CN103028443B - Porous support, preparation method and application thereof, catalyst, and hydrocracking method - Google Patents

Porous support, preparation method and application thereof, catalyst, and hydrocracking method Download PDF

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CN103028443B
CN103028443B CN201110300530.4A CN201110300530A CN103028443B CN 103028443 B CN103028443 B CN 103028443B CN 201110300530 A CN201110300530 A CN 201110300530A CN 103028443 B CN103028443 B CN 103028443B
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porous carrier
catalyst
molecular sieve
temperature
weight
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CN103028443A (en
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董松涛
辛靖
聂红
石亚华
李大东
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Sinopec Research Institute of Petroleum Processing
China Petroleum and Chemical Corp
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Sinopec Research Institute of Petroleum Processing
China Petroleum and Chemical Corp
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Abstract

The invention provides a porous support, a preparation method and application thereof. The porous support contains heat-resisting inorganic oxides and a molecular sieve, wherein the most probable pore diameter of the molecular sieve is 1-30nm, and the pore diameter concentration ratio is 22-48. The method comprises the following steps of: mixing a precursor capable of forming the heat-resisting inorganic oxides under a roasting condition, the molecular sieve, peptizing agent and water to obtain a raw material; and feeding the raw material into an extruder for extruding, and roasting an obtained forming body to obtain the porous support, wherein the temperature of the forming body at an outlet of the extruder is 40-150 DEG C. The invention also provides a catalyst adopting the porous support as a supporter, and application thereof. The invention also provides a hydrocracking method. The porous support not only has a larger pore diameter and pore volume, but also has a higher pore diameter concentration ratio. The catalyst has high catalytic activity and middle distillate selectivity when being used for hydrocracking hydrocarbon oil.

Description

Porous carrier and its preparation method and application and catalyst and method for hydrogen cracking
Technical field
The present invention relates to a kind of porous carrier and preparation method and application, the invention still further relates to a kind of catalyst containing described porous carrier and use the method for hydrogen cracking of described catalyst.
Background technology
In recent years, in world wide crude oil heaviness and in poor quality tendency day by day obvious, meanwhile, the demand of intermediate oil and reformation, steam crack material is but constantly increased.This impels heavy distillate process technology to be developed rapidly, and catalyst is wherein the most important and crucial factor.
For mink cell focus or catalyst Molecular Cloning greatly, except requiring that catalyst has except larger aperture and enough pore volumes, also require that the pore-size distribution of catalyst mesopore concentrates (that is, aperture concentration degree is high).
Owing to being generally that active component load by having a catalytic action obtains on porous support for the catalyst of mink cell focus or macromolecular conversion, therefore preparation has larger aperture and pore volume, and the key with the catalyst of higher aperture concentration degree is to provide and has large aperture and the porous carrier with higher aperture concentration degree.
At present, the method being generally used for describing aperture concentration degree is: the pore volume calculated in given pore diameter range accounts for the percentage of total pore volume, and this percentage is higher, thinks that aperture concentration degree is also higher.But the aperture concentration degree that the method being accounted for the percentage of total pore volume by the pore volume calculated in given pore diameter range carrys out evaluation carrier is difficult to reflect exactly the pore-size distribution of carrier.
CN101757929A discloses and adopts the specific pore volume that measured by BET method to amass to the differential in aperture with in the distribution curve in aperture, and the ratio of the halfwidth at the height at peak and this peak can the aperture concentration degree of evaluate catalysts exactly.On this basis, CN101757929A also discloses a kind of hydrocracking catalyst, this catalyst contains the IVB race metal component in carrier and load hydrogenation activity composition on this carrier and the periodic table of elements, wherein, the most probable pore size of described carrier is 6 ~ 14nm, and aperture concentration degree is more than 7.Although the aperture concentration degree that CN101757929A discloses described carrier can be more than 7, from embodiment disclosed in CN101757929A, the aperture concentration degree of carrier is up to 21.4, needs to improve further.
To sum up, how to obtain have high catalytic activity and intermediate oil optionally hydrogenation catalyst remain a technical problem urgently to be resolved hurrily.
Summary of the invention
The object of the invention is to overcome prior art above shortcomings, provide a kind of and there is high catalytic activity and intermediate oil optionally hydrogenation catalyst.
The present inventor finds in practice process, improve the aperture concentration degree of carrier can significantly improve the catalytic activity with the catalyst of hydrogenation that obtained by this carrier and intermediate oil selective, but adopt the method for prior art can not obtain the carrier with higher aperture concentration degree (such as: aperture concentration degree is more than 22).Thus, the present inventor is on the basis of CN101757929A, carry out more intensive research, find: preparing formed body with extruder by extrusion molding, thus when obtaining porous carrier, the temperature of described formed body in the exit of extruder is made to be 40 ~ 150 DEG C, can obtain and there is larger aperture and aperture concentration degree is the carrier of more than 22, the catalyst with hydrogenation prepared by this porous carrier not only has higher catalytic activity, and it is selective to have higher intermediate oil.This completes the present invention.
A first aspect of the present invention provides a kind of porous carrier, this porous carrier contains heat-resistant inorganic oxide and molecular sieve, wherein, the most probable pore size of described porous carrier is 1 ~ 30nm, the aperture concentration degree of described porous carrier is 22 ~ 48, and described most probable pore size adopts BET method to measure, and described aperture concentration degree refers to that the dV/dr adopting BET method to measure is with in the distribution curve of varying aperture, the ratio of the halfwidth at the height at peak and this peak, dV/dr represents that specific pore volume amasss the differential to aperture.
A second aspect of the present invention provides a kind of preparation method of porous carrier, and the method comprises: by forming the mixing of the precursor of heat-resistant inorganic oxide, molecular sieve, peptizing agent and water under roasting condition, to supply raw materials; Described raw material is sent in extruder, and extrudes after kneading in described extruder, to obtain formed body; Described formed body is carried out roasting, and to obtain described porous carrier, wherein, the temperature of described formed body in the exit of described extruder is 40 ~ 150 DEG C.
A third aspect of the present invention provides a kind of porous carrier prepared by method of the present invention.
A fourth aspect of the present invention provides a kind of porous carrier according to the present invention as the application of carrier of catalyst with hydrogenation.
A fifth aspect of the present invention provides a kind of catalyst, and this catalyst contains porous carrier and the active component with catalytic action of load on this porous carrier, and wherein, described porous carrier is porous carrier provided by the invention.
A sixth aspect of the present invention provides the application of catalyst of the present invention in hydrocarbon oil hydrogenation cracking.
A eighth aspect of the present invention provides a kind of method for hydrogen cracking, and under the method is included in hydrocracking condition, by hydrocarbon ils and catalyst exposure, wherein, described catalyst is catalyst provided by the invention.
According to porous carrier of the present invention, not only there is larger aperture and pore volume, and there is higher aperture concentration degree, be suitable for the carrier as the catalyst with hydrogenation.Catalyst according to the invention when the hydrocracking for hydrocarbon ils, there is high catalytic activity and intermediate oil selective.
Accompanying drawing explanation
Fig. 1 is that the specific pore volume of porous carrier prepared by the embodiment of the present invention 1 amasss the differential in the aperture distribution curve schematic diagram with aperture.
Detailed description of the invention
The invention provides a kind of porous carrier, this porous carrier contains heat-resistant inorganic oxide and molecular sieve.
According to porous carrier of the present invention, the most probable pore size of described porous carrier can carry out suitable selection according to the embody rule occasion of this porous carrier.At porous carrier according to the present invention for the preparation of when having the catalyst of hydrogenation, the most probable pore size of described porous carrier can be 1 ~ 30nm, is preferably 2 ~ 20nm, is more preferably 5 ~ 10nm.
