Catalysts for the polymerization of olefins

Abstract

Disclosed are catalysts for the polymerization of alpha-olefins which comprise the reaction product of:(a) an Al-alkyl compound;(b) a silicon compound containing at least one Si—OR or Si—OCOR or Si—NR2 bond, R being a hydrocarbyl radical;(c) a solid comprising, as essential support, a Mg dihalide in active form and, supported thereon, a Ti halide or a halo-Ti-alcoholate and a particular type of electron donor compound.The present invention refers to new supported components of catalysts for the polymerization of CH2═CHR olefins wherein R is an alkyl radical with 1 to 4 carbon atoms, or an aryl radical, and mixtures of said olefins with ethylene and the catalysts obtained from said components.

Description

BACKGROUND OF THE INVENTION

The supported highly active and highly stereospecific catalysts for the polymerization of propylene and higher olefins, known up to now are obtained by the reaction of an Al alkyl compound partially complexed with an electron donor compound (outside donor) with a solid component comprising a Ti compound and an electron-donor compound (inside donor) supported on a Mg halide in active form.

Examples of such catalysts have been described in British Patent No. 1,559,194 and Belgian Patent No. 868,682.

Outside donors consisting of silicon compounds containing Si—O—C bonds also have been described (published Japanese patent applications Sho 79/94590 and Sho 80/36203). Among the various and numerous inside donors such compounds as methyl methacrylate and ethyl pivalate also have been cited.

However, in all the prior art catalysts in which a silicon compound containing Si—O—C bonds is used as outside donor, esters of benzoic acid and derivatives thereof are used as inside donor.

The performance of the above catalysts, expressed in terms of activity and stereospecificity, is not different from the performance of the catalysts in which ethyl benzoate and similar esters of benzoic acid are used as outside donor.

THE PRESENT INVENTION

One object of this invention is to provide new catalyst-forming components comprising, as outside donor, a silicon compound containing Si—O—C bonds and an inside ester different from the esters of benzoic acid and derivatives, and which result in final catalysts of increased activity and stereospecificity as compared to the components heretofore known comprising, as inside donor, an ester of benzoic acid or derivative thereof; and the catalysts based on such components.

This and other objects are achieved by this invention in accordance with which, and unexpectedly, it has been found that it is possible to increase the activity and stereo-specificity of the prior art supported catalysts comprising, as outside donor, a silicon compound containing Si—O—C bonds, by using as inside donor an ester having a particular structure as described hereinafter.

The catalysts of this invention comprise the product of reaction between the following components:

(a) an Al trialkyl or an Al-alkyl compound containing 2 or more aluminum atoms linked to each other through oxygen or nitrogen atoms or through SO 4 or SO 3 groups;

(b) a silicon compound containing one or more Si—OR, Si—OCOR or Si—NR 2 bonds (R being a hydrocarbyl radical);

(c) a solid comprising, as essential support, an anhydrous Mg dihalide present in active form and, supported on said dihalide,a Ti halide or a Ti haloalcoholate and an electron-donor compound selected from the following groups of compounds:

(1) mono- and polyesters of saturated polycarboxylic acids wherein at least one of the esteric carbonyl groups is linked to a tertiary or quaternary-carbon atom or to a linear or branched chain of at least 4 carbon atoms;

(2) mono- and polyesters of unsaturated polycarboxylic acids wherein two carboxy groups are linked to vicinal double bond-forming carbon atoms and in which at least one of the R hydrocarbyl radicals of the COOR groups is a branched saturated or unsaturated radical with 3 to 20 C atoms or is an aryl or aryl-alkyl radical with 6 to 20 C atoms;

(3) mono- and diesters of aromatic dicarboxylic acids having the COOH groups in ortho position wherein at least one of the R hydrocarbyl radicals of the COOR groups contains from 3 to 20 carbon atoms;

(4) mono- and polyesters of aromatic hydroxy compounds containing at least 2 hydroxyl groups in ortho position;

(5) esters of aromatic hydroxy acids wherein at least a hydroxyl group is in ortho position to the carboxy group;

(6) esters of saturated or unsaturated carboxylic acids wherein at least one of the hydrocarbyl R and R′ radicals of the R COOR′ group is a saturated or unsaturated branched radical containing from 3 to 20 C atoms, or is an aryl-alkyl radical with 7 to 20 C atoms or R is an aryl radical with 3 to 20 carbon atoms linked to the esteric carbonyl group directly or through a methylene group, and in which the R′ radical contains from 3 to 20 C when it is a linear hydrocarbyl radical; and

(7) esters of carbonic acid of formula

in which at least one of the R radicals which can be the same or different is a hydrocarbyl radical with 3 to 20 carbon atoms.

