Processing additives - A to Z.Amides Amides are any member of either of two classes of nitrogen-containing compounds related to ammonia and amine amine (əmēn`, ăm`ēn): see under amino group. amine Any of a class of nitrogen-containing organic compounds derived, either in principle or in practice, from ammonia (NH3). . Simple amides ordinarily are prepared by reaction of acids or acid halides with ammonia or amines amines (  mēnz´),n.pl organic compounds that contain nitrogen. . They can also be produced by the reaction of water with nitriles. The characteristic reaction of covalent co·va·lent adj. Of or relating to a chemical bond characterized by one or more pairs of shared electrons. amides is hydrolysis hydrolysis (hīdrŏl`ĭsĭs), chemical reaction of a compound with water, usually resulting in the formation of one or more new compounds. (a chemical reaction with water), by which they are converted to acids and amines. Amides also can be dehydrated de·hy·drate v. de·hy·drat·ed, de·hy·drat·ing, de·hy·drates v.tr. 1. To remove water from; make anhydrous. 2. To preserve by removing water from (vegetables, for example). to nitriles. Amides are not readily oxidized oxidized having been modified by the process of oxidation. oxidized cellulose see absorbable cellulose. nor reduced, although hydrogenation hydrogenation (hīdrôj`ənā'shən, hī'drəjənā`shən), chemical reaction of a substance with molecular hydrogen, usually in the presence of a catalyst. (addition of hydrogen at high temperatures and pressures) in the presence of a catalyst will convert most amides of carboxylic acids to amines. The powerful reducing agent lithium aluminum hydride transforms amides into amines. Two very important uses of amides and amines in plastic, and now rubber compounding, are as an antistat, slip and antiblock. Static electricity is a surface phenomenon. Dissipation of a static charge is normally achieved by decreasing the surface resistivity of the polymer. This is done by using surface active additives, such as antistats. Due to the hygroscopic hygroscopic /hy·gro·scop·ic/ (hi?gro-skop´ik) readily absorbing moisture. hy·gro·scop·ic adj. Readily absorbing moisture, as from the atmosphere. nature of these additives, a conductive layer is formed on the polymer surface with a thin film of water from the atmosphere. This process allows the charge to dissipate rapidly. Thus, humidity plays a vital role in this mechanism. With increasing humidity, the surface conductivity of the polymer is increased, resulting in a rapid flow of charges and better antistatic properties (ref. 3). Based on their mode of application, there are two types of surface active antistatic additives, namely, internal and external. Internal antistatic additives are compounded into the resin matrix during processing. These surface active additives have the ability to replenish the polymer's antistatic protection which can be worn off during handling (refs. 4 and 5). The mode of action of internal antistats depends on blooming. Blooming is defined as a process whereby a partially compatible component, in this case the internal antistat, migrates to the surface of the polymer. The internal antistats, therefore, offer long-term protection against accumulation of static electric charges (refs. 6 and 7). By far the largest class of internal antistatic additives is ethoxylated fatty amine (ref. 8). Amides are based on fatty acids derived from naturally occurring feedstocks, such as tallow tallow, solid fat extracted from the tissues and fatty deposits of animals, especially from suet (the fat of cattle and sheep). Pure tallow is white, odorless and tasteless; it consists chiefly of triglycerides of stearic, palmitic, and oleic acids. and rapeseed rapeseed the seed of Target rape grown specifically for the seed and its oil. rapeseed meal as oil cake or meal after rapeseed oil is removed this is a high-protein feed supplement used in cattle. . Primary amides such as stearamide, oleamide and erucamide are internal lubricants having slip and antiblocking properties. They migrate to the surface of a polymer due to their limited compatibility and form an ultra-thin layer that reduces the friction (slip effect) and adhesion forces (antiblocking effect). They offer a solution to processing problems caused by the inherent friction and tackiness of polymers. These problems include slip-stick effect, sticking of film layers to each other (blocking), mold contamination and excessive equipment wear. These problems often result in lower production output and reduced performance during service life. Other categories include: * Amorphous polypropylene; * castor oil and its derivatives; * fluorinated fluorinated material to which a fluoride has been added, e.g. water for human consumption treated as a prophylaxis against tooth decay. products -- fluorochemical fluor·o·chem·i·cal n. A chemical compound containing fluorine, especially a fluorocarbon. and modified PTFE PTFE polytetrafluoroethylene. ; * organosilicone -- blends and combinations of fatty acids and silicone; * silicones; * sodium