DD158785A1 - METHOD FOR SELECTIVE BUTADIA POLYMERIZATION FROM C LOW 4 FRACTIONS - Google Patents

Abstract

The invention relates to a process for the selective polymerization of 1,3-butadiene from C 4-hydrocarbon mixtures, preferably from C 4 crude fractions obtained by petroleum pyrolysis, by means of stable bifunctional lithium initiators, the polymerization of the butadiene from the mixture without prior separation the other components of the C deep 4 sections and without their incorporation into the polymer is carried out. It was found that with the help of v. Dilithium adducts of conjugated dienes prepared in methyl tert. butadiene can be selectively converted into polybutadienes and butadiene copolymers with defined molecular weights. By adding suitable agents bifunctional products can be displayed.

Description

(Title of the invention

Process for the selective butadiene polymerization from C ^ - prions

Field of application of the invention

The invention relates to an economical and rational process for the preparation of polybutadienes by means of soluble, stable Dialkalimetallorgano polymerization initiators using C ^ fractions, especially obtained in the Srdölpyrolyse undivided olefin mixtures as butadiene source, the eduction process of Butadiens << saved and butadiene, which in The G ₁ , fraction is used directly as starting material and reacts selectively to polymers having the properties of a living polymer. The other unsaturated and saturated hydrocarbons of the C 1 - fraction remain unreacted and are available for further reactions. Furthermore, the invention relates to an economical process for the preparation of butadiene polymers of the type ABA and copolymers with random Mohomeranverteilung, the copolymers have a predetermined molecular weight and a narrow molecular weight distribution. "The invention also enables the production of low molecular weight polybutadienes and Butadieneopoly-

which contain a functional group at each end of the chain and which have a predetermined molecular weight at a narrow molecular weight distribution (telechelic polymers), using butadiene-containing C 1 - C fractions.

Characteristic of the known technical solutions

It is known from German Offenlegungsschrift No. 2,431,258 that polybutadienes are prepared by solution polymerization by means of organolithium polymerization initiators of the general formula H-Li (H.sub.s alkyl, aryl), .dbd.b, n-butyllithium, using a butadiene-containing G.sub.2 stream, obtained in the cracking of petroleum and / or by the dehydrogenation of a butane feed. "To obtain high 1,2-3-structure fractions in the polybutadiene, polar compounds are added as slektrone donors to the polymerization system before or during the polymerization.

The combination of the organolithium compound with © iner polar compound according to this DE-OS also gives a catalyst species which reacts less with the other constituents of the Од stream, in particular with the Cc hydrocarbons present as impurity, and consequently is deactivated to a lesser extent than this otherwise it is. This has the advantage that a smaller amount of organolithium compound must be used.

However, it can be seen from the examples of DE-OS 2,431,258 that up to 65% of the lithium organo compound used is still needed to trap impurities and that the butadiene conversion is only about 60 %

 The use of a monolithium compound as a poly

The polymerization initiator also has the disadvantage that no polymers can be prepared which contain a functional group at each end of the chain. The resulting polymers can be functionalized only at one end of the chain.

Furthermore, the synthesis of block opopolymers of iüyps A-B-A by means of initiators of the general formula B-Li is problematic ·

The .Fachmann is known that such polymers in the Hegel can be represented by anionic polymerization with bifunctional, usually Dilithimnorganoverbindungen in stoichiometrically controllable abstraction using pure butadiene as a monomer (Faserforschung and Textiltechnik 25 (1974) 5, 3. 1911 US-PS. 3 135 71bϊ DE-OS 2 425 924 \ SU-PS 296 775). In various patents (DS-PS 1 169 674, DS-AS 1 170 645, JDD- ¹ AP 99 170) are the Dilithiumaddukte of conjugated dienes, in particular of 1,3-butadiene, isoprene and 2,3-dimethylbutadiene containing 1-7 diene units are highlighted as particularly suitable initiators

To form these alkali metal alladducts, it is absolutely necessary to use an ether as the reaction medium, since they can not be prepared in low-dielectric-constant solvents (US Pat. No. 2,816,936).

When polymerizations are carried out with such ether-containing initiator solutions, it is very easy to reduce the initiator and polymer activity as a result of ether cleavage. Known processes therefore provide complete or partial replacement of the ether by a non-polar solvent before the polymerization reaction (US Pat 404, 3,388,178, DE-A3 1 768 188,

DB-OS 1 817 479) "because in the polymerization of pure 1,3- * butadiene in hydrocarbons even in the presence of small amounts of polar solvents with a corresponding Heinheit Beaktanten side reactions are unlikely to be expected. However, the conditions required to remove the ether often already result in partial deactivation of the initiator and increased operating costs.

Object of the invention

The aim of the invention is to produce polybutadienes, butadiene copolymers and telechelic butadiene homopolymers or copolymers without the disadvantages of the known processes using G ^ fractions as butadiene source, as they occur in particular in the Srdölpyrolyse, economically with short polymerization times ·

By adding other anionically polymerizable monomers to the CL fraction, butadiene block copolymers of type ABA or butadiene polymers with random monomer distribution should also be presentable. The telechelic butadiene homopolymers and copolymers should have a functionality of approximately 2. The molar mass of the polymers should be adjustable in the desired range ,

Explanation of the essence of the invention

The invention has for its object to develop a process for the selective polymerization of 1,3-butadiene from O ₁ , fractions using special bifunctional alkali metal initiators, which meets the above requirements.

