DE1811655C3 - Process for the cleavage of 4,4-dimethylm-dioxane to isoprene - Google Patents

Description

It is known that 4,4-dimethyl-m-dioxane can be converted into isoprene in the presence of catalysts containing phosphoric acid columns. The cleavage of the dioxane can be carried out in the gas phase using the known arrangements of the catalytic converter, namely working with fixed catalytic converters, the use of the moving bed or the fluidized bed.

It has been proposed (DT-AS 12 31 682), fixed Phosphoric acid catalysts for the cleavage of 4,4-dimethyl-1,3-dioxane in a fixed bed or in a fluidized bed to use. When using these catalysts in the fixed bed reactor, the catalytic activity decreases by coke formation quickly, and it must be regenerated frequently, so that a larger number of

Reactors connected in parallel are technically necessary

will-

To extend the regeneration times is further proposed the solid phosphoric acid catalysts by adding aromatic aminosulfonic acids to be modified (DT-OS 19 10 047). This measure increases the service life of the catalytic converter on the other hand, the aromatic aminosulfonic acids are partially regenerated destroyed. If you want to regain the full effectiveness of the catalysts by regeneration, you must in addition to the removal of coke, a new impregnation with aromatic aminosulfonic acids takes place, which is technical is very complex.

It is also possible to carry out the cleavage in a fluidized bed, and the catalyst in whole or in part withdraw from the fluidized bed and regenerate. The catalysts mentioned in DT-AS 12 31 682 are poorly suited for use in a continuous fluidized bed because they are only of moderate strength own and quickly to a powdery flour grinding and discharged from the reactor with the gas will.

It was therefore the task of a new catalyst

2s development to find a catalyst overall enables an economical optimum for working in a fluidized bed, in which high activities and Selectivities coupled with good abrasion properties are.

This object is achieved by the method according to the preceding claims.

For the preparation of the catalysts, one starts from aqueous, stable silica sol prepared in a manner known per se, which has a specific surface area of 150 to 400 m ² / g to 200 m ² / g. Silica fillers or fillers predominantly containing silica are understood here to mean synthetic, large-area silicas with a flake-like secondary structure obtained by precipitation from a sodium silicate solution. The precipitation from the sodium silicate solution can be carried out with acids, whereby fillers are obtained that are practically free of metal ^! links. But you can also carry out the precipitation with solutions of alkaline earth or aluminum salts and then get fillers that contain the metal oxides concerned, especially CaO or Al2O3.

The fillers with a ^{specific surface area of 30 to 200 m 2} / g consist of loose flakes with a diameter in a range from 1 to about 15 μ.

In addition to the fillers containing silica, clay minerals are also used in the aqueous, stable silica sol suspended. Clay minerals from the Kaoiinit group are particularly suitable here, Montmorillonite and atapulgite. The crude, unpurified clay minerals are not expediently used as clay minerals Products from the group mentioned, but reconditioned, slurried qualities are used. Commercial products for kaolins are, for example slurried kaolinite rich. products called "China clay". As a source for montmorillonite Clays can e.g. B. the commercially available Bewtonite can be used.

The amount of the substances to be suspended in the silica sol is measured so that - based on anhydrous substances - in addition to the S1O2 from the

Silica sol 20 to 60%, preferably 35 to 50%, of silica _{fillers and 5 to 30} %, preferably 15

up to 25% clay minerals are present.

The suspension is converted into pearl granules in a manner known per se, for. B. by addition a small amount of an aqueous suspension of finely divided magnesium oxide as a gelling reagent and Drop-shaped distribution of the suspension in an organic phase until the sol-gel conversion occurs. The distribution to small droplets, as is necessary for the production of catalyst supports for the Fluidized bed is required, succeeds with centrifugal disks or similar devices, which the liquid film accelerate by centrifugal forces. The finished catalysts should be as uniform as possible Pearls in a size of 0.2 to 2, preferably 0.3 to 1.5 mm, are present-

The granules obtained are dried and subjected to an annealing treatment at 500 to 1000 ° C. for at least 10 minutes. They have specific surface areas of 40 to 100 m ² / g.

