CN1461747A - Oxaamidination method of oxo-compound - Google Patents
Oxaamidination method of oxo-compound Download PDFInfo
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Abstract
A process for oxaminating carbonyl compound features that under existance of Si-contained catalyst, the carbonyl compound, ammonia and hydrogen peroxide take part in liquid-phase reaction while a Si-contained liquid assistant is added to make the Si concentration reach 0.1-10000 ppm. Its advantages are long service life of catalyst and long running time.
Description
Technical field
The invention relates to the Ammoximation process of carbonyl compound.
Background technology
Carbonyl compound is meant and contains>compound of C=O functional group that as aldehydes and ketone compounds, carbonyl compound and azanol reaction are the main method of synthetic corresponding oxime compound.
With the example that synthesizes of cyclohexanone-oxime, cyclohexanone-oxime is a key intermediate of producing ε-Ji Neixianan, and ε-Ji Neixianan is important Organic Chemicals, mainly is used as the monomer of synthon and engineering plastics (as nylon-6).Industrial about 91% hexanolactam is produced through the cyclohexanone-oxime route, i.e. pimelinketone-azanol technology.This process not only complex process, Production Flow Chart is long, facility investment is high, and because of producing or use NO
X, SO
XDeng and have more serious corrosion and a pollution problem.
Early eighties, Italy Taramasso is in USP4410501, a kind of new catalytic material-HTS is disclosed, it has good selective oxidation (EP0230949 to hydrocarbon, alcohol, phenol etc., USP4480135, USP4396783), it is applied to the oxidation of phenol preparing benzenediol and has realized industrialization.
Patent EP0208311, EP0267362, EP0496385, EP0564040 etc. have reported in succession under titanium molecular sieve catalysis, are carried out the novel method of Ammoximation reaction one step preparation cyclohexanone-oxime by pimelinketone and ammonia, hydrogen peroxide.This method reaction conditions gentleness, target product yield height, and have characteristics such as technological process is simple, plant investment is few, the three wastes are few, environmentally friendly.
In addition, the Ammoximation reaction of the pimelinketone of EP0347926 report is to be catalyzer with the titanium oxide that is carried on the silicon oxide, has catalytic performance preferably equally; J.Le Bars etc. have also reported other types of molecules sieve (all based on silicon oxide) that contains Ti at Appl.Catal.A136 (1996) P69 and P.Wu etc. in P.400 at J.Catal.168 (1997), as Ammoximation reaction such as Ti-ZSM-48, Ti-β, Ti-MOR etc., all has catalytic performance preferably to multiple aldehyde, ketone compound.
Along with cyclohexanone oxamidinating being prepared progressively going deep into of cyclohexanone-oxime repercussion study, various titanium-containing catalysts mainly are that the inactivation problem of HTS in this reaction also more and more causes concern.
Report is thought in reaction process among the EP0496385, needs to adopt the method for regularly taking out decaying catalyst and replenishing fresh dose, just can keep the ideal catalyst activity.
USP5498793 discloses and has a kind ofly prepared the method for oxime by carbonyl compound, hydrogen peroxide and ammonia, is to adopt the means that add co-catalyst in reaction system, to improve the Ammoximation reaction yield and the transformation efficiency of carbonyl compound.Carbonyl compound described in this patent is methyl phenyl ketone, ring 12 carbon ketone, and co-catalyst is an amorphous silicon oxide.But the problem of co-catalyst and unresolved Primary Catalysts inactivation.
The disclosed carbonyl compound of CN1345718A, hydrogen peroxide and ammonia prepare the method for oxime, are to adopt to add the means that contain acid solid co-catalyst in reaction system, to improve the amidoxime conversion rate of carbonyl compound.But the acid solid co-catalyst that this method added, and the problem of unresolved Primary Catalysts inactivation.
