WO2017080387A1 - 一种重油加氢处理系统和重油加氢处理方法 - Google Patents
一种重油加氢处理系统和重油加氢处理方法 Download PDFInfo
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- WO2017080387A1 WO2017080387A1 PCT/CN2016/104206 CN2016104206W WO2017080387A1 WO 2017080387 A1 WO2017080387 A1 WO 2017080387A1 CN 2016104206 W CN2016104206 W CN 2016104206W WO 2017080387 A1 WO2017080387 A1 WO 2017080387A1
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- hydrotreating
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- hydrotreating pretreatment
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- C—CHEMISTRY; METALLURGY
- C10—PETROLEUM, GAS OR COKE INDUSTRIES; TECHNICAL GASES CONTAINING CARBON MONOXIDE; FUELS; LUBRICANTS; PEAT
- C10G—CRACKING HYDROCARBON OILS; PRODUCTION OF LIQUID HYDROCARBON MIXTURES, e.g. BY DESTRUCTIVE HYDROGENATION, OLIGOMERISATION, POLYMERISATION; RECOVERY OF HYDROCARBON OILS FROM OIL-SHALE, OIL-SAND, OR GASES; REFINING MIXTURES MAINLY CONSISTING OF HYDROCARBONS; REFORMING OF NAPHTHA; MINERAL WAXES
- C10G65/00—Treatment of hydrocarbon oils by two or more hydrotreatment processes only
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- C—CHEMISTRY; METALLURGY
- C10—PETROLEUM, GAS OR COKE INDUSTRIES; TECHNICAL GASES CONTAINING CARBON MONOXIDE; FUELS; LUBRICANTS; PEAT
- C10G—CRACKING HYDROCARBON OILS; PRODUCTION OF LIQUID HYDROCARBON MIXTURES, e.g. BY DESTRUCTIVE HYDROGENATION, OLIGOMERISATION, POLYMERISATION; RECOVERY OF HYDROCARBON OILS FROM OIL-SHALE, OIL-SAND, OR GASES; REFINING MIXTURES MAINLY CONSISTING OF HYDROCARBONS; REFORMING OF NAPHTHA; MINERAL WAXES
- C10G45/00—Refining of hydrocarbon oils using hydrogen or hydrogen-generating compounds
- C10G45/72—Controlling or regulating
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- C—CHEMISTRY; METALLURGY
- C10—PETROLEUM, GAS OR COKE INDUSTRIES; TECHNICAL GASES CONTAINING CARBON MONOXIDE; FUELS; LUBRICANTS; PEAT
- C10G—CRACKING HYDROCARBON OILS; PRODUCTION OF LIQUID HYDROCARBON MIXTURES, e.g. BY DESTRUCTIVE HYDROGENATION, OLIGOMERISATION, POLYMERISATION; RECOVERY OF HYDROCARBON OILS FROM OIL-SHALE, OIL-SAND, OR GASES; REFINING MIXTURES MAINLY CONSISTING OF HYDROCARBONS; REFORMING OF NAPHTHA; MINERAL WAXES
- C10G65/00—Treatment of hydrocarbon oils by two or more hydrotreatment processes only
- C10G65/02—Treatment of hydrocarbon oils by two or more hydrotreatment processes only plural serial stages only
- C10G65/04—Treatment of hydrocarbon oils by two or more hydrotreatment processes only plural serial stages only including only refining steps
- C10G65/08—Treatment of hydrocarbon oils by two or more hydrotreatment processes only plural serial stages only including only refining steps at least one step being a hydrogenation of the aromatic hydrocarbons
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- C—CHEMISTRY; METALLURGY
- C10—PETROLEUM, GAS OR COKE INDUSTRIES; TECHNICAL GASES CONTAINING CARBON MONOXIDE; FUELS; LUBRICANTS; PEAT
- C10G—CRACKING HYDROCARBON OILS; PRODUCTION OF LIQUID HYDROCARBON MIXTURES, e.g. BY DESTRUCTIVE HYDROGENATION, OLIGOMERISATION, POLYMERISATION; RECOVERY OF HYDROCARBON OILS FROM OIL-SHALE, OIL-SAND, OR GASES; REFINING MIXTURES MAINLY CONSISTING OF HYDROCARBONS; REFORMING OF NAPHTHA; MINERAL WAXES
- C10G2300/00—Aspects relating to hydrocarbon processing covered by groups C10G1/00 - C10G99/00
- C10G2300/10—Feedstock materials
- C10G2300/1003—Waste materials
- C10G2300/1007—Used oils
Definitions
- the invention relates to the field of heavy oil hydrotreating, in particular to a heavy oil hydrotreating system and a heavy oil hydrotreating method.
- the main purpose of heavy oil hydrotreating process is to reduce the content of sulfur, nitrogen, metals and other impurities in the residue raw material by hydrotreating, and the non-ideal of polycyclic aromatic hydrocarbons, colloids and asphaltenes. Hydrogenation of the components, increasing the hydrogen to carbon ratio, reducing the residual carbon content, and significantly improving the cracking performance.
- Fixed bed residue oil hydrogenation technology is a heavy oil deep processing technology. Desulfurization and denitrification of atmospheric or vacuum residue are carried out under high temperature and high pressure hydrogenation conditions in a fixed bed reactor equipped with a specific catalyst. Demetallization, etc., to maximize the access to lightweight products, is one of the important means of lightweighting of residual oil.
- the fixed bed residual oil hydrogenation technology has been widely used for its high liquid product yield, good product quality, strong production flexibility, less waste, waste, environmental friendliness and high return on investment.
- the main function is Interception and deposition of impurities and scales in the feedstock, only a lower demetallization reaction, usually the reactor temperature rise is lower, the pressure drop is maintained at a lower level throughout the operating cycle, thus requiring subsequent
- the demetallization reactor is filled with a large amount of demetallization catalyst to mainly carry out the demetallization reaction and provide sufficient space for containing the metal compound and carbon deposit for hydrotreating, which inevitably causes a large amount of deposition in the demetallization reactor.
- Metal, demetallization reaction load is large, usually the reactor temperature rise is the highest, although the reactor pressure drop is low in the initial stage of operation, but the pressure drop of the reactor increases first and the fastest in the middle to the middle of operation. It becomes the main factor that restricts the operation cycle and the stable operation of the device.
- CN103059928A discloses a hydrotreating unit and its use and a residue hydrotreating method.
- the invention provides a hydrotreating unit comprising a hydrogenation protection unit and a main hydroprocessing unit in series, the hydroprotection unit comprising a main hydrogenation protection reactor and a backup hydrogenation protection reactor in parallel And the main hydrogenation protection reactor volume is larger than the backup protection reactor.
- the main hydrogenation protection reactor is used alternately with the standby hydrogenation protection reactor.
- the process shifts the main hydrogenation protection reactor and the backup hydrogenation protection reactor, and is capable of processing high calcium and high metal content residue.
- the disadvantage is that a reactor is idle, which increases investment and reduces reactor utilization. And can not fundamentally solve the problem of pre-reactor pressure drop growth.
- CN1393515A discloses a method of hydrotreating residue.
- the method is to add one or more feed ports in the first reactor in the heavy residue hydrogenation reaction system, while changing the original catalyst grading, when a countercatalyst bed is laminated to the device design pressure drop. 0.4 to 0.8 times, the next feed port is used in turn, and the original feed port can be mixed with circulating oil or circulating oil and feedstock oil.
- the process can effectively prevent the bed lamination and the operating period of the extension device, and can increase the processing capacity of the device and help to improve the distribution of the logistics.
- the disadvantage is that the manufacturing cost of the inductor is increased, the initial pressure drop is increased, and the volume utilization rate in the device is lowered.
- CN103059931A discloses a method of hydrotreating residue.
- the method is characterized in that under the hydrotreating reaction condition, the residue raw material and the hydrogen gas are sequentially passed through a plurality of reactors connected in series, and after the operation of the apparatus for 700 to 4000 hours, a split operation is performed to reduce the amount of one reverse feed or maintain a reverse feed amount. Constantly, the feed amount of each reactor in the middle of the last reactor is increased, and the increased raw material residue is injected at the inlet of the intermediate reactor.
