CA1137068A

CA1137068A - Catalysts and catalyst components useful for polymerizing olefins

Info

Publication number: CA1137068A
Application number: CA000325300A
Authority: CA
Inventors: Umberto Scata'; Giuliano Cecchin
Original assignee: Montedison SpA
Current assignee: Montedison SpA
Priority date: 1978-04-12
Filing date: 1979-04-11
Publication date: 1982-12-07
Also published as: DE2915036C2; ATA266879A; NO791186L; ZA791780B; NO156374B; BR7902268A; IT1113129B; GB2018788A; GB2018788B; AT363682B; NL191564C; ES479521A1; US4263169A; MX150891A; AU4603679A; IN151429B; JPS54154485A; BE875494A; AU529414B2; NL191564B

Abstract

ABSTRACT OF THE DISCLOSURE

There are disclosed new catalyst-forming components obtained by reacting at least the following substance:
(a) a halogenated Ti compound containing at least one Ti-halogen bond;
(b1) a support an essential constituent of which is a mixture of an oxygenated Mg compound with an ad-duct between a Mg dihalide and at least one elec-tron-donor compound and/or with the product of de composition of said adduct containing Mg dihalide;
and/or (b2) the product obtained by treating and oxygenated Mg compound with an electron-donor compound.
Also disclosed are catalysts prepared from said new ca-talyst-forming components, as is use of the catalysts in the po-lymerization of olefins, more particularly olefins CH2=CHR in which R is a alkyl or aryl radical having 1-8 carbon atoms, of mixtures of said olefins and of mixtures thereof with ethylene.

Description

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~: THE PRIOR ART :
Catalysts havlng a high act~vity and stereospecificity ~: ln polymerizlng alpha olefins are known and are~obtained by react lng an Al-alkyl compound with a Ti compound supported on a Mg ha-lide ~n activated form (German patent No. 2,643,143).
It ls:also known that it is possible to prepare ~iegler~type catalysts for poIyethylene endowed with hlgh ac-tlvity starting from reaction products of halo~enated ~1 com- :
~ ., :
.; pounds and supports consistlng of Mg oxide,~ Mg hydroxide and Mg ~:
. salts of oxygenated aclds.~ These catal~sts, su~tably modif1ed w1th eloctron-donor compounds (or Lewis bases), can be utillzed ~m~

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for the stereoregular polymerization of the alpha-olefins;
their activity, however, is not sufficiently high and in any case not such as to avoid after-purification of the polymer to ! remove catalyst residues.
l~ Attempts were made to improve the performance of said modified Ziegler-type catalysts by subjecting the oxygenated Mg I! compound to pre-halogenation treatments. However, the results !¦ obtained were not satisfactory~

~,¦ THE PRESENT INVENTION
:` i . . . ., ¦ Catalysts having characteristics comparab}e to those described in German Patent No. 2,643,143 in the polymerization of the alpha-olefins CH2 = CHR as defined herein, but prepared ,l from supports comprising oxygenated Mg compounds, such as the oxide, hydroxide, hydroxyhalides, and Mg salts of oxygenated lS ¦l acids have not been disclosed heretofore. ~`
¦¦ One object of this invention is to provide catalys-t component supported on supports comprising oxygenated Mg compounds and ~hich form catalysts that are comparable to those , `
of the German Patent in the polymerization of the alpha-olefins.
Said object and others which will become apparent are achieved by this invention because we have found that, sur-prisingly, it is possible to obtain catalysts endowed with high activity and stereospecificity for the polymerization of the alpha-olefins CH2 = CHR, in which R is an alkyl or aryl radical having 1-8 C atoms, starting from supports including Mg oxygen-¦¦ ated compounds, if such oxygenated compounds are subjected to particular pre-treatments prior to the reaction with the Ti com- ~`
pound, comprising, among other pre-treatments, partially con-verting the oxygenated compound into an adduct between a Mg dihalide and an elsctron-donor compound ED or, preferably, an

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electron-donor compound containing activated hydrogen atoms ~compoulld HED).
The catalysts so obtained offer, among other things, l the advantage that the polymers produced in the presence thereto ! do not lead to corrosion phenomena in the apparatuses (extruders, etc.), used for the transformation of the polymers into shaped articles, even when the polymer contains relatively high amounts of halogenated compounds.
The catalyst components-according to this invention ^ 10 consist of the product obtained by reacting a-t least the follow-ing substances:
- ~a) a halogenated Ti compound containing at least one Ti-halogen bond;
(b) a support the essential constituents of which are:
(bl) an oxygenated Mg compound selected from the oxide, hydroxide, hydroxyhalide of Mg, salts ;
of Mg of oxygenated acids and Mg dihalides in the form of adducts with a-t least one electron-donor compound HED and/or ED, each betng present in an amount higher than 0.1 mole per mole of dihalide, and/or a ~
decomposition product of said adduct, the molar ratio between oxygenated compound and Mg dihalide, either combined or not, rang-ing from 0.05:1 to 20:1; and/or (b2) the product obtained by trea-ting an oxygen-ated compound of the type specified in ~bl) with an electron-donor compound ED or mixtures thereof with ~IED, in amounts respectively of at leas-t 0.1 mole of com-; pound ED and HED per mole of oxygenated

