CN100590179C - Diesel oil fraction hydroupgrading process - Google Patents
Diesel oil fraction hydroupgrading process Download PDFInfo
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Abstract
The diesel oil fraction hydroupgrading process has the mixture of inferior diesel oil fraction and hydrogen passing through the hydroupgrading reaction region to result in diesel oil with improved quality through reaction under certain condition. The catalyst in the hydroupgrading reaction region includes at least one kind of bulk phase catalyst comprising complex oxide NixWyOz and oxide MoO3 in the weight ratio 0.1-10 and accounting for 40-100 wt% of total catalyst. The present invention facilitates the hydroupgrading operation, increases the treating capacity of the apparatus, increases theservice life of the catalyst and raises the quality of the diesel oil product.
Description
Technical field
The present invention relates to a kind of diesel oil fraction hydroupgrading process, select suitable catalyzer for use, poor ignition quality fuel is improved cetane value, simultaneously the purified method.
Background technology
At present worldwide, the trend of crude oil heaviness and poor qualityization is accelerated, the increasingly stringent of the sustainable development of world economy and environmental regulation in addition, need to produce a large amount of light clean fuels, these all require existing oil Refining Technologies is improved, and produce satisfactory product with minimum cost.Produce with heavy feed stock in the working method of light-end products, catalytic cracking and coking still account for critical role, along with the raw materials quality variation, the degradation of straight-run diesel oil not only, the diesel oil distillate quality that catalytic cracking and coking obtain is poorer, and these cuts adopt existing technology to be difficult to the product that direct production conforms to quality requirements, and this just requires to develop new working method.
The poor-quality diesel-oil by cut fraction processing technology generally has hydrofining, hydro-upgrading, mild hydrocracking etc.Wherein hydro-upgrading not only can remove impurities in raw materials, and can improve diesel-fuel cetane number greatly, the yield height of diesel product simultaneously, be the suitableeest and processing means.As described in CN1156752A and CN1289832A etc., although can improve diesel-fuel cetane number and reduce foreign matter contents such as sulphur, nitrogen, but be subjected to the restriction of reaction conditions, have only just to make cetane value that very significantly raising is arranged in very harsh conditions.
Adopting highly active catalyzer that diesel oil distillate is carried out hydrofining also is general method commonly used, but this method is limited to the amplitude that improves the product cetane value, and the performance of existing high activated catalyst still needs further to improve.US 4880526 discloses a kind of Ni of containing, Mo, W, the Co high reactivity is used for bulk phase catalyst of hydrotreatment and preparation method thereof, and this preparation method adopts metal to mix kneading to be equipped with technology, and the different metal component distributes under the microcosmic in mutually also inhomogeneous at body.US6299760, US6156695, US6537442, US6440888, the disclosed VIII of containing of US6652738 family/group vib active metal component are used for bulk phase catalyst of hydrotreatment and preparation method thereof, adopt and prepare the metal-powder that contains Ni-Mo or Ni-Mo-W earlier, use aluminum oxide bonding again, or the metal-powder of Ni-Mo or Ni-Mo-W is mixed back dehydration, extrusion, drying with alumina gel.Because the catalyst metal content height of this method preparation, often lack enough interactions between metal and aluminum oxide and cause catalyst strength poor.Active ingredient is made up of a large amount of metals, has some interior metal components and can not be fully utilized and cause the active ingredient loss in forming Ni-Mo or Ni-Mo-W powder process, and this problem can not be by simple bonding the solution.CN1342102A discloses a kind of mixed metal catalyst, and concrete grammar is for to obtain three kinds of reactive metal co-precipitation, and its main weak point is not find the cooperation effect between the different activities metal.US6162350, CN1339985A disclose a kind of mixed metal catalyst composition, and it is solid-state keeping at least a metal in preparation process, forms another kind of soild oxide in this solid metal compound surface reaction, finally forms the core-shell type composition.This method can not make different metal obtain good cooperation.The performance of above-mentioned high reactivity bulk phase catalyst still can further improve.
Summary of the invention
At the deficiencies in the prior art, the invention provides a kind of diesel oil fraction hydrogenation converting process, it can reduce the operating severity of hydro-upgrading reaction zone, promptly can realize reducing working pressure, reduces temperature of reaction, increases the device processing power and prolong in the effect such as catalyzer work-ing life one or more.
