(19)
(11)EP 2 814 603 B1

(12)EUROPEAN PATENT SPECIFICATION

(45)Mention of the grant of the patent:
09.09.2020 Bulletin 2020/37

(21)Application number: 13749889.5

(22)Date of filing:  15.02.2013
(51)International Patent Classification (IPC): 
B01J 23/00(2006.01)
B01J 35/00(2006.01)
(86)International application number:
PCT/US2013/026323
(87)International publication number:
WO 2013/123315 (22.08.2013 Gazette  2013/34)

(54)

SPHEROIDAL RESID HYDRODEMETALLATION CATALYST, ITS PREPARATION AND ITS USE

KUGELFÖRMIGER HYDRODEMETALLIERUNGSKATALYSATOR FÜR RÜCKSTÄNDE, VERFAHREN ZUR HERSTELLUNG UND VERWENDUNG

CATALYSEUR D'HYDRODÉMÉTALLISATION DE RÉSIDUS SPHÉROIDAL, PROCÉDÉ POUR SA PRÉPARATION ET SON UTILISATION


(84)Designated Contracting States:
AL AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HR HU IE IS IT LI LT LU LV MC MK MT NL NO PL PT RO RS SE SI SK SM TR

(30)Priority: 17.02.2012 US 201261600024 P

(43)Date of publication of application:
24.12.2014 Bulletin 2014/52

(73)Proprietor: Advanced Refining Technologies, LLC
Columbia, Maryland 21044 (US)

(72)Inventors:
  • PLECHA, Stanislaw
    Columbia, Maryland 21044 (US)
  • KAGAMI, Narinobu
    Chuoku Chiba 260-0024 (JP)
  • DUMA, Viorel
    Hercules, California 94547 (US)
  • CREIGHTON, John Everett
    Maryland 21163 (US)

(74)Representative: BRP Renaud & Partner mbB Rechtsanwälte Patentanwälte Steuerberater 
Königstraße 28
70173 Stuttgart
70173 Stuttgart (DE)


(56)References cited: : 
US-A- 3 956 105
US-A- 4 568 657
US-A1- 2010 279 854
US-A1- 2011 218 097
US-A- 4 179 408
US-A1- 2005 234 137
US-A1- 2011 218 097
US-B1- 6 383 975
  
      
    Note: Within nine months from the publication of the mention of the grant of the European patent, any person may give notice to the European Patent Office of opposition to the European patent granted. Notice of opposition shall be filed in a written reasoned statement. It shall not be deemed to have been filed until the opposition fee has been paid. (Art. 99(1) European Patent Convention).


    Description

    CROSS REFERENCE TO RELATED APPLICATION



    [0001] This application clams the benefit of the filing date of United States Provisional Patent Application No. 61/600,024 filed 17 February 2012, entitled "SPHEROIDAL RESID HYDRODEMETALLATION CATALYST.

    FIELD OF THE INVENTION



    [0002] The present invention relates to the catalytic hydrotreating of liquid hydrocarbon containing feed streams. In particular, the present invention relates to a catalyst carrier, catalyst compositions prepared using the carrier, a method of preparing the catalyst compositions and a process of reducing the metals content of a hydrocarbon heavy feedstock using the aforementioned catalyst compositions.

    BACKGROUND OF THE INVENTION



    [0003] In the petroleum refining industry it is often useful to upgrade certain oil and fractions like heavy oils and residuum by hydrotreating. Examples of such hydrotreating processes are hydrodemetallation, desulfurization, and denitrogenation. In these processes the feedstock is contacted with a hydroconversion catalyst in the presence of hydrogen at elevated pressure and temperature. Due to strict demands imposed by ecological regulations, the refining industry has become increasingly more focused on producing high quality cleaner fuels with a minimum content of contaminants such as sulfur, nitrogen and heavy metals.

    [0004] Catalysts used in hydrotreating processes generally comprise catalytically active metals from Groups 6, 9 and 10 of The Periodic Table and are typically supported on alumina, which may be combined with other inorganic refractory materials such as silica, magnesia, titania, zirconia and the like. Secondary promoters or additives, such as halogens, phosphorous and boron, have also been used to enhance catalytic properties. To achieve the maximum effect from hydrotreating processes, it is necessary to optimize catalyst activity and selectivity to a desired hydrotreating reaction. Catalyst activity and selectivity are determined and affected by such factors as the nature and properties of the catalyst support, the catalytic agents, activity and selectivity of promoters as well as the preparation and activation method used.

    [0005] Where heavy feedstocks contain organometallic compounds, the effectiveness of the hydrotreating as well as downstream catalysts tend to decline relatively rapidly, particularly when the impurity is more than about 10 to 20 ppm metals such as dissolved nickel and vanadium. These metallic impurities are said to deposit on the surface and in the pores of these catalysts reducing their effectiveness. One approach to the problem of metal impurity has been to alter the pore structure of the hydrotreating catalyst. However, the determination as to which pore structure to use is unpredictable and not easily obtained. There is yet a conflict in the art regarding optimal pore structure. Several patents which have discussed this conflict include U.S. Patent No. 4,066,574; U.S. Patent No. 4,113,661 and U.S. Patent No. 4,341,625.

    [0006] Hydrotreated hydrocarbon feedstocks having a low Conradson carbon residue are also highly desirable in the refining industry. Carbon residue is a measurement of the tendency of a hydrocarbon to form coke. Expressed in weight percent, carbon residue may be measured as microcarbon residue (MCR). The MCR content in a hydrotreated residual feedstock is an important parameter since the hydrotreated residue usually acts as feed to a coker or a fluid catalytic cracking (FCC) unit. Decreasing the MCR content in the hydrotreated residue decreases the amount of low value coke generated in the coker and increases the amount of gasoline generated in the FCC unit.

    [0007] To this end, there remains a need to develop catalyst compositions that are less expensive and/or more effective in removing metal contaminants from hydrocarbons feed streams, in particularly heavy hydrocarbon feed streams, than catalysts presently employed. There also remains a need for improved hydrodemetallation and/or hydrodesulfurization catalysts which provide good MCR conversion during a hydrotreating process.

    [0008] US 2011/218097 describes the preparation of a catalyst for hydrotreating, especially hydrodesulfurization, of residua and heavy crudes by synthesizing the support from titanium and boehmite, to form either a titanium/alumina support (TiO2/Al2O3) or a titanium-alumina support (TiO2-Al2O3) that is thereafter provided with at least one hydrogenating metal from group VIB in oxide form and a promoter from group VIII also in oxide form. The (TiO2/Al2O3) support is prepared from boehmite, which is peptized by using an inorganic acid, then extruded, calcined and impregnated with a solution containing titanium, while the (TiO2-Al2O3) support is prepared by admixing boehmite with a titanium-containing solution, peptized using an inorganic acid, extruded and calcined to obtain the titanium-alumina support.

    SUMMARY OF THE INVENTION



    [0009] The present invention is based on the discovery that the high temperature calcination of a titania alumina material containing 5 wt % or less titania (based on the total weight of titania alumina) unexpectedly provide spheroidal catalyst supports having a unique pore structure from which supported catalysts having increased catalytic activity and stability to remove metals during a hydrotreating process may be prepared. Advantageously, the supports of the invention offer the economical benefit of lower cost since catalyst compositions prepare from the supports have improved catalytic performance while maintaining a low catalytically active metal content.

    [0010] In one aspect the invention provides a method for preparing a spheroidal support material.for supporting catalytically active metals suitable for the hydrodemetallation of heavy hydrocarbon fractions containing metals under hydrotreating conditions, which process comprises:
    1. (a) forming a co-precipitated titania alumina containing 5 wt % or less titania, based on the total weight of the titania alumina;
    2. (b) peptizing the titania alumina to form an aqueous slurry containing from 20% to 35% solids and having a sufficient viscosity to form droplets;
    3. (c) dropping the slurry in a dripping column to form spheroidal particles;
    4. (d) calcining the spheroidal particles at a temperature ranging from 960°C to 1100°C to obtain a spheroidal titania alumina support having a total pore volume in the range of from 0.7 to 1.2 cc/g, and a pore volume distribution such that greater than 40% of the total pore volume having pores in a diameter larger than 200 Å, 30% or greater of the total pore volume having pores in the range of 200 Å to 500 Å and, greater than 10% of the total pore volume having pores with a diameter above 1000 Å;
    wherein the pore volume and pore size distribution properties of the support are determined by mercury penetration porosimetry using a mercury porosimeter at a pressure range from atmospheric pressure to 4,000 bar, with a contact angle, θ = 140° and a mercury surface tension of 0.47 N/m at 25°C.