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compound, the reactlon system comprising also an ED compound or adducts t~ereof at least ln the case when such compound i5 not contained . ~.
: . ln support (b) ln comblned or non~combined .
form, the amount of ED compound present in the catalyst component in combined form not .
extractable with TiCl4 at 80 C ranging from .~ O.OS to 5 moles per mole of Ti compound pre- .:
~: sent after such:treatment. ~ .~
Preferably, at least 50% of the Ti compound is not so- :
luble in TlCl4 at 80 C and, more preferably, at least 50~ of said compound ls not soluble in TiCl4 at 135 C.
In a presently pre~erred embodiment, the adduct:con~ : ~-tained ln support (b1) comprises an electron-donor compound HED :: ~:
~; 15 in amounts ranginq from 0.1 to 6 moles per mole of Mg dihalide.
When khe adduct contalns also ~he ED compound, the latter ls .
present ln amounts comprised between 0.1 and 1 mole of dihalide.
. Support ~b1) may be prepared by various methods. A pre-sently preferred method consists in.reacting, according to known techniques, an oxygenated Mg compound of the type specified here-inbefore with a halogenating agent capable of conver-tLng, at :
~:
~ least par~ially, the oxygenated compound into M~ dihalide, oper .; ating under such conditlons that from about 5~ up to 95~ o~ the :~ oxygenated compound ls converted to dlhalide. .-The halogenating reactlon can be conducted in the pre-sence of electron-donor compound EIED and/or ED; in this case the : ...
~:~ adduct between Mg dihal~de and compound HED and~or ED is formed : ln situ. It is preferable, however, to cause such reactlons to : . occur.succes~lvely, More particularly, the product of the preha .
30 logenation l~ reacted first with EIED and then wlth ED. It ls -also ` ' . ' .
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possible to react compound ED during the reaction with the Ti halogenated compound.
As halogenating agents it is possible to employ sulphuryl or thionyl chloride. phosgene, organic halides, hydrogen halides, carboxylic acid halides, ammonium halides, or ¦ Al-, B-, P- and Si-halides.
Specific examples of useful halogenating agents are, besides those already mentioned, hydrogen chloride and hydrogen ~romide, CC14, benzoyl chloride, POC13, SiC14, halo silanes, AlCl3, and Al-alkyl halides such as Al(C2H5)2Cl; Al2(c2H5)3Cl3.
¦ The reaction is generally conducted by suspending the ¦ Mg oxygenated compound in the halogenating compound, if -the ~ latter is liquid under the reac-tion conditions, and by heating ! the mixture to temperatures lower than the decomposition temperature of the halogenating compound and generally ranging from 40 to 120C.
If the halogenating compound is gaseous under the reaction conditions, it is possible to flow vapors thereof over I the oxygenated compound. When a hydrogen halide is used, the ¦ resulting Mg halide contains hydration water~ It is not nec-¦ essary to anhydrify the product to ohtain satisfactory results.
¦ When C12 is employed as halogenating agent, then the ¦ reaction is carried out in the presence of CO and at tempera-¦ tures generally higher than 400C.
l Another method of preparing support ~bl) and which is ¦ one of the presently preferred methods consists in heating, ¦ according to conventional methods, a Mg hydrated halide under ¦ conditions in which dehydration and partial hydrolysis of the dihalide take place. Depending on the temperature, mixtures o Mg dihalide with Mg hydroxyhalide and/or Mg oxide are thus obtained. A full-anhydrification of the starting dihalide is `~ -5~-.
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I not required. Water amounts in the final product up to O.S
il mole per mole of dihalide are allowable withcu~ negatively affecting the catalyst performances. Preferably, the starting I dihalides contain 1-2 moles of H2O and are heated to tempera-1 tures generally ranging from 350 to 550C. The~ resulting ¦ product is then reacted with electron-donor compounds HED and ED.
¦ According to another preparation method, the Mg Il oxygenated compound is mixed, in the already mentioned ratioq, l,~ with a preferably anhydrous Mg dihalide, by operating, for example, in a mill, whereupon the product is reacted with com-~ 1I pounds HED and ED. It is also possible to mix wi-th each other ; the Mg oxygenated compound and the adduct that has previously - ¦ formed between Mg dihalide and compound HED and, optionally, -- 15 ¦ compound ED, or support (bl) can be prepared by reacting the ¦ Mg dihalide with compound ~ED and ED, operating in the presence ¦ of an oxygenated compound.
¦ In some instances, it may be advisable to pre-treat ; ¦ support (bl) containing the adduct with compound HED and ~ optionally with ED, with a compound capable of reacting with compound HED and to form Mg dihalide. For example, one can operate according to the methods described in French Patent No.
7,724,238 using, e.g., SiC14 or an Al-alkyl compound.
It has been found, and this is another feature of the present invention, that the Mg oxygenated compound does not necessarily have to be prehaloyenated and reacted with compound HED pxior to the reaction with the halogenated Ti compound, but that said Ti ccmpound can act as a halogenating agent. In this case, the Mg oxygenated compound is subjected to a pre-treatment with compound ED or mixtures thereof with HED employed in amounts respectively of at least 0.1 mole and up to ahout 5 ~ . , , .
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moles per mole of oxygenated compound. The resulting product is then reacted with the Ti halogenated compound. 0.1 to 3 moles ¦ of compound ED and 0.5 to 2 moles of cornpound ~ED are preerably ¦ employed in the pre-treatment, which is carried out at a S I temperature generally comprised between 40 and 120C and the ¦ resulting suspension is successively reacted with the Ti ¦ compo~nd.
The reaction with the Ti compouna can be conducted in ; I the presence of a halogenating agent o-ther than the Ti com-pound. For e~ample, it is possible to operate in the presence of anhydrous hydrogen chloride, which permits an increase i~
both the amount of Ti compound that remains fixed on the support and in the performance of the resulting catalyst.
As disclosed hereinbefore, when support (bl) is pre-lS pared by pre-halogenating the Mg oxygenated compound and by converting the Mg halide so obtained into an adduct with com-; pounds HED and/or ED, the reaction leading to the formation of the adduct is preferably carried out after the halogenation reaction. One method of operating consists in reacting the halogenated product separated from the reaction mixture and then suspended in a hydrocarbon solvent with compound H~D and ED, preferably used in amounts respectively ranging from 0.2 to 2 moles and from 0.1 to 0O5 mole per mole of starting oxygenated compound. The reaction temperature may be comprised in a wide range, for example, from 40 to I20C.
;~ As also disclosed hereinabove, the reaction between the Ti compound and support (b) is conducted in the presence of a compound ED or of adducts thereof with Lewis acids, at least when such compound is not contained in the support either in a ¦ combined or non-combined form. It is necessary, in fact, that the catalytic component always contain a certain amount of .1 . . .
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compound ED in a combined form non~extractable with TlC14 at 80C.
The reaction with th~ Ti compound is carried out l according to different methods. A presently preferred method !I consists in suspending support (b) in the liquid Ti compound and ¦ in heating the suspension to temperatures of from 60 to 150C
!~ for stretches of time sufEicient to fix the ~i compound on the support in a form non-extractable with TiClg at 80C. On ~
I completion of the reaction, the solid product is separated under ~ ;
10 Ij conditions in which Ti compounds soluble in TiC14 at 80C do 11 not precipitate on it, and the solid product is then washed !l until all traces of free Ti compound are eliminated.
~ The amount of Ti compound, expressed as Ti metal, ¦ that remains fixed on the catalyst component in a form non-extractable with TiC14 at 80C, is generally comprised between 0.1 and 20% by weight. More particularly, the amount of Ti `
compound, expressed as Ti metal, that remains fixed on the ¦ catalyst component after extraction with TiC14 at 135C is coTnprised between 0.2 and 5% by weight.
The general principle followed when carrying out the reaction between the Ti compound and the support lS that of operating under such conditions that the product resuIting from the reaction between the Ti compound and electron-donor com-pound HED and optionally ED of the adduct contained in the support is removed to the greatest possible extent from such support, for example by solubilization in the reaction medium.
The adduct between the Mg dihalide and electron-donor compound HED and/or ED may contain, in a combined form~ besides the aforesaid compounds, also other compounds, such as, e.g., Lewis acids other than the Mg halide.
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The useful Mg oxygcnated compounds includa, as already isclosed herein, oxldes, hydroxides, oxrhalldes of Mg and Mg alts of organLc and inOrJaniC oxygenated acids. Said eompounds are preferably utilized in the anhydrous state. ~owever, they S l ay contaln also hydratlon water in amounts preferably lower than 2 moles per mole of Mg compound. In the case of MgO and Mg(OH)2, for example, lt ls posslble to employ products contalnlng up to bout 1 mole of chemically non-comblned water.
Some specifie examples of M~ compounds are MgO, mixed ~ I xides of Mg, Al and/or Si, hydroxide, hydroxychlor1de and bro-mide of Mg, carbonate and basic carhonate of Mg, basic carbonates of Mg and Al such as, for example, hydrotalclte, Mg nitrate, Mg phosphates and silicates ! Mg carboxylates sueh as aeetate, stea-rata, benzoate, oxalate, p-toluate and terephthalate of Mg, pro-ducts obtained irom the dehydration, under hydrolysis conditlons, of hydrated Mg-halides, and produc~ resultlng from the partial thermal decompositlon of Mg carboxylates.
~ As already mentioned herein, the Mg compounds used in the practice of this lnvention can be, also, in the form of eom-plex compounds with compounds of other metals, e.g., ~l, Fe, Mn, or of double salts or solid solutions.
- Hydrocarbyl electron-donor compounds ~ED are selectedfrom the aliphatlc, cycloaliphatic, aromatic alcohols with 1-20 carbon atoms, the phenols, sllanols, polysiloxane compounds con-taining O~l group~ thioalcohols, thiophenols, prlmary and secondary amines, amides and ammonia.
Example~of specific useful HED compounds are ethanol, butanol, 2-ethylhexanol, o¢tanol, cyclollexanol, phenol, t-butyl-phenol, tr~ethylhydroxysilane, diethildihydroxysilane, methyl--hydropolyslloxane and thioethanol. -: . . ~
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. ~ , Any electron donor compound ED is su~table. ~referably compounds ED are selected from the alkyl, aryl or cycloalkyI
~sters of the carboxyllc aclds, in particuldr from the esters of the aromatic acids. ~ ~
l ther examples of useful E~ compounds are halides and anhydrides `~ ;
f carboxylic acids, ln partlcular of aromatic acids, ethexs, ketones, ter~iary amlnes and amldeq.
Some speclfic examples of useful ED compounds are the alkyl esters (methyl, ethyl, butyl esters etc.3, of benzoic tO acid and of derivatives thereof such as, for example, p toluic acid, ben~oyl chloride, benzoic anhydride, n-butylether, iso-amylether and acetophenone~
Compound ED, when lt is reacted in the form of adduct with the dlhalide and, optionally, with the ~ED compound, i~
generally employed in amounts comprised between 0.1 and 1 mole per mole of Mg dihalide.
The Ti compounds used in practicing th$s invention con-tain at least one Ti-halogen bond and are preferably selected from the Ti tetrahalides, in particular TiCl4 and the Ti halogen--alcoholates, for example, ~nC4H90~2TlCl2 or TiC130CH3.
The catalytic component containing the compounds of tetravalent Ti can be subjected to conventional treatments or reducing such compound to a lower valence, in particular to valence three, for example, by reduction with Al-alkyl compounds.
The catalysts accordlng to the present lnvention are prepared by reacting an Al-alkyl compound, in particular Al-t~lal kyl and ~lxtures thereof with an Al-dialkyl halide, with the above-described catalyst-forming component~ The Al/Tl ratio i5 generally comprised in a wlde range, for example, from 1 to 1, 00 0 .

