FR2636455A1 - Process for preparing organic polysulphides - Google Patents

Abstract

The invention relates to the preparation of organic polysulphides by the action of sulphur on a mercaptan or on a polysulphide of lower rank in sulphur, in the presence of a basic catalyst. In the process according to the invention, an anion exchange resin is used as catalyst.

Description

PROCESS FOR PREPARING ORGANICOLY POLYSULFIDES
The present invention relates to the preparation of organic polysulfides RSnR by the action of sulfur on a mercaptan RSH or a poly
XSn, R of lower rank beam (2 4 n '<n), in the presence of a basic catalyst.

 Organic polysulfides, especially aliphatic, cycloaliphatic or aryl, and especially dialkylpolysulfides, are products of industrial interest for various applications, particularly this extreme-pressure additives in cutting oils.

Their preparation by reaction between elemental sulfur and a mercaptan is known. It requires the presence of a basic catalyst which may be an amine, an alkanolasine, an inorganic base, a vercaptide or an alcoholate, or a catalyst constituted by the combination of a mercaptan with an alkene oxide and an alkaline base. . Such methods have been described, for example, in patents
US 2,237,625, 2,237,627, 3,022,351 and 3,392,201 as well as in patents Nos. 1,381,265, GB 1,162,334, DE 2,938,156 and FR 2,607,496.

 The use of magnesium oxide comice catalyst has recently been claimed in US Patent 4,564,709. Being solid and insoluble in the reaction liquid liquids obtained by reaction of elemental sulfur with mercaptans or with organic polysulfides, such a catalyst present the most not to contaminate the polysulfides produced in these reactions. However, the magnesium oxide used in powder form requires a very efficient filtration of the reaction products, which makes it very difficult to operate such a process for the continuous manufacture of organic polysulfides.

 The production of polysulphides can also be carried out by the action of eluent sulfur on organic polysulfides, for example di-, tri- or tetrasulfides to form higher polysulfides.

This possibility is indicated for example in patent FR 1 381 265, in the presence of amines as catalysts.

 It has now been found that anion exchange resins can be used as basic catalysts. These solid resins are generally in the form of grains or easily separable beads. Being insoluble in liquid reaction media, these catalysts can be used permanently in the reactors and have the advantage of not polluting the effluents leaving the reactor.

 The subject of the invention is therefore a process for the preparation of organic polysulfides by the action of sulfur on a mercaptan in a liquid medium or on a lower sulfur organic polysulfide, characterized in that the catalyst used is a catalyst exchange resin. anions.

 The present invention is primarily applicable to the preparation of dialkyl polysulfides containing 2 to 40 carbon atoms such as dimethyl, diethyl, dipropyl, dibutyl, dipentyl, dihexyl, diheptyl, dioctyl, didecyl or didodecyl polysulfides. It is also applicable to the preparation of cycloalkyl polysulfides (for example, dicyclohexyl polysulfide), arylalkyl (for example, dibenzyl polysulfide) or aromatic polysulfides (for example, diphenyl polysulfide) and their substituted derivatives.

The solid catalysts used according to the invention are basic organic polymers or copolymers with basic function, well known in the art as anion exchangers. As such, it is more particularly possible to use crosslinked polystyrene resins, in particular with divinylbenzene, acrylic or phenylacrylic resins, acrylic resins crosslinked with divinylbenzene, or phenol-formaldehyde resins. These resins carry tertiary amine or quaternary ammonium functional groups fixed by various techniques known per se, generally after formation of the polymers or copolymers. Mention may also be made of epoxy-amine resins obtained by direct reaction between ammonia and epichlorohydrin and the resins obtained by aminolysis of acrylates with polyamines. Anion exchange resins are commercially available under different names such as, for example, Amberlite, Amberlyst,
Dowex, Duolite, Lewatit
Anion exchange resins bearing quaternary ammonium functional groups are supplied by the resin manufacturers in the ionic chloride form to guarantee maximum storage and transport stability. As their basicity is completely neutralized in this form, these resins must first be In their use as catalysts, they can be treated with a base such as sodium hydroxide to recover their basic properties in the form of functional groups of quaternary ammonium hydroxides. In practice, the starting resins in chloride form are treated with a suitable solution of sodium hydroxide so as to eliminate all the chloride ions, and then they are washed with water until complete elimination of the sodium hydroxide.

 The effectiveness of anion exchange resins, whether of the amine or quaternary ammonium type (in the OH form) is generally improved when used dry. Their catalytic activity generally manifests itself from a minimum amount of 0.1% by weight relative to the sulfur introduced into the reaction medium. In most cases, the maximum useful amount is of the order of 50% by weight relative to the sulfur used, but a larger quantity may be useful in some cases, in particular for the preparation of secondary dialkyl polysulfides or tertiary. The preferred amount is however generally between 5 and 40% by weight.

