DD262028A1 - METHOD FOR PRODUCING OXIDATED STABILIZED HYDROCARBON RESINS BASED ON CYCLOPENTADIA - Google Patents

Abstract

The invention relates to a process for the preparation of copolymers and terpolymers of cyclopentadiene, an unsaturated aromatic hydrocarbon, such as styrene, indene or their alkyl derivatives and isobutene or butene oligomers by cationic polymerization. Such polymers are distinguished from polycyclopentadiene by a sufficiently good oxidation stability if the CPD content in the polymer does not exceed that of the aromatic component. The choice of monomers, monomer concentration ratio, and reaction conditions can be used to vary the double bond content, molecular weight, and softening point so that these products can be used in a variety of typical hydrocarbon reactive resin applications, such as paint and coatings, adhesives, and coatings. and are useful in the preparation of polymeric compositions.

Description

Field of application of the invention

The invention relates to a process for the preparation of oxidation-stabilized reactive hydrocarbon resins based on cyclopentadiene, unsaturated aromatic hydrocarbons and isobutene or butene oligomers. Due to the sufficiently good oxidation stability, the adjustability of the double bond content and the softening point, these reactive hydrocarbon resins are useful with and without modification in a variety of typical applications, such as in the paint and coatings industry, in the adhesive or coating sector, as well as in the production of polymeric compositions.

Characteristic of the known state of the art

Processes for the preparation of hydrocarbon resins based on unsaturated aromatic hydrocarbons (preferably styrene and α-methylstyrene) and isobutene or butene oligomers are already known. Thus, DE-OS 2361055 and DE-OS 2361054 describe a process for the preparation of "water-light" styrene copolymers in which trimethylpent-1-ene or diisobutene mixtures or Cs-olefins act as co-components (BF ₃ , BF ₃ adducts, AICI ₃ , AIBr ₃ , SnCU, TiCl ₄ ) are the molecular weight in the limits of 250 to 3000g · moT ¹ and thus the softening points and the hardness of the resins varied.

The advantages of such resins lie in their low color, in the thermoplastic behavior and in the favorable availability of the raw materials, the disadvantage in the limited possibility of extending the range of application of the polymers chemical modification.

By incorporating double bonds into the polymer by the addition of dienes, trienes and cyclodienes to the monomer mixture, this disadvantage can be overcome. In this case, preference is given to using 1,3-butadiene (GB 1476551, DE-OS 2519084) and β-pinene (DE-OS 2558016, CH 619242) in the vinylaromatic / aliphatic olefin / diene (predominantly styrene / isobutene / diene) system.

In contrast, cyclopentadiene (CPD), as a comonomer for the production of highly unsaturated polymers due to the known high susceptibility to oxidation of the polycyclopentadiene produced by cationic means, has hitherto scarcely been used.

As a rule, it is converted into its dimer by thermal treatment and polymerized as a pure component or as the main constituent of technical fractions with FRIEDEL-CRAFTS catalysts. DD-WP 218106 describes copolymers of dicyclopentadiene (DCPD) with styrene and α-methylstyrene and DE-OS 2522080 with C ₈ olefins, the resins produced by the latter patent being hydrogenated by their good solubility in hydrocarbons and excellent adhesive properties.

In addition, cyclopentadiene and di-, tri- and tetracyclopentadiene, but preferably dicyclopentadiene, alone or in combination with codimers from CPD and serve the C ₅ fraction, with styrene (DE-OS 2163525, DE-OS 2345014) or eg vinyl or isopropenylphenol -Derivaten (DE-OS 3006001) thermally polymerized partially in the presence of free-radical initiators at temperatures of 470 to 620K. The thermal copolymers with styrene are described as largely stable to oxidation (DE-OS 2163525).

A reduction in the susceptibility to oxidation of incorporated CPD units is also achieved by cationic copolymerization with α-methylstyrene (DD-WP 206155).

Object of the invention

The aim of the invention is the synthesis of unsaturated modifiable copolymers and terpolymers with adjustable molecular weights, softening points and double bond contents from the available and not sufficiently materially used cyclopendadiene, unsaturated aromatic hydrocarbons, such as styrene and indene and isobutene or Butenoligomerisaten, which is suitable for Characterize CPD polymers by an extremely high oxidation stability and can be used in the dyeing and paint industry, as well as in the adhesive or coating sector and can be represented by a rational, energetic and inexpensive apparatus inexpensive process.

Explanation of the essence of the invention ',

Cyclopentadiene can be isolated in sufficient quantity and purity by thermal treatment by a retro-DIELS-ALDER reaction from DCPD or DCPD concentrates. Unsaturated aromatic olefins are either as pure components, such as the industrially important styrene, which is obtained by catalytic dehydrogenation of ethylbenzene, or as main constituents of fractions, such as. For example, indene, which is present together with coumarone, a likewise cationically polymerizable monomers, in about 433 to 458 K boiling tar fraction available. Butene oligomers can be obtained by known methods from butene fractions.

