CN1429883A - Preparation method of high activity fluid catalytic eracking catalyst - Google Patents
Preparation method of high activity fluid catalytic eracking catalyst Download PDFInfo
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- CN1429883A CN1429883A CN 01142881 CN01142881A CN1429883A CN 1429883 A CN1429883 A CN 1429883A CN 01142881 CN01142881 CN 01142881 CN 01142881 A CN01142881 A CN 01142881A CN 1429883 A CN1429883 A CN 1429883A
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Abstract
A high-activity catalyst for catalytic cracking process is prepared from kaolinite, solid seed, assistant, organic disperser and adhesive through spray drying, shaping, microspheres, high-temp calcining, crystallizing reaction on sodium silicate and sodium hydroxide to obtain crystallized microspheres content of zeolit is 20-70%, ratio of zeolit silica-alumina is 4.0-6.0), calcining, and exchanging with NH4 and Re3 three times. Its advantages are high resistance to heavy metal, high activity and stability, and low cost.
Description
Technical field
The technology of the present invention can be applicable to refinery stream fluidized catalytic cracking (FCC) field of refining of petroleum, specifically, the present invention be a kind of be main raw material prepares high reactivity FCC catalyzer by the in-situ crystallization technology method with kaolin.
Background technology
It is basic raw material with kaolin exactly that kaolin in-situ crystallization prepares the FCC catalyzer, form kaolin microsphere through making beating and spraying drying, again kaolin microsphere is carried out high-temperature roasting, make kaolin recurring structure and qualitative variation, mix with other solution then, carry out crystallization.In the crystallization process, active silica and aluminum oxide just change into the NaY zeolite, just obtain the zeolite catalyst of overall height mountain range soil type through exchange and roasting again.So-called " in-situ crystallization " is meant kaolin microsphere in crystallization process, and its profile and granularity are constant substantially, and crystallization is carried out at microballoon itself.Catalyzer with the preparation of this technology has following characteristics: the one, and the sial raw material of synthetic zeolite is all or be mainly kaolin.The 2nd, the catalyzer cracking-residuum and the preventing from heavy metal pollution ability of this technology preparation are strong, and active high, hydrothermal stability and structural stability are good, are the catalyst for cracking heavy oil of excellent property.USP3503900 has reported the seventies be the in-situ crystallization technology that raw material prepares active ingredient and matrix simultaneously with kaolin, and the FCC catalyzer with the in-situ crystallization method obtains is called the kaolin type catalyzer.
USP3367886,3506594,3663165,3932268 patented technologies are all used the kaolin of roasting more than 900 ℃, and the degree of crystallinity of the in-situ crystallization product of preparation is lower, generally at 20-30%.The USP3657154 patent adds thin soil partially in the crystallization system, but causes the ex situ crystallization product to increase filtration difficulty.
EP192453 and USP4493902 employing are carried out the high and low temperature roasting respectively with kaolin and are prepared the high zeolite content crystallization product.Wherein, EP192453 adopts fractional crystallization, and USP4493902 then requires expensive super-refinement kaolin.
The technology that CN1232862 adopts is similar to USP4493902, and its method for preparing the crystallization microballoon is to make slurries by kaolin, dispersion agent, caking agent.In crystallization process, need synthetic in advance directed agents to form NaY.So not only preparation process complexity, and the NaY that provides can not enter in the microballoon hole well.The catalyzer preventing from heavy metal ability that this patent application obtains is still waiting to improve.
Summary of the invention
Technical problem to be solved by this invention is that the oxide compound component of introducing preventing from heavy metal in the kaolin in-situ crystallization process prepares zeolite content height, strong, the active high FCC catalyzer of preventing from heavy metal ability and a kind of preparation method of high activity fluid catalytic eracking catalyst is provided.
