(19)
(11)EP 0 307 934 A1

(12)EUROPEAN PATENT APPLICATION

(43)Date of publication:
22.03.1989 Bulletin 1989/12

(21)Application number: 88115196.3

(22)Date of filing:  16.09.1988
(51)International Patent Classification (IPC)4C07C 25/22, C07C 17/12
(84)Designated Contracting States:
AT BE CH DE ES FR GB LI NL SE

(30)Priority: 18.09.1987 IT 2195587

(71)Applicant: SYREMONT S.p.A.
I-20121 Milan (IT)

(72)Inventors:
  • Ungarelli, Raffaele
    I-28069 Trecate Novara (IT)
  • Beretta, Maurizio Augusto
    I-20133 Milan (IT)
  • Sogli, Loris
    I- Novara (IT)

(74)Representative: Zumstein, Fritz, Dr. et al
Patentanwälte, Dr. F. Zumstein, Dipl.-Ing. F. Klingseisen, Bräuhausstrasse 4
80331 München
80331 München (DE)


(56)References cited: : 
  
      


    (54)Process for the preparation of tricyclo 8.2.2.2. hexadeca 4,6,10,12,13,15 hexaene chlorinated in the benzenic rings


    (57) It is described a process for the chlorination of the benze­nic rings of tricyclo 8.2.2.2 hexadeca 4,6,10,12,13,15 hexa­ene (or (2,2)-paracyclophane) having the formula (I):

    by gaseous chlorine, by operating in the presence of at least one metal chloride, as a catalyst and of at least one cocatalyst having the formula V:

    R - OH (V)

    wherein
    R = hydrocarbon or alkylcarboxylic radical with linear or branched chain, containing from 1 to 6 carbon atoms.


    Description


    [0001] The present invention relates to a process aimed to the preparation of tricyclo 8.2.2.2 hexadeca 4,6,10,12,13,15 hexaene (or (2,2) paracyclophane) chlorinated in the aro­matic benzenic rings.

    [0002] More particularly, the present invention relates to a process for the preparation of tricyclo 8.2.2.2 hexa­deca 4,6,10,12,13,15 hexaene chlorinated in the benzenic rings, with improved selectivity characteristics, by cata­lytic chlorination of the starting substrate (2,2)-para­cyclophane) having the formula (I)



    [0003] The chlorinated derivatives obtained by this process, having formula II:

    wherein the symbols m and n, which may be equal or different to each other, represent integers comprised between 1 and 4 and m + n = 2 to 8, are products well known in the literature and are generally utilized as intermediates in the preparation of the corresponding poly-p.xylylene. Said polymers, and in particu­lar poly-p.xylylene and its chlorinated derivatives, are advan­tageously utilized, for instance in the form of coating films in the field of the "conformal coating", obtained by application according to the vacuum vapor deposition technique, in the elec­tronic field, etc.

    [0004] As is known, the above mentioned technique of the vacuum vapor deposition requires the availability of a product having a high purity degree.

    [0005] Various processes have been proposed for preparing chlorinated (2,2)-paracyclophane (II) and its derivatives.How­ever, such known processes are not fully satisfactory and are not suitable for being adopted on an industrial scale, mainly due to the low selectivity of the process.

    [0006] It is known from the literature (see for instance H. Wiegandt and P. Lantos - Industrial and Engineering Chemi­stry - Vo.43,9 pages 2167 to 2172 - September 1951; R. Mac­Mullin - Chemical Engineering Progress - Vol. 44,3 pages 183 to 188 - march 1948) that at the most a dihalogenated deriva­tive selectivity equal to about 85% is obtained by catalytic chlorination of the benzene.

    [0007] It is also known (see USA Patent No.4,166,075) that the selectivity in dichloro derivatives ( for Example dichloropara­xylene) may be considerably improved, up to 95 - 96%, by the simultaneous use of metal haloid as catalyst and of aliphatic hydrocarbon containig oxygenated functions, as co-catalyst.

