2,938,020 Patented May‘ 24, 1960

2 and ole?n, either with or without an inert liquid diluent. By so doing, a fresh surface of. the metal catalyst is continually contacted with the haloalkane and with the 2,938,020 ole?n being polymerized. A polymerization so started PROCESS FOR PULYMERKZATIUN O1? OLEFINS may be transferred to another vessel providedv with ade quate agitation such as with a high shear agitator. When. Albert S. Matiack, Wilmington, Del., assignor to Hercules operating in a ball mill, the metal may be in any desired - Powder Company, Wilmington, Del., a corporation of shape, as for example, strip, foil, ?ake, etc., which will, Delaware of course, be reduced to the desired size during the ball ' No Drawing. Filed May 27, 1957, Ser. No. 661,573 10 milling operation, but for maximum e?iciency it is pref ' erably used in the form of ?nely divided powder or 19 Claims. (or. 260-943) ?ake. Another method of operating the process is to atomize the metal into an inert gas and after cooling to about 200° C. or less add the mixture to the ole?n stream This invention relates to the polymerization of ole?ns 15 or mixture’ of ole?n and diluent. The process of this under relatively mild conditions of pressure and tem invention may be ‘operated either on a batchwise scale perature and, more particularly, to an entirely new type or as a continuous operation. ‘ of catalyst system for the polymerization of ole?ns under Any haloalkane may be used in combination with the such conditions. - Group IV, V, VI or‘ VII transition metal to catalyze the K. Ziegler has described the polymerization of 20 polymerization. Particularly e?ective are those halo with organometallic compounds of the metals of Group wherein only one is attached to a III-A of the Periodic Table, i.e., organometallic com atom, i.e., those having the general formula pounds of aluminum, and indium to produce polymers varying in molecular weight from dimers up R to the wax range polymers. He has also described the 25 preparation of high molecular weight crystalline polymers R by contacting ethylene with a mixture of one of these organometallic compounds of aluminum, gallium or in where X is halogen, i.e., ?uorine, , or dium, etc., with a compound of a metal of Group IV-B, , and the R’s are hydrogen, or haloalkyl and V-B, VI-B or VIII of the Periodic Table. may be alike‘or different. Exemplary of such halo It has now been discovered that an entirely different alkanes are methyl chloride, methyl , ethyl chlo type of catalyst may be used to polymerize ethylene ride, ethyl bromide, ethyl iodide, ethylene chloride, ethyl and other ethylenically unsaturated hydrocarbons under ene bromide, propyl bromide, n-butyl bromide etc. In vrelatively mild conditions of temperature and pressure. some cases it may be desirable, athough not essential, to In accordance with this invention, ethylene or other 35 add a trace of iodine. Any amount of the haloalkane ethylenically unsaturated hydrocarbons may be polymer may be used in combination with the transition metal ized by contacting the ole?n with one of the metals of from a minor catalytic amount up to use as the total Groups lV?B, V-B, VI-B or VII-B including thorium diluent, but in general will be an amount of from about and uranium in combination with a haloalkane, the metal 0.05% to about 100% based on the ole?n. The above being in a ?nely divided state and having a freshly ex preferred class of haloalkanes having only one halogen posed surface in contact with the ethylene and halo attached to a carbon may be used along with less active . Just What takes place between the metal and the haloalkanes such as , , haloalkane that produces a catalyst for the polymerization etc., that may be used as diluents for the polymerization is not known. The fact remains that metals that do not process. catalyze the polymerization of ethylene, e.g., titanium, ' The polymerization process may be carried out in a chromium, manganese, etc., are activated by the addition wide variety of ways. It may be carried out in the pres of a small amount of a haloalkane and the combination ence or absence ofv an inert organic diluent as reaction is an active catalyst for the polymerization of ethylene medium. Generally, a diluent is used because it simpli?es and other ethylenically unsaturated hydrocarbons. the isolation of the polymer at the end of the polymer Any l-ole?n such as ethylene, propylene, -l, 50 i’zation reaction. Any inert liquid organic diluent may -l, -l, -l, styrene, butadiene, iso be used, as for example, aliphatic hydrocarbons