According to the present invention, the aperture concentration degree of described porous carrier can reach 22 ~ 48, even can reach 25 ~ 48 (can be such as 25 ~ 40).At porous carrier according to the present invention for the preparation of when having the catalyst of hydrogenation, the aperture concentration degree of described porous carrier is preferably 27 ~ 40.
In the present invention, term " most probable pore size " refers to: when adopting BET method to measure the pore structure of sample, and the specific pore volume of acquisition amasss differential (that is, dV/dr) to aperture with in the distribution curve in aperture, the aperture corresponding to the maximum of dV/dr.BET method is adopted to measure the pore structure of porous mass, known in those skilled in the art to obtain that specific pore volume to amass the differential in aperture with the method for the distribution curve in aperture, such as can according to " Petrochemical Engineering Analysis method " (Science Press, nineteen ninety the first edition, the volumes such as Yang Cuiding) in the RIPP 151-90 that records the method that specifies measure.
In the present invention, term " aperture concentration degree " refers to: when adopting BET method to measure the pore structure of sample, and the specific pore volume of acquisition amasss to the differential in aperture with in the distribution curve in aperture, the ratio of the halfwidth at peak height and this peak.The ratio of the halfwidth at peak height and this peak is larger, shows that the aperture intensity of porous carrier is higher.
According to the present invention, when there is multiple peak in described dV/dr is with the distribution curve of varying aperture, the ratio of the peak height at each peak and the halfwidth at this peak all should meet above-mentioned requirements.
Fig. 1 is that the specific pore volume of porous carrier prepared by the embodiment of the present invention 1 amasss the differential in the aperture distribution curve schematic diagram with aperture.In Fig. 1, abscissa is the aperture of porous carrier, and adopt logarithmic coordinates, unit is ordinate is the differential that specific pore volume amasss to aperture.In Fig. 1, M represents peak height (that is, maximum dV/dr), and N represents that (that is, on described distribution curve, ordinate is halfwidth two points between distance).When calculated hole diameters concentration degree, halfwidth and peak height all adopt identical long measure.
At porous carrier according to the present invention for the preparation of when having the catalyst of hydrogenation, the most probable pore size of described porous carrier can be 1 ~ 30nm, and aperture concentration degree can be 22 ~ 48.Preferably, the most probable pore size of described porous carrier is 2 ~ 20nm, and aperture concentration degree is 25 ~ 48 (can be such as 25 ~ 40).Be in the scope of 2 ~ 20nm at the most probable pore size of described porous carrier, and aperture concentration degree is when being in the scope of 25 ~ 48, catalyst prepared by porous carrier according to the present invention when the hydrocracking for hydrocarbon ils, higher catalytic activity can be obtained and intermediate oil selective.The catalytic activity of the catalyst finally obtained from further raising and intermediate oil optionally angle, the most probable pore size of described porous carrier is more preferably 5 ~ 10nm, and aperture concentration degree is more preferably 27 ~ 40.
According to the present invention, described porous carrier contains heat-resistant inorganic oxide and molecular sieve.
In the present invention, term " heat-resistant inorganic oxide " refers under oxygen or oxygen-containing atmosphere, and decomposition temperature is not less than the inorganic oxygen-containing compound of 300 DEG C (such as: decomposition temperature is 300 ~ 1000 DEG C).
The present invention is not particularly limited for the kind of described heat-resistant inorganic oxide, can be various heat-resistant inorganic oxide that can be shaping.The active component that load has hydrogenation is used at porous carrier according to the present invention, when having the catalyst of hydrogenation to be formed, described heat-resistant inorganic oxide can be one or more in aluminium oxide, silica, titanium oxide, magnesia, zirconia, thorium oxide and mesoporous Si-Al; Be preferably in aluminium oxide, silica and mesoporous Si-Al one or more; Be more preferably aluminium oxide and/or silica.One of the present invention preferred embodiment in, described heat-resistant inorganic oxide contains aluminium oxide.
According to the present invention, described porous carrier is also containing molecular sieve.The present invention is not particularly limited for the kind of described molecular sieve, and described molecular sieve can be zeolite molecular sieve and/or non-zeolite molecular sieve.
In the present invention, the example of described molecular sieve can be but be not limited to: ZRP molecular sieve, MCM-41 molecular sieve, erionite, ZSM-34 molecular sieve, modenite, ZSM-5 molecular sieve, ZSM-11 molecular sieve, ZSM-12 molecular sieve, ZSM-22 molecular sieve, ZSM-23 molecular screen, ZSM-35 molecular sieve, L-type molecular sieve, Y zeolite, X-type molecular sieve, ZSM-3 molecular sieve, ZSM-4 molecular sieve, ZSM-18 molecular sieve, ZSM-20 molecular sieve, ZSM-48 molecular sieve, ZSM-57 molecular sieve, faujasite, beta-molecular sieve, Ω molecular sieve, phosphate aluminium molecular sieve, HTS and SAPO are (namely, SAPO) molecular sieve.The active component that load has hydrogenation is used at porous carrier according to the present invention, when there is the catalyst of hydrogenation with preparation, described molecular sieve be preferably in ZRP molecular sieve, Y zeolite, beta-molecular sieve, modenite, ZSM-5 molecular sieve, MCM-41 molecular sieve, Ω molecular sieve, ZSM-12 molecular sieve and MCM-22 molecular sieve one or more.
According to the present invention, described porous carrier is also containing molecular sieve.Ratio between described heat-resistant inorganic oxide and molecular sieve can carry out suitable selection according to the desired use of the catalyst prepared by this porous carrier.Such as, when the hydrocracking of the catalyst prepared by described porous carrier for hydrocarbon ils, with the total amount of described porous carrier for benchmark, the content of described molecular sieve can be 0.1 ~ 60 % by weight, be preferably 0.2 ~ 50 % by weight, be more preferably 0.5 ~ 30 % by weight, more preferably 0.75 ~ 20 % by weight; The content of described heat-resistant inorganic oxide can be 40 ~ 99.9 % by weight, is preferably 50 ~ 99.8 % by weight, is more preferably 70 ~ 99.5 % by weight, more preferably 80 ~ 99.25 % by weight.According to porous carrier of the present invention, from balancing the activity with the catalyst of hydrogenation and intermediate oil optionally angle prepared by porous carrier of the present invention, with the total amount of described heat-resistant inorganic oxide and molecular sieve for benchmark, the content of described molecular sieve most preferably is 1 ~ 10 % by weight, and the content of described heat-resistant inorganic oxide most preferably is 90 ~ 99 % by weight.
According to the present invention, described porous carrier can have various shape according to concrete application scenario.Such as, described porous carrier can be spherical, bar shaped, annular, cloverleaf pattern, honeycombed and butterfly.
Present invention also offers a kind of preparation method of porous carrier, the method comprises: by forming the mixing of the precursor of heat-resistant inorganic oxide, molecular sieve, peptizing agent and water under roasting condition, to supply raw materials; Described raw material is sent in extruder, and extrudes after kneading in described extruder, to obtain formed body; Described formed body is carried out roasting, and to obtain described porous carrier, wherein, the temperature of described formed body in the exit of described extruder is 40 ~ 150 DEG C.
With extruder, raw material is being extruded, to obtain in the process of formed body, generally the cooling condition of described extruder is controlled as making the temperature of the formed body extruded be near room temperature (lower than 40 DEG C), but the present inventor finds in research process, make the temperature of formed body in the exit of described extruder be 40 ~ 150 DEG C and the most probable pore size of the porous carrier prepared by this formed body and aperture concentration degree can be made to meet previously described requirement.Preferably, the temperature of described formed body in the exit of described extruder is 60 ~ 120 DEG C.Further preferably, the temperature of described formed body in the exit of described extruder is 60 ~ 100 DEG C, can obtain higher aperture concentration degree like this.More preferably, the temperature of described formed body in the exit of described extruder is 60 ~ 98 DEG C.When the temperature of described formed body in the exit of described extruder is 60 ~ 98 DEG C, the catalyst with hydrogenation prepared by this formed body there is higher catalytic activity and intermediate oil selective.
