Title of Invention	A method for preparation of synthesis gas
Abstract	A method for the preparation of synthesis gas by partial oxidation or steam and/or dry reforming of natural gas and/or light hydro carbons by using a catalyst of formula (I) wherein: A and A' are different and are selected from the La, Ce, Ca or Sr or from the group IIa of the Mendeleev's periodical table of elements; B is selected from Mn, Fe, Co or Al; 0 < x ≤ 0.7, 0<y≤0.5, 0 ≤ x+y ≤ 0.8, 0 ≤ z ≤ 1 and 8 is the sub stoechiometric value of oxygen to obtain the electric neutrality of the Perovskite compound. at a temperature in the range of 500 to 1300°C preferably between 600 to 1100°C and pressure in the range of 105 Pa to 3 106 Pa and between 105 Pa to 106 Pa to obtain the synthesis gas.

Title of Invention

A method for preparation of synthesis gas

Abstract

A method for the preparation of synthesis gas by partial oxidation or steam and/or dry reforming of natural gas and/or light hydro carbons by using a catalyst of formula (I) wherein: A and A' are different and are selected from the La, Ce, Ca or Sr or from the group IIa of the Mendeleev's periodical table of elements; B is selected from Mn, Fe, Co or Al; 0 < x ≤ 0.7, 0<y≤0.5, 0 ≤ x+y ≤ 0.8, 0 ≤ z ≤ 1 and 8 is the sub stoechiometric value of oxygen to obtain the electric neutrality of the Perovskite compound. at a temperature in the range of 500 to 1300°C preferably between 600 to 1100°C and pressure in the range of 105 Pa to 3 106 Pa and between 105 Pa to 106 Pa to obtain the synthesis gas.

