EP2763945A1 - Method for preparing a mixture of alcohols - Google Patents

Abstract

The invention relates to a method for preparing a mixture (M) comprising at least an alcohol (Aj), said method comprising the following steps: i) a step in which at least an alcohol (Ai) in the gaseous state is oligomerized, thereby producing a mixture (A); and ii) a step in which the mixture (A) is condensed to a gaseous flux and to a liquid flux corresponding to a condensed mixture (A); and iii) a step in which the condensed mixture (A) is hydrogenated in the liquid state.

Description

 Process for the preparation of a mixture of alcohols

The present invention relates to a process for preparing a mixture of alcohols. Industrially the most important alcohols are ethanol, 1-propanol, n-butanol, alcohols for plasticizers having a (C6-C1 1) alkyl chain and fatty alcohols having a (C12-C18) alkyl chain. used as detergents. These different alcohols are prepared from fossil resources either by the oxo olefins route or by the Ziegler process (trialkylaluminum oxidation) (Ziegler, K. et al., Justus Liebigs Ann.Chem 629 (1960) 1). Alcohols are also used as solvents, paint thinners (mainly light alcohols having (C1-C6) alkyl chain), as intermediates leading to esters, but also as organic compounds, as lubricants or as fuels.

 The synthesis of these alcohols is often done in several stages and leads to mixtures of alcohols. For example, alcohols having a C6 alkyl chain are synthesized by co-dimerization of butene and propene and then converted to a mixture of aldehydes by hydroformylation, before being hydrogenated, to finally lead to a mixture of alcohols having a C6 alkyl chain. For example, butanol has so far been produced largely by the process of hydroformylation of propylene a petroleum derivative (Wilkinson et al., Comprehensive Organometallic Chemistry, The synthesis, Reactions and Structures of Organometallic Compounds, Pergamon Press 1981, 8). Butanol can also be obtained by fermentary processes that are up-to-date with the rise in petroleum raw materials. Acetobutyl fermentation, better known as ABE fermentation, co-produces a mixture of ethanol, acetone and butanol in a weight ratio of about 1/3/6. The source bacterium of fermentation belongs to the family of Clostridium acetobutylicum.

Given the variety of alcohols necessary for the chemical industry and the wide range of use, there is therefore a need to implement a simplified method of forming alcohols leading to good yields (and minimizing mixtures). It is also interesting to have a flexible process allowing the use of ethanol from renewable materials to form heavier biosourced alcohols.

The object of the present invention is to provide a process comprising a simplification of the step of separating the alcohols formed. The invention also aims to prepare a mixture of alcohols without incondensable gas.

 Another object of the present invention is to provide a process for obtaining a mixture of alcohols free of aldehyde and in particular of acetaldehyde.

 In addition, the object of the invention is to provide a process for stabilizing the reaction medium.

 Another object of the present invention is to provide a process for the preparation of alcohols, in particular butanol, which is easy to implement and leads to a better overall yield of the reaction.

The subject of the present invention is therefore a process for preparing a mixture (M) comprising at least one alcohol (Aj), said process comprising the following steps:

 i) a step of oligomerization of at least one alcohol (Ai) in the gas phase leading to a mixture (A);

 ii) a condensation step of the mixture (A) leading to a gaseous flow and a liquid flow corresponding to a condensed mixture (A); and

 iii) a step of hydrogenation in the liquid phase of the mixture (A) condensed.

In the context of the invention, and unless otherwise indicated, the term "mixture (A)", a mixture from step i) of oligomerization of at least one alcohol (Ai) gas phase. The mixture (A) therefore represents a gaseous mixture at the reaction temperature.

 In the context of the invention, and unless otherwise stated, "mixture (A) condensed" means a mixture (A) which has undergone a step ii) of condensation at the end of step i). The condensed mixture (A) constitutes the mixture subjected to step iii) of hydrogenation in the liquid phase.

In the context of the invention, and unless otherwise indicated, the term "alcohols (Ai)" means alcohols whose linear or branched alkyl chain comprises n carbon atoms, with n representing an integer of from 1 to 10. According to the invention, the term "alcohols (Ai)" also includes the term "starting alcohols". The "alcohols (Al)" according to the invention can be for example: methanol, ethanol, propanol, butanol, pentanol, hexanol, heptanol, octanol, nonanol or decanol. Alcohols (Al) denote the starting alcohols before the oligomerization step.

In the context of the invention, and unless otherwise indicated, the term "alcohols (Aj)" means alcohols whose linear or branched alkyl chain comprises m carbon atoms, with m representing an integer from 2 to 20 According to the invention, the The term "alcohols (Aj)" also includes the term "formed alcohols" or "upgraded alcohols". The "alcohols (Aj)" according to the invention may be, for example, ethanol, butanol, hexanol, octanol, decanol, ethyl-2-butanol and ethyl-2-hexanol.

 In the context of the invention, the alcohols (Aj) are obtained by oligomerization of one or more alcohols (Ai).

 In the context of the invention, and unless otherwise stated, the term "oligomerization of an alcohol" means a process for converting a monomeric alcohol into an oligomeric alcohol. According to the invention, the oligomerization may for example be a dimerization.

Preferably, the alcohol (Al) is ethanol.

 According to a particular embodiment, the oligomerization is a dimerization, preferably a dimerization of ethanol. In this embodiment, the mixture (M) obtained comprises butanol.

According to a particular embodiment, the present invention relates to a process for preparing a mixture (M) comprising butanol, said process comprising the following steps:

 i) a step of oligomerization, in particular of dimerization, of gas phase ethanol leading to a mixture (A);

 ii) a step of condensing the mixture (A) leading to a gas flow and a liquid flow corresponding to the condensed mixture (A); and iii) a liquid phase hydrogenation step of the condensed mixture (A). Typically, the oligomerization stage, in particular dimerization, in the gas phase can be carried out using any reactor, generally known to those skilled in the art.

According to the invention, the alcohol (s) (Ai) used may be anhydrous or aqueous. If the alcohol (s) (Ai) used is (are) aqueous, it (they) may (s) comprise from 0.005 to 20% by weight of water relative to the total weight of alcohol (s) (Ai).

