fatty esters of oligoesters of a dicarboxylic acid and a polyol retaining at least one free hydroxyl group, particularly of the formula (I): r1—[OR2O—C(O)—R3—(O)C—]m—R4 (I), where r1 is H, a monocarboxylic acid group, or r6O—[c(O)—R3—(O)c]—; r2s are residues of polyols having at least one substituent free hydroxyl; r3s are hydrocarbylene; r4 is —OH, —OM where M is a salt forming metal, amine or ammonium, —OR6, or —OR2O—R7; r5 is c7 to c21 hydrocarbyl; r6 is c8 to c22 hydrocarbyl; r7 is H, or —C(O)r5; and m is 1 to 20; provided that at least one of r1 and r4 is or includes a c8 to c22 group, are surfactants. A range of surfactant properties can be obtained by varying the molecules within these ranges. Especially where r2 is derived from a higher polyol e.g. sorbitol, r3 is c2 to c6, and the fatty terminal group is c8 to c14, the products can be highly water soluble and effective oil in water emulsifiers.
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1. A surfactant compound of formula (I), comprising:
r1—[OR2O—C(O)—R3—(O)C—]m—R4 (I) wherein
r1 is H, a group r5(O)C—, or a group r6O—[c(O)—R3—(O)c]—;
each r2 is independently a c3 to c10 hydrocarbyl group including at least 1 substituent free hydroxyl group;
each r3 is independently a c1 to c20;
r4 is —OH, —OM where M is a salt forming metal, an amine or ammonium group, a group —OROR6, or a group —OR2O—R7;
r5 is a c7 to c21 aliphatic hydrocarbyl group;
each r6 is independently a c8 to c22 aliphatic hydrocarbyl group;
r7 is H or a group —C(O)r5 where r5 is independently as defined above; and
m is from 3 to 20;
provided that at least one of r1 and r4 is or includes a group including a c7 to c21 hydrocarbyl group;
wherein:
i) the surfactant compound comprises a mono- or di-ester derived from the esterification of a fatty acid or fatty alcohol and an oligoester;
i) the oligoester is formed from a dicarboxylic acid and a polyol comprising primary and at least one secondary alcohol; and
ii) the mono- or di-ester comprises at least one free hydroxyl group that is at least one said secondary alcohol.
2. The compound of
a) a fatty acid mono- and bis-ester of a bis-hydroxyl ended oligoester intermediate, of the formula (Ia):
r1a—[OR2O—C(O)—R3—(O)C—]m—OR2O—R4a (Ia) where
each r2, each r3 and m are independently as defined in
r1a is a group r5(O)C—; and
r4a is —H, or a group —C(O)r5;
where each r5 is independently as defined in
b) a fatty acid or fatty alcohol mono- and fatty acid fatty alcohol bis-ester of a hydroxyl carboxyl ended oligoester intermediate, of the formula (Ib):
Rib—[OR2O—C(O)—R3—(O)C—]m—R4b (Ib) each r2, each r3 and m are independently as defined in
r1b is H or a group r5(O)C—;
r4b is —OH, —OM1 where M is a salt forming metal or amine or ammonium group, or a group —OR6;
where each r5 and r6 is independently as defined in
c) a fatty alcohol mono- or bis-ester of a bis-carboxyl ended oligoester intermediate, of the formula (Ic):
r1c—[OR2O—C(O)—R3—(O)C—]m—OR4c (Ic) each r2, each r3 and m are independently as defined in
r1c is a group r6O—C(O)—R3—(O)C—; and
r4c is H or a salt forming metal or amine or ammonium group or a group —OR6;
where each r6 is independently as defined in
4. The compound of
—(CH2)p1(CHOH)p2(CH2)p3— where p1 and p3 are each independently from 1 to 3, and p2 is from 1 to 6.
8. The compound of
11. The emulsion as claimed in
12. The emulsion of
13. A dispersion of a solid in an aqueous medium, wherein the solid phase of said dispersion comprises 0.2 to 10% by weight of the compound of
15. An agrochemical formulation including the compound of
16. A foam drilling fluid including from 1 to 3% by weight of the drilling fluid of the compound of
17. A water based drilling fluid including from 0.05 to 10% by weight of the drilling fluid of the compound of
18. A dispersion of a solid in a non-aqueous medium, wherein the solid phase of said dispersion comprises 0.5 to 7.5% by weight of the compound of
19. An emulsion explosive comprising an emulsion of an aqueous solution of an oxidiser salt in a liquid fuel including from 0.5 to 5% by weight based on the overall emulsion of the compound of
20. A personal care emulsion or dispersion comprising a continuous phase of an emollient oil having dispersed therein a water based liquid, or a hydrophile phase and including the compound of
21. The dispersion as claimed in
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This application is the National Phase application of International Application No. PCT/GB2005/004014, filed 18 Oct. 2005, which designates the United States and was published in English. This application, in its entirety, is incorporated herein by reference.
This invention relates to surfactant compounds which include oligo- or poly-meric esters made up of polyhydroxy hydrocarbyl, particularly saccharide, residues, and dicarboxylic acid residues, modified by the inclusion of a hydrophobic residue, and to the use of such compounds as surfactants, particularly as emulsifiers, especially in personal care formulations.
For effective surfactancy in water based systems, e.g. oil in water emulsions, or dispersing solids in water, it is usually desirable to use surfactants which are relatively hydrophilic, and are typically moderately water soluble. Such surfactants usually have a high HLB (Hydrophile/Lipophile Balance), typically greater than 7 and commonly in the range 8 to 18. Conventionally this has been achieved by using alcohol ethoxylates having relatively long polyoxyethylene chains, typically including at least 10 and sometimes up to about 100 EO groups, for alcohols having C12 to C18 chains, or by using fatty acid esters, usually mainly mono-esters of sugars such as sucrose.
Correspondingly for effective surfactancy in oil based systems it is desirable to use surfactants that are relatively hydrophobic, usually oil soluble and often water insoluble, typically having a low HLB e.g. less than 7 and commonly in the range 4 to 6.
The present invention is based on our finding that certain polyesters of polyols and dicarboxylic acids give intermediate oligomers or polymers that can be further esterified typically with monocarboxylic acids or monohydric alcohols to give compounds which have surfactant activity for example as oil in water emulsifiers. For convenience the intermediate materials may be simply referred to as oligoesters or oligomers.
The present invention accordingly provides a surfactant compound which is a fatty mono- or di-ester of a oligoester of a dicarboxylic acid and a polyol which after polyesterification retains at least one free hydroxyl group.
The compounds of the invention can be fatty acid mono- or di-esters of bis-hydroxyl ended oligoesters; fatty alcohol mono- or diesters of bis-carboxyl ended oligoesters; fatty acid or fatty alcohol mono-esters, or mixed fatty acid fatty alcohol bis-esters of mono-hydroxyl mono-carboxyl ended oligoesters and the invention includes these sub-types of compound.
