EP0000007A1 - Process for the polymerisation of alpha-olefins and method for preparing solid catalytic complexes for use in this polymerisation process - Google Patents

Abstract

The invention relates to a process for the polymerization of alphaolefins and to solid catalytic complexes which can be used for this polymerization and to a process for their preparation. The solid catalytic complexes are prepared by reacting between: (1) at least one compound chosen from organic oxygenated compounds and halogenated magnesium compounds; (2) at least one compound chosen from organic oxygenated compounds and halogenated titanium compounds; (3) at least one aluminum halide. The aluminum halide is chosen from organoaluminum chlorides of general formula A1RnC13-n in which R is an alkyl radical comprising at least 4 carbon atoms and n is a number such that 1 <= n <= 2. The process for polymerization makes it possible to obtain, with very high catalytic activities, polyolefins whose percentage of fine particles is reduced and whose mean particle size is higher.

Description

• (1) au moins un composé (M) choisi parmi les composés oxygénés organiques et les composés halogénés du magnésium ;
• (2) au moins un composé (T) choisi parmi les composés oxygénés organiques et les composés halogénés du titane ;
• (3) au moins un halogénure d'aluminium (A) caractérisé en ce que ce dernier est choisi parmi les chlorures organoaluminiques de formule générale AlR_nCl_3-n dans laquelle R est un radical alkyle comprenant au moins 4 atomes de carbone et n est un nombre tel que 1 ≤ n % 2.

1 - Process for the polymerization of alpha-olefins carried out in the presence of an organometallic compound of a metal from groups Ia, IIa, IIb, IIIb and IVb of the Periodic Table and a solid catalytic complex prepared by reacting with each other:

• (1) at least one compound (M) chosen from organic oxygenated compounds and halogenated magnesium compounds;
• (2) at least one compound (T) chosen from organic oxygenated compounds and halogenated titanium compounds;
• (3) at least one aluminum halide (A) characterized in that the latter is chosen from organoaluminum chlorides of general formula AlR _n Cl _3-n in which R is an alkyl radical comprising at least 4 carbon atoms and n is a number such that 1 ≤ n% 2.

2 - Process according to claim 1, characterized in that R is an alkyl radical comprising from 4 to 8 carbon atoms and n is 1.

3 - Process according to claim 2, characterized in that the organoaluminum chloride is isobutylaluminum dichloride.

4 - Method according to any one of claims 1 to 3, characterized in that the compound (M) is chosen from magnesium dialkoxides and the compound (T) is chosen from titanium compounds having only bonding sequences metal-oxygen-organic radical.

5 - Process according to any one of claims 1 to 4, characterized in that the solid catalytic complex is prepared by reacting together, in addition to the compound (M), the compound (T) and the aluminum halide ( A), a compound (Z) chosen from organic oxygenated compounds and halogenated zirconium compounds.

6 - Process according to any one of claims 1 to 5, characterized in that ': solid catalytic complex is prepared by using the aluminum halide (A) at the end of the preparation.

7 - Method according to any one of claims 1 to 6, characterized in that the temperature In reaction medium tending that the organoaluminum chloride is used is between 30 and 65 ° C.

8 - Process according to any one of claims 1 to 7, characterized in that the quantities of compounds (T), (M) and (A) used to prepare the catalytic complex are such that the ratio between the amount of titanium and the amount of magnesium is between 0.025 and 5 at.-g / at.-g and the ratio between the amount of compound (A) and the quartivate of compound (M) is between 1 and 20 mole / mole.

9 Method according to any one of claims 1 to 8, characterized in that the polymerization process is a suspension polymerization process in a liquid hydrocarbon diluent under the polymerization conditions.

• (1) au moins un composé (M) choisi parmi les composés oxygénés organiques et les composés halogénés du magnésium ;
• (2) au moins un composé (T) choisi parmi les composés oxygénés organiques et les composés halogénés du titane ;
• (3) au moins un halogénure d'aluminium (A)

caractérisé en ce que ce dernier est choisi parmi les chlorures organoaluminiques de formule générale AlR_nCl_3-n dans laquelle R est un radical alkyle comprenant au moins 4 atomes de carbone et n est un nombre tel que 1 ≤ n ≤ 2.10 - Process for the preparation of solid catalytic complexes in which one reacts with each other:

• (1) at least one compound (M) chosen from organic oxygenated compounds and halogenated magnesium compounds;
• (2) at least one compound (T) chosen from organic oxygenated compounds and halogenated titanium compounds;
• (3) at least one aluminum halide (A)

characterized in that the latter is chosen from organoaluminum chlorides of general formula AlR _n Cl _3-n in which R is an alkyl radical comprising at least 4 carbon atoms and n is a number such that 1 ≤ n ≤ 2.

• (1) au moins un composé (M) choisi parmi les composés oxygénés organiques et les composés halogénés du magnésium avec
• (2) au moins un composé (T) choisi parmi les composés oxygénés organiques et les composés halogénés du titane et avec
• (3) au moins un halogénure d'aluminium (A) caractérisé en ce que ce dernier est choisi parmi les chlorures organoaluminiques de formule générale AlR_nCl_3-n dans laquelle R est un radical alkyle comprenant au moins 4 atomes de carbone et n est un nombre tel que ≤ n ≤ 2.

d'obtenir sans affecter les avantages inhérents à ces systèmes, des polyoléfines sous forme de particules denses et dures, de diamètre moyen élevé, de distribution granulométrique serrée et de poids spécifique apparent élevé. Ces propriétés les rendent particulièrement aptes à être mises en oeuvre sous forme de poudres lors de leur transformation en objets finis.11 - Solid catalytic complexes for the polymerization of alpha-olefins prepared by reacting with each other:

• (1) at least one compound (M) chosen from organic oxygenated compounds and halogenated magnesium compounds with
• (2) at least one compound (T) chosen from organic oxygenated compounds and halogenated titanium compounds and with
• (3) at least one aluminum halide (A) characterized in that the latter is chosen from organoaluminum chlorides of general formula AlR _n Cl _3-n in which R is an alkyl radical comprising at least 4 carbon atoms and n is a number such that ≤ n ≤ 2.

to obtain without affecting the advantages inherent in these systems, polyolefins in the form of dense and hard particles, of high average diameter, of tight particle size distribution and of high apparent specific weight. These properties make them particularly suitable for being used in the form of powders when they are transformed into finished objects.

• (1) au moins un composé (M) choisi parmi les composés oxygénés organiques et les composés halogénés du magnésium
• (2) au moins un composé (T) choisi parmi les composés oxygénés organiques et les composés halogénés du titane
• (3) au moins un halogénure d'aluminium (A), ce dernier étant choisi parmi les chlorures organoaluminiques de formule générale AIR Cl_3-n dans laquelle R est un radical alkyle comprenant au moins 4 atomes de carbone et n est un nombre tel que 1 < n < 2.

