Title of Invention	"PROCESS FOR THE RECOVERY OF SULPHUR BY CATALYTICALLY OXIDISING THE H2S"
Abstract	The H2S of the gas to be treated is oxidized to sulphur on contact with an oxidation catalyst composed of at least one compound of a metal, especially a transition metal, or of the corresponding metal to the elemental state, used in combination with a silicon carbide support, the operation being carried out at temperatures which, depending on how the process is implemented, may be above or else below the dew point of the sulphur formed. Application to removing H2S present in gases from various sources with recovery of this H2S essentially in the form of sulphur.

Title of Invention

"PROCESS FOR THE RECOVERY OF SULPHUR BY CATALYTICALLY OXIDISING THE H2S"

Abstract

The H2S of the gas to be treated is oxidized to sulphur on contact with an oxidation catalyst composed of at least one compound of a metal, especially a transition metal, or of the corresponding metal to the elemental state, used in combination with a silicon carbide support, the operation being carried out at temperatures which, depending on how the process is implemented, may be above or else below the dew point of the sulphur formed. Application to removing H2S present in gases from various sources with recovery of this H2S essentially in the form of sulphur.

Full Text	The invention relates to a process for oxidizing the H2S present at a low concentration in a gas directly to sulphur by a catalytic route. It also relates to a catalyst for making use of this process. In order to recover H2S present at a low concentration, namely a concentration of less than 20% by volume and more particularly between 0.001% and 20% and very especially ranging from 0.001% to 10% by volume, in gases of various origins, it is possible to make use, in particular, of processes involving a direct catalytic oxidation of the H2S to sulphur according to the reaction H2S + l/202 -*• S + H20. In such processes, the gas to be treated, containing the H2S mixed with an appropriate quantity of a gas containing free oxygen, for example air, oxygen or else oxygen-enriched air, is passed in contact with a catalyst for oxidizing H2S to sulphur, this contact being brought about at temperatures which are either higher than the dew point of the sulphur formed, in which case the sulphur formed is present in the vapour state in the reaction mixture resulting from the reaction, or else at temperatures which are lower than the dew point of the sulphur formed, in which case the said sulphur is deposited on the catalyst, and this requires a regeneration of the sulphur-laden catalyst at regular intervals by purging with a non- oxidizing gas which is at a temperature of between 200°C and 500°C. In particular, oxidation of H2S to sulphur at temperatures above the dew point of sulphur, that is to say at temperatures above approximately 180°C, can be carried out in contact with a catalyst consisting of titanium oxide (EP-A-0078690), of titanium oxide containing an alkaline-earth metal sulphate (WO-A-8302068), of titanium oxide containing nickel oxide and optionally aluminium oxide (EP-A-0140045), of an oxide of the titanium oxide, zirconium oxide or silica type used in combination with one or more compounds of transition metals chosen from Fe, Cu, Zn, Cd, Cr, Mo, W, Co and Ni, preferably Pe, and optionally with one or more compounds of precious metals chosen from Pd, Pt, Ir and Rh, preferably Pd (FR-A-2511663) , or else of a thermally stabilized alumina used in combination with one or more compounds of transition metals such as the abovemen-tioned, especially Fe, and optionally with one or more compounds of precious metals chosen from Pd, Pt, Ir and Rh (FR-A-2540092). Oxidation of H2S to sulphur, the operation being carried out at temperatures such that the sulphur formed is deposited on the catalyst, can, for its part, be performed in contact with a catalyst consisting, for example, of one or more compounds such as salts, oxides or sulphides of transition metals, for example Fe, Cu, Cr, Mo, W, V, Co, Ni, Ag and Mn, in combination with a support of the activated alumina, bauxite, silica/alumina or zeolite type (FR-A-2277877) . This oxidation of H2S with deposition of sulphur on the catalyst can also be carried out in contact with a catalyst consisting of a catalytic phase chosen from the oxides, salts or sulphides of the metals V, Mo, W, Ni and Co used in combination with an active charcoal support (French Patent Application No. 9302996 of 16.03.1993). The catalysts such as the abovementioned, consisting of a catalytic phase based on at least one oxide, salt or sulphide of a transition metal, which phase is used in combination with a support consisting of at least one material chosen from alumina, titanium oxide, zirconium oxide, silica, zeolites, silica/alumina mixtures, silica/titanium oxide mixtures and active charcoal, which are used for the catalytic oxidation of H2S to sulphur, still exhibit certain shortcomings on prolonged use. In particular, the catalysts in which the support is based on alumina are capable of changing with time by sulphation. As regards the catalysts in which the support consists of active charcoal, precautions must be taken during their use in order to avoid combustion of the support. Moreover, for these various catalysts, the catalytic phase with which the support is impregnated has a tendency to migrate into the lattice of the support, which makes it difficult, indeed even often impossible, to recover the metal from the catalytic phase in the spent catalyst. Finally, the abovementioned catalysts have a mediocre thermal conductivity, which does not make it possible to exert efficient control over the temperature within the catalytic beds containing them by heat exchange with a coolant fluid. It has now been found that it was possible to overcome the disadvantages of the catalysts of the type mentioned above used for the catalytic oxidation of H2S to sulphur, and thus to obtain a process resulting in an improved selectivity for sulphur which is maintained durably with time, by forming the support for these catalysts from silicon carbide. The silicon carbide support, in contrast to an alumina support, is not subject to sulphation and, unlike an active charcoal support, is not combustible. Moreover, migration of the catalytic phase into the lattice of the silicon carbide support is not observed, which makes it possible to recover the metals from the catalytic phase when the catalyst is spent, such a possibility assuming particular importance in the case where the catalytic phase contains harmful substances, such as nickel compounds. Finally, the silicon carbide support has good thermal conductivity which, especially for use of the catalyst in cooled catalytic beds, makes it possible to obtain a flatter temperature front within the catalytic bed and consequently better selectivity for sulphur. The subject of the invention is therefore a process for oxidizing H2S present at a low concentration in a gas directly to sulphur by a catalytic route, the said process being of the type in which the said gas containing H3S is passed with a gas containing free oxygen, in a quantity such as to provide an 02:H2S molar ratio ranging from 0.05 to 10, in contact with a catalyst for selectively oxidizing H2S to sulphur consisting of a catalytically active phase used in combination with a support, the said active phase containing at least one metal existing in the form of a metal compound and/or in the elemental state, and it is characterized in that the said support consists of silicon carbide. In particular, the active phase used in combination with the silicon carbide support in order to form the oxidation catalyst according to the invention is advantageously composed of at least one transition metal, such as nickel, cobalt, iron, copper, silver, manganese, molybdenum, chromium, titanium, tungsten and vanadium, the said metal being in the oxide, sulphide or salt form and/or in the elemental state. The said active phase, expressed as weight of metal, most often represents 0.1 to 20%, more particularly 0.2 to 15% and more especially 0.2 to 7% of the weight of the oxidation catalyst. The silicon carbide support advantageously forms at least 40% and more particularly at least 50% of the weight of the oxidation catalyst. The specific surface of the catalyst for the oxidation of H2S to sulphur can vary quite widely, depending on the conditions of implementation of the oxidation process. Advantageously, the said specific surface, determined by the BET nitrogen adsorption method at the temperature of liquid nitrogen (NF standard X 11-621) , can represent 2 m2/g to 600 m2/g and more especially from 10 m2/g to 300 m2/g. The oxidation catalyst may be prepared by making use of the various known methods for incorporating one or more metal compounds into a divided solid forming a catalyst support. In particular, it is possible to carry out the operation by impregnating the silicon carbide support, which is in the form of a powder, pellets, granules, extrudates or other agglomerate forms, with a solution or a sol, in a solvent such as water, of the desired metal compound(s), followed by drying of the impregnated support and calcining of the dried product at temperatures which can range from 250 °C to 500°C, the operation being optionally carried out in an inert atmosphere. The calcined catalyst may be subjected to a reduction treatment under hydrogen, for example between 200°C and 500"C, in order to convert the metal of the metal compound present in its active phase to the elemental state. It is also possible to envisage preparing the catalyst by carrying out the operation so as to insert catalytically active metal atoms, such as the abovementioned, into the crystal lattice of the silicon carbide. The silicon carbide used to form the support for the catalyst for oxidizing H3S to sulphur may consist of any one of the known silicon carbides, with the proviso that it has the required specific surface characteristics, namely a specific surface, determined by the BET nitrogen adsorption method, ranging from 2 m2/g to 600 m2/g and more especially from 10 m2/g to 300 m2/g. In particular, the said silicon carbide may be prepared by making use of any one of the techniques which are described in the citations EP-A-0313480 (corresponding to US-A-4914070) , EP-A-0440569, EP-A-0511919, EP-A-0543751 and EP-A-0543752. The gas containing free oxygen which is employed for oxidizing to sulphur the HSS present in the gas to be treated is generally air, although it is possible to employ pure oxygen, oxygen-enriched air or else mixtures of various proportions of oxygen and of an inert gas other than nitrogen. The gas containing free oxygen and the gas to be treated containing H2S can be brought separately into contact with the oxidation catalyst. However, in order to obtain a very homogeneous gaseous reaction mixture during the contact with the catalyst, it is preferable first of all to mix the gas to be treated containing H2S with the gas containing free oxygen and to bring the mixture thus produced into contact with the oxidation catalyst. As indicated above, the gas containing free oxygen is employed in a quantity such as to provide an 02:H2S molar ratio ranging from 0.05 to 10, more particularly from 0.1 to 7 and very especially from 0.2 to 4 in the reaction mixture which has been brought into contact with the catalyst for oxidizing H2S to sulphur. The contact times of the gaseous reaction mixture with the oxidation catalyst may range from 0.5 of a second to 20 seconds and preferably from 1 second to 12 seconds, these values being given in standard pressure and temperature conditions. The process for catalytically oxidizing H2S to sulphur according to the invention may be implemented at temperatures above the dew point of the sulphur formed during the reaction for oxidizing H2S, the said sulphur then being present in the vapour form in the reaction mixture which is in contact with the catalyst and which is collected at the exit of the catalytic oxidation zone. It is also possible to implement the oxidation process according to the invention by carrying out the operation at temperatures below the dew point of the sulphur formed during the oxidation reaction, the said sulphur then being deposited on the catalyst and the gaseous effluent collected at the exit of the oxidation zone being substantially free of sulphur. The temperatures for implementing the process according to the invention may advantageously be chosen between 30°C and 1000°C. For implementation of the process at temperatures above the dew point of the sulphur formed, temperatures of between 180°C and 1000°C and more especially between 200°C and 9 00°C are chosen. For implementation of the process at temperatures below the dew point of the sulphur formed, temperatures in the range 30°C to 180°C and more particularly in the range 80 °C to 160 °C, which encloses the solidification range for sulphur in the vicinity of 120°C, are chosen. Prior to the stage of implementing the oxidation reaction, the oxidation catalyst according to the invention, and in particular the oxidation catalyst in which the active phase contains nickel, may be subjected to activation by bringing the said catalyst into contact with elemental sulphur, in a quantity representing a slight excess, for example an excess which may range up to 300 mol %, with respect to the stoichiometric quantity corresponding to maximum sulphurization of the metal of the active phase of the catalyst, the said operation of bringing into contact being carried out under an inert atmosphere, for example a helium or argon atmosphere, at temperatures of between 250°C and 400°C and for a period of time which is sufficient, most often between 1 hour and 4 hours, to obtain maximum sulphurization of the metal of the active phase of the catalyst. The catalyst according to the invention, especially a nickel catalyst, initially activated as indicated above, makes it possible to obtain a degree of conversion of H2S to sulphur which is equal to 100%, from the beginning of the oxidation of H2S by the oxygen of the gas containing free oxygen. The catalyst according to the invention, and very particularly the nickel catalyst, may also form the subject of an initial activation equivalent to the activation with elemental sulphur described above by bringing the said catalyst into contact with a gas mixture containing H2S and an inert gas, the operation being carried out at temperatures of between 250°C and 400 °C for a period of time which is sufficient, in general between 1 hour and 15 hours, to produce maximum sulphurization of the metal of the active phase of the catalyst, it being possible for the said gas mixture to contain especially between 0.2% and 30% or more of H2S by volume. In particular, the gas mixture containing H2S which is used for the initial activation of the oxidation catalyst may consist of the gas to be treated, when the latter does not contain, in addition to H2S, components capable of reacting, at the activation temperatures, with the active phase of the catalyst. The gas containing H2S at a low concentration which is treated by the process according to the invention may come from various sources. In particular, such a gas may be a natural gas of low H2S content or else a gas originating from the gasification of coal or of heavy oils, or even a gas resulting from the hydrogenation of a residual gas, for example a sulphur plant residual gas, containing sulphur compounds such as S02, mercaptans, COS or CS2, which can be converted to HjS by the action of hydrogen or of water vapour, or yet again a gas resulting from the treatment, in contact with a Claus catalyst capable of promoting the sulphur-formation reaction between H2S and S02, of a gaseous effluent containing H2S and S02 in an H2S:S02 molar ratio higher than 2:1, and such that the said resulting gas contains especially H2S and no or very little S02 as sulphur compounds. The process according to the invention may be applied to the treatment of a gas containing H2S at a concentration of between 0.001% and 25% by volume and more especially ranging from 0.01% to 20% by volume. The gas to be treated may also contain organic sulphur compounds such as mercaptans, COS or CS2, at an overall concentration which may range up to approximately 1% by volume. Gases containing H2S at a concentration greater than 25% by volume could be treated by using the process according to the invention; however, in this case, it is preferable to use the conventional processes for the production of sulphur containing a thermal reaction stage. The gas containing H2S which is subjected to oxidation on contact with the catalyst containing a silicon carbide support may be free of water or substantially free of water or, in contrast, contain a more or less large quantity of water. Thus, a gas containing H2S which has a water content which may range from 0% to