DE1943362C3 - Process for the preparation of a nickel-on-silica catalyst - Google Patents

Description

give.

Although numerous processes and variations thereof are found in the literature for the manufacture of nickel

K on silica catalysts have been described

[5 The invention relates to a process for 60 are, is the technical production of such cata-

^ι ψ Production of a nickel-on-silicon dioxide catalyst with the desired properties in reprosators, which is suitable for the hydrogenation of fats, has not yet been satisfactorily solved and its use for selective hydrogenation has been reduced.

of glyceride oils. One of the cheapest and therefore probably the most

Most fatty oils contain triglyc- 65 most of the processes used is a process

Riden polyunsaturated acids in addition to mono-un- in which the nickel from an aqueous solution one ^ saturated acids. In the catalylic hydrogenation of Nicke's salt by adding an aqueous solution can oil a number of competing potassium hydroxide and / or carbonate solutions in the form of a

j _r0 Yvds and / or carbonates on the carrier

trial is precipitated, with the temperature at 95 ° C

¹⁰ V, lten wi-ii and the resulting catalyst

^?; t 'reducing conditions at from 320 to 52o C ⁰

"vt'viert (compare FR-PS 15 20 584). A

thafter disadvantage of this procedure is

5n »s is very difficult to reproduce in a reproducible manner

• η to obtain a catalyst in which a high specific ^C -fi before nickel surface (surface of the nickel

i gram of nickel) with optimal porosity is combined.

Aiifpabe of the invention is the creation of a means for the production of a nickel-on-silicon- α · « catalyst, which is for the hydrogenation of fats wt.

* σ can be met in a very satisfactory and reproducible manner w > and which has a high specific Sf i

^N ™ SnI5 dta task takes place according to the invention by a process for the production of a ^ Äiumdioxyd-KEtalysatois. which is suitable for the hyp of fats, including precipitation of nickel hydroxide from an aqueous nickel salt with an aqueous Sihydroxyds, mixing of the precipitate during ^ r after the precipitation reaction with a silicon-SSd-containing carrier material, separation, and the various other previous stages in can be varied to some extent without impairing the quality of the resulting catalyst, a number of requirements must nonetheless be met.

First, the use of alkali hydroxide as a precipitant in the first stage is essential because of the process does not give the desired results when using alkali carbonate. It is known dall Nickel hydroxide can be precipitated at any pH value which exceeds a certain lower limit can, however, it is used to obtain precipitation of nickel hydroxide, with which satisfactory results are obtained, it is important that the pH, where it is felled, is not too high, and it is it has been found that precipitation occurs at pH between 7 and 10.5 is essential to achieve a catalyst with the desired properties. Very good results are obtained if the »nickel hydroxide from aqueous nickel sulfate is used in a pH falls between 8 and 10. Preferably the pH is at a constant level: while d Precipitation held, which is understood to mean that the The deviation does not exceed a value of ± 0.2.> «L * 5 The aforementioned pH values of the reaction mixture were soaked at a temperature of 20 ° C. the actual values at higher temperatures must be corrected accordingly.

7 to 10 5 measured at 20 ⁰ C, is kept and 'di by mixing the nickel hydroxide is important if nickel sulfate is used as the starting material

S from 50 to 12O ⁰ C in the presence of an aqueous and alkali hydroxide consists darm de ^

carried out by adding an aqueous solution of a can to _c . If the

_S5

Hydroxide and silicon dioxide containing material Lo ung _what a

at 20 ⁰ C, and in which the temperature atz de : ln & described operation of the

w.rd kept between 50 and 12O ⁰ F Tung of the aqueous solutions of the nickel salt

Suspension or suspended in the aqueous solution These parameters are then used as a measure of the time

i, j of the nickel salt. duration taken during which the mixture of

The next stage, the preparation of the mixture must be subjected to heat treatment. the

;, .. j the freshly precipitated nickel hydroxide, the silicon- the lower limit of this period is the one at which

; Dioxide-containing carrier material "and the aqueous 5 a composition is obtained, .die a Kataly-

; The alkali hydroxide has a pH between 11 and a nickel consumption of less than

and 13.5, in any suitable manner, yields 0.10 g / 100 g standard whale oil. Although ^ itself

_r '■ be performed. If in the first part of prolonged heating this parameter is not

p driving the preferred flow described above, such heating ultimately has a subsequent

^s "; by way of example for the unification of the carrier material with a 10-part effect on the selectivity. For this

the nickel hydroxide is used, the reason should be the upper limit of the heating time

Hold the suspension in the mixture with the requisite- be such that the dilation at 30 ° C (D ₃₀ ) still

Borrowed pH is below 100 by two different methods.

