Soaps fatty acid

In the fat-splitting process, fats and oils are hydrolysed to glycerol and fatty acid. Prior to saponification the fatty acids can be purified by, for example, distillation in a specific fraction. Soaps of fatty acids are subsequently produced by the neutralization with various 

Reprinted with permission from C Alonso and J A. Zasadzinski, A brief review of the relationships between monolayer viscosity, phase behaviour, surface pressure and temperature using a simple monolayer viscometer, 7- Phys. Chem. B, 110, 22185-22191. Copyright 2006 American Chemical Society. 

More recently. Novales et al. [54] reported the effect of organic counterions on dispersions of a fatty acid and hydroxyl-derivative salts in aqueous solutions that were 

Reprinted with permission from J.R. Kanicky etal., Cooperativity among molecules at Interfaces in relation to various technological processes Effect of chain length on the pK(a) of fatty acid salt solutions, Lanffvuir, 16,172-177. Copyright 2000 American Chemical Society. 

Soap is generally not toxic to aquatic organisms. Reported EC50 values of laurates for algae, fish and Daphnia are 53.0, 11.0 and 10.2 mg/1, respectively [55]. As the solubility of soap is lower in environmentally relevant waters than well water, the bioavailability of soap is generally lower in environmentally relevant waters. Thus, it is generally accepted that soap is even less toxic in aquatic environments than under laboratory conditions using clean water [56]. 

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Three generations of latices as characterized by the type of surfactant used in manufacture have been defined (53). The first generation includes latices made with conventional (/) anionic surfactants like fatty acid soaps, alkyl carboxylates, alkyl sulfates, and alkyl sulfonates (54) (2) nonionic surfactants like poly(ethylene oxide) or poly(vinyl alcohol) used to improve freeze—thaw and shear stabiUty and (J) cationic surfactants like amines, nitriles, and other nitrogen bases, rarely used because of incompatibiUty problems. Portiand cement latex modifiers are one example where cationic surfactants are used. Anionic surfactants yield smaller particles than nonionic surfactants (55). Often a combination of anionic surfactants or anionic and nonionic surfactants are used to provide improved stabiUty. The stabilizing abiUty of anionic fatty acid soaps diminishes at lower pH as the soaps revert to their acids. First-generation latices also suffer from the presence of soap on the polymer particles at the end of the polymerization. Steam and vacuum stripping methods are often used to remove the soap and unreacted monomer from the final product (56). 

In the other market areas, lead naphthenates are used on a limited basis in extreme pressure additives for lubricating oils and greases. Sodium and potassium naphthenates are used in emulsiftable oils, where they have the advantage over fatty acid soaps of having improved disinfectant properties. Catalyst uses include cobalt naphthenate as a cross-linking catalyst in adhesives (52) and manganese naphthenate as an oxidation catalyst (35). Metal naphthenates are also being used in the hydroconversion of heavy petroleum fractions (53,54) and bitumens (55). 

Cosmetics and Personal Care Products. Alkanolamines ate important taw materials in the manufacture of creams (95—97), lotions, shampoos, soaps, and cosmetics. Soaps (98) formed from triethanolamine and fatty acids ate mild, with low alkalinity and excellent detergency. Triethanolamine lauryl sulfate is a common base for shampoos (99—101) and offers significant mildness over sodiumlauryl sulfate. Diethanolamine lauryl sulfate and fatty acid soaps of mono- and trietban olamine can also be used in shampoos and bubble bath formulations. Chemistry similar to that used in soluble oils and other emulsifiers is appUcable to cleansing creams and lotions (102,103). Alkanolamides or salts ate added to the shampoo base to give a smooth, dense foam (104). 

Emulsions. The fatty acid soaps of alkanolamines ate excellent emulsification agents for use in such products as floor poHshes, cosmetics, and functional fluids such as hydrauhc and metalworking fluids. For example, improved hardwater stabiUty of a hydrauhc fluid emulsion is obtained using AMP in the formulation (12). 

The adsorbed layer at G—L or S—L surfaces ia practical surfactant systems may have a complex composition. The adsorbed molecules or ions may be close-packed forming almost a condensed film with solvent molecules virtually excluded from the surface, or widely spaced and behave somewhat like a two-dimensional gas. The adsorbed film may be multilayer rather than monolayer. Counterions are sometimes present with the surfactant ia the adsorbed layer. Mixed moaolayers are known that iavolve molecular complexes, eg, oae-to-oae complexes of fatty alcohol sulfates with fatty alcohols (10), as well as complexes betweea fatty acids and fatty acid soaps (11). Competitive or preferential adsorption between multiple solutes at G—L and L—L iaterfaces is an important effect ia foaming, foam stabiLizatioa, and defoaming (see Defoamers). 

