EP1370524A1

EP1370524A1 - Method for the hydrolytic cyclisation of an aminonitrile compound to give a lactam

Info

Publication number: EP1370524A1
Application number: EP02753580A
Authority: EP
Inventors: Cécile Rosier; Aline Seigneurin
Original assignee: Rhodia Polyamide Intermediates SAS
Current assignee: Rhodia Polyamide Intermediates SAS
Priority date: 2001-03-21
Filing date: 2002-03-19
Publication date: 2003-12-17
Also published as: HUP0303591A2; CN1503783A; BR0208606A; KR20030093264A; MXPA03008451A; RU2003130972A; CA2441812A1; PL365252A1; HUP0303591A3; US20040116691A1; IL158018A0; FR2822465A1; WO2002074739A1

Abstract

The invention relates to a method for the hydrolytic cyclisation of an aminonitrile compound to give a lactam in the presence of a catalyst, in particular a method for the hydrolytic cyclisation of an aminonitrile compound in the presence of a solid catalyst of a clay type. The invention relates in particular to the preparation of ε-caprolactam by hydrolytic cyclisation of the aminocapronitrile.

Description

PROCESS FOR THE CYCLISTING HYDROLYSIS OF AN AMINONITRILE COMPOUND IN

LACTAM

The present invention relates to a process for the cyclizing hydrolysis of an aminonitrile compound into lactam in the presence of a catalyst.

It relates more particularly to a process for the cyclizing hydrolysis of an aminonitrile compound into lactam in the presence of a solid catalyst of the clay type.

Lactams, such as epsilon-caprolactam, are basic compounds for the manufacture of polyamides and in particular of PA 6. Among the various known processes for the synthesis of these lactams, one of the processes is the cyclizing hydrolysis of the corresponding aminonitrile , and more particularly of a corresponding aliphatic aminonitrile, in the presence of water and a catalyst.

Thus, US Pat. No. 2,357,484 describes a process for the preparation in the vapor phase of lactam, with activated alumina, silica in the form of gel or borophosphoric acid as catalyst.

US Patent 4,628,085 also describes a process for preparing lactams by cyclizing hydrolysis in the vapor phase in the presence of a silica-based catalyst, with a specific surface area greater than 250 m ² / g. This reaction is carried out in the presence of hydrogen and ammonia.

Application WO 98/0669 proposes catalysts based on metal oxides, hydrated or not, the metals being selected from the group comprising tin, zirconium, hafnium, bismuth, vanadium, niobium, tantalum or their mixtures. The cycle time of these catalysts is very short and incompatible with industrial exploitation of the lactam manufacturing process.

Application WO96 / 22974 proposes a process for the cyclizing hydrolysis of aminonitrile in the vapor phase using as an catalyst an alumina having specific surface areas and determined pore volume.

Metallic phosphates and zeolites are also known catalysts for the reaction for preparing lactams by cyclizing hydrolysis.

In general, the catalysts used in the processes of the prior art exhibit good initial activity and make it possible to obtain good selectivity for the reaction for converting aminonitrile into lactam. On the other hand, it often turns out that their deactivation is rapid, which constitutes a very big handicap for an industrial implementation of said processes.

In addition, the process according to US 4,628,085 uses a very complex reaction mixture, requiring separation and recycling operations at the end of the reaction, which greatly complicate said process. It is advantageous, when choosing an adequate catalyst for the cyclizing hydrolysis of an aminonitrile into lactam, to have the best possible compromise between the cost, the activity and the selectivity of the catalyst, its lifetime, the simplicity of its implementation etc. The present invention provides new clay type catalysts which satisfactorily meet the various criteria mentioned above.

To this end, the subject of the invention is a process for the cyclizing hydrolysis of an aminonitrile compound into lactam by reaction of an aminonitrile of general formula (I) below: N ≡ C - R - NH ₂ (I) in which :

R represents an aliphatic, cycloaliphatic, arylaliphatic, saturated or unsaturated, linear or branched, substituted or unsubstituted radical comprising from 1 to 12 carbon atoms, with water, in the presence of a solid catalyst, characterized in that the catalyst is a clay.

Clays are phyllosilicates which are classified by groups according to their nature and their physicochemical properties, groups among which we can cite kaolins, serpentines, smectites or montmorillonites, illites or micas, glauconites, chlorites or vermiculites, attapulgites or sepiolite, mixed-layer clays, allophanes or imogolites and clays with a high alumina content.

Certain clays have a lamellar structure with an expandable network. They have the particularity of adsorbing various solvents, in particular water, between the sheets which compose them, which causes swelling of the solid as a result of the weakening of the electrostatic connections between the sheets. These clays essentially belong to the group of smectites (or group of montmorillonite) and for some of them to the group of vermiculites.