Full Text	The present invention relates to a method for the preparation of synthesis gas. The catalytic partial oxidation of hydrocarbons, natural gas or methane to synthesis gas, which consist in mixtures of hydrogen (H2) and carbon monoxide (CO) in various proportions, has been processed for mariy years. While currently limited as an industrial process, the partial oxidation is also of interest for the significant released heat and for the use of smaller reactors. More particularly, the .partial oxidation of methane at short residence time is a goal to reach synthesis gas using an alternative process to the steam reforming process, which is today the most popular one. Synthesis gas can be used as feed for fuel cell or as a reducing atmosphere in the metallurgic industry but it is mainly the key step for activation of methane for the indirect production of methanol and middle distillate in the petrochemical and chemical industries. The advantage of the catalytic partial oxidation of methane is mainly its strong exothermic character in the short residence time. Both parameters allow producing synthesis gas with lower investment cost without delivering large quantities of external energy. . Nevertheless, because this strong exothermic character of the total oxidation reactions, the temperature of the catalytic bed reaches more than well above 1000°C. There is thus a need for very stable catalyst in terms of metal sintering and support resistance. . Furthermore, as the catalyst activity affects the thermal profile of the reactor, a careful modulation is therefore required to avoid hot spot in the reactor which can light on the homogeneous reaction. A novel approach relates to the possibility of introducing the metal in the crystallographic structure of a given material and then to. activate the catalyst by reducing the metal "in situ" or under hydrogen flow. This allows in some case to develop a strong interaction between metal and surface, Some of these catalysts have a Perovskite structure. US 5,149,516 discloses the partial oxidation of methane'to produce carbon monoxide and hydrogen using a Perovskite catalyst, such as LaCoO3-. US 5,447,705 discloses a catalyst for the partial oxidation of methane or of a gaseous mixture containing methane, said catalyst preferably having a Perovskite structure with LaFeNi as a cation composition. However, in the reported examples it is very difficult to balance the structure stability. On one hand, if the reducible metal (Ni and Co) is present in large amount, the structure is completely reduced and the Perovskite structure becomes unstable. On the other hand, if the reducible cation is present in low amount, the catalytic activity is poor and does not allow to work with short residence time. US 6,110,861 discloses a two-part catalyst comprising a dehydrogenation portion and an oxide-ion conducting portion. WO 0160742 discloses a catalysts and a processes for the catalytic conversion of hydrocarbons to carbon monoxide and hydrogen employing new families of chromium-rare earth based catalysts . Today, none of the existing catalytic partial oxidation processes is able to provide a sufficiently high conversion of the reactant gas together with a high selectivity of CO and H2 reaction products, without using high quantities(of rare and costly catalysts, nor without experiencing adverse effects such as an excessive coking of the catalyst, or a premature-catalyst failure by its lack of heat resistance or by its mechanical instability or even by the mechanical instability of its structure. That is why there is a continuing need for new catalysts that are mechanically stable and retains a high level of activity and selectivity to CO and H2 products under conditions of high temperature, without excessive coking. The inventors have found that the catalysts of the present invention overcome some of these drawbacks. , Accordingly, the present invention provides a composition characterized in that it essentially consists in a solid solution of a mixture of at least a perovskite cristallographic structure with nickel and/or rhodium metal. According to the present invention there is provided a method for the preparation of synthesis gas by partial oxidation or steam and/or dry reforming of natural gas and/ or light hydro carbons by using a catalyst of formula (I) (Formula Removed) wherein: A and A' are different and are selected from the La, Ce, Ca or Sr or from the group IIa of the Mendeleev's periodical table of elements; B is selected from Mn, Fe, Co or Al; 0 0 0 ≤ x+y≤ 0.8, 0 ≤ z ≤ 1 and 8 is the sub stoechiometric value of oxygen to obtain the electric neutrality of the Perovskite compound. at a temperature in the range of 500 to 1300°C preferably between 600 to 1100°C and pressure in the range of 105 Pa to 3 106 Pa and between 105 Pa to 106 Pa to obtain the synthesis gas. According to one particular aspect the invention A and A' are independently chosen from La, Ce, Ca or Sr. A is preferably La. According to another particular aspect of the invention, B is chosen from Mn, Fe, Co or Al. The invention is more particularly- relates a composition, characterized in that it is represented by the formula (Ia): (Formula Removed) wherein A', x, y, and z and 8 are as hereinabove defined for the formula (T). Among the compounds represented by the formula (la), those represented by the formula (lb): (Formula Removed) wherein x, y, and z and 8 are as hereinabove defined for the formula (T), are preferred. According to a preferred aspect of the invention, in the formulas (I) (la) or (lb), 0 According to another preferred aspect of the invention, in the formulas (I) (la) or (lb), 0 The invention more spefically consists in the following compositions : La Fe0.7 Nio.25 Rho.05 03_s Lao.8 Ce0.2 Fe0.7 Nio.25 Rho.os 03.5 Lao.g Ce0.2 Fe0.7 Ni0.3 03.5 While two composition have been selected for comparison. La Fe0.7 Ni0.3 03.s La Feo.95 Rho.os O3-5 According to another aspect of the present invention, the composition as defined as herein above, is used as a catalyst of