The present invention therefore relates to a process for the polymerization of alpha-olefins in which one operates in the presence of a catalytic system comprising an organometallic compound of a metal from groups Ia, IIa, IIb, IIIb and IVb of the Periodic Table and a complex solid catalytic prepared by reacting with each other:

• (1) at least one compound (M) chosen from organic oxygenated compounds and halogenated magnesium compounds
• (2) at least one compound (T) chosen from organic oxygenated compounds and halogenated titanium compounds
• (3) at least one aluminum halide (A), the latter being chosen from organoaluminum chlorides of general formula AIR Cl _3-n in which R is an alkyl radical comprising at least 4 carbon atoms and n is such a number that 1 <n <2.

The term “organic oxygenated compounds of magnesium and titanium” is intended to denote all the compounds in which any organic radical is linked to the metal via oxygen, that is to say all the compounds comprising at least one sequence of organic radical metal-oxygen bonds per de-metal atom. The organic radicals linked to the metal via oxygen are arbitrary. They are preferably chosen from radicals comprising from 1 to 20 carbon atoms and, more particularly, from those comprising from 1 to 10 carbon atoms. The best results are obtained when these radicals contain from 2 to 6 carbon atoms. These radicals can be saturated or unsaturated, branched chain, straight chain or cyclic; they can also be substituted or contain heteroatoms, such as silicon, sulfur, nitrogen or phosphorus, in their chain. They are preferably chosen from hydrocarbon radicals and in particular from alkyl radicals (linear or crossed), alkenyl, aryl, cycloalkyl, arylalkyl, alkylaryl, acyl and their substituted derivatives.

The term “halogenated compounds of magnesium and titanium” is intended to denote all of the compounds comprising a metal-gene link. The metal bound halogen can be fluorine, chlorine, bromine or iodine. Of preferably, the halogen is chlorine.

Among all the organic and halogenated oxygenated compounds which are suitable, use is preferably made of those which contain only metal-oxygen-organic radical bonds and / or metal-halogen bonds to the exclusion of any other bond.

The solid catalytic complexes used in the present invention are prepared from reactants (1) which are magnesium compounds (M).

The organic oxygenated compounds (M) can comprise, in addition to the organic radicals linked to magnesium via oxygen, other radicals. These other radicals are preferably oxygen and the inorganic radicals linked to the metal via oxygen, such as the radicals -OH, - (SO ₄ ) _1/2 , NO ₃ , (PO ₄ ) _{1 / 3} , (CO ₃ ) _1/2 and -ClO ₄ . They can also be organic radicals linked directly to magnesium by carbon.

• - les alkoxydes, tels que le méthylate, l'éthylate, l'isopropylate, le le décanolate et le cyclohexanolate,
• - les alkylalkoxydes, tels que l'éthyléthylate,
• - les hydroxyalkoxydes, tels que l'hydroxyméthylate,
• - les phénoxydes, tels que le phénate, le naphténate, l'anthracénate, le phénantrénate et le crésolate,
• - les carboxylates éventuellement hydratés, tels que l'acétate, le stéarate, le benzoate, le phénylacétate, l'adipate, le sébacate, le phtalate, l'acrylate et l'oléate,
• - les composés oxygénés azotés organiques, c'est-à-dire des composés comprenant des séquences de liaisons magnésium-oxygène-azote-radical organique, tels que les oximates, en particulier, le butyloximate, le diméthylglyoximate et le cyclohexyloximate, les sels d'acides hydroxylamines en particulier le dérivé de la N-nitroso-N-phényl-hydroxylamine,
• - les chélates, c'est-à-dire les composés oxygénés organiques dans lesquels le magnésium possède au moins une séquence de liaisons normales du type magnésium oxygène-radical organique et au moins une liaison de coordination de manière à former un hétérocycle dans lequel le magnésium est inclus, tels que les énolates et en particulier l'acétylacétonate, ainsi que les complexes obtenus à partir de dérivés phénoliques possédant
• un groupe électrodonneur par exemple en position ortho ou méta par rapport au groupe hydroxyle et en particulier le 8-hydroxyquinoléinate,
• - les silanolates, c'est-à-dire des composés comprenant des séquences de liaisons magnésium-oxygène-silicium-radical hydrocarbone, tels que le triphénylsilanolate.

Among the compounds (M) belonging to the family of organic oxygenated magnesium compounds, there may be mentioned:

• - alkoxides, such as methylate, ethylate, isopropylate, decanolate and cyclohexanolate,
• - alkylalkoxides, such as ethylethylate,
• - hydroxyalkoxides, such as hydroxymethylate,
• - phenoxides, such as phenate, naphthenate, anthracenate, phenanthrenate and cresolate,
• - optionally hydrated carboxylates, such as acetate, stearate, benzoate, phenylacetate, adipate, sebacate, phthalate, acrylate and oleate,
• - organic nitrogen-containing oxygen compounds, that is to say compounds comprising sequences of magnesium-oxygen-nitrogen-organic radical linkages, such as oximates, in particular, butyloximate, dimethylglyoximate and cyclohexyloximate, salts of hydroxylamine acids, in particular the derivative of N-nitroso-N-phenyl-hydroxylamine,
• - chelates, that is to say organic oxygen compounds in which magnesium has at least one normal bond sequence of the magnesium oxygen-organic radical type and at least one coordination bond so as to form a heterocycle in which the magnesium is included, such as enolates and in particular acetylacetonate, as well as complexes obtained from phenolic derivatives having
• an electron donor group, for example in the ortho or meta position with respect to the hydroxyl group and in particular 8-hydroxyquinoline,
• - Silanolates, that is to say compounds comprising sequences of magnesium-oxygen-silicon-hydrocarbon radical linkages, such as triphenylsilanolate.

• - les composes comprenant plusieurs radicaux organiques différents, tels que le méthoxyéthylate de magnésium,
• - les alkoxydes et phénoxydes complexes du magnésium et d'un autre métal, tels que Mg[Al(OR)₄]₂ et Mg[Al(OR)₆]₂, et
• - les mélanges de deux ou de plusieurs des composés oxygénés organiques du magnésium définis ci-dessus.

It is understood that the following organic oxygenated magnesium compounds also fall within the scope of the invention 1

• - compounds comprising several different organic radicals, such as magnesium methoxyethylate,
• the complex alkoxides and phenoxides of magnesium and of another metal, such as Mg [Al (OR) ₄ ] ₂ and Mg [Al (OR) ₆ ] ₂ , and
• - mixtures of two or more of the organic oxygenated magnesium compounds defined above.