    [0008] The Applicant has now surprisingly found that, in the case of the clorination of the (2,2)-paracyclophane by using only the above-mentioned metal chloride catalyst, it is possible to obtain a selectivity in tetrachloroparacyclophane higher than 97 - 98%. Said product having the general formula III:

    where m+n = 4, is preferentially constituted by those isomers where m = n = 2.

    [0009] It has been also proved the impossibility of obtaining dichloroparacyclophane (where m+n = 2) with selectivity higher than 90%, by using only the metal halide catalyst.

    [0010] Moreover, it has been found that the joined use of the metal halide catalyst and of the oxygenated hydrocarbon co-cata­lyst hereinafter described, allows to obtain dichloroparacyclo­ phane with a selectivity ≧ 96%. Furthermore, in the mixture of the obtained dichloro-derivatives, those in which m = n = 1, corresponding to a mono-chlorination of the benzenic ring, are sharply prevailing, contrary to the disclosure in USA Patent 4,166,075 where a high selectivity in dichlo­roparaxylene (95 - 96%) and a low selectivity (1 - 7%) in monochloroparaxylene are set forth.

    [0011] It should be pointed out, moreover, that, owing to the aromatic mono-cyclic structure of the paraxylene substrate, there are in such a reference no teaching and/or sugge­stion useful for solving the problem of the symmetric chlo­rination (mono-chlorination) of the two benzenic aromatic rings present in 2,2-paracyclophane, which is the starting material of the present invention.

    [0012] In other words, the above said technique does not disclose and does not give any suggestion as to the way to be followed for obtaining the mono-chlorinated deriva­tive of the para-xylyIene, which constitutes somehow a part of the (2,2)-paracyclophane molecule.

    [0013] Object of the present invention is, therefore, to provide a process for preparing chlorinated (2,2)-paracy­clophane having the above reported formula II, which pro­cess is characterized in that (2,2)-paracyclophane is sub­jected to chlorination in gas phase by working in such a su­spending medium and/or a halogenated organic solvent, and in the presence of at least one metal chloride, as the catalyst, having formula IV:

    Me - Clp      (IV)

    wherein Me represents a metal selected from Fe, Sb, Al, I, Cu, Sn and p represents an integer selected from 1 to 5, preferably in the presence of small amount of at least one co-catalyst agent having formula V:

    R - OH      (V)

    wherein the symbol R represents a hydrocarbon or alkylcar­boxylic radical, with linear or branched chain, containing from 1 to 6 carbon atoms. Efficacious metal chloride cata­lysts proved to be: iron, aluminium, antimony, tin, iodine etc chlorides or mixtures thereof.

    [0014] Efficacious co-catalysts of formula V pro­ved to be: methanol, ethanol, (iso)propanol, butanol, for­mic acid, acetic acid, propionic acid, butyric acid or mix­tures thereof.

    [0015] The chlorination reaction is carried out, under stirring, at temperatures comprised between -70° and +100°C, preferably comprised between 0° and +30°C. The reaction is carried out in a solution and/or dispersion of (2,2)-para­cyclophane in a halogenated, linear or branched aliphatic or aromatic hydrocarbon inert solvent, preferably CCl₄ or CH₂Cl₂, at atmosphere pressure for periods of time varying from 1 to 3 hours.

    [0016] The catalyst having the above reported formula (IV) is preferably produced in situ by the action in suspension of the chlorine on the metal. The amount used is such that:



    [0017] The co-catalyst R - OH is added in amounts such that



    [0018] In the above reported definitions p has the known meaning.

    [0019] In such a way it is possible to obtain high sele­ctivity values for the single derivatives chlorinated in the ben­zenic rings having formula II. Particularly, for example, selecti­vity values in dichloro (2,2)-paracyclophane (G.C.titre) on the whole higher than 96% may be obtained and with a content of the derivative having m = n = 1 equal to or higher than 90%. In other words, the process of the present invention proved to be particularly and selectively suitable for the mono-chlorina­tion of the benzenic rings present in (2,2)-paracyclophane (I), this is in contrast with what may be deduced from the above discussed known technique, the suggestions of which should dissuade one skilled in the art to expect the above re­sults, especially in the case of the selective monochlorination ( m = n = 1) of (2,2)-paracyclophane.