Representative esters which are suitable in preparing component (c) are the following:

Class 1

diethyl diisobutylmalonate, diethyl n-butylmalonate, diethyl-n-dibutylmalonate, diethylphenylmalonate, diethyl-1,2-cyclohexane-dicarboxylate, dioctylsebacate,diisobutyl adipate.

Class 2

di-2-ethyl-hexyl-maleate, diisobutylmaleate, diisobutyl-3,4-furan-dicarboxylate, di-2-ethylhexylfumarate, 2-ethylhexyl-monomaleate.

Class 3

diisobutyl-2,3-naphthalen-dicarboxylate, di-n-propyl, din-n-butyl, diisobutyl, di-n-heptyl, di-2-ethyl-hexyl, di-n-octyl, di-neopentil phthalates, monobutyl and monoisobutyl esters of phthalic acid, ethyl-isobutyl-phthalate, ethyl-n-butyl-phthalate.

Class 4

2,3-diacetoxynaphthalene, 1,2-diacetoxybenzene, 1-methyl-2,3-diacetoxybenzene.

Class 5

benzoyl-ethylsalicylate, acetyl-methylsalicylate.

Class 6

ethyleneglycol-pivalate, 1,4-butanediol-pivalate , benzyl and isobutylpivalate, n-propylpivalate, ethyl diphenylacetate, isobutylmethacrylate, isobutylacrylate, ethyl-benzoylacetate, isobutylpyruvate, isobutyl-trans-3-methoxy-2-butenoate.

Class 7

phenyl-ethylcarbonate, diphenyl carbonate.

Preferred compounds are the esters of maleic, pivalic methacrylic, carbonic and phthalic acids.

As indicated, the esters of the polycarboxylic acids can contain, besides the ester groups, also unesterified COOH groups.

In preparing component (c) the esters are contacted with the active Mg dihalide or the precursors of said dihalides as preformed compounds or the esters can be formed in situ by means of known reactions as, for instance, by esterification between an alcohol or an alcoholate and an aryl halide or between an anhydride or a hemiester of a polycarboxylic acid with an alcohol or by transesterification. The esters can be used, also, in mixture with other known inside donors.

The active anhydrous Mg dihalides forming the essential support of component (c) are the Mg dihalides showing in the X-rays powder spectrum of component (c) a broadening of at least 30% of the most intense diffraction line which appears in the powder spectrum of the corresponding dihalide having 1 m 2 /g of surface area or are the Mg dihalides showing an X-rays powder spectrum in which said most intense diffraction line is replaced by a halo with the intensity peak shifted with respect to the interplanar distance of the most intense line and/or are the Mg dihalides having a surface area greater than 3 m 2 /g.

The measurement of the surface area of the Mg dihalides is made on component (c) after treatment with boiling TiCl 4 for 2 hours. The found value is considered as surface area of the Mg dihalide.

Very active forms of Mg dihalides are those showing an X-rays powder spectrum in which the most intense diffraction line appearing in the spectrum of the corresponding halide having 1 m 2 /g of surface area is decreased in relative intensity and broadened to form a halo or are those in which said most intense line is replaced by a halo having its intensity peak shifted with respect to the interplanar distance of the most intense line. Generally, the surface area of the above forms is higher than 30-40 m 2 /g and is comprised in particular between 100-300 m 2 /g.

Active forms are also those deriving from the above forms by heat-treatment of component (c) in inert hydrocarbon solvents and showing in the X-rays spectrum sharp diffraction lines in place of the halos.

