CA1178570A - Impregnating catalysts - Google Patents
Impregnating catalystsInfo
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- CA1178570A CA1178570A CA000395801A CA395801A CA1178570A CA 1178570 A CA1178570 A CA 1178570A CA 000395801 A CA000395801 A CA 000395801A CA 395801 A CA395801 A CA 395801A CA 1178570 A CA1178570 A CA 1178570A
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- catalyst
- oxide complex
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Abstract
(5277) IMPREGNATING CATALYSTS
ABSTRACT OF THE DISCLOSURE
An element selected from Groups IA, IB, IIB, IIIA
and IIIB is incorporated into an iron bismuth molybdate oxide complex catalyst by impregnation.
ABSTRACT OF THE DISCLOSURE
An element selected from Groups IA, IB, IIB, IIIA
and IIIB is incorporated into an iron bismuth molybdate oxide complex catalyst by impregnation.
Description
~ 7 ~ (5277) IMPREGNATING CATALYSTS
BACKGROUND OF THE INVENTION
The present invention relates to improved oxide complex catalysts for use in various oxidation-tYpe reac-tions such as, for example, the oxidation of propylene or isobutylene to produce acrolein and acrylic acid or meth-acrolein and methacrylic acid respectively, the ammoxidation of propylene or isobutylene to produce acrylonitrile or methacrylonitrile, respectively, or the oxydehydrogenation of isoamylenes to produce isoprene.
Iron bismuth molybdate oxidation catalysts are well known and many different promoters have been proposed for such systems. See, for example, U.S. Patent 3,642,930, in which alkali metals and optionally cobalt and/or nickel are disclosed as useful. See also U.S. Patent 4,123,453 wherein the Group II elements are proposed.
Although known catalysts exhibit ~ood catalytic properties, it is always beneficial to provide new catalysts having even better catalytic properties.
Accordingly, it is an object of the present inven-tion to provide a new technique for making catalysts of improved catalytic properties.
S UMMAR Y OF THE _I NVENT I ON
This and other objects are accomplished by the present invention which is based on the discovery that iron bismuth molybdate oxide complex catalysts promoted with Group I, II and/or III elements of im~roved catalytic per-formance can be obtained provided that at least some of the . . r ~
,1 ~t~57~ ~ 5277) Group I, II or III elements are incorporated into the cata-lyst by impregnation of a preformed and calcined iron bismuth molybdate oxide complex.
This, the present invention provides a process for im-proving the c~talytic properties of a substantially crystalline iron bismuth molybdate oxide complex interim catalyst which comprises incorporating at least one element from the group's IA,, IB,- IIB, IIIA and IIIB o~ the Periodic Table into the catalyst by impregnation, none o~ the group ~A elements in-coporated into the catalyst by impregnation being derived from a molybdate or silicate, the interim oxide catalyst being formed by forming a precatalyst and thereafter calcining the precatalyst in an oxygen containing gas, the interim oxide complex being impregnated with a solution of the element, and the impregnated interim oxide complex being calcined in an oxy-gen containing gas.
DETAILED DESCRIPTION
Catalysts to which the present invention applies (i.e. final catalyst product) are substantially crystalline oxide complexes having the following general Eormula:
a bCcBidFeeMofox wherein A is at least one element selected from the Group IA, IB, IIA, IIB, IIIA and IIIB elements;
B is one or more Group VIII elements other than Fe, preferably Co ~nd/or Ni and optionally Cr and/or Mn;
C is P, As, Sb, S, Te ~nd/or Sn;
and wherein a is 0.1-12;
b is 0.1-12;
c is 0.1-12;
d is greater than 0-12;
e is 0.1-12;
f is 0.1-12; and ~ t~ (5277) x is a number determined by the valence requirements of the other elements present;
and further wherein the molybdenum content is greater than the contents of any other element in the catalyst, excluding oxygen.
