EP2558197A1

EP2558197A1 - Catalyst for the oxidation of so2 to so3

Info

Publication number: EP2558197A1
Application number: EP11768535A
Authority: EP
Inventors: Michael Krämer; Markus Schubert; Thomas Lautensack; Thomas Hill; Reinhard KÖRNER; Frank Rosowski; Jürgen ZÜHLKE
Original assignee: BASF SE
Current assignee: BASF SE
Priority date: 2010-04-12
Filing date: 2011-04-12
Publication date: 2013-02-20
Also published as: BR112012026246A2; JP5833630B2; CN102892501A; JP2013523447A; KR20130097071A; WO2011128830A1; EP2558197A4; CN102892501B; CL2012002875A1

Abstract

A catalyst for the oxidation of SO₂to SO₃, a process for producing it and its use in a process for the oxidation of SO₂ to SO₃ are provided. The catalyst comprises active substance comprising vanadium, alkali metal compounds and sulfate applied to a support comprising naturally occurring diatomaceous earths, wherein the support comprises at least one relatively soft naturally occurring uncalcined diatomaceous earth which has a percentage reduction of at least 35% in its D₅₀ value determined in a particle size determination according to the dry method in comparison with the wet method.

Description

Catalyst for the oxidation of SO2 to SO3

The invention relates to a catalyst for the oxidation of SO2 to SO3 as well as a process for its preparation and its use in a method for the oxidation of S0 ₂ to S0 ₃

Today, sulfuric acid is almost exclusively obtained via the oxidation of sulfur dioxide (SO2) to sulfur trioxide (SO3) in the so-called contact / double contact process with subsequent hydrolysis. This process is characterized by the fact that SO2 is oxidized to SO3 with molecular oxygen on vanadium-containing catalysts in several consecutive adiabatic layers (hordes). The SO 2 content of the educt gas is usually between 0.01 and 50% by volume and the ratio of O 2 / SO 2 between 0.5 and 5. A preferred oxygen source is air. Part of the sulfur dioxide is converted in the individual hordes, whereby the gas is cooled in each case between the individual hordes (contact procedure). Already formed SO3 can be removed by intermediate absorption from the gas stream to achieve higher total sales (double contact method). Depending on the horde, the reaction takes place in a temperature range between 340 ° C and 680 ° C, whereby the maximum temperature decreases due to the decreasing SO2 content as the hornet number increases.

Today's commercial catalysts usually contain in addition to the active component vanadium pentoxide (V2O5) also alkali metal oxides (M2O), especially potassium oxide K2O but also sodium oxide Na2Ü and / or cesium oxide CS2O, and sulfate. As supports for the aforementioned components, porous oxides such as silica S1O2 are usually used. Under reaction conditions, an alkali metal pyrosulfate melt forms on the support material, in which the active component is dissolved in the form of oxosulfate complexes (Catal. Rev. - Sei. Eng., 1978, Vol. 17 (2), pages 203 to 272). One speaks of a supported liquid phase catalyst.

The contents of V2O5 are usually between 3 and 10 wt .-%, the alkali metal oxides depending on the species used or depending on the combination of different alkali metals between 6 and 26 wt .-%, wherein the molar ratio of alkali metal to vanadium (M / V Ratio) is usually between 2 and 5.5. The content of K 2 O is usually between 7 and 14 wt .-% and sulfate between 12 and 30

Wt .-%. In addition, the use of numerous other additional elements has been reported, such as chromium, iron, aluminum, phosphorus, manganese and boron. The porous carrier material used is predominantly S1O2. The preparation of such catalysts on an industrial scale is usually carried out by mixing aqueous solutions or suspensions of the various active components, for example corresponding vanadium compounds (V2O5, ammonia). niumvanadat, alkali metal vanadates or vanadyl sulfates) with alkali metal salts (nitrates, carbonates, oxides, hydroxides, sulfates), possibly with sulfuric acid and other components which can act as pore formers or lubricants such as sulfur, starch or graphite, with the support material. The resulting viscous mass is processed in the next step to the desired moldings and finally thermally treated (drying and calcination).