The sharp, most intense line of these forms shows, in any case, a broadening of at least 30% with respect to the corresponding line of the Mg dihalide having 1 m 2 /g of surface area. Preferred Mg dihalides are Mg dichloride and Mg dibromide. The content in water of the dihalides is generally less than 1% by weight.

By Ti halides or Ti haloalcoholates and esters supported on active Mg dihalide is meant the above compounds which may be chemically or physically fixed on the support, and not extractable from component (c) by treatment of the same with boiling 1,2-dichloroethane for 2 hours.

Components (a), (b) and (c) are made to react with each other in any order; preferably, however, components (a) and (b) are premixed before being contacted with component (c).

Component (c) may be premixed with either component (a) and/or (b). The pre-mixing of (a) and (b) is conducted at temperatures comprised, usually, between room temperature and the temperature used in the polymerization process.

The pre-reaction of (c) and (b) may be carried out also at higher temperatures. Compound (b) may be also incorporated and made to react with component (c) itself. Component (b) is made to react in a molar ratio with respect to the halogenated Ti compound supported on component (c) of at least 1 and in a molar ratio with respect to the Al-alkyl compound used as component (a) of less than 20 and preferably comprised between 0.05 to 0.3.

In component (c), the molar ratio between the Mg dihalide and the halogenated Ti compound supported therein is comprised between 1 and 500 and the molar ratio between said halogenated Ti compound and the electron-donor supported on the Mg dihalide is comprised between 0.1 and 50.

The silicon compounds set forth in (b) include compounds of general formula:

R m SiY n X p

wherein:

R is an alky, alkenyl, aryl, arylalkyl, cycloalkyl radical with from 1 to 20 carbon atoms;

Y is —OR′, —OCOR′, —NR 2 ′ wherein R′, either equal to or different from R, has the same meaning as R;

X is either a halogen or hydrogen atom or an —OCOR″ or —NR 2 ″ group wherein R″, either equal to or different from R′, has the same meaning as R′;

m, n and p are numbers comprised respectively between: m between 0 and 3, n between 1 and 4 and p between 0 and 1; and m+n+p is equal to 4.

Other silicon compounds that may be used are compounds in which two or more silicon atoms are bound to each other through oxygen or nitrogen atoms.

Examples of these compounds are hexaethoxydisiloxane, and symmetrical diphenyltetraethoxydisiloxane

Preferred silicon compounds are: phenylalkoxysilanes such as phenyltriethoxy or trimethoxysilane, diphenyldimethoxy and diethoxysilane, monochlorophenyldiethoxysilane, alkyl-alkoxysilanes such as ethyltriethoxysilane, ethyltriisopro-poxysilane.

Examples of other suitable compounds are: chloro-triethoxysilane, acetoxytriethoxysilane, vinyltriethoxysilane, butyltriethoxysilane, triphenylmonoethoxysilane, phenyltricy-cloethoxysilane, phenyldiethoxydiethylaminosilane, tetra-phenoxysilane or tetralkoxysilanes as tetramethoxysilane.

The silicon compound can be also formed in situ by reaction of, for instance, a halogenated silicon compound such as SiCl 4 with an alcohol or an alcoholate of Mg or Al.

In the catalysts of the invention, the silicon compound is present, in a combined form in the solid product of the reaction between the various catalyst-forming components, in a molar ratio between the silicon compound and the halogenated Ti compound greater than 0.05 and generally comprised between 0.1 and 5.

The Al-alkyl compounds forming component (a) include Al-trialkyls as, for instance, Al triethyl, Al triisobutyl, Al triisopropyl and compounds containing two or more Al atoms linked to each other through hetero-atoms, such as:

As indicated, Al alkyl compounds in which Al atoms are linked through groups such as SO 4 or SO 3 are also suitable.

The Al alkyl compounds may be used in mixture with Al-alkyl halides such as, for example, AlEt 2 Cl.

Component (c) is prepared according to known methods. One of these methods consists in co-milling the Mg dihalide and the electron-donor compound of this invention until the appearance in the X-ray spectrum of the milled product of the modifications above set forth for the spectrum of the Mg dihalide, and thereafter reacting the milled product with the Ti-compound.

