DE1493221B - - Google Patents

Description

The applicant's German Auslegeschrift 1 140 569 describes a process for the catalytic dimerization or trimerization of 1,3-diolefins, in which catalysts are used that allow the mixing of carbon-oxide-free compounds of nickel with halogen-free organometallic compounds, such as metal alkyls, Metal aryls, Grignard compounds or with metal hydrides or with metal hydride complex compounds and electron donors are formed. The electron donors used are Lewis bases, such as cyclic ethers, tertiary amines, especially cyclic tertiary amines, alkyl or aryl phosphines, especially triphenylphosphine, or alkyl or aryl phosphites or compounds with a carbon-carbon triple bond. Similar processes are described in the German Auslegeschrift 1 126 864 of the Badische Anilin- und Sodafabrik (the catalysts are produced by reducing transition metal compounds with the help of metals (AlMg)) and 1 144 268 (certain nickel (O) - Connections used) claimed. It is also known that butadiene according to the process described in German patent specification 881 551 or in USA patent specification 2,686,209 with the aid of catalysts, such as. B. (R ₃ P) ₂ Ni (CO) _{2 can be converted} into mixtures of cyclooctadiene (1.5) and 4-vinylcyclohexane.

The Austrian patent specification 232 495 describes the mixed oligomerization of 1,3-diolefins with olefins, Acetylenes or allenes. Ethylene and styrene are used specifically as olefins and acetylene as acetylenes and called butyne- (2).

Belgian patent 630 046 describes the mixed oligomerization of 1,3-diolefins with ethylene. Butyne- (2) or styrene described.

In the German Auslegeschriften 1 196 186 and 1 201 328 the mixed oligomerization of 1,3-diolefins described with vinyl-substituted aromatic or heteroaromatic compounds, wherein open-chain oligomers are obtained. In the German Auslegeschrift I 192 640 mixed oligomerization from!, S-dienes with acrylic acid esters v acrylic acid amide or acrylonitrile to open-chain compounds.

The invention relates to a process for the production of substituted 8-, 10- and 12-membered members

ίο alicyclic compounds through catalytic co-cyclooligomerization of 1,3-diolefin hydrocarbons with unsaturated compounds in the presence of catalysts known for cyclooligomerization, which is characterized in that 1,3-butadiene with substituted 1,3-diolefins, the substituents of which can also be functional groups or may contain, the functional groups in the presence of excess butadiene must not enter into any reactions with the catalysts, or that butadiene with cyclic mono- or diacetylene hydrocarbons or with bicyclo (2.2, l) -heptene- (2), or that one substituted! Butadienes codimerized with 2-substituted or 2,3-disubstituted butadienes.

In the following mean

COD = cyclooctadiene (1.5),
VCH = 4-vinylcyclohexene,
CDT = cyclododecatriene (1,5.9),

CDD = cyclodecadiene (1.5).

Substituted 12-rings are obtained e.g. B. with simultaneous action of butadiene and isoprene on catalysts of zero-valent nickel. In addition to CDT, 1-methyl-CDT is predominantly used alongside a little dimethyl-CDT educated.

A substituted 8-ring is obtained according to the invention if one z. B. in a solution of a catalyst ■ - Nickel (O) to tri- (o-phenylphenyl) phosphite like 1: 1 —in isoprene introduces butadiene; it forms in yields of almost 90%, based on the reacted Isoprene, the 1-methyl-COED.

According to the invention, the co-cyclooligomerization according to the following reaction schemes can be used to produce the most varied of substituted 8-, 10- and 12-rings. In the formulas below, R ₁ , R ₂ , R ₃ and R ₄ denote alkyl, alkoxy, aryl radicals and all R except one R is hydrogen.

VS

According to the invention, besides butadiene, in the co-dimerization and mixed co-trimerization with particular advantage as additional 1,3-diolefins 1,2- and 2,3-substituted butadiene- (1,3) are used. the

Substituents can optionally themselves be functional groups (for example alkoxy groups) or else contain such functional groups. The only functional groups that come into question are those in Do not react with the catalysts in the presence of excess butadiene.