The preparation method of high activity fluid catalytic eracking catalyst of the present invention, comprise that kaolin in-situ crystallization obtains crystallization microballoon and crystallization microballoon through exchange and calcination process process, the method that kaolin in-situ crystallization obtains the crystallization microballoon is: comprise by protokaolin, the slurries that caking agent and water are made with certain solid content, the spray-dried parent microballoon that is shaped to of slurries, the parent microballoon is again through roasting, the process of mixing crystallization with other solution, it is characterized in that kaolin in-situ crystallization obtains adding the preventing from heavy metal auxiliary agent in the method for crystallization microballoon when the preparation slurries, add-on is the 0.1-1.5% (quality) of kaolin amount.
Principal feature of the present invention is to introduce the preventing from heavy metal auxiliary agent in the preparation method of known kaolin type fluid catalytic cracking catalyst, and the catalyzer preventing from heavy metal ability of preparation is strengthened.Described preventing from heavy metal auxiliary agent is soluble zinc salt, soluble alkaline earth salt, soluble ree compound.Mainly be that the parent microballoon is at the oxide compound that corresponding zinc, alkaline-earth metal and rare earth are provided in catalyzer after the roasting.Above-mentioned soluble substance can be hydrochloride, vitriol, nitrate.As zinc chloride, magnesium chloride, rare earth chloride.Preferred Cerium II Chloride of rare earth chloride or Lanthanum trichloride.
The present invention can also add the solid crystal seed in the preparation process of slurries, when providing crystallization, can impel the solid crystal seed silicon oxide, aluminum oxide to be converted into the Y zeolite of NaY, utilize Industrial products directly to add, overcome prior art existing synthetic complex process in crystallization process, the add-on of solid crystal seed is kaolinic 1-5% (quality), and the preferred crystal grain of solid crystal seed is NaY, ReY, HY or USY (silica alumina ratio is 10~15 the high silica alumina ratio NaY) zeolite (Y zeolite) of 800~1000nm.
The present invention can also add organic dispersing agent when the preparation slurries, it is identical with the effect of caking agent, promptly can use simultaneously with caking agent, also can replace caking agent.The add-on of organic dispersing agent is kaolinic 0.3-1.2% (quality), selects sodium polyacrylate, polyacrylamide for use.
The preferred slurries of the present invention are by kaolin, solid crystal seed, auxiliary agent, organic dispersing agent or/and caking agent adds solid content that water makes is 30~55% slurries.The add-on of caking agent is kaolinic 2-12% (quality), selects water glass, silicon sol, aluminium colloidal sol, pseudo-boehmite for use.
Original kaolin of the present invention (raw material) comprises the high clay of lightweight, hard kaolinite, coal gangue, and wherein footpath position is for the kaolinic weight content of crystal of 2.0-3.0 micron will be higher than 80%, Fe
2O
3Content is lower than 1.5%, K
2O content is lower than 0.5%.
The preferred method that kaolin in-situ crystallization of the present invention makes the crystallization microballoon is:
To make solid content be 30~55% slurries or/and caking agent adds water with kaolin, solid crystal seed, auxiliary agent, organic dispersing agent, the spray-dried parent microballoon A that is shaped to 20~149 μ m;
Obtaining main content in 1.5~3 hours through 780~1100 ℃ of roastings is metakaolin microballoon AP;
Join in the crystallizing kettle successively water glass, sodium hydroxide, AP, deionized water in proportion then, stirred crystallization 18-40 hour at 90-100 ℃, remove by filter mother liquor, to washings PH=9.5, filter cake obtains the crystallization microballoon product A PJ that the NaY zeolite content is 20-70% (quality), zeolite silica alumina ratio 4.0-6.0 (quality) to filter cake after drying with deionized water wash.The amount of water glass, sodium hydroxide, AP, deionized water is that the weight ratio according to the liquid phase of AP and formation is 1: 10~20, SiO in the liquid phase
2With the weight ratio of AP be 0.4~5: 1, Na in the liquid phase
2The weight ratio of O and AP is 0.3~1.5: 1 calculating.
The naoh concentration of the above is preferably 20-40%, and sodium silicate silicate is preferably 15-40%.