According to one aspect of the invention, step i) of oligomerization, in particular of dimerization, of the process can be carried out in the presence of an acid-base solid catalyst. Preferably, the catalyst is alkaline earth phosphate type. More particularly, the catalyst is selected from catalysts of the family of calcium hydroxyapatite (HAP) of the general formula Caio- _z (HP0 _{4) z} (P0 _{4) 6-z} (OH) ₂ - _z with 0 <z < 1. According to one embodiment, when the catalyst is chosen from calcium hydroxyapatites, the molar ratio (Ca + M) / P (with Ca representing calcium, P phosphorus and M a metal) is between 1, 5 and 2 preferably from 1.5 to 1.8, and preferably from 1.6 to 1.8. According to the invention, M may represent a metal or a metal oxide, ranging from 0 to 50 mol% of calcium substitution, in particular from 0 to 20 mol%, and may be chosen from Li, Na, K, Rb, Cs, Se, Y, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn, Zr, Nb, Mo, Ru, Rh, Pd, Ag, Hf, Ta, W, Re, Os, Ir, Pt, Au, La, Ce, Pr, Nd, Sm, Eu, Gd, Tb and Yb.

According to the invention, step i) of the process may be carried out at a temperature of from 100 ° C. to 500 ° C., preferably from 200 ° C. to 450 ° C., and preferably from 300 ° C. to 450 ° C. In particular, the temperature is from 350 ° C to 425 ° C, and more particularly from 375 ° C to 425 ° C.

According to the invention, step i) can be carried out at a pressure of from 0.3 to 6 bar absolute, and preferably from 0.8 to 5 bar absolute.

In step i) of the process of the invention, one or more alcohols (Ai), in particular ethanol, can (wind) be fed (s) in the vapor phase. The flow rate of alcohol (s) (Ai) of said step i) is from 1 to 10 g of alcohol (Ai), per hour and per g of catalyst, preferably from 1 to 8, preferably from 1 to 6 and even more preferably from 1 to 5. In particular, the flow rate of alcohol (s) (Ai) is from 2 to 6 g of alcohol (s) (Ai) per hour and per g of catalyst.

In the context of the invention, and unless otherwise stated, the term "productivity" means measuring the efficiency of the process. The productivity according to the invention corresponds to the amount of an alcohol (Aj), in particular butanol, produced per hour, for one gram of catalyst used in the process.

 In the context of the invention, and unless otherwise indicated, "yield" means the ratio expressed as a percentage, between the quantity of product obtained and the desired theoretical amount.

In the context of the invention, and unless otherwise indicated, the term "selectivity" means the number of moles of alcohol (Ai), and especially of ethanol, converted into the desired product relative to the number of moles of alcohol. (Ai), transformed. According to the invention, step i) in the gas phase (vapor phase), can lead to a mixture (A) comprising especially from 1% to 30% by weight of reducible products, considered as reaction intermediates.

In the context of the invention, and unless otherwise indicated, the term "reducible product" means a compound that can be reduced during the hydrogenation step iii), such as an alkene, an alkyne, an aldehyde or a ketone. According to the invention, the reducible products can be, for example, acetaldehyde, the crotonaldéhydes (c / ^'s and trans), the crotyl alcohol (c ^/' s and trans), the buten-1-ol, butadiene, butanal, hexenols and hexanal.

According to the invention, the mixture (A) is subjected at the end of step i) and before step iii), to a condensation step of the mixture (A) (step ii) leading to a gas flow and to a condensed mixture (A) corresponding to a liquid flow. This step makes it possible to carry out the hydrogenation reaction in the liquid phase.

According to another aspect of the invention, the condensed mixture (A) may be subjected at the end of step ii) and before step iii), to a step of separation of the liquid / gas streams, in order to eliminate the gas flow.

 According to the invention, the additional step of separating the liquid / gas flows can be carried out on the condensed mixture (A), in order to eliminate the gas flow and the non-valorized light constituents. This step advantageously makes it possible to overcome incondensable gases.

 In the context of the invention, and unless otherwise stated, "incondensable gas" means a gas that can not be condensed in a liquid phase at a temperature above 20 ° C at atmospheric pressure. According to the invention, the non-condensable gases may be for example carbon monoxide, butene, ethylene, hexene, butane, carbon dioxide, hydrogen and ethane.

Thus, the process according to the invention advantageously makes it possible to obtain a better life of the catalyst of the hydrogenation reaction. Indeed, the process according to the invention comprises a step ii) of the condensation of the reaction mixture (A) at the exit of oligomerization, in particular of dimerization, (at the end of stage i) and of separation of the liquid streams / gas, separates the incondensable gases from the liquid phase to be hydrogenated (step iii). However, these noncondensable gases contain in particular significant amounts of carbon monoxide (CO), up to 130 ppm, which is a poison of hydrogenation catalysts conventionally used industrially as nickel. This separation also makes it possible to avoid the coking of the hydrogenation catalyst, which is often due to the incondensible carbonaceous species of the ethane, ethylene, hexene, butane or butadiene type. Some of these species tend to polymerize.

 This separation also allows a saving of hydrogen since the unsaturated species, butadiene, ethylene, hexene in particular present in the gas stream are not hydrogenated.

According to one embodiment, the mixture (A) obtained at the end of step i) is cooled to a temperature of between 0 ° C. and 100 ° C. in order to condense and separate the various constituents of said mixture (A) . Cooling can be achieved using technology well known to those skilled in the art, such as a tube / shell heat exchanger or a plate heat exchanger. At the end of the condensation step ii) of the mixture (A), a vapor flow (gas flow) and a liquid flow (condensed mixture (A)) are obtained.

According to the invention, the vapor stream and the condensed mixture (A) can be separated in one or more single vapor liquid separators operating at lower and lower temperatures, including heat exchangers, in a distillation column or in these two types of equipment in series.

 At the end of the separation step, two flows can be obtained, a gas flow preferably containing at least one alcohol (Ai), in particular ethanol, and gases such as hydrogen, ethane, ethanol. ethylene or butene and a liquid stream containing the remainder of alcohol (s) (Ai) unconverted, the water from the reaction and the alcohols (Aj) valued.