    [0011] In a specific embodiment the titania alumina of the support comprises at least 90 wt% of a titania alumina having an alumina R value of from about 0.4 to about 1.7, the R value being defined as the ratio between the integrated intensity of the X-ray diffraction peak at 2θ = 32° and the integrated intensity of the X-ray diffraction peak at 2θ = 46°.

    [0012] In another aspect the present invention provides a spheroidal catalyst support comprising co-precipitated titania alumina having 5 wt% or less titania based on the total titania alumina, said support having a total pore volume in the range of 0.7 to 1.2 cc/g, and a pore volume distribution such that greater than 40% of the total pore volume have pores in a diameter larger than 200 Å, 30 % or greater of the total pore volume have pores in the range of 200 Å to 500 Å and, greater than 10% of the total pore volume have pores with a diameter above 1000 Å, wherein the pore volume and pore size distribution properties of the support are determined by mercury penetration porosimetry using a mercury porosimeter at a pressure range from atmospheric pressure to 4,000 bar, with a contact angle, θ = 140° and a mercury surface tension of 0.47 N/m at 25°C.

    [0013] In yet another aspect the present invention provides a catalyst for hydrodemetallation of heavy hydrocarbons, comprising:
    1. (a) a spheroidal support comprising co-precipitated titania alumina having 5 wt% or less titania, based on the total weight of titania alumina; and
    2. (b) at least one catalytic agent comprising a metal selected from the group consisting of a metal of Group 6 of The Periodic Table, a metal of Group 9 of The Periodic Table, a metal of Group 10 of The Periodic Table, and combinations thereof, and optionally phosphorous;
    wherein the support has a total pore volume in the range of from 0.7 to 1.2 cubic centimeters per gram, with greater than 40% of the total pore volume having pores in a diameter larger than 200 Å, 30% or greater of the total pore volume having pores in the range of 200 Å to 500 Å and, greater than 10% of the total pore volume having pores with a diameter above 1000 Å; and
    wherein the pore volume and pore size distribution properties of the support are determined by mercury penetration porosimetry using a mercury porosimeter at a pressure range from atmospheric pressure to 4,000 bar, with a contact angle, θ = 140° and a mercury surface tension of 0.47 N/m at 25°C.

    [0014] The present invention also provides improved hydrotreating catalysts which have the ability to reduce the content of metals simultaneously with reducing the content of sulfur and the MCR of a heavy hydrocarbon during a hydrotreating process.

    [0015] The present invention further provides improved hydrotreating processes using spheroidal supported catalyst compositions and processes of the present invention.

    [0016] These and other aspects and embodiments of the present invention are described in further details below.

    DETAILED DESCRIPTION OF OF THE INVENTION



    [0017] The present invention provide spheroidal catalyst compositions comprised of catalytically active metals or metal compounds of Groups 6, 9 and 10 of The Periodic Table, and optionally, phosphorous compounds supported on a spheroidal titania alumina support in accordance with the invention. In one embodiment of the invention, the support material used to prepare the catalyst of the invention generally comprises a titania alumina which contains 5 wt% or less titania, based on the total weight of the titania alumina. In another embodiment of the invention the titania alumina comprises from about 2.5 to about 4 wt% titania, based on the total weight of the titania alumina. In yet another embodiment of the invention, the titania alumina comprises from about 0.3 to about 1 wt% titania.

    [0018] In a preferred embodiment of the invention, the titania alumina used to prepare the supports of the invention comprises at least 90 wt. % of an alumina having a mixture of gamma-alumina and delta- and/or theta-alumina, such that the titania alumina composition is reflected by an alumina R value in the range of from about 0.4 to about 1.7, preferably from about 0.6 to about 1.4. The term "R value" as used herein is used to indicate the ratio between the integrated intensity of the X-ray diffraction peak at 2 θ=32° and the integrated intensity of the X-ray diffraction peak at 2 θ=46°. R values are determined by a method as disclosed and described in U.S. Patent No. 5,888,380.

    [0019] The R value can be expressed in by the formula:

    in which [I(2θ)=32°] and [I(2θ)=46°] stand for the integrated intensity of the peak at a 2θ angle of the X-ray diffraction spectrum at 32° and 46°, and 46°, respectively. In the present specification, use is made of a PANalytical X'Pert X-RAY DIFFRACTOMETER. The following measurement conditions and apparatus were used: CuK alpha-ray vessel, vessel voltage 50 kV, vessel current 30 mA, double axis vertical goniometer, scanning rate 0.867°/min, emitting slit width 1°, scattering slit width, 1°, receiving slit width 0.3 mm, 2θ angle 4°≤2θ≤ 82°.The peak which appears at 2θ=46° is due to gamma-alumina, while the peak appearing at 2θ=32° is due to delta- and/or theta-alumina. At this angle the latter two alumina types cannot be distinguished from each other by way of X-ray diffraction. The two peaks at 2θ=46° and 2θ=32° do not overlap and can therefore be readily integrated to calculate the integrated intensity. In calculating the integrated intensity, the background intensity is not taken into account, as is well known to the person skilled in the art.

    [0020] In this respect it is noted that the R value should be determined on a support, on which no catalytically active metals are present.

    [0021] The spheroidal titania alumina supports in accordance with the present invention generally comprise at least 90 wt% of titania alumina as described herein. Preferably, the support material comprises at least 95 wt%, most preferably, greater than 99 wt% of the titania alumina, said weight percent being based on the total weight percent of the support. The support material thus can "consist essentially of' the titania alumina as described herein. The phrase "consist essentially of' as used herein with regard to the composition of the support material is used herein to indicate that the support material may contain the titania alumina and other components, provided that such other components do not materially affect or influence the catalytic properties of the final hydroconversion composition.

    [0022] Spheroidal titania alumina supports of the present invention possess specific properties of surface area, pore volume and pore volume distribution. Unless otherwise specified herein, the pore volume and pore size distribution properties of the titania alumina supports as defined herein are determined by mercury penetration porosimetry. The mercury measurement of the pore volume and the pore size distribution of the alumina support material is performed using any suitable mercury porosimeter capable of a pressure range of atmospheric pressure to about 4,000 bar, with a contact angle, θ = 140° and with a mercury surface tension of 0.47 N/m at room temperature.

    [0023] Surface area as defined herein is determined by BET surface area analysis. The BET method of measuring surface area is described in detail in an article by Brunauer, Emmett and Teller in J. Am. Chem. Soc. 60 (1938) 309-319.

    [0024] The surface area of the titania alumina support ranges from about 80 m2/g to about 150 m2/g. In a preferred embodiment of the invention, the surface area of the titania supports ranges from about 90 m2/g to about 130 m2/g.

    [0025] Generally, supports of the invention have a total pore volume in the range of from about 0.6 cc/g to about 1.2 cc/g. In a preferred embodiment of the invention, the total pore volume of the supports ranges from about 0.8 to about 1.1 cc/g.

    [0026] The support of the invention has a distinct pore volume distribution such that generally greater than 40% of the total pore volume have pores in a diameter larger than 200 Å, with about 30% or greater of the total pore volume having pores in a diameter in the range of about 200Å to about 500 Å and, greater than 10% of the total pore volume having pores with a diameter above 1000 Å.

    [0027] In one embodiment of the invention, about 50% to about 90% of the total pore volume of the supports has pores in a diameter larger than 200 Å.

    [0028] In another embodiment of the invention, about 30% to about 80% of the total pore volume of the supports has pores with a diameter ranging from about 200Å to about 500Å.

    [0029] In yet another embodiment of the invention, greater than about 15% of the total pore volume has pores with a diameter above 1000 Å.

    [0030] Spheroidal titania alumina supports of the invention have a general spherical or oblate shape and may be in the form of pellets, extrudates, and the like. The supports of the invention may be prepared by any conventional method in the catalyst arts useful for making a spheroidal shaped support, provided however that the final support have the desired pore structure. Generally, supports of the invention are prepared by a process comprising co-precipitating a titania alumina containing 5 wt% or less titania under specific and controlled conditions of reaction temperature, time, and pH. In a preferred embodiment of this invention, the titania alumina spheroidal support is prepared by an external gelation oil-drop process as disclosed and described in U.S. Patent 4,279,779. In the titania-alumina co-precipitation process, a sufficient amount of an aqueous aluminum sulfate and titanium sulfate mixture is added simultaneously with sodium aluminate to a water heel at a temperature of about 50°C to about 80°C to precipitate titania-alumina having 5 wt% or less titania in the co-precipitated titania-alumina. During the precipitation step, the pH of the slurry is maintained at about 7.2 to about 9.0 and the temperature is maintained from about 50°C to about 80°C. At the end of the precipitation step, the pH of the slurry is adjusted to about 8.6 to about 9.3 to enable maximum removal of residual impurities, e.g. soda and sulfates. Thereafter, the co-precipitated titania alumina is filtered, washed with water and dried to provide a titania alumina having a moisture content from about 22 wt % to about 40 wt %, preferably from about 25 wt% to about 32 wt%, as determined by a moisture analyzer at 955°C.