approximately 50% by volume may be treated according to the invention. Advantageously, when the oxidation reaction of the gas containing H2S, in contact with a catalyst according to the invention, very particularly a nickel catalyst, containing a silicon carbide support, is implemented at temperatures below the dew point of the sulphur formed by the oxidation and more particularly at temperatures below the melting point of the sulphur, the presence, in the gas to be treated containing H2S, of a quantity of water ranging from 10% to 50% by volume and more especially from 15% to 3 0% by volume makes it possible to substantially increase the period of time during which the efficiency of the catalyst is maintained at an optimum level. When the process according to the invention is implemented at temperatures of between 180°C and 1000°C and more particularly between 200 °C and 900 °C, the operation of bringing the gas to be treated into contact with the oxidation catalyst containing a silicon carbide support may be carried out in a single oxidation zone containing the oxidation catalyst, especially when the H2S content of the gas to be treated is not greater than approximately 5% by volume, or alternatively in a plurality of oxidation zones arranged in series, each containing the oxidation catalyst, especially when the H2S content of the gas to be treated is greater than approximately 5% by volume, the said single oxidation zone or each of the zones of the plurality of oxidation zones operating at temperatures within the abovementioned ranges. Each of the oxidation zones functions in the range of temperatures corresponding to a substantially optimum selectivity of the catalyst for the formation of sulphur. At the exit of the single oxidation zone or of each of the zones of the plurality of oxidation zones in series, a gaseous effluent laden with sulphur vapour is collected, which gaseous effluent, before any subsequent treatment for removing H2S, is caused to pass into a zone for separating sulphur in which it is freed from the greater part of the sulphur which it contains by condensing. When the gas containing H2S is treated by passing into a plurality of oxidation zones in series containing the oxidation catalyst containing a silicon carbide support, only a fraction of the H2S present in the gas to be treated is oxidized to sulphur in each of the said zones, the oxidation being carried out by injecting into the zone concerned, preferably mixed with the said gas conveyed to this zone, the appropriate quantity of the gas containing free oxygen for carrying out this oxidation to sulphur. The quantity of H2S subjected to oxidation to sulphur in each of the zones, which represents a fraction of the total quantity of H2S in the gas to be treated, is advantageously between 2% and 5% by volume of the gas to be treated and the number of catalytic oxidation zones is chosen so that the gas to be treated arriving at the final catalytic zone contains not more than 5% by volume of H2S. If need be, the gaseous effluent, which is collected at the exit of the single oxidation zone or at the exit of the final zone of the plurality of oxidation zones in series, in the implementation at temperatures above the dew point of the sulphur formed, may be subjected to an additional purification treatment after separation of the sulphur which it optionally contains, the said treatment depending on the nature of the gaseous sulphur compounds remaining in the effluent. The implementation of the process according to the invention at temperatures above the dew point of the sulphur formed may constitute, in particular, the stage for oxidizing H2S of the processes for removing sulphur compounds present in a residual gas described in the citations FR-A-2589141 and FR-A-2589082 or the stage for oxidizing H2S of the process for treating sour gas described in the citation FR-A-2589140. The said implementation may also form the stage for oxidizing H2S to sulphur in Claus stoichiometry used in the processes of the type described in the citation FR-A-2511663 or the citation FR-A-2540092, which processes comprise bringing a gas having an H2S content below 2 5% by volume into contact, the operation being carried out at high temperature, that is to say between 200°C and 1000°C and more particularly between 350°C and 900°C, and in the presence of a catalyst for oxidizing H2S, with a controlled quantity of a gas containing free oxygen, in order to form a gaseous effluent containing H2S and S02 in an H2S:SO2 molar ratio which is substantially equal to 2:1 and a certain proportion of sulphur, and then bringing the said gaseous effluent, after cooling and optionally separating the sulphur which it contains, into contact with a Claus catalyst, in order to form a new quantity of sulphur, the said Claus catalyst being arranged in a single catalytic converter or in a plurality of catalytic converters, for example two or three, in series. When the process according to the invention is implemented at temperatures below the dew point of the sulphur formed during the reaction for oxidizing H2S, that is to say at temperatures within the range 3 0°C to 180°C and more particularly in the range 80°C to 160°C, the operation of bringing the gas to be treated, which in this embodiment preferably contains less than 5% by volume of H2S and very particularly less than 2% by volume of H2S, into contact with the oxidation catalyst containing a silicon carbide support results in the formation of sulphur which is deposited on the catalyst. If the H2S concentration and/or the temperature of the gas to be treated containing H2S brought into contact with the oxidation catalyst are such that, due to the high exothermicity of the reaction H2S + l/202 -» S + H20, the temperature of the reaction mixture, on conclusion of the oxidation, is capable of exceeding the temperature limit beyond which the reaction no longer has the desired selectivity, the heat given off by the said reaction is removed by subjecting the catalyst to cooling, by any known method. It is possible, for example, to carry out this cooling using a cold fluid circulating within the said catalyst, by indirect exchange of heat with the latter. It is alternatively possible to carry out the operation by placing the catalyst in a tubular reactor consisting of tubes arranged in a calandria with, for example, the catalyst present in the tubes and a cold fluid circulating between the tubes by the calandria. The catalytic oxidation can also be carried out in a multi-stage catalytic reactor with cooling of the reaction mixture between the successive stages by indirect exchange of heat with a cold fluid, exchange of heat taking place inside or outside the oxidation reactor. If the gas to be treated contains, in addition to H2S, a significant quantity of water, for example greater than 10% by volume, the temperatures for oxidizing H2S to sulphur below the dew point of the sulphur formed during the oxidation are preferably chosen in order to be above the dew point of the water present in the gas to be treated. During the oxidation of H2S to sulphur at temperatures below the dew point of the sulphur formed, the oxidation catalyst gradually becomes laden with sulphur. Regeneration of the sulphur-laden catalyst is undertaken at regular intervals by purging the said catalyst with a non-oxidizing gas, the operation being carried out at temperatures of between 200°C and 500°C and preferably between 230°C and 450°C, to vaporize the sulphur retained on the catalyst, and the regenerated catalyst is then cooled to a temperature below the dew point of the sulphur for a new implementation of the oxidation reaction, this cooling being carried out with a gas which is at a suitable temperature below 180°C. The purging gas, employed for regenerating the sulphur-laden catalyst, may be such as methane, nitrogen, C02 or mixtures of such gases or may alternatively consist of a fraction of the gas stream originating from the oxidation stage or of a fraction of the gas to be treated. The purging gas employed for the abovementioned regeneration may optionally contain a certain proportion of a gaseous reducing compound such as, for example, H2, CO or H2S, at least during the final stage of the regeneration, that is to say after the vaporization of the greater part of the sulphur deposited on the oxidation catalyst. The implementation of the oxidation reaction according to the invention at temperatures below the dew point of the sulphur formed may be carried out in a single oxidation zone, containing the oxidation catalyst containing a silicon carbide support, which operates alternately in an oxidation stage and in a regeneration/cooling stage. Such an implementation is adopted when the gas to be treated contains little H2S and when consequently the regeneration of the catalyst is not very frequent. The catalytic reaction is advantageously implemented in a plurality of oxidation zones, each containing the oxidation catalyst containing a silicon carbide support, which operate so that at least one of the said zones operates in a regeneration/cooling stage while the other zones are in a catalytic oxidation stage. It is also possible to operate by having one or more zones in an oxidation reaction stage, at least one zone in a regeneration stage and at least one zone in a cooling stage. The gas employed for regenerating the oxidation catalyst preferably circulates in a closed circuit starting with a heating zone, passing successively through the catalytic zone being regenerated and a cooling zone, in which most of the sulphur present in the said gas is separated off by condensation, to return to the heating zone. The regenerating gas may, of course, also travel in an open circuit. The gas used for cooling the regenerated oxidation catalyst is of the same type as that employed for regenerating the sulphur-laden catalyst. The said gas may optionally contain oxygen in a proportion which is less than or equal to that used in the catalytic oxidation stage. The regeneration gas and coolant gas circuits may be independent of one another. However, according to one embodiment, the regenerating gas circuit defined above may also comprise a bypass connecting the exit of its cooling zone to the entry of the zone being regenerated by bypassing its heating zone, and this makes it possible to short-circuit the said heating zone and thus to employ the regenerating gas as coolant gas. The embodiment of the process according to the invention for oxidizing H2S to sulphur at temperatures below the dew point of the sulphur formed during the oxidation may advantageously form the stage for catalytic Oxidation of H2 S which follows the claus reaction stage at a temperature below 180°C in the process for the desulphurization of gas containing H2S described in the citation FR-A-2277877. Accordingly, the present invention relates to a process for the recovery of sulphur by catalytically oxidizing the H2S present at a low concentration in a gas, which comprises the steps of: contacting the gas containing H2S and a gas containing free oxygen, in a quantity such as to provide an O2:H 2S molar ratio ranging from 0.05 to 10, with an oxidation catalyst comprised of a silicon carbide support in association with an active phase composed of at least one transition metal such as nickel, cobalt, iron, copper , silver, manganese, molybdenum, chromium, titanium, tungsten and vanadium, the said transition metal being in the oxide or salt form and/or in the elemental state, to selectively oxidize H2S oxidation whereby the said sulphur is deposited on the catalyst; subjecting periodically the sulphur-laden catalyst to regeneration by purging with a purging gas at temperatures between 200°C and 500°C to vaporize the sulphur retained on the catalyst and recovering the vaporized sulphur by condensation, and cooling the regenerated catalyst to a temperature below the dew point of the sulphur for a new implementation of the H2S oxidation, the said cooling being performed with a coolant gas which is at a temperature below 180° C. The invention is illustrated by the following examples, given without any limitation being implied. EXAMPLE 1 The treatment was carried out of a gas consisting, by volume, of 1% of H2S, 5% of H2O and 94% of C02, the operation being carried out at temperatures above the dew point of the sulphur formed, with the use of a catalyst composed of a silicon carbide support impregnated with an iron compound and with a chromium compound and containing, expressed as weight of metal with respect to the weight of the catalyst, 3.2% of iron and 0.35% of chromium. The catalyst was prepared as follows. Silicon carbide grains, with a particle size between 0.8 mm and 1 mm and a BET specific surface of 78 m2/g, were first of all impregnated with a solution of an iron compound and of a chromium compound at concentrations such as to provide the desired quantities of iron and of chromium in the resulting catalyst. The impregnated product obtained was dried at ambient temperature for 40 hours and then at 120°C for 50 hours and was subsequently subjected to a calcination at 500°C for 20 hours, in order to produce the catalyst. The catalyst obtained contained, as indicated above, 3.2% by weight of iron and 0.35% by weight of chromium and had a BET specific surface equal to 77 m2/g. The gas containing H2S was treated in a stationary bed catalytic reactor containing 1.1m3 of catalyst, the said reactor being equipped, on the one hand, with a delivery conduit for the gas to be treated and, on the other hand, with a discharge conduit for the gases forming the exit of the reactor. The gas delivery conduit contained a branch connection for the injection of air as gas containing free oxygen and was additionally equipped with an indirect heat exchanger, operating as a heater, fitted between the branch connection for injection of air and the entry of the reactor. The gas exit conduit was equipped with a sulphur condenser cooled by circulation of steam. The gas is passed from the entry to the exit of the reactor through the catalyst bed. The gas to be treated, introduced via the gas delivery conduit with a flow rate of 1000 Nm3/h and a temperature of 40°C, received, via the branch connection, an addition of air corresponding to a flow rate of 2 9 Nm3/h, this air being injected at ambient temperature. The mixture of gas to be treated and of air, in which the O2:H2S molar ratio was equal to 0.6, was brought to a temperature of 180°C, by passing into the heater, and was then injected into the reactor at this temperature. The contact time of the said mixture with the catalyst present in the reactor was equal to 4 seconds. The gaseous effluent exiting from the reactor, via the gas discharge conduit, no longer contained free oxygen nor H2S and had a temperature of 240°C. This effluent was cooled to approximately 130°C in the condenser in order to separate therefrom the sulphur which it contained. The conversion of H2S was complete and the selectivity of the sulphur was equal to 92%. EXAMPLE 2 The treatment was carried out of a residual gaseous effluent containing, by volume, 0.8% of H2S as the only sulphur compound, this effluent being obtained by hydrogenation/hydrolysis of a residual gas from a Claus sulphur plant in which a sour gas containing 70% by volume of H2S was treated. The said gaseous effluent was treated at a temperature below the dew point of the sulphur formed by the oxidation of the said H2S and by making use of a catalyst consisting of silicon carbide impregnated with a nickel compound and containing, by weight, 4% of nickel, the said catalyst having a BET specific surface of 220 m2/g- The said catalyst was obtained by impregnating microporous silicon carbide grains with an appropriate quantity of nickel acetate in aqueous solution, then drying the impregnated product at 100°C and finally calcining the dried product at 300°C for 3 hours. The silicon carbide grains, with a mean diameter of 1 mm, had a BET specific surface of 240 m2/g. The operation was carried out in a plant composed of two catalytic oxidation reactors fitted in parallel, each reactor having an entry and an exit separated by a stationary bed of the abovementioned catalyst. The said reactors were additionally arranged so that alternately, by means of valves which could be switched by a clock, one of the reactors operated in a reaction stage, that is to say had its entry connected to a gas delivery conduit, on which was fitted an indirect heat exchanger and, downstream of the exchanger, a branch connection for injection of air, and its exit connected to a gas discharge conduit, and the other reactor operated in a regeneration/cooling stage, that is to say was arranged in a regeneration/cooling circuit equipped with means for ensuring the circulation of a purging gas through the oxidation reactor starting from a heater as far as a sulphur condenser and return to the said heater and for subsequently circulating a cold gas, of the same