According to the invention, the method may comprise a step of washing the gas stream obtained at the end of the separation step. The washing step can be carried out in an absorber in order to recover the alcohol (s) (Ai) contained, in particular ethanol, as well as acetaldehyde entrained in the gas stream resulting from the step of separation.

According to one embodiment, this absorption washing step can be carried out in a washing column operating at the minimum possible temperature, comprised between 0 ° C. and 50 ° C., depending on the cold sources available, and at the same pressure as step i) (with the pressure losses close). It can be carried out with alcohol-free water (Al), and in particular free of ethanol, or by using alcohols (Aj) produced later in the process. The gas stream from the washing step is advantageously purified so as to recover the hydrogen present in said gas stream for use in the hydrogenation step iii). In particular, the hydrogen can be purified by a pressure swing adsorption mechanism (known under the PSA technology to denote the expression Pressure Swing Adsorption), by use of a porous membrane, by absorption or by cryogenics.

According to another embodiment of the invention, the condensed mixture (A), having optionally been subjected to an additional separation step, is subjected to a step iii) of hydrogenation in the liquid phase. More specifically, the alcohol (s) (Ai), used in said step i) of the process according to the invention, present in said mixture (A) condensed and unreacted, for example ethanol, are advantageously separated from (es) alcohol (s) (Aj) also present (s) in said mixture (A) condensed by liquid / liquid separation, prior to the implementation of said step iii). According to this embodiment, said condensed mixture (A) is preferably subjected to at least one distillation step so as to obtain at least a first liquid stream comprising, preferably consisting of, the alcohol (s) (Ai) n ' unreacted during the implementation of said step i) of the process according to the invention and a second liquid stream comprising, preferably consisting of (s) alcohol (s) (Aj). According to said embodiment, the alcohol (s) (Ai) extracted (s) from said mixture (A) condensed are advantageously directly valued, for example to be introduced (s) into fuel bases.

 According to one embodiment, the condensed mixture (A) resulting from stage ii) can be brought to a temperature below 165 ° C. by a technology well known to those skilled in the art, such as a heat exchanger. shell or plate type.

According to the invention, the hydrogenation step in the liquid phase is carried out at a temperature of less than or equal to 165 ° C. In particular, the temperature is from 50 ° C to 165 ° C, preferably from 60 ° C to 162 ° C, and preferably from 80 ° C to 160 ° C.

According to the invention, the condensed mixture (A) is then brought into contact with a hydrogen flow rate sufficient to hydrogenate the reducible products. According to the invention, the hydrogen flow rate can be from 0.48 to 240 L / g _a | _C00 | _(A i gcataiys _e ur and preferably 1, 5-48 L / g aicooi (Ai) gcataiyseur under normal conditions of temperature and pressure.. According to one embodiment, the hydrogenation step in the liquid phase is carried out at a pressure greater than or equal to 10 bar. In particular, the pressure is from 10 to 50 bar, preferably from 12 to 45 bar, and preferably from 15 to 40 bar.

 According to the invention, the hydrogen used in said step iii) comes from said purified gas stream according to one of the methods described above and / or from a process for producing hydrogen using a hydrocarbon or an alcohol such as ethanol.

According to the invention, the liquid phase hydrogenation step may be carried out in the presence of a metal catalyst selected from the group consisting of Fe, Ni, Co, Cu, Cr, W, Mo, Pd, Pt, Rh and Ru, said catalyst being optionally supported. As a support, mention may be made of alumina, celite, zirconium dioxide, titanium dioxide or silica. Preferably, the catalyst used is selected from the group consisting of Ni, Co, Cu, Pd, Pt, Rh and Ru, optionally supported. The catalyst may be of the Raney nickel type.

 According to the invention, the metals can be used alone or as a mixture.

Typically, the hydrogen phase in the liquid phase can be carried out using any reactor, generally known to those skilled in the art.

 According to one embodiment, the liquid phase hydrogenation step can be carried out in a tubular or multitubular fixed bed reactor, isothermal or adiabatic, or a catalyst-coated exchanger reactor, or a reactor agitated by a self-aspirating mobile, or a venturi or tubular ejector.

 According to the invention, the catalyst used in step iii) can be immobilized, in the form of grains, extrusions or in the form of metal foam.

 According to the invention, the catalyst used in step iii) may be in the form of fine particles.

According to the invention, two different equipments can be envisaged to carry out the hydrogenation step:

 a) wherein the catalyst can be immobilized in a reactor in the form of grains or extrudates or supported on a metal foam. The reactor associated with this type of catalyst is preferably a fixed tubular or multitubular bed, isothermal or adiabatic, or a catalyst-coated exchanger reactor, operated in dripping or flooded mode;

 b) the other in which the catalyst can be in the form of fine particles (from

5 to 100 μηη of diameter) in suspension in the liquid phase. The reactor preferred for this type of catalyst may be selected from the group of reactors agitated by a self-aspirating mobile or a venturi or tubular ejector. Typically, in this type of equipment, the catalyst must then be separated by a suitable technology type tangential filter or decanter.

Preferably, the hydrogenation stage in the liquid phase is carried out in equipment of type a) described above. According to the invention, the mixture (M) obtained at the end of the hydrogenation stage is devoid of the intermediate species obtained at the end of stage i), such as alcohologens, such as crotyl alcohols (c). / ^'s and trans), butanal, buten-1-ol, hexanal or crotonaldéhydes (c ^/' s and trans), the héxénols which were reduced in the form of products of economic value. The hydrogenation step may therefore allow an increase in the yield of the reaction in all the different alcohols (Aj) generated.

 According to the invention, the mixture (M) obtained is devoid of aldehyde species, and in particular free of acetaldehyde, which allows a better stability over time of said mixture (M). According to the invention, the mixture (M) may comprise the remainder of unconverted alcohol (s) (Ai), and in particular ethanol, water resulting from the reaction and / or derived from alcohol. (s) (Ai) nine, and alcohols (Aj), especially butanol.

 According to a particular embodiment, the mixture (M) obtained according to the process may comprise at least 5% (by weight relative to the total weight of the mixture (M)) of butanol, preferably at least 8%, and preferably at least 10% butanol.