After cooling, the granules are provided with 5 to 30% phosphoric acid and then to 300 bis 650 "C. It is also possible to add the phosphoric acid in the reactor by adding for example, aqueous granules are introduced into the fluidized state in the reactor at an elevated temperature Injecting solutions of phosphoric acid, advantageously using water vapor as a distribution medium and as a Fluidizing gas is used for the granules. It is also possible to use phosphoric acid in the form of its esters * bring in, for example, the ester with alcohols or with phenols, triisobuiyl phosphate particularly suitable, since isobutene ran during the decomposition, which is present anyway.

The finished catalysts generally have specific surface areas of 25 to 50 nv '/ g and in the circulation catalyst, specific surface areas of, for. B. 10bis30m ² / gein.

The gases or vapors leaving the reaction space when the cleavage reaction is carried out lead small amounts of phosphoric acid with it, so that it is convenient to the loss so occurring Balance phosphoric acid by adding fresh phosphoric acid, primarily in the form of its esters.

As a starting material, a product is used which has been obtained by reacting i-butene with formaldehyde, in addition to the 4, * dimethylm-dioxane contains even smaller amounts of the corresponding enols and glycols as well as tert.-butanol, or fractions from it. The following enols and glycols may be mentioned by way of example: 3-methylbuten-3-ol-1,3-methylbuten-2-ol 1,3-methylbutene-l-ol-l, 3-methylbutanediol

The cleavage of the dioxane to isoprene in the gas phase in the presence of the catalysts described in the fluidized state can be carried out at normal or slightly elevated pressure at temperatures of, for. B. 200 to 400 ⁰ C, advantageously 250 to 300 ⁰ C. It is advantageous to add steam to the dioxane to be cleaved in amounts of about 10 to 100, advantageously 1 to 50 parts by weight of water per 100 parts by weight of the dioxane to be used. You can z. B. with hourly throughputs of the dioxane of 0.3 to 2, advantageously 0.7 to 1.2 kg per liter of the fluidizing catalyst erfüiiiem ^ reaction space work. As the residence time of the reactants in the fluidized bed, those of z. B. 0.3 hU 1 advantageously 0.5 to 2 seconds. It is advisable, within the limits described, to set conditions under which 50 to 100, advantageously 80 to 95% of the dioxane introduced is converted in a single pass through the reaction chamber

It can be useful to arrange "baffles" (impact bodies) in the reaction space, which the Promote uniform mixing of gases and swirling catalyst.

The mentioned baffles, and in particular tubular baffles, can be from heated liquids or gases are flowed through, so that in this way some of the heat of reaction required in the system is introduced. These are liquids, such as the known heat exchangers, such as Diphenyl. But you can also use steam under such a pressure that it is at the desired Reaction temperature condenses in the pipes and thus also the heat of condensation for utilization is available.

When carrying out the cleavage reaction, small amounts of high molecular weight carbon-containing products can be deposited on the catalyst grains and thus reduce their catalytic effect. It is therefore advisable to continuously remove part of the catalyst content from the reactor and to burn off the carbonaceous products on it by treatment with oxygen-containing gases - advantageously in a fluidized bed - at 500 to 70O ⁰ C, after which the catalyst regenerated in this way can be returned to the reaction space. When removing the catalyst from the reactor, care must be taken that the adsorbed volatile constituents are removed by wiping them off with steam and that they are added to the reaction gases.

A catalyst circulation of, for example, 3 to 10, advantageously 4 to 8 parts by weight per liter is recommended Part by weight of dioxane introduced into the reactor per unit of time.