G.Petrini etc. Stud.Surf.Sci.Catal.68 (1991) P.761 in, deactivation cause to HTS in the cyclohexanone oxamidinating reaction has carried out comparatively detail analysis, thinks that the deactivation cause that causes HTS has three: silicon dissolving in (1) molecular sieve, the migration of (2) skeleton titanium and (3) by product plug-hole.Preceding two reasons are all caused by ammonia, because the existence of ammonia, reaction system is alkalescence, and the silicon on the molecular sieve just can dissolve.Because the silicon dissolving is run off, and Ti still resides on the catalyzer, causes Ti content increase relatively on the catalyzer, molecular sieve crystallinity is also on a declining curve.This article is further pointed out, though in reactant flow, only be dissolved with very a spot of silicon (ppm level), but in the process of long-term operation, the silicon dissolving can cause in the reaction system molecular sieve quantity in continuous minimizing, reclaim the catalyst weight that catalyst weight is lower than initial interpolation, under extreme conditions, catalyst recovery yield only 35%.
(2001, P112) in the book, the silicon dissolving of also mentioning the molecular sieve that ammonia causes is the primary factor that causes cyclohexanone oxamidinating reacting middle catalyst inactivation at Selective Oxidation by Heterogeneous Catalysis.Because ammonia is requisite raw material in the cyclohexanone oxamidinating reaction, and is inevitable by its problem that causes.Though this problem is proved, the series of solutions of not appearing in the newspapers.Also there is similar problem in oxamidinating reaction system at other aldehyde, ketone.
In the carbonyl compound Ammoximation reaction recited above, because the silicon dissolving is run off in the catalyzer, can cause the disadvantageous effect that the catalyzer steady running time shortens and catalyst recovery yield descends, but, though the dissolving of the silicon of the molecular sieve that ammonia causes is the primary factor of catalyst deactivation, but in system, add the acid solid described in CN1345718A, but can not solve the catalyst deactivation problem as solid silica gel.
Summary of the invention
The objective of the invention is at deficiency of the prior art, a kind of catalyst deactivation process that delays is provided, prolong the catalyzer steady running time, improve the Ammoximation process of the carbonyl compound of catalyst recovery yield.
Method of the present invention comprises makes the liquid-phase reaction system that comprises carbonyl compound, ammonia and hydrogen peroxide contain reaction in the presence of the Si catalyst, it is characterized in that, the silicon additive that contains that in reaction system, has added a kind of liquid state, make the silicon concentration in the system reach 0.1~10000ppm, preferred silicon concentration reaches the dissolution equilibrium concentration of silicon in the solution.
Said carbonyl compound is selected from a kind of in pimelinketone, acetone, methylethylketone, cyclopentanone, methyl phenyl ketone, right-hydroxy acetophenone, ring 12 carbon ketone, furfural, phenyl aldehyde and the p-tolyl aldehyde.
The said Si catalyst that contains is meant the silicon oxide catalyst that contains si molecular sieves or loaded metal, wherein saidly contains form that si molecular sieves can be a molecular screen primary powder or through the form of moulding.Preferred HTS as TS-1, TS-2, Ti-ZSM-5, Ti-ZSM-12, Ti-ZSM-48, Ti-β, Ti-MCM-41 or Ti-MOR etc., wherein more preferably has the TS-1 molecular sieve of MFI crystalline structure in the said molecular sieve.
No matter contain Si catalyst is the si molecular sieves that contains of unbodied silicon oxide or different structure, in containing ammonia solution, all exist the silicon oxide structure dissolved and can reach the phenomenon of an equilibrium concentration, can variation (0.1~thousands of ppm) in but form different these equilibrium concentration values very on a large scale with medium.The inventor is surprised to find that if add liquid silicon-containing material in reaction system, this material can be preferentially dissolved in reaction system so, and it is dissolved hardly to contain Si catalyst.
In method provided by the invention, said liquid state contain silicon additive, can be the form that colloidal sol, solution, suspension or emulsion etc. are liquid, the silicon additive that contains of this liquid form can be preferentially dissolved in reaction system, and to contain Si catalyst dissolved hardly thereby make.Said liquid state contain the gas, liquid, solid form that silicon additive does not limit its raw material, add as long as this siliceous raw material is liquid form with colloidal sol, solution, suspension or emulsion etc. when adding system.The liquid form that contains silicon additive preferred sols or solution of said liquid state.
