The present disclosure relates to compositions comprising one or more reverse micelles, and methods for their preparation and use. The compositions have switchable viscosities, due to the formation or disruption of the micelles.
In the industrial field, especially in the machine industry, various types of cleaners are used in large quantities to remove machining or preservative oils from machine parts. Recently, efforts such as the use of water-soluble cleaners have begun to be taken to reduce environmental burdens, but more efforts are still needed. Oils used in the machine industry are used for lubrication in machining (e.g., press working) or for protection against rust during storage and have to be highly viscous or adherent. This makes them difficult to be removed. Oils that are difficult to be removed from machine parts significantly affect the subsequent processes other than washing, such as welding, secondary processing, painting, plating and bonding, and also affect the washing system itself when washing is performed.
In the following detailed description, reference is made to the accompanying drawings, which form a part hereof. The illustrative embodiments described in the detailed description, drawings, and claims are not meant to be limiting. Other embodiments may be used, and other changes may be made, without departing from the spirit or scope of the subject matter presented herein. It will be readily understood that the aspects of the present disclosure, as generally described herein, and illustrated in the Figures, may be arranged, substituted, combined, separated, and designed in a wide variety of different configurations, all of which are explicitly contemplated herein.
Compositions, machine oils, press working oils, antirust oils, processes for preparing the compositions and methods for using the compositions are disclosed. The compositions can comprise at least one reverse micelle comprising a first compound and a second compound. The second compound is configured to change conformation from a first conformation to a second conformation, or from a second conformation to a first conformation, in response to a stimulus. The change in conformation can be reversible or irreversible. A first conformation is compatible with formation of the reverse micelle, while a second conformation is not compatible with formation of the reverse micelle, and may either inhibit formation of, or disrupt a previously formed reverse micelle. Examples of conformations include cis- and trans-isomers of compounds, or conformational or configurational isomers (sometimes referred to as “conformers” or “rotamers”) such as staggered or eclipsed isomers. The first compound is selected to interact with the first conformation of the second compound to form the reverse micelle. The second compound is capable of forming the reverse micelle with the first compound. The presence or absence of one or more reverse micelles in the compositions will affect the viscosity of the composition, where increasing the number or concentration of reverse micelles will increase the viscosity of the composition, and decreasing the number or concentration of reverse micelles will decrease the viscosity of the composition. A composition containing reverse micelles can maintain sufficient viscosity for machining applications or storage, and can subsequently be removed using little or no cleaner by disrupting the reverse micelle and lowering the viscosity of the composition. While compositions are described as containing at least one reverse micelle, compositions may contain large numbers of reverse micelles, depending on the volume and concentration of the composition.
The second compound can generally be any one or more compounds having the above described two conformations. In one example, the second compound can comprise a surfactant. The surfactant can form a reverse micelle with the first compound in response to a stimulus such as photostimulation or electric stimulation. The reverse micelle can have a structure in which hydrophilic groups of the second compound are arranged towards the micelle core, and hydrophobic groups are arranged towards the outer phase such as an oil phase. The surfactant can change its structure in response to a stimulus in order to change the hydrophilic-hydrophobic balance such that a formation and/or disruption of a reverse micelle are possible. Various stimuli can be used, such as photostimulation and electrical stimulation.
A surfactant changing its structure in response to the photostimulation can undergo reversible structural changes. Reversible changes of the surfactant can be, for example, conformational changes in response to irradiation with light having a particular wavelength (e.g. visible light) and then return to the original conformation in response to irradiation with light having another particular wavelength (e.g. ultraviolet light). Appropriate wavelengths for a particular surfactant may be known or readily determined. Examples of surfactants that undergo conformational changes in response to photostimulation include photoswitchable azobenzene-modified surfactants. Specific examples of photoswitchable azobenzene-modified surfactants include quaternary ammonium salts of azobenzene compounds.
Compositions containing reverse micelles formed with quaternary ammonium salts of azobenzene compounds exhibit a high degree of change in viscosity when the reverse micelles are disrupted by structural changes in the second compound, and thus can be easily removed from articles such as machine parts. This quaternary ammonium salt can change into a trans-isomer in response to irradiation of visible light, and form a reverse micelle (see
In the formula, R2, R3 and R4 each independently represent a lower alkyl group such as an alkyl group having 1 to 6 carbon atoms or form a pyridinium with the nitrogen atom, R5 represents an alkyl group, L represents an alkylene group or an alkylene-oxy group and X represents a halogen atom.
The lower alkyl group can be a methyl group. R5 can be an alkyl group having 4 to 8 carbon atoms, such as a butyl group, hexyl group or octyl group. L can be an alkylene-oxy group such as an ethylene-oxy group. X can be a bromine atom or a chlorine atom.
