Synthetic resins or natural rubbers -- part of the class 520 ser – Synthetic resins – Mixing of two or more solid polymers; mixing of solid...
Reexamination Certificate
2000-06-12
2002-07-09
Lipman, Bernard (Department: 1713)
Synthetic resins or natural rubbers -- part of the class 520 ser
Synthetic resins
Mixing of two or more solid polymers; mixing of solid...
C525S332900, C525S333300, C525S339000, C525S390000, C525S437000, C525S471000, C525S472000, C525S480000, C525S534000, C525S535000, C525S536000
Reexamination Certificate
active
06417287
ABSTRACT:
The present invention provides a process for the hydrogenation of aromatic polymers, which process is characterised in that the solvent used is an ether which has no &agr;-hydrogen atom on a carbon atom adjacent to the ether function or a mixture of solvents containing this ether and solvents conventional for hydrogenation reactions.
It is already known to hydrogenate aromatic polymers. DE-AS 1 131 885 describes the hydrogenation of polystyrene in the presence of catalysts and solvents. Solvents which are mentioned in general are aliphatic and cycloaliphatic hydrocarbons, ethers, alcohols and aromatic hydrocarbons. A mixture of cyclohexane and tetrahydrofuran is stated to be preferred.
WO 96/34 896 (=U.S. Pat. No. 5,612,422) describes, for example, a process for hydrogenating aromatic polymers in which hydrogenation is performed in the presence of a metal supported on silicon dioxide as the hydrogenation catalyst, the silicon dioxide having a certain pore size distribution. Solvents which are mentioned are aliphatic or cycloaliphatic hydrocarbons. Diethylene glycol dimethyl ether and tetrahydrofuran are stated as ethers.
EP-A-322 731 describes the production of predominantly syndiotactic crystalline polymers based on vinylcyclohexane, wherein a styrene-based polymer is hydrogenated in the presence of hydrogenation catalysts and solvents. Cycloaliphatic and aromatic hydrocarbons, but not ethers, are mentioned as solvents.
None of the cited documents mentions the ethers described above as solvents. The ethers described in the above-stated documents may form peroxides in air and are solvents which are difficult to control in an industrial process. Were these ethers to be used industrially for hydrogenating aromatic polymers, complex inertisation measures would be necessary in order to keep air away from these solvents. The ethers must furthermore exhibit sufficiently high ignition temperatures since polymers generally come into contact with hot metal surfaces, possibly in the presence of air, during processing.
Pure hydrocarbons as the solvent have the disadvantage, especially in conjunction with nickel catalysts, at elevated polymer concentrations, of requiring elevated reaction temperatures (>160° C.) and elevated pressures for complete hydrogenation of polystyrene (Examples 1, 2). The temperatures are necessary in order to accelerate progress of the hydrogenation reaction to complete conversion within reasonable reaction times and this is accompanied by molecular weight degradation. This degradation is manifested by a reduction in the molecular weights Mn and Mw, in particular reduction in Mw.
For nickel catalysts in these solvents at an elevated polymer concentration, the extent of molecular weight degradation in the completely hydrogenated products is dependent, for example, on pressure and temperature. The molecular weight degradation results in a loss of mechanical properties of the hydrogenated polystyrene. The brittleness of a largely degraded material virtually completely precludes industrial use.
It has now been found that the hydrogenation of aromatic polymers is distinctly improved by using ethers which have no &agr;-hydrogen atom on a carbon atom adjacent to the ether function as the solvent or as a solvent mixture with other solvents suitable for hydrogenation reactions. The process is distinguished in that, especially at elevated polymer concentrations, no appreciable degradation of the final product occurs and no peroxide is formed. Moreover, an increase in catalyst activity is observed which is manifested by lower reaction temperatures and shorter reaction times to complete hydrogenation (Example 3). Addition of these ethers permits higher polymer/catalyst ratios for complete hydrogenation than when purely aliphatic systems are used. The reactions may be performed under identical conditions at lower pressures to achieve complete hydrogenation.
The present invention provides a process for the hydrogenation of aromatic polymers, optionally in the presence of catalysts, wherein an ether which has no &agr;-hydrogen atom on a carbon atom adjacent to the ether function, or a mixture of such ethers or a mixture of at least one of the stated ethers with solvents suitable for hydrogenation reactions is used as the solvent.
