RU2634724C2 - Additive copolymer 3,3,4-tris(trimethylsilyl)tricyclononene-7 and 3-trimethylsilyltricyclononene-7, method of its production and method for separating gas mixtures with its application - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: additive copolymer 3,3,4-tris(trimethylsilyl)tricyclononene-7 and 3-trimethylsilyltricyclononene-7 of the formula

(I), where n and m are the proportion of these monomeric units, Me - methyl, the weight-average molecular weight M_w=(3.5-4.5)×10⁵ g/mol, the polydispersity index M_w/M_n=2.5-2.8, the content of 3,3,4-tris (trimethylsilyl) tricyclononene - 7 to 20 mol %. A method of producing the said copolymer and a method for separating gas mixtures using a selectively permeable membrane are also provided, the material of which is said to be an additive copolymer.

EFFECT: increasing the gas permeability of membranes on the basis of the received polymers.

3 cl, 3 dwg, 1 tbl, 2 ex

Description

The invention relates to the synthesis of new additive copolymers based on tricyclononenes, as well as to the separation of gas mixtures using membranes based on these copolymers and can be used in various sectors of the economy, in particular in the processes of separation of components of natural gas (for example, hydrocarbon gases), processes of oxidation, gasification, etc., where membrane gas separation processes are used as one of the technological stages.

The tricyclononene molecule contains a norbornene fragment and thus can be considered as a derivative of norbornene. In turn, it is known that norbornene and its derivatives are able to enter into polymerization reactions according to additive and metathesis schemes (Scheme 1).

Metathesis polymerization involves ring opening and the formation of unsaturated polycyclopentylene vinylenes. Additive (“vinyl”) polymerization proceeds with preservation of the bicyclic structure, that is, with the disclosure of only the π-component of the double bond, and leads to the formation of saturated polymers [Blank F., Janiak C. Metal catalysts for the vinyl / addition polymerization of norbornene. // Coord. Chem. Rev., 2009, 253 (7-8), p. 827-861; Makovetsky K.L. Additive polymerization of cycloolefins, new polymeric materials for advanced technologies. // High. Comp., series B, 1999, 41 (9), p. 1525-1543]. The polymers obtained from one monomer according to different polymerization schemes have different main chain structures and physicochemical properties, for example, the level of thermal and chemical stability, mechanical properties and others.