Preferably, a is 0.1 to 6, b is 0.1 to 12, c is 0.1 to 12, d is greater than O to 4, e is 0.1 to 12 and f is 12.
The above catalysts normally contain at least some alkali metal. Also, the bismuth content is usually 0.1 to 5, preferably 0.5 to 2, more preferably about 1, based on 12 atoms of molybdenum. ~In addition, the iron content is nor-mally about 1 to 5, preferably 1.5 to 4, more preferably 2 to 3, based on 12 atoms of molybdenum.
Especially preferred catalysts are those defined by the following formula:
m n o p q r s t x wherein I is at least one Group I element, preferably K, Rb, Cs and/or Cu;
II is at least one Group II element, pref-erably Mg, Ca and/or Zn;
III is at least one Group III element, pref-erably Al and/or Tl;
B is at least one of Co, Ni, Mg and optionally Mn and/or Cr;
D is P, As, Sb, Te and/or Sn;
and wherein m is O to l;
n is O to 12;
o is O to 12;
p is O to 10;
q is O to 6;
r is 1 to 1/2 t;
s is 0.5 ts 1/2 t;
t is 8 to 16;
:.,_ 7.ff~ ' ' ' (5277) x is a number determined by the valence requirements of the other elements present, The catalysts of the invention can be either unsup-ported or supported. If supported, conventional supports such as silica, alumina, Alundum, zirconia, ~itania and the like ~an be employed. Any amount of support can he employed.
- The catalysts of the present invention are made by forming an oxide complex in a conventional manner except that at least some of tl~e Group ~, IIB and/or III elements of the catalvsts are added by an impregnation technique using a solution of these elements to impre~nate a preformed and calcined oxide complex of the other elements. Thus in accordance with the present invention, an oxide complex is formed bv a conventional technique, this oxide complex con-taining all oÇ the elements of the objective catalyst except for at least some of the Group I, IIB and/or III elements which will be added by subsequent impregnation. After this interim oxide complex is made, it is impregnated with a solution of a Group I, II and/or III element, dried and cal-cined to produce the objective catalyst.
Thus, in accordance with the first step of the present invention, an interim oxide complex is formed by a conventional technique. Most easily, this is accomplished by formin~ a solution or slurry, usually in water, of the elements to be incorporated into the interim oxide complex usually in ehe form of salts having heat decomposable anions or cations and/or oxides. The liquid slurry medium is removed from the slurry to form a precatalyst and the pre-catalyst is then calcined in air at elevated temperature, for example 600 to 900C for an extended period of time, 0.5 to 50 hours. Durin~ such calcination, care should be (5277) taken to avoid gross decomposition of the catalyst such as occurs in McClellan, U.S. Patent 3,415,886.
In this regard, an esseneial feature of the McClellan technique is that the interim bismuth molybdate on silica material which is composed of various crystalline molybdates be heated under conditions which are so severe that these crystalline materials are substantially destroyed and replaced with a substantially amorphous phase. This procedure is totally avoided in accordance with the present invention whereby the catalysts produced have the conven-tional structure, i.e. they are substantially erystalline.
Techniques for making oxide complexes in the conventional manner are well known and disclosed, for example, in Grasselli, U.S. Patent 3,642,930.
In another embodiment of the invention, the interim oxide complex can be a used catalyst, that is a catalyst which has already been used in an oxidation or ammoxidation type reaction to produce valuable product.
Once the interim oxide complex is produced as i described above, it is impregnated in accordance with the present ;nvention with a solution of a Group I, IIB or III
element. In order to obtain dissolution of the Group I, II3 or III element, a compound of the element which is soluble ! in the liquid used to form the slurry is normally employed.
For example, if water is chosen as the solution medium, nitrates of the elements can be used. On the other hand, if an or~anic liquid such as an alcohol is used as the l;quid, organic compounds of the elements in question, such as for example acetates can be employed. Also, it is possible to ~ 3 (5277) use the element directly if they can be made to dissolve in the appropriate liquid.
