前苏联专利SU942576A3 Method of preparing catalyst for oxidizing mercaptanes

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专利摘要:
A catalyst comprising a metal phthalocyanine composition of matter is prepared by reacting a 4-sulfophthalic acid with a metal salt, an ammonium donor and a phthalic anhydride or derivative thereof at 250 to 325 C for one-half to ten hours.
公开号:SU942576A3
申请号:SU772454654
申请日:1977-02-23
公开日:1982-07-07
发明作者:Марк Дуглас Уолтер
申请人:Юоп Инк. (Фирма)；
IPC主号:

专利说明:

(54) METHOD FOR PREPARING A CATALYST TO COMBINED MERCAPTANS
one
The invention relates to the manufacture of catalysts, in particular, to methods for preparing catalysts for the oxidation of mercaptans.
The closest to the invention by. The j technical essence is a method for preparing a catalyst for the oxidation of mercaptans based on cobalt phthalocyanines, which consists in the interaction of phthalic anhydride with urea, a cobalt salt, ammonium molybdate and a sulfuric acid with sulfuric acid
0-2000S G1.
The disadvantages of this method include its complexity, which implies 5 seconds of use of sulfuric acid or oleum in the amount of sulfating agent.
The purpose of the invention is to simplify the method of preparation. .
This goal is achieved by the fact that 20 according to the method for preparing a catalyst for the oxidation of mercaptans based on cobalt phthalocyanines, consisting in the interaction of phthalic anhydride with urea, a cobalt salt, and
ammonium and a sulphating agent, 4-sulfophthalic acid or its sodium salt is used as a sulfiding agent at a phthalic anhydride: 4-sulfophthalic acid or its sodium salt weight ratio equal to (2-4): 1, and the reaction is carried out in aqueous medium at 165-266 ° C for 1-6.5 hours. The distinctive features of the proposed method are the use of 4-hydrophthalic acid as its sulfating agent, its sodium syphide, the specified ratio of phyalevic acid and sulfating agent, and in these conditions conduct interaction.
The essence of the proposed method is as follows.
The reaction mass, containing 4-sulfophthalic acid, phthalic anhydride, cobalt salt, urea and ammonium molybdate, is heated in steps, with one or two intermediate temperatures or heated immediately to a high temperature of 25 ° -25 ° C. With three degrees of heating, the reaction mass is first heated to 165-2 ± ± r ° C, then brought to a temperature of 20 ° C250 ° C. And finally, the temperature is raised to 25 ° -25 ° C. With a lower temperature, the percentage of the required component reaches about 25%. If the initial temperature is below 165 ° C, low outputs make this process economically advantageous. When using one-step heating, the optimum yield of the target component of the catalytic composition is achieved by heating to 250325 C and keeping at this temperature for 1 / 2-10 hours. When using three-step heating at the first temperature, the reaction between 4-sulfate phthalic acid, phthalic anhydride No.-. house and urea with the formation of an intermediate substance of the desired composition and configuration required for the subsequent co-dexation into the product. It is characterized by the internal ring structure of phthalocyanine compounds. The use of lower temperatures in the first stage of heating reduces the amount of the target component in the final catalytic product by 50%. A typical catalyst contains more than one co-agent, one of which (the monosulfonated component) is the most desirable component for a fixed bed system used in the desulfurization process. If the first reaction temperature is according to the present invention, then the final product. i L .- - -. contains more than 50% of the target component and the rest falls to more heavily sulfonated compounds. If the first reaction temperature is lower than that specified in the present invention, the content of the target component may fall below 25% of the resulting product with a corresponding increase in the yield of more deeply sulfonated compounds. This effect is undesirable. Since more deeply sulfonated compounds are such components that can be removed. The carrier on which the catalyst is supported. At lower temperatures, the reactivity of 4-Sulfophthalic acid is higher than: the reactivity of phthalic anhydride. In this case, the acid preferably enters into a condensation reaction with the formation of an intermediate compound, which is prone to subsequent condensation into a phalohaline structure. As a result of this dominance of the first reaction, the product is enriched with more highly sulfonated compounds. During the second stage of heating, the oS is decomposed in the first stage, then the southerne compound is condensed by forming and closing the ring, in re.