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In the case of the polymerlzation o~ the alph~-oleflns, lt ls preferable to employ an ~l-trialkyl compound such as, for example, Al-trlethyl, Al-trllsobutyl, ln the ~orm o addltion products thereoE wlth electron-donor compounds, in which the amount of reacted ~l-alkyl compound ranges from 10 to 90~.
When use is made of an Al alkyl compound partlally com-plexed wlth an electron-donor compound, the AlfTl ratlo is ge-nerally higher than 20 and comprised between 30 and 300.
I The electron-donor compound to be reacted with the Al- .
alkyl compound can be the same compound as employed in the re-action for preparlng the catalyst component including the Mg oxyger.ated compound. Preferably, it is an alkyl, aryl or cy-cloalkyl ester of an aromatic acid and in partlcular of benzolc acid and derivatlves thereof.
The oleflns polymerizable with the catalystsof this invention include ethylene, propylene, butene-1, 4-methyl-pentene--1, styrene and mlxtures thereof.
The polymerization processes are of the Xnown type, namely the polymerization is carried out ln the liquid phase, either in the presence or absence of an inert hydrocarbon di-luent, such as butanel pentane~ hexane, heptane; or it is car-ried out ln the gaseous phase.
The polymerization temperature is comprlsed in a wide range, for example, between 50 and 150 C, preferably between 60 and 90 C. The pressure can be the atmospheric pressure or hlgher.
In the case of the polymerizatlon of propylene, the cata lysts are utllized for preparing both propylene homopolymer and ra ~; ~ ~dom copolymer f propy~eDe ~i ~h ethy lene, and poIymerlc composl'clo ' ~ ..
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. ~ :' Il obtained, for axample, by polymerizing at first propylene and, i! successively, in one or more steps, ethylene or mixtures thereof i~ with propylene. The ethylene content of these COmpoSitioJlS can ,l reach about 30C, by weight.
~ The following examples are given to illustrate the present invention in more detail and are not intended to be ¦ limiting.
I . .: .
~ I EXAXPLE 1 ,, , ; il (a) Preparation of the catalyst component ~ 8.1 g of MgO (200 millimoles; commercially pure) were ; jl fed to a jacketed glass reactor having a 500-ml capacity, !i equipped with a filteriny fritted bottom, and in to 238 g ~¦ (2 moles) of thionyl chloride (SOC12)~were introd~lced. The ¦I suspension, under stirring, was heated to boiling (77C) o~ a :; 15 ¦¦ contact time of 2 hours, whereupon SOC12 in excess was removed i by hot filtering ana the residual solid was washed with hexane at 60C until disappearance of the chlorine ion from the ¦I filtrate. The resulting solid product was suspended again, in the same reactor, in a solution containing 3 g (20 m. moles) of ¦ ethyl ben~oate and 2.3 g (50 m. moles) of ethanol diluted with ¦ 100 ml of anhydrous hexane. The suspension was heated 1 hour to 60C. Then the solvent was evaporated at 30C under moderate vacuum (40 Torr). The residual solid product was reacted with 110 ml of TiC14 (1 mole) at 100C for 2 hours. The TiC14 was then removed by filtration at 100C and the residual solid was washed with heptane until disappearance of the chlorine ion.