The properties of the catalyst are determined on the one hand by the active material content, the type and amount of the alkali metal used, the M / V ratio and by the use of any further promoters, but also by the nature of the carrier material used. A stable under reaction conditions support material helps to increase the surface of the melt and thus the number of accessible dissolved active component complexes. The pore structure of the carrier material has a central importance. Small pores stabilize the liquid state of aggregation and therefore lower the melting point of the molten salt (React. Kinet. Catal. Lett, 1986, Vol. 30 (1), pages 9 to 15) and, moreover, bring about a particularly high surface area. Both effects result in increased reactivity in the lower temperature range, i. according to the classification made in DD92905 in the temperature range <400 ° C. Large pores are particularly relevant at high temperatures (reaction temperatures> 440 ° C) to avoid transport limitation.

In addition to the catalytic activity of a catalyst and its life is of immense importance. On the one hand, the lifetime is influenced by toxins which enter the reactor from the outside with the feed gas and gradually accumulate on the bed, but also by impurities contained in the feedstocks, such as the silica carrier, which become mobile under reaction conditions and can react with sulfate ions and thus adversely affect the properties of the catalyst. Examples of such impurities are alkaline earth metal compounds (such as calcium compounds), iron or aluminum compounds. In addition, the catalyst can simply sinter in the extreme conditions and thus gradually lose its active surface. Of particular importance is also the pressure drop across the bed, which should be as low as possible and should increase as little as possible over the lifetime. For this purpose, it is necessary that a freshly prepared catalyst has the best possible mechanical properties. Typical parameters for this are, for example, the abrasion stability or the resistance to the penetration of a cutting edge (cutting hardness). In addition, the Rütteldichte the catalyst plays a central role, as only so can be ensured that a certain necessary mass of active material is filled in the given reactor volume.

As inert carrier materials for commercial sulfuric acid catalysts, especially cost-effective, porous materials based on S1O2 are used. there find synthetic variants of S1O2 as well as natural forms of S1O2 use.

With synthetic variants, the desired carrier properties, such as pore structure or mechanical stability, can generally be set well. RU

For example, 2186620 describes the use of precipitated silica gel as a carrier for a sulfuric acid catalyst. DE 1235274 discloses a process for the oxidation of SO 2 using a catalyst based on V 2 O 5 K 2 O / S 2 O 2, which is characterized in that catalysts are used with a respectively corresponding pore structure at different operating temperatures. These compounds can be exemplified by use of certain synthetic S1O2 components such as precipitated sodium water glass. SU 1616-688 describes the use of high surface area amorphous synthetic S1O2. However, the disadvantage of such components is the relatively high production and material costs.

Therefore, naturally occurring silicon dioxides (also called kieselguhr or diatomaceous earth) are frequently used in practice, which are much cheaper to obtain as a natural product, but often deviate in their properties from the desired optimum. The authors of SU 1803180 use kieselguhr as a carrier for a corresponding catalyst. CN 1417110 discloses a catalyst for the oxidation of SO2 based on V2O5 and K2SO4 in which the kieselguhr used comes from a particular province in China. The properties of a sulfuric acid catalyst can also be influenced by the nature of the pretreatment of the pure natural support material. Fedoseev et al. report, for example, a modification of the pore structure (shift of the maximum to smaller pores) of a vanadium-based sulfuric acid catalyst by mechanical crushing of diatomaceous earth (Sbornik Nauchnykh Trudov - Rossiiskii Khimiko-Tekhnologicheskii Universitet im. DI Mendeleeva (2000), (178, Protsessy i Materialy Khimicheskoi Promyshlennosti), 34-36 CODES: SNTRCV). This resulted in improved mechanical stability. A disadvantage of this modification on the one hand, the application of an additional step (12 h comminution of the carrier) and, secondly, the resulting reduced catalytic activity.

SU 1824235 describes a catalyst for the oxidation of SO 2 to SO 3 for a high-temperature process, characterized in that the diatomaceous earth carrier used contains between 10 and 30 wt .-% clay minerals, calcined at 600 to 1000 ° C and then before mixing with the actual active components are comminuted, with at least 40% of the calcined diatomaceous earth having a particle size have diameter of <10 μηι. Again, in this example, an additional step (crushing) is necessary.