- the method can alleviate the increase of pressure drop by changing the feed load of each reactor, but can not fundamentally change the growth trend of the pressure drop of the pre-reactor. From the perspective of industrial actual operation, once the pressure drop begins to increase, it will quickly reach the design limit. And changing the inlet of each reactor inlet is not conducive to stable operation of the unit.
- CN102676218A discloses a fixed bed residue oil hydrogenation process comprising the following steps: (1) a mixture of feedstock oil and hydrogen enters a first fixed bed reactor, and is contacted with a hydrogenation catalyst for hydrogenation reaction; (2) when first fixed When the bed reactor pressure drop is increased to 0.2-0.8 MPa, the feedstock oil and hydrogen mixture enters the first fixed bed reactor and the alternate first fixed bed reactor, and the reaction product enters the subsequent hydrogenation reactor.
- the first fixed bed reactor and the alternate first fixed bed reactor may be used in parallel, in series, or one of them may be used alone to use the other reactor alone.
- the disadvantage is that a reactor is idle at the beginning, which reduces the reactor utilization rate, and does not fundamentally solve the problem of the pressure drop of the pre-reactor.
- CN103540349A discloses a combined process of inferior heavy oil and residue hydrotreating, comprising heavy oil and/or residue raw materials being subjected to slurry bed hydrotreating pretreatment, and after liquid-liquid separation, liquid phase products are further subjected to fixed bed hydrotreating.
- the slurry bed hydrotreating pretreatment section comprises a slurry bed hydrogenation reactor and a slurry bed hydrogenation catalyst;
- the reactor used in the fixed bed hydro-upgrading section mainly comprises: two upflow deferred decalcification reactions , an upflow demetallization reactor, a fixed bed desulfurization reactor, a fixed bed denitrification reactor, wherein two upflow deferred decalcification reactors can be connected in series, in parallel, or one of them can be used alone Use another reactor.
- the disadvantage is that the operation cycle of each process type is not matched, the investment is high, and the operation is difficult.
- the object of the present invention is to overcome the defects that the existing heavy oil hydrotreating method cannot fundamentally solve the problem of reactor pressure drop growth, thereby affecting the operation cycle and stability of the device, and providing a heavy oil hydrotreating system and heavy oil. Hydrotreating process.
- the method of the invention has simple process flow, and only needs simple improvement of the existing device, the operation cycle of the heavy oil hydrotreating device can be greatly extended, and the utilization efficiency of the catalyst can be maximized.
- the present invention provides a heavy oil hydrotreating system comprising a hydrocracking reaction zone, a transition reaction zone and a hydrotreating reaction zone, and a sensing unit and a control unit, which are sequentially connected in series, the sensing unit For detecting a pressure drop in each of the hydrotreating pretreatment reactors in the hydrotreating pretreatment reaction zone, the control unit for receiving a pressure drop signal from the sensing unit;
- the hydrotreating pretreatment reaction zone comprises at least two hydrocracking reactors connected in parallel with each other, the transition reaction zone including or not including a hydrotreating pretreatment reactor;
- control unit controls the feeding and discharging of each hydrotreating pretreatment reactor in the hydrotreating pretreatment reaction zone according to the pressure drop signal of the sensing unit, so that when the hydrogenation is performed
- the hydrotreating pretreatment reactor having a pressure drop reaching a predetermined value is switched from the hydrotreating pretreatment reaction zone to the transition reaction Area.
- the pressure drop of the hydrotreating pretreatment reactor is predetermined to be 50% to 80%, preferably 60%, of the upper limit of the pressure drop design of the hydrotreating reactor. ⁇ 70%.
- the hydrotreating reaction zone comprises from 3 to 6, preferably from 3 to 4 hydrotreating reactors.
- the transition reaction zone does not include a hydrotreating pretreatment reactor in an initial stage of the reaction; moreover, the control unit controls the hydrotreating pretreatment according to a pressure drop signal of the sensing unit Feeding and discharging of each hydrotreating pretreatment reactor in the reaction zone results in:
- the hydrotreating pretreatment reactor When the pressure drop of a hydrotreating pretreatment reactor reaches the predetermined value, the hydrotreating pretreatment reactor is switched from the hydrotreating pretreatment reaction zone to the transition reaction zone, and the hydrotreating pretreatment reaction is performed.
- the reactor is named as the cut-off hydrotreating pretreatment reactor I, and the hydrotreating pretreatment reaction zone, the cut-off hydrotreating pretreatment reactor I and the The hydrotreating reaction zones are connected in series in series;
- the hydrotreating pretreatment reactor is switched from the hydrotreating pretreatment reaction zone to the transition reaction zone, and the hydrotreating pretreatment reaction is performed.
- the device is named as a cut-off hydrotreating pretreatment reactor II, and the hydrotreating pretreatment reaction zone, the cut-off hydrotreating pretreatment reactor II, the cut-off hydrotreating pretreatment reactor I And the hydrotreating reaction zones are sequentially connected in series;
- the hydrotreating reaction zone comprises from 1 to 5 hydrotreating reactors arranged in series, preferably comprising from 1 to 2 hydrotreating reactors arranged in series.
- the discharge port of any one of the hydrotreating pretreatment reactors and the feed port of the other hydrotreating pretreatment reactor and the hydrotreating reaction are connected by a pipeline with a control valve, and the feed port of any one of the hydrotreating pretreatment reactor and the supply source of the mixture flow of the heavy oil feedstock and the hydrogen gas are connected through a pipeline with a control valve, wherein The control unit controls the feed and discharge by controlling the control valves corresponding to the respective hydroprocessing reactors.
- the invention also provides a heavy oil hydrotreating method, which comprises: mixing a heavy oil raw material with hydrogen, and then passing through a series of hydrotreating pretreatment reaction zone, a transition reaction zone and a hydrotreating reaction zone;
- the hydrotreating pretreatment reaction zone comprises at least two hydrocracking reactors connected in parallel with each other, the transition reaction zone including or not including a hydrotreating pretreatment reactor;
- the hydrocracking reactor having a pressure drop of a predetermined value is from the hydrogenation
- the pretreatment reaction zone is switched to the transition reaction zone, wherein the pressure drop of the hydrotreating pretreatment reactor is predetermined to be 50% to 80%, preferably 60, of the upper limit of the pressure drop design of the hydrotreating reactor. % ⁇ 70%.
- the hydrotreating reaction zone comprises from 3 to 6, preferably from 3 to 4 hydrotreating reactors.
- the transition reaction zone does not include a hydrotreating pretreatment reactor; and, when the pressure drop of a hydrotreating pretreatment reactor reaches the predetermined value, the addition is a hydrogen pretreatment reactor is switched from the hydrotreating pretreatment reaction zone to the transition reaction zone, the hydrotreating pretreatment reactor is named as a cut hydrogenation pretreatment reactor I, and the hydrogenation pretreatment is Treating the reaction zone, the cut-off hydrotreating pretreatment reactor I and the hydrotreating reaction zone are connected in series in series;
- the hydrotreating pretreatment reactor is switched from the hydrotreating pretreatment reaction zone to the transition reaction zone, and the hydrotreating pretreatment reaction is performed.
- the device is named as a cut-off hydrotreating pretreatment reactor II, and the hydrotreating pretreatment reaction zone, the cut-off hydrotreating pretreatment reactor II, the cut-off hydrotreating pretreatment reactor I And the hydrotreating reaction zones are sequentially connected in series;
- the pressure drop of all the hydrotreating pretreatment reactors does not reach a predetermined value at the same time, and preferably the time difference between the two adjacent hydrotreating reactors which are closest to the predetermined value of the pressure drop reaches a predetermined value of the pressure drop. Less than 20% of the entire operating cycle, preferably 20% to 60%.
- the respective hydrotreating pretreatment reactors in the hydrotreating pretreatment reaction zone do not simultaneously reach a predetermined pressure drop value by the setting of operating conditions and/or the difference in catalyst bed properties,
- different catalyst loading densities are used by controlling different catalyst loading heights, different feed amounts, different feed properties, different operating conditions, and the same loading height in each hydrotreating pretreatment reactor.