composition as the regenerating gas, through the reactor which has undergone regeneration. The gaseous effluent to be treated arrived via the gas delivery conduit with a flow rate equal to 940 kmol/h and was brought to a temperature of 90°C in the exchanger fitted to the said conduit and then 44 kmol/h of ambient air were added via the branch connection. The mixture obtained entered into the reactor in the oxidation stage with a temperature substantially equal to 90 °C. The contact time of the gas mixture, passing into the reactor in the oxidation reaction stage, with the catalyst layer present in the said reactor was equal to 10 seconds. The degree of conversion of H2S, in the reactor in the oxidation reaction stage, was equal to 100%. At the exit of the said reactor, a gas stream was discharged which had a temperature of approximately 140°C and contained 160 vpm of SO 2, the said gas stream being conveyed to an incinerator before being discharged to the atmosphere. A purging gas was injected into the reactor operating in the regeneration/cooling stage for the purposes of regenerating the sulphur-laden oxidation catalyst, the said purging gas consisting of nitrogen and being injected into the said reactor with a temperature of between 250°C and 350°C and a flow rate equal to 10,000 Nm3/h. On conclusion of the catalyst regeneration stage, the temperature of the purging gas was lowered to approximately 125°C and the purging was continued with the cooled purging gas until the regenerated catalyst bed reaches substantially the said temperature. On regenerating under nitrogen, all the sulphur deposited on the catalyst is recovered. The oxidation reactors operated alternately for 3 0 hours in the reaction stage and for 3 0 hours, 10 hours of which were for cooling, in the regeneration/cooling stage. The sulphur plant, incorporating the process according to the invention for treating the residual gases produced by the said plant, which gases were hydrogenated prior to the treatment according to the invention, had an overall sulphur yield of 99.9% over a period of several months. EXAMPLE 3 The treatment was carried out of an H2S-depleted sour gas, the said gas consisting, by volume, of 95.5% of C02, 4% of H20 and 0.5% of H2S. The said sour gas was treated at a temperature below the dew point of the sulphur produced by oxidizing the H2S of this sour gas, the operation being carried out in a plant similar to that used in Example 2 and use being made of a catalyst composed of silicon carbide, containing 4% of nickel by weight and having a BET specific surface equal to 210 m2/g. This catalyst was prepared as described in Example 2 and, after its calcination, it was reduced under a hydrogen stream at 400°C for 10 hours. The depleted sour gas to be treated arrived via the gas delivery conduit with a flow rate equal to 2241 Nm3/h and a temperature of approximately 30°C and was brought to a temperature of 80°C in the exchanger fitted to the said conduit, and then 89.6 Nm3/h of air, brought to 80°C, was added via the branch connection. The mixture obtained entered the reactor in the oxidation stage with a temperature substantially equal to 80°C. The contact time of the gas mixture, passing into the reactor in the oxidation reaction stage, with the catalyst layer present in the said reactor was equal to 10 seconds. The degree of conversion of H2S, in the reactor in the oxidation reaction stage, was equal to 100%. At the exit of the said reactor, a gas stream was discharged which had a temperature of approximately 105°C and contained less than 100 vpxn of S02, the said gas stream being conveyed to an incinerator before being discharged to the atmosphere. In the reactor operating in the regeneration/cooling stage, a purging gas consisting of nitrogen was injected for the purposes of regenerating the sulphur-laded oxidation catalyst, and then of cooling the regenerated catalyst, the operation being carried out as indicated in Example 2. On regenerating under nitrogen, all the sulphur deposited on the catalyst is recovered. The oxidation reactors operated alternately for 3 0 hours in the reaction stage and for 3 0 hours, 10 hours of which were for cooling, in the regeneration/cooling stage. EXAMPLE 4 The treatment was carried out of a sour gas containing, by volume, 20% of H2S, 8% of water and 72% of CO2 by a process comprising a catalytic oxidation stage in Claus stoichiometry followed by a Claus reaction stage carried out in two successive stages, the first above the dew point of the sulphur formed and the second below the said dew point. The operation was carried out in a plant compri- sing the following components: - a stationary bed oxidation reactor containing an oxidation catalyst according to the invention, the said reactor being fitted with a conduit for delivering the mixture of sour gas and of air and with a conduit for discharging the effluent from the oxidation; - a gas/gas indirect heat exchanger, one of the exchange circuits of which is fitted in series to the conduit for delivering the mixture of sour gas and of air and the other exchange circuit of which is in series with the conduit for discharging the effluent from the oxidation; - a primary stationary bed catalytic converter which contains a Claus catalyst in the form of extrudates with a diameter of 3 mm composed of titanium oxide containing 10% by weight of calcium sulphate and the entry of which is connected to the conduit for discharging the oxidation effluent through the appropriate exchange circuit of the heat exchanger; - a catalytic conversion array comprising two secondary catalytic converters and a sulphur condenser cooled with steam, in which, on the one hand, each of the said secondary converters contains a Claus catalyst composed of an activated alumina in the form of balls with a diameter of 4 to 6 mm and, on the other hand, the secondary converters and the sulphur condenser are arranged so that the exit of the primary converter can be switched alternately to the entry of one or the other of the said secondary converters and so that the latter are connected in series through the sulphur condenser; and - a catalytic incinerator, the entry of which is connected to the exit of the catalytic conversion array and the exit of which is connected to a chimney open to the atmosphere, this incinerator using a catalyst composed of a silica impregnated with iron sulphate and with palladium oxide. The oxidation catalyst used in the oxidation stage in Claus stoichiometry was composed of a silicon carbide support impregnated with an iron compound and containing 4.6% by weight of iron with respect to the total weight of the catalyst. The catalyst was prepared as follows. Silicon carbide grains, having a particle size of between 0.8 nun and 1 mm and a BET specific surface of 78 m2/g, were first of all impregnated with an aqueous iron sulphate solution in a concentration such as to provide the desired quantity of iron in the resulting catalyst. The impregnated product obtained was dried and calcined as indicated in Example 1. The catalyst obtained contained, as indicated above, 4.6% by weight of iron and had a BET specific surface equal to 76 m2/g. The sour gas arriving with a flow rate of 1000 Nm3/h (standard conditions) had 285.6 Nm3/hour of air added to it and the gas mixture obtained was preheated to a temperature of 200°C, by passing into the heat exchanger, and was then injected into the oxidation reactor. The contact time between the gas mixture and the oxidation catalyst was equal to 2 seconds (standard conditions) and the temperature within the catalytic bed rose to 800°C. The effluent from the oxidation reactor contained H2S and S02 in an H2S:S02 molar ratio equal to 2:1, as well as 6 v.p.m. of free oxygen and a quantity of sulphur vapour corresponding to a degree of conversion of H2S to sulphur equal to 59%. This effluent was cooled to 150°C in the heat exchanger in order to condense the sulphur which it contains and to use a portion of the heat from the said effluent for preheating the mixture of sour gas and of air. The cooled effluent was then heated to 2 50°C and conveyed into the primary Claus catalytic converter. The contact time between the catalyst, based on titanium oxide, and the gaseous effluent in the said converter was equal to approximately 3 seconds and the temperature within the catalytic bed was 3 00°C. The reaction mixture containing H2S, S02 and sulphur vapour resulting from the primary Claus converter was conveyed through the converter in the "regeneration" stage of the catalytic conversion array in order to carry out purging of the sulphur-laden catalyst present in this converter, the said purging being carried out at a temperature of approximately 300°C with a gas/catalyst contact time of approximately 6 seconds. The sulphur-laden gas originating from the converter being regenerated then passed through the steam-cooled sulphur condenser, in which the said gas was cooled to a temperature of approximately 150°C and freed from the sulphur which it contained by condensation. The resulting cooled gas, which contained H2S and S02 as well as a very small quantity of sulphur vapour, was conveyed into the catalytic converter in the "Claus reaction" stage of the catalytic conversion array operating at a temperature of 150°C, with a gas/catalyst contact time equal to approximately 6 seconds, in order to form sulphur by reaction between H2S and SO2, the said sulphur being deposited on the catalyst. The residual gases coming from the converter in the "Claus reaction" stage were conveyed to catalytic incineration and the smoke resulting from the incineration, which contained SO2 at a very low concentration as the only sulphur compound, was discharged to the atmosphere via the chimney. The residual gases exiting from the catalytic conversion array contained only 800 v.p.m. of total sulphur, namely H2S, S02, sulphur vapour and/or vesicular sulphur, which corresponds to an overall yield for conversion of H2S to sulphur equal to 99.6%. After an operating time of 800 hours, under the abovementioned conditions, the effluent from the catalytic oxidation reactor in Claus stoichiometry contained H2S and SO2 in an H2S:SO2 molar ratio equal to 2.02 and a quantity of sulphur vapour corresponding to a degree of conversion of H2S equal to 56%, the overall yield for conversion of H2S to sulphur then being 99.4%. EXAMPLE 5: The treatment was carried out of a gas consis- ting, by volume, of 1% of H2S, 5% of H2O and 94% of C02, the operation being carried out at temperatures above the dew point of the sulphur formed, with the use of a catalyst composed of a silicon carbide support impregnated with an iron compound and with a chromium compound and containing, expressed as weight of metal with respect to the weight of the catalyst, 3.2% of iron and 0.35% of chromium, the said catalyst being activated by a direct sulphurization. The catalyst was prepared as follows. Silicon carbide grains, with a particle size of between 0.8 mm and 1 mm and a BET specific surface of 7 8 m2/g, were first of all impregnated with a solution of an iron compound and of a chromium compound at concentrations such as to provide the desired quantities of iron and of chromium in the resulting catalyst. The impregnated product obtained was dried at ambient temperature for 40 hours and then at 120°C for 50 hours and was then subjected to a calcination at 500°C for 2 0 hours. The calcined product obtained, containing the elements iron and chromium in the oxide form supported on silicon carbide, was then treated either with H2S diluted to the concentration of 1% by volume in a helium flow or with solid sulphur mechanically mixed with the catalyst, the quantity of sulphur representing 6.2% of the weight of the said catalyst. The said treatment was implemented at 3 00°C for two hours, in order to bring the metals iron and chromium to the sulphide form constituting the active phase of the catalyst. The sulphur-containing catalyst obtained contained, as indicated above, 3.2% by weight of iron and 0.35% by weight of chromium and had a BET specific surface equal to 76 m2/g. The gas containing H2S was treated by using the sulphur-containing catalyst, the operation being carried out as indicated in Example 1. The conversion of H2S was total from the beginning of the treatment of the gas containing H2S and the selectivity for sulphur was equal to 93%. EXAMPLE 6 The treatment was carried out of an H2S-depleted sour gas, the said gas consisting, by volume, of 95.5% of C02, 4% of H2O and 0.5% of H2S. The said sour gas was treated at 100°C, a temperature below the dew point of the sulphur produced by oxidizing the H2S of this sour gas, the operation being carried out in a plant similar to that used in Example 2 and use being made of a catalyst composed of silicon carbide containing 4% by weight of nickel and having a BET specific surface equal to 210 m2/g. This catalyst was prepared as described in Example 2 and, after its calcination, it was reduced under a hydrogen stream at 400°C for 10 hours. The depleted sour gas to be treated arrived via the gas delivery conduit with a flow rate equal to 2241 Nm3/h and a temperature of approximately 3 0°C and was brought to a temperature of 80°C in the exchanger fitted to the said conduit and then it was mixed, via the branch connection, with 89.6 Nm3/h of air and 1000 Nm3/h of an inert gas charged with 55% by volume of steam and brought to 100°C. The quantity of steam present in the final mixture was approximately 20% by volume. The mixture obtained entered the reactor in the oxidation stage with a temperature of 86°C. The contact time of the gas mixture, passing into the reactor in the oxidation reaction stage, with the catalyst layer present in the said reactor was equal to 10 seconds. The degree of conversion of H2S, in the reactor in the oxidation reaction stage, was equal to 100%. At the exit of the said reactor, a gas stream was discharged which had a temperature of approximately 110°C and contained less than 100 vpm of S02, which gas stream was conveyed to an incinerator before being discharged to the atmosphere. A purging gas consisting of nitrogen was injected into the reactor operating in the regeneration/cooling stage for the purposes of regenerating the sulphur-laden oxidation catalyst, and then of cooling the regenerated catalyst, the operation being carried out as indicated in Example 2. On regenerating under nitrogen, all the sulphur deposited on the catalyst is recovered. The presence of the abovementioned quantity of steam in the reaction mixture and more generally of a quantity of between 10% and 50% and especially lying between 15% and 30% by volume makes it possible to substantially extend the period of time during which the optimum desulphurizing activity of the catalyst is maintained. The steam acts as dispersant for the sulphur deposited on the catalyst and thus protects access of the reactants to the active sites of the catalyst. WE CLAIM: 1. A process for the recovery of sulphur by catalytically oxidizing the H2S present at a low concentration in a gas , which comprises the steps of: contacting the gas containing H2S and a gas containing free oxygen, in a quantity such as to provide an O2:H2S molar ratio ranging from 0.05 to 10, with an oxidation catalyst comprised of a silicon carbide support in association with an active phase composed of at least one transition metal such as nickel, cobalt, iron, copper , silver, manganese, molybdenum, chromium, titanium, tungsten and vanadium, the said transition metal being in the oxide or salt form and/or in the elemental state, to selectively oxidize H2S oxidation whereby the said sulphur is deposited on the catalyst; subjecting periodically the sulphur-laden catalyst to regeneration by purging with a gas of the kind such as herein described at temperatures between 200°C and 500°C to vaporize the sulphur retained on the catalyst and recovering the vaporized sulphur by condensation, and cooling the regenerated catalyst to a temperature below the dew point of the sulphur for a new implementation of the H2S oxidation, the said cooling being performed with a gas of the kind such as herein described which is at a temperature below 180°C. 2. A process as claimed in claim 1, wherein the regeneration of the sulphur-laden catalyst is carried out at temperature of between 230°C and 450°C. 3. A process as claimed in any one of preceding claims, wherein the gas containing free oxygen is used in a quantity such as to provide an O2:H2S molar ratio ranging from 0.1 to 7 and more particularly from 0.2 to 4. 4. A process as claimed in any one of claims 1 to 3, wherein the contacting of the gas containing H2S and a gas containing free oxygen with the oxidation catalyst is at a temperature between 90°C and 140°C. 5. A process for the recovery of sulphur by catalytically oxidizing the H2S present at a low concentration in a gas substantially as herein described with reference to the foregoing examples.