As reactors 1. B. shaft furnace with layer heights of the fluidized bed of z. B. 0.5 to 3, advantageously 1 to 2 m can be used. The diameter of the shaft furnace can, for. B. 0.5 to 5 m. It is advantageous if the participants in the reaction are distributed as uniformly as possible over the entire cross section of the reactor. For the introduction of the reaction participants dioxane and steam are suitable, for. B. horizontally arranged pipes with outlet openings for the reaction participants. The pipes for the introduction of the dioxane are advantageously provided with a cooling jacket in order to prevent a thermal change in the feedstock already taking place in the pipes with the separation of higher-boiling products. The pipes for the introduction of the steam can be arranged below the pipes for the introduction of the dioxane in order to keep the lower part of the reactor free of organic vapors which would decompose here in an undesirable manner on the catalyst grains.

To maintain the fluidized bed in the reactor, the reactants are placed in the bottom of the reactor introduced, rise up in this and leave the reactor at the upper end.

In principle, the circulating catalyst can be used in cocurrent or countercurrent to the Pass the reaction participants through the reactor. It has been found to be particularly favorable Results are obtained when the catalyst and reactants are passed upwards cocurrently through the

Reactor passes through. The separation of the catalyst from the reaction products is carried out in the upper section Part of the reactor in front, pulls the catalyst intended for the circulation out of the upper end Reactor out and brings it into the regenerator in a suitable manner. The hot one, from the regenerator Coming catalyst can be from the outside to the inside at the lower end of the reactor in the reactor introduce. But you can also pass the hot catalyst through a central tube through the fluidized bed pass through and introduce below the point of addition for the dioxane into the reactor below and then from distribute inside out. Combinations of these two ways are also possible.

After the catalyst has been separated off, the reaction products leave the reactor, are optionally passed over a cyclone to separate any entrained Kaialysatorstaub and immediately afterwards cooled quickly by introduction into a water cycle, which is at a temperature of 40 to 90 ^c . advantageously 50 to 80 ⁰ C is kept. The unreacted feedstock and most of the water vapor used condense here. In addition, most of the formaldehyde formed is dissolved in this water cycle. The gases emerging from the water cycle are cooled in a wide quench system to 0 to 30 ° C., advantageously 5 to 10 ° C. This is where the isoprene formed is mainly deposited. The emerging gases are washed free of formaldehyde in a counter sirom wash using a compressor compressed condensed and fed directly to a CVCv distillation. The organic phases obtained in the two cooling circuits are distilled together, whereby unreacted feedstock is obtained as Sunipf product, which is returned to the cleavage. The top product of this distillation is washed free of formaldehyde with water and the above-mentioned C4 / CV distillation. The subsequent distillation to pure isoprene takes place in a manner known per se. The washing water is advantageously returned to the cooling circuits.

The technical importance of the process described! Is particularly in the conversion of 4,4-Dimet hyl-m-dioxane to isoprene. The dioxane to be used is prepared from isobutene and formaldehyde in a manner known per se, e.g. B. using sulfuric acid as a catalyst in this condensation reaction. It is particularly suitable to use cation exchangers containing sulfonic acid groups as a catalyst on the basis of crosslinked vinyl aromatic polymers for the condensation reaction mentioned, for example the reaction participants - i.e. isobutene and formaldehyde - being passed through a series of reactors with interposed separating containers and learning from the separating containers the hydrocarbon layer is withdrawn and separated by distillation into unconverted hydrocarbons and conversion products, and the hydrocarbons removed from the separation tanks are replaced by fresh or recycled hydrocarbons. _(l0

The crude dioxane obtained by the process described can be used for distillation Obtain pure dioxane and introduce this into the Spalirc action. During the production of the dioxynes are formed by hydration of the isobulene certain amounts (, <; tert-butanol as a by-product of dioxane. F.s is advantageous, this tcrt.-ßutanol not from the dioxane but together with the dioxane in the Bringing cleavage, the presence of the tert-butanol or of it in the reactor itself forming isobutene air beneficial for the expiry of the Cleavage reaction proves