The object of the invention is to develop a process for the production of oxidation-stabilized copolymers and terpolymers of cyclopentadiene, styrene and / or indene or their alkyl derivatives and isobutene or. Butene oligomerizates with adjustable molecular weights, softening points and double bond contents.

The object is achieved in that the monomer combinations are subjected by means of metal halide LEWIS acids of a cationic polymerization.

As initiator systems alkylaluminum halides are used in conjunction with coinitiators such as water, alcohols or alkyl halides, preferably tert-butyl chloride, or metal halide-LEWIS acids, such as. 8. AICI ₃ , AIBr ₃ , TiCU, BF ₃ · OEt ₂ or other BF ₃ adducts, in conjunction with water that is already present or added as residual water in the polymerization system. The use of the alkylaluminum halides R ₂ AICI, R ₃ Al ₂ Cl ₃ and RAICI ₂ with R = C _n H _2n +, (n = 1-4, preferably η = 2) is not only because of the good solubility and high catalytic activity , but also because of the easy separability of the aluminum residues.

Initiator concentrations of from 0.5 to 5 mol% (based on the monomer concentration) are used in the process according to the invention, with the initiator concentration required to achieve a specific yield being dependent on the composition and purity of the comonomer mixture and the polymerization conditions. High isobutene or butene oligomerizate shares require high initiator concentration. The ratio of initiator to Coinitiatorkonzentration is particularly variable when using alkyl halides as non-protic co-initiators within a wide range.

In the process according to the invention, cyclopentadiene is used, which is obtained from DCPD or from a low-cost isoprene-free DCPD fraction having a DCPD content of 60 mol% by a retro-DIELS-ALDER reaction. As unsaturated aromatic hydrocarbons, styrene, vinyltoluene, indene and its alkylated derivatives, which are used either as pure substances or as constituents of corresponding pyrolysis-treated petroleum fractions, but especially styrene and indene, can be used. As termonomers find isobutene or Butenoligomerisate, preferably diisobutene (2,4,4-trimethylpent-i-ene, 2,4,4-trimethylpent-2-ene) rich C ₈ -Olefingemische which by known methods from isobutene or the butadiene-free C ₄ -fraction are synthesized, application. Since isobutene or Butenoligomerisate in the presence of metal halide LEWIS acids undergo various oligomerization, cleavage and isomerization reactions, higher, ie Ci ₂ - or C-ie-lsoolefingemische can also be used under suitable reaction conditions and a corresponding reaction.

In the process according to the invention inert solvents are used, for. As aromatic, aliphatic or cycloaliphatic hydrocarbons, but preferably chlorinated hydrocarbons having 1 to 2 carbon atoms.

Monomers and solvents must not contain the initiator deactivating impurities in excessively high concentrations, i. H. they must be cleaned or dried as needed. An inert working method is recommended, but not required.

The polymerization temperatures are according to the invention 200-330 K, but preferably between 250 and 310K and the total monomer concentration of between 1.0 and 5,0mol · I ^'1. At high polymerization temperatures, high initiator and Gesamtmonomerkonzentrationen, especially CPD-high portion and a low Content of alone non-polymerizable isoolefins there is a risk of deterioration of the product properties, in particular it can lead to dyeing of the polymers and gelation.

The monomer concentration ratio of cyclopentadiene, as a reactive monomer to the comonomer styrene or indene or to the comonomers should be 40:60 to 5:95, but preferably 35:65 to 20:80, the ratio of styrene or indene to isobutene or Butene oligomerizate on the other hand 50:50 to 100: 0 (CPD / styrene or CPD / inden copolymers).

The polymerization is carried out according to the invention by initially introducing the initiator with a portion of the solvent and dropping the monomer mixture, the remainder of the solvent and the coinitiator, to the extent that it is soluble in the monomer mixture, after the polymerization temperature has reached eiriregulation. In particular, when using a higher isobutene or Butenoligomerisates it is advantageous to submit this completely or partially with, since it is not only polymerizable on the one hand alone and on the other hand by reaction with the LEWIS acid lower Oligomiere can be formed. The rate of addition of the monomer mixture must be adjusted to avoid greater temperature differences and to ensure that a uniform polymer is formed throughout the polymerization.

After the intended polymerization time, the reaction is stopped with a mixture of methanol / aqueous ammonia solution (1: 1). The initiator residues precipitated as hydroxides are filtered off and the polymer is precipitated 5 to 8 times the volume of methanol. Solvents and residual monomers can also be removed by vacuum or steam distillation. The polymer is then dried in a vacuum drying oven at 290 to 320 K to Gewichtskonstan2.

