FR2946045A1 - METHOD FOR MANUFACTURING SOLID CARBON MATERIAL WITH ADJUSTED PROPERTY (S), MATERIAL THAT CAN BE OBTAINED BY THE PROCESS, BIOHUILES ADDITIVE AS PRECURSORS - Google Patents

Abstract

The invention relates to a method for producing a solid carbon material with controllable property (s) for the purpose of catalyzing the destruction of pollutants contained in a fluid, the material obtainable by the process bio-additives additives as precursors of the material.

Description

TECHNICAL FIELD The present invention belongs to the field of solid carbonaceous materials. It relates more particularly to the manufacture of a solid carbonaceous material at least one property (s) can be adjusted to catalyze the destruction of pollutants contained in a fluid. STATE OF THE ART Using thermochemical gasification processes, the biomass can be converted into a synthesis gas consisting essentially of carbon monoxide (CO) and hydrogen (H2). However, these conversion processes have the disadvantage that they also generate degradation by-products (tars, soot, etc.) which pollute the synthesis gas formed, thus penalizing its recovery through processes such as cogeneration processes. or Fischer-Tropsch biofuel synthesis. In order to obtain the purest possible synthesis gas, one of the solutions consists in carrying out the thermochemical conversion of the biomass while at the same time catalysing the destruction of the pollutants formed at a temperature most often between 800 ° C. and 1400 ° C. , using for example a conversion process said medium temperature (800 ° C to 1000 ° C) or high temperature (1100 ° C to 1400 ° C). The medium temperature conversion processes can be catalyzed using inorganic catalysts such as

-2- those based on natural ores (dolomite, olivine) or nickel. These inorganic catalysts nevertheless have at least one disadvantage such as a high manufacturing cost, a tendency to deactivate (in particular by poisoning or coking) and a low mechanical strength from 900 ° C. to 1000 ° C., which prevents their setting in motion. in high temperature conversion processes. Carbonaceous materials have one of the best efficiency / cost ratios to catalyze the destruction of pollutants, because they are generally less expensive to produce (some can be manufactured in situ) and less sensitive to the decline in catalytic efficiency. . They can also be used at a higher temperature than the implementation of the inorganic catalysts, which is particularly intended for the catalysis of high temperature conversion processes. These carbonaceous materials are mainly derived from the heat treatment of i) coal (obtaining activated carbon, ...), ii) solid biomass (solid carbonaceous residue obtained by carbonization / slow pyrolysis and usually spontaneous biomass), or iii) gases such as acetylene, propylene (obtaining pyrocarbons or soot). Their catalytic efficiency is improved by accentuating intrinsic characteristics such as: - the amorphous character (weak structural organization) and the presence of energetic instabilities (free valence, degree of aromaticity, punctual defect, electronic gap, discontinuity, ...) which are conducive to the formation of active sites; the specific surface, a large value of this parameter generally inducing a large catalytic efficiency;

The ratio (microporosity and / or mesoporosity) / total porosity, the micropores and mesopores having the advantage of limiting the gasification and therefore the consumption of the carbonaceous material, while participating in the dissociative absorption mechanism of methane and tars; ; the presence of heteroatoms, such as oxygen or hydrogen, which can form active intermediate species for the conversion of pollutants (in particular tars); the content of inorganic element, intrinsic catalyst of certain reactions of reforming / destroying tars. However, it is difficult or impossible to adjust or optimize one or more of the characteristics of carbon materials of the prior art to improve their catalytic efficiency. Catalytic optimization thus poses numerous problems for the first category of carbon material mentioned above (catalyst derived from coal).

As indicated above for all the carbon-based catalysts, the catalytic efficiency of the coal depends on its amorphous nature. For example, during the catalysis of the methane conversion, this efficiency decreases when we go from lignite (amorphous structure) to bituminous coal (turbostratic structure) and graphite (graphitic structure), as described in document Bai. Z. et al, Hydrogen production by methane decomposition over coal char, International Journal of Hydrogen Energy, 2006, vol. 31, pp. 899-905 [1].

However, the structure of a carbon-based catalyst derived from coal is highly dependent on the original coal chosen to develop it. In particular, it is very difficult to significantly increase the degree of amorphousness of this carbon catalyst relative to that of its original carbon. Regarding the specific surface area of a catalyst derived from coal, even if this characteristic can be improved by chemical treatment (with water vapor, CO2r, etc.) as described in patent application EP 1897852 (KUREHA CORP) [4], such treatment is generally not compatible with the increase of the ratio (microporosity and / or mesoporosity) / total porosity. The amount of oxygen or hydrogen heteroatoms in the catalyst again depends on that of the original coal, it is generally low and can not be easily modified. Finally, the content of inorganic element (such as ash) is a characteristic of the catalyst which is also limited by the nature of the original coal. In order to remedy this, US Pat. Nos. 4,087,378 (CARLSON DAVID H. J.) [2] and WO / 1994/000383 (MINNESOTA MINING AND MANUFACTURING COMPANY) [3] propose to impregnate a coal with an inorganic element. However, these impregnations tend to cover the active sites of the coal and to clog the pores, which goes against the objective of increasing the specific surface area and the microporosity and / or mesoporosity. In addition, these processes require large amounts of solution or impregnation times, which makes them expensive and generate effluents. As regards the second category of catalysts mentioned above, the carbonaceous materials derived from solid biomass may possibly have a content of heteroatoms (such as oxygen and hydrogen) and a degree of aromaticity that are not negligible, even if all like charcoals, such characteristics can vary greatly depending on the composition of the initial biomass and the heat treatment that made it possible to obtain such materials.

Impregnations in inorganic element or chemical treatments aimed at developing the specific surface may again be carried out, but these processes generally have the same disadvantages as those encountered with catalysts derived from coal. As regards the last category of catalysts mentioned above, the catalysts resulting from the heat treatment of gaseous feeds generally have a developed graphitic structure which is unfavorable to their intrinsic reactivity. In particular, pyrocarbons have a relatively isotropic structure.

These catalysts also develop a greater or lesser specific surface area according to the parameters of the heat treatment process. Finally, it is difficult to ensure the presence of heteroatom or inorganic element within this type of catalyst because of the very nature of the precursors (gaseous feeds). It therefore appears that the carbon catalysts currently used have one or more characteristics that are difficult or impossible to adjust (or even optimize) in order to increase their catalytic power, particularly with respect to destruction reactions. pollutants (in particular tars) contained in a synthesis gas obtained by gasification of the biomass.

One of the aims of the invention is precisely to meet this need by providing a method for manufacturing a solid carbonaceous material, all or part of the structure and / or composition characteristics of which can be easily modified, in particular in view of a more high efficiency as a catalyst of the destruction reactions of the pollutants contained in a synthesis gas.

