CN1187334C - Preparation of hexanolactam - Google Patents
Preparation of hexanolactam Download PDFInfo
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- CN1187334C CN1187334C CNB021374589A CN02137458A CN1187334C CN 1187334 C CN1187334 C CN 1187334C CN B021374589 A CNB021374589 A CN B021374589A CN 02137458 A CN02137458 A CN 02137458A CN 1187334 C CN1187334 C CN 1187334C
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- reaction
- hexanolactam
- parts
- oxime
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P20/00—Technologies relating to chemical industry
- Y02P20/50—Improvements relating to the production of bulk chemicals
- Y02P20/52—Improvements relating to the production of bulk chemicals using catalysts, e.g. selective catalysts
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Abstract
The present invention relates to a method for preparing caprolactam from cyclohexanone oxime by gas-phase Beckmann rearrangement reaction, which mainly solves the problems of low conversion rate of cyclohexanone oxime, or low caprolactam selectivity and poor stability in the prior art. The method well solves the technical problems and is capable of being used for the industrial production of caprolactam preparation by the technical scheme that the cyclohexanone oxime is converted into the caprolactam by gas-phase Beckmann rearrangement reaction in the mode of boron oxide carried on a titanium zirconium compound oxide carrier as a catalyst under the conditions of reaction temperature of 250 to 400 DEG C, reaction pressure of 0 to 0.5MPa, inert gas as carrying gas and strong-polarity compounds as solvent.
Description
Technical field
The present invention relates to a kind of method for preparing hexanolactam, particularly rearrangement reaction prepares the method for hexanolactam about cyclohexanone-oxime gas phase Beckmann.
Background technology
Hexanolactam is one of important source material of synthon and synthetic materials, be mainly used in and make daiamid-6 fiber (nylon 6), resin and film, also be used as the raw material of medicine, coating, leatheroid, softening agent, and be used for chemosynthesis Methionin on a small quantity, at numerous areas such as weaving, plastics, fine chemistry industries purposes is widely arranged.The Beckmann rearrangement reaction of cyclohexanone-oxime is a most important technological process in the caprolactam production process, and the influence of quality product is played a crucial role.Current industrial production is to be catalyzer with the vitriol oil or oleum, and cyclohexanone-oxime is converted into hexanolactam vitriol through liquid phase Beckmann rearrangement reaction, and then makes with the ammonia neutralization.Though use the vitriol oil to have very high selectivity, produce the byproduct of ammonium sulfate that belongs to the poor efficiency chemical fertilizer in a large number simultaneously, and because the existence of the vitriol oil a series of problems such as conversion unit burn into contaminate environment and safety have been caused as catalyzer.
In order to overcome problems and the shortcoming that above-mentioned homogeneous phase Beckmann rearrangement reaction is brought, people developed under the solid acid catalyst effect heterogeneous rearrangement technology especially gas-solid reset technology mutually.Used catalyzer mainly contains oxide compound (comprising single oxide and composite oxides) and molecular sieve (comprising zeolite-type molecular sieves and non-zeolitic molecular sieves).
Document is entitled as to disclose in the U.S. Pat 3639391 (1972) of " method that the cyclic ketone oxime rearrangement prepares acid amides " and a kind ofly prepares corresponding amide by the ring-type ketoxime, and particularly by the solid acid catalyst of preparing caprolactam with cyclohexanone-oxime, it is with Thorotrast (ThO
2) be carrier, the oxide compound of boron is an active ingredient.Though this catalyzer is to have higher initial activity under the reaction conditions of carrier gas at normal pressure, 320 ℃ of temperature of reaction, argon gas, the cyclohexanone-oxime transformation efficiency that reacted 0.5 hour is 99.1%, but its less stable, after reaction 5 hours, the cyclohexanone-oxime transformation efficiency just drops to 68.5%.
