Vinyl butyral polymers

Polymers and Rubbers Poly(vinyl butyral) polymer N/A — — 162... 

Transesterification has a number of important commercial uses. Methyl esters of fatty acids are produced from fats and oils. Transesterification is also the basis of recycling technology to break up poly(ethylene terephthalate) [25038-59-9] to monomer for reuse (29) (see Recycling, plastics). Because vinyl alcohol does not exist, poly(vinyl alcohol) [9002-89-5] is produced commercially by base-cataly2ed alcoholysis of poly(vinyl acetate) [9003-20-7] (see Vinyl polymers). An industrial example of acidolysis is the reaction of poly(vinyl acetate) with butyric acid to form poly(vinyl butyrate) [24991-31-9]. 

Plasticizers. Plasticizers are materials that soften and flexibilize inherently rigid, and even britde polymers. Organic esters are widely used as plasticizers in polymers (97,98). These esters include the benzoats, phthalates, terephthalates, and trimeUitates, and aUphatic dibasic acid esters. Eor example, triethylene glycol bis(2-ethylbutyrate) [95-08-9] is a plasticizer for poly(vinyl butyral) [63148-65-2] which is used in laminated safety glass (see Vinyl POLYMERS, poly(vinyl acetals)). Di(2-ethyUiexyl)phthalate [117-81-7] (DOP) is a preeminent plasticizer. Variation of acid and/or alcohol component(s) modifies the efficacy of the resultant ester as a plasticizer. In phthalate plasticizers, molecular sizes of the alcohol moiety can be varied from methyl to tridecyl to control permanence, compatibiUty, and efficiency branched (eg, 2-ethylhexyl, isodecyl) for rapid absorption and fusion linear (C6—Cll) for low temperature flexibiUty and low volatility and aromatic (benzyl) for solvating. Terephthalates are recognized for their migration resistance, and trimeUitates for their low volatility in plasticizer appHcations. 

The solution of poly(vinyl butyral) is diluted with methanol and the polymer precipitated by the addition of water during vigorous agitation. The polymer is then stabilised, washed and dried. 

Water-soluble polymers eomprise a major elass of polymerie materials and are used in a wide variety of applieations. Synthetie water-soluble polymers inelude poly(vinyl aleohol), poly(aerylamide), poly(aerylie aeid), poly(ethylene oxide), poly(vinyl pyrrolidone), eellulosies, and many eopolymers of these types. Their end uses are quite varied and their applieations depend mainly on their viseosify-ing, rheologieal, and surfaee-aetive properties (1). For example, poly (vinyl aleohol) is used in adhesives, fibers, textile and paper sizing, paekaging, as a stabilizer for emulsion polymerization, and as a preeursor for the manufaeture of poly(vinyl butyral), whieh is used in automotive windshields. Poly(vinyl aleohol) is also the world s largest volume, eommodity, water-soluble polymer. 

PolyCvinyl butyrate), 10 492-493 Polyvinylcarbazole (PVK), 22 207t PolyCvinyl carbonates), 25 601 PolyCvinyl chloride) (PVC), 23 407 24 170 25 657-691. See also PVC entries Vinyl chloride polymers antioxidant applications, 3 123 asbestos substitute, 3 315 cadmium stabilizers with, 4 501 coatings, 7 39... 

Poly(vinyl acetate) (PVAc) and its corresponding polymers poly(vinyl alcohol) (PVA) and poly (vinyl butyral) (PVB) have long been known and their histories of discovery and development are as closely linked as their chemistries, which are characterised by an all-carbon polymer backbone and by 1,3-diol structures or their... 

Anticorrosive pigment Air- drying alkyd primers Alkyd- melamine primers 2-Compo- nent epoxy primers 2-Compo-nent acrylic isocyanate primers Chlor- inated rubber primer Aqueous polymer dispersions Poly(vinyl- butyral) primers Electro- deposition coatings Mirror coatings References... 