According to the invention, cyclic mono- or diacetylene hydrocarbons or bicyclo- (2,2, l) -hepten- (2) be reacted with butadiene.

According to the invention, another type of co-dimerization of 1,3-diolefins, namely the co-dimerization of oil-substituted ones Butadienes with 2-substituted or 2,3-disubstituted butadienes.

R,

R ₃ R ₂

tially to the corresponding 1- or 1,2-disubstituted Hydrogenate cyclo-monoolefins.

By co-oligomerization of cyclic acetylene hydrocarbons with butadiene, yields of over 95%, based on the converted cycloalkyne, give 4,5-polymethylene cyclodecatrienes (1,4,7).

R ₁ , R- ,, R ₃ = aryl or alkyl radicals or R ₂ or R ₃ = H.

In principle, the selective co-oligomerization can be carried out by any of the processes mentioned above are, however, catalysts of zero-valent nickel, as they are in the German Auslegeschrift 1 140 569 and the Austrian patent specification 232 495 are described, particularly suitable since with these catalysts no isomerization, as it occurs for. B. in accordance with with the help of alkali metals the German Auslegeschrift 1 126 864 are observed to a certain extent, occurs. The first-mentioned catalysts also have the advantage for co-cyclooligomerization that they are catalytically active at lower temperatures than z. B. the catalysts according to German Auslegeschrift 1 144 268 can also be used as catalysts in the German Auslegeschrift 1 191 375 described complexes of nickel (O) can be used.

The inventive method can be carried out in the presence of inert solvents, but only from those that neither the catalysts, nor the organometallic components or the Metal hydrides, which are used to manufacture the catalysts, attack.

Preference is given to using aliphatic or aromatic hydrocarbons, aliphatic or cycloaliphatic ethers. However, it is particularly advantageous to use the starting diolefins or the products which can be prepared according to the process as solvents during the preparation of the catalyst, so that no foreign substances have to be separated off from the reaction product. The process can be carried out at normal pressure or at elevated pressure. The pressure range is determined by the desired direction of reaction and the temperature required in each case. The process may proceed at temperatures from -10 to +200 ⁰ C, but are preferably carried out at 20 to 120 ° C.

By the process according to the invention, substituted 8-, 10- and 12-rings, based on the reacted represent substituted butadiene- (1,3) in high yields. Those which can be produced according to the invention Compounds are valuable starting materials for further syntheses. So z. B. 1- and 1,2-substituted Cyclooctadienes or cyclododecatrienes and also 4,5-dimethylcyclodecatrienes (1.4,7) slightly par-

20 according to the invention according to the above formulation can be prepared materials may be partially hydrogenated.

The compounds obtained as by-products, e.g. B. COD, CDD and CDT, are valuable starting materials for already known technical processes.
The substituted 8, 10 and 12 rings can be used as solvents.

example 1

4.34 g = 17.05 mmol Ni acetylacetonate and 9.19 g = 17.05 mmol of tri- (o-phenylphenyl) phosphite are dissolved in 85 ecm of benzene in which about 10 g of butadiene are dissolved

- Are, with 4.43 g = 34.1 mmol Monoäthoxydiäthylaluminium at 0 to 20 ⁰ C reduced. In 2 hours, about 250 g of butadiene / hour (680 g in total) are introduced into the catalyst solution at 60 ° C. for about 2 hours and 40 minutes, while about 60 g of isoprene / hour (165 g in total) are added dropwise. The reaction is interrupted and then distilled directly from the reaction vessel at 10 ~ ⁴ Torr and a bath temperature of up to 100 ⁰ C on. 766 g of product with the following composition are obtained:

15.5 2 = 2.0% VCH, 4.3 σ - 0.6% mono-substituted VCH, 5.2 g = 0.7% p-diprene, 610.0 g = 79.7% COD, 119.5 g = 15.6% 1-methyl-COD, 7.4 0.9% dimethyl-COD, 1.1 g = 0.1% CDT, 1.8 g = 0.2% 1-methyl-CDT, 0.7 g = 0.1% dimethyl CDT, 0.4 g = 0.1% trimethyl CDT.