In particular, the compounds of the invention are of the formula (I)
R1—[OR2O—C(O)—R3—(O)C]m—R4 (I)
where
Within the general formula (I) there are three main groups of compounds:
The compounds of the formula (Ia) include an “extra” residue of the polyol residue —OR2O— and as the residue —OR2O— are the main source of hydrophilicity in the molecule it is likely that such compounds will be intended to be relatively hydrophilic, commonly water soluble and particularly having an HLB value of from 8 to 18. It is likely that such compounds will use relatively short fatty monocarboxylic acid chains e.g. C8 to C14 particularly C10 to C12 in the final esters and will usually be mono-esters (di-esters being less hydrophilic).
Compounds of the formula (Ib) have equal numbers of polyol and dicarboxylic acid residues and are likely to be intermediate in their hydrophilicity and hydrophobicity depending on the particular residues used and the length of the fatty chain(s) in the final esters.
The compounds of the formula (Ic) include an “extra” residue of the —C(O)—R3—(O)C— dicarboxylic acid residue and as this is a source of hydrophobicity in the molecule it is likely that such compounds will be intended to be relatively hydrophobic, commonly water Insoluble, often oil soluble and particularly having an HLB value of from 4 to 6 and may have relatively longer fatty chains in the final ester e.g. derived from C12 to C20, particularly C16 to C18 alcohols.
Compounds of the formula (I) are linear compounds in that the oligoester chain is shown as not being branched or crosslinked and the fatty group in R1 or R4 is shown as terminal on the oligoester chain. As is discussed below, the polyols [typically of the formula (II): HOR2—OH] used in making the compounds of the formula (I) have hydroxyl functionality >2, e.g. sorbitol has a total of 6 hydroxyl groups, so there is a possibility that branching reactions may take place, similarly the dicarboxylic acid [typically of the formula (III): HOOC—R3—COOH] may include functionality that may enable branching e.g. further carboxyl group(s) or hydroxyl group(s). The compounds of the formula (I) have use as surfactants and in such uses it is desirable to avoid this type of branching as we believe it reduces the effectiveness of the compounds as surfactants. Desirably the proportion of such materials having a structure analogous to formula (I) but including branching in the oligoester chain is less than 20 wt %, more desirably less than 10 wt %, and particularly less than 5 wt % of the surfactant product.
The hydrocarbyl group R2 can be considered as the residue of a corresponding polyol HO—R2—OH (II) after removing two hydroxyl groups. R2 is desirably an aliphatic hydrocarbyl group, which will usually be saturated, having from 3 to 10 and particularly 4 to 8, and especially 6, carbon atoms and it will usually be linear though it may include branching. The residue R2 includes at least 1 and more usually from 1 to 6, particularly 1 to 4 and especially 4, hydroxyl groups which will usually be secondary hydroxyl groups (see also below).
To aid manufacture of the desired linear oligomeric intermediate products the polyol (II) desirably includes two relatively reactive hydroxyl groups, the remaining groups being substantially less reactive. Thus, in synthesis involving reaction of the polyol (II) with dicarboxylic acid (III) or a reactive derivative (see below), the predominant reaction is between the carboxylic acid groups and the more reactive hydroxyl groups to give linear oligomers [which are subsequently reacted with the monocarboxylic acid (IV) or a reactive derivative or alcohol (V) (see below)]. In particular, the polyol (II) will have two primary hydroxyl groups and 1 to 6, particularly 1 to 4 and especially 4, secondary hydroxyl groups.
Particularly desirably, R2 is of the formula: —(CH2)p1(CHOH)p2(CH2)p3—where p1 and p3 are each independently from 1 to 3, desirably 1, and p2 is from 1 to 6, more usually from 1 to 4. The corresponding polyols include glycerol, C4 polyols such as threitol and erythritol, C5 polyols such as inositol, arabitol and xylitol and C6 polyols such as sorbitol. The C4 to C6 polyols are commonly the reduced or hydrogenated forms of the corresponding tetrose, pentose and hexose sugars. In such polyols there are two primary hydroxyl groups and 1 to 4 secondary hydroxyl groups. Usually it will be desirable to have a relatively large number of free hydroxyl groups to maximise the hydrophilic contribution of this part of the molecule, however, if desired the number of free hydroxyl groups can be less than the maximum possible e.g. 4 with sorbitol, either by reacting the groups e.g. by etherification or esterification, or by using modified polyols e.g. by forming sorbitan by the anhydridisation of sorbitol.
It is possible to include relatively small proportions of polyol residues which have no free hydroxyl groups e.g. as derived from ethylene, dlethylene, triethylene or propylene glycols or by reacting the polyol so that it only has 2 hydroxyl groups e.g. as in iso-sorbide derived by di-anhydridisation of sorbitol. However, as it is generally desirable to use this part of the molecule to provide hydrophilicity, the proportion of such residues will generally be low, typically an average of not more than 25 mol %, more usually not more than 10 mol %, and desirably not more than 5 mol % of the polyol residues in the molecule.
The group R3 can be considered as the residue of the corresponding dicarboxylic acid HOOC—R3—COOH (III) after removing the carboxylic acid groups and the dicarboxylic acid (III) or a reactive derivative will usually be the synthetic precursor providing the group R3 to the compound of the invention. R3 can be saturated or unsaturated, linear or branched and can be aromatic e.g. a phenyl ring (thus giving a phthalic, terephthalic or iso-phthalic dicarboxylic acid) or and desirably aliphatic, typically an alkylene or alkenylene group, and may be linear or branched, and may be cyclic though it is desirably open chain. Commonly R3 is a group: —(CH2)n—, where n is from 1 to 10, usually from 2 to 10, particularly from 2 to 8, more particularly from 2 to 6. Because mixtures of different dicarboxylic acids (or reactive derivatives) may be used to make materials used in practice, n may appear to be non integral, because it will be an average. The group R3 is usually unsubstituted, but may be substituted e.g. with further hydroxyl or carboxyl groups as in citric acid (which has both).
The C7 to C21 aliphatic hydrocarbyl group R5 can be considered as the residue of the corresponding carboxylic, particularly fatty, acid: R5COOH (IV) and within the compounds of the invention usually appears as part of a carboxyl residue R5(O)C—. Desirably, R5 is a C7 to C17, alkyl, alkenyl or alkadienyl group. Generally within this range, it will be a C7 to C13 particularly a C9 to C13 group when the end product is desired to be hydrophilic and a C15 to C17 group when the end product is desired to be hydrophobic.
The group R6 is a C8 to C22 hydrocarbyl group and can be considered as the residue of the corresponding, particularly fatty, alcohol R1OH (V) and within the compounds of the invention usually appears as part of a hydrocarbyloxy group —OR6. Desirably, R6 is a C8 to C18, group especially an alkyl, alkenyl or alkadienyl group.
Each group R5 or R6 is independently desirably an alkyl, alkenyl or alkadienyl group. In use it may be desired to use a mixture of compounds having different groups R5 or R6 respectively, e.g. as derived from naturally occurring fats and oils or as iso-stearic acid or iso-stearyl alcohol respectively. Further R5 and R6 may each independently be straight chain or branched e.g. as derived from iso-stearic acid or iso-stearyl alcohol respectively, and saturated as derived from lauric, palmitic, stearic or iso-stearic acids or lauryl, palmityl, stearyl or iso-stearyl alcohol respectively; or unsaturated as derived from oleic, linoleic or palmitoleic acids or oleyl, linoleyl or palmitoleyl alcohols respectively.