Preparations of this type are described in British Patent No. 1,559,194.

Another method consists in reacting the adduct of a Mg halide with an alcohol, with a Ti compound in the presence of an electron-donor compound not containing active hydrogen atoms. This method is described in Belgian Patent No. 868,682.

According to another method, which is described in published German patent application No. 3,022,738, the adduct between the Mg dihalide and the alcohol is reacted in liquid form with the halogenated Ti compound and the electron-donor compound.

Further methods are described in published German application 2,924,029 and U.S. Pat. No. 4,220,554 as well as in the pending U.S. application of Antonio Monte et al, Ser. No. 206,541, filed Nov. 13, 1980.

Another method consists in co-milling the Mg dihalide the halogenated Ti compound and the electron-donor compound until the Mg dihalide is activated and in treating a suspension of the milled product in a halogenated hydrocarbon, for instance 1,2-dichloroethane, chlorobenzene, methylene chloride or hexachloroethane.

The treatment is carried out at temperatures comprised between 40° C. and the boiling point of the halogenated hydrocarbon for a time ranging in general from 1 to 4 hours.

According to another method, a porous support like Sio 2 or Al 2 O 3 , having a low content of OH groups (preferably less than 1% by weight) is impregnated with a liquid adduct between the Mg dihalide and an alcohol; the support is then treated with an excess of TiCl 4 containing, dissolved therein, the electron-donor compound, the procedure being as described, for instance, in published German patent application No. 3,022,738 or Belgian patent 868,682.

In all the above methods, the final product contains a Mg dihalide present in the active form as set forth herein-above.

Other known methods which lead to the formation of Mg dihalide in active form or to Ti containing Mg dihalide supported components, in which the dihalide is present in active form, are based on the following reactions:

reaction of a Grignard reagent or a MgR 2 compound (R being a hydrocarbyl radical) or complexes of said MgR 2 compounds with Al trialkyls, with halogenating agents as AlX 3 or AlR m X n compounds (X is halogen, R is a hydrocarbyl, m+n=3), SiCl 4 or HSiCl 3 ;

reaction of a Grignard reagent with a silanol or polysiloxane, H 2 O or with an alcohol and further reaction with a halogenating agent or with TiCl 4 ;

reaction of Mg with an alcohol and a halogenhydric acid or of Mg with a hydrocarbyl halide and an alcohol;

reaction of MgO with Cl 2 or AlCl 3 ;

reaction of MgX 2 .nH 2 O (X=halogen) with halogenating agent or TiCl 4 ;

reaction of Mg mono- or dialcoholates or Mg carboxylates with a halogenating agent.

The Ti-halides or Ti halogenalcoholates include, in particular, the Ti tetrahalides, Ti trihalides and Ti trihalogenalcoholates. Preferred compounds are: TiCl 4 , TiBr 4 , 2,6-dimethylphenoxytrichlorotitanium.

The Ti trihalides are obtained according to known methods, for instance by reduction of TiCl 4 with Al, an organometallic Al compound or hydrogen.

In the case of the Ti trihalides, it may be convenient, for the purpose of improving the performance of the catalysts, to carry out an oxidization, even if partial, of the titanium, either during or after the preparation of component (c). For this purpose there may be used halogens, iodine halides.

Preferred catalysts are those in which component (c) is obtained from MgCl 2 , TiCl 4 and esters of maleic, pivalic and phthalic acids and in which component (b) is phenyl or ethyl-triethoxysilane or diphenyldimethoxy or diethoxysilane.

Component (a) is an Al trialkyl as Al triethyl or Al triisobutyl.

Component (c) is prepared according to the methods described in British Patent No. 1,559,194, Belgian Patent No. 868,682, published German application No. 2,924,029, U.S. Pat. No. 4,220,554, published German application No. 3,022,738 or in the pending Monte et al application referred to supra.

The preferred method of preparing component (c) includes also the co-milling of MgCl 2 , TiCl 4 and the ester and in treating the milled product with a halogenated hydrocarbon, such as 1,2-dichloroethane.