In the context of the invention, and unless otherwise indicated, the term "alcohol (Ai) nine", the alcohol (Ai) used as a starting reagent in the oligomerization reaction. According to the invention, the alcohol (Ai) new differs from the alcohol (Ai) recycling. According to the process according to the invention, said mixture (M) preferably comprises several alcohols (Aj) whose linear or branched alkyl chain comprises m carbon atoms, with m representing an integer equal to 2 or comprised from 2 to 20 Preferably, said mixture (M) comprises at least butanol (m = 4). According to another aspect of the invention, the mixture (M) comprises, besides butanol, other alcohols (Aj), the linear or branched alkyl chain of which comprises m carbon atoms, with m representing an integer equal to at 2 or from 2 to 20. More particularly, the mixture (M) may comprise, in addition to butanol, linear alcohols, such as hexanol, octanol or decanol, or branched alcohols such as ethyl-2-butanol or ethyl- 2-hexanol. According to one aspect of the invention, the process may comprise, at the end of step iii), successive distillation steps for separating the different valued alcohols from the mixture (M), as well as stages of alcohol recycling. (s) (Ai), especially ethanol.

 More particularly, the mixture (M) containing the residue of unconverted alcohol (s) (Ai), especially ethanol, the water resulting from the reaction and / or from alcohol (s) (Ai) nine (s), and the valued alcohols, can be separated into a set of distillation columns intended to recover the valuable alcohols, remove the water resulting from the reaction and the water from alcohol (s) (Ai) nine ( s) (in the case where the alcohol (s) (Ai) used for the oligomerization is (are) aqueous) and recycle the unconverted alcohol (s) (Ai) ( s) of the reaction, usually in their azeotropic form.

According to one embodiment, the mixture (M) resulting from the hydrogenation under pressure can be expanded to a pressure making it possible to carry out the separation of the azeotrope water / alcohol (s) (Ai) and of the valued alcohols.

 In the context of the invention, and unless otherwise indicated, the term "mixture (M) expanded", a mixture (M) which was expanded at the end of the hydrogenation step.

According to the invention, the expanded mixture (M) resulting from the hydrogenation can be directed to a set of two distillation columns designated C1 and C2, nested to obtain three streams:

 F1: the azeotrope water / alcohol (s) (Al), and especially the water / ethanol azeotrope, which is recycled;

 - F2: water from alcohol (s) (Ai) nine (s) and the water resulting from the reaction; and

- F3: alcohols (Aj), especially butanol. According to one embodiment, the columns C1 and C2 may be tray columns or packed columns.

The presence of the azeotrope water / alcohol (s) (Al), and in particular the water / ethanol azeotrope, makes it difficult to eliminate the water of reaction. To facilitate this separation, the phenomenon of demixing mixtures (alcohol) (Aj) / water can be used. During the distillation to obtain the alcohols (Aj) (F3) in the foot and the azeotrope water / alcohol (s) (Ai) (F1) at the head, demixing can occur to generate two liquid phases in equilibrium, a phase rich in alcohol (s) (Aj) and a phase rich in water. This phenomenon can be used to facilitate the separation of various constituents.

 The supply can be performed in column C1, the floor to optimize the performance of the whole.

 According to the invention, a decanter can be installed in the lower part of the column C1, below the supply tray which separates these two liquid phases, or the settling tank can be installed inside or outside the column. C1. The organic phase, rich in alcohol (s) (Aj) can be recycled as internal reflux of the column C1 and provides the mixture of alcohols (Aj) at the bottom of this column C1. The aqueous phase can exit column C1 and be sent to a column C2 which can be a reflux separation column or a simple stripper. This column C2 may be reboiled and may make it possible to obtain at the bottom a flow of water which is free of alcohols (Al) and (Aj), and in particular of ethanol and butanol.

 According to the invention, the distillate of the column C2 may be preferably in vapor form, this column operating at the same pressure as the column C1. The vapor phase of this column C2 can be returned to the column C1, preferably to the stage above the stage of the liquid / liquid settler. The head of column C1 is conventional and may include a condenser to obtain the reflux required for separation. The azeotrope water / alcohol (s) (Al) (F1), and in particular the water / ethanol azeotrope, can then be obtained at the top. It can be obtained in the vapor phase or in the liquid phase. If it is obtained in the vapor phase, it avoids having to vaporize it before feeding the synthesis reaction, which advantageously makes it possible to reduce the energy consumption required.

 According to the invention, the alcohols (Aj) (F3) are obtained at the bottom of the column C1. They can be separated by simple distillation in an additional C3 column to obtain the pure butanol at the head and the other alcohols (Aj) different from butanol at the bottom.

 The different alcohols (Aj) can then be separated by successive distillations to obtain these different alcohols in the order of their boiling points. Distillation of the alcohols by distillation can still be carried out by the so-called partition column distillation technique (known by the English term DWC to designate the expression Dividing Wall Column).

According to one embodiment, the alcohol (Ai) new, and in particular new ethanol, pure or containing water as well as the alcohol (Ai) recycling, including recycling ethanol, if is liquid can be vaporized and then overheated to the temperature reaction before entering a reactor where the oligomerization takes place (oligomerization reactor). If the recycling alcohol (Ai), in particular the recycle ethanol, is in vapor form, the alcohol (Ai) new, and especially the fresh ethanol, may be vaporized and then superheated to the reaction temperature before to enter the oligomerization reactor.

The method according to the invention advantageously allows an increase in the overall yield of the reaction, a simplification of the separation step of the alcohols (Aj) formed and a stabilization of the reaction medium.

 The hydrogenation step in the liquid phase advantageously allows a better selectivity than a process comprising a step of hydrogenation in the gas phase. Indeed, the gas phase hydrogenation of batches resulting from an oligomerization, and in particular a dimerization, of alcohol (s) (Al), and in particular ethanol, on acid-base catalysts is not complete; In particular, aldehydes such as acetaldehyde remain, as has been observed in application EP 2206763. This is due to a thermodynamic equilibrium. However, acetaldehyde is not a valuable product and causes separation problems. Indeed, the separation of ethanol and acetaldehyde is difficult because there is an azeotrope.

