FR2820134A1 - RARE EARTH OXYCHLORIDE WITH A HIGH SPECIFIC SURFACE, ITS PREPARATION METHODS AND ITS USE AS A CATALYST - Google Patents

Abstract

The invention concerns a novel pure-phase rare earth oxychloride, that is having a single and unique phase by X-ray analysis. Said rare earth oxychloride has a specific surface not more than 25 m<2>/g. The invention also concerns a rare earth oxychloride having a specific surface not less than 14 m<2>/g, after calcining for 6 hours at 800 DEG C. In a first embodiment, the inventive oxychloride can be prepared by a method which consists in reacting a rare earth chloride with a hydroxylated base, whereby a hydroxychloride precipitate is obtained; and wherein the resulting precipitate is calcined. In a second embodiment, the method consists in reacting a rare earth not comprising chloride ion, with a hydroxylated base, whereby a precipitate is obtained; in reacting the precipitate with a chlorinated acid; in calcining the resulting reaction product. The inventive rare earth oxychloride can be used as catalyst or catalyst support. FIG. 1: A ECHELLE THETA B NOMBRES C DONNEES DE L'UTILISATEUR

Description

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RARE EARTH OXYCHLORIDE WITH A HIGH SPECIFIC SURFACE, ITS PREPARATION METHODS AND ITS USE AS A CATALYST
The present invention relates to a novel rare earth oxychloride with a high specific surface area, its preparation processes and its use as a catalyst.

Rare earth oxychlorides are known in particular as catalysts. They are used in particular as cracking catalysts or for the coupling oxidation of methane.

The known routes for the synthesis of rare earth oxychlorides are routes implementing solid / solid reactions from rare earth oxides in particular. These routes require, in order to obtain a rare earth oxychloride in a single phase, a high temperature, of the order of 800oC.

These routes lead to rare earth oxychlorides with a low specific surface area, of between 8 and 12 m 2 / g, due to the high temperature used during their preparation.

However, rare earth oxychlorides, mainly used in catalysis, require a high specific surface, in order to obtain a good yield and a high selectivity of the reactions catalyzed. It is also desirable to obtain these rare earth oxychlorides with a high specific surface area phasically pure, at the lowest possible temperature.

A first object of the present invention is to obtain a rare earth oxychloride which is phaseically pure and which has a high specific surface.

A second object of the present invention is to obtain a rare earth oxychloride with a stabilized specific surface, that is to say with a high specific surface even at high temperature.

For this purpose, the subject of the invention, according to a first embodiment, is a phasically pure rare earth oxychloride, having a specific surface area of at least 25 m2 / g.

The subject of the invention is also, according to a second embodiment, a rare earth oxychloride having a specific surface area at least equal to 14 m2 / g, after calcination for 6 h at 800OC.

Additionally, the invention relates to methods of preparing a rare earth oxychloride.

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According to a first variant of the process, a rare earth chloride is reacted with a hydroxylated base, whereby a precipitate of rare earth hydroxychloride is obtained; and the precipitate thus obtained is calcined.

According to a second variant of the process, a rare earth salt not comprising a chloride ion is reacted with a hydroxylated base, whereby a precipitate is obtained; the precipitate is reacted with a chlorinated acid; the product obtained after this reaction is calcined.

Other characteristics, details and advantages of the invention will emerge even more fully on reading the description which follows, the various concrete but non-limiting examples intended to illustrate it, as well as the appended drawing in which: FIG. unique is an X-ray diagram of a rare earth oxychloride according to the invention.

The present invention relates, according to a first embodiment, to a phasically pure rare earth oxychloride, having a specific surface area at least equal to 25 μm / g, preferably at least equal to 40 m2 / g.

In the case of this first embodiment, specific surfaces with a value of up to approximately 70 μm / g can be obtained.

By rare earth is meant the elements of the group consisting of yttrium and the elements of the periodic table with atomic number included between 57 and 71 inclusive.

The term “phasically pure product” is understood to mean a product exhibiting a single and unique phase, by observation and X-ray analysis. This single phase is a rare earth oxychloride phase of formula: TROCI, in which TR represents the rare earth. In this case, no parasitic phase of the TR202CO3 type for example is observed.

By specific surface is meant the BET specific surface determined by nitrogen adsorption in accordance with standard ASTM D 3663-78 established from the BRUNAUER-EMMETT-TELLER method described in the periodical The Journal of the American Chemical Society, 60,309 ( 1938).