The catalysts according to the invention are used to polymerize the alpha-olefins according to known methods that is by carrying out the polymerization in a liquid phase, either in the presence or absence of an inert hydrocarbon solvent, or in gas phase or also by combining, for instance, a liquid phase polymerization step with a step in gas phase.

In general, the polymerization temperature is comprised between 40° and 160° C., but preferably between 60° and 90° C., operating either at atmospheric or at greater than atmospheric pressure.

As a molecular weight regulator hydrogen or other regulators of a known type are used.

The catalysts are particularly suitable for polymerizing propylene, butene-1, styrene and 4-methylpentene. The catalysts may also be used according to known methods to polymerize mixtures of propylene and ethylene to form modified polypropylenes having better shock-resistance at low temperatures (the so called block copolymers of propylene and ethylene) or to obtain random crystalline copolymers of propylene with minor proportions of ethylene.

The following examples are given for merely illustrative purpose and are not intended to be in any way limiting with respect to the scope of the invention.

EXAMPLES 1-10

Into a stainless steel autoclave having a total volume of 31, equipped with a magnetized stirrer and a thermo-couple heat-stabilized at 60° C. and kept under pressure by a nitrogen atmosphere, there were introduced 1,000 ml of a suspension in degassed and anhydrous n-heptane containing 5 m mols of triethylaluminum, the phenyltriethoxysilane (PES) and a solid catalytic component prepared according to Example 1 of the aforementioned pending Monte et al application, but using, instead of ethylbenzoate, the esters listed in Table I, while propylene was also fed in. The catalytic components thus prepared showed X-rays powder spectra in which the most intense diffraction line appearing in the spectrum of MgCl 2 having 1 m 2 /g of surface area is decreased in relative intensity and broadened to form a halo.

The autoclave was closed and thereafter hydrogen was introduced up to a pressure of 0.2 atmospheres, the temperature was brought to 70° C. and simultaneously, propylene was introduced up to a total pressure of 7 atmospheres.

During the-polymerization, the pressure was kept constant by continuous feeding of the monomer. After 4 hours, the polymerization was stopped by quick cooling and degassing of the polymeric slurry. The polymer was separated from the solvent by filtering and was dried in a hot nitrogen flow at 70° C. The quantity of polymer dissolved in the filtrate was thereupon isolated, weighed and summed to the polymer soluble in boiling n-heptane, for calculation of the isotacticity index (I.I.).

The quantity of catalytic component used and the content of Ti in said component, the molar ratio of the phenyl-triethoxysilane with respect to the triethylaluminum, the yield in polymer with respect to the introduced catalytic component, the isotacticity index (I.I.), the surface area of the solid catalytic component and the inherent viscosity determined in tetralin at 135° C., are reported in Table I.

EXAMPLE 11

Example 8 was repeated under the same polymerization conditions described in Examples 1-10, but using a solid catalytic component prepared according to Example 7 of published German patent application 2,643,143.

The catalytic component showed an X-rays powder spectrum in which the most intense diffraction line appearing in the spectrum of MgCl 2 having 1 m 2 /g of surface area is decreased in relative intensity and broadened to form a halo.

The content of Ti in the solid catalytic component, the quantity of said component, the molar ratio between triethylaluminum and PES, and the results of the polymerization test are reported in Table I.

EXAMPLE 12

The solid catalytic component prepared according to Example 11 was suspended in the inert hydrocarbon solvent Isopar G (a mixture of isoparaffinic hydrocarbons boiling in the temperature range of from 158° to 172.5° C.) and heat-treated at 120° C. for 24 hours. The catalytic components thus obtained showed an X-rays powder spectrum in which the most intense diffraction line appeared as a sharp line, the half peak breadth of which, however, was broadened more than 30% of the corresponding half peak breadth of MgCl 2 having 1 m 2 /g of surface area.

The catalyst component obtained was used under the same polymerization conditions as described in Example 11.

The characteristics of the solid catalytic component and the results of the polymerization test are reported in Table I.

COMPARATIVE EXAMPLES 1 AND 2

Example 1 was repeated but using the solid catalytic component prepared according to Example 1 of Italian patent application No. 27,261/79, which is the priority document for the aforementioned pending Monte et al U.S. application. The X-rays powder spectrum was similar to that of the catalytic component of Example 1.