(b) Polymerization of propylene in hexane (solvent) 5.05 m. moles of a mixture of Al-butyls (54.5% moles of Al-i-Bu3 and 45.5% moles of Al-n-Bu3) were reacted at room ~ -12-,, .,, , . :~:
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` ~ 37~8 tcmperature with 1.69 m.moles (254 mg) of methyl p-toluate in 80 ml of anhydrous hexane in 5 minutes. 30 ml of this solution, diluted with 50 ml of anhydrous hexane, were contacted with 2 Il ml of the catalys' component suspension prepared as described 'I in (la) for a 5-minute contact time. This suspension was in-¦¦ troduced, in a pure nitrogen atmosphere, into a stainless steel autoclave havlng a total volume of 2.5 1, equipped with a magnetic screw stirrer and a thermocouple, and containing 870 ml of propylene-saturated hexane at 40C. Successively, the ¦
j remaininy 50 ml of the solution of Al-butyl and methyl p-toluate were introduced in a propylene flow.
After closing the autoclave, 250 Ncc of hydrogen were introduced, raising the temperature to 60~C and simultaneously I bringing the total pressure -to 9 kg/cm2 gauge with propylene.
The pressure was kept constant by con-tinuously feeding the monomer.
1l After 2 hours the polymeri~ation was stopped by means ¦¦ of quick degassing and cooling of the polymeric slurry. The ¦ sol~ent was evaporated from the polymeric slurry. The dry 1~ 20 l¦ polymer obtained t470 g) contained the following catalyst residues: Ti = 7.5 ppm; Mg = 112 ppm; Cl = 186 ppm. The yield I was 133,500 g of polypropylene/g of Ti, and the residue of the l extraction with boiling heptane was equal to 93.5% by weight.

l (a) Preparation of the catalyst component 8.1 g (200 m.moles) of MgO were reacted, as in Example ¦ (la), for 2 hours at 77C with 238 g of SOC12. The solid pro-duct so obtained, after removal of SOC12 by washings with hot ~ hexane, was suspended in a solution containing 3 g (20 m.moles) of ethyl benzoate and 9.22 g (200 m.moles) of ethanol diluted . , . . ' ! - - . I ~
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' with 100 ml of hexane. ~his suspension was reacted at 60C for 2 hours. Then the solvent was evaporated, as already d~scribed, !
¦ and the solid was reacted with 181 ml (1.65 moles) of TiC14 at 110C for 2 hours.
¦ Before filtering the TiC14, 45 ml of heptane were introduced, whereupon the whole was iltered at 110C. After ¦
the washings with heptane, a portion of the catalyst component !
¦ suspension was dried. The analysls of the resulting solid was ~i as follows: Ti = 2.96~ by weight; ethyl benzoate - 4.65% by weight.

- l (b) Polymerization of propylene in hexane (solvent~
, 0.8 ml of the suspension in heptane of the catalyst ¦
I li component prepared in 2(a) were utilized under the conditions Ij of the propylene polymerization test described in l(b). After lS 11l a 4-hour polymerization there were obtained 363 g of dry : !¦ polymer, havl~g the following catalyst residues: Ti = 6 ppm;
~j Mg = 47 ppm; Cl = 105 ppm. The yield was 166,500 g of poly- ¦~
¦I propylene/g of Ti, and the residue of the extraction with I -~
i boiling heptane was equal to ~0.5% by weight.
11 ~
~ ¦ EXAMPLE 3 ¦ (a) Preparation of the catalyst component The starting material was chemically pure basic I magnesium carbonate having the Eollowiny composition:

4 My(CO3).Mg~OH)2.5H2O. It was transformed into magnesium ~ oxide by calcining in dry nitrogen at 400C for 69 hours.

¦ 81. g of this magnesium oxide (200 m.moles) were utilized to prepare the catalyst according to the procedure ¦ described In Example 2(al.

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A portion of the suspension of the catalyst component in heptane at the end was dried. The dry solid ploduct con-tained 3.15~ by weight of Ti, 5.25% by weight of ethyl benzoate.
I (b) Pol~merization of propylene in hexane ~solvent) l Use was made of 1 ml of the suspension in heptane of the catalyst component prepared in 3~a), under the polymeriza-tion test conditions specified in 1 (b). After a 4-hour polymerization, 422 g of dry polymer were obtained, such polymer containing the following catalyst residues: Ti = 5.7 ppm; ~1 ~Ig = 50 ppm; Cl = 154 ppm. The yield was 175,500 g of poly-propylene/g of Ti, with a resid-le of the extraction with boiling ~ heptane equal to 92% by weight.

I i EXAMPLE 4 I ~
ta) Preparation of the catalyst component Commercial type, chemically pure maqnesium hydroxide was converted into magnesium oxide by calcining at 500C in dry ;
~ il nitrogen for 24 hours.
1: ¦! 8.1 g ~200 m.mo~les) of the magnesium oxide thus jl obtained were utilized to prepare the catalyst according to the 1l modalities described in Example 2 (a). I
(b) ~ymerization of propylene in hexane ~solvent) ¦
~1 1 ml of the suspension in heptane of the catalyst Il component prepared in 4 (a) was utilized under the polymeriza-tion test conditions described in 1 (b). After a 4-hour poly-1~ merization, there were obtained 232 g of dry polymer that con- I
tained the following catalyst residues: Ti = 6.7 ppm;
Mg = 234 ppm; Cl = 273 ppmi the yield was of 149,000 g of poly-¦ propylene/g of Ti, the residue of the extraction with boiling ¦ heptane ~as equal to 88.5% by weight.
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EX~MPI.E 5 .
~' (a) Pr~aration of the catalyst com~onent ,¦ Chemically pure magneslum oxide of the commercial type was calcined at S00C for 24 hours in a dry nitrogen atmosphere.
~; 5 ~ 8.1 g (200 m.moles) of MgO, calcined as alreaày - I described herein, were reacted with 238 g (2 moles) of SOC12 at 77C for 2 hours. After removal of the thlonyl chloride by repeated washing of the residual solid with hexane at 60C, the same was suspended again in a sclution containing 3 g (20 m.
' moles) of ethyl benzoate and 14.82 g ~200 m.molesl of n-BuOH i~
diluted in 100 ml of hexane.
The suspensio~ was reacted for 2 hours at 60C.
Successively the solvent was evaporated, as described herein, ¦ and the residue was reacted with ~iC14 at 110C as in Example j 2 (a).
After the washings [see Example l(a)] with hep~ane, it was found that all traaes of free TiC14 were removed.
; ¦ (b) Polymerization o propylene in hexane ~solvent) 1 ml of the suspension in heptane of the catalyst I component prepared in 5 ~a) was utilized under the polymeriza-~ ¦ tion test conditions described in 1 ~b). After a 4-hour poly-¦~ merization, 176 g of dry polymer were obtained, that contained the following catalyst residues: Ti = 36.2 ppm; Mg = 137 ppm;
Cl = 263 ppm; the yield was 27,600 g of polymer/g of Ti, the ~5 ¦ residue of the extraction with boiling heptane being 90~ by ~ ~ I