Commonly assigned U.S. Patent 3,280,166 shows improving the properties of a bismuth molybdate or bismuth phosphomolybdate catalyst by impregnating the catalysts with materials which decompose to yield barium oxide and silicon oxide. Potassium silicate is an example of a material which will supply silicon for the silicon oxide. D'Armore, U.S.
4,052,332, discloses a process for rejuvenating used or spent iron bismuth molybdates in which the spent catalyst is impregnated with a solution containing bismuth and molyb-denum. Alkali metal molybdates are examples of materials which can be used to supply molybdenum to the impregnating solution. In accordance with both these techniques, alkali metal would be deposited on the catalyst if a silicate or molybdate of an alkali metal were employed as a source com-pound, and therefore in accordance with the present inven-tion silicates or molybdates of alkali metal are not employed as source compounds for supplying alkali metal to the impregnating solution.
The liquid used for the impregnating solution is not critical and both aqueous and organic liquids can be employed. For example, in addition to water, various alcohols and especially ethanol, propanol and so forth can be employed as can acetone, hydrocarbons, etc. Also, mixed systems can be employed. For example, solutions oE water and various organic acids such as tartaric, oxalic, acetic, citric, chloroacetic acid and the like can be employed.
Also, various compounds which aid solubility can also be included. For example, various mineral acids such 3S
~ (5277) HNO3, H2SO4, HCl, H3PO4 and the like can be included. Basically, any liquid can be employed so long as the liquid does not exhibit a significant adverse effect on the ultimate catalyst produced. For example, strong bases should be avoided since they may poison the ultimate cata lyst product.
The impregnating element is deposited in the interim oxide complex by mixing the interim complex with the impregnating solution and thereafter removin~ the liquid.
For ease of operation and control of the amount of impreg-nant deposited on the catalyst, this is usually accomplished by mixing the impregnating solu~ion and the interim complex together and thereafter evaporating the impregnating liquid.
The concentration of impregnant in the impregnating liquid and the relative amounts of impregnating liquid and interim oxide complex are not critical and can be easily selected by those skilled in the art to facilitate ease of impregnation. Usually, however, the amount of impregnating solution will be no more than 1.5, preferably 1.1, more preferably 1.0 times the pore volume of the interim catalyst to be impregnated.
Once the impregnating liquid is removed, the impregnated interim oxide complex is calcined at elevated temperature and pressure to set the impregnant metal into the catalyst and establish the final relationship of the atoms therein. Calcination is accomplished by heating a~
elevated temperature in the presence of an oxygen-containing gas, normally air, in a routine manner. For example, heating in accordance with the above-noted Grasselli patent, U.S. 3,642,930, is preferred. Again, care must be taken to ~'s'~ (5277) avoid de~struction of the crystalline bismuth molyhdates as occurs in the above-noted McClellan patent.
The catalysts produced by the inventive process can be used in all oxidation-eype reactions in which analogous catalysts are used, such as for example oxidation of olefins to produce aldehydes and acids, ammoxidation of olefins to produce unsaturated nitriles and oxydehydrogenation of olefins to produce diolefins.
The following examples are provided to more thoroughly describe the present invention.
COMPARATIVE EXAMPLE A
A silica-supported, alkali metal-promoted catalyst of the type shown in commonly assigned U.S. 3,642,930 was charged into a fluid-bed reactor and contacted with a feed comprising 1.8 propylene/2.2 NH3/3.6 O2/2.4 N2/6 H2O
at 430C for a contact time oE 2 secondsO The gross reac-tion product obtained was recovered and analyzed and it was found that acrylonitrile was produced in yields of 77.6%
based on the propylene fed with a selectivity to acrylo-nitrile of 82.2%.