Numerous documents describe an optimization of the catalyst properties by the common use of natural and synthetic S1O2 variants. DE

No. 4,000,609 discloses a catalyst for the oxidation of SO2 consisting of vanadium and alkali metal compounds on a support material with a defined pore structure, which is characterized in that different S1O2 components with different pore diameters are mixed in defined proportions, so that the resulting support a high proportion of pores with a diameter <200 nm. A similar approach is followed in WO 2006/033588, WO 2006/033589 and RU 2244590. There, catalysts for the oxidation of SO2 based on V2O5, alkali metal oxides, sulfur oxide and S1O2 are described with an oligomodal pore distribution adapted to the respective working temperature range. The setting of such a defined pore structure can be done for example by combining synthetic silica with natural diatomaceous earth. RU 2080176 describes a positive effect on the hardness and activity of a sulfuric acid catalyst based on V2O5 / K2O / SO4 / S1O2 by an admixture of S1O2 waste resulting from the recovery of silicon to the silica gel. A similar effect is found in SU 1558-463 by the addition of silica sols to diatomaceous earth.

US 1952057, FR 691356, GB 337761 and GB 343441 describe a combined use of natural diatomaceous earth with synthetic S1O2 in the form of the corresponding potassium waterglasses. The synthetic silicon component is applied from an aqueous solution, for example by precipitation on the diatomaceous earth, so that finally formed with S1O2 sheathed kieselguhr particles that can be soaked with the corresponding active components. The catalysts thus prepared are characterized by improved properties such as hardness or catalytic activity.

DE 2500264 discloses a vanadium-based catalyst for the oxidation of SO2, wherein as a carrier mixed with potassium waterglass solution mixture of diatomaceous earth with asbestos and bentonite are used as carrier components with increased mechanical stability.

In addition to the exclusive use of synthetic or natural S1O2 variants or the mixture of synthetic with natural S1O2 variants, mixtures of different natural S1O2 variants can also be used. Jiru and Brüll describe a modification of the pore structure of a certain type of kieselguhr by the addition of 30 wt.% Coarse kieselguhr waste of the same support, resulting in a shift of the mean pore diameter of 56 nm to 80 nm (Chemicky Prumysl (1957), 7, 652-4 CODEN: CHPUA4; ISSN: 0009-2899). PL 72384 claim a S1O2 natural diatomaceous earth support for a vanadium catalyst, characterized in that 20-35% of the particles are between 1 and 5 μηη, 10-25% between 5 and 10 μηη, 10-25% between 20 and 40 μηη, 10-25% between 40 and 75 μηη and 1-7% are greater than 75 μηη and by calcination of the diatomaceous earth at 900 ° C with subsequent mixing with the uncalcined diatomaceous earth in the ratio 1: 1 to 1: 4 is shown. DE 2,640,169 describes a vanadium-based sulfuric acid catalyst having high durability and effectiveness, which uses as carrier a finely divided freshwater diatomaceous earth containing at least 40% by weight of a calcined, diatomaceous earth

Melatira granulata diatomaceous earth, wherein the diatomaceous earth was calcined at a temperature between 510 and 1010 ° C before mixing with the active component, suitable accelerators and promoters. The catalysts thus prepared have a higher catalytic activity and mechanical resistance compared to the catalysts which consist exclusively of the corresponding diatomaceous earth in uncalcined and / or comminuted form, wherein it is irrelevant whether the proportion of diatomaceous earth to be comminuted before or after the Calcination is crushed. It is thus known that in order to optimize the mechanical stability of sulfuric acid catalysts, the diatomaceous earth used can be mechanically comminuted prior to the catalyst preparation and uncalcined diatomaceous earth can be treated with corresponding calcined or calcined and crushed diatomaceous earth or with synthetic SiO 2 variants. However, it has been found that the known approaches for improving the catalyst properties, in particular the mechanical stability, have at least one of the following disadvantages:

(i) Significantly higher preparative effort, since additional operations such as comminution or calcination of or parts of the carrier, precipitation, filtration or washing are necessary;

(ii) conversion or partial conversion of the natural kieselguhr carrier into the health-threatening cristobalite by preliminary calcination;

(iii) Higher feed costs when blending natural diatomaceous earth carriers with expensive synthetic variants;

(iv) loss of catalytic activity by improving the mechanical properties (comminution of the natural diatomaceous earth carrier).

It was an object of the present invention to provide a catalyst for the oxidation of SO 2 to SO 3, which can be used in the widest possible temperature range and as economically as possible, in particular, the mechanical stability of the catalyst should be improved. This object is achieved by a catalyst whose carrier contains at least one softer naturally occurring non-calcined diatomaceous earth.