According to the present invention, the formed body that various method can be adopted to make to be extruded by described extruder is within scope mentioned above in the temperature in the exit of this extruder.Such as: described raw material can carried out in an extruder in kneading or the process extruded, by regulating cooling condition or the heating condition of extruder fuselage and/or head, the formed body extruded by described extruder is within scope mentioned above in the temperature in the exit of this extruder.The method regulating the fuselage of extruder and/or the cooling condition of head or heating condition is known in the field, repeats no more herein.
The present inventor finds further in research process, when described raw material is sent into extruder, make the temperature of raw material (namely, described raw material is in the temperature of the porch of described extruder) be 40 ~ 100 DEG C, the most probable pore size of the porous carrier prepared can not only be made to meet previously described requirement, but also the porous carrier prepared can be made to have higher aperture concentration degree, the porous carrier simultaneously prepared also has higher mechanical strength.
Therefore, one of the present invention preferred embodiment in, the temperature of described raw material in the porch of described extruder is 40 ~ 100 DEG C.Under guaranteeing that the porous carrier prepared has the prerequisite in the aperture of expection, from the mechanical strength of porous carrier and the angle of aperture concentration degree that improve preparation further, described raw material is preferably 40 ~ 80 DEG C in the temperature of the porch of described extruder, is more preferably 50 ~ 80 DEG C.
Various method can be adopted to be 40 ~ 100 DEG C (are preferably 40 ~ 80 DEG C, are more preferably 50 ~ 80 DEG C) to make the temperature of described raw material in the porch of described extruder.
Usually, the process that described precursor, molecular sieve, peptizing agent and the water that can form heat-resistant inorganic oxide under roasting condition can be made to carry out mixing is carried out in a heated condition, the condition of described heating makes the temperature of raw material in the porch of described extruder obtained be 40 ~ 100 DEG C (are preferably 40 ~ 80 DEG C, are more preferably 50 ~ 80 DEG C).Such as: can by the mixed process of described precursor, molecular sieve, peptizing agent and the water that can form heat-resistant inorganic oxide under roasting condition, being undertaken heating by external heat source makes the temperature of the raw material of preparation be within the scope of 40 ~ 100 DEG C (preferably 40 ~ 80 DEG C, more preferably 50 ~ 80 DEG C); Also can by least one heating in described precursor, molecular sieve, peptizing agent and the water that can form heat-resistant inorganic oxide under roasting condition, then mix, make the temperature of the described raw material obtained be 40 ~ 100 DEG C and (be preferably 40 ~ 80 DEG C, be more preferably 50 ~ 80 DEG C), and be that the raw material of 40 ~ 100 DEG C (are preferably 40 ~ 80 DEG C, are more preferably 50 ~ 80 DEG C) is sent in described extruder by this temperature.
According to method of the present invention, when preparing described raw material, usually first peptizing agent is mixed with water, and then the precursor that the mixture obtained can be formed heat-resistant inorganic oxide with described under roasting condition and molecular sieve mix, thus prepare described raw material; Therefore, can by hot water be mixed with peptizing agent, obtain the mixture of heat, the precursor that again mixture of this heat can be formed heat-resistant inorganic oxide with described under roasting condition and molecular sieve mix, thus preparation temperature is 40 ~ 100 DEG C (preferably 40 ~ 80 DEG C, be more preferably 50 ~ 80 DEG C) raw material, and be that the raw material of 40 ~ 100 DEG C (are preferably 40 ~ 80 DEG C, are more preferably 50 ~ 80 DEG C) is sent in extruder by this temperature.
In addition, it can also be 40 ~ 100 DEG C (preferably 40 ~ 80 DEG C described raw material was heated to temperature by means of external heat source before feeding extruder, be more preferably 50 ~ 80 DEG C), and be that the raw material of 40 ~ 100 DEG C (are preferably 40 ~ 80 DEG C, are more preferably 50 ~ 80 DEG C) is sent in extruder by this temperature.
One of the present invention more preferred embodiment in, the temperature of described raw material in the porch of described extruder is 40 ~ 80 DEG C, and the temperature of described formed body in the exit of described extruder is 60 ~ 98 DEG C.According to porous carrier prepared by this embodiment, not only there is higher aperture concentration degree, and there is higher mechanical strength.
According to the present invention, the preparation method of described porous carrier also comprises and the precursor that can form described heat-resistant inorganic oxide under roasting condition, molecular sieve being mixed with peptizing agent and water, to be provided for the raw material extruded.
According to the present invention, the described ratio that can be formed under roasting condition between the precursor of described heat-resistant inorganic oxide and molecular sieve can carry out suitable selection according to the relative scale of the heat-resistant inorganic oxide in the porous carrier of expection and molecular sieve.Such as, when the hydrocracking of the catalyst prepared by described porous carrier for hydrocarbon ils, the content of described raw material Middle molecule sieve makes in the porous carrier prepared, with the total amount of described porous carrier for benchmark, the content of described molecular sieve can be 0.1 ~ 60 % by weight, be preferably 0.2 ~ 50 % by weight, be more preferably 0.5 ~ 30 % by weight, more preferably 0.75 ~ 20 % by weight; The content of described heat-resistant inorganic oxide can be 40 ~ 99.9 % by weight, is preferably 50 ~ 99.8 % by weight, is more preferably 70 ~ 99.5 % by weight, more preferably 80 ~ 99.25 % by weight.According to porous carrier of the present invention, from balancing the activity with the catalyst of hydrogenation and intermediate oil optionally angle prepared by porous carrier of the present invention, with the total amount of described heat-resistant inorganic oxide and molecular sieve for benchmark, the content of described molecular sieve most preferably is 1 ~ 10 % by weight, and the content of described heat-resistant inorganic oxide most preferably is 90 ~ 99 % by weight.
There is no particular limitation for the kind that method according to the present invention is sieved for described raw material Middle molecule and consumption, and described molecular sieve can be zeolite molecular sieve and/or non-zeolite molecular sieve.In the present invention, the example of described molecular sieve can be but be not limited to: ZRP molecular sieve, MCM-41 molecular sieve, erionite, ZSM-34 molecular sieve, modenite, ZSM-5 molecular sieve, ZSM-11 molecular sieve, ZSM-12 molecular sieve, ZSM-22 molecular sieve, ZSM-23 molecular screen, ZSM-35 molecular sieve, L-type molecular sieve, Y zeolite, X-type molecular sieve, ZSM-3 molecular sieve, ZSM-4 molecular sieve, ZSM-18 molecular sieve, ZSM-20 molecular sieve, ZSM-48 zeolite, ZSM-57 zeolite, faujasite, beta-molecular sieve, Ω molecular sieve, phosphate aluminium molecular sieve, HTS and SAPO are (namely, SAPO) molecular sieve.The active component that load has hydrogenation is used at porous carrier according to the present invention, when there is the catalyst of hydrogenation with preparation, described molecular sieve be preferably in ZRP molecular sieve, Y zeolite, beta-molecular sieve, modenite, ZSM-5 molecular sieve, MCM-41 molecular sieve, Ω molecular sieve, ZSM-12 molecular sieve and MCM-22 molecular sieve one or more.
The present invention is not particularly limited for the kind of described heat-resistant inorganic oxide, can carry out suitable selection according to the embody rule occasion of the porous carrier finally obtained.Such as, at the porous carrier finally obtained for the preparation of when having the catalyst of hydrogenation, described heat-resistant inorganic oxide can be one or more in aluminium oxide, silica, titanium oxide, magnesia, zirconia, thorium oxide and mesoporous Si-Al; Be preferably in aluminium oxide, silica and mesoporous Si-Al one or more; And be more preferably aluminium oxide and/or silica.One of the present invention preferred embodiment in, described heat-resistant inorganic oxide contains aluminium oxide.
