Thermoplastic polyurethane hydrolysis stability

Schollenberger, C. S.; Stewart, F.D.

doi:10.1002/apmc.1973.050290118

Cited by 45 publications

(27 citation statements)

References 5 publications

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“…41 Another reason for the deterioration of shell compactness may be that more water molecules diffused into the core of the microcapsules and consumed more HDI with longer reaction duration. The released amount of core material aer the isothermal process decreased gradually with increasing reaction duration, and reached a lowest value (0.9 wt%) when the reaction duration was 2 h. Subsequently, the released amount of core material aer the isothermal process started to increase from 0.9 wt% to 1.9 wt% with increasing reaction duration to 2.5 h. This phenomenon indicates that the tightness of the microcapsule shell is rst improved and then deteriorated with the extension of reaction duration.…”

Section: Parametric Study To Optimize the Encapsulation Processmentioning

confidence: 99%

Double-layered reactive microcapsules with excellent thermal and non-polar solvent resistance for self-healing coatings

Sun

et al. 2015

J. Mater. Chem. A

124

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Double-layered polyurea microcapsules containing hexamethylene diisocyanate (HDI) with outstanding shell tightness have been successfully synthesized via interfacial polymerization reaction in an oil-inwater emulsion. The resultant capsules were systematically characterized by scanning electron microscopy (SEM), thermogravimetric analysis (TGA) and Fourier transform infrared (FTIR) spectroscopy. The reaction parameters including reaction temperature (40 C, 50 C, 60 C), reaction duration (1 h, 1.5 h, 2 h and 2.5 h), amount of Suprasec 2644 (2.4 g, 3 g and 3.6 g) and emulsification time (15 min, 45 min and 75 min) were investigated and evaluated in terms of core fraction and quality of microcapsules. The core fraction of microcapsules was reduced with an increase of reaction temperature, reaction duration, mass of Suprasec 2644 and emulsification time, while the quality of microcapsules fluctuated. The thermal and organic solvent resistances were assessed by using TGA and titration. The results showed that the microcapsules had 1.6% weight loss compared with pure HDI with 90% weight loss after 60 min isothermal treatment at 100 C. After immersion in various solvents for 24 days, the microcapsules released as low as $3% of core in weakly polar solvents (i.e. hexane and xylene), about 5-60% in polar aprotic solvents (i.e. ethyl acetate, acetone, DMF and DMSO), and 60-90% in water and polar protic solvents (i.e. isopropanol and ethylene glycol). Both fresh and hexane-treated HDI capsules showed excellent anticorrosion performance in scratched coatings via self-healing functionality, indicating promising practical application in industrial coating and paint systems.

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Section: Parametric Study To Optimize the Encapsulation Processmentioning

confidence: 99%

Double-layered reactive microcapsules with excellent thermal and non-polar solvent resistance for self-healing coatings

Sun

et al. 2015

J. Mater. Chem. A

124

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“…The additional free hydroxyl groups in polycarbonate polyols provide sites for the attachment of dyes, flame retardants, bioactive molecules, or cross‐linking of materials. In addition, polycarbonate polyols have been introduced for the manufacture of polyurethanes for high‐performance coating applications . However, the respective cyclic carbonate monomers have to be prepared in multistep reactions, which represent a drawback for actual application.…”

Section: Introductionmentioning

confidence: 99%

Controlled Synthesis of Multi‐Arm Star Polyether–Polycarbonate Polyols Based on Propylene Oxide and CO₂

Hilf

Schulze

Seiwert

et al. 2013

Macromol. Rapid Commun.