The reaction is generally performed at volume concentrations of the ether component relative to the total solvent of 0.1%-100%, preferably of 1%-60%, very particularly preferably of 5%-50%. The ether component may be described as a cocatalyst.
The process according to the invention generally results in virtually complete hydrogenation of the aromatic units. The degree of hydrogenation is usually ≧80%, preferably ≧90%, very particularly preferably ≧99%, in particular 99.5 to 100%. The degree of hydrogenation may be determined, for example, by NMR or UV spectroscopy.
The starting substances used are aromatic polymers which may be selected, for example, from polystyrene optionally substituted in the phenyl ring or on the vinyl group or copolymers thereof with monomers selected from the group of olefins, (meth)acrylates or mixtures thereof Further suitable polymers are aromatic polyethers, in particular polyphenylene oxide, aromatic polycarbonates, aromatic polyesters, aromatic polyamides, polyphenylenes, polyxylylenes, polyphenylenevinylenes, polyphenyleneethylenes, polyphenylene sulfides, polyaryl ether ketones, aromatic polysulfones, aromatic polyether sulfones, aromatic polyimides and the mixtures, copolymers thereof, optionally copolymers with aliphatic compounds.
Substituents on the phenyl ring which may be considered are C
1
-C
4
alkyl, such as methyl, ethyl, C
1
-C
4
alkoxy, such as methoxy, ethoxy, fused aromatics which are attached to the phenyl ring via one carbon atom or two carbon atoms, with phenyl, biphenyl, naphthyl.
Substituents on the vinyl group which may be considered are C
1
-C
4
alkyl, such as methyl, ethyl, n- or iso-propyl.
Olefinic comonomers which may be considered are ethylene, propylene, isoprene, isobutylene, butadiene, cyclohexadiene, cyclohexene, cyclopentadiene, optionally substituted norbornene, optionally substituted dicyclopentadiene, optionally substituted tetracyclododecenes, optionally substituted dihydrocyclopentadienes,
C
1
-C
8
, preferably C
1
-C
4
alkyl esters of (meth)acrylic acid, preferably methyl and ethyl ester,
C
1
-C
8
, preferably C
1
-C
4
alkyl ethers of vinyl alcohol, preferably methyl and ethyl ether,
C
1
-C
8
, preferably C
1
-C
4
alkyl esters of vinyl alcohol; preferably of ethanoic acid,
derivatives of maleic acid, preferably maleic anhydride, derivatives of acrylonitrile, preferably acrylonitrile and methacrylonitrile.
The aromatic polymers generally have molecular weights Mw of 1000 to 10000000, preferably of 60000 to 1000000, particularly preferably of 70000 to 600000, determined by light scattering.
The polymers may have a linear chain structure and have branch points due to co-units (for example graft copolymers). The branch centers contain, for example, star-shaped polymers or other geometric shapes of the primary, secondary, tertiary, optionally quaternary polymer structure.
The copolymers may be random, alternating or in the form of block copolymers.
Block copolymers contain di-blocks, tri-blocks, multi-blocks and star-shaped block copolymers.
The starting polymers are generally known (for example WO 94/21 694).
Ethers of the formula (I) are preferably used as the solvent:
in which
R
1
, R
2
, R
3
and R
4
mutually independently denote C
1
-C
8
alkyl, which is linear or branched, or C
5
-C
6
cycloalkyl optionally substituted by C
1
-C
4
alkyl or
two of the residues R
1
, R
2
, R
3
and R
4
form a ring having 3 to 8, preferably 5 or 6 carbon atoms.
Methyl t.-butyl ether, ethyl t.-butyl ether, propyl t.-butyl ether, butyl t.-butyl ether, methyl (2-methyl-2-butyl) ether (tert.-amyl methyl ether), 2-ethoxy-2-methylbutane (ethyl tert.-amyl ether) are particularly preferred.
The quantity of catalyst used depends upon the process which is performed, it being possible
Rechner Johann
Wege Volker
Bayer Aktiengesellschaft
Gil Joseph C.
Lipman Bernard
Preis Aron
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