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_XAMPLE 6 ~a) Preparation of the catalyst component ¦ 8.1 g (200 m.moles) of MgO, pure product of the com-¦ mercial type, were treated with a solution consisting of 3 g I (20 m.moles) of ethyl benzoate and of 18.44 g (400 m.moles) of EtOH diluted in 50 ml of heptane, at a temperature of 80C for ,¦ 2 hours. Successively, the whole was cooled to 80C and, under stirring and in 15 minutes, 181 ml (1.65 moles) of TiC14 were dropped in. Gaseous HCl evolved while the mixture temperature I was brought to 110C; at this temperature gaseous HCl was ! ;~:
directly introduced into the suspension at a feeding rate of 1 g. mole~hour for 2 hours, corresponding to 73 g of HCl in the ¦
aggregate.
; After stopping the HCl feed, the suspension was diluted with 45 ml of C7-~ (heptane) and filtered at 110C. The solid residue was treated with 181 ml of TiC14 for 2 hours at ¦ lI0C. The solid was then washed three times with heptane ¦
(200 ml each time) at 80~C and five times at room temperature.
(b) Polymerization of propylene in hexane (solvent) 1 ml of the suspension in heptane of the catalyst ; component prepared in 6 (a) was utilized under the same polymer- ization test conditions as described in 1 ~b), with the excep~ion that a temperature of 70C was employed.
After a 4-hour polymerization, there were obtained 251 g of dry polymer containing the following catalyst residues:
Ti = 35 ppm; Mg = 57 ppm; Cl = 175 ppm; the yield was 28,400 g of polypropylene/g of Ti, the residue of the extraction with boiling heptane was equal to 93% by weight.
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lj . , j~ EXAMPLE 7 ta) Prehalogenation of MgO _y_ rea_nent with RCl B0.5 g ~600 m.moles) of commercial MgO wexe reacted ~I in a fluid bed 500 ml reactor at 180C and for 2 hours with a , HCl gaseous stream (2.14 moles/h) diluted with nitrogen, in a ratio by volume equal to 2 HCl;l N2. It was cooled in a stream of nitrogen only. The recovered solid product revealed on analysis the following composition: Mg -- 42.75 y/100 gi Cl = 29.50 g/100 g; H2O = 12.0 g/100 g.
l~ (b) Preparation of the catalyst component In a 250-ml flask, under s-tirring, 15.4 g of the product obtained in Example 7 (a) were reacted with a solution consisting of 4.05 (27 m.moles) of ethyl benzoate and of 12.45 g l (270 m.moles) of EtOH ailuted in 100 ml of hexane, at a -~ 15 1 temperature of 60C for 2 hours. The solvent was then i ,¦ evaporated at room temperature, under vacuum, at a residual partial pressure of 40 mm ~g.
i 30 g of solid product were recovered and introduced I I into a reactor as described in 1 (a), and reacted with 181 ml I (1.65 moles~ of TiC14 at 110C for 2 hours. Successively, the ¦~ l mass was diluted wi-th 45 ml of heptane and at 110C the solid was separa-ted by filtration. All traces of TiC14 were removed by repeateclly washing with heptane (200 ml each time), namely 3 times at 80C and 5 times at room temperature.
From a portion of the catalyst component suspension the solvent was evaporated at 30C under vacuum (20 mm Hg).
I I On analysis the solid residue proved to have the following ;~
composition. Ti = 11.70 g/100 g, Mg = 17.75 g/100 g, Cl = 55.0 g/100 g, ethyl benzo~te = 3.53 g/100 g.

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(c) Polymerizatlon o propylene in hexane (solvent 0.5 ml of the suspension of the catalyst cornponent prepared in 7 (b) was used under -the same polymerization test ' conditions as illustrated in 1 (b), ' After a 4-hour polymerization, 352 g of dry polymer Il were obtained. It contained the following catalyst residues-i, Ti = 25 ppm; Mg = 31 ppm; Cl = 114 ppm. The yield was 40,000 g ~-;l of polypropylene/g o~ Ti and the residue of the extraction with - boiling heptane was equal to 93% by weight.
~ ' . , ':~
` lQ 1I EXAMP~E 8 (a) Preparation-oE -the catalyst component In a 500 ml reactor as describsd in 1 (a), 39 g of a ¦ support based on MgO (20.3%) (an aluminum-magnesium silicate in micro-spheroidal form, marketed by Grace-Davison under item ¦! SM/30)were reacted with 476 g of SOC12 at 77~C Eor 3 hours.
After having removed all traces of SOC12 by means of il several washings with hexane at 60C, the residual solid product was suspended in a solution consisting of 3 g of ethyl benæoate jj (20 m.moles) and 9.22 g of E-tOH (200 m.moles) diluted with 100 ml of hexane and reacted at 60C for 2 hours. ;~
The solvent hexane was evaporated and the solid residue was then treated with 181 ml oE TiCl4 (1.6S moles) at 110C for 2 hours, whereupon the suspenslon was diluted with 45 ml of heptane and filtered at 110C.

(b) Polymerization oE propylene in hexane (solvent) ¦~ 3 ml of the suspension in heptane of the catalyst component prepared in 8 (a) were used under the same polymer-1- i ation test conditions as lllustrated in 1 fb).
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~:~37 Ij ' . . ' ¦¦ After a 4-hour polymerization, 358 g of dry polymer exhibiting a narrow particle size distribution and a micro-spheroidal form were obtained, the yield being of 10,000 g of ~I polymer/g of Ti and the residue of the extraction with boiling I! heptane being 86.5%. ' (c) P ymerization o~ 1 ne in he ane (solvent) 200 mg of the dry catalyst component prepared in 8 (a) ~10.8 mg of Ti) were suspended in 1,000 ml of hexane containing ` 1.5 g of an aluminum-butyls mixture [see Example 1 (b)] and the , whole was then introduced into a 2.5-liter autoclave, in a Il slight ethylene atmosphere. The -temperature was brought to 75C, then hydrogen was fed up to 3 atm gauge and ethylene up to 13 atm gauge in the aggregate. Ethylene was Eed, keeping a l pressure of 13 atm gauge for ~ hours. The polymeric slurry was ^~15 ¦ discharged, and the polymer was separated from the solvent by filtration.
After drying, 347 y of polyethylene having a narrow ll particle size distribution were obtained, the yield being of ¦1 32,100 g of polyethylene/g of Ti.
! . .