The present invention is not particularly limited for the described kind that can form the precursor of heat-resistant inorganic oxide under roasting condition, can according to expection heat-resistant inorganic oxide kind carry out suitable selection, as long as this precursor can form described heat-resistant inorganic oxide under roasting condition.Usually, described precursor can be: can form the hydrous oxide of described heat-resistant inorganic oxide under roasting condition, contain the gel of the precursor that can form heat-resistant inorganic oxide under roasting condition and contain the colloidal sol of the precursor that can form heat-resistant inorganic oxide under roasting condition.In the present invention, term " hydrous oxide " refers to the hydrate of oxide.
Such as, when described heat-resistant inorganic oxide is aluminium oxide, the example of described precursor can include but not limited to: hydrated alumina (such as: aluminium hydroxide, boehmite), the gel containing hydrated alumina and the colloidal sol containing hydrated alumina.
According to method of the present invention, the average particulate diameter that the described average particulate diameter that can form the precursor of heat-resistant inorganic oxide under roasting condition can be commonly used for this area.The present inventor finds in research process: when the described average particulate diameter that can form the precursor of heat-resistant inorganic oxide under roasting condition is 30 ~ 100nm, the porous carrier prepared by method of the present invention has higher aperture concentration degree.From the angle of the aperture concentration degree of the porous carrier of raising preparation further, the described average particulate diameter that can form the precursor of heat-resistant inorganic oxide under roasting condition is preferably 30 ~ 80nm, is more preferably 30 ~ 60nm.Further preferably, the described average particulate diameter that can form the precursor of heat-resistant inorganic oxide under roasting condition is 40 ~ 60nm.
The various methods that this area can be adopted to commonly use make the described average particulate diameter that can form the precursor of heat-resistant inorganic oxide under roasting condition be within previously described scope.Such as, can by before use, the described precursor that can form heat-resistant inorganic oxide under roasting condition is carried out grinding and/or sieving, thus the described average particulate diameter that can form the precursor of heat-resistant inorganic oxide under roasting condition is within previously described scope.
In the present invention, described average particulate diameter adopts XRD method, obtained by the Scherrer formulae discovery shown in formula I,
D = 0.89 λ β HKL cos θ - - - ( I )
In formula I, D is average particulate diameter;
λ is the wavelength of X-ray;
β hKLfor the broadening degree that the high peak intensity place of diffracted ray half causes because of grain size refinement, wherein, β hKL=B-B 0;
B is the peak width at half height of actual measurement;
B 0for the broadening degree of instrument;
θ is incidence angle.
According to the present invention, at described porous carrier for the preparation of when having the catalyst of hydrogenation, described raw material is preferably containing the precursor that can form aluminium oxide under roasting condition.Such as, described raw material is preferably containing the boehmite that can form aluminium oxide under roasting condition.Although adopt various boehmite all can form aluminium oxide, and realize object of the present invention, but the present inventor finds in research process: adopt degree of crystallinity be more than 80% boehmite can under guaranteeing that the porous carrier of final preparation has the condition of large aperture and pore volume, the further aperture concentration degree improving the porous carrier obtained, and then make catalyst of the present invention have higher catalytic activity and intermediate oil selective, the mechanical strength of the porous carrier of preparation can also be improved simultaneously.
In the present invention, described degree of crystallinity is relative crystallinity, adopt " Petrochemical Engineering Analysis method " (Science Press, nineteen ninety the first edition, the Yang Cui volume such as surely) in the method that specifies in the RIPP 139-90 that records measure, wherein, the standard specimen used is the sample being numbered S87-16B, the absolute crystallinity of this standard specimen is 98.0%, can be commercially available by Research Inst. of Petroleum Processing, SINOPEC.
One of the present invention preferred embodiment in, the described precursor that can form heat-resistant inorganic oxide under roasting condition contains boehmite, and the relative crystallinity of described boehmite is more than 80%, be preferably more than 90%.From the angle of aperture concentration degree improving the porous carrier obtained further, the relative crystallinity of described boehmite is preferably 90 ~ 110%.
One of the present invention more preferred embodiment in, the described precursor that can form heat-resistant inorganic oxide under roasting condition contains boehmite, the relative crystallinity of described boehmite is more than 80%, and the average particulate diameter of described boehmite is 30 ~ 100nm.
In a kind of further preferred embodiment of the present invention, the described precursor that can form heat-resistant inorganic oxide under roasting condition contains boehmite, the relative crystallinity of described boehmite is 90 ~ 110%, and the average particulate diameter of described boehmite is 30 ~ 80nm.
In the most preferred embodiment of one of the present invention, the temperature of described raw material in the porch of described extruder is 40 ~ 80 DEG C, the temperature of described formed body in the exit of described extruder is 60 ~ 98 DEG C, and the described precursor that can form heat-resistant inorganic oxide under roasting condition contains boehmite, the relative crystallinity of described boehmite is 90 ~ 110%, and the average particulate diameter of described boehmite is 30 ~ 80nm.According to porous carrier prepared by this embodiment, there is higher aperture concentration degree and the mechanical strength of Geng Gao.
According to method of the present invention, described raw material is also containing peptizing agent.The amount of the peptizing agent in described raw material can carry out suitable selection according to the used kind that can form the precursor of heat-resistant inorganic oxide under roasting condition.Usually, with the total amount of described raw material for benchmark, the content of described peptizing agent can be 0.1 ~ 5 % by weight, is preferably 0.5 ~ 4 % by weight.
The present invention is not particularly limited for the kind of described peptizing agent, can be that the routine of this area is selected.In the present invention, the instantiation of described peptizing agent can be but be not limited to: nitric acid, hydrochloric acid, phosphoric acid, trichloroacetic acid and citric acid.
According to method of the present invention, use water as decentralized medium when preparing described raw material, the precursor that can form heat-resistant inorganic oxide by described under roasting condition and peptizing agent mix.The present invention is not particularly limited for the consumption of described water, can be that the routine of this area is selected, as long as described precursor and peptizing agent can mix by the amount of described water.
According to method of the present invention, described raw material can also contain extrusion aid.The content of described extrusion aid and kind can be that the routine of this area is selected.
Usually, with the total amount of described raw material for benchmark, the consumption of described extrusion aid can be 0.1 ~ 5 % by weight, is preferably 1 ~ 3 % by weight.In the present invention, the example of described extrusion aid can for but be not limited to: one or more in organic carboxyl acid, polyalcohol, organic amine and surfactant.
In the present invention, term " organic carboxyl acid " refers in molecular structure the organic compound with one or more carboxyl, such as " Lan Shi Chemical manual " second edition, the organic carboxyl acid enumerated in 1.26 ~ 1.27.Preferably, described organic carboxyl acid to be carbon number be 1 ~ 20 unary organic carboxylic acid or polybasic organic carboxylic acid's (such as: binary organic carboxyl acid).In the present invention, the example of described organic carboxyl acid can be but be not limited to: formic acid, acetic acid, ethanedioic acid, propionic acid, malonic acid, butyric acid, succinic acid, glutaric acid, adipic acid, benzoic acid, phthalic acid and benzenpropanoic acid.
In the present invention, term " polyol " refers in molecular structure the organic compound with two or more hydroxyl.The example of described polyalcohol can be but be not limited to: ethylene glycol, glycerine and butanediol.
In the present invention, term " organic amine " refers to the organic compound containing one or more amido in molecular structure.The example of described organic amine can be but be not limited to: monoethanolamine, diethanol amine, triethanolamine, N methyldiethanol amine and urea.