The reaction of isobutene and formaldehyde also forms 4,4-dimethyl-m-dioxane and the tert-butanol also other reaction products, namely enols and diols and other higher boiling points Products. One can use the higher boiling products; in addition to ordinary distillation also in the course of the Remove the implementation of the dioxane cleavage by adding an evaporator to the reactor, in which one introduces the raw dioxane and by introducing superheated steam and circulation of the contents of the evaporator via a heater, the dioxane and the lower-boiling products evaporated and immediately introduced into the reactor. At the lower end of the evaporator, the high-boiling products deducted. The RoMioxane can advantageously be put into the fluidized bed as a whole bring in, it being expediently in liquid form by the Einfüh described above introduces rungsrohrc into the fluidized bed and ensures that a fine distribution of the liquid product when it emerges from the nozzle of the inlet tube is achieved.

During the production of the dioxane described above - as mentioned - glycols are also formed; solve this partly in the aqueous phase of dioxane production. It is possible to do this in the aqueous phase dissolved by-products that are more volatile than water also enter the cleavage process after enrichment to be used, advantageously after prior distribution in the crude dioxane.

example 1

a) The catalyst used for the cleavage of the crude dioxane was prepared as follows:

To produce the support, it was suspended in aqueous silica sol (density 1.20 g / ml, 30 percent by weight SiO ² ) with a BET specific surface area of 200 m 2 / g with the aid of an intensive mixer

1. a silica filler obtained by precipitating sodium silicate solution with calcium chloride solution containing 8% CaO, a BET value of 50 ni ² / g, a sediment volume in toluene of 40 ml and a mean particle diameter according to Andrcasen of 7.5 μ and

2. Medium particle diameter kaolin after Andreasen from b, 3 μ

in such amounts that the finished dry phosphoric acid-free catalyst

47.6% S1O2 from the silica sol,
36.7% of the silica filler and
15.7% kaolin

contained.

100 parts by volume of this suspension were mixed with 10 parts by volume of an aqueous magnesium oxide suspension, which contained 80 g MgO / liter, brought together in a mixing vessel, from where the Mixture supplied to a distributor device. This device was a conically expanding downwards Vessel with a number of!. (Iern immediately

above the bottom of the vessel, which was a few centimeters above the liquid surface of a column filled with o-dichlorobenzene. The suspension mixture solidified into beads of about 0.5 to 2 mm by sol-gel conversion. The granulate was freed from o-dichlorobenzene, dried in a stream of air and then heated to 70O ^{0 C for 2 hours.} The finished granulate had a BET specific surface area of 94 m ² / g, an abrasion value of 0.8% and a water absorption capacity of 54 g / 100 g of granulate.

For further preparation of the catalyst, the granules were impregnated with phosphoric acid so that the final, dried and heated at 600 ^c C catalyst contained 18 weight percent phosphoric acid. The finished catalyst had a specific surface area of 32 m ² / g and an abrasion value of 0.5%.

b) For the cleavage of the crude dioxane, a reactor was used, consisting of a conical bottom tapered pipe made of stainless steel with a diameter of 80 mm and a length of 120 °; the tube was conical at the top extended to 135 mm clear diameter with a length of 600 mm. There was harassment in the reactor arranged to ensure an even distribution of gases and solids. Through the gaseous Reactant, the catalyst was kept fluidized in the reactor. At the bottom A nozzle for supplying the water vapor was arranged in the cone of the reactor.

At the upper end of the cone, a connection was attached to the side for supplying the circulating catalyst. Two nozzles were arranged above the feed point for the catalyst for feeding in the crude dioxane. which evaporated immediately upon exposure to the hot catalyst and water vapor. The reactants - dioxane and water vapor - rose through the catalyst layer, with the cleavage of the dioxane taking place. A catalyst stand was kept in the upper, enlarged part of the reactor and it was here that the gaseous reaction products were separated off from the catalyst. The catalyst, which arrived from a regeneration device, entered the reactor at the bottom hot, rose in cocurrent with the reactants in the reactor, left the reactor in the upper, enlarged part, was freed from adhering organic products that were admixed with the reaction products by stripping with steam and reached the regeneration device via a lift, where it was ^{heated to 600 to 620 °} C. by adding oxygen-containing combustion gases, whereupon it returned to the reactor below, thus closing the circuit. The sensible heat of the catalyst coming from the regenerator was used to evaporate the dioxane, to heat the reaction participants and to generate the heat of the gap.

