WO2020187545A1

WO2020187545A1 - Method for preparing a catalyst support

Info

Publication number: WO2020187545A1
Application number: PCT/EP2020/055223
Authority: WO
Inventors: Aurelie Dandeu; Mehdi Le Moel; Fabien Salvatori; Jean-Marc Schweitzer; Chloe BERTRAND-DRIRA
Original assignee: IFP Energies Nouvelles
Priority date: 2019-03-15
Filing date: 2020-02-28
Publication date: 2020-09-24
Also published as: FR3093653B1; FR3093653A1

Abstract

The present invention concerns a method for preparing a Fischer-Tropsch reaction catalyst support in the form of a powder, the support comprising alumina and silica or the derivatives thereof, from: - a first reagent comprising an alumina compound or precursor suspended in a solvent, - and a second reagent made from silicic acid and/or a compound or precursor of silicic acid, suspended or solubilised in a solvent. The method comprises: - a step (a) of preparing the first reagent in a first reactor (10), - a step (b) of storing the second reagent in a second reactor (20), - a step (c) of mixing the two reagents from the two reactors in a mixer or group of mixers (40, 41), in which the reaction between the two reagents takes place. The pH of the first reagent is adjusted to a value not exceeding a given maximum pH threshold before being added to the mixer.

Description

PROCESS FOR PREPARING A CATALYST SUPPORT

Technical area

The present invention relates to the field of catalysts used for reactions for the synthesis of hydrocarbons from a mixture of gases comprising carbon monoxide and hydrogen, generally called Fischer-Tropsch synthesis.

Prior art

The Fischer-Tropsch synthesis processes make it possible to obtain a wide range of hydrocarbon cuts from the CO + Fl ₂ mixture, commonly called synthesis gas. The global equation of the Fischer-Tropsch synthesis can be written as follows:

n CO + (2n + 1) Fl ₂ C _n I _{2n +} 2 + n Fl ₂ 0

The Fischer-Tropsch synthesis is at the heart of the processes for converting natural gas, coal or biomass into fuels or intermediates for the chemical industry. These processes are called GTL (“Gas to Liquids” according to Anglo-Saxon terminology) in the case of the use of natural gas as initial charge, CTL (“Coal to Liquids” according to Anglo-Saxon terminology) for coal, and BTL (“Biomass to Liquids” according to English terminology) for biomass.

In each of these cases, the initial charge is first gasified to a synthesis gas which comprises a mixture of carbon monoxide and dihydrogen. The synthesis gas is then transformed mainly into paraffins thanks to the Fischer-Tropsch synthesis, and these paraffins can then be transformed into fuels by a hydroisomerization-hydrocracking process. For example, transformation processes such as hydrocracking, dewaxing, and hydroisomerization of heavy cuts (C16 +) make it possible to produce different types of fuels in the middle distillates range: gas oil (180-370 ° C cut) and kerosene (140-300 ° C cut). The lighter C5-C15 fractions can be distilled and used as solvents.

The Fischer-Tropsch synthesis reaction can be carried out in different types of reactors (fixed bed, moving bed, or three-phase (gas, liquid, solid) for example of perfectly stirred autoclave type, or bubble column), and the products of the reaction exhibit in particular the characteristic of being free from sulfur-containing, nitrogen-containing or aromatic-type compounds. In an implementation in a bubble column type reactor (or "slurry bubble column" according to the English terminology, or "slurry" in a simplified expression), which implements a divided catalyst in the state of very fine powder, typically of the order of a few tens of micrometers, this powder forms a suspension with the reaction medium.

The Fischer-Tropsch reaction takes place in a conventional manner between 1 and 4 MPa (10 and 40 bar), at temperatures conventionally between 200 ° C and 350 ° C. The reaction is generally exothermic, which requires particular attention to the use of the catalyst, which is also also subject to particularly severe conditions in terms of mechanical and chemical stress.

The catalysts used for the Fischer-Tropsch synthesis generally consist of supports, for example silica or alumina, which are associated with one or more active agents, which are deposited on the surface of the supports (and / or which can impregnate these supports. on a certain thickness). We then speak of supported metal catalysts. These active agents are generally metallic, in particular based on cobalt or iron. The conventional methods of preparing these supported metal catalysts used for the Fischer-Tropsch synthesis consist in depositing a metal salt or a metal-ligand coordination complex on the support, then in carrying out one or more heat treatment (s) carried out. (s) in air, followed by reducing treatment carried out ex-situ or in-situ.

The invention will be more particularly interested in the preparation of supports for these catalysts, in particular supports comprising a mixture of alumina and silica (hydrated or not).