The invention thus relates to a catalyst for the oxidation of SO 2 to SO 3, comprising active substance comprising vanadium, alkali metal compounds and sulfate applied to a carrier containing naturally occurring diatomaceous earth, characterized in that the carrier contains at least one softer naturally occurring non-calcined diatomaceous earth, which has a percentage decrease of its in a pond size determination by the dry method in comparison to the determined by the wet method D50 value of at least 35%.

A preferred embodiment of the invention is a catalyst for the oxidation of SO 2 to SO 3, comprising on a support containing naturally occurring diatomaceous earth applied active substance containing vanadium, alkali metal compounds and sulfate, characterized in that the carrier contains at least one softer naturally occurring non-calcined diatomaceous earth which has a percentage decrease in its dry-method pond size compared to the wet-method D50 value of at least 35% and also contains at least one harder naturally-occurring undecalcified diatomaceous earth which has a percentage decrease in its at least Pond size determination according to the dry method in comparison to the determined by the wet method D50 value.es of less than 35%.

The inventive catalysts according to the preferred embodiment, whose support contains at least one uncalcined harder diatomaceous earth and also another non-calcined softer diatomaceous earth, which has a significantly lower mechanical stability than the other diatomaceous earth, have significantly better properties, in particular over one improved mechanical stability, as the previously known catalysts. It is irrelevant whether the harder diatomaceous earth mainly on the cylindrical diatom Melosira granulata such as the commercially available types MN or LCS from EP Minerals LLC or on a plate-shaped diatom same or similar to the coscinodicineae type such as those commercially available Types Celite 209, Celite 400, Masis, AG-WX1, AG-WX3 or CY-100 or is based on other variants, or is a corresponding mixture of different variants of harder diatomaceous earth with similar mechanical stabilities. An example of a softer diatomaceous earth having markedly lower mechanical stability is diatomite diatomaceous earth from Mineral Resources Co. Diatomaceous earths suitable for preparing the catalysts of the invention should have a content of aluminum oxide Al 2 O 3 of less than 5% by weight, preferably less than 2, 6 wt .-% and in particular less than 2.2 wt .-% have. Your salary Iron (III) oxide Fe 2 O 3 should be less than 2% by weight, preferably less than 1.5% by weight and in particular less than 1.2% by weight. Their content of the sum of alkaline earth metal oxides (magnesium oxide MgO + calcium oxide CaO) should be less than 1.8% by weight, preferably less than 1.4% by weight and in particular less than 1.0% by weight.

In the context of this invention, non-calcined diatomaceous earth means that a diatomaceous earth was not treated at temperatures above 500 ° C., preferably not above 400 ° C. and especially not above 320 ° C., before mixing with the active components. A characteristic feature of uncalcined diatomaceous earth is that the material is quasi amorphous, i. the content of cristobalite is <5% by weight, preferably <2% by weight and particularly preferably <1% by weight (determined by means of X-ray diffraction analysis).

An advantage of the present invention is that the non-calcined diatomaceous earth with the lower mechanical stability is not subjected to further process steps such as calcination or comminution, so that the production process remains virtually unchanged.

In the context of this invention, the measure of the hardness or mechanical stability of a diatomaceous earth is the percentage decrease in its particle size determination by the so-called dry method in comparison to the D ₅ o value determined by the so-called wet method. The particle size determination can be carried out, for example, with an apparatus such as the Mastersizer 2000 from Malvern Instruments. D ₅ o is the mean particle diameter, that is to say 50% of the particles have a maximum diameter of the value indicated as D ₅ o.

Particle size determination by the wet method is a very gentle method, in which the samples to be examined are not exposed to any significant mechanical stresses. In the wet method, about 0.1 to 2 g of the sample are dispersed in water by means of a dispersing device such as the Hydro 2000G from Malvern Instruments (pump capacity: 2000 rpm, stirrer setting: 500 rpm) and as a suspension in the Mastersizer 2000 introduced. In the particle size determination by the dry method, the samples are dispersed in an air jet, for example by means of the dispersing module Scirocco 2000A from Malvern Instruments at a pressure of 1 bar. For this purpose, about 0.5 to 2 g of the sample is placed on the vibrating trough of the dispersion unit and slowly introduced into the air jet (1 bar). Depending on the mechanical stability of the various diatomaceous earths, smaller diatomaceous earth particles and larger particles of harder diatomaceous earth have a greater percentage decrease in the D ₅ o value during the measurement and thus softer diatomaceous earths. By friction and collisions with one another or with the vessel wall, the particles of the diatomaceous earth to be examined are stressed mechanically during this analysis, which leads to fractures and attrition of the particles. The more stable the diatomaceous earth is the lower the percentage decrease of the average particle size and thus of the D ₅ o value.