-. the result. receive a product with characteristic features of phalocyanine structure. Ammonium molybdate facilitates the formation and closure of the ring by the coordination reaction to the intermediate compound. This reaction KOOJ of the translation translates part of the intermediate compound into the spatial state that is necessary before the final formation of the product. At some points during this process, the atoms of metals, such as cobalt, nickel, vanadium, etc., which will be part of the final product, are placed in the center of the phthalocyanine ring, giving the final product. In the case when one-stage mixing with heating up to temperatures of 250325 0, reactions that develop with two-fold and three-stage heating, are accelerated and, if properly fulfilled, the conditions for dehydration of the initial reaction mass and increasing its temperature can be considered as proceeding simultaneously. The cobalt phthalocyanine is obtained in accordance with the proposed method and contains predominantly monosulfonate, but also includes some more deeply sulfonated materials, such as disulfonate, trisulfonate and tetrasulfonate. In contrast to the catalysts prepared by the sulfonation of cobaltphthalocyanine in oleum (in accordance with the previously known method), the presence of these more iviy6oKo sulfonated components in the catalytic reaction mass prepared by the proposed method does not lead to the loss of the catalyst from the base layer. The catalyst obtained by the proposed method can be introduced into a solid carrier, as which any porous material with a highly developed surface can be used, for example, Fuller's earth, bentonite, charcoal, alumina, mordenite, fuja. zit or any other well-known - carrier, catalysts. However, when using different media dos. Different results are expected, and the technique for impregnating different carriers is not the same. Charcoal is particularly preferred. PRI me R. In accordance with the proposed method, as well as with previously known methods, several specimens of catalysts are prepared. In order to compare the proposed catalyst with known catalysts, cobalt-phthalodianine is sulphured with sulfuric acid in a carbon dioxide atmosphere by the ITlJ method. In this experiment, 52 hours of cobalt-phthalodianine was added to 720 parts of 1.OO% sulfuric acid for 1.5 hours. The mixture was stirred at KOMatal temperature for 16 hours in order to completely dissolve the cobalt-phthalocyanine. The reaction mixture is heated to 120il ° C for 2.5-3.0 h and then maintained at the specified temperature for 6, O h. The reaction is considered to completely pass when 2 sulphonated products boil for 30 s. 1O cm 1O% sodium carbonate is completely dissolved by the addition of 2 cm of pyridine. To achieve this, a holding time of 6 hours is necessary. The sulfonation product is isolated according to a known method. In the preparation of the catalyst according to the proposed method is mixed with 15 wt. 4.50% solution of 4-sulfophthalic acid, 9.3 parts, p, 0.1 ppm ammonium molybdate and 15 wt. partly up to complete dissolution of the solid. 4O urea is added to the gdn solution and the mixture is stirred until the bulk of the urea is dissolved. The resulting reaction mixture is poured into a reactor, to which 14 parts of a gum anhydride is preliminarily added. The entire reaction mixture is placed in a heating vessel, which is preheated to 21 ° C. The temperature of the reaction mixture is maintained within 190-215 0 for 3 hours, then it is raised to 260-270 ° C and the mixture is kept at this temperature for another 3.5 hours. After cooling and grinding the reaction product, the material is subjected to chromatographic analysis. It is found that 54% of the monosulfonated material is contained in the product (Catalysis Ator O, Table 2). Chromatographic analysis of various catalysts is carried out in order to establish the difference between the different catalysts obtained. From chromatography it follows that the catalyst according to the inventive method differs from the known catalyst. However, not all chromatographic separated substances were identified. Some of the components of the catalyst are only indicated to unidentified substances A and B,. relative to others, it is known that it is. two forms of monosulfonate M (and Mrj, but