• - les dihalogénures du type commercial qui sont appelés conventionnellement "anhydres" et qui sont en fait des dihalogénures hydratés contenant une molécule et moins d'eau par molécule de dihalogénure; les dichlorures de magnésium "anhydres du commerce" sont un exemple typique de ces composés;
• - les dihalogénures complexés au moyen de divers donneurs d'électrons, comme par exemple les complexes avec l'ammoniac, tels que MgCl₂.6NH₃, MgCl₂.2NH₃, et les complexes avec les alcools, tels que MgCl₂.6CH₃OH, MgCl₂.6C₂.H₅OH et MgCl₂.6C₃H₇OH,
• - les dihalogénures hydratés contenant plus d'une molécule d'eau par molécule de dihalogénure, tels que MgCl₂.6H₂O, MgCl₂.2H₂O,
• - les composés comprenant, outre la liaison magnésium-halogène, un radical inorganique, lié au magnésium par l'intermédiaire de l'oxygène, tel qu'un radical hydroxyle, comme dans Mg(OH)Cl et Mg(OH)Br,
• - les composés comprenant, outre la liaison magnésium-halogène (de préférence la liaison magnésium-chlore) une liaison magnésium-radical organique, de préférence une liaison magnésium-radical hydrocarboné (tel que défini plus haut), comme dans Mg(C₂H₅)Cl et Mg(C₆H₅)Cl,
• - les produits de l'hydrolyse des halogénures (de préférence des chlorures) hydratés du magnésium, pour autant que ces produits contiennent encore des liaisons magnésium-halogène,
• - les compositions mixtes comprenant des composés halogènes et oxygénés du magnésium. Des exemples typiques de ces compositions sont les halogénures (de préférence les chlorures) basiques de magnésium tels que MgCl₂·MgO.H₂O, MgCl₂.3MgO.7H₂O et MgBr₂.3MgO.6H₂O,
• - les mélanges de deux ou plusieurs des composés halogénés du magnésium définis ci-dessus.

Among the halogenated magnesium compounds (M), there may be mentioned:

• - dihalides of the commercial type which are conventionally called "anhydrous" and which are in fact hydrated dihalides containing one molecule and less water per molecule of dihalide; "commercial anhydrous" magnesium dichlorides are a typical example of these compounds;
• - dihalides complexed by means of various electron donors, such as for example complexes with ammonia, such as MgCl ₂ .6NH ₃ , MgCl ₂ .2NH ₃ , and complexes with alcohols, such as MgCl ₂ .6CH ₃ OH, MgCl ₂ .6C ₂ .H ₅ OH and MgCl ₂ .6C ₃ H ₇ OH,
• hydrated dihalides containing more than one molecule of water per molecule of dihalide, such as MgCl ₂ .6H ₂ O, MgCl ₂ .2H ₂ O,
• the compounds comprising, in addition to the magnesium-halogen bond, an inorganic radical, linked to magnesium via oxygen, such as a hydroxyl radical, as in Mg (OH) Cl and Mg (OH) Br,
• - the compounds comprising, in addition to the magnesium-halogen bond (preferably the magnesium-chlorine bond) a magnesium-organic radical bond, preferably a magnesium-hydrocarbon radical bond (as defined above), as in Mg (C ₂ H ₅ ) Cl and Mg (C ₆ H ₅ ) Cl,
• - the products of the hydrolysis of halides (preferably chlorides) hydrated with magnesium, provided that these products still contain magnesium-halogen bonds,
• - mixed compositions comprising halogenated and oxygenated magnesium compounds. Typical examples of these compositions are the halides (preferably chlorides) of basic magnesium such as MgCl ₂ · MgO.H ₂ O, MgCl ₂ .3MgO.7H ₂ O and MgBr ₂ .3MgO.6H ₂ O,
• - mixtures of two or more of the halogenated magnesium compounds defined above.

Finally, it is understood that the use of two or more compounds as defined above also falls within the scope of the present invention.

Similarly, the use of magnesium compounds containing both a magnesium-halogen bond and an organic radical as defined above linked to magnesium via oxygen is also part of the invention. The compounds of this type giving the best results are of course, chlorakloxides and chlorphenoxides such as Mg (OCH ₃ ) Cl, Mg (OC ₂ H ₅ ) Cl and Mg (OC ₆ H ₅ ) Cl for example.

The best results are obtained when the compound (M) of magnesium is a dialkoxide.

The reagents (2) used to prepare the catalytic complexes according to the invention are titanium compounds (T). The tetravalent titanium compounds are preferably used because they are more often liquid and in any case more often and better soluble than those where this metal is at a valence of less than 4. The organic oxygenated compounds (T) of the titanium which can be used as reactants (2) can also be compounds comprising metal-oxygen bonds and condensed compounds comprising sequences of metal-oxygen-metal bonds, provided that they also comprise at least one sequence of metal-oxygen-organic radical bonds by molecule.

The organic oxygenated compounds (T) can be represented by the general formula [TiO _x (OR) _4-2x ] _n where R represents an organic radical as defined above, where x is a number such that 0 <x <1, 5 and where n is. an integer. We prefer to use organic oxygenated compounds where x is such that 0 <x <1 and n such that 1 <n <6.

The use of organic oxygenated compounds (T) comprising several different organic radicals also falls within the scope of the present invention.

• - les alkoxydes, tels que Ti(OC₂H₅)₄, Ti(OnC₃H₇)₄, Ti(OnC₄H₉)₄, Ti(OC₄H₉)₄, et Ti(O-tertC₄H₉)₄,
• - les phénoxydes, tels que Ti(OC₆H₅)₄,
• - les oxyalkoxydes, tels que TiO(OC₂H₅)₂,
• - les alkoxydes condensés, tels que Ti₂O(CiC₃H₇)₆,
• - les carboxylates, tels que Ti(OOCCH₃)_4'
• - les énolates, tels qué l'acétylacétonate de titane.

Among the organic oxygenated compounds (T) of titanium, there may be mentioned:

• - alkoxides, such as Ti (OC ₂ H ₅ ) ₄ , Ti (OnC ₃ H ₇ ) ₄ , Ti (OnC ₄ H ₉ ) ₄ , Ti (OC ₄ H ₉ ) ₄ , and Ti (O-tertC ₄ H ₉ ) ₄ ,
• - phenoxides, such as Ti (OC ₆ H ₅ ) ₄ ,
• - oxyalkoxides, such as TiO (OC ₂ H ₅ ) ₂ ,
• - condensed alkoxides, such as Ti ₂ O (CiC ₃ H ₇ ) ₆ ,
• - carboxylates, such as Ti (OOCCH ₃ ) _{4 '}
• - enolates, such as titanium acetylacetonate.

