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Hydrolysis polyurethane polymers

Marans and Preckel " synthesized both the mononitrate (95) and the dinitrate (92) esters of metriol by using a similar strategy to that used for pentaerythritol trinitrate. Thus, nitration of both the mono- (90) and the di- (93) acetate esters of metriol, followed by selective hydrolysis of the acetate groups, yields (92) and (95) respectively the latter could be useful as a monomer for the synthesis of energetic polyurethane polymers. [Pg.112]

Huang, T.C. and Chen, D.H., Kinetic studies on urea hydrolysis by immobilized urease in a batch squeezer and flow reactor, Biotechnol. Bioeng., (1992) 40,10,1203-09. Storey, K.B., Duncan, J.A., and Chakrabarti, A., Immobilization of amyloglucosidase using two forms of polyurethane polymer, Appl. Biochem. Biotechnol., (1990) 23, 3, 221-36. [Pg.17]

The synthesis of dimeric fatty acids is based on the reaction between a fatty acid with one double bond (oleic acid) and a fatty acid with two double bonds (linoleic acid) or three double bonds (linolenic acid), at higher temperatures in the presence of solid acidic catalysts (for example montmorillonite acidic treated clays). Dimerised fatty acids (C36) and trimerised fatty acids (C54) are formed. The dimer acid is separated from the trimeric acid by high vacuum distillation. By using fatty dimeric acids and dimeric alcohols in the synthesis of polyesters and of polyester polyurethanes, products are obtained with an exceptional resistance to hydrolysis, noncrystalline polymers with a very flexible structure and an excellent resistance to heat and oxygen (Chapter 12.5). Utilisation of hydrophobic dicarboxylic acids, such as sebacic acid and azelaic acid in polyesterification reactions leads to hydrolysis resistant polyurethanes. [Pg.277]

Similarly, a recent patent combines aminolysis and hydrolysis reactions for achieving polyurethane decomposition.98 Thus, scrap polyurethane is reacted with a mixture of diethanolamine and aqueous sodium hydroxide. The simultaneous attack of these agents on the polymeric chains allows the reaction time to be appreciably shortened. The reaction product, obtained as an emulsion, is subjected to a second treatment with propylene oxide in order to transform the amines and ureas present in the mixture into polyols, giving a final product which is substantially free of any hydrogen-containing nitrogen atoms. The polyols produced have been found to be particularly suitable for the preparation of fresh polyurethane polymer which can be used as an elastomer or flexible foam. [Pg.52]

Thompson DG, Osborn JC, Kober EM, Schoonover JR. Effects of hydrolysis-induced molecular weight changes on the phase separation of a polyester polyurethane. Polym Degrad Stab 2006 91(12) 3360-70. [Pg.163]

Almost all IDA derived chain extenders are made through ortho-alkylation. Diethyltoluenediamine (DE I DA) (C H gN2) (53), with a market of about 33,000 t, is the most common. Many uses for /-B I DA have been cited (1,12). Both DE I DA and /-B I DA are especially useful in RIM appHcations (49,53—55). Di(methylthio)-TDA, made by dithioalkylation of TDA, is used in cast urethanes and with other TDI prepolymers (56). Styrenic alkylation products of TDA are said to be useful, eg, as in the formation of novel polyurethane—polyurea polymers (57,58). Progress in understanding aromatic diamine stmcture—activity relationships for polyurethane chain extenders should allow progress in developing new materials (59). Chlorinated IDA is used in polyurethane—polyurea polymers of low hysteresis (48) and in reinforced polyurethane tires (60). The chloro-TDA is made by hydrolysis of chloro-TDI, derived from TDA (61). [Pg.239]

Thermoplastic polyurethane elastomers have now been available for many years (and were described in the first edition of this book). The adipate polyester-based materials have outstanding abrasion and tear resistance as well as very good resistance to oils and oxidative degradation. The polyether-based materials are more noted for their resistance to hydrolysis and fungal attack. Rather specialised polymers based on polycaprolactone (Section 25.11) may be considered as premium grade materials with good all round properties. [Pg.879]

PCL-diol and diphenylmethane-i -diisocyanate (MDI), by R. delemar lipase were examined. These polyurethanes have both the hydrogen bonds among polymer chains and aromatic rings in the polymer molecules. R. delemar lipase could hydrolyze the polyurethanes though the rate of hydrolysis toward polyurethanes decreased as compared to that ward PCL-diol. The rate of hydrolysis decreased with decreasing the Mn of PCL-moiety of polyurethanes (Figure T). [Pg.145]

This bibliographical survey shows the wide range of syntheses of the fluorinated difunctional compounds, whatever the position of the fluorinated substituent in the molecule. However, major efforts were developed, for example, to protect a group from hydrolysis in the case of esters protected by gera-trifluoromethyl groups. Actually, because of the electroattractive effects of the difluoromethyl groups in a position about the functions, the fluorinated polyesters and polyurethanes exhibit weak points which affect the applications of such polymers. [Pg.164]

Oligomeric carbodiimides are useful stabilizers for ester based polymers, such as polyesters, polyester based polyurethanes, polyether based polyurethanes, polyether based poly(urethane ureas) and polycarbonates. The scavenging of carboxyl end groups or carboxyl groups, generated in the hydrolysis of polyesters, with carbodiimide prevents hydrolysis of the polymers caused by the catalytic effect of the carboxyl groups. Neumann... [Pg.271]

Plastics with a carbonyl group can be converted to monomers by hydrolysis or glycolysis. Condensation polymers such as polyesters and nylons can be depolymerized to form monomers. For Polyurethanes (PURs), what is obtained is not the initial monomer, but a reaction product of the monomer diamine, which can be converted to diisocyanate. For PURs. hydrolysis is attractive as they can be easily broken down to polyols and diamines. The only issue is to separate them later. Steam-assisted hydrolysis has been shown to yield 60 to 80 percent recovery of polyols from PUR foam products. A twin screw extruder can be used as a reactor for hydrolysis. Glycolysis of PURS, yields mixture of polyols that can be reused directly. [Pg.377]

A plot depicting the effect of aging In water on the tensile strength of polymer A Is shown In Fig. 1. The plot Is characterized by an Initial slow decrease In strength with time which accelerates after 10 days. This Increase In the rate of tensile strength loss Is consistent with the autocatalytic nature of the hydrolysis reaction. The reaction generates an acid which In turn catalyzes further hydrolysis of the polyurethane XLL ... [Pg.176]

Tn Instances where the polyurethanes were aged In pure water, very low concentrations of the specific hydrolysis product 6-hydroxy caproic acid were observed in the residue of polymer B... [Pg.185]

See other pages where Hydrolysis polyurethane polymers is mentioned: [Pg.264]    [Pg.54]    [Pg.2375]    [Pg.175]    [Pg.92]    [Pg.481]    [Pg.879]    [Pg.435]    [Pg.208]    [Pg.168]    [Pg.146]    [Pg.397]    [Pg.59]    [Pg.69]    [Pg.43]    [Pg.54]    [Pg.50]    [Pg.105]    [Pg.481]    [Pg.86]    [Pg.88]    [Pg.12]    [Pg.70]    [Pg.181]    [Pg.216]    [Pg.46]    [Pg.141]    [Pg.162]    [Pg.111]    [Pg.315]    [Pg.100]    [Pg.879]    [Pg.173]    [Pg.471]   
See also in sourсe #XX -- [ Pg.516 ]



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