In the context of this invention, diatomaceous earths are said to be hard when the percentage decrease of their Dox value determined in a pond size determination by the dry method is smaller than 35% as compared to the Dso value determined by the wet method. A diatomaceous earth is said to be soft if its percentage decrease in its dry-method pond size compared to the Dso value determined by the wet method is at least 35%.

A soft diatomaceous earth with low mechanical stability generally has a particle size determination by means of the dry method in the Mastersizer 2000 combined with the dispersing unit Scirocco 2000A at 1 bar D ₅ o of at most 6 μηη, preferably of at most 5 μηη while the corresponding value in the harder diatomaceous earth with higher mechanical stability is generally at least 7 μηη. The median volume-related pore diameter (ie the pore diameter above and below which in each case 50% of the total pore volume, determined by means of mercury porosimetry) of the various diatomaceous earth usable in the context of this invention should be between 0.1 μηη and 10 μηη, preferably between 0.5 μηη and 9 μηη and in particular between 0.7 μηη and 7 μηη are. The median volume-related pore diameter of inventive mixtures of uncalcined diatomaceous earths should be between 0.5 μηη and 9 μηη, preferably between 0.8 and 7 μηη and in particular between 0.9 and 5 μηη. The shape of the pore distribution of the mixtures according to the invention can differ significantly from that of the individual diatomaceous earth. Oligomodal or bimodal

Pore distributions or monomodal pore distributions with pronounced shoulders can result depending on the combination of different diatomaceous earths. The setting of a given median volume pore diameter within the limits described above by mixing different

Diatomaceous earth in different proportions is possible in principle.

In the production of the sulfuric acid catalysts according to the invention, partial reduction of the diatom structures as a result of the mechanical stress during the mixing step or the shaping step and by application of the active composition to the diatomaceous earth support leads to a shift in the median volume-related pore diameters, so that the resulting catalyst in the Usually has a significantly lower median volume pore diameter than the underlying carrier. The median volume men-related pore diameter is for the sulfuric acid catalysts according to the invention between 0.1 μηη and 5 μηη, preferably between 0.2 μηη and 4 μηη and in particular between 0.3 μηη and 3.2 μηη, wherein the shape of the pore distribution of the catalysts, their support to mixtures are based on uncalcined diatomaceous earths, can be adjusted by the nature and the ratio of the different diatomaceous earths, so that also here oligomodal or bimodal pore distributions or monomodal pore distributions with pronounced shoulders can result.

Particularly good catalysts are obtained when using a carrier material in which the proportion of softer diatomaceous earths based on the total carrier mass in the range of 10 wt .-% and 42 wt .-%, preferably in the range of 14 wt .-% and 37 wt .-% and particularly preferably in the range of 18 wt .-% and 32 wt .-% is. The catalysts according to the invention generally have a cutting hardness of at least 60 N, preferably of at least 70 N and particularly preferably of at least 80 N. Their abrasion is usually <4 wt .-%, preferably <3% by weight. Their shaking density is generally in the range of 400 g / l to 520 g / l, preferably in the range of 425 g / l to 500 g / l. Their porosity is at least 0.38 ml / g, preferably at least 0.4 ml / g and more preferably at least 0.45 ml / g.

To determine the Rütteldichte a catalyst about 1 liter of the shaped body via a vibrating channel in a graduated cylinder with a volume of 2 liters. This measuring cylinder is located on a tamping volumeter, which taps over a defined time and thus compresses the shaped bodies in the measuring cylinder. The determination of the Rütteldichte finally takes place from the weight and the volume.

The characteristic physical catalyst parameters cutting hardness, abrasion and porosity were determined in analogy to the instructions described in EP 0019174. The determination of the catalytic activity was carried out according to the method described in DE4000609. The reference catalyst used was a commercially available catalyst according to DE 4000609, Example 3.