So-called “iso-stearic acid” is a commercially available material, e.g. from Uniqema, and is a mixture of acids having from 14 to 22, with about ⅔ having 18, carbon atoms, including short, mainly methyl but also including some ethyl, side chains, branching from the main chain mainly in the middle of the chain, typically about the 9-position e.g. from about the 6-position to about the 12-position, in an 18 carbon molecule. The assay molecular weight (e.g. by acid number) is close to that of stearic acid. “Iso-stearic acid” is a co-product (after separation and hydrogenation) from the manufacture of so-called “dimer acids” from C18 unsaturated (mainly oleic and linoleic) fatty acids by catalytic thermal polymerisation.
M is a salt forming metal, an amine or ammonium group. Where M is metal it is particularly an alkali metal e.g. sodium or potassium atom; where M is amine it is particularly mono-, di- or tri-, alkyl or hydroxyalkyl amine, typically containing in total from 1 to 12 carbon atoms; and where M is ammonium, it may be unsubstituted or substituted e.g. with 1 to 4 alkyl groups, the typically containing in total from 1 to 16 carbon atoms.
The index m represents the average number of repeat units in oligomeric ester part of the molecule. Typically m will be at least 3, more usually at least 3.5, and desirably at least 5, though not usually more than 20 and desirably not more than 10 and will desirably be from 3.5, especially 4, to 7. As the number is an average, m may be non-integral.
The properties of the compounds of the invention, particularly the HLB can be varied by choice of the hydrophilic and hydrophobic components of the molecules. Thus increasing the length of the hydrocarbylene group R3 and/or the groups R5, and/or R6, when these are hydrocarbyl, will give a more hydrophobic product; and increasing the number of free hydroxyl groups in the group R2, generally linked with increasing length of the R2 chain, will increase the hydrophilicity of the compounds of the formula (I). Further, the bis-hydroxyl ended oligoester intermediates will generally give more hydrophilic products that corresponding mono- or bis-carboxyl ended intermediates because they will have a (slightly) higher proportion of hydroxyl containing groups. Where the compounds of the formula (I) have a free carboxyl group, then they may have anionic surfactant properties as well as non-ionic properties, especially under alkaline conditions (though being polyesters alkaline conditions may lead to some hydrolysis).
The polymeric chain in the compounds of the invention will generally increase the molecular weight and size of the compounds as compared with e.g. alcohol ethoxylate surfactants. This may lead to useful properties as stabilisers at interfaces e.g. oil water interfaces, as in emulsions, because the molecules will be less easy to displace from the interface.
The compounds of the invention and particularly of the formula (I) can be made by reacting a precursor oligoester (or a reactive derivative) with a reactant which is either or both of a fatty monocarboxylic acid (or a reactive derivative) or a fatty alcohol (or a reactive derivative) under esterification conditions. The reactant chosen in any particular case used will depend on whether the precursor oligoester is bis-hydroxyl ended, mono-hydroxyl mono-carboxyl ended or bis-carboxyl ended. For bis-hydroxyl ended precursor oligoesters the reactant will be a carboxylic acid (or a reactive derivative) for bis-carboxyl ended precursor oligoesters the reactant will be an alcohol (or a reactive derivative) for mono-hydroxyl mono-carboxyl ended precursor oligoesters the reactant will be either a carboxylic acid (or a reactive derivative) or an alcohol (or a reactive derivative) when the desired product is the mono-ester and both such reactants when the desired product is the diester. As those skilled in the art will appreciate, it will often be the case that practical precursor oligoesters will be a mixture of two or possibly all three of the different end group types and the choice of subsequent reactant(s) may be determined by the particular mixture.
The invention accordingly includes a method of making a surfactant compound of the invention which comprises reacting a precursor oligoester (or a reactive derivative) with a reactant which is either or both of fatty monocarboxylic acid (or a reactive derivative) or a fatty alcohol (or a reactive derivative) under esterification conditions to form a fatty ester surfactant of the oligoester intermediate.
The invention particularly includes a method of making a compound of the formula (I) as defined above which comprises reacting a precursor oligoester (or a reactive derivative) with a reactant which is either or both of a C8 to C22 monocarboxylic acid (IV): R5COOH, or a reactive derivative, or a C8 to C22 alcohol (V): R6OH (or a reactive derivative) under esterification conditions to form a fatty ester surfactant of the formula (I).
The oligoester precursor is typically of the formula (VI):
H—[OC(O)—R3—(O)C]n1—[OR2O—C(O)—R3—(O)C]m1—[OR2]n2—OH (VI)
where
Corresponding to the three sub groups of compounds of the invention as discussed above, the invention further includes:
When the oligoester precursor is bis-hydroxy ended it will typically be of the formula (VIa):
H—[OR2—OC(O)—R3—(O)C]m—[OR2]—OH (VIa)
where R2, R3 and m are as defined above for formula (I); and will be reacted with an acid of the formula (IV), under esterification conditions, to make the compound of the formula (I). The molar proportion of acid of the formula (IV) will usually be at least 1 mole per mole of hydroxyl in oligomer (VIa) that it is desired to esterify, generally 1 for a mono-ester and 2 for a di-ester. We have not generally found it necessary to use a significant molar excess of the monocarboxylic acid to promote formation of the ester product.
When the oligoester precursor is mono-hydroxy mono-carboxy ended it will typically be of the formula (VIb):
H—[OR2—OC(O)—R3—(O)C]m—OH (VIb)
and will be reacted with an acid of the formula (IV) or alcohol of the formula (V), under esterification conditions to make the compound of the formula (I). The molar proportion of acid and/or alcohol will usually be at least 1 mole per mole of hydroxyl in oligomer (VIb) that it is desired to esterify, generally 1 for a mono-ester and 2 for a di-ester (of course for the diester one of these moles will be derived from a mono-carboxylic acid and one from an alcohol). We have not generally found it necessary to use a significant molar excess of the monocarboxylic acid to promote formation of the ester product.
When the oligoester precursor is bis-carboxy ended it will typically be of the formula (VIc):
HO—C(O)—R3—(O)C—[OR2—OC(O)—R3—(O)C]m—OH (VIc)
where R2, R3 and m are as defined above for formula (I); and will be reacted with an alcohol of the formula (V), under esterification conditions, to make the compound of the formula (I). The molar proportion of alcohol of the formula (V) will usually be at least 1 mole per mole of carboxyl in oligomer (VIc) that it is desired to esterify, generally 1 for a mono-ester and 2 for a di-ester.
Of course, the immediate resulting product will be a statistical mixture of mono-ester, di-ester and unreacted oligomer the proportions depending on the proportions of the oligomer and acid and the reaction conditions employed.