Diesel oil fraction hydroupgrading process of the present invention comprises following content: with one or more of poor-quality diesel-oil by cut fraction is raw material, under the hydro-upgrading reaction conditions, stock oil and hydrogen order are by pre-refining reaction zone and hydro-upgrading reaction zone, the hydro-upgrading that obtains generates oil and uses in the gas circulation that gas-liquid separator separates obtains, and the liquid fractionation that obtains is a following products: gas, petroleum naphtha, diesel oil etc.At least comprise a kind of bulk phase catalyst bed in the described pre-refining reaction zone, bulk phase catalyst contains Mo, W, three kinds of metal components of Ni, and catalyzer W, Ni before sulfuration exist with the composite oxides form: Ni
xW
yO
z, z=x+3y, Mo exists with oxide form: MoO
3Composite oxides Ni
xW
yO
zThe ratio of middle x and y (atomic molar ratio) is 1: 8~8: 1, is preferably 1: 4~4: 1.Composite oxides Ni
xW
yO
zWith oxide M oO
3Weight ratio be 1: 10~10: 1, be preferably 1: 5~5: 1.Composite oxides Ni in the bulk phase catalyst
xW
yO
zWith oxide M oO
3Gross weight content be 40%~100%, be preferably 50%~80%.
The stock oil that the inventive method is used can be the catalytic cycle oil that obtains in the petroleum refining process, coker gas oil, and one or more of viscosity breaking diesel oil etc. also can be coal tar, gelatin liquefaction wet goods.
The operational condition of hydrogenation reaction is generally reaction pressure 2.0~20.0MPa, and hydrogen to oil volume ratio is 200: 1~2500: 1, and the cumulative volume air speed is 0.1~6.0h
-1, 310 ℃~455 ℃ of temperature of reaction; Preferred operational condition is reaction pressure 3.0~19.0MPa, hydrogen to oil volume ratio 300: 1~2000: 1, volume space velocity 0.2~4.0h
-1, 320~435 ℃ of temperature of reaction.
The catalyzer of pre-refining reaction zone of the present invention can all be a bulk phase catalyst, also can be the combination of conventional Hydrobon catalyst and bulk phase catalyst.During combination loading, bulk phase catalyst can be seated in the top of reaction zone, also can be seated in the bottom of reaction zone, and perhaps two types catalyzer loads at interval, the volume ratio of bulk phase catalyst and conventional catalyst is 90: 10~10: 90, preferred 20: 80~80: 20.During combination loading, preferred feed by common pre-refining beds, by bulk phase catalyst bed of the present invention, helps bringing into play the catalyzer overall activity most earlier then.Wherein conventional Hydrobon catalyst can be various commercial catalysts, as Fushun Petrochemical Research Institute (FRIPP) develop 3936,3996, FF-16, FF-26, Hydrobon catalysts such as FH-5, FH-98, the HC-K of Uop Inc., HC-P, S-120, the TK-557 of Topsor company, TK-915 catalyzer, the KF-756 of AKZO company, KF757, KF-848 etc.
The catalyzer of hydro-upgrading reaction zone of the present invention is the diesel oil hydrogenation modification catalyzer.The carrier of catalyst for hydro-upgrading is aluminum oxide and Y molecular sieve, and molecular sieve content is generally 5wt%~80wt%, 3963 and FC-18 etc. that commercial catalyst for hydro-upgrading is developed as: FRIPP.Also can be by disclosed relevant patented technology preparation, as CN1098912C, CN1054150C, CN1049679C etc.The catalyst volume ratio of pre-refining reaction zone and upgrading reaction zone is 20: 80~80: 20, is preferably 30: 70~70: 30.
Can contain in the components such as aluminum oxide, silicon oxide, amorphous aluminum silicide, phosphorous oxides, titanium oxide, Zirconium oxide, molecular sieve one or more in the bulk phase catalyst of the present invention as required, the weight content of these components in catalyzer is 0~60%, is preferably 20%~50%.The specific surface area of bulk phase catalyst is 120~400m
2/ g, pore volume are 0.10~0.50ml/g.
The preparation process of bulk phase catalyst of the present invention comprises following content: (1) coprecipitation method generates Ni
xW
yO
zThe composite oxides precursor; (2) Ni
xW
yO
zComposite oxides precursor and MoO
3Making beating mixes, filters; (3) moulding, activation are final catalyzer.