- the maximum of each hydrotreating pretreatment reactor in parallel in the hydrotreating pretreatment reaction zone packing density 400kg / m 3 ⁇ 600kg / m 3, preferably 450kg / m 3 ⁇ 550kg / m 3; the minimum packing density of 300kg / m 3 ⁇ 550kg / m 3, preferably 350kg / m 3 ⁇ 450kg / m 3 ;
- the two hydrotreating pretreatment reactors having the closest packing density have a catalyst packing density difference of 50 to 200 kg/m 3 , preferably 80 to 150 kg/m 3 .
- the ratio of the feed volume to the space velocity of the two hydrotreating pretreatment reactors with the closest feed amount is 1.1 to 3:1. Preferably, it is 1.1 to 1.5:1.
- the difference in the metal content of the two hydrotreating pretreatment reactors having the closest feed properties is 5 to 50 ⁇ g/g, preferably 10 to 30 ⁇ g / g.
- the operating temperature difference is 2 ⁇ 30° C., preferably 5 to 20° C.; or the operating conditions of the two hydrotreating pretreatment reactors that control the operating pressure and the operating temperature are the closest, the volume space velocity difference is 0.1 to 10 h ⁇ 1 , preferably 0.2 ⁇ 5h -1 .
- a hydrogenation preservative, a hydrodemetallization catalyst, and an optional hydrodesulfurization catalyst are sequentially charged according to the flow direction of the material; the reactor in the hydrotreating reaction zone is in turn The hydrodesulfurization catalyst and the hydrodenitrogenation residual carbon conversion catalyst are loaded.
- the operating conditions of the hydrotreating pretreatment reaction zone include: a temperature of 370 ° C to 420 ° C, preferably 380 ° C to 400 ° C; a pressure of 10 MPa to 25 MPa, preferably 15 MPa to 20 MPa; a hydrogen oil volume ratio 300 to 1,500, preferably 500 to 800; hourly space velocity of the feedstock oil 0.15h -1 ⁇ 2h -1, preferably from 0.3h -1 ⁇ 1h -1.
- the hydrotreating reaction zone comprises 1 to 5 hydrotreating reactors arranged in series, preferably It is selected to include 1 to 2 hydrotreating reactors arranged in series.
- the operating conditions of the hydrotreating reaction zone comprise: a temperature of from 370 ° C to 430 ° C, preferably from 380 ° C to 410 ° C; a pressure of from 10 MPa to 25 MPa, preferably from 15 MPa to 20 MPa; and a hydrogen to oil volume ratio of 300 to 1,500, preferably from 400 to 800; hourly space velocity of the feedstock oil 0.15h -1 ⁇ 0.8h -1, preferably from 0.2h -1 ⁇ 0.6h -1.
- the heavy oil feedstock is selected from the group consisting of atmospheric heavy oil and/or vacuum residue, and more preferably, the heavy oil feedstock is blended with straight-run wax oil, vacuum wax oil, secondary processing wax oil, and catalytic recovery. At least one of refining.
- the hydrotreating pretreatment reaction zone includes a plurality of hydrocracking reactors connected in parallel, so that the ability of the entire catalyst system to remove/capacitance metal is greatly improved.
- the hydrotreating pretreatment reactor pressure is solved by adjusting the operation mode of each hydrotreating pretreatment reactor in the hydrotreating pretreatment reaction zone from parallel to series switching operation mode. The problem of rapid growth is reduced, while increasing the operational flexibility and material adaptability of the device.
- the amount of metal contained in the catalyst system is greatly increased by providing a parallel form of the hydrotreating pretreatment reactor, so that the stability of the system is enhanced, so that the growth of the device pressure drop can be obtained. Control, extend the operating cycle of the device.
- the heavy oil hydrotreating method according to the present invention can achieve synchronous deactivation of various types of catalysts to the greatest extent, thereby improving the operating efficiency of the device and improving economic benefits.
- FIG. 1 is a schematic illustration of one embodiment of a heavy oil hydrotreating system of the present invention.
- the heavy oil hydrotreating system comprises a hydrotreating pretreatment reaction zone, a transition reaction zone and a hydrotreating reaction zone and a sensing unit and a control unit which are sequentially connected in series, and the sensing unit is used for detecting the addition a pressure drop in each of the hydrotreating pretreatment reactors in the hydrogen pretreatment reaction zone, the control unit for receiving a pressure drop signal from the sensing unit;
- the hydrotreating pretreatment reaction zone comprises at least two hydrocracking reactors connected in parallel with each other, the transition reaction zone including or not including a hydrotreating pretreatment reactor;
- control unit controls the feeding and discharging of each hydrotreating pretreatment reactor in the hydrotreating pretreatment reaction zone according to the pressure drop signal of the sensing unit, so that when the hydrogenation is performed
- the hydrotreating pretreatment reactor having a pressure drop reaching a predetermined value is switched from the hydrotreating pretreatment reaction zone to the transition reaction Area.
- the predetermined value of the hydrotreating pretreatment reactor is preferably 50% to 80% of the upper limit of the pressure drop design of the hydrotreating pretreatment reactor, for example, 50%, 52%, 54%, 55%, 56%, 57%, 58%, 60%, 61%, 62%, 63%, 64%, 65%, 66%, 67%, 68%, 69%, 70% Any value between 71%, 72%, 74%, 75%, 76%, 78%, 80% and any two of them.
- the predetermined value is from 60% to 70% of the upper limit of the pressure drop design.
- the upper limit of the pressure drop design refers to the maximum value of the pressure drop of the reactor. When the pressure drop of the reactor reaches this value, the reaction system needs to be shut down, and the upper limit of the pressure drop design is usually 0.7 to 1 MPa.
- the transition reaction zone may or may not include a hydrotreating pretreatment reactor during the initial stage of the reaction.
- the transition reaction zone does not include a hydrotreating pretreatment reactor during the initial stage of the reaction.
- At least one hydrotreating pretreatment reactor is included in the hydrotreating pretreatment reaction zone during the reaction. Moreover, when the hydrotreating pretreatment reaction zone has only two hydrotreating pretreatment reactors in the initial stage of the reaction, the hydrotreating pretreatment reactor is switched from the hydrotreating pretreatment reaction zone to the transition reaction zone. The operation only needs to be performed once; when the hydrotreating pretreatment reaction zone has more than three hydrotreating pretreatment reactors in the initial stage of the reaction, the hydrotreating pretreatment reactor is taken from the hydrotreating pretreatment reaction zone. Switch to The operation of the transition reaction zone can be carried out one or more times.
- the hydrotreating reaction zone comprises from 3 to 6, preferably from 3 to 4 hydrotreating reactors. Further preferably, the operation of switching the hydrotreating pretreatment reactor from the hydrotreating pretreatment reaction zone to the transition reaction zone is carried out such that the hydrotreating pretreatment reaction zone has only one hydrotreating pretreatment at the end of the reaction. reactor.
- the transition reaction zone may or may not include a hydrotreating pretreatment reactor during the initial stage of the reaction.
- the plurality of hydrotreating pretreatment reactors in the transition reaction zone may be connected to each other in series and/or in parallel; preferably, the plurality of hydrotreating pretreatment reactors in the transition reaction zone are connected to each other; most preferably, The plurality of hydrotreating pretreatment reactors in the transition reaction zone are arranged in series with each other, and the hydrotreating reaction is first switched out from the hydrotreating pretreatment reaction zone along the flow direction of the transition reaction zone
- the hydrotreating reactors arranged downstream and later switched out are arranged upstream.
- the transition reaction zone does not include a hydrotreating pretreatment reactor, and the hydrotreating pretreatment reaction zone comprises 3 to 6, preferably 3 to 4 hydrotreating pretreatment reactors;
- control unit controls the feeding and discharging of each hydrotreating pretreatment reactor in the hydrotreating pretreatment reaction zone according to the pressure drop signal of the sensing unit, such that:
- the hydrotreating pretreatment reactor When the pressure drop of a hydrotreating pretreatment reactor reaches the predetermined value, the hydrotreating pretreatment reactor is switched from the hydrotreating pretreatment reaction zone to the transition reaction zone, and the hydrotreating pretreatment reaction is performed.
- the device is named as the cut-off hydrotreating pretreatment reactor I, and the hydrotreating pretreatment reaction zone, the cut-off hydrotreating pretreatment reactor I and the hydrotreating reaction zone are sequentially connected in series. connect them;
- the hydrotreating pretreatment reactor is switched from the hydrotreating pretreatment reaction zone to the transition reaction zone, and the hydrotreating pretreatment reaction is performed.