 The process according to the invention can be carried out in a stirred reactor, where the catalyst is suspended in the liquid reaction medium. In this case, all the techniques of introduction of sulfur in different forms can be used: solid sulfur, sulfur to the liquid, sulfur solution in a selective solvent, sulfur solution in the polysulfide to be made or even solution of sulfur in an organic polysulfide having a sulfur rank lower than that of the polysulfide i manufacture.

 The process according to the invention can also be carried out using a tubular reactor in which the catalyst is arranged in a fixed bed, in a moving bed or in an expanded bed. In this embodiment, the sulfur is introduced either in the liquid state or in solution under the various forms previously enumerated (selective solvent or polysulfide).

 The reaction itself can take place in a wide range of temperatures depending on the mercaptan transform and the type of basic resin used. It is generally carried out at a temperature between -100 ° C. and the limit temperature of thermal stability of the resin used. Even for the weakest basic resins most stable, it is preferable not to exceed 100 C, especially in the case of prolonged use of the resin.

 The reaction can be conducted at atmospheric pressure. However, in the case of a volatile mercaptan such as methyl mercaptan, it is preferable that the sulfur is in contact with the liquid mercaptan; the application of a sufficient pressure to prevent the mercaptan being trapped with the hydrogen sulphide formed can then be favorable to the reaction. On the other hand, in the case of low volatility, high boiling mercaptans, the introduction of an inert gas (for example nitrogen) through the reaction mixture or maintaining in the reactor an adequate depression of in order to facilitate the elimination of the hydrogen sulphide as soon as it is formed and thus to maximize the reaction.

 The mercaptan / sulfur molar ratio to be used depends on the nature of the organic polysulfide to be prepared and the desired sulfur rank. This ratio can range from 0.3 to 5 and is preferably between 0.4 and 3.

 In the case where starting from an organic polysulfide (for example di-, tri-, tetrasulfide, etc.), the amount of sulfur to be used is determined as a function of this starting polysulfide and of the higher-order polysulfide in sulfur to synthesize. The molar ratio between the two reactants: starting organic polysulfide and sulfur can vary from 0.2 to 1.

 The following examples which illustrate the invention without limiting it, were made in a reactor having a useful reaction volume of the order of 600 ml, provided with a central stirrer and an outer jacket, and equipped to work. either at atmospheric pressure or under pressure.

EXAMPLE 1: DIMETHYLPOLPSULFORE FROM METEYIMERCAPTAN
64 g of solid sulfur and 6 g of dry Amberlyst A21 resin (anionic resin containing tertiary amine functional groups produced by Rohm and Haas) are introduced into the reactor, then the reactor is pressurized with nitrogen to a pressure of 3 bar. absolute. 48 g of liquid methyl mercaptan are then added and the reaction mixture is maintained at 300 ° C., with stirring and at a pressure of 3 bar absolute, by means of a pneumatic expansion valve whose output at atmospheric pressure makes it possible to eliminate the gases produced by At the end of one hour, the resin is separated from the reaction crude which is treated with a stream of nitrogen to remove the non-consumed methyl mercaptan and the dissolved hydrogen sulfide.

This gives 85 g of a liquid whose snalvse shows that it consists of a mixture of polysulfides having the following weight distribution
dimethyl disulphide: 1.5%
dimethyltrisulphide: 27.7%
dimethyltetrasulfide: 30.9%
dimethylpentasulfide: 24.3%
Upper polysulfides: 15.6 X
EXAMPLE 2 DIMEIHYLPOLYSOLFURE WITH PAETIR DIHETHYLDISULFIDE
64 g of solid sulfur, 8 g of resin are introduced into the reactor.
Amberlyst A21 and 94 g of dimethyl disulphide, then the mixture is maintained at atmospheric pressure, with stirring and 600C for 2 hours.

After separation of the resin and elimination of the dissolved gases, 152 g of a liquid are recovered, the analysis of which indicates the following weight composition.
dimethyl disulphide: 2.1%
dimethyltetrasulfide: 47.2%
dimethyltetrasulfide: 31.4%
dimethylpentasulfide: 18.1%
Upper polysulfides: 1.2 Z
EXAMPLE 3: DITR = ERTIOBUTYLPOLYSULFURE FROM TERTIOBURYL MERCAPTAI
A series of three runs were run using 52 g of sulfur, 10 g of dry Amberlyst A21 resin and a variable amount (440 g, 293 g or 73.3 g) of tertlobutinecaptan (TBM). each test was carried out at atmospheric pressure, with stirring and at 60 ° C., over a period of 3 hours.

