WO1981000970A1

WO1981000970A1 - Catalyst compositions,their method of formulation and combustion processes using the catalyst compositions

Info

Publication number: WO1981000970A1
Application number: PCT/US1979/000813
Authority: WO
Inventors: M Angwin; W Pfefferle
Original assignee: Acurex Corp
Priority date: 1979-10-03
Filing date: 1979-10-03
Publication date: 1981-04-16
Also published as: GB2072035A; GB2072035B; DE2953867A1; JPS56501233A; BR7909042A

Abstract

The catalytic compositions comprise a catalytically active material which is homogeneously interspersed throughout a monolithic structure of ceramic composition. The composition is shaped into a unitary monolith which is employed as the catalyst structure. In the method the active material or materials are admixed with a ceramic material, which can be either active or inactive, in finely divided form and then shaped into the monolithic structure. The catalytic compositions are used with reactants in a combustion process.

Description

" CATALYST COMPOSITIONS, THEIR METHOD OF FORMULATION AND COMBUSTION PROCESSES USING THE CATALYST COMPOSITIONS"

This invention relates to catalyst systems, compositions and methods for the formulation of such compositions. More, particularly, the invention relates to catalyst systems in which the active material is homogeneously interspersed throughout a monolith structure of ceramic composition.

Presently known catalyst systems for use in applications such as combustors employ surface active materials in the form of pure pellets of the active material, or in the form of a surface coating of the active material on substrates such as ceramics. For example, it is well known to apply a catalyst material by slip coating onto a ceramic substrate which is in a honeycomb or other suitable monolith structure. For certain applications, such as gas turbine eombustors, monolithic structures are most advantageous.

The disadvantages and limitations of conventional monolithic catalyst systems include the problem of loss of the active material by flaking off or volatilization from the substrate with a resulting loss in catalytic activity, or the problem of a change in the mechanical properties of the structures, due to an interaction of the catalyst coating and the monolith. In certain application, e.g. in eombustors for gas turbines, the flaking material can cause erosion and damage to turbine blades, or the weakened catalyst/support can undergo therm ostructural failure and enter the turbine, causing damage to the blades.

It is an object of the present invention to provide new and improved catalyst systems and compositions and methods of formulating the compositions. Another object is to provide a catalyst system of the type described in which the active material is an integral part of the monolith structure to obviate the problems of coating flake-off or volatilization and consequent loss of catalytic activity.

Another object is to provide a catalyst system in which the integrity of the monolith structure is maintained during sustained combustion while obviating the problem of undesirable interaction of a catalyst metal with a substrate which results in structural weakening.

Another object is to provide a catalyst system which provides relatively longer operating life, especially in high temperature applications, and which provides good performance through relatively higher combustion efficiency over a long period of time.

Another object is to provide a catalyst system which achieves relatively good catalytic activity wherein the light-off temperatures of the systems compare favorably to the light-off temperatures of catalyst systems employing noble metals.

The invention in summary comprises a system in which the catalytic composition includes a catalytically active material which is homogeneously interspersed throughout a monolith structure of ceramic composition. The composition is shaped into a unitary monolith which is employed as the catalyst structure. In one version of the method the active material or materials are admixed with a ceramic material, which can be either active or inactive, in finely divided form and then shaped into the monolith structure which ic calcined. The combustion process of the invention comprises combusting reactants in the presense of the monolithic catalytic structures.

The foregoing and additional objects and features of the invention will appear from the following specification in which the several embodiments are set forth.

The catalyst systems of the invention are comprised in general of a catalytically active metal oxide material homogeneously mixed or interspersed in a ceramic metal oxide material. The mixture can be shaped into a unitary monolith of the desired configuration. The resulting monolith is thereby comprised throughout of the catalytically active material to provide a catalysis system with a high degree of structural integrity and with improved performance.

In one embodiment of the invention the active material is a metal oxide which is homogeneously mixed throughout an inactive (or less active) metal oxide, which can be a mixed metal oxide.