the partial oxydation of natural gas and/or Kght hydrocarbons to synthesis gas, as a catalyst of the steam and/or drv reforming- of natural gas and/or light hydrocarbons (C2-C4) to synthesis gas and/or selective oxidations. By light hydrocarbons, those which have a carbon chain containing from two to four carbon atoms (C2-C4), are more sepecifically within the scope of the present invention. The composition of the invention are more specifically worked on in the operating catalyst temperature conditions in the range of 500 to 1300°C and preferably between 600 to 1100°C, and/or in the operating catalyst pressure conditions in the range of 105 Pa to 3 106 Pa and preferably between 105 Pa to 106 Pa. In the use herein before mentioned uses, the oxydant gaseous feed is of any kind; it is preferably pure oxygen, oxygen and inert £as mixture, steam, carbon dioxide or a mixture of part or/and all of them. According to another aspect the present invention, the composition as defined as herein above, is used as a catalyst of hydrogenation reactions or as a catalyst of dehydrogenated oxydative reactions. The following examples illustrate the present invention without limiting it. Example 1: LaFe0.7Ni0.25Rh0.05O3 (Invention) 5.3 g of La(NO3)3, 4.6 g of Fe(NO3)3, 1.2 g of Ni(NO3)2 and 0.83 g of Rh nitrate solution 10 % w/w are dissolved in 300 ml of distilled water and slowly dropped in a solution containing 7.7 g of citric acid dissolved in 400 ml of ethylene glycol. After mixing, the resulting solution are heated at 90°C for 4 h. The evaporation of water from the solution brings to the formation of a sol (colloidal solution with micrometric micelles). The catalyst is dried in oven at 90°C then the oven temperature is increased to 180°C over night. In this step, a gel is formed and dried. The obtained solid is calcined at 500°C for 4 h and then at 900°C for 12 h. The XRD shows the perovskite cubic pattern (figure 1) and the surface area after calcination is 8 m2/g. Figure 1 discloses XRD patterns of LaFei.xMx03 catalysts after calcination at 900°C (Mx = Ni0.3, Nio.25Rho.05 or Rho.05). (O) LaFeM03 perovskite structure. Example 2: La0.8Ce0.2Fe0.7Ni0.25Rh0.05O3 (Invention) 5.3 g of La(NO3)3, 1.8 g Ce(NO3)3, 5.7 g of Fe(NO3)3, 1.5 g of Ni(NO3)2 and 1.0 g of Rh nitrate solution 10 % w/w are dissolved in 400 ml of distilled water and slowly dropped in a solution containing 9.5 g of citric acid dissolved in 500 ml of ethylene glycol. After mixing, the resulting solution is heated at 90°C for 4 h. The evaporation of water from the solution brings to the formation of a sol (colloidal solution with micrometric micelles). The catalyst is dried in oven at 90°C then the oven temperature is increased to 180°C over night. In this step, a gel is formed and dried. The obtained solid is calcined at 500°C for 4 h and then at 900°C for 12 h. The XRD shows the perovskite cubic pattern and the reflection of the CeO2 phase (Figure 2). The surface area after calcination is 10 m /g. Figure 2 discloses XRD patterns of La0.8Ce0.2Fe0.7Ni0.25Rh0.05O3 catalysts after calcination at 900°C / (+) ABO3 perovskite structure, () CeO2 compound. Example 3: LaFe0.7Ni0.3O3 (Comparative example) 5.3 g of La(NO3)3, 4.7 g of Fe(NO3)3, 1.4 g of Ni(NO3)2 are dissolved in 300 ml of distilled water and slowly dropped in a solution containing 7.7 g of citric acid dissolved in 400 ml of ethylene glycol. After mixing, the resulting solution is heated at 90°C for 4 h. The evaporation of water from the solution brings to the formation of a sol (colloidal solution with micrometric micelles). The catalyst is dried in oven at 90°C then the oven temperature is increased to 180°C over night. In this step, a gel is formed and dried. The obtained solid is calcined at 500°C for 4 h and then at 900°C for 12 h. The XRD shows the perovskite cubic pattern (Figure 1) and the surface area after calcination is 8 m2/g. Example 4: LaFe0.95Rh0.05O3 (Comparative example) 5.3 g of La(NO3)3, 6.3 g of Fe(NO3)3, and 0.84 g of Rh nitrate solution 10% w/w are dissolved in 300 ml of distilled water and slowly dropped in a solution containing 7.7 g of citric acid dissolved in 400 ml of ethylene glycol. After mixing, the resulting solution is heated at 90°C for 4 h. The evaporation of water from the solution brings to the formation of a sol (colloidal solution with micrometric micelles). The catalyst is dried in oven at 90°C then the oven temperature is increased to 180°C over night. In this step, a gel is and dried. The solid obtained is calcined at 500°C for 4 h and then at 900°C for 12 h. The XRD shows the perovskite cubic pattern (Figure 1) and the surface area after calcination is 5 m2/g. Example 5: La0.8Ce0.2Fe0.7Ni0.3O3 (Invention) 4.3 g of La(NO3)3, 1.4 g Ce(NO3)3, 4.6 g of Fe(NO3)3, 1.4 g of Ni(NO3)2 are dissolved in 400 ml of distilled water and slowly dropped in a solution containing 9.5 g of citric acid dissolved in 500 ml of ethylene glycol. After mixing, the resulting solution is heated at 90°C for 4 h. The evaporation of water from the solution brings to the formation of a sol (colloidal solution with micrometric micelles). The catalyst is dried in oven at 90°C then the oven temperature is increased to 180°C over night. In this step, a gel is formed and dried. The solid obtained is calcined at 500°C for 4 h and then at 900°C for 12h. The XRD shows the perovskite cubic pattern and the reflection of the Ce02 phase (Figure 2). The surface area after calcination is 10 m2/g. The same CPO material can be obtained by solid state reaction. The precursors chosen are La203, Fe203, Ce2(C03)3,xH20 and 2NiC03,3Ni(0H)2,4H20. The oxides and carbonates are ball mixed during one hours in alcohol or water. After drying at 50 °C the mixture is calcined at 900 °C during 12 hr. The XRD shows the perovskite cubic pattern and the reflection of the Ce02 phase (Figure 2). The surface area after calcination is less than 5 m2/g. The powder could be attrited after calcination to increase the surface area around 8-10 m2/g. Example 6 The catalyst of the example 2 was analysed by XRD