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Multi-arm star copolymers based on a hyperbranched poly(propylene oxide) polyether-polyol (hbPPO) as a core and poly(propylene carbonate) (PPC) arms are synthesized in two steps from propylene oxide (PO), a small amount of glycidol and CO2 . The PPC arms are prepared via carbon dioxide (CO2 )/PO copolymerization, using hbPPO as a multifunctional macroinitiator and the (R,R)-(salcy)CoOBzF5 catalyst. Star copolymers with 14 and 28 PPC arms, respectively, and controlled molecular weights in the range of 2700-8800 g mol(-1) are prepared (Mw /Mn = 1.23-1.61). Thermal analysis reveals lowered glass transition temperatures in the range of -8 to 10 °C for the PPC star polymers compared with linear PPC, which is due to the influence of the flexible polyether core. Successful conversion of the terminal hydroxyl groups with phenylisocyanate demonstrates the potential of the polycarbonate polyols for polyurethane synthesis.

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“…Poly(ester urethanes) are known to degrade by several mechanisms,2, 3 one of which is hydrolysis 4–9. To study the hydrolysis of Estane® 5703 and related poly(ester urethanes), it is necessary to first determine their absorption of water and the diffusion of water through them.…”

Section: Introductionmentioning

confidence: 99%

“…The hard segments in poly(ester urethanes) tend to clump together to produce a microphase separation between hard‐ and soft‐segment domains 4–6. The extent of the microphase separation depends on the hard‐segment fraction of the polymer, and the domains are expected to differ in their attraction and permeability to water.…”

Section: Introductionmentioning

confidence: 99%

“…This is a low fraction of hard segments as compared with many poly(ester urethanes). The polymers used by Schollenberger and coworkers4–6, 14 and Brown et al7–9 had about the same molecular weight PBA but had molar fractions of 0.5 MDI, 0.25 PBA, and 0.25 BDO so that they have a higher hard‐segment fraction than Estane® 5703. Three of the samples used by Potts15 were commercial poly(ester urethanes) that are probably similar to Estane® 5703, but they are not identified in his article.…”

Section: Introductionmentioning

confidence: 99%

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Degradation of a poly(ester urethane) elastomer. I. Absorption and diffusion of water in Estane® 5703 and related polymers

Salazar

Thompson

Laintz

et al. 2001

J Polym Sci B Polym Phys

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In preparation for studying the hydrolytic degradation of Estane® 5703 and related poly(ester urethane) elastomers, the absorption (solubility) and diffusion of water in these polymers have been examined experimentally and modeled theoretically. Weight gain and loss experiments have been carried out. The amount of water absorbed per gram of sample was linear at low relative humidities (RHs) but curved upward at higher RHs. This curvature was not fit by Henry's law or the Flory–Huggins equation but was easily fit by a water‐cluster model. Diffusion coefficients were determined by fitting the time dependence of the sample weights, and the diffusion appeared Fickian to within experimental uncertainty. The similarity of related polymers was used to determine the approximate temperature dependence of the absorption. © 2001 John Wiley & Sons, Inc. J Polym Sci Part B: Polym Phys 40: 181–191, 2002

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Thermoplastic polyurethane hydrolysis stability

Cited by 45 publications

References 5 publications

Double-layered reactive microcapsules with excellent thermal and non-polar solvent resistance for self-healing coatings

Double-layered reactive microcapsules with excellent thermal and non-polar solvent resistance for self-healing coatings

Controlled Synthesis of Multi‐Arm Star Polyether–Polycarbonate Polyols Based on Propylene Oxide and CO₂

Degradation of a poly(ester urethane) elastomer. I. Absorption and diffusion of water in Estane® 5703 and related polymers

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Thermoplastic polyurethane hydrolysis stability

Cited by 45 publications

References 5 publications

Double-layered reactive microcapsules with excellent thermal and non-polar solvent resistance for self-healing coatings

Double-layered reactive microcapsules with excellent thermal and non-polar solvent resistance for self-healing coatings

Controlled Synthesis of Multi‐Arm Star Polyether–Polycarbonate Polyols Based on Propylene Oxide and CO2

Degradation of a poly(ester urethane) elastomer. I. Absorption and diffusion of water in Estane® 5703 and related polymers

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Controlled Synthesis of Multi‐Arm Star Polyether–Polycarbonate Polyols Based on Propylene Oxide and CO₂