- be converted, namely either of the For explanation it is pointed out that very

pH value of the suspension directly to the 15 good results can be obtained if one

desired value by adding a concentrated suspension of freshly precipitated nickel hydroxide and

aqueous alkali hydroxide, or carrier material in aqueous alkali hydroxide with a

'' ■ the solids can be separated from the suspension pH 12 to 13 during a period of

and then boiling with aqueous alkali hydroxide for 5 to 10 minutes.

■; It should be noted that boiling of a suspension of at the required pH can be achieved. freshly prepared nickel hydroxide and silica The subsequent stage, the heat treatment of material containing aqueous alkali as the first stage of the process is obtained in the mixture having the desired pH value and, and by any of the above-mentioned working a pH Has a value of 7 to 10.5, if a compositing has not been obtained, it can be carried out again in various compositions with the desired properties. Although touch testifies, which illustrates that adjustment of the three components to 11 to 13.5 is essential even with only slightly increased pH.
Temperatures finally a catalyst with the An alternative method of working consists in that the desired properties are obtained, if the contact time is subjected to a heat treatment as follows in the case of the practical mixture with a pH of 11 to 13.5 of the table version. Acceptable length can be reduced, that is, that most of the aqueous solution is first removed from the lower limit of the temperature at which the mixture, e.g. B. by filtration or centrifugation, mixture is kept, not removed ^{significantly below 50 c C.} The resulting paste is then supposed to be, too. On the other hand, due to the presence of at 50 to 120 ⁰ C, according to conventional methods, dried, water in the mixture, the upper limit of the temperature-35 is more observed to no weight loss. Geratur at about 100 ° C or only a little above. The resulting composition would of course be possible to heat the mixture in a catalyst with the required properties, closed vessel under superatmospheric pressure but this should also be checked in preliminary tests, so that a higher temperature is reached because under certain conditions, z. B., if the paste could be, but an excessive increase in the temperature 40 is dried in a very thin layer, the temperature has an adverse effect on the pore drying time is too short to provide a sufficient counter structure of the carrier material, so that the desired side effect between the components is lost to effect. For this reason, allow. This must be avoided because, if the upper limit of the temperature is around 120 ⁰ C. once the composition is freed from water, when the mixture has become a sufficiently thin 45, even a repeated heat treatment of the sludge or a sufficiently thin suspension will affect the quality of the If the composition is insufficient, it can simply be improved to the desired temperature. Since the effect of the heat treatment is preferably heated under boiling conditions. not only on the contact time, but also on Since the length of time during which such mixtures have to be heated to the pH of the aqueous alkali hydroxide in order to achieve the desired result, it is advisable, in cases where briefly to achieve, of various factors such as expected drying times, e.g. B., if the pH and temperature is dependent, mixing in small amounts or in a thin layer ¹ no exact values regarding the lower and drying, the pH of the aqueous alkali upper limits of this heating time period given hydroxyds to a value of at least 12. However, the time can increase by preceding 55.

Try using relatively simple methods Regardless of the method used;

to be determined. To do this, a sample is heating the mixture, which becomes solid together

the heat treatment mixture to be heated preferably settles as far as possible from foreign objects

subjected under the desired conditions, ions obtained from the used as starting material!

and samples will be obtained from the reaction mixture in 60% nickel salt by washing with water or

taken from different time periods. These samples are freed with aqueous alkali metal hydroxide before they are ge

are then filtered off, dried and dried with water. Who: nickel sulfate as a starting point

If material is used at 450 ^c C according to customary methods under Vermaterial, this washing stage is so-called

using a hydrogen flow of 301 / hr. ever essential. When the heat treatment in the 0.5 g composition reduced. The resulting 65 boiling of a suspension of nickel hydroxide uni

Catalysts are characterized in that there is a carrier material, this washing stage can ent

one their nickel consumption and their selectivity in neither before or immediately after the heat treatment

determined in the manner described above. execution. When the heat treatment

43 * 362

consists in drying a thick paste must these are washed before being placed in the drying oven.