The said silicon additive that contains is selected from all kinds of inorganic silicon-containing materials or all kinds of organic silicon-containing material, and said inorganic silicon-containing material comprises silicon oxide or silicate, and said silicate comprises water glass, potassium silicate, pure aluminium silicate etc.; Said organic silicon-containing material is selected from silicon ester or silane, the preferred tetraethyl silicate of said silicon ester.
In method provided by the invention, the addition that contains silicon additive of said liquid state should make silicone content in the reaction solution at 0.1~10000ppm, makes silicone content in the reaction solution reach the addition of its dissolution equilibrium concentration after preferred the adding.Because with the difference of reaction system composition (as solvent, ammonia concentration etc.), the equilibrium concentration of silicon can change in the system, is in the reaction system of tertiary butanol and water at solvent for example, the dissolution equilibrium concentration of silicon is between 10~100ppm; And in the reaction system of water, the dissolution equilibrium concentration of silicon is 1000~3000ppm.In addition, in the method provided by the invention said liquid state contain silicon additive can with continuously or mode intermittently add, wherein preferably add in a continuous manner.
The Ammoximation process of carbonyl compound provided by the invention, be according to the dissolution law of silicon in basic solution, in the Ammoximation reaction of carbonyl compound, adopted and added the liquid step that contains silicon additive, can suppress the silicon dissolving on the catalyzer like this, slowed down the destruction of ammonia catalyzer, stable catalyst concentration in the maintenance system, minimizing prolongs catalyst life by the catalyst deactivation that silicon dissolving in the catalyzer causes, and has improved the steady running time.From the cyclohexanone oxamidinating reaction with the TS-1 molecular sieve catalytic is example, adopts method provided by the invention, and the analysis and characterization result of the TS-1 molecular sieve after the running sees, compares with fresh dose, and its degree of crystallinity, Ti content all do not change; And for not adding the system that contains the system of silicon additive or just added the silicon-containing material of solid form, deactivator after the running is then owing to the dissolving of silicon in the molecular sieve is run off, Ti still resides on the molecular sieve, cause the increase of Ti content relatively on the molecular sieve, molecular sieve crystallinity is also on a declining curve.
Embodiment
The present invention will be further described below by embodiment.
In embodiment and Comparative Examples, used HTS (TS-1) is built long stock company by Yueyang and is produced; Pimelinketone (purity 〉=99.5%) is provided by the Beijing Chemical Plant, and hydrogen peroxide (contains H
2O
227.5 weight %) provide by the Tianjin factory that orientalizes; Ammonia (purity 〉=99.9%) is provided by test chemical plant, Beijing; The trimethyl carbinol (contain the trimethyl carbinol 86.5 weight %, all the other are water and small amount of impurities) is provided by the smooth-going chemical industry in Beijing company limited; Silicon sol is Haiyang Chemical Plant, Qingdao's product; As not being specifically noted, other chemical reagent all adopts Beijing Chemical Plant's product, chemical pure.
Among the embodiment, reaction product is formed with gc analysis, and the transformation efficiency of hydrogen peroxide obtains by its content of iodometric determination.In the catalyzer in the content of Ti and the reaction system silicone content measure by inductively coupled plasma atomic emission (ICP).The degree of crystallinity of molecular sieve is measured by X-grating spectrum (XRD).
Embodiment 1
Present embodiment is the process that cyclohexanone oxamidinating prepares cyclohexanone-oxime, and catalyzer is titanium silicon (TS-1) molecular screen primary powder.
Reactor volume 150ml, magnetic agitation, oil bath heating.Reaction raw materials and the reaction product reactor of being back to back, molecular sieve is intercepted in the reactor.