Examples of the active metal oxides suitable for use in this embodiment include:

NiO CeO₂

^Fe3^O4 ZrO₂

LaCrO₃

^Co2^O3 CoAl₂O₄

Examples of the inactive (or less active) materials suitable for use in this embodiment include:

Zireonia Spinel Yttria-stabilized zireonia MgAl₂O₄

SrZrO₃ CaZrO₃

Examples of the catalyst systems formed by the above materials for this embodiment include:

Zireonia Spinel doped with nickel oxide (5% by weight) Yttria-stabilized zireonia doped with nickel oxide (5% by weight) Cerium Oxide (80% by weight) with zireonia (20% by weight) Cerium Oxide (17% by weight) with zireonia (78% by weight) with nickel oxide dopant (5% by weight) SrCrO₃ Pecovskite doped with Co₂O₃ (5% by weight) CaZrO₃ doped with Co₂O₃ (5% by weight)

CaZrO₃ arc-plasma sprayed with CoAl₂O₄ doped with MgAl₂O₄ (5% by weight)

SrZrO₃ arc-plasma sprayed with CoAl₂O₄ doped with MgAl₂O₄ (5% by weight)

LaCrO₃ (10% by weight) with ZrO₂ (90% by weight)

^Mg.25^Ni.75^Cr2^O4 MgAl₂O₄ : Fe₃O₄

In other embodiments of the invention the monolithic catalytic composition is of the perovskite, spinel, corundum or ilmenite crystal structure type in which primary catalytically active metal oxide materials are in intimate admixture with carriers comprising inactive or active metal oxide materials which are capable of forming ceramics. The resulting composition comprises a random interspersion of the various possible crystal structures, e.g. of the perovskites, or the spinels, or the corundum, or the ilmenite, as the case may be.

In one such embodiment a catalytically active base metal oxide of the perovskite crystal structure ABO₃ forms a solid solution with another material (either active or inactive) comprising a metal oxide of the perovskite structure ABO₃ suitable for formation of a ceramic. Generally the perovskite structure is comprised of cations of different types of metals, one of type A and another of Type B and in which the cations are of different size with the smaller cations in the ccp array occupying the octahedral holes formed exclusively by the oxide ions.

The following are examples of the primary active perovskite base metal oxides which can be employed in this embodiment:

LaCrO₃

LaNiO₃ LaMnO₃

^La0.5^Sr0.5^MnO3

^La0.8^K0.2^Rh0.1^Mn0.9^O3 ZrXWO₃ (X = Ni, Co)

LaCoFeO₃

LaMNiO₃ (M = Ca, or Sr) The following are examples of perovskite type metal oxides suitable for use as carrier materials in this embodiment:

LaAlO₃ (^Sr0.4^La0.6^{) (Co}0.5^V0.2^)O3

^(Sr0.2^La0.8^)CoO3 (^Sr0.4^La0.6^)(Co0.9^Pt0.1^)O3

The following are examples of catalytically active perovskite metal oxides in solid solution with perovskite metal oxides as carriers:

LaAlO₃:LaCrO₃ (3:1 mole ratio) LaAlO₃:LaNiO₃ (3:1 mole ratio)

Another embodiment of the invention provides a primary catalytically active metal oxide of the spinel crystal structure in solid solution with a spinel structured compound which is suitable for formation of a ceramic. The spinel crystal structure takes the form A[B₂] O ₄ or the inverse structure B[AB] O₄.

The following are examples of the primary active spinel metal oxides which can be employed in this embodiment:

^Fe3^O4 NiAl₂O₄ Nⁱ0.5^MgO0.5^(A10.5^Cr0.3^Fe0.2⁾2^O4

Ni(Al_0.3Cr_0.5Fe_0.2)₂O₄ + NiO (1% by weight)

Co(Al _0.3Cr_0.5Fe_0.2)₂O₄ + CoO (5% by weight)

MgCr₂O₄

The following is an example of a spinel type metal oxide suitable for use as the carrier material in this embodiment:

MgAl₂O₄

The following are examples of the solid solutions of the catalytically active spinel materials with the carrier spinel materials: MgAl₂O₄:NiAl₂O₄ (3:1 mole ratio) MgAl₂O₄:MgCr₂O₄ (3:1 mole ratio) MgAl₂O₄:Fe₃O₄ (9:1 mole ratio)

Alternatively, an oxide cermet such as the following spinel cermet example can be used:

MgAl₂O₄:Fe₃O₄ : (3:1 mole ratio) + 40% Cr by weight

In another embodiment of the invention a primary catalytically active base metal oxide of either the corundum B₂O₃ or ilmenite ABO₃ crystal structures forms a solid solution with another material (either active or inactive) comprising a metal oxide of the corundum crystal structure suitable for formation of a ceramic.