Wherein (1) described coprecipitation method generates Ni
xW
yO
zThe process of composite oxides precursor can adopt following method: with the salts solution of tungstenic, nickel, form required ratio in catalyzer and add in the glue jar, add precipitation agent and make gelatinous mixture.Precipitation agent can be inorganic or organic alkaline ammoniac compounds, is preferably ammonia, can working concentration ammoniacal liquor arbitrarily.
Add required catalyst adjuvant and add component in a step that can be in above-mentioned steps or a few step.Auxiliary agent generally comprise P, F, Ti, Si, B, Zr etc. one or more.Add component and be generally refractory porous mass and precursor thereof, as aluminum oxide and precursor (aluminium hydroxide, aluminum salt solution etc.), clay, sial, titanium oxide-magnesium oxide, molecular sieve etc.The method that adds auxiliary agent and interpolation component adopts this area ordinary method.
Though W, Mo, Ni are activity of hydrocatalyst component commonly used, find that through a large amount of The effects the performance of different fit system catalyzer has very big-difference.Particularly in the bigger bulk phase catalyst of total metal content, the different fit systems of these metals are bigger to the performance impact of catalyzer.The present invention finds by a large amount of experiments, is used for the body phase hydrogenation catalyst that the hydrocarbon material degree of depth is taken off impurity, earlier with W and Ni co-precipitation, makes Ni
xW
yO
zThe precursor of composite oxides, this composite oxides precursor again with MoO
3Making beating mixes, and adopts conventional means to prepare preformed catalyst then, and this preparation process organically cooperates element W and Ni, forms a kind of composite oxides, then with MoO
3Combination finally forms Ni
xW
yO
zThe composition of composite oxides and Mo oxide compound.The result shows when the catalyzer of this microtexture of the present invention is used for hydrocarbons hydrogenation, to have the outstanding impurity activity of taking off, and during especially for deep impurity removal process, significantly improves than the activity of such catalysts of similar chemical constitution.The mechanism that the composition of Ni-W composite oxides of the present invention and Mo oxide compound can improve catalyst activity is very not clear and definite as yet, and, in bulk phase catalyst, the content of reactive metal is higher, reactive metal exist form different fully with traditional loaded catalyst, therefore, can not be suitable for the metal cooperation theory of conventional negative supported catalyst.For example, it is generally acknowledged that Ni can promote the activity of Mo to improve, wishing has a stronger interaction between Ni and the Mo, and the present invention finds in experiment, for bulk phase catalyst, Mo and Ni is fully combined then take off impurity in the degree of depth and do not show perfect performance.The composition catalyzer of Ni-W composite oxides of the present invention and Mo oxide compound, the possible cause that takes off the unexpected raising of performance in the impurity in the degree of depth is, in the very high bulk phase catalyst of metal content, reactive metal exist form different with loaded catalyst, take off in the impurity process in the hydrocarbon raw material degree of depth, the Ni-W composite oxides have stronger hydrogenation activity after sulfuration, make to have the effective hydrogenation of complex construction macromole, eliminate and take off the sterically hindered of impurity reaction.Has the stronger impurity activity of taking off after the Mo sulfuration in the bulk phase catalyst, simple in structure, the sterically hindered little heteroatoms hydrocarbon that contains is easy to react, reduced of the interference of this part heteroatoms hydro carbons, helped the hydrogenation that Ni-W high reactivity center is used for the complex construction molecule the Ni-W hydrogenation activity.After containing the effective hydrogenation in heteroatomic complex construction macromole process Ni-W high reactivity center, take off the sterically hindered of impurity and reduce greatly, can in taking off impurity activity, remove easily in the heart.Therefore, the active centre of Ni-W composite oxides of the present invention and Mo oxide compound obtains cooperation, and combination catalyst takes off in the impurity reaction in the degree of depth and has outstanding activity.Bulk phase catalyst preparation method of the present invention does not use the salts solution of Mo, because the reaction product of Mo salts solution and precipitation agent generally has certain solubleness, has therefore avoided the loss of Mo.