after reaction and after calcination at 1100°C and reaction (Figure 3). Figure 3 discloses XRD patterns of Lao.8Ceo.2Feo.7Nio.25Rho.o503 catalysts after calcination at 900°C and 1100°C (fresh C9 and Cll) before reaction and after CPO tests (used C9 and Cll) / (+) AB03 perovskite structure, () CeO2 compound. The XRD reported show that the calcined at 1100°C and the reaction does not change the phase composition. In all cases the perovskite structure and a CeO2 side phase are detected. These analyses confirm the stability of the catalyst at high temperature (> 1000 °C) and in hard reaction conditions. The catalyst does not show the Ni and Rh crystal due to the dispersion of the metals on the catalyst surface. Results After reduction of the catalysts under a mixture of N2 and H2 at 750 °C / 1 hr, the materials were tested in CPO reactions. The reduction is useful to have immediately the catalyst in its maximum of activity without waiting for stabilisation and to avoid that part of the catalyst is still oxidised. This activation period (time during which the active phase will be form under reductive conditions) could also be obtained under time on stream with the initial mixture methane/oxygen. The tests were carried out in a fixed bed quartz microreactor of 8 mm of diameter, loaded with 1.50 g in granules (20-30 mesh). The tests were carried out at atmospheric pressure in three different conditions of feed and two different oven temperature : methane/oxygen/helium 2/1/20 and 2/1/4 v/v at 500°C and 750°C (residence time = 0.2 s) and methane/oxygen/helium 2/1/1 at 750°C (residence time = 0.33 s). The reaction products were analysed by gas chromatography. All the catalyst in all the conditions shows total oxygen conversion. The initial temperature is the temperature of the gas mixture at the beginning of the catalytic bed. The temperature maximal (Tmax) is the temperature measured at the end of the catalytic bed. CPO tests of LaFe (Example 1) The catalyst prepared in the example 1, LaFe0.7Ni0.25Rh0.05O3, is tested under CPO conditions. At low temperature the catalyst behaviour leads to the total combustion products. The methane conversion and the CO and H2 is high at high temperature (750°C) since the catalyst requires high temperature to be activated. The test were carried out using methane/oxygen/helium 2/1/20 and 2/1/4 v/v at 500°C and 750°C with residence time of 0.2 s, and methane/oxygen/helium 2/1/1 at 750 °C with a residence time of 0.33 s. (Table Removed) 1 at low temperature in diluted conditions but is higher also in hard reaction conditions. This is due to the effects of the Ce which promotes the reduction of the catalyst. The test were carried out using methane/oxygen/helium 2/1/20 and 2/1/4 v/v at 500°C and 750°C with residence time of 0.2 s, and methane/oxygen/helium 2/1/1 at 750°C with a residence time of 0.33 s. No deactivation of the catalyst is observed after return to initial conditions (500°C, 2/1/20). (Table Removed) *500°C ret. is a test carried out at 500°C 2/1/20 to confirm the result of the first test after all the test CPO tests of LaFeo.7Nio.3O3 (Example 3, as comparison) The catalyst prepared in the example 3 LaFeo.7Nio.3O3. This catalyst shows low activity at low and high temperature due to the not complete reduction of the Ni. The test were carried out using methane/oxygen/helium 2/1/20 and 2/1/4 v/v at 500°C and 750°C with residence time of 0.2 s, and methane/oxygen/helium 2/1/1 at 750°C with a residence time of 0.33 s. (Table Removed) CPO tests of LaFeo.95Rho.05O3 (example 4 as comparison) The catalyst prepared in the example 4, LaFeo.95Rho.05O3. The catalyst shows a methane conversion and CO and H2 selectivities very low in all reaction conditions. This is due to the fact that the catalyst is not reduced during the activation step in hydrogen flow or in the reaction conditions (methane/oxygen/helium 2/1/20 and 2/1/4 v/v at 500°C and 750°C (residence time = 0.2 s) and methane/oxygen/helium 2/1/1 at 750°C (residence time = 0.33 s). (Table Removed) Aging CPO tests of La (Example 2) The catalytic results of duration tests of the catalyst prepared as in example 2 ( La are reported in figure 4. Figure 4 discloses CPO tests (conversion, selectivity) of catalyst under time on stream at 500 and 750 °C. The test were carried out using methane/oxygen/helium 2/1/20 and 2/1/4 v/v at 500°C and 750°C with respectively residence time of 0.2 s. In all cases no deactivation are observed under time on stream. At 750°C the methane conversion is around 90 %, the CO and hydrogen selectivities respectively 94 and 92 %. The results were compared with those of a commercial catalysts Pt 0.5%wt on alfa AI2O3 calcined at 900°C (0.5 % wt Pt/a-Al203). The results of the duration tests of the commercial catalyst are carried out in the same conditions of the CPO tests of Lao.8Ceo.2Feo.7Nio.25Rho.05O3. The comparisons between the two catalysts are described in the next table. The perovskite CPO material presents the same performances and stability as the commercial product. (Table Removed) The advantages of the perovskite catalysts are the thermal stability in hard reaction conditions the high activity at short residence time and the presence of synergetic effect among Rh and Ni. WE CLAIM: 1. A method for the preparation of synthesis gas by partial oxidation or steam and/or dry reforming of natural gas and/or light hydro carbons by using a catalyst of formula (I) (Formula Removed) wherein: A and A' are different and are selected from the La, Ce, Ca or Sr or from the group IIa of the Mendeleev's periodical table of elements; B is selected from Mn, Fe, Co or Al; 0 8 is the sub stoechiometric value of oxygen to obtain the electric neutrality of the Perovskite compound, at a temperature in the range of 500 to 1300°C preferably between 600 to 1100°C and pressure in the range of 105 Pa to 3 106 Pa and between 105 Pa to 106 Pa to obtain the synthesis gas. 2. A method for the preparation of synthesis gas substantially as hereinbefore described with reference to the accompanying drawings.