The present invention has improved the method that kaolin in-situ crystallization makes the crystallization microballoon, and the aftertreatment of crystallization microballoon promptly exchanges can be as the method for known technology with the calcination process process, the invention provides the lower method of following a kind of cost and is:
1. once exchange: add people's ammonium sulfate and crystallization product APJ successively, ammonium sulfate/APJ is 0.3-0.6 (mass ratio), is 3.5-4.5 at PH, temperature 90-100 ℃ of down exchange 0.5-1 hour, the microballoon after the exchange after filtration, wash to such an extent that one hand over material;
2. secondary exchanges: one hands over material to carry out the secondary exchange, and condition is the same, 110 ℃ of dry two friendship material that get;
3. roasting: two hand over material under steam atmosphere 560-680 ℃ roasting 1.5-3 hour roasting material;
4. three exchanges: roasting material is pressed friendship condition ammonium sulfate, ReCl
3Mix exchange, three hand over material, be 3.5-4.5 at PH, temperature 90-100 ℃ of exchange 0.5-1 hour down, the microballoon after the exchange is after filtration, washing and drying obtains product catalyst, ammonium sulfate/APJ is 0.1-0.25, ReCl
3/ APJ is 0.010-0.45.
The catalyst n aY zeolite content of the present invention's preparation is 20~70% (mass percents), (silicon oxide: be 4.0~6.0 the mol ratio of aluminum oxide), preferred NaY zeolite 28-50%, silica alumina ratio 4.5-5.5, rare earth oxide content 1.5-4.5%, sodium oxide are below 0.3% for the zeolite silica alumina ratio.
Advantage of the present invention: the catalyst zeolite content height of preparation, the preventing from heavy metal ability is strong, cracking activity is high, activity stability is good, preparation process is simplified, cost is low.
Embodiment
The present invention is not limited by the following examples.
Embodiment 1-embodiment 4 is the preparation of kaolin microsphere.
Embodiment 1
Kaolin, 10g ZnO, 80g NaY, the 60g water glass of 2000g (butt) added water, and to make solid content be 42% slurries, and spray shaping obtains the microballoon A of 16500g.
Embodiment 2
Kaolin, 10g ZnO, 80g NaY, 60g water glass, the 20g sodium polyacrylate of 2000g (butt) added water, and to make solid content be 53% slurries, and spray shaping obtains the microballoon A of 1800g.
Embodiment 3
Kaolin, 80g NaY, the 60g water glass of 2000g (butt) added water, and to make solid content be 35% slurries, and spray shaping obtains the microballoon A of 1600g.
Embodiment 4
Kaolin, the water glass of 2000g (butt) added water, and to make solid content be 35% slurries, and spray shaping obtains the microballoon A of 1600g.
Embodiment 5-embodiment 15 is the crystallization of kaolin microsphere.
Embodiment 5
Microballoon A 920 ℃ of roastings in muffle furnace of getting among a certain amount of embodiment 1 got microballoon AP in 2.5 hours, stirring under the shape successively with water glass 1100mL, sodium hydroxide 250mL, AP200g adds crystallizing kettle, be warming up to 95 ℃ of crystallization 28 hours, filtration washing gets crystallization microballoon APJ.Measure APJ through X-ray and contain 53% NaY, silica alumina ratio is 5.2.
Embodiment 6
Microballoon A 920 ℃ of roastings in muffle furnace of getting among a certain amount of embodiment 2 got microballoon AP in 2.5 hours.Stirring under the shape successively with water glass 1100mL, sodium hydroxide 250mL, AP200g adds crystallizing kettle, is warming up to 95 ℃ of crystallization 28 hours, and filtration washing gets crystallization microballoon APJ.Measure APJ through X-ray and contain 61% NaY, silica alumina ratio is 5.2.
Embodiment 7
Microballoon A 920 ℃ of roastings in muffle furnace of getting among a certain amount of embodiment 3 got microballoon AP in 2.5 hours, stirring under the shape successively with water glass 1100mL, sodium hydroxide 250mL, AP200g adds crystallizing kettle, be warming up to 95 ℃ of crystallization 28 hours, filtration washing gets crystallization microballoon APJ.Measure APJ through X-ray and contain 52% NaY, silica alumina ratio is 5.1.