According to a preferred embodiment of the invention, the phasically pure rare earth oxychloride described in the first embodiment of the invention above, has a specific surface area at least equal to 14 rn / g, after calcination at 800OC for 6 hours. .

According to another preferred embodiment of the invention, this phasically pure rare earth oxychloride has a specific surface area at least equal to 9 m2 / g, after calcination at 900OC for 6 hours.

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The rare earth of the phasically pure rare earth oxychloride is preferably chosen from neodymium, samarium, cerium and lanthanum.

Even more preferably, the rare earth is lanthanum.

A subject of the present invention is also, according to a second embodiment, a rare earth oxychloride having a specific surface area at least equal to 14 m2 / g after calcination at 800OC for 6 hours. This surface area is preferably at least equal to 20 m2 / g.

In the case of this second embodiment, surfaces with a value of up to 40 rn / g approximately after calcination at 800OC for 6 hours can be obtained.

According to a preferred embodiment of the invention, the rare earth oxychloride described in the second embodiment has a specific surface area at least equal to 9 m2 / g, after calcination at 900OC for 6 hours.

According to a particular variant of this second embodiment, the earth oxychloride is phaseically pure.

The rare earth of the rare earth oxychloride is chosen in the same way as for the first embodiment of the invention.

The products described above preferably have a TRACT ratio close to 1 or equal to 1.

They can also be in the form of a powder.

In the case of a presentation in powder form, the latter may have good flowability.

The present invention also relates to methods of preparing rare earth oxychlorides.

According to a first variant of the process, a rare earth chloride is reacted with a hydroxylated base in order to obtain a precipitate of rare earth hydroxychloride. The precipitate is then calcined.

The term “rare earth chloride” is understood to mean a rare earth salt comprising at least one chloride ion. As an example, there may be mentioned lanthanum chloride La (cri) 3.

By hydroxylated base is meant a base comprising at least one hydroxyl group.

The hydroxylated base is preferably ammonia.

Rare earth chloride and hydroxyl base are generally used in the form of solutions. The reaction then takes place by bringing these solutions into contact. The hydroxylated base in solution is preferably introduced into the solution of the rare earth salt.

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The nature of the rare earth chloride, the amount of hydroxylated base used and the reaction conditions are chosen so as to obtain a precipitate of rare earth hydroxychloride, which generally corresponds to the formula TR (OH) 2Cl.

A filtration step as well as a step of washing the precipitate obtained after reaction with the hydroxylated base can be carried out. These optional steps can be supplemented subsequently by a step of drying the precipitate.

Such steps are implemented according to conventional methods known to those skilled in the art.

During the implementation of the process, it is possible to mix with the precipitate, preferably during the optional drying step and at the latest before the calcination step, an additive which is capable of being substantially eliminated during the drying process. calcination. This additive can be of the polyvinyl alcohol, polyethylene glycol, polyvinyl pyrolidone, acrylic acid, ammonium salts such as ammonium nitrate or chloride, glycerin type or it can also be chosen from carbohydrates (sugars). Polyvinyl alcohol is used in particular. This additive can increase the specific surface of the rare earth oxychloride. The amount of additive can be between 0 and 20% more particularly between 0 and 10% by weight expressed relative to the rare earth oxide.

The optional drying is preferably spray-drying, that is to say by spraying the mixture into a hot atmosphere (spray-drying). The atomization can be carried out by means of any sprayer known per se, for example by a spray nozzle of the sprinkling head type or the like. So-called turbine atomizers can also be used.

On the various spraying techniques that may be used in the present process, reference may be made in particular to the basic work by MASTERS entitled SPRAY-DRYING (second edition, 1976, Editions George Godwin-London).

In the case of spray drying, the precipitate obtained after reaction with the hydroxylated base, whether or not it has undergone the preceding filtration and washing steps, is suspended in a liquid, in particular water, before drying.

Such type of drying, by atomization, can improve the flowability of the powder.

In particular, the presence of an additive product as described above, during the drying step, can also improve the flowability.

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In addition, a maturing step can be carried out before calcination or before the optional drying step.

In this case, the precipitate obtained after reaction with the hydroxylated base is resuspended in water in water, and the medium thus obtained is maintained at a temperature at least equal to 40 ° C.