Specific examples of quaternary ammonium salts of azobenzene compounds include 4-butylazobenzene-4′-(oxyethyl)trimethylammonium bromide or chloride, 4-hexylazobenzene-4′-(oxyethyl)trimethylammonium bromide or chloride, and 4-octylazobenzene-4′-(oxyethyl)trimethylammonium bromide or chloride. One photoswitchable azobenzene-modified surfactant can be used alone, or two or more photoswitchable azobenzene-modified surfactants can be used in combination.
Alternatively, a surfactant which forms a reverse micelle with the first compound can comprise a quaternary ammonium salt other than a photoswitchable azobenzene-modified surfactant. Such quaternary ammonium salt can be used together with the photoswitchable azobenzene-modified surfactant, or can be used instead of the photoswitchable azobenzene-modified surfactant. When the quaternary ammonium salt is used together with the photoswitchable azobenzene-modified surfactant, the photoswitchable azobenzene-modified surfactant itself can contribute to the formation and disruption of a reverse micelle as at least a part of the reverse micelle. Alternatively, the photoswitchable azobenzene-modified surfactant itself may not be incorporated in the reverse micelle, but can promote the formation or disruption of the reverse micelle by the quaternary ammonium salt. When the composition includes such quaternary ammonium salt instead of the photoswitchable azobenzene-modified surfactant, the composition can include at least one selected from a group consisting of a substituted or unsubstituted cinnamic acid, salt thereof and an ester thereof.
The quaternary ammonium salt can generally be any quaternary ammonium salt. A specific example of a quaternary ammonium salt can be represented by the following formula (2):
wherein R1 represents an alkyl group having 14 to 18 carbon atoms, R2, R3 and R4 each independently represent a lower alkyl group such as an alkyl group having 1 to 6 carbon atoms or form a pyridinium with the nitrogen atom, R5 represents an alkyl group, L represents an alkylene group or an alkylene-oxy group and X represents a halogen atom.
For example, the quaternary ammonium salt can include at least one selected from the group consisting of cetyltrimethylammonium bromide or chloride, cetylpyridinium chloride, octadecyltrimethylammonium bromide or chloride and octadecylpyridinium chloride, or can include cetyltrimethylammonium bromide.
An alternative to photostimulation is electrical stimulation. A surfactant changing its structure in response to the electric stimulation can undergo reversible or irreversible structural changes. When the surfactant's conformational changes are reversible, the formation and disruption of a reverse micelle may also be reversible. When the surfactant's conformation changes are irreversible, the formation and disruption of a reverse micelle may also be irreversible. Reversible changes of the surfactant can be, for example, conformational changes in response to electrolytic oxidation and return to the original conformation in response to electrolytic reduction, and vice versa. Specific examples of such surfactants include redox-active ferrocenyl surfactants. Examples of redox-active ferrocenyl surfactants include (11-ferrocenylundecyl)trimethylammonium bromide. In the redox-active ferrocenyl surfactant, the N terminals are hydrophilic groups and the ferrocene terminals are hydrophobic (lipophilic) groups in the absence of electric stimulation (in the reduced state). In this state, since it is difficult for the reverse micelle to form, and consequently it is also difficult for the reverse wormlike micelle to form, the viscosity of the composition is low. On the other hand, when the redox-active ferrocenyl surfactant is oxidized in response to electric stimulation, the ferrocene terminals are changed into hydrophilic groups. As a result, the hydrophilic-hydrophobic balance changes, forming the reverse micelle (see
The first compound, which interacts with the first conformation of the second compound to form the reverse micelle, can generally be any compound that so interacts. For example, the first compound can comprise at least one compound selected from the group consisting of a substituted or unsubstituted cinnamic acid, a salt thereof and an ester thereof. Specific examples of the compound include cis-cinnamic acid, trans-cinnamic acid, sodium cinnamate, potassium cinnamate, α-methylcinnamic acid, 2-methylcinnamic acid, 2-fluorocinnamic acid, 2-(trifluoromethyl)cinnamic acid, 2-chlorocinnamic acid, 2-methoxycinnamic acid, 2-hydroxycinnamic acid, 2-nitrocinnamic acid, 2-carboxycinnamic acid, trans-3-fluorocinnamic acid, 3-(trifluoromethyl)cinnamic acid, 3-chlorocinnamic acid, 3-bromocinnamic acid, 3-methoxycinnamic acid, 3-hydroxycinnamic acid, 3-nitrocinnamic acid, 4-methylcinnamic acid, 4-fluorocinnamic acid, trans-4-(trifluoromethyl)-cinnamic acid, 4-chlorocinnamic acid, 4-bromocinnamic acid, 4-methoxycinnamic acid, 4-hydroxycinnamic acid, 4-nitrocinnamic acid, 3,3-dimethoxycinnamic acid, ethyl 4-methoxycinnamate, isopropyl 4-methoxycinnamate, octyl 4-methoxycinnamate, 2-ethoxyethyl 4-methoxycinnamate, sodium 4-methoxycinnamate, potassium 4-methoxycinnamate and glyceryl ethylhexanoate dimethoxycinnamate. The first compound can optionally undergo structural changes such as isomerization or dimerization in response to photostimulation such as irradiation with visible light or ultraviolet light. A structural change in the first compound can promote formation or disruption of the reverse micelle by the second compound. For example, when the first compound is changed from a trans-isomer into a cis-isomer by isomerization, this can promote disruption of the reverse micelle, and when the first compound is changed from a cis-isomer into a trans-isomer, this can promote formation of the reverse micelle. The wavelength of light used for the first compound to promote the second compound to form a reverse micelle can generally be any wavelength, and can be in the range of, for example, about 230 nm to about 255 nm, and the wavelength of light used for the first compound to promote the second compound to inhibit or disrupt the reverse micelle can be in the range of, for example, about 260 nm to about 400 nm. The first compound that undergoes structural changes under photodimerization reaction can disrupt or inhibit the reverse micelle with the photodimerization. Photodimerization can be reversible or irreversible.