SUMMARY OF THE INVENTION The present invention thus relates to a method of manufacturing a solid carbonaceous material, comprising the following successive steps. a) at least one additive is incorporated in a base bio-oil to prepare an additive bio-oil; b) heating said additive bio-oil by applying a temperature gradient of between 50 ° C / s and 5000 ° C / s to obtain said carbonaceous solid material. The invention also relates to the solid carbonaceous material that can be obtained by this manufacturing process, as well as additivated bio-oils constituting the precursors of this material.

Finally, the invention relates to a solid carbonaceous material, its uses, and a part comprising this material. Other objects, features and advantages of the invention will now be specified in the description which follows, given by way of illustration and not limitation, with reference to the following appended figures.

BRIEF DESCRIPTION OF THE FIGURES Figure 1 is a graph showing the mass variation of a base bio-oil as a function of temperature. Figures 2a and 3a schematize two possible orientations graphene carbon materials. Figures 2b and 3b show Transmission Electron Microscopy (TEM) photographs of carbonaceous materials. Figure 4 is a diagram showing the essential steps and the main optional steps of the manufacturing method of the invention. Figure 5 illustrates the regenerative capacity of the specific surface of the solid carbonaceous material of the invention by opening its initially closed porosity. FIG. 6 is a graph showing the evolution of the catalytic efficiency as a function of the duration of use of the solid carbonaceous material of the invention. Figure 7 is a graph showing the amount of gas volatilizing during the additional heat treatment of the manufacturing process of the invention.

DETAILED DESCRIPTION OF THE INVENTION The term "heater" designates a heat treatment carried out in the absence of oxygen (thermolysis) or in the latter's fault (pyrolysis), the presence of oxygen not being generally prohibitive for the implementation of the process. of the invention, as long as its concentration does not exceed a few% (typically 3%) of the volume of the reaction atmosphere in which this process takes place.

The term base bio-oil defines a mixture in variable proportions of mostly carbonaceous molecules, such a mixture generally comprising one or more elements belonging to the group of phenols, sugars, alcohols, organic acids. The base bio oil can also contain water. The average elemental composition of the base bio-oil can in particular be such that, subjected to an increasing temperature at a speed of less than 100 ° C./minutes, this bio-oil generally has a mass variation (dM / dT) in which the molecules it contains most of the time divided into three main ranges of volatilization temperature (which may be partly related to their molecular weight) as shown in Figure 1 or described for example in the documents Branca C. et al., Multistep mechanism for

The Devolatilization of Biomass Fast Pyrolysis Oils, Industrial Eng. Chem. Research, 2006, 45, 5891 [5] or Garcia-Perez M. et al., Characterization of Bio-Oils in Chemical Families, Biomass and Bioenergy, 2007, vol. 31, pp. 222-242 [6]. At a temperature of 25 ° C., this composition can generally be represented by a crude formula of the CH 1,900,7E type, the stoichiometric indices of hydrogen and oxygen being able to vary to plus or minus 30 atomic%.

Element E represents one or more elements, different from C, H or O, selected for example from the group consisting of Si, N, K, Mg, Na, and P. The value of The index E is generally such that the mass proportion within the basic bio-oil of the element E (or, if appropriate, the sum of the elements E) is less than 1%. The base bio-oil, in particular the basic bio-oil of synthetic origin as defined below, generally has an amorphous character such that the proportion of cyclic carbon (saturated or unsaturated aromatic cycle) can vary from 20% to 80% (preferably 30% to 70%) relative to the total number of constituent carbon atoms of the base bio-oil, such that: 0.2 <_ (unsaturated Ccycle + saturated Ccycle) / Ctotal <0 8

The amounts unsaturated Ccycle, saturated Ccycle, and Ctotal can be evaluated by methods known to those skilled in the art such as Nuclear Magnetic Resonance (NMR) or Transmission Electron Microscopy (TEM). In practice, the number of carbon atoms integrated in a cycle (saturated or not) in the base bio-oil is most often lower (generally at least 10%) than that of any type of carbon or the carbon residue. solid obtained after pyrolysis of biomass. The base bio-oil and the additive bio-oil can be liquid. This state is generally not stable: at room temperature, these bio-oils can freeze more or less quickly, typically after a week to a few months depending on the storage conditions (brightness, humidity, ...). A paste is then obtained. It constitutes an intermediate state between a liquid phase and a solid phase. If necessary, the passage of the base bio-oil or the bio-oil with a liquid state to a pasty state can be accelerated or even provoked by subjecting it to slow pyrolysis generally consisting in applying a temperature of between 100 ° C. and 600 ° C. C at a temperature rise rate of less than 100 ° C / s.

Regarding the origin of the base bio-oil, it can be obtained in different ways. Generally, said base bio-oil according to the invention constitutes the liquid phase obtained after rapid pyrolysis of a condensed carbonaceous material, typically a condensed carbonaceous material of organic origin. The term "condensed carbonaceous material" is understood to mean a carbonaceous material which is in the form of a condensed phase (for example a liquid, pasty or solid phase), which excludes in particular a gaseous phase. The average elemental composition of this carbonaceous condensed material is generally represented by the formula CHXOyEZ, wherein 0 <x <4 and / or 0 <-y <1. E represents one or more elements, as defined previously for the base bio-oil. The value of the index z is generally such that the mass proportion within the solid carbonaceous material of the element E (or, if appropriate, the sum of the elements E) is between 0% and 60% of the dry mass of the condensed carbonaceous material.

Preferably, this condensed carbonaceous material is biomass (such as lignocellulosic biomass), or a naturally occurring carbonaceous condensed matter such as coal, sludge or even natural gas or methane which are then liquefied. . For the purposes of the invention, biomass covers any organic carbon substance that can become a source of energy (wood, plants, organic waste, etc.), as defined in Article 2 of the European Directive 2001 / 77 / EC of 27 September 2001. Rapid pyrolysis is generally characterized by pyrolysis in which a temperature of between 400 ° C and 1000 ° C is applied according to a temperature gradient of between 100 ° C / s and 1000 ° C / s. .