This temperature can advantageously be at least equal to 70OC, more preferably at least equal to 90OC. Generally, the ripening temperature is between 40 and 160OC.

The duration of the optional ripening step can vary between 1 h and 10 h, it is more particularly between 2 h and 6 h. This optional ripening step can increase the specific surface of the rare earth oxychloride.

The calcination is carried out according to a conventional method, known to those skilled in the art.

Taking into account the subject of the first embodiment of the invention, it is carried out at a temperature and over a period of time sufficient to obtain a product in the form of rare earth oxychloride.

The calcination temperature can also be adjusted and / or chosen as a function of the subsequent use temperature reserved for the product of the invention, and this taking into account the fact that the specific surface of the product is even lower than the calcination temperature used is higher. Such calcination is generally carried out in air, but calcination carried out for example under inert gas is obviously not excluded.

With respect to the present invention, the calcination temperature can be as low as 400oC. It is more particularly at least equal to 500OC.

The duration of the calcination is usually between 2h and 6h.

According to a second variant of the process, a rare earth salt which does not contain chloride is reacted with a hydroxylated base in order to obtain a precipitate. The precipitate is reacted with a chlorinated acid. The product obtained after this reaction is then calcined.

An example of a rare earth salt not containing chloride, which can be used for the reaction with the hydroxylated base, is rare earth nitrate, more particularly lanthanum nitrate La (NO3) 3.

The hydroxylated base is preferably ammonia.

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The rare earth salt and the hydroxylated base are generally used in the form of solutions. The reaction then takes place by bringing these solutions into contact.

According to a preferred embodiment, the hydroxylated base solution is placed at the bottom of the vessel and the rare earth salt solution is added to the base solution.

The amount of hydroxylated base used and the reaction conditions are chosen so as to precipitate a hydroxylated compound of the rare earth. Generally the pH of the reaction medium is at least equal to 7.

In addition, a weak acid, preferably acetic acid, is optionally used during the reaction of the rare earth salt with the hydroxylated base. This acid can increase the specific surface of the rare earth oxychloride obtained by the second variant of the process of the invention.

A filtration step as well as a step of washing the precipitate, as in the context of the first variant of the process, can be carried out before reaction with the chlorinated acid.

The reaction of the precipitate with the chlorinated acid usually takes place between a suspension in water of the precipitate and the acid in the form of a solution. Preferably in this case, the acid is introduced in solution in said suspension.

The quantity of chlorinated acid used during the reaction with the precipitate is chosen such that the H + / TR molar ratio is close to 1 or equal to 1. This makes it possible to minimize the variations in pH during the introduction. acid.

The reaction medium during the reaction of the precipitate with the chlorinated acid is maintained at a temperature at least equal to 40 ° C. This temperature can advantageously be at least equal to 70 ° C., more preferably at least equal to 90 ° C. Generally, the reaction temperature is between 40 and 160OC.

The duration of the possible ripening step can vary between 1 hour and 1 Oh, it is more particularly between 2 hours and 6 hours.

The chlorinated acid is preferably hydrochloric acid.

A filtration step as well as a step of washing the product obtained after reaction with chlorinated acid can be carried out. These optional steps can be supplemented subsequently by a step of drying the precipitate.

Such steps are implemented according to conventional methods known to those skilled in the art.

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What has been said about the drying in the first variant of the process applies here identically, in particular as regards the preferential spray drying. It is also possible to use an additive as in the first variant.

The calcination is carried out according to a conventional method, known to those skilled in the art. What was said in the first variant of the process concerning calcination applies identically here.

The present invention also relates to the use of a rare earth oxychloride as described above, in particular as a catalyst or catalyst support.

More precisely, the invention relates to a catalyst or catalyst support characterized in that it comprises a rare earth oxychloride as described above or as obtained by the processes according to the two variants which have just been studied above. .

The catalyst or catalyst support of the invention can consist solely of the rare earth oxychloride or it can comprise this rare earth oxychloride in combination with any other catalytically active element.

The catalyst of the invention is used most particularly as a cracking catalyst or as a catalyst for the coupling oxidation of methane.

Examples will now be given.

Example 1
This example concerns the synthesis of LaOCI by precipitation from LaCl3. 6H2O
The raw materials used are: - LaCt3. 6H20 in solution C = 0.95 mol / L; -NH40H 20% (Protabo &commat;).