In the present invention, described surfactant can be anionic surfactant, cationic surface active agent, amphoteric ionic surfactant and nonionic surface active agent.The example of described anionic surfactant can be but be not limited to: stearic acid and neopelex.The example of described cationic surface active agent can be but be not limited to: quaternary ammonium compound.The example of described amphoteric ionic surfactant can be but be not limited to: lecithin, amino acid type surfactant and betaine type amphoteric surfactant.The example of described nonionic surface active agent can be but be not limited to: fatty glyceride, aliphatic acid sorb smooth (span series), polysorbate (TWEEN Series surfactant), polyoxyethylene-type surfactant and polyox-yethylene-polyoxypropylene block copolymer.
Comprise according to the preparation method of porous carrier of the present invention and described raw material being extruded, to obtain formed body.According to the preparation method of porous carrier of the present invention, the various extruders that described extruder can be commonly used for this area.The present invention is also not particularly limited for described kneading and the condition extruded, and can be that the routine of this area is selected.
Also comprise according to the preparation method of porous carrier of the present invention and described formed body is carried out roasting, thus obtain porous carrier.
The present invention is not particularly limited for the condition of described formed body being carried out roasting, can be the normal condition of this area.Usually, the temperature of described roasting can be 350 ~ 800 DEG C, is preferably 450 ~ 650 DEG C; The time of described roasting can be 1 ~ 10 hour, is preferably 2 ~ 5 hours.Described roasting can be carried out in oxygen-containing atmosphere, also can carry out in an inert atmosphere.
In the present invention, described inert atmosphere refers under drying or roasting condition to be inactive gas, such as: nitrogen and group 0 element gas (as argon gas).
According to the preparation method of porous carrier of the present invention, before described formed body is carried out roasting, can also comprise and described formed body is carried out drying, described drying can be carried out under the normal condition of this area, such as: the temperature of described drying can be 100 ~ 200 DEG C, the time of described drying can be 2 ~ 12 hours.Described drying can be carried out under the condition of normal pressure, also can carry out at reduced pressure, be not particularly limited.Described drying can be carried out in oxygen-containing atmosphere, also can carry out in an inert atmosphere.
Present invention also offers a kind of porous carrier prepared by method of the present invention, this porous carrier contains heat-resistant inorganic oxide and molecular sieve.Prepared according to the methods of the invention porous carrier not only has higher aperture, and has high aperture concentration degree.The porous carrier adopting the preferred embodiment of method of the present invention to prepare also has high mechanical strength.
Usually, the most probable pore size of prepared according to the methods of the invention porous carrier can be 1 ~ 30nm, is preferably 2 ~ 20nm, is more preferably 5 ~ 10nm; Aperture concentration degree can be 22 ~ 48, is preferably 25 ~ 48 (can be such as 25 ~ 40), is more preferably 27 ~ 40.
According to porous carrier of the present invention, not only aperture is large, and aperture concentration degree is high, is particularly suitable for the carrier as the catalyst with hydrogenation.Thus, present invention also offers a kind of porous carrier according to the present invention as the application of carrier of catalyst with hydrogenation.
Present invention also offers a kind of catalyst, this catalyst contains porous carrier and the active component with catalytic action of load on this porous carrier, and described porous carrier is porous carrier provided by the invention.
Described porous carrier and preparation method thereof is described in detail above, does not repeat them here.
The kind with the active component of catalytic action in catalyst according to the invention can carry out suitable selection according to the embody rule occasion of described catalyst.
Such as, when catalyst according to the invention is used for the hydrocracking of hydrocarbon ils, described in there is catalytic action active component can be group vib metal and group VIII metal.Described group vib metal and group VIII metal can respectively with the various forms load of this area routine on described porous carrier, such as: described group vib metal and group VIII metal can be loaded on described porous carrier respectively in the form of the oxide.
The described load capacity of active component on described porous carrier with catalytic action can be the conventional amount used of this area.Usually, with the total amount of the catalyst finally obtained for benchmark, with oxide basis, described in there is the active component of catalytic action amount can be 5 ~ 60 % by weight, be preferably 10 ~ 50 % by weight; The amount of described carrier can be 40 ~ 95 % by weight, is preferably 50 ~ 90 % by weight.Particularly, the described active component with catalytic action be group vib metal and group VIII metal time, with the total amount of described catalyst for benchmark, with oxide basis, the content of described group vib metal can be 10 ~ 40 % by weight, is preferably 15 ~ 30 % by weight; The content of described group VIII metal can be 2 ~ 10 % by weight, is preferably 2.5 ~ 6.5 % by weight; The content of described porous carrier can be 50 ~ 88 % by weight, is preferably 63.5 ~ 82.5 % by weight.
The various method preparations that catalyst provided by the invention can adopt this area conventional, as long as use porous carrier provided by the invention as carrier.Such as, can by the active component load with catalytic action be prepared described catalyst on porous carrier provided by the invention.
According to the present invention, can adopt and well known to a person skilled in the art various method by described active constituent loading on described porous carrier.
Such as, can by porous carrier described in the solution impregnation with the compound containing described active component, and the carrier of described compound load be had to carry out drying and roasting, thus by described active component load on described porous carrier.Described active component be group vib metal and group VIII metal time, the compound containing group vib metal that described compound can be commonly used for this area and containing the compound of group VIII metal.Described group vib metal be molybdenum and/or tungsten time, the described compound containing group vib metal is preferably the compound of tungsten and/or the compound of molybdenum.In the present invention, the described example containing the compound of group vib metal can for but be not limited to: one or more in wolframic acid, molybdic acid, metatungstic acid, ethyl metatungstic acid, para-molybdic acid, ammonium molybdate, ammonium paramolybdate, ammonium metatungstate and ethyl ammonium metatungstate.Described group VIII metal be cobalt and/or nickel time, the described compound containing group VIII metal is preferably and is cationic oxysalt with nickel, is cationic anaerobic hydrochlorate with nickel, take cobalt as cationic oxysalt and be one or more in cationic anaerobic hydrochlorate with cobalt.In the present invention, the example of the described compound containing group VIII metal can for but be not limited to: one or more in nickel nitrate, nickelous sulfate, nickel acetate, basic nickel carbonate, cobalt nitrate, cobaltous sulfate, cobalt acetate, basic cobaltous carbonate, nickel chloride and cobalt chloride.
According to the present invention, the solution of the compound containing described active component prepared by the various solvents that this area can be adopted to commonly use, as long as described compound can be dissolved in described solvent, forms the solution of stable homogeneous.Such as: described solvent can for water or carbon number be 1 ~ 5 alcohol (as: ethanol), be preferably water and/or ethanol, be more preferably water.
The method of described dipping can be the conventional various dipping methods in this area, such as, can be the saturated infusion process in hole.The present invention was not particularly limited for the time of described dipping and the number of times of dipping, as long as can guarantee that the amount with the active component of catalytic action on the catalyst that finally obtains meets concrete instructions for use.Usually, the time of described dipping can be 0.5 ~ 12 hour.
According to the present invention, carry out dry condition for load there being the porous carrier of described compound and be not particularly limited.Usually, the temperature of described drying can be 80 ~ 300 DEG C, is preferably 100 ~ 200 DEG C; The time of described drying can be 0.5 ~ 24 hour, is preferably 1 ~ 12 hour.
The present invention is not particularly limited for the condition having the carrier of described compound to carry out roasting the load of drying, can be the normal condition of this area.Usually, the temperature of described roasting can be 350 ~ 700 DEG C, is preferably 400 ~ 650 DEG C; The time of described roasting can be 0.2 ~ 12 hour, is preferably 1 ~ 10 hour.Described roasting can be carried out in oxygen-containing atmosphere, also can carry out in an inert atmosphere.
Invention further provides a kind of catalyst prepared by method of the present invention.
The porous carrier that catalyst according to the invention adopts not only has large aperture, and has high aperture concentration degree, is particularly suitable for the hydrocracking catalyst as hydrocarbon ils, thus produces the hydrocarbon system cut had compared with low boiling and lower molecular weight.