such as prene, etc., or mixtures thereof may be polymerized in hexane, heptane, etc., cycloaliphatic hydrocarbons such accordance with this invention. as cyclohexane or aromatic hydrocarbons such as ben a Any of the transition metals of Groups IV, V, VI and zene, , xylene, etc., or any mixture of such hydro VII are active catalysts for the polymerization of ethyl 55 , halogenated hydrocarbons such as chloroform, ene and other l-ole?ns when combined with a haloalkane. carbon tetrachloride, chlorobenzene, etc., or as mentioned’ Particularly effective metals of the sub-Groups IV-B, V-B, above, the haloalkane cocatalyst or a mixture of such VI-B and VII-B are titanium, zirconium, hafnium, thori with any other halogenated hydrocarbon diluent. um, vanadium, niobium, tantalum, chromium'and manga The temperature and pressure used for the polymeli nese. As already mentioned, the metal is most effective 60 zation process may be varied over a wide range and will when used in a ?nely divided state with an active surface. largely depend upon the method by which the ole?n is ’ Such ?nely divided metals may be obtained by ball contacted with the metal and haloalkane. In general, milling in an inert atmosphere, atomizing the molten metal . the polymerization will be carried out at room tempera into an inert atmosphere, etc. In general, the ?nely t ture or slightly above, but any temperature within the divided metal will have an average particle size varying 65 range of from about --80° C. to about 200° C. may be from about 1 micron or less to about 100 microns and used, preferably from about 0° C. to about 100° C., and ‘ preferably from about 1 micron to about 20 microns. more preferably from about 20° C. to about 60° C. In Obviously, many means may be devised whereby the the same way, while atmospheric pressure or a pressure ; ole?n may be contacted with the ?nely divided metal hav . of only a few pounds may be used, the polymerization 5. ing an active surface. A particularly effective method of 70 may be carried out over a Wide range of pressures, but. carrying out the process in accordance with this invention higher pressures do not appreciably alter the course of is to ball mill the metal in the presence of the haloalkane polymerization" and, hence, are not required.“ "'ln'gerF" eral, it is‘ desirable to operate under anhydrous and ’ EXAMPLE 6 ’ anaerobic conditions. The following examples will demonstrate the process Example 1 was repeated except that 70 parts of n of polymerizing l-ole?ns in accordance with this inven heptane used as the diluent in that example was replaced tion. The molecular weight of the polymers produced with 160 parts of carbon tetrachloride. The polyeth in these examples is indicated by the Reduced Speci?c ylene so obtained had an RSV of 2.3 and a melting point Viscosity (RSV) given for each. By the term “Reduced of 132° C. Speci?c Viscosity” is meant the nap/c determined on an EXAMPLES 7-9 0.1% solution of the polymer in decalin, containing 0.1 The procedure described in Examples 1-5 was fol g. of the polymer per 100 ml. of solution (unless other- 10 lowed in these examples except that propylene was used wise indicated), at 135° C. Where the melting point of in place of the ethylene charged in those examples. At the polymer is given, it is the temperature at which the the end of 16 hours the polymer slurry was removed birefringence due to crystallinity disappears. All parts from the mill. The heptane-insoluble polymer was iso and percentages are by weight unless otherwise indi ' lated by centrifugation and puri?ed by the same method cated. 15 as described in the foregoing examples for polyethylene. EXAMPLES 1-5 The heptane-soluble polymer was isolated from the re In these examples the polymerization was carried out action mixture ?ltrate by distilling off the diluent. The in cylindrical vibratory ball mills which were constructed catalyst metal, alkyl halide cocatalyst and the amount of stainless steel (analysis: carbon—0.008% max.; of each used, the percent of heptane-soluble and hep 20 Cr — 18.00-20.00%; Ni - 8.004000%; Mn -- 2.00% tane-insoluble polymer obtained in each case and the max.) and out?tted with a gas inlet tube and a main physical properties of the polymers are tabulated below opening. The mills were 80% full of 0.5 inch stainless along with control runs wherein metal catalyst but no steel balls. alkyl halide was added. Table II

Heptane-Soluble Heptane-Insoluble Polymer Polymer Example Metal Parts Alkyl Parts ' Number Halide , Percent RSV Percent RSV Melttn Total Total Point° .