- the device is named as a cut-off hydrotreating pretreatment reactor II, and the hydrotreating pretreatment reaction zone, the cut-off hydrotreating pretreatment reactor II, the cut-off hydrotreating pretreatment reactor I And the hydrotreating reaction zones are sequentially connected in series;
- all of the hydrotreating pretreatment reactors are connected in series.
- the hydrotreating pretreatment reaction zone which reaches the predetermined value of the pressure drop in the order of reaching the predetermined value of the pressure drop, the hydrotreating pretreatment reaction zone which reaches the predetermined value of the pressure drop is downstream, and then reaches a predetermined value of the pressure drop.
- the hydrotreating pretreatment reaction zone is upstream and the hydrotreating pretreatment reactor which first reaches the predetermined pressure drop is at the most downstream position.
- the discharge port of any one of the hydrotreating pretreatment reactors and other hydrogenation is connected by a pipeline with a control valve, and any one of the hydrotreating pretreatments
- the feed source of the reactor and the supply of the mixture of the heavy oil feedstock and the hydrogen are all connected via a line with a control valve, wherein the control unit controls the control by controlling the respective control valves corresponding to the respective hydrotreatment reactors. Material and discharge.
- the hydrotreating reaction zone may comprise from 1 to 5 hydrotreating reactors arranged in series, preferably comprising from 1 to 2 hydrotreating reactors arranged in series.
- FIG. 1 is a schematic illustration of a preferred embodiment of a heavy oil hydrotreating system of the present invention.
- the heavy oil hydrotreating process and the heavy oil hydrotreating system according to the present invention will be further described below with reference to Fig. 1, but the invention is not limited thereby.
- the heavy oil hydrotreating system and the heavy oil hydrotreating method according to the present invention comprise: the material F mixed with the heavy oil raw material and the hydrogen is fed into the series through the feed line 1, the feed line 2 and the feed line 3. a hydrotreating pretreatment reaction zone and a hydrodesulfurization reaction zone, wherein the hydrotreating pretreatment reaction zone comprises three hydrotreating pretreatment reactors arranged in parallel, respectively, a hydrotreating pretreatment reactor A, and a hydrotreating pretreatment Reactor B, hydrotreating pretreatment reactor C, the feed ports of the hydrotreating pretreatment reactor A, the hydrotreating pretreatment reactor B, and the hydrotreating pretreatment reactor C are respectively fed to the feed line 1, respectively
- the pipeline 2 is connected to the feed line 3, and the outlet of the hydrotreating pretreatment reactor A is divided into three paths, the first passage is connected to the feed port of the hydrotreating pretreatment reactor B via the pipeline 6, and the second passage is via the pipeline 7 Connected to the feed port of the hydrotreating pretreatment reactor C,
- the pipeline 1 is provided with a valve 101
- the pipeline 2 is provided with a valve 102
- the pipeline 3 is provided with a valve 103
- the pipeline 4 is provided with a valve 104
- the pipeline 5 is provided with a valve 105 is disposed on the pipeline 6 with a valve 106.
- the pipeline 7 is provided with a valve 107.
- the pipeline 8 is provided with a valve 108.
- the pipeline 9 is provided with a valve 109.
- the pipeline 10 is provided with a valve 109.
- the valve 1010 is provided with a valve 1011 on the pipeline 11, and the pipeline 12 is provided with a valve 1012.
- the produced oil obtained by the hydrodesulfurization reactor enters the separator E and is separated to obtain a liquefied gas 14 and a hydrogenated oil.
- the hydrogenated oil may also be further fractionated into a plurality of fractions.
- the hydrotreating pretreatment reactor A, the hydrotreating pretreatment reactor B, and the hydrotreating pretreatment reactor C are each provided with a sensing unit (not shown) for monitoring the pressure drop, and
- the heavy oil hydrotreating system further includes a control unit (not shown) for receiving a pressure drop signal from the sensing unit and controlling the respective hydrotreating pretreatment reactors according to the pressure drop signal valve.
- hydrotreating pretreatment reactor A hydrotreating pretreatment reactor B and hydrogenation pretreatment
- the treatment reactor C can be deactivated in any order, preferably in the following six ways:
- Method 1 The pressure drop predetermined value is reached in the order of the hydrotreating pretreatment reactor A, the hydrotreating pretreatment reactor B, and the hydrotreating pretreatment reactor C.
- valve 1011 of the line 11 and the valve 1012 of the line 12 open the valve 108 on the line 8 and the valve 104 on the line 4, so that the hydrotreating pretreatment reaction zone (including the hydrotreating pretreatment reactor B and the hydrotreating pretreatment reaction) The C), the hydrotreating pretreatment reactor A and the hydrodesulfurization reaction zone form a series connection, and at this time, the switching operation from parallel to series is completed once;
- the pressure drop of the hydrotreating pretreatment reactor B reaches a predetermined value
- the pressure drop signal from the sensing unit corresponding to the hydrotreating pretreatment reactor B is transmitted to the control unit, and the control unit receives the signal Thereafter, the valve is regulated, specifically, the valve 102 of the feed line 2, the valve 108 of the line 8 is closed, and the valve 109 on the line 9 is opened to make the hydrotreating pretreatment reactor C, the hydrotreating pretreatment reactor B,
- the hydrotreating pretreatment reactor A and the hydrodesulfurization reaction zone are connected in series, and at this time, the second switching operation from parallel to series is completed;
- Mode 2 The pressure drop predetermined value is reached in the order of the hydrotreating pretreatment reactor A, the hydrotreating pretreatment reactor C, and the hydrotreating pretreatment reactor B.
- valve 1011 of the line 11 and the valve 1012 of the line 12 open the valve 108 on the line 8 and the valve 104 on the line 4 to make the hydrotreating pretreatment reaction zone (including hydro-pretreatment reactor B and hydro-pretreatment reactor C), hydro-pretreatment reactor A and hydrodesulfurization reaction zone form a series connection, at this time complete a switching operation from parallel to series;
- Mode 3 The pressure drop predetermined value is reached in the order of the hydrotreating pretreatment reactor B, the hydrotreating pretreatment reactor C, and the hydrotreating pretreatment reactor A.
- Valve 1010 of line 10 and valve 1012 of line 12 open valve 109 on line 9 and valve 106 on line 6 to provide a hydrotreating pretreatment reaction zone (including hydrotreating reactor A and hydrotreating reaction)
- the C), the hydrotreating pretreatment reactor B and the hydrodesulfurization reaction zone are connected in series, and at this time, the switching operation from parallel to series is completed once;
- the pressure drop of the hydrotreating pretreatment reactor C reaches a predetermined value
- the pressure drop signal from the sensing unit corresponding to the hydrotreating pretreatment reactor C is transmitted to the control unit, and the control unit receives the signal Thereafter, the valve is regulated, specifically, the valve 103 of the feed line 3, the valve 106 of the line 6 is closed, and the valve 107 on the line 7 is opened to make the hydrotreating pretreatment reactor A, the hydrotreating pretreatment reactor C,
- the hydrotreating pretreatment reactor B and the hydrodesulfurization reaction zone form a series connection, and at this time, the second switching operation from parallel to series is completed;
- Mode 4 The pressure drop predetermined value is reached in the order of the hydrotreating pretreatment reactor B, the hydrotreating pretreatment reactor A, and the hydrotreating pretreatment reactor C.
- Valve 1010 of line 10 and valve 1012 of line 12 open valve 109 on line 9 and valve 106 on line 6 to provide a hydrotreating pretreatment reaction zone (including hydrotreating reactor A and hydrotreating reaction)
- the C), the hydrotreating pretreatment reactor B and the hydrodesulfurization reaction zone are connected in series, and at this time, the switching operation from parallel to series is completed once;
- Mode 5 The pressure drop predetermined value is reached in the order of the hydrotreating pretreatment reactor C, the hydrotreating pretreatment reactor B, and the hydrotreating pretreatment reactor A.