Document EP 2 173 481 describes, for example, the preparation of a support based on alumina alone, which further includes a phosphorus promoter, presented as making it possible to improve the hydrothermal resistance of a catalyst in a Fischer-Tropsch reaction. . The preparation comprises mixing a solution of aluminum alkoxide dissolved in an organic alcohol-based solvent, an organic carboxylic acid having a pKa of 3.5 to 5 and water, followed by heating of the whole at a temperature of 80 to 130 ° C to prepare a boehmite sol. This soil is then dried, then baked at a temperature of 400 to 700 ° C to prepare alumina having a specific surface area in the range of 300 to 800 m ² / g, which will then be treated to incorporate the promoter therein. phosphorus. Supports in a silica-alumina mixture are also marketed by the company SASOL under the name SIRAL for the silica-alumina hydrates, and under the name SIRALOX for their corresponding oxides.

It has hitherto been known to prepare the supports as an alumina-silica mixture by batch processes, with the preparation of a stirred tank suspension from the alumina-based reagent or its precursor, and from the silica precursor. in the form of silicic acid. It turns out that the control of the reaction in the tank is difficult, because the suspension has a complex rheology, in particular during the introduction of silicic acid into the tank, the acid running the risk of crosslinking to form an irreversible gel. . There is therefore a real difficulty in controlling the change in viscosity in the tank, especially since the next step consists in recovering the suspension in order to dry it by atomization, an operation which requires to have at the outlet of the tank a a suspension with a well-controlled viscosity that does not exceed a critical threshold beyond which the suspension can no longer be atomized.

The aim of the invention is therefore to develop an improved process for preparing a Fischer-Tropsch catalyst support based on silica-alumina, a process which overcomes the aforementioned drawbacks. It is therefore a question of proposing a new process which is, in particular, more robust, more reproducible, which allows production on an industrial scale in a shorter time with the same quality of end product, or even higher quality. Subsidiarily, the object of the invention is also to obtain such a support which can have a maintained or improved hydrothermal resistance, and / or to obtain such a support in the form of a powder with precise dimensional calibration and reproducible.

Summary of the invention

A subject of the invention is firstly a process for preparing a reaction catalyst support of the Fischer-Tropsch type in the form of a powder, said support comprising alumina and silica or their derivatives, to starting from: - a first reagent comprising a compound or precursor of alumina, and optionally alumina, in suspension in a solvent, in particular an aluminum oxyhydroxide, - and a second reagent based on silicic acid and / or of a compound or precursor of silicic acid, and optionally of silica, in suspension or dissolved in a solvent. According to the invention, the method comprises: - a step (a) of preparing the first reagent in a first reactor, - a step (b) of storing the second reagent in a second reactor, - a step (c) of mixing the two reagents from the two reactors in a mixer or group of mixers, in which the reaction between the two reagents takes place, and is such that the pH of the first reagent is adjusted to a value not exceeding a maximum threshold, the threshold maximum in question being a pH equal to 3.4.

Preferably, the solvents used are aqueous or essentially aqueous.

Preferably, the support according to the invention consists only of alumina and silica, or their respective derivatives, (with possible traces of impurities), and it is therefore prepared only with the two reagents mentioned. upper.

This method of synthesis has turned out to be very interesting: indeed, by controlling the pH of the first reagent, it is possible to control the viscosity of this first reagent, and, consequently, that of the mixture with the second reagent until the end of l. 'mixing step. The viscosity of the mixture is then sufficiently low and sufficiently reproducible to guarantee the operability of the production of this catalyst support: on the one hand it promotes the association of the two reactants during the mixing step, and on the other hand it allows the shaping of the mixture to obtain the support particles expected by the so-called atomization technology, which does not tolerate viscosities that are too variable / too high.

With the invention, therefore, we finally have easy access to this technology, which is the only one which, on an industrial scale, makes it possible to obtain particles having the desired particle size, geometry and reproducibility. We can then obtain particles which behave better hydrodynamically, and the sizing of their grains is easier to measure (measurement of a diameter or a pseudo-diameter easier than the sizing of an irregular grain) . The powder ultimately obtained was also found to show very satisfactory hydrothermal resistance, which is very important in view of its end use in the Fischer-Tropsch process.

These very advantageous results would be obtained because thus imposing a maximum (acid) pH threshold allows the pH of the first reagent not to significantly exceed the isoelectric point of the second, in particular of silicic acid, which would have the beneficial effect and unexpected to fight against the increase in viscosity of the first reactant and then of the mixture as observed in the prior art. Preferably, the pH of the first reagent can be adjusted during all or part of step (a) of its preparation and / or at the end of step (a) and / or after step (a) and before l. 'step (c). It is therefore preferred, but not essential, to control the pH of the first reagent from its formation in step (a) until its use in step (c).