Compared with prior art, characteristics of the present invention are: because the present invention has used some or all of highly active bulk phase catalyst, strengthened the hydrogenation performance of hydrofining reaction district catalyzer, can effectively reduce the content and the aromaticity content of organonitrogen in the stock oil, promptly under the identical operations condition, can reduce reaction pressure, reduce service temperature etc., perhaps under same reaction pressure, service temperature, increase the treatment capacity of device, perhaps reduce the usage quantity of catalyzer, reduced the construction investment and the running cost of device.And owing to improved the hydrorefined degree of depth, the aromatic hydrocarbons saturation depth also increases, thereby can increase substantially diesel-fuel cetane number, and can carry out ultra-deep desulfurization.
Description of drawings
Fig. 1 is a principle process flow diagram of the present invention.
Fig. 2 is another principle process flow diagram of the present invention.
Embodiment
According to the scale of device, the inventive method can adopt a reactor or two (or a plurality of) reactors, adopts a reactor to be commonly referred to single hop technology, adopts two (or a plurality of) reactors to be commonly referred to one-stage serial technology.Adopt one way pass-through mode those skilled in the art to know, hydrofining reaction district and hydro-upgrading reaction zone need the layering filling according to the temperature distribution situation, cold hydrogen inlet is arranged between each bed, inject cold hydrogen during operation, take away the reaction heat that hydrogenation reaction and cracking reaction are given birth to, make temperature of reaction control within the specific limits, make operation safe, steady.
Hydrogenation modification method of the present invention specific as follows: with one or more of inferior distillate oil is stock oil, adopt single hop or one-stage serial technical process, under the hydro-upgrading operational condition, stock oil and hydrogen order are by pre-refining reaction zone and hydro-upgrading reaction zone, the hydro-upgrading that obtains generates oil and uses in the gas circulation that gas-liquid separator separates obtains, and the liquid that obtains obtains following products in the stripping tower fractionation: one or more in gas, petroleum naphtha, the diesel oil.
Specifically technical process as shown in Figure 1: stock oil is mixed into all or part of high reactivity body of the filling pre-refining reaction zone of Hydrobon catalyst mutually with hydrogen, the refining generation oil that obtains is mixed into the hydro-upgrading reaction zone with hydrogen, the generation oil continuation fractionation stripping tower that obtains from the hydro-upgrading reaction zone obtains gas, products such as petroleum naphtha and diesel oil.
The difference of Fig. 2 and Fig. 1 is to have used the one-stage serial technical process.
Bulk phase catalyst of the present invention can make as follows.
1, Ni
xW
yO
zComposite oxides precursor and MoO
3The preparation of mixture
In retort, add the saline solution that contains reactive metal Ni, W component by catalyst component content proportioning.Contain nickel salt and can be single nickel salt, nickelous nitrate, nickelous chloride etc.Tungstenic salt can be sodium wolframate, ammonium metawolframate etc.Mix the back, precipitation agent is added under stirring state in the said mixture, until forming collosol intermixture.Becoming the glue temperature is 30-100 ℃, and becoming the glue pH value is 7.0-10.0.Can become under the glue temperature to wear out 1-5 hour after becoming glue.Becoming in the glue thing promptly is Ni
xW
yO
zThe precursor of composite oxides.Can filter or not filter before and after becoming glue, add the solid molybdic oxide, making beating mixes, and filters then and obtains filter cake, and filter cake can wash or not wash, and filter cake dehydrates under 50-150 ℃ of condition, 0.5~24 hour time of drying, obtains Ni
xW
yO
zComposite oxides precursor and MoO
3Mixture.
Preferably 30~80 ℃ of described one-tenth glue temperature, gelation time was generally 0.5~5 hour, was preferably 0.5~3 hour, slurries pH value 7.0-9.0 preferably during cemented into bundles.Preferably 50~100 ℃ of described drying temperatures are preferably 1~8 hour time of drying.
Can add aluminum salt solution in the saline solution of Ni, W component, make the precursor that contains aluminum oxide in the throw out, aluminum salt solution can be aluminum nitrate, Tai-Ace S 150, aluminum chloride or aluminum acetate etc.Directly add aluminium hydroxide after also can becoming glue.The purpose of introducing aluminium in the catalyzer mainly is the intensity that increases catalyzer, and improves pore structure etc.In the preparation process of this mixture, can add auxiliary agent and additive etc. as required.