In the continuously operated apparatus, 10 kg of crude dioxane per hour were passed through the mentioned side nozzles. the 12% tert-butanol. 63% 4,4-dimethyl-1,3-dioxane and 25% higher-boiling products, mainly enols and diols. contained, with a temperature of 25 to 30 ° C on the coming from the regenerator. 510 ⁰ C hot catalyst sprayed. 3.9 kg of water vapor at 400 ° C. per hour were introduced through the nozzle in the lower cone of the reactor. The catalyst was passed through the reactor in an hourly amount of 53 kg. The temperature in the reactor was 260 to 270 ° C. and the pressure 0.2 to 0.3 atmospheric.

The circulating catalyst loses some phosphoric acid in the course of time, so that this has to be replenished. For this purpose, 0.3% tri-iso-butyl-phosphate was added to the oxy-dioxane, which decomposes to isobutene and phosphoric acid under the reaction conditions. This results in a stationary phosphoric acid concentration of 9 to 13% in the circulating catalyst. A specific surface area of 15 to 20 m ² / g is established in the circulating catalyst. When passing through the reactor once, the catalyst absorbs about 0.3% of coke-like products, which are burned off again in the regenerator.

The exiting the top of the reactor gases are led to the deposition of entrained catalyst fines through a cyclone and quenched in a first quencher to about 350 liter / hr circulation water of 50 ⁰ C. The water vapor and the higher-boiling products are condensed in the process. Most of the formaldehyde formed is also taken up by the water here. The residual gases with a temperature of 50 to 60 ^° C. are then further cooled in a second quencher in which a water cycle of around 400 liters is maintained at 10 ° C. In this quench cycle, most of the isoprene formed is condensed consists of isobutene, is washed with water in a bubble-cap washer to remove the remaining formaldehyde and compressed to 5 atmospheres in a compressor and condensed.

A part of each of the two quenching circuits mentioned is branched off into a calming zone and from there the aqueous and organic phases are drawn off separately. The aqueous phase from the calming zone of the second quenching circuit is introduced into the first quenching circuit and the aqueous phase of the calming zone of the first quenching stage, which contains about 15 to 16% formaldehyde and 2 to 3% dioxane, can be used again to recycle the formaldehyde directly to produce dioxane will. The organic phases from the calming zones of both quench circuits are introduced together into a distillation in which O and Ci are drawn off overhead, and the higher-boiling by-products and unreacted dioxane remain in the bottom of the distillation.

The top product of the destination mentioned is combined with the compressor condensate and washed free of formaldehyde in a second washing column. The further separation of the Ca and Cs and the fine purification of the isoprene obtained are then carried out in a known manner.

The washing water running off the laundry mentioned last is the laundry before the compressor abandoned and gets from there into the circuit of the second quencher.

Under these conditions, 86% of the 4,4-dimethyl-1,3-dioxane, 99.5% of the tert-butanol and all higher-boiling products converted, and 2.4 kg of isoprene per hour were obtained, which is about 0.3% n-butenes contained 13 kg of isobutene and 1.61 kg of formaldehyde in addition to 1.0 kg of non-converted dioxane and higher boiling products. This corresponds to an isoprene selectivity of 75.3%. related to implemented » Pure dioxane and a formaldehyde reactivity before 96.5%.

c) That introduced into the Rcaktcr in Example 1 b) Rnh-dioxane was prepared in the following way