- valve 1010 of the line 10 and the valve 1011 of the line 11 open the valve 107 on the line 7 and the valve 105 on the line 5, so that the hydrotreating pretreatment reaction zone (including the hydrotreating pretreatment reactor A and the hydrotreating reaction)
- the B), the hydrotreating pretreatment reactor C and the hydrodesulfurization reaction zone form a series connection, and at this time, the switching operation from parallel to series is completed once;
- Mode 6 A predetermined pressure drop value is obtained in the order of the hydrotreating pretreatment reactor C, the hydrotreating pretreatment reactor A, and the hydrotreating pretreatment reactor B.
- valve 1010 of the line 10 and the valve 1011 of the line 11 open the valve 107 on the line 7 and the valve 105 on the line 5, so that the hydrotreating pretreatment reaction zone (including the hydrotreating pretreatment reactor A and the hydrotreating reaction)
- the B), the hydrotreating pretreatment reactor C and the hydrodesulfurization reaction zone form a series connection, and at this time, the switching operation from parallel to series is completed once;
- the heavy oil hydrotreating method of the present invention comprises: mixing the heavy oil raw material with hydrogen, and then passing through the hydrogenation pretreatment reaction zone, the transition reaction zone and the hydrotreating reaction zone in series;
- the hydrotreating pretreatment reaction zone comprises at least two hydrocracking reactors connected in parallel with each other, the transition reaction zone including or not including a hydrotreating pretreatment reactor;
- the hydrocracking reactor having a pressure drop of a predetermined value is from the hydrogenation
- the pretreatment reaction zone is switched to the transition reaction zone.
- the hydrotreating pretreatment reaction zone A hydrogenation pretreatment reactor comprising at least two parallel arrangements is included.
- the pressure drop of each hydrotreating pretreatment reactor gradually reaches a predetermined value, and the hydrotreating reactor which gradually reduces the pressure drop to a predetermined value is switched from the hydrotreating pretreatment reaction zone to the The transition reaction zone is until there is only one hydrotreating pretreatment reactor in the hydrotreating reaction zone.
- the hydrotreating pretreatment reaction zone comprises two hydrotreating pretreatment reactors arranged in parallel in the initial stage of the reaction, during the reaction, any hydrotreating pretreatment reaction in the hydrotreating pretreatment reaction zone
- the hydrotreating reactor having a pressure drop reaching a predetermined value is switched from the hydrotreating pretreatment reaction zone to the transition reaction zone until the remaining one in the hydrotreating pretreatment reaction zone
- the pressure drop of a hydrotreating pretreatment reactor reaches the upper design limit (usually 0.7 to 1 MPa)
- the entire reaction process is completed and the entire reaction system needs to be shut down.
- the hydrotreating pretreatment reaction zone comprises three or more (preferably 3-6, more preferably 3-4) parallel hydrocracking reactors in the initial stage of the reaction, and the transition reaction zone does not include addition
- the hydrotreating pretreatment reactor is switched from the hydrotreating pretreatment reaction zone to the In the transition reaction zone, the hydrotreating pretreatment reactor is named as the cut hydrogenation pretreatment reactor I, and the hydrotreating pretreatment reaction zone, the cut hydrogenation pretreatment reactor I and the The hydrotreating reaction zones are connected in series in series;
- the hydrotreating pretreatment reactor is cut out from the hydrotreating pretreatment reaction zone, and the hydrotreating pretreatment reactor is named as cut out.
- Hydrotreating the pretreatment reactor II, and the hydrotreating pretreatment reaction zone, the cut hydrogenation pretreatment reactor II, the cut hydrogenation pretreatment reactor I, and the hydrotreating The reaction zones are connected in series in series;
- all of the hydrotreating pretreatment reactors are connected in series.
- the hydrotreating pretreatment reaction zone which reaches the predetermined value of the pressure drop in the order of reaching the predetermined value of the pressure drop, the hydrotreating pretreatment reaction zone which reaches the predetermined value of the pressure drop is downstream, and then reaches a predetermined value of the pressure drop.
- the hydrotreating pretreatment reaction zone is upstream and the hydrotreating pretreatment reactor which first reaches the predetermined pressure drop is at the most downstream position.
- the predetermined value is 50% to 80% of the upper limit of the pressure drop design, for example, 50%, 52%, 54%, 55%, 56%, 57%, 58 %, 60%, 61%, 62%, 63%, 64%, 65%, 66%, 67%, 68%, 69%, 70%, 71%, 72%, 74%, 75%, 76%, Any value between 78%, 80%, and the range of any two of them.
- the predetermined value is from 60% to 70% of the upper limit of the pressure drop design.
- the upper limit of the pressure drop design refers to the maximum value of the pressure drop of the reactor. When the pressure drop of the reactor reaches this value, the reaction system needs to be shut down, and the upper limit of the pressure drop design is usually 0.7 to 1 MPa.
- the pressure drop of all of the hydrotreating pretreatment reactors does not reach a predetermined value at the same time.
- the time difference between the two adjacent hydro-pretreatment reactors closest to the predetermined value of the pressure drop reaching a predetermined value of the pressure drop is not less than 20% of the entire operating cycle, preferably 20-60% of the entire operating cycle. ,example For example, 20%, 25%, 30%, 35%, 40%, 45%, 50%, 55%, 60%.
- the entire operating cycle refers to the time elapsed from the start of the heavy oil hydrotreating system to the shutdown.
- each hydrotreating pretreatment reactor in the hydrotreating pretreatment reaction zone In order to achieve a predetermined value of pressure drop for each hydrotreating pretreatment reactor in the hydrotreating pretreatment reaction zone, it can be carried out by setting the operating conditions and/or the difference in catalyst bed properties. Preferably, different catalyst loading densities are employed by controlling different catalyst loading heights, different feed amounts, different feed properties, different operating conditions, and the same loading height in each hydrotreating pretreatment reactor. One or more ways are achieved to achieve a predetermined pressure drop for each hydrotreating pretreatment reactor in the hydrotreating pretreatment reaction zone.
- the maximum packing density may be from 400 kg/m 3 to 600 kg/m 3 , preferably from 450 kg/m 3 to 550 kg/m 3 ; and the minimum packing density may be from 300 kg/m 3 to 550 kg/m 3 , preferably 350kg/m 3 to 450kg/m 3 .
- the two hydrotreating pretreatment reactors having the closest packing density have a catalyst packing density difference of 50 to 200 kg/m 3 , preferably 80 to 150 kg/m 3 .
- the catalyst packing density of the hydrocracking reactor which is first cut out is set to the maximum, and the catalyst packing density of the hydrocut pretreatment reactor which is finally cut out is set to the minimum, and is cut out successively.
- the catalyst packing density of the hydrotreating pretreatment reactor is gradually decreased.
- Different catalyst packing densities can be achieved by different types of catalyst grade loading, such as catalyst loading in each hydrotreating pretreatment reactor by hydrogenation inhibitor, hydrodemetallization catalyst, hydrodesulfurization catalyst in different ratios. The density is different.
- the feed volume airspeed of the two hydrotreating pretreatment reactors with the closest feed amount is achieved by controlling the different feed amounts in the respective hydrotreating pretreatment reactors.
- the ratio may be from 1.1 to 3:1, preferably from 1.1 to 1.5:1.
- the difference in the metal content of the two hydrotreating pretreatment reactors with the closest feed properties can be It is 5 to 50 ⁇ g/g, preferably 10 to 30 ⁇ g/g.
- the operating conditions of the two hydroprocessing reactors that control the operating pressure and volumetric space velocity are the same when controlled by controlling different operating conditions within each hydrotreating reactor.
- the operating temperature difference may be 2 to 30 ° C, preferably 5 to 20 ° C; or the operating conditions of the two hydrotreating pretreatment reactors that control the operating pressure and the operating temperature are the closest, the volumetric airspeed difference may be 0.1 to 10 h -1 , preferably 0.2 to 5 h -1 .
- the operating conditions of the hydrotreating pretreatment reaction zone may include: a temperature of 370 ° C to 420 ° C, preferably 380 ° C to 400 ° C; a pressure of 10 MPa to 25 MPa, preferably is 15MPa ⁇ 20MPa; hydrogen oil ratio of 300 to 1500, preferably 500 to 800; hourly space velocity of the feedstock oil 0.15h -1 ⁇ 2h -1, preferably from 0.3h -1 ⁇ 1h -1.
- pressure refers to the hydrogen partial pressure at the inlet of the reactor.