Full Text

The invention relates to a process for oxidizing the H2S present at a low concentration in a gas directly to sulphur by a catalytic route. It also relates to a catalyst for making use of this process.
In order to recover H2S present at a low concentration, namely a concentration of less than 20% by volume and more particularly between 0.001% and 20% and very especially ranging from 0.001% to 10% by volume, in gases of various origins, it is possible to make use, in particular, of processes involving a direct catalytic oxidation of the H2S to sulphur according to the reaction H2S + l/202 -*• S + H20.
In such processes, the gas to be treated, containing the H2S mixed with an appropriate quantity of a gas containing free oxygen, for example air, oxygen or else oxygen-enriched air, is passed in contact with a catalyst for oxidizing H2S to sulphur, this contact being brought about at temperatures which are either higher than the dew point of the sulphur formed, in which case the sulphur formed is present in the vapour state in the reaction mixture resulting from the reaction, or else at temperatures which are lower than the dew point of the sulphur formed, in which case the said sulphur is deposited on the catalyst, and this requires a regeneration of the sulphur-laden catalyst at regular intervals by purging with a non- oxidizing gas which is at a temperature of between 200°C and 500°C.
In particular, oxidation of H2S to sulphur at temperatures above the dew point of sulphur, that is to say at temperatures above approximately 180°C, can be carried out in contact with a catalyst consisting of titanium oxide (EP-A-0078690), of titanium oxide containing an alkaline-earth metal sulphate (WO-A-8302068), of