The results of the polymerization tests are reported in Table I.

COMPARATIVE EXAMPLE 3

Example 11 was repeated except that the solid catalytic component prepared according to Example 7 of German patent application 2,643,143 was used. The X-rays powder spectrum was similar to that of catalytic component of Example 11.

The results of the polymerization tests have been reported in Table I.

EXAMPLES 13-18

Example 1 was repeated using a solid catalytic component prepared as follows.

Anhydrous MgCl 1 an ester, listed in Table II, and TiCl 4 in molar ratio of 1:1 with respect to the ester, were co-ground in a vibrating mill of the type VIBRATOM manufactured by N.V. TEMA, s'Gravenhage, Holland, having a total volume of one liter and containing 3 kg of stainless steel balls of 16 mm diameter.

Grinding was effected for 72 hours employing a filling coefficient equal to 100 g/l of, total volume (vacuum), at an interior temperature of the mill of 25° C.

Charging of the mill, the grinding and discharging of the mill occurred in a nitrogen atmosphere.

10 g of the co-ground product were contacted with 100 ml of 1,2-dichloroethane at 80° C. for 2 hours. After this period, 1,2-dichloroethane was removed by filtration at 80° C. and the residual solid product was repeatedly washed with n-heptane at room temperature until the chlorine ions disappeared from the filtrate and then was kept in heptanic suspension.

The catalytic components thus prepared showed an X-rays powder spectrum in which the most intense diffraction line appearing in the spectrum of MgCl 2 having 1 m 2 /g of surface area was decreased in relative intensity and broadened to form a halo.

The type of ester used, the characteristics of the solid catalytic component 6 and the results of polymerization tests have been reported in Table II.

EXAMPLES 19-26

Example 1 was repeated but using a solid catalytic component prepared according to Example 3 of Italian Patent application No. 26,908 A/78, which is the priority document for the pending U.S. application of Mario Ferraris et al, Ser. No. 226,837, filed Jan. 21, 1981.

A solid adduct MgCl 2 .2.5C 2 H 5 OH in the form of spherical particles was slowly added to a suspension of an adduct TiCl 4 -ester using molar ratios Mg/ester of 10 and TiCl 4 /C 2 H 5 OH of 10.

The whole was then heated at 100° C., kept at said temperature for 2 hours and then filtered at 100° C. The resulting solid product was treated with 110 ml of TiCl at 120° C. for 2 hours. After this period, TiCl 4 was removed by filtration and the solid was washed with n-heptane at temperatures decreasing from 90° C. to room temperature until the chlorine ions disappeared from the filtrate and then kept in heptanic suspension.

The catalytic components thus prepared showed the X-rays spectra similar to those of the catalytic component of Examples 1-10.

The esters used, the characteristics of the solid catalytic component and the results of the polymerization tests are reported in Table III.

COMPARATIVE EXAMPLE 4

Example 19 was repeated but using the solid catalytic component prepared according to Example 3 of the Italian Patent Application 26,908 A/78. The X-rays spectrum of that catalytic component was similar to those of Examples 1-10.

The characteristics of the solid product and the results of the polymerization test are given in Table III.

EXAMPLES 27-29

Example 1 was repeated, but using a solid catalytic component prepared according to Example 1 of published German Patent Application 3,022,738, wherein, instead of ethylbenzoate esters of phthalic acid, listed in Table IV, were used and the treatment with TiCl 4 was effected at 120° C.

The X-rays spectrum of the catalytic components was similar to those of Examples 1-10.

The type of ester and the ratios are shown in Table IV, together with the working conditions and the results of the polymerization tests.

COMPARATIVE EXAMPLE 5

Example 27 was repeated but using a solid catalytic component prepared according to Example 1 of German Patent Application 3,022,738.

The working conditions and the results of the polymerization test are reported in Table III.

EXAMPLES 30-34

Example 8 was repeated using instead of phenyl-triethoxysilane an equimolecular amount of the alkoxysilanes reported in Table V.

The characteristics of the catalytic components and the results of the polymerization tests are reported in Table V.