- the average reaction temperature of the hydrotreating pretreatment reaction zone is significantly higher than that of the prior art heavy oil hydrodemetallization reactor, and the prior art heavy oil hydrodemetallization reaction temperature is usually 350 ° C to 390 °C.
- the hydrogenation pretreatment reaction zone provided in the front part of the method of the invention eliminates the unfavorable factor of the pressure drop growth limitation cycle by optimizing the process flow, and can be operated at a high temperature, and the relatively high reaction temperature is favorable for the loading.
- the performance of the catalyst system is beneficial to the hydroconversion of macromolecules and the removal of impurities.
- the hydrotreating reaction zone may comprise from 1 to 5 hydrotreating reactors arranged in series, preferably comprising from 1 to 2 hydrotreating reactors arranged in series.
- the operating conditions of the hydrotreating reaction zone may include: a temperature of 370 ° C to 430 ° C, preferably 380 ° C to 410 ° C; a pressure of 10 MPa to 25 MPa, preferably 15MPa ⁇ 20MPa; hydrogen oil ratio of 300 to 1500, preferably from 400 to 800; hourly space velocity of the feedstock oil 0.15h -1 ⁇ 0.8h -1, preferably from 0.2h -1 ⁇ 0.6h -1.
- pressure refers to the hydrogen partial pressure at the inlet of the reactor.
- the heavy oil hydrogenation technology adopts a fixed bed heavy oil hydrotreating technology, and each hydrotreating pretreatment reactor in the hydrotreating pretreatment reaction zone can be filled with a hydrogenation protecting agent, One or more of a hydrodemetallization catalyst, a hydrodesulfurization catalyst and a hydrodenitrogenation residual carbon conversion catalyst, wherein the hydrotreating reaction zone reactor can be filled with a hydrodesulfurization catalyst and a hydrodenitrogenation residue One or more of the carbon conversion catalysts.
- each hydrotreating pretreatment reactor is sequentially filled with a hydrogenation protecting agent, a hydrodemetallization catalyst, and an optional hydrodesulfurization catalyst according to the flow direction of the material;
- the reactor is sequentially charged with a hydrodesulfurization catalyst and a hydrodenitrogenation residual carbon conversion catalyst.
- the deprotection/capacitance metal capacity of the entire system is greatly improved, and the pressure drop of each hydrotreating pretreatment reactor is increased within the control range by the adjustment of the catalyst gradation.
- the catalyst system loaded in each hydro-pretreatment reactor in parallel in the hydrotreating pretreatment zone is mainly based on the function of de-discharging metal, which enhances the demetallization performance and strengthens the addition of macromolecules such as colloidal asphaltenes in the raw materials.
- the ability of hydrogen conversion lays a foundation for subsequent deep desulfurization and carbon residue conversion, so that the hydrodesulfurization reaction zone facilitates further deep reaction, and therefore, the hydrodemetallization catalyst is used in the process of the present invention compared with the conventional technology.
- the proportion has been improved, but the overall desulfurization activity and the hydroconversion performance of the carbon residue have not been reduced but have been improved.
- the hydrogenation protecting agent, the hydrodemetallization catalyst, the hydrodesulfurization catalyst and the hydrodenitrogenation residual carbon conversion catalyst may all be conventionally used in a fixed bed heavy oil hydrotreating process.
- catalyst These catalysts are usually supported by a porous refractory inorganic oxide such as alumina, and an oxide of a Group VIB and/or Group VIII metal (such as W, Mo, Co, Ni, etc.) is optionally added.
- a Group VIB and/or Group VIII metal such as W, Mo, Co, Ni, etc.
- Other various additives such as catalysts of elements such as P, Si, F, and B.
- FZC series heavy oil hydrotreating catalyst produced by Catalyst Branch of China Petroleum & Chemical Corporation.
- the heavy oil raw material may be a heavy oil raw material conventionally used in a fixed bed heavy oil hydrotreating process, for example, it may be a normal pressure heavy oil or a vacuum residue, and is usually blended with One or more of straight-run wax oil, vacuum wax oil, secondary processing wax oil, and catalytic refining oil.
- the heavy oil raw material may have a sulfur content of not more than 4% by weight, a nitrogen content of not more than 0.7% by weight, a metal content (Ni+V) of not more than 120 ⁇ g/g, a residual carbon value of not more than 17% by weight, and an asphaltene content. Not more than 5% by weight.
- the raw materials used in the examples and comparative examples of the present invention include three kinds of raw materials A, raw materials B and raw materials C.
- the specific properties are shown in Table 1, and the heavy oil used for hydrogenation is used.
- the properties of the catalyst are shown in Table 2.
- the loading methods of the catalysts in Examples 1 to 4 are shown in Table 3.
- the loading methods of the catalysts in Comparative Examples 1 to 4 are shown in Table 4, and the reaction conditions in Examples 1 to 4 are shown in Table 5.
- Comparative Example 1 The reaction conditions of ⁇ 4 are shown in Table 6, and the results of the reactions of Examples 1-4 and Comparative Examples 1-4 are shown in Table 7.
- the hydrotreating reactor A, the hydrotreating pretreating reactor B, and the hydrotreating pretreating reactor C used were reactors of the same type and size.
- This embodiment performs the switching operation in accordance with the above mode 5, that is, the predetermined value of the pressure drop is reached in the order of the hydrotreating pretreatment reactor C, the hydrotreating pretreatment reactor B, and the hydrotreating pretreatment reactor A.
- the raw material A, the hydrotreating pretreatment reactor A, and the hydrotreating pretreatment reactor B are used in the hydrotreating pretreatment reactor A, the hydrotreating pretreatment reactor B, and the hydrotreating pretreatment reactor C.
- Hydrogen pretreatment reactor C has the same total catalyst loading, feed properties and feed amount, hydrotreating pretreatment reactor A, hydrotreating pretreatment reactor B, hydrotreating pretreatment reactor C, hydrodesulfurization
- the catalyst of Reactor D was charged in the manner shown in Table 3. The operating conditions are shown in Table 5. The specific reaction results are shown in Table 7.
- This embodiment performs the switching operation in accordance with the above mode 5, that is, the predetermined value of the pressure drop is reached in the order of the hydrotreating pretreatment reactor C, the hydrotreating pretreatment reactor B, and the hydrotreating pretreatment reactor A.
- the raw material B is used in the hydrotreating pretreatment reactor A, the hydrotreating pretreatment reactor B, and the hydrotreating pretreatment reactor C.
- the specific properties are shown in Table 1.
- the air velocity of each reverse feed is different, plus when the volume of liquid reactor a pretreatment hydrogen space velocity of 0.2h -1, hydrotreating reactor when the volume space velocity of solution B 0.32h -1, hydrotreating reactor when the liquid hourly space velocity is C 0.44h -1 .
- the same catalyst loading method is used in the hydrotreating pretreatment reactor A, the hydrotreating pretreatment reactor B, and the hydrotreating pretreatment reactor C.
- the catalyst charging method is shown in Table 3.
- the operating conditions of each reactor are shown in Table 5.
- the results are shown in Table 7.
- This embodiment performs the switching operation in accordance with the above mode 1, that is, the predetermined value of the pressure drop is reached in the order of the hydrotreating pretreatment reactor A, the hydrotreating pretreatment reactor B, and the hydrotreating pretreatment reactor C.
- the raw material A is used in the hydrotreating pretreatment reactor A
- the raw material B is used in the hydrotreating pretreatment reactor B
- the raw material C is used in the hydrotreating pretreatment reactor C.
- the properties of the raw materials used are shown in Table 1.
- the feed amount of the hydrotreating pretreatment reactor A, the hydrotreating pretreatment reactor B, and the hydrotreating pretreatment reactor C is the same, the hydrotreating pretreatment reactor A, the hydrotreating pretreatment reactor B, and the hydrotreating pretreatment reaction
- the same catalyst loading method is used in the device C.
- the catalyst loading method is shown in Table 3.
- the operating conditions of each reactor are shown in Table 5.
- the specific reaction results are shown in Table 7.
- This embodiment performs the switching operation in accordance with the above mode 5, that is, the predetermined value of the pressure drop is reached in the order of the hydrotreating pretreatment reactor C, the hydrotreating pretreatment reactor B, and the hydrotreating pretreatment reactor A.