titanium oxide containing nickel oxide and optionally aluminium oxide (EP-A-0140045), of an oxide of the titanium oxide, zirconium oxide or silica type used in combination with one or more compounds of transition metals chosen from Fe, Cu, Zn, Cd, Cr, Mo, W, Co and Ni, preferably Pe, and optionally with one or more compounds of precious metals chosen from Pd, Pt, Ir and Rh, preferably Pd (FR-A-2511663) , or else of a thermally stabilized alumina used in combination with one or more compounds of transition metals such as the abovemen-tioned, especially Fe, and optionally with one or more compounds of precious metals chosen from Pd, Pt, Ir and Rh (FR-A-2540092).
Oxidation of H2S to sulphur, the operation being carried out at temperatures such that the sulphur formed is deposited on the catalyst, can, for its part, be performed in contact with a catalyst consisting, for example, of one or more compounds such as salts, oxides or sulphides of transition metals, for example Fe, Cu, Cr, Mo, W, V, Co, Ni, Ag and Mn, in combination with a support of the activated alumina, bauxite, silica/alumina or zeolite type (FR-A-2277877) . This oxidation of H2S with deposition of sulphur on the catalyst can also be carried out in contact with a catalyst consisting of a catalytic phase chosen from the oxides, salts or sulphides of the metals V, Mo, W, Ni and Co used in combination with an active charcoal support (French Patent Application No. 9302996 of 16.03.1993).
The catalysts such as the abovementioned, consisting of a catalytic phase based on at least one oxide, salt or sulphide of a transition metal, which phase is used in combination with a support consisting of at least one material chosen from alumina, titanium oxide, zirconium oxide, silica, zeolites, silica/alumina mixtures, silica/titanium oxide mixtures and active charcoal, which are used for the catalytic oxidation of H2S to sulphur, still exhibit certain shortcomings on prolonged use. In particular, the catalysts in which the support is based on alumina are capable of changing with

time by sulphation. As regards the catalysts in which the support consists of active charcoal, precautions must be taken during their use in order to avoid combustion of the support. Moreover, for these various catalysts, the catalytic phase with which the support is impregnated has a tendency to migrate into the lattice of the support, which makes it difficult, indeed even often impossible, to recover the metal from the catalytic phase in the spent catalyst. Finally, the abovementioned catalysts have a mediocre thermal conductivity, which does not make it possible to exert efficient control over the temperature within the catalytic beds containing them by heat exchange with a coolant fluid.
It has now been found that it was possible to overcome the disadvantages of the catalysts of the type mentioned above used for the catalytic oxidation of H2S to sulphur, and thus to obtain a process resulting in an improved selectivity for sulphur which is maintained durably with time, by forming the support for these catalysts from silicon carbide.
The silicon carbide support, in contrast to an alumina support, is not subject to sulphation and, unlike an active charcoal support, is not combustible. Moreover, migration of the catalytic phase into the lattice of the silicon carbide support is not observed, which makes it possible to recover the metals from the catalytic phase when the catalyst is spent, such a possibility assuming particular importance in the case where the catalytic phase contains harmful substances, such as nickel compounds. Finally, the silicon carbide support has good thermal conductivity which, especially for use of the catalyst in cooled catalytic beds, makes it possible to obtain a flatter temperature front within the catalytic bed and consequently better selectivity for sulphur.
The subject of the invention is therefore a process for oxidizing H2S present at a low concentration in a gas directly to sulphur by a catalytic route, the said process being of the type in which the said gas containing H3S is passed with a gas containing free

oxygen, in a quantity such as to provide an 02:H2S molar ratio ranging from 0.05 to 10, in contact with a catalyst for selectively oxidizing H2S to sulphur consisting of a catalytically active phase used in combination with a support, the said active phase containing at least one metal existing in the form of a metal compound and/or in the elemental state, and it is characterized in that the said support consists of silicon carbide.
In particular, the active phase used in combination with the silicon carbide support in order to form the oxidation catalyst according to the invention is advantageously composed of at least one transition metal, such as nickel, cobalt, iron, copper, silver, manganese, molybdenum, chromium, titanium, tungsten and vanadium, the said metal being in the oxide, sulphide or salt form and/or in the elemental state. The said active phase, expressed as weight of metal, most often represents 0.1 to 20%, more particularly 0.2 to 15% and more especially 0.2 to 7% of the weight of the oxidation catalyst. The silicon carbide support advantageously forms at least 40% and more particularly at least 50% of the weight of the oxidation catalyst.
The specific surface of the catalyst for the oxidation of H2S to sulphur can vary quite widely, depending on the conditions of implementation of the oxidation process. Advantageously, the said specific surface, determined by the BET nitrogen adsorption method at the temperature of liquid nitrogen (NF standard X 11-621) , can represent 2 m2/g to 600 m2/g and more especially from 10 m2/g to 300 m2/g.
The oxidation catalyst may be prepared by making use of the various known methods for incorporating one or more metal compounds into a divided solid forming a catalyst support. In particular, it is possible to carry out the operation by impregnating the silicon carbide support, which is in the form of a powder, pellets, granules, extrudates or other agglomerate forms, with a solution or a sol, in a solvent such as water, of the desired metal compound(s), followed by drying of the

impregnated support and calcining of the dried product at temperatures which can range from 250 °C to 500°C, the operation being optionally carried out in an inert atmosphere. The calcined catalyst may be subjected to a reduction treatment under hydrogen, for example between 200°C and 500"C, in order to convert the metal of the metal compound present in its active phase to the elemental state. It is also possible to envisage preparing the catalyst by carrying out the operation so as to insert catalytically active metal atoms, such as the abovementioned, into the crystal lattice of the silicon carbide.
The silicon carbide used to form the support for the catalyst for oxidizing H3S to sulphur may consist of any one of the known silicon carbides, with the proviso that it has the required specific surface characteristics, namely a specific surface, determined by the BET nitrogen adsorption method, ranging from 2 m2/g to 600 m2/g and more especially from 10 m2/g to 300 m2/g.
In particular, the said silicon carbide may be prepared by making use of any one of the techniques which are described in the citations EP-A-0313480 (corresponding to US-A-4914070) , EP-A-0440569, EP-A-0511919, EP-A-0543751 and EP-A-0543752.
The gas containing free oxygen which is employed for oxidizing to sulphur the HSS present in the gas to be treated is generally air, although it is possible to employ pure oxygen, oxygen-enriched air or else mixtures of various proportions of oxygen and of an inert gas other than nitrogen.
The gas containing free oxygen and the gas to be treated containing H2S can be brought separately into contact with the oxidation catalyst. However, in order to obtain a very homogeneous gaseous reaction mixture during the contact with the catalyst, it is preferable first of all to mix the gas to be treated containing H2S with the gas containing free oxygen and to bring the mixture thus produced into contact with the oxidation catalyst.
As indicated above, the gas containing free

oxygen is employed in a quantity such as to provide an 02:H2S molar ratio ranging from 0.05 to 10, more particularly from 0.1 to 7 and very especially from 0.2 to 4 in the reaction mixture which has been brought into contact with the catalyst for oxidizing H2S to sulphur.
The contact times of the gaseous reaction mixture with the oxidation catalyst may range from 0.5 of a second to 20 seconds and preferably from 1 second to 12 seconds, these values being given in standard pressure and temperature conditions.
The process for catalytically oxidizing H2S to sulphur according to the invention may be implemented at temperatures above the dew point of the sulphur formed during the reaction for oxidizing H2S, the said sulphur then being present in the vapour form in the reaction mixture which is in contact with the catalyst and which is collected at the exit of the catalytic oxidation zone. It is also possible to implement the oxidation process according to the invention by carrying out the operation at temperatures below the dew point of the sulphur formed during the oxidation reaction, the said sulphur then being deposited on the catalyst and the gaseous effluent collected at the exit of the oxidation zone being substantially free of sulphur. The temperatures for implementing the process according to the invention may advantageously be chosen between 30°C and 1000°C. For implementation of the process at temperatures above the dew point of the sulphur formed, temperatures of between 180°C and 1000°C and more especially between 200°C and 9 00°C are chosen. For implementation of the process at temperatures below the dew point of the sulphur formed, temperatures in the range 30°C to 180°C and more particularly in the range 80 °C to 160 °C, which encloses the solidification range for sulphur in the vicinity of 120°C, are chosen.
Prior to the stage of implementing the oxidation reaction, the oxidation catalyst according to the invention, and in particular the oxidation catalyst in which the active phase contains nickel, may be subjected to

activation by bringing the said catalyst into contact with elemental sulphur, in a quantity representing a slight excess, for example an excess which may range up to 300 mol %, with respect to the stoichiometric quantity corresponding to maximum sulphurization of the metal of the active phase of the catalyst, the said operation of bringing into contact being carried out under an inert atmosphere, for example a helium or argon atmosphere, at temperatures of between 250°C and 400°C and for a period of time which is sufficient, most often between 1 hour and 4 hours, to obtain maximum sulphurization of the metal of the active phase of the catalyst.
The catalyst according to the invention, especially a nickel catalyst, initially activated as indicated above, makes it possible to obtain a degree of conversion of H2S to sulphur which is equal to 100%, from the beginning of the oxidation of H2S by the oxygen of the gas containing free oxygen.
The catalyst according to the invention, and very particularly the nickel catalyst, may also form the subject of an initial activation equivalent to the activation with elemental sulphur described above by bringing the said catalyst into contact with a gas mixture containing H2S and an inert gas, the operation being carried out at temperatures of between 250°C and 400 °C for a period of time which is sufficient, in general between 1 hour and 15 hours, to produce maximum sulphurization of the metal of the active phase of the catalyst, it being possible for the said gas mixture to contain especially between 0.2% and 30% or more of H2S by volume. In particular, the gas mixture containing H2S which is used for the initial activation of the oxidation catalyst may consist of the gas to be treated, when the latter does not contain, in addition to H2S, components capable of reacting, at the activation temperatures, with the active phase of the catalyst.
The gas containing H2S at a low concentration which is treated by the process according to the invention may come from various sources. In particular, such