Processing parameter the following is H
2O
2: pimelinketone=1.10: 1 (mol ratio), ammonia: pimelinketone=1.70: 1 (mol ratio), the trimethyl carbinol: pimelinketone=3.30: 1 (mol ratio), silicone content=35ppm in the reaction solution, catalyst concn are 1.8 weight %, and the material mean residence time is 72min, temperature of reaction is 76 ± 1 ℃, reaction pressure is a normal pressure, adds silicon sol, adds continuously.Reaction result sees Table 1, and wherein the catalyzer steady running time is in the one way runtime of pimelinketone transformation efficiency 〉=97%.
Comparative Examples 1
Repeat embodiment 1, difference is not add silicon sol.Reaction result sees Table 1.
Comparative Examples 2
Repeat embodiment 1, not continuous the interpolation contained silicon additive when difference was to react, but disposable adding acidic silica gel solid, itself and catalyzer (TS-1) amount ratio are 0.4: 1, reaction result sees Table 1.
Embodiment 2
Repeat embodiment 1, difference is: replace the trimethyl carbinol to make solvent with toluene, add tetraethoxy (Beijing chemical reagents corporation) aqueous solution, silicone content 1035ppm in the reaction solution.Reaction result sees Table 1.
Embodiment 3
Repeat embodiment 1, difference is: 83 ± 1 ℃ of temperature of reaction, reaction pressure 0.3Mpa, catalyst concn are 2.0 weight %, H
2O
2With pimelinketone mol ratio 1.08: 1, silicone content 100ppm in the reaction solution.Reaction result sees Table 2, and wherein the catalyzer steady running time is in the one way runtime of pimelinketone transformation efficiency 〉=97%.
Comparative Examples 3
Repeat embodiment 3, difference is: do not add and contain silicon additive.Reaction result sees Table 2.
Table 1
Numbering | Comparative Examples 1 | Comparative Examples 2 | Embodiment 1 | Embodiment 2 |
Contain the silicon additive kind | ????---- | The acidic silica gel solid | Silicon sol | Tetraethoxy |
Reaction result | ||||
Pimelinketone transformation efficiency % | ????98.5 | ????98.5 | ????98.6 | ????98.5 |
????H 2O 2Transformation efficiency % | ????100 | ????100 | ????100 | ????100 |
Ketone is to cyclohexanone-oxime selectivity % | ????99.6 | ????99.6 | ????99.7 | ????99.5 |
????H 2O 2To cyclohexanone-oxime selectivity % | ????89.2 | ????89.2 | ????89.4 | ????89.1 |
Catalyzer steady running time h | ????40 | ????42 | ????65 | ????60 |
Catalyst recovery yield (roasting), weight % | ????87.7 | ????88.5 | ????98.7 | ????97.8 |
Catalyst characterization result | ||||
Ti content (fresh relatively dose) % | ????106.8 | ????106.0 | ????99.5 | ????101.1 |
Degree of crystallinity (fresh relatively dose) % | ????99 | ????99 | ????100 | ????100 |
Table 2
Numbering | Comparative Examples 3 | Embodiment 3 |
Contain the silicon additive kind | ????---- | Silicon sol |
Reaction result | ||
Pimelinketone transformation efficiency % | ????99.5 | ????99.5 |
????H 2O 2Transformation efficiency % | ????100 | ????100 |
Ketone is to cyclohexanone-oxime selectivity % | ????99.6 | ????99.7 |
????H 2O 2To cyclohexanone-oxime selectivity % | ????91.8 | ????91.9 |
Catalyzer steady running time h | ????100 | ????210 |
Catalyst recovery yield (roasting), weight % | ????80.3 | ????102.8 |
Catalyst characterization result | ||
Ti content (fresh relatively dose) % | ????113.1 | ????98.6 |
Degree of crystallinity (fresh relatively dose) % | ????97 | ????100 |
From table 1 and 2 as can be seen, add after the siliceous colloidal sol or solution, activity of such catalysts, selectivity are all uninfluenced, and the steady running time ratio of comparing has obvious prolongation, and catalyst recovery yield is greater than 97 weight %; Decaying catalyst is compared with fresh dose, its degree of crystallinity, Ti content all do not change, and in the Comparative Examples, do not add siliceous colloidal sol or solution (Comparative Examples 1,3) or only silicon-containing material just join (Comparative Examples 2) in the system with solid form, the deactivator that obtains after its running is then owing to the dissolving of silicon in the molecular sieve is run off, Ti still resides on the molecular sieve, cause the increase of Ti content relatively on the molecular sieve, molecular sieve crystallinity is also on a declining curve.