    [0031] The dried titania alumina is thereafter peptized by mixing with a suitable peptizing agent to form an aqueous acidic titania alumina slurry containing from about 20% to about 35, preferably from about 22% to about 30% solids. Droplets of the slurry are thereafter passed through air into a suitable dripping column containing an upper body of a water immiscible liquid, e.g. kerosene, toluene, heavy naptha, light gas oil, paraffin oil and the like, and anhydrous ammonia and a lower body of aqueous alkaline coagulating agent, e.g. ammonium hydroxide solution, to form spheroidal particles. The titania alumina spheroids are dried to a total moisture content of about 20 wt% to 35 wt % and are thereafter calcined at a high temperature ranging from about 960 °C to 1100°C, preferably from about 980°C to about 1060°C, for about 1 hour to about 3 hours, to obtain a final titania alumina spheroidal support having the desired pore structure.

    [0032] Optionally, the titania alumina slurry is aged with agitation prior to formation of the droplet in the dripping column. Agitation and aging of the slurry aid in forming a uniform material with a viscosity that permits proper formation of droplets from which the spheroids can be formed. For droplet formation, slurry viscosities of about 300 to about 2000 cps, preferably about 600 to about 1500 cps are suitable. Agitation of the slurry may be accomplished by a variety of means ranging from hand stirring to mechanical high shear mixing. Following agitation, the slurry is aged from a few minutes to many days. Preferably, the slurry is aged for about 1hr to about 3 hrs.

    [0033] The length of the column can vary widely and will usually range from about 3.05 m to about 9.14 m (10 to 30 feet) in height. The organic phase may generally comprise from about 30% to about 60% of the column length and the coagulation phase the remainder. As will be understood by the one skilled in the arts, the cross sectional area of the dripping column will vary depending upon the number of droplet nozzles used. Typically, the cross sectional area of the column ranges from about 0.032 m2 (50 inch squared) to about 0.32 m2 (500 inch squared).

    [0034] Suitable peptizing agents useful to prepare the supports of the invention include, but are not limited to, nitric acid, acetic acid, hydrochloric acid and other strong monobasic acids. In a preferred embodiment of the invention, the peptizing agent is a mixture of nitric acid and acetic acid.

    [0035] Spheroidal supports in accordance with the invention may have various sizes. Generally the support has an average particle size ranging from about 0.5 mm to about 15 mm. In a preferred embodiment of the invention, the spheroid support has a diameter ranging from about 1 to about 10 mm. In a more preferred embodiment the diameter ranges from 2 to about 5 mm. As will be understood by one skilled in the catalyst arts, catalyst particles produced from the supports will have a similar size and shape as the support.

    [0036] Catalysts in accordance with the invention are prepared by contacting titania alumina supports of the invention with an aqueous solution of at least one catalytically active metal or precursor compound to uniformly distribute the desired metal on the support. Preferably, the metal is distributed uniformly throughout the pores of the support. In one embodiment of the invention, the catalysts are prepared by impregnation of the catalyst supports to incipient wetness with an aqueous solution of the desired catalytically active metal or precursor metal compound.

    [0037] Catalytically active metal and/or precursor metals compounds useful to prepare the catalyst composition of the invention, include, but are not limited to metals or compounds of metals selected from the group consisting of Group 6 of The Periodic Table, Group 9 of The Periodic Table, Group 10 of The Periodic Table and combinations thereof. Preferred Group 6 metals include, but are not limited to, molybdenum and tungsten. Preferred Groups 9 and 10 metals include, but are not limited to, cobalt and nickel.

    [0038] Concentrations of Group 6 metals and/or metal compounds useful to prepared catalyst composition of the present invention typically is an amount sufficient to provide from about 1 wt% to about 10 wt% of the desired Group 6 metal, preferably from about 2 wt% to about 5 wt% , in the total catalyst composition. Concentrations of Group 9 metals and/or metal compounds useful to prepare the catalyst compositions of the present invention typically is an amount sufficient to provide from about 0 wt% to about 5 wt% of the desired Group 9 metal, preferably from about 0.5 wt% to about 2 wt%, in the total catalyst composition. Concentrations of Group 10 metals and/or metal compounds useful to prepare the catalyst compositions of the present invention typically is an amount sufficient to provide from about 0 wt% to about 5 wt% of the desired Group 10 metal, preferably from about 0.5 wt% to about 2 wt%, in the total catalyst composition.

    [0039] In a preferred embodiment of the invention the catalytic agent is a combination of nickel and molybdenum. In a more preferred embodiment of the invention, the resulting catalyst comprises Mo concentrations in the range of about 2 wt% to about 4 wt% and Ni concentrations in the range of about 0.5 wt% to about 2 wt%, said percentages being based on the total catalyst composition.

    [0040] Suitable metal compounds of Groups 9 and 10 metals include, but are not limited to, metallic salts such as nitrates, acetates and the like. Suitable metal compounds of Group 6 metals include, but are not limited to, ammonium molybdate, molybdic acid, molybdenum trioxide, and the like.

    [0041] Catalytically active metals contemplated for use in the present invention are preferably used in the form of oxides and/or sulfides of the metals. In the more preferred embodiment of the invention, the catalytically active metals are used in the form of oxides.

    [0042] Catalyst compositions of the invention may also comprise a phosphorus component. In this case, the impregnating solution may also contain a phosphorus compound, such as for example phosphoric acid, phosphates, and the like, in addition to desired catalytically active metal or metal compounds. Concentrations in the range of about 0 to about 2 wt% phosphorous, based on the total weight of the catalyst composition, are suitable for use in catalysts of the invention.

    [0043] Following treatment with the desired catalytic agent/s, the catalysts are optionally dried at a temperature in the range of from about 100°C to 200°C for about 10 minutes to about 2 hours, and thereafter the resulting catalysts are calcined at a temperature in the range of from about 300°C to about 600°C for about 1 hour to about 3 hours, to convert at least part, preferably all, of the metal components or precursors to the oxide form.

    [0044] As will be clear to a person skilled in the art, there is a wide range of variations on the impregnating method used to support the catalytic active metals on the supports. It is possible to apply a plurality of impregnating steps or the impregnating solutions may contain one or more of the metal components or precursors to be deposited, or a portion thereof. Instead of impregnating techniques, dipping methods, spraying methods and the like can be used. In the case of multiple impregnations, dipping, and the like, drying and/or calcining may be carried out as between steps.

    [0045] The catalysts of the invention exhibit an increased catalytic activity and stability for hydrodemetallization of a heavy hydrocarbon feedstock containing metals during a hydrotreating process. The heavy hydrocarbon feedstock useful in the present invention can be obtained from any suitable source of hydrocarbons, including, for example, petroleum crude oils and tar sand hydrocarbons, such as, the heavy oils extracted from tar sand. The heavy hydrocarbon feedstock can be a vacuum resid or atmospheric resid component of a petroleum crude oil or a tar sand hydrocarbon. The heavy hydrocarbon feedstock may also include light and heavy gas oils, as well as petroleum crude oil, atmospheric residues and vacuum residues blended with gas oils, particularly vacuum gas oils, crudes, shale oils, and tar sand oils.

    [0046] The heavy hydrocarbon feedstock generally will include a mixture of hydrocarbons derived from a crude oil or tar sand hydrocarbon material or other source of heavy hydrocarbons. A portion, preferably a major portion, of the heavy hydrocarbons of the mixture has a boiling temperature exceeding about 343° C. (650° F.). The heavy hydrocarbon feedstock is thus defined as having a boiling range, as determined by ASTM test procedure D-1160, such that at least about 20 wt% of the heavy hydrocarbon feedstock boils at a temperature exceeding 524° C. (975° F.). The preferred heavy hydrocarbon feedstock has a boiling range such that at least 30 wt% boils at a temperature exceeding 524° C. (975° F.), and, most preferably, at least 40 wt% of the heavy hydrocarbon feedstock boils at a temperature exceeding 524° C. (975° F.).

    [0047] The API gravity of the heavy hydrocarbon feedstock can range from about 3 to about 20, but, more specifically, the API gravity is in the range of from 4 to 15, and, more specifically, from 4 to 11.

    [0048] The heavy hydrocarbon feedstock can have a Conradson carbon residue content, as determined by ASTM testing method D-189, exceeding 5 weight percent and, more specifically, the Conradson carbon residue content is in the range of from 8 weight percent to 30 weight percent.