- the raw material C is used as the feed in the hydro-pretreatment reactor A, the hydro-pretreatment reactor B, and the hydro-pretreatment reactor C, and the feed amount is completely the same.
- the average reaction temperature of the hydrotreating pretreatment reactor A is 365 ° C
- the average reaction temperature of the hydrotreating pretreatment reactor B is 375 ° C
- the average reaction temperature of the hydrotreating pretreatment reactor C is 385 ° C
- the average reaction temperature of D is 383 ° C
- the catalyst loading method is shown in Table 3
- the operating conditions are shown in Table 5
- the specific reaction results are shown in Table 7.
- Reactor A Reactor B
- Reactor C Reactor D
- Reactor A Reactor B
- Reactor C Reactor D
- Reactor A Reactor B
- Reactor C Reactor D
- Reactor A Reactor B
- Reactor C Reactor D
- Reactor A Reactor B
- Reactor C Reactor D
- Reactor A Reactor B
- Reactor C Reactor D
- Reactor A Reactor B
- Reactor C Reactor D
- Reactor A Reactor B
- Reactor C Reactor D
- the total catalyst loading of Reactor A, Reactor B, Reactor C and Reactor D corresponds to Example 1 Hydrotreating Pretreatment Reactor A, Hydrotreating Pretreatment Reactor B, Hydrotreating Pretreatment Reactor C, Hydrogenation
- the desulfurization reactor D was the same, but the loading amount of each type of catalyst was different, and it was filled in the manner shown in Table 4, and the operating conditions are shown in Table 6, and the specific reaction results are shown in Table 7.
- reactors were also used in this comparative example, Reactor A, Reactor B, Reactor C, Reactor D, Reactor A, Reactor B, Reactor C and Reactor D were connected in series. .
- Starting material B properties are shown in Table 1
- reactor A inlet was identical to the total feed and feed properties of Example 2.
- the total amount of catalyst in the reactor A, the reactor B, the reactor C and the reactor D is the hydrotreating reactor A, the hydrotreating pretreatment reactor B, the hydrotreating pretreatment reactor C, and the addition corresponding to the second embodiment.
- the hydrogen desulfurization reactor D was the same, but the loading amount of each type of catalyst was different, and it was filled in the manner shown in Table 4, and the operating conditions are shown in Table 6.
- Table 7 The specific reaction results are shown in Table 7.
- Reactor A, Reactor B, Reactor C, Reactor D, Reactor A, Reactor B, Reactor C and Reactor D were connected in series.
- the comparative example used a raw material A, a raw material B, and a raw material C in a ratio of mixed raw materials, and the reactor A inlet was the same as the total feed amount and mixed feed property of Example 3.
- the total amount of catalyst in the reactor A, the reactor B, the reactor C and the reactor D is the hydrotreating reactor A, the hydrotreating pretreatment reactor B, the hydrotreating pretreatment reactor C, and the addition corresponding to the third embodiment.
- the hydrogen desulfurization reactor D was the same, but the loading amount of each type of catalyst was different, and it was filled in the manner shown in Table 4, and the operating conditions are shown in Table 6.
- the specific reaction results are shown in Table 7.
- Reactor A, Reactor B, Reactor C, Reactor D, Reactor A, Reactor B, Reactor C and Reactor D were connected in series.
- the comparative example used the starting material C, the properties of which are shown in Table 1, and the inlet of the reactor A was the same as the total feeding amount and the feeding property of the example 4.
- the total amount of catalyst in the reactor A, the reactor B, the reactor C and the reactor D is the hydrotreating reactor A, the hydrotreating pretreatment reactor B, the hydrotreating pretreatment reactor C, and the addition corresponding to the fourth embodiment.
- the hydrogen desulfurization reactor D was the same, but the loading amount of each type of catalyst was different, and it was filled in the manner shown in Table 4, and the operating conditions are shown in Table 6.
- the specific reaction results are shown in Table 7.
- the maximum design pressure (ie, design upper limit) for all reactor pressure drops is 0.7 MPa.
- the heavy oil hydrotreating process according to the present invention can greatly extend the operating cycle of the heavy oil hydrotreating unit.
- the reactor, the raw materials, the loading amount and type of the catalyst in each reactor, and the reaction conditions used in the present embodiment are the same as those in the first embodiment, except that the switching operation mode employed is different from that in the first embodiment, and the switching is performed.
- the operation is as follows:
- the hydrotreating pretreatment reaction zone (including the hydrotreating pretreatment reactor A and the hydrotreating pretreatment reactor B) and the hydrogenation pretreatment are controlled by the control unit.
- Processing reactor C and hydrodesulfurization reaction zone form a series connection;
- the hydrotreating pretreatment reactor A, the hydrotreating pretreatment reactor C, the hydrotreating pretreatment reactor B, and the hydrodesulfurization reaction zone are controlled by the control unit. Forming a series connection;
- the reactor, the raw materials, the loading amount and type of the catalyst in each reactor, and the reaction conditions used in the present embodiment are the same as those in the first embodiment, except that the switching operation mode employed is different from that in the first embodiment, and the switching is performed.
- the operation is as follows:
- the hydrotreating pretreatment reaction zone (including the hydrotreating pretreatment reactor A and the hydrotreating pretreatment reactor B) and the hydrogenation pretreatment are controlled by the control unit.
- Processing reactor C and hydrodesulfurization reaction zone form a series connection;
- the hydrotreating pretreatment reactor A, the hydrotreating pretreatment reactor C/the hydrotreating pretreatment reactor B, and the hydrodesulfurization reaction zone are controlled by the control unit. Forming a series, and the hydrotreating pretreatment reactor C and the hydrotreating pretreatment reactor B are connected in parallel;
- the switching operation method of the preferred embodiment of the heavy oil hydrotreating method according to the present invention can further improve the operational stability of the apparatus and prolong the operation cycle of the heavy oil hydrotreating unit.