The precursor oligoesters of the formula (VIa), (VIb) and (VIc) can be made by reacting a polyol (III) and dicarboxylic acid (IV) under esterification conditions, particularly using a catalyst e.g. an alkali catalyst. The particular nature of the oligoester or the proportions of the oligoesters (VIa), (VIb) and (VIc) In a mixture will depend on the effective molar ratio of the starting polyol (II) and dicarboxylic acid (III) and the reaction conditions used in the esterification reaction. Where the starting materials include groups that may be susceptible to decarboxylation reactions e.g. malonic acid, or to branching reactions e.g. tricarboxylic acids such as citric acid (which may also be susceptible to decarboxylation) the use of relatively gentle oligomerisation (esterification) conditions can be useful to obtain the desired product. We have found that not adding a separate catalyst (the acid groups in the starting materials will provide some catalysis), while operating under relatively moderate elevated temperatures as is described below, can enable successful reactions with such materials, particularly malonic and citric acids, where the use of catalysts may in effect act to promote side reactions to an undesirable extent.
Especially where the polyol (II) has four or more carbon atoms and four or more hydroxyl groups, usually two primary hydroxyls and 2 or more secondary hydroxyls, it may be susceptible to react to form cyclic ethers. For example sorbitol can form sorbitan cyclic ethers which may react further to form the dicyclic diether iso-sorbide. This reduces the number of free hydroxyl groups and is thus generally undesirable, but may need to be taken into account in choosing the proportions of starting materials for making the intermediate oligoester. Where the intermediate oligomer is hydroxyl or predominantly hydroxyl ended, it may be desirable to use a molar excess of the polyol (II) to promote speedy polyesterification In making the intermediate, leaving unreacted polyol at this stage. We have not generally found it necessary to remove such unreacted polyol before the second stage reaction.
We have found that it is practical to make the compounds of the formula (I), by first making the oligoester (VI) by reaction of polyol (II) and dicarboxylic acid (III) under alkali catalysis and then further reacting the oligomer with carboxylic acid (IV) and or alcohol (V). The same reaction vessel may be used and it may not be necessary to separate or purify the oligomer, before further reaction. Using alkali derived from alkali metals e.g. sodium or potassium hydroxide or carbonate, particularly mild alkali such as carbonates, especially potassium carbonate, appears to be effective, particularly when making oligoesters that are hydroxyl ended e.g. the bis-hydroxyl ended oligoesters especially of the formula (Ia). Further such catalysts can be used for the further esterification and it is thus possible to use the same catalyst used in the oligomerisation. If required further catalyst may be added between the first and second stages of reaction.
In relation to the synthesis of the intermediate oligoesters, the present invention includes a method of making an oligoester which comprises reacting a polyol (or a reactive derivative) with a dicarboxylic acid (or a reactive derivative), under esterification conditions to form an oligoester.
In this aspect, the invention particularly provides a method of making an oligoester of the formula (VI) as defined above which comprises reacting a polyol of the formula (II): HO—R2—OH, (or a reactive derivative) with a dicarboxylic acid of the formula (III): HOOC—R3—COOH, (or a reactive derivative), under esterification conditions to form the oligoester. As is noted above the oligoesters can be bis-hydroxyl ended of the formula (VIa), bis-carboxyl ended of the formula (VIc), or mono-hydroxyl mono carboxyl ended of the formula (VIa).
Desirably the esterification conditions include:
In these reactions (making the oligoester intermediate or subsequent esterification to form the surfactant compounds) carboxylic acid functionality may be substituted by reactive derivatives such as lower e.g. C1 to C6, alkyl, particularly methyl or ethyl, esters, as in dialkyl esters of the dicarboxylic acid (III) or esters of the acid (IV) which may be glycerides such as triglycerides having residues of the fatty acid (IV), or anhydrides. We have successfully used acid anhydrides to make the intermediate oligoesters, but care may be needed when using anhydrides because they are relatively reactive and in making the oligomer they may react also with less reactive hydroxyl groups thus potentially leading to branched oligomers which are likely to form water Insoluble or intractable gels of little value as emulsifiers even after subsequent esterification. Even more reactive carboxylic acid derivatives such as acid halides will not generally be used for this reason. Where esters are used as the source of the carboxylic acids, the catalyst used may be an alkali as described above or a catalyst specifically for trans-esterification reactions e.g. titanate ester such as tetrabutyl titanate.
Particularly where the polyol used in making the oligoester intermediate has more than 3 hydroxyl groups e.g. where it has five or more hydroxyl groups, particularly on adjacent carbon atoms, the polyol may be liable to react such as by cyclising e.g. to form sorbitan from sorbitol, or pyrolysis, if heated sufficiently. Thus, when these materials are used, it is desirable to use temperatures that are lower that are typically in making carboxylic acid esters, particularly with relatively long chain acids. Typically, using such materials, the temperatures used will be at least 100° C., more usually at least 120° C. and desirably at least 150° C., but not more than 200° C., more usually not more than 185° C., particularly not more than 180° C., with reaction temperatures about 170° C., being particularly suitable. Such relatively mild esterification temperatures also appear to avoid or reduce the extent of reaction at secondary hydroxyl groups this minimising the degree of branching in the oligoester intermediate of side chain esterification in the surfactant compounds. The use of mildly subambient pressure e.g. from 50 to 250 mBar (0.5 to 25 kPa) e.g. about 100 mBar (10 kPa) can benefit reaction speed to make the use of such temperatures more practical.
If the materials produced by the synthesis are coloured, particularly by coloured impurities, then the level of colour may be reduced by treatment with activated carbon and/or by bleaching e.g. with hydrogen peroxide particularly in making products for personal care end use applications.
The compounds of this invention can be made to have a range of water and/or oil solubility and thus can be used as surfactants in water or oil based systems. In particular, the compounds of the invention may have HLB values in the range 4 to 18, including the relatively hydrophilic range 8 to 18 and the relatively oleophilic (hydrophobic) range 4 to 6.
Surfactants used in water based systems are generally water soluble, having an HLB greater than 7, particularly from 8 to 18. Such materials can be used as oil in water emulsifiers, particularly in personal care applications; as dispersants for pigments; as emulsifiers in emulsion polymerisation; as wetting agents in aqueous systems; as surfactants in domestic detergents, particularly in laundry formulations; in crop protection formulations particularly as adjuvants, dispersants and/or emulsifiers in agrochemical formulations; and other applications.
The properties of the surfactants of this invention also make them suitable as emulsifiers particularly in oil in water emulsions e.g. in personal care applications. Personal care emulsion products can take the form of creams and milks desirably and typically include emulsifier to aid formation and stability of the emulsion. Typically, personal care emulsion products use emulsifiers (including emulsion stabilisers) in amounts of about 3 to about 5% by weight of the emulsion. The oil phase of such emulsions are typically emollient oils of the type used in personal care or cosmetic products, which are oily materials which is liquid at ambient temperature or solid at ambient temperature, in bulk usually being a waxy solid, provided it is liquid at an elevated temperature, typically up to 100° C. more usually about 80° C., so such solid emollients desirably have melting temperatures less than 100° C., and usually less than 70° C., at which it can be included in and emulsified in the composition.
The concentration of the oil phase may vary widely and the amount of oil is typically from 1 to 90%, usually 3 to 60%, more usually 5 to 40%, particularly 8 to 20%, and especially 10 to 15% by weight of the total emulsion. The amount of water (or polyol, e.g. glycerin) present in the emulsion is typically greater than 5%, usually from 30 to 90%, more usually 50 to 90%, particularly 70 to 85%, and especially 75 to 80% by weight of the total composition. The amount of surfactant used on such emulsions is typically from 0.1 to 10%, more usually 0.5 to 8%, more desirably 1 to 7%, particularly 1.5 to 6%, and especially 2 to 5.5%, by weight of the emulsion.
