Superacid catalyst for the hydroisomerization of n-paraffins

Chemistry of hydrocarbon compounds – Saturated compound synthesis – By isomerization

Reexamination Certificate

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C585S750000, C585S751000, C502S217000, C502S223000, C502S339000, C502S349000

Reexamination Certificate

active

06495733

ABSTRACT:

BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a superacid catalyst based on sulfated zirconium oxide, optionally containing a noble metal, prepared in the presence of acetylacetone. This catalyst is useful in acid-catalyzed processes and in the hydroisomerization of n-paraffins.
2. Description of the Background
Catalysts based on sulfated oxides of zirconium, titanium, iron having superacid characteristics, are known in the art, according to the definition of Gillespie, as described for example by K. Arata, Adv. Catal., 37, 165, 1990. These superacid catalysts are usually prepared by means of an articulate synthesis comprising numerous steps. For example sulfated zirconia (ZrO
2
/SO
4
−2
) is generally prepared in the following way:
1) precipitation of fresh zirconia hydroxide;
2) drying;
3) impregnation with a sulfating agent;
4) calcination.
Step (3) can be carried out in various ways: via wet inbibition point, as described in EP 520 543, by treatment with a gaseous stream of H
2
S or SO
2
, as described by J. R. Shon, H. W. Kim, in J. Mol. Catal., 52, (1989), 361, or by treatment in solution (R. Le Van Mao, S. Xiao and T. Si Le, Catal. Lett., 35, (1995), 107; D. Farcasiu, J. Qi Li, in Appl. Cat. A, 128, (1995), 97). All the steps of this preparation are critical: zirconium precursor, drying temperature, sulfating agent, concentration of the sulfating agent solution used, temperature and calcination time. As a result the control and reproducibility of the synthesis are complicated. Simplified syntheses of ZrO
2
/SO
4
2−
comprising a single synthesis step have recently been effected. For example H. Arata et al. use Zr(SO
4
)
2
as precursor (Bull. Chem. Soc.Jpn., 63, (1990), 244): this method however does not allow control of the sulfur content and its dispersion. U. Ciesla et al. precipitate zirconium hydroxide in the presence of alkyl sulfonates or sulfonates (EUROPACAT II Congress 3-8 September 1995). The crystallization of the amorphous phase begins at very high temperatures, higher than 650° C. Another synthesis method in a single step is based on the gelation of Zr(OC
3
H
7
)
4
dispersed in propaol, nol, in an acid environment by HNO
3
/H
2
SO
4
. The material, before being calcined, must be dried under supercritical conditions (D. A. Ward, E. I. Ko. J.Cat. 150, (1994), 18).
In D. Tichit et al., Catal. Let., 38 (1996) 109-113, Zr(OC
3
H
7
)
4
dispersed in propanol, is gelified in an acid environment by H
2
SO
4
. The materials obtained after calcination at 650° C. consist of tetragonal phase associated with small quantities of monoclinic phase. Patent application MI 97A00358 describes a sulfated zirconia catalyst with particular porosity characteristics and with high acid properties prepared by means of a process in a single reaction step. This superacid catalyst comprising zirconium oxide on the surface of which sulfate groups are present in a quantity corresponding to total coverage of the surface of the zirconium oxide by means of a monolayer of these sulfate groups, is characterized by a porosity ranging from 0.1 to 0.3 cm
3
/g consisting of at least 70% of pores having a diameter ranging from 1 to 4 nm. According to a preferred aspect, this material may additionally contain a noble metal, preferably platinum, in a quantity ranging from 0.1 to 3% by weight.
These materials are prepared by means of a process which comprises:
(a) hydrolysis in an alkaline environment of a hydrolyzable compound of zirconium in the presence of a tetra-alkylammonium hydroxide (TAA) and sulfuric acid
(b) drying of the resulting product and its calcination at a temperature ranging from 250 to 650° C.