The yield of 1-methyl-COD, based on converted (about 50% conversion) isoprene, is 82% of theory.

The 1-methyl-COD- (1,5) (sp. ₁₄ : 59.5 ° C, nf 1.4910) not previously described was characterized by IR, H ¹ -NMR and MS spectra. With absorption of 1 mol of H _2, it can be easily at normal pressure and 2O ⁰ C with Raney catalyst Nials partially to the 1-Methylcyclookten hydrogenate. Oxidative cleavage leads to 8-keto-nonanaldehyde.

For example ρ iel 2

The same catalyst as described above was made in isoprene instead of benzene. 28 hours at a reaction temperature that is slowly increased from 30 ° C to 52 ° C, about 20 g of butadiene / hour (a total of about 600 g of butadiene) introduced. Obtained after working up as in Example 1 686 g of product of the following composition:

11.2 G = 1.6% VCH. 8.2 G = 1.2% mono-substituted VCH, 4.5 G = 0.7% p-diprene, 517.0 G = 75.3% COD, 125.7 G = 18.3% 1-methyl-COD, 3.7 G = 0.5% dimethyl-COD, 1.5 G = 0.2% CDT, 1.5 G = 0.2% 1-methyl-CDT, 13.0 G = 1.9% higher oligomers.

The yield of 1-methyl-COD, based on converted (about 21% conversion) isoprene, is about

84% of theory. _. . . ,
Example3

Catalyst (double the amount) and execution as in example 1. Instead of the phosphite, however, the corresponding amount (4.45 g) of triphenylphosphine used. At a temperature of 60 ° C, the Catalyst solution per hour about 30 g of butadiene (250 g in total) introduced and at the same time 25 g Isoprene was added dropwise. After working up as in Example 1, 362 g of product with the following composition are obtained:

61.6 g = 17.0% VCH,

19.5 g = 5.4% mono-substituted VCH,

15.9 g = 4.5% p-diprene,

124.8 g = 34.6% COD,

74.0 g = 20.5% 1-methyl-COD,

17.5 g = 4.8% dimethyl-COD,

2, Ig = 0.6% unknown substance,

7.7 g = 2.2% CDT,

15.4 g = 4.2% 1-methyl-CDT,

6.2 g = 1.7% dimethyl CDT,

5.6 g = 1.6% unknown substance,

4.1 g = 1.2% trimethyl CDT,

6.9 g = 1.9% higher oligomers.

B e i s ρ i e 1 5

Catalyst and execution as in example 1.

58 g of 2-phenyl-butadiene are initially introduced and 50 g of butadiene / hour are introduced at 80 ^° C. for 6 hours. Customary work-up gives 342.4 g of product with the following composition:

9.5 g = 2.8% VCH,
280.3 g = 81.9% COD,

7.2 g = 2.1% mono-substituted VCH,

42.2 g = 12.3% 1-phenyl-COD,
3.2 g = 0.9% higher oligomers.

The yield of 1-phenyl-COD, based on converted (Conversion 64%) 2-phenyl-butadiene, is 81% of theory.

The previously described 1-phenyl-COD (1.5) (Kp. = ₁₄ 155 ⁰ C, nf = 1.5764) may be partially catalytically hydrogenated to Phenylcyclooktan (Kp. 149 ° C _14, ^n! = ° _D 1.5319) and thereby characterize it.

Example 6

Catalyst and execution as in example 1.

60.1 g of 1-methoxybutadiene are heated to 60 ° C. together with the catalyst solution and then heated for 20 hours about 30 g of butadiene / hour (620 g in total) were introduced. 661 g of the following product are obtained Composition:

16.6 g = 2.5% VCH,

571.0 g = 86.3% COD,

1.6 g = 0.2% mono-substituted VCH'ene,
68.6 g = 10.4% 3-methoxy-COD,

3.0 g = 0.5% higher oligomers.