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Abstract
Description
项目 | 原料A | 原料B | 原料C |
S,wt% | 3.32 | 2.86 | 2.35 |
N,μg/g | 3566 | 3320 | 4200 |
残炭(CCR),wt% | 13.50 | 12.62 | 11.46 |
密度(20℃),kg/m3 | 987.6 | 984.0 | 976.5 |
粘度(100℃),mm2/s | 130.0 | 112.0 | 69.0 |
Ni+V,μg/g | 105.0 | 82.0 | 63.0 |
Fe,μg/g | 8 | 5 | 10 |
Ca,μg/g | 5 | 5 | 3 |
催化剂牌号 | FZC-100B | FZC-12B | FZC-13B | FZC-28A | FZC-204A | FZC-34B | FZC-41B |
催化剂种类 | 保护剂 | 保护剂 | 保护剂 | 脱金属剂 | 脱金属剂 | 脱硫剂 | 脱残炭剂 |
颗粒形状 | 四叶轮 | 四叶轮 | 四叶草 | 四叶草 | 四叶草 | 四叶草 | 四叶草 |
颗粒直径/mm | 6.0~8.0 | 3.2~4.2 | 1.5~1.8 | 1.3~1.6 | 1.1~1.6 | 1.0~1.6 | 1.0~1.6 |
强度/N(mm)-1 | ≥10.0 | ≥8.0 | ≥8.0 | ≥10.0 | ≥12.0 | ≥12.0 | ≥12.0 |
装填密度/kg.m-3 | 700 | 410 | 410 | 460 | 480 | 540 | 595 |
比表面积/m2.g-1 | — | 100~150 | 100~150 | 110~145 | 135~185 | 140~180 | 160~200 |
孔容/cm3.g-1 | ≥0.30 | ≥0.75 | ≥0.75 | ≥0.80 | ≥0.55 | ≥0.48 | ≥0.42 |
磨损率,m% | ≤2.0 | ≤2.0 | ≤2.0 | ≤2.0 | ≤2.0 | ≤1.5 | ≤1.5 |
化学组成 | Mo-Ni | Mo-Ni | Mo-Ni | Mo-Ni | Mo-Ni | Mo-Ni | Mo-Ni |
Claims (19)
- 一种重油加氢处理系统,该加氢处理系统包括依次串联的加氢预处理反应区、过渡反应区和加氢处理反应区以及传感单元和控制单元,所述传感单元用于检测所述加氢预处理反应区中的各个加氢预处理反应器内的压降,所述控制单元用于接收来自所述传感单元的压降信号;在反应初始阶段,所述加氢预处理反应区包括至少两个相互并联的加氢预处理反应器,所述过渡反应区包括或不包括加氢预处理反应器;在反应过程中,所述控制单元根据所述传感单元的压降信号控制所述加氢预处理反应区中的各个加氢预处理反应器的进料和出料,使得当所述加氢预处理反应区中的任意一个加氢预处理反应器的压降达到预定值时,将压降达到预定值的加氢预处理反应器从所述加氢预处理反应区切换至所述过渡反应区。
- 根据权利要求1所述的系统,其中,所述加氢预处理反应器的压降预定值为该加氢预处理反应器的压降设计上限的50%~80%,优选为60%~70%。
- 根据权利要求1或2所述的系统,其中,在反应初始阶段,所述加氢预处理反应区包括3~6个,优选为3~4个加氢预处理反应器;所述加氢处理反应区包括1~5个串联设置的加氢处理反应器,优选包括1~2个串联设置的加氢处理反应器。
- 根据权利要求3所述的系统,其中,在反应初始阶段,所述过渡反应区不包括加氢预处理反应器;而且,所述控制单元根据所述传感单元的压降信号控制所述加氢预处理反应区中的各个加氢预处理反应器的进料和出料,使得:当一个加氢预处理反应器的压降达到所述预定值时,将该加氢预处理反应器从所述加氢预处理反应区切换至所述过渡反应区,将该加氢预处理反应器命名为切出的加氢预处理反应器I,并将所述加氢预处理反应区、所述切出的加氢预处理反应器I和所述加氢处理反应区以串联的方式依次连接起来;当下一个加氢预处理反应器的压降达到所述预定值时,将该加氢预处理反应器从 所述加氢预处理反应区切换至所述过渡反应区,将该加氢预处理反应器命名为切出的加氢预处理反应器II,并将所述加氢预处理反应区、所述切出的加氢预处理反应器II、所述切出的加氢预处理反应器I和所述加氢处理反应区以串联的方式依次连接起来;按照上述方式,直至所有的加氢预处理反应器全部都以串联的方式连接。
- 根据权利要求1-4中任意一项所述的系统,其中,在所述加氢预处理反应区中,任意一个加氢预处理反应器的出料口与其他加氢预处理反应器的进料口和所述加氢处理反应区的进料口均通过带有控制阀的管线连接,任意一个加氢预处理反应器的进料口与重油原料和氢气的混合物流的供给源均通过带有控制阀的管线连接,其中,所述控制单元通过控制与各个加氢预处理反应器对应的控制阀来控制进料和出料。
- 一种重油加氢处理方法,该方法包括:将重油原料与氢气混合后依次经过串联的加氢预处理反应区、过渡反应区和加氢处理反应区;在反应初始阶段,所述加氢预处理反应区包括至少两个相互并联的加氢预处理反应器,所述过渡反应区包括或不包括加氢预处理反应器;在反应过程中,当所述加氢预处理反应区中的任意一个加氢预处理反应器的压降达到预定值时,将压降达到预定值的加氢预处理反应器从所述加氢预处理反应区切换至所述过渡反应区,其中,所述加氢预处理反应器的压降预定值为该加氢预处理反应器的压降设计上限的50%~80%,优选为60%~70%。
- 根据权利要求6所述的方法,其中,在反应初始阶段,所述加氢预处理反应区包括3~6个,优选为3~4个加氢预处理反应器。
- 根据权利要求7所述的方法,其中,在反应初始阶段,所述过渡反应区不包括加氢预处理反应器;而且,当一个加氢预处理反应器的压降达到所述预定值时,将该加氢预处理反应器从所述加氢预处理反应区切换至所述过渡反应区,将该加氢预处理反应器命名为切出的加氢预处理反应器I,并将所述加氢预处理反应区、所述切出的加氢预处理反应器I和所述加氢处理反应区以串联的方式依次连接起来;当下一个加氢预处理反应器的压降达到所述预定值时,将该加氢预处理反应器从 所述加氢预处理反应区切换至所述过渡反应区,将该加氢预处理反应器命名为切出的加氢预处理反应器II,并将所述加氢预处理反应区、所述切出的加氢预处理反应器II、所述切出的加氢预处理反应器I和所述加氢处理反应区以串联的方式依次连接起来;按照上述方式,直至所有的加氢预处理反应器全部都以串联的方式连接。
- 根据权利要求6-8中任意一项所述的方法,其中,所有的加氢预处理反应器的压降不同时达到预定值,优选相邻两个最接近达到压降预定值的加氢预处理反应器达到其压降预定值的时间差不小于整个运行周期的20%,优选为20%~60%。
- 根据权利要求9所述的方法,其中,通过操作条件的设置和/或催化剂床层性质的差异使得加氢预处理反应区中各个加氢预处理反应器不同时达到压降预定值,优选地,通过控制各个加氢预处理反应器内不同的催化剂装填高度、不同的进料量、不同的进料性质、不同的操作条件以及相同的装填高度条件下采用不同的催化剂装填密度中的一种或多种方式来实现使加氢预处理反应区中各个加氢预处理反应器不同时达到压降预定值。
- 根据权利要求10所述的方法,其中,当通过控制各个加氢预处理反应器内相同的装填高度条件下采用不同的催化剂装填密度的方式来实现时,在所述加氢预处理反应区并联的各个加氢预处理反应器中,最大装填密度为400kg/m3~600kg/m3,优选为450kg/m3~550kg/m3;最小装填密度为300kg/m3~550kg/m3,优选为350kg/m3~450kg/m3;优选地,装填密度最接近的两台加氢预处理反应器的催化剂装填密度差值为50~200kg/m3,优选为80~150kg/m3。
- 根据权利要求10所述的方法,其中,当通过控制各个加氢预处理反应器内不同的进料量的方式来实现时,进料量最接近的两台加氢预处理反应器的进料体积空速之比为1.1~3:1,优选为1.1~1.5:1。
- 根据权利要求10所述的方法,其中,当通过控制各个加氢预处理反应器内不同的进料性质的方式来实现时,进料性质最接近的两台加氢预处理反应器的金属含量差 值为5~50μg/g,优选为10~30μg/g。
- 根据权利要求10所述的方法,其中,当通过控制各个加氢预处理反应器内不同的操作条件的方式来实现时,控制操作压力和体积空速最接近的两台加氢预处理反应器的操作条件中,操作温度差值为2~30℃,优选为5~20℃;或者控制操作压力和操作温度最接近的两台加氢预处理反应器的操作条件中,体积空速差值为0.1~10h-1,优选为0.2~5h-1。
- 根据权利要求6-8中任意一项所述的方法,其中,按照物料流动方向,各个加氢预处理反应器内依次装填加氢保护剂、加氢脱金属催化剂以及可选的加氢脱硫催化剂;所述加氢处理反应区的反应器依次装填加氢脱硫催化剂和加氢脱氮残炭转化催化剂。
- 根据权利要求6-8中任意一项所述的方法,其中,所述加氢预处理反应区的操作条件包括:温度为370℃~420℃,优选为380℃~400℃;压力为10MPa~25MPa,优选为15MPa~20MPa;氢油体积比为300~1500,优选为500~800;原料油液时体积空速为0.15h-1~2h-1,优选为0.3h-1~1h-1。
- 根据权利要求6所述的方法,其中,所述加氢处理反应区包括1~5个串联设置的加氢处理反应器,优选包括1~2个串联设置的加氢处理反应器。
- 根据权利要求6或17所述的方法,其中,所述加氢处理反应区的操作条件包括:温度为370℃~430℃,优选为380℃~410℃;压力为10MPa~25MPa,优选为15MPa~20MPa;氢油体积比为300~1500,优选为400~800;原料油液时体积空速为0.15h-1~0.8h-1,优选为0.2h-1~0.6h-1。
- 根据权利要求6-8中任意一项所述的方法,其中,所述重油原料选自常压重油和/或减压渣油;优选地,所述重油原料掺炼直馏蜡油、减压蜡油、二次加工蜡油和催化回炼油中的至少一种。
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