    [0049] As earlier noted, the metals contained in the heavy hydrocarbon feedstock can include nickel or vanadium, or both. The nickel concentration in the heavy hydrocarbon feedstock can exceed 10 parts per million by weight (ppmw) or it can exceed 30 ppmw. More specifically, the nickel concentration in the heavy hydrocarbon feedstock can be in the range of from 40 ppmw to 500 ppmw. The vanadium concentration in the heavy hydrocarbon feedstock can exceed 50 ppmw or it can exceed 100 ppmw. More specifically, the vanadium concentration in the heavy hydrocarbon feedstock can be in the range of from 150 ppmw to 1500 ppmw.

    [0050] Catalysts of the invention are also useful to increase the hydrodesulfurization activity simultaneously with hydrodemetallization during a hydrotreating process where the hydrocarbon feedstock contains both sulfur and metals. The sulfur content of the feed is generally above 0.1 wt% and will frequently be more than 1 wt%.

    [0051] Further, catalysts in accordance with the present invention provide an increased micro carbon residue (MCR) conversion during a hydrotreating process as compared to prior demetallation and/or desulfurization catalysts prepared from alumina or aluminia titania supports where the supports aree calcined at a low temperature (i.e. below 960 °C). Consequently, the hydrotreated hydrocarbon fraction obtained exhibits a reduced MCR content as compared to the MCR content of the starting heavy hydrocarbon feedstock.

    [0052] A hydrotreating process employing the catalyst compositions of this invention may be carried out under hydrotreating process conditions in an apparatus whereby an intimate contact of the catalyst composition with said metal containing feedstock and a free hydrogen containing gas is achieved, to produce a hydrocarbon-containing product having a reduced level of metals, e.g., nickel and vanadium, and, optionally sulfur. In accordance with the invention, the hydrotreating process is preferably carried out using an Onstream Catalyst Replacement (OCR) technology. Typical hydrotreating process conditions useful in the invention include, but are not limited to, reaction temperatures ranging from about 300° to about 450° C., hydrogen pressures of about 25 to about 200 bar, H2:oil ratios ranging from about 150 to about1500 N1/1, and space velocities (hr-1) of about 0.1 to about 5. In one embodiment of the invention, the operating conditions for metal containing hydrocarbon feedstock desulfurizaton process include a reaction zone temperature of about 370°C to about 400°C, a pressure of about 100 to about 200 bar, and a hydrogen feed rate between about 200 and about 500 N1/1 of oil feed.

    [0053] To further illustrate the present invention and the advantages thereof, the following specific examples are given. The examples are given as specific illustrations of the claimed invention. It should be understood, however, that the invention is not limited to the specific details set forth in the Examples.

    [0054] All parts and percentages in the examples as well as the remainder of the specification that refers to solid compositions or concentrations are by weight unless otherwise specified. However, all parts and percentages in the examples as well as the remainder of the specification referring to gas compositions are molar or by volume unless otherwise specified.

    [0055] Further, any range of numbers recited in the specification or claims, such as that representing a particular set of properties, units of measure, conditions, physical states or percentages, is intended to literally incorporate expressly herein by reference or otherwise, any number falling within such range, including any subset of numbers within any range so recited.

    EXAMPLES



    [0056] Five catalysts (A, B, C, D and E) were prepared and their performance evaluated. R values were determined as described hereinabove.

    EXAMPLE 1



    [0057] Alumina was prepared by co-precipitation by runoff of aqueous streams of aluminum sulfate and sodium aluminate followed by filtration/washing and drying step. The dried powder contains 100% wt% Al2O (dry basis). The powder contained 32 % water.

    [0058] The alumina powder was peptized by mixing nitric acid/acetic acid and water to form a slurry containing 25% solids. The slurry was formed into spheres on the dripping column. Wet spheres were dried at 120°C and calcined at 1080°C for 1 hour in a muffle to give calcined spheres having a R value of 0.47.

    [0059] The calcined spheres were impregnated with Mo-Ni-P aqueous impregnation solution by incipient wetness technique and then dried and calcined at 510°C to decompose the Mo-Ni-P impregnation solution compounds. The finished catalyst, identified as Catalyst A, had a nominal active metal content of 3 wt% Mo, 1 wt% Ni, 1 wt% P. Catalyst properties were as identified in Table 1 below.

    EXAMPLE 2



    [0060] Aqueous streams of aluminum sulfate (7% Al2O3) and titanium sulfate (9% TiO2) were mixed in a 9:1 ratio to form an aluminum-titanium sulfate mixture. Water (624.6 litres-165 gallons) was added to the strike tank and heated to 57°C and the contents of the strike tank were maintained at this temperature for the remainder of the process. 18.9 litres (5 gallons) of aluminum-titanium sulfate mixture was added to the strike tank prior to precipitation process. After that the aluminum sulfate and titanium sulfate mixture and sodium aluminate were concomitantly added to the strike tank. The aluminum sulfate and sodium sulfate mixture were added at constant flow and the sodium aluminate flow rate was varied to maintain a constant pH of 8.4 in the strike tank. The aluminum-titanium sulfate mixture flow was stopped 50 minutes after the start of the simultaneous aluminum-titanium sulfate mixture and sodium aluminate flows. At this time the concentration of precipitated titania-alumina solids was about 6 wt%. The sodium aluminate flow was reduced to 2.65 litres (0.7 gallons) per minute and turned off when a pH of 9.2 was obtained in the strike tank. The precipitated titania alumina mix was then filtered and washed on a filter belt to remove residual sodium sulfate. The resulting filter cake was then spray dried. Dried titania alumina powder was then used to make a catalyst support.

    [0061] The dried titania alumina powder contains 3.5 wt. % TiO2 (dry basis) and the balance (dry basis) is alumina (Al2O3). The powder contained 26 % water. The titania-alumina powder was peptized by mixing nitric acid/acetic acid and water to form a slurry containing 24% solids. The slurry was formed into spheres on a dripping column. Wet spheres were dried at 120°C and calcined at a temperature of 1010°C for 1 hour in a muffle to form spheres having a R value of 0.69.

    [0062] The calcined spheres were impregnated with Mo-Ni-P aqueous impregnation solution by incipient wetness technique and then dried and calcined at 510°C to decompose the Mo-Ni-P impregnation solution compounds. The finished catalyst, identified as Catalyst B, had a nominal active metal content of 3 wt% Mo, 1 wt% Ni and 1 wt% P. Catalyst properties were as identified in Table 1 below.

    EXAMPLE 3



    [0063] Aqueous streams of aluminum sulfate (7% Al2O3) and titanium sulfate (9% TiO2) were mixed in a 9:1 ratio to form an aluminum-titanium sulfate mixture. City water (795 litres-210 gallons) was added to the strike tank and heated to 68°C and the contents of the strike tank were maintained at this temperature for the remainder of the process. Flows of aluminum-titanium sulfate mixture and sodium aluminate were then concomitantly added to the strike tank. The sodium aluminate flow rate was varied to maintain a constant pH of 7.6 in the strike tank. The aluminum-titanium sulfate mixture flow was stopped 22 minutes after the start of the simultaneous aluminum-titanium sulfate mixture and sodium aluminate flows. Sodium aluminate flow was turned off when a pH of 9.2 was obtained in the strike tank. The precipitated titania alumina mix was then filtered and washed on a filter belt to remove residual sodium and sulfate. The resulting filter cake was then spray dried. Dried titania alumina powder was then used to make catalyst support.

    [0064] The dried powder contains 3.5 wt. % TiO2 (dry basis) and the balance (dry basis) is alumina (Al2O3). The powder contained 26 % water. The titania alumina powder was peptized by mixing nitric acid/acetic acid and water to form a slurry containing 30% solids. The slurry was formed into spheres on a dripping column. Wet spheres were dried at 120°C and calcined at a temperature of 1050°C for 1 hour in a muffle to form spheres having a R value of 0.76.

    [0065] The calcined spheres were impregnated with Mo-Ni-P aqueous impregnation solution by incipient wetness technique and then dried and calcined at 510°C to decompose the Mo-Ni-P impregnation solution compounds. The finished catalyst, identified as Catalyst C, had a nominal active metal content of 3 wt% Mo, 1 wt% Ni and 1 wt% P. Catalyst properties were as identified in Table 1 below.

    EXAMPLE 4



    [0066] Aqueous streams of aluminum sulfate (7 wt% Al2O3) and titanium sulfate (9 wt% TiO2) were mixed in a 9:1 ratio to form an aluminum-titanium sulfate mixture. City water (1022 litres - 270 gallons) was added to the strike tank and heated to 66°C and the contents of the strike tank were maintained at this temperature for the remainder of the process. 15.1 litres (4 gallons) of aluminum-titanium sulfate mixture was added to the strike tank. Flows of aluminum-titanium sulfate mixture and sodium sluminate were then concomitantly added to the strike tank. The sodium aluminate flow rate was varied to maintain a constant pH of 7.6 in the strike tank. The aluminum-titanium sulfate mixture flow was stopped 22 minutes after the start of the simultaneous aluminum-titanium sulfate mixture and sodium aluminate flows. Sodium aluminate flow was turned off when a pH of 9.2 was obtained in the strike tank. The precipitated titania alumina mix was then filtered and washed on a filter belt to remove residual sodium and sulfate. The resulting filter cake was then spray dried. Dried titania alumina powder was then used to make catalyst support.