This is for example a pyrolysis flash pyrolysis in which one can apply a temperature below 1000 ° C at a speed between 500 ° C / s and 1000 ° C / s. According to the invention, the basic bio-oil obtained at the end of the rapid pyrolysis of the biomass can in particular be described in terms of composition, structure and properties in the book Fast Pyrolysis of Biomass: A handbook, CPL Press, 2008, Bridgwater AV et al, ISBN-13: 978-1872691077 [7], in particular chapters 1, 2, 5, 7, 9, 11. Alternatively, the base bio-oil used in the manufacturing process of the invention is of synthetic origin, in that it results from the mixing of specific molecules incorporated at the desired concentrations. The synthetic base bio-oil respects all or some of the definitions of the basic bio-oil as previously indicated. Preferably, it simulates the basic bio-oil obtained by rapid pyrolysis of the condensed-carbon-containing material, preferably the biomass, preferably lignocellulosic-type biomass. By way of example, Table 1 illustrates the bulk composition of a synthetic base bio-oil. Table 1 Molecules% by mass Phenol 11.0 Acetic Acid 23.5 Levoglucosan 6.0 Eugenol 19.0 Lignin (or constituent 3.5 elements of the monolignol type) Hexadecanoic acid 8.0 Naphthalene 0.5 P-Xylene 0.5 Water The condensed carbonaceous material (preferably biomass) for rapid pyrolysis to produce the base bio-oil according to the invention may itself be of synthetic origin. This synthetic carbonaceous condensed material then preferably simulates the lignocellulosic type biomass, it then generally comprises at least one molecule chosen from the group consisting of lignin (in its various forms, or of molecules resulting from its transformation or purification), cellulose, hemicellulose, and a degradation product of these 20 molecules. One of the essential characteristics of the manufacturing process of the invention resides in the use of an additivated bio-oil having one or more characteristics conferred in particular by the additive (s) it contains. the la5

Unexpectedly, while the state of the art is most often subjected to the presence of a bio-oil and strives to stabilize its initial liquid state (to counteract its tendency to solidification in the form of a paste) , on the contrary, the process of the invention takes advantage of this solidification tendency to transmit to the solid carbonaceous material all or part of the advantageous characteristics (in particular of structure and / or composition) of the additivated bio-oil.

This tendency is even accentuated by increasing the rate of solidification of the additive-enriched bio-oil by virtue of another essential characteristic of the process of the invention which is the heating of the additivated bio-oil, such a heat treatment making it possible to solidify the bio-oil additive while freezing. as quickly as possible the aforementioned characteristics of this bio-oil before they deteriorate. To obtain such an effect, the heating of the additive bio-oil is characterized by a temperature rise rate of between 50 ° C./s and 5000 ° C./s. A rate of rise in temperature higher than 5000 ° C / s is however not prohibitive for the implementation of the manufacturing method of the invention. Under such conditions, the solid carbonaceous material is generally obtained after a time of between 0.1 to 10 seconds of heating. Advantageously, the state in which the additive bio-oil (in particular the liquid state) is present is favorable to the optimal absorption of the thermal energy necessary for its rapid solidification, despite the application of the high temperature gradient of its own. to the heating. The heating according to the invention can be obtained by various techniques known to those skilled in the art.

A temperature gradient of between 50 ° C./s and 5000 ° C./s can be obtained by heating the bio-oil with added

By sonochemistry, by microwave, or with the aid of a piston furnace which makes it possible to impose a thermal shock on the additive-like bio-oil such as the piston furnace described in the document Thermal shock resistance of thermomechanical ceramics PhD thesis, National Institute of Applied Sciences of Lyon, France, 1991, P. Peigne [8]. When the temperature gradient of the heater according to the invention is between 50 ° C./s and 1000 ° C./s, the heating may consist of a flash pyrolysis that can be carried out using methods known to those skilled in the art. such as those using an ablation pyrolyser or a cyclone furnace. Preferably, the temperature gradient of the heating process of the invention is between 1500 ° C / s and 5000 ° C / s (even more preferably between 2000 ° C / s and 5000 ° C / s) in order to achieve an even higher rate of solidification. Such a gradient allows an optimal transfer of the aforementioned characteristics of the additive-based bio-oil to the solid carbonaceous material, or even, if appropriate, the creation of micro-explosions due to the fact that the volatilization rate of certain molecules of the additive-containing bio-oil becomes lower than the rate of absorption of thermal energy by this same bio-oil. These micro-explosions lead to the fractionation of the additive bio-oil, which accentuates the advantageous effects of the rapid solidification caused by a high temperature gradient. The minimum temperature that can be reached during the heating is generally 100 ° C (temperature from which the vaporization of the water occurs and thus the solidification of the bio-oil additive). Preferably, the minimum temperature is that from which all the constituent molecules of the additive bio-oil are pyrolyzed, that is most often a temperature of between 500 ° C. and 600 ° C. at which all the lignitic derivatives have been charred.

The maximum temperature of the heating is only limited by the sublimation destruction of the solid carbonaceous material. However, this maximum temperature is preferably 2000 ° C (graphitization temperature of most carbonaceous materials at atmospheric pressure) in order to better preserve the amorphous nature of the solid carbonaceous material. The temperature applied during the heating is thus most often between 500 ° C and 2000 ° C.

Preferably, the maximum temperature of the heating is set such that at least one of the inorganic elements contained in the additive bio-oil does not volatilize completely, or that at least one of these inorganic elements (or their mixtures) does not become liquefied. not. Even more preferably, this maximum temperature is less than 1300 ° C.-1400 ° C., the temperature above which the compounds comprising hydrogen and / or oxygen generally all volatilize significantly (as shown in FIG. in Figure 7) and the solid carbonaceous material can be densified by decreasing its porosity. Of course, these minimum and maximum temperature values are given at atmospheric pressure. Those skilled in the art will be able to adapt them according to the pressure of implementation of the manufacturing method of the invention. Regarding the additive incorporated in the base bio-oil of the manufacturing process of the invention, it may be any type of additive known to those skilled in the art to confer a specific property. The incorporated additive generally represents from 0.5% to 70% by weight of the additivated bio-oil. Ideally, the additive is soluble in the basic bio-oil except as indicated below where it consists of a solid particle. If necessary, the base bio-oil is brought to a temperature between 20 ° C and 90 ° C to facilitate the incorporation of the additive. The incorporation of the additive can be carried out by simple mixing of the base bio-oil in liquid form with the additive, which makes it possible to obtain a particularly homogeneous mixture. When the base bio-oil is in the form of a paste, this incorporation can be carried out by mixing / kneading.