The two types of polynorbornenes shown in Scheme 1 also differ greatly in their gas separation characteristics. Moreover, additive polynorbornenes possess more promising properties (higher permeability coefficients) [Finkelshtein E.Sh., Bermeshev MV, Gringolts ML, Starannikova LE, Yampolskii Yu.P. // Russian Chemical Reviews, 2011, 80 (4), p. 341-361]. However, not only the structure of the main chain, but also the nature and number of substituents in the monomer unit have a significant effect on the properties of the polymer, in particular on gas permeability. Thus, we previously showed that the presence of two bulk Me ₃ Si groups in the main chain of polynorbornene, where Me is methyl, leads to a significant increase in gas permeability coefficients compared to analogues that do not contain this substituent or contain one such group [Gringolts ML, Bermeshev MV, Starannikova LE, Rogan Yu.V., Yampol'skii Yu.P., Finkel'shtein E.Sh. Synthesis and Gas Separation Properties of Metathesis Polynorbornenes with Different Positions of One or Two SiMe3 Groups in a Monomer Unit // Polymer Science, Ser. A, 2009, 51 (11-12), 1233-1240; Gringolts M., Bermeshev M., Yampolskii Yu., Starannikova L., Shantarovich V., Finkelshtein E. New High Permeable Addition Poly (tricyclononenes) with Si (CH ₃ ) ₃ Side Groups. Synthesis, Gas Permeation Parameters, and Free Volume. // Macromolecules, 2010, 43 (17), p. 7165-7172]. The introduction of other asymmetric silicon-containing substituents, for example PhMe ₂ Si- or Me (z-Pr) ₂ Si-, where Ph is phenyl, i-Pr is isopropyl, could not achieve a significant increase in gas transport characteristics [Gringol'ts M.L. , Bermeshev MV, Syromolotov AV, Starannikova LE, Filatova MP, KL Makovetskii and E. Sh. Finkel'shtein. Highly Permeable Polymer Materials Based on Silicon Substituted Norbornenes // Petroleum Chemistry, 2010, 50 (5), p. 352-361]. Thus, the highest gas permeability is achieved when precisely Me ₃ Si groups are introduced into polymer chains. Previously, silicon-containing additive polymers were synthesized, containing only two Me ₃ Si groups, connected directly with the tricyclononene fragment [Gringolts M., Bermeshev M., Yampolskii Yu., Starannikova L., Shantarovich V., Finkelshtein E. New High Permeable Addition Poly (tricyclononenes) with Si (CH ₃ ) ₃ Side Groups. Synthesis, Gas Permeation Parameters and Free Volume. // Macromolecules, 2010, 43 (17), 7165-7172]. The introduction of three Me ₃ Si groups through flexible Si-O-Si spacers failed to achieve a synergistic effect of improving transport properties [MV Bermeshev, AV Syromolotov, ML Gringolts, LE Starannikova, YP Yampolskii and E.Sh. Finkelshtein. Synthesis of High Molecular Weight Poly [3- {tris (trimethylsiloxy) silyl} tricyclononenes-7] and Their Gas Permeation Properties. // Macromolecules 2011, 44, 6637-6640]. By the introduction of three Me ₃ Si groups directly linked to the tricyclononene fragment, it would probably be possible to achieve it. However, under the conditions of additive polymerization, only a low molecular weight 3,3,4-tris (trimethylsilyl) tricyclononene-7 homopolymer is formed in trace amounts, which is due to the close arrangement of three bulk Me ₃ Si groups with respect to the polymerized double bond, which leads to a decrease in activity in polymerization reactions. All this does not allow to obtain high molecular weight additive polymers based on 3,3,4-tris (trimethylsilyl) tricyclononene-7, suitable for membrane gas separation.

We synthesized additive polymers containing 3,3,4-tris (trimethylsilyl) tricyclononene-7 (TCNSi3) by copolymerizing TCNSi3 with the more active monomer 3-trimethylsilyl tricyclononene-7 (TCNSi1), which made it possible to reduce steric difficulties in the polymerization and to obtain high molecular weight copolymers.

In addition, it was previously shown that additive poly (3-trimethylsilyl tricyclononene-7) has high gas permeability coefficients and belongs to the group of the most permeable polymers [Gringolts M., Bermeshev M., Yampolskii Yu., Starannikova L., Shantarovich V., Finkelshtein E .New High Permeable Addition Poly (tricyclononenes) with Si (CH ₃ ) ₃ Side Groups. Synthesis, Gas Permeation Parameters and Free Volume. // Macromolecules, 2010, 43 (17), p. 7165-7172]. This homopolymer is the closest analogue in the structure of the monomer unit, the main chain and in terms of permeability to the new copolymers considered in this paper.

However, the claimed additive copolymer of 3,3,4-tris (trimethylsilyl) tricyclononene-7 and 3-trimethylsilyl tricyclononene-7 has no analogues.

As a prototype of the claimed method, the method of separation of gas mixtures using membranes based on additive poly (3-trimethylsilyl tricyclononene-7) according to the patent [RF Patent No. 2410397, M.L. Gringolts, M.V. Bermeshev, L.E. Starannikova, Yu.P. Yampolsky, E.Sh. Finkelstein. Mono- or di-silicon-substituted tricyclononene, additive poly (mono- or di-silicon-substituted tricyclononene) and a method for separating gas mixtures using membranes based on it. 2010].

It is worth noting that the prototype method provides not high enough gas separation (permeability) with respect to hydrocarbons (CH ₄ -C ₄ H ₁₀ ), as well as light gases - He, H ₂ , O ₂ , N ₂ , CO ₂ .

The objective of the proposed technical solution is to increase the gas permeability of the membranes for light gases - He, H ₂ , O ₂ , N ₂ , CO ₂ and C ₃₊ hydrocarbons by synthesis of high molecular weight copolymers based on 3,3,4-tris (trimethylsilyl) tricyclononene-7 and 3-trimethylsilyl tricyclononene-7 and effective separation of gas mixtures using membranes based on them.