After the heat treatment beendet'ist, the resulting composition, "which the solids obtained either by drying a paste or ⁷ boiling a suspension with nächfolgendem filtering the solids and drying is activated by that they with hydrogen according to conventional methods , preferably at a temperature between 400 and 55O ° C, reduced to the desired to obtain nickel-on-silicon oxide catalyst. a very suitable method of activation is that the composition in a hydrogen atmosphere at a temperature of about 450 ⁰ C to about Heated for 30 minutes.

Although the various stages of the process mentioned above can be carried out in batches, some embodiments are particularly apt to be carried out in a continuous manner.

In a particularly preferred embodiment of the method according to the invention, the continuous Procedure carried out as follows

An aqueous solution of a nickel salt and an aqueous suspension of the silicon dioxide containing it Carrier material, either separated or combined, and an aqueous solution of alkali metal hydroxide at the same time introduced into a first vessel with a heating system, a stirrer, one with a pH meter coupled pH electrode and an outlet, usually from an overflow consists.

During the addition, the reactants are thoroughly mixed while the mixture formed is maintained at the desired temperature, which is preferably maintained at a constant value by coupling the heating system to a temperature control device. Furthermore, the concentrations of the reactants and ^; Their relative amounts added are chosen so that the pH of the mixture formed is kept at the desired value.

Preferably this is done by controlling the amount of one of the ingredients, usually the aqueous, added Alkali hydroxide, e.g. B. by means of a solenoid valve, which by the pH meter, which the records the pH of the mixture, is actuated. This valve can immediately control the flow of the aqueous Regulate alkali hydroxide, or it can regulate the flow of an additional stream of alkali hydroxide, which is superimposed on the main stream.

The dimensions of the vessel are chosen so that the mean residence time of the mixed reactants is between about 3 and 10 minutes, preferably between 5 and 7 minutes. The resulting suspension exiting the vessel through the outlet is then introduced into a second vessel which is also provided with heating equipment, an efficient stirrer, pH electrode and an outlet. Simultaneously with this suspension, an aqueous solution of alkali metal hydroxide is introduced into this vessel, the concentration of the solution being sufficiently high to adjust the pH of the resulting mixture to the required level. The ingredients are thoroughly mixed throughout the process while the temperature of the mixture and its pH are controlled in the same manner as described in the cip series. In this case, the pH is kept at the desired value by regulating the amount of the aqueous alkali hydroxide added. The dimensions of this second vessel are chosen so that the ^! mean residence time within the limits determined by preliminary tests as described above, usually between 5 and 15 minutes. The suspension leaving the second vessel is then collected and, as described above; worked up.

ίο With reference to those to be used as starting materials Materials, the following should be noted. Although any nickel salt that is soluble in water, can be used, is preferably - especially for large-scale manufacturing - Nickel sulphate is used, as this is the cheapest nickel salt that is technically available.

The choice of silica containing material is again made in large part by economic Factors are determined and it has been found that excellent results by application from kieselguhr, which is a relatively inexpensive product.

The same applies to the choice of alkali hydroxide used in any of the steps in the process. In general, sodium hydroxide, which is the cheapest, is used.

The invention is illustrated in Examples 1 to 6 below, while the Comparative Examples 1 and 2 are given for comparison purposes.

In all examples, the same basic system was used as shown schematically in the drawing is. This system consists of:

(a) three feed vessels 1, 2 and 3 connected via lines 4, 5 and 6 and pumps 7, 8 and 9 to:

(b) are connected to a reaction vessel 10, which is connected to

(1) an effective stirrer 11,

(2) a contact thermometer 12 which controls a heating coil 14 via a first relay 13,

(3) a set of pH electrodes 15 that have a pH meter 16 and a second relay 17 control a magnetic 3-way valve 18 which is switched into one of the lines 5 and is connected to the supply vessel 2 via a second line 5 ', and

(4) an overflow 19 leading either to the filter or to a similarly equipped one second reaction vessel leads,

Is provided.