• - les tétrahalogénures, tels que TiCl₄, TiBr₄,
• - les halogénures complexés au moyen de divers donneurs d'électrons, tels que TiCl₄.6NH₃, TiCl₄.2C₅H₅N, TiCl₄.C₄H₈O₂
• - les halogénures complexes de titane et d'un métal alcalin, tels que R₂TiCl₆ et Na₂TiCl₆,
• - les oxyhalogénures, tels que TiOCl₂,
• - les halogénoalkoxydes, tels que Ti(OC₂H₅)₂Cl₂, Ti(OC₂H₅)₃Cl, Ti(OiC₃H₇)₃Cl, Ti(OiC₄H₉)₂Cl₂.

Among the halogenated compounds (T) of titanium, there may be mentioned:

• - tetrahalides, such as TiCl ₄ , TiBr ₄ ,
• - halides complexed using various electron donors, such as TiCl ₄ .6NH ₃ , TiCl ₄ .2C ₅ H ₅ N, TiCl ₄ .C ₄ H ₈ O ₂
• - complex halides of titanium and an alkali metal, such as R ₂ TiCl ₆ and Na ₂ TiCl ₆ ,
• - oxyhalides, such as TiOCl ₂ ,
• - haloalkoxide, such as Ti (OC ₂ H ₅ ) ₂ Cl ₂ , Ti (OC ₂ H ₅ ) ₃ Cl, Ti (OiC ₃ H ₇ ) ₃ Cl, Ti (OiC ₄ H ₉ ) ₂ Cl ₂ .

The best results are obtained with titanium tetraalkoxides.

It goes without saying that the use of several compounds (T) different from titanium also falls within the scope of the invention.

It may be advantageous, for the manufacture of alpha-olefin polymers of wide molecular weight distribution, to additionally use at least one additional transition metal compound (reagent (4)) to prepare the solid catalytic complexes of l 'invention. This additional compound is then a compound (Z) chosen from organic oxygenated compounds and halogenated zirconium compounds.

These compounds (Z) correspond in all points to the definitions and limitations set out above in relation to the compounds (T).

• - les alkoxydes, tels que Zr(OC₄H₉)₄,
• - les phénoxydes, tels que Zr(OC₆H₅)₄,
• - les oxyalkoxydes, tels que zr[Ozr(OC₂H₅)₃]₄,
• - les carboxylates, tels que Zr(OOCCH₃)₄, Zr(C₂O₄)₂,
• - les énolates, tels que l'acétylacétonate de zirconium,
• - les tétrahalogénures, tels que ZrC14 et ZrF₄,
• - les halogénures complexés au moyen de divers donneurs d'électrons, tels que ZrCl₄.8NH₃, ZrCl₄.4NH₃ et ZrCl₄.4C₅H₅N,
• - les oxyhalogénures, tels que ZrOF₂ et ZzOCl₂.8H₂O,
• - les halogénoalkoxydes, tels que Zr(OC₄H₉)Cl₃.

As examples of zirconium (Z) compounds which can be used, mention may be made of:

• - alkoxides, such as Zr (OC ₄ H ₉ ) ₄ ,
• - phenoxides, such as Zr (OC ₆ H ₅ ) ₄ ,
• - oxyalkoxides, such as zr [Ozr (OC ₂ H ₅ ) ₃ ] ₄ ,
• - carboxylates, such as Zr (OOCCH ₃ ) ₄ , Zr (C ₂ O ₄ ) ₂ ,
• - enolates, such as zirconium acetylacetonate,
• - tetrahalides, such as ZrC14 and ZrF ₄ ,
• the halides complexed by means of various electron donors, such as ZrCl ₄ .8NH ₃ , ZrCl ₄ .4NH ₃ and ZrCl ₄ .4C ₅ H ₅ N,
• - oxyhalides, such as ZrOF ₂ and ZzOCl ₂ .8H ₂ O,
• - haloalkoxide, such as Zr (OC ₄ H ₉ ) Cl ₃ .

The best results are obtained with tetralkoxides and zirconium tetrachloride.

In this particular embodiment of the invention, it is preferred to use these different compounds (T) and (Z) as described in Belgian patent 840,378 filed on 5.4.1976 in the name of the Applicant, the content of which is applicable at any point in this particular embodiment of the invention.

The solid catalytic complexes which can be used according to the present invention are finally prepared from reactants (3) which must be organoaluminum chlorides of general formula AlR _n Cl _3-n in which R and n are as defined above.

These reagents (3) are preferably organoaluminum chlorides corresponding to the general formula above in which R is an alkyl radical, linear or branched, comprising from 4 to 18 carbon atoms and in which n is from 1 to 1.5 .

When the alkyl radical is connected, the side chain is preferably single and short, and is in particular a methyl group. Preferably, the branched radical is a single “iso” radical, that is to say a radical in which the substituent group is in position α with respect to the terminal carbon of the radical.

The best results are obtained when the organoaluminum chlorides correspond to the above formula., In which R is an alkyl radical, linear or branched, comprising from 4 to 18 carbon atoms, and in which n is 1. Organic chlorides corresponding to this definition - tion are for example the dichlorides of n-butyl- and isobutylaluminium, n-octyl- and isooctylaluminium, n-hexadécylaluminium, n-octadécylaluminium. A particularly preferred and easily accessible organoaluminum chloride is isobutylaluminum dichloride Al (iC ₄ H ₉ ) Cl ₂ .

The choice of reagent (3) is an essential characteristic of the invention. It is indeed the nature of this reagent which, surprisingly, is at the basis of the appreciable improvement in the morphology of polyolefins obtained according to the method of the invention.

The use of several different organoaluminum chlorides is not excluded from the scope of the invention, provided that the alkyl radicals contained in each of them contain at least 4 carbon atoms.

These organoaluminum chlorides can be prepared, optionally "in situ" and preferably prior to their use, in particular by mixing the corresponding trialkylaluminums with aluminum chlorides containing more chlorine than the chloride which it is desired to obtain. It goes without saying that the scope of the invention is not limited to the use of organoaluminum chlorides consisting exclusively of compounds corresponding to the general formula mentioned above but that it extends to technical products containing, in addition to a proportion substantial of these compounds, by-products such as the reagents used for their preparation. However, it is preferred that these products contain at least 80% by weight of organoaluminum chlorides corresponding to the general formula.

The solid catalytic complexes of the invention can be prepared from the reactants (1), (2), (3) and optionally (4) above according to all the methods inducing a chemical reaction between them.

It is preferred to carry out the reaction for forming the complexes in a liquid medium. To do this, it is possible to operate in the presence of a diluent, in particular when the reagents are not themselves liquid under the operating conditions or when there are not enough liquid reagents. When a diluent is used, it is generally chosen from those which are capable of dissolving at least one of the reactants and in particular from alkanes, cycloalkanes and aromatic hydrocarbons comprising from 4 to 20 carbon atoms such as for example the isobutane, hexane, heptane, cyclohexane, benzene, toluene, etc. It is also possible to use polar solvents such as ethers and alcohols comprising from to 12 carbon atoms (ethanol and diethyl ether, for example), tetrahydrofuran, pyridine, methylene chloride, etc. When using a diluent dissolving at least one of the reagents, it is preferred that the total concentration of the dissolved reagent (s) is greater than 5% by weight and preferably 20% by weight relative to the diluent.