The object is achieved in that 1,3-butadiene from a butadiene-containing C ^ -fraction with the aid of dilithium adducts of conjugated dienes, in particular 1,3-butadiene or isoprene containing 1 to 6 monomer units and tert in methyl tert. butyl ether, is converted into living Butadienhomo- or copolymers. The polymerization can be carried out in a manner known per se. Ea is; a polymerization in the Ob fraction without additional solvent or depending on the concentration of butadiene in the C ^ fraction in solution with the addition of nonpolar solvents, eg. B _e benzene, toluene, η-hexane, n-heptane, cyclohexane or benzine fractions, possible · It is preferable to use the polymerization medium without the addition of a nonpolar solvent, the non-polymerizable components of the C 1 -C fraction acting as diluent.

Suitable comonomers for a copolymerization are all anionically polymerizable monomers, such as isoprene, acrylonitrile, otyrene, alpha-methylstyrene or methyl methacrylate, as an additive to C 1 -C 4 -i

The polymerization can be carried out at temperatures of 198 to 423 K, preferably at 263 to 373 K at atmospheric pressure or at elevated pressure. »

The polymerization times in the Hegel are 1-3 hours *

The amount of initiator to be used is determined by the desired molecular weight of the polymers, since it is a stoichiometric polymerization · According to the invention, homo- and copolymers with very high molecular weight, z. B · 200,000 »as well as very low molecular weight, e.g. 1000 to 10 000, are produced.

The microstructure of the polybutadienes can be controlled by the addition of tert amines · ·! Triethylamine causes only a slight decrease of the 1,4-structure proportion, while an addition of N, N, U *, N ^f tetramethylethylenediamine polybutadienes containing predominantly 1,2 Structure provides ·

The active ingredients of the resulting living polymers can be functionalized in a known manner with electrophilic end-capping agents such as COg, alkylene oxides, epichlorohydrin or gamma-butyrolactone, so that very advantageous telechelic polymers can be prepared.

During the polymerization reaction, no termination reactions occur, so that after functionalization of the active polymers, high-functionality telechelic polymers are obtained.

The products produced by the process according to the invention have the same properties as the polymers obtained using pure butadiene. The process according to the invention thus offers a convenient process

and cheap method for producing polybutadienes and butadiene copolymers with and without functional end groups without the need for an expensive butadiene extraction stage «

The method is further characterized by the fact that a homogeneous anionic polymerization in the absence of highly polar solvent is possible · ether cleavage and the associated reduction of the initiator and polymer activity does not occur, since the used for InitiatorSynthese methyl tert, butyl ether to Bithiumorganoverbindungen is inert ,

The examples given are intended to illustrate the process according to the invention without restricting it in any way.

- 8 Example 1:

79.5 mmol (= s 1104 mg of active lithium) of a Jjilithiumaaduktes of butadiene, dissolved in 290 ml of methyl tert. Butyl ether is continuously in 313 & within 2 hours in a glass autoclave with 393 g of a C ^ -Ji'raktion containing 153 g of 1,3-butadiene-1,3. The mixture is then stirred for a further 1 hr and then the polymerization is stopped with a mixture of 13.7 g of gamma-butyrolactone and 7 S ethylene oxide. The unreacted C ^ -hydrocarbons are removed by means of vacuum and the Polybutadienalkoholat formed hydrolyzed with 50 ml of water. The aqueous solution is separated and the organic phase with 1 liew, % 2,6-di-tert-butyl-p-cresol, based on the amount of ßutadien used, stabilized. The drying of a product is carried out in an ITacuum rotary evaporator at 323 £.

A liquid, hydroxyl-terminated polybutadiene having an average molar mass of 2750 and a hydroxyl content of 1.133 % is obtained in 1% yield . The functionality is 1.85. The polymer has a microstructure of 50 mol% of 1.2 and 50 mol%. % 1.4 units on.

Example 2:

To 177 mmol Dilithiumaddukt of butadiene, dissolved in 472 ml of methyl-tert-butyl ether, within 2 hours 643.5 g of a C ^ -Fraction containing 30 wt .-% butadiene, continuously at 283 K in a Glasautokiaven dosed, Hach terminated polymerization

- Q -

Add 83 »25 S of ethylene oxide to the homogeneous solution * Work up as in the example

This gives 193 S of a liquid polybutadiene with OH end groups, which corresponds to a butadiene conversion of 100 % . The average molecular weight, determined by steam pressure osmosis in benzene at 303 K, is 2000. The polymer has a microstructure of 46 mol% of 1.4 and 54 mol% of 1,2-structural components. The functionality is 1.66, which corresponds to an OH content of 1.4%.

Claims (2)

Claim for invention 1. "A process for the selective butadiene polymerization of C ^ fractions to homopolymers or copolymers which optionally contain functional groups and have a pre-selected molecular weight in the range of 1000 to 250,000, in the presence of alkali metal initiators, preferably lithium initiators, and optionally at Presence of anionically polymerizable α-comonomers, preferably of acrylonitrile, styrene, α-methylstyrene, isoprene or methyl methacrylate, characterized in that the polymerization in the presence of dilithium adducts of conjugated, optionally substituted dienes, the 1 to 6 monomer units per molecule and 1 or 2 methyl groups as Substituents contained in the diene molecule, and which are prepared in methyl tert-butyl ether, is carried out, wherein the polymerization in the absence of a solvent, under pressure and at a temperature at which the σ ^ -Fraction is in the liquid phase, preferably in the temperature range v on 263 to 373 2, takes place. Method according to item 1, characterized in that a solution of a dilithium adduct of conjugated diene containing 4 to 12 carbon atoms in the molecule, preferably butadiene-1,3-isoprene or 2,3-dimethyl-1,3-butadiene, im Methyl butyl ether is used.