Thus, the present invention still further provides the application of a kind of catalyst according to the invention in hydrocarbon oil hydrogenation cracking.
Present invention also offers a kind of method for hydrogen cracking, under the method is included in hydrocracking condition, by hydrocarbon ils and catalyst exposure, wherein, described catalyst is catalyst provided by the invention.
According to method for hydrogen cracking of the present invention, described hydrocarbon ils can be various heavy mineral oil, artificial oil or their mixture.Particularly, the example of described hydrocarbon ils can be but be not limited to: vacuum gas oil (VGO), metal removal oil, reduced crude, de-asphalted vacuum residue, decompression residuum, coker distillate, shale oil, asphalt sand oil and liquefied coal coil.
The present invention is by using catalyst according to the invention, and improve the conversion ratio of hydrocarbon ils in hydrocracking and intermediate oil optionally, all the other conditions for hydrocracking are not particularly limited, and can be the normal condition of this area.Usually, described hydrocracking condition comprises: temperature can be 200 ~ 650 DEG C, is preferably 300 ~ 510 DEG C; In gauge pressure, pressure can be 3 ~ 24 MPas, is preferably 4 ~ 15 MPas; Hydrogen to oil volume ratio can be 150 ~ 2500; During liquid, volume space velocity can be 0.1 ~ 30 hour -1, be preferably 0.2 ~ 10 hour -1.
According to method for hydrogen cracking of the present invention, described catalyst preferably carries out presulfurization before use.The condition of described presulfurization can be the normal condition of this area.Such as, the condition of described presulfurization can comprise: in presence of hydrogen, at the temperature of 140 ~ 370 DEG C, carries out presulfurization with sulphur, hydrogen sulfide or sulfur-bearing raw material.According to method for hydrogen cracking of the present invention, described presulfurization can be carried out outside reactor, also can be In-situ sulphiding in reactor.
The present invention is described in detail below in conjunction with embodiment.
The reagent used in following examples and comparative example, except special instruction, is chemically pure reagent.
In following examples and comparative example, being purchased the model from Quantachrome company be on the six full-automatic specific surfaces in station of-6B and pore size distribution determining instrument, BET method is adopted to measure most probable pore size and the aperture concentration degree of porous carrier according to the method specified in RIPP 151-90.
In following examples and comparative example, adopt the 3271E type Xray fluorescence spectrometer be purchased from Rigaku electric machine industry Co., Ltd., analysiss mensuration is carried out to the content of element each in catalyst.
In following examples and comparative example, being on the X-ray diffractometer of X ' pert being purchased from the model of Philips company, measuring the average particulate diameter of porous carrier and degree of crystallinity, wherein, degree of crystallinity is relative crystallinity, is to measure according to the method specified in RIPP 139-90.
In following examples and comparative example, be the upper crushing strength measuring porous carrier of crushing strength analyzer (manufacture of alkaline research institute of the Ministry of Chemical Industry) of QCY-602 in model according to the method specified in GB3635-1983.
In following examples and comparative example, pressure is all in gauge pressure.
Embodiment 1 ~ 10 is used for illustrating according to porous carrier of the present invention and preparation method thereof.
Embodiment 1
Getting C1 powder (is purchased from sasol company, contents on dry basis is 74.5 % by weight, for a kind of boehmite, relative crystallinity is 93.1%, average particulate diameter is 53nm) 73.8g, aluminum silicon powder SIRAL 40 powder (is purchased from sasol company, contents on dry basis is 77.5 % by weight, for the mixture of the hydrate of aluminium oxide and the hydrate of silica, with oxide basis, the content of silica is 40 % by weight, the content of aluminium oxide is 60 % by weight, average particulate diameter is 55nm, lower same) 51.6g, (lattice constant is 24.55 to USY molecular sieve relative crystallinity is 74.6%, and contents on dry basis is 76.9 % by weight) 6.5g, add sesbania powder 4g and be dry mixed evenly, obtain dry powder.3mL red fuming nitric acid (RFNA) (concentration is 65 % by weight, lower same) is added in the beaker being contained with 103mL deionized water, mixes, obtain acid solution.By acid solution and dry powder blend, and stirring, obtaining the raw mixture for extruding, the temperature of described deionized water makes the temperature of the raw mixture obtained be 65 DEG C.Be that in the mixture feeding banded extruder of 65 DEG C, be extruded into the butterfly bar that circumscribed circle diameter is 1.4 millimeters, the temperature of extrudate in the exit of extruder is 88 DEG C by the temperature obtained.By extrudate 110 DEG C of dryings 8 hours.Then, in air atmosphere, at the temperature of 600 DEG C, roasting 2 hours, in roasting process, the flow of air is 65L hour -1, obtain after being cooled to room temperature according to porous carrier of the present invention, be designated as porous carrier A1.The most probable pore size of this porous carrier, aperture concentration degree and intensity are listed in Table 1
Embodiment 2
The method identical with embodiment 1 is adopted to prepare porous carrier, unlike, the temperature of raw mixture when entering described extruder is room temperature (25 DEG C), and the porous carrier obtained is designated as porous carrier A2.The most probable pore size of this porous carrier, aperture concentration degree and intensity are listed in Table 1.
Embodiment 3
Getting CL powder (is purchased from Chang Ling catalyst plant, contents on dry basis is 71 % by weight, for a kind of boehmite, relative crystallinity is 98.1%, average particulate diameter is 33nm) 91.5g, aluminum silicon powder SIRAL 20 powder (is purchased from sasol company, contents on dry basis is 75 % by weight, for the mixture of the hydrate of aluminium oxide and the hydrate of silica, with oxide basis, the content of silica is 20 % by weight, the content of aluminium oxide is 80 % by weight, average particulate diameter is 53nm) 46.7g, (silica alumina ratio is 61.4 to beta-molecular sieve, relative crystallinity is 84.2%, contents on dry basis is 83 % by weight) 1.2g, adding sesbania powder 4g is dry mixed evenly, to obtain dry powder.3.5mL red fuming nitric acid (RFNA) is added in the beaker being contained with 95mL deionized water, mixes, to obtain acid solution.By acid solution and dry powder blend, and stirring, obtaining the raw mixture (temperature of raw mixture is room temperature (25 DEG C)) for extruding.Sent in banded extruder by the mixture obtained (temperature is room temperature (25 DEG C)), be extruded into the butterfly bar that circumscribed circle diameter is 1.4 millimeters, the extrudate temperature in the exit of described extruder is 64 DEG C.By extrudate 120 DEG C of dryings 5 hours.Then, in air atmosphere, at the temperature of 560 DEG C, roasting 3 hours, in roasting process, the flow of air is 35L hour -1, obtain after being cooled to room temperature according to porous carrier of the present invention, be designated as porous carrier A3.The most probable pore size of this porous carrier, aperture concentration degree and intensity are listed in Table 1.
Embodiment 4
The method identical with embodiment 3 is adopted to prepare porous carrier, unlike, the extrudate temperature in the exit of described extruder is 43 DEG C.The porous carrier of the present invention of preparation is designated as porous carrier A4.The most probable pore size of this porous carrier, aperture concentration degree and intensity are listed in Table 1.
Embodiment 5
The method identical with embodiment 3 is adopted to prepare porous carrier, unlike, the extrudate temperature in the exit of described extruder is 98 DEG C.The porous carrier according to the present invention of preparation is designated as porous carrier A5.The most probable pore size of this porous carrier, aperture concentration degree and intensity are listed in Table 1.
Comparative example 1
The method identical with embodiment 3 is adopted to prepare porous carrier, unlike, the extrudate temperature in the exit of described extruder is 35 DEG C, and the porous carrier obtained is designated as porous carrier B1.Most probable pore size and the aperture concentration degree of this porous carrier are listed in Table 1.