Another object of the invention is a process for the preparation of the above-described catalysts for the oxidation of SO 2 to SO 3, characterized in that a carrier comprising at least one softer naturally occurring non-calcined diatomaceous earth, which a percentage decrease in their in a Teichengröße after the Drying method compared to the determined by the wet method D50- value.es of at least 35%, with a solution or suspension containing vanadium, alkali metal compounds and sulfate added. A preferred embodiment of the invention is a process for the preparation of the catalysts described above for the oxidation of SO 2 to SO 3, characterized in that a carrier containing at least one softer naturally occurring non-calcined diatomaceous earth, which a percentage decrease in their in a pond size determination according to the dry method in Compared to the determined by the wet method D50- value.es of at least 35% and also contains at least one harder naturally occurring non-calcined diatomaceous earth, which is a percentage decrease in their pond size determination by the dry method compared to the determined by the wet method D ₅ o- Value of less than 35%, mixed with a solution or suspension containing vanadium, alkali metal compounds and sulfate.

Another object of the invention is a method for the oxidation of SO 2 to SO 3 using the catalysts described above. In a preferred embodiment of the invention, a gas mixture containing oxygen and sulfur dioxide SO 2 is brought into contact with the catalyst at temperatures in the range from 340 to 680 ° C., with at least part of the sulfur dioxide being converted to sulfur trioxide SO 3. Examples:

All of the diatomaceous earths used below contain less than 4% by weight of aluminum oxide Al 2 O 3, less than 1.5% by weight of iron (II) oxide Fe 2 O 3 and less than 1.0% by weight of alkaline earth metal oxides (sum of magnesium oxide MgO and calcium oxide CaO). The proportion of crystalline cristobalite was below the limit of quantification of about 1 wt .-%. The loss on ignition at 900 ° C was typically between 5 and 12% by weight.

The synthesis of all catalysts was carried out in accordance with DE 4000609 Example 3. The determination of the catalyst activity was also based on the procedure described in DE 4000609.

Table 1: Mean particle size D ₅ o of different diatomaceous earths determined by the wet method and by the dry method

1>: Determination of the particle size distribution according to the wet method (Mastersizer 2000 with dispersion in Hydro 2000G).

² >: Determination of the particle size distribution according to the dry method at 1 bar (Mastersizer 2000 with dispersion in the Scirocco 2000A at 1 bar).

Example 1: Comparative Example

3.926 kg of a MN diatomaceous earth from EP Minerals LLC, Reno, USA were mixed with a suspension of 1.7 liters of 40% KOH, 0.563 kg of 25% NaOH and 0.398 kg of 90% ammonium polyvanadate and 2.35 kg of 48 % sulfuric acid mixed. Subsequently, 250 g of a 7.4 wt .-% aqueous starch solution was added, the mixture mixed thoroughly and deformed to 1 1 x 5 mm star strands. These strands were then dried at 120 ° C and calcined at 650 ° C.

The catalyst thus prepared had a porosity of 0.49 ml / g. The

The cutting hardness was 74.3 N, the abrasion 3.0 wt .-% and the bulk volume 431 g / l (see Table 2).

Example 2: Comparative Example 3.51 kg of a Masis diatomaceous earth from Diatomite SP CJSC, Armenia, was mixed with a suspension of 1.705 kg of 40% KOH, 0.575 kg of 25% NaOH and 0.398 kg of 90% ammonium polyvanadate and 2.35 kg 48% sulfuric acid mixed. Subsequently, 250 g of a 7.4 wt .-% aqueous starch solution was added, the mixture mixed thoroughly and deformed to 1 1 x 5 mm star strands. These strands were then dried at 120 ° C and calcined at 650 ° C. Example 3: Comparative Example

3.565 kg of diatomite 1 diatomaceous earth from Mineral Resources Co., Lima, Peru, was treated with a suspension of 1.666 kg of 40% KOH, 0.559 kg of 25% NaOH and 0.396 kg of 90% ammonium polyvanadate and 2, 35 kg 48% sulfuric acid mixed. Subsequently, 250 g of a 7.4 wt .-% aqueous starch solution was added, the mixture mixed thoroughly and deformed to 1 1 x 5 mm star strands. These strands were then dried at 120 ° C and calcined at 650 ° C.