Comparative example 1

A) Preparation of the mixed suspension from nickel hydroxide and kieselguhr in aqueous sodium hydroxide with a pH of 9.0 ± 0.2

The feed vessels are loaded as follows:
Vessel 1 with a suspension of kieselguhr (14 g / l) in an aqueous solution of nickel sulfate (0.85 N), Vessel 2 with an aqueous solution of sodium hydroxide (0.5 N; pH 13.4),

Vessel 3 with an aqueous solution of sodium hydroxide (0.85N; pH 13.6).

6g The reaction was carried out by simultaneously pumping in the kieselguhr suspension and the aqueous 0.85 N sodium hydroxide solution at approximately equal amounts in the reaction vessel while the suspension formed

ίο

was stirred vigorously, set in motion. This suspen- collected and filtered off. The solids were marked with J ^

sion is heated by means of the heating coil and placed on an aqueous 0.1 N sodium hydroxide solution (pH

maintained at a constant temperature of 96 ± 2 ° C. Value 13.0) washed until the washing liquid is free ", V

The pH of the suspension is adjusted to a level of sulfate ions. The wet composition \ * -

constant value of 9.0 ± 0.2 (measured at 2O ⁰ C) 5 (pH value of the adhering liquid 13.0) was ς ¹

dried by regular dosing of the aqueous 0.5 N Na- 16 hours at 12O ⁰ C and, as in part C) «~,

trium hydroxide solution set. The total amount of described by comparative example 1, activated. It i. _

liquids added were such that after a nickel-on-silica catalyst resulted,. ^M.

a constant state in the vessel achieves its properties in the table below - -

the suspension was given an average residence time of io,

had a time of about 7 minutes. That part of the _R. . . ,

Suspension of comparable the vessel through the overflow ^p

left, before the steady state was reached, A) The mixed suspension of nickel hydroxide

was discarded. and kieselguhr, which as in part A) of comparative

B, processing de, Susp _e " _si on" ^ StS

The suspension obtained, as transferred to the above-mentioned addition vessel. In this vessel the was written, was filtered off, the filter being changed every temperature of the suspension constant to 98 ± 2 ° C for half an hour. The precipitate held while the pH to a constant was washed with water until no sulfate ions 20 value of 13 ± 0.3 (measured at 2O ⁰ C) in a manner more were present in the washing liquid, WO completely with that was at the same in the first vessel to the resulting wet product 16 hours but now ⁰ C was dried by a regular 12O. Dosing of an aqueous 2 N sodium hydroxide solution

C) The composition obtained as it was adjusted under solution. The dimensions of this B) is described, was prepared by known methods 25 second reaction vessel were such that after Eraktiviert by being the average a current of hydrogen with a flow residence time of the suspension in 30 minutes at 45O ⁰ C and the range of a steady state this vessel about an amount of 301 / hour. each 0.5 g of composition for 5 minutes acted. After leaving the second vessel through the

The properties of the nickel-on-overflow thus obtained, the suspension was collected and off-silica catalyst are filtered in the following.

Table given. B) The wet filter cake, as in part A) of this

Comparative Example 2 Example was obtained, was ge with water

wash until there are no more sulfate ions

The mixed suspension of nickel hydroxide and SE wash liquor showed. After the kieselguhr has dried the wet composition as described in part A) of Comparative Example 1 for 16 hours was produced, was collected at 120 ° C this was as in part C) of Ver and cooked for 60 minutes. same example 1 activated. It resulted in a nickel

The precipitate was filtered off and treated with water on silica catalyst, its properties washed until the wash liquor is free of sulfate 40 indicated in the table. ions, after which the wet product at 16 hours