it is not possible to indicate the difference between these substances. Similarly, using the chromatographic method, it was found that there are two forms of disulfonated Hbtx products, but it was impossible to establish the exact configuration of the derivatives. Table 1 and No. 2 indicate the reaction conditions for the preparation of each catalyst and the used weight ratios of the reagents. Data on the activity of some of the most promising catalysts are given - With respect to the conversion sulfur of mercaptans to disulfides. During the experiment, the ability of the catalyst to desulfurize away from the kerosene fraction, the desulfurization of which is known to be rather difficult, is determined. These experiments were carried out only for comparison. The experimental procedure is the same for all catalysts - charcoal, the same reaction conditions during the oxidation of mercaptans and the use of the same type of processed raw materials. Thus, the pred. it is possible to compare catalysts under certain identical conditions. The results indicate the weight content of mercaptans, expressed in parts per million, at the exit of the installation with a STILL layer after 2 hours of operation of the installation. For some talizatorov. Indicated content of mercaptans and for some intermediate sampling times. From the results of the experiments, it follows that the catalyst prepared in accordance with the oleum method, and even a part of the catalyst according to the proposed method, is characterized by an increase in activity during a certain initial time, after which the activity slowly decreases. Other catalysts for the proposed method seb differently, namely, their highest activity is recorded at the very beginning of the process of precipitating
79425768
Riva1sh to 8th active gradually are predpochtvtelnyh are katumenshayas. lvtortori received one-step nag
In tab. 1 is shown to a high temperature, i.e.
The concentration of phthalic angiocatalysts S in T. lzmenett. The activity of the cathode on the product at natomal values 5 and T and T is higher than the industrial time of the reaction temperature. In tab. The 2nd monosulfurized catalyst (J, N 3 illustrates the effect of some Changes in the reagents used, but the effect of the Temperature change during the preparation process of the catalyst is illustrated beforehand. In Table 4, the data correspond to the exact time intervals of the mercaptans transformation process. All The catalysts listed in Table 4 are also included in Tables 2 and 3. However, additional data are given in Table 4. Having analyzed the obtained data, it is clear that the catalyst according to the proposed method has The increased fe activity of the process of transforming mercaptans. The catalyst U is obtained in the same way as catalyst V by reaction with sulfuric acid or oleum. The ratio M2 / M is the same in each of the oleum methods and is equal to 2.7: 1. The catalyst according to the proposed method is characterized a completely different ratio, equal to pruaderno 0.5: 1 for catalyst S and 0.8: 1 for catalyst T. These ratios refer to the different monosulfonated isomers M- and Mij. Thus, the catalysts of the proposed method are different from catalysts obtained previously by known methods, and they are obtained in a much simpler way, I.Table
1 23.4
26.0
24.9 25.8
135/1 A35 / 2
135/1 135/2 165/2 165/2 165/2 165/2 210/2 210/1 210/1 210/1 260/2 260/2 260/2 260/2
1.0 1.0
1.0
28,229.0 23.6
135/1135/1 170/2
165/2165/2 225/2
210/1210/1 266/2
260/2260/2 1, 0
1.0
1.0
1.0 1.0
28 47
Monosulfonat.
# Disulfonate,
# Trisulfonate.
Tetrasulfonat. TERMS AND CONDITIONS hacking; galizagora, C / h 215 / 2.5 215 / 2.5 1 265 / 3.75565 / 3.75 4-sulfofga. left acid 1,01,0 phthalic anhydride 2, 53,0
Catalyst activity (after 20 hours), parts per million 36 Disodium 4-sulfophthalate, used instead of
942576
lO Continued table. one
table 2
26
24
28
28 , 5 165 / 2.5 215/3 215/3 115-210 / 3 215 / 2.0 215 / 2.0 265 / 3.5265 / 3.5 265/3 265 / 2.5 265 / 2.5 -1, 0 1, 01.01.0 3.02.23.03.33.0 4-sulfophalic acid f
48
47
natov
Conditions of receipt
catalyst, C / h 115-210 / 3 19O / 3
21O / 1
265/3 260/3
Weight
4-sulfofthale "
1.0
1.0 wa acid
Phagel Yn3, 0 3.2 gyrc
Catalitic activity (20 hours empty after the start of the experiment), hours
24
24 million. Sample industrial monosulfone,
All results ± 4
four
68
57 65
45
265/5 NA Known
265/5 chamois lot (ij.
- -NA
NA
NA
1,01,01,0
NA
3,23,03,5
nineteen
22 24
22
26 obtained by reaction with oleum. Table 4
1394257614