    [0067] The dried powder contains 3.5 wt. % TiO2 (dry basis) and the balance (dry basis) is alumina (Al2O3). The powder contained 26 % water. The titania alumina powder was peptized by mixing nitric acid/acetic acid and water to form a slurry containing 23% solids. The slurry was formed into spheres on a dripping column. Wet spheres were dried at 120°C and calcined at a temperature of 1057°C for 1 hour in a muffle to form spheres having a R value of 0.91.

    [0068] The calcined spheres were impregnated with Mo-Ni-P aqueous impregnation solution impregnation solution compounds. The finished catalyst, identified as Catalyst D, had a nominal active metal content of 3 wt% Mo, 1 wt% Ni and 1 wt% P. Catalyst properties were as identified in Table 1 below.
    Table 1 - Catalyst Properties of Catalysts A-D
    Catalyst ACatalyst ACatalyst BCatalyst CCatalyst D
    Titania Content, wt% 0 3.5 3.5 3.5
    SA, m2/g 96 103 94 102
    PV, cm3/g 0.79 0.90 0.83 0.96
    PSD, vol%        
    <100 Å 0.6 0.0 0.0 0.0
    100-200 Å 27.6 15.0 18.9 16.7
    200-500 Å 32.5 48.9 39.5 36.7
    >500 Å 39.6 36.3 41.4 46.6
    >1,000 Å 35.7 30.4 35.9 40.4

    EXAMPLE 5



    [0069] Titania alumina spheres were prepared as described in Example 4 above with the exception that the dried spheres were calcined at a temperature of 600°C in order to obtain a mesopore structure with smaller pore diameters. The R value of the calcined spheres was 0.15. The pore structure of Catalyst E was similar to the pore structure of a low temperature calcined desulfurization catalyst. Properties of Catalyst E are shown in Table 2 below.
    Table 2: Properties of Catalyst E
     Catalyst E
    SA, m2/g 231
    PV, cm3/g 0.71
    PSD, vol%  
    <50 Å 7.5
    50-100 Å 68.3
    100-200 Å 11.8
    200-500 Å 6.8
    >500 Å 5.5

    EXAMPLE 6



    [0070] Catalysts A, B, C, D and E were evaluated for performance in a hydrotreating process as described hereinafter. The catalyst pellets were loaded in a plug-flow reactor. The feed consisted of an atmospheric resid and hydrogen. The resid had a metal content of 362 ppm V and 71 ppm Ni and a Sulfur content of 4.6 wt%. The reactor temperature was maintained at different levels between 395-375°C, and the average hourly space velocity was 0.8 L/(L.h). Comparative results for metal and sulfur conversion are given in Table 3 below. The results are given at three different time-on-stream values (210, 402, and 738 hours) and the corresponding reactor temperatures.
    Table 3: Catalyst Testing Results
     Vanadium conversion, %Nickel conversion, %Sulfur conversion, %MCR conversion, %
     at 210 h, 395°Cat 402 h, 390°Cat 737 h, 385°Cat 210 h, 395°Cat 402 h, 390°Cat 737 h, 385°Cat 210 h, 395°Cat 402 h, 390°Cat 737 h, 385°Cat 210 h, 395°Cat 402 h, 390°Cat 737 h, 385°C
    Catalyst A 68.5 60.4 51.2 52.4 46.3 39.2 45.2 40.8 40.1 27.8 25.5 23.8
    Catalyst B 71.2 63.2 53.1 55.8 49.4 41.0 58.8 52.3 41.1 35.9 32.0 26.2
    Catalyst C 72.8 67.9 54.8 54.8 49.9 38.7 51.8 47.2 35.8 32.5 30.8 24.3
    Catalyst D 74.6 67.5 58.8 57.9 52.2 45.8 48.7 43.0 37.1 33.6 30.5 26.8
    Catalyst E 66.3 55.8 41.0 48.4 40.3 28.7 46.2 45.3 31.5 29.4 28.3 20.6


    [0071] As shown in the Table 3 above, Catalysts B, C and D, being promoted with titania and having a pore structure according to the present invention, exhibited enhanced performance for metal, sulfur and MCR conversion when compared to the performance of Catalyst A (alumina only). While Catalyst E exhibited an initial performance comparable to Catalyst A, the performance of Catalyst E for conversion of metals, sulfur and MCR unexpectedly declined over time evidencing a lack of stability.


    Claims

    1. A process for preparing a spheroidal support material for supporting catalytically active metals suitable for the hydrodemetallation of heavy hydrocarbon fractions containing metals under hydrotreating conditions, which process comprises:

    (a) forming a co-precipitated titania alumina containing 5 wt % or less titania, based on the total weight of the titania alumina;

    (b) peptizing the titania alumina to form an aqueous slurry containing from 20% to 35% solids and having a sufficient viscosity to form droplets;

    (c) dropping the slurry in a dripping column to form spheroidal particles;

    (d) calcining the spheroidal particles at a temperature ranging from 960°C to 1100°C to obtain a spheroidal titania alumina support having a total pore volume in the range of from 0.7 to 1.2 cc/g, and a pore volume distribution such that greater than 40% of the total pore volume having pores in a diameter larger than 200 Å, 30% or greater of the total pore volume having pores in the range of 200 Å to 500 Å and, greater than 10% of the total pore volume having pores with a diameter above 1000 Å;

    wherein the pore volume and pore size distribution properties of the support are determined by mercury penetration porosimetry using a mercury porosimeter at a pressure range from atmospheric pressure to 4,000 bar, with a contact angle, θ = 140° and a mercury surface tension of 0.47 N/m at 25°C.
     
    2. The process of claim 1 wherein the titania alumina of the support comprises at least 90 wt% alumina having an R value of from 0.4 to 1.7, wherein R is the ratio between the integrated intensity of the X-ray diffraction peak at 2Θ = 32° and the integrated intensity of the X-ray diffraction peak at 2Θ = 46°.
     
    3. The process of claim 1 wherein the co-precipitated titania alumina of step (a) is formed by co-precipitating aqueous solutions of aluminum sulfate, sodium aluminate and an amount of titanyl sulfate sufficient to provide 5 wt% or less titania in the co-precipitated titania alumina.
     
    4. The process of claim 1 wherein the spheroidal shaped particles are calcined at a temperature ranging from 980°C to 1060°C for 1 hour to 3 hours.
     
    5. The process of claim 1 wherein the titania alumina containing powder of step (a) has titania amount of 2.5 to 4.0 wt% titania, based on the total weight of the titania alumina.
     
    6. A spheroidal catalyst support comprising co-precipitated titania alumina having 5 wt% or less titania based on the total titania alumina, said support having a total pore volume in the range of 0.7 to 1.2 cc/g, and a pore volume distribution such that greater than 40% of the total pore volume have pores in a diameter larger than 200 Å, 30 % or greater of the total pore volume have pores in the range of 200 Å to 500 Å and, greater than 10% of the total pore volume have pores with a diameter above 1000 Å, wherein the pore volume and pore size distribution properties of the support are determined by mercury penetration porosimetry using a mercury porosimeter at a pressure range from atmospheric pressure to 4,000 bar, with a contact angle, θ = 140° and a mercury surface tension of 0.47 N/m at 25°C.
     
    7. The support of claim 6 wherein titania is present in the co-precipitated titania alumina in an amount ranging from 2.5 to 4.0 wt% titania, based on the total weight of the titania alumina.
     
    8. The support of claim 6 wherein the support comprises at least 90 wt% titania alumina having an alumina R value of from 0.4 to 1.7, wherein R is the ratio between the integrated intensity of the X-ray diffraction peak at 2Θ = 32° and the integrated intensity of the X-ray diffraction peak at 2Θ = 46°.
     
    9. The support of claim 6 or 8 wherein pore volume distribution of the support is selected from the group consisting of: from 50% to 90% of the total pore volume is in pores having a diameter larger than 200 Å; from 30% to 80% of the total pore volume is in pores having a diameter from 200 to 500 Å; greater than 15 % of the total pore volume of the support have pores in a diameter above 1000 Å; and combinations thereof; wherein the pore volume and pore size distribution properties of the support are determined by mercury penetration porosimetry using a mercury porosimeter at a pressure range from atmospheric pressure to 4,000 bar, with a contact angle, θ = 140° and a mercury surface tension of 0.47 N/m at 25°C.
     