Emulsion Polymerization. In this method, polymerization is initiated by a water-soluble catalyst, eg, a persulfate or a redox system, within the micelles formed by an emulsifying agent (11). The choice of the emulsifier is important because acrylates are readily hydrolyzed under basic conditions (11). As a consequence, the commonly used salts of fatty acids (soaps) are preferably substituted by salts of long-chain sulfonic acids, since they operate well under neutral and acid conditions (12). After polymerization is complete the excess monomer is steam-stripped, and the polymer is coagulated with a salt solution the cmmbs are washed, dried, and finally baled. 

Fatty-acid soaps Alkali, alkaline earth, and other metal soaps sodium stearate aluminum stearate Gear oils paper stock paper sizing glue solutions... 

An emulsified fatty acid soap (e.g., magnesium or iron tallate, having between 8 and 18% metal content. This type of product is cationic and may exhibit some partial solubility in both oil and water. It can be fed by pump (usually a progressive cavity pump or a screw pump). 

Emulsified fatty acid soap, in fuel additives Emulsifiers 680... 

A major part of the physicochemical properties of ether carboxylic acids can be ascertained from the structure by comparing it with that of fatty acid soap, ethoxylated alcohol, and other anionics [64,73] ... 

A fatty acid soap in which a polyglycol ether group has been introduced between the fatty chain and the carboxylic group, which transforms some unfavorable properties of soaps into positive characteristics without decreasing the overall positive effects, and... 

Due to the good lime soap dispersing properties it is possible to improve the foaming properties of hard water-susceptible surfactants. Improvement of the formulation of a fatty acid soap by laureth-17 carboxylic acid, sodium salt [57,62], and an amidether carboxylate [62] has been described. 

Because of improved mildness and lime soap dispersing properties ether carboxylates are also used in fatty acid soap-containing products like soap bars and liquid soaps [57,62] a foam improvement in hard water takes place. 

The use of AOS in toiletries and personal care products has now been established. In India, for example, AOS has been used by leading toilet soap manufacturers with clear performance benefits, especially in hard water-sensitive areas. Combo bars, where part of the usual fatty acid soap is replaced by synthetic AOS as shown in Table 29, seem to be especially attractive from a cost/performance point of view. 

Several decades ago, metal salts of fatty acids—soaps—were the most common anionic surfactants. Due to lots of disadvantages (irritation potential, lime soap, etc.) and the rise of petrochemical industry, the market for soaps dropped down with the exception of the field of body cleaning [1]. Today either surfactants based on petrochemical or natural products can be found in the market. 

Vinyl monomers may be polymerized at favorable rates in an aqueous medium containing an emulsifier and a water-soluble initiator. A typical simple Tecipe would consist of the following ingredients with their proportions indicated in parts by weight 100 of monomer, 180 of water, 2 to 5 of a fatty acid soap, and 0.1 to 0.5 of potassium persulfate. Cationic soaps (e.g., dodecylamine hydrochloride) may be used instead of the fatty acid soap, and various other initiators may replace the persulfate (e.g., hydrogen peroxide and ferrous ion, or a water-soluble organic hydroperoxide). 

Surfactant Fatty acid soaps Emulsification of product... 

The collector used in this experiment was sodium oleate at additions of 300 g/t. In addition to sodium oleate, other fatty acid collectors were examined. The results are given in Table 24.10. From these data, the saturated fatty acid soap was a poor collector for monazite, as well as sodium laurate. 

T. J. Farrell, C. C. Nunn, Fatty acid soap/fatty acid bars which process and have good lather, US Patent 6 846 787 B1 (2005). 

W. Narath, G. Omoski, J. Corr, Enhanced processing of synthetic bar compositions comprising amphoterics based on minimal levels of fatty acid soap and minimum ratios of saturated to unsaturated soap, US Patent No. 6 121 216 (2000). 

Anomolous results have been observed in some emulsion polymerizations—inverse dependencies of N, Rp, and Xn on surfactant concentration. Some surfactants act as inhibitors or retarders of polymerization, especially of the more highly reactive radicals from vinyl acetate and vinyl chloride [Okamura and Motoyama, 1962 Stryker et al., 1967]. This is most apparent with surfactants possessing unsaturation (e.g., certain fatty acid soaps). Degradative chain transfer through allyl hydrogens is probably quite extensive. 

Anionic surfactants are the most commonly used surfactants in emulsion polymerization [Blackley, 1975 Gardon, 1977]. These include fatty acid soaps (sodium or potassium... 

Air-entraining water-reducing admixtures containing lignosulfonates can be based on impure lignosulfonate raw materials, as stated earlier, where only 2-3% additional air is required. However, this air may not be of the amount, type, and stability required, therefore additions of surfactants are made. Several different types can be used but in the majority of cases they are based on alkyl-aryl sulfonates (e. g. sodium dodecyl benzene sulfonate) or fatty-acid soaps (e.g. the sodium salt of tail-oil fatty acids). Additions of these types will allow incorporation of sufficient stable air of the correct bubble size to meet durability requirements under freeze-thaw conditions. 

Air-entraining Neutralized wood resins Fatty acid soaps Alky-aryl sulfonates -3 to 0... 

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