DE1072596B - Process for the production of catalysts on porous alumina supports using extrusion presses - Google Patents

Description

GERMAN

PATENT OFFICE

kl. 12 g 4/01 ^

INTERNAT. KL. BOIj

N 14142 IVa / 12 g

A N M E L D E T A G: SEPTEMBER 26, 1957

NOTICE THE REGISTRATION AND ISSUE OF THE EDITORIAL: 7. Y A N U A R 1 9 6 O

The invention relates to the production of catalysts from calcined alumina with low Additions of activating metal oxide mixtures using extrusion presses.

In processes which are carried out using fixed or moving catalyst beds, are The catalyst particles are subjected to severe stress because of the weight on a given particle the overlying catalyst mass weighs down. In such processes, the catalyst is usually in in the form of particles having a "diameter between about 0.16 and 1.3 cm and a length between approximately 0.16 and 2.5 cm, the length of which is preferably approximately equal to its diameter, is used.

One method of making such stable catalyst particles is that of Smaller catalyst particles are pressed into tablets, whereby the strength of the tablets is largely changed the pressure applied for tabletting can be influenced.

However, the tablets obtained in such procedures are often proportionate according to the type of treatment used high pressure little porous, reducing their activity, especially in reactions in which the reactants can penetrate into the pores of the catalyst particles is impaired.

It is also already known to prepare porous catalyst particles by, for example, a mixture of small Aluminiumoxydhydratteilchen, pressed with water by extrusion through small holes into endless strands, the d ann to Te ilchen broken or cut, the catalyst mass having a length approximately equal to their diameter is, and then to dry and calcine these particles (see. German Patent 864 863). The catalyst mass fed to the extruder in the form of a paste must be such that it can obtain its final shape, but at the same time so moist that it can be pressed out continuously and does not crumble. In the production of catalyst particles by means of extrusion, particles of greater porosity are obtained than by tabletting. However, the particles obtained in this way are usually not very strong and break easily, which is presumably due to the fact that relatively low pressures are used during extrusion in order to obtain particles of good porosity. The particles present after the extrusion process have cracks, and further, even more disadvantageous cracks occur during drying and calcination. The strength of the catalyst particles can also be impaired by the added activating metal.

To produce aluminum oxide catalyst particles using extrusion, the cobalt and / or method of manufacture

of catalysts

on porous clay carriers

using extrusion presses

Applicant:

National Aluminate Corporation,
Chicago, 111. (V. St. A.)

Representative:

Dipl.-Ing. E. Prince and Dr. rer. nat. G. Hauser,
Patent attorneys, Munich-Pasing, Bodenseestr. 3 a

Claimed priority:
V. St. v. America September 28, 1956

Carl D. Keith, Munster, Ind.,

Henry Erickson, Park Forest, 111.,

Edwin H. McGrew, Riverside, 111.,

and David G. Braithwaite, Chicago, 111. (V. St. Α.),

have been named as inventors

Nickel oxide together with oxides of molybdenum, vanadium and / or tungsten contain and sufficient are solid and porous, a number of experiments have been carried out which have shown that Measures that have proven to be beneficial in a particular processing, not the other processing methods are equivalent to advantageous measures.

In the process of the present invention, using extrusion, alumina particles, which contain a smaller amount of catalytically active metal oxides, of sufficient Preserved strength and porosity. The method consists in making an aqueous slurry from alumina hydrate, which contains about 10 to 90% alumina trihydrate, to small spherical ones Particles with a mean diameter of about 20 to 125 / i and a content of up to about 20% Spray-dried free water in a known manner, the spray-dried particles in the presence of water

909 708/317

with smaller amounts of AronA compounds from cobalt or nickel and molybdenum, vanadium or tungsten or mixtures thereof treated so that a impregnated aluminum oxide hydrate with a content of at least 50% free water is obtained, drying the moist particles to a level of 5 to 20% 'ari free' water by soaking them in Bringing the dispersed form into contact with a hot gas, from the dried particles by mixing of so much water that the mixture contains about 30 to 50% free water, a squeezable one Produces mixture, this mixture is compressed using extrusion presses, then the compacts at a temperature up to about 204 ° C to a content of less than 5% free water and then calcined.

In the process of the present invention, as mentioned above, the spray-dried spherical alumina hydrate particles are combined with compounds of the catalytically active metals, and this process can be carried out by any desired procedure, with only water present, in order to increase the free water content of the resulting mixture at least about 50 percent by weight can be increased. The spray-dried aluminum oxide hydrate can be treated with the metal compounds by mixing it with aqueous solutions of water-soluble compounds of the catalytically active metals so that the metal compounds are adsorbed on the carrier. The aluminum oxide hydrate carrier can be suspended in an aqueous solution of acidic salts of dcSi catalyst metals. Preferably, however, mixing the spray dried Aluminiumoxydhydratausgangsstofr in the presence of water with a substantially water-insoluble compounds of the catalytically active metals, thereby react the insoluble Mctallbestandteile with the carrier or are adsorbed on it. Normally, the mixing is carried out for at least about 10 minutes at a temperature of about 51 to 99 %. If necessary, higher or lower temperatures can be used, for example one can work at room temperature. However, temperatures above 100 ° C require the Use of pressure to maintain the liquid phase. The water-insoluble compounds are usually "inorganic" and are in the form of oxides, hydroxides, carbonates, basic carbonates or sulfides.