Embodiment 4~7
With Ti-MOR (Si/Al=300, with the p.400 method preparation of middle record of J.Catal.168 (1997)) be catalyzer, embodiment 4~7 is respectively to be that carbonyl compound raw material and ammonia, hydrogen peroxide carry out the Ammoximation reaction process with acetone, cyclopentanone, phenyl aldehyde, p-tolyl aldehyde, with water is solvent, adds silicon sol.Reaction process condition the following is H
2O
2: ketone (aldehyde)=1.15: 1 (mol ratio), ammonia: ketone (aldehyde)=2.0: 1 (mol ratio), water: ketone (aldehyde)=8: 1 (volume ratio), catalyst concn is 3.0 weight %, the material mean residence time is 120min., and temperature of reaction is 60 ± 1 ℃, and pressure is normal pressure.
Reaction result sees Table 3, and wherein the catalyzer steady running time is in the one way runtime of used ketone or the transformation efficiency of aldehyde 〉=90%.
Table 3
Numbering | Embodiment 4 | Embodiment 5 | Embodiment 6 | Embodiment 7 |
The carbonyl compound type | Acetone | Cyclopentanone | Phenyl aldehyde | P-tolyl aldehyde |
Silicone content ppm in the reaction solution | ??150 | ??450 | ?520 | 600 |
Relative catalyzer steady running time % (with comparing the runtime of not adding silicon) | ??155 | ??140 | ?130 | 145 |
Catalyst recovery yield (roasting) weight % | ??98.5 | ??97.2 | ?96.5 | 97.9 |
Adopt method provided by the invention, after adding silicon sol, activity of such catalysts, selectivity are all uninfluenced, transformation efficiency is more than 90%, selectivity is 95~99.5%, as can be seen from Table 3, the steady running time of catalyzer is with having compared tangible prolongation the runtime of not adding silicon sol, and catalyst recovery yield is more than 96 weight %.
Embodiment 8
Adopt the silicon oxide catalyst (preparation method is with EP0347926 embodiment 6) of load Ti, carry out the reaction of pimelinketone and ammonia, hydrogen peroxide, processing condition are with embodiment 1.After adding silicon sol, this activity of such catalysts, selectivity are all uninfluenced, but the steady running time of catalyzer do not add and prolong 30% the runtime of silicon sol, catalyst recovery yield is 97 weight %.
Claims (15)
1, a kind of Ammoximation process of carbonyl compound, comprising making the liquid-phase reaction system that comprises carbonyl compound, ammonia and hydrogen peroxide contain reaction in the presence of the Si catalyst, it is characterized in that, the silicon additive that contains that has added a kind of liquid state in reaction system makes the silicon concentration in the system reach 0.1~10000ppm.
2,, it is characterized in that said carbonyl compound is selected from a kind of in pimelinketone, acetone, methylethylketone, cyclopentanone, methyl phenyl ketone, right-hydroxy acetophenone, ring 12 carbon ketone, furfural, phenyl aldehyde and the p-tolyl aldehyde according to the said method of claim 1.
3,, it is characterized in that the said Si catalyst that contains is selected from the silicon oxide catalyst that contains si molecular sieves or loaded metal according to the said method of claim 1.
4,, it is characterized in that the said si molecular sieves that contains is a HTS according to the said method of claim 3.
5,, it is characterized in that said HTS is selected from a kind of among TS-1, TS-2, Ti-ZSM-5, Ti-ZSM-12, Ti-ZSM-48, Ti-β, Ti-MCM-41 or the Ti-MOR according to the said method of claim 4.
6,, it is characterized in that saidly containing form that si molecular sieves is a molecular screen primary powder or through the form of moulding according to the said method of claim 3.