2, Preparation of Catalyst
The filter cake that above-mentioned drying is good rolls extruded moulding.Can or contain with water purification after the moulding and can decompose salt (as ammonium acetate) solution and wash.The activation of catalyzer comprises processes such as dry and roasting.To wash back stripe shape thing drying, roasting obtains final catalyst prod.Dry and roasting can be adopted this area normal condition, as 50~200 ℃ of dryings 1~48 hour, 450~600 ℃ of roastings 0.5~24 hour, is preferably 1~8 hour.Also can introduce auxiliary agent and additive as required in the catalyst preparation process.
Catalyst shape can be sheet, spherical, cylinder bar and special-shaped bar (trifolium, Herba Galii Bungei), preferably cylinder bar and special-shaped bar (trifolium, Herba Galii Bungei) as required.The diameter of carrier can be 0.8~2.0mm slice and>the thick bar of 2.5mm.
Bulk phase catalyst of the present invention has higher hydrodenitrification, hydrogenating desulfurization, the saturated isoreactivity energy of aromatic hydrocarbons.
Further specify Preparation of catalysts method of the present invention and use properties below by embodiment.Wherein the percentage composition of clear and definite benchmark is not a weight percentage.
Embodiment 1
In retort, add 1000mL water, add nickelous chloride 40g dissolving then, add ammonium metawolframate 52g dissolving again, add zirconium oxychloride 5g dissolving again, add 10% ammoniacal liquor then and become glue, until pH value is 8, becoming the glue temperature is 50 ℃, wears out 1 hour behind the one-tenth glue, filters then, filter cake adds 600ml water purification and 16g molybdic oxide and 32g aluminium hydroxide, making beating stirs, and filters, and filter cake was 80 ℃ of dryings 5 hours, extruded moulding then, with water purification washing 3 times, wet bar is 120 ℃ of dryings 5 hours, 500 ℃ of roastings 4 hours, obtain final catalyst A, composition and main character see Table 1.
Embodiment 2
Method according to embodiment 1, press the component concentration proportioning of catalyst B in the table 1, adding aluminum chloride, nickelous chloride, sodium wolframate in retort, add 16% ammoniacal liquor then and become glue, is 9 until pH value, becoming the glue temperature is 80 ℃, wore out 3 hours after becoming glue, filter then, filter cake washs 2 times with the 500mL water purification, add water purification and molybdic oxide, making beating stirs, and filters, and filter cake was 70 ℃ of dryings 7 hours, extruded moulding then, with water purification washing 2 times, wet bar is 100 ℃ of dryings 8 hours, 550 ℃ of roastings 3 hours, obtain final catalyst B, composition and main character see Table 1.
Embodiment 3
Method according to embodiment 1, press the component concentration proportioning of catalyzer C in the table 1, in retort, add nickelous nitrate, ammonium metawolframate, aluminium hydroxide, silicon sol, add 12% ammoniacal liquor then and become glue, until pH value is 10, and becoming the glue temperature is 60 ℃, wears out 2 hours behind the one-tenth glue, filter then, filter cake adds molybdic oxide, and making beating stirs, and filters, filter cake was 120 ℃ of dryings 1 hour, extruded moulding then, wet bar is 130 ℃ of dryings 3 hours, 600 ℃ of roastings 3 hours, obtain final catalyzer C, composition and main character see Table 1.
Embodiment 4
Method according to embodiment 1, press the component concentration proportioning of catalyzer D in the table 1, in retort, add 1000mL water, add nickelous chloride 48g dissolving then, add ammonium metawolframate 40g dissolving again, adding 10% ammoniacal liquor then and become glue, is 8 until pH value, and becoming the glue temperature is 40 ℃, wore out 3 hours after becoming glue, filter then, filter cake adds 600ml water purification and 28g molybdic oxide and 17g aluminium hydroxide, and making beating stirs, filter, filter cake is 80 ℃ of dryings 5 hours, and extruded moulding then is with water purification washing 3 times, wet bar was 120 ℃ of dryings 5 hours, 500 ℃ of roastings 4 hours, obtain final catalyzer D, composition and main character see Table 2.
Comparative example
Catalyzer according to embodiment 1 is formed, and presses the disclosed method for preparing catalyst of Chinese patent CN1342102A, preparation reference agent E.