The first compound can comprise at least one selected from the group consisting of an organic acid, an organic salt, sodium bromide, sodium chloride and hydrogen phthalate. Salicyclic acid is a specific example of an organic acid. Sodium salicylate is a specific example of an organic salt. These first compounds can provide a reversible viscosity change to the composition when used in combination with the second compound. Since the melting point of sodium salicylate is 211° C. at a pressure of 20 mm Hg, the composition can be used in cold press working at room temperature, while it is a less desirable choice for use at high temperatures. In a process involving a high degree of processing (or deformation) expected to generate intense heat due to friction (for example, up to 400° C.), the composition can include sodium bromide which has a high boiling point of 1390° C. at ordinary pressure. In this way, the first compound can be selected depending on the environment in which the composition is used, such as the temperature and the atmosphere.
The composition can further comprise a disperse medium, in which reverse micelles are dispersed. The disperse medium can generally be any suitable material. An example of a disperse medium is an oil. The oil included in the composition can generally be any oil. Specific examples of oils include mineral oil, plant oil and synthetic oil. Other examples include paraffin oil, naphthene oil, aliphatic acid or derivatives thereof, grease-based oil, poly-α-olefin, polyol ester and siloxane. The derivative of the aliphatic acid can include an alkaline metal salt of lanolin acid. The disperse medium can contain one oil or mixtures of two or more oils.
Oils may be selected based upon the intended use or application of the composition. For example, when the composition is used for press working, paraffin oil or naphthene oil can be included as an oil. Oils can also be selected based upon physical or chemical characteristics such as their heat stability, cold gelling, antioxidizing property or extreme-pressure property based upon the intended use or application of the composition.
When the oil composition is used to confer protection against rust for a metallic article, for example by being applied onto the surface of the article, the antirust effect can be increased due to the composition's removal of rust-inducing substances adhered to the article's surface. The second compound can be adsorbed onto the article's surface to avoid adsorption or direct contact of rust-inducing substances such as water or oxygen. The second compound may additionally displace substances already adsorbed onto the article's surface. In addition, since the reverse micelle can incorporate water, the composition can prevent water from directly contacting the surface of the article. A composition used for protection against rust can include mineral oil and/or synthetic oil, a lanolin acid derivative, or plant oil. Examples of lanolin acid derivatives include an alkaline metal salt of lanolin acid. The composition used for protection against rust can include one or more oils such as grease-based oil, naphthene-base mineral oil, paraffin-base mineral oil, poly-α-olefin, polyol ester, and polydimethyl siloxane.
The composition can include one or more additional additives. Examples of additives include viscosity improvers, oiliness improvers, extreme-pressure additives; solid lubricants, antirust agents, antioxidizing agents, anticorrosives, emulsifiers and solublizers. Examples of the oiliness improvers include fats/oils such as colza oil, soybean oil and lard, fatty acids such as oleic acid and stearic acid, higher alcohol such as oleyl alcohol and stearyl alcohol, and esters such as fatty acid ester. Examples of extreme-pressure additives include chlorine-based extreme-pressure additives such as chlorinated paraffin and chlorinated fatty acid, sulfur-based extreme-pressure additives such as polysulfide, sulfurated mineral oil and sulfurated fats/oils, phosphorus-based extreme-pressure additives such as alkyl phosphoric acid ester, and complex extreme-pressure additives such as thiophosphate. Examples of solid lubricants include particulate solid lubricants such as talc, metal powder and polytetrafluoroethylene, and layered solid lubricants such as graphite, molybdenum disulfide (MoS2), boron nitride (BN), and mica. Examples of antirust agents include sulfonate, carboxylate and amine salt. Examples of antioxidizing agents include phenolic compounds and amine salts. Examples of anticorrosives include benzotriazole. One or more additives can be added to the compositions. Examples of commonly used oil additives include Aristonate® series, Calamide® series, Calimulse® EM-95, Calsoft® OS-45S and Pilot® series of Pilot Chemical Company.