(a) Preparation of the catalyst component 8.1 g of MgO (200 m.moles), a pure commercial type product, were reacted with a solution made up of 3 g of ethyl benzoate (20 m.moles) and of 9.22 g of EtOH (200 m.moles~
diluted with 100 ml of hexane, at a temperature of 60C for 2 hours. The solvent was evaporated at room temperature under a sligl-t vacuum ~40 Torr.~. The solid residue was reacted with TiC14 at 110C as describea in E~ample 2 (a). After five ¦ washings with heptane (200 ml each washing), two at 80C and . . . '' ' ~ ~- -20-~:, ~' . ~ ~
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1! 11370~8 i three at room temperature, a portion of the suspension was , dried, and, on analysis, the residual solid product was found ! to have the following composition: Ti ~ 0.9 g/100 g;
Mg = 38 g/100 g; Cl = 47.4 g/100 g; ethyl benzoate = 1.8 g/100 g.;
~1 (b) Polymerization of propylene in hexane tSolvent) I! 1. s ml of the suspension in heptane of the catalyst component prepared in 9 (a) were utilized under the same poly- ' I merization test conditions as illustrated in 1 (b). After a '~ 4--hollr polymerizatlon, there were ob-tained 75 ~ of dry polymer Ij that contained the following catalys-t residues: Tl = 3.5 ppm;
il Mg = 360 ppm; Cl = 420 ppm. The yield was 105,263 g of poly-: i! propylene/g of Ti, and the residue of the extraction with boiling heptane amounted to 86.5% of the total (or crude) I polymerizate.

; 15 ~¦ EXAMPLE 10 !l (a) Preparation of the catalys componen~
- ¦ 8.1 g of MgO (200 m.moles), a pure commercial type pxoduct, were reacted with 238 g ~2 moles) of SOC12 at 77C for I
2 hours. I
After removal, by means of washings with hexane at 60~C, of all -traces of SQC12, the residual solid product was ¦
. reacted with 3 g of ethyl benzoate (20 m.moles) diluted with 100 ml of hexane, at a temperature of 60C for 1 hour. Succes-sively the sol~ent was evaporated at 30C and under vacuum (40 Torr of residual partial pressure). The solid dry product I was treated with 110 ml of TiC14 (1 mole) at 110C for 2 hours.
TiC14 Was then removed by filtration at 100C. The solid ¦¦ residue was washed with heptane (200 ml each time) three times ¦¦ at 80C and -three times at roc,m temperature.
.

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!l lb) ~ p~lene in hexane (solvent) i 1.1 ml of the suspension in heptane o~ the catalyst ;~
component prepared in 10 (a~ were utiliæed under the same polymerization test conditlons as illustrated in 1 ~b). i~;
1 After a 4-hour polymerization, 142 g of dry polyme~
!l were obtained. It contained the following catalyst residues: ¦ ~
Il Ti = 35 ppm; Mg = 183 ppm; Cl - 290 ppm. The yield was 28,571 g , ~1 - I of polypropylene/g of Ti; the residue of the extraction with boiling heptane being equal to 86% of the total (or crude) polymerizate. ¦

¦¦ EXAMPLE 11 I ta) Preparation of the catalyst component ¦
¦ 4.05 g of MgO ~100 m.moles) were reacted with 37.5 g of ethyl benzoate (250 m.moles), diluted with 50 ml of heptane, 15 ¦1 at a temperature of 80~C for 2 hours.
Successlvely, 250 ml of TiC14 (2.28 moles) were ¦
j introduced, bringing the temperature to 110C for 2 hours. The ¦
mass was flltered at~ll0C and the soiid thus separated was treated again with TiCl~ as described herein. The separated ~ solid was repeatedly washed with heptane t200 ml each time):
3 times at 80C and 3 times at room temperature.

~- (b) Pol~nerization of propylene in hexane 1 olvent) 1.5 ml of the suspension of -the catalyst component prepared in ll ta) were utilized under the same polymerization test conditions as described in 1 (b).
¦ After 4 hours, 30 g of dry polymer containing the following catalyst residues were obtained: Ti = 1~ ppm; .
Mg - 348 ppm; Cl = 700 ppm. The yield was 83,200 g of poly-propylene/g of Ti the residue of the extraction with boiling ¦ 30 ¦ heptane was 94.5% of the total or crude polypropylene. The intrinsic viscosity was 1.9 dl~g.

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¦ EXAMPLE 12 - ~
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! (a) Preparation of the catalyst component l .
I 8.1 g of MgO (200 m.moles) were employed, operating I under the same conditions as of Example 6 ta), with the ! exception that EtOH was excludea from the reaction mixture.
~b) Polymerization of propylene in a solvent

5 ml of the suspension in heptane of the catalyst ; ,, component prepared in 12 (ai were utilized under the polymeriza~
,, tion test conditions of 1 (b), except that the temperature was II raised to 70C.
¦¦ At the conclusion of the polymerization run, 193 g of - ,, dry polymer were obtained, containing -the following catalyst ¦ residues: Ti = 13.2 ppm; Mg = 908 ppm; C1 = 1,075 ppm. The yield was 75,757 g of polypropylenejg of Ti, with a residue of ¦ the extraction with boiling heptane of 91.5% of the total or ; I crude polymerizate.
The polymer was characterized by the following 1~ I properties:
¦ intrinsic viscosity = 2.2 dl/g lI
l apparent density = 0.46 kg/1.
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¦ E~AMPLE 13 .. ; I _ I ~a) Preparation of t.he catalxst component I .
¦ A microspheroidal support ~20-70 ~) of a complex ¦ ~gC12.1.237 H2O (18.8~ of H2O), calcined at 400C for 1 hour ¦ was utilized.
In a 250-ml flask, eq~lipped with a stirrer, 10.2 g of ¦ the calcined product were treated with a solution of 4.6 g -~

¦ (100 m.moles) of EtOH diluted with 50 ml of heptane at a -~
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¦ temperature of 0C for 1 hour, under stirring, whereupon 3 g (20 m.mole9) of ethyl benzoate were added to the suspension, I raising tlle temperature to 60~C for 1 h-our.
¦ Successivaly, 154 ml oE TiC14 tl.4 moles) were l 5 '', introduced, raising the temperature to 110C for 2 hours. The I I solid was then aecanted, removing the TiC14 solution along with ~ -the by-products therein dissolved, by siphoning at 110C. ¦
~b) Polymerization of propylene in hexane ~solvent) 0.6 ml of the suspension of ~he catalyst component in i' heptane prepared in 13 (a) were utilized under the polymeriza- ¦ ;~
tion test conditions of 1 (b).
~¦ After 4 hours, 433 g of dry polymer were obtained.
I It contained the followlng catalyst residues: Ti = 4.4 ppm;
¦ Mg = 66 ppm; Cl = 150 ppm The yield was 227,000 g of poly-¦! propylene/g of Ti; the residue of the extraction with boiling heptane was equal to 90.5~ of the total or crude polymerizate.