Embodiment 8
Microballoon A 920 ℃ of roastings in muffle furnace of getting among a certain amount of embodiment 4 got microballoon AP in 2.0 hours, stirring under the shape successively with water glass 1100mL, sodium hydroxide 250mL, AP200g adds crystallizing kettle, be warming up to 95 ℃ of crystallization 28 hours, filtration washing gets crystallization microballoon APJ.Measure APJ through X-ray and contain 4% NaY, silica alumina ratio is 5.0.
Embodiment 9
Microballoon A 860 ℃ of roastings in muffle furnace of getting among a certain amount of embodiment 1 got microballoon AP in 2.5 hours, stirring under the shape successively with water glass 1900mL, sodium hydroxide 210mL, AP200g adds crystallizing kettle, be warming up to 95 ℃ of crystallization 28 hours, filtration washing gets crystallization microballoon APJ.Measure APJ through X-ray and contain 46% NaY, silica alumina ratio is 5.3.
Embodiment 10
Microballoon A 860 ℃ of roastings in muffle furnace of getting among a certain amount of embodiment 2 got microballoon AP in 2.5 hours, stirring under the shape successively with water glass 1900mL, sodium hydroxide 210mL, AP200g adds crystallizing kettle, be warming up to 95 ℃ of crystallization 28 hours, filtration washing gets crystallization microballoon APJ.Measure APJ through X-ray and contain 59% NaY, silica alumina ratio is 5.2.
Embodiment 11
Microballoon A 860 ℃ of roastings in muffle furnace of getting among a certain amount of embodiment 3 got microballoon AP in 2.5 hours, stirring under the shape successively with water glass 1900mL, sodium hydroxide 210mL, AP200g adds crystallizing kettle, be warming up to 95 ℃ of crystallization 28 hours, filtration washing gets crystallization microballoon APJ.Measure APJ through X-ray and contain 44% NaY, silica alumina ratio is 5.3.
Embodiment 12
Microballoon A 800 ℃ of roastings in muffle furnace of getting among a certain amount of embodiment 1 got microballoon AP in 3.0 hours, stirring under the shape successively with water glass 3000mL, sodium hydroxide 340mL, AP200g adds crystallizing kettle, be warming up to 95 ℃ of crystallization 28 hours, filtration washing gets crystallization microballoon APJ.Measure APJ through X-ray and contain 56% NaY, silica alumina ratio is 4.8.
Embodiment 13
Microballoon A 800 ℃ of roastings in muffle furnace of getting among a certain amount of embodiment 3 got microballoon AP in 3.0 hours, stirring under the shape successively with water glass 3000mL, sodium hydroxide 340mL, AP200g adds crystallizing kettle, be warming up to 95 ℃ of crystallization 28 hours, filtration washing gets crystallization microballoon APJ.Measure APJ through X-ray and contain 55% NaY, silica alumina ratio is 4.9.
Embodiment 14
Microballoon A 800 ℃ of roastings in muffle furnace of getting among a certain amount of embodiment 1 got microballoon AP in 3.0 hours, stirring under the shape successively with water glass 3800mL, sodium hydroxide 400mL, AP200g adds crystallizing kettle, be warming up to 95 ℃ of crystallization 28 hours, filtration washing gets crystallization microballoon APJ.Measure APJ through X-ray and contain 68% NaY, silica alumina ratio is 4.2.
Embodiment 15
Microballoon A 800 ℃ of roastings in muffle furnace of getting among a certain amount of embodiment 3 got microballoon AP in 3.0 hours, stirring under the shape successively with water glass 3800mL, sodium hydroxide 400mL, AP200g adds crystallizing kettle, be warming up to 95 ℃ of crystallization 28 hours, filtration washing gets crystallization microballoon APJ.Measure APJ through X-ray and contain 65% NaY, silica alumina ratio is 4.1.