    [0020] The present invention may be therefore considered as a surprising overcoming of a prejudice existing in the known art.

    [0021] Furthermore the titre of the obtained product, especially of dichloro-(2,2)-paracyclophane (> 96% G.C.) allows the remar­kable advantage of the possibility to use the chlorinated raw product as such as obtained in the application processes, without the necessity of incurring in the burdensome purification opera­tions etc.

    [0022] By increasing the halogenation degree of the aroma­tic (benzenic) rings of (2,2)-paracyclophane, the selectivities of the desired species increase: for instance, when m = n = 2 in formula II (tetrachloro (2,2)-paracyclophane), a titre (G. C.) > 99% has been obtained.

    [0023] The starting product (2,2)-paracyclophane (8.2.2.2 hexadeca 4,6,10,12,13,15 hexaene) is a well known product availa­ble on yhe market or which may be prepared according to known processes.

    [0024] Thus, for instance, (2,2)-paracyclophane may be ob­tained ("Organic Syntheses -Collective Volume 5 - John Wiley and Sons Inc. New York - London - Sydney - Toronto, 1973, pa­ges 883 - 886) by the Hofmann elimination starting from p.meth­yl-benzyl-trimethyl-ammonium hydroxide obtained by reacting the corresponding bromide with silver oxide. The elimination is car­ried out in the presence of a basic compound and of an inert organic solvent (toluene).

    [0025] When the reaction is finished, the mixture is treated for separating the chlorinated product, by operating according to conventional methods; by removing the catalyst, distillation of the solvent, washing etc.

    [0026] The present invention is still further elucida­ted by the following examples, which however are to be con­structed as merely illustrative. The term G.C. means gas­chromatography.

    [0027] Example 1 has been carried out without the use of a co-catalyst (V) in order to show the selectivity impro­vement of the yields obtained by the use of the c-catalyst having formula (V), in the case of the dichloroparacyclophane.

    [0028] Examples 10 and 11 set forth the no influence of the co-catalyst presence, in the case of tetrachloroparacyclo­phane.

    EXAMPLE 1 (Preparation of dichloroparacyclophane)



    [0029] 36.5 g (0.175 moles) of (2,2)-paracyclophane, 0.05 g (0.0009 g-atoms) of Fe in power and 0.5 1 of CCl₄, were charged into a reactor having the capacity of 1 liter. Ga­seous Cl₂ was then fed by maintaining the temperature at 18 - 20°C, under stirring and at atmospheric pressure.

    [0030] After a period of time of 1 hour, 25.6 g of chlo­rine were bubbled.

    [0031] The solution was washed with alcaline H₂O (5% of NaHCO₃), CCl₄ was evaporated at reduced pressure by obtaining 48.8 g of an amorphous white solid product having the titre G.C. 89.2% of dichloroparacyclophane, correspon­ding to a yield of 89.8%.

    [0032] The above data are listed in Table 1

    EXAMPLES 2 - 9 (Preparation of dichloroparacyclophane in the presence of co-catalyst)



    [0033] It was operated according to example 1 up to the feeding of 70% of the desired Cl₂, then the co-catalyst was added and the addition of gaseous Cl₂ was completed.

    [0034] The used reactives, the amounts thereof and the obtained products are listed in Table 1.

    EXAMPLES 10 AND 11 ( Preparation of tetrachloroparacy­clophane in the presence (11) and in the absence of the co-catalyst).



    [0035] It was operated according to example 1 up to the feeding of 70% of the determined Cl₂, the co-ca­talyst was added and the chlorination was completed and the product recovered.