_ Comparative Example A was repeated except that 25 gms. of the catalyst of Comparative E~ample A after being formed was impregnated with 20 gms. of an aqueous solution containing 0.042 gms. potassium acetate. After impregna-tion, the catalyst was washed with water, dried and then calcined in air at 570C for 3 hours. The potassium-impregnated catalyst was then used in the same way as in ~ (5277) Comparative Example A to produce acrylonitrile. In this example, acrylonitrile was produced with yields of 80.0%
based on the propylene fed with a selectivity to acrYlo-nitrile of 81.8%.
Example 1 was repeated except the impregnating solution was composed of an aqueous solution of copper acetate, and the amount of copper impregnated in the cata-lyst was such that the copper content was CuO 2 based on 12 molybdenum atoms. In this example, acrylonitrile was produced with yields of 79.47O based on the propylene fed with a selectivity to acrylonitrile of 81.8%.
From the foregoin~, it can be seen that catalysts of improved properties can be produced by forming the cata-lysts usin~ an impregnating technique to incorporate at least some of the Group I, II or III elements into the catalyst.
Although only a few embodiments of the invention are described above, it should be appreciated that many modifications can be made without departin~ from the spirit and scope oE the invention. All such modiEications are intended to be included within the scope of the present invention, which is to be limited only by the followin~
claims.
BACKGROUND OF THE INVENTION
The present invention relates to improved oxide complex catalysts for use in various oxidation-tYpe reac-tions such as, for example, the oxidation of propylene or isobutylene to produce acrolein and acrylic acid or meth-acrolein and methacrylic acid respectively, the ammoxidation of propylene or isobutylene to produce acrylonitrile or methacrylonitrile, respectively, or the oxydehydrogenation of isoamylenes to produce isoprene.
Iron bismuth molybdate oxidation catalysts are well known and many different promoters have been proposed for such systems. See, for example, U.S. Patent 3,642,930, in which alkali metals and optionally cobalt and/or nickel are disclosed as useful. See also U.S. Patent 4,123,453 wherein the Group II elements are proposed.
Although known catalysts exhibit ~ood catalytic properties, it is always beneficial to provide new catalysts having even better catalytic properties.
Accordingly, it is an object of the present inven-tion to provide a new technique for making catalysts of improved catalytic properties.
S UMMAR Y OF THE _I NVENT I ON
This and other objects are accomplished by the present invention which is based on the discovery that iron bismuth molybdate oxide complex catalysts promoted with Group I, II and/or III elements of im~roved catalytic per-formance can be obtained provided that at least some of the . . r ~
,1 ~t~57~ ~ 5277) Group I, II or III elements are incorporated into the cata-lyst by impregnation of a preformed and calcined iron bismuth molybdate oxide complex.
This, the present invention provides a process for im-proving the c~talytic properties of a substantially crystalline iron bismuth molybdate oxide complex interim catalyst which comprises incorporating at least one element from the group's IA,, IB,- IIB, IIIA and IIIB o~ the Periodic Table into the catalyst by impregnation, none o~ the group ~A elements in-coporated into the catalyst by impregnation being derived from a molybdate or silicate, the interim oxide catalyst being formed by forming a precatalyst and thereafter calcining the precatalyst in an oxygen containing gas, the interim oxide complex being impregnated with a solution of the element, and the impregnated interim oxide complex being calcined in an oxy-gen containing gas.
DETAILED DESCRIPTION
Catalysts to which the present invention applies (i.e. final catalyst product) are substantially crystalline oxide complexes having the following general Eormula:
a bCcBidFeeMofox wherein A is at least one element selected from the Group IA, IB, IIA, IIB, IIIA and IIIB elements;
B is one or more Group VIII elements other than Fe, preferably Co ~nd/or Ni and optionally Cr and/or Mn;
C is P, As, Sb, S, Te ~nd/or Sn;
and wherein a is 0.1-12;
b is 0.1-12;
c is 0.1-12;
d is greater than 0-12;
e is 0.1-12;
f is 0.1-12; and ~ t~ (5277) x is a number determined by the valence requirements of the other elements present;
and further wherein the molybdenum content is greater than the contents of any other element in the catalyst, excluding oxygen.
