Научный журнал
European Journal of Natural History
ISSN 2073-4972
ИФ РИНЦ = 0,301

DEVELOPMEND OF METHOD OBTAINING m-XYLYLENEDIAMINE FOR PRODUCTION OR POLYMERIC MATERIALS

AbildinT.S. 1, 2 Zhubanov K.A. 2 Aubakirov E.A. 1, 2 Vasilina G.K. 1, 2 Burkhanbekov K.E. 1, 2
1 Al-Farabi Kazakh National University
2 The Scientific research institute of new chemical technologies and materials

The results of studying reaction of isphthtalonitrile hydration upon promoted catalysts at the foundation of Ni-Rhenejais alloy Ni:Al = 1:1 in spirit environment under the pressure of oxygen in presence of ammonia.

It is established that in the described conditions studied catalysts can be placed in the following line according to degradation of isophthalonitrile hydration:

Ni-Nbsk>Ni-Tisk>Ni-Mgsk>Nisk

And according to output of m-xylylenediamine (m-XDA) sequence of catalysts preserves. Alloying of Ni-Al-alloy with a small amount of Ti, Nb has a positive effect upon activity and selectivity. Activity of Ni-Nbск catalyst in 2–3 times greater that of Ni-Tiск and Ni-Mgск, and 4–5 times greater than that of Niск.

It is shown that the studied solvents can be placed in the following line according to degradation isophthalonitrile hydration speed on Ni-Nbск under 4,0 MPa of Н2 and 80 °С:

CH3OН + NH3 > C2H5OH + NH> iso-C3H7OH + NH> iso-C4H9OH + NH3

In aliphatic spirits (С14), under nitrile-ammonia proportion = 1–3 (g/g), output of XDA equals 96–98 % on Ni-Nbск catalyst.

Nowadays attention of reserchers is mostly drawn to problems of using lipid-aromatic diamines in synthesis of heat-resistant polymers, as introduction of aromatic rings into the chain of polymers increases solidity of thermomolecula, temperature of softening and melting sharply [1]. The basic similar product for heat-resistant polymers will be m-, p-xylylendiamines, synthesized via catalyst hydration of isophthalo- and terephthalonitriles, received via oxidation ammonolysis of m-, p-xylols [1, 2]. Therefore, problem of synthesizing m-, p-xylylendiamines draws our interest for studying.

The most rational method of receiving m-xylylendiamine is catalyst hydration of isophtholodinitrile, received via oxidation ammonolysis of oil m-xylol. Up until the modern days kinetics and mechanisms of hydration isophthalodinitrile into m-xylylendiamine are not studied sufficiently.

The objective of this work is to develop an efficient method of receiving m-xylylendiamine, monomer for heat-resistant polymers, via hydrating isophthalonitrile.

Earlier all researches, devoted to a direct hydration of isophthalo-, terephthalonitriles were carried out in static conditions, and consumption of hydrogen was monitored according to a drop of hydrogen pressure in the system. Among such researches we can outline works by academy member A.A. Balandin, L.K. Freindlin, T.A. Sladkova, and others [3, 4] and academy member D.V. Sokolskiy, F.B. Bazhanov [5]. Among the disadvantages of these works we can outline lack of studies on kinetics of nitrile group hydration, hard conditions of the process, and insufficient output of the desired product (ab01.wmf = 10,0–20,0 MPa Н2, Т = 120–150 °С, output of m-, p-xylylendiamine 80–90 %).

The work [6] describes catalyst method of receiving m-xylylendiamine from isophthalonitrile on Ni / fossil meal under 80–100 °С, 8,0 MPa Н2 in presence of organic solvent and ammonia (mole proportion of isophthalonitrile:dioxane:ammonia = 1:3:2). Output of m-xylylendiamine equals 80-85 %).

The author’s testimony [7] describes catalyst method of receiving m-, p-xylylendiamine from isophthalo-, terephthalonitriles on Pt-Ni / Al2O3 or Pd-Ni / AI2O3 under 120–130 °С, 22,0 MPa Н2 in presence of organic solvent (xylol, toluol, propanol) and ammonia (mole proportion of isophthalonitrile/ammonia = 1:50–100). Output of m-, p-xylylendiamine 90–95 %. For disadvantages of this method we can outline hard conditions of the process on noble metals in presence of great amount of ammonia.

In industry m-xylylendiamine is received via electrochemical restoration of isophthalonitrile, its catalyst hydration on Ni-Rheneja, Pt, or Pd / AI2O3 (60–100 °С, 10,0–13,0 MPa Н2) in organic solvents leads to cyanbensilamine.

Materials and methods of research. With the aim of intensifying the catalytic synthesis of m- xylylenediamine isophthalonitrile for the first time we studied in the presence of various alloyed catalysts based on Ni-Raney, showed high activity and selectivity in hydrogenation reactions of other aromatic compounds.