    10. A catalyst for hydrodemetallation of heavy hydrocarbons, comprising:

    (a) a spheroidal support comprising co-precipitated titania alumina having 5 wt% or less titania, based on the total weight of titania alumina; and

    (b) at least one catalytic agent comprising a metal selected from the group consisting of a metal of Group 6 of The Periodic Table, a metal of Group 9 of The Periodic Table, a metal of Group 10 of The Periodic Table, and combinations thereof, and optionally phosphorous;

    wherein the support has a total pore volume in the range of from 0.7 to 1.2 cubic centimeters per gram, with greater than 40% of the total pore volume having pores in a diameter larger than 200 Å, 30% or greater of the total pore volume having pores in the range of 200 Å to 500 Å and, greater than 10% of the total pore volume having pores with a diameter above 1000 Å;
    wherein the pore volume and pore size distribution properties of the support are determined by mercury penetration porosimetry using a mercury porosimeter at a pressure range from atmospheric pressure to 4,000 bar, with a contact angle, θ = 140° and a mercury surface tension of 0.47 N/m at 25°C.
     
    11. The catalyst of claim 10 wherein the support comprises titania alumina having at least 90 wt% alumina having an R value of from 0.4 to 1.7, wherein R is the ratio between the integrated intensity of the X-ray diffraction peak at 2Θ = 32° and the integrated intensity of the X-ray diffraction peak at 2Θ = 46°.
     
    12. The catalyst of claim 10 wherein said at least one catalytic agent is selected from the group consisting of cobalt, nickel, molybdenum, and a combination thereof.
     
    13. A method for preparing a catalyst having high activity and stability for hydrodemetallation of metal-containing heavy hydrocarbon fractions in a hydrotreating process, which method comprises impregnating a porous spheroidal support with an aqueous solution containing at least one catalytic agent or precursor comprising at least one metal selected from the group consisting of: a metal of Group 6 of The Periodic Table; a metal of Group 9 of The Periodic Table; a metal of Group 10 of The Periodic Table; and combinations thereof; and optionally phosphorous, said agents being thermally decomposable to the metal oxides, and thereafter drying and calcining the resulting impregnated support to provide a supported catalyst, said support having been prepared by the process of claim 1.
     
    14. A process for hydrotreating a heavy hydrocarbon fraction containing metals to reduce the content of, or remove, said metals, which process comprises contacting said heavy hydrocarbon fraction with a catalyst of claim 10 under hydrotreating process conditions comprising a reaction temperature ranging from 300°C to 450°C, a hydrogen pressure of 25 to 200 bar, a H2:oil ratio ranging from 150 to 1500 N1/1, and a space velocity from 0.1 to 5 h-1.
     
    15. The process of claim 14 wherein the heavy hydrocarbon fraction contains a metal selected from the group consisting of nickel, vanadium and combinations thereof.
     
    16. A process for reducing the microcarbon residue (MCR) content of a heavy hydrocarbon feed, which process comprises contacting said heavy hydrocarbon fraction with a catalyst of claim 10 under hydrotreating process conditions comprising a reaction temperature ranging from 300°C to 450°C, a hydrogen pressure of 25 to 200 bar, a H2:oil ratio ranging from 150 to 1500 N1/1, and a space velocity from 0.1 to 5 h-1 and providing a hydrotreated hydrocarbon fraction having a reduced MCR content as compared to the MCR content of the heavy hydrocarbon feed.
     
    17. The process of claim 14 or 16 wherein the heavy hydrocarbon feed further contains sulfur, and wherein the hydrotreated hydrocarbon fraction has a reduced content of sulfur.
     


    Ansprüche

    1. Verfahren zum Herstellen eines kugelförmigen Trägermaterials zum Tragen katalytisch aktiver Metalle, das für die Wasserstoffdemetallierung von Fraktionen von schwerem Kohlenwasserstoff, die Metalle enthalten, unter Wasserstoffbehandlungsbedingungen geeignet ist, wobei das Verfahren umfasst:

    (a) Bilden eines gemeinsam gefällten Titandioxid-Aluminiumoxids, das zu 5 Gew.-% oder weniger Titandioxid enthält, bezogen auf das Gesamtgewicht des Titandioxid-Aluminiumoxids;

    (b) Peptisieren des Titandioxid-Aluminiumoxids, um eine wässrige Aufschlämmung zu bilden, die zu von 20 % bis 35 % Feststoffe enthält und eine ausreichende Viskosität aufweist, um Tröpfchen zu bilden;

    (c) Abtropfen der Aufschlämmung in einer Tropfsäule, um kugelförmige Teilchen zu bilden;

    (d) Kalzinieren der kugelförmigen Teilchen bei einer Temperatur, die von 960 °C bis 1100 °C reicht, um einen kugelförmigen Titandioxid-AluminiumoxidTräger zu erhalten, der ein Gesamtporenvolumen in dem Bereich von 0,7 bis 1,2 cm3/g und eine solche Porenvolumenverteilung aufweist, dass mehr als 40 % des Gesamtporenvolumens Poren mit einem Durchmesser von mehr als 200 Å aufweisen, 30 % oder mehr des Gesamtporenvolumens Poren in dem Bereich von 200 Å bis 500 Å aufweisen und mehr als 10 % des Gesamtporenvolumens Poren mit einem Durchmesser von über 1000 Å aufweisen;

    wobei die Porenvolumen- und Porengrößenverteilungseigenschaften des Trägers durch Quecksilbereindringporosimetrie unter Verwendung eines Quecksilberporosimeters in einem Druckbereich von Atmosphärendruck bis 4.000 bar mit einem Kontaktwinkel θ = 140 ° und einer Quecksilberoberflächenspannung von 0,47 N/m bei 25 °C bestimmt werden.
     
    2. Verfahren nach Anspruch 1, wobei das Titandioxid-Aluminiumoxid des Trägers zu mindestens 90 Gew.-% Aluminiumoxid umfasst, das einen R-Wert von 0,4 bis 1,7 aufweist, wobei R das Verhältnis zwischen der integrierten Intensität der Röntgenstrahlenbrechungsspitze bei 2Θ = 32 ° und der integrierten Intensität der Röntgenstrahlenbrechungsspitze bei 2Θ = 46 ° ist.
     
    3. Verfahren nach Anspruch 1, wobei das gemeinsam gefällte Titandioxid-Aluminiumoxid von Schritt (a) durch gemeinsames Fällen von wässrigen Lösungen aus Aluminiumsulfat, Natriumaluminat und einer Menge an Titanylsulfat gebildet wird, die ausreichend ist, um in dem gemeinsam gefällten Titandioxid-Aluminiumoxid 5 Gew.-% oder weniger Titandioxid bereitzustellen.
     
    4. Verfahren nach Anspruch 1, wobei die kugelförmigen Teilchen bei einer Temperatur, die von 980 °C bis 1060 °C reicht, 1 bis 3 Stunden kalziniert werden.
     
    5. Verfahren nach Anspruch 1, wobei das Titandioxid-Aluminiumoxid enthaltende Pulver von Schritt (a) Titandioxidmenge von 2,5 bis 4,0 Gew.-% Titandioxid bezogen auf das Gesamtgewicht des Titandioxid-Aluminiumoxids aufweist.
     
    6. Kugelförmiger Katalysatorträger, umfassend gemeinsam gefälltes Titandioxid-Aluminiumoxid, das zu 5 Gew.-% oder weniger Titandioxid, bezogen auf das gesamte Titandioxid-Aluminiumoxid, aufweist, wobei der Träger ein Gesamtporenvolumen in dem Bereich von 0,7 bis 1,2 cm3/g und eine solche Porenvolumenverteilung aufweist, dass mehr als 40 % des Gesamtporenvolumens Poren mit einem Durchmesser von mehr als 200 Å aufweisen, 30 % oder mehr des Gesamtporenvolumens Poren in dem Bereich von 200 Å bis 500 Å aufweisen und mehr als 10 % des Gesamtporenvolumens Poren mit einem Durchmesser von über 1000 Å aufweisen, wobei die Porenvolumen- und Porengrößenverteilungseigenschaften des Trägers durch Quecksilbereindringporosimetrie unter Verwendung eines Quecksilberporosimeters in einem Druckbereich von Atmosphärendruck bis 4.000 bar mit einem Kontaktwinkel θ = 140 ° und einer Quecksilberoberflächenspannung von 0,47 N/m bei 25 °C bestimmt werden.
     
    7. Träger nach Anspruch 6, wobei Titandioxid in dem gemeinsam gefällten Titandioxid-Aluminiumoxid in einer Menge vorliegt, die von 2,5 bis 4,0 Gew.-% Titandioxid, bezogen auf das Gesamtgewicht des Titandioxid-Aluminiumoxids, reicht.
     