 It has been found that by hydrogenating these batches in the liquid phase, a complete reduction of all species is obtained, including acetaldehyde which forms ethanol. Thus, the process according to the invention makes it possible to facilitate the separations insofar as the mixture comprises one less species to be separated and that there are fewer acetaldehyde-alcohol binaries. The ethanol formed from the acetaldehyde according to the invention can then be reinjected into the process. This has the effect of lowering the conversion of ethanol and thus increasing selectivities and yields of valuable alcohols, especially butanol. Thus, the hydrogenation stage in the liquid phase makes it possible to improve the efficiency and the overall selectivity of the process. Moreover, the hydrogenation in liquid phase is interesting because it allows to stabilize the mixture over time, due to the absence of aldehyde species.

The hydrogenation stage in the liquid phase is advantageous for reducing the size of the process. In fact, a hydrogenation in the liquid phase makes it possible to use smaller amounts of hydrogen and catalyst than for hydrogenation in the gas phase (of which a molar excess of H ₂ is necessary), while maintaining a high efficiency. The following examples illustrate the invention without limiting it. Examples

Example 1: Hydrogenation Liquid Phase with Catalyst Ni (HTC) at 130 ° C.

To a reactor (80 cm in height, diameter 2.8 cm) containing 68 g of calcium hydroxyapatite (Ca / P ratio = 1.71) (supplier: Sangi), 3.1 ml / min of 99.8% ethanol pds (water qs 100) were fed. The reaction temperature was 390 ° C and the pressure was 1 bar absolute. A liquid phase was recovered after condensation at 10 ° C of the mixture at the reactor outlet. The hydrogenation was carried out on a batch of 200 g of the liquid phase previously collected in an autoclave under a pressure of 30 bar of hydrogen, at 130 ° C. for 30 minutes with 2 g of nickel-bearing supported on alumina catalyst Johnson Matthey (Or HTC 500, extruded 1, 2mm containing 21% by weight of nickel), activated according to the supplier's recommendations. The mixture resulting from this hydrogenation step was injected, after filtration, into a gas chromatography (Agilent HP6890N GC, HP-innowax (PEG) 30mxO column, 25mm × W, 25 m, FID detector, cyclohexanol internal standard). The conversion of ethanol is 31.2%. The weight percentages of the different products quantified are as follows:

 Butanol: 16%

 Diethyl ether: 0.2%

 Ethyl butanol: 1, 4%

Hexanol: 1, 8%

 Ethyl-Hexanol: 0.3%

 Octanol: 0.25%

 Xylene: 0.08%

 Acetaldehyde: 0%

Crotyl alcohol and isomers: 0%

 Hexen-1-ol: 0%

 Butanal: 0%

 Crotonaldehyde: 0%

Hexanal: 0% Thus, a butanol yield of 19.6% and a productivity of 0.34 g of butanol per hour and per g of catalyst were obtained. No trace of aldehydes or unsaturations was detected, confirming that the hydrogenation was complete. EXAMPLE 2 Hydrogenation Liquid Phase with Ni Catalyst (HTC) Powdered at 120 ° C.

To a reactor (80 cm in height, diameter 2.8 cm) containing 68 g of calcium hydroxyapatite (Ca / P ratio = 1.71) (supplier: Sangi), 5.35 ml / min of 99.8% ethanol pds (water qs 100) were fed. The reaction temperature was 400 ° C, the pressure was 1 bar absolute. A liquid phase was recovered after condensation at 10 ° C of the mixture at the reactor outlet. The hydrogenation was carried out on a batch of 200 g of the liquid phase previously collected in an autoclave under a pressure of 30 bar of hydrogen, at 120 ° C. for 30 minutes with 2 g of nickel catalyst supported on ground alumina powder. supplier Johnson Matthey (Ni HTC 500, containing 21% nickel by weight), activated according to the supplier's recommendations. The mixture resulting from this hydrogenation step was injected, after filtration, into a gas chromatography (Agilent HP6890N GC, HP-innowax (PEG) 30mxO column, 25mm × W, 25 m, FID detector, cyclohexanol internal standard).

The conversion of ethanol is 25.5%. The weight percentages of the different products are as follows:

 Butanol: 13.9%

 Diethyl ether: 0.1%

 Ethyl butanol: 1%

 Hexanol: 1, 4%

Ethyl-Hexanol: 0.2%

 Octanol: 0.17%

 Xylene: 0.06%

 Acetaldehyde: 0%

 Crotyl alcohol and isomers: 0%

Hexen-1-ol: 0%

 Butanal: 0%

 Crotonaldehyde: 0%

Hexanal: 0% Thus, a butanol yield of 17% and a productivity of 0.51 g of butanol per hour and per g of catalyst were obtained. No trace of aldehydes or unsaturations was detected, the hydrogenation was complete. In addition, it was noted that 100% of the committed mass was recovered, so there was no cracking of the material in CO and methane.

EXAMPLE 3 Hydrogenation Liquid Phase with Ni (HTC) Catalyst at 120 ° C., Dimerization Resulting from a Different Ca / P Ratio

 To a reactor (80 cm in height, diameter 2.8 cm) containing 72 g of calcium hydroxyapatite (Ca / P ratio = 1.685) (supplier: Sangi), 5.65 ml / min of 95% w ethanol ( water qs 100) were fed. The reaction temperature was 400 ° C, the pressure was 1 bar absolute. A liquid phase was recovered after condensation at 10 ° C of the mixture at the reactor outlet. The hydrogenation was carried out on a batch of 200 g of the liquid phase previously collected in an autoclave under a pressure of 30 bar of hydrogen, at 120 ° C. for 30 minutes with 2 g of nickel-bearing supported on alumina catalyst Johnson Matthey (Or HTC 500, extruded 1, 2mm containing 21% by weight of nickel), activated according to the supplier's recommendations. The mixture resulting from this hydrogenation step was injected, after filtration, into a gas chromatography (Agilent HP6890N GC, HP-innowax (PEG) 30mxO column, 25mm × W, 25 m, FID detector, cyclohexanol internal standard).