The additive incorporated in particular makes it possible to confer an improved catalytic power on the solid carbonaceous material which then acts as a catalyst. Throughout the description of the invention, the term "catalyst" may also denote a pseudocatalyst, namely a solid carbonaceous material which is wholly or partly consumed during the reaction which it promotes (it is considered here that it is a catalysis despite the consumption of the pseudo-catalyst). For example, a solid carbonaceous pseudocatalyst may be consumed by the gasification reaction that it catalyzes. The catalytic power of the solid carbonaceous material is favored by the fact that all or part of the complex and heterogeneous nature of the base bio-oil (notably the presence of structural defects, of heteroatoms such as oxygen and hydrogen) is advantageously transferred. to the solid carbonaceous material, via the additive bio-oil, by the manufacturing method of the invention. The catalytic power of the solid carbonaceous material is furthermore improved by the rate of rise in temperature specific to the heating (and in particular by a high value of this speed), such heating having the particular advantages of: increasing the total porosity of the makes rapid degassing imposed by the heat gradient can be high heating. -16- to minimize or avoid graphitization (or even destroy the graphitic structures), in order to better preserve the heterogeneous nature of the additive bio-oil. The microstructure of the solid carbonaceous material of the invention is then such that a portion of the graphenes (graphite structural units) it contains has anisotropic orientations (cleaved plane structure) as illustrated by the diagram of FIG. 2a. and by the Transmission Electron Microscopy (TEM) micrograph of Figure 2b. This microstructure is to be compared with the conventional graphite microstructure (graphene with parallel planes) illustrated in Figures 3a and 3b. to limit the vaporization of (i) catalytically active volatile or semi-volatile substances which may be initially contained in the base bio-oil (eg compounds comprising hydrogen and / or oxygen) and / or (ii) loss of an additive included in the bio-oil additive. Preferably, said at least one additive incorporated in the base bio-oil to prepare an additive bio-oil is an additive or a mixture of several additives chosen from the group consisting of a solid particle, an inorganic element, a compound comprising hydrogen and / or oxygen, a surfactant, a gas, an oxidizing agent, and a pore-forming agent. The additivated bio-oil can thus comprise several additives of the same type (for example several surfactants of distinct structure) or of different types (for example a solid particle and a surfactant).

The percentages by weight for each type of additive contained in the bio-oil additive as indicated below refer to the percentage by weight for this additive when it is the only one of this type, or if appropriate to the sum percentages by weight of the additives of the same type when they are several.

Preferably, said additive is said solid particle constituting from 5% to 70% by weight of said additivated bio-oil (even more preferably from 30% to 70% by weight). This amount ensures that the emulsion formed generally has a viscosity such that the additive bio-oil is pumpable for the industrialization of the process of the invention. It can nevertheless vary depending on parameters such as the particle size of the particles or the energy applied to produce the emulsion.

Said solid particle preferably has a mean size of between 0.1 .mu.m and 50 .mu.m, more preferably between 1 .mu.m and 10 .mu.m. This average size corresponds to the average value of the diameter of the solid particle when it is substantially spherical, or to the average value of its main dimensions when it is not substantially spherical. The average size of the solid particle preferably follows an at least bimodal particle size distribution. This distribution can be determined by laser diffraction or according to the method defined by the ISO 15901-1 2005 standard, using, for example, a high-resolution X-ray microtomograph or a high-energy radiograph tomograph.

Preferably, the height ratio between a first distribution profile centered on a determined average size and a second distribution profile centered on the next higher average size is 10, which has the effect of favoring a high particle content by weight. solid within the bio-oil additive approaching the compact stacking model. Thus, in the case of a trimodal particle size distribution in which the profiles P1, P2 and P3 designate profiles centered on an increasing mean size, the corresponding heights of these profiles are such that: H1 / H2 = H2 / H3 = 10. The solid particle has the advantage that it constitutes a nucleation and heterogeneity point which favors the polycondensation of the molecules contained in the additive bio-oil, and thus its transition from the liquid state to the paste state. or in the solid state when it is subjected to the manufacturing process of the invention. The solid particle also makes it possible to create structural defects in the additivated bio-oil, which makes it possible to increase the amorphous nature of the solid carbonaceous material obtained by the process of the invention. Finally, it constitutes a point of attachment of germination by presence of defects which promotes the formation of bubbles during the fractionation of the bio-additive oil. Said solid particle is preferably composed of more than 50% by weight of carbon. This solid carbonaceous particle is for example part of the family of fines (particles comprising one or more carbonaceous substances (or their derivatives) such as lignin, cellulose, biomass, and preferably charcoal, activated carbon). This is for example the solid carbon residue obtained by rapid pyrolysis of a condensed carbonaceous material, (preferably biomass, for example lignocellulosic biomass), such a residue conferring an increased catalytic power to the solid carbonaceous material in which it is incorporated. For example, Table 2 shows the average elemental composition of wood and carbon residues that can be obtained by slow pyrolysis at different temperatures. Table 2 Product Composition% by weight of carbon Wood CH1.53O0.74 47.3 Carbonated residue at 400 ° C CH0.5800,19 76.8 Carbonated residue at 600 ° C CH0.27O0007 89.6 Carbonated residue at 800 ° C. CH0,2800,06 90,6 -19- By their generally black color, the solid carbonaceous particles constitute as many black bodies (in the thermal sense of the term) having the capacity to generate by radiation a strong and localized elevation of the temperature, which promotes a high rate of solidification of the bio-oil additive during the process of the invention. The additive incorporated in the base bio-oil can also be an inorganic element.

It can be provided in native form, compound comprising the inorganic element, or salt. These forms may comprise more than one inorganic element. Preferably, said inorganic element as an additive constitutes from 0.1% to 30% by weight of said additive-added bio-oil (even more preferably from 5% to 30%, or even 10% to 30%). This amount refers to the weight of the inorganic element only, regardless of whether or not it is included in a compound (or salt) incorporating the inorganic element. Said inorganic element is preferably selected from the group consisting of K, Mg, Fe, Ni, Co and / or mixtures thereof. Generally, at the temperature of use of the solid carbonaceous material, the inorganic element is in solid form and / or it does not produce a precipitate, liquid or even volatile or semi-volatile material likely to constitute a polluting material. Advantageously, the presence of an inorganic element in the additivated bio-oil makes it possible to avoid the disadvantages of the methods of the state of the art in which an inorganic element impregnation is carried out a posteriori on a solid carbonaceous catalyst, these disadvantages being in particular the clogging of the active sites, the poor distribution of the inorganic element, the production of effluents as well as higher production costs. The additive may also consist of a compound comprising hydrogen and / or oxygen, such that the additive bio-oil has an excess of at least one of these heteroatoms relative to the average elemental composition of the basic bio oil. This excess is generally such that said additive-containing bio-oil comprises, in additional amount relative to said base bio-oil, from 5% to 30% of moles of oxygen and / or from 5% to 50% of moles of hydrogen supplied (s). ) by said compound as an additive. The excess is generally maximum for a temperature, applied during the heating, which is between 300 ° C and 1000 ° C.