In all cases, whether a diluent is used or there are sufficient liquid reagents under the operating conditions, the reaction medium is preferably in the form of a relatively viscous liquid in which may be present. solid matter in dispersed state.

The order of addition of the reagents is arbitrary. The reagents (3) can, in particular, be introduced into the reaction medium at any time during the preparation of the solid catalytic complex.

• 1) on met en présence le réactif (I) et le réactif (2) en les mélangeant progressivement ou en les ajoutant l'un à l'autre; on ajoute ensuite progressivement le réactif (3);
• 2) on mélange, de préférence rapidement, le réactif (2) et le réactif (3), puis on ajoute le réactif (I);
• 3) on mélange simultanément et progressivement les trois réactifs.

For reasons of convenience, however, it is preferable to prepare these solid catalytic complexes according to one of the methods below:

• 1) the reagent (I) and the reagent (2) are brought together by gradually mixing them or by adding them to each other; the reagent (3) is then gradually added;
• 2) the reagent (2) and the reagent (3) are mixed, preferably rapidly, then the reagent (I) is added;
• 3) the three reagents are mixed simultaneously and gradually.

Whichever method is chosen, it is therefore preferred that the addition of reagent (3) takes place at the end of the preparation of the catalytic complexes, that is to say as soon as possible while the reagents (1) and (2) are brought together. The best results are obtained when the reagent (3) is used after the reagents (1) and (2) have been brought together in their entirety.

The methods for preparing the solid catalytic complexes according to the invention also extend to the use, in place of the reactants (1) and (2) preformed, of magnesium, of a hydroxylated organic compound such as an alcohol and reagent (2).

The preparation of such catalytic complexes is described in Belgian patent 819,609 of September 6, 1974 in the name of the Applicant, the content of which is applicable in all respects to this particular embodiment of the invention.

The pressure under which the preparation of the catalytic complexes is carried out, the rate of addition of the reactants and the duration of their contact are not critical factors. For reasons of convenience, one generally works under atmospheric pressure; the speed is generally chosen so as not to cause a sudden heating of the reaction medium due to a possible self-acceleration of the reaction; the duration can generally vary between 5 minutes and 12 hours. We generally agitates the reaction medium so as to promote its homogenization during the reaction period. The reaction can be carried out continuously or batchwise.

The temperature at which the reactant (1) and the reactant (2) are brought into contact is not critical. For reasons of convenience, it is generally chosen between 200 and -50 ° C., preferably between 150 ° C. and ambient temperature (25 ^° C.). On the other hand, when the catalytic complexes are prepared by reacting the reagent (3) with the mixture resulting from the bringing together of the reagent (1) and reagent (2), it is surprisingly found that the temperature at which this reaction is carried out has an influence on the morphology of the polyolefin powder finally obtained. All other things being equal, it is possible to reinforce the favorable action of the organoaluminum chloride in accordance with the invention on the size, hardness and particle size of the particles of the polyolefin and on its apparent specific weight, by suitably choosing the temperature at which this reagent (3) is added to the product resulting from the prior mixing of the reagents (1) and (2). This temperature, which is generally above 0 ° C and below the boiling temperature under ordinary pressure of organoaluminum chloride, is preferably between 30 and 65 ° C. The best results are obtained between around 45 and 60 ° C. The preparation of the catalytic complexes in accordance with the invention can advantageously be completed by a treatment of the ripening carried out at a temperature generally equivalent to or higher than that at which the reaction with the reagent (3) takes place for a non-critical period ranging from 5 minutes. at 12 o'clock in general, preferably for at least 1 hour.

The quantity of compound (M), of compound (T) and of organoaluminum chloride (A) to be used preferably are specified below.

The quantity of the compound (s) (T) to be used is defined relative to the total quantity of the compound (s) (M) used. It can vary widely. In general, it is between 0.01 and 10 at.-g (gram atom) of metal present in the compound (T) per at.-g of magnesium present in the compound (M). It has been observed that the performance of the catalytic complexes of the invention is optimal when a ratio of between 0.025 and 5 at.-g of titanium per at-g of magnesium is used. The best compromise between productivity (i.e. the quantity of polymer produced compared to the quantity of cataly complex tick used), and the specific activity (that is to say the amount of polymer produced relative to the amount of titanium and / or zirconium used) of the catalytic complexes, on the one hand, and the morphology of the polyolefin obtained, on the other hand, is obtained when this ratio varies between 0.10 and 2 at.-g per at.-g approximately.

The amount of organoaluminum chloride to be used is also defined relative to the total amount of the compound (s) used. It can also vary widely. In general, it is between 1 and 100 moles of organoaluminum chloride per mole of compound (M). Preferably, this amount is between 1 and 20 moles per mole. The best compromise (as defined above) is obtained when this ratio is between 2 and 10 moles per mole.

The catalytic complexes according to the invention are solid. They are insoluble in alkanes and cycloalkanes which can be used as diluents. They can be used in polymerization as they are obtained, without being separated from the reaction reaction medium. They can however be separated from this reaction medium, in particular when they are prepared in the presence of a polar solvent, by any known means. When the reaction medium is liquid, it is possible to use, for example, filtration, decantation or centrifugation.

After separation, the catalytic complexes can be washed so as to remove the excess reactants with which they could still be impregnated. Any inert diluent can be used for this washing, for example those which can be used as constituents of the reaction medium, such as alkanes and cycloalkanes. After washing, the eatalytic complexes can be dried, for example, by sweeping with a stream of dry nitrogen or under vacuum.

The mechanism of the reaction for the formation of the catalytic complexes of the invention is not known. Elementary analysis of the catalytic complexes, after separation and washing, shows that these are indeed chemically linked complexes, products of chemical reactions, and not the result of mixtures or adsorption phenomena. Indeed, it is impossible to dissociate one or the other of the constituents of these complexes using purely physical separation methods.

- The catalytic systems according to the invention also comprise an organometallic compound which serves as an activator. The organometallic compounds of the metals of groups Ia, IIa, IIb, IIIb and IVb of the Periodic table such as organometallic compounds of lithium, magnesium, zinc, aluminum or tin. The best results are obtained with organoaluminum compounds.

It is possible to use fully alkylated compounds whose alkyl chains contain from 1 to 20 carbon atoms and are straight or branched, such as for example lithium, diethylmagnesium, diethylzinc., Tetraethyltin, tetrabutyltin and trialkylalumi- niums.