. 2. 0 ...... _ - (1) (1) (1) (1) (1) '_ 2.0 CzHsBr. _ _ 4. 3 78 0. 7 2-2 4.2 162 _ ' 2.0 ...... -. 0) 0) (1) t‘) (1) 8 _ V 2.0 (l?sBln 4.3 77 2.2 23 ______Control.--" Th 2.0 ______. O) (1) (1) (I) (l) 9 ______Th 2.0 (hHrBz‘.-. 4.3 100 0.03 0 ______

1 No polymer formed. In each case the mill, previously dried 1for 4 hours at EXAMPLE l0 ‘ 120° C., was charged with 70 parts of n-heptane, which had been dried over pentoxide, 2.0 parts of The procedure of Example 8 was repeated except that the metal in the form of powder, except in Example 3 18 parts of styrene was polymerized instead of the pro where 3.0 parts of vanadium granules was used, and 4.3_ pylene used in that example and 86 parts of toluene was parts of ethyl bromide containing a trace of iodine ex 45 used as the diluent. t the end of 16 hours the toluene~ cept in the case of Example 2 where ‘1.3 parts of ethylene soluble and toluene-insoluble polymer fractions were sep chloride was used. . The mill in each case was then arated as described. above. The toluene-insoluble poly capped, twice ?lled with'dry nitrogen and evacuated and mer had an RSV of 0.08 as measured on a 0.1% solu then ethylene was injected to a pressure of 50l'p.s.i.g.' tion in ot-chloronaphthalene at 135 ° C. After 16 hours of milling at room temperature, the poly-, so EXAMPLE 1 1 mer slurry'was removed from the mill and the poly ethylene was isolated by ?ltration. The polymer so ob The procedure of Example 7 was repeated except that tained was puri?ed ‘by ‘leaching with a 50:50 mixture of 16.3 parts of butadiene was substituted for the propylene. nl- and 48% hydro?uoric acid for 16 hours at The polymer fractions were separated as before. The room temperature, again separating the polymer by ?l heptane-soluble fraction amounted to 14% and the hep tration and washing it free of acid with water and eth tane~insoluble fraction to 86% of the total polybutadiene. anol and then drying for 16 hours at 80° C. in vacuo The Periodic Chart used in this speci?cation and ap The catalyst metal and alkyl halide coca-talyst and the pended claims for designating the groups and subgroups amount of each used, the ?nal pressure, percent con of the Periodic Table is that given in the “Handbook of version of ethylene to polymer and the physical proper so Chemistry and Physics” published by Chemical Rubber ties of the polymer obtained in each case are tabulated Publishing Comp-any, Cleveland, Ohio, on pages 392-3 in Table I below ‘along with control runs wherein in one of the 36th edition. Thus, the metals designated as case the alkyl halide was omitted, and in the other, the Groups lV-B, V-B, VI-B and VII—B are those that occur metal was omitted. in the left-hand side of Groups IV, V, VI and VII in the Table I

. ' Alkyl Final Percent Melting Example Number Metal Parts Halide Parts Pressure, Converg RSV Point, - ' p.s.i.g. sion ° C.