Examples of the primary active corundum oxides include:

^Fe2^O3

Co₂O₃ stabilized with Yttria

Examples of the primary active ilmenite oxides employed in this embodiment include:

^Cr2^O3 Fe _x Mg_{1 -x} TiO₃ (x between 0.85 and 0.90, for example)

An example of a corundum structured compound suitable for use in this embodiment as the ceramic carrier comprises alumina.

Examples of solid solutions formed between eorundum structured active compounds and the ilmenite structured carrier comprises Cr₂O₃ :Al₂O₃ (1:5 mole ratio) and Fe_.85Mg_.15TiO₃ : Al₂O₃ (1:9 mole ratio).

Examples of solid solutions between active compounds and carriers which are both of corundum structure include:

Al₂O₃ : Fe₂O₃ (3:1 mole ratio) Al₂O₃ : Co₂O₃ (5:1 mole ratio) stabilized with Yttria (2% by weight)

From the potentially large number of metal oxide compounds which could formulate into solid solutions of the foregoing type, it will be realized that those compounds containing metals with volatile oxides are generally unsuitable for com bust or service. Thus, the many compounds containing barium, lead, rhenium, ruthenium, sodium and other volatile metals are not preferred. Similarly, compounds containing halogens are not considered useful for combustor service and are not preferred in this invention. Additionally, compounds of the type with known melting points below about 1873K are suitable only for lower temperature applications.

One method of formulating the catalyst systems of the invention comprises selection of the starting material in a predetermined proportion according to the mole weight formula of the composition desired for the resulting monolith structure. The starting compounds are pulverized and intermixed, such as by a ball mill or other method, to insure complete dispersion and a small particle size on the order of 10 to 20 microns. The mixture of powder is then formed into the shape which is desired for the particular ceramic technique which is to be used to form the catalyst structure. The mixture is then fired at a temperature of at least 1000° C.

As one example of a method of molding the catalyst structure to a desired shape, e.g. a honeycomb shape, would be to form an aqueous or organic slurry with the reactive powders and a binder, pour the slurry into a mold, apply heat to drive off the water and binder, and then sinter at the high temperature.

Another example would be to apply a coating of such a mixture to a substrate such as paper formed into the desired shape and then burn the paper off.

Another example for use where one of the starting materials is a pure compound such as alumina would be to press the powders together into the desired shape and then cause them to react.

The following is a specific example of a method of formulating a perovskitebased catalyst system which is a solid solution of LaAlO₃ and LaCrO₃. Ammonium dichromate (NH₄)₂Cr₂O₃ is dissolved in deionized water. Added to that solution is the appropriate mole percentage of La₂O₃. Added to that mixture is a reactive alumina in the appropriate mole percentage. The resulting mixture is dried at about 150° C to form a sludge, then calcined at a temperature above about 600° C. The resulting powder is ball milled and than recalcined above 1300° C. A sample of the recalcined material may be checked by X-ray diffraction. If reaction is not complete, the powder is recalcined until the desired state is achieved.

At this stage the powder which has been made is a completely reacted composition of the base metal oxide. The reacted powder is ball milled with water or other suitable liquid to develope a rheology suited to the chosen forming method, then formed and shaped into the desired unitary configuration.

Another method for making materials suitable for this invention is by gelling solutions of the proper composition of the desired metals. In this case the gel may be spray-dried to provide a powder of the proper rheology for further processing.

After the powder has been brought to the proper rheology, the shaping step may be carried out by formation of a water-based slip (with appropriate organic binders and dispersants) and then casting, extruding, molding or pressing the material into the desired shape. This step may comprise coating of the slip onto a paper, polymer or sponge substrate, after which the substrate can be removed as by firing.