The problem is solved in that the authors were first able to obtain an additive copolymer of (3,3,4-tris (trimethylsilyl) tricyclononene-7 and 3-trimethylsilyl tricyclononene-7 of the general structural formula:

where n, m is the fraction of these monomer units, Me is methyl.

The resulting copolymers have a weight average molecular weight of M _w = (3.5-4.5) × 10 ⁵ g / mol and a polydispersity index of M _w / M _n = 2.5-2.8, the content of 3,3,4-tris (trimethylsilyl) tricyclononene-7 units 20 mol. %

The problem is also solved by the fact that the proposed method of obtaining the additive copolymer of (3,3,4-tris (trimethylsilyl) tricyclononene-7 and 3-trimethylsilyl tricyclononene-7, characterized in that it involves the dissolution of toluene 3,3,4-tris ( trimethylsilyl) tricyclononene-7 and palladium (II) acetate, adding with stirring a solution in toluene of trityl tetrakis (pentafluorophenyl) borate to form the catalytic system of palladium (II) acetate / trityl tetrakis (pentafluorophenyl) borate, adding 3-trimethylsilonylsilyl nitride nim (3,3,4-tris (trimethylsilyl) tricyclononene-7 at room temperature in the presence of the obtained catalyst system.

The problem in the field of gas separation is solved by the fact that in a method involving supplying a separable mixture on one side of a selectively permeable membrane from a material based on tricyclononene and selecting components penetrating through it on the other hand, a new additive poly copolymer is used as the membrane material (3, 3,4-tris (trimethylsilyl) tricyclononene-7 and 3-trimethylsilyl tricyclononene-7).

The structure of the synthesized copolymers was established by the methods of XRD, ¹ H-NMR spectroscopy, IR spectroscopy, elemental analysis, which indicate that the polymerization proceeds according to the additive scheme as follows:

X-ray diffraction measurements were carried out on a DRON-3M diffractometer in the “pass through” mode (asymmetric, focusing on the detector, quartz monochromator on the primary beam). Used CuK _α radiation. The diffraction pattern was scanned in a “step-by-step mode” with a step of Δ2θ = 0.04 ° and an accumulation time of τ = 10 s. The XRD of the polymer is shown in FIG. one.

NMR spectra of polymers were recorded on a Bruker Avance-400 spectrometer at an operating frequency of the spectrometer of 400 MHz (CDCl _{3 was} used as the internal standard).

¹ H-NMR spectrum of additive poly (3,3,4-tris (trimethylsilyl) tricyclononen-7-co-3-trimethylsilyl tricyclononen-7) (Fig. 2) consists of carbon proton signals (broadened multiplet (broad.s.) 3.19 -1.10 ppm) and protons of trimethylsilyl groups (br. M, 0.3 ppm). According to elemental analysis, the compositions of the corresponding copolymers were determined.

IR spectra were obtained on a Specord M-82 spectrometer (tablets with KBr) (Fig. 3): 688, 746, 830 (Si-C), 1249 ((CH ₃ ) ₃ Si) cm ^-1 ; they also confirm the structure of additive poly (3-tris (trimethylsiloxy) silyltricyclononenes-7).

The molecular weight characteristics of the samples of the copolymers were determined by gel permeation chromatography (GPC) on a Waters instrument in a toluene solution calibrated to polystyrene standards.

To determine the glass transition temperature, differential scanning calorimetry (DSC) was used (Mettler TA 4000 instrument, heating rate 20 ° / min). In DSC thermograms up to 350-370 ° C (the beginning of decomposition) there are no transitions corresponding to devitrification of the polymer.

The following examples illustrate the present invention, but in no way limit its scope.

Polymer Production

The polymers are prepared by the additive copolymerization of 3,3,4-tris (trimethylsilyl) tricyclononene-7, which is a solid fusible substance, and 3-trimethylsilyl tricyclononene-7, which is a colorless transparent liquid. The resulting polymers are amorphous.