In retort, add 1000mL water, add Ammonium Heptamolybdate 25g dissolving then, add ammonium metawolframate 52g dissolving again, add 25% ammoniacal liquor then and become glue, until pH value is 10.0, and being heated to temperature is 90 ℃, drips the solution that contains the 40g nickelous chloride simultaneously in retort.The suspension liquid that forms is continued to stir 90 ℃ of temperature 30 minutes.Filter then, the filter cake hot wash, 100 ℃ of dryings 5 hours add 32g aluminium hydroxide extruded moulding then, and wet bar 500 ℃ of roastings 4 hours, obtains final reference catalyst E 100 ℃ of dryings 8 hours, and composition and main character see Table 2.Prepare catalyzer by this kind method, the molybdic oxide yield can only reach 80%, and in order to guarantee metal content and proportioning in the catalyzer, Ammonium Heptamolybdate adds 20% when feeding intake.
The catalyzer and the character of the preparation of table 1 the inventive method
| The catalyzer numbering | A | B | C | D | E |
| NiO,wt% | 18.1 | 17.1 | 12.5 | 22.1 | 17.9 |
| WO 3,wt% | 42.3 | 21.3 | 28.4 | 32.2 | 41.8 |
| MoO 3,wt% | 16.5 | 57.6 | 18.6 | 28.1 | 17.0 |
| Al 2O 3,wt% | Surplus | Surplus | Surplus | Surplus | Surplus |
| Other, wt% | ZrO 2/2.0 | Do not have | SiO 2/4.0 | TiO 2/3.0 | Do not have |
| Specific surface/m 2·g -1 | 143 | 258 | 202 | 135 | 105 |
| Pore volume/mlg -1 | 0.216 | 0.40 | 0.258 | 0.12 | 0.132 |
| Intensity/Nmm -1 | 11.5 | 11.0 | 16.7 | 18.2 | 8.6 |
Embodiment 5
Stock oil character sees Table 2, catalyst property sees Table 3, and processing condition and test-results see Table 4.Oxidized catalyst is carried out conventional sulfidizing before use.As under the 8MPa condition, vulcanize with the diesel oil that contains dithiocarbonic anhydride 2wt%, 230 ℃ of constant temperature 8 hours, 330 ℃ of constant temperature 10 hours, volume space velocity was 1.0h during liquid
-1, hydrogen to oil volume ratio is 500: 1.
From table 4 test-results as can be seen, adopt technology of the present invention can effectively improve the activity of Hydrobon catalyst, can reduce working pressure, reduce service temperature, perhaps improve treatment capacity, also can reduce the usage quantity of catalyzer, saved facility investment and process cost.Because the more intense hydrogenation performance of Hydrobon catalyst makes the aromatic hydrocarbons degree of depth saturated, be beneficial to selective opening more, thereby the cetane value increase rate is bigger simultaneously in hydrodenitrification.
Table 2 stock oil character
| The stock oil title | Stock oil-1 | Stock oil-2 |
| Density (20 ℃)/gcm -3 | 0.9030 | 0.9273 |
| The boiling range scope/℃ | 178~365 | 200~381 |
| Sulphur content, wt% | 0.40 | 2.10 |
| Nitrogen content, wt% | 0.07 | 0.08 |
| Cetane value | 29.0 | 20.1 |
The main composition and the character of table 3. hydrogenation catalyst
Table 4 embodiment 5 processing condition and test-results
| Processing condition | Process program 1 | Reference scheme 1 | Process program 2 | Reference scheme 2 |
| Catalyzer | A/3963 | FH-98/3963 | B/3963 | E/3963 |
| Stock oil | Raw material 1 | Raw material 1 | Raw material 1 | Raw material 1 |
| The catalyst loading volume ratio | 60∶40 | 60∶40 | 55∶45 | 55∶45 |
| Pressure/MPa | 8.0 | 8.0 | 6.0 | 6.0 |
| The inlet hydrogen to oil volume ratio | 600∶1 | 600∶1 | 700∶1 | 700∶1 |
| Air speed/h -1 | 1.0/1.5 | 1.0/1.5 | 1.2/1.5 | 1.2/1.5 |
| Temperature/℃ | 350/360 | 350/360 | 360/360 | 360/360 |
| Diesel yield, wt% | 98.7 | 97.2 | 98.1 | 97.9 |
| Diesel oil sulphur content/μ gg -1 | 4.6 | 26.5 | 5.8 | 12.4 |
| Diesel oil nitrogen content/μ gg -1 | 3.0 | 15.2 | 5.3 | 8.6 |
| Diesel cetane-number | 51.0 | 40.0 | 46.7 | 43.1 |
Continuous table 4 embodiment 5 processing condition and test-results