Embodiment 16-embodiment 18 is the aftertreatment of crystallization microballoon
Embodiment 16
1. once exchange: add successively crystallization product APJ150g among ammonium sulfate and the embodiment 5 (ammonium sulfate/APJ=0.35), be 3.5-4.5 at PH, temperature 90-100 ℃ of exchange 0.5-1 hour down, the microballoon after the exchange after filtration, wash to such an extent that one hand over material,
2. secondary exchanges: one hands over material to carry out secondary exchange (condition is the same), 110 ℃ of dry two friendship material that get.
3. roasting: two hand over material under steam atmosphere 600 ℃ roasting 1.5-3 hour roasting material.
4. three exchanges: roasting material is pressed friendship condition ammonium sulfate, ReCl
3Mix exchange, get three and hand over material, ReCl
3/ APJ=0.018, ammonium sulfate/APJ are 0.15.Microballoon after the exchange after filtration, the washing and drying product catalyst.
Embodiment 17
Method by example 16 prepares catalyzer with the crystallization product APJ among the embodiment 6.
Embodiment 18
Method by example 16 prepares catalyzer with the crystallization product APJ among the embodiment 7.
The physico-chemical property such as the table 1 of Zhi Bei catalyzer as stated above, contrast medium (trade mark DIMENSION) is external preferably at present similar FCCization agent, the contrast cracking performance of catalyzer sees Table 2.
The character contrast of table 1 catalyzer
| The catalyzer numbering | Contrast medium | Embodiment 16 catalyzer | Embodiment 17 catalyzer | Embodiment 18 catalyzer | |
| Chemical constitution | Al 2O 3,%(w) | 44.3 | 42.8 | 43.4 | 43.1 |
| Na 2O,%(w) | 0.24 | 0.18 | 0.20 | 0.18 | |
| ZnO,%(w) | / | 1.1 | 1.3 | / | |
| Fe 2O 3,%(w) | 0.32 | 0.46 | 0.38 | 0.35 | |
| Physical properties | Abrasion index, % (w) | 2.2 | 1.7 | 1.4 | 1.6 |
| Specific surface area, m 2/g | 289 | 321 | 332 | 334 | |
| Pore volume, ml/g | 0.32 | 0.32 | 0.34 | 0.34 | |
| Apparent density, g/ml | 0.76 | 0.70 | 0.69 | 0.70 | |
The hydrothermal stability of table 2 catalyzer and anti-V, Ni performance
| Catalyzer | Contain Ni, ppm | Contain V, ppm | Micro anti-active index (800 ℃/4h) | Micro anti-active index (800 ℃/17h) |
| Contrast medium | 0 | ?0 | ?77.2 | ?63.0 |
| Embodiment 16 | ?78.0 | ?67.8 | ||
| Embodiment 17 | ?78.9 | ?69.6 | ||
| Embodiment 18 | ?77.4 | ?67.1 | ||
| Contrast medium | 1500 | ?4500 | ?60.3 | ?50.7 |
| Embodiment 16 | ?67.2 | ?64.4 | ||
| Embodiment 17 | ?69.0 | ?65.9 | ||
| Embodiment 18 | ?60.6 | ?51.6 |
As can be seen from Table 2, catalyzer is without pollution of huge sum of money week and digestion time short (4 hours) time, and activity of such catalysts of the present invention and contrast medium are suitable; But after long-time (17 hours) were aging, catalyst activity of the present invention illustrated that than the high 4-7 of a contrast medium unit hydrothermal stability of catalyzer of the present invention is qualitative higher.
Catalyzer is after heavy metal contamination, and the embodiment of the invention 16, embodiment 17 activity of such catalysts are higher than contrast medium, and digestion time is long more, and embodiment 16, embodiment 17 catalyzer demonstrate its preventing from heavy metal and hydrothermally stable performance more.Embodiment 18 catalyzer do not demonstrate preventing from heavy metal performance preferably, and its reason is not add in the catalyzer crystallization process preventing from heavy metal component ZnO.
