t refers to time of aging; 1'0 and a,,, are the corresponding parameters without chain scission.…”

Section: Thermal Aging Of Crosslinked "Viton" Ahvmentioning

confidence: 99%

Network characterization of “viton” ahv fluoroelastomer

Fogiel

1975

J. polym. sci., C Polym. symp.

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Polymer‐solvent interaction parameter, elastically effective crosslink density Ce, and crosslinking index γ (the number of crosslinked units per polymer chain) have been determined on several vulcanizates of “Viton” AHV fluoroelastomer by means of swelling equilibrium, swollen compression modulus, and sol‐gel analysis. The parameter decreases strongly with increasing Ce for “Viton” AHV/2‐butanone, which suggests that Ce in three‐dimensional expansion (swelling) may not necessarily be equivalent to Ce calculated from uniaxial compression. The relation between γ and Ce is linear and the intercept at Ce = 0 agrees fairly well with Flory's chain‐end correction. The agreement between the initial molecular weight μMn calculated from the slope of this relation is within 25% of μMn measured before crosslinking. In view of the complex cure system the agreement is adequate to conclude that Ce calculated from the swollen compression modulus represents essentially elastically effective crosslinks of chemical nature. For comparable concentrations of the crosslinking agents used, the highest attainable Ce decreases in the order: bisphenol > hydroquinone > diamine. The bisphenol‐cured system yields Ce values far in excess of the theoretical requirements for bisether crosslinks, which is indicative of a more complex crosslinking chemistry than assumed heretofore. The γ‐Ce relation has been applied successfully to distinguish scission in the crosslinks and in the polymer chain during aging at 250°C.

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“…Alternatively, the sulfur-accelerator type of free radical curing system employed to vulcanize natural rubber and conventional unsaturated synthetic rubbers can be used to crosslink special-structured polyurethane millable gums [5,. Such polymers are rendered responsive to sulfur-accelerator cure by building occasional, special cure sites into the polymer chains which are more reactive in the free radical cure mechanism.…”

Section: Introductionmentioning

confidence: 99%

“…Such structures are readily incorporated in the polyurethane chains via ethylenically unsaturated glycols, e.g., glyceryl-a-ally1 ether, trimethylolpropane monoallylether, as chain extender[ 5, or as macroglycol polymerization initiator [17, 181.The sulfur-accelerator cure of urethane millable gums can be rapid[ 191. It likely proceeds according toFigure 4if analogy to the same cure of conventional hydrocarbon rubbers holds.…”

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confidence: 99%

Thermoplastic Urethane Chemical Crosslinking Effects

Schollenberger¹,

Dinbergs²

1975

Journal of Elastomers & Plastics

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SYNOPSISThis paper reviews the chemical structures and attendant polymer morphology that have been advanced to explain the virtual crosslink (VC) phenomenon in segmented polyurethane elastomers. The different chemical methods employed to produce useful vulcanizates from the classical polyurethane elastomer use-forms (castable liquid, millable gum) through covalent crosslinks (CC) are discussed. And finally, the nature of the polymer property changes occurring when a CC network is superposed on the VC network of a representative thermoplastic poly(ester-urethane) elastomer composition through the use of a free radical curing agent (organic peroxide) is described. The CC-VC network polymer of the subject polyurethane composition proved to have greater resistance to: solvation and its effects, stress relaxation, heat distortion, and compression set, and showed much higher modulus values than the VC network polymer. But the CC-VC network polyurethane also showed less extensibility, tear strength, low temperature flexibility, and flex life. The degrees of these changes are discussed and molecular explanations proposed in some cases.

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Relation of structure to properties in polyurethanes

Cited by 23 publications

References 8 publications

Preparation, Properties, and Crosslinking Studies on Polyurethane Elastomers

Preparation, Properties, and Crosslinking Studies on Polyurethane Elastomers

Network characterization of “viton” ahv fluoroelastomer

Thermoplastic Urethane Chemical Crosslinking Effects

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