alkylsulphates; * stearates; * vulcanized vul·ca·nize tr.v. vul·ca·nized, vul·ca·niz·ing, vul·ca·niz·es To improve the strength, resiliency, and freedom from stickiness and odor of (rubber, for example) by combining with sulfur or other additives in the presence of heat vegetable oils. Natural synthetic resins Natural synthetic resins are products originating from thermal polymerization polymerization Any process in which monomers combine chemically to produce a polymer. The monomer molecules—which in the polymer usually number from at least 100 to many thousands—may or may not all be the same. of side products or residues of petroleum or coal industries. These include aliphatic/naphthenic/ aromatic resin blends and combinations; polar surfactants, comprising of mixture of barium salts of tall oil bound to inorganic fillers; polar surfactants on high activity silica; and processing lubricants with surfactant Surfactant Definition Surfactant is a complex naturally occurring substance made of six lipids (fats) and four proteins that is produced in the lungs. It can also be manufactured synthetically. activity. Homogenizing agents Homogenizing agents are included in a large class of products listed under this classification. Homogenizing agents are low molecular weight polymeric resin blends. They assist the widely dissimilar ingredients used in a rubber compound to coalesce and mix into a homogenous uniform processable mass. Each type of elastomer has a plasticizer or plasticizers which are effective in lowering the viscosity or softening the elastomer. In figure 6, some common elastomers have been listed, along with the type of plasticizer that is most effective at softening it. Note that the solubility parameters and polarities of the plasticizers closely match those of the elastomer in which it is most effective. The further apart any two elastomers are in solubility parameter or viscosity, the more difficult they are to get to produce a homogenous mix. Blends of plasticizers, each compatible with different elastomers being blended, are effective at improving blend homogeneity. Plasticizer blends for homogenizing have the disadvantage of being prone to migration and bloom. To overcome the migration problem and still obtain the homogenizing effect, the homogenizing agents contain higher molecular weight homologues of the plasticizers, i.e. resins. The homogenizing resin blend contains portions that are compatible with aliphatic aliphatic /al·i·phat·ic/ (al?i-fat´ik) pertaining to any member of one of the two major groups of organic compounds, those with a straight or branched chain structure. al·i·phat·ic adj. , naphthenic and aromatic parts of the elastomers in a blend. They have a wetting effect, and thereby reduce the energy necessary to get dissimilar components to mix more easily. The polarity and molecular weight of homogenizing agents are shown compared to oils and resins in figures 7 and 8. Peptizers It has been known since the 1800s that natural rubber could be broken down by milling. It was discovered that oxygen was necessary during milling to obtain necessary breakdown. Peptizers are generally radical acceptors or oxidation catalysts, which effectively remove the free radicals formed during the milling and mixing procedures. This action thus prevents recombination recombination, process of "shuffling" of genes by which new combinations can be generated. In recombination through sexual reproduction, the offspring's complete set of genes differs from that of either parent, being rather a combination of genes from both parents. , resulting in a plasticizer effect on the polymer. Thiophenols, aromatic disulfides and chelate chelate Any of a class of coordination or complex compounds consisting of a central atom of a metal (usually a transition element) attached to a large molecule (ligand). complexes of iron, cobalt, copper and manganese catalyze the thermo-oxidative characteristics of some elastomers. Sulfonate sul·fo·nate n. A salt or ester of sulfonic acid. v. 1. To introduce one or more sulfonic acid groups into an organic compound. 2. To treat with sulfonic acid. esters are also considered mild peptizers for natural rubber. Table 8 lists peptizers available in the current market place.
Table 8 -- peptizers
Akrochem peptizer 66 "activated" dibenzamido
diphenyldisulfide on inert carrier
Pepton 44 "activated" dibenzamido
diphenyldisulfide on inert carrier
Pepton 80 "activated" dibenzamido
diphenyldisulfide on inert carrier
Renacit 11 "activated" dibenzamido
diphenyldisulfide on inert carrier
Struktol A 95 "activated"
pentachlorothiophenol on inert carrier
Aktiplast 8 "activated" mixture of fatty
acids, fatty acid soaps and fatty
alcohols
Aktiplast F "activated" combination of zinc
salts of higher molecular
weight, mainly unsaturated fatty
acids
Aktiplast M "activated" combination of zinc
salts of higher molecular
weight, mainly unsaturated fatty
acids
Renacit 8 "activated" blend of unsaturated
fatty acids
Struktol A 80 "activated" mixture of high molecular
weight fatty acids