It is also possible to use alkyl metal hydrides in which the alkyl radicals also comprise from 1 to 20 carbon atoms such as diisobutyl aluminum hydride and trimethyl tin hydride. Also suitable are metal alkyl halides in which the alkyl radicals also contain from 1 to 20 carbon atoms such as ethyl aluminum sesquichloride, diethyl aluminum chloride and diisobutyl aluminum chloride.

It is also possible to use organoaluminum compounds obtained by reacting trialkylaluminiums or dialkylaluminium hydrides whose radicals contain from 1 to 20 carbon atoms with diolefins comprising from 4 to 20 carbon atoms, and more particularly the compounds called isoprenylaluminiums.

For the manufacture of certain qualities of polyolefins, it is preferred to use trialkylaluminiums whose alkyl chains are straight and contain from 1 to 18 carbon atoms. It is in fact found, quite surprisingly, that when these compounds serve as activators for the catalytic complexes prepared in accordance with the invention, that is to say by involving a reagent (3) which is an organoaluminum chloride as defined above, the molecular weight distributions of the polyolefins obtained are wider, all other conditions equal, than those of the polyolefins obtained in the presence of catalytic complexes prepared by using the usual reagents (3) (ethylaluminum dichloride).

This unexpected result (wider distribution of molecular weights) is particularly advantageous when the polyolefin is intended for the manufacture of large objects such as drums and large containers by extrusion-blowing techniques.

The process of the invention applies to the polymerization of terminal unsaturation olefins whose molecule contains from 2 to 20 atoms, and preferably from 2 to 6 carbon atoms, such as ethylene, propylene, butene- 1, 4-methylpentene-1 and hexene-1. It also applies to the copolymerization of these olefins together as well as with diolefins comprising preferably from 4 to 20 carbon atoms. These diolefins can be non-conjugated aliphatic diolefins such as 1,4-hexadiene, monocyclic diolefins such as 4-vinylcyclohexene, 1,3-divinylcyclohexane, cycopentadiene or cyclo-octadiene-1,5, alicyclic diolefins having an endocyclic bridge such as dicyclopentadiene or norbornadiene and conjugated aliphatic diolefins such as butadiene and isoprene.

The process of the invention is particularly applicable to the manufacture of homopolymers of ethylene and of copolymers containing at least 90 molar Z and preferably 95 molar ethylene.

The polymerization can be carried out according to any known process: in solution or in suspension in a hydrocarbon solvent or diluent or also in the gas phase. For the processes in solution or in suspension, solvents or diluents similar to those used for the preparation of the catalytic complex are used: these are preferably alkanes or cycloalkanes such as isobutane, pentane, hexane, l 'heptane, cyclohexane, methylcyclohexane or mixtures thereof. It is also possible to carry out the polymerization in the monomer or one of the monomers maintained in the liquid state. It is particularly advantageous to carry out polymerization processes in which the polymers are generated directly in the form of particles. Among these methods, the polymerization processes in suspension in a liquid hydrocarbon diluent under the polymerization conditions are preferred, which, after separation of the unreacted monomer and the diluent, provide, in the presence of catalytic systems of the invention, polymer particles which have the morphological characteristics of the powders used in the transformation processes mentioned above. ;

The polymerization pressure is generally between atmospheric pressure 2 and 100 kg / cm, preferably 50 kg / cm. The temperature is generally chosen between 20 and 200 ° C. It is preferably between 60 and 120 ° C so as to directly obtain the polymer in solid form. No degradation in the morphology of the polyolefin particles obtained in the presence of the catalytic systems of the invention is observed when the polymerization temperature is lowered in this preferred zone. On the contrary, when solid catalytic complexes are prepared from the usual reagents (3) of the prior art, it is found that the lowering of the polymerization temperature exerts a detrimental effect on the morphology of the polyolefin obtained (the particles are thinner and less harsh).

The polymerization can be carried out continuously or batchwise.

The organometallic compound and the catalytic complex can be added separately to the polymerization medium: They can also be brought into contact, at a temperature between -40 and 80 ° C, for a period of up to 2 hours, before they are removed. introduce into the polymerization reactor. They can also be brought into contact in several stages or else add a part of the organometallic compound before the reactor or else add several different organometallic compounds.

The total amount of organometallic compound used can vary to a large extent. It is generally between 0.02 and 50 mmol per dm ³ of solvent, diluent or reactor volume and preferably between 0.5 and 2.5 mmol per dm ³ .

The amount of catalytic complex used is determined as a function of the titanium content of the catalytic complex. It is generally chosen so that the concentration is between 0.001 and 2.5 and preferably between 0.01 and 0.25 mat.-g of titanium or zirconium per dm of solvent, diluent or reactor volume (mat.-g = milli- atom-gram).

The ratio of the amounts of organometallic compound and catalytic complex is also not critical. It is generally chosen so that the organometallic compound / titanium ratio expressed in mole / at.-g is greater than 1 and preferably greater than 10.

The average molecular weight, and therefore the melt index of the polymers produced according to the process of the invention can be adjusted by the addition to the polymerization medium of one or more molecular weight modifiers such as hydrogen, zinc or cadmium diethyl, alcohols or carbon dioxide.

The specific gravity of the homopolymers manufactured according to the process of the invention can also be adjusted by the addition to the polymerization medium of a 1 μm alkoxide metal from groups IVa and Va of the Periodic Table. Thus it is possible to manufacture polyethylenes of specific gravity intermediate between that of conventional high density polyethylenes and that of polyethylenes prepared according to a high pressure process.

Among the alkoxides suitable for this adjustment, those of titanium and vanadium whose radicals contain from 1 to 20 carbon atoms each are particularly effective. These include Ti (OCH ₃ ) ₄ , Ti (OC ₂ H ₅ ) ₄ , Ti [OCH ₂ CH (CH ₃ ) ₂ ] ₄ , Ti (OC ₈ H ₁₇ ) ₄ and Ti (OC ₁₆ H ₃₃ ) ₄ ,

The process of the invention makes it possible to manufacture polyolefins with very high productivities. Thus, in the homopolymerization of ethylene, the productivity expressed in grams of polyethylene per gram of catalytic complex used regularly exceeds 10,000 and in some cases 20,000. The activity related to the amount of transition metals present in the catalytic complex is also very high. In the homopolymerization of ethylene, also expressed in grams of polyethylene per at.-g of titanium used, it regularly exceeds 200,000. In the most favorable cases, it is greater than 500,000. It is in all cases the cases at least at the level of the activities conferred on the preferred catalytic systems of the prior art, comprising the solid catalytic complexes prepared from ethylaluminum dichloride as reagent (3), and it is even often superior to these activities.