The materials obtained in step (b) can be impregnated with a solution of a compound of a noble metal to obtain a sulfated zirconia on whose surface a noble metal is deposited in a quantity that varies from 0.1 to 3% by weight. The presence of superacid sites in these materials was verified by pyridine absorption and FT-IR spectrum analysis. It is specified in fact by K. Tanabe et al., Successful Design of Catalysts, T. Inui Ed., (1988), 616, that sulfated zirconia has an intense IR band at about 1370 cm
−1
, attributed to the asymmetrical stretching of the S═O group. The absorption of pyridine causes a consistent shift of this signal and the entity of this shift is correlated to the superacid strength of the material and its catalytic properties. The material described in MI 97A00358 showed a shift ranging from 50 to 60 cm
−1
against a maximum value provided in literature of 50 cm
−1
.
These catalysts based on sulfated zirconia are superacid solids and can therefore be used in acid-catalyzed reactions. When they additionally contain a noble metal they are bifunctional catalysts that can be used in the hydroisomerization process of n-paraffins, to convert these hydrocarbons with a linear chain to hydrocarbons with a branched chain. According to a preferred aspect, light n-paraffins can be particularly subjected to hydroisomerization to obtain hydrocarbons with a branched chain having a higher octane number, for use as fuels.
SUMMARY OF THE INVENTION
We have now unexpectedly found that by carrying out the synthesis of this sulfated zirconia in the presence of acetylacetone, catalysts based on zirconium oxide are obtained, on whose surface sulfate groups are present with improved superacid characteristics and which are therefore more active in acid-catalyzed reactions.
The present invention therefore relates to a superacid catalyst comprising zirconium oxide on whose surface sulfate groups are present, in a quantity corresponding to total coverage of the surface of the zirconium oxide by means of a monolayer of these sulfate groups, having a porosity ranging from 0.1 to 0.30 cm
3
/g, consisting of at least 70% of pores with a diameter ranging from 1 to 4 nm, optionally containing a noble metal in a quantity ranging from 0.1 to 3% by weight, obtained by means of:
(a) hydrolysis in an alkaline environment of a hydrolyzable compound of zirconium in the presence of a tetra-alkylammonium hydroxide (TAA) and sulfuric acid and acetylacetone;
(b) drying of the resulting product and calcination at a temperature ranging from 250 to 650° C.;
(c) optional treatment of the product resulting from step (b) with an aqueous solution of a compound of a noble metal, drying and calcination.
The presence in step (a) of the synthesis of acetylacetone (AcAc) allows the preparation of sulfated zirconia with improved superacid characteristics, and therefore more active in acid-catalyzed reactions.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
In step (a) of the preparation process of the material of the present invention the tetra-alkylammonium hydroxide is selected from hydroxides of the type R
1
R
2
R
3
R
4
NOH, wherein R
1
, R
2
, R
3
and R
4
are the same or different and are alkyl groups, preferably comprising from 1 to 6 carbon atoms; the hydrolyzable derivative of zirconium is selected from alkoxyderivatives, nitrate, sulfate, and is preferably tetrapropylorthozirconate. The sulfuric acid is used in aqueous solution in a concentration ranging from 0.01 to 10 M. The molar ratios of the mixture of step (a) are the following:
AcAc/Zr=0.001-0.5
TAA/Zr=0.05-0.25
ROH/Zr=10-100
H
2
SO
4
/Zr=0.1-0.5
H
2
O/Zr=2-100
According to a preferred aspect the zirconium compound is dispersed in an alcohol ROH wherein R is an alkyl with from 1 to 6 carbon atoms, and is preferably propanol; the acetylacetone is then added to this mixture followed by the tetra-alkylammonium hydroxide in aqueous solution, preferably tetrapropylammonium hydroxide, and the resulting solution is left under stirring for a few hours before adding the sulfuric acid solution. The resulting dense slurry, which must have a basic pH, is left under stirring for a period of time ranging from 2-20 hours.
In step (b) the resulting product, after possible concentration, is dried to a temperature ranging from 80 to 150° C. and is then calcined at a t

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