Claims (11)
1, the preparation method of high activity fluid catalytic eracking catalyst, comprise that kaolin in-situ crystallization obtains crystallization microballoon and crystallization microballoon through exchange and calcination process process, the method that kaolin in-situ crystallization obtains the crystallization microballoon is: comprise by kaolin, the slurries that caking agent and water are made with certain solid content, the spray-dried parent microballoon that is shaped to of slurries, the parent microballoon is again through roasting, the process of mixing crystallization with other solution, it is characterized in that kaolin in-situ crystallization obtains adding the preventing from heavy metal auxiliary agent in the method for crystallization microballoon when the preparation slurries, add-on is the 0.1-1.5% (quality) of kaolin amount.
2, preparation method according to claim 1 is characterized in that described preventing from heavy metal auxiliary agent is soluble zinc salt, soluble alkaline earth salt, soluble ree compound.
3, preparation method according to claim 2 is characterized in that described preventing from heavy metal auxiliary agent is zinc chloride, magnesium chloride, Cerium II Chloride or Lanthanum trichloride.
4, preparation method according to claim 1, it is characterized in that described slurries are by kaolin, solid crystal seed, preventing from heavy metal auxiliary agent, organic dispersing agent or/and caking agent adds solid content that water makes is 30~55% slurries, described solid crystal seed can impel silicon oxide, aluminum oxide to be converted into the Y zeolite of NaY when providing crystallization.
5, preparation method according to claim 4 is characterized in that described solid crystal seed is the NaY of crystal grain 800~1000nm, ReY, HY or USY zeolite, and the add-on of solid crystal seed is kaolinic 1-5% (quality).
6, preparation method according to claim 4, the add-on that it is characterized in that organic dispersing agent is kaolinic 0.3-1.2% (quality), selects sodium polyacrylate, polyacrylamide for use.
7, preparation method according to claim 4, the add-on that it is characterized in that caking agent is kaolinic 2-12% (quality), selects water glass, silicon sol, aluminium colloidal sol, pseudo-boehmite for use.
8, according to claim 1 or 4 described preparation methods, it is characterized in that described kaolin comprises the high clay of lightweight, hard kaolinite, coal gangue, wherein crystal kaolinite content to be higher than 80%, Fe
2O
3Content is lower than 1.5%, K
2O content is lower than 0.5%.
9, preparation method according to claim 4 is characterized in that the method that kaolin in-situ crystallization makes the crystallization microballoon is:
To make solid content be 30~55% slurries or/and caking agent adds water with kaolin, solid crystal seed, auxiliary agent, organic dispersing agent, the spray-dried parent microballoon A that is shaped to 20~149 μ m;
Obtaining main content in 1.5~3 hours through 780~1100 ℃ of roastings is metakaolin microballoon AP;
Then with water glass, sodium hydroxide, AP, deionized water according to the weight ratio of AP and liquid phase be 1: 10~20, the weight ratio of SiO2 and AP is 0.4~5 in the liquid phase: 1, the weight ratio of Na2O and AP is that 0.3~1.5: 1 ratio of determining joins in the crystallizing kettle successively in the liquid phase, stirred crystallization 18-40 hour at 90-100 ℃, remove by filter mother liquor, to washings PH=9.5, filter cake obtains the crystallization microballoon product A PJ that the NaY zeolite content is 20-70%, zeolite silica alumina ratio 4.0-6.0 to filter cake after drying with deionized water wash.
10, preparation method according to claim 9 is characterized in that described naoh concentration is 20-40%, and sodium silicate silicate is 15-40%.