Embodiment 6
Get CL powder (be purchased from Chang Ling catalyst plant, contents on dry basis is 71 % by weight, and be a kind of boehmite, relative crystallinity is 98.1%, and average particulate diameter is 33nm) 119.7g, (lattice constant is 24.55 to USY molecular sieve relative crystallinity is 74.6%, and contents on dry basis is 76.9 % by weight) 19.5g, add sesbania powder 4g and be dry mixed evenly, to obtain dry powder.3.5mL red fuming nitric acid (RFNA) and 5g urea are added in the beaker being contained with 106mL deionized water, mixes, to obtain acid solution.By acid solution and dry powder blend, and stir, obtain raw mixture (temperature of raw mixture is room temperature (25 DEG C)).Sent in banded extruder by the mixture obtained (temperature is room temperature (25 DEG C)), be extruded into the butterfly bar that circumscribed circle diameter is 1.4 millimeters, the extrudate temperature in the exit of described extruder is 80 DEG C.By extrudate 120 DEG C of dryings 8 hours.Then, in air atmosphere, at the temperature of 580 DEG C, roasting 2 hours, in roasting process, the flow of air is 65L hour -1, obtain after being cooled to room temperature according to porous carrier of the present invention, be designated as porous carrier A6.The most probable pore size of this porous carrier, aperture concentration degree and intensity are listed in Table 1.
Embodiment 7
Adopting adopts identical method to prepare porous carrier with embodiment 6, unlike, dry glue powder (the method preparation disclosed in CN100999328B embodiment 3 used, for a kind of boehmite, relative crystallinity is 76%, average particulate diameter is 36nm) replace CL powder, the porous carrier of preparation is designated as porous carrier A7.The most probable pore size of this porous carrier, aperture concentration degree and intensity are listed in Table 1.
Embodiment 8
Getting SD powder (is purchased from Shandong Aluminum Plant, contents on dry basis is 64 % by weight, for a kind of boehmite, relative crystallinity is 103%, average particulate diameter is 46nm) 71.8g, aluminum silicon powder SIRAL 30 powder (is purchased from sasol company, contents on dry basis is 77.5 % by weight, for the mixture of the hydrate of aluminium oxide and the hydrate of silica, with oxide basis, the content of silica is 30 % by weight, the content of aluminium oxide is 70 % by weight, average particulate diameter is 53nm) 59.2g, (silica alumina ratio is 51% to ZSM-5 molecular sieve, relative crystallinity is 77.3%, contents on dry basis is 81 % by weight, lower same) 11.1g, adding sesbania powder 4g is dry mixed evenly, to obtain dry powder.1mL red fuming nitric acid (RFNA) is added in the beaker being contained with 92mL deionized water, mixes, to obtain acid solution.By acid solution and dry powder blend, and stir, to obtain the raw mixture (temperature of raw mixture is room temperature (25 DEG C)) for extruding.Sent in banded extruder by the mixture obtained (temperature is room temperature (25 DEG C)), be extruded into the butterfly bar that circumscribed circle diameter is 1.4 millimeters, the extrudate temperature in the exit of described extruder is 60 DEG C.By extrudate 105 DEG C of dryings 5 hours.Then, in air atmosphere, at the temperature of 540 DEG C, roasting 4 hours, in roasting process, the flow of air is 105L hour -1, obtain after being cooled to room temperature according to porous carrier of the present invention, be designated as porous carrier A8.The most probable pore size of this porous carrier, aperture concentration degree and intensity are listed in Table 1.
Embodiment 9
Getting C1 powder (is purchased from sasol company, contents on dry basis is 74.5 % by weight, for a kind of boehmite, relative crystallinity is 93.1%, average particulate diameter is 53nm) 40.3g, aluminum silicon powder SIRAL 20 powder (is purchased from sasol company, contents on dry basis is 75 % by weight, for the mixture of the hydrate of aluminium oxide and the hydrate of silica, with oxide basis, the content of silica is 20 % by weight, the content of aluminium oxide is 80 % by weight, average particulate diameter is 53nm) 40.0g, ZSM-5 molecular sieve 49.4g, adding sesbania powder 3.5g is dry mixed evenly, to obtain dry powder.The red fuming nitric acid (RFNA) of 2.5mL is added in the beaker being contained with 100mL deionized water, mixes, to obtain acid solution.By acid solution and dry powder blend, and stir, to obtain the raw mixture for extruding, the temperature of described deionized water makes the temperature of the raw mixture obtained be 80 DEG C.Be that in the mixture feeding banded extruder of 80 DEG C, be extruded into the butterfly bar that circumscribed circle diameter is 1.4 millimeters, the extrudate temperature in the exit of described extruder is 94 DEG C by the temperature obtained.By extrudate 105 DEG C of dryings 5 hours.Then, in air atmosphere, at the temperature of 540 DEG C, roasting 4 hours, in roasting process, the flow of air is 105L hour -1, obtain after being cooled to room temperature according to porous carrier of the present invention, be designated as porous carrier A9.The most probable pore size of this porous carrier, aperture concentration degree and intensity are listed in Table 1.
Embodiment 10
Getting CL powder (is purchased from Chang Ling catalyst plant, contents on dry basis is 71 % by weight, for a kind of boehmite, relative crystallinity is 98.1%, average particulate diameter is 33nm) 59.9g, aluminum silicon powder SIRAL 30 powder (is purchased from sasol company, contents on dry basis is 77.5 % by weight, for the mixture of the hydrate of aluminium oxide and the hydrate of silica, with oxide basis, the content of silica is 30 % by weight, the content of aluminium oxide is 70 % by weight, average particulate diameter is 53nm) 72.4g, ZSM-5 molecular sieve 2.5g, adding sesbania powder 3g is dry mixed evenly, to obtain dry powder.The red fuming nitric acid (RFNA) of 2mL is added in the beaker being contained with 91mL deionized water, mixes, to obtain acid solution.By acid solution and dry powder blend, and stir, to obtain the raw mixture for extruding, the temperature of described deionized water makes the temperature of the raw mixture obtained be 50 DEG C.Be that in the mixture feeding banded extruder of 50 DEG C, be extruded into the butterfly bar that circumscribed circle diameter is 1.4 millimeters, the extrudate temperature in the exit of described extruder is 81 DEG C by the temperature obtained.By extrudate 105 DEG C of dryings 5 hours.Then, in air atmosphere, at the temperature of 540 DEG C, roasting 4 hours, in roasting process, the flow of air is 105L hour -1, obtain after being cooled to room temperature according to porous carrier of the present invention, be designated as porous carrier A10.The most probable pore size of this porous carrier, aperture concentration degree and intensity are listed in Table 1.
Table 1
Numbering Porous carrier is numbered Aperture, most probable hole (nm) Aperture concentration degree Crushing strength (N/mm)
Embodiment 1 A1 8.2 33.4 27.3
Embodiment 2 A2 8.1 25.8 20.1
Embodiment 3 A3 9.1 28.1 24.5
Embodiment 4 A4 8.8 25.7 21.2
Embodiment 5 A5 9.1 27.0 25.3
Comparative example 1 B1 8.9 19.0 18.8
Embodiment 6 A6 5.8 25.4 27.7
Embodiment 7 A7 6.2 22.0 22.4
Embodiment 8 A8 6.4 26.9 19.8
Embodiment 9 A9 6.6 23.7 24.4
Embodiment 10 A10 6.8 27.9 22.9
Embodiment 11 ~ 20 is used for catalyst according to the invention and application thereof are described.
Embodiment 11 ~ 20
Ammonium metatungstate (being purchased from Chang Ling catalyst plant) and nickel nitrate (being purchased from the sharp chemical reagent factory of Beijing benefit) are dissolved in the water, be mixed with maceration extract, flood the porous carrier A1 ~ A10 of preparation in embodiment 1 ~ 10 respectively according to hole saturation with this maceration extract, and by the carrier after dipping at 120 DEG C in air atmosphere dry 2 hours, then roasting 5 hours in air atmosphere at 350 DEG C, thus the obtained catalyst with hydrogenation, be designated as catalyst X1 ~ X10 respectively.Ammonium metatungstate and nickel nitrate load capacity on porous support makes with the total amount of catalyst for benchmark, with oxide basis, in catalyst X1 ~ X10, and WO 327.0 % by weight and 2.6 % by weight are respectively with NiO content.