In a system of 6 stirred kettles at a temperature of 110 to 115 ° C and a pressure of 20 up to 25 atm. 37% aqueous formaldehyde solution with i-butene, which is in the form of 45.5% i-butene containing C4 cut was implemented. An acidic cation exchanger on the served as a catalyst Based on polystyrene, which was crosslinked with 2 percent by weight divinylbenzene. This catalyst was in a Grain size from 80 to 500 μ and in a concentration of 30 percent by volume, based on the aqueous phase, used. A separator was located behind each 2 kettles, in which the aqueous one under full pressure Formaldehyde solution was separated from the dioxane-containing hydrocarbon layer. The upper phase was in a C <i stripper into unconverted C4 hydrocarbons as top product and crude dioxane separated as the bottom product. The top product of this column was partially returned to the Stirring vessel that follows the separating vessel. The aqueous phase was pressed through the entire cascade. Downstream of the last separator, the pressure was released, the catalyst was separated off by centrifugation and poured into the recycled to the first boiler and the catalyst-free wastewater to remove dissolved reaction products extracted with feed C4 hydrocarbons. The wastewater leaving the facility had one Residual formaldehyde content of 0.4, the residual C4 hydrocarbon mixture leaving the C4 stripper an i-butylene content of 17%.

The crude dioxane obtained as bottom product in the above-mentioned distillation was used without further treatment used in the reaction described in Example 1 b).

Example 2

For the cleavage of the crude dioxane, a reactor was used which had a length of 7 m and consisted of a brick-lined part of length 950 mm and a diameter of 450 mm, into which the hot contact was introduced. There were 35 nozzles for injecting steam at the bottom of the reactor. An additional, cooled nozzle was introduced into a zone above for the addition of dioxane. The actual reactor part also had a diameter of 450 mm and a length of 3150 mm. In this part the catalyst stand was kept at a height of 2 m by overflow. Above the actual reaction part there was a separation space with a diameter of 650 mm and a height of 2250 mm, in which the catalyst carried along was separated out. The catalyst ran into the lower zone of the reactor via a line from the regenerator located above the reactor. Vs rose in the reactor with the Re; ikh> nsgas and ran off over the overflow at the top. In this overflow it was freed from adhering reaction products by wipers with steam and mechanically conveyed back into the regenerator. In the regenerator, the coke on the catalyst was burned off with flue gas at around 600 to 700 ° C., thus maintaining its activity. There

ίο traces of the reaction products on the Phosphoric acid contained in the catalyst was discharged continuously with the reaction product injected phosphoric acid into the reactor together.

The following were used per hour in the reactor:

a) Via the steam nozzles to mix in the catalyst and to maintain the vortex 125 kg steam,

b) 196.5 kg of raw material through the cooled product nozzle dioxane (a mixture of freshly made

Dioxane, the associated share of the recycled dioxar and that in the wastewater of the overall process the proportions of higher boilers after a concentration by distillation to 70 weight percent organic content) with a composition of 62% 4,4-dimethyl-1,3-dioxane. 6.3% tert-butanol, 11.3% water, 20.4% higher-boiling products and 0.2 percent by weight H3PO Maintaining the cleavage activity of the phosphoric ίο acid catalyst,

C; an additional 4.5 kg of steam was fed into the catalyst stripping zone used.

The catalyst cycle was about 2400 kg / h at an inlet ^{temperature of about 510 °} C. into the reactor. The cleavage temperature was 315 to 32O ⁰ C. In the reaction, 77% of the employed 4,4-dimethyl-l, 3-dioxane and about 80% of higher-boiling products were converted on average. The isoprene selectivity was 85%. the formaldehyde selectivity 99%. The basic test time was about 1200 hours.

Following this experiment, the catalyst

only another 1300 hours without dioxane cleavage

with steam to set the mechanical

Checked service life, but at the same time the

discharged phosphoric acid was supplemented.