The conversion of ethanol is 20%. The weight percentages of the different products are as follows:

 Butanol: 10.4%

 Diethyl ether: 0.1%

 Ethyl butanol: 0.9%

 Hexanol: 1%

Ethyl-Hexanol: 0.12%

 Octanol: 0.14%

 Xylene: 0.06%

 Acetaldehyde: 0%

 Crotyl alcohol and isomers: 0%

Hexen-1-ol: 0%

 Butanal: 0%

 Crotonaldehyde: 0%

Hexanal: 0% Thus, a butanol yield of 17% and a productivity of 0.51 g of butanol per hour and per g of catalyst were obtained. No trace of aldehydes or unsaturations was detected, so the hydrogenation was complete. Example 4: liquid phase hydrogenation with Co (HTC) catalyst at 130 ° C.

 To a reactor (80 cm in height, diameter 2.8 cm) containing 68 g of calcium hydroxyapatite (Ca / P ratio = 1.71) (supplier: Sangi), 5.35 ml / min of 99.8% ethanol pds (water qs 100) were fed. The reaction temperature was 400 ° C, the pressure was 1 bar absolute. A liquid phase after condensation at 10 ° C of the mixture at the reactor outlet. The hydrogenation was carried out on a batch of 200 g of the liquid phase previously collected in an autoclave under a pressure of 30 bar of hydrogen, at 130 ° C. for 30 minutes with 2 g of alumina-supported cobalt catalyst from Johnson Matthey supplier. (HTC 2000 Co, extruded 1, 2mm containing 15% by weight of cobalt), activated according to the supplier's recommendations. The mixture resulting from this hydrogenation step was injected, after filtration, into a gas chromatography (Agilent HP6890N GC, HP-innowax (PEG) 30mxO column, 25mm × W, 25 m, FID detector, cyclohexanol internal standard).

The conversion of ethanol is 30.4%. The weight percentages of the different products are as follows:

 Butanol: 15%

 Diethyl ether: 0.1%

 Ethyl butanol: 1, 25%

 Hexanol: 1, 55%

Ethyl-Hexanol: 0.28%

 Octanol: 0.2%

 Xylene: 0.06%

 Acetaldehyde: 0%

 Crotyl alcohol and isomers: 0%

Hexen-1-ol: 0%

 Butanal: 0%

 Crotonaldehyde: 0%

Hexanal: 0% Thus, a butanol yield of 18.4% and a productivity of 0.55 g of butanol per hour and per g of catalyst were obtained. No trace of aldehydes or unsaturations was detected, so the hydrogenation was complete. EXAMPLE 5 Hydrogenation Liquid Phase with Ni-3354E Catalyst (BASF) Powdered at 120 ° C.

 To a reactor (80 cm in height, diameter 2.8 cm) containing 68 g of calcium hydroxyapatite (Ca / P ratio = 1.71) (supplier: Sangi), 5.35 ml / min of 99.8% ethanol wt (water qs 100) was fed. The reaction temperature was 400 ° C, the pressure was 1 bar absolute. A liquid phase was recovered after condensation at 10 ° C of the mixture at the reactor outlet. The hydrogenation was carried out on a batch of 200 g of the liquid phase previously collected in an autoclave under a pressure of 30 bar of hydrogen, at 120 ° C. for 30 minutes with 2 g of nickel catalyst supported on ground silica powder. BASF supplier (Ni-3354 E, containing 60% by weight of nickel), activated according to the supplier's recommendations. The mixture resulting from this hydrogenation step was injected, after filtration, into a gas chromatography (Agilent HP6890N GC, HP-innowax (PEG) 30mxO column, 25mm × W, 25 m, FID detector, cyclohexanol internal standard). The conversion of ethanol is 25.9%. The weight percentages of the different products are as follows:

 Butanol: 13.9%

 Diethyl ether: 0.1%

 Ethyl butanol: 1%

Hexanol: 1, 4%

 Ethyl-Hexanol: 0.2%

 Octanol: 0.17%

 Xylene: 0.06%

 Acetaldehyde: 0%

Crotyl alcohol and isomers: 0%

 Hexen-1-ol: 0%

 Butanal: 0%

 Crotonaldehyde: 0%

Hexanal: 0% Thus, a butanol yield of 17% and a productivity of 0.51 g of butanol per hour and per g of catalyst were obtained. No trace of aldehydes or unsaturations was detected, so the hydrogenation was complete. It was observed that 100% of the committed mass was recovered, so there was no cracking of the material in CO and methane.

Example 6: Hydrogenation Liquid Phase with Catalyst Ni (HTC) at 160 ° C.

To a reactor (80 cm in height, diameter 2.8 cm) containing 68 g of calcium hydroxyapatite (Ca / P ratio = 1.71) (supplier: Sangi), 3.1 ml / min of 99.8% ethanol pds (water qs 100) were fed. The reaction temperature was 390 ° C., the pressure was 1 bar absolute. A liquid phase was recovered after condensation at 10 ° C of the mixture at the reactor outlet. The hydrogenation was carried out on a batch of 200 g of the liquid phase previously collected in an autoclave under a pressure of 30 bar of hydrogen, at 160 ° C. for 30 minutes with 2 g of nickel-bearing catalyst supported on alumina by supplier Johnson Matthey. (Or HTC 500, extruded 1, 2mm containing 21% by weight of nickel), activated according to the supplier's recommendations. The mixture resulting from this hydrogenation step was injected, after filtration, into a gas chromatography (Agilent HP6890N GC, HP-innowax (PEG) 30mxO column, 25mm × W, 25 m, FID detector, cyclohexanol internal standard). The conversion of ethanol is 30.8%. The weight percentages of the different products are as follows:

 Butanol: 16.2%

 Diethyl ether: 0.2%

 Ethyl butanol: 1, 43%

Hexanol: 1.87%

 Ethyl-Hexanol: 0.34%

 Octanol: 0.26%

 Xylene: 0.1%

 Acetaldehyde: 0%

Crotyl alcohol and isomers: 0%

 Hexen-1-ol: 0%

 Butanal: 0%

 Crotonaldehyde: 0%

Hexanal: 0% Thus, a butanol yield of 19.8% and a productivity of 0.34 g of butanol per hour and per g of catalyst were obtained. No trace of aldehydes or unsaturations was detected, the hydrogenation was complete. In addition, it was observed that 100% of the committed mass was recovered, so there was no cracking of the material in CO and methane (loss of material).