The total amount of active metal components on the alumina can vary considerably. In general, this amount is a small part of the catalyst; a content of only about 0.1 percent by weight of the finished catalyst already results in a noticeable catalytic effect. The total active metal components can constitute about 1 to 40 percent by weight of the catalyst; each constituent is at least about 0.05 percent by weight of the finished catalyst. All of these percentages are calculated as metal oxides.

In the process of the present invention, the soaked, moist alumina hydrate, the contains more than about 50 percent by weight free water, dried by contact with a hot gas, for example by the hydrate particles falling through the drying zone. When you look at this Mode of operation regulates the free water content of the dried product so that there is enough water Direct transfer to the extruder remains in the particle mixture, become the final Catalyst particles are very cracked and therefore have very little resistance.

It has now been found that the product from the dryer is an inhomogeneous mixture of particles that had bound significantly different amounts of free water. If this inhomogeneous Product was extruded and then dried, the wetter particles shrunk more than that

ίο littleci'feucht.cn what a number of break points in the finished calcined catalysts.

According to the present invention, porous, large-grain catalyst particles, e.g. ^{B. at least 0.3 cm s} / g and better at least 0.4 cm s / g pore

"vOlüTficn" * - according to the Barrett method (Journal of the American Chemical Society, Volume 73, 1951, p. 373) determined - have been more satisfactory Resilience can be established. While drying the soaked, moist aluminum oxide hydrate before extrusion

• the hydrate particles, finely divided, brought into contact with the hot gas until they are 5 to 20 percent by weight, better contain 5 to 10% free water. The soaked hydrate is expediently filtered beforehand and the wet filter cake is used as a feed to the drying stage. For this' drying stage A high-speed dryer can be used in which the finely divided hydrate particles are exposed to a hot gas fall through. Only if there is enough free water this drying could be done by spray drying up to the specified free moisture content. The dried particles are then converted back into an extrudable mixture by adding water, which is usually approximately Contains 30 to 50 percent by weight free water. This mixture then becomes coarser to form Extruded balls with the desired diameter. The extrusion of such beads is conveniently carried out in stages by removing the extruded beads from the first extruder goes directly into a second extrusion line. This causes greater compression of the Globules and consequently higher resistance. Any abrasion that occurs during extrusion formed is removed and added to the material fed to the first extrusion line. The large-grain, extruded particles are then kept at a temperature of up to about 204 ° C dried until they contain less than 1% by weight of free water and better than 1%. These pre-dried particles are finally calcined. The information about the free water or the free moisture content were measured with an infrared moisture meter, which is a 125 watt incandescent lamp contains, received.

The drying and calcination temperatures used in the present process in the treatment of the Alumina hydrate applied after extrusion can vary widely. While the Drying temperatures usually range up to about 204 ° C, for example 93 to 204 ° C, the calcination temperatures can be about 400 to 700 ° C or more. The calcination furnace is favorably a rotary kiln, which is useful for continuous operation. The added catalyst, however, is immediately exposed to high temperatures, which reduce the resistance of the Particulate matter reduction unless the furnace has a cryogenic preheat section. Nevertheless the rotary kiln was found to be sufficient for

Particles in which the free moisture content of the Good is lower than about 5 percent by weight.

The known aluminum oxide hydrate includes the monohydrate, boehmite, another hydrate or hydrous aluminum oxide, which appears to be amorphous, and also the trihydrates, bayerite, Gibbsite and Randomit. According to the invention, aluminum oxyhydrate is used, which is about 10 to 90 percent by weight, more preferably less than about 50 percent by weight, trihydrate and the remainder monohydrate or the amorphous hydrate or a mixture of this form. Marking the various Forming of the aluminum oxide hydrate is carried out by means of X-ray diffraction methods on samples, which have been dried at about 110 to 120 ° C. The aluminum oxyhydrate can contain small amounts of others Contain substances such as silicon oxide.

The alumina trihydrate-containing alumina hydrate used according to the invention can be displayed in any desired way. For example, an aqueous solution of aluminum chloride or another acidic aluminum salt reacted with aqueous ammonium hydroxide to precipitate mainly boehmite or amorphous alumina hydrate. These Mass can be washed to remove chlorine and ammonium ions, and in that To the extent that the concentrations of these electrolytes decrease, the aluminum oxide hydrate is converted into Trihydrate around. This conversion can be stopped by drying the alumina material will. This way of working thus offers a means of producing a trihydrate-containing substance. on the other hand can also use the aluminum oxide monohydrate or amorphous forms and the aluminum oxide trihydrate in separate reaction processes can be prepared, and these aqueous phases can then be used to achieve of the desired trihydrate-containing material are mixed. A multiphase alumina hydrate feedstock can by reacting part of an aqueous sodium aluminate solution with carbon dioxide to generate the desired amount of trihydrate and then react with the remaining aluminate an acidic aluminum salt, such as sulphate, to form boehmite and hydrate, amorphous components getting produced. The alumina hydrate can prior to its use in the process of the present Invention or washed with water after spray drying to remove accompanying substances will.