What is recommended is in fact to control and, if necessary, modify the pH of the first reagent when it is going to be mixed with the second reagent, and the time elapsing between the end of step (a) and the start of step (c) will guide the most appropriate choice, the viscosity of the first reagent tending to increase with time.

It is thus possible to choose either to prepare the first reagent by regulating the pH to maintain it at at most 3.4, and then to mix it just after its preparation with the second reagent, the first reagent therefore being at the pH according to the invention when 'we operate the mixture.

Mixing can also be carried out after intermediate storage, and, before actual mixing, readjust the pH of the first reagent to at most 3.4 if it has changed during its intermediate storage.

The first reagent can also be prepared at a pH greater than this threshold pH, for example at a pH of more than 3.4 and at most 4.5, for example at a pH of about 4, then readjust the pH of the first reagent at a pH of at most 3.4 during mixing, both in the case of a mixture directly following the preparation of the first reagent and in the case of intermediate storage.

In a preferred embodiment of the invention, step (a) is a peptization reaction of an alumina derivative, in particular of an aluminum oxyhydroxide such as boehmite, in the presence of an acid, in particular nitric acid, so as to form solid particles in suspension at least partly colloidal.

Peptization is understood to be a process responsible for forming a stable dispersion of colloidal particles in an aqueous-type solvent. (Peptization is also used during the synthesis of nanoparticles in order to allow a large grouping of particles to separate into several primary particles). This peptization is obtained by changing the surface state of the particles, by applying a load or by adding a surfactant. In the context of the invention, and in particular in the case of the boehmite gels of more particular interest to the invention, an acid is used to carry out this peptization, the acid being adsorbed on the crystalline phases of the grains, and charging them. .

In the case of boehmite gels in particular, this dispersion in colloidal form can be total or partial.

In particular in this embodiment, the pH threshold (pH _max ) of the first reagent, in particular an aluminum oxyhydroxide peptized in the form of solid particles in suspension at least partly colloidal, is set to at most 3.4, and is in particular between 2.8 and 3.4 or between 2.9 and 3.4 or between 3 and 3.4 or between 3 and 3.2. In fact, peptization takes place in an acidic medium, but the invention has shown that it is by maintaining the pH at such low values during the manufacture of the first reagent, or at least by reducing it to such values when it is mixed with the second reagent, that the desired effect on the viscosity of the mixture is obtained.

Advantageously, the second reagent is maintained at a pH of at most 3.4, in particular at most 3.2, for example between 2.9 and 3.1. In this case again, the second reagent is acidic, but the acidic pH is preferably adjusted to such low values to make its pH as close and compatible as possible with the pH of the first reagent, so that their mixture, whatever or the ratio between the two reagents remains at low pH values (and in particular at a value of at most the maximum pH threshold value of the first reagent). There is thus the pH of the first reagent which is close to and preferably at most the value of the isoelectric point of silicic acid, which is in the vicinity of 3, which promotes good peptization and maintenance of the viscosity of the mixture. obtained at relatively low values.

Preferably, step (c) of mixing takes place continuously in the mixer or the group of mixers in which the reaction between the two reactants takes place. This method of continuous support synthesis has proven to be very interesting, insofar as it avoids any intermediate storage of the first reagent at the end of step (a): when it is a hydrate peptization step aluminum, it turns out that intermediate storage tends to increase the pH (and viscosity) of the reagent, significantly and not necessarily reproducible. Mixing in the continuity of the step of preparing the first reagent prevents / limits this development, and thus avoids having to readjust the pH before mixing. The invention has shown that a pH regulation of the first reagent combined with a continuous mixing step gives the best results, both in terms of ease of production and subsequently in terms of shaping the mixture into. grains.

Preferably, step (c) of mixing takes place with regulation of the inlet flow rates of the first and second reagents at the inlet of said mixer / group of mixers, in particular carried out by slaving one of the reactant flow rates to the other.

It is possible to regulate the inlet flow rates of the first and second reagent in step (c) so as to maintain a volume ratio of the flow rate of the first reagent to the flow rate of the second reagent of between 2 and 4, in particular between 2, 8 and 3.6, preferably 3.1 to 3.3. This ratio makes it possible to best adjust the final ratio between aluminum derivative and silica in the catalyst support, in particular for a mass concentration of 10% for each of the reactants in their respective liquid phases.

Advantageously, the viscosity of the mixture produced in step (c) is kept less than or equal to 300 cP, in particular less than or equal to 250 cP, preferably not more than 30 or 40 cP.

The viscosity measurement is carried out at atmospheric pressure at ambient temperature, with a shear at 30 s ¹ . The temperature can be regulated (in the examples it is regulated around 10 ° C).