Preferably, a is 0.1 to 6, b is 0.1 to 12, c is 0.1 to 12, d is greater than O to 4, e is 0.1 to 12 and f is 12.
The above catalysts normally contain at least some alkali metal. Also, the bismuth content is usually 0.1 to 5, preferably 0.5 to 2, more preferably about 1, based on 12 atoms of molybdenum. ~In addition, the iron content is nor-mally about 1 to 5, preferably 1.5 to 4, more preferably 2 to 3, based on 12 atoms of molybdenum.
Especially preferred catalysts are those defined by the following formula:
m n o p q r s t x wherein I is at least one Group I element, preferably K, Rb, Cs and/or Cu;
II is at least one Group II element, pref-erably Mg, Ca and/or Zn;
III is at least one Group III element, pref-erably Al and/or Tl;
B is at least one of Co, Ni, Mg and optionally Mn and/or Cr;
D is P, As, Sb, Te and/or Sn;
and wherein m is O to l;
n is O to 12;
o is O to 12;
p is O to 10;
q is O to 6;
r is 1 to 1/2 t;
s is 0.5 ts 1/2 t;
t is 8 to 16;
:.,_ 7.ff~ ' ' ' (5277) x is a number determined by the valence requirements of the other elements present, The catalysts of the invention can be either unsup-ported or supported. If supported, conventional supports such as silica, alumina, Alundum, zirconia, ~itania and the like ~an be employed. Any amount of support can he employed.
- The catalysts of the present invention are made by forming an oxide complex in a conventional manner except that at least some of tl~e Group ~, IIB and/or III elements of the catalvsts are added by an impregnation technique using a solution of these elements to impre~nate a preformed and calcined oxide complex of the other elements. Thus in accordance with the present invention, an oxide complex is formed bv a conventional technique, this oxide complex con-taining all oÇ the elements of the objective catalyst except for at least some of the Group I, IIB and/or III elements which will be added by subsequent impregnation. After this interim oxide complex is made, it is impregnated with a solution of a Group I, II and/or III element, dried and cal-cined to produce the objective catalyst.
Thus, in accordance with the first step of the present invention, an interim oxide complex is formed by a conventional technique. Most easily, this is accomplished by formin~ a solution or slurry, usually in water, of the elements to be incorporated into the interim oxide complex usually in ehe form of salts having heat decomposable anions or cations and/or oxides. The liquid slurry medium is removed from the slurry to form a precatalyst and the pre-catalyst is then calcined in air at elevated temperature, for example 600 to 900C for an extended period of time, 0.5 to 50 hours. Durin~ such calcination, care should be (5277) taken to avoid gross decomposition of the catalyst such as occurs in McClellan, U.S. Patent 3,415,886.
In this regard, an esseneial feature of the McClellan technique is that the interim bismuth molybdate on silica material which is composed of various crystalline molybdates be heated under conditions which are so severe that these crystalline materials are substantially destroyed and replaced with a substantially amorphous phase. This procedure is totally avoided in accordance with the present invention whereby the catalysts produced have the conven-tional structure, i.e. they are substantially erystalline.
Techniques for making oxide complexes in the conventional manner are well known and disclosed, for example, in Grasselli, U.S. Patent 3,642,930.
In another embodiment of the invention, the interim oxide complex can be a used catalyst, that is a catalyst which has already been used in an oxidation or ammoxidation type reaction to produce valuable product.
Once the interim oxide complex is produced as i described above, it is impregnated in accordance with the present ;nvention with a solution of a Group I, IIB or III
element. In order to obtain dissolution of the Group I, II3 or III element, a compound of the element which is soluble ! in the liquid used to form the slurry is normally employed.