This incorporation makes it possible in particular to compensate for the possible loss, for example during the heating of the process of the invention, of hydrogen and / or oxygen initially present in the base bio-oil. Generally, with respect to the carbonaceous residue resulting from the pyrolysis of biomass, an exemplary composition of which is indicated in Table 2, the solid carbonaceous material of the invention may thus have an excess of hydrogen and / or oxygen which remains up to a temperature of the order of 1300 ° C. Beyond this temperature, the hydrogenated and / or oxygenated compounds contained in the bio-oil additive or initially contained in the base bio-oil are generally volatilized. Preferentially, the hydrogenated and / or oxygenated compounds included in the additivated bio-oil comprise carbon. Even more preferentially, they comprise, at least in part, oxygen in the form of a function of the -CO or even -C = O type, these functions exhibiting binding energies between the carbon atom and the oxygen which guarantee an increased stability of this compound vis-à-vis the temperature. This stability allows in particular

To avoid or limit the degassing of such compounds at the temperature of use of the solid carbonaceous material. For example, the compound comprising hydrogen and / or oxygen may be selected from the group consisting of water, carboxylic acids, alcohols, and / or mixtures thereof. The compound comprising hydrogen and / or oxygen may also comprise an inorganic element as defined above. Said compound comprising hydrogen and / or oxygen is for example a metal oxide, preferably iron oxide. A surfactant may also be incorporated as an additive to the bio-oil of the base in order to foam the bio-oil additive as indicated below.

Said surfactant as an additive preferably constitutes from 0.1% to 5% by weight of said additivated bio-oil (even more preferably between 0.1 and 1%). Preferably, said surfactant is a nonionic surfactant whose elementary composition advantageously comprises a large part of hydrogen and / or oxygen, and / or it is free of inorganic element as defined above. The nonionic surfactant is preferably a sugar ester or a nonylphenol ethoxylate. The sugar ester may be selected from the group consisting of ethyl stearate, methyl stearate, methyl oleate, methyl palmitate, and / or mixtures thereof. Still preferentially, the surfactant is a surfactant that does not contain an inorganic element (such as sodium) that is detrimental to the catalytic effect of the solid carbon material or that promotes corrosion. The additive may also consist of a gas, the added gas then being generally dissolved in the additive bio-oil. The dissolution of the gas can be promoted by subjecting the additive-treated bio-oil to an overpressure (typically a pressure of between 1 and 30 bars). Generally, the amount of gas added is such that said gas as an additive constitutes from 0.1% to 5% by weight of said additive-containing bio-oil (preferably from 1% to 5% by weight). The addition of the gas to the base bio-oil can be achieved by different methods. The gas can be added directly to the base bio-oil, for example by bubbling. This gas is then most often an inert gas such as nitrogen or argon. Alternatively, the added gas is generated in the base bio-oil using a pore-forming agent (preferably soluble) which then constitutes an additive within the meaning of the invention. The blowing agent is then generally added in an amount such that it constitutes, as an additive, from 0.1% to 1% by weight of said additivated bio-oil. It is chosen from the porogenic agents known to those skilled in the art. According to another embodiment, the added gas is generated by oxidation of the base bio-oil with an oxidizing agent, which can lead to extreme fractionation of the additive-containing bio-oil in the form of a foam.

Generally, said oxidizing agent constitutes, as an additive, from 0.1% to 5% by weight of said additivated bio-oil. The oxidizing agent may be a molecule such as hydrogen peroxide, an acid, or even an oxidizing reaction gas such as carbon monoxide, carbon dioxide or oxygen. After adding the gas according to one of these methods, said gas as an additive generally undergoes expansion during said heating to form gas bubbles within said additive bio-oil. The expansion may be preceded by a pressurization of the additivated bio-oil (typically a pressure of between 1 and 30 bar). This formation of gas bubbles makes it possible to generate a total porosity (in particular a closed porosity) within the solid carbonaceous material obtained at the end of the heating. It generally consists in bringing the gas-additive bio-oil to a temperature of between 20 ° C. and 90 ° C. and a pressure of 1 to 30 bars. Then, during the heating, a sudden decrease in the pressure (pressure between 0.1 to 20 bar) (or the thermal shock due to this heating) causes the expansion of the gas and generates gas bubbles whose diameter can be less than 1 μm, or even less than 50 nm. The formation of gas bubbles can be promoted by the presence of solid particles as an additive which constitute points of attachment of the bubbles.

The size of the bubbles may be reduced in the additive-enriched bio-oil to result in particular in microbubbles (bubbles with a diameter of less than 1 μm, or even 50 nm), so that the total resulting porosity of the solid carbonaceous material comprises a significant part. at least one type of porosity such as microporosity, mesoporosity, closed porosity. This decrease in the size of the bubbles can be achieved by: - decreasing the pressure of the gas as an additive during its expansion or the average size of the solid particle as an additive, or - promoting the rate of volatilization and / or degradation of constituent compounds of the additive bio-oil (by increasing the temperature gradient of the heating), which leads to the fractionation of the bubbles. Thus, preferably, the total porosity of the solid carbonaceous material is such that the ratio (microporosity + mesoporosity) / total porosity is between 10% and 80%. Such a ratio has the advantage of i) limiting the gasification and therefore the consumption of the solid carbonaceous material of the invention, and ii) participating in the

Dissociative absorption mechanism of methane and tars. Total porosity results from the sum of open porosity and closed porosity. The measurement methods for determining these porosities are detailed below. The closed porosity may represent an important part of the total porosity of the solid carbonaceous material (preferably between 1% and 60% of the volume of the total porosity, even more preferably between 20% and 60%, and even between 40% and 60%). . Still preferentially, the manufacturing method of the invention may further comprise different steps detailed in the description which follows. The main preferred steps are diagrammatically represented in dashed lines in FIG. 4. Thus, in a particular embodiment, the absorption of the thermal energy by said additive bio-oil can be further improved by carrying out its fractionation during said heating. For the purposes of the invention, the fractionation denotes an operation for breaking up the additivated bio-oil. Preferably, the fractionation of said additivated bio-oil is carried out by controlled micro-explosion, by sonochemistry, or by the formation of gas bubbles within the bio-additive oil as described above. The fractionation is facilitated when it is carried out with a low viscosity additive bio-oil such as a bio-oil additive in liquid form and / or prepared from a synthetic base bio-oil. The controlled micro-explosion can be carried out by adding an explosive (or explosive) gas to the additive bio-oil, generally to a quantity such that the additive-containing bio-oil comprises from 0.1% to 5% by weight of the explosive (or explosive) gas. Explosive (or explosive) gas is typically selected from the group consisting of CH4, H2, C3H8 and / or mixtures thereof. It is added in the absence of oxygen or air for safety reasons.