Document is entitled as the HOII P NL8204837 (1984) of " method that cyclohexanone-oxime is converted into hexanolactam with silica-based heterogeneous catalyst ", adopts the silica-based molecular sieve (SiO of boracic
2/ B
2O
3Than being 220) be catalyzer, be solvent, N at 340 ℃ of temperature of reaction, toluene
2Under the reaction conditions for carrier gas, the transformation efficiency of cyclohexanone-oxime is 100%, but this selectivity of catalyst has only 58%.
The disclosed solid acid catalyst of European patent EP 0823422A1 (1998) that document is entitled as " by the method for oxime system acid amides " is the SiO with special construction
2-Al
2O
3Compound, its Si/Al ratio is 20~1000, average pore radius is 20~100 , still is undefined structure after 550 ℃ of roastings.Though this catalyzer is made solvent, N at methyl alcohol
2Have good active under the reaction conditions for 380 ℃ of carrier gas, temperature, react 44 hours cyclohexanone-oxime transformation efficiencys still greater than 99%, but its selectivity not ideal enough (<80%).
Above-mentioned several solid acid catalyst is used for cyclohexanone-oxime gas phase Beckmann rearrangement reaction, and its performance can't be satisfactory, and particularly active and selectivity often can't reach high value simultaneously, so can't satisfy industrial requirement.
Summary of the invention
Technical problem to be solved by this invention is in the prior art, activity of such catalysts and selectivity can't reach high value simultaneously, thereby make the yield of hexanolactam not high, cause the problem of subsequent process loaded down with trivial details or the wasting of resources and poor stability, provide a kind of cyclohexanone-oxime gas phase Beckmann that is used for to reset the method for preparing hexanolactam.Use this method to have cyclohexanone-oxime transformation efficiency height, the hexanolactam selectivity is good, makes the good characteristics of catalyst stability simultaneously.
For solving the problems of the technologies described above, the technical solution used in the present invention is as follows: a kind of method for preparing hexanolactam, with the cyclohexanone-oxime is raw material, reaction is inert gasses is carrier gas, with the polar compound is solvent, and raw material is 250~400 ℃ by beds in temperature of reaction, reaction pressure is 0~0.5Mpa, and weight space velocity is 0.1~1.0 hour
-1Beckmann takes place under the condition reset the generation hexanolactam, used catalyzer contains following component in parts by weight:
A) composite oxide carrier of being made up of titanium oxide and zirconium white is 50~95 parts; Be stated from this composite oxide carrier
B) oxide compound of boron is 5~50 parts.
In the used composite oxide carrier, the molar fraction of titanium atom is 0.1~0.95 in the technique scheme, and preferable range is 0.5~0.75.In parts by weight, the amount preferable range of composite oxide carrier is 70~90 parts in the catalyzer, and the amount preferable range of the oxide compound of boron is 10~30 parts, and the catalyzer preferred version is 0.1~5 part of the metal that also contains platinum or oxide compound.The temperature of reaction preferable range is 280~320 ℃, and the reaction pressure preferable range is 0~0.2MPa, and the weight space velocity preferable range is 0.2~0.4 hour
-1Reaction is inert gasses is selected from least a in helium, neon, argon gas, hydrogen, nitrogen or the carbonic acid gas, preferred version is a nitrogen; Polar compound is selected from least a in trichloromethane, acetone, tetrahydrofuran (THF) or the acetonitrile, and preferred version is an acetonitrile, cyclohexanone-oxime: the weight ratio of solvent is 1: 1~50.
Catalyzer of the present invention be by the metal of composite oxides and boric acid or composite oxides, boric acid and platinum or oxide compound through dipping or after mixing drying and high-temperature roasting make.
The composite oxide carrier preparation method can adopt method preparations such as coprecipitation method, sluggish precipitation and sol-gel method.Used raw material can be muriate such as TiCl
4, AlCl
3Oxychlorination thing such as ZrOCl
2Nitrate such as Zr (NO
3)
4Nitric acid oxonium salt such as ZrO (NO
3)
2With vitriol such as TiSO
4, (Ti)
2(SO
4)
3Deng; Precipitation agent can adopt ammoniacal liquor or urea etc.