¦ ~a) Preparation of the catalyst component 95.3 g of anhydrous MgC12 (1 molei and 40.3 g of 1 20 I chemically pure MgO (1 mole) were introduced into a l-liter vibrating ball milI. Such mixture was co-ground for 30 hours and then discharged from the mill.
13.56 g oE the above mixture (9.53 g of MgC12 ~ 4.04 g of MgO) were reacted, in a ~50-ml flask, with a solution con-sisting of 3 g of ethyl benzoate (20 m.moles) and 9.22 g of ¦ EtO~ diluted with 100 ml of n-hexane, at a temperature of 60C
¦ for 2 hours. The solvent was evaporated from the suspension at room temperature under a sliyht vacuum (40 Torr of residual ; pressure), recoverlng at the conclusion 25.43 g of solid product ~. i ' .
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The solid product was charged into a jacketed 500-ml reactor equipped with a porcelain filtering fritted bottom, lBl ml ~1.65 moles) of TiC14 were then introduced and t}le mix-ture was brought to a temperature o 110C ~or a 2-hour contact time, whereupon the suspension was diluted with 45 ml of l heptane and the solid was separated by filtration at 110C.
The catalyst component was washed 4 times with heptane at 80C
and 3 times at room temperature (employing 200 ml of heptane each time).

~ (b) Polymerization of propyl ne in he~ane (solvent) 0.6 ml of the suspension of the catalyst component prepared according to Example 14 (a) were employed under the polymerization test conditions described in 1 (b).
After a 2.5-hour poly~erization, 432 g of dry polymer 1l were obtained. It contained the following catalyst residues:
, Ti = 4.5 ppm; Mg = 25 ppm; Cl = 105 ppm. The yield was 222,000 g of polypropylene/g of Ti. The solid residue of the ~1`
I extraction with boiling heptane was equal to 89~ of the total , (or crude) polymerizate.
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~l ~ XAMPLE 15 (a) Preparation of the catalyst component Synthetic hydrotalcite of formula Mg6A12CO3(OH)16.411~0 (produced by Kyowa Kasei Ind. Co. L-td.) was used as starting I -l material and was calcined in a dry air atmosphere at 450C for ;1 25 , 24 hours.
11.5 g of the product (6MyO.A12O3), obtained by the ¦

¦I calcination of the hydrotalcite, were weighed and suspended in ¦¦ a solution consisting of 4.2 g of ethyl ben~oate ~28 m.moles) and 12.9 g of EtOH diluted with 5Q ml of heptane. The :~'' . . '~

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37~3 . ' suspension, contained in a jacketed 500-ml reactor equipped with a filtering fritted bottom, was heated to 60C for 2 hours, :.
whereupon 181 ml tl.65 moles) of TiC14 were introduced into the reactor at constant temperature. The temperature was then S ¦ rapidly raised to 110C with simultaneous feeding of gaseous ¦ HCl, directly into the reaction mixture, at a rate of 1 mole/
¦ hour for 2 hours. .: :
-I ¦ After stopping the feeding of HCl, the mixture was diluted by the addition thereto of 45 ml of heptane, whereupon .
Ij it was filtered at 110C, separating the solid component from ~ 1I the products soluble in TiC14.
: ~ A-fter diluting the reaction mix-ture with 45 ml of : . heptane, it was filtered again at 110C, separating the solid from the excess of TiC14. The catalyst component was washed with heptane ~200 ml each treatment) 4 times at 80C and 3 ~:
. times at room temperature, to remove all traces of free TiC14.

. ~ (b) Polymerization of propylene ln hexane (solvent) .~ . :
2 ml of the suspension in heptane of the cata-lyst component prepared as described in Example 15 (a) wexe utilized under the polymerization test conditions described in . 1 ~b).
.~ AEter 4 hours, there were o~tai.ned 243 g of dry polymer which contained the following catalyst residues: .
Ti = 3 ppm; Mg = 133 ppm; Cl = 222 ppm. The yield was 77,00U g ~:~
of polypropylene/c3 of Ti. The solid residue of the extraction with boiling heptane was equal to 88% of the total (or crude) polymerizate.
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(a) Pr~paration of the catalyst component The microspheroidal complex Mgcl2.l.24 H2O 52Q-70 ~) Il was calcined at 525C for 3 hours. The resulting product 5 1~ exhi~ited the following composition: Mg = 51.35 gJ100 g;
I Cl = 17.15 g~100 g. The atomic ratio between Cl:Mg was equal to 0.229.
In a 250-ml flask, 11 g of the product obtained by calcining ~gC12.1.24 H2O were reacted at 60C for 2 hours with ' a solution consisting of 2.74 g (18.25 m.moles) of ethyl benzoate and 8.4 g (182 m.moles~ of Et~ diluted with 90 ml of hexane. After evaporation of the solvent at 20C under vacuum ¦ (40 Torr residual pressure), 21.35 g of solid product were ¦ weighed and put into a 500-ml reactor (according to Example ¦ 16 (a), where they were reacted with 167 ml (1.52 moles) of ¦ TiC14 at llODC for 2 hours. Before separating the solid from i the ~iC14 solution containing the reaction by-products in dissolved form, 42 ml of heptane were introduced, whereupon the whole was filtered at 110C. ~
(b) Polymerization of propylene in hexane (solvent) 1 1 ml of the catalyst component suspension, prepared according to Example 16 (a), was utilized under the -test con-ditions described in 1 (b).
~fter 4 hours, 336 g of dry polymer were obtained.
It contained the following residual cornponents of the catalyst:
- Ti = 4.3 ppm; Mg = 62 ppm; Cl = 122 ppm, the yield being 232,000 g of polypropylene/g of Ti, and the residue of the extraction with boiling heptane being 90.5~ of the total (or crude) polymeri~ate.
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¦ The polymer was furthex characterized by the I following properties:
I intrinsic Viscosity 2.1 dl~g ~;
`; I melt-flow index 3.7 g/10' ~ 1.
! flexural rigidity 12~930 kg/cm2 I apparent density 0.38 kg/l.
~ . .
F.X~MPLE 17 (a) Preparation of the catalyst component ' The starting material was 57.7 g of a complex ;
~1 lo 1! MgC12-1.24 H2O which~ after being put into a fluid bea reac-tor j with a 200 l/h nitrogen flow (linear velocity = 4.4 cm/sec.~ ¦ ;
humidified at 20C, was heated to 220C for 6.5 hours, to 270C
for 1 hour, and to 270C with dry nitrogen for another hour.
; 36.3 g of a product were recovered that, subjected to chemical !-~ 15 l analysis, exhibited the following~ composition: Mg - 28.85 g/100 ~ ~ I g; Cl = 48.05 g/100 g;~ OH = 23.25 g~l00 g. 30 g of this ;, '' I product were co-ground~for 60 hours with 33.6 g (353 m.moles) ¦ of anhyarous MgC12 ~n a vibrating'ball mill having a capacity ~ I
of 1 liter.
17.3 g of the;mixture~(MgC12 ~ MgCIOH) obtained after the cogrinding were introduced into a 250-ml flask and trea-ted with a solution consisting of 6 g (40 m.moles) of ethyl benzoate and 9.2 g (200 m.moles) of EtOH diluted with 100 ml of n-hexane, at a temperature of 60C for 2 hours. The solvent ~ 25 ,, was then evaporated at 25C under vacuum, at a residual pressure ¦~ I of 40 Torr.
32 g of a solid product were recovered and introduced into a 500-ml reactor equipped with a filtering fritted bottom; ~ ' 164 ml of TiC14 were then rapidly dropped in and the suspension '' I . , '~1 . , , ~ ~
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~37~8 :~ was brought to a temperature of 110C for 2 hours, under stlrr-lnq.
Successlvely, the mixture was diluted wlth 41 ml of heptane and filtered at 110 C. The solid was suspended with 41 ~:
ml of heptane and filtered. The resultlng solid was then washed with heptane at 80 C 4 times (150 ml each time) and at room tem-perature 3 times. .
(b) Polymerization of the product ln solvent 0.75 ml of the suspenslon in heptane of the catalyst IO component prepared in 17 (a), was used under the polymerlzatlon test conditions described in 1 ~b), wlth the exception that the temperature was raised to 70 C.
After a 4-hour polymeri~ation, there were obtalned 298 g of dry polymer that contained the following catalyst re- :-sidual components: Tl = 5.5 ppm; Mg = 43 ppm; Cl = 185 ppm. ~:.
The yield was 181,500 g of polypropylene/g of Ti, and ~ the residue of the extraction with boillng heptane was equal .
: to 93.5~ by ght oE the tot-I (or crude~ poIymeri~ate.