Their structure is composed of “elementary” sheets with three layers: two simple layers of SiO ₄ tetrahedra in which part of the silicon can be replaced by other cations in tetrahedral position such as Al ³⁺ or possibly Fe ³⁺ , and between these two layers of tetrahedra, a layer of oxygen octahedra at the center of which are metal cations such as Al ³⁺ , Fe ³⁺ , Mg ²⁺ . This octahedral layer consists of a compact stack of oxygen either from the vertices of the preceding tetrahedra or from OH hydroxyl groups. The compact hexagonal network of these oxygen contains 6 octahedral cavities. When the metal cations occupy 4 of these cavities (2 cavities out of 3 as in the case of aluminum for example), the layer is said to be dioctahedral; when they occupy all the cavities (3 cavities out of 3 as in the case of magnesium for example), the layer is said to be trioctahedral. The elementary sheets of these clays carry negative charges which are compensated for by the presence of exchangeable, alkaline cations such as Li ⁺ , Na ⁺ , K ⁺ , alkaline earths such as Mg ²⁺ , Ca ²⁺ , and possibly the hydronium ion H ₃ O ⁺ . The smectites have charge densities on the sheets lower than those of clays of the vermiculite type: approximately 0.66 charge per elementary mesh against 1 to 1.4 charge per elementary mesh for the vermiculites.

The compensating cations are essentially sodium and calcium in smectites, magnesium and calcium in vermiculites. From the point of view of charge densities, smectites and vermiculites are intermediate between talc and pyrophyllite on the one hand, whose sheets are neutral and micas on the other hand, characterized by a high charge density on the sheets (approximately 2 per elementary mesh) generally compensated by K ⁺ ions.

The interfoliar cations of smectites and vermiculites can be fairly easily replaced by ion exchange by other cations such as, for example, ammonium ions or ions of alkaline earth metals or rare earth metals.

The swelling properties of clays depend on various factors including the charge density and the nature of the compensating cation.

Thus, smectites whose charge density is lower than that of vermiculites have swelling properties clearly superior to those of the latter, and therefore constitute a very interesting class of solids. The repetitive distance or basal spacing represents the shortest distance separating two crystallographically identical patterns located in two adjacent sheets. The basic spacing of the smectites can thus reach, by swelling, values ranging from about 1 nm to more than 2 nm. Among the “swelling” phyllitous silicates of the smectite type, the following main solids of general formula may be mentioned: (Mn * _{/ n} (M ₂ ) ₂ ^v M ₃ ) ₄ ^lv O ₁₀ (OH) ₂ where Mi is the interfoliar cation M ₂ is the metal in the octahedral position M ₃ is the metal in the tetrahedral position x is the number of charges provided by the cation M-, The dioctahedral smectites montmorillonite (H, Na, Ca _1/2 ) _x (Mg _x AI ₂ . _x ) ^vl Si ₄ ^ιv O ₁₀ (OH) ₂ beidellite (H, Na, Ca _1/2 ) _x AI ₂ ^I (Al _x Si _4. _x ) ^lv O ₁₀ (OH) ₂ nontrolite (H, Na, Ca _{1 / 2} ...) _x (Fe, AI) ₂ ^VI (Al _x Si _4. _X ) ^lv O ₁₀ (OH) ₂

Trioctahedral smectorites hectorite Na _x (Li _x Mg _3. _X ) ^vl Si ₄ ^ιv O ₁₀ (OH) ₂ saponite Na _x Mg ₃ ^vι (Al _x Si _4. _X ) ^lv O ₁₀ (OH) ₂ stevensite Na _2x Mg ₃ . _x ^vl Si ₄ ^ιv O ₁₀ (OH) ₂

After adsorption to saturation of water or an organic polar solvent in a smectite, the interfoliar spacing (between two sheets) is maximum. It can reach a value close to 1 nm. These solids are therefore potentially of interest in catalysis because their specific surface area and their potential acidity are high.

According to a preferred embodiment of the invention, the clay which constitutes the catalyst for cyclizing hydrolysis of aminonitrile into lactam is a smectite. More preferably, the clay is montmorillonite. Some clays unfortunately have the drawback of losing their expanded character by heating to 100 ° C. and therefore of not preserving the increase in specific surface resulting from their expansion. This is particularly the case for smectites.

Various methods have been described in the prior art for introducing between the sheets smectites from the pillars or bridges to obtain bridged smectites which retain a high interfoliar spacing after being subjected to a heat treatment.

