DE1183245B - Process for the production of polyolefins with a uniform degree of polymerization - Google Patents

Description

Process for the production of polyolefins with a uniform degree of polymerization The low-pressure polymerization process gives polymerizable olefins with the help of mixed catalysts made from organometallic compounds of the metals the I. to III. Group of the periodic table on the one hand and compounds of the IV. To VI. and the VIII. Subgroup of the Periodic System on the other hand, appropriate in the presence of inert diluents, at moderate temperatures and pressures high molecular weight polyolefins. The technical properties and thus the possible uses these low-pressure polyolefins largely depend on the degree of polymerization. The The degree of polymerization can also be determined by the type and amount of the catalyst components by certain known measures in the preparation of the mixed catalysts as well change through the polymerization conditions. All of these known means of However, changes in the degree of polymerization affect the low-pressure polymerization still in another direction. The rate of polymerization changes in each case, Space-time yield, yield based on the catalyst, etc.

In addition to the average degree of polymerization, the molecular weight distribution can also be used of decisive importance for the properties and thus for the possible applications of the polymers obtained. The molecular weight distribution changes in generally relatively strong in the course of the polymerization, as the catalysts change their properties over time.

Attempts have already been made to obtain polymers with a uniform degree of polymerization by allowing the mixed catalysts to mature for a while at elevated temperatures before the actual polymerization, but even in this way no satisfactory uniform products are obtained. The ratio of the weight average molecular weight Mw (determined e.g. from light scattering) and the number average molecular weight Mn (determined from osmatic pressure), reduced by 1, is the measure of the unevenness U naturalized. The unevenness of the polymers produced by known processes is consistently greater than 4.

It has been found that polymers with a uniform degree of polymerization are obtained by low pressure polymerization of gaseous olefins, which is 50 to 90 percent by volume contained in mixtures with inert gases and in the course of the polymerization are increasingly diluted with inert gases, in the presence of mixed catalysts from organometallic compounds of metals from I. to III. Periodic group Systems on the one hand and compounds of metals from IV. To VI. and the VIII. subgroup of the periodic table on the other hand, especially in the presence of diluents, can be advantageously produced if the gaseous feed to the polymerization batch is used Olefin in the course of the polymerization to an increasing extent with inert gases to 15 diluted to 40 percent by volume olefin, the olefin concentration being less than is reduced by half.

Suitable polymerizable olefins for the process are ethylene and other olefins such as propylene and α-butylene. Suitable mixed catalysts are obtained for example from compounds of titanium, especially halides, such as titanium tetrachloride, Titanium trichloride, titanium tetrabromide, titanium tribromide, titanium tetraiodide and titanium triiodide as well as titanium compounds in which some of the halogen atoms are replaced by alkoxy groups is replaced, e.g. B.

Monochlorine, dichloro, monofluorine, difluorine, monoiodine, diiodine and in particular monobromo- and dibromorthotitanic acid esters, the alcohol component of which is from lower aliphatic alcohols such as methyl alcohol, ethyl alcohol, n- and iso-butyl alcohol, 2-ethylhexyl alcohol, isopropyl alcohol or from cyclohexyl alcohol, benzyl alcohol or is formed by phenols, on the one hand and organoaluminum compounds on the other hand.

Examples of organometallic compounds of aluminum are the following in question: Aluminum trialkyls, aluminum triaryls and aluminum triaralkyls, such as aluminum trimethyl, aluminum triethyl, aluminum triisobutyl, aluminum triphenyl, Aluminum triethylphenyl and mixtures thereof, also dialkylaluminum monohalides, Diaryl aluminum monohalides and diaralkyl aluminum monohalides, e.g. B. diethyl aluminum monochloride, Diphenyl aluminum monochloride, diethylphenyl aluminum monochloride, diethyl aluminum monochloride, Diethylaluminum bromide, finally also the monoalkylaluminum dihalides, monoarylaluminum dihalides, z. B. monoethyl aluminum dichloride, monoethyl aluminum dibromide. Besides are also Dialkyl aluminum hydrides, e.g. B. diethyl aluminum monohydride, diisobutyl aluminum monohydride, suitable. The alkyl aluminum sesquichlorides are used with particular advantage designated reaction mixtures of metallic aluminum with alkyl chlorides.