a gas may be a natural gas of low H2S content or else a gas originating from the gasification of coal or of heavy oils, or even a gas resulting from the hydrogenation of a residual gas, for example a sulphur plant residual gas, containing sulphur compounds such as S02, mercaptans, COS or CS2, which can be converted to HjS by the action of hydrogen or of water vapour, or yet again a gas resulting from the treatment, in contact with a Claus catalyst capable of promoting the sulphur-formation reaction between H2S and S02, of a gaseous effluent containing H2S and S02 in an H2S:S02 molar ratio higher than 2:1, and such that the said resulting gas contains especially H2S and no or very little S02 as sulphur compounds. The process according to the invention may be applied to the treatment of a gas containing H2S at a concentration of between 0.001% and 25% by volume and more especially ranging from 0.01% to 20% by volume. The gas to be treated may also contain organic sulphur compounds such as mercaptans, COS or CS2, at an overall concentration which may range up to approximately 1% by volume. Gases containing H2S at a concentration greater than 25% by volume could be treated by using the process according to the invention; however, in this case, it is preferable to use the conventional processes for the production of sulphur containing a thermal reaction stage.
The gas containing H2S which is subjected to oxidation on contact with the catalyst containing a silicon carbide support may be free of water or substantially free of water or, in contrast, contain a more or less large quantity of water. Thus, a gas containing H2S which has a water content which may range from 0% to approximately 50% by volume may be treated according to the invention. Advantageously, when the oxidation reaction of the gas containing H2S, in contact with a catalyst according to the invention, very particularly a nickel catalyst, containing a silicon carbide support, is implemented at temperatures below the dew point of the sulphur formed by the oxidation and more particularly at temperatures below the melting point of

the sulphur, the presence, in the gas to be treated containing H2S, of a quantity of water ranging from 10% to 50% by volume and more especially from 15% to 3 0% by volume makes it possible to substantially increase the period of time during which the efficiency of the catalyst is maintained at an optimum level.
When the process according to the invention is implemented at temperatures of between 180°C and 1000°C and more particularly between 200 °C and 900 °C, the operation of bringing the gas to be treated into contact with the oxidation catalyst containing a silicon carbide support may be carried out in a single oxidation zone containing the oxidation catalyst, especially when the H2S content of the gas to be treated is not greater than approximately 5% by volume, or alternatively in a plurality of oxidation zones arranged in series, each containing the oxidation catalyst, especially when the H2S content of the gas to be treated is greater than approximately 5% by volume, the said single oxidation zone or each of the zones of the plurality of oxidation zones operating at temperatures within the abovementioned ranges. Each of the oxidation zones functions in the range of temperatures corresponding to a substantially optimum selectivity of the catalyst for the formation of sulphur.
At the exit of the single oxidation zone or of each of the zones of the plurality of oxidation zones in series, a gaseous effluent laden with sulphur vapour is collected, which gaseous effluent, before any subsequent treatment for removing H2S, is caused to pass into a zone for separating sulphur in which it is freed from the greater part of the sulphur which it contains by condensing. When the gas containing H2S is treated by passing into a plurality of oxidation zones in series containing the oxidation catalyst containing a silicon carbide support, only a fraction of the H2S present in the gas to be treated is oxidized to sulphur in each of the said zones, the oxidation being carried out by injecting into the zone concerned, preferably mixed with the said gas

conveyed to this zone, the appropriate quantity of the gas containing free oxygen for carrying out this oxidation to sulphur. The quantity of H2S subjected to oxidation to sulphur in each of the zones, which represents a fraction of the total quantity of H2S in the gas to be treated, is advantageously between 2% and 5% by volume of the gas to be treated and the number of catalytic oxidation zones is chosen so that the gas to be treated arriving at the final catalytic zone contains not more than 5% by volume of H2S.
If need be, the gaseous effluent, which is collected at the exit of the single oxidation zone or at the exit of the final zone of the plurality of oxidation zones in series, in the implementation at temperatures above the dew point of the sulphur formed, may be subjected to an additional purification treatment after separation of the sulphur which it optionally contains, the said treatment depending on the nature of the gaseous sulphur compounds remaining in the effluent.
The implementation of the process according to the invention at temperatures above the dew point of the sulphur formed may constitute, in particular, the stage for oxidizing H2S of the processes for removing sulphur compounds present in a residual gas described in the citations FR-A-2589141 and FR-A-2589082 or the stage for oxidizing H2S of the process for treating sour gas described in the citation FR-A-2589140. The said implementation may also form the stage for oxidizing H2S to sulphur in Claus stoichiometry used in the processes of the type described in the citation FR-A-2511663 or the citation FR-A-2540092, which processes comprise bringing a gas having an H2S content below 2 5% by volume into contact, the operation being carried out at high temperature, that is to say between 200°C and 1000°C and more particularly between 350°C and 900°C, and in the presence of a catalyst for oxidizing H2S, with a controlled quantity of a gas containing free oxygen, in order to form a gaseous effluent containing H2S and S02 in an H2S:SO2 molar ratio which is substantially equal to 2:1

and a certain proportion of sulphur, and then bringing the said gaseous effluent, after cooling and optionally separating the sulphur which it contains, into contact with a Claus catalyst, in order to form a new quantity of sulphur, the said Claus catalyst being arranged in a single catalytic converter or in a plurality of catalytic converters, for example two or three, in series.
When the process according to the invention is implemented at temperatures below the dew point of the sulphur formed during the reaction for oxidizing H2S, that is to say at temperatures within the range 3 0°C to 180°C and more particularly in the range 80°C to 160°C, the operation of bringing the gas to be treated, which in this embodiment preferably contains less than 5% by volume of H2S and very particularly less than 2% by volume of H2S, into contact with the oxidation catalyst containing a silicon carbide support results in the formation of sulphur which is deposited on the catalyst.
If the H2S concentration and/or the temperature of the gas to be treated containing H2S brought into contact with the oxidation catalyst are such that, due to the high exothermicity of the reaction H2S + l/202 -» S + H20, the temperature of the reaction mixture, on conclusion of the oxidation, is capable of exceeding the temperature limit beyond which the reaction no longer has the desired selectivity, the heat given off by the said reaction is removed by subjecting the catalyst to cooling, by any known method. It is possible, for example, to carry out this cooling using a cold fluid circulating within the said catalyst, by indirect exchange of heat with the latter. It is alternatively possible to carry out the operation by placing the catalyst in a tubular reactor consisting of tubes arranged in a calandria with, for example, the catalyst present in the tubes and a cold fluid circulating between the tubes by the calandria. The catalytic oxidation can also be carried out in a multi-stage catalytic reactor with cooling of the reaction mixture between the successive stages by indirect exchange of heat with a cold

fluid, exchange of heat taking place inside or outside the oxidation reactor.
If the gas to be treated contains, in addition to H2S, a significant quantity of water, for example greater than 10% by volume, the temperatures for oxidizing H2S to sulphur below the dew point of the sulphur formed during the oxidation are preferably chosen in order to be above the dew point of the water present in the gas to be treated.
During the oxidation of H2S to sulphur at temperatures below the dew point of the sulphur formed, the oxidation catalyst gradually becomes laden with sulphur. Regeneration of the sulphur-laden catalyst is undertaken at regular intervals by purging the said catalyst with a non-oxidizing gas, the operation being carried out at temperatures of between 200°C and 500°C and preferably between 230°C and 450°C, to vaporize the sulphur retained on the catalyst, and the regenerated catalyst is then cooled to a temperature below the dew point of the sulphur for a new implementation of the oxidation reaction, this cooling being carried out with a gas which is at a suitable temperature below 180°C.
The purging gas, employed for regenerating the sulphur-laden catalyst, may be such as methane, nitrogen, C02 or mixtures of such gases or may alternatively consist of a fraction of the gas stream originating from the oxidation stage or of a fraction of the gas to be treated. The purging gas employed for the abovementioned regeneration may optionally contain a certain proportion of a gaseous reducing compound such as, for example, H2, CO or H2S, at least during the final stage of the regeneration, that is to say after the vaporization of the greater part of the sulphur deposited on the oxidation catalyst.
The implementation of the oxidation reaction according to the invention at temperatures below the dew point of the sulphur formed may be carried out in a single oxidation zone, containing the oxidation catalyst containing a silicon carbide support, which operates

alternately in an oxidation stage and in a regeneration/cooling stage. Such an implementation is adopted when the gas to be treated contains little H2S and when consequently the regeneration of the catalyst is not very frequent. The catalytic reaction is advantageously implemented in a plurality of oxidation zones, each containing the oxidation catalyst containing a silicon carbide support, which operate so that at least one of the said zones operates in a regeneration/cooling stage while the other zones are in a catalytic oxidation stage. It is also possible to operate by having one or more zones in an oxidation reaction stage, at least one zone in a regeneration stage and at least one zone in a cooling stage.
The gas employed for regenerating the oxidation catalyst preferably circulates in a closed circuit starting with a heating zone, passing successively through the catalytic zone being regenerated and a cooling zone, in which most of the sulphur present in the said gas is separated off by condensation, to return to the heating zone. The regenerating gas may, of course, also travel in an open circuit.
The gas used for cooling the regenerated oxidation catalyst is of the same type as that employed for regenerating the sulphur-laden catalyst. The said gas may optionally contain oxygen in a proportion which is less than or equal to that used in the catalytic oxidation stage. The regeneration gas and coolant gas circuits may be independent of one another. However, according to one embodiment, the regenerating gas circuit defined above may also comprise a bypass connecting the exit of its cooling zone to the entry of the zone being regenerated by bypassing its heating zone, and this makes it possible to short-circuit the said heating zone and thus to employ the regenerating gas as coolant gas.
The embodiment of the process according to the invention for oxidizing H2S to sulphur at temperatures below the dew point of the sulphur formed during the oxidation may advantageously form the stage for catalytic

Oxidation of H2 S which follows the claus reaction stage at a temperature below 180°C in the process for the desulphurization of gas containing H2S described in the citation FR-A-2277877.
Accordingly, the present invention relates to a process for the recovery of sulphur by catalytically oxidizing the H2S present at a low concentration in a gas, which comprises the steps of:
contacting the gas containing H2S and a gas containing free oxygen, in a quantity such as to provide an O2:H 2S molar ratio ranging from 0.05 to 10, with an oxidation catalyst comprised of a silicon carbide support in association with an active phase composed of at least one transition metal such as nickel, cobalt, iron, copper , silver, manganese, molybdenum, chromium, titanium, tungsten and vanadium, the said transition metal being in the oxide or salt form and/or in the elemental state, to selectively oxidize H2S oxidation whereby the said sulphur is deposited on the catalyst;
subjecting periodically the sulphur-laden catalyst to regeneration by purging with a purging gas at temperatures between 200°C and 500°C to vaporize the sulphur retained on the catalyst and recovering the vaporized sulphur by condensation, and
cooling the regenerated catalyst to a temperature below the dew point of the sulphur for a new implementation of the H2S oxidation, the said cooling being performed with a coolant gas which is at a temperature below 180° C.