In parallel to this experiment, the catalyst was in

a laboratory fixed bed reactor is monitored for its chemical activity, the results include the following

Table (two parallel tests each, information in

Percent).

Fresh catalyst 1600 h run time 2200 h run time 2468 h run time

Dioxane sales

Cs selectivity

Formaldehyde select

90/90
74.2 / 71.8 69.8 / 67.1

75.1 / 78.8
75.6 / 72.5
108 / 99.2

91.8 / 91.4
77 / 78.5
110.8 / 110.4

82.8 / 81
74.3 / 76.6
1183 / 120.4

During the entire duration of the experiment, about 0.05 percent by weight of the catalyst was run off every hour the system carried away by abrasion and replaced by fresh contact

Example 3 (comparative example)
Determination of the catalyst abrasion resistance

100 g of catalyst prepared according to Example la are covered with dust through a 400 μ sieve and poured into a glass tube of 50 mm diameter, which is drawn in at the bottom to about 15 mm. A nozzle with 25 mm diameter is inserted into this taper of the Olas tube. In the glass tube there is a 300 mm long metal tube with an internal diameter of 6 mm and an internal diameter of 6 to 8 mm, which carries a baffle plate at the top at a distance of 30 mm from the opening

™ ^ Τ ^{Test If the} catalyst is pushed through the nozzle against the baffle plate for one hour with JOOO I / h of air

shot. The dust is then separated again via the 400 μ sieve and reweighed. The loss expressed as a percentage is called abrasion.

In this test, the catalyst of Example la gives an abrasion of <10.

The catalysts described in Examples 1 and 2 of DT-AS 12 31682 were used for comparison made and brought into the form of balls with a diameter of 0.5 to 2 mm and also in the abrasion apparatus tested.

Both the catalysts prepared according to Example 1 and according to Example 2 of DT-AS 12 31682 delivered abrasion values of> 100 in the test apparatus, i.e. H. test line before one hour has elapsed the catalysts were ground to dust. A Einsat2 of the catalysts according to DT-AS 12 31682 for Cleavage of 4,4-dimethyl-dioxane to isoprene in the gas phase in a fluidized bed therefore does not occur Consideration.

Claims (4)

<f ζ. Patent claims: 1. A process for the continuous cleavage of 4,4-dimethyl-m-dioxane to isoprene in the gas phase in a fluidized bed in the presence of catalysts containing phosphoric acid and with the regeneration of these catalysts, characterized in that one uses catalysts which have been prepared by The suspension obtained is suspended in an aqueous, stable silica sol with a specific surface area of 150 to 400m ² / g silica fillers or predominantly silica-containing fillers with a specific surface area of 30 to 200 m ² / g and also clay minerals from the group kaoiinite, montmorionite and atspulgite gelled to beads in a manner known per se by adding relatively small amounts of an aqueous magnesium oxide suspension, the beads then drying, ^{heated to 500 to 1000 °} C. for at least 10 minutes, then mixed with 5 to 30% phosphoric acid and ^{heated to 300 to 650 °} C., and that the catalysts thus obtained between a reaction space f For the splitting of 4,4-dimethyl-m-dioxane and a regeneration chamber for burning off the carbon-containing products deposited on the catalyst in the reactor, 3 to 10 parts by weight of 1 part by weight of 4,4-dimethyl-m-dioxane are circulated. 2. The method according to claim 1, characterized in that that the catalyst is in the form of beads with a size of 0.2 to 2 mm in diameter applies. 3. The method according to claim 2, characterized by dadu-.xh, that the catalyst is in the form of beads with a size of 0.3 to 1.5 mm Diameter used. 4. The method according to claim 1 to 3, characterized in that the 4,4-dimethyl-m-dioxane and passing the catalyst cocurrently up through the reactor and at the top At the end of the reactor, the separation between the catalyst and the reaction products is carried out, whereby one advantageously removes the catalyst by stripping with inert gases, advantageous Water vapor, freed from adhering volatile organic compounds and these the reaction products feeds.