A method consisting in introducing bridges constituted by oligomers of a hydroxide of a metal, in particular aluminum hydroxide, has been described by LAHAV, SHAMI and SHABTAI in Clays and Clays Ore, vol. 26 (n ° 2 ), p. 107-115 (1978) and in French patent 2,394,324. The formation of bridges consisting of oligomers of mixed hydroxides of silicon and boron is described in US Pat. No. 4,248,739. A technique for bridging smectites, by dialysis, using aluminum hydroxides, chromium, zirconium and titanium, etc. is claimed in patent EP 0.073.718. These methods consist in principle of bringing the clay into contact with a solution containing more or less oligomerized ionic species of the hydroxyaluminic type (in the case of aluminum). This operation is generally carried out in a slightly concentrated solution, at a temperature below 80 ° C. and if possible in the absence of cloudiness consisting of the start of precipitation of the metal hydroxide. The concentrations of metal ion and clay must be optimized so that sufficient solid pillars are formed and the porosity of the clay is not greatly reduced by the insertion of too much metal oxide.

When the alkali or alkaline earth interfoliar ions are replaced by protons either directly using a very dilute solution, or preferably by exchange with an ammonium salt followed by calcination between 300 and 700 ° C., the bridged smectites acquire a strong acidity although globally lower than those of conventional zeolites of type Y or mordenite for example.

According to a preferred embodiment of the invention, the clay used as catalyst for the cyclizing hydrolysis of aminonitrile into lactam is bridged. According to a particular variant of the invention, the catalyst can comprise, in addition to a clay, one or more other metallic compounds, often called dopants, such as for example chromium, titanium, molybdenum, tungsten, iron, zinc. Among these dopants, the chromium and / or iron and / or titanium compounds are considered to be the most advantageous. These dopants usually represent, by weight per weight of clay, from 0% to 10% and preferably from 0% to 5%.

The term “metallic compound” means both the metal element and the metal ion or any combination comprising the metal element.

The clay according to the invention can be calcined, according to a technique known to those skilled in the art.

According to another particular variant of the invention, the catalyst is used in the form of balls, crushed, extruded in the form of cylindrical granules or of hollow or full multilobed form or of honeycombs, pellets.

The shaping can optionally be carried out using a binder. It can first of all be clay beads obtained from oil-drop shaping

(or coagulation in drops). This type of beads can for example be prepared by a process similar to that described for the formation of alumina beads in patents EP-A-0 015 801 or EP-A-0 097 539. The control of the porosity can be produced in particular, according to the method described in patent EP-A-0 097 539, by coagulation in drops of a suspension, of an aqueous dispersion of clay.

The balls can also be obtained by the agglomeration process in a bezel or rotating drum.

It can also be extruded clay. These can be obtained by mixing, then extruding a clay-based material. The porosity of these extrusions can be controlled by the choice of clay used and by the conditions of preparation of this clay or by the conditions of kneading of this clay before extrusion. The clay can thus be mixed during mixing with porogens. By way of example, the extrusions can be prepared by the process described in US Pat. No. 3,856,708. Similarly, beads with controlled porosity can be obtained by addition of porogen and agglomeration in a rotating bowl or a beverage pan or by 'Oil-drop' process.

Thus, as will be demonstrated below, the cyclizing hydrolysis reaction can be carried out with a minimum of side reactions, with good selectivity of the lactam process and therefore the purity of the crude product obtained.

The aminonitriles which can be cyclized by the process of the invention are advantageously aliphatic ω-aminonitriles such as ω-aminovaleronitrile, ω-aminocapronitrile, ω-aminooctanitrile, ω-aminononanitrile, ω-aminodecanitrile, ω-aminodecanonitrile, ω-aminododecanonitrile, methyl-aminovaleronitrile.

The preferred and most important compound is amino-6 capronitrile which leads to ε-caprolactam. The latter compound is the polyamide 6 monomer used for the manufacture of various articles such as moldings, threads, fibers, filaments, cables or films.

The ε-caprolactam produced by the cyclizing hydrolysis reaction is advantageously purified by the various known purification methods, such as distillation, crystallization in a solvent medium or in the molten phase, treatment on resin, treatment with an oxidant and / or hydrogenation. These different stages can be partially or totally combined in different orders and according to the degree of purity of the ε-caprolactam produced.

The cyclizing hydrolysis reaction requires the presence of water. The molar ratio between the water and the aminonitrile used is usually between 0.5 and 50 and preferably between 1 and 20. The higher value of this ratio is not critical for the invention, but higher ratios have little interest in economic matters.

According to a particular embodiment of the invention, the cyclizing hydrolysis reaction is carried out in the vapor phase. Thus, the reactants are maintained in the vapor state in the reactor loaded with a determined quantity of catalyst. The aminonitrile and the water can be used in the form of their mixtures in the vapor state or can be introduced separately into the reactor. The reagents can be pre-evaporated, which then circulate in a mixing chamber.

According to another particular embodiment of the invention, the cyclizing hydrolysis reaction is carried out in the liquid phase. Thus the aminonitrile and water reagents are used in the liquid state under pressure, optionally in the presence of a solvent.