500 ml of the LaCb solution are introduced into a reactor with a capacity of 1 L equipped with an anchor stirrer. 6H2O (C = 0.95 mol / L). 237 mL of an ammonia solution C = 3.8 mol / L is added to this solution at a flow rate of 70 mL / min, so that the OH / La molar ratio is 2. The pH at the end of addition is equal to 7.7.

The precipitate is filtered off on a frit? 4 then washed at iso-volume, that is to say with a volume of water identical to the volume of the solution to be filtered, at pH = 7.7 (the pH being adjusted by NH4OH).

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The cake thus obtained is resuspended at a concentration of 10% expressed as rare earth oxide, then atomized with a Buch &commat;. The air inlet and outlet temperatures of the Buchi # are respectively equal to 220oC and 110OC.

The dried solid is then calcined in a muffle furnace for 6 hours at 550OC (rise rate 5 C / min).

The results obtained are shown in Table 1 below.

Example 2
The procedure is the same as in Example 1 for the precipitation step, by adding an additional maturing step of 3 h at 95OC, of the cake resuspended after washing. At the end of the ripening, the cake thus obtained is filtered, washed at iso-volume and at pH = 7, 7. Finally the product obtained is dried in an oven at 110 ° C. for 6 h, then calcined under the same conditions as in example 1.

The results obtained are shown in Table 1 below.

Table 1
X-ray diffraction was carried out on the product after calcination at 550OC.

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<tb>

Examples <SEP> Surface <SEP> Surface <SEP> Surface <SEP> Diffraction <SEP> X
<tb> specific <SEP> m2 / g <SEP> specific <SEP> m2 / g <SEP> specific <SEP> m2 / g
<tb> 6h <SEP> 550OC <SEP> 6h <SEP> 800OC <SEP> 6h <SEP> 900oC
<tb> 1 <SEP> 27 <SEP> 14.5 <SEP> 10, <SEP> 5 <SEP> LaOCI
<tb> 2 <SEP> 40
<tb> LAOCI
<tb> traces <SEP> of
<tb> La202CO3
<tb>

Example 3
This example concerns the synthesis of LaOCI by precipitation of La (NO3) 3.

The raw materials used are: -La (NO3) 3 in solution C = 2.76 mol / L d = 1.682 g / cm3; -NH40H 20% (Prolabo &commat;); -CH3COOH C = 0.5 mol / L d = 1.05 g / cm3 at 100% (Pro! Abo &commat;); -36% HCl (Prolabo #); - Polyvinyl alcohol Rhodoviol 4/125 (Prolabo &commat;).

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Into a reactor with a capacity of 1 L equipped with an anchor stirrer is introduced 500 ml of a solution of NH4OH C = 2M placed at the bottom of the vessel. A solution of volume equal to 250 mL containing 0.25 mol of La (NOs) 3 and 0.125 mol of acetic acid is added to ammonia with a flow rate of 4mUmin, so that the OH / La molar ratio is equal to 4. The concentrations before reaction, of the nitrate and of the acetic acid are respectively 1M and 0.5M. The reaction medium has a pH of 9.5 at the end of the introduction.

The precipitate obtained is filtered off on a frit? 4 then washed to iso-volume by adjusting the pH to 9.5 with NH4OH.

The cake is then resuspended in a volume of water of 750 mL, the suspension then having a pH of 9.2, then 25.5 g of concentrated hydrochloric acid is added with stirring (deflocculating), so that the H + / La molar ratio is equal to 1.

The suspension then having a pH of 7.6, is heated for 3 hours at 95 ° C. (rise rate 1.7 ° C. / min) with anchor stirring (300 revolutions / min).

The precipitate is then filtered through a frit? 4 then washed at iso-volume at pH = 8 (the pH being adjusted with NH4OH).

The cake thus obtained is resuspended at a concentration of 10% expressed as rare earth oxide, then atomized with Buch &commat; with an inlet air temperature of 220OC and an outlet air temperature of 120OC.

The solid is finally calcined for 6 hours at 550OC (rate of rise 5 C / min).

The results obtained are shown in Table 2 below.

The single attached figure represents the X-ray diagram of the oxychloride calcined at 550OC. This diagram shows that there is no parasitic phase, the product appearing under a single phase corresponding to LaOCI.

Example 4
The procedure is the same as in Example 3, without using acetic acid and with a starting concentration of nitrate (before reaction) equal to 2M.

The results obtained are shown in Table 2 below.

