Reactor for carrying out an autothermal gas-phase dehydrogenation

The invention claimed is: 1. A reactor in the form of a cylinder having a vertical longitudinal axis for carrying out an autothermal gas-phase dehydrogenation of a hydrocarbon-comprising gas stream by means of an oxygen-comprising gas stream to give a reaction gas mixture over a heterogeneous catalyst which is configured as a monolith, wherein one or more catalytically active zones each comprising a packing composed of monoliths stacked next to one another and/or above one another are arranged in the interior space of the reactor and a mixing zone having fixed internals is provided upstream of each catalytically active zone, with one or more feed lines for the hydrocarbon-comprising gas stream to be dehydrogenated at the lower end of the reactor, with one or more independently regulable feed lines, where each independently regulable feed line supplies one or more distributors, for the oxygen-comprising gas stream into each of the mixing zones and with one or more discharge lines for the reaction gas mixture of the autothermal gas-phase dehydrogenation at the upper end of the reactor, where the interior wall of the reactor is provided over its entire area with an insulation layer, and where the one or each of the plurality of catalytically active zones each comprising a packing composed of monoliths stacked next to one another and/or above one another including the mixing zone having fixed internals and being provided upstream of each catalytically active zone, the one or more independently regulable feed lines, and the one or more distributors, each supplied by one independently regulable feed line, is designed as one component which can individually be mounted and removed. 2. The reactor according to claim 1 , wherein the component can individually be mounted and removed by means of flanges. 3. The reactor according to claim 1 , wherein the insulation layer is a double layer having a first pressure-stable layer resting against the interior wall of the reactor and a second layer formed by an expandable mat facing the interior of the reactor in the region of the catalytically active zones and is in the form of a single layer composed of a high-temperature-stable fiber mat provided on the side facing the interior of the reactor with a sheet metal cladding in the other regions. 4. The reactor according to claim 1 , wherein the packing composed of monoliths stacked next to one another and above one another rests on a support grating, with the region directly adjoining the support grating being provided with one or more layers of monoliths which have channels having a larger cross section compared to the other monoliths located further away from the support grating. 5. The reactor according to claim 4 , wherein the region directly adjoining the support grating is provided with a layer of an open-pored foam ceramic having a gap volume through which flow occurs of from 70 to 90%. 6. The reactor according to claim 4 , wherein the region directly adjoining the support grating is provided with a first layer of a high-porosity open-pored foam ceramic and a second layer formed by monoliths which have channels having a larger cross section compared to the other monoliths located further away from the support grating is located above the first layer. 7. The reactor according to claim 1 , wherein a heat exchanger is arranged above the uppermost catalytically active zone or outside the reactor, where the hydrocarbon-comprising gas stream to be dehydrogenated is introduced via a feed line into the heat exchanger, heated by the reaction gas mixture in countercurrent by indirect heat exchange in the heat exchanger and conveyed further to the lower end of the reactor, introduced via a port into the reactor and mixed with the oxygen-comprising gas stream in the mixing zones, whereupon the autothermal gas-phase dehydrogenation takes place in the reactor. 8. The reactor according to claim 7 , wherein the heat exchanger can be mounted and removed by means of flanges. 9. The reactor according to claim 7 , wherein the hydrocarbon-comprising gas stream to be dehydrogenated is introduced at two or more points into the heat exchanger, preferably as a main stream having a relatively high mass flow and one or more secondary streams having a lower mass flow than the main stream. 10. The reactor according to claim 7 , wherein one or more supplementary heating facilities are provided in addition to the heat exchanger for the hydrocarbon-comprising gas stream to be dehydrogenated. 11. The reactor according to claim 10 , wherein an electric heating element, which is preferably configured so as to be detachable, as a plug-in system or as a muffle burner, is provided as supplementary heating facility in the hydrocarbon-comprising gas stream to be dehydrogenated after the stream leaves the heat exchanger. 12. The reactor according to claim 1 , wherein two or more catalytically active zones each having a packing composed of monoliths stacked next to one another and above one another are provided in the reactor. 13. The reactor according to claim 1 , wherein the monoliths within the same catalytically active zone in each case have a different catalytic activity. 14. The reactor according to claim 12 , wherein the two or more catalytically active zones in each case have a different catalytic activity. 15. The reactor according to claim 1 , wherein the monoliths stacked next to one another and above one another to form a packing are enveloped in an expandable mat or in a mineral fiber nonwoven and inserted in a casing having a clamping device. 16. The reactor according to claim 1 , wherein each mixing zone comprises in each case a tube distributor configured as a plurality of parallel plug-in tubes which are arranged in a plane perpendicular to the longitudinal direction of the reactor and are connected to one or more distribution chambers and have a plurality of uniformly spaced exit openings for the oxygen-comprising gas stream from the plug-in tubes, and also a plurality of uniformly spaced mixing elements. 17. The reactor according to claim 4 , wherein the region directly adjoining the support grating is provided with a first layer of a high-porosity open-pored foam ceramic, with a height from 10 to 100 mm, and a second layer formed by monoliths which have channels having a larger cross section compared to the other monoliths located further away from the support grating is located above the first layer. 18. A process comprising carrying out an autothermal gas-phase dehydrogenation in the reactor according to claim 1 , wherein the autothermal gas-phase dehydrogenation is a dehydrogenation of propane, of butane, of isobutane, of butene to butadiene, of ethylbenzene to styrene or of ethane to ethene.