Theory.

Example 4

The yield of 1-methyl-COD, based on converted (37% conversion) isoprene, is 40% of the

The catalyst (1.5 times the amount as in Example 1) is prepared in about 11 piperylene (740 g). 28 hours are introduced into this solution at a temperature of initially 44 ° C and after 6 hours, finally at 5O ⁰ C for about 45 g butadiene / hour (total 1280 g). After working up as in Example 1, 1642 g of product with the following composition are obtained:

22.9 g = 1.4% VCH,
5, Ig = 0.3% mono-substituted VCH,

3.8 g = 0.2% disubstituted VCH,

970.0 g = 59.1% COD,

592 g = 36.0% 3-methyl-COD,

44.0 g = 2.6% dimethyl-COD,

4.4 g = 0.3% higher oligomers.

Based The yield of 3-methyl-COD, on reacted (51% conversion) piperylene, 86.4% of theory (Sp. ₁₄ = 166.5 ⁰ C, nf = 1.4859).

The yield of 3-methoxy-COD, based on converted (75% conversion) 1-methoxybutadiene, is 94% of theory. The previously described 3-methoxy-COD (Kp _{2: 0} -. 86 ⁰ C, nf = 1.4887) may be the uptake of 2 moles of H ₂ for catalytically easily enbenfalls not described Methylcyclooktyl ether (b.p. _2p. 75 to 76 ° C, nf = 1.4578) hydrogenate. Both compounds were characterized by their IR, H ¹ - NMR and MS spectra.

Example 7

Catalyst (1.5 times the amount) and execution as in Example 1. The catalyst solution is 122 g 5-methyl-heptatriene- (1,3,6) mixed. At 60 ° C., about 10 g of butadiene / hour are passed in for 28 hours (about 290 g in total). 353 g of product with the following composition are obtained:

6g
238.0 g

3.3 g
105.2 g

1.7% VCH,
67.5% COD,

1.2% mono-substituted VCH,
29.8% 3- (butene- (l) -yl- (3)) - COD,

The yield of substituted butadiene, based on converted (60% conversion) 5-methyl-heptatriene, is 96.3% of theory.

The 3- (butene- (l) -yl- (3)) - COD is not isolated as such, since when heated more strongly than 1,5-diene to Cope rearrangement tends to. The catalytic hydrogenation

with uptake of 3 moles of H, leads to sec-butylcyclooctane (boiling point ₂ i: 111.5 ° C., n ^! g = 1.4648).

If the Cope rearrangement does not take place, 3- (butene- (1) -yl- (3)) - COD with a bp. ₀₂ = 48 to 50 ° C and nl ° = 1.5001 is obtained.

The hydrocarbon was characterized by its H ¹ - NMR and MS spectrum.

B e i s ρ i e 1 8

Catalyst and execution as in example 1.

77.2 g of 2,3-dimethyl-butadiene are heated to 60 ° C. together with the catalyst. About 30 g of butadiene / hour (460 g in total) are passed into a _{T for} 16 hours and 494.5 g of product of the following composition are obtained:

11.9 g = 2.4% VCH,

425.0 g = 85.9% COD,

4.2 g = 0.8% disubstituted VCH,

50.4 g = 10.2% 1,2-dimethyl-COD,

3.0 g = 0.6% higher oligomers.

The yield of 1,2-dimethyl-COD, based on converted (45% conversion) 2,3-dimethyl-butadiene, is 93 % of theory.

The 1,2-dimethyl-COD (boiling point ₁₈ = 78.5 ^° C., n ^. = 1,4941j), which has not been described previously, can easily be partially hydrogenated in hexane with Raney nickel as a catalyst to give 1,2-dimethylcyclooctene 1,2-dimethyl-cyclooctene is obtained by oxidative degradation of n-decadiene- (2.9) (melting point 63 ° to 64 ° C.).

