Source: {"pile_set_name": "USPTO Backgrounds"}

The present invention relates to an improved process for preparing telomers of chlorotrifluoroethylene, hereinafter designated as "CTFE". CTFE telomers are saturated low molecular weight polymers, typically of general formula CCl.sub.3 (CF.sub.2 CClF).sub.n Cl, where n, the molecular number (the number of repeating units in the telomer chain) is in the range of 1 to 20. Fluorination of the telomer results in replacement of one or more chlorine atoms in the terminal group(s) with fluorine and gives products which are inherently nonflammable, thermally stable, and are particularly suitable for use as hydraulic fluids and high temperature lubricants. Such fluorination can be achieved using a variety of fluorinating agents. For example, British Pat. Nos. 712,184 and 761,053 disclose the fluorination of CTFE oils using both chlorine trifluoride and cobalt trifluoride. The use of hydrofluoric acid as a fluorinating agent for CTFE oils is also disclosed in U.S. Pat. No. 2,636,908, while U.S. Pat. No. 2,886,607 illustrates the use of antimony trifluoride and antimony pentachloride as fluorinating agents.
Various methods of preparing CTFE telomers are known in the prior art and have been practiced commercially for many years. An article by William T. Miller, Jr. et al in Industrial and Engineering Chemistry, pages 333-337 (1947), entitled "Low Polymers of Chlorotrifluoroethylene", describes a process for producing low molecular weight polymers of CTFE by carrying out the polymerization in a solution of chloroform using benzoyl peroxide as a polymerization promoter. Other solvents disclosed in the reference as being useful for this purpose include carbon tetrachloride and tetrachloroethylene. The solution is heated in a pressure vessel for 13/4 hours at 100.degree. C. and the unreacted CTFE monomer and chloroform are removed by distillation, leaving a "crude" telomer of the general formula CHCl.sub.2 (CF.sub.2 CClF).sub.n Cl, which can be further heated and distilled to yield products ranging from a light oil to a semi-solid wax or grease.
U.S. Pat. No. 2,793,201, issued May 21, 1957, discloses improved promoters for polymerizing CTFE monomers to produce low molecular weight polymers. Specific promoters disclosed in the reference include various peroxides such as bis-(trichloroacetyl) peroxide and bis-(perchloroacrylyl) peroxide. The use of such promoters produces a more stable polymer by eliminating the amount of reactive hydrogen present in the polymer.
Another process which has been developed for producing low molecular weight CTFE polymers is described in U.S. Pat. No. 2,788,375, issued Apr. 9, 1957. This process comprises reacting CTFE with a saturated organic bromo compound, such as bromotrichloromethane, in the presence of actinic light in a de-oxygenated system to obtain saturated bromopolychlorofluoro compounds containing one or more CTFE units per molecule. These saturated bromopolychlorofluoro compounds can then be converted to corresponding polychlorofluoro compounds by treatment with chlorine, and subsequently fluorinated using, for example, cobalt trifluoride or chlorine trifluoride, in combination with antimony catalysts, to yield more highly fluorinated products.
A more recent development in this field is described in a series of articles by Y. Pietrasanta et al entitled "Telomerization by Redox Catalysis" appearing in the European Polymer Journal, Vol. 12 (1976). This technology involves the reaction of a chlorinated telogen, such as carbon tetrachloride, with CTFE in the presence of benzoin and a suitable redox catalyst, such as ferric chloride hexahydrate (FeCl.sub.3.sup.. 6H.sub.2 O). The telomerization reaction is suitably carried out in acetonitrile which is a common solvent for the reactants and catalysts. The telomerization reaction can be illustrated as follows: ##STR1##
The redox method has the advantage of directly preparing a high yield of low molecular weight product without the necessity of cracking or fractionating a higher molecular weight polymer.
It is known that benzoin acts as a reducing agent for Fe.sup.+3 ions in solution and that, in the absence of benzoin, product yield falls to less than 5%. See European Polymer Journal, supra. However, there are certain disadvantages associated with the use of benzoin in the redox telomerization process which could effectively render uneconomical any commercial scale process based on this technology. For example, benzoin must be removed from the crude telomer prior to fluorination or the fluorinated product will contain unsaturation as determined by the KMnO.sub.4 test and, as a result, will not meet product specifications. Removal of the benzoin from the crude telomer requires the use of an absorption column, such as a column of activated alumina, which not only removes benzoin but retains a significant amount of telomer which must be reclaimed using, for example, solvent extraction. The use of an activated alumina column is a costly and time-consuming procedure.
It has also been proposed to substitute nickel or some equivalent metal reductant for benzoin in reaction (1). See, in this regard, commonly assigned copending application Ser. No. 374,561, filed May 3, 1982. This has the advantage of simplifying the reaction by eliminating the necessity for removing benzoin from the reaction mixture, which is a time-consuming and costly operation. In addition, when telomers prepared using such a substituted system are directly fluorinated, the resulting product will not contain unsatisfactory levels of unsaturation. However, the substitution of nickel for benzoin produces a telomer distribution having an increased proportion of higher molecular weight telomers. This is unfortunate since the higher weight telomers are less useful commercially than the lighter telomers. Consequently, it is desirable to reduce the higher weight fraction to more acceptable levels.
It is therefore a principal object of the present invention to provide an improved process for preparing CTFE telomers with enhanced levels of lower molecular weight material. It is a further object of this invention to provide a process for preparing CTFE telomers which can be directly fluorinated after removal of solvent and unreacted materials without containing unacceptable levels of unsaturation.