The precipitated polymers have molar masses of 950 to 5 500 g · mol ¹ and softening points of 340 to 470 K. According to WIJS certain ido number, which allows conclusions on the double bond content, lies between 70 and 160.

The random copolymers and terpolymers are compatible with paraffins and other hydrocarbon resins. They are distinguished from cationically prepared polycyclopentadiene by a very good oxidation stability, which can be found in particular in polymers with high aromatic content (Figure 1), and are soluble in technical solvents even after storage for several months in air. By terpolymerization with isobutene and Butenoligomerisaten the molecular weights and the softening products of the polymers can be varied well. The incorporation of aliphatic constituents leads to a reduction in the brittleness and improved aliphatic solubility.

The examples given are intended to explain the process according to the invention, which can also be operated continuously.

embodiments example 1

In a temperature-controlled 150 ml Doppelwandgiasgefäß with stirrer, thermometer and dropping funnel sets the selected amount of initiator and coinitiator (30 or 15mmol · Γ ¹ ) in two-thirds of the solvent methylene chloride (48ml), tempered and drips within 30 min, a CPD / Styrene monomer mixture (1 or 2 mol · Γ ¹ ) in one third of the solvent (24 ml) in such a way that the reaction temperature does not deviate more than 2 K from the thermostat temperature. After completion of monomer addition is allowed to react for an hour at the appropriate temperature. The reaction is stopped by adding 2 to 4 ml of a mixture of methanol and an aqueous ammonia solution (1: 1) and the initiator residues are removed by filtration. Thereafter, the polymerization solution is precipitated in 5 times the volume of methanol. The copolymer is dried in a vacuum oven at 298 K to constant weight.

Examples 2-5

The polymerizations are carried out as described in Example 1, but a termonomer mixture ₍ consisting of cyclopentadiene, styrene and a butene oligomerizate is added dropwise in one third of the intended solvent.) In Application Examples 2 and 5 this mixture additionally contains the co-initiator tert-butyl chloride.

The Butenoligomerisat used, preferably consisting of C ₄ -dimers, with a boiling range of 373 to 393 K need not be further characterized. The average molecular mass is assumed to be that of diisobutene.

Examples 6 and 7

The polymerizations are carried out as described in Example 1, but a comonomer mixture consisting of cyclopentadiene and indene is added dropwise in one third of the indicated solvent (methylene chloride), which further contains the co-initiator tert-butyl chloride.

Examples 8 to 10

The polymerizations are carried out as described in Example 1, but a monomer mixture consisting of cyclopentadiene, indene and a butene oligomerisate is added dropwise in one third of the intended solvent. In Application Examples 8 and 10, the monomer mixture additionally contains the co-initiator tert-butyl chloride. The polymerization conditions and the polymer characteristics of the products obtained are summarized in Tables 1 and 2.

Claims (5)

claims: 1. A process for the preparation of oxidation-stable reactive hydrocarbon resins based on cyclopentadiene, unsaturated aromatic hydrocarbons, styrene and indene, and their alkyl derivatives and isobutene or Butenoligomerisaten, characterized in that said monomers by a cationic polymerization with metal halide-LEWIS acids in Combination with water, alcohols or alkyl halides in copolymers and terpolymers with adjustable molecular weights, softening points and double bond contents can be converted. 2. The method according to claim 1, characterized in that as initiators metal halide LEWIS acids, such as. As AICI ₃ , AIBr ₃ , TiCl ₄ , SnCl ₄ , BF ₃ · OEt ₂ and other BF ₃ adducts in combination with water, but primarily the aluminum alkyl halides AIR ₂ CI, AI ₂ R ₃ CI ₃ and AIRCI ₃ with R = C _n H _2n + 1 (n '= 1 to 4, preferably η = 2) in conjunction with water, alcohols and alkyl halides, in particular tert-butyl chloride, in concentrations of about 10 to 100 mmol · Γ ¹ or based on the Monomers 0.5 to 5 mol% can be used. 3. The method according to claim 1, characterized in that the polymerization in inert solvents, such as. As aromatic, aliphatic or cycloaliphatic hydrocarbons, but preferably in chlorinated hydrocarbons having 1 to 2 carbon atoms is performed. 4. The method according to claim 1, characterized in that the polymerization at temperature between 200 and 330K, but preferably between 250 to 310K is performed. 5. The method according to claim 1, characterized in that the cyclopentadiene to the unsaturated aromatic hydrocarbon or to the sum of the comonomers (unsaturated aromatic hydrocarbon plus isobutene or Butenoligomerisat) in a concentration ratio 40:60 to 5:95 and that the unsaturated aromatic hydrocarbon to Isobutene or Bunte oligomerizate in a concentration ratio of 50:50 to 100: 0 are used.