	TABLE I
	Solid catalytic component	Polymerization
		MgCl 2	Ti content				Yield
		ester	of solid	Surface	Al(C 2 H 5 ) 3		g polymer
Example		grinding	component	area	PES	Catalyst	g catalyst	I.I.	η in h
No.	Ester	mols/mols	% by weight	m 2 /g	mols/mols	mg	component	%	dl/g
1	diisobutyl-2,3-naphthalen-dicarboxylate	14	2.3	—	10	35	7,750	92.7	1.1
2	di-2-ethyl-hexyl-maleate	14	1.8	296	10	25	6,600	94	1.1
3	diisobutylmaleate	14	2.9	—	10	54	5,700	92.2	1.2
4	isobutylacetate	7	3.2	—	10	32	5,700	91.2	1.8
5	isobutylpivalate	7	2.6	—	10	22	9,700	92.9	1.3
6	diethyl diisobutyl-malonate	14	2.4	—	10	47	4,750	94.3	1.7
7	di-n-butylphthalate	14	2.6	—	20	35	9,600	91.2	1.3
8	diisobutylphthalate	14	2.4	350	20	36	16,100	91.8	1.3
9	diisobutylphthalate	14	2.4	350	10	38	13,200	95.5	1.2
10	di-2-ethylhexylsebacate	14	2.3	—	10	52	4,500	94.8	1.2
11	di-isobutyl-phthalate	8	3.0	—	10	17	15,000	97.5	1.6
12	di-isobutyl-phthalate	8	1.4	21.8	10	14	7,000	97.2	1.5
comp. 1	ethylbenzoate	7	2.0	266	10	46	6,000	90.6	1.4
comp. 2	ethylbenzoate	7	2.0	266	5	47	4,000	92.7	1.6
comp. 3	ethylbenzoate	7	1.5	—	3.33	60	2,400	91.3	1.2

	TABLE II
	Solid catalytic component	Polymerization
		MgCl 2	Ti content				Yield
		ester	of solid	Surface	Al(C 2 H 5 ) 3		g polymer
Example		grinding	component	area	PES	Catalyst	g catalyst	I.I.	η in h
No.	Ester	mols/mols	% by weight	m 2 /g	mols/mols	mg	component	%	dl/g
13	diphenylcarbonate	8	2	—	10	29	6,050	93.2	1.5
14	1,2-diidroxy-diacetate benzene	6	1.3	—	10	41	6,100	92.1	1.4
15	ethyl-diphenylacetate	5	1.9	—	10	38	6,400	91.1	1.2
16	diisobutyl-phthalate	7	1.4	157	20	19	9,100	98	1.3
17	diisobutyl-phthalate	7	1.4	157	100	20	9,000	94.3	1.1
18	isobutyl-benzoylacetate	7	2.1	—	10	42	5,900	95.4	1.2

	TABLE III
	Solid catalytic component	Polymerization
		Ti content			Yield
		of solid	Al(C 2 H 5 ) 3		g polymer
Example		component	PES	Catalyst	g catalyst	I.I.	η in h
No.	Ester	% by weight	mols/mols	mg	component	%	dl/g
19	dioctylphthalate	2.7	20	19	12,100	92.2	1.8
20	diisobutylphthalate	2.4	20	22	13,900	96.9	1.2
21	dineopentylphthalate	3.5	20	15	18,500	97	1.2
22	diphenylphthalate	2.6	10	25	11,000	94.5	1.8
23	diethyl-butylmalonate	3.9	10	29	12,800	93.3	1.7
24	benzyl butylpthalate	3.1	20	24	14,000	96.1	1.4
25	mono-2-ethyl-hexylmaleate	2.8	10	50	8,000	92.5	1.3
26	monoisobutylphthalate	3.1	10	24	10,000	94.3	1.6
comp. 4	ethylbenzoate	3.8	5	38	6,850	91.5	1.5