The results are presented in the following table

<tb> COMPOSITION <SEP> EN <SEP> DITERIIOBUTYLPOLYSULFURES
<tb> Ratio <SEP> molar <SEP> C4H9-Sn-C4H9 <SEP> (% <SEP> weight)
<tb> TBM
<tb> S <SEP> n <SEP> = <SEP> 2 <SEP> n <SEP> = <SEP> 3 <SEP> n <SEP> = <SEP> 4 <SEP> n <SEP> = <SEP > 5 <SEP> n <SEP> = <SEP> 5 <SEP> n <SEP> = <SEP> 5
<tb>! <SEP> 3 <SEP>! <SEP> 4.1 <SEP>! <SEP> 59.3 <SEP>! <SEP> 30.7 <SEP>! <SEP> 5.9 <SEP>! <SEP> - <SEP>!
<tb> 1
<tb> 2/1 <SEP> 1.1 <SEP> 27.8 <SEP> 61.5 <SEP> 9.2 <SEP> 0.4
<tb><SEP> - <SEP> 10.8 <SEP> 72.1 <SEP> 16.1 <SEP> 1
<Tb>
A series of three tests performed under the same conditions, but replacing the Amberlyst A21 resin with Amberlite resin
IRA 93 SP (anionic resin with tertiary amine functional groups) gave virtually equivalent results.

EXAMPLE 4: DITERTIOOCTYLPOLYSULFURE FROM TERTIOOCTYL
MERCAPTAN
Using 32 g of sulfur, 10 g of dry Amberlyst A21 resin and a variable amount (439 g, 292.6 g or 73.2 g) of tert-octyl mercaptan (TOM), three tests each carried out at atmospheric pressure were carried out. stirring at 80 ° C. for 3 hours.

The following table presents the results obtained

<tb> COMPOSITION <SEP> EN <SEP> DITERTIOOCTYLPOLYSULFURES
<tb> C8H17-Sn-C8H17 <SEP> (% <SEP> molars <SEP> determined <SEP> by <SEP> NMR)
<tb> Report <SEP> molar
<tb> TOM <SEP> n <SEP> = <SEP> 3 <SEP> n <SEP> = <SEP> 4 <SEP> n <SEP> = <SEP> 5 <SEP> n <SEP> = <SEP > 6 <SEP> n <SEP>><SEP> 6
<tb> S
<tb> 3/1 <SEP> 44 <SEP> 56 <SEP> - <SEP> - <SEP>
<tb>! <SEP> ~~~~~~~~~~~~~ t <SEP> ~~~~~~ t <SEP> ~~~~~~ t <SEP> ~~~~~~ t <SEP> ~~~~~~ t <SEP><SEP> t
<tb> t <SEP> 2 <SEP>! <SEP> 34 <SEP>! <SEP> 66 <SEP>! <SEP> - <SEP>! <SEP> - <SEP> t <SEP> - <SEP>!
<tb> 1
<tb><SEP> | <SEP> 7 <SEP>! <SEP> 48 <SEP>! <SEP> 20 <SEP>! <SEP> 11 <SEP>! <SEP> 14! <September>
<Tb>
EXAMPLE 5: DITERTIONONYLPOLYSULFURE FROM TERTIONONYL-
MERCAPTAN
32 g of solid sulfur, 5% of resin are introduced into the reactor.
Amberlyst A21 dry and 80 g of tertiononylmercaptan obtained from a propylene trimer. The mixture is then stirred at atmospheric pressure and at 800 ° C. for 3 hours.

 After separation of the resin and degassing of the liquid with a stream of nitrogen, a ditertiononylpolysulphide is obtained whose sulfur content is 37.9%, which corresponds to a yield of 98.2% relative to theory.

EXAMPLE 6: DIETERTIODODECYLPOLYSULFURE FROM TERTIODODECTL-
MERCAPRN
The procedure is as in Example 5, but replacing the tertiononyl mercaptan by 101 g of tert-dodecyl mercaptan obtained from a propylene tetramer.

 The sulfur content of the di-tert-dodecyl-polysulfide thus obtained is 31.3%, which corresponds to a yield of 97.4% relative to theory.

Claims (7)

 1. Process for preparing organic polysulfides RS R by the action of sulfur on a RSE mercaptan or on a lower sulfur RSn, R polysulfide (2 4 n1 <n) in a liquid medium and in the presence of a basic catalyst, characterized in that an anion exchange resin is used as the catalyst.  2. Method according to claim 1, wherein the amount of resin used is between 0.1 and 50% by weight relative to the sulfur introduced, preferably between 5 and 40%.  3. Process according to claim 1 or 2, in which a temperature of between -10 ° C. and the temperature of thermal stability of the resin used is used, preferably below 100 ° C.  4. Method according to one of claims 1 to 3, wherein the molar ratio mercaptan / sulfur is between 0.3 and 5, preferably between 0.4 and 3.  5. Process according to one of claims 1 to 4, wherein the mercaptan is an alkyl-, cycloalkyl-, aryl- or aralkyl-mercaptan.  6. Method according to one of claims 1 to 3, wherein one starts from a polysulfide RSn, R, the molar ratio of this polysulfide to the sulfur introduced is between 0.2 and 1.  7. The process according to one of claims 1 to 6, wherein the anion exchange resin is a tertiary amine or quaternary ammonium functional group resin.