11, preparation method according to claim 1 is characterized in that the crystallization microballoon through exchange and calcination process process is:
(1). once exchange: add ammonium sulfate and crystallization product APJ successively, ammonium sulfate/APJ is 0.3-0.6 (mass ratio), is 3.5-4.5 at PH, temperature 90-100 ℃ of down exchange 0.5-1 hour, the microballoon after the exchange after filtration, wash to such an extent that one hand over material;
(2). secondary exchanges: one hands over material to carry out the secondary exchange, and condition is the same, 110 ℃ of dry two friendship material that get;
(3). roasting: two hand over material under steam atmosphere 560-680 ℃ roasting 1.5-3 hour roasting material;
(4). three exchanges: roasting material is pressed friendship condition ammonium sulfate, ReCl
3Mix exchange, three hand over material, be 3.5-4.5 at PH, temperature 90-100 ℃ of exchange 0.5-1 hour down, the microballoon after the exchange is after filtration, washing and drying obtains product catalyst, ammonium sulfate/APJ is 0.1-0.25, ReCl
3/ APJ is 0.010-0.45.
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|---|---|---|---|
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|---|---|---|---|
| CN 01142881 CN1204228C (en) | 2001-12-31 | 2001-12-31 | Preparation method of high activity fluid catalytic eracking catalyst |
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Cited By (7)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US7390762B2 (en) | 2004-11-26 | 2008-06-24 | Petrochina Company Limited | Method for the preparation of high-content NaY molecular sieves synthesized from kaolin sprayed microspheres |
| CN100404128C (en) * | 2005-05-12 | 2008-07-23 | 中国石油天然气股份有限公司 | Catalytic cracking auxiliary agent for reducing sulfur content of gasoline, preparation method and application |
| CN100429293C (en) * | 2005-06-15 | 2008-10-29 | 中国石油天然气股份有限公司 | Preparation method of catalytic cracking catalyst |
| CN101537368B (en) * | 2008-03-19 | 2010-12-15 | 中国石油天然气股份有限公司 | Preparation method of in-situ crystallization type catalytic cracking catalyst |
| CN104211084A (en) * | 2014-09-03 | 2014-12-17 | 中国海洋石油总公司 | Preparation method of integrated NaY molecular sieve with high silica-alumina ratio |
| CN107473238A (en) * | 2016-06-08 | 2017-12-15 | 中国石油化工股份有限公司 | A kind of KL molecular sieves and its preparation method and application |
| CN112108171A (en) * | 2019-06-21 | 2020-12-22 | 中国石油天然气股份有限公司 | Preparation method of anti-heavy metal catalytic cracking catalyst |
-
2001
- 2001-12-31 CN CN 01142881 patent/CN1204228C/en not_active Expired - Fee Related
Cited By (9)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US7390762B2 (en) | 2004-11-26 | 2008-06-24 | Petrochina Company Limited | Method for the preparation of high-content NaY molecular sieves synthesized from kaolin sprayed microspheres |
| CN100404128C (en) * | 2005-05-12 | 2008-07-23 | 中国石油天然气股份有限公司 | Catalytic cracking auxiliary agent for reducing sulfur content of gasoline, preparation method and application |
| CN100429293C (en) * | 2005-06-15 | 2008-10-29 | 中国石油天然气股份有限公司 | Preparation method of catalytic cracking catalyst |
| CN101537368B (en) * | 2008-03-19 | 2010-12-15 | 中国石油天然气股份有限公司 | Preparation method of in-situ crystallization type catalytic cracking catalyst |
| CN104211084A (en) * | 2014-09-03 | 2014-12-17 | 中国海洋石油总公司 | Preparation method of integrated NaY molecular sieve with high silica-alumina ratio |
| CN104211084B (en) * | 2014-09-03 | 2016-06-15 | 中国海洋石油总公司 | A kind of preparation method of monoblock type high silica alumina ratio NaY molecular sieve |
| CN107473238A (en) * | 2016-06-08 | 2017-12-15 | 中国石油化工股份有限公司 | A kind of KL molecular sieves and its preparation method and application |
| CN107473238B (en) * | 2016-06-08 | 2019-11-01 | 中国石油化工股份有限公司 | A kind of KL molecular sieve and its preparation method and application |
| CN112108171A (en) * | 2019-06-21 | 2020-12-22 | 中国石油天然气股份有限公司 | Preparation method of anti-heavy metal catalytic cracking catalyst |
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| Publication number | Publication date |
|---|---|
| CN1204228C (en) | 2005-06-01 |
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