Example 9

Catalyst and execution as in example 1.

232 g of n-octatriene (1,3,6) are mixed with the catalyst solution heated to 80 ° C. while passing in butadiene. About 400 g of butadiene are used in 1.5 hours recorded. 527 g of product with the following composition are obtained:

■; · 8.7 g == '1.6% VCH,

326.9 g = 62.1% COD,

11.3g = 2.1% mono-substituted VCH,

178.8 g = 33.9% 3- (butene- (2) -yl- (l)) - COD,

-C-C = C-C

1.5 g · ■■ -: · ■ 0.3% higher oligomers.

The yield of 3-substituted COD, based on converted (55% conversion) n-octatriene (1,3,6), is 93% of theory. 3- (Butene- (2) -yl- (l)) - COD with a _{boiling point of OI} = 47 ° C and n ² g = 1.5058. In the catalytic hydrogenation occurs with absorption of 3 moles of H ₂ n-butyl-cyclo-octane (bp. ₁₄ 107 ⁰ C, "o ° = 1.4609). The hydrocarbon was clearly characterized by its IR and mass spectrum.

Example 10

The same catalyst as in Example 1 is reduced in a mixture of 340 g of piperylene and 432 g of isoprene with the addition of 17 g of butadiene and the reaction mixture is ^{heated to 55 to 57 °} C. for 96 hours in an autoclave. After working up as in Example 1, 713 g of product with the following composition are obtained:

50.7 g = 7.3% five unknown substances,.

14.4 g = 2.1% 3-methyl-COD,

15.0 g = 2.2% p-diprene,

24.4 g = 3.5% r-methyl-COD,

22.5 g = 3.2% six unknown substances,

70.2 g = 10.1% dimethyl-COD (from piperylene),

68.2g = 9.7% 1,4- and 2,4-dimethyl-COD,

, 236, Og = 34.1% 1,4- and 2,4-dimethyl-COD,

ίο 102.0 g = 14.7% dimethyl-COD (from isoprene),

86.5 g = 12.5% cyclic and open-chain

Trimers,

3.5 g = 0.5% higher oligomers.

1,4- or 2,4- dimethyl - cyclooctadiene - (1.5) are determined by the retention index (according to K ο ν a t s) in the gas chromatogram, Eunelphor 0.80 ° at 1167 and 1169 and squalene at 1058 and 1059, 50 m capillary column (Steel), 80 ° C.

Example 11

4.34 g = 17.05 mmol of nickel acetylacetonate

in 380 g of isoprene with 4.43 g = 34.1 mmol of ethoxy-aluminum diethyl reduced. The catalyst solution is sucked into a 2-1 autoclave and mixed with 500 g of butadiene

mixed. ,

The reaction mixture remains at room temperature for 5 days. After hydrogenation at 60 ° C. and 100 atm. H ₂ pressure, 251 g of product of the following 30; Composition:

1.5 g = 0.6% ethylcyclohexane,

1.5 g = 0.6% unknown substance,

1.5 g = 0.6% cyclooctane,

23.4 g = 9.4% n-decane,

8.0 g = 3.2% iso-undecane (methyl decane),

2.0 g = 0.8% dimethyl-n-decane,

149.5 g = 60.0% cyclodecane,

39.7 g = 15.9% methyl cyclodecane,

1.0 g = 0.4% unknown substance,

15.7 g = 6.3% cyclododecane,

2.0 g = 0.8% methyl cyclododecane, 3.5 g = 1.4% higher oligomers.

The yield of methyl cyclodecane, based on converted (conversion 7%) isoprene, is about 72%

the theory.