12O ⁰ C was dried. The resulting composite Example 4

composition was activated as described in part C) The wet filter cake, which has been prepared as described in part A) of both comparative example 1, game 3, was prepared with a nickel-on-silicon dioxide catalyst 45 0 .05 n-sodium hydroxide solution (pH value 12.7), the properties of which are also given in the table below which is washed until the washing liquid is free of sulfate. ions was. After drying the ° resulting Zu-Example 1 composition for 16 hours at 120 ° C. _XT . . ,. ^{,,, they} activated, as described in part C) of comparative

The mixed suspension of nickel hydroxide and example 1 described resulted in a kieselguhr which had been prepared as described in part A) of Comparative Example 1 nickel-on-silicon dioxide catalyst, the self-described nickel-on-silicon dioxide catalyst, was collected and filtered off as shown in the table below and with an aqueous 0.01 n-Natiium- are,
hydroxide solution (pH 12.0) washed until

no more sulfate ions in the washing liquid 55 example

showed. The moist filter cake, in which the mixed suspension of nickel hydroxide and

adherent aqueous solution a pH of 12.0 kieselguhr, the same as in part A) of comparative example 1 was then dried at 120 ° C. for 16 hours, was prepared, was collected and then removed the resulting composition is activated filtered. The wet solids were left without first how to wash it in part C) of Comparative Example 1 60 was described as much of the above has been. It resulted in the nickel-releasing moisture by sticking it on firmly Silica catalyst, the properties of which pressed into the filter, but without drying it. The in the table below. the resulting product was then roughly that

Example 2 10 times its volume of aqueous 0, In-Na-

⁶ S trium hydroxide solution (pH 13.0) suspended,

The mixed suspension of nickel hydroxide after which this suspension was boiled for 30 minutes, and diatomaceous earth, as in part A) of comparative The precipitate was filtered off and washed with water Example 1 had been prepared, was washed until the wash water was free of sulfate,

after which it was dried ^{at 120 ° C. for 16 hours.} The resulting product was activated as described in Part C) of Comparative Example 1. A nickel-on-silica catalyst resulted, the properties of which are given in the table below.

Example 6

A) The. Feed vessels were loaded as follows:

Vessel 1 with a suspension of diatomaceous earth (14 g / l) in distilled water;

Vessel 2 with an aqueous solution of sodium hydroxide (0.85 n; pH 13.6) and

Vessel 3 with an aqueous solution of nickel sulfate (0.85N).

The reaction was started by simultaneously pumping the three components into the reaction vessel, the volumes of kieselguhr suspension and nickel sulfate solution per minute which were introduced into the vessel being the same and the amount of aqueous sodium hydroxide being controlled so that within the pH of the suspension formed is kept at a constant level of 9.0 ± 0.2 (measured at 20 ^° C.) during the reaction. The total amount of liquid was such that, after a constant state had been reached, the mean residence time of the suspension in the vessel was about 6 minutes. The resulting suspension was vigorously stirred throughout the reaction while its temperature was maintained at 96 ± 2 ° C. That part of the suspension which left the vessel through the overflow before

the steady state was reached, was discarded.

B) The mixed suspension of nickel hydroxide and kieselguhr, which, as described in part A), was filtered off and the solids were washed with an aqueous 0.05N sodium hydroxide solution washed until the wash liquid was free of sulfate.

After drying of the wet product (pH of the aqueous solution adhering to 12.7) for 16 hours at 12O ⁰ C was this, activated as described in Part C) of Comparative Example. 1 A nickel-on-silica catalyst was obtained, the properties of which are described in the table below.

Properties of Nickel-on-Silica Catalysts

Nickel consumption selectivity
Whale oil at 180 ⁰ CD ₃₀ (JZ) *)

Comparative example 1 0.18 125 (90) Comparative example 2 0.18 140 (89) example 1 0.09 80 (90) Example 2 0.09 75 (90) Example 3 0.08 75 (90) Example 4 0.07 55 (90) Example 5 0.07 40 (90) Example 6 0.08 80 (9Ö) *) J. Z. = iodine number.