Catalytic hydrogenation of isophthalonitrile was conducted in the liquid phase in the isobaric-isothermal mode to a high-pressure kinetic (KUVD) allowing monitoring the consumption of hydrogen per unit time [8]. The reactor is a catalytic “duck” stainless steel. The volume of the reaction vessel is 0,15 l., the number of single-sided swing of 600–700 per minute. Solvent – alcohol + NH3. Hydrogenation is carried out until the termination of hydrogen uptake from the gas phase. The equipment and the experimental procedure described previously [9], the catalyst is prepared according to known methods [5].

For the analysis of hydrogenation products were applied potentiometric titration, IKS, Fourier- spectroscopy and elemental analysis.

Results of research and their discussion. In the study of catalytic hydrogenation isophthalonitrile we deliberately were trying to select such process conditions – the catalyst, solvent, temperature, hydrogen pressure, and the ratio of ammonia to dinitrile, which could provide a high yield and quality of the desired product while reducing the duration of the experiment.

Comparative results for the hydrogenation of isophthalonitrile Ni-Reneyaiz Ni-alloy Ni: Al = 50:50 and modified with additives Mg, Ti, Nb catalysts based on Ni-Raney in ethanol at 4,0MPa Н2 pressure and 80 °С show that a characteristic feature of the kinetics of the hydrogenation of isophthalonitrile as in the case of the hydrogenation terephthalonitrile it is constant and fairly large (for large initial velocities) reducing the reaction rate throughout the experiment [1, 10].

On the Ni-Raney (Niск), a fairly sharp decrease in the rate of hydrogenation, and by the time hemihydrogenation (after absorption of 2,0 moles (50 %) of the desired hydrogen) it becomes zero, that is, reaction dies, apparently as a result of the formation of byproducts.

On the catalysts Ni-Mgsk, Ni-Tisk and Ni-Nbsk hydrogenation rate of izoftalonitrile hemihydrogenation becomes an order of magnitude lower than the original; the test was terminated by absorption of the calculated amount of hydrogen. By active catalyst Ni-Nbsk turned is 5 times as active Nisk and Ni-Mgsk, Ni-Tisk- almost 2–3 times.

It has been established that catalysts Ni-Mgsk, Ni-Tisk, and Ni-Nbsk izftalonitrila hydrogenation proceeds at a decreasing rate with time, the calculated amount of hydrogen is absorbed. The hydrogenation starts with a very high rate of absorption to two moles of hydrogen per mole of dinitrile, after which the rate of hydrogen absorption decreases somewhat, the next two moles of hydrogen are joined slowly.

Hydrogenation of izoftalonitrile to m-xylylenediamine in a liquid phase under a hydrogen pressure of isobaric-isothermal conditions investigated to reduce the activity of catalysts arranged in series:

Ni-Nbsk>Ni-Tisk>Ni-Mgsk>Nisk

We have previously shown that the hydrogenation terephthalonitrile significant influence on the process by the nature of the solvent, and the best results are achieved when using alcohols in the presence of ammonia [1, 10] . Solubility of phthalonitriles, e.g., methanol at 25 °C in order to increase the presence of ammonia in comparison with pure methanol, and the temperature rises to 50 °C for a further two times.

We are in our studies under the hydrogenation of izoftalonitrile to m-xylylenediamine for the catalyst Ni-Nbsk in liquid phase under a hydrogen pressure of isobaric-isothermal conditions (4,0 MPa H2, at 80 C) was used as solvent, methanol, ethanol, isopropanol previously saturated with ammonia under cooling (nitrile: ammonia = 1: 1 and 1: 3 ratio in g).

It was shown that the investigated solvents to reduce the rate of hydrogenation of izoftalonitrile arranged in the following series:

CH3OН + NH> C2H5OH + NH3 > iso-C3H7OH + NH3 > iso-C4H9OH + NH3

The output from m-xylylenediamine (m-CDA), the sequence arrangement of solvents is maintained. The shape of the kinetic curves does not change.

Suitable ratio of the reactants on the catalyst surface in alcohol in our experiments is observed at a ratio of nitrile: ammonia = 1:3 (g /g). In the alcohol in a ratio of nitrile: ammonia = 1: 3 (g / g), the yield of m-CDA on Nisk 68–70 % on Ni-Mgsk, Ni-Ni-Tisk and Nbsk catalysts 90–91, 91–92 and 96–98 % respectively.

From this sequence, it follows that as the molecular weight increases the rate of hydrogenation of izoftalonitrile alcohol in a solvent decreases.

Increasing the speed of hydrogenation and high yield of m-xylylenediamine (96–98 %) in the alcohol-ammonia solutions favors aldiminovogo mechanism [1, 3, 5, 9–14].

To confirm the completeness of the reaction hydrogenation of izoftalonitrile to m-xylylenediamine, we studied the infrared spectra of the final product to catalytic reduction izoftalonitrile-promoted the skeletal catalyst Ni-Nbsk.