The end uses formulations of such emulsions include moisturizers, sunscreens, after sun products, body butters, gel creams, high perfume containing products, perfume creams, baby care products, hair conditioners, skin toning and skin whitening products, water-free products, antiperspirant and deodorant products, tanning products, cleansers, 2-in-1 foaming emulsions, multiple emulsions, preservative free products, emulsifier free products, mild formulations, scrub formulations e.g. containing solid beads, silicone in water formulations, pigment containing products, sprayable emulsions, colour cosmetics, conditioners, shower products, foaming emulsions, make-up remover, eye make-up remover, and wipes. A preferred formulation type is a sunscreen containing one or more organic sunscreens and/or inorganic sunscreens such as metal oxides, but desirably includes at least one particulate titanium dioxide and/or zinc oxide,
The surfactants of this invention can be used as emulsifiers in emulsion polymerisation. Typically emulsion polymerisation is carried out on emulsions of ethylenically unsaturated monomers in water. Suitable monomers include unsaturated carboxylic acids and their alkyl esters, amides, N-substituted amides and nitrites, aromatic vinyl compounds, diene compounds which may be included as monomers or specifically as crosslinking agents, vinylethers, vinylesters, olefines and hydrophobic allyl compounds.
Such emulsion polymerisation methods are particularly applicable to the manufacture of acrylic copolymers, for example those where at least 50%, more usually at least 60%, desirably at least 80% e.g. 90% or more up to 100%, by weight of the monomers are acrylic monomers. The acrylic polymers may be those based on mixed alkyl acrylates, especially where the predominant monomer is methyl methacrylate, and may include anionic units such as (meth)acrylic acid units or cationic units such as amino substituted ethylenically unsaturated monomers.
The amount of surfactant used will depend on the particular monomers and the polymerisation system used, the degree of colloidal stability needed and the desired particle size of the polymer in the product latex. For an otherwise conventional oil in water emulsion polymerisation, to give a latex having a particle size of from 80 to 500 nm the amount of surfactant used will typically be from 0.25 to 5 parts by weight surfactant per 100 parts by weight total monomer (phm). More usually the amount will be from 0.5 to 2.5 phm, particularly from 1 to 2 phm.
In microemulsion polymerisation systems, the concentration of monomer is typically substantially lower than in conventional emulsion or other dispersion polymerisation systems e.g. from 3 to 10% by weight. The proportion of surfactant relative to the amount of monomer is also relatively high because the microemulsion has higher interface area per unit mass of monomer corresponding to the smaller emulsion particle size and typical levels can be from 10 to 150 phm. Overall solids contents of microemulsion systems are usually in the range 15 to 30% by weight of the total emulsion.
The surfactants of this invention can be used as dispersants for solids in aqueous media, particularly for pigments, including inorganic pigments e.g. titanium dioxide, pigmentary iron oxide and organic pigments e.g. phthalocyanine pigments, carbon black, and similar materials. The amount of surfactant used in such dispersant applications depends on the materials employed and the dispersion concentration required, but is usually from 0.2 to 10% by weight of the solid e.g. pigment being dispersed. In aqueous dispersions, for inorganic pigments the amount used is typically from 0.05 to 5%, more usually 0.1 to 2.5%, by weight of the solid dispersed and for organic pigments typically the amount used is from 3 to 10% by weight of the solid dispersed. Typical such dispersions will contain up to about 70%, often up to about 65%, of inorganic pigment and up to about 35% by weight organic pigment, but this may be up to 50% for pigment pastes. When incorporated into end use products such as paints typical pigment levels in the final product will be about 3 to about 30%, particularly about 20 to about 25%, for inorganic pigments, about 1 to about 15% for organic pigments, particularly about 10 to about 12%, especially for phthalocyanine type organic pigments, and about 0.5 to about 5%, particularly about 3 to about 3%, for carbon black. The continuous phase in such dispersions will usually be water based.
The surfactants can also be used as domestic detergents for example in laundry applications and may be used alone or in combination with other, non-ionic, anionic, cationic, amphoteric and/or zwitterionic surfactants. Formulations including surfactants of this invention for laundry use will typically also include further components including one or more of builders e.g. phosphates, particularly sodium tripolyphosphate; organics such as citrate and/or tartrate; and/or zeolites; flow and/or filter aids, commonly used in powder formulations, which may include co-builders such as sodium carbonate and/or bicarbonate, particularly in powders where the builder is a zeolite (though because typical co-builders are alkali, they will not usually be used in hand washing formulations); corrosion inhibitors; anti-redeposition aids such as carboxy methyl cellulose; and optical brighteners. Further components may include perfumes; enzymes, including lipases, proteases, cellulases and/or amylases; bleaches, typically based on sodium perborate, sodium percarbonate or similar materials, which will typically be used with bleach activators such as tetra-acetyl ethylene diamine (TAED); and stabilisers such as phosphonates or ethylene diamine tetra-acetic acid (EDTA) usually as the sodium salt; soaps; foam control agents (often soaps) and fabric conditioners (softeners) such as quaternary ammonium salts and amine oxides which may be coated onto bentonite type clays.
The compounds of the invention can used as surfactants in agrochemical formulations, in particular as adjuvants for example with herbicides, fungicides, insecticides, acaricides and plant growth regulator formulations, dispersants and/or emulsifiers. The amount of surfactant used to disperse agrochemical(s), is typically at a concentration of 1 to 30% based on the formulation and used as adjuvants, a concentration of from 5 to 60% based on concentrate formulations and 1 to 100% in or as components for addition to tankmixes. Other conventional components can be included in such formulations such as oils e.g. mineral oil(s), vegetable oil(s) and alkylated vegetable oil(s); solvents and/or diluents; and other surfactants which may be anionic surfactants, cationic surfactants or non-ionic surfactants. Such other components will, as with formulations using purely conventional surfactants, be used in amounts based on the desired effect.
The surfactants of the invention can also be used in oilfield applications e.g. as foaming agents in foam drilling, as kinetic gas hydrate inhibitors and as water based drilling fluid lubricants.
Foam drilling fluids are water based drilling fluids in which the water phase is foamed e.g. to minimise formation damage of water sensitive formations. As foaming agents in foam drilling fluids the amount of the surfactant used will typically be from 1 to 3%, more usually from 1 to 2%, by weight of the drilling fluid.
Kinetic gas hydrate inhibitors are materials added to water containing hydrocarbon, particularly C1 to C4 hydrocarbon alkane containing streams to slow down gas hydrate formation or to modify the crystal form of the gas hydrate so as to reduce crystal agglomeration which otherwise would lead to pipe or similar blockage. In gas hydrate inhibition, the surfactants will typically be used at from 0.05 to 5% by weight based on the water phase of the stream being treated.
The surfactant compounds of the invention may be used to provide enhanced lubricity in water based drilling fluids. In use in this application the amount of surfactant used will typically be from 0.05 to 10% by weight of the fluid.