Example 7 (Comparative Example): hydrogenation gas phase

 This example corresponds to amounts identical to Example 6, but with a different hydrogenation equipment adapted for gaseous phases.

To a reactor (80 cm in height, diameter 2.8 cm) containing 68 g of calcium hydroxyapatite (Ca / P ratio = 1.71) (supplier: Sangi), 3.1 ml / min of 99.8% ethanol pds (water qs 100) were fed. The reaction temperature was 390 ° C., the pressure was 1 bar absolute. A liquid phase was recovered after condensation at 10 ° C of the mixture at the reactor outlet. On a batch resulting from this dimerization (378 g), hydrogenation in the gas phase was carried out with 16.8 g of 0.5% Pd / SiO ₂ catalyst (by weight) from the supplier Calcicat (beads of 3 to 5 mm in diameter). immobilized in a glass reactor (height 20 cm, diameter 2.8 cm) at 150 ° C. with a flow rate of 50 ml / min of hydrogen at atmospheric pressure and a flow rate of liquid to be hydrogenated of 0.55 ml / min. The conversion of ethanol is 34%. The weight percentages of the different products are as follows:

 Butanol: 15.43%

 Diethyl ether: 0.08%

 Ethyl butanol: 1, 29%

Hexanol: 1.77%

 Ethyl-Hexanol: 0.3%

 Octanol: 0.23%

 Xylene: 0.06%

 Acetaldehyde: 0.84% (corresponding to 2.54% of selectivity)

Crotyl alcohol and isomers: 0.05%

Hexen-1-ol: 0%

Butanal: 0%

Crotonaldehyde: 0%

Hexanal: 0% Thus, under hydrogenation conditions in the gas phase, 0.84% by weight of acetaldehyde remains after hydrogenation.

Example 8 (comparative example): hydrogenation gas phase with another catalyst and a different flow rate

To a reactor (80 cm in height, diameter 2.8 cm) containing 68 g of calcium hydroxyapatite (Ca / P ratio = 1.71) (supplier: Sangi), 3.1 ml / min of 99.8% ethanol pds (water qs 100) were fed. The reaction temperature was 390 ° C., the pressure was 1 bar absolute. A liquid phase was recovered after condensation at 10 ° C of the mixture at the reactor outlet. On a batch resulting from this dimerization (193 g), a hydrogenation was carried out with 14.4 g of catalyst 13% (by weight) CuO / SiO ₂ from the supplier Evonik-Degussa (beads 3 to 5 mm in diameter) immobilized in a glass reactor (height 20 cm, diameter 2.8 cm) at 150 ° C. with a hydrogen flow rate of 100 ml / min at atmospheric pressure and a liquid flow rate to be hydrogenated of 0.55 ml / min.

The conversion of ethanol is 31.6%. The weight percentages of the different products are as follows:

 Butanol: 15.18%

 Diethyl ether: 0.08%

Ethyl butanol: 1.74%

 Hexanol: 1.41%

 Ethyl-Hexanol: 0.3%

 Octanol: 0.15%

 Xylene: 0.06%

Acetaldehyde: 0.79% (2.57% selectivity)

 Crotyl alcohol and isomers: 0.06%

 Hexen-1-ol: 0%

 Butanal: 0%

 Crotonaldehyde: 0%

Hexanal: 0%

Thus, under hydrogenation conditions in the gas phase, 0.79% by weight of acetaldehyde remains after hydrogenation. In view of Example 7, it has been observed that even by changing the nature of the catalyst and increasing the flow of hydrogen, the presence of acetaldehyde remains problematic. EXAMPLE 8 (Comparative Example): hydrogenation gas phase at a high temperature A reactor (80 cm in height, diameter 2.8 cm) containing 68 g of calcium hydroxyapatite (Ca / P ratio = 1.71) (supplier: Sangi), 3.1 ml / min of ethanol at 99.8 wt.% (Water qs 100) were fed. The reaction temperature was 390 ° C., the pressure was 1 bar absolute. A liquid phase was recovered after condensation at 10 ° C of the mixture at the reactor outlet. On a batch resulting from this dimerization (193 g), a hydrogenation was carried out with 14.4 g of catalyst 13% (by weight) CuO / SiO ₂ from the supplier Evonik-Degussa (beads 3 to 5 mm in diameter) immobilized in a glass reactor at 180 ° C with a hydrogen flow rate of 100 ml / min at atmospheric pressure and a liquid flow rate to be hydrogenated of 0.55 ml / min.

The conversion of ethanol is 31.16%. The weight percentages of the different products are as follows:

 Butanol: 15.64%

Diethyl ether: 0.08%

 Ethyl butanol: 1, 42%

 Hexanol: 1.75%

 Ethyl-Hexanol: 0.3%

 Octanol: 0.22%

Xylene: 0.06%

 Acetaldehyde: 0.72% (2.4% selectivity)

 Crotyl alcohol and isomers: 0.06%

 Hexen-1-ol: 0%

 Butanal: 0%

Crotonaldehyde: 0%

 Hexanal: 0%

Thus, under hydrogenation conditions in the gas phase, 0.79% by weight of acetaldehyde remains after hydrogenation. It has thus been observed that even by increasing the temperature of the hydrogenation reaction in the gas phase, acetaldehyde is present and remains problematic.

Simulations were made using the Aspen simulation software to estimate the equilibrium acetaldehyde and hydrogen that gives ethanol under these conditions. With the thermodynamic properties present in the simulator, the hydrogenation under the conditions of flow, composition, pressure and temperature above led to a in acetaldehyde of 1.3% by weight in the liquid collected for a temperature of 150 ° C and a hydrogen flow rate of 50 ml / min. This confirms, to the calculation errors and measurement ready that the hydrogenation of acetaldehyde is not total gas phase.