The polymerization is carried out in absolute toluene at room temperature in the presence of catalytic systems based on, for example, palladium compounds Pd (OAc) ₂ / [Ph ₃ C] + [B (C ₆ F ₅ ) ₄ ] ^- .

Pd (OAc) ₂ - palladium (II) acetate; [Ph ₃ C] ⁺ [B (C ₆ F ₅ ) ₄ ] ^- - trityl tetrakis (pentafluorophenyl) borate.

All synthesis procedures are carried out in an atmosphere of dry argon using absolute solvents. The selection of polymers is carried out in air.

Example 1

In a glass ampoule load 2.0 g of 50 weight. % solution of 3,3,4-tris (trimethylsilyl) tricyclononene-7 and 2.47 ml of Pd (OAc) ₂ in toluene (2.1 mM), then 2.45 ml of a solution in toluene [Ph ₃ C] ⁺ [B (C ₆ ) is added with stirring F ₅ ) ₄ ] ^- (6.36 mM). The reaction mass is stirred for 30 minutes and 1.0 g of 3-trimethylsilyl tricyclononene-7 is added, while providing molar ratios of the components in the reaction mass [TCNSi3]: [TCNSi1]: [Pd (OAc) ₂ ]: [[Ph ₃ C] ⁺ + [B (C ₆ F ₅ ) ₄ ] ^- ] = 570: 1000: 1: 3 reagents. The resulting mixture was stirred for 24 hours at room temperature.

The obtained polymer (SP-20) was dissolved in toluene, precipitated with ethanol and dried in vacuum for 10 hours at a temperature of 60 ° C, reprecipitated from toluene with ethanol and dried again in vacuum, the procedure was repeated twice.

The isolated polymer is a white solid, yield 50%, M _w = 350,000, M _w / M _n = 2.5.

Elemental analysis. Found (%) 69.10 (C), 13.29 (H), 17.61 (Si), the content of TCNSi3 units is 20 mol. %

Example 2

In a glass ampoule load 1.0 g of 50 weight. % solution of 3,3,4-tris (trimethylsilyl) tricyclononene-7 and 2.47 ml of Pd (OAc) ₂ in toluene (2.1 mM), then 2.45 ml of a solution in toluene [Ph ₃ C] ⁺ [B (C ₆ ) is added with stirring F ₅ ) ₄ ] ^- (6.36 mM). The reaction mass is stirred for 30 minutes and 1.0 g of 3-trimethylsilyl tricyclononene-7 is added, while providing molar ratios of the components in the reaction mass [TCNSi3]: [TCNSi1]: [Pd (OAc) ₂ ]: [[Ph ₃ C] ⁺ [B ( C ₆ F ₅ ) ₄ ] ^- ] = 280: 1000: 1: 3 reagents. The resulting mixture was stirred for 24 hours at room temperature.

The resulting polymer (SP-10) is dissolved in toluene, precipitated with ethanol and dried in vacuum for 10 hours at a temperature of 60 ° C, reprecipitated from toluene with ethanol and dried again in vacuum, the procedure is repeated twice.

The isolated polymer is a white solid, yield 55%, M _w = 378000, M _w / M _n = 2.6.

EA. Found (%) 68.80 (C), 14.80 (H), 16.40 (Si), the content of TCNSi3 units is 10 mol. %

Measurement of the permeability coefficients of the additive copolymer of 3,3,4-tris (trimethylsilyl) tricyclononene-7 and 3-trimethylsilyl tricyclononene-7 for various gases.

To conduct gas permeability tests, the copolymers obtained by the methods described in examples 1 and 2 are dissolved in toluene in an amount providing a concentration of 2.5 weight. % in solution. The resulting solution is placed in a metal cylinder, the bottom of which is formed by a cellophane film, mounted on a horizontal table and left at room temperature to remove the solvent during its slow evaporation. The resulting polymer film is separated from the cellophane base and the gas permeability is measured by gas chromatography after the film is kept in vacuum until a constant weight is achieved. The studied films have a thickness of about 100 μm.