Preferably, said additivated bio-oil is in the form of a foam or droplets, in particular after said fractionation. The additive-based bio-oil in the form of a foam advantageously consists of a film whose small thickness (less than a few microns) promotes optimal and isothermal absorption of the thermal energy transmitted during heating. In another particular embodiment of the process of the invention, said additive bio-oil is in paste form. It can then be shaped before said heating by an operation such as molding, extrusion, injection. This makes it possible to obtain a solid carbon material of specific shape after the process of the invention, with a view to producing a piece of complex shape with good precision in industrial series. According to another particular embodiment, said solid carbonaceous material obtained at the end of said heating of the manufacturing method of the invention may undergo at least one additional treatment such as additional heat treatment, chemical etching, grinding. The additional heat treatment consists in bringing the solid carbonaceous material to a temperature equal to or greater than its temperature of use as a catalyst (denoted the catalyst), namely typically at a temperature which does not exceed that of the heating and which does not exceed In practice, the temperature applied during the additional heat treatment is generally between 500 ° C. and 1300 ° C. Such a treatment makes it possible to avoid or limit the degassing of volatile or semi-volatile molecules of the solid carbonaceous material when it is used as a catalyst while at the same time best preserving its amorphous nature, the presence of oxygen, d hydrogen and inorganic element provided as an additive. As shown schematically in FIG. 7, it can consist in the application of different isothermal stages during which molecules which have similar evaporation temperatures volatilize together. The last step corresponds to the application of a temperature higher than the temperature Tcataiyseur. The additional heat treatment may be of reduced speed (5 to 100 ° C / minute). It is generally short-lived (typically from 10 to 30 minutes) in order not to favor the graphitization of the solid carbonaceous material. Alternatively, it may also consist in the application of a high thermal gradient according to the heating step of the process of the invention in order to minimize or avoid the graphitization of the carbon (or even destroy the graphitic structures) as indicated above. In order to increase the total porosity and the specific surface area of the solid carbonaceous material, the additional treatment carried out at the end of the heating step of the process of the invention may also consist of a chemical attack (by carbon dioxide, water vapor, ...) by one of the methods known to those skilled in the art. This attack is generally carried out at a temperature of between 20 ° C. and 1300 ° C.

Grinding can also be carried out so that the solid carbonaceous material is in the form of a powder with a particle size favorable for the intended use, for example to increase the specific surface area of the solid carbonaceous material if it is intended to be used as a catalyst. The powder of solid carbonaceous material obtained after grinding can be compacted in order to shape the solid carbonaceous material obtained by the manufacturing method of the invention.

A binder (eg water) and / or a blowing agent may be added to the solid carbonaceous material powder prior to compaction. Compaction is generally carried out under an atmosphere composed of a gas (such as carbon dioxide, argon, nitrogen, helium) and / or at a temperature between 20 ° C and 600 ° C. The invention also relates to the solid carbonaceous material obtainable by the manufacturing method described above, which differs in particular from the solid carbonaceous materials of the state of the art by the combination of a specific surface, a porosity and of a particular amorphous character. These microstructure characteristics are advantageously obtained by the application of a high heating rate intended to solidify an additivated bio-oil, such speed notably making it possible i) to better preserve the amorphous nature of the additive-containing bio-oil and ii) to provoke volatilization. all or part of the volatile matter contained in the additive-containing bio-oil in order to obtain a specific surface area and a porosity specific to the solid carbonaceous material of the invention. The invention also relates to a number of additive-containing bio-oils (and / or mixtures thereof) which may be suitable for carrying out the manufacturing process of the invention, and which may, in a preferred manner, comprise one or more of the characteristics of the additive-containing bio-oil such as ) as previously described for the manufacturing method of the invention. These additive bio-oils are characterized by the fact that they comprise: from 5% to 70% by weight of at least one solid particle as an additive to a base bio-oil and / or - 5% at 30% by weight of at least one inorganic element as an additive to a base bio-oil and / or, in additional amount relative to a base bio-oil, from 5% to 30% by moles of oxygen and or 5% to 50% moles of hydrogen provided by at least one compound as an additive to a base bio-oil and / or from 0.1% to 5% by weight of at least a surfactant as an additive to a base bio-oil and / or - from 0.1% to 5% by weight of at least one gas (preferably dissolved) as an additive to a base bio-oil and / or from 0.1% to 1% by weight of at least one pore-forming agent as an additive to a base bio-oil and / or from 0.1% to 5% by weight of at least one agent oxidant as an additive to a basic bio-oil. Preferably, this additivated bio-oil is prepared from a base bio-oil obtained after a rapid pyrolysis of a condensed carbonaceous material, preferably the biomass, more preferably the lignocellulosic biomass. Alternatively, the bio-oil additive according to the invention is prepared from a basic bio-oil of synthetic origin as described above. The bio-oil additive according to the invention may be in the form of foam or paste. When it is in the form of a paste of sufficient viscosity to exhibit good mechanical strength, the additivated bio-oil can be shaped to form a pasty preform intended to produce a piece of specific geometry. The invention also relates to a solid carbonaceous material comprising at least one additive, the microstructure of said solid carbonaceous material being such that it has both. A BET specific surface area of between 50 m 2 / g and 2000 m 2 / g, a total porosity of between 800 mm 3 / g and 1300 mm 3 / g, in which the volume due to the microporosity and the mesoporosity represents between 10% and 80% of the volume of the total porosity, - an amorphous character such that the ratio between the amount of carbon of graphitic structure and the total amount of carbon is between 20% and 95%.

The joint production of a BET surface area of between 50 m 2 / g and 2000 m 2 / g and a total porosity of between 800 mm 3 / g and 1300 mm 3 / g, in which the volume due to the microporosity and the mesoporosity represents between 10% and 80% of the volume of the total porosity, is unexpected, characteristics of such a value being commonly considered as incompatible. Indeed, the specific surface of a solid carbonaceous material is most often developed by subjecting it to a chemical and / or thermal attack. However, this manufacturing method of the state of the art does not provide significant microporosity and mesoporosity. These porosities however have the advantage of limiting the gasification and therefore the consumption of the solid carbonaceous material, while participating where appropriate in the destruction of pollutants such as methane and tars contained in a fluid. The characteristics specific to the microstructure of the solid carbonaceous material of the invention can be determined as indicated below.