Examples 4:

The catalyst was prepared in analogy to Examples 1 to 3 using a mixture of diatomaceous earth, which to 70 wt .-% of the type MN from. EP Minerals and to 30 wt .-% of the type Diatomite 1 of the Fa. Mineral Resources Co. existed. The composition of the actual active component was not varied except for process-related slight fluctuations (deviations <5% relative, S0 ₄ <9% relative). Example 5:

The catalyst was prepared in analogy to Examples 1 to 3 using a mixture of diatomaceous earths containing 20% by weight of the MN type from EP Minerals LLC, to 50% by weight of the Masis Fa diatomite type SP CJSC and to 30 wt .-% of the type Diatomite 1 from the company Mineral Resources Co. was. The composition of the actual active component was not varied except for process-related slight fluctuations (deviations <5% relative, S0 ₄ <9% relative). Examples 6 and 7 describe the influence of a partial replacement of the more stable diatomaceous earth by a mechanically unstable diatomaceous earth on the properties of cesium-containing sulfuric acid catalysts.

Example 6:

2.753 kg of MN diatomaceous earth from EP Minerals LLC were mixed with a suspension of 0.956 kg Cs ₂ SO ₄ , 1.394 kg 47% KOH, 0.417 kg 90% ammonium polyvanadate and 1.906 kg 48% sulfuric acid , Subsequently, 177 g of a 10.68% strength by weight aqueous starch solution were added, and the mixture was thoroughly mixed and shaped into 1 × 5 mm star strands. These strands were then dried at 120 ° C and calcined at 510 ° C. Example 7:

The catalyst was prepared in analogy to Example 6 using a mixture of diatomaceous earths containing up to 50% by weight of the MN type from EP Minerals LLC, to 20% by weight from the Celite 400 from the Fa. Lehmann & Voss & Co., Hamburg, and to 30 wt .-% of the type Diatomite 1 of the Fa. Mineral Resources Co. was. The composition of the actual active component was not varied except for process-related slight fluctuations (deviations <5% relative, S0 ₄ <9% relative).

The combination of significantly improved mechanical properties with comparable or increased catalytic activities over the entire investigated temperature range of the catalyst according to Examples 4, 5 and 7 illustrates the superiority of the catalysts according to the invention.

Table 2: Pore volume, cutting hardness, abrasion, Rütteldichte and catalytic properties of the catalysts prepared according to Examples 1 to 7.

¹ > Cs-containing sulfuric acid catalyst

² > Using Celite 400 instead of Masis

Claims

claims

A catalyst for the oxidation of S0 ₂ to S0 ₃ , comprising on a support containing naturally occurring diatomaceous earth applied active substance containing vanadium, alkali metal compounds and sulfate, characterized in that the carrier contains at least one softer naturally occurring non-calcined diatomaceous earth, which a percentage decrease in their of the size of the ponds according to the dry method compared to the D50 value determined by the wet method of at least 35%.

A catalyst according to claim 1, characterized in that the carrier contains at least one harder naturally occurring non-calcined diatomaceous earth which has a percentage decrease of its in a pond size determination by the dry method compared to the determined by the wet D ₅₀ - value of less than 35%.

Catalyst according to one of claims 1 or 2, characterized in that the proportion of softer diatomaceous earths based on the total carrier mass in the range of 10 wt .-% and 42 wt .-% is.

A process for preparing a catalyst for the oxidation of S0 ₂ to S0 ₃ , characterized in that a carrier containing at least one softer naturally occurring non-calcined diatomaceous earth, which a percentage decrease in their D50 in a pond size determination according to the dry method compared to the determined by the wet method Value of at least 35%, admixed with a solution or suspension containing vanadium, alkali metal compounds and sulphate.

A method according to claim 4, characterized in that the carrier contains at least one harder naturally occurring non-calcined diatomaceous earth, which has a percentage decrease of their in a Teichengröße after the dry method compared to the determined by the wet method D ₅₀ value of less than 35%.

A process for the oxidation of S0 ₂ to S0 ₃ using a catalyst according to any one of claims 1 to 3.

The method of claim 6, wherein a gas mixture containing oxygen and sulfur dioxide S0 _{2 is} contacted with the catalyst at temperatures in the range of 340 to 680 ° C.