7,, it is characterized in that the said silicon additive that contains is selected from all kinds of inorganic silicon-containing materials or all kinds of organic silicon-containing material according to the said method of claim 1.
8,, it is characterized in that said inorganic silicon-containing material is selected from silicon oxide or silicate according to the said method of claim 7.
9,, it is characterized in that said silicate is selected from water glass, potassium silicate or pure aluminium silicate according to the said method of claim 8.
10,, it is characterized in that said organic silicon-containing material is selected from silicon ester or silane according to the said method of claim 7.
11,, it is characterized in that said silicon ester is a tetraethyl silicate according to the said method of claim 10.
12, according to the said method of claim 1, the addition that contains silicon additive that it is characterized in that said liquid state should make the silicone content in the reaction solution reach the dissolution equilibrium concentration of silicon in the solution.
13,, it is characterized in that the silicon additive that contains of said liquid state adds with continuous or mode intermittently according to the said method of claim 1.
14,, it is characterized in that the silicon additive that contains of said liquid state adds in a continuous manner according to the said method of claim 13.
15,, it is characterized in that the silicon additive that contains of said liquid state is silicon sol or siliceous solution according to the said method of claim 1.
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Cited By (7)
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CN1328248C (en) * | 2005-12-28 | 2007-07-25 | 华东师范大学 | Process for producing oxime |
CN100378069C (en) * | 2005-02-05 | 2008-04-02 | 中国石油化工股份有限公司 | P-hydroxy acetophenone oxamidine reaction product refining method |
CN102336683A (en) * | 2010-07-15 | 2012-02-01 | 住友化学株式会社 | Method for producing oxime |
CN1978425B (en) * | 2005-12-07 | 2012-07-04 | 住友化学株式会社 | Process for producing cyclohexanone oxime |
CN107008493A (en) * | 2017-04-12 | 2017-08-04 | 中国天辰工程有限公司 | A kind of preparation method for alkene epoxidation or the titanium-containing catalyst of ketone oxamidinating |
CN107118124A (en) * | 2017-06-19 | 2017-09-01 | 中触媒新材料股份有限公司 | A kind of method for suppressing ammoxidation of cyclohexanone catalyst loss |
US10654795B2 (en) | 2017-03-03 | 2020-05-19 | Chemical Technology Academy Of Shandong Province | Method for synthesizing ketoxime |
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2003
- 2003-05-30 CN CN 03137914 patent/CN1246301C/en not_active Expired - Lifetime
Cited By (9)
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CN100378069C (en) * | 2005-02-05 | 2008-04-02 | 中国石油化工股份有限公司 | P-hydroxy acetophenone oxamidine reaction product refining method |
CN1978425B (en) * | 2005-12-07 | 2012-07-04 | 住友化学株式会社 | Process for producing cyclohexanone oxime |
CN1328248C (en) * | 2005-12-28 | 2007-07-25 | 华东师范大学 | Process for producing oxime |
CN102336683A (en) * | 2010-07-15 | 2012-02-01 | 住友化学株式会社 | Method for producing oxime |
US10654795B2 (en) | 2017-03-03 | 2020-05-19 | Chemical Technology Academy Of Shandong Province | Method for synthesizing ketoxime |
CN107008493A (en) * | 2017-04-12 | 2017-08-04 | 中国天辰工程有限公司 | A kind of preparation method for alkene epoxidation or the titanium-containing catalyst of ketone oxamidinating |
CN107008493B (en) * | 2017-04-12 | 2020-05-22 | 中国天辰工程有限公司 | Preparation method of titanium-containing catalyst for olefin epoxidation or ketone ammoximation |
CN107118124A (en) * | 2017-06-19 | 2017-09-01 | 中触媒新材料股份有限公司 | A kind of method for suppressing ammoxidation of cyclohexanone catalyst loss |
CN107118124B (en) * | 2017-06-19 | 2019-04-23 | 中触媒新材料股份有限公司 | A method of inhibiting ammoxidation of cyclohexanone catalyst loss |
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