The invention is illustrated by the following examples, given without any limitation being implied. EXAMPLE 1
The treatment was carried out of a gas consisting, by volume, of 1% of H2S, 5% of H2O and 94% of C02, the operation being carried out at temperatures above the dew point of the sulphur formed, with the use of a catalyst composed of a silicon carbide support impregnated with an iron compound and with a chromium compound and containing, expressed as weight of metal with respect to the weight of the catalyst, 3.2% of iron and 0.35% of chromium.
The catalyst was prepared as follows. Silicon carbide grains, with a particle size between 0.8 mm and 1 mm and a BET specific surface of 78 m2/g, were first of all impregnated with a solution of an iron compound and of a chromium compound at concentrations such as to provide the desired quantities of iron and of chromium in the resulting catalyst. The impregnated product obtained was dried at ambient temperature for 40 hours and then at 120°C for 50 hours and was subsequently subjected to a calcination at 500°C for 20 hours, in order to produce the catalyst.
The catalyst obtained contained, as indicated above, 3.2% by weight of iron and 0.35% by weight of chromium and had a BET specific surface equal to 77 m2/g.
The gas containing H2S was treated in a stationary bed catalytic reactor containing 1.1m3 of catalyst, the said reactor being equipped, on the one hand, with a delivery conduit for the gas to be treated and, on the other hand, with a discharge conduit for the gases forming the exit of the reactor. The gas delivery conduit contained a branch connection for the injection of air as gas containing free oxygen and was additionally equipped with an indirect heat exchanger, operating as a

heater, fitted between the branch connection for injection of air and the entry of the reactor. The gas exit conduit was equipped with a sulphur condenser cooled by circulation of steam. The gas is passed from the entry to the exit of the reactor through the catalyst bed.
The gas to be treated, introduced via the gas delivery conduit with a flow rate of 1000 Nm3/h and a temperature of 40°C, received, via the branch connection, an addition of air corresponding to a flow rate of 2 9 Nm3/h, this air being injected at ambient temperature. The mixture of gas to be treated and of air, in which the O2:H2S molar ratio was equal to 0.6, was brought to a temperature of 180°C, by passing into the heater, and was then injected into the reactor at this temperature. The contact time of the said mixture with the catalyst present in the reactor was equal to 4 seconds. The gaseous effluent exiting from the reactor, via the gas discharge conduit, no longer contained free oxygen nor H2S and had a temperature of 240°C. This effluent was cooled to approximately 130°C in the condenser in order to separate therefrom the sulphur which it contained.
The conversion of H2S was complete and the selectivity of the sulphur was equal to 92%. EXAMPLE 2
The treatment was carried out of a residual gaseous effluent containing, by volume, 0.8% of H2S as the only sulphur compound, this effluent being obtained by hydrogenation/hydrolysis of a residual gas from a Claus sulphur plant in which a sour gas containing 70% by volume of H2S was treated.
The said gaseous effluent was treated at a temperature below the dew point of the sulphur formed by the oxidation of the said H2S and by making use of a catalyst consisting of silicon carbide impregnated with a nickel compound and containing, by weight, 4% of nickel, the said catalyst having a BET specific surface of 220 m2/g-
The said catalyst was obtained by impregnating microporous silicon carbide grains with an appropriate

quantity of nickel acetate in aqueous solution, then drying the impregnated product at 100°C and finally calcining the dried product at 300°C for 3 hours. The silicon carbide grains, with a mean diameter of 1 mm, had a BET specific surface of 240 m2/g.
The operation was carried out in a plant composed of two catalytic oxidation reactors fitted in parallel, each reactor having an entry and an exit separated by a stationary bed of the abovementioned catalyst. The said reactors were additionally arranged so that alternately, by means of valves which could be switched by a clock, one of the reactors operated in a reaction stage, that is to say had its entry connected to a gas delivery conduit, on which was fitted an indirect heat exchanger and, downstream of the exchanger, a branch connection for injection of air, and its exit connected to a gas discharge conduit, and the other reactor operated in a regeneration/cooling stage, that is to say was arranged in a regeneration/cooling circuit equipped with means for ensuring the circulation of a purging gas through the oxidation reactor starting from a heater as far as a sulphur condenser and return to the said heater and for subsequently circulating a cold gas, of the same composition as the regenerating gas, through the reactor which has undergone regeneration.
The gaseous effluent to be treated arrived via the gas delivery conduit with a flow rate equal to 940 kmol/h and was brought to a temperature of 90°C in the exchanger fitted to the said conduit and then 44 kmol/h of ambient air were added via the branch connection. The mixture obtained entered into the reactor in the oxidation stage with a temperature substantially equal to 90 °C. The contact time of the gas mixture, passing into the reactor in the oxidation reaction stage, with the catalyst layer present in the said reactor was equal to 10 seconds. The degree of conversion of H2S, in the reactor in the oxidation reaction stage, was equal to 100%. At the exit of the said reactor, a gas stream was discharged which had a temperature of approximately 140°C

and contained 160 vpm of SO 2, the said gas stream being conveyed to an incinerator before being discharged to the atmosphere.
A purging gas was injected into the reactor operating in the regeneration/cooling stage for the purposes of regenerating the sulphur-laden oxidation catalyst, the said purging gas consisting of nitrogen and being injected into the said reactor with a temperature of between 250°C and 350°C and a flow rate equal to 10,000 Nm3/h. On conclusion of the catalyst regeneration stage, the temperature of the purging gas was lowered to approximately 125°C and the purging was continued with the cooled purging gas until the regenerated catalyst bed reaches substantially the said temperature. On regenerating under nitrogen, all the sulphur deposited on the catalyst is recovered.
The oxidation reactors operated alternately for 3 0 hours in the reaction stage and for 3 0 hours, 10 hours of which were for cooling, in the regeneration/cooling stage.
The sulphur plant, incorporating the process according to the invention for treating the residual gases produced by the said plant, which gases were hydrogenated prior to the treatment according to the invention, had an overall sulphur yield of 99.9% over a period of several months. EXAMPLE 3
The treatment was carried out of an H2S-depleted sour gas, the said gas consisting, by volume, of 95.5% of C02, 4% of H20 and 0.5% of H2S.
The said sour gas was treated at a temperature below the dew point of the sulphur produced by oxidizing the H2S of this sour gas, the operation being carried out in a plant similar to that used in Example 2 and use being made of a catalyst composed of silicon carbide, containing 4% of nickel by weight and having a BET specific surface equal to 210 m2/g. This catalyst was prepared as described in Example 2 and, after its calcination, it was reduced under a hydrogen stream at 400°C

for 10 hours.
The depleted sour gas to be treated arrived via the gas delivery conduit with a flow rate equal to 2241 Nm3/h and a temperature of approximately 30°C and was brought to a temperature of 80°C in the exchanger fitted to the said conduit, and then 89.6 Nm3/h of air, brought to 80°C, was added via the branch connection. The mixture obtained entered the reactor in the oxidation stage with a temperature substantially equal to 80°C. The contact time of the gas mixture, passing into the reactor in the oxidation reaction stage, with the catalyst layer present in the said reactor was equal to 10 seconds. The degree of conversion of H2S, in the reactor in the oxidation reaction stage, was equal to 100%. At the exit of the said reactor, a gas stream was discharged which had a temperature of approximately 105°C and contained less than 100 vpxn of S02, the said gas stream being conveyed to an incinerator before being discharged to the atmosphere.
In the reactor operating in the regeneration/cooling stage, a purging gas consisting of nitrogen was injected for the purposes of regenerating the sulphur-laded oxidation catalyst, and then of cooling the regenerated catalyst, the operation being carried out as indicated in Example 2. On regenerating under nitrogen, all the sulphur deposited on the catalyst is recovered.
The oxidation reactors operated alternately for 3 0 hours in the reaction stage and for 3 0 hours, 10 hours of which were for cooling, in the regeneration/cooling stage. EXAMPLE 4
The treatment was carried out of a sour gas containing, by volume, 20% of H2S, 8% of water and 72% of CO2 by a process comprising a catalytic oxidation stage in Claus stoichiometry followed by a Claus reaction stage carried out in two successive stages, the first above the dew point of the sulphur formed and the second below the said dew point.
The operation was carried out in a plant compri-

sing the following components:
- a stationary bed oxidation reactor containing an oxidation catalyst according to the invention, the said reactor being fitted with a conduit for delivering the mixture of sour gas and of air and with a conduit for discharging the effluent from the oxidation;
- a gas/gas indirect heat exchanger, one of the exchange circuits of which is fitted in series to the conduit for delivering the mixture of sour gas and of air and the other exchange circuit of which is in series with the conduit for discharging the effluent from the oxidation;
- a primary stationary bed catalytic converter which contains a Claus catalyst in the form of extrudates with a diameter of 3 mm composed of titanium oxide containing 10% by weight of calcium sulphate and the entry of which is connected to the conduit for discharging the oxidation effluent through the appropriate exchange circuit of the heat exchanger;