This viscosity range guarantees, in particular, that the subsequent atomization step takes place under good conditions, with the possibility of forming a spray. (As seen above, it is by adjusting the pH of the first reagent, possibly combined with continuous mixing, that one manages to keep the viscosity of the mixture within these ranges.

Advantageously, the method according to the invention also comprises: a step (d) operating continuously following the mixing step (c), step (d) being a step of drying by atomization of the product resulting from step (c) of mixing in order to obtain a powder.

As mentioned above, this step generally requires having a suspension of particles / grains in a liquid phase with an imposed maximum viscosity, which could pose a problem with the previous batch processes, whereas with the contacting process. of the two continuous reagents according to the invention, it is possible to control the viscosity of the suspension before introduction into the atomization device and to keep it below the required threshold much more easily.

Advantageously, the process according to the invention can also generally comprise a step (e) of calcining the powder obtained in step (d), in particular at a temperature between 900 and 1200 ° C, optionally followed by a step ( f) sieving.

Advantageously, in step (a), the mass concentration of alumina derivative is chosen between 5 and 30%, in particular between 10 and 20%.

Preferably, step (a) and / or step (b) is carried out in a reactor equipped with an inlet, an outlet and a recycling line from the outlet back to the reactor, in particular below the liquid level in said reactor. This recycling is optional and can be used as a means of regulating the flow rate leaving the reactor in question (or even as a means of stirring for the reactor in question).

More preferably, step (a) is carried out in the first reactor equipped with stirring means, in particular chosen from stirring wheels and inclined blade turbines. These stirring means prevent sedimentation, and can be active (mechanical agitators with moving parts) or passive, with a flow studied in the reactor to cause turbulence.

Advantageously, step (b) of storing the second reagent uses a second reactor provided with cooling and stirring means. The stirring means can be of the same type, active or passive, as those equipping the reactor used for step (a). The cooling means are useful for controlling and limiting the aging of the silica derivative / precursor, particularly when it is a question of silicic acid more particularly of interest to the invention. The stirring means ensure thermal homogeneity of the liquid phase in the reactor.

Preferably, in step (b), the silica concentration of the second reagent based on silica, silicic acid and / or a compound or precursor of silicic acid is between 30 and 200 g / l, in particular between 30 and 70 g / l, in particular between 40 and 60 g / l, for example approximately 50 g / l. The method according to the invention preferably also comprises:

- a step (e) preliminary to step (b), which is a step of preparing silicic acid, when it is the latter which is chosen as the second reagent, from silicate, in particular alkali silicate sodium type, which is passed through an ion exchange resin to remove alkalis.

Preferably, the residence time of the reactants in the mixer or group of mixers in step (c) is at most 3 hours, in particular at most 3000 seconds or at most 2000 seconds. This will be a so-called crossing time when mixing is done continuously.

More preferably, step (c) of mixing, in particular continuously, is carried out with several, in particular two, mixers in series, preferably static, or with a disperser in series with at least one preferably static mixer.

Advantageously, step (d) of spray drying uses a spray member, also called an atomizer, in particular of the turbine or monofluid nozzle type, projecting the product resulting from step (c) in the form of droplets into a drying chamber. . As seen above, the spray mixture preferably has a viscosity of at most 300 cP at the inlet of the organ in question. The atomization temperature can be between 200 and 350 ° C, and the average residence time in the atomizer is generally short, no more than 30 seconds.

A subject of the invention is also the Fischer-Tropsch type reaction catalyst support obtained by the process described above, and which is in the form of a powder with a particle size of between 30 and 120 μm, in particular centered on 80 μm. (this dimensioning being comparable to a diameter of particles, which, here, are close to the shape of spheres).

A subject of the invention is also the Fischer-Tropsch type reaction catalyst support obtained by the process described above, and which is in the form of a silica-alumina powder, with a silica content by weight of between 6 and 12%, especially between 8 and 10%. A subject of the invention is also a process for preparing a catalyst of the Fischer-Tropsch catalyst type, in which the catalyst support obtained according to the process described above is treated with active agents of metallic type or their precursors.

The subject of the invention is also an installation for preparing a reaction catalyst support of the Fischer-Tropsch type, said support comprising alumina and silica or their derivatives, from:

- a first reagent comprising a compound or precursor of alumina in suspension, in particular an aluminum oxyhydroxide, and optionally alumina,

- and a second reagent based on silicic acid and / or on a compound or precursor of silicic acid, and optionally silica, suspended or dissolved in a solvent, such that the installation comprises:

- a first reactor in which a step (a) of preparation of the first reagent is carried out,

- a second reactor in which a step (b) of storing the second reagent is carried out,

- a mixer or group of mixers operating a step (c) of mixing, in particular continuously, the two reactants from the two reactors and in which the reaction between the two reactants takes place, the first reactor and the second reactor each being in fluid connection with the mixer / group of mixers, with means for regulating the pH of the first reactant in the first reactor or in the mixer or in the means for fluid connection between the first reactor and the mixer.