    [0036] The obtained quantitative data are listed in Table 1.
    TABLE 1
    Chlorination of (2,2)-paracyclophane
    Example No.PCF g.SolventCatalystCo-CatalystCl₂ g.Temperature °CTime hObtained product
      Typel.TypegTypeg   Typeg.Tit % GCYield %
    1 36.5 CCl₄ 0.5 Fe powder 0.05 -- -- 25.6 20 1 Dichloro PCF 48.8 89.2 89.8
    2 " " " " " Acet.Ac 0.5 25.5 18 1.25 " 48.5 96.5 96.6
    3 " CH₂Cl₂ " " " Methanol 0.55 " " " " 47.9 96.1 94.9
    4 " " " Sb 0.11 Ethanol 0.8 " " 1 " 47.3 96 93.7
    5 " " " Al 0.03 Isoprop 1.5 " 20 1.5 " 46.4 96.3 92.2
    6 " CCl₄ " I₂ 0.11 Methanol 0.55 " 18 " " 46.2 96.4 91.9
    7 20.8 " " Sn " " " 14.5 " 3 " 25.9 95.9 89.7
    8 " " " Cu 0.03 Ethanol 0.5 " 20 2 " 26.1 96 90.4
    9 36.5 " " Fe Wool 0.05 Acet.Ac 0.5 25.5 18 1.25 " 48.7 96.7 97.1
    10 " " " Fe powder 0.05 --- --- 50.5 20 1.5 Tetrachloro PCF 60.9 99.1 99.4
    11 " " " Fe Wool " " " 50.5 " 1.25 " 60.8 99 99.4
    PCF = Paracyclophane



    Claims

    1. Process for preparing chlorinated (2,2)-paracyclophane having formula II:

    where m and n, which may be equal or different to each other, represent integers comprised between 1 and 4 and m+n=2 to 8, which process is characterized in that (2,2)-paracyclophane is subjected to gaseous chlorination by operating in a halogenated organic suspending and/or solvent medium and in the presence of at least one metal chloride catalyst having formula IV:

    Me-Clp      (IV)

    where Me represents a metal selected among Fe, Sb, Al, I, Cu, Sn and p represents a integer from 1 to 5.
     
    2. The process according to claim 1, characterized in that it is carried out in the presence of at least one co-­catalyst agent having formula V:

    R-OH      (V)

    where symbol R represents a hydrocarbon or alkylcarboxylic radical, with a linear or branched chain, containing from 1 to 6 carbon atoms.
     
    3. The process according to claims 1 and 2, characterized in that the reaction is carried out by operating in a chlorinated organic solvent and/or suspending medium, at a temperature comprised between about -70°C and +100°C and at atmospheric pressure.
     
    4. The process according to claim 3, characterized in that the reaction is carried out by operating in a solvent and/or suspending medium selected between CCl₄ and CH₂Cl₂, at a temperature comprised between 0°C and +30°C and at about the atmospheric pressure.
     
    5. The process according to the preceding claims, characterized in that the metal chloride catalyst having formula IV is prepared in situ by the action of the gaseous chlorine on the metal in the reaction medium suspension.
     
    6. The process according to the preceding claims, characterized in that the molecular ratio of the metal chloride catalyst having formula IV with respect to the starting (2,2)-paracyclophane is comprised between about 0.001 and 0.01 and the molar ratio of the co-­catalyst having formula V with respect to the metal chloride catalyst having formula IV is comprised between about 1 and 30.
     
    7. The process according to the preceding claims, characterized in that the metal chloride catalyst having formula IV is ferric chloride.
     
    8. The process according to the preceding claims, characterized in that the co-catalyst having formula V is selected from the group consisting of methyl alcohol, ethyl alcohol, isopropyl alcohol, acetic acid or mixture thereof.
     
    9. A process for preparing chlorinated (2,2)-­paracyclophane having formula II as defined in claim 1, and particularly the derivative mono- chlorinated in the benzenic rings, as above described and exemplified.
     
    10. Chlorinated (2,2)-paracyclophane having formula II as defined in claim 1, and particularly (2,2)-­paracyclophane mono-chlorinated in the benzenic rings, when obtained by the above described and claimed process.
     





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