For example, if water is chosen as the solution medium, nitrates of the elements can be used. On the other hand, if an or~anic liquid such as an alcohol is used as the l;quid, organic compounds of the elements in question, such as for example acetates can be employed. Also, it is possible to ~ 3 (5277) use the element directly if they can be made to dissolve in the appropriate liquid.
Commonly assigned U.S. Patent 3,280,166 shows improving the properties of a bismuth molybdate or bismuth phosphomolybdate catalyst by impregnating the catalysts with materials which decompose to yield barium oxide and silicon oxide. Potassium silicate is an example of a material which will supply silicon for the silicon oxide. D'Armore, U.S.
4,052,332, discloses a process for rejuvenating used or spent iron bismuth molybdates in which the spent catalyst is impregnated with a solution containing bismuth and molyb-denum. Alkali metal molybdates are examples of materials which can be used to supply molybdenum to the impregnating solution. In accordance with both these techniques, alkali metal would be deposited on the catalyst if a silicate or molybdate of an alkali metal were employed as a source com-pound, and therefore in accordance with the present inven-tion silicates or molybdates of alkali metal are not employed as source compounds for supplying alkali metal to the impregnating solution.
The liquid used for the impregnating solution is not critical and both aqueous and organic liquids can be employed. For example, in addition to water, various alcohols and especially ethanol, propanol and so forth can be employed as can acetone, hydrocarbons, etc. Also, mixed systems can be employed. For example, solutions oE water and various organic acids such as tartaric, oxalic, acetic, citric, chloroacetic acid and the like can be employed.
Also, various compounds which aid solubility can also be included. For example, various mineral acids such 3S
~ (5277) HNO3, H2SO4, HCl, H3PO4 and the like can be included. Basically, any liquid can be employed so long as the liquid does not exhibit a significant adverse effect on the ultimate catalyst produced. For example, strong bases should be avoided since they may poison the ultimate cata lyst product.
The impregnating element is deposited in the interim oxide complex by mixing the interim complex with the impregnating solution and thereafter removin~ the liquid.
For ease of operation and control of the amount of impreg-nant deposited on the catalyst, this is usually accomplished by mixing the impregnating solu~ion and the interim complex together and thereafter evaporating the impregnating liquid.
The concentration of impregnant in the impregnating liquid and the relative amounts of impregnating liquid and interim oxide complex are not critical and can be easily selected by those skilled in the art to facilitate ease of impregnation. Usually, however, the amount of impregnating solution will be no more than 1.5, preferably 1.1, more preferably 1.0 times the pore volume of the interim catalyst to be impregnated.
Once the impregnating liquid is removed, the impregnated interim oxide complex is calcined at elevated temperature and pressure to set the impregnant metal into the catalyst and establish the final relationship of the atoms therein. Calcination is accomplished by heating a~
elevated temperature in the presence of an oxygen-containing gas, normally air, in a routine manner. For example, heating in accordance with the above-noted Grasselli patent, U.S. 3,642,930, is preferred. Again, care must be taken to ~'s'~ (5277) avoid de~struction of the crystalline bismuth molyhdates as occurs in the above-noted McClellan patent.
The catalysts produced by the inventive process can be used in all oxidation-eype reactions in which analogous catalysts are used, such as for example oxidation of olefins to produce aldehydes and acids, ammoxidation of olefins to produce unsaturated nitriles and oxydehydrogenation of olefins to produce diolefins.
The following examples are provided to more thoroughly describe the present invention.
COMPARATIVE EXAMPLE A
A silica-supported, alkali metal-promoted catalyst of the type shown in commonly assigned U.S. 3,642,930 was charged into a fluid-bed reactor and contacted with a feed comprising 1.8 propylene/2.2 NH3/3.6 O2/2.4 N2/6 H2O
at 430C for a contact time oE 2 secondsO The gross reac-tion product obtained was recovered and analyzed and it was found that acrylonitrile was produced in yields of 77.6%
based on the propylene fed with a selectivity to acrylo-nitrile of 82.2%.