Example 12

The catalyst is prepared as in Example 1. ^{The catalyst solution is heated to 40 °} C. together with 114 g of cyclododecine, and about 30 g of butadiene / hour are then passed in over the course of 20 hours. All volatiles are distilled off from the reaction mixture at 10 " ⁴ Torr and up to a bath temperature of 40 ^° C. The distillation residue, which, in addition to the higher-boiling hydrocarbon, also contains the catalyst, is taken up in about 300 ecm of pentane. With admission of air, the catalyst becomes destroyed with 2N HCl. The tri- (o-phenylphenyl) phosphate formed is practically insoluble in pentane and is filtered off with suction. By cooling and concentrating the pentane solution, the bicyclo- (10,8,0) -eikosatriene- ( cis, cis, tr-I, 3.7) isolated, melting point 89 to 94 ° C. The following is obtained in total:

11.6 G = 1.6% VCH, 209 537/556 569.4 G = 78.8% COD, 9.9 G =. 1.4% unknown connections in C, 2-C ₂₀ range,

122.1 g = 17.0% Bicycloeikosatrien,
9.0 g = 1.2% higher oligomers.

The yield of bicyclo-ecosatriene, based on converted (68% conversion) cyclododecine, is 94% of theory.

The compound is characterized by IR, Raman, H ¹ -NMR spectra and by chemical reactions. Partial hydrogenation with Pt in glacial acetic acid at atmospheric pressure results in bicyclo (10,8,0) -eikosadien- (cis, cis, l ^u0, 3) (mp. 77.5 to 80 ⁰ C, according to gas chromatogram 98.6% ig). Hydrogenation using Raney nickel under pressure at 8O ⁰ C resulting in formation of bicyclo (10,8,0) eikosen- (CISI. ¹ - ¹⁰ J (m.p. 63.5 to 64 ° C).

The melting point of Bicycloeikosatriene is 89 to 94 ° C depending on the heating rate, since the rearrangement into cis-divinyl observed in all cyclodeca- (1,5) -dienes (or cyclodeca- (1,4,7) -trienes) -cyclohexane system entry, which at higher temperatures completely delivers 3,4-divinyl-bicyclo- (10,4,0) -hexadecen- (cis-I ¹ ' ⁰ ). Its partial hydrogenation leads to 3,4-diethyl-bicyclo- (10,4,0) -hexadecen-icis- ^ MKpo,!: 135 to 139 ° C, nf 1.5045).

Example 13

In the catalyst solution prepared according to Example 1 is introduced at 80 to 90 ⁰ C for 3 hours, about 200 g of butadiene / hour, a simultaneously added dropwise about 70 g of bicyclo- (2,2, l) -hepten- (2) to. After working up according to Example 1, 636 g of product with the following composition are obtained:

13.9 g = 2.2% VCH,
448.0 g = 70.4% COD,
0.6 g = 0.1% CDT,
6.6 g = 1.2% unknown hydrocarbons,

119.8 g = 26.1% tricyclo-i 10,2,1 ₁ O ² - ¹¹⁾ -peritädekadien- (cis, Tr 4.8).

At the high reaction temperature, this hydrocarbon partially isomerizes to form cis-4,5-divinyl-tricyclo-foil.O ^ J-undecane (boiling point _2O 147 ° C., / ii? 1.5120). The corresponding cis-diethyl compound (boiling point ₂₀ 153 ° C., Yi ² S 1.4934) is formed by uptake of 2 moles of H _2. (Mp. 19.5 to 20 ° C) The Tricyclopentadekadien yields in the catalytic hydrogenation with platinum / glacial acetic acid tricyclo - (10,2,1,0 ²¹¹⁾ - pentadecane (bp ₂₀₁₆₇ "Cn 1.5110.?).

All compounds not previously described are characterized by their IR and H ¹ -NMR spectra.

The yield of tricyclo-pentadecadiene based on converted (39% conversion) bicyclo- (2.2.1) -hep-. ten- (2), is 95% of theory.

Example 14

18 g = 65.5 mmoles of Ni (COD) ₂ are mixed with 1082 g of isoprene and 20 (K) g of butadiene in an autoclave and left to stand for 2 months at 60 ° C. After cooling, the catalyst in the reaction mixture is mixed with 2 N- HCl destroyed.