Struktol A 82 "activated" mixture of fatty acid
salts
Struktol A 91 "activated" mixture of fatty acid
zinc salts
Struktol A 86 blend of organo-metal
complexes, dispersing agents
Struktol A 88 blend of organo-metal
complexes, dispersing agents
Akrochem peptizer 9344 arylamine hydrocarbon mixture
Akrochem peptizer 9349 modified aryl sulfide
hydrocarbon mixture
Akrochem Proaid Pep Zinc salts of high molecular
weight fatty acids
Reogen mineral oil/sulfonate blend
Bondogen mineral oil/sulfonate blend
Peptizer 7010N mineral oil/sulfonate blend
Vanplast PL mineral oil/sulfonate blend
Vanplast R mineral oil/sulfonate blend
Modes of action (table 9)(ref. 9) Limited compatibility (bloom-slippage) Medium to low compatibility (slippage) High compatibility Intermacromolecular action -- reducing the entangle en·tan·gle tr.v. en·tan·gled, en·tan·gling, en·tan·gles 1. To twist together or entwine into a confusing mass; snarl. 2. To complicate; confuse. 3. To involve in or as if in a tangle. ments between polymer molecules. Intramacromolecular action -- swelling and softening polymer molecules. Limited compatibility The product blooms to the surface of the rubber and acts as an external lubricant at the rubber-metal interface producing slippage in the equipment. Medium to low compatibility Below a certain concentration, the material acts as an internal lubricant causing slippage between the flow units of the compound. If the compatibility limit is exceeded, the product also acts as an external lubricant. High compatibility No blooming occurs and the product acts as a bulk viscosity modifier by either of the following mechanisms: * Intermacromolecular action -- the reduction of the entanglements between polymer molecules. Peptizing. * Intramacromolecular action -- the swelling of the polymer molecules and softening them. Plasticization. Tribology tribology Study of the interactions of sliding surfaces. It includes three subjects: friction, wear, and lubrication. Many manifestations of tribology are beneficial and make modern life possible. interaction Adhesive/lubricant/surfactants (ref 10). Examples in elastomers case studies Summary (table 10) We have reviewed a very large class of compounding ingredients called processing additives. I hope that every one of you will have a better understanding of what these products can and cannot do, and that their use is not magic but solid technology. Table 10 -- processing additives according to their effect Antistat Amines Antiblocking Primary amides Assembling agents Vulcanized vegetable oils Dispersant dis·per·sant n. Chemistry A liquid or gas added to a mixture to promote dispersion or to maintain dispersed particles in suspension. Fatty acids Metal soaps Waxes Fatty alcohols Homogenizers HC resins Fatty acid derivatives Phenolic resins Lubricants Metal soaps Fatty acid amides Fatty acid esters Low-molecular HC Mastication mastication /mas·ti·ca·tion/ (mas?ti-ka´shun) chewing; the biting and grinding of food. mastication (mas´tikā´sh aids Aryldisulphides Pentachlorothiophenol Zinc salts unsaturated fatty acids unsaturated fatty acids, n.pl the double- or triple-bonded fatty acids contained primarily in vegetable oils and fish, which remain liquid at room temperature; linked to a reduction in the risk of developing heart disease. Sulphonic acids Reinforcing agents Polymer agents Phenolic resins Tackifiers Phenolic resins HC resins References [1.] Dr. Vince Kuceski, "Plasticizers" (Chicago, IL). [2.] AlliedSignal Technical Reprint CTG CTG Cartridge CTG Center for Technology in Government (SUNY, Albany, New York) CTG Center for Technology in Government CTG Computer Task Group (IT consulting company; Buffalo, NY, USA) 027 by Dr. Eric H. Erenrich and Marco A. Garcia Lopez. [3.] Pfahler, G., "Plastic additives handbook," Gachter R., Muller H., Eds., Hanser Publishers, New York, 3rd Edition, 1990, Chapter 13, 749-772. [4.] Polzhofer, K., Lehman H.D., "Angew. Makromol. Chem., " 1974, 36,145. [5.] Rombusch, K. Maahs G., "Angew. Makromol. Chem.," 1973, 34, 50. [6.] Sharma, A.H., "Plastics handbook," edited by Modern Plastics Magazine, McGraw-Hill, Inc., New York, 1994, ISBN ISBN abbr. International Standard Book Number ISBN International Standard Book Number ISBN n abbr (= International Standard Book Number) → ISBN m 042805-0: Antistats, 94-96; also see van Drumpt, J.D., "Modern plastics encyclopedia," McGraw-Hill, New York, 1992, Mid-October 1992 issue, Chemicals and Additives, Antistats, 150-154. [7.] Balbach, G., "Kunststoffe," 1977, 67, 154. [8.] Reck, R.A., "Encyclopedia of polymer science and engineering, "John Wiley & Sons, New York, 1985, 2, Antistatic Additives, 99-115. [9.] D. G. Lloyd, "Additives in rubber processing," (Monsanto Europe S.A., Brussells, Belgium, Reprinted in Rubber Developments, Vol. 43, No. 314, 1990, 26-33. [10.] Dr. JP. Vander Kooi, "Role of additives in processing of polymers," (ACS (Asynchronous Communications Server) See network access server. Rubber Division, Montreal, Canada, May 5-9, 1996). |
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