The final step in this method is calcining the resultant monolith material in the range of 1100-1600° C. It is preferable to calcine in an oxidizing atmosphere. However, with constituents having oxides such as Cr₂O₃, which have some volatility, it may be necessary to calcine under an inert atmosphere such as argon. If the material is calcined under a forming gas to reduce the chance of oxide vaporization, a sample of it must be checked by X-ray diffraction to make sure that segregated reduced phases have not been introduced.

The following is a specific example of a method of forming a catalyst system with a corundum-based active ceramic. In the first step appropriate mole percentages of (NH₄)₂Cr₂O₇ and Al₂O₃ (reactive) are added to deionized water using suitable dispersants. The slurry is dried at 150° C to a sludge, the sludge is calcined at a temperature of 600° C and the resulting powder is ball milled. The remaining steps are carried out as set forth in the above example for the perovskite-based system.

The following is a specific example of a method of forming a spinel-based metal oxide catalyst system which is a solid solution of MgAl₂O₄ and NiAl₂O₄. Basic magnesium carbonate MgCO₃. Mg(OH)₂ . 3H₂O is dispersed in deionized water, and to that mixture are added suitable quantities of reactive Al₂O₃ and Ni(CO₃). The product is then dried at 150° C to a sludge, and the sludge is calcined at a temperature range of 1000° C - 1300° C. The remaining steps are carried out as in the above-described example for the method of preparing the perovskite-based system.

The following is a specific example of a method of formulating another spinelbased system which is a solid solution of MgAl₂O₄ and MgCr₂O₄. In the first step (NH₄)₂Cr₂O₇ is dispersed in deionized water. To that mixture appropriate quantities of basic magnesium carbonate and reactive Al₂O₃ are added as well as a dispersant. The remaining steps are carried out as described in the immediately preceding example.

In the method of forming catalyst systems based upon the above-described general ceramic materials, a common catalytic substrate having several percent (preferably from 1 to 10% but up to 25%) of a catalytically active metal oxide is added to the material before monolith formation. For example, nickel oxide in yttria-stabilized zireonia; nickel oxide or chromium oxide in mullite or cordierite or zircon mullite; LaCrO₃ and mullite; MgCr₂O₄ and alumina; or nickel oxide or Co₂O₃ and alumina. The material is then shaped as described above in connection with the perovskite-based system. Longer times at calcining temperatures may be required to insure that any solid state reaction is complete during formulation.

Another preferred embodiment of the present invention is the use of eatalytically-active oxide composition as both the catalytic and the structural materials. Although there are many advantages to be gained by mixing active materials with less-active materials, it is often desirable to use the active oxide composition for the catalytic and structural materials. An example of this is the use of LaCrO₃ as the performing catalytically active, electricallyconducting monolith material. Example I

Oxide powders of MgAl₂O₄ and NiAl₂O₄ (3:1 mole ratio) were prepared by pressing the powders into discs and calcining in the manner described above. The disc size was 2-1/4" in diameter and 1-1/4" long with 18 to 30 holes of 0.25" diameter drilled axially to form gas flow passages. The resulting monolith structure was tested in a eombustor using air and natural gas reactants under fuel-lean conditions down to a minimum preheat of 325° F. Blowout of the catalyst bed did not occur at the highest throughput attained, 849,000 hr^-1 space velocity. The catalyst was also tested on lean diesel fuel and sustained combustion to a minimum preheat of 590° F. During the diesel fuel test blowout did not occur during maximum throughput at a space velocity of 1,152,000 hr^-1.

The results of the test of the first example are listed in Table I. CO emissions were below 50 ppm, and NO emissions ranged from 1 to 30 ppm.

Example II

Powders of LaAlO₃ and LaCrO₃ (3:1 mole ratio) were pressed and calcined into discs shaped as described for Example 1. The catalyst was tested in a eombustor using reactants of air and natural gas as well as diesel fuel. The test results are depicted in Table II.