The composition can in some cases contain water. If the composition contains a small amount of water, the hydrophilic groups of the second compound surround the water in the composition's reverse micelles. Such reverse micelles can exist in a more stabilized manner based on the interaction between the hydrophilic groups and the water, and thus a composition with a high viscosity can be obtained. If the composition substantially does not contain water, the antirust effect for a metallic article can be increased when the composition is applied on the article, as the reverse micelles can sequester water that subsequently contacts the article. The amount of water added to the composition can be selected accordingly. Example concentrations of water include 0% (no water added), or about 1% to about 10% by weight with respect to the total weight of the composition.
The composition can generally be prepared by any suitable process. For example, a second compound, a first compound, and if desired, water are added and mixed in a disperse medium, and then stirred, for example, with a stirrer, such that a composition can be obtained in a state in which a reverse micelle formed by the first and second compounds is dispersed in the medium. The various components can be combined stepwise or all at once. If the composition contains additives, the composition can be prepared in accordance with the flow chart shown in
The viscosity of the composition with a reverse micelle and the viscosity of the composition without a reverse micelle can be controlled by adjusting the combination and the compounding ratio of each component contained in the composition or by selecting the second compound in consideration of the molecular configuration of the second composition (e.g. length of the long chain portion such as alkyl group).
The viscosity of the composition with a reverse micelle can be selected according to its intended use. For example, when the composition is used as a machining oil such as a press working oil, its viscosity can be about 10×10−3 to about 1000×10−3 Pa·s at 40° C. When the oil composition is used as an anti-rust oil, its viscosity can be about 4×10−3 Pa·s or more at 40° C.
The lower the viscosity of the composition without a reverse micelle is, the easier it is to remove the composition from articles or to apply the composition into pores or holes of the article. For example, considering that the viscosity of water is 0.65×10−3 Pa·s at 40° C., the composition can have a viscosity near water or even lower for easy application and removal. For example, the viscosity of the composition without a reverse micelle can be about 2×10−3 Pa·s or less at 40° C.
The viscosity of the composition can be estimated, for example, by proportional calculation, from the viscosity of each individual component or the viscosity of when a certain component is dissolved in another component. Therefore, after each component is combined based on such estimation and the viscosity of the composition is measured, a composition with a desired viscosity can be obtained by making a fine adjustments to the compounding ratio of each component. The composition can be prepared by referring to or using JIS Handbook No. 25, Oil Volume (2001 edition), or ASTM D341-93 (1998).
The predicted decrease in viscosity when a certain second component is used can be estimated to some extent. Since the formation of the reverse micelle is an exactly opposite phenomenon from the disruption of the reverse micelle, the degree of increase in viscosity is the same as the degree of decrease in viscosity for the disruption. Therefore, after each component is combined based on the above-mentioned estimation and the degree of decrease or increase in viscosity of the composition is measured, a composition with a desired degree of decrease or increase in viscosity can be obtained by making fine adjustments to the compounding ratio of each component.
The composition can be used as described below, for example as also shown in
At some point in time after treatment of an article, an operator may wish to remove the composition from the treated article. This removal is made easier by converting the composition from a relatively high viscosity state to a relatively low viscosity state. Disrupting the reverse micelle structure by applying an appropriate stimulus will decrease the viscosity of the composition. The stimulus can be any appropriate stimulus such as photostimulation, ultraviolet light irradiation, electric stimulation, or electrolytic reduction such as discussed above. Since the lower viscosity facilitates removal of the composition from the article, a higher degree of removal can be achieved using less effort and decreased amounts of cleaners, solvents, and times relative to cleaning a conventionally treated article. Additionally, negative effects caused by residual compositions remaining on the article after cleaning will be reduced in subsequent steps such as when welding, painting, plating, bonding, and other secondary processings are performed on the cleaned article.
The degrees of photostimulation and electric stimulation are not particularly limited, and can be determined according to the type and use of each component such as the first and second compounds. For the degree of photostimulation, the amount of irradiation of light can be, for example, about 100 J/cm2 or more. For the degree of electric stimulation, the applied voltage can be, for example, about +0.15V or more and can be about +0.5V or more.
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/JP2010/071941 | 12/1/2010 | WO | 00 | 7/14/2011 |