权利要求:
Claims (1)
[1]
The formula of the invention for a lot go its water fat with weight
Method for the preparation of catalyst phageum anhydride: 4-sulfo.
for oxipame mercaptan based on phg phagevic acid ssh its sodium salt,
cobalt lopianins, including mutually, (2-4): 1. and interaction provo
the effect of phalic anhydride with urine - 5d t in aqueous medium at 165-266 ° С
wine, salt of cobalt, ammonium molybdate for 1-16.5 hours
nk and a sulphurizing agent, about tl and -sources of information,
This is due to the fact that, for the purpose, the methods are simplified and taken into account in the expert method, as sulphating one. US Patent No. ZO91618,
agents use 4-sulfophthalic cio-gji. 260-314 5, pubi. 1963 (Protopsh)

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引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

GB496819A|1937-06-01|1938-12-07|Ig Farbenindustrie Ag|Process for the manufacture of new dyestuffs of the phthalocyanine series|

US2673854A|1950-11-14|1954-03-30|Gen Aniline & Film Corp|Process for preparing metal phthalocyanines|

US3108081A|1959-07-17|1963-10-22|Universal Oil Prod Co|Catalyst and manufacture thereof|

US3230180A|1963-02-07|1966-01-18|Universal Oil Prod Co|Metal phthalocyanine catalyst preparation|

US3393200A|1965-10-23|1968-07-16|Allied Chem|Metal-containing phthalocyanines|

US3519641A|1966-06-03|1970-07-07|Basf Ag|Continuous production of copper phthalocyanines from phthalic anhydride and urea|

US3471254A|1967-01-03|1969-10-07|Universal Oil Prod Co|Oxidation of soluble sulfides|

FR1570577A|1968-03-29|1969-06-13|

US3565959A|1968-05-24|1971-02-23|Nippon Oil Co Ltd|Process for oxidizing mercaptans to disulfides|

US3963743A|1973-10-01|1976-06-15|Chemetron Corporation|Method of conditioning phthalocyanine pigments and product thereof|US4088569A|1976-02-24|1978-05-09|Uop Inc.|Mercaptan oxidation in a liquid hydrocarbon with a metal phthalocyanine catalyst|

FR2431481B1|1978-07-19|1981-01-30|Uop Inc|

EP0253890B1|1985-12-24|1993-02-24|Daiwaboseki Kabushikikaisha|Deodorant bedding|

DE3703837A1|1987-02-07|1988-08-18|Basf Ag|METHOD FOR CATALYTICALLY DEGRADING OXIDIZABLE ORGANIC AND INORGANIC COMPOUNDS IN WATER|

US4885268A|1988-03-30|1989-12-05|Ari Technologies, Inc.|Catalyst composition and method|

US4968411A|1988-03-30|1990-11-06|Ari Technologies, Inc.|Method of treating a hydrocarbon chargestock|

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法律状态:

优先权:

申请号 | 申请日 | 专利标题

US05/660,899|US4049572A|1976-02-24|1976-02-24|Catalyst and method of manufacture and use thereof|

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