Full Text

The present invention relates to a method for the preparation of synthesis gas.
The catalytic partial oxidation of hydrocarbons, natural gas or methane to synthesis gas, which consist in mixtures of hydrogen (H2) and carbon monoxide (CO) in various proportions, has been processed for mariy years. While currently limited as an industrial process, the partial oxidation is also of interest for the significant released heat and for the use of smaller reactors. More particularly, the .partial oxidation of methane at short residence time is a goal to reach synthesis gas using an alternative process to the steam reforming process, which is today the most popular one.
Synthesis gas can be used as feed for fuel cell or as a reducing atmosphere in the metallurgic industry but it is mainly the key step for activation of methane for the indirect production of methanol and middle distillate in the petrochemical and chemical industries.
The advantage of the catalytic partial oxidation of methane is mainly its strong
exothermic character in the short residence time. Both parameters allow producing
synthesis gas with lower investment cost without delivering large quantities of external
energy. .
Nevertheless, because this strong exothermic character of the total oxidation reactions, the temperature of the catalytic bed reaches more than well above 1000°C.
There is thus a need for very stable catalyst in terms of metal sintering and support
resistance. .
Furthermore, as the catalyst activity affects the thermal profile of the reactor, a careful modulation is therefore required to avoid hot spot in the reactor which can light on the homogeneous reaction.
A novel approach relates to the possibility of introducing the metal in the crystallographic structure of a given material and then to. activate the catalyst by reducing the metal "in situ" or under hydrogen flow. This allows in some case to develop a strong interaction between metal and surface, Some of these catalysts have a Perovskite structure.
US 5,149,516 discloses the partial oxidation of methane'to produce carbon monoxide and hydrogen using a Perovskite catalyst, such as LaCoO3-.
US 5,447,705 discloses a catalyst for the partial oxidation of methane or of a gaseous mixture containing methane, said catalyst preferably having a Perovskite structure with LaFeNi as a cation composition. However, in the reported examples it is very difficult
to balance the structure stability. On one hand, if the reducible metal (Ni and Co) is present in large amount, the structure is completely reduced and the Perovskite structure becomes unstable. On the other hand, if the reducible cation is present in low amount, the catalytic activity is poor and does not allow to work with short residence time.
US 6,110,861 discloses a two-part catalyst comprising a dehydrogenation portion and an oxide-ion conducting portion.
WO 0160742 discloses a catalysts and a processes for the catalytic conversion of hydrocarbons to carbon monoxide and hydrogen employing new families of chromium-rare earth based catalysts .
Today, none of the existing catalytic partial oxidation processes is able to provide a sufficiently high conversion of the reactant gas together with a high selectivity of CO and H2 reaction products, without using high quantities(of rare and costly catalysts, nor without experiencing adverse effects such as an excessive coking of the catalyst, or a premature-catalyst failure by its lack of heat resistance or by its mechanical instability or even by the mechanical instability of its structure.
That is why there is a continuing need for new catalysts that are mechanically stable and retains a high level of activity and selectivity to CO and H2 products under conditions of high temperature, without excessive coking.
The inventors have found that the catalysts of the present invention overcome some
of these drawbacks. ,
Accordingly, the present invention provides a composition characterized in that it essentially consists in a solid solution of a mixture of at least a perovskite cristallographic structure with nickel and/or rhodium metal.
According to the present invention there is provided a method for the preparation of synthesis gas by partial oxidation or steam and/or dry reforming of natural gas and/ or light hydro carbons by using a catalyst of formula (I)
(Formula Removed)
wherein:
A and A' are different and are selected from the La, Ce, Ca or Sr or from the group IIa of the Mendeleev's periodical table of elements;
B is selected from Mn, Fe, Co or Al;
0 0 0 ≤ x+y≤ 0.8,
0 ≤ z ≤ 1 and
8 is the sub stoechiometric value of oxygen to obtain the electric neutrality of the Perovskite compound.
at a temperature in the range of 500 to 1300°C preferably between 600 to 1100°C and pressure in the range of 105 Pa to 3 106 Pa and between 105 Pa to 106 Pa to obtain the synthesis gas.
According to one particular aspect the invention A and A' are independently chosen from La, Ce, Ca or Sr. A is preferably La.
According to another particular aspect of the invention, B is chosen from Mn, Fe,
Co or Al.
The invention is more particularly- relates a composition, characterized in that it is represented by the formula (Ia):
(Formula Removed)
wherein A', x, y, and z and 8 are as hereinabove defined for the formula (T).
Among the compounds represented by the formula (la), those represented by the formula (lb):
(Formula Removed)