The mixed catalysts are brought together in a manner known per se of the components, expediently in inert diluents. Possibly the precipitate that forms when the components are brought together can be separated, washed with fresh diluents and then reactivated. Farther In many cases it is advantageous to use the mixed catalysts before the polymerization to mature and / or to be mixed with small amounts of a polymerizable olefin.

The polymerization takes place in a manner known per se, for the purpose in the presence of inert diluents, e.g. B. under the polymerization conditions liquid hydrocarbons and hydrocarbon mixtures such as butane, pentane, Hexane, isopropylcyclohexane, gasoline fractions, benzene, toluene, at temperatures between - 20 and 2000 C and with normal or slightly increased pressure up to 20 at.

The dilution of the gaseous olefins in the course of the polymerization takes place with inert gases such as nitrogen, noble gases, gaseous hydrocarbons, like methane and ethane, and finally with those used in polymerization liquid diluents in vapor form, insofar as they are subject to the polymerization conditions are sufficiently volatile, such as butane, pentane and hexane. The degree of dilution depends largely by nature - d. H. of the components and also of the pretreatment - The mixed catalysts used, since the dilution of the olefins makes the change compensate for the properties of the mixed catalysts in the course of the polymerization target. The easiest way to determine the dilution is through a simple preliminary test. The olefin content of the gas mixture to be polymerized drops from an initial 50 to 90 percent by volume in the course of the polymerization to 15 to 40 percent by volume, with the olefin concentration is reduced to less than half. If you have mixed catalysts used for polymerization immediately after the components have been combined, It may be necessary or at least appropriate to increase the dilution initially to increase and to increase only slowly towards the end of the polymerization. If, on the other hand, one assumes mixed catalysts that had time before the polymerization To ripen at elevated temperatures, the dilution can mostly from onfang to be increased linearly towards the end of the polymerization.

It is possible to dilute the olefin by running and increasing To effect admixture of the above gases. In most cases, however, it will be simpler and more useful, from an olefin with a constant inert gas content go out and the residual gas leaving the polymerization, which the total amount of Inert gas components and also parts of the olefin and evaporated diluent contains to lead in the cycle. If the inert gas content of the starting olefin is too high, it can be more advantageous to recirculate only part of the residual gas and to use to dilute the olfin. This way of working also comes from the desire opposed to carrying out the polymerization at the highest possible speed and to fully utilize the activity of the mixed catalyst, since the olefin is then can apply in excess.

If volatile diluents such as butane, Pentane, hexane, can be used, which leads to the dissipation of the heat of polymerization Evaporative cooling often happens, so one becomes the vaporous diluent from the residual gas before circulation through condensation in a cooling system need to remove. If one starts in this case from a relatively pure olefin with degrees of purity of more than 95 percent by volume, you can use the dilution possibly also effect by changing the temperature of the cooling system in the course the polymerization increases and thereby the amount of vaporous diluents can increase in the cycle gas. A lowering of the pressure has the same effect, under which the polymerization system stands.

Due to an increasing dilution of the The gaseous olefins used make it possible to uniformize valuable polyolefins Degree of polymerization whose unevenness U is less than 4 to be obtained. Goes if one starts from alefine, such as propylene, the isotactic one increases at the same time Proportion of.

Example 1 725 g of diethylaluminum monochloride are dissolved in 17 l of hexane dissolved and treated with a solution of 1138 g of titanium tetrachloride in 2.5 l of hexane. After a maturing time of 15 to 30 minutes at 370 ° C., the mixture is diluted with 300 liters of hexane and then Ethylene with an inert gas content of 4 ovo (ethane, methane) at one rate initiated by 40 Nm3 / h. After 1/4 hour, when the temperature of the polymerization batch has risen to 700 ° C., the process according to the invention begins. It will be a Liquid ring pump switched on, which the unreacted ethylene with higher Inert gas level and evaporated hexane via a cooling system in which the evaporated Hexane is condensed again, returned to the kettle. At the same time, the Amount of the gassed ethylene decreased so that after 5 hours a suspension of 20 is reached. In this way, the ethylene content in the cycle gas is reduced from 70 to 80 percent by volume at the beginning to 20 to 30 percent by volume at the end of the polymerization. The reduced viscosity of the polyethylene obtained when using a pure ethylene during the polymerization rises sharply, remains constant and is 1.7 over the entire polymerization time. The product obtained has an unevenness U = 2.8, while it is otherwise greater than 5. The mechanical The values of polyethylene improve accordingly.