	TABLE IV
	Solid catalytic component	Polymierzation
		MgCl 2	Ti content			Yield
		ester	of solid	Al(C 2 H 5 ) 3		g polymer
Example		grinding	component	PES	Catalyst	g catalyst	I.I.	η in h
No.	Ester	mols/mols	% by weight	mols/mols	mg	component	%	dl/g
27	dioctylphthalate	4.7	1.9	20	27	12,000	93.9	1.5
28	isobutylphthalate	4.7	3.8	20	32	10,000	96.5	1.4
29	neopentylphthalate	9.4	1.9	20	30	12,800	97.8	1.0
comp. 5	ethylbenzoate	5	3.1	10	49	7,900	94.2	1.5

	TABLE V
	Polymerization
				Yield
				g polymer
	Example		Catalyst	g catalyst	I.I.	η in h
	No.	Alkoxysilane	mg	component	%	dl/g
	30	ethyltri-	33.4	11,000	89.3	1.2
		ethoxysilane
	31	chloro-	44.6	9,800	91.0	1.3
		phenyldi-
		ethoxysilane
	32	diphenyl-	25.1	14,300	92.4	1.0
		diethoxy-
		silane
	33	phenyldi-	31.2	13,200	91.5	1.3
		ethoxysilane
	34	diphenyl-	22.2	18,200	93.1	1.5
		dimethoxy-
		silane

Claims

1. A process for the polymerization of alpha-olefins CH2═CHR, where R is an alkyl radical with 1 to 4 carbon atoms, or an aryl radical, or mixtures of such alpha-olefins with ethylene, comprising contacting the alpha-olefin with a catalyst, the catalyst comprising:a solid component which includes: MgCl2 in active form as an essential support, wherein the MgCl2 essential support has a surface area higher than 40 m2/g, a Ti compound selected from the group consisting of Ti halides or Ti haloalcoholates, and an inside donor selected from the group consisting of diesters of aromatic dicarboxylic acids having the COOH groups in ortho position and wherein the R radicals of the COOR groups contain from 3 to 20 carbon atoms, the molar ratio between the MgCl2 and the Ti compound being between 1 and 500, and the molar ratio between the Ti compound and the inside donor being between 0.1 and 50, wherein the solid component is combined with an Al-alkyl compound and a silicon compound containing at least one Si—OR, Si—OCOR or Si—NR2 bond, where R is a hydrocarbyl radical, the silicon compound being the outside donor, the silicon compound being made to react in a molar ratio with respect to the Ti compound of at lest 1 and in a molar ratio with respect to the Al-alkyl compound of less than 20.

2. The process according to claim 1, wherein the silicon compound is a phenyl di- or trialkoxysilane or an alkyl di- or trinaloxysilane.

3. The process according to claim 1, wherein the polymerization process is carried out in liquid phase in the presence or absence of an inert hydrocarbon solvent or in gas phase, and wherein the resulting polymer has an isotacticity index of at least about 90%.

4. The process according claim 1 in which, in the solid component, the Mg dihalide is MgCl2 or MgBr2.

5. The process according claim 1 in which, in the solid component, the Ti compound is a Ti tetrahalide.

6. The process according claim 1 in which, in the solid component, the Mg dihalide is MgCl2 or MgBr2, and the Ti compound is a Ti tetrahalide.

7. The process according to claim 1, wherein the silicon compound has the formula RmSiYnXp, whereinR is an alkyl, alkenyl, aryl, arylalkyl, or cycloalkyl radical with from 1 to 20 carbon atoms; Y is —OR′, —OCOR′, NR′2 wherein R′, either equal to or different from R, has the same meaning as R; X is either a halogen or a hydrogen atom or an —OCOR″ or —NR2″ wherein R″, either equal to or different from R′, has the same meaning as R′; m, n and p are numbers, with m comprised between 0 and 3, n comprised between 1 and 3, and p comprised between 0 and 1; and m+n+p is equal to 4.

8. The process of claim 1, wherein the ester is an ester of phthalic acid.

9. The process of claim 1, wherein the ester is selected from the group consisting of di-n-propyl phthalate, di-n-butyl phthalate, diisobutyl phthalate, di-n-heptyl phthalate, di-2-ethyl-hexyl phthalate, di-n-octyl phthalate, ethyl-isobutyl phthalate and ethyl-n-butyl phthalate.

10. The process is of claim 9, wherein the ester is diisobutyl phthalate.