The general preparation method of composite oxide carrier is that the salt solution mix with two or more is even then with the salt wiring solution-forming of each component.Under vigorous stirring, adding a certain amount of precipitation agent to the pH value of solution is 7~12.Through ageing, filtration, do not exist to there being harmful ion then with the distilled water repetitive scrubbing.Last drying, certain temperature (100~800 ℃) are descended roasting and are made.
Among the present invention, be carrier owing to adopted with the titanium zirconium mixed oxide, prepared boron oxide catalyzer not only has very high activity, and has very high selectivity, thereby makes the yield of hexanolactam improve greatly.The high-performance that catalyzer of the present invention had may to have unique character relevant with the composite oxide carrier that is adopted, composite oxide carrier and the loading type boron oxide catalyzer for preparing thus, have more cyclohexanone-oxime the acid site that the Beckmann rearrangement reaction generates the required certain strength of hexanolactam takes place, thereby improved activity of such catalysts and selectivity greatly.In addition, owing to adopted the stronger solvent of polarity, it helps reacting the hexanolactam that generated from the quick desorption of catalyst surface, generates the speed of carbon deposit thereby suppressed it by further reaction, has finally improved selectivity of catalyst and stability significantly.The transformation efficiency of cyclohexanone-oxime is up to 100%, and the selectivity of product hexanolactam has obtained better technical effect up to 98.6% simultaneously.
The present invention uses the continuous flow fixed-bed micro-reactor to carry out the investigation of cyclohexanone-oxime gas phase Beckmann rearrangement reaction catalyst performance, and reactor inside diameter is 6 millimeters, and length is 300 millimeters, stainless steel.Adopt electrically heated, temperature is controlled automatically.Reactor bottom filling 40~60 purpose inert materials are as upholder, filling 0.8 gram catalyzer in the reactor, and filling 40~60 purpose inert materials in catalyzer top are made for the usefulness of raw material preheating and vaporization.The raw material cyclohexanone-oxime mixes with carrier gas, from top to bottom by beds, the Beckmann rearrangement reaction takes place, and generates purpose product hexanolactam and by products such as a spot of pimelinketone, cyclonene, 5-cyanogen pentane, 5-cyanogen-1-amylene and aniline.
The present invention is further elaborated below by embodiment.
Embodiment
[embodiment 1]
Analytical pure boric acid 4.8 gram is dissolved in 16 ml waters is made into boric acid aqueous solution, adding 20 then in this solution, to restrain titaniums, atomic percent zirconium be 1: 1 TiO
2-ZrO
2Composite oxide carrier (40~60 order) makes catalyzer then after oven drying, retort furnace high-temperature roasting.
[embodiment 2]
With embodiment 1 prepared catalyzer, in continuous flow fixed bed minisize reaction evaluating apparatus, carry out the active investigation of cyclohexanone-oxime gas phase Beckmann rearrangement reaction.The loadings of catalyzer: 0.8 gram; Temperature of reaction: 250~400 ℃; Pressure: 0.1MPa; Air speed: 0.33 hour
-1(in cyclohexanone-oxime weight); Carrier gas (high-purity N
2); Flow: 30 ml/min.After catalyst loading is intact, be pre-treatment 60 minutes under the condition of 50 ml/min at 350 ℃, carrier gas flux earlier.Then with the stupid solution (5 weight %) of cyclohexanone-oxime through micro-fresh feed pump injecting reactor.Reaction product adopts ice-water bath cooling back to collect quantitative analysis on the HP4890 gas chromatograph.Evaluation result sees Table 1.