| Processing condition | Process program 3 | Process program 4 |
| Stock oil | Raw material 2 | Raw material 2 |
| Catalyzer | FH-98/C/FC-18 | D/3963 |
| The catalyst loading volume ratio | 30∶30∶40 | 50∶50 |
| Pressure/MPa | 10.0 | 7.0 |
| Temperature/℃ | 350/350/370 | 370/370 |
| Air speed/h -1 | 2.4/2.4/1.8 | 2.6/2.6 |
| The inlet hydrogen to oil volume ratio | 500∶1 | 1000∶1 |
| Diesel yield, wt% | 98.2 | 97.1 |
| Diesel oil sulphur content/μ gg -1 | 3.7 | 4.5 |
| Diesel oil nitrogen content/μ gg -1 | 4.9 | 1.2 |
| Diesel cetane-number | 45.7 | 44.5 |
Claims (9)
1, a kind of diesel oil fraction hydroupgrading process, comprise following content: with one or more of poor-quality diesel-oil by cut fraction is raw material, under the hydro-upgrading reaction conditions, stock oil and hydrogen order are by pre-refining reaction zone and hydro-upgrading reaction zone, the hydro-upgrading that obtains generates oil and uses in the gas circulation that gas-liquid separator separates obtains, and the liquid fractionation that obtains is gas, petroleum naphtha, diesel oil; It is characterized in that comprising at least in the described pre-refining reaction zone a kind of bulk phase catalyst bed, bulk phase catalyst contains Mo, W, three kinds of metal components of Ni, catalyzer before sulfuration W, Ni with Ni
xW
yO
z, the composite oxides form of z=x+3y exists, and Mo is with MoO
3Oxide form exists; Composite oxides Ni
xW
yO
zThe ratio of middle x and y is 1: 8~8: 1, composite oxides Ni
xW
yO
zWith oxide M oO
3Weight ratio be 1: 10~10: 1, composite oxides Ni in the bulk phase catalyst
xW
yO
zWith oxide M oO
3Gross weight content be 40%~100%.
2, in accordance with the method for claim 1, it is characterized in that composite oxides Ni in the described bulk phase catalyst
xW
yO
zThe ratio of middle x and y is 1: 4~4: 1, composite oxides Ni
xW
yO
zWith oxide M oO
3Weight ratio be 1: 5~5: 1, composite oxides Ni in the bulk phase catalyst
xW
yO
zWith oxide M oO
3Gross weight content be 50%~80%.
3, in accordance with the method for claim 1, it is characterized in that described hydro-upgrading reaction conditions is: reaction pressure 2.0~20.0MPa, hydrogen to oil volume ratio are 200: 1~2500: 1, and the cumulative volume air speed is 0.1~6.0h
-1, 310 ℃~455 ℃ of temperature of reaction.
4, in accordance with the method for claim 1, it is characterized in that described hydro-upgrading reaction conditions is: reaction pressure 3.0~19.0MPa, hydrogen to oil volume ratio 300: 1~2000: 1, volume space velocity 0.2~4.0h
-1, 320~435 ℃ of temperature of reaction.
5, in accordance with the method for claim 1, the catalyzer that it is characterized in that described pre-refining reaction zone is to be bulk phase catalyst all, or the combination of conventional Hydrobon catalyst and bulk phase catalyst; When being used in combination, the volume ratio of bulk phase catalyst and conventional catalyst is 90: 10~10: 90.
6, in accordance with the method for claim 1, the catalyst volume ratio that it is characterized in that described pre-refining reaction zone and upgrading reaction zone is 20: 80~80: 20.
7, in accordance with the method for claim 1, the catalyst volume ratio that it is characterized in that described pre-refining reaction zone and upgrading reaction zone is 30: 70~70: 30.
8, in accordance with the method for claim 1, the specific surface area that it is characterized in that described bulk phase catalyst is 120~400m
2/ g, pore volume are 0.10~0.50ml/g.
9, in accordance with the method for claim 5, when it is characterized in that being used in combination of described conventional Hydrobon catalyst and bulk phase catalyst, the volume ratio of bulk phase catalyst and conventional catalyst is 20: 80~80: 20.
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