_ Comparative Example A was repeated except that 25 gms. of the catalyst of Comparative E~ample A after being formed was impregnated with 20 gms. of an aqueous solution containing 0.042 gms. potassium acetate. After impregna-tion, the catalyst was washed with water, dried and then calcined in air at 570C for 3 hours. The potassium-impregnated catalyst was then used in the same way as in ~ (5277) Comparative Example A to produce acrylonitrile. In this example, acrylonitrile was produced with yields of 80.0%
based on the propylene fed with a selectivity to acrYlo-nitrile of 81.8%.
Example 1 was repeated except the impregnating solution was composed of an aqueous solution of copper acetate, and the amount of copper impregnated in the cata-lyst was such that the copper content was CuO 2 based on 12 molybdenum atoms. In this example, acrylonitrile was produced with yields of 79.47O based on the propylene fed with a selectivity to acrylonitrile of 81.8%.
From the foregoin~, it can be seen that catalysts of improved properties can be produced by forming the cata-lysts usin~ an impregnating technique to incorporate at least some of the Group I, II or III elements into the catalyst.
Although only a few embodiments of the invention are described above, it should be appreciated that many modifications can be made without departin~ from the spirit and scope oE the invention. All such modiEications are intended to be included within the scope of the present invention, which is to be limited only by the followin~
claims.
Claims (3)
1. A process for improving the catalytic proper-ties of a substantially crystalline iron bismuth molybdate oxide complex interim catalyst comprising incorporating at least one element from Groups IA, IB, IIB, IIIA and IIIB of the Periodic Table into the catalyst by impregnation, none of the Group IA elements incorporated into the catalyst by impregnation being derived from a molybdate or silicate said interim oxide complex being formed by forming a precatalyst and thereafter calcining said precatalyst in an oxygen containing gas, said interim oxide complex being impregnated with a solution of said element, and the im-pregnated interim oxide complex being calcined in an oxygen containing gas.
2. The process of claim 1 wherein the improved catalyst produced by said process has the formula:
AaBbCcBidFeeMofOx wherein A is at least one element selected from the Group I, II and III elements;
B is one or more Group VIII elements other than Fe, preferably Co and/or Ni and optionally Cr and/or Mn;
C is P, As, Sb, S, Te and/or Sn;
and wherein a is 0.1-12;
b is 0.1-12;
c is 0.1-12;
d is greater than 0-12;
e is 0.1-12;
f is 0.1-12; and x is a number determined by the valence requirements of the other elements present;
10.
(5277)
AaBbCcBidFeeMofOx wherein A is at least one element selected from the Group I, II and III elements;
B is one or more Group VIII elements other than Fe, preferably Co and/or Ni and optionally Cr and/or Mn;
C is P, As, Sb, S, Te and/or Sn;
and wherein a is 0.1-12;
b is 0.1-12;
c is 0.1-12;
d is greater than 0-12;
e is 0.1-12;
f is 0.1-12; and x is a number determined by the valence requirements of the other elements present;
10.
(5277)
3. The process of claim 1 wherein said solution is free of molybdenum and silicon.
11.
11.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA000395801A CA1178570A (en) | 1982-02-08 | 1982-02-08 | Impregnating catalysts |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA000395801A CA1178570A (en) | 1982-02-08 | 1982-02-08 | Impregnating catalysts |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1178570A true CA1178570A (en) | 1984-11-27 |
Family
ID=4122002
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA000395801A Expired CA1178570A (en) | 1982-02-08 | 1982-02-08 | Impregnating catalysts |
Country Status (1)
| Country | Link |
|---|---|
| CA (1) | CA1178570A (en) |
-
1982
- 1982-02-08 CA CA000395801A patent/CA1178570A/en not_active Expired
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