The synthesis of poly(vinyl acetals) (252) represents another example of generating a heterocycle, in this case the 1,3-dioxane nucleus, by application of a polymer modification reaction. Generally, the polymer modified is poly(vinyl alcohol) (180) or one of its copolymers. The 1,3-dioxane ring is generated (Scheme 122) by an acid-catalyzed acetalization reaction with an aldehyde, although ketones have also been reacted. A review (71MI11102) is available covering synthesis, properties and applications of the two most common and industrially important poly(vinyl acetals), poly(vinyl butyral) and poly(vinyl formal), as well as many other functional aldehydes that have been attached. 

Adhesion of Coatings. Except for K-l polycarbonate [4,4 -(2-nor-bornylidene)diphenol polycarbonate] (4), an experimental polymer (inherent viscosity 0.85), all the coatings were prepared with commercial products EAB-381-0.5 and EAB-381-20 cellulose acetate butyrates from Eastman Chemical Products, Inc. VYHH vinyl chloride (87%)/vinyl acetate (13%) copolymer from Union Carbide Corp. Butvar B76 poly-(vinyl butyral) from Shawinigan Resins Corp. Plexiglas V poly (methyl methacrylate) from Rohm and Haas Co. Dylene P3I polystyrene from... 

Copolymers of VIMA with other alkylamide polymers Ring-closed oxazaline polymers VIMA vinyl butyrate copolymer Alkyl acrylate VP copolymers... 

Sinicropi et al. (1996a) measured hole mobilities of ENA-B doped into a series of polymers poly(styrene) (P-1), bisphenol-A polycarbonate (P-2), pofy(4,4 -isopropylidene bisphenylene-co-4,4 -hexafluoroisopropylidene)bis-phenylene (50/50) terephthalate-co-azelate (65/35) (P-3), poly(4,4 -(2-norbotyli-dene)diphenylene terephthalate-co-azelate (40/60) (P-4), a phosgene-based polyester carbonate (P-5), and poly(vinyl butyral) (P-6). The ENA-B concentrations were 45%. Figure 64 shows the room temperature field dependencies. The mobilities vary by over four orders of magnitude. The field and temperature dependencies were described as log/i fiEl/2 and -(TJT)2. Table S summarizes the results. 

Kanemitsu and Einami (1990) investigated the role of the polymer on hole transport in a series of 2-(p-dipropylaminophenyl)-4-(p-dimethylaminophenyl)-5-(o-chlorophenyl)-l,3-oxazole (OX) doped polymers. The polymers were a polyarylate (PA), bisphenol-A polycarbonate (PC), poly(methyl methacrylate) (PMMA), poly(styrene) PS, poly(vinyl chloride) (PVC), polyethylene terephthalate) (PET), and poly(vinyl butyral) (PVB). The glass transition temperatures of the polymers range from 322 (PVB) to 448 K (PA). The temporal features of the photocurrent transients were strongly dependent on the polymer. Figure 76 shows the results. The field was 4.0 x H)5 V/cm and the temperature 295 K. The transients were near rectangular for PS, PET, PA, and PMMA, and highly dispersive for PVC land PVB. This was attributed to the fact... 

Enokida et al. (1993) measured hole mobilities of dispersions of y-TiOPc in a series of polymers polyaciylate (PA), polycarbonate (PC), polyester (PES), poly(methyl methacrylate) (PMMA), poly(styrene) (PS), polysulfone (PSL), poly(vinyl butyral) (PVB), and poly(N-vinylcarbazole) (PVK). Over a wide range of fields and temperatures, the results followed a logn < pE relationship. The temperature dependencies were described by an Arrhenius relationship with slopes that decreased with increasing field. For all temperatures, the maximum mobilities were observed at approximately 30% TiOPc. The results were also dependent on the specific form of the pigment as well as the polymer. Figure 81 shows the results obtained with different polymers. The TiOPc concentration was 30% and the temperature 295 K. 

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