wherein x, y, and z and 8 are as hereinabove defined for the formula (T), are preferred.
According to a preferred aspect of the invention, in the formulas (I) (la) or (lb), 0 According to another preferred aspect of the invention, in the formulas (I) (la) or (lb), 0 The invention more spefically consists in the following compositions :
La Fe0.7 Nio.25 Rho.05 03_s
Lao.8 Ce0.2 Fe0.7 Nio.25 Rho.os 03.5
Lao.g Ce0.2 Fe0.7 Ni0.3 03.5 While two composition have been selected for comparison.
La Fe0.7 Ni0.3 03.s
La Feo.95 Rho.os O3-5
According to another aspect of the present invention, the composition as defined as herein above, is used as a catalyst of the partial oxydation of natural gas and/or Kght
hydrocarbons to synthesis gas, as a catalyst of the steam and/or drv reforming- of natural gas
and/or light hydrocarbons (C2-C4) to synthesis gas and/or selective oxidations.
By light hydrocarbons, those which have a carbon chain containing from two to four carbon atoms (C2-C4), are more sepecifically within the scope of the present invention.
The composition of the invention are more specifically worked on in the operating catalyst temperature conditions in the range of 500 to 1300°C and preferably between 600 to 1100°C, and/or in the operating catalyst pressure conditions in the range of 105 Pa to 3 106 Pa and preferably between 105 Pa to 106 Pa.
In the use herein before mentioned uses, the oxydant gaseous feed is of any kind; it is preferably pure oxygen, oxygen and inert £as mixture, steam, carbon dioxide or a mixture of part or/and all of them.
According to another aspect the present invention, the composition as defined as herein above, is used as a catalyst of hydrogenation reactions or as a catalyst of dehydrogenated oxydative reactions.
The following examples illustrate the present invention without limiting it.
Example 1: LaFe0.7Ni0.25Rh0.05O3 (Invention)
5.3 g of La(NO3)3, 4.6 g of Fe(NO3)3, 1.2 g of Ni(NO3)2 and 0.83 g of Rh nitrate solution 10 % w/w are dissolved in 300 ml of distilled water and slowly dropped in a solution containing 7.7 g of citric acid dissolved in 400 ml of ethylene glycol. After mixing, the resulting solution are heated at 90°C for 4 h. The evaporation of water from the solution brings to the formation of a sol (colloidal solution with micrometric micelles). The catalyst is dried in oven at 90°C then the oven temperature is increased to 180°C over night. In this step, a gel is formed and dried. The obtained solid is calcined at 500°C for 4 h and then at 900°C for 12 h. The XRD shows the perovskite cubic pattern (figure 1) and the surface area after calcination is 8 m2/g. Figure 1 discloses XRD patterns of LaFei.xMx03 catalysts after calcination at 900°C (Mx = Ni0.3, Nio.25Rho.05 or Rho.05). (O) LaFeM03 perovskite structure.
Example 2: La0.8Ce0.2Fe0.7Ni0.25Rh0.05O3 (Invention)
5.3 g of La(NO3)3, 1.8 g Ce(NO3)3, 5.7 g of Fe(NO3)3, 1.5 g of Ni(NO3)2 and 1.0 g of Rh nitrate solution 10 % w/w are dissolved in 400 ml of distilled water and slowly dropped in a solution containing 9.5 g of citric acid dissolved in 500 ml of ethylene glycol. After
mixing, the resulting solution is heated at 90°C for 4 h. The evaporation of water from the solution brings to the formation of a sol (colloidal solution with micrometric micelles). The catalyst is dried in oven at 90°C then the oven temperature is increased to 180°C over night. In this step, a gel is formed and dried. The obtained solid is calcined at 500°C for 4 h and then at 900°C for 12 h. The XRD shows the perovskite cubic pattern and the reflection of the CeO2 phase (Figure 2). The surface area after calcination is 10 m /g. Figure 2 discloses XRD patterns of La0.8Ce0.2Fe0.7Ni0.25Rh0.05O3 catalysts after calcination at 900°C / (+) ABO3 perovskite structure, (*) CeO2 compound.
Example 3: LaFe0.7Ni0.3O3 (Comparative example)
5.3 g of La(NO3)3, 4.7 g of Fe(NO3)3, 1.4 g of Ni(NO3)2 are dissolved in 300 ml of distilled water and slowly dropped in a solution containing 7.7 g of citric acid dissolved in 400 ml of ethylene glycol. After mixing, the resulting solution is heated at 90°C for 4 h. The evaporation of water from the solution brings to the formation of a sol (colloidal solution with micrometric micelles). The catalyst is dried in oven at 90°C then the oven temperature is increased to 180°C over night. In this step, a gel is formed and dried. The obtained solid is calcined at 500°C for 4 h and then at 900°C for 12 h. The XRD shows the perovskite cubic pattern (Figure 1) and the surface area after calcination is 8 m2/g.
Example 4: LaFe0.95Rh0.05O3 (Comparative example)
5.3 g of La(NO3)3, 6.3 g of Fe(NO3)3, and 0.84 g of Rh nitrate solution 10% w/w are dissolved in 300 ml of distilled water and slowly dropped in a solution containing 7.7 g of citric acid dissolved in 400 ml of ethylene glycol. After mixing, the resulting solution is heated at 90°C for 4 h. The evaporation of water from the solution brings to the formation of a sol (colloidal solution with micrometric micelles). The catalyst is dried in oven at 90°C then the oven temperature is increased to 180°C over night. In this step, a gel is and dried. The solid obtained is calcined at 500°C for 4 h and then at 900°C for 12 h. The XRD shows the perovskite cubic pattern (Figure 1) and the surface area after calcination is 5 m2/g.
Example 5: La0.8Ce0.2Fe0.7Ni0.3O3 (Invention)
4.3 g of La(NO3)3, 1.4 g Ce(NO3)3, 4.6 g of Fe(NO3)3, 1.4 g of Ni(NO3)2 are dissolved in