50 0 ______4. 3 so 0 ______-_ 4.3 —0 94 5.2 130 1. 3 —-12 49 3.4. 131 C2HsBr_._-- 4. 3 —5 80 1. 0 117 CzHsBr._--- 4. 3 ~15 . 78 3.1 132 (hHsBl‘. .__. 4. 3 7 45 2. 3 134 2,938,020 S 0 Mendeleev form of the Periodic Table (see Deming, prises contacting ethylene with a mixture of from about "General Chemistry,” sixth edition, 1952, John Wiley & 0.05 % to about 100%, based on the weight of ole?n, of Sons, Inc., New York). an alkyl halide and ?nely divided vanadium having a What I claim and desire to protect by Letters Patent is: ‘freshly exposed surface and a particle size of from about 1. The process of polymerizing a l-ole?n which com 1 micron to about 100 microns. prises contacting said ole?n with a mixture of from 16. The process of polymerizing ethylene which com about 0.05% to about 100%, based on the weight of prises contacting ethylene with a mixture of from about ole?n, of a haloalkane and a ?nely divided metal having 0.05 % to about 100%, based on the weight of ole?n, of a freshly exposed surface and a particle size of from an alkyl halide and ?nely divided chromium having a about 1 micron to about 100 microns, said metal being 10 freshly exposed surface and a particle size of from about selected from the group consisting of the metals of Groups 1 micron to about 100 microns. IV-B, V-B, VI-B and VII-B of the Mendeleev Periodic 17. The process of polymerizing ethylene which com Table, and said haloalkane having the formula R1R2R3CX prises ball milling a mixture of ethylene, ethyl bromide where X is halogen and R1, R2 and R3 are selected from and ?nely divided titanium having a particle size of from the group consisting of hydrogen, alkyl, and haloalkyl. about 1 micron to about 100 microns, said ethyl bromide 2. The process of claim 1 wherein the metal is a Group being present in an amount of from about 0.05% to about IV-B metal. 100% based on the weight of ethylene. 3. The process of claim 1 wherein the metal is a Group 18. The process of polymerizing ethylene which com V-B metal. prises ball milling a mixture of ethylene, ethyl bromide 4. The process of claim 1 wherein the metal is a Group 20 and ?nely divided vanadium having a particle size of ‘VI-B metal. from about 1 micron to about 100 microns, said ethyl 5. The process of claim 1 wherein the metal is a Group bromide being present in an amount of from about 0.05 % VIiI-B metal. to about 100% based on the weight of ethylene. 6. The process of claim 2 wherein the haloalkane is 19. The process of polymerizing ethylene which com an alkyl halide. prises ball milling a mixture of ethylene, ethyl bromide 7. The process of claim 2 wherein the haloalkane is and ?nely divided chromium having a particle size of an alkylene halide having at least two carbon atoms. from about 1 micron to about 100 microns, said ethyl 8. The process of claim 3 wherein the haloalkane is an bromide being present in an amount of from about 0.05% alkyl halide. to about 100% based on the weight of ethylene. 9. The process of claim 4 wherein the haloalkane is an alkyl halide. References Cited in the ?le of this patent 10. The process of claim 5 wherein the haloalkane is UNITED STATES PATENTS an alkyl halide. 11. The process of claim 6 wherein the ole?n is 2,721,189 Anderson et al. ______Oct. 18, 1955 ethylene. V35 2,727,023 Evering ______Dec. 13, 1955 12. The process of claim 8 wherein the ole?n is ethylene. _ I FOREIGN PATENTS 13. The process of claim 9 wherein the ole?n is 533,362 Belgium ______May 16, 1955 ethylene. 534,792 Belgium ______Ian. 31, 1955 14. The process of polymerizing ethylene which com~ 40 prises contacting ethylene with a mixture of from about OTHER REFERENCES 0.05% to about 100%, based on the weight of ole?n, of Gilman et al: Journal of Organic Chemistry, vol. 10, an alkyl halide and ?nely divided titanium having a freshly pages 505-515 (pages 512-515 relied on), 1949. exposed surface and a particle size of from about 1 US. Industrial Chemicals Co., High Surface on micron to about 100 microns. 45 Inert Solids, 19 pages, copyright 1953; address is 120 15. The process of polymerizing ethylene which com Broadway, New York 5, N.Y. '