The free volume of the reactor can be occupied by an inert solid such as, for example, quartz, in order to promote the vaporization and the dispersion of the reactants.

Any inert gas can be used without disadvantage as a carrier, such as nitrogen, helium or argon. The temperature at which the vapor phase process is carried out is advantageously sufficient for the reactants to be in the vapor state. It is generally between 200 ° C and 450 ° C and preferably between 250 ° C and 400 ° C.

In the case of a liquid phase process, the reaction is carried out under pressure.

The contact time between the aminonitrile and the catalyst is not critical. It can vary depending on the equipment used in particular. This contact time is preferably between 0.5 and 200 seconds and even more preferably between 1 and 100 seconds.

Pressure is not a critical process parameter. Thus one can operate under pressures from 10 ^~ 3 bar to 200 bar. Preferably, the method will be implemented under a pressure of 0.1 to 20 bar. In the case of hydrolysis carried out in the vapor phase, this pressure is advantageously between 10 ^" 3 bar and 3 bar.

It is not excluded to use an inert solvent under the reaction conditions, such as for example an alkane, a cycloalkane, an aromatic hydrocarbon or one of these preceding halogenated hydrocarbons, and thus to have a liquid phase in the reaction flow.

Examples will now be given, only for information and to illustrate the invention.

EXAMPLE

In a 20 ml cylindrical fixed-bed Pyrex glass reactor, arranged vertically and fitted with heating means and a temperature probe, openings for the arrival and exit of gas flows as well as for the arrival and at the outlet of the liquid flows and of a system for injecting the reagents, 10 g of quartz beads are successively loaded, 2 g of Flor® bridged Montmorillonite ref. 69907 in the form of powder of 0.8 to 1.25 micrometer mixed or no to 2g of quartz beads and again 10 g of quartz beads.

The reactor thus charged is heated to 300 ° C. under a stream of nitrogen (with a flow rate of 5.2 liters / hour) for 2 hours.

A mixture of 6-amino-capronitrile (ACN) and water (water / ACN molar ratio of 4.1) is then injected using a pump. The speed of injection of the mixture is 4.34 ml / h.

At the outlet of the reactor, the vapors are condensed in a glass trap at room temperature over a period of 2 hours: the reaction product is thus recovered in two successive sections of 1 hour.

The final reaction mixture (the second fraction taken) is assayed by vapor phase chromatography in particular to determine the concentration of caprolactam. The transformation rate (TT) of aminocapronitrile, the selectivity is determined

(RT) in caprolactam (CPL) relative to the transformed aminocapronitrile, the activity of the catalyst over 2 hours of reaction, measured in grams of caprolactam formed per gram of catalyst and per hour.

The following stable performances are obtained for a reaction time of 50 hours:

- ACN TT: 19.6%

- RT in CPL: 92.8%

-activity: 6.25 g / g. h

Claims

1 - Process for the cyclizing hydrolysis of an aminonitrile compound into lactam by reaction of an aminonitrile of general formula (I):

N ≡ C - R - NH ₂ (I) in which R represents an aliphatic, cycloaliphatic, arylalyphatic radical, saturated or unsaturated, linear or branched, substituted or not comprising from 1 to 12 carbon atoms, with water, in presence of a solid catalyst, characterized in that the catalyst is a clay.

2 - Process according to claim 1, characterized in that the clay is chosen from kaolins, serpentines, smectites or montmorillonites, illites or micas, glauconites, chlorites or vermiculites, attapulgites or sepiolites, clays with mixed layers, allophanes or imogolites and clays with a high alumina content.

3 - Method according to claim 1 or 2, characterized in that the clay is a montmorillonite.

4 - Method according to one of the preceding claims, characterized in that the clay is bridged.

5 - Method according to one of the preceding claims, characterized in that the catalyst comprises one or more dopants.

6 -Process according to one of the preceding claims, characterized in that the catalyst is in the form of balls, crushed, extruded in the form of cylindrical granules or of hollow or full multilobed form or of honeycombs, pellets.

7 - Method according to one of the preceding claims, characterized in that the aminonitrile of formula (I) is amino-6-capronitrile.

8 - Method according to one of the preceding claims, characterized in that the molar ratio between the water and the aminonitrile used is between 0.5 and 50.

9 - Process according to claim 8, characterized in that the molar ratio between the water and the aminonitrile used is between 1 and 20. 10 - Method according to one of the preceding claims characterized in that the cyclizing hydrolysis reaction is carried out in the vapor phase.

11 - Method according to one of claims 1 to 9, characterized in that the cyclizing hydrolysis reaction is carried out in the liquid phase.

12 - Method according to one of claims 1 to 10, characterized in that the temperature at which the cyclizing hydrolysis step is carried out is between 200 ° C and 450 ° C.