    8. Träger nach Anspruch 6, wobei der Träger zu mindestens 90 Gew.-% Titandioxid-Aluminiumoxid umfasst, das einen Aluminiumoxid-R-Wert von 0,4 bis 1,7 aufweist, wobei R das Verhältnis zwischen der integrierten Intensität der Röntgenstrahlenbrechungsspitze bei 2Θ = 32 ° und der integrierten Intensität der Röntgenstrahlenbrechungsspitze bei 2Θ = 46 ° ist.
     
    9. Träger nach Anspruch 6 oder 8, wobei eine Porenvolumenverteilung des Trägers aus der Gruppe ausgewählt ist, bestehend aus: von 50 % bis 90 % des Gesamtporenvolumens bestehen aus Poren, die einen Durchmesser von mehr als 200 Å aufweisen; von 30 % bis 80 % des Gesamtporenvolumens bestehen aus Poren, die einen Durchmesser von 200 bis 500 Å aufweisen; mehr als 15 % des Gesamtporenvolumens des Trägers weisen Poren mit einem Durchmesser von über 1000 Å auf; und Kombinationen davon; wobei die Porenvolumen- und Porengrößenverteilungseigenschaften des Trägers durch Quecksilbereindringporosimetrie unter Verwendung eines Quecksilberporosimeters in einem Druckbereich von einem Atmosphärendruck bis 4.000 bar mit einem Kontaktwinkel θ = 140 ° und einer Quecksilberoberflächenspannung von 0,47 N/m bei 25 °C bestimmt werden.
     
    10. Katalysator zur Wasserstoffdemetallierung von schweren Kohlenwasserstoffen, umfassend:

    (a) einen kugelförmigen Träger, der gemeinsam gefälltes Titandioxid-Aluminiumoxid umfasst, das zu 5 Gew.-% oder weniger Titandioxid, bezogen auf das Gesamtgewicht des Titandioxid-Aluminiumoxids, aufweist; und

    (b) mindestens ein Katalysatormittel, das ein Metall umfasst, das aus der Gruppe ausgewählt ist, bestehend aus einem Metall aus Gruppe 6 des Periodensystems, einem Metall aus Gruppe 9 des Periodensystems, einem Metall aus Gruppe 10 des Periodensystems und Kombinationen davon, und gegebenenfalls Phosphor;

    wobei der Träger ein Gesamtporenvolumen in dem Bereich von 0,7 bis 1,2 Kubikzentimeter pro Gramm aufweist, wobei mehr als 40 % des Gesamtporenvolumens Poren mit einem Durchmesser von mehr als 200 Å aufweisen, 30 % oder mehr des Gesamtporenvolumens Poren in dem Bereich von 200 Å bis 500 Å aufweisen und mehr als 10 % des Gesamtporenvolumens Poren mit einem Durchmesser von über 1000 Å aufweisen;
    wobei die Porenvolumen- und Porengrößenverteilungseigenschaften des Trägers durch Quecksilbereindringporosimetrie unter Verwendung eines Quecksilberporosimeters in einem Druckbereich von einem Atmosphärendruck bis 4.000 bar mit einem Kontaktwinkel θ = 140 ° und einer Quecksilberoberflächenspannung von 0,47 N/m bei 25 °C bestimmt werden.
     
    11. Katalysator nach Anspruch 10, wobei der Träger Titandioxid-Aluminiumoxid umfasst, das zu mindestens 90 Gew.-% Aluminiumoxid aufweist, das einen R-Wert von 0,4 bis 1,7 aufweist, wobei R das Verhältnis zwischen der integrierten Intensität der Röntgenstrahlenbrechungsspitze bei 2Θ = 32 ° und der integrierten Intensität der Röntgenstrahlenbrechungsspitze bei 2Θ = 46 ° ist.
     
    12. Katalysator nach Anspruch 10, wobei das mindestens eine Katalysatormittel aus der Gruppe ausgewählt ist, bestehend aus Kobalt, Nickel, Molybdän und einer Kombination davon.
     
    13. Verfahren zum Herstellen eines Katalysators, der eine hohe Aktivität und Stabilität zur Wasserstoffdemetallierung von Metall enthaltenden Fraktionen von schwerem Kohlenwasserstoff in einem Wasserstoffbehandlungsverfahren aufweist, wobei das Verfahren ein Imprägnieren eines porösen kugelförmigen Trägers mit einer wässrigen Lösung umfasst, die mindestens ein Katalysatormittel oder einen Vorläufer enthält, das/der mindestens ein Metall umfasst, das aus der Gruppe ausgewählt ist, bestehend aus: einem Metall aus Gruppe 6 des Periodensystems; einem Metall aus Gruppe 9 des Periodensystems; einem Metall aus Gruppe 10 des Periodensystems; und Kombinationen davon; und gegebenenfalls Phosphor, wobei die Mittel thermisch zu den Metalloxiden zersetzbar sind, und danach Trocknen und Kalzinieren des sich ergebenden imprägnierten Trägers, um einen getragenen Katalysator bereitzustellen, wobei der Träger gemäß dem Verfahren nach Anspruch 1 hergestellt wurde.
     
    14. Verfahren zum Wasserstoffbehandeln einer Fraktion von schwerem Kohlenwasserstoff, die Metalle enthält, um den Gehalt der Metalle zu reduzieren oder diese zu entfernen, wobei das Verfahren ein Inkontaktbringen der Fraktion von schwerem Kohlenwasserstoff mit einem Katalysator nach Anspruch 10 unter Wasserstoffbehandlungsverfahrensbedingungen umfasst, die eine Reaktionstemperatur, die von 300 °C bis 450 °C reicht, einen Wasserstoffdruck von 25 bis 200 bar, ein H2-Öl-Verhältnis, das von 150 bis 1500 N1/1 reicht, und eine Raumgeschwindigkeit von 0,1 bis 5 h-1 umfassen.
     
    15. Verfahren nach Anspruch 14, wobei die Fraktion von schwerem Kohlenwasserstoff ein Metall enthält, das aus der Gruppe ausgewählt ist, bestehend aus Nickel, Vanadium und Kombinationen davon.
     
    16. Verfahren zum Reduzieren des Gehalts an Mikrokohlenstoffrückstand (MCR) einer Zufuhr von schwerem Kohlenwasserstoff, wobei das Verfahren ein Inkontaktbringen der Fraktion von schwerem Kohlenwasserstoff mit einem Katalysator nach Anspruch 10 unter Wasserstoffbehandlungsverfahrensbedingungen, die eine Reaktionstemperatur, die von 300 °C bis 450 °C reicht, einen Wasserstoffdruck von 25 bis 200 bar, ein H2-Öl-Verhältnis, das von 150 bis 1500 N1/1 reicht, und eine Raumgeschwindigkeit von 0,1 bis 5 h-1 umfasst, und ein Bereitstellen einer wasserstoffbehandelten Kohlenwasserstofffraktion umfasst, die einen im Vergleich zu dem MCR-Gehalt der Zufuhr von schwerem Kohlenwasserstoff reduzierten MCR-Gehalt aufweist.
     
    17. Verfahren nach Anspruch 14 oder 16, wobei die Zufuhr von schwerem Kohlenwasserstoff ferner Schwefel enthält und wobei die wasserstoffbehandelte Kohlenwasserstofffraktion einen reduzierten Gehalt an Schwefel aufweist.
     


    Revendications

    1. Procédé de préparation d'un matériau de support sphéroïdal pour supporter des métaux catalytiquement actifs appropriés pour l'hydrodémétallisation de fractions d'hydrocarbures lourds contenant des métaux dans des conditions d'hydrotraitement, lequel procédé comprend :

    (a) la formation de dioxyde de titane-alumine co-précipité contenant 5 % en poids ou moins de dioxyde de titane, sur la base du poids total du dioxyde de titane-alumine ;

    (b) la peptisation du dioxyde de titane-alumine pour former une bouillie aqueuse contenant de 20 % à 35 % de solides et ayant une viscosité suffisante pour former des gouttelettes ;

    (c) l'écoulement de la bouillie dans une colonne d'égouttement pour former des particules sphéroïdales ;

    (d) la calcination des particules sphéroïdales à une température allant de 960 °C à 1100 °C pour obtenir un support de dioxyde de titane-alumine sphéroïdal ayant un volume total de pores dans la plage allant de 0,7 à 1,2 cm3/g, et une distribution en volume des pores de telle sorte que plus de 40 % du volume total de pores ont des pores dans un diamètre supérieur à 200 Å, 30 % ou plus du volume total de pores ont des pores dans la plage de 200 Å à 500 Å et, plus de 10 % du volume total de pores ont des pores avec un diamètre supérieur à 1000 Å ;

    dans lequel les propriétés de volume de pores et de distribution en volume des pores du support sont déterminées par porosimétrie par pénétration de mercure en utilisant un porosimètre au mercure à une plage de pression allant de la pression atmosphérique à 4000 bar, avec un angle de contact, θ = 140° et une tension superficielle de mercure de 0,47 N/m à 25 °C.
     