Comparative example 2
Adopt the method Kaolinite Preparation of Catalyst identical with embodiment 11 ~ 20, unlike, porous carrier is porous carrier B1 prepared by comparative example 1.Obtained catalyst is designated as CX.Ammonium metatungstate and nickel nitrate load capacity on porous support makes with the total amount of catalyst for benchmark, with oxide basis, and WO 327.0 % by weight and 2.6 % by weight are respectively with NiO content.
Embodiment 21 ~ 30 is used for the application of catalyst according to the invention and method for hydrogen cracking are described.
Embodiment 21 ~ 30
Adopt once by flow process, feedstock oil adopts sand gently to subtract two, and the density (20 DEG C) of this feedstock oil is 0.9062g/cm 3, refraction index (20 DEG C) is 1.4852; Initial boiling point (IBP) is 299 DEG C, and 5% recovered (distilled) temperature is 359 DEG C, and 50% recovered (distilled) temperature is 399 DEG C, and 95% recovered (distilled) temperature is 436 DEG C.
Diameter is become by catalyst breakage to be the particle of 0.5 ~ 1.0 millimeter, this catalyst 200 milliliters is loaded in 200 milliliters of fixed bed reactors, before logical oil, first catalyst is 15.0MPa in hydrogen dividing potential drop, and temperature is sulfuration 28 hours under the condition of 300 DEG C, is 14.7MPa in hydrogen dividing potential drop afterwards, passes into feedstock oil when temperature is 350 DEG C, hydrogen-oil ratio is 900 volume/volume, and during liquid, volume space velocity is 0.75h -1, and sample after 400 hours in reaction.
Catalytic activity and the intermediate oil of evaluate catalysts are selective, wherein
The cracking reaction temperature needed when activity refers to that recovered (distilled) temperature is 60% higher than the conversion ratio of the hydrocarbon ils of 350 DEG C, the catalytic activity of cracking reaction temperature lower explanation catalyst is higher;
Intermediate oil is selective refers to that recovered (distilled) temperature is the percentage that the content of the cut of 132 ~ 371 DEG C accounts for recovered (distilled) temperature and is less than the gross mass of 371 DEG C of cuts.
Comparative example 3
The performance of the catalyst adopting the method evaluation comparative example 2 identical with embodiment 21 ~ 30 to prepare.
The result display of embodiment 21 ~ 30 and comparative example 3, the intermediate oil that catalyst according to the invention has higher catalytic activity and Geng Gao is selective.Table 2 lists by the hydrodesulfurization activity of embodiment 21,22,23,26 and 30 and comparative example 3 and intermediate oil optionally concrete numerical value.
Table 2
Numbering Catalyst Active (DEG C) Selective (%)
Embodiment 21 X1 384.4 82.8
Embodiment 22 X2 386.5 82.6
Embodiment 23 X3 395.0 83.4
Comparative example 3 CX1 398.7 83.1
Embodiment 26 X6 371.7 79.6
Embodiment 30 X10 392.2 81.7
Embodiment 23 and comparative example 3 are compared and can find out, catalyst according to the invention there is higher catalytic activity and intermediate oil selective.
Embodiment 21 and embodiment 22 are compared and can find out, under the condition that all the other conditions are identical, aperture concentration degree for the preparation of the porous carrier of catalyst is higher, then the catalyst with hydrogenation prepared there is higher catalytic activity and intermediate oil selective.

Claims (20)

1. a preparation method for porous carrier, the method comprises: by forming the mixing of the precursor of heat-resistant inorganic oxide, molecular sieve, peptizing agent and water under roasting condition, to supply raw materials; Described raw material is sent in extruder, and extrudes after kneading in described extruder, to obtain formed body; Described formed body is carried out roasting, to obtain described porous carrier, it is characterized in that, the temperature of described formed body in the exit of described extruder is 40 ~ 150 DEG C, and the temperature of described raw material in the porch of described extruder is 40 ~ 100 DEG C.
2. method according to claim 1, wherein, the temperature of described formed body in the exit of described extruder is 60 ~ 120 DEG C.
3. method according to claim 1, wherein, the temperature of described raw material in the porch of described extruder is 40 ~ 80 DEG C.
4. method according to claim 1, wherein, the described average particulate diameter that can form the precursor of heat-resistant inorganic oxide under roasting condition is 30 ~ 100nm.
5. method according to claim 4, wherein, the described average particulate diameter that can form the precursor of heat-resistant inorganic oxide under roasting condition is 30 ~ 80nm.
6. method according to claim 1, wherein, the content of the molecular sieve in described raw material makes in the porous carrier prepared, with the total amount of described porous carrier for benchmark, the content of described molecular sieve is 0.1 ~ 60 % by weight, and the content of described heat-resistant inorganic oxide is 40 ~ 99.9 % by weight.
7. the method according to claim 1 or 6, wherein, described molecular sieve is one or more in ZRP molecular sieve, Y zeolite, beta-molecular sieve, modenite, ZSM-5 molecular sieve, MCM-41 molecular sieve, Ω molecular sieve, ZSM-12 molecular sieve and MCM-22 molecular sieve.
8. according to the method in claim 1 and 4 ~ 6 described in any one, wherein, described heat-resistant inorganic oxide is one or more in aluminium oxide, silica, titanium oxide, magnesia, zirconia, thorium oxide and mesoporous Si-Al.
9. according to the method in claim 1,4 and 5 described in any one, wherein, the described precursor that can form heat-resistant inorganic oxide under roasting condition contains the boehmite that relative crystallinity is more than 80%, and described relative crystallinity measures according to the method specified in RIPP 139-90.
10. method according to claim 9, wherein, the relative crystallinity of described boehmite is 90 ~ 110%.
11. methods according to claim 1, wherein, the condition of described roasting comprises: temperature is 350 ~ 800 DEG C, and the time is 1 ~ 10 hour.
12. 1 kinds of porous carriers prepared by the method in claim 1 ~ 11 described in any one.
13. porous carriers according to claim 12 are as the application of carrier of catalyst with hydrogenation.
14. 1 kinds of catalyst, this catalyst contains porous carrier and the active component with catalytic action of load on this porous carrier, and it is characterized in that, described porous carrier is porous carrier according to claim 12.
15. catalyst according to claim 14, wherein, with the total amount of this catalyst for benchmark, with oxide basis, the content of described active component is 5 ~ 60 % by weight, and the content of described porous carrier is 40 ~ 95 % by weight.
16. catalyst according to claims 14 or 15, wherein, described active component is group vib metal and group VIII metal.
17. catalyst according to claim 16, wherein, with the total amount of this catalyst for benchmark, with oxide basis, the content of described group vib metal is 10 ~ 40 % by weight, and the content of described group VIII metal is 2 ~ 10 % by weight, and the content of described porous carrier is 50 ~ 88 % by weight.
18. according to the application of the catalyst in claim 14 ~ 17 described in any one in hydrocarbon oil hydrogenation cracking.
19. 1 kinds of method for hydrogen cracking, under the method is included in hydrocracking condition, by hydrocarbon ils and catalyst exposure, is characterized in that, described catalyst is the catalyst in claim 14 ~ 17 described in any one.
20. methods according to claim 19, wherein, described hydrocracking condition comprises: temperature is 200 ~ 650 DEG C, and in gauge pressure, pressure is 3 ~ 24 MPas, and hydrogen to oil volume ratio is 150 ~ 2500, and during liquid, volume space velocity is 0.1 ~ 30 hour -1.
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