The final product (after the absorption of 4.0 moles of hydrogen required) in the IR spectrum the absorption bands disappear completely, corresponding S≡N group (valency fluctuations 2240–2230 cm-1), and in 3400–3290 cm-1 manifested intense absorption bands of stretching vibrations of the NH2 group [9, 10, 15].

The desired product m-xylylenediamine – a colorless liquid; temp. Solidification 14 °C. temp. boiling. 245–248 °C, 105 °C / 2 mm Hg.; d204 1,055; nD20 1,5720. It is readily soluble in ether, dioxane, and lower aliphatic alcohols.

FT-IR and Raman spectra of the starting materials and reaction products were recorded on FTIR spectrometer IFS-66 with Raman prefix FRA-106.

The formation of the aminonitrile in the catalytic hydrogenation of aromatic dinitriles indicates sequential recovery of the nitrile groups [1, 5, 10, 12]. First intermediate compound formed on the surface of the catalyst in the hydrogenation of nitriles and dinitriles is aldimine [1, 3, 5, 9–14]:

abild1.wmf

abild2.tif

The classic way of getting primary mono- and diamines is hydrogenation process of nitriles and dinitrils in the presence of ammonia [1, 3–7, 9–12]. Ammonia prevents reactive aldimines react with a primary amine, which are formed by reacting a Schiff base and further reaction with hydrogen passes to a secondary amine. It is also possible interaction with a secondary amine aldimine [5, 9–13]. A reactive aldimine interacting with ammonia forms an unstable compound, which is easily transferred to the primary amine, by interacting with the hydrogen and splitting off the ammonia [1, 5, 9, 10, 12]:

abild3.wmf

To direct the reaction towards the formation of primary mono- and diamines is necessary to increase the hydrogen concentration on the catalyst surface, for example, using elevated hydrogen pressure and strengthen the adsorption of hydrogen bond with the surface by promoting the skeletal nickel, or the selection of the solvent, in particular, its introduction into the ammonia or additives basic character [1, 3–7, 9–12, 16, 17].

Many authors attributed the increased activity of skeletal Ni-Tisk, and Ni-catalysts Nbsk to a change ratio NiAl3 aluminide alloy and Ni2Al3 in upward phase NiAl3, which leads to a change in the lattice parameters Ni. The observed deformation of the lattice of nickel is an additional indication in explaining the higher activity of the catalyst. The activity and selectivity of studied catalysts under the catalytic synthesis of primary amines can be associated with a high degree of enrichment of the catalyst strongly bound by adsorbed hydrogen and the oxides of d-metal oxide catalysts in skeletal layer leads to an increase in the proportion of micropores, increase in the specific surface of the catalyst influence the adsorption properties, selectivity and stability.

Introduction to the Ni-Al-alloy and oxidize easily leachable infusion (up to 10 wt. %), leads to an increase in efficiency factor [1, 10, 16, 17].

General Linear flowsheet producing polymers can be represented as follows:

abild4.wmf

The authors of [1] terephthalonitrile synthesized by hydrogenation of p-xylylenediamine, and on its basis – heat-resistant polymers.

Conclusion. Experiments with a high-pressure kinetic showed that under the conditions of the experiment on Ni-promoted Mgsk, Ni-Tisk, Ni-Nbsk catalizators the liquid phase hydrogenation proceeds at a decreasing rate over time. The hydrogenation starts with a very high rate of absorption to two moles of hydrogen per mole of dinitrile, after which the rate of hydrogen absorption decreases somewhat, the next two moles of hydrogen are joined slowly.

The activity of the catalyst Ni-Nbsk in 2–3 times higher than Ni-Tisk and Ni-Mgsk and 4-5 times higher activity of Ni-Raney (Nisk.).

It is shown that the experimental conditions studied (4,0 MPaN2 and 80 °C) with increasing molecular weight of the alcohol rate of hydrogenation in a solvent izoftalonitrile is decreasing. The form of the kinetic curves is being unchanged. The aliphatic alcohols (С1-С4) at a ratio of nitrile: ammonia = 1: 3 (g / g), the yield of m-xylylenediamine is on Ni-catalyst Nbsk 96–98 %.

An attempt was made to explain the course of the process of catalytic hydrogenation of izoftalonitrile to m-xylylenediamine by aldimine mechanism.

General linear flowsheet producing polymers can be represented as follows: Raw material – Oil → Aromatic compounds of oil → p, m-xylene → tereftalo-, izoftalonitrily → p, m-xylylenediamine → polymers.


The work is submitted to the International Scientific Conference “Engineering science and modern manufacture”, France, October, 18–25, 2015, came to the editorial office оn 28.07.2015.

Библиографическая ссылка

AbildinT.S., Zhubanov K.A., Aubakirov E.A., Vasilina G.K., Burkhanbekov K.E. DEVELOPMEND OF METHOD OBTAINING m-XYLYLENEDIAMINE FOR PRODUCTION OR POLYMERIC MATERIALS // European Journal of Natural History. – 2015. – № 4. – С. 6-9;
URL: https://world-science.ru/ru/article/view?id=33457 (дата обращения: 25.11.2024).

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