Example III

Powders of MgAl₂O₄ and Fe₃O₄ (3:1 mole ratio) were pressed and calcined into pellets shaped as described in Example I. The catalyst was tested in a eombustor on lean natural gas and lean diesel fuel. The test results are set forth in Table III.

Example IV

Powders of MgAl₂O₄ and MgCr₂O₄ (3:1 mole ratio) were pressed and calcined into the shape of tubes 2" in length having nominal dimensions of 1/4" OD and

1/8" ID. Forty-four of these tubes were bundled and wrapped together in insulation and supported vertically within a holder tube on a disc of Torvex alumina 1" long by 2" diameter which was honeycombed with 3/16" diameter cells. The catalyst structure was tested on air and lean and rich natural gas and diesel fuel. The results of the test are depicted in Table IV. The performance shows that on lean natural gas CO and NO emissions were at or below 18 and 10 ppm respectively. There was no loss in catalytic activity after 5 hours of testing.

Example V

Powders of Al₂O₃ and Cr₂O₃ (9:1 mole ratio) were pressed and calcined into the shape of tubes 2" in length having nominal dimensions of 1/4" OD and 1/8" ID. A plurality of the tubes were bundled, wrapped together and supported in the manner described above for example IV. Platinum was added to the front segment to promote light-off. The catalyst structure was tested on air and natural gas. The results of the test are depicted in Table V.

From the foregoing it will be seen that the catalyst system compositions of the present invention provide good performance with high combustion efficiency over a long period of time. The catalytic monolith maintains its structural integrity in operation without loss of catalytic activity through flake-off or volatilization. There is no problem of interaction of base metal catalysts with the substrate, nor is there the problem of degradation of surface area due to growth in crystallite size of the active component when in operation so that there is a relatively longer life, especially in high temperature applications. Additionally, the manufacturing process is relatively less expensive in that there are fewer steps to formulate the monolith structure as compared to existing techniques of manufacturing a substrate, applying a wash coat and then applying the catalyst.

While the foregoing embodiments are at present considered to be preferred, it is understood that numerous variations and modifications may be made therein by those skilled in the art and it is intended to cover in the appended claims all such variations and modifications as fall within the true spirit and scope of the invention.

Claims

What Is Claimed Is:

1. A monolithic catalytic structure comprising a catalytically active base metal oxide of the perovskite, spinel, corundum or ilmenite crystal structure suitable for forming structurally sound catalytic compositions.

2. A catalytic structure as in Claim 1 in which the active metal oxide is of the perovskite crystal structure ABO₃ in intimate admixture with an additional base metal oxide of the perovskite crystal structure ABO, suitable for forming structually sound catalytic compositions.

3. A catalytic structure as in Claim 2 in which the active metal oxide is comprised of a metal of the cation B selected from the group consisting of Cr, Ni, Mn, Fe, Sr, and Ca.

4. A catalytic structure as in Claim 2 in which the additional metal oxide is comprised of a metal of the cation A selected from the group consisting of La and Sr and is further comprised of a metal of the cation B selected from the group consisting of Al and Cr.

5. A catalytic structure as in Claim 1 in which the active metal oxide is of the spinel crystal structure A[B₂]O₄ or B[AB] O₄ in intimate admixture with an additional base metal oxide of the spinel crystal structure suitable for forming structurally sound catalytic compositions.

6. A catalytic structure as in Claim 5 in which the active metal oxide is comprised of a metal of the cation B selected from the group consisting of Ni, Fe and Cr.

7. A catalytic structure as in Claim 5 in which the active metal oxide comprises Fe₃ O₄ or NiAl₂O ₄ and the additional metal oxide comprises MgAl₂O₄.

8. A catalytic structure as in Claim 5 in which the active metal oxide comprises Fe₃O₄ with Cr.

9. A catalytic structure as in Claim 1 in which the active metal oxide is of the corundum crystal structure B₂O₃ or of the ilmenite crystal structure ABO₃ in intimate admixture with an additional base metal oxide of the corundum crystal structure suitable for formation of a structurally sound catalytic composition.