Example 9: Demonstration of CO Formation at the Dimerization Outlet:

 To a reactor (height 12 cm, diameter 1 cm) containing 6 g of calcium hydroxyapatite of Ca / P ratio = 1.67 (supplier: Sangi), 0.47 ml / min of ethanol at 95 wt% (water qs 100) were powered. The temperature was 400 ° C, the pressure of 1 bar absolute.

 An ethanol conversion of 25.7% was observed and the following selectivities:

It should be noted that a selectivity of 0.1% (CO) corresponds to 0.013% (by weight) or 130 ppm of CO in the stream to be hydrogenated. This level is largely sufficient to deactivate a hydrogenation catalyst very rapidly.

Example 10 (Comparative Example): Cracking During a Gas Phase Hydrogenation

To a reactor (height 12 cm, diameter 1 cm) containing 6 g of calcium hydroxyapatite of Ca / P ratio = 1.67 (supplier: Sangi), 0.47 ml / min of ethanol at 95 wt% (water qs 100) were powered. The temperature was 400 ° C, the pressure of 1 bar absolute. This dimerization was followed by hydrogenation with 7.7g of a commercial Ni HTC catalyst (extruded) from Johnson Matthey at 150 ° C under atmospheric pressure with a hydrogen flow rate of 33ml / min. An ethanol conversion of 24.6% was observed and the following selectivities:

The selectivities of the table above correspond to the following percentages (by weight):

 Butanol: 12%

 Diethyl ether: 0.3%

 Ethyl butanol: 1%

 Hexanol: 1, 2%

 Ethyl-Hexanol: 0.2%

 Octanol: 0.1%

 Xylene: 0.2%

 Acetaldehyde: 1, 4%

 Crotyl alcohol and isomers: 0%

 Hexen-1-ol: 0%

 Butanal: 0.2%

 Crotonaldehyde: 0%

 Hexanal: 0.1%

It was thus observed the formation of CO and methane markers of the loss of material in the gas phase hydrogenation. These products are difficult to separate and therefore not valued.

This hydrogenation was carried out with the same catalyst as Example 1 (liquid phase) but in the gas phase this time. It has been observed that acetaldehyde (and other aldehydes) is always present at the end of hydrogenation, during hydrogenation in the gas phase. On the other hand, during the hydrogenation in the liquid phase (Example 1), no trace of acetaldehyde was observed (or other aldehydes). This shows the advantage of working in the liquid phase.

Claims

A process for preparing a mixture (M) comprising at least one alcohol (Aj), said process comprising the following steps:

 i) an oligomerization step of at least one alcohol (Ai) in the gas phase leading to a mixture (A); and

 ii) a condensation step of the mixture (A) leading to a gaseous flow and a liquid flow corresponding to a condensed mixture (A); and

 iii) a step of hydrogenation in the liquid phase of the mixture (A) condensed.

Process according to claim 1, characterized in that step i) is a dimerization of ethanol.

Process according to Claim 1 or 2, characterized in that the mixture (M) comprises butanol.

Process according to any one of Claims 1 to 3, characterized in that the mixture (M) comprises several alcohols (Aj) whose linear or branched alkyl chain comprises m carbon atoms, with m equal to 2 or inclusive of 2 to 20.

Process according to any one of Claims 1 to 4, characterized in that step i) is carried out in the presence of an alkaline earth phosphate catalyst.

Process according to any one of Claims 1 to 5, characterized in that the catalyst is chosen from calcium hydroxyapatites.

Process according to Claim 6, characterized in that the molar ratio (Ca + M) / P of the calcium hydroxyapatite is from 1.5 to 2, preferably from 1.6 to 1.8, M being a metal.

8. Process according to any one of claims 1 to 7, characterized in that step i) is carried out at a temperature of 100 ° C to 500 ° C, preferably 300 ° C to 450 ° C.

9. Process according to any one of claims 1 to 8, characterized in that step i) is carried out at a pressure of from 0.3 to 6 bar absolute, preferably from 0.8 to 5 bar absolute.

10. Process according to any one of claims 1 to 9, characterized in that the flow rate of alcohol (s) (Ai) of step i) is from 1 to 10 g of alcohol (s) (Ai). ), per hour and per gram of catalyst. A process according to any one of claims 1 to 10, characterized in that the liquid phase hydrogenation step is carried out in the presence of a metal catalyst, selected from the group consisting of Fe, Ni, Co, Cu, Cr, W, Mo, Pd, Pt, Rh and Ru, said catalyst possibly being supported. 12. The method of claim 1 1, characterized in that the catalyst is immobilized in the form of grains, extrudates or in the form of metal foam.

13. The method of claim 1 1, characterized in that the catalyst is in the form of fine particles.

14. Process according to any one of Claims 1 to 13, characterized in that the hydrogenation step in the liquid phase is carried out at a temperature of between 50 ° C and 165 ° C, preferably between 80 ° C and 160 ° C. vs.

15. Method according to any one of claims 1 to 14, characterized in that the hydrogenation step in the liquid phase is carried out at a pressure of 10 to 50 bar, preferably 15 to 40 bar. 16. Process according to any one of Claims 1 to 15, characterized in that the liquid phase hydrogenation step is carried out in a fixed-bed tubular or multitubular, isothermal or adiabatic bed reactor; or a catalyst-coated exchanger reactor; or a reactor agitated by a self-aspirating mobile or a venturi or tubular ejector.

17. Method according to any one of claims 1 to 16, characterized in that the condensed mixture (A) is subjected at the end of step ii) and before step iii), to a separation step of liquid / gas flow, in order to obtain a liquid flow and eliminate the gas flow.

18. A method according to any one of claims 1 to 17, characterized in that it comprises, at the end of step iii), successive distillation steps for separating the different alcohols from the mixture (M), and as stages of recycling alcohol (s) (Ai).

19. Method according to one of claims 1 to 18 characterized in that the (s) alcohol (s) (Ai), implemented in said step i), present (s) in said mixture (A) condensed and n unreacted, are separated from the alcohol (s) (Aj) present (s) in said mixture (A) condensed by liquid / liquid separation, prior to the implementation of said step iii).