As a result, the content of catalytic residues in the polymers produced according to the process of the invention is. extremely low. More particularly, the content of residual transition metal is excessively low. However, these are the derivatives of the transition metals which are especially troublesome in the catalytic residues because of the colored complexes which they form with the phenolic antioxidants usually used in polyolefins and the toxic nature of said metals.

In the process of the invention, the content of the annoying residues in polymers is so low that it is possible to save on the purification treatment (for example an alcohol treatment), which is compulsory when the content catalytic residue is high and is an expensive operation in terms of raw materials and energy and requiring considerable fixed assets.

The polyolefin powders produced in accordance with the invention are therefore characterized by a remarkable morphology and can be used in this form. This is particularly the case for the powders of ethylene polymers. The polyolefins obtained according to the invention can however be granular and be used in the form of granules according to conventional molding techniques: by injection, by extrusion, by extrusion- blowing, calendering, etc.

The examples which follow are intended to illustrate the invention and do not limit its scope.

Examples 1 to 4 and comparative example 5R

• (1) de l'éthylate de magnésium Mg(OC₂H₅)₂ vendu par Dynamit Nobel
• (2) du tétrabutylate de titane Ti(OnC4H9)4 vendu par Dynamit Nobel
• (3) différents chlorures organoaluminiques définis ci-après.

The following reagents are used:

• (1) magnesium ethylate Mg (OC ₂ H ₅ ) ₂ sold by Dynamit Nobel
• (2) titanium tetrabutylate Ti (OnC4H9) 4 sold by Dynamit Nobel
• (3) various organoaluminum chlorides defined below.

A stock solution (S) is prepared by heating together, at 150 ° C, with stirring and for 2 hours, 9 moles of the reagent (2) and 4.5 moles of the reagent (1). In this mixture, the Ti / Mg atomic ratio is therefore approximately 2 at.-g / at.-g. 500 ml of the stock solution (S), in which it. there has been almost complete dissolution of the reagent (1) and which has been cooled beforehand, 1000 ml of hexane are added, so as to obtain a solution at approximately 500 g / bed.

• - dans l'exemple 1, du dichlorure d'isobutylaluminium Al(iC₄H₉)Cl₂;
• - dans l'exemple 2, du dichlorure de n-butylaluminium Al(nC₄H₉)Cl₂;
• - dans l'exemple 3, du dichlorure de n-octylaluminium Al(nC₈H₁₇)Cl₂;
• - dans l'exemple 4, du dichlorure de n-octadécylaluminium Al(nC₁₈H₃₇)Cl₂;
• - dans l'exemple comparatif 5R, du dichlorure d'éthylaluminium Al(C₂H₅)Cl₂. Les chlorures organoaluminiques mis en oeuvre selon les exemples 1 et 5R sont des produits commerciaux vendus par Schering.

The different organoaluminum chlorides used are:

• - In Example 1, isobutylaluminum dichloride Al (iC ₄ H ₉ ) Cl ₂ ;
• - In Example 2, n-butylaluminum dichloride Al (nC ₄ H ₉ ) Cl ₂ ;
• - In Example 3, n-octylaluminum dichloride Al (nC ₈ H ₁₇ ) Cl ₂ ;
• - In Example 4, n-octadecylaluminum dichloride Al (nC ₁₈ H ₃₇ ) Cl ₂ ;
• - In Comparative Example 5R, ethyl aluminum dichloride Al (C ₂ H ₅ ) Cl ₂ . The organoaluminum chlorides used according to Examples 1 and 5R are commercial products sold by Schering.

The organoaluminum chlorides used according to Examples 2, 3, 4 were prepared, in a known manner, by reaction of the corresponding trialkylaluminum with aluminum trichloride.

These organoaluminum chlorides are used in the form of solutions in hexane at 400 g / bed. They are gradually added to fractions of stock solutions (S), diluted as indicated above, at a temperature of about 50 ° C and with stirring, for about 90 minutes. At the end of this addition, the reaction mixture is subjected to curing for 1 hour at 60 ° C. The amount of organoaluminum chloride used in each of the examples is such that the molar ratio of organoaluminum chloride / magnesium ethylate is approximately 10.

The catalytic complexes thus formed are used as such, without being separated from their reaction medium, in polymerization tests the general conditions of which are defined below.

Determined quantities of catalytic complex and 0.5 mmol of triethylaluminum are introduced into a 1.5 l autoclave containing 0.5 l of hexane. The temperature of the autoclave is then brought to approximately 85 ° C. Ethylene is introduced under a partial pressure of 10 kg / cm ² and hydrogen under a partial pressure of 4 kg / cm ² .

The polymerization is continued for 1 hour with stirring while keeping the total pressure constant by continuous addition of ethylene. After 1 h, the autoclave is degassed and the polyethylene thus produced is collected.

Table I lists the conditions specific to each test, the results obtained and the morphological characteristics of the polyethylenes produced.

• - PSA signifie "poids spécifique apparent" du polymère et est exprimé en kg/dm³;
• - D signifie "dureté" du polymère et est exprimée en pour cent. Cette dureté est appréciée en mesurant le PSA du polymère, de manière connue, par écoulement, avant et après un broyage d'une durée de 6 secondes dans un broyeur à lamelles tournant à plus de 20 000 trs/min. La dureté est donnée par la formule empirique PSA avant broyage x 100 (%) PSA après broyage 100

In this Table, and in the following examples:

• - PSA means "apparent specific weight" of the polymer and is expressed in kg / dm ³ ;
• - D means "hardness" of the polymer and is expressed in percent. This hardness is assessed by measuring the PSA of the polymer, in a known manner, by flow, before and after grinding for a duration of 6 seconds in a lamellar mill rotating at more than 20,000 rpm. The hardness is given by the empirical formula PSA before grinding x 100 (%) PSA after grinding 100

• - la distribution granulométrique G du polymère est aussi exprimée en pour cent et est mesurée après broyage dans les conditions définies ci-dessus.
• - MI représente l'indice de fluidité du polyéthylène, exprimé en g/10 min. et mesuré selon la norme ASTM-D 1238-70.
• la quantité de suspension en complexe catalytique mise en oeuvre est exprimée indirectement par le poids, en mg, de titane qu'elle contient.
• - HLMI représente l'indice de fluidité du polyéthylène sous forte charge, exprimé en g/10 min, mesuré selon la norme ASTM-D 1238-70.
• - le rapport HLMI/MI est représentatif de l'étalement de la distribution des poids moléculaires. Il est d'autant plus élevé que la distribution est large.
  

The higher the value obtained, the harder the polymer particles;

• - the particle size distribution G of the polymer is also expressed in percent and is measured after grinding under the conditions defined above.
• - MI represents the melt index of the polyethylene, expressed in g / 10 min. and measured according to ASTM-D 1238-70.
• the quantity of suspension in catalytic complex used is expressed indirectly by the weight, in mg, of titanium which it contains.
• - HLMI represents the melt index of polyethylene under high load, expressed in g / 10 min, measured according to standard ASTM-D 1238-70.
• - The HLMI / MI ratio is representative of the spread of the molecular weight distribution. The higher the distribution, the higher the distribution.
  