The installation may further include means for regulating the flow rates of the first and second reactants at the inlet of said mixer / group of mixers, the first reactor and the second reactor each being in fluid connection with the mixer / group of mixers.

A subject of the invention is also the use of the process or installation described above for producing a catalyst of the Fischer-Tropsch catalyst type. Description of embodiments

The invention will be detailed below with the aid of non-limiting examples illustrated by the following figures:

Figure 1 shows a schematic representation of the process in the form of a block diagram according to the invention.

FIG. 2 represents a graph showing the change in the pH of the boehmite suspension at the end of step (a) as a function of the age expressed in hours of the suspension.

FIG. 3 represents a graph representing, for the three examples carried out, the change in viscosity, expressed in cPs, as a function of time, expressed in seconds, of the mixture obtained at the end of step (c).

FIG. 1 very schematically shows the different steps of a process for the synthesis according to the invention of a Fischer-Tropsch catalyst support based on alumina and silica from boehmite and silicic acid, by the dividing into 5 blocks numbered 1 to 5 in Figure 1, from the most upstream stage to the most downstream stage of the process:

- Block 1: step (a), with a stirred tank for the preparation of alumina from a first reagent, boehmite

- Block 2: step (b), with a storage tank for the second reagent, silicic acid

- Block 3: intermediate stage of injection regulation of boehmite and silicic acid to meet a target ratio

- Block 4: step (c) of injection of the flows from blocks 1 and 2 into a group comprising a disperser mounted in series with a static mixer

- Block 5: stage (d) of spray drying of the suspension from block 4.

Let us detail these blocks successively:

Block 1: step (a) of peptization of boehmite by adding nitric acid. The peptization is carried out in a tank 10 provided with mechanical stirring means 11 which ensure the suspension of the boehmite in powder form in water, and sufficient shearing to maintain the boehmite in suspension and peptize.

An example of a tank is as follows:

- the tank 10 has a capacity of 30 liters, the liquid height in the tank is equal to the diameter of the tank

- the tank 10 can be thermostatically controlled if necessary. The peptization reaction can be carried out at room temperature and does not need to be thermostated. However, it It may be necessary to control the temperature and thermostate the double walled tank.

- The stirring means 11 are stirring wheels marketed by the company Lightnin, or inclined blade turbines: preferably the height of the mobile relative to the bottom of the tank is in a 1/3 ratio. The motor actuating these stirring means 1 1 can provide a wide range of stirring speed, for example between 50 and 500 rpm.

- Baffles can be provided in the tank, for example in the form of counter-blades detached from the wall and held by the cover of the tank (not shown)

- A pump 12 is also provided, which is used both to supply the static mixer of the unit 4 (flow rate for example 5-20 L / h) but also to ensure a possible recycling around the tank, via the recycling line 13 , which can constitute a means of regulating the flow leaving the tank (maximum flow 50 L / h). High pressure pumps, screw pump type or other, are preferable because they make it possible to control the flow, to overcome the pressure drop of the downstream line (flowmeter, mixer and disperser, atomization device). The goal is to have a pressure of around 10 bars (5 to 15 bars) in front of the atomizing device in block 5.

- the possible recycle line 13 has a return to the top of the tank 10 immersed in the liquid (in order to avoid injecting bubbles).

- A valve is also provided, for example on a roundabout (at the level of blocks 1 and 2 in the figure) This adjustment valve allows the pressure to be adjusted upstream of the atomization device of block 5.

- A regulator can be provided (at the level of block 3 in the figure) in order to reduce the stabilization time.

Procedure: The action of nitric acid on boehmite modifies its surface state and allows its at least partial peptization. Here, the reagent is boehmite, a precursor of alumina. It is also possible to add to the boehmite, at this stage, alumina, which is therefore already transformed. The peptization is carried out as follows: a mixture of water + HN0 ₃ is prepared in tank 10, then the boehmite is gradually added, and the mixture is kept under stirring in the tank for about 30 minutes.