The BET specific surface area can be measured using a method such as that defined in the standard DIN 66131 or NF X 11 622. The total porosity (complement of the compactness) expressed in mm 3 / g can in turn be determined by statistical observation of images taken in Scanning Electron Microscopy (SEM) in section of the solid carbonaceous material, or by a method known to those skilled in powder metallurgy (for example the measuring method such as described in DIN 25494). The total porosity can also be determined indirectly by a method known to those skilled in the art in which the solid carbonaceous material is measured: the mass and apparent volume (volume excluding closed porosity) in order to calculate the bulk density; the open porosity (for example by pyknometry or immersion) and the true density (for example by flotation (hydrostatic measurement) of the density of the very finely ground sample, or by X-ray imaging), which makes it possible to calculate the porosity closed (comparing true density and apparent density), - total porosity which is the sum of closed porosity and open porosity. Microporosity and macroporosity refer to pores as defined by the International Union of Pure and Applied Chemistry (IUPAC) classification, namely pores having an average diameter of less than 2 nm and greater than 50 nm, respectively. Mesoporosity denotes pores of intermediate average diameter, namely a mean diameter of between 2 nm and 50 nm. The distribution of the average pore size may in particular be determined by statistical image analysis taken in Electron Microscopy or by a method such as that described in Adsorption of CO, and SO 2 on activated carbon with a wide range of micropore size distribution, M MOLINA-SABIO and Al., Carbon, 1995, Vol. 33, No. 12, Pages 1777-1782 [9]. The amounts of carbon of graphitic structure and of total carbon of the solid carbonaceous material can be measured by X-ray diffraction. The solid carbonaceous material of the invention not comprising any additive generally has at 25 ° C. an elemental composition in accordance with the present invention. formula CH, -Oy-E = ,.

The stoichiometric indices x 'and y' are such that 0 <- x '<-1.5 and 0 y' S 1 and / or 0.01 <x '+ y' <2.5. Preferably, these indices are such that 0.003 ≤ 0.03 and / or 0.001 ≤ 0.008.

Element E represents one or more elements, as defined previously for the base bio-oil and the condensed carbonaceous material. The value of the index z 'may be such that the mass proportion within the solid carbonaceous material of the element E (or, if appropriate, the sum of the elements E) is less than 1%. By way of example, the elemental composition without additive of the solid carbonaceous material of the invention is CH0, 1900.04 at 1000 ° C., the stoichiometric indices of hydrogen and oxygen being able to vary to more or less 30%. atomic, preferably at plus or minus 15 atomic%. Generally, the apparent density of the solid carbonaceous material without additive represents less than 90% (or even less than 80%) of the theoretical density of graphite generally considered to be 2.25. Preferably, the solid carbonaceous material of the invention has one or more of the following microstructure characteristics. a BET specific surface area of between 200 m 2 / g and 2000 m 2 / g; the volume due to the microporosity and the mesoporosity represents between 20% and 80% of the volume of the total porosity; the ratio between the amount of carbon of graphitic structure and the total amount of carbon is between 20% and 80% (even more preferably between 20% and 50%); the closed porosity represents between 1% and 60% of the volume of said total porosity (even more preferably between 20% and 60%, or even between 40% and 60%). The advantage of the solid carbonaceous material as a catalyst resides in particular in its specific porosity. The open pores of the solid carbonaceous material are in direct contact with the external environment. They thus increase its specific surface and thus its catalytic capacity. After prolonged use of the solid carbonaceous material, especially as a catalyst, the open pores may, however, be clogged by the products resulting from the catalyzed reactions, or their wall may be consumed when it acts as a pseudo catalyst. These two phenomena can greatly reduce the life of the solid carbonaceous material. However, they do not affect the closed pores of the solid carbonaceous material, the latter being not accessible by the external environment. Advantageously, the solid carbonaceous material thus comprises a large part of closed pores which are moreover generally distributed homogeneously throughout its volume. These closed pores can regenerate the solid carbonaceous material to compensate for the decrease in specific surface area due to the loss of initial open porosity. This regeneration can be carried out either by grinding the solid carbonaceous material or by gradually opening the initially closed porosity in the case where the solid carbonaceous material acting as a pseudocatalyst is, for example, consumed by gasification during its use in an atmosphere containing water vapor or CO2.

This ability of the solid carbonaceous material of the invention to regenerate is illustrated in FIG. 5 in which the progressive opening of the closed porosity (denoted PF) makes it possible to create a new open porosity (denoted PO2) which is added to the initial open porosity (denoted PO1) of the solid carbonaceous material. As shown diagrammatically in FIG. 6, the specific surface area of the solid carbonaceous material thus remains stable longer or decreases less rapidly during use, which notably allows its catalytic power to be prolonged. Still preferentially, the solid carbonaceous material of the invention has one or more of the following composition characteristics. said at least one additive is distributed homogeneously in the mass of the solid carbonaceous material (ie within the material constituting the solid carbonaceous material, which excludes the pores of this material); the solid carbonaceous material comprises, in additional weight relative to the weight of carbon which constitutes it, from 0.1% to 1% oxygen and / or from 0.025% to 0.25% hydrogen by weight originating from the constituent molecules of a basic bio-oil; said at least one additive is an additive or a mixture of several additives selected from the group consisting of a solid particle, an inorganic element, a compound comprising hydrogen and / or oxygen, and a gas; said additive is said solid particle constituting from 5% to 70% (or even 10% to 40%) by weight of said solid carbonaceous material; said solid particle is composed of more than 50% by weight of carbon; said solid particle is the carbon residue obtained by rapid pyrolysis of a condensed carbonaceous material; said solid particle has a mean size of between 0.1 μm and 50 μm; said additive is said inorganic element constituting from 0.1% to 30% (or even 5% to 25%) by weight of said solid carbonaceous material; said inorganic element is selected from the group consisting of K, Mg, Fe, Ni, Co and / or mixtures thereof; The solid carbonaceous material comprises, in additional weight relative to the weight of carbon constituting it, from 1% to 130% (or even 10% to 130%) of oxygen and / or from 0.1% to 12.5% (or even 1% to 12.5%) of hydrogen by weight provided by said compound as an additive; said compound comprising hydrogen and / or oxygen is a metal oxide; said additive is said gas constituting from 0.1% to 5% by weight of said solid carbonaceous material.