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Claims

THE EMBODIMENTS OF THE INVENTION IN WHICH AN EXCLUSIVE
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:

1. Components for catalysts for polymerizing olefins comprising the product of the reaction between at least the following substances (a) a halogenated Ti compound selected from Ti tetrahalides and Ti haloalcoholates;
(b) a solid support comprising the following essential components or mixtures thereof:
component (b1) containing (A) an oxygenated Mg compound selected from the group consisting of MgO, mixed oxide of Mg, Al and/or Si, Mg hydroxide Mg hydrocychloride or bromide, Mg nitrate, Mg phosphates, Mg silicates, Mg carboxylates and the product obtained from the dehydration, under hydrolysis conditions, of hydrated My halides, and (B) an adduct between a Mg dihalide and at least one hydrocarbyl electron-donor compound or the product of the decomposition of said adduct to Mg dihalide; or component (b2) obtained by reacting an oxygenate Mg compound as defined in (A) with a hydrocarbyl electron-donor compound free from active hydrogen atoms (ED) or with a mixture thereof with an electron-donor compound containing active hydrogen atoms (HED);
the reaction system also comprising a compound ED, at least when said compound ED or derivatives thereof is not used in preparing support (b), the amount of compound ED present in the catalyst component, in a form not extractable with TiCl4 at 80°C, being in the range of from 0.05 to 5 moles per mole of Ti compound existing after the treatment at 80°C.

2. A catalyst component according to claim 1, in which the adduct existing in support (b1) contains compound HED and/or ED each in amounts of at least 0.1 mole per mole of Mg dihalide, the molar ratio between the Mg oxygenated compound and the Mg dihalide both combined and being comprised between 0.05:1 and 20:1.

3. A catalyst component according to claim 1, in which product (b2) contains compound ED or mixtures thereof with HED
in amounts ranging from 0.1 to 5 moles of ED and from 0.1 to 5 moles of HED.

4. A catalyst component according to claim 1, in which less than 50% of the Ti compound is soluble in TiCl4 at 80°C.

5. A catalyst component according to claim 1, in which less than 50% of the Ti compound is soluble in TiCl4 at 135°C.

6. A catalyst component according to claim 1, in which support (b1) is prepared by halogenating an oxygenated Mg com-pound of (b1), and by reacting the Mg dihalide with a compound HED and/or ED, either simultaneously with the halogenation or successively.

7. A catalyst component according to claim 1, in which support (b1) is prepared by dehydration, under hydrolysis con-ditions, of Mg hydrated dihalides and by reaction of the Mg di-halide with compound HED and/or ED.

3. A catalyst component according to claim 7, in which the Mg hydrated halide is MgCl2.nH2O, wherein is comprised between 0.5 and 6, and the dehydration is effected by heating the Mg hydrated halide to a temperature ranging from 350° to 500°C.

9. A catalyst component according to claim 8, in which the dehydration is effected by heating the Mg hydrated halide to a temperature ranging from 350° to 450°C.

10. A catalyst component according to claim 1, in which support (b1) is prepared by mixing the oxygenated Mg compound with the adduct of (b1).

11. A catalyst component according to claim 1, in which support (b1) is prepared by reacting the Mg dihalide with compound HED and/or ED in the presence of the oxygenated Mg compound.

12. A catalyst component according to claim 1, in which compound ED is reacted, in either combined or uncombined form, with a pre-formed support (b1).

13. A catalyst component according to claim 1, in which the Ti compound is TiCl4.

14. Catalysts for polymerizing alpha-olefins containing at least three carbon atoms, comprising the product obtained by mixing the following components:
(a) an organometallic Al compound selected from the Al-alkyl compounds;
(b) a catalyst component according to claim 1.

15. A catalyst according to claim 14, in which the catalyst-component (a) is an Al-trialkyl or mixtures thereof with an Al-dialkyl halide complexed for 20-100% with an electron-donor compound selected from the esters of the aromatic acids.

16. A catalyst according to claim 14, in which the Al/Ti ratio is comprised between 1 and 1,000.

17. A catalyst according to claim 15, in which the Al/Ti ratio is comprised between 1 and 1,000.

18. A process for (co)polymerizing olefins CH2 = CHR, in which R is an alkyl or aryl radical having 1 to 8 C, and mixtures of said olefins with ethylene in which the (co)polymerization is carried out in the presence of a catalyst according to claim 14.