1 sheet of drawings

Claims (3)

Reactions take place, some of which are undesirable because they give rise to the formation of fully hydrogenated fats, which are less suitable for food 1. Process for the production of a nickel-on-are suitable. Silica catalyst used for hydrogenation 5 by using suitable selective Kavon Fat is suitable, among cases of nickel in catalysts, which are catalysts Promote the form of nickel hydroxide from an aqueous reaction, while reacting to another solution of a nickel salt by means of an aqueous ion are not or much less active, it is possible to use alkali hydroxide, Mixing the precipitate selectively borrowed, essentially the formation of undesirable rend or after the precipitation reaction with an io by-products. It is known that Support material containing silicon dioxide, Ab catalysts with nickel on supports, in particular separate, washing and drying as well as given-nickel-on-silicon dioxide catalyst. -n, for a solfalls Activation of the mixture by heating before selective hydrogenation is suitable, provided that a hydrogen stream, characterized by the fact that they meet certain requirements with regard to their strengths I η et that the pH of the reaction corresponds to 15 door. A very important factor in this medium during the precipitation to 7 to 10.5, the relationship is the width of the pores of the one measure at 20 ° C, and the mixture, supported catalyst. According to J.W.E, by mixing the nickel hydroxide and the C ο e η e n, H. B ο e r m a, B. G. L i η s e η and B. de Support material containing silicon dioxide is described in Proceedings Third International Conhalten was, before drying at a temperature 20 gress on Catalysis ", Vol. II (1965), p. 1387, the Selek- _m temperature of 50 to 12O ⁰ C in the presence of a wäß- tivity of a nickel-on-silica catalyst 1 medium with a pH value of 11 to 13.5 is strongly dependent on the volume of the pores with a through-treatment or a suspension of the mixture of less than 25 Å in relation to the total of the nickel hydroxide and the silicon dioxide ent-pore volume. Under the expression "Selekhaltenden carrier material in an aqueous 25 activity", as it is used in this context medium with a pH value of 12 to 13, the selectivity of a catalyst is formed and the suspension is then pressed through the boiling temperature Dilatation at 30 ° C (D ₃₀ ) (beralur is heated for 5 to 10 minutes. Correct, as in HA B 0 eke η ο 0 gen, »Analysis 2. The method according to claim 1, characterized and Characterization of Oils and Fat Products «, draws that it is carried out continuously, 30 London, New York, Sidney [1964], vol. 1, p. 144, bell by writing an aqueous solution of a nickel salt), a standard soybean oil understood, and an aqueous suspension; Silica of the 100 g by means of this catalyst with one containing material, either separately or containing 0.2 g of nickel under standard conditions, Ij combined, and an aqueous solution of an alkali namely 100 ° C and a hydrogen off flow of II hydroxyds in a first reaction vessel in such a way 35 60 1 / h., Until a Jcd number (JZ) of 90 ± 1 reaches j ¹ .-; results in the pH of the reaction mixture being hydrogenated. In addition to being selective, between 7 and 10.5, measured at 20 ° C., such curing catalysts should also be active and the temperature in the reaction vessel should be overly resistant to poisons, otherwise ε 90 ° C is kept, the reactants the amount of to be added or during the hy- over a residence time of 3 to 10 minutes in 40 dration process to spent catalyst leaves the vessel, the sludge obtained is high, which is not for economic reasons freshly precipitated nickel hydroxide and silicon is portable. The latter two properties ■ Dioxide-containing material in a second vessel also depends on the pore size distribution of the carrier Convicted, in which he left 5 to 15 minutes and dependent, but they are particularly through the is mixed with further alkali hydroxide solution, 45 size of the nickelum present on the surface the pH of the contents of the second vessel is determined particles. In this context is one in the range from 11 to 13.5, measured at 20 ° C, an important property of nickel consumption. Under : to bring, and in which the temperature between this expression, as he did in this context 50 and 120 ° C is maintained. used is the minimum amount of nickel 3. Use a nickel-on-silicon manufactured according to one of the 50 (expressed in grams) which is required Proverbs 1 or 2 to understand 100 g of a standard whale oil (with a dioxide catalyst for the hydrogenation of GIy-sulfur content of 30 ppm) under standard condition unceride oils and fats. gen (hydrogenation time 8 hours, temperature 18O ⁰ C ₁ Hydrogen stream 60 1 / h) to harden in order to produce a product 55 with a refractive index of N "= 1.4480