Table I shows that the use of organoaluminum chlorides meeting the definition of the invention as reagents (3) (examples 1 to 4) leads, with improved catalytic activities, to polyethylenes which contain a proportion of large particles clearly higher than that present in the polyethylenes obtained with the usual reagent (3) of the prior art (example 5 R).

Examples 6 and 7. R

Example 7 R is given for comparison.

Catalytic complexes are prepared in accordance with the preceding examples except that the reactants (2) and (1) are mixed so that the atomic ratio Ti / Mg is approximately 1.2 at.-g / at.-g, that the amount of organoaluminum chloride used is such that the molar ratio of organoaluminum chloride / magnesium ethylate is approximately 3.5 and that the organoaluminum chloride is added at a temperature of approximately 30 ° C.

In Example 6, the catalytic complex is prepared by using isobutylaluminum dichloride as the organoaluminum chloride.

In Example 7 ^- R, the catalytic complex is prepared by making use of ethylaluminum dichloride as organoaluminum chloride.

The catalytic complexes obtained are used in the form of a suspension in the medium which served to prepare them for carrying out ethylene polymerization tests under general conditions absolutely identical to those described in the previous examples.

The morphological characteristics of the polyethylenes obtained are collated in Table II.

It is therefore found that the advantageous results of the use of organoaluminum chloride (reagents (3)) meeting the definition of the invention remain acquired despite significant changes in the molar ratios between reagents.

Examples 8 to 12

Catalytic complexes are prepared in accordance with Examples 1 to 5 R using isobutylaluminum dichloride as the organoaluminum chloride.

However, the hexane solution of this reagent is added to the stock solution (S) at varying temperatures.
Polymerization tests of ethylene are carried out with the catalytic complexes thus prepared under the general conditions described in Examples 1 to 5 R.
The conditions specific to each test, the results obtained and the morphological characteristics of the polyethylenes produced are collated in Table III.

It can therefore be seen that, in the particular case of the use of isobutylaluminum dichloride as reagent (3), the results relating to the morphology of the polymer and the catalytic performances are higher when the temperature at which this compound is used is higher than 30 ° C. In addition, increasing the temperature at which this compound is added does not decrease the PSA or widen the particle size distribution.

Examples 13 to 15 and comparative examples 16 R to 18 R

Catalytic complexes are prepared in accordance with Examples 1 to 5 R using isobutylaluminum dichloride used at 50 ° C, as the organoaluminum compound in Examples 13 to 15, and ethylaluminum dichloride, used at 30 ° C, in examples 16 R to 18 R.

• - du triéthylaluminium Al(C₂H₅)₃ dans les exemples 13 et 16 R;
• - du trioctylaluminium Al(C₈H₁₇)₃ dans les exemples 14 et 17 R;
• - du trioctadécylaluminium Al(C₁₈H₃₇)₃ dans les exemples 15 et 18 R.

Tests for the polymerization of ethylene are carried out with the catalytic complexes thus prepared under the general conditions described in Examples 1 to 5 R but using the following organoaluminum compounds as activators of the catalytic systems:

• - Triethylaluminium Al (C ₂ H ₅ ) ₃ in Examples 13 and 16 R;
• - Trioctylaluminium Al (C ₈ H ₁₇ ) ₃ in Examples 14 and 17 R;
• - Trioctadecylaluminium Al (C ₁₈ H ₃₇ ) ₃ in Examples 15 and 18 R.

The conditions specific to each test, the results obtained and the characteristics of the polyethylenes produced are collated in Table IV.

Examination of this table makes it possible to conclude that when organoaluminum chlorides (reagents (3)) in accordance with the invention are used, polyethylenes are obtained under strictly identical polymerization conditions, which, in addition to their more advantageous morphology , have larger molecular weight distributions than when the catalytic complexes are prepared with the preferred reagent (3) of the prior art.

Claims (11)

The present invention relates to an improved process for the polymerization of alpha-olefins. It also relates to solid catalytic complexes which can be used for the polymerization of alpha-olefins and to a process for preparing these complexes. It is known to use, for the low pressure polymerization of olefins, catalytic systems comprising a transition metal compound and an organometallic compound. Also known, by the Belgian patents 791,676 of November 21, 1972 and 799,977 of July 24, 1973 in the name of the Applicant, catalytic systems, a component of which is obtained by reacting with each other: (1) an organic oxygenated compound or a metal halide, such as magnesium ethylate or magnesium dichloride, (2) an organic oxygenated compound of a transition metal, such as titanium tetrabutylate, and (3) an aluminum halide, such as ethyl aluminum dichloride. These catalytic systems are unique in that they have extremely important advantages. Thus, their activity and their productivity are very high. Their preparation is extremely simple and does not lead to any polluting by-product. Finally, the morphology of the polymer obtained makes it possible to polymerize in suspension continuously with a very high relative polymer content and therefore a relative amount of diluent to be treated before very-low recycling. However, the use of catalytic systems such as that described above still has a serious disadvantage when used in a process where the polymer is obtained directly in the form of particles. It has in fact been found that the polymers obtained in particles directly upon their intervention, although of regular particle size, contain a relatively high percentage of fine particles and have a relatively small average particle size. The morphology of the particles of these polymers therefore poses problems during their drying, their storage, their transport, their handling and their use by known molding techniques. The attempts made so far to increase the average particle size of the polymer particles obtained directly by polymerization using the catalytic systems described above have not been completely satisfactory. It has thus been found that a certain increase in the average diameter of the particles can be obtained by raising the temperature at which the aluminum halide is used. This increase in the mean diameter is however unfortunately accompanied by a decrease in the apparent specific weight and a significant widening of the particle size distribution. The main object of the present invention is therefore to obtain, without the above-mentioned harmful side effects, polyolefins in which the percentage of fine particles is reduced and in which the average particle size is higher. In addition, polyolefins are increasingly used in the form of powders, that is to say in the form of dense and regular particles, a large percentage of which have a diameter: average greater than 250 microns, preferably greater at 500 microns. Polyolefin powders are particularly appreciated for processing by injection. Other interesting outlets for polyolefin powders are the production of coatings by various techniques (electrostatic coating, spray coating, etc.) and the use as additives, release agents, waxes, compositions for paints, binders for nonwoven textiles. , etc. Another object of the present invention is the manufacture of polyolefin powders by means of polymerization processes which directly give polymers in the form of particles which have the morphological characteristics of the powders used in the processes mentioned above. The invention is based on the surprising discovery that a very particular class of catalytic systems described above allows. ,