Surfactants used in oil based systems are generally oil soluble and usually water insoluble and in particular having an HLB of less than 7, more usually from 4 to 6. Such materials can be used as emulsifiers and/or stabilisers for water in oil emulsions; or as dispersants for solids in non-aqueous liquids. As such they can be used in a wide variety of applications including in: (water in oil) emulsion polymerisations, particularly to make polyacrylamide (PAM) or related polymers by free radical inverse emulsion polymerisation (i-PAM); emulsion explosives; in water in oil cosmetic emulsions; agrochemical, particularly plant growth regulator, herbicide, and/or pesticide, emulsions dispersions and suspoemulsions; and as emulsifiers and/or dispersants; dispersions of solids, such as pigments and/or inert inorganic metal salts, especially in organic media; oilfield drilling fluid additives, particularly as dispersants and/or emulsifiers for drilling muds and invert emulsion drilling fluids; metal working applications particularly in rolling oil emulsions and cutting fluids.
The surfactants of the invention can be used as emulsifiers in i-PAM polymerisation, in which acrylamide and any co-monomer(s), are dissolved in water, this solution is emulsified in oil, using surfactants as emulsifiers and stabilisers, and the polymerisation initiated. The result is a dispersion of water droplets, containing dissolved PAM, in the oil. Although the viscosity of the aqueous PAM solution is high, the effective viscosity of the emulsion is determined primarily by the oil continuous phase, chosen to be suitably low. In use e.g. in water treatment, the emulsion has to be broken, usually by inverting on dilution into water. The surfactant system must provide adequate emulsion stability before, during and after (for storage) polymerisation, but permit ready breaking of the emulsion during inversion on dilution into water, to facilitate rapid release of the polyacrylamide polymer into the water phase in which it will act. Inversion is commonly promoted by the addition of hydrophilic surfactants after the polymerisation. Relatively oleophilic surfactants of the invention can be used to emulsify and/or stabilise the water in oil emulsion used in this type of polymerisation process.
In i-PAM, the oil phase is typically a mineral oil, particularly a paraffin oil, or an ester oil and the amount of emulsifier surfactant used is typically from 2.5 to 7%, usually from 3 to 4%, by weight of the polymerisation emulsion. The emulsifier system will typically combine a polymeric surfactant, particularly including a surfactant of invention especially of the formula (I), and a low molecular weigh low HLB surfactant (relatively less effective as an emulsion stabiliser so that the stabilisation of the emulsion is not so good that inversion is difficult)—the low molecular weight enables it to readily diffuse away from the phase interface during inversion. Commonly the low molecular weight surfactants are fatty acid monoglycerides, fatty acid sorbitan esters or similar surfactants. The relative proportions by weight of polymeric surfactant to low HLB low molecular weight surfactant is typically from 5:95 to 50:50 more usually from 10:90 to 40:60 and commonly about 15:85 to 30:70.
Oleophilic types of surfactants of this invention can also be used in dispersing solids, particularly pigments such as those described above, in non-aqueous media such as white spirit or aromatic media. In such uses the amount of surfactant used will typically be from 0.5 to 7.5%, more usually from 1 to 5%, by weight of the dispersion.
The compounds of the invention are also useful as emulsifiers or emulsion stabilisers in emulsion explosives in which an oxidiser, typically an aqueous solution of an oxidiser salt usually nitrates, is emulsified in a liquid fuel, typically a hydrocarbon fuel such as mineral and/or paraffin oil, which may also include other petroleum components e.g. micro-crystalline wax, paraffin wax, slack wax, and/or petroleum refining distillation residues. The oxidiser solution is usually a saturated or supersaturated aqueous solution, of nitrate salts, particularly NH4NO3, alkali metal nitrates or alkaline earth metal nitrates, optionally with minor proportions of other salts e.g. NH4Cl and typically contains 40% to 70% by weight ammonium nitrate and 20% of other nitrates. The internal oxidiser phase is typically at least 75% more usually more than 90% e.g. about 95%, by volume of the emulsion explosive. For use, emulsion explosives typically also include additives to sensitise the compositions to detonation. Commonly this is done by adding materials that provide solid surfaces e.g. solid NH4NO3, especially as prills, or gas filled voids e.g. by including sodium nitrite, which produces gas by chemical reaction, or glass microspheres, which provide physical voids.
The compounds of the invention particularly of the formula (I) can be used as emulsifiers alone or in combination with other typically oil soluble emulsifiers particularly sorbitan fatty acid esters such as sorbitan mono oleate (SMO); phospholipids such as soyalecithin or oxazoline or imidazoline derivatives thereof; PIBSA alkanolamine reaction products; or fatty acid condensation products with polyethylene glycols. The total amount of emulsifier used in emulsion explosives is typically from 0.5 to 5%, more usually from 1 to 4%, by weight based on the overall emulsion. Desirably, the proportion of emulsifier of the formula (I) is at least 50%, more usually at least 75%, by weight of the total emulsifier used in the emulsion explosive.
The compounds of the invention can be used as water in oil dispersants and/or emulsifiers in personal care and cosmetic applications, in particular, in formulations including relatively high concentrations of solutes in a dispersed hydrophilic phase and in the manufacture of multiple emulsions. The oil phase used in this aspect of the invention is typically an emollient oil which may be liquid or solid at ambient temperature.
The discontinuous, usually aqueous, phase can be water or a water based liquid, or a hydrophile phase which can be a solution in water of the hydrophilic material or the discontinuous phase can, in certain cases, be a substantially water free liquid phase of the hydrophilic material. In such systems the surfactant of the invention is typically used in an amount of 0.5 to 5%, more usually from 1 to 2%, by weight of the total emulsion.
The surfactants of this invention can be used as emulsifiers and/or dispersants in agrochemical applications. The invention accordingly includes an agrochemical emulsion or dispersion, in which at least one surfactant compound of the invention, particularly of the formula (I), is included as an emulsifier or dispersant. Within this, more particularly the invention includes:
The agrochemically active material(s) included in the emulsions and/or dispersions in this aspect of the invention can include one or more plant growth regulators, herbicides, and/or pesticides, for example insecticides, fungicides, acaricides, nematocides, miticides, rodenticides, bactericides, molluscicides and bird repellants. Examples of classes of actives include: Herbicides: including water soluble, particularly non-selective, herbicides, particularly N-phosphonomethyl glycine herbicides e.g. Glyphosate and Sulfosate, and the glufosinate and bipyridyl types of non-selective herbicides, triazines, substituted ureas, sulphonyl ureas, pyridine carboxylic acids, aryloxy alkanoic acids, 2-(4-aryloxy-phenoxy)propionic acids, bis-carbamates; Fungicides: including thiocarbamates, particularly alkylenebis(dithiocarbamate)s, strobilurins, dicarboximides, benzimidazoles, azoles, inorganic fungicides; insecticides including benzoyl ureas; and Acaricides including tetrazines.
Particular applications of the polymeric surfactants of the invention in agrochemicals include:
In agrochemical compositions, the surfactants of the invention, particularly of the formula (I), can be used alone or in combination with other polymeric surfactants, but desirably, the proportion of surfactant of the invention, particularly of the formula (I), is at least 50%, more usually at least 75%, by weight of the total polymeric surfactant used as emulsifier and/or stabiliser and/or dispersant in the composition.