400 ml of distilled water and slowly dropped in a solution containing 9.5 g of citric acid dissolved in 500 ml of ethylene glycol. After mixing, the resulting solution is heated at 90°C for 4 h. The evaporation of water from the solution brings to the formation of a sol (colloidal solution with micrometric micelles). The catalyst is dried in oven at 90°C then the oven temperature is increased to 180°C over night. In this step, a gel is formed and dried. The solid obtained is calcined at 500°C for 4 h and then at 900°C for 12h. The XRD shows the perovskite cubic pattern and the reflection of the Ce02 phase (Figure 2). The surface area after calcination is 10 m2/g.
The same CPO material can be obtained by solid state reaction. The precursors chosen are La203, Fe203, Ce2(C03)3,xH20 and 2NiC03,3Ni(0H)2,4H20. The oxides and carbonates are ball mixed during one hours in alcohol or water. After drying at 50 °C the mixture is calcined at 900 °C during 12 hr. The XRD shows the perovskite cubic pattern and the reflection of the Ce02 phase (Figure 2). The surface area after calcination is less than 5 m2/g. The powder could be attrited after calcination to increase the surface area around 8-10 m2/g.
Example 6
The catalyst of the example 2 was analysed by XRD after reaction and after calcination at 1100°C and reaction (Figure 3). Figure 3 discloses XRD patterns of Lao.8Ceo.2Feo.7Nio.25Rho.o503 catalysts after calcination at 900°C and 1100°C (fresh C9 and Cll) before reaction and after CPO tests (used C9 and Cll) / (+) AB03 perovskite structure, (*) CeO2 compound. The XRD reported show that the calcined at 1100°C and the reaction does not change the phase composition. In all cases the perovskite structure and a CeO2 side phase are detected. These analyses confirm the stability of the catalyst at high temperature (> 1000 °C) and in hard reaction conditions. The catalyst does not show the Ni and Rh crystal due to the dispersion of the metals on the catalyst surface.
Results
After reduction of the catalysts under a mixture of N2 and H2 at 750 °C / 1 hr, the materials were tested in CPO reactions. The reduction is useful to have immediately the catalyst in its maximum of activity without waiting for stabilisation and to avoid that part
of the catalyst is still oxidised. This activation period (time during which the active phase will be form under reductive conditions) could also be obtained under time on stream with the initial mixture methane/oxygen.
The tests were carried out in a fixed bed quartz microreactor of 8 mm of diameter, loaded with 1.50 g in granules (20-30 mesh). The tests were carried out at atmospheric pressure in three different conditions of feed and two different oven temperature : methane/oxygen/helium 2/1/20 and 2/1/4 v/v at 500°C and 750°C (residence time = 0.2 s) and methane/oxygen/helium 2/1/1 at 750°C (residence time = 0.33 s). The reaction products were analysed by gas chromatography. All the catalyst in all the conditions shows total oxygen conversion. The initial temperature is the temperature of the gas mixture at the beginning of the catalytic bed. The temperature maximal (Tmax) is the temperature measured at the end of the catalytic bed.
CPO tests of LaFe
(Example 1)
The catalyst prepared in the example 1, LaFe0.7Ni0.25Rh0.05O3, is tested under CPO conditions. At low temperature the catalyst behaviour leads to the total combustion products. The methane conversion and the CO and H2 is high at high temperature (750°C) since the catalyst requires high temperature to be activated.
The test were carried out using methane/oxygen/helium 2/1/20 and 2/1/4 v/v at 500°C and 750°C with residence time of 0.2 s, and methane/oxygen/helium 2/1/1 at 750 °C with a residence time of 0.33 s.

(Table Removed)
1 at low temperature in diluted conditions but is higher also in hard reaction conditions.
This is due to the effects of the Ce which promotes the reduction of the catalyst.
The test were carried out using methane/oxygen/helium 2/1/20 and 2/1/4 v/v at 500°C and
750°C with residence time of 0.2 s, and methane/oxygen/helium 2/1/1 at 750°C with a
residence time of 0.33 s.
No deactivation of the catalyst is observed after return to initial conditions (500°C, 2/1/20).