Block 2: step (b) with silicic acid storage tank

- silicic acid is prepared upstream from sodium silicate, then passage through an ion exchange resin in order to remove the sodium ions. This two-step preparation is carried out as follows: Sodium (meta) silicate is a strong base forming very alkaline solutions (pH 13 in 1% solution). It is formed naturally by the reaction of silica (silicon dioxide) with sodium carbonate in the molten state. Sodium silicate and carbon dioxide are obtained according to the following reaction:

Na ₂ C0 ₃ + S1O2 Na Si0 ₃ + CO2

It is found in two main forms: an anhydrous form (it then appears as a translucent white crystalline solid of the formula Na ₂ Si0 ₃ ), and a hydrated form (Na ₂ SiO ₃ .nH ₂ 0), so it is sometimes qualified as "liquid glass"("waterglass" or "liquid glass" for English speakers).

The silicate is then neutralized with an acid and leads to the formation of silanol groups by hydrolysis (silicic acid): the acidification is carried out by passing through an ion exchange resin which makes it possible to remove the sodium ions and replace them. by H + ions. As a result, the silicic acid monomers come together to form Si-O-Si bonds, and constitute the silicic acid which is used in step (b).

- the tank 20 used serves as a storage tank for silicic acid. The concentration of silicic acid is around 50 g / L and the pH is set around 3.

- The tank 20 has for example a capacity of 10 L, with a height of liquid equal to the diameter of the tank.

- the tank 20 is thermostatically controlled with a cooling unit making it possible to maintain a temperature between 5 ° C and 10 ° C. This is because silicic acid undergoes aging at room temperature, and it is therefore useful to have a cooled tank in order to limit the aging of the silicic acid solution.

- The tank 20 is stirred in order to have good temperature homogeneity, being provided with stirring means, for example in the form of a marine propeller or of the type marketed by the company Lightnin: preferably, the height of the mobile by compared to the bottom of the tank is in a ratio 1/3. The motor driving the mobile is capable of ensuring a wide range of stirring speed between 50 and 500 rpm.

- Baffles can be provided in the tank 20, for example counter blades detached from the wall and fixed to the lid of the tank.

- a pump 22 is provided: it is used both to supply the static mixer of block 4 (flow rate between 0.5 and 5 L / H) but also to ensure a possible recycling around the tank 20 (which is a means of the flow rate regulation of the co-injection of the two effluents from tanks 10 and 20 of blocks 1 and 2 to the mixer of block 3, with a maximum flow rate of 50 L / H). High pressure pumps, of the screw pump type, are preferable because they allow the flow to be controlled and the pressure drop in the downstream line to be overcome (flowmeter, mixer and disperser, atomization device).

- the objective is to have a pressure of around 10 bars (5 to 15 bars) at the inlet of the atomization device in block 5.

- a valve is provided on a roundabout. This adjustment valve is used to adjust the pressure upstream of the atomization device of block 5. An optional regulator is desirable in order to reduce the time for stabilizing

- Optionally, a heat-insulated recycling line is provided (line diameter approximately 1 cm for example) with a return to the top of the reactor 20 immersed in the liquid (in order to avoid injecting bubbles).

This step (b) is therefore a cold storage (maintaining the solution at around 10 ° C here) of the silicic acid. Block 3: regulation of injection flow rates of boehmite and silicic acid

This type of regulation is based on slave valves and requires two flow meters and a valve on the slave line (here that of silicic acid). A manual adjustment valve is for example arranged in parallel with the control valve so as to widen the operating valve coefficient. The flow rate regulation is important because it makes it possible to maintain a ratio between the two reagents (suspension of boehmite and silicic acid), despite the possible change in the viscosity of the silicic acid.

The boehmite flow rate is fixed, and that of silicic acid is controlled to maintain a ratio R, for example between 2.8 and 3.5, in particular close to or equal to 3. Block 4: injection of the two flow rates of the creepers 30 and 31 from block 3 in a static mixer

At the inlet of the mixer, each flow of lines 30 and 31 can be interrupted by quarter-turn valves (in order to avoid a return from one line to the other during the starting and stopping phases). The envisaged configuration involves two consecutive static mixers 40,41 serving respectively:

- dispersal zone of silicic acid in the boehmite suspension for the reaction

- mixing zone of the poly-silicic acid / boehmite product

A pressure measurement is provided upstream and downstream of the static mixers 40, 41.

The static mixers of block 4 are positioned as close as possible to the atomization device of block 5, so as to minimize the residence time after the mixing zone preceding drying. If the reaction requires a longer residence time, the static mixers are placed further from the atomizer, so as to leave an additional length, for example 1 to 3 m, of tube before atomization.

Block 5: drying by atomization of the suspension

Once the suspension has been prepared, it is conveyed by a common line 42 via the static mixers 40,41 to the chamber 50 of the spray dryer so as to be sprayed into fine droplets which, after evaporation of the solvent , form solid particles. The purpose of the spraying process is to obtain liquid droplets or filaments through local deformation which leads to atomization. The main parameters which influence the spraying are: the properties of the fluid (density, viscosity, surface tension); the properties of the nozzle (spray angle, spray shape, orifice size); operating parameters (fluid pressure and flow rate, temperature). The drying chamber 50 has all the equipment known to those skilled in the art necessary for the generation of the spray supplied with hot air, it is followed by a train of cyclones in order to effect the gas / solid separation.