- a catalytic conversion array comprising two secondary catalytic converters and a sulphur condenser cooled with steam, in which, on the one hand, each of the said secondary converters contains a Claus catalyst composed of an activated alumina in the form of balls with a diameter of 4 to 6 mm and, on the other hand, the secondary converters and the sulphur condenser are arranged so that the exit of the primary converter can be switched alternately to the entry of one or the other of the said secondary converters and so that the latter are connected in series through the sulphur condenser; and
- a catalytic incinerator, the entry of which is connected to the exit of the catalytic conversion array and the exit of which is connected to a chimney open to the atmosphere, this incinerator using a catalyst composed of a silica impregnated with iron sulphate and with palladium oxide.
The oxidation catalyst used in the oxidation stage in Claus stoichiometry was composed of a silicon carbide support impregnated with an iron compound and

containing 4.6% by weight of iron with respect to the total weight of the catalyst.
The catalyst was prepared as follows. Silicon carbide grains, having a particle size of between 0.8 nun and 1 mm and a BET specific surface of 78 m2/g, were first of all impregnated with an aqueous iron sulphate solution in a concentration such as to provide the desired quantity of iron in the resulting catalyst. The impregnated product obtained was dried and calcined as indicated in Example 1.
The catalyst obtained contained, as indicated above, 4.6% by weight of iron and had a BET specific surface equal to 76 m2/g.
The sour gas arriving with a flow rate of 1000 Nm3/h (standard conditions) had 285.6 Nm3/hour of air added to it and the gas mixture obtained was preheated to a temperature of 200°C, by passing into the heat exchanger, and was then injected into the oxidation reactor. The contact time between the gas mixture and the oxidation catalyst was equal to 2 seconds (standard conditions) and the temperature within the catalytic bed rose to 800°C.
The effluent from the oxidation reactor contained H2S and S02 in an H2S:S02 molar ratio equal to 2:1, as well as 6 v.p.m. of free oxygen and a quantity of sulphur vapour corresponding to a degree of conversion of H2S to sulphur equal to 59%.
This effluent was cooled to 150°C in the heat exchanger in order to condense the sulphur which it contains and to use a portion of the heat from the said effluent for preheating the mixture of sour gas and of air. The cooled effluent was then heated to 2 50°C and conveyed into the primary Claus catalytic converter. The contact time between the catalyst, based on titanium oxide, and the gaseous effluent in the said converter was equal to approximately 3 seconds and the temperature within the catalytic bed was 3 00°C.
The reaction mixture containing H2S, S02 and sulphur vapour resulting from the primary Claus converter

was conveyed through the converter in the "regeneration" stage of the catalytic conversion array in order to carry out purging of the sulphur-laden catalyst present in this converter, the said purging being carried out at a temperature of approximately 300°C with a gas/catalyst contact time of approximately 6 seconds. The sulphur-laden gas originating from the converter being regenerated then passed through the steam-cooled sulphur condenser, in which the said gas was cooled to a temperature of approximately 150°C and freed from the sulphur which it contained by condensation. The resulting cooled gas, which contained H2S and S02 as well as a very small quantity of sulphur vapour, was conveyed into the catalytic converter in the "Claus reaction" stage of the catalytic conversion array operating at a temperature of 150°C, with a gas/catalyst contact time equal to approximately 6 seconds, in order to form sulphur by reaction between H2S and SO2, the said sulphur being deposited on the catalyst.
The residual gases coming from the converter in the "Claus reaction" stage were conveyed to catalytic incineration and the smoke resulting from the incineration, which contained SO2 at a very low concentration as the only sulphur compound, was discharged to the atmosphere via the chimney.
The residual gases exiting from the catalytic conversion array contained only 800 v.p.m. of total sulphur, namely H2S, S02, sulphur vapour and/or vesicular sulphur, which corresponds to an overall yield for conversion of H2S to sulphur equal to 99.6%.
After an operating time of 800 hours, under the abovementioned conditions, the effluent from the catalytic oxidation reactor in Claus stoichiometry contained H2S and SO2 in an H2S:SO2 molar ratio equal to 2.02 and a quantity of sulphur vapour corresponding to a degree of conversion of H2S equal to 56%, the overall yield for conversion of H2S to sulphur then being 99.4%. EXAMPLE 5:
The treatment was carried out of a gas consis-

ting, by volume, of 1% of H2S, 5% of H2O and 94% of C02, the operation being carried out at temperatures above the dew point of the sulphur formed, with the use of a catalyst composed of a silicon carbide support impregnated with an iron compound and with a chromium compound and containing, expressed as weight of metal with respect to the weight of the catalyst, 3.2% of iron and 0.35% of chromium, the said catalyst being activated by a direct sulphurization.
The catalyst was prepared as follows. Silicon carbide grains, with a particle size of between 0.8 mm and 1 mm and a BET specific surface of 7 8 m2/g, were first of all impregnated with a solution of an iron compound and of a chromium compound at concentrations such as to provide the desired quantities of iron and of chromium in the resulting catalyst. The impregnated product obtained was dried at ambient temperature for 40 hours and then at 120°C for 50 hours and was then subjected to a calcination at 500°C for 2 0 hours. The calcined product obtained, containing the elements iron and chromium in the oxide form supported on silicon carbide, was then treated either with H2S diluted to the concentration of 1% by volume in a helium flow or with solid sulphur mechanically mixed with the catalyst, the quantity of sulphur representing 6.2% of the weight of the said catalyst. The said treatment was implemented at 3 00°C for two hours, in order to bring the metals iron and chromium to the sulphide form constituting the active phase of the catalyst.
The sulphur-containing catalyst obtained contained, as indicated above, 3.2% by weight of iron and 0.35% by weight of chromium and had a BET specific surface equal to 76 m2/g.
The gas containing H2S was treated by using the sulphur-containing catalyst, the operation being carried out as indicated in Example 1.
The conversion of H2S was total from the beginning of the treatment of the gas containing H2S and the selectivity for sulphur was equal to 93%.

EXAMPLE 6
The treatment was carried out of an H2S-depleted sour gas, the said gas consisting, by volume, of 95.5% of C02, 4% of H2O and 0.5% of H2S.
The said sour gas was treated at 100°C, a temperature below the dew point of the sulphur produced by oxidizing the H2S of this sour gas, the operation being carried out in a plant similar to that used in Example 2 and use being made of a catalyst composed of silicon carbide containing 4% by weight of nickel and having a BET specific surface equal to 210 m2/g. This catalyst was prepared as described in Example 2 and, after its calcination, it was reduced under a hydrogen stream at 400°C for 10 hours.
The depleted sour gas to be treated arrived via the gas delivery conduit with a flow rate equal to 2241 Nm3/h and a temperature of approximately 3 0°C and was brought to a temperature of 80°C in the exchanger fitted to the said conduit and then it was mixed, via the branch connection, with 89.6 Nm3/h of air and 1000 Nm3/h of an inert gas charged with 55% by volume of steam and brought to 100°C. The quantity of steam present in the final mixture was approximately 20% by volume. The mixture obtained entered the reactor in the oxidation stage with a temperature of 86°C. The contact time of the gas mixture, passing into the reactor in the oxidation reaction stage, with the catalyst layer present in the said reactor was equal to 10 seconds. The degree of conversion of H2S, in the reactor in the oxidation reaction stage, was equal to 100%. At the exit of the said reactor, a gas stream was discharged which had a temperature of approximately 110°C and contained less than 100 vpm of S02, which gas stream was conveyed to an incinerator before being discharged to the atmosphere.
A purging gas consisting of nitrogen was injected into the reactor operating in the regeneration/cooling stage for the purposes of regenerating the sulphur-laden oxidation catalyst, and then of cooling the regenerated catalyst, the operation being carried out as indicated in

Example 2. On regenerating under nitrogen, all the sulphur deposited on the catalyst is recovered.
The presence of the abovementioned quantity of steam in the reaction mixture and more generally of a quantity of between 10% and 50% and especially lying between 15% and 30% by volume makes it possible to substantially extend the period of time during which the optimum desulphurizing activity of the catalyst is maintained. The steam acts as dispersant for the sulphur deposited on the catalyst and thus protects access of the reactants to the active sites of the catalyst.

WE CLAIM:
1. A process for the recovery of sulphur by catalytically oxidizing the H2S
present at a low concentration in a gas , which comprises the steps of:
contacting the gas containing H2S and a gas containing free oxygen,
in a quantity such as to provide an O2:H2S molar ratio ranging from
0.05 to 10, with an oxidation catalyst comprised of a silicon carbide
support in association with an active phase composed of at least one
transition metal such as nickel, cobalt, iron, copper , silver,
manganese, molybdenum, chromium, titanium, tungsten and
vanadium, the said transition metal being in the oxide or salt form
and/or in the elemental state, to selectively oxidize H2S oxidation
whereby the said sulphur is deposited on the catalyst;
subjecting periodically the sulphur-laden catalyst to regeneration by purging with a gas of the kind such as herein described at temperatures between 200°C and 500°C to vaporize the sulphur retained on the catalyst and recovering the vaporized sulphur by condensation, and
cooling the regenerated catalyst to a temperature below the dew point of the sulphur for a new implementation of the H2S oxidation, the said cooling being performed with a gas of the kind such as herein described which is at a temperature below 180°C.
2. A process as claimed in claim 1, wherein the regeneration of the sulphur-laden catalyst is carried out at temperature of between 230°C and 450°C.
3. A process as claimed in any one of preceding claims, wherein the gas containing free oxygen is used in a quantity such as to provide an O2:H2S molar ratio ranging from 0.1 to 7 and more particularly from 0.2 to 4.

4. A process as claimed in any one of claims 1 to 3, wherein the contacting of the gas containing H2S and a gas containing free oxygen with the oxidation catalyst is at a temperature between 90°C and 140°C.
5. A process for the recovery of sulphur by catalytically oxidizing the H2S present at a low concentration in a gas substantially as herein described with reference to the foregoing examples.

Documents:

1079-del-1996-abstract.pdf

1079-del-1996-claims.pdf

1079-del-1996-complete specification (granted).pdf

1079-DEL-1996-Correspondence-Others.pdf

1079-del-1996-correspondence-po.pdf

1079-del-1996-description (complete).pdf

1079-del-1996-form-1.pdf

1079-del-1996-form-13.pdf

1079-del-1996-form-2.pdf

1079-del-1996-form-3.pdf

1079-del-1996-form-4.pdf

1079-del-1996-gpa.pdf

1079-del-1996-pct-210.pdf

1079-del-1996-petition-137.pdf

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Patent Number

232806

Indian Patent Application Number

1079/DEL/1996

PG Journal Number

13/2009

Publication Date

27-Mar-2009

Grant Date

21-Mar-2009

Date of Filing

22-May-1996

Name of Patentee

ELF EQUITAINE PRODUCTION

Applicant Address

ELF-2 PLACE DE LA COUPOLE, LA DEFENSE 6-92400 COURBEVOIE, FRANCE

Inventors:

#	Inventor's Name	Inventor's Address
1	ANDRE PHILLIPE	LOTISSEMENT DE LA TRINITE 64300 ORTHEZ, FRANCE
2	SABINE SAVIN-PONCET	CHEMIN DE LANGLES, 64160 BUROS, FRANCE
3	JEAN NOUGAYREDE	13 RUE DU PROFESSUR J MONOD, 64000, PAU, FRANCE
4	MARC LEDOUX	11 RUE D'USSE, 67000, STRASBOURG, FRANCE
5	CUONG PAHM HUU	4 RUE DES FRERES, 67700, SAVERNE, FRANCE
6	CLAUDE CROUZET	9 RUE CHENONCEAUX 67000, STRANSBOURG, FRANCE

PCT International Classification Number

B01J 8/00

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1			NA