10. A catalytic structure as in Claim 9 in which the active metal oxide of the corundum structure is comprised of a metal of the cation B selected from the group consisting of Cr, Co and Fe.

11. A catalytic structure as in Claim 9 in which the active metal oxide of the ilmenite structure is comprised of a metal selected from the group consisting of Fe and Cr.

12. A catalytic structure as in Claims 10 or 11 in which the additional metal oxide is comprised of the metal Al of the cation B.

13. A catalytic structure as in Claim 9 in which the active metal oxide comprises yttria-stabilized Co₂O₃.

14. A combustion process comprising combusting reactants in the presense of a monolithic catalytic structure comprising a catalytically active base metal oxide of the perovskite, spinel, corundum or ilmenite crystal structure suitable for forming structurally sound catalytic compositions.

15. A combustion process as in Claim 14 in which the active metal oxide is of the perovskite crustal structure ABO₃ in intimate admixture with an additional base metal oxide of the perovskite crustal structure ABO₃ suitable for forming structually sound catalytic compositions.

16. A combustion process as in Claim 15 in which the active metal oxide is comprised of a metal of the cation B selected from the group consisting of Cr,

Ni, Mn, Fe, Sr, and Ca.

17. A combustion process as in Claim 15 in which the additional metal oxide is comprised of a metal of the cation A selected from the group consisting of La and Sr and is further comprised of a metal of the cation B selected from the group consisting of Al and Cr.

18. A combustion process as in Claim 14 in which the active metal oxide is of the spinel crystal structure A[B₂] O₄ or B[AB] O₄ in intimate admixture with an additional base metal oxide of the spinel crystal structure suitable for forming structurally sound catalytic compositions.

19. A combustion process as in Claim 18 in which the active metal oxide is comprised of a metal of the cation B selected from the group consisting of Ni, Fe and Cr.

20. A combustion process as in Claim 18 in which the active metal oxide comprises Fe₃O₄ or NiAl₂O₄ and the additional metal oxide comprises MgAl₂O₄.

21. A combustion process as in Claim 18 in which the active metal oxide comprises Fe₃O. with Cr.

22. A combustion process as in Claim 14 in which the active metal oxide is of the corundum crystal structure B₂O₃ or of the ilmenite crystal structure ABO₃ in intimate admixture with an additional base metal oxide of the corundum crystal structure suitable for formation of a structurally sound catalytic composition.

23. A combustion process as in Claim 22 in which the active metal oxide of the corundum structure is comprised of a metal of the cation B selected from the group consisting of Cr, Co and Fe.

24. A combustion process as in Claim 22 in which the active metal oxide of the ilmenite structure is comprised of a metal selected from the group consisting of Fe and Cr.

25. A combustion process as in Claims 23 or 24 in which the additional metal oxide is comprised of the metal Al of the cation B.

26. A combustion process as in Claim 22 in which the active metal oxide comprises yttria-stabilized Co₂O₃.

27. A method of formulating a catalyst system comprising the steps of preparing an intimate admixture of a catalytically active base metal oxide having the perovskite crystal structure and an average particle size on the order of 10-20 microns with an additional base metal oxide having the perovskite crystal structure of the type suitable for formation of structurally sound catalytic compositions and with an average particle size on the order of 10-20 microns, forming the mixture into a unitary structure, and calcining the formed structure.

28. A method of formulating a catalyst system comprising the steps of preparing an intimate admixture of a catalytically active base metal oxide of the spinel crystal structure and an average particle size on the order of 10-20 microns with an additional base metal oxide of the spinel crystal structure of the type suitable for formation of structurally sound catalytic compositions and with an average particle size on the order of 10-20 microns, forming the mixture into a unitary structure, and calcining the formed structure.

29. A method of formulating a catalyst structure comprising the steps of preparing an intimate admixture of a catalytically active base metal oxide of the corundum crystal structure or of the ilmenite crystal structure, said active metal oxides having an average particle size on the order of 10-20 microns, with an additional base metal oxide of the corundum crystal structure of the type suitable for formation of structurally sound catalytic compositions and having an average particle size on the order of 10-20 microns, forming the mixture into a unitary structure, and calcining the formed structure.