The following example serves to explain the method of operation according to the invention.

example

An aqueous slurry with an alumina hydrate concentration of about 6%, of which approximately 20% aluminum oxide trihydrate is pumped into a spray dryer with a high pressure pump and at a pressure of 63 to 70 atmospheres in a hot atomizer, which has an inlet temperature of 540 to 600 ° C, is sprayed into tiny particles. The particle temperature is about 127 ° C, and the resulting small spherical particles have approximately 50 percent by weight of grain sizes of less than 0.075 mm and 50 percent by weight of grain sizes greater than 0.075 mm. The dry mass is collected for the next stage of the process. These Mass contains approximately 10 to 15% free water and approximately 25 to 30% total water (free water plus crystal water).

The amount of these dried aluminum oxide hydrate pellets corresponding to 680 kg of Al ₂ O ₃ is added to 2000 l of water, heated to 82 ° C., and stirring is started. 79 kg of pure molybdenum oxide are slurried in 57 to 76 liters of water and added to the previously prepared aluminum oxide hydrate-water · ¹ mixture. 48.5 kg of cobajt carbonate are slurried with 57 to 76 l of water and added to the aluminum oxide hydrate-water mixture. That

ίο Stir the porridge at a temperature of 82 ° C continues for 1 hour.

The resulting mixture is pumped to a filter and filtered off as quickly as possible; simultaneously the filter cake is kept as thick as possible. The filter cake is placed in a rapid dryer transferred, where the hydrate particles fall through the drying zone in finely divided form and come into contact with a stream of hot gas, the outlet temperature of which is 93 to 121 °. C held

ao will, around about 25% total water and 'about 5 to 10% free water containing ,, mass to produce. The mass pours out of the rapid dryer into a hammer mill, which crushes all hard particles. The dried, impregnated Mass can be stored for use in the next stage of the process.

113 kg of the dried, impregnated material, which has approximately 5 to 10% free moisture, are mixed in a mixer with 65 l of water for 10 to 20 minutes at about 15 to 27 ° C. Of the Moisture content is reduced to approximately 33 percent by weight of free water by adding a small amount Amount of previously dried, impregnated material or waste from previous extrusion set.

The impregnated alumina hydrate, which contains approximately 33 percent by weight free moisture, is extruded into particles about 0.32 cm in diameter and 0.32 to 0.64 cm in length. These particles are emptied directly into a second extruder, where they become particles of deformed about the same size. This compresses the particles more strongly and increases their resistance will be raised. Then the particles are placed on a sieve to separate fine particles. the the latter are returned to the mixer which is used to prepare the mixture to be extruded must be used. The beads, which now contain about 27 to 29% free water, are ready for Drying, sieving and calcining.

The extruded particles are predried at a temperature of 121 ° C until the content in free moisture is reduced to less than 5 percent by weight. Then the fine particles become again sieved and returned to the mixer. The sifted out particles go straight into a Roasting oven, which is kept at a temperature of 565 to 620 ° C, passed. The calcined Particles are ready for use in catalytic processes and are excellent, for example as catalysts for the desulfurization of oils at elevated temperatures and pressures.

These particles have a bulk density of about 750 kg / m ³ , are blue in color, and their hardness is such that they do not break until a load of 6.8 kg / 0.32 cm in length is applied to them. The CoO plus MoO ₃ content corresponds to approximately 11 to 12% of the catalyst obtained.
Other catalysts can be prepared using the procedure of this example. Example

The molybdenum oxide can be replaced by 95 kg of tungstic acid (WO ₃ -H ₂ O) and the cobalt carbonate by kg of nickel carbonate. Alternatively, nickel carbonate can be used in place of cobalt carbonate and kg of vanadium pentoxide can be used in place of molybdenum oxide.

Claims (1)

Claim: Process for the production of catalysts on porous aluminum oxide supports which have a ge ίο contain ringcre amount of catalytically active metal oxides, using extrusion presses, wherein an aqueous slurry of alumina hydrate containing about 10 to 90% alumina trihydrate contains, is spray-dried into small spherical particles with a content of free water of up to about 20%, characterized in that that the spray-dried particles in 'the presence of water with smaller amounts of compounds of cobalt or Nickel and molybdenum or X ^ anadiums or Treated tungsten or mixtures thereof, so that an impregnated aluminum oxide hydrate with a content of at least 50% free water is obtained, the moist particles up to a content of 5 to 20% of free water dries by using them in finely divided form brings into contact with a hot gas, from the dried particles by mixing in so a lot of water so that the mixture contains about 30 to 50% free water, a mixture that can be squeezed out produces, this mixture is shaped using extrusion presses, then the compacts at a temperature up to about 204 ° C to a content of less than 5% free Water dries and then calcined. Considered publications:
German Patent Nos. 820 893, 864 863;
British Patent No. 756 702. © 909 708/317 12.59