One area of practical importance in this aspect of the invention is sunfilters and sunscreens or other cosmetics containing sunfilter and/or sunscreen components. The sunfilters or sunscreens can be physical sunscreens such as those based on titanium dioxide e.g. ultra-fine titanium dioxide, or zinc oxide, which are understood to act by strongly scattering ultraviolet radiation, or chemical sunfilters or sunscreens such as compounds that absorb ultraviolet radiation, particularly UVB and UVA sunscreen agents. The amount of sunfilters and/or sunscreen used will depend on the properties of the materials used, but typically for physical sunscreens the amount will be 0.1% to 5%, more usually from 0.25 to 2.5%, by weight of the overall emulsion and for chemical sunfilters and/or sunscreens 0.05 to 3%, more usually from 0.1 to 1.5%, by weight of the overall emulsion. Depending on their nature the sunfilter and sunscreen components may be present in the generally aqueous discontinuous phase or in the oil continuous phase or in both phases. Particularly where the sunscreens is a physical sunscreen, the overall emulsion will be combined suspension and emulsion and these are commonly referred to as suspoemulsions (see further below).
Suspoemulsions are a further important area in this aspect of the invention. They are briefly referred to above in connection with sunscreens, but other solid components can be included such as pigments as are often included in make up cosmetics. When pigments are used, they may be pigments organic or inorganic and may be present in the oil phase, particularly for organic pigments and hydrophobic inorganic pigments, or in the present in the water phase, particularly for hydrophilic Inorganic pigments, or in both phases, when used are typically present in concentrations of from 0.5 to 20% more usually from 1 to 10%, by weight of the emulsion.
Generally the amount of the compound of the formula (I) used in cosmetic compositions of this aspect of the invention is from 0.5 to 7%, more usually from 1 to 5%, by weight of the formulation. The compound of the formula (I) can be used alone or in combination with other polymeric emulsifiers, but desirably, the proportion of the compound of the formula (I) is at least 50%, more usually at least 75%, by weight of the total emulsifier used in stabilising the cosmetic emulsion.
The surfactant compounds of the invention may also be used as demulsifiers in oilfield applications. Demulsifiers are typically used to aid separation of water emulsified in the hydrocarbon phase of oils. In use as demulsifiers, the amount of surfactant used as a demulsifier will typically be from 1 to 500 ppm, particularly from 5 to 150 ppm, by weight of the oil stream.
The surfactant compounds of the invention may also be used as emulsifiers and/or lubricants in metal working applications particularly in rolling oil emulsions and cutting fluids.
The compounds of the invention can further be used as dispersants finely divided solids in non-aqueous fluids, particularly liquid organic media. Examples of such materials include pigments, particularly for paints and solvent inks; dyes including disperse dyes; magnetic metal oxides; extenders and fillers; optical brightening agents; and textile auxiliaries; solids for oil based and invert emulsion drilling muds; dirt and solid particles in dry cleaning fluids; and magnetic materials for magnetic recording media. The medium is typically an oil such as a hydrocarbon or A natural or synthetic ester oil, or a coating composition resin such as an alkyd resin, or special mixture of glycols typically used in the preparation of multi-purpose pigment pastes or pigment concentrates. Such dispersions typically contain from 5 to 95%, more usually from 10 to 60%, and especially from 20 to 50%, by weight of the solid, depending on the nature of the solid and the relative densities. The dispersion may be made by conventional method for making dispersions.
The following Examples illustrate the invention. All parts and percentages are by weight unless otherwise stated.
Materials
Polyols
PC6a
sorbitol (100% active)
PC6b
sorbitol (70 wt % aqueous solution)
PC3
glycerol (100% active)
PC5
xylitol (100% active)
PC3/C6
glycerol sorbitol mixture (1:3 molar ratio)
Di-acids
DAC6
adipic acid
DADMA
dimethyl adipate
DAC4
succinic acid
DAC8
suberic acid
DAC10
sebacic acid
DAC5
glutaric acid
Mono-acids
MAC8
octanoic acid
MAC12
lauric acid—Prifac 2922 ex Uniqema
MAcofa
coconut oil fatty acids (mainly C12)
MAC16
palmitic acid
MAC18
stearic acid
MAC18i
iso-stearic acid (a mixture of C14 to C22 fatty acids averaging
about C18)
Catalysts
Cat1
K2CO3
Cat2
NaOH
Oils
Oil1
iso-hexadecane oil (Arlamol HD ex Uniqema)
Surfactants
Surf1
stearyl alcohol 20 ethoxylate (Brij 78 ex Uniqema)
Test Methods
Acid Value (AV) was measured by the method of ASTM D1980-87.
Emulsion Stability
Oil in water emulsions (1% w/w emulsifier, 20% w/w oil) were prepared by weighing 158 g of demineralised water into a 400 ml tall form beaker, adding 2 g of test emulsifier and stirring the mixture using a magnetic flea and hotplate/stirrer at room temperature until completely dissolved. 40 g of Oil 1 were then added to the aqueous solution and the mixture homogenised using an Ultra Turrax T25 blender at 11000 rpm (ca 183 Hz) for 2 mins. The resultant emulsion was transferred to two 50 ml volumetric cylinders, one of which was stored at room temperature (Amb) and the other in a hotbox at 50° C. The emulsion mean droplet size (in μm) of the stored samples was measured using a Coulter Multisizer II after 1 day (1 D), 1 week (1 W), and 1 month (1 M).
Anhydrous sorbitol (182 g; 1 mol), adipic acid (87.6 g; 0.6 mol) and potassium carbonate (9.66 g; 7 mol % based on sorbitol) were charged to a 250 ml round bottomed flask fitted with a propeller stirrer, side-arm water condenser and collection flask, vacuum pump, nitrogen sparge and thermometer (thermocouple) and on an isomantle. The mixture was heated under stirring (200 rpm) to distil off free water (mostly at below 130° C.); vacuum (100 mbar) was then applied and the temperature was increased to 170° C. and held until the acid value of the mix was <5 mg KOH.g−1 (normally 3 to 4 hrs). The vacuum was then released and molten lauric acid (30.1 g; 0.15 mol) at ca. 90° C. was added. Vacuum (500 mbar) was re-applied and the mix stirred (300 rpm) with the nitrogen sparge until the acid value was <5 mg KOH.g−1 (normally after ca, another 3 to 4 hours); the vacuum was then released and the product discharged.
The structure of the product was confirmed using MALDI mass spectrometry and gel permeation chromatography.
Further esters of oligopolyol esters were made by the general method set out in Example SE1 but making changes to the starting materials, material proportions or conditions. Table 1a below (including SE1 for completeness) sets out the diacid and other materials used and reaction conditions for the oligomerisation esterification and Table 1b the monoacid and reaction conditions for the second stage esterification together with some information on the properties of the products made. In these tables, the molar % figures are based on the polyol used.