Two components for spraying the suspension were used:

- Turbine (preferred mode). The peripheral speed at the atomization wheel conventionally varies between 10 and 200 m / s. Such spraying systems make it possible to obtain a homogeneous jet. In this case, the distribution of droplet sizes depends mainly on the speed of rotation of the turbine and very little on the pressure. It is therefore unnecessary to add a pump upstream of the atomizer. With this type of spraying which radially ejects the particles, it will be necessary to control the severity of the drying in order to ensure that the particles have crusted before touching the wall and thus avoid clogging. - Monofluid nozzle: the flow rate is adjusted by a screw pump to maintain an appropriate pressure. It is possible to adopt a co-current configuration, or, preferably, to switch to counter-current, also called fountain mode, in order to increase the residence time.

For this atomization, the goal is to dry the suspension below the bubble point (to avoid internal boiling in the drop). The atomization is preferably carried out between 200 and 400 ° C. The residence times can vary from a few seconds to one minute (for example conventionally 25 seconds). Atomization is carried out if the viscosity of the suspension is below 800-1000 Cps at the atomization nozzle, ideally below 300 CPs, which is the case with the suspension prepared according to the invention and coming from previous blocks.

Examples

The examples exploit the results of a rheokinetic study (shear 30s ¹ ) which made it possible to measure the viscosity of the reactive mixture between the peptized boehmite and the silicic acid over time. The ratio of the volume flow rates is 3.22 (Q boehmite / Q silicic acid). The cell is an imposed strain rheometer (TA Instruments ARES) equipped with a single helical tape, with a 30 ml flat bottom tank. which is thermostatically controlled by the pelletizer effect at 10 ° C.

Tests have been carried out to define the viscosity windows where the mixture can be atomized.

In Examples 1 to 3, the preparation of the reagents, peptization of boehmite on the one hand, preparation of silicic acid from silicate on ion exchange resins on the other hand, strictly follows the same protocol (see below). below).

- Peptization of Boehmite (block 1):

- Nature of the boehmite: boehmite marketed by the company AXENS under the trade name GA 7001 (any other boehmite may also be suitable)

- Quantity of boehmite: 13% by mass (the rest is water). Preferably, for the boehmite GA7001, it remains less than 22%.

- Nitric acid: 9% equivalent weight / boehmite, other acids may also be suitable, such as weak or strong acids, mineral or organic acids.

The mixture is stirred for 45 minutes at 10 ° C. At the end of the peptization, the pH of the solution is equal to 3. By adsorption of H ⁺ ions on the crystal faces, the pH tends to fall. go up over time as shown in Figure 2: after 5 hours, the pH has gone from 3 to 3.5, then it tends to 3.8 after 10 hours.

Example 1 (according to the invention)

In Example 1, the mixture with silicic acid is carried out at pH = 3, immediately after the end of step (a) of peptization. It corresponds to the curve C1 in figure 3.

Example 2 (comparative)

In this example 2, the reaction mixture is produced 6 hours after the end of the peptization (a), when the pH has risen to 3.6. It corresponds to the curve C2 of fig 3.

Example 3 (according to the invention) In this example, the boehmite suspension, the pH of which rose to 3.6 after 6 hours, is re-acidified with nitric acid to again reach the isoelectric point of the acid. silicic acid, i.e. a pH of 3 (corresponding to a pH = 3). It corresponds to the curve C3 in figure 3.

- Preparation of silicic acid (block 2):

- Temperature: 10 ° C Silicic acid (block 2):

Silicic acid: 52.5g / L Temperature: 10 ° C. A fresh silicic acid is used. It is obtained from sodium silicate passed through H ⁺ ion exchange resins making it possible to obtain a solution at pH = 3.

- Reactive mixture (blocks 3, 4) The results are presented in figure 3:

- In the case of Example 1 (Curve C1), the mixture leads to a low viscosity, below 30cPs, which remains stable for 3000 s, a mixture which can therefore be atomized,

- In the case of Example 2 (Curve C2), the mixing leads to a rapid rise in viscosity which rapidly exceeds 30 cps. In this case, the mixture is not atomizable. - In the case of Example 3 (Curve C3), the mixture leads to a low viscosity, below 30cPs, and stable for 4000 s, a mixture which can therefore be atomized.