Example 2 The polymerization conditions of Example 1 are used modified by converting from pure ethylene with an ethylene content greater than 99.5 0 / o goes out and the dilution from initially 90% ethylene to 40% at the end of the Polymerization is effected by vaporous hexane by changing the temperature of the cooling system Increased from 20 to 400 C in the course of the polymerization. Polyethylene is obtained with a constant reduced viscosity flred = 1.6 and with an unevenness U = 3.

Example 3 The polymerization is carried out under the conditions of the example 2, but keeps the temperature of the cooling system constant at 200 C and causes the Dilution by continuously adding nitrogen to the cycle gas to such an extent that its ethylene content goes from 80 to 90 percent by volume at the beginning to 30 to 40 percent by volume lowered at the end of the polymerization, a polyethylene is obtained with the reduced one Viscosity x1, ed = 1.8 and the non-uniformity U = 2.9.

Example 4 A mixed catalyst suspension is prepared by a solution of 1430 g of dichlorothotitanic acid diisobutyl ester in 25 l of hexane with a solution of 1340 g of ethyl aluminum sesquichloride mixed, 15 minutes at 450 C is allowed to mature and then diluted with 300 liters of hexane.

980% ethylene is passed in at one rate with stirring from 40 to a. After 15 minutes, when the temperature of the polymerisation approach has risen to 700 ° C., the process according to the invention is started with circulation of the residual gas which, in addition to the total amount of nitrogen, also contains part of the ethylene as well as vaporous hexane, which in a cooling system cooled to 200 C largely Will get removed. At the same time, the ethylene supply is throttled to about 10 Nms / h, which means the olefin concentration, which is 80 to 90 percent by volume at the beginning of the circulation of gas at the end of the polymerization drops to 30 to 40 percent by volume. After 3 to 4 hours one receives a 200 / above polyethylene suspension, which in a known manner is worked up. The polyethylene has a reduced viscosity flred = 2.0 and an unevenness U = 1.

Example 5 1000 g of titanium trichloride are suspended in 201 hexane at 500 ° C. then 1500 g of aluminum triethyl are added. After a maturing time of 15 minutes grooves at 500 ° C., the mixture is diluted with 380 liters of hexane at 500 ° C. and then propylene with an inert gas content of 35 percent by volume (propane) introduced at a rate of 7Nm8 / h. Simultaneously If a fan is switched on, the unreacted propylene with a higher inert gas level and the evaporated hexane is returned to the boiler via a cooling system. In the course During the polymerization, the propylene content in the cycle gas drops from 50 to 60 Volume percent at the beginning to 15-25 volume percent at the end of the polymerization. To a polymerization time of 8 hours gives a polypropylene with a reduced Viscosity of 4.6 and an unevenness U = 3, which is especially useful for manufacturing of polypropylene dispersion is suitable.

Claims (3)

Claims: 1. Process for the production of polyolefins uniform Degree of polymerisation through low pressure polymerisation of gaseous olefins, of which 50 to 90 percent by volume are contained in mixtures with inert gases and are increasingly diluted with inert gases in the course of the polymerization, in the presence of mixed catalysts made from organometallic compounds of the metals the I. to M. Group of the Periodic Table - on the one hand and compounds of metals the IV. to VI. and the VIII subgroup of the Periodic Table on the other hand, especially in the presence of under the polymerization conditions liquid inert Diluents, characterized in that one adds to the polymerization batch supplied gaseous olefin in the course of the polymerization to an increasing extent inert gases diluted to 15 to 40 percent by volume olefin, the olefin concentration is reduced to less than half. 2. The method according to claim 1, characterized in that the gaseous Olefins through an increasing addition of inert gases in the course of the polymerization be diluted. 3. The method according to claims 1 and 2, characterized in that that the dilution of the gaseous olefins by recycling the polymerization leaving olefin-depleted but substantial amounts of volatile diluents containing residual gases after passing through a cooling zone for condensation of excess Diluent takes place, the temperature of the in the course of the polymerization The cooling zone is increased or the pressure in the polymerization device is decreased. Publications considered: Documents laid out by the Belgian Patent Nos. 538,782, 543,259, 543,941; Austrian patent specification No. 196620.