Table 1 temperature of reaction is to B
2O
3/ TiO
2-ZrO
2The influence of reactivity worth
*
Temperature of reaction, ℃ cyclohexanone-oxime transformation efficiency, % hexanolactam selectivity, % hexanolactam yield, %
250 43.8 91.5 37.5
280 77.4 92.6 67.8
300 98.3 95.0 93.4
320 100 85.2 85.2
350 100 79.8 79.8
400 100 63.5 63.5
*React 6 hours mean value.
This shows, when temperature of reaction is 280~320 ℃, B
2O
3/ TiO
2-ZrO
2Catalyzer has high reaction activity and high and hexanolactam selectivity and stable preferably, thereby has the highest hexanolactam yield.
[embodiment 3]
Adopt and the influence of the similar different carrier gas of condition evaluating of the foregoing description 2 catalyst performance.Wherein, temperature of reaction is 300 ℃.Evaluation result sees Table 2.
Table 2 carrier gas is to B
2O
3/ TiO
2-ZrO
2The influence of catalytic performance
*
Carrier gas cyclohexanone-oxime transformation efficiency, % hexanolactam selectivity, % hexanolactam yield, %
He 95.3 96.8 92.2
N
2 98.3 97.0 95.4
H
2 96.8 97.2 94.1
CO
2 96.8 94.3 91.3
NH
3-He
** 78.9 79.2 62.5
*React 6 hours mean value;
The result of table 2 shows, with He, H
2, N
2And CO
2When doing carrier gas, the transformation efficiency of cyclohexanone-oxime and the selectivity of hexanolactam are all higher, wherein, and with N
2During for carrier gas, the yield of hexanolactam is the highest.Contain alkaline gas NH and adopt
3Percent by volume is 5% NH
3When-He gas mixture was done carrier gas, the transformation efficiency of cyclohexanone-oxime and the selectivity of hexanolactam all obviously reduced, and this is because the NH of alkalescence
3Poisoned due to the acid site of catalyst surface.
[embodiment 4]
With embodiment 1 prepared catalyzer, adopt the influence of the condition evaluating different solvents similar to catalyst performance to the foregoing description 2.Wherein, temperature of reaction is 300 ℃, and carrier gas is a nitrogen.Evaluation result sees Table 3.
Table 3 solvent is to B
2O
3/ TiO
2-ZrO
2The influence of catalytic performance
*
Solvent cyclohexanone-oxime transformation efficiency, % hexanolactam selectivity, % hexanolactam yield, %
Benzene 98.3 97.0 95.4
Hexanaphthene 97.6 95.6 93.3
Trichloromethane 98.4 88.9 87.5
Acetone 100 90.6 90.6
Tetrahydrofuran (THF) 100 97.2 97.2
Acetonitrile 100 98.6 98.6
*React 6 hours mean value.
By table 3 as seen, when adopting the lower benzene of polarity, cyclohexane give solvent, the transformation efficiency that reacts cyclohexanone-oxime in 6 hours has been lower than 100%, and when adopting stronger acetonitrile, acetone and the tetrahydrofuran (THF) of polarity to make solvent, any deactivation phenomenom do not occur at 6 hours inner catalysts of reaction, the transformation efficiency of cyclohexanone-oxime maintains 100% all the time.Particularly, when being solvent with acetonitrile, not only the stability of catalyzer significantly improves, and the selectivity of hexanolactam also obviously improves (react in 6 hours, hexanolactam optionally mean value reaches 98.6%).When being solvent with acetonitrile, in successive reaction 9 hours, the transformation efficiency of cyclohexanone-oxime keeps 100% all the time.
[embodiment 5]
Preparation catalyzer method and examining method and condition are all with embodiment 4, and the carrier add-on that just changes composite oxides is 40 grams, boric acid 9.6 grams, and other adds 0.25 gram Platinic chloride, and solvent is an acetonitrile, and carrier gas is a nitrogen.Appraisal result is 100% for the cyclohexanone-oxime transformation efficiency, and the hexanolactam selectivity is 98.1%.In the successive reaction 11 hours, the transformation efficiency of cyclohexanone-oxime is always 100%.