In Example 2, the suspension was not atomized because of too high a viscosity. In Examples 1 and 3, the powder obtained after atomization (block 5) is then calcined at a temperature of the order of 900 to 1200 ° C., then sieved (optionally) to remove the smallest particles.

It is then a powder of a silica-alumina mixture having the following characteristics:

- Si0 ₂ content: The preferred range of the Si0 ₂ content is 6-12% by weight, and more particularly the 8-10% range.

- Median diameter 80 micrometers

In embodiments of the invention 1 and 3, the dry SiO ₂ content (by weight) is 9.75%, and the dry Al ₂ O _{3 content} (by weight) is 90.25%.

We observe that the powder grains are regular and approach a spherical shape. It is because the invention provides a pH-controlled manufacturing process, preferably moreover continuously, that spray drying can be carried out which makes it possible to obtain, in comparison with other drying processes, particles of more spherical and more regular shape, and of more reproducible average size.

The mixture is preferably operated continuously because the mixture always ends up increasing in viscosity. Batch mixing can still be envisaged if the intermediate storage of the reagents has a limited duration, if the mixture itself remains of a limited duration, and if the pH, in particular of the first reagent, remains controlled in accordance with the invention. Examples 2 and 3 show the benefit of adding a pH regulation to the peptized boehmite suspension, either during its preparation (example 2), or at least before its contact with silicic acid (example 3). .

Claims

1. Process for preparing a Fischer-Tropsch type reaction catalyst support in the form of a powder, said support comprising alumina and silica or their derivatives, from:

- a first reagent comprising a compound or precursor of alumina, and optionally alumina, suspended in a solvent, in particular an aluminum oxyhydroxide,

- and a second reagent based on silicic acid and / or on a compound or precursor of silicic acid, and optionally silica, in suspension or dissolved in a solvent, characterized in that the process comprises:

- a step (a) of preparing the first reagent in a first reactor (10),

- a step (b) of storing the second reagent in a second reactor (20),

a step (c) of mixing the two reagents from the two reactors in a mixer or group of mixers (40,41), in which the reaction between the two reagents takes place, and in that the pH of the first reagent at a value not exceeding a maximum pH threshold (pH _max ) given before its introduction into the mixer in mixing step (c), being adjusted to a value of at most 3.4.

2. Method according to the preceding claim, characterized in that the pH of the first reagent is adjusted during all or part of step (a) of its preparation and / or at the end of step (a) and / or after step (a) and before step (c).

3. Method according to one of the preceding claims, characterized in that step (a) is a peptization reaction of an alumina derivative, in particular of an aluminum oxyhydroxide such as boehmite, in the presence of an acid, in particular nitric acid, so as to form solid particles in suspension at least partly colloidal.

4. Method according to one of the preceding claims, characterized in that the pH threshold (pH _max ) of the first reagent, in particular an aluminum oxyhydroxide peptized in the form of solid particles in suspension at least partly colloidal, is set between 2.8 and 3.4, especially between 3 and 3.2.

5. Method according to one of the preceding claims, characterized in that the second reagent is at a pH of at most 3.4, in particular at most 3.2.

6. Method according to one of the preceding claims, characterized in that step (c) of mixing takes place continuously in the mixer or the group of mixers (40,41) in which the reaction takes place between the two reagents.

7. Method according to the preceding claim, characterized in that step (c) of mixing takes place with a regulation of the inlet flow rates of the first and second reagents at the inlet of said mixer / group of mixers, in particular carried out by slaving a reagent flow rates to each other.

8. Method according to one of the preceding claims, characterized in that the regulation of the inlet flow rates of the first and second reagent is carried out in step (c) to maintain a volume ratio of flow rate of the first reagent to the flow rate. of the second reagent between 2 and 4, in particular between 2.8 and 3.6, preferably from 3.1 to 3.3.

9. Method according to one of the preceding claims, characterized in that the viscosity of the mixture produced in step (c) is less than or equal to 300 cP, in particular less than or equal to 250 cP, preferably at most 30 or 40 cP.

10. Method according to one of the preceding claims, characterized in that it comprises:

- a step (d) operating continuously following the mixing step (c), step (d) being a step of spray drying the product from mixing step (c) in order to get a powder.

1 1. Process according to one of the preceding claims, characterized in that the mass concentration of alumina derivative is chosen between 5 and 30%, in particular between 10 and 20%.

12. Method according to one of the preceding claims, characterized in that, in step (b), the silica concentration of the second reagent is between 30 and 200 g / l, in particular between 40 and 60 g / l, for example about 50 g / l.

13. Method according to one of the preceding claims, characterized in that step (c) of mixing, in particular continuously, is carried out with several, in particular two, mixers in series, preferably static, or with a disperser ( 40) in series with at least one mixer (41), preferably static.