In a particular embodiment, the solid carbonaceous material is in the form of a solid preform intended to produce a piece of specific geometry. The invention also relates to the use as a catalyst of the solid carbonaceous material, preferably for catalyzing the destruction of pollutants contained in a fluid. Such a fluid is in particular a gas or a liquid such as an oil, a waste water. Preferably, the solid carbonaceous material of the invention catalyzes the destruction of the pollutants contained in a synthesis gas resulting from the thermochemical conversion of the biomass. This destruction may possibly be carried out simultaneously or as a result of the thermochemical conversion of the biomass at medium or high temperature (800 ° C. to 1200 ° C.) indicated previously. The invention also relates to the use of the solid carbonaceous material for making a filter element. The solid carbonaceous material can thus be shaped to form a filtering element in which the open porosity is preferred with respect to the porosity of closed porosity, for example by grinding the solid carbonaceous material of the invention in powder form. . The invention also relates to a part comprising the solid carbonaceous material. It is clear from the foregoing description that the process of the invention makes it possible to manufacture a solid carbonaceous material which, while retaining good mechanical strength, temperatures generally between 800 ° C and 1200 ° C, has one or more characteristics of structure and / or composition which can be easily adjusted or even optimized, in particular with a view to greater efficiency for catalyzing pollutant destruction reactions contained in a synthesis gas. REFERENCES CITED [1] Bai Z. et al, Hydrogen production by methane decomposition over coal char, International Journal of Hydrogen Energy, 2006, vol. 31, pp. 899-905. [2] US 4,087,378 [3] WO / 1994/000383 [4] [5] Branca C. et al., Multistep mechanism for the devolatilization of biomass fast pyrolysis oils, Industrial Eng. Chem. Research, 2006, 45, 5891 [6] Garcia-Perez M. et al., Characterization of Biooils in Chemical Families, Biomass and Bioenergy, 2007, vol. 31, pp 222-242. [7] Fast Pyrolysis of Biomass. A handbook, CPL Press, 2008, Bridgwater AV et al, ISBN-13978-1872691077 [8] Thermal shock resistance of thermomechanical ceramics, PhD thesis, National Institute of Applied Sciences of Lyon, France, 1991, P. Peigne [ 9] Adsorption of CO, and SO2 on activated carbons with a wide range of micropore size distribution, M. MOLINASABIO and Al., Carbon, 1995, Vol. 33, No. 12, Pages 1777-1782

Claims (35)

CLAIMS1) A method of manufacturing a solid carbonaceous material, comprising the following successive steps a) at least one additive is incorporated in a basic bio-oil to prepare an additive bio-oil; b) heating said additive bio-oil by applying a temperature gradient of between 50 ° C / s and 5000 ° C / s to obtain said carbonaceous solid material. 2) The manufacturing method according to claim 1, wherein said base bio-oil constitutes the liquid phase obtained after a rapid pyrolysis of a condensed carbonaceous material. 3) The manufacturing method according to claim 2, wherein said condensed carbonaceous material is biomass. 4) The manufacturing method according to claim 3, wherein the biomass is lignocellulosic biomass. 5) The manufacturing method according to claim 1, wherein said base bio-oil is of synthetic origin. 6) A manufacturing method according to any one of the preceding claims, wherein said temperature gradient is between 1500 ° C / s and 5000 ° C / s. 7) A manufacturing method according to any one of the preceding claims, wherein said at least one additive is an additive or a mixture of several additives selected from the group consisting of a solid particle, an inorganic element, a compound comprising hydrogen and / or oxygen, a surfactant, a gas, an oxidizing agent, and a blowing agent. 8) The manufacturing method according to claim 7, wherein said additive is said solid particle constituting from 5% to 70% by weight of said additive bio-oil. 9) A manufacturing method according to claim 7 or 8, wherein said solid particle is composed of more than 50% by weight of carbon. 15 10) A manufacturing method according to any one of claims 7 to 9, wherein said solid particle is the solid carbon residue obtained by rapid pyrolysis of a condensed carbonaceous material. 20 11) The manufacturing method according to any one of claims 7 to 10, wherein said solid particle has an average size between 0.1 pm and 50 pm. 12) A manufacturing method according to any one of claims 7 to 11, wherein said additive is said inorganic element constituting from 0.1% to 30% by weight of said additive bio-oil. 13) A manufacturing method according to any one of claims 7 to 12, wherein said inorganic element is selected from the group consisting of K, Mg, Fe, Ni, Co and / or mixtures thereof. 14) A manufacturing method according to any one of claims 7 to 13, wherein said additive bio-oil comprises, in additional amount to said base bio-oil, from 5% to 30% moles of oxygen. and / or 5% to 50% moles of hydrogen provided by said compound as an additive. 15) The manufacturing method according to any one of claims 7 to 14, wherein said compound comprising hydrogen and / or oxygen is a metal oxide. 16) The manufacturing method according to any one of claims 7 to 15, wherein said additive is said surfactant constituting 0.1% to 5% by weight of said additive bio-oil. 17) A manufacturing method according to any one of claims 7 to 16, wherein said surfactant is a sugar ester. 18) A manufacturing method according to any one of claims 7 to 17, wherein said additive is said constituent gas of 0.1% to 5% by weight of said additive bio-oil. 19) The manufacturing method according to any one of claims 7 to 18, wherein said gas as an additive is expanded during said heating to form gas bubbles within said additive bio-oil. 20) A manufacturing method according to any one of claims 7 to 19, wherein said additive is said blowing agent constituting 0.1% to 1% by weight of said additive bio-oil. 21) A manufacturing method according to any one of claims 7 to 20, wherein said additive is said oxidizing agent constituting 0.1% to 5% by weight of said additive bio-oil. 22) A manufacturing method according to any one of the preceding claims, wherein the fractionation of said bio-oil additivée during said heating. 23) Manufacturing process according to claim 22, wherein the fractionation of said additive bio-oil is achieved by controlled micro-explosion or by the formation of gas bubbles. 24) A manufacturing method according to any one of the preceding claims, wherein said additive bio-oil is in the form of a foam. 25) A manufacturing method according to any one of the preceding claims, wherein said additive bio-oil is in paste form. 26) The manufacturing method according to claim 25, wherein said additive bio-oil is shaped before said heating by an operation such as molding, extrusion, injection. 27) A manufacturing method according to any one of the preceding claims, wherein said solid carbon material obtained at the end of said heating undergoes at least one additional treatment such as additional heat treatment, etching, grinding. 28) solid carbonaceous material obtainable by the manufacturing method as defined by any one of the preceding claims.-40- 29) additive bio-oil, characterized in that it comprises from 5% to 70% by weight of at least one solid particle as an additive to a base bio-oil. 30) additive bio-oil, characterized in that it comprises from 5% to 30% by weight of at least one inorganic element as an additive to a base bio-oil. 31) Bio-oil additive, characterized in that it comprises, in additional amount relative to a base bio-oil, from 5% to 30% of moles of oxygen and / or 5% to 50% of moles of hydrogen supplied ( s) by at least one compound as an additive to a base bio-oil. 32) Bio-oil additive, characterized in that it comprises from 0.1% to 5% by weight of at least one surfactant as an additive to a base bio-oil. 33) Bio-oil additive, characterized in that it comprises from 0.1% to 5% by weight of at least one gas as an additive to a basic bio-oil. 34) Bio-oil additive, characterized in that it comprises from 0.1% to 1% by weight of at least one pore-forming agent as an additive to a base bio-oil. 35) Bio-oil additive, characterized in that it comprises from 0.1% to 5% by weight of at least one oxidizing agent as an additive to a base bio-oil.