[embodiment 6]
Preparation catalyzer method and examining method and condition are all with embodiment 4, and the carrier add-on that just changes composite oxides is 5 grams, boric acid 4.6 grams, and other adds 0.25 gram Platinic chloride, and solvent is an acetonitrile, and carrier gas is a nitrogen.Appraisal result is 100% for the cyclohexanone-oxime transformation efficiency, and the hexanolactam selectivity is 98.4%.In the successive reaction 12 hours, the transformation efficiency of cyclohexanone-oxime is always 100%.
Claims (10)
1, a kind of method for preparing hexanolactam, with the cyclohexanone-oxime is raw material, reaction is inert gasses is carrier gas, with the polar compound is solvent, raw material is 250~400 ℃ by beds in temperature of reaction, and reaction pressure is 0~0.5MPa, weight space velocity is Beckmann to take place under 0.1~1.0 hour-1 condition reset and generate hexanolactam, and used catalyzer contains following component in parts by weight:
A) composite oxide carrier of being made up of titanium oxide and zirconium white is 50~95 parts; Be stated from this composite oxide carrier
B) oxide compound of boron is 5~50 parts.
2, according to the described method for preparing hexanolactam of claim 1, in the composite oxide carrier that it is characterized in that being made up of titanium oxide and zirconium white, the molar fraction of titanium atom is 0.1~0.95.
3, according to the described method for preparing hexanolactam of claim 2, in the composite oxide carrier that it is characterized in that being made up of titanium oxide and zirconium white, the molar fraction of titanium atom is 0.5~0.75.
According to the described method for preparing hexanolactam of claim 1, it is characterized in that 4, the amount of composite oxide carrier is 70~90 parts in parts by weight.
According to the described method for preparing hexanolactam of claim 1, it is characterized in that 5, the amount of the oxide compound of boron is 10~30 parts in parts by weight.
6,, it is characterized in that in the catalyzer also containing 0.1~5 part of the metal of platinum or oxide compound in parts by weight according to the described method for preparing hexanolactam of claim 1.
7, according to the described method for preparing hexanolactam of claim 1, it is characterized in that temperature of reaction is 280~320 ℃, reaction pressure is 0~0.2MPa, weight space velocity is 0.2~0.4 hour
-1
8,, it is characterized in that reaction is inert gasses is selected from least a in helium, neon, argon gas, hydrogen, nitrogen or the carbonic acid gas according to the described method for preparing hexanolactam of claim 1; Polar compound is selected from least a in trichloromethane, acetone, tetrahydrofuran (THF) or the acetonitrile.
9, the described according to Claim 8 method for preparing hexanolactam is characterized in that it is nitrogen that reaction is inert gasses, and polar compound is an acetonitrile.
10, according to the described method for preparing hexanolactam of claim 1, it is characterized in that cyclohexanone-oxime: the weight ratio of solvent is 1: 1~50.
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CNB021374589A CN1187334C (en) | 2002-10-16 | 2002-10-16 | Preparation of hexanolactam |
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Families Citing this family (4)
Publication number | Priority date | Publication date | Assignee | Title |
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CN100389108C (en) * | 2004-11-17 | 2008-05-21 | 中国石油化工股份有限公司 | Production of hexyl lactam in ion liquid |
CN109503483B (en) * | 2018-12-27 | 2021-12-14 | 中国天辰工程有限公司 | Catalyst for preparing caprolactam through liquid phase Beckmann rearrangement and preparation method thereof |
CN114507171B (en) * | 2022-02-24 | 2024-07-23 | 江苏扬农化工集团有限公司 | Preparation method of caprolactam |
CN115364894B (en) * | 2022-08-25 | 2023-06-06 | 太原理工大学 | Preparation method of high-selectivity catalyst for preparing olefin from methanol |
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