After working up, 1383 g of product with the following composition are obtained:

5.5 & = 0.4% two unknown coals Hydrogens, 47.6 g = 3.3% VCH, 77.6 ι »-: 5.6% p-diprene,

35.8 g = 2.6% COD,
2.5 g = 0.2% unknown hydrocarbons.

27.7 g - 2.0% dipentene,
558.9 g - ■ - ■: 40.4% ttt-CDT (trans, trans, trans-

CDT),
21.6 g - = 1.6% ttc-CDT (trans, trans, cis-

CDT).

21.8i? - ·; 1.6% tcc-CDT (trans, cis, cis-CDT),
ίο 224.7 g --- = 16.2% 1-methyl-CDT I,
80.4 g = 5.8% 1-methyl-CDT II,
17.2 g = 1.2% dimethyl CDT I,

7.3 g: = 0.5% dimethyl-CDT II,
181.2 g - 13.1% higher oligomers.

Part of the product is hydrogenated, and with the help of preparative gas chromatography, methylcyclododecane (/ if? 1.4718) is isolated. The 1-methyl-CDT I, which has not been described so far, boils at 14.5 torr at 118 ° C (n ⁷ ? 1, 5048). The 1-methyl-CDT II was characterized only by hydrogenation to methylcyclododecane. The yield of 1-methyl-CDT, based on converted (27% conversion) isoprene, is 40% of theory.

Example 15

Catalyst and amounts of isoprene and butadiene used as in Example 14.,

The reaction mixture is, however, with a residence time of about 60 minutes at 110 ° C by a Pumped reactor, which consists of a copper capillary of 21 free space, which is located in a heating bath and at the end there is a relief valve set to 50 atm. Total duration 2.5 hours. The composition of the products is similar to Example 14, but 150 g of product / g Nickel formed in the catalyst per hour. The yield of 1-methyl-CDT, based on converted (35% conversion) isoprene, is 47%.

Example 16

Catalyst and execution as in Example 15, (however, instead of isoprene, 1.08 kg of piperylene used. The reaction product obtained is shaken in air until it is almost colorless. The precipitated nickel hydroxide is centrifuged off and then distilled. One receives 1514g of a product of the following composition:

119.2 g = 7.9% VCH,

5.4 g = 0.4% two unknown coals

hydrogen,

26.6 g = 5.7% COD,

1.7 g = 0.1% 3-methyl-COD,

73.7 g = 4.8% five unknown coals

hydrogen,

1057.3 g = 69.8% cyclododecatrienes,
130.0 g = 8.6% 3-methyl-CDT,
40.0 g = 2.6% higher oligomers.

The yield of 3-methyl-CDT, based on converted (29% conversion) piperylene, is 53% Theory.

The distillation gives a 3-methyl-CDT (Κρ., Ο 105 ° C, ni ° = 1.4968, 92%) which still contains 8% tcc-CDT. The catalytic hydrogenation yields methyl cyclododecane in addition to cyclododecane.

Claims (2)

Patent claims: 1. Process for the preparation of substituted 8-, 10- and 12-membered alicyclic compounds by catalytic co-cyclooligomerization of 1,3-Diolefin hydrocarbons with unsaturated ones Compounds in the presence of catalysts known for cyclooligomerization, thereby ge indicates that 1,3-butadiene is reacted with substituted 1,3-diolefins, whose substituents can also be or can contain functional groups, the functional groups in the presence of excess butadiene with the catalysts do not May enter into reactions, or that one butadiene with cyclic mono- or diacetylene hydrocarbons or with bicyclo (2.2, l) -hepten- (2), or that 1-substituted butadienes are reacted codimerized with 2-substituted or with 2,3-disubstituted butadienes. 2. The method according to claim 1, characterized in that that substituted 1,3-diolefins are isoprene, piperylene. 3-phenylbutadiene, 1-methoxybutadiene, 2,3-Dimethylbutadiene, 5-methylheptatriene- (1,3,6) or n-octatriene- (1,3,6) are used.