The gas chromatographic apparatus for measuring permeability includes a flow cell into which a membrane of the described solid film is placed, hermetically sealed at the edges with a rubber ring. The test gas is passed from above the membrane, helium carrier gas is passed from below the membrane (nitrogen is used as the carrier gas in measuring the permeability of He and H ₂ ). The flow of carrier gas with an admixture of penetrated through the membrane of the test gas passes through a chamber with a thermal conductivity detector that records the concentration of penetrant. A sample is taken using a metering valve and sent to a chromatograph. The permeability coefficient is determined from the measured mixture composition and space velocity. Measurements are carried out at a temperature of 20-22 ° C and a differential pressure of the test gas of 1 atm. The working surface of the membrane is 15.2 cm.

The found values of the coefficients of permeability (Barrer) and selectivity for various vapor pairs are shown in Table 1.

As can be seen from Table 1, the synthesized new additive copolymers have high permeability coefficients. Comparison with other membrane materials [Gringolts M., Bermeshev M., Yampolskii Yu., Starannikova L., Shantarovich V., Finkelshtein E. New High Permeable Addition Poly (tricyclononenes) with Si (CH ₃ ) ₃ Side Groups. Synthesis, Gas Permeation Parameters and Free Volume. // Macromolecules, 2010, 43 (17), p. 7165-7172] shows that they belong to the class of highly permeable polymers. A comparison of the permeability of the prototype additive poly (3-trimethylsilyl tricyclononene-7) and the obtained copolymers SP-10, SP-20 shows that SP-10, SP-20 have light gas permeability coefficients (He, H ₂ , O ₂ , N ₂ , CO ₂ ) 5-40% higher than the prototype.

Very high permeability factors for higher hydrocarbons are noteworthy. At the same time, an increase in permeability coefficients is observed with an increase in the molecular weight of the penetrant (n-alkane) molecule, which allows one to consider these copolymers as a promising membrane material for removing the C ₃₊ fraction from natural gas and associated petroleum gas.

Moreover, the additive copolymer SP-20 has a significantly higher permeability to propane (50% higher) and butane (11% higher) than the prototype. It is very important that the copolymers obtained also have high separation factors for the C ₄ H ₁₀ / CH ₄ gas pair (Table 1).

Thus, the synthesized new amorphous glassy additive poly (3,3,4-tris (trimethylsilyl) tricyclononene-7-co-3-trimethylsilyl tricyclononene-7), which belong to a new class of highly permeable polymers - polytricyclononenes, exhibit good gas transport properties: very high gas permeability combined with good selectivity of gas separation of hydrocarbons C ₁ -C ₄ . The above data on the gas transport properties of the corresponding copolymers allow us to rely on the use of membranes based on them to extract higher hydrocarbons (C ₃ +) from their mixtures with methane in natural and associated petroleum gases and to concentrate CO ₂ from gas mixtures with methane and nitrogen.

Claims (7)

1. Additive copolymer of 3,3,4-tris (trimethylsilyl) tricyclononene-7 and 3-trimethylsilyl tricyclononene-7 of the General structural formula:

where n, m is the proportion of these monomer units, Me is methyl, characterized in that the weight average molecular weight is M _W = (3.5-4.5) × 10 ⁵ g / mol and the polydispersity index M _W / M _n = 2.5-2.8, the content of 3,3,4-tris (trimethylsilyl) tricyclononene units is 7 to 20 mol. % 2. A method of obtaining an additive copolymer of 3,3,4-tris (trimethylsilyl) tricyclononene-7 and 3-trimethylsilyl tricyclononene-7 according to claim 1, characterized in that it comprises dissolving 3,3,4-tris (trimethylsilyl) tricyclononene in toluene -7 and palladium (II) acetate, adding with stirring a solution in toluene of trityl tetrakis (pentafluorophenyl) borate to form the catalytic system of palladium (II) acetate / trityl tetrakis (pentafluorophenyl) borate, adding 3-trimethylsilyl tricyclononene-7 and copolymerization 3,4-tris (trimethylsilyl) tricyclononene-7 at room temperature in the presence of the resulting catalyst system. 3. A method of separating gas mixtures, comprising supplying a separable mixture from one side of a selectively permeable membrane from a material based on tricyclononene and selecting components penetrating through it, on the other hand, characterized in that the additive copolymer according to claim 1 is used as said membrane material.

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