Example 5
The procedure is the same as in Example 4, adding polyvinyl alcohol to the suspension before atomization with Buch &commat;. The amount

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polyvinyl alcohol introduced corresponds to 0.5% by weight expressed relative to the rare earth oxide.

The results obtained are shown in Table 2 below.

Table 2
X-ray diffraction was carried out on the product after calcination at 550OC.

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Examples <SEP> Surface <SEP> Surface <SEP> Surface <SEP> Diffraction <SEP> X
<tb> specific <SEP> m / g <SEP> specific <SEP> m2 / g <SEP> specific <SEP> m2 / g
<tb> 6h <SEP> T = 550 C <SEP> 6h <SEP> T = 800 C <SEP> 6h <SEP> T = 900 C
<tb> 3 <SEP> 52 <SEP> - <SEP> - <SEP> LaOCl
<tb> 4 <SEP> 45 <SEP> 22.5 <SEP> 12.5 <SEP> LaOCI
<tb> traces <SEP> La2O2CO3
<tb> 5 <SEP> 60 <SEP> 21.5 <SEP> 12 <SEP> LaOCI
<tb> traces <SEP> La202CO3
<tb>

Claims (20)

1. Rare earth oxychloride, characterized in that it is phasically pure and in that it has a specific surface area of at least 25 m2 / g. 2. Rare earth oxychloride according to claim 1, characterized in that it has a specific surface area of at least 40 rn / g. 3. Rare earth oxychloride according to claim 1 or 2, characterized in that it has a specific surface area at least equal to 14 m2jg after calcination for 6 hours at 800OC. 4. Rare earth oxychloride, characterized in that it has a specific surface area of at least 14 m2 / g after calcination for 6 hours at 800oC. 5. Rare earth oxychloride according to claim 4, characterized in that it has a specific surface area of at least 20 m2 / g after calcination for 6 hours at 800OC. 6. Rare earth oxychloride according to any one of the preceding claims, characterized in that it has a specific surface area at least equal to 9 m2 / g after calcination for 6 hours at 900OC. 7. Rare earth oxychloride according to any one of claims 4 to 6, characterized in that it is phasically pure. 8. Rare earth oxychloride according to any one of claims 1 to 7, characterized in that the rare earth is chosen from neodymium, samarium, cerium or lanthanum. 9. A process for preparing a rare earth oxychloride, characterized in that a chloride of said rare earth is reacted with a hydroxyl base, whereby a precipitate of rare earth hydroxychloride is obtained; and the precipitate thus obtained is calcined. <Desc / Clms Page number 12>

10. The method of claim 9, characterized in that one carries out a ripening of the precipitate at a temperature of at least 40OC, before calcination. 11. Process for preparing a rare earth oxychloride, characterized in that a salt of said rare earth not comprising chloride ion is reacted with a hydroxylated base, whereby a precipitate is obtained; the precipitate is reacted with a chlorinated acid; and the product obtained after this reaction is calcined. 12. The method of claim 11, characterized in that one carries out the reaction between the precipitate and the chlorinated acid while maintaining the reaction medium at a temperature of at least 40OC. 13. The method of claim 11 or 12, characterized in that the salt of said rare earth is reacted with the hydroxylated base in the presence of a weak acid, more particularly acetic acid. 14. Method according to any one of claims 11 to 13, characterized in that the chlorinated acid is hydrochloric acid. 15. Method according to any one of claims 9 to 14, characterized in that the hydroxylated base is ammonia. 16. A method according to any one of claims 9 to 15, characterized in that the precipitate obtained after reaction with the hydroxylated base and / or the product obtained after reaction with chlorinated acid is filtered; and we wash it. 17. Method according to any one of claims 9 to 16, characterized in that the precipitate is dried before calcination, more particularly by atomization. 18. Method according to one of claims 9 to 17, characterized in that the precipitate is mixed with an additive of the type polyvinyl alcohol, polyethylene glycol, polyvinyl pyrolidone, acrylic acid, ammonium salts, glycerin, carbohydrates. <Desc / Clms Page number 13> 19. Catalyst or catalyst support, characterized in that it comprises a rare earth oxychloride according to any one of claims 1 to 8, or a rare earth oxychloride prepared by the process according to any one of claims 9 to 18. 20. Use of the catalyst according to claim 19 for the coupling oxidation of methane or the cracking of hydrocarbons.