    2. Procédé selon la revendication 1, dans lequel le dioxyde de titane-alumine du support comprend au moins 90 % en poids d'alumine ayant une valeur R allant de 0,4 à 1,7, dans lequel R est le rapport entre l'intensité intégrée du pic de diffraction des rayons X à 2Θ = 32° et l'intensité intégrée du pic de diffraction des rayons X à 2Θ = 46°.
     
    3. Procédé selon la revendication 1, dans lequel le dioxyde de titane-alumine co-précipité de l'étape (a) est formé par co-précipitation de solutions aqueuses de sulfate d'aluminium, d'aluminate de sodium et d'une quantité de sulfate de titanyle suffisante pour fournir 5 % en poids ou moins de dioxyde de titane dans le dioxyde de titane-alumine co-précipité.
     
    4. Procédé selon la revendication 1, dans lequel les particules profilées sphéroïdales sont calcinées à une température allant de 980 °C à 1060 °C pendant 1 heure à 3 heures.
     
    5. Procédé selon la revendication 1, dans lequel la poudre contenant du dioxyde de titane-alumine de l'étape (a) a une quantité de dioxyde de titane de 2,5 à 4,0 % en poids de dioxyde de titane, sur la base du poids total du dioxyde de titane-alumine.
     
    6. Support de catalyseur sphéroïdal comprenant du dioxyde de titane-alumine co-précipité ayant 5 % en poids ou moins de dioxyde de titane sur la base du dioxyde de titane-alumine total, ledit support ayant un volume total de pores dans la plage de 0,7 à 1,2 cm3/g, et une distribution en volume des pores de telle sorte que plus de 40 % du volume total de pores ont des pores dans un diamètre supérieur à 200 Å, 30 % ou plus du volume total de pores ont des pores dans la plage de 200 Å à 500 Å et, plus de 10 % du volume total de pores ont des pores avec un diamètre supérieur à 1000 Å, dans lequel les propriétés de volume de pores et de distribution en volume des pores du support sont déterminées par porosimétrie par pénétration de mercure en utilisant un porosimètre au mercure à une plage de pression allant de la pression atmosphérique à 4000 bar, avec un angle de contact, θ = 140° et une tension superficielle de mercure de 0,47 N/m à 25 °C.
     
    7. Support selon la revendication 6 dans laquelle du dioxyde de titane est présent dans le dioxyde de titane-alumine co-précipité en une quantité allant de 2,5 à 4,0 % en poids de dioxyde de titane, sur la base du poids total du dioxyde de titane-alumine.
     
    8. Support selon la revendication 6 dans lequel le support comprend au moins 90 % en poids de dioxyde de titane-alumine ayant une valeur R d'alumine allant de 0,4 à 1,7, dans lequel R est le rapport entre l'intensité intégrée du pic de diffraction des rayons X à 2Θ = 32° et l'intensité intégrée du pic de diffraction des rayons X à 2Θ = 46°.
     
    9. Support selon la revendication 6 ou 8 dans lequel la distribution en volume des pores du support est choisie dans le groupe constitué de : de 50 % à 90 % du volume total de pores est dans des pores ayant un diamètre supérieur à 200 Å ; de 30 % à 80 % du volume total de pores est dans des pores ayant un diamètre allant de 200 à 500 Å ; plus de 15 % du volume total de pores du support ont des pores dans un diamètre supérieur à 1000 Å ; et des combinaisons de ceux-ci ; dans lequel les propriétés de volume de pores et de distribution en volume des pores du support sont déterminées par porosimétrie par pénétration de mercure en utilisant un porosimètre au mercure à une plage de pression allant de la pression atmosphérique à 4000 bar, avec un angle de contact, θ = 140° et une tension superficielle de mercure de 0,47 N/m à 25 °C.
     
    10. Catalyseur pour hydrodémétallisation d'hydrocarbures lourds, comprenant :

    (a) un support sphéroïdal comprenant du dioxyde de titane-alumine co-précipité ayant 5 % en poids ou moins de dioxyde de titane, sur la base du poids total de dioxyde de titane-alumine ; et

    (b) au moins un agent catalytique comprenant un métal choisi dans le groupe constitué d'un métal du Groupe 6 du Tableau périodique, un métal du Groupe 9 du Tableau périodique, un métal du Groupe 10 du Tableau périodique, et des combinaisons de ceux-ci, et éventuellement du phosphore ;

    dans lequel le support a un volume total de pores dans la plage allant de 0,7 à 1,2 centimètre cube par gramme, avec plus de 40 % du volume total de pores ayant des pores dans un diamètre supérieur à 200 Å, 30 % ou plus du volume total de pores ayant des pores dans la plage de 200 Å à 500 Å et, plus de 10 % du volume total de pores ayant des pores avec un diamètre supérieur à 1000 Å ;
    dans lequel les propriétés de volume de pores et de distribution en volume des pores du support sont déterminées par porosimétrie par pénétration de mercure en utilisant un porosimètre au mercure à une plage de pression allant de la pression atmosphérique à 4000 bar, avec un angle de contact, θ = 140° et une tension superficielle de mercure de 0,47 N/m à 25 °C.
     
    11. Catalyseur selon la revendication 10 dans lequel le support comprend du dioxyde de titane-alumine ayant au moins 90 % en poids d'alumine ayant une valeur R allant de 0,4 à 1,7, dans lequel R est le rapport entre l'intensité intégrée du pic de diffraction des rayons X à 2Θ = 32° et l'intensité intégrée du pic de diffraction des rayons X à 2Θ = 46°.
     
    12. Catalyseur selon la revendication 10 dans lequel ledit au moins un agent catalytique est choisi dans le groupe constitué de cobalt, nickel, molybdène, et une combinaison de ceux-ci.
     
    13. Procédé de préparation d'un catalyseur ayant une activité et une stabilité élevées pour l'hydrodémétallisation de fractions d'hydrocarbures lourds contenant du métal dans un procédé d'hydrotraitement, lequel procédé comprend l'imprégnation d'un support sphéroïdal poreux avec une solution aqueuse contenant au moins un agent catalytique ou précurseur comprenant au moins un métal choisi dans le groupe constitué de : un métal du Groupe 6 du Tableau périodique ; un métal du Groupe 9 du Tableau périodique ; un métal du Groupe 10 du Tableau périodique ; et des combinaisons de ceux-ci ; et éventuellement du phosphore, lesdits agents pouvant être thermiquement décomposés en les oxydes métalliques, et par la suite le séchage et la calcination du support imprégné résultant pour fournir un catalyseur supporté, ledit support ayant été préparé par le procédé selon la revendication 1.
     
    14. Procédé d'hydrotraitement d'une fraction d'hydrocarbures lourds contenant des métaux pour réduire la teneur en, ou éliminer, lesdits métaux, lequel procédé comprend la mise en contact de ladite fraction d'hydrocarbures lourds avec un catalyseur selon la revendication 10 dans des conditions de procédé d'hydrotraitement comprenant une température de réaction allant de 300 °C à 450 °C, une pression d'hydrogène de 25 à 200 bar, un rapport H2:huile allant de 150 à 1500 Nl/l, et une vitesse spatiale allant de 0,1 à 5 h-1.
     
    15. Procédé selon la revendication 14 dans lequel la fraction d'hydrocarbures lourds contient un métal choisi dans le groupe constitué de nickel, vanadium et des combinaisons de ceux-ci.
     
    16. Procédé pour réduire la teneur en résidus de microcarbone (MCR) d'une alimentation d'hydrocarbures lourds, lequel procédé comprend la mise en contact de ladite fraction d'hydrocarbures lourds avec un catalyseur selon la revendication 10 dans des conditions de procédé d'hydrotraitement comprenant une température de réaction allant de 300 °C à 450 °C, une pression d'hydrogène de 25 à 200 bar, un rapport H2:huile allant de 150 à 1500 Nl/l, et une vitesse spatiale allant de 0,1 à 5 h-1 et la fourniture d'une fraction d'hydrocarbures hydrotraitée ayant une teneur réduite en MCR par comparaison avec la teneur en MCR de l'alimentation d'hydrocarbures lourds.
     
    17. Procédé selon la revendication 14 ou 16 dans lequel l'alimentation d'hydrocarbures lourds contient en outre du soufre, et dans lequel la fraction d'hydrocarbures hydrotraitée a une teneur réduite en soufre.
     






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