In making these compounds variations of the synthetic route described in Example SE1 were also used. In particular anhydrous sorbitol could be substituted for the aqueous sorbitol used in SE1 and for materials including succinic acid residues succinic anhydride could be used instead of succinic acid e.g. using the following procedure:
200 g anhydrous sorbitol (1.10 mol), 65.9 g (0.66 mol) succinic anhydride and 11.5 g (7.5 mol % based on sorbitol) potassium carbonate were charged to a 500 ml round bottomed flask equipped as in SE1. The mixture was heated under stirring (200 rpm) to 140° C. After 30 mins at this temperature, a sample was taken for FT-IR analysis (to confirm the absence of anhydride). The temperature was increased to 165° C. and a vacuum (100 mbar) was applied. The reaction was maintained under these conditions until the acid value of the reaction mix was <5 mg KOH.g−1 (normally 3 to 4 hrs). The vacuum was released and the product discharged.
Using these methods the products were very similar to corresponding compounds made using the method of SE1.
TABLE 1a
Ex
Diacid
Catalyst
Temp
Press
Time
No
Polyol
type
mol1
type
mol %1
(° C.)
(mbar)
(hr)
AV
SE1
PC6a
DAC6
0.6
K2CO3
7.5
173
atm
3.5
4.7
SE2
PC6a
DAC6
0.7
K2CO3
7.5
171
atm
9.7
4.9
SE3
PC6a
DAC6
0.6
K2CO3
7.5
174
atm
9
4.9
SE4
PC6a
DAC6
0.6
NaOH
7.0
168
atm
13
4.8
SE52
PC6a
DADMA
0.6
K2CO3
7.5
159
atm
8
n/a
SE62
PC6a
DAC4
0.6
K2CO3
7.5
165
atm
12.5
9.2
SE7
PC6b
DAC6
0.6
K2CO3
7.5
170
100
4.5
4.4
SE8
PC6a
DAC6
0.6
K2CO3
7.5
170
100
3.5
5.9
SE9
PC6a
DAC6
0.6
K2CO3
7.5
170
100
2.0
7.3
SE10
PC6a
DAC6
0.6
K2CO3
7.5
170
100
2.0
6.8
SE11
PC6a
DAC8
0.6
K2CO3
7.5
170
100
2.5
3.9
SE12
PC6a
DAC10
0.6
K2CO3
7.5
170
100
3
4.6
SE13
PC6a
DAC6
0.6
K2CO3
7.5
170
100
3
3.9
SE14
PC6a
DAC5
0.6
K2CO3
7.5
170
100
2
4.6
SE15
PC6a
DAC4
0.6
K2CO3
7.5
170
100
3
6.2
SE16
PC6a
DAC8
0.6
K2CO3
7.5
170
100
2.5
5.1
SE17
PC6b
DAC6
0.6
K2CO3
7.5
170
100
4.5
2.6
SE18
PC3
DAC4
0.6
K2CO3
7.5
170
100
4.0
4.2
SE19
PC3
DAC6
0.6
K2CO3
7.5
170
100
4.5
2.4
SE203
PC3/PC6b
DAC6
0.6
K2CO3
7.5
170
100
5.2
2.9
SE21
PC5
DAC6
0.6
K2CO3
7.5
170
100
4.0
3.9
SE22
PC6b
DAC10
0.6
K2CO3
7.5
170
100
4.0
4.5
TABLE 1b
Ex
Monoacid
Temp
Press
Time
No
type
mol1
(° C.)
(mbar)
(hr)
AV
Notes
SE1
MAC12
0.25
173
atm
3.5
4.5
clear—1 phase
SE2
MAC12
0.25
171
atm
9.3
4.5
clear—1 phase
SE3
MAC12
0.35
174
atm
7.3
4.3
clear—1 phase
SE4
MAC12
0.25
177
atm
19
2.5
clear—1 phase
SE52
MAC12
0.25
174
atm
9.0
3.8
cloudy 2
phase mixture
SE62
MAC12
0.25
183
atm
18.5
9.2
cloudy 2
phase mixture
SE7
MAC12
0.25
170
500
6.5
4.7
clear—1 phase
SE8
MAcofa
0.25
182
atm
20.0
5.9
cloudy 2
phase mixture
SE9
MAi-C18
0.25
200
atm
16.0
7.3
cloudy 2
phase mixture
SE10
MAC16
0.25
180
400
13.0
6.8
cloudy 2
phase mixture
SE11
MAC12
0.25
170
500
4
4.3
clear—1 phase
SE12
MAC12
0.25
170
500
5
3.3
clear—1 phase
SE13
MAC12
0.25
170
500
3
4.6
clear—1 phase
SE14
MAC8
0.25
170
atm
7.5
8
clear—1 phase
SE15
MAC8
0.25
170
atm
9
13.8
clear—1 phase
SE16
MAC12
0.25
170
500
3
4.7
clear—1 phase
SE17
MAC12
0.20
170
500
3
4.8
clear—1 phase
SE18
MAC12
0.25
170
500
4
12.3
cloudy—2
phase
SE19
MAC12
0.25
170
500
4.5
2.3
clear—1 phase
SE20
MAC12
0.25
170
500
5.3
4.1
clear—1 phase
SE21
MAC12
0.25
170
500
4
3.9
clear—1 phase
SE22
MAC18
0.15
170
500
6
4.2
clear—1 phase
1molar ratios/percentages based on sorbitol
2lauric acid added after 8 hours of oligomerisation reaction
3glycerol:sorbitol—0.25:0.75 molar ratio
Test oil in water emulsions were made up using the following general emulsion formulation:
Material
amount (wt %)
surfactant
1
Oil 1
20
salt
0 or 3
water
to 100
These emulsions were tested for stability as described above and the results are as set out in Table 2 below.
TABLE 2
Emulsion Stability
Salt
(mean droplet size in μm)
Surfactant
Conc
Amb
Amb
50° C.
50° C.
Ex No
Type
(wt %)
1D
1W
Amb 1M
1D
1W
50° C. 1M
AE1C.a
Surf1
0
7.8
8.9
9.0
7.8
8.9
8.9
AE1C.b
Surf1
3
7.8
8.9
9.0
7.8
8.9
8.9
AE1.1.a
SE4
0
8.7
10.2
10.0
8.7
9.9
9.4
AE1.1b
SE4
3
8.7
10.2
10.0
8.7
9.9
9.4
AE1.2.a
SE5
0
9.5
9.0
8.7
9.5
10.6
9.3
AE1.2b
SE5
3
9.5
9.3
8.7
9.5
10.6
9.3
AE1.3.a
SE6
0
9.0
8.4
7.8
9.0
10.8
8.9
AE1.3b
SE6
3
9.0
8.4
7.8
9.0
10.8
9.0
AE1.4
SE21
0
9.2
9.3
9.2
9.4
9.3
9.1
AE1.5
SE23
0
6.0
6.0
5.9
6.0
6.0
6.2
AE1.6
SE24
0
6.2
6.8
6.8
6.4
6.6
8.4
AE1.7
SE25
0
9.8
9.9
9.9
9.4
9.5
10.4
AE1.8
SE26
0
9.8
9.6
9.7
9.7
9.8
9.8
AE1.9
SE32
0
9.6
9.8
9.6
9.8
9.8
9.8
Bevinakatti, Hanamanthsa S, Waite, Alan G
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