(Table Removed)
*500°C ret. is a test carried out at 500°C 2/1/20 to confirm the result of the first test after all the test
CPO tests of LaFeo.7Nio.3O3 (Example 3, as comparison)
The catalyst prepared in the example 3 LaFeo.7Nio.3O3. This catalyst shows low activity at low and high temperature due to the not complete reduction of the Ni. The test were carried out using methane/oxygen/helium 2/1/20 and 2/1/4 v/v at 500°C and 750°C with residence time of 0.2 s, and methane/oxygen/helium 2/1/1 at 750°C with a residence time of 0.33 s.

(Table Removed)
CPO tests of LaFeo.95Rho.05O3 (example 4 as comparison)
The catalyst prepared in the example 4, LaFeo.95Rho.05O3. The catalyst shows a methane conversion and CO and H2 selectivities very low in all reaction conditions. This is due to

the fact that the catalyst is not reduced during the activation step in hydrogen flow or in the reaction conditions (methane/oxygen/helium 2/1/20 and 2/1/4 v/v at 500°C and 750°C (residence time = 0.2 s) and methane/oxygen/helium 2/1/1 at 750°C (residence time = 0.33 s).

(Table Removed)
Aging CPO tests of La (Example 2)
The catalytic results of duration tests of the catalyst prepared as in example 2 ( La are reported in figure 4. Figure 4 discloses CPO tests (conversion, selectivity) of catalyst under time on stream at 500 and 750 °C. The test were carried out using methane/oxygen/helium 2/1/20 and 2/1/4 v/v at 500°C and 750°C with respectively residence time of 0.2 s.
In all cases no deactivation are observed under time on stream. At 750°C the methane conversion is around 90 %, the CO and hydrogen selectivities respectively 94 and 92 %. The results were compared with those of a commercial catalysts Pt 0.5%wt on alfa AI2O3 calcined at 900°C (0.5 % wt Pt/a-Al203). The results of the duration tests of the commercial catalyst are carried out in the same conditions of the CPO tests of Lao.8Ceo.2Feo.7Nio.25Rho.05O3. The comparisons between the two catalysts are described in the next table. The perovskite CPO material presents the same performances and stability as the commercial product.
(Table Removed)
The advantages of the perovskite catalysts are the thermal stability in hard reaction conditions the high activity at short residence time and the presence of synergetic effect among Rh and Ni.

WE CLAIM:
1. A method for the preparation of synthesis gas by partial oxidation or steam and/or dry reforming of natural gas and/or light hydro carbons by using a catalyst of formula (I)
(Formula Removed)
wherein:
A and A' are different and are selected from the La, Ce, Ca or Sr or from the group IIa of the Mendeleev's periodical table of elements;
B is selected from Mn, Fe, Co or Al;
0 8 is the sub stoechiometric value of oxygen to obtain the electric neutrality of the Perovskite compound,
at a temperature in the range of 500 to 1300°C preferably between 600 to 1100°C and pressure in the range of 105 Pa to 3 106 Pa and between 105 Pa to 106 Pa to obtain the synthesis gas.
2. A method for the preparation of synthesis gas substantially as hereinbefore described with reference to the accompanying drawings.

Documents:

1332-del-2003-abstract.pdf

1332-del-2003-claims.pdf

1332-del-2003-complete specification (granded).pdf

1332-del-2003-correspondence-others.pdf

1332-del-2003-correspondence-po.pdf

1332-del-2003-description (complete).pdf

1332-del-2003-drawings.pdf

1332-del-2003-form-1.pdf

1332-del-2003-form-19.pdf

1332-del-2003-form-2.pdf

1332-del-2003-form-3.pdf

1332-del-2003-gpa.pdf

1332-del-2003-petition-138.pdf

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Patent Number

228276

Indian Patent Application Number

1332/DEL/2003

PG Journal Number

38/2008

Publication Date

19-Sep-2008

Grant Date

23-Mar-2007

Date of Filing

29-Oct-2003

Name of Patentee

L'air Liquide, Societe Anonyme a Directoire Et Conseil De Surveillance Pour L'Etude Et L'Exploitation Des Process Georges Claude a French Company

Applicant Address

75 Quai d'Orsay, F-75321 Paris Cedex 7, France

Inventors:

#	Inventor's Name	Inventor's Address
1	Fransesco Basile	Via A. Vespucci 23, 88063 Catanzaro, Italy
2	Giuseppe Fornasari	G. de Albornoz 10, 40141 Bologna
3	Angelo Vaccari	Via Belletini 16, 40127 Bologna
4	Pascal Del Gallo	5 rue de la Chapelle Saint-Laurent, 91410 Dourdan
5	Daniel Gary	2 Allee d' Anjou, 78180, Montigny le Bretonneux

PCT International Classification Number

B01 J 23/00

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1			NA